ABCA4 p.Arg212Cys

ClinVar:	c.635G>A , p.Arg212His N , Benign c.634C>T , p.Arg212Cys D , Pathogenic
Predicted by SNAP2:	A: D (71%), C: D (80%), D: D (66%), E: D (66%), F: D (75%), G: D (66%), H: D (59%), I: D (71%), K: N (72%), L: D (71%), M: D (71%), N: N (57%), P: D (66%), Q: D (59%), S: N (53%), T: N (53%), V: D (91%), W: D (85%), Y: D (71%),
Predicted by PROVEAN:	A: D, C: D, D: D, E: N, F: D, G: D, H: N, I: D, K: N, L: D, M: D, N: N, P: D, Q: N, S: N, T: N, V: D, W: D, Y: D,

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[hide] Spectrum of ABCR gene mutations in autosomal reces... Eur J Hum Genet. 1998 May-Jun;6(3):291-5. Rozet JM, Gerber S, Souied E, Perrault I, Chatelin S, Ghazi I, Leowski C, Dufier JL, Munnich A, Kaplan J
Spectrum of ABCR gene mutations in autosomal recessive macular dystrophies.
Eur J Hum Genet. 1998 May-Jun;6(3):291-5., [PMID:9781034]

Abstract [show]
Stargardt disease (STGD) and late-onset fundus flavimaculatus (FFM) are autosomal recessive conditions leading to macular degenerations in childhood and adulthood, respectively. Recently, mutations of the photoreceptor cell-specific ATP binding transporter gene (ABCR) have been reported in Stargardt disease. Here, we report on the screening of the whole coding sequence of the ABCR gene in 40 unrelated STGD and 15 FFM families and we show that mutations truncating the ABCR protein consistently led to STGD. Conversely, all mutations identified in FFM were missense mutations affecting uncharged amino acids. These results provide the first genotype-phenotype correlations in ABCR gene mutations.

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34 By contrast, in the second and third families, the grandmothers affected with AMD were found to carry one of the two different mutations identified in their grandsons affected with Stargardt disease (R1107C, family JUL; R212C, family JEG; see Table 1).

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ABCA4 p.Arg212Cys 9781034:34:220

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45 Furthermore, all ABCR missense mutations Table 1 Mutations in the ABCR gene in STGD and FFM families Conserved aa in: Nucleotide change Amino acid change Domain ABCs RmP Phenotype Families Comment (571-2)A®G splicing mutation STGD 1 HAD1 (1938-2)A®G splicing mutation STGD 1 (4668+2)T®C splicing mutation STGD 1 (4735+2)T®A splicing mutation STGD 1 del(5196+1-5196+6 splicing mutation STGD 1 LOZ2 2570 delT frameshift mutation STGD 1 3209insGT frameshift mutation STGD 2 CHE2 G3754T E1252X STGD 1 C3994T Q1332X STGD 1 C6337G I2113X STGD 1 JEG2 C52T R18W IC - + STGD 1 C634T R212C EC - + STGD 5 GEN2, JEG2 G1908T Q636H IC - + STGD 1 LOZ2 C3056T T1019M IC - + STGD 1 C3322T R1107C IC - + STGD 1 JUL2 C4916T R1640W IC + + STGD 2 MAR1 G5929A G1977S ATP2 + + STGD 1 GEN2 G6320A R2107H IC + + STGD 1 JUL2 C3114T A1038V IC - + STGD 2 CHE2 +FFM +1 VII2 T1622C L541P EC - + FFM 1 VII2 T31C L11P IC + + FFM 1 G3272A G1090E IC + + FFM 1 G4522T G1508C IC + + FFM 1 C5908T L1970F IC + + FFM 1 GON2 T5912G L1971R IC + + FFM 1 GON2 Mutations refer to the standard nomenclature.

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ABCA4 p.Arg212Cys 9781034:45:594

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[hide] Role of the C terminus of the photoreceptor ABCA4 ... J Biol Chem. 2009 Feb 6;284(6):3640-9. Epub 2008 Dec 4. Zhong M, Molday LL, Molday RS
Role of the C terminus of the photoreceptor ABCA4 transporter in protein folding, function, and retinal degenerative diseases.
J Biol Chem. 2009 Feb 6;284(6):3640-9. Epub 2008 Dec 4., [PMID:19056738]

Abstract [show]
ABCA4 is an ATP-binding cassette transporter that is expressed in rod and cone photoreceptor cells and implicated in the removal of retinal derivatives from outer segments following photoexcitation. Mutations in the ABCA4 gene are responsible for a number of related retinal degenerative diseases, including Stargardt macular degeneration, cone-rod dystrophy, retinitis pigmentosa, and age-related macular degeneration. In order to determine the role of the C terminus of ABCA4 in protein structure and function and understand mechanisms by which C-terminal mutations cause retinal degenerative diseases, we have expressed and purified a series of deletion and substitution mutants of ABCA4 and ABCA1 in HEK 293T cells for analysis of their cellular localization and biochemical properties. Removal of the C-terminal 30 amino acids of ABCA4, including a conserved VFVNFA motif, resulted in a loss in N-retinylidene-phosphatidylethanolamine substrate binding, ATP photoaffinity labeling, and retinal-stimulated ATPase activity. This mutant was also retained in the endoplasmic reticulum of cells. Replacement of the VFVNFA motif with alanine residues also resulted in loss in function and cellular mislocalization. In contrast, C-terminal deletion mutants that retain the VFVNFA motif were functionally active and localized to intracellular vesicles similar to wild-type ABCA4. Our studies indicated that the VFVNFA motif is required for the proper folding of ABCA4 into a functionally active protein. This motif also contributes to the efficient folding of ABCA1 into an active protein. Our results provide a molecular based rationale for the disease phenotype displayed by individuals with mutations in the C terminus of ABCA4.

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261 A patient with cone-rod dystrophy was reported to be compound heterozygous for a 6730-16del44 mutation, which causes the loss in the C-terminal 29 amino acids of ABCA4, including the VFVNFA motif and a R212C missense mutation (26).

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ABCA4 p.Arg212Cys 19056738:261:4

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ABCA4 p.Arg212Cys 19056738:261:202

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263 The R212C missense mutation appears to retain some of its activity at least with respect to azido-ATP photoaffinity labeling (21).

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ABCA4 p.Arg212Cys 19056738:263:4

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260 A patient with cone-rod dystrophy was reported to be compound heterozygous for a 6730-16del44 mutation, which causes the loss in the C-terminal 29 amino acids of ABCA4, including the VFVNFA motif and a R212C missense mutation (26).

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ABCA4 p.Arg212Cys 19056738:260:202

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262 The R212C missense mutation appears to retain some of its activity at least with respect to azido-ATP photoaffinity labeling (21).

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ABCA4 p.Arg212Cys 19056738:262:4

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259 A patient with cone-rod dystrophy was reported to be compound heterozygous for a 6730-16del44 mutation, which causes the loss in the C-terminal 29 amino acids of ABCA4, including the VFVNFA motif and a R212C missense mutation (26).

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ABCA4 p.Arg212Cys 19056738:259:202

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[hide] Correlation between photoreceptor layer integrity ... Invest Ophthalmol Vis Sci. 2012 Jul 3;53(8):4409-15. doi: 10.1167/iovs.11-8201. Print 2012 Jul. Testa F, Rossi S, Sodi A, Passerini I, Di Iorio V, Della Corte M, Banfi S, Surace EM, Menchini U, Auricchio A, Simonelli F
Correlation between photoreceptor layer integrity and visual function in patients with Stargardt disease: implications for gene therapy.
Invest Ophthalmol Vis Sci. 2012 Jul 3;53(8):4409-15. doi: 10.1167/iovs.11-8201. Print 2012 Jul., [PMID:22661472]

Abstract [show]
PURPOSE: To perform a clinical characterization of Stargardt patients with ABCA4 gene mutation, and to investigate the correlation between the inner and outer segment (IS/OS) junction morphology and visual acuity, fundus lesions, electroretinogram abnormalities, and macular sensitivity. METHODS: Sixty-one patients with Stargardt disease (STGD) were given a comprehensive ophthalmic examination. Inner-outer photoreceptor junction morphology evaluated by spectral-domain optical coherence tomography was correlated with visual acuity, fundus lesions, fundus autofluorescence, full-field and multifocal electroretinography responses, and microperimetric macular sensitivities. We classified STGD patients into three groups: (1) IS/OS junction disorganization in the fovea, (2) IS/OS junction loss in the fovea, and (3) extensive loss of IS/OS junction. Mutation analysis of the ABCA4 gene was carried out by sequencing the complete coding region. RESULTS: A significant difference in visual acuity was observed between IS/OS groups 1 and 2 and between IS/OS groups 2 and 3 (P < 0.0001). A significant difference in microperimetry sensitivity was observed between IS/OS groups 2 and 3, and between IS/OS groups 1 and 3 (P < 0.0001). There was also a statistically significant correlation between IS/OS abnormalities and the extent of fundus lesions (Spearman P </= 0.01), as well as with the type of ERG and multifocal ERG results (Spearman P </= 0.01). Finally, the degree of IS/OS junction preservation showed a statistically significant correlation with the extension of foveal abnormalities assessed by fundus autofluorescence imaging (Spearman P </= 0.01). The G1961E mutation was more frequent in the patients without extensive loss of IS/OS junction (P = 0.01) confirming its association with a milder STGD phenotype. CONCLUSIONS: The results of this study suggest that a comprehensive approach in the examination of Stargardt patients has the potential to improve the understanding of vision loss and may provide a sensitive measure to evaluate the efficacy of future experimental therapies in patients with STGD.

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66 Clinical and Molecular Data of STGD Patients Patient ID/Fam Age (y) Visual Acuity OCT ft (lm) MP (dB) IS/OS* Fundus† FAF‡ ERG§ mfERGjj Mutation 1 Mutation 2 4/2 50 0.0715 134 5.25 - 1 - 2 4 G1961E 250InsCAAA 5/2 47 0.1 127 14.2 2 1 1 1 3 G1961E 250InsCAAA 6/3 33 0.05 125 9.8 2 2 2 1 3 G1961E R2149X 7/4 18 0.085 135 0 - 2 - 3 4 5917del G 5917del G 8/5 16 0.095 104 0.9 3 2 3 3 4 L541P; A1038V L541P; A1038V 9/6 71 0.03 109 0 3 3 3 2 4 IVS35þ2t > c G1961E 11/7 46 0.2 137 9.35 2 1 2 1 1 Y850K A1598D 13/8 35 0.017 163 0 - 3 - 3 4 L541P R1098C 15/10 20 0.1 135.5 11.05 2 1 1 1 4 IVS35þ2t > c G1961E 16/11 20 0.47 96 16.7 2 1 2 1 2 L541P; A1038V L541P; A1038V 17/11 34 0.1 114.5 7.55 2 1 2 1 3 L541P; A1038V L541P; A1038V 18/11 18 1 134 16.15 1 1 1 1 3 L541P; A1038V L541P; A1038V 19/12 12 0.12 242 6.5 3 1 2 1 2 L541P; A1038V L541P; A1038V 20/13 28 0.1 111 14.2 2 2 2 1 3 R1443H IVS35þ2t > c 21/14 34 0.2 152 14.15 2 1 2 2 4 R653C G1961E 22/15 69 0.079 122 0 3 3 3 3 4 I1562T R2149X 23/15 46 0.55 162 1.05 3 3 3 3 4 I1562T IVS45þ1g > c 25/16 28 0.11 105.5 3.1 3 2 2 3 4 R212C R212C 26/17 13 0.084 138.5 0.2 3 2 3 1 3 R18W C1490Y 27/4 20 0.0775 131 0 - 3 - 3 4 5917del G 5917del G 28/4 23 0.042 159.5 0 - 3 - 3 4 5917del G 5917del G 30/18 29 0.0375 103 0 3 3 3 3 4 N965S G1961E 31/19 17 0.1 102 9 3 2 2 3 4 L541P F655C 38/20 20 0.225 95 16 2 1 1 3 4 L541P G1961E 39/21 20 0.17 146 16.7 2 1 1 1 3 G1961E R2030X 42/22 43 0.575 127 7.05 2 1 2 1 2 250insCAAA G1961E 43/23 12 0.1 117.5 11.55 2 2 2 1 3 IVS40þ5g > a IVS15-8g > a 44/24 29 0.1 149 18.5 2 1 2 1 3 G1961E 4736del6bpins2bp 46/25 38 0.0075 182.5 0 - 3 - 3 4 G618R G1972R 48/26 35 0.46 133.5 12.25 2 1 - 1 3 4538insC G1961E 50/27 13 0.2 122.5 17.35 2 1 2 1 3 IVS35þ2t > c G1961E 51/28 24 0.065 123 0 3 3 3 3 4 250InsCAAA V767D 52/29 14 1 147 6.15 1 1 1 3 4 L2027F A1881V 53/30 45 0.1 120 6.05 3 2 2 1 3 G1961E R2030X 54/30 24 0.09 159 2.65 3 3 3 3 4 V767D R2030X 55/31 34 0.085 150 5.15 3 3 3 3 4 N96H IVS40þ5g > a 56/32 48 0.0335 118.5 4.4 - 3 - 2 4 IVS35þ2t > c G1961E 58/32 52 0.05 124 5.8 3 2 2 2 4 IVS35þ2t > c G1961E 60/33 43 0.065 163 15.95 2 1 - 1 2 250InsCAAA G1961E 61/34 45 0.03 187.5 4.5 1 1 1 2 1 R1640Q G1961E 64/35 33 0.0665 158 0 3 3 3 3 4 C2150R 2626InsTTT 65/35 38 0.008 172 0.05 3 3 3 3 4 C2150R 2626InsTTT 66/36 42 0.4 137 0.95 3 2 2 1 3 N96D IVS40þ5g > a 67/37 14 0.235 132 0.15 3 2 3 3 4 IVS6-2a > t IVS6-2a > t 69/38 19 0.09 120 0 3 1 2 1 3 R511H N529S 70/39 42 0.515 140 0.4 3 3 3 3 4 IVS40þ5g > a N965S 72/40 33 0.096 116.5 5.1 3 2 2 1 3 N96D L2140Q 73/41 17 0.1 160 14.35 2 2 2 3 4 G690D A1598D 74/42 36 0.0125 142.5 0 3 3 3 3 4 N96H N96H 75/43 45 0.2 214.5 11.7 2 1 2 1 3 IVS35þ2t > c G1961E 77/44 19 0.34 137.5 11.75 2 1 - 1 3 G1961E G618R 81/45 66 0.335 163 2 - 3 - 2 4 N96D G1961E 82/46 41 0.1 116.5 0.15 3 3 3 3 4 4538insC IVS40þ5g > a 83/47 17 0.395 165 19.25 1 1 1 1 2 G1961E IVS45þ1g > c 84/47 26 0.135 120 16.2 2 1 2 1 3 G1961E IVS45þ1g > c 85/48 10 0.16 149.5 12.4 2 2 2 1 3 IVS35þ2t > c IVS40þ5g > a 87/40 25 0.9 155 15 2 1 2 1 2 N96D L2140Q 88/49 32 0.0715 144 0.1 - 3 - 3 4 IVS45þ1g > c R2149X 89/50 14 0.1185 147 1.85 3 1 - 3 4 P402A 250insCAAA 90/51 35 0.07 116.5 0 - 3 - 3 4 A1598D R2030X 94/52 30 0.1 144 12.85 2 1 - 1 1 A1598D G1961E Fam, family; OCT ft, optical coherence tomography foveal thickness; MP, microperimetry; IS/OS, inner-outer segment junction; FAF, fundus autofluorescence; ERG, electroretinogram; mfERG, multifocal-electroretinogram.

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ABCA4 p.Arg212Cys 22661472:66:1108

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ABCA4 p.Arg212Cys 22661472:66:1114

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67 Clinical and Molecular Data of STGD Patients Patient ID/Fam Age (y) Visual Acuity OCT ft (lm) MP (dB) IS/OS* Fundusߤ FAFߥ ERG&#a7; mfERGjj Mutation 1 Mutation 2 4/2 50 0.0715 134 5.25 - 1 - 2 4 G1961E 250InsCAAA 5/2 47 0.1 127 14.2 2 1 1 1 3 G1961E 250InsCAAA 6/3 33 0.05 125 9.8 2 2 2 1 3 G1961E R2149X 7/4 18 0.085 135 0 - 2 - 3 4 5917del G 5917del G 8/5 16 0.095 104 0.9 3 2 3 3 4 L541P; A1038V L541P; A1038V 9/6 71 0.03 109 0 3 3 3 2 4 IVS35&#fe;2t > c G1961E 11/7 46 0.2 137 9.35 2 1 2 1 1 Y850K A1598D 13/8 35 0.017 163 0 - 3 - 3 4 L541P R1098C 15/10 20 0.1 135.5 11.05 2 1 1 1 4 IVS35&#fe;2t > c G1961E 16/11 20 0.47 96 16.7 2 1 2 1 2 L541P; A1038V L541P; A1038V 17/11 34 0.1 114.5 7.55 2 1 2 1 3 L541P; A1038V L541P; A1038V 18/11 18 1 134 16.15 1 1 1 1 3 L541P; A1038V L541P; A1038V 19/12 12 0.12 242 6.5 3 1 2 1 2 L541P; A1038V L541P; A1038V 20/13 28 0.1 111 14.2 2 2 2 1 3 R1443H IVS35&#fe;2t > c 21/14 34 0.2 152 14.15 2 1 2 2 4 R653C G1961E 22/15 69 0.079 122 0 3 3 3 3 4 I1562T R2149X 23/15 46 0.55 162 1.05 3 3 3 3 4 I1562T IVS45&#fe;1g > c 25/16 28 0.11 105.5 3.1 3 2 2 3 4 R212C R212C 26/17 13 0.084 138.5 0.2 3 2 3 1 3 R18W C1490Y 27/4 20 0.0775 131 0 - 3 - 3 4 5917del G 5917del G 28/4 23 0.042 159.5 0 - 3 - 3 4 5917del G 5917del G 30/18 29 0.0375 103 0 3 3 3 3 4 N965S G1961E 31/19 17 0.1 102 9 3 2 2 3 4 L541P F655C 38/20 20 0.225 95 16 2 1 1 3 4 L541P G1961E 39/21 20 0.17 146 16.7 2 1 1 1 3 G1961E R2030X 42/22 43 0.575 127 7.05 2 1 2 1 2 250insCAAA G1961E 43/23 12 0.1 117.5 11.55 2 2 2 1 3 IVS40&#fe;5g > a IVS15-8g > a 44/24 29 0.1 149 18.5 2 1 2 1 3 G1961E 4736del6bpins2bp 46/25 38 0.0075 182.5 0 - 3 - 3 4 G618R G1972R 48/26 35 0.46 133.5 12.25 2 1 - 1 3 4538insC G1961E 50/27 13 0.2 122.5 17.35 2 1 2 1 3 IVS35&#fe;2t > c G1961E 51/28 24 0.065 123 0 3 3 3 3 4 250InsCAAA V767D 52/29 14 1 147 6.15 1 1 1 3 4 L2027F A1881V 53/30 45 0.1 120 6.05 3 2 2 1 3 G1961E R2030X 54/30 24 0.09 159 2.65 3 3 3 3 4 V767D R2030X 55/31 34 0.085 150 5.15 3 3 3 3 4 N96H IVS40&#fe;5g > a 56/32 48 0.0335 118.5 4.4 - 3 - 2 4 IVS35&#fe;2t > c G1961E 58/32 52 0.05 124 5.8 3 2 2 2 4 IVS35&#fe;2t > c G1961E 60/33 43 0.065 163 15.95 2 1 - 1 2 250InsCAAA G1961E 61/34 45 0.03 187.5 4.5 1 1 1 2 1 R1640Q G1961E 64/35 33 0.0665 158 0 3 3 3 3 4 C2150R 2626InsTTT 65/35 38 0.008 172 0.05 3 3 3 3 4 C2150R 2626InsTTT 66/36 42 0.4 137 0.95 3 2 2 1 3 N96D IVS40&#fe;5g > a 67/37 14 0.235 132 0.15 3 2 3 3 4 IVS6-2a > t IVS6-2a > t 69/38 19 0.09 120 0 3 1 2 1 3 R511H N529S 70/39 42 0.515 140 0.4 3 3 3 3 4 IVS40&#fe;5g > a N965S 72/40 33 0.096 116.5 5.1 3 2 2 1 3 N96D L2140Q 73/41 17 0.1 160 14.35 2 2 2 3 4 G690D A1598D 74/42 36 0.0125 142.5 0 3 3 3 3 4 N96H N96H 75/43 45 0.2 214.5 11.7 2 1 2 1 3 IVS35&#fe;2t > c G1961E 77/44 19 0.34 137.5 11.75 2 1 - 1 3 G1961E G618R 81/45 66 0.335 163 2 - 3 - 2 4 N96D G1961E 82/46 41 0.1 116.5 0.15 3 3 3 3 4 4538insC IVS40&#fe;5g > a 83/47 17 0.395 165 19.25 1 1 1 1 2 G1961E IVS45&#fe;1g > c 84/47 26 0.135 120 16.2 2 1 2 1 3 G1961E IVS45&#fe;1g > c 85/48 10 0.16 149.5 12.4 2 2 2 1 3 IVS35&#fe;2t > c IVS40&#fe;5g > a 87/40 25 0.9 155 15 2 1 2 1 2 N96D L2140Q 88/49 32 0.0715 144 0.1 - 3 - 3 4 IVS45&#fe;1g > c R2149X 89/50 14 0.1185 147 1.85 3 1 - 3 4 P402A 250insCAAA 90/51 35 0.07 116.5 0 - 3 - 3 4 A1598D R2030X 94/52 30 0.1 144 12.85 2 1 - 1 1 A1598D G1961E Fam, family; OCT ft, optical coherence tomography foveal thickness; MP, microperimetry; IS/OS, inner-outer segment junction; FAF, fundus autofluorescence; ERG, electroretinogram; mfERG, multifocal-electroretinogram. Statistics Our set of data is described by continuous (BCVA, OCT foveal thickness, and macular sensitivities) and categorical (fundus, FAF, IS/ OS, ERG, and mfERG groups) variables.

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ABCA4 p.Arg212Cys 22661472:67:1101

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ABCA4 p.Arg212Cys 22661472:67:1107

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[hide] A subgroup of age-related macular degeneration is ... Invest Ophthalmol Vis Sci. 2012 Apr 30;53(4):2112-8. doi: 10.1167/iovs.11-8785. Print 2012 Apr. Fritsche LG, Fleckenstein M, Fiebig BS, Schmitz-Valckenberg S, Bindewald-Wittich A, Keilhauer CN, Renner AB, Mackensen F, Mossner A, Pauleikhoff D, Adrion C, Mansmann U, Scholl HP, Holz FG, Weber BH
A subgroup of age-related macular degeneration is associated with mono-allelic sequence variants in the ABCA4 gene.
Invest Ophthalmol Vis Sci. 2012 Apr 30;53(4):2112-8. doi: 10.1167/iovs.11-8785. Print 2012 Apr., [PMID:22427542]

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Purpose. Age-related macular degeneration (AMD) is a heterogeneous condition of high prevalence and complex etiology involving genetic as well as environmental factors. By fundus autofluorescence (FAF) imaging, AMD can be classified into several distinct phenotypes, with one subgroup characterized by fine granular pattern with peripheral punctate spots (GPS[+]). Some features of GPS[+] overlap with Stargardt disease (STGD1), a recessive macular dystrophy caused by biallelic sequence variants in the ATP-binding cassette transporter 4 (ABCA4) gene. The aim of this study was to investigate the role of ABCA4 in GPS[+]. Methods. The ABCA4 gene was sequenced in 25 patients with the GPS[+] phenotype and 29 with geographic atrophy (GA)-AMD but no signs of GPS (GPS[-]). In addition, frequencies of risk-increasing alleles at three known AMD susceptibility loci, including complement factor H (CFH), age-related maculopathy susceptibility 2 (ARMS2), and complement component 3 (C3), were evaluated. Results. We demonstrate that GPS[+] is associated significantly with monoallelic ABCA4 sequence variants. Moreover, frequencies of AMD risk-increasing alleles at CFH, ARMS2, and C3 are similar in GPS[+] and STGD1 patients, with risk allele frequencies in both subcategories comparable to population-based control individuals estimated from 3,510 individuals from the NHLBI Exome Sequencing Project. Conclusions. Our data suggest that the GPS[+] phenotype is accounted for by monoallelic variants in ABCA4 and unlikely by the well-established AMD risk-increasing alleles at CFH, ARMS2, and C3. These findings provide support for a complex role of ABCA4 in the etiology of a minor proportion of patients with AMD.

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93 These patients were heterozygous for variants c.634C>T (p.R212C), c.4556C>G (p.T1519R), and c.6148G>C (p.V2050L), respectively.

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ABCA4 p.Arg212Cys 22427542:93:58

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91 These patients were heterozygous for variants c.634C>T (p.R212C), c.4556C>G (p.T1519R), and c.6148G>C (p.V2050L), respectively.

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ABCA4 p.Arg212Cys 22427542:91:58

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[hide] Macular function in macular degenerations: repeata... Invest Ophthalmol Vis Sci. 2012 Feb 21;53(2):841-52. Print 2012 Feb. Cideciyan AV, Swider M, Aleman TS, Feuer WJ, Schwartz SB, Russell RC, Steinberg JD, Stone EM, Jacobson SG
Macular function in macular degenerations: repeatability of microperimetry as a potential outcome measure for ABCA4-associated retinopathy trials.
Invest Ophthalmol Vis Sci. 2012 Feb 21;53(2):841-52. Print 2012 Feb., [PMID:22247458]

Abstract [show]
PURPOSE: To measure macular visual function in patients with unstable fixation, to define the photoreceptor source of this function, and to estimate its test-retest repeatability as a prerequisite to clinical trials. METHODS: Patients (n = 38) with ABCA4-associated retinal degeneration (RD) or with retinitis pigmentosa (RP) were studied with retina-tracking microperimetry along the foveo-papillary profile between the fovea and the optic nerve head, and point-by-point test-retest repeatability was estimated. A subset with foveal fixation was also studied with dark-adapted projection perimetry using monochromatic blue and red stimuli along the horizontal meridian. RESULTS: Macular function in ABCA4-RD patients transitioned from lower sensitivity at the parafovea to higher sensitivity in the perifovea. RP patients had the inverse pattern. Red-on-red microperimetric sensitivities successfully avoided ceiling effects and were highly correlated with absolute sensitivities. Point-by-point test-retest limits (95% confidence intervals) were +/-4.2 dB; repeatability was not related to mean sensitivity, eccentricity from the fovea, age, fixation location, or instability. Repeatability was also not related to the local slope of sensitivity and was unchanged in the parapapillary retina. CONCLUSIONS: Microperimetry allows reliable testing of macular function in RD patients without foveal fixation in longitudinal studies evaluating natural disease progression or efficacy of therapeutic trials. A single estimate of test-retest repeatability can be used to determine significant changes in visual function at individual retinal loci within diseased regions that are homogeneous and those that are heterogeneous and also in transition zones at high risk for disease progression.

