ABCC6 p.Arg1064Trp
| LOVD-ABCC6: |
p.Arg1064Trp
D
|
| Predicted by SNAP2: | A: D (85%), C: D (91%), D: D (95%), E: D (91%), F: D (95%), G: D (91%), H: D (91%), I: D (91%), K: D (80%), L: D (91%), M: D (91%), N: D (91%), P: D (95%), Q: D (85%), S: D (85%), T: D (85%), V: D (91%), W: D (85%), Y: D (95%), |
| Predicted by PROVEAN: | A: N, C: D, D: D, E: N, F: D, G: D, H: N, I: D, K: N, L: N, M: N, N: N, P: D, Q: N, S: N, T: N, V: D, W: D, Y: D, |
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[hide] Heterozygous carriers of Pseudoxanthoma elasticum ... J Neurol. 2003 Aug;250(8):983-6. Morcher M, Hausser I, Brandt T, Grond-Ginsbach C
Heterozygous carriers of Pseudoxanthoma elasticum were not found among patients with cervical artery dissections.
J Neurol. 2003 Aug;250(8):983-6., [PMID:12928920]
Abstract [show]
In this study of patients with spontaneous cervical artery dissections (sCAD) we searched for mutations in ABCC6, the candidate gene for Pseudoxanthoma elasticum (PXE). Genomic DNA samples from 12 sCAD patients with pronounced electron microscopic alterations in their dermal connective tissue and from 2 patients with PXE were analysed. One patient with PXE was compound heterozygous for two missense point mutations, in the second patient with PXE we did not find changes in the ABCC6 gene. We observed several missense mutations (H623Q, R3190W and R1268Q) in the patients with sCAD, but these mutations were not disease specific,since they were also detected in a series of 25 healthy control subjects.The finding of several sequence variants in sCAD patients and of disease causing mutations in one of the PXE patients suggests that our strategy of mutation search is reliable. Since we did not find disease causing mutations in our series of patients with sCAD we suggest that ABCC6 is not a candidate gene for sCAD.
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No. Sentence Comment
35 We found three missense mutations in our patients with sCAD (H623Q, R1064W and R1268Q).
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ABCC6 p.Arg1064Trp 12928920:35:68
status: NEW45 However, the R1141X muTable ABCC6sequencevariationin12patientswithsCADand2patientswithPXE exon nucleotide Amino-acid Occurrence Occurrence position change among patients among controls 10 1233T¡C synonymous sCAD not tested 10 1245G¡A synonymous sCAD not tested 15 1890C¡G synonymous sCAD not tested 15 1896C¡A H623Q sCAD + 19 2490C¡T synonymous sCAD not tested 20 2631C¡A synonymous sCAD not tested 22 2835C¡T synonymous sCAD not tested 22 2836C¡A L946I PXE - 23 3190C¡T R1064W sCAD + 24 3389C¡T T1130M PXE - 27 3803G¡A R1268Q sCAD + tation is common in European patients, whereas a large deletion of exons 23-26 is repeatedly found in patients from the United States [22].
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ABCC6 p.Arg1064Trp 12928920:45:516
status: NEW51 Several missense mutations (H632Q in exon 15, R1064W in exon 23 and R1268Q in exon 27) were found.
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ABCC6 p.Arg1064Trp 12928920:51:46
status: NEW[hide] Molecular genetics of pseudoxanthoma elasticum: ty... Hum Mutat. 2005 Sep;26(3):235-48. Miksch S, Lumsden A, Guenther UP, Foernzler D, Christen-Zach S, Daugherty C, Ramesar RK, Lebwohl M, Hohl D, Neldner KH, Lindpaintner K, Richards RI, Struk B
Molecular genetics of pseudoxanthoma elasticum: type and frequency of mutations in ABCC6.