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42 Clinical and Molecular Characteristics of the ABCA4 Patients Patient Age (y)/Sex ABCA4 Mutation Clinical Diagnosis Visual Acuity* Kinetic Visual Field Extent (V-4e)†Allele 1 Allele 2 Foveal Fixation P1‡ 12/M N965S W821R STGD 20/20 97 P2‡ 17/F V989A IVS28ϩ5 GϾT STGD 20/100 90 P3 18/M G1961E R1129L§ STGD 20/100 105 P4 21/F R212C P68R STGD 20/125 101 P5 24/M P1511 del1ccgC R1705Q STGD 20/25 114 P6 31/M G863A R1108C STGD 20/25 105 P7 32/F IVS40ϩ5 GϾA V935A STGD 20/32 103 P8 34/M G1961E - CRD 20/32 98 P9 37/F R681X P309R STGD 20/20 109 P10 39/M G1961E C54Y§ STGD 20/40 101 P11‡ 42/F G1961E V256V STGD 20/32 105 P12‡ 46/F G1961E V256V STGD 20/32 106 P13 52/F G1961E P1380L STGD 20/40 105 P14 58/M D600E R18W§ STGD 20/40 84 Extrafoveal Fixation P15 11/M V256V T1526M CRD 20/200 102 P16 15/M C54Y IVS35ϩ2 TϾC STGD 20/200 96 P17‡ 16/F V989A IVS28ϩ5 GϾT STGD 20/100 100 P18‡ 16/M N965S W821R STGD 20/125 100 P19 19/F A1038V/L541P N965S STGD 20/400 90 P20 21/M G863A IVS35ϩ2 TϾC STGD 20/200 99 P21 22/F G1961E R152X STGD 20/50 104 P22 27/M G863A P1660S§ STGD 20/100 98 P23 27/F G1961E A1038V/L541P STGD 20/100 109 P24 29/M G1961E T1019M STGD 20/100 104 P25 33/M P1486L deletion of exon 7 STGD 20/400 98 P26 36/F G863A C1490Y STGD 20/100 93 P27 41/M A1038V/L541P - STGD 20/125 108 P28 49/F T1526M R2030Q STGD 20/125 98 P29 55/F W855X - STGD 20/160 87 P30 56/F G1961E IVS37ϩ1 GϾA§ STGD 20/125 89 P31 60/F G1961E M669 del2ccAT STGD 20/125 104 STGD, Stargardt disease; CRD, cone-rod dystrophy.

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ABCA4 p.Arg212Cys 22247458:42:358

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[hide] Stargardt macular dystrophy: common ABCA4 mutation... Mol Vis. 2012;18:280-9. Epub 2012 Feb 1. Roberts LJ, Nossek CA, Greenberg LJ, Ramesar RS
Stargardt macular dystrophy: common ABCA4 mutations in South Africa--establishment of a rapid genetic test and relating risk to patients.
Mol Vis. 2012;18:280-9. Epub 2012 Feb 1., [PMID:22328824]

Abstract [show]
PURPOSE: Based on the previous indications of founder ATP-binding cassette sub-family A member 4 gene (ABCA4) mutations in a South African subpopulation, the purpose was to devise a mechanism for identifying common disease-causing mutations in subjects with ABCA4-associated retinopathies (AARs). Facilitating patient access to this data and determining the frequencies of the mutations in the South African population would enhance the current molecular diagnostic service offered. METHODS: The majority of subjects in this study were of Caucasian ancestry and affected with Stargardt macular dystrophy. The initial cohort consisted of DNA samples from 181 patients, and was screened using the ABCR400 chip. An assay was then designed to screen a secondary cohort of 72 patients for seven of the most commonly occurring ABCA4 mutations in this population. A total of 269 control individuals were also screened for the seven ABCA4 mutations. RESULTS: Microarray screening results from a cohort of 181 patients affected with AARs revealed that seven ABCA4 mutations (p.Arg152*, c.768G>T, p.Arg602Trp, p.Gly863Ala, p.Cys1490Tyr, c.5461-10T>C, and p.Leu2027Phe) occurred at a relatively high frequency. The newly designed genetic assay identified two of the seven disease-associated mutations in 28/72 patients in a secondary patient cohort. In the control cohort, 12/269 individuals were found to be heterozygotes, resulting in an estimated background frequency of these mutations in this particular population of 4.46 per 100 individuals. CONCLUSIONS: The relatively high detection rate of seven ABCA4 mutations in the primary patient cohort led to the design and subsequent utility of a multiplex assay. This assay can be used as a viable screening tool and to reduce costs and laboratory time. The estimated background frequency of the seven ABCA4 mutations, together with the improved diagnostic service, could be used by counselors to facilitate clinical and genetic management of South African families with AARs.

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139 of alleles detected Frequency p.Cys54Tyr c. 161 G>A 2 0.55% p.Arg152* c. 454 C>T 12 3.31% p.Arg152Gln c. 455 G>A 3 0.83% p.Gly172Ser c. 514 G>A 1 0.28% p.Arg212Cys c. 634 C>T 1 0.28% p.Lys223Gln c. 667 A>C 1 0.28% p.V256V (Splice) c. 768 G>T 18 4.97% p.Pro291Leu c. 872 C>T 1 0.28% p.Trp439* c. 1317 G>A 1 0.28% p.Ala538Asp c. 1613 C>A 1 0.28% p.Leu541Pro c. 1622 T>C 1 0.28% p.Arg602Trp c. 1885C>T 30 8.29% p.Val643Met c. 1927 G>A 1 0.28% p.Arg653Cys c. 1957 C>T 1 0.28% p.Arg681* c. 2041 C>T 3 0.83% p.Val767Asp c. 2300 T>A 1 0.28% p.Trp855* c.2564_2571delGGTACCTT 2 0.55% p.Gly863Ala c. 2588 G>C 11 3.04% p.Val931Met c. 2791 G>A 1 0.28% p.Asn965Ser c. 2894 A>G 4 1.10% p.Val989Ala c. 2966 T>C 1 0.28% p.Gly991Arg c. 2971 G>C 1 0.28% p.Thr1019Met c. 3056 C>T 1 0.28% p.Ala1038Val c. 3113 C>T 3 0.83% p.Glu1087Lys c. 3259 G>A 1 0.28% p.Arg1108Cys c. 3322 C>T 2 0.55% p.Leu1201Arg c. 3602 T>G 4 1.10% p.Arg1300Gln c. 3899 G>A 4 1.10% p.Pro1380Leu c. 4139 C>T 3 0.83% p.Trp1408Arg c. 4222 T>C 1 0.28% - c. 4253+5G>A 1 0.28% p.Phe1440Ser c. 4319 T>C 1 0.28% p.Arg1443His c. 4328 G>A 1 0.28% p.Cys1490Tyr c.4469 G>A 54 14.92% p.Gln1513Pro fs*42 c. 4535 insC 1 0.28% p.Ala1598Asp c. 4793C>A 1 0.28% p.Arg1640Trp c. 4918 C>T 2 0.55% p.Ser1642Arg c. 4926 C>G 1 0.28% p.V1681_C1685del c. 5041 del15 1 0.28% - c. 5461-10T>C 24 6.63% - c. 5714+5 G>A 2 0.55% p.Pro1948Leu c. 5843 C>T 1 0.28% p.Gly1961Glu c. 5882 G>A 4 1.10% p.Leu2027Phe c.6079 C>T 30 8.29% p.Arg2030* c. 6088 C>T 1 0.28% p.Arg2030Gln c. 6089 G>A 3 0.83% p.Arg2038Trp c. 6112 C>T 1 0.28% p.Arg2107His c. 6320 G>A 2 0.55% p.Arg2118Glu fs*27 c. 6352 delA 1 0.28% p.Cys2150Tyr c. 6449 G>A 1 0.28% p.Gln2220* c. 6658 C>T 1 0.28% p.Gly863Ala mutation, which appears to have a founder effect in the Netherlands [13,15], the results obtained from the current study are in agreement with September et al.`s conclusions [9].

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ABCA4 p.Arg212Cys 22328824:139:154

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[hide] Cone photoreceptor abnormalities correlate with vi... Invest Ophthalmol Vis Sci. 2011 May 17;52(6):3281-92. doi: 10.1167/iovs.10-6538. Print 2011 May. Chen Y, Ratnam K, Sundquist SM, Lujan B, Ayyagari R, Gudiseva VH, Roorda A, Duncan JL
Cone photoreceptor abnormalities correlate with vision loss in patients with Stargardt disease.
Invest Ophthalmol Vis Sci. 2011 May 17;52(6):3281-92. doi: 10.1167/iovs.10-6538. Print 2011 May., [PMID:21296825]

Abstract [show]
PURPOSE. To study the relationship between macular cone structure, fundus autofluorescence (AF), and visual function in patients with Stargardt disease (STGD). METHODS. High-resolution images of the macula were obtained with adaptive optics scanning laser ophthalmoscopy (AOSLO) and spectral domain optical coherence tomography in 12 patients with STGD and 27 age-matched healthy subjects. Measures of retinal structure and AF were correlated with visual function, including best-corrected visual acuity, color vision, kinetic and static perimetry, fundus-guided microperimetry, and full-field electroretinography. Mutation analysis of the ABCA4 gene was completed in all patients. RESULTS. Patients were 15 to 55 years old, and visual acuity ranged from 20/25-20/320. Central scotomas were present in all patients, although the fovea was spared in three patients. The earliest cone spacing abnormalities were observed in regions of homogeneous AF, normal visual function, and normal outer retinal structure. Outer retinal structure and AF were most normal near the optic disc. Longitudinal studies showed progressive increases in AF followed by reduced AF associated with losses of visual sensitivity, outer retinal layers, and cones. At least one disease-causing mutation in the ABCA4 gene was identified in 11 of 12 patients studied; 1 of 12 patients showed no disease-causing ABCA4 mutations. CONCLUSIONS. AOSLO imaging demonstrated abnormal cone spacing in regions of abnormal fundus AF and reduced visual function. These findings provide support for a model of disease progression in which lipofuscin accumulation results in homogeneously increased AF with cone spacing abnormalities, followed by heterogeneously increased AF with cone loss, then reduced AF with cone and RPE cell death.

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109 TABLE1.ClinicalCharacteristicsofthePatientswithStargardtDisease Patient/EyeAge(y)/SexABCA4MutationsBCVA ETDRS ScoreColorVision* GoldmannVisual Field† HumphreyVisualField 10-2 Foveal Threshold (dB)Fixation F1P1OS16/MPro1486Leu/6bp insϩ32bpdel atbase672 20/4075None,0,1.34V4e:full;14e:1°ctl scotoma 8°ctlscotomawithϽ1 logunitsensitivityloss 30Foveal F1P2OS15/MPro1486Leu/6bp insϩ32bpdel atbase672 20/16040NS,2,1.99V4e:full;14e:1°ctl scotoma Densescotomabeginning 4°superiortofixation 27Superior F2P1OS25/FGlu1412Stop20/6361None,0,1.00V4e,14e:full,12e: 5°ctlscotoma 6°ctlscotoma31Foveal F3P1OD24/MGly863Ala20/10050NS,6,2.72V4e:full;14e:3-4° ctlscotoma 3°-4°scotomasuperior tofixation 32Superior F4P1OS16/FNodisease-causing mutations identified 20/20035NS,5,2.25V4e:full;14e:35° ctlscotoma 15°ctlscotomawith eccentricfixation superonasally 8Nasal,slightlybelow horizontal meridian F5P1OS42/M5461-10TϾCintron 39/Gly1961Glu 20/32023NS,5,2.27V4e:full;14e:10° ctlscotoma 12°densectlscotoma27Superonasal F6P1OS19/FLys223Gln/C2291 15bp/5amino aciddeletion (CSGVI) 20/20035NS,6,1.99V4e:full;14e:35° ctlscotoma 10°ctlscotoma20Superonasal F7P1OS55/FArg212Cys/ Gly863Ala/ Thr959Ile 20/16040NS,3,2.01V4e:10°ctl scotoma;14e:20° ctlscotoma Dense15°ctlscotoma6Superonasal F8P1OS36/MSer336Cys/ Arg1068/Ser‡ 20/20034NS,8,3.62V4e:20°ctl scotoma;14e:25° ctlscotoma Densescotomabeginning 6°superiortofixation 12Superior F9P1OS28/MArg1108His/ Val1433lle 20/32025NS,11,3.30V4e:full;14e:15° scotomafrom5- 25°superiorto fixation Densescotomabeginning 5°superiortofixation 23Superior F10P1OS55/FIVS20ϩ5GϾA splice/Gly1961Glu 20/32025NS,6,2.55V4e:30°ctl scotoma;14e:35° ctlscotoma Densescotomaextending fromfixationto10° inferonasally 19Inferonasal F11P1OS50/MArg2030Gln20/2580Tritan,7,2.61V4e:full;14e:25° ctlscotomafrom 10-25°with fovealsparing Densescotomaextending fromfixationto10° withfovealsparing 27Foveal ctl,central;F,family;F,female;M,male;NS,nonspecificorientation;OD,righteye;OS,lefteye;P,proband.

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ABCA4 p.Arg212Cys 21296825:109:1390

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[hide] Loss of peripapillary sparing in non-group I Starg... Exp Eye Res. 2010 Nov;91(5):592-600. Epub 2010 Aug 7. Burke TR, Allikmets R, Smith RT, Gouras P, Tsang SH
Loss of peripapillary sparing in non-group I Stargardt disease.
Exp Eye Res. 2010 Nov;91(5):592-600. Epub 2010 Aug 7., [PMID:20696155]

Abstract [show]
The aim of this study was to assess peripapillary sparing in patients with non-group I Stargardt disease. We suggest this as a useful clinical sign for formulating disease severity. Patients with a diagnosis of Stargardt disease were grouped by electroretinogram (ERG). Fundus autofluorescence was used to assess the peripapillary area for involvement in the Stargardt disease process. From a cohort of 32 patients (64 eyes), 17 patients (33 eyes) demonstrated loss of peripapillary sparing. One of 15 patients in Group I, six of 7 patients in group II and 9 of 10 patients in group III demonstrated peripapillary atrophy. One patient in group II had peripapillary flecks. All patients had at least one mutation detected in the ABCA4 gene. Both mutations were detected in 21 patients. Patients in groups II and III had the earliest ages of onset and the poorest visual acuities. Two novel disease causing mutation in the ABCA4 gene were detected. Our data supports the observation that peripapillary sparing is not universal finding for Stargardt disease and peripapillary atrophy is a useful clinical sign for identifying patients with Stargardt disease who fall into the more severe ERG groups, i.e. groups II and III. The presence of atrophy suggests a continuum of disease between groups II and III. Loss of peripapillary sparing is likely associated with the more deleterious mutations of the ABCA4 gene.

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184 Also, the type of involvement of the peripapillary area Table 1 Summary of clinical and genetic information for patients with ERG Group I Stargardt Disease. Case Mutation Mutation OA Duration Age at AF Visual Acuity Flecks Atrophy GA (mm2 ) PPA # Sex Allele 1 Allele 2 PPA (years) (years) (years) OD OS OD OS OD OS OD OS Pattern RON 1 Male G1961E G1961E e 19 13 32 20/70 20/70 M M M M 1.6 0.2 None 2 Female G1961E *IVS43 þ 1 G > T e 8 21 27 20/200 20/200 M M M M na na None 3.1 Male L541P/A1038V G1961E e 28 3 31 20/50 20/30 M M M M na na None 3.2 Male L541P/A1038V G1961E e 28 5 33 20/60 20/50 M M M M na na None 4.1 Female L541P/A1038V G1961E e 14 3 17 20/30 20/25 None None None None na na None 4.2 Female L541P/A1038V G1961E e 14 10 24 20/150 20/200 M M M M na na None 5 Female G1961E R2077W e 25 5 30 20/60 20/50 None None M M na na None 6.1 Female G1961E L541P/A1038V e 18 3 21 20/150 20/150 None None M M na na None 6.2 Female G1961E L541P/A1038V e 15 3 18 20/150 20/150 None None M M na na None 7 Female R602Q R602Q e 31 5 36 20/20 20/60 M,EM M,EM M M 0.7 0.3 None 8 Male L541P/A1038V ND e 22 24 46 20/200 20/200 M M M M 13.2 4.1 None 9 Femlae A1038V ND e 27 10 37 20/100 20/60 M,EM M,EM M M na na None 10 Female G1961E ND e 27 6 33 20/150 20/150 M M M M na na None 11 Female G1961E ND e 43 24 67 20/40 20/200 M M M M 4.8 na None 12 Male R212C ND OU 5 23 28 20/200 20/200 M,EM M,EM M M 1.6 4.2 Patchy N,T Abbreviations: ERG, electroretinogram; PPA, peripapillary atrophy; OD, right eye; OS, left eye; OU, both eyes; OA, onset age; AF, autofluoresence; M, macula; EM, extramacular retina; GA, geographic atrophy; na, not available; RON, relation to optic nerve; N, nasal; T, temporal; ND, mutation was not detected by the ABCR array e suggesting the presence of a currently unknown mutant allele; and *newly described mutation.

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ABCA4 p.Arg212Cys 20696155:184:1351

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183 Also, the type of involvement of the peripapillary area Table 1 Summary of clinical and genetic information for patients with ERG Group I Stargardt Disease. Case Mutation Mutation OA Duration Age at AF Visual Acuity Flecks Atrophy GA (mm2 ) PPA # Sex Allele 1 Allele 2 PPA (years) (years) (years) OD OS OD OS OD OS OD OS Pattern RON 1 Male G1961E G1961E e 19 13 32 20/70 20/70 M M M M 1.6 0.2 None 2 Female G1961E *IVS43 &#fe; 1 G > T e 8 21 27 20/200 20/200 M M M M na na None 3.1 Male L541P/A1038V G1961E e 28 3 31 20/50 20/30 M M M M na na None 3.2 Male L541P/A1038V G1961E e 28 5 33 20/60 20/50 M M M M na na None 4.1 Female L541P/A1038V G1961E e 14 3 17 20/30 20/25 None None None None na na None 4.2 Female L541P/A1038V G1961E e 14 10 24 20/150 20/200 M M M M na na None 5 Female G1961E R2077W e 25 5 30 20/60 20/50 None None M M na na None 6.1 Female G1961E L541P/A1038V e 18 3 21 20/150 20/150 None None M M na na None 6.2 Female G1961E L541P/A1038V e 15 3 18 20/150 20/150 None None M M na na None 7 Female R602Q R602Q e 31 5 36 20/20 20/60 M,EM M,EM M M 0.7 0.3 None 8 Male L541P/A1038V ND e 22 24 46 20/200 20/200 M M M M 13.2 4.1 None 9 Femlae A1038V ND e 27 10 37 20/100 20/60 M,EM M,EM M M na na None 10 Female G1961E ND e 27 6 33 20/150 20/150 M M M M na na None 11 Female G1961E ND e 43 24 67 20/40 20/200 M M M M 4.8 na None 12 Male R212C ND OU 5 23 28 20/200 20/200 M,EM M,EM M M 1.6 4.2 Patchy N,T Abbreviations: ERG, electroretinogram; PPA, peripapillary atrophy; OD, right eye; OS, left eye; OU, both eyes; OA, onset age; AF, autofluoresence; M, macula; EM, extramacular retina; GA, geographic atrophy; na, not available; RON, relation to optic nerve; N, nasal; T, temporal; ND, mutation was not detected by the ABCR array e suggesting the presence of a currently unknown mutant allele; and *newly described mutation.

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ABCA4 p.Arg212Cys 20696155:183:1350

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[hide] Novel mutations in of the ABCR gene in Italian pat... Eye (Lond). 2010 Jan;24(1):158-64. Epub 2009 Mar 6. Passerini I, Sodi A, Giambene B, Mariottini A, Menchini U, Torricelli F
Novel mutations in of the ABCR gene in Italian patients with Stargardt disease.
Eye (Lond). 2010 Jan;24(1):158-64. Epub 2009 Mar 6., [PMID:19265867]

Abstract [show]
PURPOSE: Stargardt disease (STGD) is the most prevalent juvenile macular dystrophy, and it has been associated with mutations in the ABCR gene, encoding a photoreceptor-specific transport protein. In this study, we determined the mutation spectrum in the ABCR gene in a group of Italian STGD patients. METHODS: The DNA samples of 71 Italian patients (from 62 independent pedigrees), affected with autosomal recessive STGD, were analysed for mutations in all 50 exons of the ABCR gene by the DHPLC approach (with optimization of the DHPLC conditions for mutation analysis) and direct sequencing techniques. RESULTS: In our group of STGD patients, 71 mutations were identified in 68 patients with a detection rate of 95.7%. Forty-three mutations had been already reported in the literature, whereas 28 mutations had not been previously described and were not detected in 150 unaffected control individuals of Italian origin. Missense mutations represented the most frequent finding (59.2%); G1961E was the most common mutation and it was associated with phenotypes in various degrees of severity. CONCLUSIONS: Some novel mutations in the ABCR gene were reported in a group of Italian STGD patients confirming the extensive allelic heterogeneity of this gene-probably related to the vast number of exons that favours rearrangements in the DNA sequence.

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57 Table 2 Summary of the mutations identified in the ABCR gene in our series of STGD Italian patients Patient Allele 1 mutation Allele 2 mutation S 1 R212C T1019M S 8 V1433I V1433I S 21 A1598D A1598D S 33 N96K G978D S 56 A1598D G1961E S 70 R212C T1019M S 71 W700X WT S 74 6750delA V767D S 77 G1961E WT S 82 Q21X G1961E S 106 C1177X G1961E S 107 C1177X G1961E S 114 T970P-F1015E - S 115 T970P-F1015E - S 120 N415K G1961E S 162 324-327insT 324-327insT S 181 W1408X G1961E S 190 C1177X A1598D S 201 G1961E WT S 202 Q21X T970P-F1015E S 213 M840R G1961E S 231 WT WT S 236 C1177X G1961E S 237 WT WT S 241 V256 splice WT S 246 IVS6-1g4t R1108C S 260 L2221P 5109delG-I156V S 321 IVS9 þ 1G4C S1099X S 328 IVS42 þ 4delG IVS35 þ 2t4c S 346 E2096K WT S 347 IVS28 þ 5g4a WT S 353 P1484S-G1961E P68L S 354 P1484S-G1961E P68L S 355 P1484S-G1961E P68L S 360 G1961E 5961delGGAC S 364 IVS35 þ 2t4c G1961E S 365 L541P/A1038V G1961E S 377 IVS42 þ 4delG IVS35 þ 2t4c S 380 R653C WT S 413 R212C T1019M S 414 A1598D G1961E S 417 G1078E G1961E S 438 R1055W WT S 440 4021ins24bp T1526M-G1961E S 449 W1479X L2140Q S 450 W1479X L2140Q S 474 W1461X G 1977S S 486 WT WT S 492 R1098C/L1970F 6548insTGAA S 528 T977P IVS40 þ 5g4a S 531 G690V Q1332X S 532 R572X L1473M-4733delGTTT S 535 IVS40 þ 5g4a 5917delG S 550 IVS40 þ 5g4a 6750delA S 555 250insCAAA WT S 556 250insCAAA WT S 575 N96H G1961E S 590 W821R IVS40 þ 5g4a S 592 V931M R1108C S 593 V767D R2030X Table 2 (Continued ) Patient Allele 1 mutation Allele 2 mutation S 594 G172S G1961E S 602 P1380L G1961E S 607 E616K L1580S-K2172R S 640 250insCAAA S1696N S 694 IVS35 þ 2t4c G1961E S 725 IVS13 þ 1g4a Q1376 splice S 731 L541P-A1038V G1961E S 755 N965S IVS40 þ 5g4a S 789 E1087K G1977S S 968 T1019M G1961E S 992 R212C G1961E Bold values indicate novel mutations.

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ABCA4 p.Arg212Cys 19265867:57:148

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ABCA4 p.Arg212Cys 19265867:57:238

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ABCA4 p.Arg212Cys 19265867:57:993

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ABCA4 p.Arg212Cys 19265867:57:1000

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ABCA4 p.Arg212Cys 19265867:57:1788

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ABCA4 p.Arg212Cys 19265867:57:1802

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[hide] Lipofuscin- and melanin-related fundus autofluores... Am J Ophthalmol. 2009 May;147(5):895-902, 902.e1. Epub 2009 Feb 25. Kellner S, Kellner U, Weber BH, Fiebig B, Weinitz S, Ruether K
Lipofuscin- and melanin-related fundus autofluorescence in patients with ABCA4-associated retinal dystrophies.
Am J Ophthalmol. 2009 May;147(5):895-902, 902.e1. Epub 2009 Feb 25., [PMID:19243736]

Abstract [show]
PURPOSE: To compare melanin-related near-infrared fundus autofluorescence (NIA; excitation 787 nm, emission > 800 nm) to lipofuscin-related fundus autofluorescence (FAF; excitation 488 nm, emission > 500 nm) in patients with retinal dystrophies associated with ABCA4 gene mutations (ABCA4-RD). DESIGN: Observational case series. METHODS: Sixteen consecutive patients with ABCA4-RD diagnosed in one institution were included. FAF and NIA imaging were performed with a confocal scanning laser ophthalmoscope (Heidelberg Retina Angiograph 2; Heidelberg Engineering, Heidelberg, Germany). The pattern and size of retinal pigment epithelial (RPE) alterations detected with FAF and NIA were evaluated. RESULTS: FAF and NIA alterations were detected in all patients. In 7 of 16 patients, the alterations progressed beyond the vascular arcades, and in 9 of 16, they were confined to the macula. Spots of increased NIA (4/16) were less frequent compared with spots of increased FAF (15/16). Confluent patches of reduced NIA were frequent (12/16), and severely reduced NIA was observed in 3 cases. Areas with reduced NIA corresponded to either increased or reduced FAF. Preservation of subfoveal FAF or NIA corresponded to visual acuity > or = 0.4. Abnormalities detected with NIA were more extensive or more severe compared to FAF in 15 of 16 patients. CONCLUSION: Patterns of FAF and NIA indicate different involvement of lipofuscin and melanin and their derivates in the pathophysiologic process of ABCA4-RD. NIA imaging provides a noninvasive in vivo visualization of RPE abnormalities that may precede FAF alterations during the degenerative process. Combined FAF and NIA imaging will provide further insight in the development of ABCA4-RD and could help to monitor future therapeutic interventions.

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32 Age Gender ABCA4 Mutation VA RE/LE Full-field ERG Multifocal ERG Group 1a CRD 2808 34 F c.5413AϾG (p.Asn1805Asp) c.4880_4903dup24 (p.Leu1627_Ala1634dup) 0.05 0.05 DA and LA markedly reduced No recordable potentials CRD 2830 53 F c.2690CϾT (p.Thr897Ile), c.6176GϾC (p.Gly2059Ala) 0.5 0.7 DA and LA moderately reduced Pericentral amplitude reduction CRD 2797 54 M c.4297GϾA (p.Val1433Ile) 2. mutation not foundc 0.1 0.16 DA and LA moderately reduced Not done SD 2872 44 F c.4462TϾC (p.Cys1488Arg) 2. mutation not done 0.6 0.7 DA and LA borderline Central amplitude reduction CRD 2861 72 F c.122GϾA (p.Trp41Ter) 2. mutation not done 0.4 0.5 DA: mildly and LA: moderately reduced Central amplitude reduction CRD 2644 67 F c.634CϾT (p.Arg212Cys), c.656GϾC (p.Arg219Thr), c.2588GϾC (p.Gly863Ala/ delGly863) 0.6 0.04 DA and LA moderately reduced Central amplitude reduction CRD 2936 44 F c.1622TϾC (p.Leu541Pro)/ c.3113CϾT (p.Ala1038Val), 2. mutation not done 1.0 1.0 DA: mildly and LA: moderately reduced Pericentral amplitude reduction Group 2b SD 2837 42 M c.1622TϾC (p.Leu541Pro)/ c.3113CϾT (p.Ala1038Val), c.5882GϾA (p.Gly1961Glu) 0.16 0.16 Normal Central amplitude reduction SD 2780 37 M c.768GϾT (splice mutation) c.5882GϾA (p.Gly1961Glu) 0.1 0.1 Normal Central amplitude reduction SD 2942 47 F c.1622TϾC (p.Leu541Pro) c.6320 GϾA (p.Arg2107His) 0.1 0.16 Not done Central amplitude reduction SD 2930 40 F c.6089GϾA (p.Arg2030Gln) c.6543del36bp, (p.Leu2182_Phe2193del) 0.1 0.1 DA and LA mildly reduced Central amplitude reduction SD 2933 43 F c.1609CϾT (p.Arg537Cys) c.5882GϾA (p.Gly1961Glu) c.1654GϾA (p.Val552Ile) 0.05 0.1 Normal Not done SD 2669 13 F c.768GϾT (splice mutation) c.6449GϾA (p.Cys2150Tyr) 0.1 0.16 DA and LA borderline Central amplitude reduction SD 2700 22 F c.1609CϾT (p.Arg537Cys) c.2588GϾC (p.Gly863Ala) 0.1 0.1 Normal Central amplitude reduction SD 2833 29 M c.1928TϾG (p.Val643Gly) 2. mutation not foundc 0.1 0.1 Normal Not done SD 2799 13 M c.3113CϾT (p.Ala1038Val) c.5461-10TϾC 0.4 0.4 Not done Central amplitude reduction CRD ϭ cone-rod dystrophy; DA ϭ dark adaptation; ERG ϭ electroretinography; F ϭ female; LA ϭ light adaptation; LE ϭ left eye; M ϭ male; RE ϭ right eye; SD ϭ Stargardt disease; VA ϭ visual acuity.

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ABCA4 p.Arg212Cys 19243736:32:772

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ABCA4 p.Arg212Cys 19243736:32:886

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[hide] Molecular analysis of the ABCA4 gene for reliable ... Br J Ophthalmol. 2009 May;93(5):614-21. Epub 2008 Nov 21. Aguirre-Lamban J, Riveiro-Alvarez R, Maia-Lopes S, Cantalapiedra D, Vallespin E, Avila-Fernandez A, Villaverde-Montero C, Trujillo-Tiebas MJ, Ramos C, Ayuso C
Molecular analysis of the ABCA4 gene for reliable detection of allelic variations in Spanish patients: identification of 21 novel variants.
Br J Ophthalmol. 2009 May;93(5):614-21. Epub 2008 Nov 21., [PMID:19028736]

Abstract [show]
BACKGROUND/AIMS: Mutations in ABCA4 have been associated with autosomal recessive Stargardt disease (STGD), a few cases with autosomal recessive cone-rod dystrophy (arCRD) and autosomal recessive retinitis pigmentosa (arRP). The purpose of the study was threefold: to molecularly characterise families with no mutations or partially characterised families; to determine the specificity and sensitivity of the genotyping microarray; and to evaluate the efficiency of different methodologies. METHODS: 23 STGD, five arCRD and three arRP Spanish patients who were previously analysed with the ABCR400 microarray were re-evaluated. Results were confirmed by direct sequencing. In patients with either none or only one mutant allele, ABCA4 was further analysed by denaturing high-performance liquid chromatography (dHPLC) and multiplex ligation-dependent probe amplification (MLPA). Haplotype analysis was also performed. RESULTS: In the first analysis performed with the microarray, 27 ABCA4 variants (27/62; 43.5%) were found. By dHPLC scanning, 12 novel mutations were additionally identified. In addition, two previously described mutations, one false negative (1/62; 1.6%) and one false positive (1.6%), were detected. MLPA analysis did not reveal additional substitutions. The new strategy yielded an increment of 21% compared with the approach used in the first round. CONCLUSION: ABCA4 should be analysed by optimal combination of high-throughput screening techniques such as microarray, dHPLC and direct sequencing. To the best of our knowledge, this strategy yielded significant mutational spectrum identification in Spanish patients with ABCA4-associated phenotypes. Follow-up of patients, presenting an early onset of the disease and severe mutations, seems essential to perform accurate genotype-phenotype correlations and further characterisation of pathological ABCA4 alleles.

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112 Interestingly, Paloma et al19 described one CRD case, compound heterozygous for the c.3211insGT and p.Arg212Cys variants, showing symptoms at the age of 9.

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ABCA4 p.Arg212Cys 19028736:112:102

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113 Interestingly, Paloma et al19 described one CRD case, compound heterozygous for the c.3211insGT and p.Arg212Cys variants, showing symptoms at the age of 9.

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ABCA4 p.Arg212Cys 19028736:113:102

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[hide] Evolution of ABCA4 proteins in vertebrates. J Mol Evol. 2005 Jan;60(1):72-80. Yatsenko AN, Wiszniewski W, Zaremba CM, Jamrich M, Lupski JR
Evolution of ABCA4 proteins in vertebrates.
J Mol Evol. 2005 Jan;60(1):72-80., [PMID:15696369]

Abstract [show]
The ABCA4 (ABCR) gene encodes a retinal-specific ATP-binding cassette transporter. Mutations in ABCA4 are responsible for several recessive macular dystrophies and susceptibility to age related macular degeneration (AMD). The protein appears to function as a flippase of all-trans-retinaldehyde and/or its derivatives across the membrane of outer segment disks and is a potentially important element in recycling visual cycle metabolites. However, the understanding of ABCA4's role in the visual cycle is limited due to the lack of a direct functional assay. An evolutionary analysis of ABCA4 may aid in the identification of conserved elements, the preservation of which implies functional importance. To date, only human, murine, and bovine ABCA4 genes are described. We have identified ABCA4 genes from African (Xenopus laevis) and Western (Silurana tropicalis) clawed frogs. A comparative analysis describing the evolutionary relationships between the frog ABCA4s, annotated T. rubripes ABCA4, and mammalian ABCA4 proteins was carried out. Several segments are conserved in both intradiscal loop (IL) domains, in addition to the transmembrane and ATP-binding domains. Nonconserved segments were found in the IL and cytoplasmic linker domains. Maximum likelihood analyses of the aligned sequences strongly suggest that ABCA4 was subject to purifying selection. Collectively, these data corroborate the current evolutionary model where two distinct ABCA half-transporter progenitors were combined to form a full ABCA4 progenitor in ancestral chordates. We speculate that evolutionary alterations may increase the retinoid metabolite recycling capacity of ABCA4 and may improve dark adaptation.

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130 As anticipated, the most frequently occurring STGD- associated missense ABCA4 alterations (R212C, L541P, D645N, G863A, A1038V, R1108C, R1380L, W1408R, T1526M, R1640W, G1961E, L2027F, and L2030Q) map to highly conserved regions.

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ABCA4 p.Arg212Cys 15696369:130:90

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[hide] Mutation spectrum and founder chromosomes for the ... Invest Ophthalmol Vis Sci. 2004 Jun;45(6):1705-11. September AV, Vorster AA, Ramesar RS, Greenberg LJ
Mutation spectrum and founder chromosomes for the ABCA4 gene in South African patients with Stargardt disease.
Invest Ophthalmol Vis Sci. 2004 Jun;45(6):1705-11., [PMID:15161829]

Abstract [show]
PURPOSE: To assess the mutation spectrum of ABCA4 underlying Stargardt disease (STGD) in South Africa (SA) and to determine whether there is a single or a few founder chromosomes in SA STGD families. METHODS: Sixty-four probands exhibiting the STGD phenotype were screened for mutations in the 50 exons of ABCA4 by single-strand conformational polymorphism-heteroduplex analysis sequencing and restriction fragment length polymorphism analysis. Microsatellite marker haplotyping was used to determine the ancestry in 10 families. RESULTS: Fifty-seven ABCA4 disease-associated alleles were identified that comprised 16 different sequence variants, of which two were novel, in 40 individuals of the cohort of 64 subjects. The most common variants identified included the C1490Y, L2027F, R602W, V256splice, R152X, and 2588G-->C mutations. The C1490Y variant was the most common disease-associated variant identified (19/64 subjects) and was absent in 392 control chromosomes. At least 10 ABCA4 disease-associated haplotypes were identified. Two of these haplotypes, which carried the C1490Y mutation, were identified in three unrelated families. CONCLUSIONS: Results suggest that ABCA4 is the major gene underlying STGD in the cohort investigated. Five of the six common sequence variants identified were at a higher frequency in the SA cohort than reported in published data on individuals of similar ancestry. The mutation and haplotype data suggests that there are several ancestral haplotypes underlying STGD in SA. There seems to be at least two different origins for the common C1490Y mutation, as well as two for the R602W mutation, thereby suggesting several founder effects for STGD in SA.

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71 List of 16 Different Potential Disease-Associated Sequence Variants Identified in 64 SA Subjects with arSTGD Nucleotide Change Amino Acid Change Families (N ‫؍‬ 64) Exon Reference C454T R152X 4 5 3,33 G455A R152Q 1 5 35 C634T R212C 1 6 16,27 G768T (Splice donor) V256splice 5 6 15 C1885T R602W 6 13 9 2588G3C G863A 4 17 8 T3047C V989A 1 20 11 T4319C F1440S 1 29 9 G4328A* R1443H 1 29 This study G4469A C1490Y 19 30 15,9 G5077A V16931 1 36 36 C6079T L2027F 8 44 8 C6088A R2030X 1 44 9,37 C6112T R2038W 2 44 5 IVS45ϩ7G3A Splice donor 1 45 26 6352⌬A* Frameshift 1 46 This study No individuals positive for the R1443H variant were identified in 47 control individuals of Indian ancestry.

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ABCA4 p.Arg212Cys 15161829:71:246

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125 AO (y) Phenotype Mutation 1 Mutation 2 224.1 9 STGD C1490Y R602W 170.2 10 STGD C1490Y R602W 241.1 9 STGD C1490Y 25883C 448.1 20 STGD C1490Y 2588G3C 113.3 10 STGD C1490Y L2027F 209.1 18 STGD C1490Y L2027F 165.4 10 STGD C1490Y V256splice 166.3 27 STGD C1490Y R152X 151.4 5 STGD C1490Y ND 219.1 5 (rapid clinical progression was observed by 9 years) STGD C1490Y ND 223.1 9 STGD C1490Y ND 307.1 9 STGD C1490Y ND 319.3 9 STGD C1490Y ND 385.1 10 STGD C1490Y ND 226.1 10 STGD C1490Y ND 142.2 10 STGD C1490Y ND 273.1 11 STGD C1490Y ND 382.1 12 STGD C1490Y ND 449.1 14 STGD C1490Y ND 344.2 ND STGD C1490Y ND 374.1 10 STGD L2027F 6352⌬A† 305.1 18 STGD L2027F R2038W 377.1 25 STGD L2027F R2038W 276.1 27 STGD L2027F R212C 204.4 8 STGD L2027F ND 135.4 13 STGD L2027F ND 446.1 9 STGD R602W ND 109.3 11 STGD R602W ND 110.7 13 STGD R602W ND 438.3 12 STGD R602W ND 123.1 9 STGD V256splice R152X 105.1* 10 STGD AND atypical RP V256splice R152X 24 129.3* 10 (rapid clinical progression was observed) STGD V256splice ND 163.22 10 STGD V256splice ND 173.1 8 STGD 2588G3C ND 9.4 27 STGD 2588G3C R152X 330.2 29 STGD R152Q V989A 372.1 31 STGD R1443H† R2030X 141.3 11 STGD F1440S IVS45ϩ7G3A (splice site mutation) 206.3 ND STGD V1693I ND Rows are arranged according to the age of onset (AO) starting with the earliest AO for the most common sequence variant.

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ABCA4 p.Arg212Cys 15161829:125:719

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[hide] Alterations of slow and fast rod ERG signals in pa... Invest Ophthalmol Vis Sci. 2002 Apr;43(4):1248-56. Scholl HP, Besch D, Vonthein R, Weber BH, Apfelstedt-Sylla E
Alterations of slow and fast rod ERG signals in patients with molecularly confirmed Stargardt disease type 1.
Invest Ophthalmol Vis Sci. 2002 Apr;43(4):1248-56., [PMID:11923272]

Abstract [show]
PURPOSE: To investigate the slow and fast rod signals of the scotopic 15-Hz flicker ERG in patients with molecularly confirmed Stargardt disease type I (STGD1). There is evidence that these slow and the fast rod ERG signals can be attributed to the rod bipolar-AII cell pathway and the rod-cone coupling pathway, respectively. METHODS: Twenty-seven patients with STGD1 with mutations in both alleles of the ABCA4 gene were included. Scotopic ERG response amplitudes and phases to flicker intensities ranging from -3.37 to -0.57 log scotopic troland x sec (log scot td x sec) were measured at a flicker frequency of 15 Hz. In addition, scotopic standard ERGs were obtained. Twenty-two normal subjects served as controls. RESULTS: The amplitudes of both the slow and fast rod ERG signals were significantly reduced in the STGD1 group. The phases of the slow rod signals lagged significantly, whereas those of the fast rod signals did not. The standard scotopic ERG did not reveal significant alterations. CONCLUSIONS: The results provide evidence that a defective ABCA4 transporter can functionally affect both the rod bipolar-AII cell pathway and the rod-cone coupling pathway. In STGD1, the scotopic 15-Hz flicker ERG may reveal subtle abnormalities at different sites within the rod system that remain undetected by standard ERG techniques.

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97 Characteristics of the 27 patients with STGD1 Patient Sex Age Onset VA (OD) VA (OS) CFC DF Mut(1) Mut(2) Slow Rod ERG Fast Rod ERG 1 M 32 9 1/50 20/400 Severe ϩϩ Q1412X R2077W 19.2 12.1 2 M 49 17 20/200 20/200 Severe ϩ 768G3T G1961E 56.1 23.8 3 M 46 30 20/40 20/200 Mild ϩ E471K G1961E 31.7 29.0 4* M 27 19 20/32 20/100 Moderate ϩ 2588G3C E1885K 35.0 45.1 5* M 31 18 20/400 20/400 Severe ϩϩ 2588G3C E1885K 36.1 39.1 6* F 29 12 20/200 20/200 Moderate ϩϩ 2588G3C E1885K 23.4 8.1 7 F 23 18 20/400 20/400 Mild ϩϩ E1399K G1977S 103.5 39.3 8 M 28 17 20/200 20/200 Mild ϩϩ R1898H G1975R 44.4 19.5 9 M 39 29 20/100 20/200 Moderate ϩ G607R G1961E 45.8 20.7 10 F 23 17 20/200 20/200 Mild - P68L S1689P 80.2 25.9 11 F 33 30 20/50 20/50 Mild - E1399K G1961E 49.8 62.0 12 M 50 42 20/400 20/64 Severe ϩϩ 2588G3C L541P/A1038V 53.8 30.2 13 M 36 25 20/40 20/32 Moderate ϩϩ 296insA A1038V 88.2 40.0 14 F 55 16 HM HM Severe ϩϩ Q635K IVS40ϩ5G3A 11.7 11.2 15 F 27 25 20/100 20/50 Moderate ϩ 2588G3C Q1412X 65.8 71.5 16 F 45 14 1/50 1/35 Severe ϩϩ L541P/A1038V S1063P 16.4 16.6 17 M 40 23 20/100 20/200 Moderate ϩ 296insA G1961E 46.1 58.3 18** M 35 15 20/400 20/400 Moderate ϩ 2588G3C Q1750X 14.1 12.9 19** M 43 14 HM HM Severe ϩϩ 2588G3C Q1750X 17.4 8.6 20 F 32 8 20/200 20/200 Severe ϩ G1961E G1961E 66.2 79.0 21 F 23 12 20/400 20/400 Mild - R212C T9591 24.6 25.3 22 F 29 9 20/200 20/200 Moderate ϩ L541P/A1038V G1961E 72.3 31.8 23 M 20 9 20/400 20/400 Moderate ϩϩ L541P/A1038V IVS40ϩ5G3A 64.7 42.2 24 F 39 23 20/400 20/50 Moderate - W663X G1961E 92.6 68.8 25 F 41 36 20/200 20/64 Severe ϩ F1440V G1748R 97.2 52.7 26*** M 13 10 20/100 20/200 Moderate - R572Q/2588G3C IVS35ϩ2T3A 59.2 33.5 27*** M 16 15 20/200 20/200 Moderate ϩ R572Q/2588G3C IVS35ϩ2T3A 31.1 22.9 Age at examination (y), gender, age of onset (y), visual acuity (VA), central fundus changes (CFC), and existence and distribution of the typical white-yellow flecks (DF) are shown.

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ABCA4 p.Arg212Cys 11923272:97:1496

status: NEW

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ABCA4 p.Arg212Cys 11923272:97:1514

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[hide] Cosegregation and functional analysis of mutant AB... Hum Mol Genet. 2001 Nov 1;10(23):2671-8. Shroyer NF, Lewis RA, Yatsenko AN, Wensel TG, Lupski JR
Cosegregation and functional analysis of mutant ABCR (ABCA4) alleles in families that manifest both Stargardt disease and age-related macular degeneration.
Hum Mol Genet. 2001 Nov 1;10(23):2671-8., [PMID:11726554]

Abstract [show]
Mutations in ABCR (ABCA4) have been reported to cause a spectrum of autosomal recessively inherited retinopathies, including Stargardt disease (STGD), cone-rod dystrophy and retinitis pigmentosa. Individuals heterozygous for ABCR mutations may be predisposed to develop the multifactorial disorder age-related macular degeneration (AMD). We hypothesized that some carriers of STGD alleles have an increased risk to develop AMD. We tested this hypothesis in a cohort of families that manifest both STGD and AMD. With a direct-sequencing mutation detection strategy, we found that AMD-affected relatives of STGD patients are more likely to be carriers of pathogenic STGD alleles than predicted based on chance alone. We further investigated the role of AMD-associated ABCR mutations by testing for expression and ATP-binding defects in an in vitro biochemical assay. We found that mutations associated with AMD have a range of assayable defects ranging from no detectable defect to apparent null alleles. Of the 21 missense ABCR mutations reported in patients with AMD, 16 (76%) show abnormalities in protein expression, ATP-binding or ATPase activity. We infer that carrier relatives of STGD patients are predisposed to develop AMD.

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97 Pedigree Maternal allele Paternal allele AMD relative A priori Cosegregation AR19 pGM, -6 0.5 - AR33 [W1408R; R1640W] R24H and D1532N mA, -16 0.5 Yes AR59 4232insTATG C1488R pGM, -6 0.5 No AR80 T1526M pGF, -5 0.5 - AR80 T1526M mGF, -7 0.5 Yes AR125 4947delC C1488R pGM, -7 0.5 Yes AR215 [H1406Y; V2050L] pGM, -5 0.5 - AR218 2160+1G→C G1961E mA, -8 0.5 No AR262 W821R pGGF, -7 0.25 No AR271 P68R E1087K mGA, -6 0.25 No AR335 D645N F608I mGM, -9 0.5 Yes AR382 R1108C mGM, -6 0.5 Yes AR389 E2096K 5714+5G→A pGM, -8 0.5 Yes AR397 5196+1G→A 5585-1G→A mA, -5 0.5 No AR410 A1038V 768G→T pC, -5 0.25 Yes AR422 pGM, -6 0.5 - AR423 P1380L D1532N pGF, -4 0.5 No AR468 P1380L P1380L mU, -9 0.5 Yes AR484 L2027F G550R mGU, -5 0.25 Yes AR562 R2107H 3050+5G→A pGU, -5 0.25 No AR643 5196+2T→C L2027F mU, -4 0.5 Yes AR661 P1380L C54Y mGF, -6 0.5 Yes AR669 664del13 pGF, -4 0.5 No AR534 W821R P1380L pGM, -7 0.5 Yes (17) Family 1 R212C I2113M mGM, I-2 0.5 Yes (27) Family 2 R1108C R2107H mGM, I-2 0.5 Yes (27) Family 3 R212C G1977S mGF, I-1 0.5 Yes (27) 10.25 15 unlikely to account for many of the remaining alleles (our unpublished observations).

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ABCA4 p.Arg212Cys 11726554:97:954

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ABCA4 p.Arg212Cys 11726554:97:961

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ABCA4 p.Arg212Cys 11726554:97:1043

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ABCA4 p.Arg212Cys 11726554:97:1050

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114 Sun et al. (28) reported substantial defects in protein expression or ATP binding of eight AMD-associated mutations (R212C, G863A, A1038V, R1108C, R1129L, P1380L, G1961E and L2027F) and an abnormal increase in the ATPase activity of the D2177N mutation, and they reported mild defects or wild-type activity within the sensitivity of the assay in four other AMD-associated variants (E471K, C1488R, T1526M and R1898H).

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ABCA4 p.Arg212Cys 11726554:114:117

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[hide] Spectrum of ABCA4 (ABCR) gene mutations in Spanish... Hum Mutat. 2001 Jun;17(6):504-10. Paloma E, Martinez-Mir A, Vilageliu L, Gonzalez-Duarte R, Balcells S
Spectrum of ABCA4 (ABCR) gene mutations in Spanish patients with autosomal recessive macular dystrophies.
Hum Mutat. 2001 Jun;17(6):504-10., [PMID:11385708]

Abstract [show]
The ABCA4 gene has been involved in several forms of inherited macular dystrophy. In order to further characterize the complex genotype-phenotype relationships involving this gene, we have performed a mutation analysis of ABCA4 in 14 Spanish patients comprising eight STGD (Stargardt), four FFM (fundus flavimaculatus), and two CRD (Cone-rod dystrophy) patients. SSCP (single-strand conformation polymorphism) analysis and DNA sequencing of the coding and 5' upstream regions of this gene allowed the identification of 16 putatively pathogenic alterations, nine of which are novel. Most of these were missense changes, and no patient was found to carry two null alleles. Overall, the new data agree with a working model relating the different pathogenic phenotypes to the severity of the mutations. When considering the information presented here together with that of previous reports, a picture of the geographic distribution of three particular mutations emerges. The R212C change has been found in French, Italian, Dutch, German, and Spanish but not in British patients. In the Spanish collection, R212C was found in a CRD patient, indicating that it may be a rather severe change. In contrast, c.2588G>C, a very common mild allele in the Dutch population, is rarely found in Southern Europe. Interestingly, the c.2588G>C mutation has been found in a double mutant allele together with the missense R1055W. Finally, the newly described L1940P was found in two unrelated Spanish patients, and may be a moderate to severe allele.

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6 The R212C change has been found in French, Italian, Dutch, German, and Spanish but not in British patients.

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ABCA4 p.Arg212Cys 11385708:6:4

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7 In the Spanish collection, R212C was found in a CRD patient, indicating that it may be a rather severe change.

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ABCA4 p.Arg212Cys 11385708:7:27

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59 Pathogenic Mutations In the absence of a functional assay, it is difficult to relate the structural alteration with the TABLE 1. Summary of the Pathogenic Variants Found in the Screening of the ABCA4 Gene Family (NAS) Paternal allele (E) Maternal allele (E) Onset (years) Phenotype SB1 c.3211-3212insGT (22) R212C (6) 9 CRD M266 (2) c.4253+5G>A (28) L2060R (46) 7/4 CRD SM3 [R152Q (5); R2107H (46)] [R152Q (5); R2107H (46)] 7 STGD SZ2 L1940P (41) ND 8 STGD SM1 N1799D (38) ND 9 STGD SM2 c.2888delG (19) [R1055W (21); C.2588G>C (17)] 11 STGD SP1 ND ND 12 STGD SZ3 ND ND 12 STGD M280 N1805D (39) N1805D (39) 14 STGD SB2 (2) R1108C (22) L686S (14) 18/11 STGD SZ4 ND ND 20/28 FFM SP2 ND ND 21 FFM SM4 [T1253L (25); G1961E (42)] ND 38 FFM SZ1 L1940P (41) ND 28 FFM Novel putative pathogenic variants are depicted in bold type and their corresponding nucleotide changes are as follows: L686S=c.2057T>C; R1055W=c.3163C>T; T1253L=c.3758C>T; N1799D=c.5396A>G; N1805D=c.5413A>G; L1940P=c.5819T>C; L2060R=c.6179T>G.

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ABCA4 p.Arg212Cys 11385708:59:308

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90 When we consider our data together with previous reports of mutation screenings in the USA [Lewis et al., 1999], France [Rozet et al., 1998], Western Europe [Maugeri et al., 1999], United Kingdom [Papaioannou et al., 2000], Italy [Simonelli et al., 2000], and Germany [Rivera et al., 2000], the following picture emerges: 1) Mutation R212C is common in Southern Europe (1/14 Spanish, 2/11 Italian, and 5/55 French), infrequent in the USA (1/150) and Germany (1/144), and absent in UK. 2) Mutation c.2588G>C is rarely found in Southern Europe (1/14 Spanish, 0/11 Italian, 0/55 French) but is frequent in Western and Central Europe and the USA (15/40 Dutch, 5/70 British, 17/144 German, 11/150 USA).

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ABCA4 p.Arg212Cys 11385708:90:334

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101 In patient SB1, R212C in combination with a frameshift mutation is associated with CRD.

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ABCA4 p.Arg212Cys 11385708:101:16

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102 This indicates that the R212C variant belongs to the moderate to severe group.

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ABCA4 p.Arg212Cys 11385708:102:24

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103 In agreement with this, homozygous Italian and heterozygous French patients carrying R212C were affected with early onset STGD disease (before 10-12 years) [Rozet et al., 1998; Simonelly et al., 2000], and one R212C heterozygous Dutch patient was affected with CRD [Maugeri et al., 2000].