Hum Mutat. 2005 Sep;26(3):235-48., [PMID:16086317]
Abstract [show]
Pseudoxanthoma elasticum (PXE) is a systemic heritable disorder that affects the elastic tissue in the skin, eye, and cardiovascular system. Mutations in the ABCC6 gene cause PXE. We performed a mutation screen in ABCC6 using haplotype analysis in conjunction with direct sequencing to achieve a mutation detection rate of 97%. This screen consisted of 170 PXE chromosomes in 81 families, and detected 59 distinct mutations (32 missense, eight nonsense, and six likely splice-site point mutations; one small insertion; and seven small and five large deletions). Forty-three of these mutations are novel variants, which increases the total number of PXE mutations to 121. While most mutations are rare, three nonsense mutations, a splice donor site mutation, and the large deletion comprising exons 23-29 (c.2996_4208del) were identified as relatively frequent PXE mutations at 26%, 5%, 3.5%, 3%, and 11%, respectively. Chromosomal haplotyping with two proximal and two distal polymorphic markers flanking ABCC6 demonstrated that most chromosomes that carry these relatively frequent PXE mutations have related haplotypes specific for these mutations, which suggests that these chromosomes originate from single founder mutations. The types of mutations found support loss-of-function as the molecular mechanism for the PXE phenotype. In 76 of the 81 families, the affected individuals were either homozygous for the same mutation or compound heterozygous for two mutations. In the remaining five families with one uncovered mutation, affected showed allelic compound heterozygosity for the cosegregating PXE haplotype. This demonstrates pseudo-dominance as the relevant inheritance mechanism, since disease transmission to the next generation always requires one mutant allelic variant from each parent. In contrast to other previous clinical and molecular claims, our results show evidence only for recessive PXE. This has profound consequences for the genetic counseling of families with PXE.
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209 Type and Frequency of Polymorphisms in ABCC6 Identi'ed in170 Chromosomes of 81 PXE Familiesà Exon/ Intron Nucleotide substitution Amino acid change Location Frequency (] of families) Referencea E 03 c.232G4A p.A78T ABCC6-C2 81 This study, (C,H) IVS 03 c.345112T4C Intron duplication 81 This study IVS 03 c.345126C4T Intron 1 This study IVS 03 c.346À6G4A Intron 10 This study, (C) E 04 c.373G4A p.E125K ABCC6-C1 81 This study, (C) E 04 c.473C4T p.A158V ABCC6-C2 81 This study, (C) IVS 04 c.474113 G4A Intron duplication 2 This study IVS 04 c.474143C4T Intron duplication 80 This study, (C) IVS 04 c.475À76A4C Intron duplication 81 This study IVS 04 c.475À45C4T Intron 3 This study IVS 04 c.475À22T4C Intron duplication 80 This study, (C) E 05 c.549G4A L183L ABCC6 2 This study, (E) IVS 05 c.600123C4T Intron 1 This study E 06 c.645G4A T215T ABCC6 8 This study, (C) IVS 06 c.662112C4T Intron 1 This study, (C) E 07 c.793A4G R265G ABCC6-C1 81 This study, (C,H) IVS 07 c.794136A4C Intron duplication 81 This study, (C) E 08 c.841A4G K281E ABCC6-Cx 81 This study, (H) E 08 c.855C4T T285T ABCC6-C1 81 This study, (C) E 08 c.955A4G I319V ABCC6-Cx 81 This study, (H) E 09 c.1077A4G S359S ABCC6, ABCC6-C1 1 This study, (C,H) E 09 c.1132C4T Q378X ABCC6-C1 81 This study, (C,H) E 09 c.1141T4C L381L ABCC6, ABCC6-C1 81 This study, (C,H) IVS 09 c.117616C4T No SSM Intron 1 This study E 10 c.1233T4C N411N ABCC6 1 This study, (B,L) E 10 c.1245G4A V415V ABCC6 Frequent This study, (B,L) IVS 10 c.133817C4G Intron Frequent This study IVS 10 c.1338120C4G Intron Frequent This study IVS 10 c.1338162G4C Intron Frequent This study IVS 11 c.1432À41A4G Intron Frequent This study, (E) E 12 c.1540G4A V514I ABCC6 1 This study IVS 12 c.1635147C4T Intron Frequent This study E 14 c.1841T4C V614A ABCC6 Frequent This study, (B,E) IVS 14 c.1868À57G4A Intron 3 This study E 15 c.1890C4G T630T ABCC6 Frequent This study, (B,L) E 15 c.1896C4A H632Q ABCC6 