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ABCA4 p.Arg212Cys 11385708:103:85

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ABCA4 p.Arg212Cys 11385708:103:210

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[hide] L- and M-cone-driven electroretinograms in Stargar... Invest Ophthalmol Vis Sci. 2001 May;42(6):1380-9. Scholl HP, Kremers J, Vonthein R, White K, Weber BH
L- and M-cone-driven electroretinograms in Stargardt's macular dystrophy-fundus flavimaculatus.
Invest Ophthalmol Vis Sci. 2001 May;42(6):1380-9., [PMID:11328755]

Abstract [show]
PURPOSE: To study the dynamics of the long (L)- and middle (M)-wavelength-sensitive cone-driven pathways and their interactions in patients with Stargardt's macular dystrophy-fundus flavimaculatus (SMD-FF) and to correlate them with other clinical parameters and individual genotypes. METHODS: Forty-seven patients with SMD-FF participated in the study. In addition to standard 30-Hz flicker electroretinograms (30-Hz fERG), ERG responses were measured to stimuli that modulated exclusively the L or the M cones (L/M cones) or the two simultaneously. Blood samples were screened for mutations in the 50 exons of the ABCA4 gene. RESULTS: Patients with SMD-FF did not show a decrease in the mean L/M-cone-driven ERG sensitivity, but there was a significant increase in the interindividual variability. The mean L-/M-cone weighting ratio was normal. However, the L-cone-driven ERG was significantly phase delayed, whereas the M-cone-driven ERG was significantly phase advanced. These phase changes were significantly correlated with disease duration. The amplitude and implicit time of the standard 30-Hz fERG both correlated significantly with the L/M-cone-driven ERG sensitivity and with the phase difference between the L/M-cone-driven ERGs, indicating the complex origin of the standard 30-Hz fERG. Probable disease-associated mutations in the ABCA4 gene were found in 40 of 45 patients, suggesting that they form a genetically fairly uniform SMD-FF study group. There was no correlation between the genotype and the L/M-cone-driven ERGS: CONCLUSIONS: The changes in L/M-cone-driven ERG sensitivity and phase possibly represent two independent disease processes. The phase changes are similar to those found in patients with retinitis pigmentosa and possibly are a general feature of retinal dystrophies.

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43 Characteristics of the Patients with SMD-FF Patient Sex Age (y) Age at Onset (y) VA CFC DF CV Exon (1) Mut (1) Exon (2) Mut (2) 1 M 32 29 0.6 Moderate ϩ Normal 48 L2241V NF 2 F 39 23 0.4 Moderate - Chaotic 14 W663X 42 G1961E 3 M 34 16 0.1 Moderate ϩ - 42 G1961E NF 4 M 49 17 0.1 Severe ϩ NP 6 G768T/splice 42 G1961E 5 F 36 35 0.6 Moderate ϩ VS (T) 6 C230S 42 G1961E 6 M 28 17 0.1 Mild ϩϩ INS 40 R1898H 43 G1975R 7 M 20 9 0.05 Moderate ϩϩ VS (P/D) 12 ϩ 21 L541P ϩ A1038V 40 IVS40 ϩ 5G 3 A 8 M 33 6 0.1 Mild - Chaotic NF NF 9 M 39 29 0.2 Moderate ϩ VS (P/D) 13 G607R 42 G1961E 10 M 38 22 0.1 Severe ϩ Chaotic NF NF 11 F 28 20 0.7 Mild ϩϩ INS 3 A60T 40 R1898H 12 M 46 30 0.5 Mild ϩ Chaotic 11 E471K 42 G1961E 13 F 25 11 0.1 Moderate ϩϩ S 17 G863A NF 14 F 51 41 0.8 Moderate ϩϩ NP 40 R1898H NF 15 F 23 17 0.1 Mild - Chaotic 3 P68L 36 S1689P 16 F 33 30 0.4 Mild - Chaotic 28 E1399K 42 G1961E 17 F 41 36 0.1 Severe ϩ VS (T) 29 F1440V 37 G1748R 18 M 59 54 0.1 Severe ϩ VS (P/D) 42 G1961E NF 19* M 35 15 0.05 Moderate ϩ Chaotic 17 G863A 37 Q1750X 20* M 43 14 HM Severe ϩϩ NP 17 G863A 37 Q1750X 21 F 46 16 0.1 Moderate ϩ NP NF NF 22 F 32 22 0.05 Moderate ϩ INS 21 A1038V NF 23 M 50 42 0.3 Severe ϩϩ VS (P/D) 12 ϩ 21 L541P ϩ A1038V 17 G863A 24 F 30 14 0.1 Moderate ϩϩ INS 17 G863A 40 IVS40 ϩ 5G 3 A 25 M 36 25 0.5 Moderate ϩϩ - 3 296INSA 21 A1038V 26 M 40 23 0.2 Moderate ϩ S 3 296INSA 42 G1961E 27 F 35 9 0.1 Severe ϩϩ VS (P/D) 22 R1108C NF 28 F 23 18 0.05 Mild ϩϩ S 28 E1399K 43 G1977S 29 F 25 18 0.2 Mild ϩ Chaotic 37 L1763P NF 30 F 16 11 0.1 Moderate ϩ Chaotic 22 R1108C NF 31 M 40 35 0.1 Moderate ϩϩ VS (P/D) 14 R681X NF 32 F 28 27 0.1 Moderate ϩ S 12 ϩ 21 L541P ϩ A1038V 21 A1038V 33 M 32 9 0.05 Severe ϩϩ Chaotic 28 Q1412X 45 R2077W 34 F 23 21 0.2 Moderate ϩ INS 6 G768T/splice NF 35 F 38 33 FC Moderate - Chaotic 17 G863A NF 36 F 39 10 HM Severe ϩϩ NP NF NF 37 F 13 8 0.1 Moderate ϩϩ S - - 38 F 27 25 0.2 Moderate ϩ Chaotic 17 G863A 28 Q1412X 39 M 16 15 0.1 Moderate ϩ VS (P/D) 12 ϩ 17 R572Q ϩ G863A 35 IVS35 ϩ 2T 3 A 40 M 27 26 0.6 Moderate - S 17 G863A NF 41 M 18 16 0.2 Moderate ϩ - - - 42 M 25 24 0.1 Mild - - NF NF 43 F 29 9 0.1 Moderate ϩ Chaotic 12 ϩ 21 L541P ϩ A1038V 42 G1961E 44 M 39 28 0.1 Mild - NP 6 N247S NF 45 F 23 12 0.05 Mild - NP 6 R212C 19 T959I 46 M 43 36 0.2 Moderate ϩ VS (P/D) 21 A1038V NF 47 M 21 18 0.4 Mild ϩϩ INS 28 Q1412X NF Shown are age at examination, age of onset, visual acuity, central fundus changes, and existence and distribution of the typical white-yellow flecks.

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ABCA4 p.Arg212Cys 11328755:43:2632

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44 Characteristics of the Patients with SMD-FF Patient Sex Age (y) Age at Onset (y) VA CFC DF CV Exon (1) Mut (1) Exon (2) Mut (2) 1 M 32 29 0.6 Moderate af9; Normal 48 L2241V NF 2 F 39 23 0.4 Moderate afa; Chaotic 14 W663X 42 G1961E 3 M 34 16 0.1 Moderate af9; - 42 G1961E NF 4 M 49 17 0.1 Severe af9; NP 6 G768T/splice 42 G1961E 5 F 36 35 0.6 Moderate af9; VS (T) 6 C230S 42 G1961E 6 M 28 17 0.1 Mild af9;af9; INS 40 R1898H 43 G1975R 7 M 20 9 0.05 Moderate af9;af9; VS (P/D) 12 af9; 21 L541P af9; A1038V 40 IVS40 af9; 5G 3 A 8 M 33 6 0.1 Mild afa; Chaotic NF NF 9 M 39 29 0.2 Moderate af9; VS (P/D) 13 G607R 42 G1961E 10 M 38 22 0.1 Severe af9; Chaotic NF NF 11 F 28 20 0.7 Mild af9;af9; INS 3 A60T 40 R1898H 12 M 46 30 0.5 Mild af9; Chaotic 11 E471K 42 G1961E 13 F 25 11 0.1 Moderate af9;af9; S 17 G863A NF 14 F 51 41 0.8 Moderate af9;af9; NP 40 R1898H NF 15 F 23 17 0.1 Mild afa; Chaotic 3 P68L 36 S1689P 16 F 33 30 0.4 Mild afa; Chaotic 28 E1399K 42 G1961E 17 F 41 36 0.1 Severe af9; VS (T) 29 F1440V 37 G1748R 18 M 59 54 0.1 Severe af9; VS (P/D) 42 G1961E NF 19* M 35 15 0.05 Moderate af9; Chaotic 17 G863A 37 Q1750X 20* M 43 14 HM Severe af9;af9; NP 17 G863A 37 Q1750X 21 F 46 16 0.1 Moderate af9; NP NF NF 22 F 32 22 0.05 Moderate af9; INS 21 A1038V NF 23 M 50 42 0.3 Severe af9;af9; VS (P/D) 12 af9; 21 L541P af9; A1038V 17 G863A 24 F 30 14 0.1 Moderate af9;af9; INS 17 G863A 40 IVS40 af9; 5G 3 A 25 M 36 25 0.5 Moderate af9;af9; - 3 296INSA 21 A1038V 26 M 40 23 0.2 Moderate af9; S 3 296INSA 42 G1961E 27 F 35 9 0.1 Severe af9;af9; VS (P/D) 22 R1108C NF 28 F 23 18 0.05 Mild af9;af9; S 28 E1399K 43 G1977S 29 F 25 18 0.2 Mild af9; Chaotic 37 L1763P NF 30 F 16 11 0.1 Moderate af9; Chaotic 22 R1108C NF 31 M 40 35 0.1 Moderate af9;af9; VS (P/D) 14 R681X NF 32 F 28 27 0.1 Moderate af9; S 12 af9; 21 L541P af9; A1038V 21 A1038V 33 M 32 9 0.05 Severe af9;af9; Chaotic 28 Q1412X 45 R2077W 34 F 23 21 0.2 Moderate af9; INS 6 G768T/splice NF 35 F 38 33 FC Moderate afa; Chaotic 17 G863A NF 36 F 39 10 HM Severe af9;af9; NP NF NF 37 F 13 8 0.1 Moderate af9;af9; S - - 38 F 27 25 0.2 Moderate af9; Chaotic 17 G863A 28 Q1412X 39 M 16 15 0.1 Moderate af9; VS (P/D) 12 af9; 17 R572Q af9; G863A 35 IVS35 af9; 2T 3 A 40 M 27 26 0.6 Moderate afa; S 17 G863A NF 41 M 18 16 0.2 Moderate af9; - - - 42 M 25 24 0.1 Mild afa; - NF NF 43 F 29 9 0.1 Moderate af9; Chaotic 12 af9; 21 L541P af9; A1038V 42 G1961E 44 M 39 28 0.1 Mild afa; NP 6 N247S NF 45 F 23 12 0.05 Mild afa; NP 6 R212C 19 T959I 46 M 43 36 0.2 Moderate af9; VS (P/D) 21 A1038V NF 47 M 21 18 0.4 Mild af9;af9; INS 28 Q1412X NF Shown are age at examination, age of onset, visual acuity, central fundus changes, and existence and distribution of the typical white-yellow flecks.

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ABCA4 p.Arg212Cys 11328755:44:2686

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[hide] An analysis of allelic variation in the ABCA4 gene... Invest Ophthalmol Vis Sci. 2001 May;42(6):1179-89. Webster AR, Heon E, Lotery AJ, Vandenburgh K, Casavant TL, Oh KT, Beck G, Fishman GA, Lam BL, Levin A, Heckenlively JR, Jacobson SG, Weleber RG, Sheffield VC, Stone EM
An analysis of allelic variation in the ABCA4 gene.
Invest Ophthalmol Vis Sci. 2001 May;42(6):1179-89., [PMID:11328725]

Abstract [show]
PURPOSE: To assess the allelic variation of the ATP-binding transporter protein (ABCA4). METHODS: A combination of single-strand conformation polymorphism (SSCP) and automated DNA sequencing was used to systematically screen this gene for sequence variations in 374 unrelated probands with a clinical diagnosis of Stargardt disease, 182 patients with age-related macular degeneration (AMD), and 96 normal subjects. RESULTS: There was no significant difference in the proportion of any single variant or class of variant between the control and AMD groups. In contrast, truncating variants, amino acid substitutions, synonymous codon changes, and intronic variants were significantly enriched in patients with Stargardt disease when compared with their presence in subjects without Stargardt disease (Kruskal-Wallis P < 0.0001 for each variant group). Overall, there were 2480 instances of 213 different variants in the ABCA4 gene, including 589 instances of 97 amino acid substitutions, and 45 instances of 33 truncating variants. CONCLUSIONS: Of the 97 amino acid substitutions, 11 occurred at a frequency that made them unlikely to be high-penetrance recessive disease-causing variants (HPRDCV). After accounting for variants in cis, one or more changes that were compatible with HPRDCV were found on 35% of all Stargardt-associated alleles overall. The nucleotide diversity of the ABCA4 coding region, a collective measure of the number and prevalence of polymorphic sites in a region of DNA, was found to be 1.28, a value that is 9 to 400 times greater than that of two other macular disease genes that were examined in a similar fashion (VMD2 and EFEMP1).

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102 Thirty-Three Truncated and 98 Amino Acid-Changing Variants in the ABCA4 Gene Exon Nucleotide Change Effect (A) (B) AMD (n ‫؍‬ 182) Control (n ‫؍‬ 96) STGD (n ‫؍‬ 374) Allele Prevalence 2 106delT FS NS 0 0 1 Ͻ0.01 2 160 ϩ 1g 3 a Splice site NS 0 0 1 Ͻ0.01 3 161G 3 A Cys54Tyr NS 0 0 6 Ͻ0.01 3 179C 3 T Ala60Val NS 0 0 2 Ͻ0.01 3 194G 3 A Gly65Glu NS 0 0 2 Ͻ0.01 3 223T 3 G Cys75Gly NS 0 0 2 Ͻ0.01 3 247delCAAA FS NS 0 0 2 Ͻ0.01 3 298C 3 T Ser100Pro NS 0 0 1 Ͻ0.01 5 454C 3 T Arg152Stop NS 0 0 2 Ͻ0.01 6 574G 3 A Ala192Thr NS 0 0 1 Ͻ0.01 6 618C 3 G Ser206Arg NS 0 0 3 Ͻ0.01 6 634C 3 T Arg212Cys 0.02 Yes 0 0 7 0.01 6 635G 3 A Arg212His NS 2 2 6 0.01 6 658C 3 T Arg220Cys NS 0 0 2 Ͻ0.01 6 661delG FS NS 0 0 1 Ͻ0.01 666delAAAGACGGTGC 6 GC FS NS 0 0 1 Ͻ0.01 6 746A 3 C Asp249Gly NS 0 0 1 Ͻ0.01 8 899C 3 A Thr300Asn NS 0 0 1 Ͻ0.01 8 997C 3 T Arg333Trp NS 0 0 1 Ͻ0.01 9 1140T 3 A Asn380Lys NS 0 0 1 Ͻ0.01 9 1222C 3 T Arg408Stop NS 0 0 1 Ͻ0.01 10 1268A 3 G His423Arg NS 1 0 7 0.01 10 1335C 3 G Ser445Arg NS 0 0 1 Ͻ0.01 10 1344delG FS NS 0 0 1 Ͻ0.01 11 1411G 3 A Glu471Lys NS 0 0 3 Ͻ0.01 11 1513delATCAC FS NS 0 0 1 Ͻ0.01 12 1622T 3 C Leu541Pro 0.001 Yes 0 0 11 0.01 13 1804C 3 T Arg602Trp NS 0 0 3 Ͻ0.01 13 1805G 3 A Arg602Gln NS 0 0 1 Ͻ0.01 13 1819G 3 T Gly607Trp NS 0 0 1 Ͻ0.01 13 1823T 3 A Phe608Ile NS 0 0 1 Ͻ0.01 13 1927G 3 A Val643Met NS 0 0 1 Ͻ0.01 14 1989G 3 T Trp663Stop NS 0 0 1 Ͻ0.01 14 2005delAT FS NS 0 0 3 Ͻ0.01 14 2041C 3 T Arg681Stop NS 0 0 2 Ͻ0.01 14 2147C 3 T Thr716Met NS 0 0 1 Ͻ0.01 15 2291G 3 A Cys764Tyr NS 0 0 1 Ͻ0.01 15 2294G 3 A Ser765Asn NS 0 0 1 Ͻ0.01 15 2300T 3 A Val767Asp NS 0 0 2 Ͻ0.01 16 2385del16bp FS NS 0 0 1 Ͻ0.01 16 2453G 3 A Gly818Glu NS 0 0 1 Ͻ0.01 16 2461T 3 A Trp821Arg NS 0 0 1 Ͻ0.01 16 2546T 3 C Val849Ala NS 0 0 4 Ͻ0.01 16 2552G 3 A Gly851Asp NS 0 0 1 Ͻ0.01 16 2560G 3 A Ala854Thr NS 0 0 1 Ͻ0.01 17 2588G 3 C Gly863Ala 0.0006 No 2 2 28 0.02 17 2617T 3 C Phe873Leu NS 0 0 1 Ͻ0.01 18 2690C 3 T Thr897Ile NS 0 0 1 Ͻ0.01 18 2701A 3 G Thr901Ala NS 0 1 0 Ͻ0.01 18 2703A 3 G Thr901Arg NS 0 0 2 Ͻ0.01 19 2828G 3 A Arg943Gln NS 20 13 37 0.05 19 2883delC FS NS 0 0 1 Ͻ0.01 20 2894A 3 G Asn965Ser NS 0 0 3 Ͻ0.01 19 2912C 3 A Thr971Asn NS 0 0 1 Ͻ0.01 19 2915C 3 A Thr972Asn NS 0 0 1 Ͻ0.01 20 2920T 3 C Ser974Pro NS 0 0 1 Ͻ0.01 20 2966T 3 C Val989Ala NS 0 0 2 Ͻ0.01 20 2977del8bp FS NS 0 0 1 Ͻ0.01 20 3041T 3 G Leu1014Arg NS 0 0 1 Ͻ0.01 21 3055A 3 G Thr1019Ala NS 0 0 1 Ͻ0.01 21 3064G 3 A Glu1022Lys NS 0 0 1 Ͻ0.01 21 3091A 3 G Lys1031Glu NS 0 0 1 Ͻ0.01 21 3113G 3 T Ala1038Val 0.001 Yes 1 0 17 0.01 22 3205insAA FS NS 0 0 1 Ͻ0.01 22 3261G 3 A Glu1087Lys NS 0 0 2 Ͻ0.01 22 3322C 3 T Arg1108Cys 0.04 Yes 0 0 6 Ͻ0.01 22 3323G 3 A Arg1108His NS 0 0 1 Ͻ0.01 23 3364G 3 A Glu1122Lys NS 0 0 1 Ͻ0.01 (continues) Exon Nucleotide Change Effect (A) (B) AMD (n ‫؍‬ 182) Control (n ‫؍‬ 96) STGD (n ‫؍‬ 374) Allele Prevalence 23 3386G 3 T Arg1129Leu NS 0 0 3 Ͻ0.01 24 3531C 3 A Cys1158Stop NS 0 0 1 Ͻ0.01 25 3749T 3 C Leu1250Pro NS 0 0 1 Ͻ0.01 26 3835delGATTCT FS NS 0 0 1 Ͻ0.01 27 3940C 3 A Pro1314Thr NS 0 1 0 Ͻ0.01 28 4139C 3 T Pro1380Leu 0.001 Yes 0 0 10 0.01 28 4222T 3 C Trp1408Arg NS 0 0 2 Ͻ0.01 28 4223G 3 T Trp1408Leu NS 0 0 2 Ͻ0.01 28 4234C 3 T Gln1412stop NS 0 0 1 Ͻ0.01 29 4297G 3 A Val1433Ile NS 1 0 0 Ͻ0.01 29 4319T 3 C Phe1440Ser NS 0 0 1 Ͻ0.01 30 4353 - 1g 3 t Splice site NS 0 0 1 Ͻ0.01 30 4457C 3 T Pro1486Leu NS 0 0 1 Ͻ0.01 30 4462T 3 C Cys1488Arg NS 0 0 3 Ͻ0.01 30 4463G 3 T Cys1488Phe NS 0 0 2 Ͻ0.01 30 4469G 3 A Cys1490Tyr NS 0 0 3 Ͻ0.01 30 4531insC FS NS 0 0 2 Ͻ0.01 32 4538A 3 G Gln1513Arg NS 0 0 1 Ͻ0.01 30 4539 ϩ 1g 3 t Splice site NS 0 0 1 Ͻ0.01 31 4574T 3 C Leu1525Pro NS 0 0 1 Ͻ0.01 33 4733delGTTT FS NS 0 0 1 Ͻ0.01 4859delATAACAinsTCC 35 T FS NS 0 0 1 Ͻ0.01 36 4909G 3 A Ala1637Thr NS 0 0 1 Ͻ0.01 35 4918C 3 T Arg1640Trp NS 0 0 1 Ͻ0.01 35 4919G 3 A Arg1640Gln NS 0 0 1 Ͻ0.01 35 4954T 3 G Tyr1652Asp NS 0 0 1 Ͻ0.01 36 5077G 3 A Val1693Ile NS 0 0 1 Ͻ0.01 36 5186T 3 C Leu1729Pro NS 0 0 2 Ͻ0.01 36 5206T 3 C Ser1736Pro NS 0 0 1 Ͻ0.01 36 5212del11bp FS NS 0 0 1 Ͻ0.01 37 5225delTGGTGGTGGGC FS NS 0 0 1 Ͻ0.01 del LPA 37 5278del9bp 1760 NS 0 0 1 Ͻ0.01 37 5288delG FS NS 0 0 1 Ͻ0.01 38 5395A 3 G Asn1799Asp NS 0 0 1 Ͻ0.01 38 5451T 3 G Asp1817Glu NS 1 0 4 Ͻ0.01 39 5584 ϩ 5g 3 a Splice site 0.02 Yes 0 0 6 Ͻ0.01 40 5603A 3 T Asn1868Ile 0.0006 No 20 7 79 0.08 40 5651T 3 A Val1884GLu NS 0 0 1 Ͻ0.01 40 5657G 3 A Gly1886Glu NS 0 0 1 Ͻ0.01 40 5687T 3 A Val1896Asp NS 0 0 1 Ͻ0.01 40 5693G 3 A Arg1898His NS 0 0 1 Ͻ0.01 40 5714 ϩ 5g 3 a Splice site NS 0 0 1 Ͻ0.01 42 5843CA 3 TG Pro1948Leu NS 11 7 28 0.04 42 5882G 3 A Gly1961Glu Ͻ0.0001 Yes 1 0 43 0.03 43 5908C 3 T Leu1970Phe NS 1 0 1 Ͻ0.01 43 5917delG FS NS 0 0 1 Ͻ0.01 44 6079C 3 T Leu2027Phe 0.01 Yes 0 0 9 0.01 44 6088C 3 T Arg2030Stop NS 0 0 2 Ͻ0.01 44 6089G 3 A Arg2030Gln NS 0 0 1 Ͻ0.01 44 6112A 3 T Arg2038Trp NS 0 0 1 Ͻ0.01 45 6148A 3 C Val2050Leu NS 1 0 0 Ͻ0.01 46 6212A 3 T Tyr2071Phe NS 0 0 1 Ͻ0.01 45 6229C 3 T Arg2077Trp NS 0 0 2 Ͻ0.01 46 6320G 3 A Arg2107His 0.01 Yes 0 0 10 0.01 46 6383A 3 G His2128Arg NS 0 0 1 Ͻ0.01 47 6446G 3 T Arg2149Leu NS 0 0 1 Ͻ0.01 47 6449G 3 A Cys2150Tyr NS 0 0 5 Ͻ0.01 48 6529G 3 A Asp2177Asn NS 2 0 0 Ͻ0.01 48 6686T 3 C Leu2229Pro NS 0 0 1 Ͻ0.01 48 6707delTCACACAG FS NS 0 0 1 Ͻ0.01 48 6729 ϩ 1g 3 a Splice site NS 0 0 1 Ͻ0.01 49 6764G 3 T Ser2255Ile 0.009 No 16 4 54 0.06 49 6788G 3 T Arg2263Leu NS 0 0 1 Ͻ0.01 (A) The probability under the null hypothesis of similar prevalence of each variant in Stargardt (STGD) compared with non-STGD alleles (two-tailed Fisher`s exact test); (B) compatability of the variant existing in a ratio of 100:1 in STGD to control alleles, calculated using the binomial distribution.

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ABCA4 p.Arg212Cys 11328725:102:714

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148 These included three nonconservative changes, Gly1961Glu, Arg1108Cys, and Arg212Cys, and five other changes that were conservative by our criteria, Leu541Pro, Ala1038Val, Pro1380Leu, Leu2027Phe, and Arg2107His.

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ABCA4 p.Arg212Cys 11328725:148:74

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103 Thirty-Three Truncated and 98 Amino Acid-Changing Variants in the ABCA4 Gene Exon Nucleotide Change Effect (A) (B) AMD (n d1d; 182) Control (n d1d; 96) STGD (n d1d; 374) Allele Prevalence 2 106delT FS NS 0 0 1 b0d;0.01 2 160 af9; 1g 3 a Splice site NS 0 0 1 b0d;0.01 3 161G 3 A Cys54Tyr NS 0 0 6 b0d;0.01 3 179C 3 T Ala60Val NS 0 0 2 b0d;0.01 3 194G 3 A Gly65Glu NS 0 0 2 b0d;0.01 3 223T 3 G Cys75Gly NS 0 0 2 b0d;0.01 3 247delCAAA FS NS 0 0 2 b0d;0.01 3 298C 3 T Ser100Pro NS 0 0 1 b0d;0.01 5 454C 3 T Arg152Stop NS 0 0 2 b0d;0.01 6 574G 3 A Ala192Thr NS 0 0 1 b0d;0.01 6 618C 3 G Ser206Arg NS 0 0 3 b0d;0.01 6 634C 3 T Arg212Cys 0.02 Yes 0 0 7 0.01 6 635G 3 A Arg212His NS 2 2 6 0.01 6 658C 3 T Arg220Cys NS 0 0 2 b0d;0.01 6 661delG FS NS 0 0 1 b0d;0.01 666delAAAGACGGTGC 6 GC FS NS 0 0 1 b0d;0.01 6 746A 3 C Asp249Gly NS 0 0 1 b0d;0.01 8 899C 3 A Thr300Asn NS 0 0 1 b0d;0.01 8 997C 3 T Arg333Trp NS 0 0 1 b0d;0.01 9 1140T 3 A Asn380Lys NS 0 0 1 b0d;0.01 9 1222C 3 T Arg408Stop NS 0 0 1 b0d;0.01 10 1268A 3 G His423Arg NS 1 0 7 0.01 10 1335C 3 G Ser445Arg NS 0 0 1 b0d;0.01 10 1344delG FS NS 0 0 1 b0d;0.01 11 1411G 3 A Glu471Lys NS 0 0 3 b0d;0.01 11 1513delATCAC FS NS 0 0 1 b0d;0.01 12 1622T 3 C Leu541Pro 0.001 Yes 0 0 11 0.01 13 1804C 3 T Arg602Trp NS 0 0 3 b0d;0.01 13 1805G 3 A Arg602Gln NS 0 0 1 b0d;0.01 13 1819G 3 T Gly607Trp NS 0 0 1 b0d;0.01 13 1823T 3 A Phe608Ile NS 0 0 1 b0d;0.01 13 1927G 3 A Val643Met NS 0 0 1 b0d;0.01 14 1989G 3 T Trp663Stop NS 0 0 1 b0d;0.01 14 2005delAT FS NS 0 0 3 b0d;0.01 14 2041C 3 T Arg681Stop NS 0 0 2 b0d;0.01 14 2147C 3 T Thr716Met NS 0 0 1 b0d;0.01 15 2291G 3 A Cys764Tyr NS 0 0 1 b0d;0.01 15 2294G 3 A Ser765Asn NS 0 0 1 b0d;0.01 15 2300T 3 A Val767Asp NS 0 0 2 b0d;0.01 16 2385del16bp FS NS 0 0 1 b0d;0.01 16 2453G 3 A Gly818Glu NS 0 0 1 b0d;0.01 16 2461T 3 A Trp821Arg NS 0 0 1 b0d;0.01 16 2546T 3 C Val849Ala NS 0 0 4 b0d;0.01 16 2552G 3 A Gly851Asp NS 0 0 1 b0d;0.01 16 2560G 3 A Ala854Thr NS 0 0 1 b0d;0.01 17 2588G 3 C Gly863Ala 0.0006 No 2 2 28 0.02 17 2617T 3 C Phe873Leu NS 0 0 1 b0d;0.01 18 2690C 3 T Thr897Ile NS 0 0 1 b0d;0.01 18 2701A 3 G Thr901Ala NS 0 1 0 b0d;0.01 18 2703A 3 G Thr901Arg NS 0 0 2 b0d;0.01 19 2828G 3 A Arg943Gln NS 20 13 37 0.05 19 2883delC FS NS 0 0 1 b0d;0.01 20 2894A 3 G Asn965Ser NS 0 0 3 b0d;0.01 19 2912C 3 A Thr971Asn NS 0 0 1 b0d;0.01 19 2915C 3 A Thr972Asn NS 0 0 1 b0d;0.01 20 2920T 3 C Ser974Pro NS 0 0 1 b0d;0.01 20 2966T 3 C Val989Ala NS 0 0 2 b0d;0.01 20 2977del8bp FS NS 0 0 1 b0d;0.01 20 3041T 3 G Leu1014Arg NS 0 0 1 b0d;0.01 21 3055A 3 G Thr1019Ala NS 0 0 1 b0d;0.01 21 3064G 3 A Glu1022Lys NS 0 0 1 b0d;0.01 21 3091A 3 G Lys1031Glu NS 0 0 1 b0d;0.01 21 3113G 3 T Ala1038Val 0.001 Yes 1 0 17 0.01 22 3205insAA FS NS 0 0 1 b0d;0.01 22 3261G 3 A Glu1087Lys NS 0 0 2 b0d;0.01 22 3322C 3 T Arg1108Cys 0.04 Yes 0 0 6 b0d;0.01 22 3323G 3 A Arg1108His NS 0 0 1 b0d;0.01 23 3364G 3 A Glu1122Lys NS 0 0 1 b0d;0.01 (continues) Exon Nucleotide Change Effect (A) (B) AMD (n d1d; 182) Control (n d1d; 96) STGD (n d1d; 374) Allele Prevalence 23 3386G 3 T Arg1129Leu NS 0 0 3 b0d;0.01 24 3531C 3 A Cys1158Stop NS 0 0 1 b0d;0.01 25 3749T 3 C Leu1250Pro NS 0 0 1 b0d;0.01 26 3835delGATTCT FS NS 0 0 1 b0d;0.01 27 3940C 3 A Pro1314Thr NS 0 1 0 b0d;0.01 28 4139C 3 T Pro1380Leu 0.001 Yes 0 0 10 0.01 28 4222T 3 C Trp1408Arg NS 0 0 2 b0d;0.01 28 4223G 3 T Trp1408Leu NS 0 0 2 b0d;0.01 28 4234C 3 T Gln1412stop NS 0 0 1 b0d;0.01 29 4297G 3 A Val1433Ile NS 1 0 0 b0d;0.01 29 4319T 3 C Phe1440Ser NS 0 0 1 b0d;0.01 30 4353 afa; 1g 3 t Splice site NS 0 0 1 b0d;0.01 30 4457C 3 T Pro1486Leu NS 0 0 1 b0d;0.01 30 4462T 3 C Cys1488Arg NS 0 0 3 b0d;0.01 30 4463G 3 T Cys1488Phe NS 0 0 2 b0d;0.01 30 4469G 3 A Cys1490Tyr NS 0 0 3 b0d;0.01 30 4531insC FS NS 0 0 2 b0d;0.01 32 4538A 3 G Gln1513Arg NS 0 0 1 b0d;0.01 30 4539 af9; 1g 3 t Splice site NS 0 0 1 b0d;0.01 31 4574T 3 C Leu1525Pro NS 0 0 1 b0d;0.01 33 4733delGTTT FS NS 0 0 1 b0d;0.01 4859delATAACAinsTCC 35 T FS NS 0 0 1 b0d;0.01 36 4909G 3 A Ala1637Thr NS 0 0 1 b0d;0.01 35 4918C 3 T Arg1640Trp NS 0 0 1 b0d;0.01 35 4919G 3 A Arg1640Gln NS 0 0 1 b0d;0.01 35 4954T 3 G Tyr1652Asp NS 0 0 1 b0d;0.01 36 5077G 3 A Val1693Ile NS 0 0 1 b0d;0.01 36 5186T 3 C Leu1729Pro NS 0 0 2 b0d;0.01 36 5206T 3 C Ser1736Pro NS 0 0 1 b0d;0.01 36 5212del11bp FS NS 0 0 1 b0d;0.01 37 5225delTGGTGGTGGGC FS NS 0 0 1 b0d;0.01 del LPA 37 5278del9bp 1760 NS 0 0 1 b0d;0.01 37 5288delG FS NS 0 0 1 b0d;0.01 38 5395A 3 G Asn1799Asp NS 0 0 1 b0d;0.01 38 5451T 3 G Asp1817Glu NS 1 0 4 b0d;0.01 39 5584 af9; 5g 3 a Splice site 0.02 Yes 0 0 6 b0d;0.01 40 5603A 3 T Asn1868Ile 0.0006 No 20 7 79 0.08 40 5651T 3 A Val1884GLu NS 0 0 1 b0d;0.01 40 5657G 3 A Gly1886Glu NS 0 0 1 b0d;0.01 40 5687T 3 A Val1896Asp NS 0 0 1 b0d;0.01 40 5693G 3 A Arg1898His NS 0 0 1 b0d;0.01 40 5714 af9; 5g 3 a Splice site NS 0 0 1 b0d;0.01 42 5843CA 3 TG Pro1948Leu NS 11 7 28 0.04 42 5882G 3 A Gly1961Glu b0d;0.0001 Yes 1 0 43 0.03 43 5908C 3 T Leu1970Phe NS 1 0 1 b0d;0.01 43 5917delG FS NS 0 0 1 b0d;0.01 44 6079C 3 T Leu2027Phe 0.01 Yes 0 0 9 0.01 44 6088C 3 T Arg2030Stop NS 0 0 2 b0d;0.01 44 6089G 3 A Arg2030Gln NS 0 0 1 b0d;0.01 44 6112A 3 T Arg2038Trp NS 0 0 1 b0d;0.01 45 6148A 3 C Val2050Leu NS 1 0 0 b0d;0.01 46 6212A 3 T Tyr2071Phe NS 0 0 1 b0d;0.01 45 6229C 3 T Arg2077Trp NS 0 0 2 b0d;0.01 46 6320G 3 A Arg2107His 0.01 Yes 0 0 10 0.01 46 6383A 3 G His2128Arg NS 0 0 1 b0d;0.01 47 6446G 3 T Arg2149Leu NS 0 0 1 b0d;0.01 47 6449G 3 A Cys2150Tyr NS 0 0 5 b0d;0.01 48 6529G 3 A Asp2177Asn NS 2 0 0 b0d;0.01 48 6686T 3 C Leu2229Pro NS 0 0 1 b0d;0.01 48 6707delTCACACAG FS NS 0 0 1 b0d;0.01 48 6729 af9; 1g 3 a Splice site NS 0 0 1 b0d;0.01 49 6764G 3 T Ser2255Ile 0.009 No 16 4 54 0.06 49 6788G 3 T Arg2263Leu NS 0 0 1 b0d;0.01 (A) The probability under the null hypothesis of similar prevalence of each variant in Stargardt (STGD) compared with non-STGD alleles (two-tailed Fisher`s exact test); (B) compatability of the variant existing in a ratio of 100:1 in STGD to control alleles, calculated using the binomial distribution.

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ABCA4 p.Arg212Cys 11328725:103:666

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149 These included three nonconservative changes, Gly1961Glu, Arg1108Cys, and Arg212Cys, and five other changes that were conservative by our criteria, Leu541Pro, Ala1038Val, Pro1380Leu, Leu2027Phe, and Arg2107His.

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ABCA4 p.Arg212Cys 11328725:149:74

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[hide] A comprehensive survey of sequence variation in th... Am J Hum Genet. 2000 Oct;67(4):800-13. Epub 2000 Aug 24. Rivera A, White K, Stohr H, Steiner K, Hemmrich N, Grimm T, Jurklies B, Lorenz B, Scholl HP, Apfelstedt-Sylla E, Weber BH
A comprehensive survey of sequence variation in the ABCA4 (ABCR) gene in Stargardt disease and age-related macular degeneration.
Am J Hum Genet. 2000 Oct;67(4):800-13. Epub 2000 Aug 24., [PMID:10958763]

Abstract [show]
Stargardt disease (STGD) is a common autosomal recessive maculopathy of early and young-adult onset and is caused by alterations in the gene encoding the photoreceptor-specific ATP-binding cassette (ABC) transporter (ABCA4). We have studied 144 patients with STGD and 220 unaffected individuals ascertained from the German population, to complete a comprehensive, population-specific survey of the sequence variation in the ABCA4 gene. In addition, we have assessed the proposed role for ABCA4 in age-related macular degeneration (AMD), a common cause of late-onset blindness, by studying 200 affected individuals with late-stage disease. Using a screening strategy based primarily on denaturing gradient gel electrophoresis, we have identified in the three study groups a total of 127 unique alterations, of which 90 have not been previously reported, and have classified 72 as probable pathogenic mutations. Of the 288 STGD chromosomes studied, mutations were identified in 166, resulting in a detection rate of approximately 58%. Eight different alleles account for 61% of the identified disease alleles, and at least one of these, the L541P-A1038V complex allele, appears to be a founder mutation in the German population. When the group with AMD and the control group were analyzed with the same methodology, 18 patients with AMD and 12 controls were found to harbor possible disease-associated alterations. This represents no significant difference between the two groups; however, for detection of modest effects of rare alleles in complex diseases, the analysis of larger cohorts of patients may be required.

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80 Nucleotide alterations occurring in sim- Table 2 ABCA4 Mutations Found in Patients with STGD and AMD and in Controls EXON AND NUCLEOTIDE CHANGE EFFECT NO. OF ALLELES REFERENCE(S) STGD (288) AMD (400) Control (440) 3: 178GrA A60T 1 0 0 This study 179CrT A60E 1 0 0 This study 194GrA G65E 1 0 0 Fishman et al. (1999) 203CrT P68L 1 0 0 This study 214GrA G72R 1 0 0 This study 296insA Frameshift 2 0 0 This study 5: 454CrT R152X 1 0 0 This study 6: 634CrT R212C 1 0 0 Lewis et al. (1999) 688TrA C230S 1 0 0 This study 730delCT Frameshift 1 0 0 This study 740ArG N247S 1 0 0 This study 768GrT Splice 2 0 0 Maugeri et al. (1999) 8: 983ArT E328V 1a 0 0 This study 1086TrA Y362X 1 0 0 This study 10: 1317GrA W438X 1 0 0 This study 11: 1411GrA E471K 1 0 0 Lewis et al. (1999) 12: 1622TrC L541P 21a 1a 0 Rozet et al. (1998), Fishman et al. (1999), Lewis et al. (1999), Maugeri et al. (1999) 1715GrA R572Q 1a 0 0 Lewis et al. (1999) 13: 1819GrA G607R 1 0 0 This study 1903CrA Q635K 2a 0 0 This study 1903CrT Q635X 1 0 0 This study IVS13ϩ1GrA Splice 2 0 0 This study 14: 1957CrT R653C 1 0 0 This study 1988GrA W663X 1 0 0 This study 2041CrT R681X 4 0 0 Maugeri et al. (1999) 15: 2291GrA C764Y 1 0 0 This study 2292delT Frameshift 1a 0 0 This study 2295TrG S765R 1a 0 0 This study 16: 2564GrA W855X 1 0 0 Nasonkin et al. (1998) 17: 2588GrC Spliceb 17a 6 5 Allikmets et al. (1997a), Cremers et al. (1998), Lewis et al. (1999), Maugeri et al. (1999), Papaioannou et al. (2000) 18: 2701ArG T901A 0 2 0 This study 2741ArG H914A 0 0 1 This study 19: 2876CrT T959I 1 0 0 This study 20: IVS20ϩ5GrA Splice 1 0 0 This study 21: 3106GrA E1036K 1a 0 0 Nasonkin et al. (1998) 3113CrT A1038V 26a 4a 1 Allikmets et al. (1997a), Cremers et al. (1998), Rozet et al. (1998), Fishman et al. (1999), Lewis et al. (1999), Maugeri et al. (1999) T3187TrC S1063P 1 0 0 This study (Continued) 805 Table 2 Continued EXON AND NUCLEOTIDE CHANGE EFFECT NO. OF ALLELES REFERENCE(S) STGD (288) AMD (400) Control (440) 22: 3292CrT R1097C 1 0 0 This study 3322CrT R1108C 4 0 0 Rozet et al. (1998), Fishman et al. (1999), Lewis et al. (1999) 24: 3528insTGCA Frameshift 1 0 0 This study 25: 3808GrT E1270X 1 0 0 This study 27: 3898CrT R1300X 1 0 0 This study 28: IVS28ϩ5GrA Splice 1 0 0 This study 4139CrT P1380L 1 0 0 Lewis et al. (1999) 4195GrA E1399K 2 0 0 This study 4234CrT Q1412X 4 0 0 Maugeri et al. (1999) 29: 4289TrC L1430P 2 0 0 This study 4318TrG F1440V 1 0 0 This study 4328GrA R1443H 1 0 0 This study 30: 4457CrT P1486L 1 0 0 Lewis et al. (1999) 4463GrA C1488Y 1 0 0 This study 31: 4610CrT T1537M 1 0 0 This study 35: IVS35ϩ2TrA Splice 1 0 0 This study 36: 5065TrC S1689P 1 0 0 This study 5114GrT R1705L 1 0 0 This study IVS36ϩ1GrA Splice 1 0 0 This study 37: 5198TrC M1733T 0 0 1 This study 5242GrA G1748R 1 0 0 This study 5248CrT Q1750X 1 0 0 This study 5288TrC L1763P 1 0 0 This study 38: IVS38ϩ1GrA Splice 1 0 0 This study 40: 5653GrA E1885K 1 0 0 This study 5693GrA R1898H 5 2 1 Allikmets et al. (1997b), Lewis et al. (1999) IVS40ϩ5GrA Splice 8a 0 0 Cremers et al. (1998), Lewis et al. (1999), Maugeri et al. (1999) 42: 5882GrA G1961E 34 4 2 Allikmets et al. (1997b), Fishman et al. (1999), Lewis et al. (1999), Maugeri et al. (1999) 43: 5917delG Frameshift 3 0 0 This study 5923GrC G1975R 1 0 0 This study 5929GrA G1977S 1 0 0 Rozet et al. (1998), Lewis et al. (1999) 45: 6229CrG R2077G 1 0 0 This study 6229CrT R2077W 1 0 0 Allikmets et al. (1997a), Fishman et al. (1999), Lewis et al. (1999) 48: 6609CrA Y2203X 2 0 0 This study 6647GrT A2216V 0 0 1 This study a Mutation pairs occurring on a single haplotype.

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ABCA4 p.Arg212Cys 10958763:80:454

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111 Likewise, for the intron 28 alteration, a spliced product Table 5 Patients with STGD Who Have Two Identified Disease Alleles AGE AT ONSET AND PATIENT MUTATION SEGREGATION IN FAMILY a Allele 1 Allele 2 5-9 years: STGD17 Q1412X R2077W Yes STGD88 G65E G1961E NA STGD93 G1961E G1961E Yes STGD99 L541P-A1038V G1961E Yes STGD100 L541P-A1038V IVS40ϩ5GrA Yes STGD108 Y362X IVS40ϩ5GrA Yes STGD109 L541P-A1038V W855X Yes STGD139b 5917delG 5917delG Yes STGD167 C1488Y IVS40ϩ5GrA Yes 10-14 years: STGD21 R681X R1898H NA STGD37 L541P-A1038V L541P-A1038V Yes STGD47/164 IVS13ϩ1GrA 2588GrC Yes STGD50 2588GrC A1038V NA STGD70 2588GrC IVS40ϩ5GrA NA STGD82 L541P-A1038V S1063P Yes STGD87 2588GrC Q1750X Yes STGD98 R212C T959I Yes STGD102 R572Q-2588GrC IVS35ϩ2TrA Yes STGD107 C764Y 3528ins4 Yes STGD120 L1430P L1430P NA STGD121 R1300X IVS40ϩ5GrA Yes STGD156 R1108C G1961E NA STGD159 R1108C Q1412X Yes STGD171 L541P-A1038V G1961E NA 15-19 years: STGD34 G768T G1961E Yes STGD39 L541P-A1038V R1443H NA STGD40/163 2588GrC E1885K Yes STGD45 E1399K G1977S Yes STGD59 R1898H G1975R NA STGD67 P68L S1689P Yes STGD75 Q635K IVS40ϩ5GrA Yes STGD111 2292delT-S765R G1961E Yes STGD114 Y2203X G1961E Yes STGD138 IVS13ϩ1GA 2588GrC Yes 20-24 years: STGD41 R681X G1961E Yes STGD63 A60T R1898H NA STGD86 296insA G1961E Yes STGD91 L541P-A1038V A1038V NA STGD113 L541P-A1038V 2588GrC Yes STGD118b IVS20ϩ5GrA G1961E Yes STGD119 L541P-A1038V G1961E Yes STGD122 L541P-A1038V G1961E Yes STGD135 W663X G1961E NA STGD147 IVS36ϩ1GrA G1961E Yes STGD168 L541P-A1038V G1961E NA 25-29 years: STGD62 G607R G1961E NA STGD71 296insA A1038V Yes STGD78 2588GrC Q1412X Yes STGD103 2588GrC IVS20ϩ5GrA Yes STGD116 L541P-A1038V G1961E Yes STGD139bb G1961E 5917delG Yes у30 years: STGD38 E471K G1961E Yes STGD68 E1399K G1961E Yes STGD69 L541P-A1038V 2588GrC NA STGD95 F1440V G1748R Yes STGD134 C230S G1961E NA STGD144 2588GrC R1705L NA STGD148 R1097C Y2203X NA STGD170 L541P-A1038V 2588GrC NA a NA p not applicable.

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ABCA4 p.Arg212Cys 10958763:111:730

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[hide] New ABCR mutations and clinical phenotype in Itali... Invest Ophthalmol Vis Sci. 2000 Mar;41(3):892-7. Simonelli F, Testa F, de Crecchio G, Rinaldi E, Hutchinson A, Atkinson A, Dean M, D'Urso M, Allikmets R
New ABCR mutations and clinical phenotype in Italian patients with Stargardt disease.
Invest Ophthalmol Vis Sci. 2000 Mar;41(3):892-7., [PMID:10711710]

Abstract [show]
PURPOSE: To assess the mutation spectrum in the ABCR gene and clinical phenotypes in Italian families with autosomal recessive Stargardt disease (STGD1) and fundus flavimaculatus (FFM). METHODS: Eleven families from southern Italy, including 18 patients with diagnoses of STGD1, were clinically examined. Ophthalmologic examination included kinetic perimetry, electrophysiological studies, and fluorescein angiography. DNA samples of the affected individuals and their family members were analyzed for variants in all 50 exons of the ABCR gene by a combination of single-strand conformation polymorphism analysis and direct sequencing techniques. RESULTS: TenABCR variants were identified in 16 (73%) of 22 mutant alleles of patients with STGD1. Five mutations of 10 that were found had not been previously described. The majority of variants represent missense amino acid substitutions, and all mutant alleles cosegregate with the disease in the respective families. These ABCR variants were not detected in 170 unaffected control individuals (340 chromosomes) of Italian origin. Clinical evaluation of these families affected by STGD1 showed an unusually high frequency of early age-related macular degeneration (AMD) in parents of patients with STGD1 (8/22; 36%), consistent with the hypothesis that some heterozygous ABCR mutations enhance susceptibility to AMD. CONCLUSIONS: Patients from southern Italy with Stargardt disease show extensive allelic heterogeneity of the ABCR gene, concordant with previous observations in patients with STGD1 from different ethnic groups. Half the mutations identified in this study had not been previously described in patients with STGD1. Screening of increasingly large numbers of patients would help to determine whether this can be explained by ethnic differences, or is an indicator of extensive allelic heterogeneity of ABCR in STGD1 and other eye diseases. In 6 (55%) of 11 families, the first-degree relatives of patients with STGD1 were diagnosed with early AMD, supporting the previous observation that some STGD1 alleles are also associated with AMD.

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55 Clinical Characteristics and Segregation of Mutations in 11 Italian STGD/FFM Pedigrees Pedigree Patients Age Age of Onset Visual Acuity Diagnosis Allele 1 Allele 2 431 431 S 18 10 20/200 STGD R212C R212C 433 D 29 8 20/200 STGD R212C R212C 432 F 63 10 LE 20/40RE LP High myopia with macular involvement R212C R212H(p) 858 Gm 87 10 LP High myopia with macular involvement wt R212H(p) 774 M 60 58 20/25 Pigmentary abnormalities and drusen R212C wt 260 D 41 35 20/200 STGD 250ƒCAAA G1961E 759 S 39 38 20/100 STGD 250ƒCAAA G1961E 760 M 60 57 20/40 Pigmentary abnormalities and drusen wt G1961E 761 Gs 20/20 Normal wt G1961E 762 Gs 20/20 Normal 250ƒCAAA wt 631 631 S 18 3 20/200 STGD / FFM 5018 ϩ 2T 3 C 5018 ϩ 2T 3 C 777 F 59 58 20/20 Soft distinct drusen 5018 ϩ 2T 3 C wt 779 M 52 50 20/20 Hard distinct drusen 5018 ϩ 2T 3 C wt 624 624 D 40 18 20/200 STGD R1640Q G1961E 625 S 36 20 20/200 STGD R1640Q G1961E 834 M 74 20/20 Normal R1640Q wt 636 636 S 22 15 20/400 STGD / FFM E1087K G1961E 778 M 43 43 20/20 Hard distinct drusen wt G1961E 632 632 D 24 8 20/200 STGD / FFM 250ƒCAAA V767D 628 628 S 27 18 20/200 STGD T897I N/D 4 F 63 20/20 Normal wt N/D 5 M 62 62 20/20 Pigmentary abnormalities and drusen T897I N/D 633 633 D 12 8 20/400 STGD / FFM A1038V N/D 776 S 15 20/20 Normal A1038V N/D 634 D 20 10 20/400 STGD / FFM A1038V N/D 3 F 60 60 20/20 Pigmentary abnormalities and drusen wt N/D 2 M 49 20/20 Normal A1038V N/D 615 615 S 22 8 20/200 STGD / FFM 5018 ϩ 2T 3 C N/D 616 D 23 10 20/200 STGD / FFM 5018 ϩ 2T 3 C N/D 764 D 25 20/20 Normal 5018 ϩ 2T 3 C N/D 763 F 60 20/20 Normal 5018 ϩ 2T 3 C N/D 765 M 55 55 20/20 Pigmentary abnormalities and drusen wt N/D 629 629 D 23 10 STGD / FFM E1399K N/D 622 627 D 47 12 20/400 STGD N/D N/D 622 D 35 8 20/400 STGD / FFM N/D N/D 623 C 19 10 20/200 STGD / FFM S, son; D, daughter; F, father; M, mother; C, cousin; Gm, grandmother; Gs, grandson; (p), polymorphism; wt, wild type; N/D, not determined.

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ABCA4 p.Arg212Cys 10711710:55:192

status: NEW

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ABCA4 p.Arg212Cys 10711710:55:198

status: NEW

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ABCA4 p.Arg212Cys 10711710:55:227

status: NEW

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ABCA4 p.Arg212Cys 10711710:55:233

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ABCA4 p.Arg212Cys 10711710:55:302

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ABCA4 p.Arg212Cys 10711710:55:436

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[hide] Age-related macular degeneration in grandparents o... Am J Ophthalmol. 1999 Aug;128(2):173-8. Souied EH, Ducroq D, Gerber S, Ghazi I, Rozet JM, Perrault I, Munnich A, Dufier JL, Coscas G, Soubrane G, Kaplan J
Age-related macular degeneration in grandparents of patients with Stargardt disease: genetic study.
Am J Ophthalmol. 1999 Aug;128(2):173-8., [PMID:10458172]

Abstract [show]
PURPOSE: To report clinical features and molecular genetic study in three unrelated families in which age-related macular degeneration was observed in grandparents of patients with Stargardt disease. METHODS: A complete ophthalmologic examination including best-corrected visual acuity measurement, fundus examination, and fluorescein angiography was performed on all members of the three families. The entire coding sequence of the ABCR gene was analyzed using a combination of single strand conformation polymorphism and direct sequence analysis of the 50 exons. RESULTS: Compound heterozygous missense mutations were observed in patients with Stargardt disease (Arg212Cys, Argl107Cys, Gly1977Ser, Arg2107His, and le2113Met). Heterozygous missense mutations were observed in the grandparents with age-related macular degeneration (Arg212Cys and Arg1107Cys). CONCLUSIONS: We report phenotype and genotype findings in three unrelated families segregating patients with Stargardt disease and age-related macular degeneration. The hypothesis that the Arg212Cys and Arg1107Cys ABCR gene mutations could be susceptibility factors for age-related macular degeneration is discussed. We speculate that the relatives of patients affected with Stargardt disease who are carriers of heterozygous ABCR gene mutations may have a higher risk of developing age-related macular degeneration.

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3 ● RESULTS: Compound heterozygous missense mutations were observed in patients with Stargardt disease (Arg212Cys, Arg1107Cys, Gly1977Ser, Arg2107His, and le2113Met).

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ABCA4 p.Arg212Cys 10458172:3:109

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4 Heterozygous missense mutations were observed in the grandparents with age-related macular degeneration (Arg212Cys and Arg1107Cys).

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ABCA4 p.Arg212Cys 10458172:4:105

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6 The hypothesis that the Arg212Cys and Arg1107Cys ABCR gene mutations could be susceptibility factors for age-related macular degeneration is discussed.

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ABCA4 p.Arg212Cys 10458172:6:24

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46 Compound heterozygous missense mutations were observed in patients with Stargardt disease: Arg212Cys and Ile2113Met (III.1 and III.2, family 1), Arg1107Cys and Arg2107His (III.1 and III.2, family 2), Arg212Cys and Gly1977Ser (III.1 family 3) (Figure 1).

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ABCA4 p.Arg212Cys 10458172:46:91

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ABCA4 p.Arg212Cys 10458172:46:200

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47 Heterozygous missense mutations were observed in the three grandparents affected with age-related macular degeneration: Arg212Cys (I.2 family 1; I.1 family 3) and Arg1107Cys (I.2 family 2) (Figure 3).

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ABCA4 p.Arg212Cys 10458172:47:120

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49 Among them, II.2 family 1 and II.2 family 2, carrying the Arg212Cys and Arg1107Cys mutations, displayed hard drusen on retinal examination.

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ABCA4 p.Arg212Cys 10458172:49:58

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56 Clinical Data of Individuals From the Three Pedigrees Individual, Family Age (yrs) Visual Acuity Macular Involvement (fundus examination and FA) Genotype*RE LE I.2, fam 1 78 CF CF RPE atrophy, some hard drusen and choroidal new vessel (Figure 2, top left) Arg212Cys/wt I.2, fam 2 86 CF CF Progressive geographic atrophy since the age of 80 (Figure 2, top right) Arg1107Cys/wt I.1, fam 2 75 20/30 20/40 Patches of RPE atrophy and perimacular soft drusen (Figure 2, middle left) Arg212Cys/wt I.2, fam 3 72 20/20 20/20 None wt/wt II.1, fam 1 44 20/20 20/20 None Ile2113Met/wt II.2, fam 1 50 20/20 20/25 Diffuse hard drusen (Figure 2, middle right) Arg212Cys/wt II.1, fam 2 70 20/20 20/20 None Arg2107His/wt II.2, fam 2 66 20/20 20/25 Diffuse hard drusen (Figure 2, bottom) Arg1107Cys/wt II.1, fam 3 37 20/20 20/20 None Gly1977Ser/wt II.2, fam 3 39 20/20 20/20 None Arg212Cys/wt III.1, fam 1 10 20/200 20/200 RPE atrophy, fundus flavimaculatus and choroidal silent Arg212Cys/Ile2113Met III.2, fam 1 6 20/20 20/20 None Ile2113Met/wt III.1, fam 2 33 20/200 CF RPE atrophy, fundus flavimaculatus and choroidal silent Arg1107Cys/Arg2107His III.2, fam 2 28 CF CF RPE atrophy, fundus flavimaculatus and choroidal silent Arg1107Cys/Arg2107His III.3, fam 2 24 20/20 20/20 None Arg2107His/wt III.1, fam 3 12 CF 20/200 RPE atrophy, fundus flavimaculatus and choroidal silent Arg212Cys/Gly1977Ser III.2, fam 3 9 20/20 20/20 None wt/wt CF ϭ counting fingers; FA ϭ fluorescein angiography; None ϭ no macular degeneration; RPE ϭ retinal pigment epithelium; wt ϭ wild type.

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ABCA4 p.Arg212Cys 10458172:56:256

status: NEW

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ABCA4 p.Arg212Cys 10458172:56:477

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ABCA4 p.Arg212Cys 10458172:56:645

status: NEW

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ABCA4 p.Arg212Cys 10458172:56:862

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ABCA4 p.Arg212Cys 10458172:56:961

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ABCA4 p.Arg212Cys 10458172:56:1361

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76 First, the Arg212Cys codon change occurs in the extracellular domain loop of the protein (predicted N-glycosylation site), and the Arg1107Cys occurred in a codon adjacent to the first transporter signature-motif.

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ABCA4 p.Arg212Cys 10458172:76:11

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90 Identification of the Arg212Cys ABCR gene mutation.

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ABCA4 p.Arg212Cys 10458172:90:22

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[hide] Genotype/Phenotype analysis of a photoreceptor-spe... Am J Hum Genet. 1999 Feb;64(2):422-34. Lewis RA, Shroyer NF, Singh N, Allikmets R, Hutchinson A, Li Y, Lupski JR, Leppert M, Dean M
Genotype/Phenotype analysis of a photoreceptor-specific ATP-binding cassette transporter gene, ABCR, in Stargardt disease.
Am J Hum Genet. 1999 Feb;64(2):422-34., [PMID:9973280]

Abstract [show]
Mutation scanning and direct DNA sequencing of all 50 exons of ABCR were completed for 150 families segregating recessive Stargardt disease (STGD1). ABCR variations were identified in 173 (57%) disease chromosomes, the majority of which represent missense amino acid substitutions. These ABCR variants were not found in 220 unaffected control individuals (440 chromosomes) but do cosegregate with the disease in these families with STGD1, and many occur in conserved functional domains. Missense amino acid substitutions located in the amino terminal one-third of the protein appear to be associated with earlier onset of the disease and may represent misfolding alleles. The two most common mutant alleles, G1961E and A1038V, each identified in 16 of 173 disease chromosomes, composed 18.5% of mutations identified. G1961E has been associated previously, at a statistically significant level in the heterozygous state, with age-related macular degeneration (AMD). Clinical evaluation of these 150 families with STGD1 revealed a high frequency of AMD in first- and second-degree relatives. These findings support the hypothesis that compound heterozygous ABCR mutations are responsible for STGD1 and that some heterozygous ABCR mutations may enhance susceptibility to AMD.

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76 2 0071GrA R24H 1 19 2894ArG N965S 3 36 5196ϩ1GrA Splice 2 3 0161GrA C54Y 1 21 3113CrT A1038V 16 5196ϩ2TrC Splice 1 0179CrT A60V 1 22 3211insGT FS 1 37 5281del9 PAL1761del 1 0203CrG P68R 1 3212CrT S1071L 1 38 5459GrC R1820P 1 0223TrG C75G 1 3215TrC V1072A 1 39 5512CrT H1838Y 1 6 0634CrT R212C 1 3259GrA E1087K 1 5527CrT R1843W 1 0664del13 FS 1 3322CrT R1108C 6 40 5585-1GrA Splice 1 0746ArG D249G 1 23 3364GrA E1122K 1 5657GrA G1886E 1 8 1007CrG S336C 1 3385GrT R1129C 1 5693GrA R1898H 4 1018TrG Y340D 1 3386GrT R1129L 2 5714ϩ5GrA Splice 8 11 1411GrA E471K 1 24 3602TrG L1201R 1 42 5882GrA G1961E 16 12 1569TrG D523E 1 25 3610GrA D1204N 1 5898ϩ1GrT Splice 3 1622TrC L541P 1 28 4139CrT P1380L 4 43 5908CrT L1970F 1 1715GrA R572Q 2 4216CrT H1406Y 1 5929GrA G1977S 1 1715GrC R572P 1 4222TrC W1408R 4 6005ϩ1GrT Splice 1 13 1804CrT R602W 1 4232insTATG FS 1 44 6079CrT L2027F 11 1822TrA F608I 2 4253ϩ5GrT Splice 1 6088CrT R2030X 1 1917CrA Y639X 1 29 4297GrA V1433I 1 6089GrA R2030Q 1 1933GrA D645N 1 4316GrA G1439D 2 6112CrT R2038W 1 14 2005delAT FS 1 4319TrC F1440S 1 45 6148GrC V2050L 2 2090GrA W697X 1 4346GrA W1449X 1 6166ArT K2056X 1 2160ϩ1GrC Splice 1 30a 4462TrC C1488R 2 6229CrT R2077W 1 16 2453GrA G818E 1 4457CrT P1486L 1 46 6286GrA E2096K 1 2461TrA W821R 1 30b 4469GrA C1490Y 3 6316CrT R2106C 1 2536GrC D846H 1 4539ϩ1GrT Splice 1 47 6391GrA E2131K 1 2552GrC G851D 1 31 4577CrT T1526M 7 6415CrT R2139W 1 17 2588GrC G863A 11 4594GrA D1532N 3 6445CrT R2149X 1 19 2791GrA V931M 2 35 4947delC FS 1 48 6543del36 1181del12 1 2827CrT R943W 1 36 5041del15 VVAIC1681del 2 6709insG FS 1 2884delC FS 1 5087GrA S1696N 1 NOTE.-FS ϭ frameshift.

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ABCA4 p.Arg212Cys 9973280:76:299

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77 2 0071GrA R24H 1 19 2894ArG N965S 3 36 5196af9;1GrA Splice 2 3 0161GrA C54Y 1 21 3113CrT A1038V 16 5196af9;2TrC Splice 1 0179CrT A60V 1 22 3211insGT FS 1 37 5281del9 PAL1761del 1 0203CrG P68R 1 3212CrT S1071L 1 38 5459GrC R1820P 1 0223TrG C75G 1 3215TrC V1072A 1 39 5512CrT H1838Y 1 6 0634CrT R212C 1 3259GrA E1087K 1 5527CrT R1843W 1 0664del13 FS 1 3322CrT R1108C 6 40 5585afa;1GrA Splice 1 0746ArG D249G 1 23 3364GrA E1122K 1 5657GrA G1886E 1 8 1007CrG S336C 1 3385GrT R1129C 1 5693GrA R1898H 4 1018TrG Y340D 1 3386GrT R1129L 2 5714af9;5GrA Splice 8 11 1411GrA E471K 1 24 3602TrG L1201R 1 42 5882GrA G1961E 16 12 1569TrG D523E 1 25 3610GrA D1204N 1 5898af9;1GrT Splice 3 1622TrC L541P 1 28 4139CrT P1380L 4 43 5908CrT L1970F 1 1715GrA R572Q 2 4216CrT H1406Y 1 5929GrA G1977S 1 1715GrC R572P 1 4222TrC W1408R 4 6005af9;1GrT Splice 1 13 1804CrT R602W 1 4232insTATG FS 1 44 6079CrT L2027F 11 1822TrA F608I 2 4253af9;5GrT Splice 1 6088CrT R2030X 1 1917CrA Y639X 1 29 4297GrA V1433I 1 6089GrA R2030Q 1 1933GrA D645N 1 4316GrA G1439D 2 6112CrT R2038W 1 14 2005delAT FS 1 4319TrC F1440S 1 45 6148GrC V2050L 2 2090GrA W697X 1 4346GrA W1449X 1 6166ArT K2056X 1 2160af9;1GrC Splice 1 30a 4462TrC C1488R 2 6229CrT R2077W 1 16 2453GrA G818E 1 4457CrT P1486L 1 46 6286GrA E2096K 1 2461TrA W821R 1 30b 4469GrA C1490Y 3 6316CrT R2106C 1 2536GrC D846H 1 4539af9;1GrT Splice 1 47 6391GrA E2131K 1 2552GrC G851D 1 31 4577CrT T1526M 7 6415CrT R2139W 1 17 2588GrC G863A 11 4594GrA D1532N 3 6445CrT R2149X 1 19 2791GrA V931M 2 35 4947delC FS 1 48 6543del36 1181del12 1 2827CrT R943W 1 36 5041del15 VVAIC1681del 2 6709insG FS 1 2884delC FS 1 5087GrA S1696N 1 NOTE.-FS afd; frameshift.

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ABCA4 p.Arg212Cys 9973280:77:299

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[hide] Complete exon-intron structure of the retina-speci... Genomics. 1998 Feb 15;48(1):139-42. Gerber S, Rozet JM, van de Pol TJ, Hoyng CB, Munnich A, Blankenagel A, Kaplan J, Cremers FP
Complete exon-intron structure of the retina-specific ATP binding transporter gene (ABCR) allows the identification of novel mutations underlying Stargardt disease.
Genomics. 1998 Feb 15;48(1):139-42., [PMID:9503029]

Abstract [show]
Stargardt disease, an autosomal recessive macular dystrophy of childhood, leading to severe visual impairment, is caused by mutations in the retina-specific ATP binding transporter gene (ABCR). Previously, the ABCR cDNA and part of the exon-intron structure were described. We have determined the complete ABCR exon-intron structure by exon-exon PCR. The ABCR gene encompasses 50 exons, 29 of which are first described here with their corresponding intron-exon boundaries. The discovery of a splicing mutation (571: 2A-->G) and missense mutations in the newly identified exons (R18W, R212C) gives additional support to the broad allelic heterogeneity of Stargardt disease.

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6 Amplification conditions were 94ЊC for 4 exons (R18W, R212C) gives additional support to the min followed by 10 cycles at 93ЊC for 10 s, 59ЊC for 15 broad allelic heterogeneity of Stargardt disease.

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ABCA4 p.Arg212Cys 9503029:6:60

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[hide] Detection rate of pathogenic mutations in ABCA4 us... Arch Ophthalmol. 2012 Nov;130(11):1486-90. doi: 10.1001/archophthalmol.2012.1697. Downes SM, Packham E, Cranston T, Clouston P, Seller A, Nemeth AH
Detection rate of pathogenic mutations in ABCA4 using direct sequencing: clinical and research implications.
Arch Ophthalmol. 2012 Nov;130(11):1486-90. doi: 10.1001/archophthalmol.2012.1697., [PMID:23143460]

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28 In 5 of the 11 patients, the identification of 2 pathogenic mutations confirmed the historical diagnosis and all had chorioretinal atro- Table. Results From Direct Sequencing of the ABCA4 Gene in 50 Patients Subject No. Change 1 Change 2 Phase Segregation Age at Onset, y Phenotype Grade, Macula Flecks/ Cones/Rodsa Additional Variants Conclusion Nucleotide Amino Acid Nucleotide Amino Acid 1 1Ab0e;G M1V 2588Gb0e;C G863A In trans Unaffected parents carriers 30 STGD maf9;/0/0 R2030Q 3 PVs 2 161Gb0e;A C54Y 2588Gb0e;C G863A In trans Affected sibling with same mutations 12 STGD m/0/0 0 2 PVs 3 161Gb0e;A C54Y 5882Gb0e;A G1961E NK NK 18 STGD m/0/0 0 2 PVs 4 634Cb0e;T R212C 4457Cb0e;T P1486L In trans Unaffected parents carriers 17 STGD m/0/0 0 2 PVs 5 2588Gb0e;C G863A 4469Gb0e;A C1490Y NK NK 48 STGD maf9;/0/1 0 2 PVs 6 2971Gb0e;C G991R 4254-2Ab0e;G Splice NK NK 21 STGD m/0/0 0 2 PVs 7 2971Gb0e;C G991R 3602Tb0e;G L1201R NK NK 18 STGD maf9;af9;/NP/NP V643M (likely), G885E (likely), G1441D (unlikely), V2244V (highly likely) b0e;2 PVs 8 3322Cb0e;T R1108C 768Gb0e;T V256V NK NK 13 STGD maf9;af9;/1/1 0 2 PVs 9 3322Cb0e;T R1108C 6079Cb0e;T L2027F NK NK 26 STGD maf9;/0/0 0 2 PVs 10 3386Gb0e;T R1129L 4469Gb0e;A C1490Y In trans Unaffected parents carriers 15 STGD maf9;/0/0 R152Q (unlikely) 2 PVs (continued) ARCH OPHTHALMOL/VOL 130 (NO. 11), NOV 2012 WWW.ARCHOPHTHALMOL.COM 1486 phy on current clinical examination, consistent with progression of the disorder.5 One of the 11 patients with chorioretinal atrophy (subject 40) had a single stop codon, again strongly supporting the original clinical diagnosis. Six of the 11 patients did not have pathogenic mutations in ABCA4.

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ABCA4 p.Arg212Cys 23143460:28:691

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[hide] ABCA4 mutational spectrum in Mexican patients with... Exp Eye Res. 2013 Apr;109:77-82. doi: 10.1016/j.exer.2013.02.006. Epub 2013 Feb 16. Chacon-Camacho OF, Granillo-Alvarez M, Ayala-Ramirez R, Zenteno JC
ABCA4 mutational spectrum in Mexican patients with Stargardt disease: Identification of 12 novel mutations and evidence of a founder effect for the common p.A1773V mutation.
Exp Eye Res. 2013 Apr;109:77-82. doi: 10.1016/j.exer.2013.02.006. Epub 2013 Feb 16., [PMID:23419329]

Abstract [show]
The aim of this study was to assess the mutational spectrum of the ABCA4 gene in a cohort of patients with Stargardt disease from Mexico, a previously uncharacterized population. Clinical diagnosis in each patient was supported by a complete ophthalmological assessment that included visual acuity measurement, a slit lamp examination, a fundus examination and photography, electroretinography, fluorescein angiography, and computerized visual fields testing. Molecular analysis was performed by PCR amplification and direct nucleotide sequence of the 50 exons of the ABCA4 gene in genomic DNA. A total of 31 unrelated subjects with the disease were enrolled in the study. Molecular analysis in the total group of 62 alleles allowed the identification of 46 mutant ABCA4 alleles carrying 29 different pathogenic disease-associated mutations. Two ABCA4 mutant alleles were detected in 20 of the 31 patients (64.5%), a single disease allele was identified in six (19.4%), and no mutant alleles were detected in five of the cases (16.1%). Most patients with two ABCA4 mutations (11/20, 55%) were compound heterozygotes. Twelve variants were novel ABCA4 mutations. Nucleotide substitutions were the most frequent type of variation, occurring in 26 out of 29 (89.7%) different mutations. The two most common mutations in our study were the missense changes p.A1773V and p.G818E, which were identified in eight (17%) and seven (15%) of the total 46 disease-associated alleles, respectively. Haplotype analyses of intragenic SNPs in four subjects carrying the p.A1773V mutation supported a common origin for this mutation. In conclusion, this is the first report of ABCA4 molecular screening in Latin American Stargardt disease patients. Our results expand the mutational spectrum of the disease by adding 12 novel ABCA4 pathogenic variants and support the occurrence of a founder effect for the p.A1773V mutation in the Mexican population. The identification of recurrent mutations in our cohort will direct future ABCA4 molecular screening in patients from this ethnic group.

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100 Allele 1 Allele 2 Genotype Exon Nucleotide change Polypeptide change Exon Nucleotide change Polypeptide change Familial case # 1 38 c.5318C>T p.A1773V (D) 38 c.5318C>T p.A1773V (D) Homozygous 2 e NI e e NI e e 3 6 c.634C>T p.R212C (D) 38 c.5318C>T p.A1773V (D) Compound heterozygous 4 23 c.3386G>T p.R1129L (D) 28 c.4139C>T p.P1380L (D) Compound heterozygous 5 e NI e e NI e e 6 38 c.5318C>T p.A1773V (D) 38 c.5318C>T p.A1773V (D) Homozygous 7 e NI e e NI e e 8 16 c.2453G>A p.G818E (D) 28 c.4249_4251 delTTC p.F1417del (D; N) Compound heterozygous 9 38 c.5318C>T p.A1773V (D) 38 c.5318C>T p.A1773V (D) Homozygous Sporadic case # 1 8 c.868C>T p.R290W (D) e IVS8&#fe;1G>A Splicing (D; N) Compound heterozygous 2 38 c.5318C>T p.A1773V (D) - NI - Heterozygous 3 20 c.3041T>G p.L1014R (D) 1; 49 c.52C>T; c.6764G>T p.R18W (D); p.S2255I (B) Compound heterozygous 4 13; 19 c.1804C>T; c.2828G>A p.R602W (D); p.R943Q (U) 16 c.2453G>A p.G818E (D) Compound heterozygous 5 38 c.5324T>A p. I1775N (D; N) 38 c.5324T>A p.I1775N (D; N) Homozygous 6 e NI e e NI e e 7 49 c.6764G>T p.S2255I (B) 49 c.6764 G>T p.S2255I (B) Homozygous 8 19; 40 c.2828 G>A; c.5503A>T p.R943Q (U); p.N1868I (U) 3 c.265G>T p.E89* (D; N) Compound heterozygous 9 38 c.5335T>C p.Y1779H (D;N) 38 c.5335T>C p.Y1779H (D;N) Homozygous 10 16 c.2453G>A p.G818E (D) 16 c.2453G>A p.G818E (D) Homozygous 11 6 c.723A>T p.E241D (D;N) 36 c.5114G>A p.R1705Q (D) Compound heterozygous 12 2 c.71G>A (D) p.R24H e NI e Heterozygous 13 30 c.4537_4538insC p.Q1513Pfs*41 (D; N) e NI e Heterozygous 14 32 c.4667G>C p.R1556T (D; N) 32 c.4667G>C p.R1556T (D; N) Homozygous 15 45 c.6221G>T p.G2074V (D; N) 16 c.2453G>A p.G818E (D) Compound heterozygous 16 16; 41 c.2453G>A; c.5824G>C p. G818E (D); p. E1942Q (B;N) 46 c.6384A>G p.H2128R (D) Compound heterozygous 17 16 c.2453G>A p. G818E (D) e NI e Heterozygous 18 32 c.4653G>A p. W1551* (D; N) e NI e Heterozygous 19 23 c.3386G>T p. R1129L (D) e NI e Heterozygous 20 36 c.5045_5059del GTTGCCATCTGCGTG p.V1682_ V1686del (D; N) 29; 49 c.4328G>A; c.6764G>T p.R1443H (D); p.S2255I (B) Compound heterozygous 21 19 c.2894A>G p.N965S (D) 19 c.2894A>G p.N965S (D) Homozygous 22 e NI e e NI e e STGD accounts for approximately 7% of all retinal dystrophies; it is one of the most common genetic forms of juvenile or early adult onset macular degeneration.

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ABCA4 p.Arg212Cys 23419329:100:225

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119 ABCA4 Exon # Nucleotide change Predicted protein effect Number of alleles Population genotypic frequency in EVS Population allelic frequency in EVS (%) 1 c.52C>T p.R18W 1 TT &#bc; 0/TC &#bc; 2/CC &#bc; 6501 T &#bc; 0.015/C &#bc; 99.985 2 c.71G>A p.R24H 1 AA &#bc; 0/AG &#bc; 1/GG &#bc; 6502 A &#bc; 0.008/G &#bc; 99.992 3 c.265G>T p.E89* (N) 1 NR NR 6 c.634C>T p.R212C 1 TT &#bc; 0/TC &#bc; 2/CC &#bc; 6501 T &#bc; 0.015/C &#bc; 99.985 6 c.723A>T p.E241D (N) 1 NR NR 8 c.868C>T p.R290W 1 NR NR IVS8 IVS8 &#fe; 1G>A Splicing mutation (N) 1 NR NR 13 c.1804C>T p.R602W 1 NR NR 16 c.2453G>A p.G818E 7 NR NR 19 c.2828G>A p.R943Q 2 AA &#bc; 8/AG &#bc; 400/GG &#bc; 6095 A &#bc; 3.199/G &#bc; 96.801 19 c.2894A>G p.N965S 2 GG &#bc; 0/GA &#bc; 1/AA &#bc; 6502 G &#bc; 0.008/A &#bc; 99.992 20 c.3041T>G p.L1014R 1 NR NR 23 c.3386G>T p.R1129L 2 NR NR 28 c.4139C>T p.P1380L 1 TT &#bc; 0/TC &#bc; 2/CC &#bc; 6501 T &#bc; 0.015/C &#bc; 99.985 28 c.4249_4251del TTC p.F1417del (N) 1 NR NR 29 c.4328G>A p.R1443H 1 AA &#bc; 0/AG &#bc; 1/GG &#bc; 6502 A &#bc; 0.008/G &#bc; 99.992 30 c.4537_4538insC p.Q1513Pfs*41 (N) 1 NR NR 32 c.4653G>A p.W1551* (N) 1 NR NR 32 c.4667G>C p.R1556T (N) 2 NR NR 36 c.5044_5058del GTTGCCATCTGCGTG p.V1682_V1686del (N) 1 NR NR 36 c.5114G>A p.R1705Q 1 AA &#bc; 0/AG &#bc; 1/GG &#bc; 6502 A &#bc; 0.008/G &#bc; 99.992 38 c.5318C>T p.A1773V 8 NR NR 38 c.5324T>A p.I1775N (N) 2 NR NR 38 c.5335T>C p.Y1779H (N) 2 NR NR 40 c.5503A>T p.N1868I 1 TT &#bc; 16/TA &#bc; 589/AA &#bc; 5898 T &#bc; 4.775/A &#bc; 95.225 41 c.5824G>C p.E1942Q (N) 1 NR NR 45 c.6221G>T p.G2074V (N) 1 NR NR 46 c.6384A>G p.H2128R 1 NR NR 49 c.6764G>T p.S2255I 4 TT &#bc; 516/TG &#bc; 1473/GG &#bc; 4514 T &#bc; 19.26/G &#bc; 80.74 gold standard for ABCA4 mutational screening.

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ABCA4 p.Arg212Cys 23419329:119:363

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[hide] The clinical effect of homozygous ABCA4 alleles in... Ophthalmology. 2013 Nov;120(11):2324-31. doi: 10.1016/j.ophtha.2013.04.016. Epub 2013 Jun 12. Fujinami K, Sergouniotis PI, Davidson AE, Mackay DS, Tsunoda K, Tsubota K, Robson AG, Holder GE, Moore AT, Michaelides M, Webster AR
The clinical effect of homozygous ABCA4 alleles in 18 patients.
Ophthalmology. 2013 Nov;120(11):2324-31. doi: 10.1016/j.ophtha.2013.04.016. Epub 2013 Jun 12., [PMID:23769331]

Abstract [show]
PURPOSE: To describe the phenotypic presentation of a cohort of individuals with homozygous disease-associated ABCA4 variants. DESIGN: Retrospective case series. PARTICIPANTS: Eighteen affected individuals from 13 families ascertained from a total cohort of 214 families with ABCA4-related retinal disease presenting to a single center. METHODS: A detailed history was obtained, and color fundus photography, autofluorescence (AF) imaging, optical coherence tomography (OCT), and electrophysiologic assessment were performed. Phenotypes based on ophthalmoscopy, AF, and electrophysiology were assigned using previously reported characteristics. ABCA4 mutation detection was performed using the ABCR400 microarray (Asper Biotech, Tartu, Estonia) and high-throughput DNA sequencing, with direct sequencing used to assess segregation. MAIN OUTCOME MEASURES: Detailed clinical, electrophysiologic, and molecular genetic findings. RESULTS: Eleven disease-associated homozygous ABCA4 alleles were identified, including 1 frame shift, 2 stops, 1 intronic variant causing splice-site alteration, 2 complex missense variants, and 5 missense variants: p.Glu905fsX916, p.Arg1300X, p.Gln2220X, c.4253+4 C>T, p.Leu541Pro and p.Ala1038Val (homozygosity for complex allele), p.Val931Met and p.Arg1705Gln (complex allele), p.Arg212Cys, p.Cys1488Arg, p.Arg1640Trp, p.Gly1961Glu, and p.Leu2027Phe. Eight of these 11 homozygous alleles have not been reported previously. Six of 7 patients with homozygous null alleles had early-onset (<10 years) disease, with all 7 having a severe phenotype. Two patients with homozygous missense variants (p.Leu541Pro and p.Ala1038Val [complex], and p.Arg1640Trp) presented with a severe phenotype. Three patients with homozygous p.Gly1961Glu had adult-onset disease and a mild phenotype. One patient with homozygous p.Leu2027Phe showed a spared fovea and preserved visual acuity. CONCLUSIONS: The phenotypes represented in patients identified as homozygous for presumed disease-associated ABCA4 variants gives insight into the effect of individual alleles. Null alleles have severe functional effects, and certain missense variants are similar to nulls, suggesting complete abrogation of protein function. The common alleles identified, p.Gly1961Glu and p. Leu2027Phe, both have a mild structural and functional effect on the adult retina; the latter is associated with relatively retained photoreceptor architecture and function at the fovea.

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7 Results: Eleven disease-associated homozygous ABCA4 alleles were identified, including 1 frame shift, 2 stops, 1 intronic variant causing splice-site alteration, 2 complex missense variants, and 5 missense variants: p.Glu905fsX916, p.Arg1300X, p.Gln2220X, c.4253&#fe;4 C>T, p.Leu541Pro and p.Ala1038Val (homozygosity for complex allele), p.Val931Met and p.Arg1705Gln (complex allele), p.Arg212Cys, p.Cys1488Arg, p.Arg1640Trp, p.Gly1961Glu, and p.Leu2027Phe.

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ABCA4 p.Arg212Cys 23769331:7:387

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60 Sex Ethnicity Consanguinity Age at Onset (yrs) Age (yrs) Duration of Disease (yrs) LogMAR VA Fundus Appearance AF Pattern ERG Group OCT Central Foveal Thickness (mm) Mutation Status RE LE RE LE 1 1 M S Asian Yes (1st cousin) 11 33 22 1.0 1.0 2 2 1 64 69 c.634 C>T, p.Arg212Cys 2 1 F S Asian Yes (1st cousin) 11 36 25 1.0 1.0 2 2 3 31 41 c.634 C>T, p.Arg212Cys 3* 2 M European No 3 8 5 1.2 1.2 2 2 3y 41 36 c.1622 T>C, p.Leu541Pro / c.3113 C>T, p.Ala1038Val 4 3 F S Asian Yes (2nd cousin once removed) 5 8 3 1.0 1.0 2 2 3 NA NA c.2713delG, p.Glu905fsX916 5 4 M S Asian Yes (unknown) 10 25 15 1.0 1.08 2 2 3 64 60 c.2791 G>A, p.Val931Met / c.5114 G>A, p.Arg1705Gln 6 5 M S Asian Yes (1st cousin) 10 30 20 1.0 1.0 2 2 3 NA NA c.4462 T>C, p.Cys1488Arg 7 5 F S Asian Yes (1st cousin) 10 22 12 2.0 1.0 2 2 3 NA NA c.4462 T>C, p.Cys1488Arg 8 6 M ME Asian Yes (1st cousin) 30 36 6 1.08 2.0 3 3 3 103 95 c.4918 C>T, p.Arg1640Trp 9 7 F S Asian Yes (2nd cousin) 19 27 8 1.78 2.0 1 2 1 128 90 c.5882 G>A, p.Gly1961Glu 10 7 M S Asian Yes (2nd cousin) 30 34 4 0.48 0.48 1 2 1 NA NA c.5882 G>A, p.Gly1961Glu 11 8 F S Asian Yes (1st cousin) 17 26 9 0.78 0.78 1 1 1 54 47 c.5882 G>A, p.Gly1961Glu 12 9 F European No 44 44 0 0.18 0.0 2 2 1 NA NA c.6079 C>T, p.Leu2027Phe 13 10 M ME Asian Yes (1st cousin) 5 11 6 1.3 1.0 3 2 3 62 68 c.3898 C>T, p.Arg1300X 14 11 M S Asian Yes (unknown) 8 11 3 1.0 1.0 2 2 3 NA NA c.4253&#fe;4 C>T 15 12 M S Asian Yes (1st cousin) 9 48 39 3.0 3.0 3 NA 3 NA NA c.6658 C>T, p.Gln2220X 16 13 M S Asian Yes (uncle and niece) 4 7 3 1.08 1.08 1 NA 3 NA NA c.6658 C>T, p.Gln2220X 17 13 M S Asian Yes (uncle and niece) 6 8 2 1.08 1.0 1 NA 3 NA NA c.6658 C>T, p.Gln2220X 18 13 M S Asian Yes (1st cousin) 17 25 8 1.78 1.78 3 NA 3 NA NA c.6658 C>T, p.Gln2220X AF &#bc; autofluorescence; ERG &#bc; electroretinography; F &#bc; female; FM No.

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ABCA4 p.Arg212Cys 23769331:60:267

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ABCA4 p.Arg212Cys 23769331:60:350

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97 Two siblings (patients 1 and 2), homozygous for p.Arg212Cys, showed a similar moderate findings: age of onset (11 years), logMAR visual acuity (1.0), type 2 fundus appearance, type 2 AF pattern, and atrophic change at the fovea on OCT, but ERG grouping was discordant (group 1 and 3).

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ABCA4 p.Arg212Cys 23769331:97:50

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118 This supports previous reports of p.Leu2027Phe in heterozygous patients.14,23 Of note, p.Gly1961Glu and p.Leu2027Phe are both situated in the nucleotide-binding domain 2 subunit, shown to be the site of adenosine triphosphatase activity (Fig 5, available at http://aaojournal.org).39,40 Subjects homozygous for p.Arg212Cys had phenotypes of moderate severity, and these findings are generally in keeping with previous reports.19 Patient 5, homozygous for p.Val931Met and p.Arg1705Gln in complex, and subjects 6 and 7, homozygous for p.Cys1488Arg, had "typical" Stargardt`s disease fundus and AF findings with macular atrophy surrounded by flecks with electrophysiologic evidence of generalized rod and cone system dysfunction.

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ABCA4 p.Arg212Cys 23769331:118:313

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124 Concordance in phenotypic features between patients with an identical disease-causing variant was observed in individuals homozygous for p.Arg212Cys, p.Cys1488Arg, p.Gly1961Glu, and p.Gln2220X, suggesting that few modifiers exist.

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ABCA4 p.Arg212Cys 23769331:124:139

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[hide] Clinical and molecular analysis of Stargardt disea... Am J Ophthalmol. 2013 Sep;156(3):487-501.e1. doi: 10.1016/j.ajo.2013.05.003. Fujinami K, Sergouniotis PI, Davidson AE, Wright G, Chana RK, Tsunoda K, Tsubota K, Egan CA, Robson AG, Moore AT, Holder GE, Michaelides M, Webster AR
Clinical and molecular analysis of Stargardt disease with preserved foveal structure and function.
Am J Ophthalmol. 2013 Sep;156(3):487-501.e1. doi: 10.1016/j.ajo.2013.05.003., [PMID:23953153]

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PURPOSE: To describe a cohort of patients with Stargardt disease who show a foveal-sparing phenotype. DESIGN: Retrospective case series. METHODS: The foveal-sparing phenotype was defined as foveal preservation on autofluorescence imaging, despite a retinopathy otherwise consistent with Stargardt disease. Forty such individuals were ascertained and a full ophthalmic examination was undertaken. Following mutation screening of ABCA4, the molecular findings were compared with those of patients with Stargardt disease but no foveal sparing. RESULTS: The median age of onset and age at examination of 40 patients with the foveal-sparing phenotype were 43.5 and 46.5 years. The median logMAR visual acuity was 0.18. Twenty-two patients (22/40, 55%) had patchy parafoveal atrophy and flecks; 8 (20%) had numerous flecks at the posterior pole without atrophy; 7 (17.5%) had mottled retinal pigment epithelial changes; 2 (5%) had multiple atrophic lesions, extending beyond the arcades; and 1 (2.5%) had a bull's-eye appearance. The median central foveal thickness assessed with spectral-domain optical coherence tomographic images was 183.0 mum (n = 33), with outer retinal tubulation observed in 15 (45%). Twenty-two of 33 subjects (67%) had electrophysiological evidence of macular dysfunction without generalized retinal dysfunction. Disease-causing variants were found in 31 patients (31/40, 78%). There was a higher prevalence of the variant p.Arg2030Gln in the cohort with foveal sparing compared to the group with foveal atrophy (6.45% vs 1.07%). CONCLUSIONS: The distinct clinical and molecular characteristics of patients with the foveal-sparing phenotype are described. The presence of 2 distinct phenotypes of Stargardt disease (foveal sparing and foveal atrophy) suggests that there may be more than 1 disease mechanism in ABCA4 retinopathy.

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141 Allele Frequencies of 72 ABCA4 Variants Identified in a Comparison Groupa With the Typical Stargardt Disease (140 Patients Without Evidence of Foveal Sparing on Autofluorescence Imaging) Exon Nucleotide Substitution and Amino Acid Change Number of Alleles Allele Frequency 2 c.71G>A, p.Arg24His 1 0.36% 2 c.161G>A, p.Cys54Tyr 3 1.07% 3 c.223T>G, p.Cys75Gly 1 0.36% 5 c.455G>A, p.Arg152Gln 1 0.36% 5 c.454C>T, p.Arg152* 1 0.36% 5 c.466 A>G, p.Ile156Val 2 0.71% 6 c.634C>T, p. Arg212Cys 3 1.07% 6 c.656G>C, p.Arg219Thr 1 0.36% 6 c.666_678delAAAGACGGTGCGC, p.Lys223_Arg226delfs 2 0.71% 6 c.768G>T, Splicing site 4 1.42% 8 c.1037A>C, p.Lys346Thr 1 0.36% 10 c.1222C>T, p.Arg408* 3 1.07% 12 c.1622T>C, p.Leu541Pro 2 0.71% 12 c.1648 G>T, p.Gly550* 1 0.36% 13 c.1804C>T, p.Arg602Trp 1 0.36% 13 c.1817G>A, p.Gly606Asp 1 0.36% 13 c.1922G>C, p.Cys641Ser 1 0.36% Int 13 c.1937&#fe;1G>A, Splicing site 2 0.71% 14 c.1957C>T, p.Arg653Cys 2 0.71% 17 c.2588G>C, p.Gly863Ala 19 6.79% 18 c.2701A>G, p.Thr901Ala 1 0.36% 19 c.2791G>A, p.Val931Met 2 0.71% 19 c.2894A>G, p.Asn965Ser 1 0.36% 20 c.2966T>C, p.Vla989Ala 3 1.07% 20 c.2971G>C, p.Gly991Arg 2 0.71% 21 c.3056C>T, p.Thr1019Met 1 0.36% 21 c.3113C>T, p.Ala1038Val 3 1.07% 21 c.3064G>A, p.Glu1022Lys 2 0.71% 22 c.3211_3212insGT, p.Ser1071Cysfs 6 2.14% 22 c.3259G>A, p.Glu1087Lys 4 1.43% 22 c.3292C>T, p.Arg1098Cys 1 0.36% 22 c.3322C>T, p.Arg1108Cys 5 1.79% 22 c.3323G>A, p.Arg1108His 1 0.36% 23 c.3364G>A, p.Glu1122Lys 1 0.36% 23 c.3386G>A, p.Arg1129His 1 0.36% 24 c.3602T>G, p.Leu1201Arg 3 1.07% 27 c.3898C>T, p.Arg1300* 2 0.71% 28 c.4139C>T, p.Pro1380Leu 14 5.00% 28 c.4222T>C, p.Trp1408Arg 1 0.36% 28 c.4234C>T, p.Gly1412* 1 0.36% 28 c.4253&#fe;5G>T, Splice site 1 0.36% 28 c.4253&#fe;4C>T, Splice site 1 0.36% 29 c.4283C>T, p.Thr1428Met 1 0.36% 29 c.4319T>C, p.Phe1440Ser 1 0.36% 29 c.4462T>C, p.Cys1488Arg 1 0.36% 30 c.4469G>A, p.Cys1490Tyr 5 1.79% 30 c.4537_4538insC, p.Gly1513Profs 1 0.36% 31 c.4577C>T, p.Thr1526Met 2 0.71% 33 c.4715C>T, p.Thr1572Met 1 0.36% Continued on next page TABLE 3.

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ABCA4 p.Arg212Cys 23953153:141:475

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[hide] Quantitative fundus autofluorescence in recessive ... Invest Ophthalmol Vis Sci. 2014 May 1;55(5):2841-52. doi: 10.1167/iovs.13-13624. Burke TR, Duncker T, Woods RL, Greenberg JP, Zernant J, Tsang SH, Smith RT, Allikmets R, Sparrow JR, Delori FC
Quantitative fundus autofluorescence in recessive Stargardt disease.
Invest Ophthalmol Vis Sci. 2014 May 1;55(5):2841-52. doi: 10.1167/iovs.13-13624., [PMID:24677105]

Abstract [show]
PURPOSE: To quantify fundus autofluorescence (qAF) in patients with recessive Stargardt disease (STGD1). METHODS: A total of 42 STGD1 patients (ages: 7-52 years) with at least one confirmed disease-associated ABCA4 mutation were studied. Fundus AF images (488-nm excitation) were acquired with a confocal scanning laser ophthalmoscope equipped with an internal fluorescent reference to account for variable laser power and detector sensitivity. The gray levels (GLs) of each image were calibrated to the reference, zero GL, magnification, and normative optical media density to yield qAF. Texture factor (TF) was calculated to characterize inhomogeneities in the AF image and patients were assigned to the phenotypes of Fishman I through III. RESULTS: Quantified fundus autofluorescence in 36 of 42 patients and TF in 27 of 42 patients were above normal limits for age. Young patients exhibited the relatively highest qAF, with levels up to 8-fold higher than healthy eyes. Quantified fundus autofluorescence and TF were higher in Fishman II and III than Fishman I, who had higher qAF and TF than healthy eyes. Patients carrying the G1916E mutation had lower qAF and TF than most other patients, even in the presence of a second allele associated with severe disease. CONCLUSIONS: Quantified fundus autofluorescence is an indirect approach to measuring RPE lipofuscin in vivo. We report that ABCA4 mutations cause significantly elevated qAF, consistent with previous reports indicating that increased RPE lipofuscin is a hallmark of STGD1. Even when qualitative differences in fundus AF images are not evident, qAF can elucidate phenotypic variation. Quantified fundus autofluorescence will serve to establish genotype-phenotype correlations and as an outcome measure in clinical trials.

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84 [A854T; A1038V]; p.C2150Y 512 2.3 26 F 52 1 0.70 0.48 I - p.R212C 722 2.0 27 F 52 13 1.00 1.00 - I p.A1038V; p.A848D 459 4.1 28 M 20 5 0.30 0.40 I - p.L2027F; p.R1108H 507 2.3 29 M 23 7 1.00 1.00 I I p.G1961E; p.R2030Q 334 347 2.4 2.0 30 M 44 26 0.70 0.70 - II p.P1380L; p.R1108H 453 4.7 31 F 30 22 1.00 1.30 - I p.G1961E; c.6005&#fe;1G > T 428 2.3 32 M 12 8 0.40 0.40 I - p.W821R; p.C2150Y 306 2.0 33 F 20 9 0.88 0.88 III III p.R602W; p.M1882I 650 655 2.6 2.5 34 F 47 4 0.40 0.40 I - p.G1961E; p.R1129C 400 2.5 35 F 19 3 0.70 0.48 II II p.

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ABCA4 p.Arg212Cys 24677105:84:60

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[hide] Molecular diagnostic testing by eyeGENE: analysis ... Invest Ophthalmol Vis Sci. 2014 Jul 31;55(9):5510-21. doi: 10.1167/iovs.14-14359. Alapati A, Goetz K, Suk J, Navani M, Al-Tarouti A, Jayasundera T, Tumminia SJ, Lee P, Ayyagari R
Molecular diagnostic testing by eyeGENE: analysis of patients with hereditary retinal dystrophy phenotypes involving central vision loss.
Invest Ophthalmol Vis Sci. 2014 Jul 31;55(9):5510-21. doi: 10.1167/iovs.14-14359., [PMID:25082885]

Abstract [show]
PURPOSE: To analyze the genetic test results of probands referred to eyeGENE with a diagnosis of hereditary maculopathy. METHODS: Patients with Best macular dystrophy (BMD), Doyne honeycomb retinal dystrophy (DHRD), Sorsby fundus dystrophy (SFD), or late-onset retinal degeneration (LORD) were screened for mutations in BEST1, EFEMP1, TIMP3, and CTRP5, respectively. Patients with pattern dystrophy (PD) were screened for mutations in PRPH2, BEST1, ELOVL4, CTRP5, and ABCA4; patients with cone-rod dystrophy (CRD) were screened for mutations in CRX, ABCA4, PRPH2, ELOVL4, and the c.2513G>A p.Arg838His variant in GUCY2D. Mutation analysis was performed by dideoxy sequencing. Impact of novel variants was evaluated using the computational tool PolyPhen. RESULTS: Among the 213 unrelated patients, 38 had BMD, 26 DHRD, 74 PD, 8 SFD, 6 LORD, and 54 CRD; six had both PD and BMD, and one had no specific clinical diagnosis. BEST1 variants were identified in 25 BMD patients, five with novel variants of unknown significance (VUS). Among the five patients with VUS, one was diagnosed with both BMD and PD. A novel EFEMP1 variant was identified in one DHRD patient. TIMP3 novel variants were found in two SFD patients, PRPH2 variants in 14 PD patients, ABCA4 variants in four PD patients, and p.Arg838His GUCY2D mutation in six patients diagnosed with dominant CRD; one patient additionally had a CRX VUS. ABCA4 mutations were identified in 15 patients with recessive CRD. CONCLUSIONS: Of the 213 samples, 55 patients (26%) had known causative mutations, and 13 (6%) patients had a VUS that was possibly pathogenic. Overall, selective screening for mutations in BEST1, PRPH2, and ABCA4 would likely yield the highest success rate in identifying the genetic basis for macular dystrophy phenotypes. Because of the overlap in phenotypes between BMD and PD, it would be beneficial to screen genes associated with both diseases.

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39 Mutations and Unknown Variants Detected in Patients With Central Vision Loss Patient Gene Exon DNA Change Protein Change Genotype Result PolyPhen Description PolyPhen Score Molecular Diagnosis Late-onset retinal degeneration NA CTRP5 NA NA NA NA NA NA Sorsby fundus dystrophy Patient 1 TIMP3 1 c.113C>G p.Ser38Cys Het vAR/us Probably damaging 1 Positive Patient 2 TIMP3 1 c.113C>G p.Ser38Cys Het vAR/us Probably damaging 1 Positive Patient 3 TIMP3 5 c.610A>T p.Ser204Cys Het Mut Positive Doyne honeycomb dystrophy Patient 1 EFEMP1 9 c.1033C>T p.Arg345Trp Het Mut Positive Patient 2 EFEMP1 9 c.1033C>T p.Arg345Trp Het Mut Positive Patient 3 EFEMP1 IVS10 c.IVS10-14C>T None Het vAR/us NA NA Unconfirmed Best macular dystrophy Patient 1 BEST1 2 c.28G>A p.Ala10Thr Het Mut Positive Patient 2 BEST1 2 c.47C>T p.Ser16Phe Het Mut Positive Patient 3 BEST1 2 c.72G>T p.Trp24Cys Het Mut Positive Patient 4 BEST1 3 c.240C>A p.Phe80Leu Het Mut Positive Patient 5 BEST1 3 c.240C>A p.Phe80Leu Het Mut Positive Patient 6 BEST1 4 c.248G>C p.Gly83Ala Het vAR/us Probably damaging 1 Positive Patient 7 BEST1 4 c.277T>C p.Trp93Arg Het vAR/us Probably damaging 1 Positive Patient 8 BEST1 4 c.279G>C p.Trp93Cys Het Mut Positive Patient 9 BEST1 6 c.652C>T p.Arg218Cys Het Mut Positive Patient 10 BEST1 6 c.652C>T p.Arg218Cys Het Mut Positive Patient 11 BEST1 6 c.680A>G p.Tyr227Cys Het Mut Positive Patient 12 BEST1 6 c.741G>A p.Arg218His Het Mut Positive Patient 13 BEST1 6 c.741G>A p.Arg218His Het Mut Positive Patient 14 BEST1 7 c.727G>A p.Ala243Thr Het Mut Positive Patient 15 BEST1 7 c.727G>A p.Ala243Thr Het Mut Positive Patient 16 BEST1 7 c.728C>T p.Ala243Val Het Mut Positive Patient 17 BEST1 7 c.728C>T p.Ala243Val Het Mut Positive Patient 18 BEST1 8 c.880C>T p.Leu294Phe Het vAR/us Probably damaging 1 Positive Patient 19 BEST1 8 c.887A>G p.Asn296Ser Het Mut Positive Patient 20 BEST1 8 c.903T>G p.Asp301Glu Het Mut Positive Patient 21 BEST1 8 c.903T>G p.Asp301Glu Het Mut Positive Patient 22 BEST1 8 c.910G>A p.Asp304Asn Het Mut Positive Patient 23 BEST1 8 c.925T>C p.Trp309Arg Het vAR/us Probably damaging 1 Positive Patient 24 BEST1 8 c.929T>C p.Ile310Thr Het Mut Positive Patient 25, case 3 BEST1 4 c.250T>G p.Phe84Val Het vAR/us Probably damaging 1 Positive Pattern dystrophy Patient 1 ABCA4 6 c.634C>T p.Arg212Cys Het Mut Positive ABCA4 30 c.4469G>A p.Cys1490Tyr Het Mut Patient 2 ABCA4 17 c.2588G>C p.Gly863Ala Het Mut Unconfirmed Patient 3 ABCA4 IVS26 c.3862&#fe;3A>G Abnormal splicing Het vAR/us Unconfirmed Patient 4 PRPH2 1 c.271T>A p.Tyr91Asn Het vAR/us Probably damaging 0.909 Positive PRPH2 1 c.310-313del(AT) p.Ile104Val Het Mut Patient 5, case 6 PRPH2 1 c.422A>G p.Tyr141Cys Het Mut Positive Patient 6 PRPH2 1 c.422A>G p.Tyr141Cys Het Mut Positive Patient 7 PRPH2 1 c.515G>A p.Arg172Gln Het Mut Positive Patient 8 PRPH2 2 c.583C>T p.Arg195Stop Het Mut Positive Patient 9 PRPH2 2 c.629C>G p.Pro210Arg Het Mut Positive Patient 10 PRPH2 2 c.635G>C p.Ser212Thr Het Mut Positive Patient 11 PRPH2 2 c.683C>T p.Thr228Ile Het Mut Positive Patient 12 PRPH2 2 c.708C>G p.Tyr236Stop Het Mut Positive Patient 13, case 4 PRPH2 IVS2 c.828&#fe;3A>T Splice Het Mut Positive TABLE 2. Continued Patient Gene Exon DNA Change Protein Change Genotype Result PolyPhen Description PolyPhen Score Molecular Diagnosis Patient 14 PRPH2 IVS2 c.828&#fe;3A>T Splice Het Mut Positive Patient 15 PRPH2 IVS2 c.828&#fe;3A>T Splice Het Mut Positive Patient 16 PRPH2 IVS2 c.828&#fe;3A>T Splice Het Mut Positive Patient 17, case 2 ABCA4 IVS38 c.5461-10T>C None Het Mut Unconfirmed Patient 18 PRPH2 2 c.584G>A p.Arg195Gln Het vAR/us Probably damaging 1 Positive Cone-rod dystrophy Patient 1, dominant GUCY2D 13 c.2512C>T p.Arg838Cys Het Mut Positive Patient 2, dominant GUCY2D 13 c.2513G>A p.Arg838His Het Mut Positive Patient 3, dominant GUCY2D 13 c.2513G>A p.Arg838His Het Mut Positive Patient 4, dominant GUCY2D 13 c.2513G>A p.Arg838His Het Mut Positive Patient 5, dominant GUCY2D 13 c.2513G>A p.Arg838His Het Mut Positive CRX 3 c.607T>C p.Ser213Pro Het vAR/us Probably damaging 0.999 Patient 6, recessive ABCA4 2 c.156T>G p.His52Gln Het vAR/us Probably damaging 0.998 Positive ABCA4 3 c.161G>A p.Cys54Tyr Het Mut ABCA4 28 c.4169T>C p.Leu1390Pro Het Mut Patient 7, recessive ABCA4 16 c.2385C>T p.Ser795Arg Het vAR/us Probably damaging 0.99 Positive ABCA4 IVS40 c.5714&#fe;5G>A Splice Het Mut Patient 8, recessive ABCA4 42 c.5882G>A p.Gly1961Glu Het Mut Positive ABCA4 45 c.6221G>T p.Gly2074Val Het vAR/us Probably damaging 1 Patient 9, recessive ABCA4 IVS42 c.5898&#fe;1G<A Splice Het Mut Positive ABCA4 IVS42 c.5899-2delA Splice Het Mut Patient 10, recessive ABCA4 5 c.559C>T p.Arg187Cys Het Mut Positive ABCA4 40 c.5645T>C p.Met1882Thr Het Mut Patient 11, recessive ABCA4 6 c.768G>T p.Val256Val (abnlspl) Het Mut Positive ABCA4 31 c.4577C>T p.Thr1526Met Het Mut Patient 12, recessive ABCA4 12 c.1622T>C p.Leu541Pro Het Mut Positive ABCA4 21 c.3113C>T p.Ala1038Val Het Mut ABCA4 12 c.1622T>C p.Leu541Pro Hom Mut ABCA4 21 c.3113C>T p.Ala1038Val Hom Mut ABCA4 22 c.3322C>T p.Arg1108Cys Het Mut Patient 13, recessive ABCA4 12 c.1622T>C p.Leu541Pro Hom Mut Positive ABCA4 21 c.3113C>T p.Ala1038Val Hom Mut Patient 14, recessive ABCA4 13 c.1927G>A p.Val643Met Het Mut Positive ABCA4 24 c.3602T>G p.Leu1201Arg Het Mut ABCA4 36 c.5186T>C p.Leu1729Pro Het Mut Patient 15, recessive ABCA4 23 c.3364G>A p.Glu1122Lys Het Mut Positive ABCA4 48 c.6529G>A p.Asp2177Asn Het Mut Patient 16, recessive ABCA4 35 c.4918C>T p.Arg1640Trp Het Mut Positive ABCA4 28 c.4222T>C p.Trp1408Arg Het Mut Patient 17, recessive ABCA4 11 c.1532G>A p.Arg511His Het Mut Unconfirmed Patient 18, recessive ABCA4 27 c.3899G>A p.Arg1300Gln Het vAR/us Benign 0.143 Unconfirmed Patient 19, recessive ABCA4 13 c.1933G>A p.Asp645Asn Het Mut Unconfirmed Patient 20, recessive ABCA4 35 c.4918C>T p.Arg1640Trp Het Mut Unconfirmed Patient 21, recessive ABCA4 IVS7 c.859-9T>C Unknown Hom vAR/us NA NA Unconfirmed Molecular Diagnostic Testing by eyeGENE IOVS j September 2014 j Vol. 55 j No. 9 j were screened for the p.Arg838His mutation in GUCY2D, and mutations in the CRX, ELOVL4, PRPH2, and/or ABCA4 genes.

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ABCA4 p.Arg212Cys 25082885:39:2298

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116 Mutations or Unknown Variants Detected in Patients With Central Vision Loss Gene Exon DNA Change Protein Change Genotype Result PolyPhen Description PolyPhen Score Frequency* Variant ID Late-onset retinal degeneration CTRP5 NA NA NA NA NA NA NA NA NA Sorsby fundus dystrophy TIMP3 1 c.113C>G p.Ser38Cys Het vAR/us Probably damaging 1 2 TIMP3 5 c.610A>T p.Ser204Cys Het Mut 1 CM941325/ rs137853298 Doyne honeycomb dystrophy EFEMP1 9 c.1033C>T p.Arg345Trp Het Mut 2 CM990504 EFEMP1 IVS10 c.IVS10-14C>T None Het vAR/us NA NA 1 Best macular dystrophy BEST1 2 c.28G>A p.Ala10Thr Het Mut 1 CM982017 BEST1 2 c.47C>T p.Ser16Phe Het Mut 1 CM010520 BEST1 2 c.72G>T p.Trp24Cys Het Mut 1 CM982018 BEST1 3 c.240C>A p.Phe80Leu Het Mut 2 CM004423 BEST1 4 c.248G>C p.Gly83Ala Het vAR/us Probably damaging 1 1 BEST1 4 c.277T>C p.Trp93Arg Het vAR/us Probably damaging 1 1 BEST1 4 c.279G>C p.Trp93Cys Het Mut 1 rs28940273/ CM982021 BEST1 6 c.652C>T p.Arg218Cys Het Mut 2 CM982023 BEST1 6 c.680A>G p.Tyr227Cys Het Mut 1 CM982024 BEST1 6 c.741G>A p.Arg218His Het Mut 2 CM003486 BEST1 7 c.727G>A p.Ala243Thr Het Mut 2 CM004434 BEST1 7 c.728C>T p.Ala243Val Het Mut 2 rs28940570/ CM00841 BEST1 8 c.880C>T p.Leu294Phe Het vAR/us Probably damaging 1 1 BEST1 8 c.887A>G p.Asn296Ser Het Mut 1 CM010524 BEST1 8 c.903T>G p.Asp301Glu Het Mut 2 CM991243 BEST1 8 c.910G>A p.Asp304Asn Het Mut 1 CM024219 BEST1 8 c.925T>C p.Trp309Arg Het vAR/us Probably damaging 1 1 BEST1 8 c.929T>C p.Ile310Thr Het Mut 1 CM000843 BEST1 4 c.250T>G p.Phe84Val Het vAR/us Probably damaging 1 1 Pattern dystrophy ABCA4 6 c.634C>T p.Arg212Cys Het Mut 1 rs61750200 ABCA4 17 c.2588G>C p.Gly863Ala Het Mut 1 CM970003/ rs76157638 ABCA4 IVS26 c.3862&#fe;3A>G Abnormal splicing Het vAR/us 1 NA ABCA4 30 c.4469G>A p.Cys1490Tyr Het Mut 1 CM990056/ rs61751402 ABCA4 IVS38 c.5461-10T>C None Het Mut 1 CS057513 PRPH2 1 c.271T>A p.Tyr91Asn Het vAR/us Probably damaging .909 1 PRPH2 1 c.310-313del(AT) p.Ile104Val Het Mut 1 NA/Deletion PRPH2 1 c.422A>G p.Tyr141Cys Het Mut 2 CM010125/ rs61755781 PRPH2 1 c.515G>A p.Arg172Gln Het Mut 1 CM930637/ rs61755792 PRPH2 2 c.583C>T p.Arg195Stop Het Mut 1 CM032999 PRPH2 2 c.629C>G p.Pro210Arg Het Mut 1 CM941210 PRPH2 2 c.635G>C p.Ser212Thr Het Mut 1 CM971289/ rs61755801 PRPH2 2 c.683C>T p.Thr228Ile Het Mut 1 TMP_ESP_6_ 42672248 PRPH2 2 c.708C>G p.Tyr236Stop Het Mut 1 rs61755813 PRPH2 IVS2 c.828&#fe;3A>T Splice Het Mut 4 CS010139 PRPH2 2 c.584G>A p.Arg195Gln Het vAR/us Probably damaging 1 1 TABLE 3. Continued Gene Exon DNA Change Protein Change Genotype Result PolyPhen Description PolyPhen Score Frequency* Variant ID Cone-rod dystrophy ABCA4 2 c.156T>G p.His52Gln Het vAR/us Probably damaging 0.998 1 ABCA4 3 c.161G>A p.Cys54Tyr Het Mut 1 CM990012/ rs150774447 ABCA4 28 c.4169T>C p.Leu1390Pro Het Mut 1 CM014810/ rs61752430 ABCA4 16 c.2385C>T p.Ser795Arg Het vAR/us Probably damaging 0.99 1 ABCA4 IVS40 c.5714&#fe;5G>A Splice Het Mut 1 CS982057 ABCA4 27 c.3899G>A p.Arg1300Gln Het vAR/us Benign 0.143 1 ABCA4 32 c.4661A>G p.Glu1554Gly Het vAR/us Benign 0.326 1 ABCA4 30 c.4383G>A p.Trp1461Stop Het Mut 1 Stop/NA ABCA4 IVS38 c.5461-10T>C None Het Mut NA NA 2 CS057513 ABCA4 22 c.3259G>A p.Glu1087Lys Het Mut 1 CM970008/ rs61751398 ABCA4 42 c.5882G>A p.Gly1961Glu Het Mut 2 CM970016/ rs1800553 ABCA4 45 c.6221G>T p.Gly2074Val Het vAR/us Probably damaging 1 1 ABCA4 IVS42 c.5898&#fe;1G<A Splice Het Mut 1 CS011524 ABCA4 IVS42 c.5899-2delA Splice Het Mut 1 rs3112831 CRX 3 c.607T>C p.Ser213Pro Het vAR/us Probably damaging 0.999 1 ABCA4 5 c.559C>T p.Arg187Cys Het Mut 1 COSM913472 ABCA4 40 c.5645T>C p.Met1882Thr Het Mut 1 rs4147830 ABCA4 6 c.768G>T p.Val256Val (abnlspl) Het Mut 1 CM990057/ rs61750152 ABCA4 31 c.4577C>T p.Thr1526Met Het Mut 1 rs62645944 ABCA4 11 c.1532G>A p.Arg511His Het Mut 1 rs140482171 ABCA4 12 c.1622T>C p.Leu541Pro Het Mut 1 CM990022/ rs61751392 ABCA4 21 c.3113C>T p.Ala1038Val Het Mut 1 CM970006/ rs61751374 ABCA4 12 c.1622T>C p.Leu541Pro Hom Mut 2 CM990022/ rs61751392 ABCA4 21 c.3113C>T p.Ala1038Val Hom Mut 2 CM970006/ rs61751374 ABCA4 22 c.3322C>T p.Arg1108Cys Het Mut 1 CM990039/ rs61750120 ABCA4 13 c.1927G>A p.Val643Met Het Mut 1 CM014293/ rs61749417/ rs143548435 ABCA4 24 c.3602T>G p.Leu1201Arg Het Mut 1 CM990042/ rs61750126 ABCA4 36 c.5186T>C p.Leu1729Pro Het Mut 1 CM990062/ rs61750567 ABCA4 13 c.1933G>A p.Asp645Asn Het Mut 1 rs617494181933 ABCA4 23 c.3364G>A p.Glu1122Lys Het Mut 1 CM990041 ABCA4 48 c.6529G>A p.Asp2177Asn Het Mut 1 CM970023/ rs1800555 ABCA4 35 c.4918C>T p.Arg1640Trp Het Mut 2 CM983728/ rs61751404 ABCA4 28 c.4222T>C p.Trp1408Arg Het Mut 1 CM990048/ rs61750135 GUCY2D 13 c.2512C>T p.Arg838Cys Het Mut 1 rs61750172 GUCY2D 13 c.2513G>A p.Arg838His Het Mut 5 CM012606/ rs61750173 ABCA4 IVS7 c.859-9T>C Unknown Hom vAR/us NA NA 1 ABCA4 42 c.5882G>A p.Gly1961Glu Hom Mut 1 CM970016/ rs1800553 ABCA4 43 c.5917delG Deletion Hom Mut 1 RISN_ABCR: c.5917delG Molecular Diagnostic Testing by eyeGENE IOVS j September 2014 j Vol. 55 j No. 9 j Six patients with late-onset retinal pathology and drusen had well-characterized clinical data.

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ABCA4 p.Arg212Cys 25082885:116:1578

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[hide] Quantitative fundus autofluorescence distinguishes... Ophthalmology. 2015 Feb;122(2):345-55. doi: 10.1016/j.ophtha.2014.08.017. Epub 2014 Oct 3. Duncker T, Tsang SH, Lee W, Zernant J, Allikmets R, Delori FC, Sparrow JR
Quantitative fundus autofluorescence distinguishes ABCA4-associated and non-ABCA4-associated bull's-eye maculopathy.
Ophthalmology. 2015 Feb;122(2):345-55. doi: 10.1016/j.ophtha.2014.08.017. Epub 2014 Oct 3., [PMID:25283059]

Abstract [show]
PURPOSE: Quantitative fundus autofluorescence (qAF) and spectral-domain optical coherence tomography (SD OCT) were performed in patients with bull's-eye maculopathy (BEM) to identify phenotypic markers that can aid in the differentiation of ABCA4-associated and non-ABCA4-associated disease. DESIGN: Prospective cross-sectional study at an academic referral center. SUBJECTS: Thirty-seven BEM patients (age range, 8-60 years) were studied. All patients exhibited a localized macular lesion exhibiting a smooth contour and qualitatively normal-appearing surrounding retina without flecks. Control values consisted of previously published data from 277 healthy subjects (374 eyes; age range, 5-60 years) without a family history of retinal dystrophy. METHODS: Autofluorescence (AF) images (30 degrees , 488-nm excitation) were acquired with a confocal scanning laser ophthalmoscope equipped with an internal fluorescent reference to account for variable laser power and detector sensitivity. The grey levels (GLs) from 8 circularly arranged segments positioned at an eccentricity of approximately 7 degrees to 9 degrees in each image were calibrated to the reference (0 GL), magnification, and normative optical media density to yield qAF. In addition, horizontal SD OCT images through the fovea were obtained. All patients were screened for ABCA4 mutations using the ABCR600 microarray, next-generation sequencing, or both. MAIN OUTCOME MEASURES: Quantitative AF, correlations between AF and SD OCT, and genotyping for ABCA4 variants. RESULTS: ABCA4 mutations were identified in 22 patients, who tended to be younger (mean age, 21.9+/-8.3 years) than patients without ABCA4 mutations (mean age, 42.1+/-14.9 years). Whereas phenotypic differences were not obvious on the basis of qualitative fundus AF and SD OCT imaging, with qAF, the 2 groups of patients were clearly distinguishable. In the ABCA4-positive group, 37 of 41 eyes (19 of 22 patients) had qAF8 of more than the 95% confidence interval for age. Conversely, in the ABCA4-negative group, 22 of 26 eyes (13 of 15 patients) had qAF8 within the normal range. CONCLUSIONS: The qAF method can differentiate between ABCA4-associated and non-ABCA4-associated BEM and may guide clinical diagnosis and genetic testing.

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65 Sex Age (yrs) Race or Ethnicity Best-Corrected Visual Acuity (Logarithm of the Minimum Angle of Resolution Units) Genetic Data Average of Quantitative Fundus Autofluorescence Values of the 8 Segments ABCA4 Mutations Right Eye Left Eye Allele 1 Allele 2 Right Eye Left Eye 1 M 36 White 0.70 0.70 p.G1961E p.G1961E 282 279 2 F 46 White 0.40 0.40y p.G1961E p.R1129C 391 3 M 17 Asian Indian 0.70 0.88 p.G1961E c.6729&#fe;4_&#fe;18del 340 363 4 M 17 White 0.88 0.88 p.G1961E p.A1773V 340 366 5 M 21 White 0.88 0.88 p.G1961E p.W15* 341 325 6 F 22 White 0.70 0.48 p.G1961E p.G863A 361 351 7 F 20 White 0.70z 0.88z p.G1961E p.L541P 317 8 M 12 White 0.80 0.70 p.G1961E p.P1380L 251 242 9 F 21 White 0.88 0.88 p.G1961E p.R212C 407 439 10 F 26 White 0.40z 0.70z p.G1961E c.5196&#fe;1056A/G 379 344 11 F 24 White 0.88z 0.88z p.G1961E p.C2150R 405 396 12 F 24 White 0.30z 0.18z p.G1961E p.N96D 513 549 13 F 20 White 0.30 0.40 p.G1961E p.N96D 397 355 14 M 25 White 0.00y 0.30 p.G1961E p.Q1003* 322 328 15 M 8.2 White 0.88 0.88 p.

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ABCA4 p.Arg212Cys 25283059:65:711

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[hide] Correlations among near-infrared and short-wavelen... Invest Ophthalmol Vis Sci. 2014 Oct 23;55(12):8134-43. doi: 10.1167/iovs.14-14848. Duncker T, Marsiglia M, Lee W, Zernant J, Tsang SH, Allikmets R, Greenstein VC, Sparrow JR
Correlations among near-infrared and short-wavelength autofluorescence and spectral-domain optical coherence tomography in recessive Stargardt disease.
Invest Ophthalmol Vis Sci. 2014 Oct 23;55(12):8134-43. doi: 10.1167/iovs.14-14848., [PMID:25342616]

Abstract [show]
PURPOSE: Short-wavelength (SW) fundus autofluorescence (AF) is considered to originate from lipofuscin in retinal pigment epithelium (RPE) and near-infrared (NIR) AF from melanin. In patients with recessive Stargardt disease (STGD1), we correlated SW-AF and NIR-AF with structural information obtained by spectral-domain optical coherence tomography (SD-OCT). METHODS: Twenty-four STGD1 patients (45 eyes; age 8 to 61 years) carrying confirmed disease-associated ABCA4 mutations were studied prospectively. Short-wavelength AF, NIR-AF, and SD-OCT images were acquired. RESULTS: Five phenotypes were identified according to features of the central lesion and extent of fundus change. Central zones of reduced NIR-AF were typically larger than areas of diminished SW-AF and reduced NIR-AF usually approximated areas of ellipsoid zone (EZ) loss identified by SD-OCT (group 1; r, 0.93, P < 0.0001). In patients having a central lesion with overlapping parafoveal rings of increased NIR-AF and SW-AF (group 3), the extent of EZ loss was strongly correlated with the inner diameter of the NIR-AF ring (r, 0.89, P < 0.0001) and the eccentricity of the outer border of the NIR-AF ring was greater than that of the SW-AF ring. CONCLUSIONS: Lesion areas were more completely delineated in NIR-AF images than with SW-AF. In most cases, EZ loss was observed only at locations where NIR-AF was reduced or absent, indicating that RPE cell atrophy occurs in advance of photoreceptor cell degeneration. Because SW-AF was often increased within the central area of EZ disruption, degenerating photoreceptor cells may produce lipofuscin at accelerated levels. Consideration is given to mechanisms underlying hyper-NIR-AF in conjunction with increased SW-AF.

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91 [L541P;A1038V] 5 14 22.4 F White Brown 0.8 0.8 p.R212C 3 15 20.2 M White Brown 0.9 0.9 p.G1961E p.P1380L 1 16 27.6 M Arabic Brown 0.0 0.0 p.R1300* p.R2106C 3 17 26.8 M White Blue 0.5 0.5 p.G1961E c.3050&#fe;5G>A 1 18 24.9 F White Hazel 0.9 0.9 p.G1961E p.C2150R 5 19 13.2 M White Blue 0.9 1.0 p.W821R p.C2150Y 3 20 61.0 F White Green 2.0 0.0 c.250_251insCAAA 2 21 36.3 F White Blue 1.3 0.1 p.N1799D 1 22 14.1 F White Green 1.0 0.9 p.R1108C p.Q1412* 2 23 18.6 M White Brown 0.9 0.9 p.G1961E p.A1773V 3 24 53.3 F White Blue 0.3 (0.2) p.R2077W 2 BCVA values in parenthesis indicate fellow eyes that were not included in the study.

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ABCA4 p.Arg212Cys 25342616:91:49

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[hide] Quantitative Fundus Autofluorescence and Optical C... Invest Ophthalmol Vis Sci. 2015 May;56(5):3159-70. doi: 10.1167/iovs.14-16343. Duncker T, Tsang SH, Woods RL, Lee W, Zernant J, Allikmets R, Delori FC, Sparrow JR
Quantitative Fundus Autofluorescence and Optical Coherence Tomography in PRPH2/RDS- and ABCA4-Associated Disease Exhibiting Phenotypic Overlap.
Invest Ophthalmol Vis Sci. 2015 May;56(5):3159-70. doi: 10.1167/iovs.14-16343., [PMID:26024099]

Abstract [show]
PURPOSE: To assess whether quantitative fundus autofluorescence (qAF), a measure of RPE lipofuscin, and spectral-domain optical coherence tomography (SD-OCT) can aid in the differentiation of patients with fundus features that could either be related to ABCA4 mutations or be part of the phenotypic spectrum of pattern dystrophies. METHODS: Autofluorescence images (30 degrees , 488-nm excitation) from 39 patients (67 eyes) were acquired with a confocal scanning laser ophthalmoscope equipped with an internal fluorescent reference and were quantified as previously described. In addition, horizontal SD-OCT images through the fovea were obtained. Patients were screened for ABCA4 and PRPH2/RDS mutations. RESULTS: ABCA4 mutations were identified in 19 patients (mean age, 37 +/- 12 years) and PRPH2/RDS mutations in 8 patients (mean age, 48 +/- 13 years); no known ABCA4 or PRPH2/RDS mutations were found in 12 patients (mean age, 48 +/- 9 years). Differentiation of the groups using phenotypic SD-OCT and AF features (e.g., peripapillary sparing, foveal sparing) was not reliable. However, patients with ABCA4 mutations could be discriminated reasonably well from other patients when qAF values were corrected for age and race. In general, ABCA4 patients had higher qAF values than PRPH2/RDS patients, while most patients without mutations in PRPH2/RDS or ABCA4 had qAF levels within the normal range. CONCLUSIONS: The high qAF levels of ABCA4-positive patients are a hallmark of ABCA4-related disease. The reason for high qAF among many PRPH2/RDS-positive patients is not known; higher RPE lipofuscin accumulation may be a primary or secondary effect of the PRPH2/RDS mutation.

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64 [A854T;A1038V] p.C2150Y NS 367 426 26 F 53.5 White 0.60 0.48 p.R212C NF NF 754 683 27 M 52.2 White 0.70 0.60 p.G1961E c.3050&#fe;5G>A NF 644 n/a 28 M 31.7 Asian&#a7; 0.48 0.48 c.859-9T>C c.859-9T>C NF n/a 317 29 F 49.8 White 0.00 0.00 NF NF NF 493 510 30 M 24.8 White 0.00 0.00 p.G1961E c.3050&#fe;5G>A NS 381 451 31 F 29.3 White 0.40 0.40 p.G1961E p.

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ABCA4 p.Arg212Cys 26024099:64:63

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[hide] Near-infrared autofluorescence: its relationship t... Invest Ophthalmol Vis Sci. 2015 May;56(5):3226-34. doi: 10.1167/iovs.14-16050. Greenstein VC, Schuman AD, Lee W, Duncker T, Zernant J, Allikmets R, Hood DC, Sparrow JR
Near-infrared autofluorescence: its relationship to short-wavelength autofluorescence and optical coherence tomography in recessive stargardt disease.
Invest Ophthalmol Vis Sci. 2015 May;56(5):3226-34. doi: 10.1167/iovs.14-16050., [PMID:26024107]

Abstract [show]
PURPOSE: We compared hypoautofluorescent (hypoAF) areas detected with near-infrared (NIR-AF) and short-wavelength autofluorescence (SW-AF) in patients with recessive Stargardt disease (STGD1) to retinal structure using spectral domain optical coherence tomography (SD-OCT). METHODS: The SD-OCT volume scans, and SW-AF and NIR-AF images were obtained from 15 eyes of 15 patients with STGD1 and registered to each other. Thickness maps of the total retina, receptor-plus layer (R+, from distal border of the RPE to outer plexiform/inner nuclear layer boundary), and outer segment-plus layer (OS+, from distal border of the RPE to ellipsoid zone [EZ] band) were created from SD-OCT scans. These were compared qualitatively and quantitatively to the hypoAF areas in SW-AF and NIR-AF images. RESULTS: All eyes showed a hypoAF area in the central macula and loss of the EZ band in SD-OCT scans. The hypoAF area was larger in NIR than SW-AF images and it exceeded the area of EZ band loss for 12 eyes. The thickness maps showed progressive thinning towards the central macula, with the OS+ layer showing the most extensive and severe thinning. The central hypoAF areas on NIR corresponded to the OS+ thinned areas, while the hypoAF areas on SW-AF corresponded to the R+ thinned areas. CONCLUSIONS: Since the larger hypoAF area on NIR-AF exceeded the region of EZ band loss, and corresponded to the OS+ thinned area, RPE cell loss occurred before photoreceptor cell loss. The NIR-AF imaging may be an effective tool for following progression and predicting loss of photoreceptors in STGD1.

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74 Selected Demographic, Clinical, and Genetic Characteristics of the Study Cohort Patient Sex Disease-Associated ABCA4 Variant(s) Age Eye BCVA 1 F p.G1961E; c2382&#fe;1G>A 36 OS 0.8 2 M p.[L541P;A1038V] 8 OS 0.6 3 M p.G1961E; c.6729&#fe;5_&#fe;19del 18 OS 0.9 4 M p.P1380L; p.G1961E 12 OD 0.8 5 M c.571-1G>T 43 OD 0.4 6 M p.Q1003*; p.G1961E 25 OS 0 7 M p.[L541P;A1038V]; p.L2027F 8 OD N/A 8 F p.R212C; p.G1961E 22 OD 0.8 9 F p.P1380L; p.G1961E 20 OD 0.9 10 M p.R1300*; p.R2106C 26 OS 0 11 M c.3050&#fe;5G>A; p.G1961E 27 OD 0.5 12 F p.G1961E; p.C2150R 25 OD 0.7 13 M p.W821R; p.C2150Y 13 OD 0.4 14 F p.N1799D 36 OD 1.3 15 M p.A1773V; p.G1961E 19 OD 0.7 FIGURE 1.

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ABCA4 p.Arg212Cys 26024107:74:393

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[hide] Identification of Genetic Defects in 33 Probands w... PLoS One. 2015 Jul 10;10(7):e0132635. doi: 10.1371/journal.pone.0132635. eCollection 2015. Xin W, Xiao X, Li S, Jia X, Guo X, Zhang Q
Identification of Genetic Defects in 33 Probands with Stargardt Disease by WES-Based Bioinformatics Gene Panel Analysis.
PLoS One. 2015 Jul 10;10(7):e0132635. doi: 10.1371/journal.pone.0132635. eCollection 2015., [PMID:26161775]

Abstract [show]
Stargardt disease (STGD) is the most common hereditary macular degeneration in juveniles, with loss of central vision occurring in the first or second decade of life. The aim of this study is to identify the genetic defects in 33 probands with Stargardt disease. Clinical data and genomic DNA were collected from 33 probands from unrelated families with STGD. Variants in coding genes were initially screened by whole exome sequencing. Candidate variants were selected from all known genes associated with hereditary retinal dystrophy and then confirmed by Sanger sequencing. Putative pathogenic variants were further validated in available family members and controls. Potential pathogenic mutations were identified in 19 of the 33 probands (57.6%). These mutations were all present in ABCA4, but not in the other four STGD-associated genes or in genes responsible for other retinal dystrophies. Of the 19 probands, ABCA4 mutations were homozygous in one proband and compound heterozygous in 18 probands, involving 28 variants (13 novel and 15 known). Analysis of normal controls and available family members in 12 of the 19 families further support the pathogenicity of these variants. Clinical manifestation of all probands met the diagnostic criteria of STGD. This study provides an overview of a genetic basis for STGD in Chinese patients. Mutations in ABCA4 are the most common cause of STGD in this cohort. Genetic defects in approximately 42.4% of STGD patients await identification in future studies.

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69 (Continued) Patient Nucleotide Amino Acid State Computational Prediction Allele Frequency in Reported ID Change Change P/SS Proven SIFT 1000G EVS ExAC NC RC c.5196 +1G>A Splicing defect Het SSA NA NA NA NA 3/49858 - 0/456 Allikmets et al. 1997; Wiszniewski et al. 2005 QT1317 c.5646G>A p.M1882I Het PoD D D NA NA 3/121340 - 0/456 Zernant et al. 2011 c.4622T>C p.L1541P Het PrD D D NA NA NA 0/192 0/456 Novel MD19 c.4793C>G p.A1598G het PoD D N NA 0.0001 NA - 0/456 Maugeri et al. 2000; Cideciyan et al. 2009; Burke et al. 2010 c.634C>T p.R212C het D D D NA 0.0002 14/ 120056 - 0/456 Gerber et al.1998; Thiadens et al. 2012 The following abbreviations are used: P/SS, Polyphen-2/Splice Site Prediction; 1000G, 1000 Genomes; EVS, Exome Variant Server; ExAC, Exome Aggregation Consortium; Het, heterozygous; Hom, homozygous; NC, normal control; RC, relative control; PrD, probably damaging; PoD, possibly damaging; B, benign; SSA, splicing site abolished; N, neutral; D, damaging; and NA, not applicable;-, not done.

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ABCA4 p.Arg212Cys 26161775:69:538

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