Frequent This study, (C,G) E 17 c.2171G4A R724K ABCC6 2 This study E 17 c.2175A4T V725V ABCC6 2 This study E 17 c.2224A4G I742V ABCC6 2 This study E 19 c.2490C4T A830A ABCC6 Frequent This study, (E) E 22 c.2820T4G R940R ABCC6 1 This study E 22 c.2835C4T P945P ABCC6 8 This study, (J) E 22 c.2836C4A L946I ABCC6 3 This study E 22 c.2904G4A L968L ABCC6 1 This study, (J) E 23 c.3190C4T R1064W ABCC6 2 This study IVS 24 c.3507À16T4C No SSM Intron 4 This study IVS 24 c.3507À3C4T No SSM Intron 3 This study E 27 c.3803G4A R1268Q ABCC6 Frequent This study, (C,M) IVS 27 c.3883À24G4A Intron 1 This study IVS 28 c.4041149C4T Intron Frequent This study, (E) IVS 28 c.4042À30C4T Intron Frequent This study IVS 29 c.420819G4A Intron 2 This study E 30 c.4305C4T G1435G ABCC6 1 This study IVS 30 c.4405À31G4A Intron Frequent This study 30 UTR c.4512117G4A UTR 5 This study, (E) 30 UTR c.4512138G4A UTR 1 This study ÃDNA mutation numbering is based on the ABCC6 cDNA sequence (GenBank accession no. AF076622.1) and 11 corresponds to the A of the ATG translation initiation codon of the reference sequence.
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ABCC6 p.Arg1064Trp 16086317:209:2345
status: NEW199 Coding sequence SNPs were considered as neutral (non-disease-causing) when they resulted in a synonymous amino acid substitution or a nonsynonymous substitution that did not cosegregate with the disease haplotype and phenotype (p.V614A, p.R724K, p.I742V, p.L946I, p.R1064W, and p.R1268Q) or did cosegregate with other PXE mutations in linkage disequilibrium in individual families (p.V514I, p.H632Q, and p.R1268Q).
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ABCC6 p.Arg1064Trp 16086317:199:266
status: NEW[hide] Molecular docking simulations provide insights in ... PLoS One. 2014 Jul 25;9(7):e102779. doi: 10.1371/journal.pone.0102779. eCollection 2014. Hosen MJ, Zubaer A, Thapa S, Khadka B, De Paepe A, Vanakker OM
Molecular docking simulations provide insights in the substrate binding sites and possible substrates of the ABCC6 transporter.
PLoS One. 2014 Jul 25;9(7):e102779. doi: 10.1371/journal.pone.0102779. eCollection 2014., [PMID:25062064]
Abstract [show]
The human ATP-binding cassette family C member 6 (ABCC6) gene encodes an ABC transporter protein (ABCC6), primarily expressed in liver and kidney. Mutations in the ABCC6 gene cause pseudoxanthoma elasticum (PXE), an autosomal recessive connective tissue disease characterized by ectopic mineralization of the elastic fibers. The pathophysiology underlying PXE is incompletely understood, which can at least partly be explained by the undetermined nature of the ABCC6 substrates as well as the unknown substrate recognition and binding sites. Several compounds, including anionic glutathione conjugates (N-ethylmaleimide; NEM-GS) and leukotriene C4 (LTC4) were shown to be modestly transported in vitro; conversely, vitamin K3 (VK3) was demonstrated not to be transported by ABCC6. To predict the possible substrate binding pockets of the ABCC6 transporter, we generated a 3D homology model of ABCC6 in both open and closed conformation, qualified for molecular docking and virtual screening approaches. By docking 10 reported in vitro substrates in our ABCC6 3D homology models, we were able to predict the substrate binding residues of ABCC6. Further, virtual screening of 4651 metabolites from the Human Serum Metabolome Database against our open conformation model disclosed possible substrates for ABCC6, which are mostly lipid and biliary secretion compounds, some of which are found to be involved in mineralization. Docking of these possible substrates in the closed conformation model also showed high affinity. Virtual screening expands this possibility to explore more compounds that can interact with ABCC6, and may aid in understanding the mechanisms leading to PXE.
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No. Sentence Comment
230 (Asp1056Glu) R1064 3190C.T R1064W Missense 23 p.
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ABCC6 p.Arg1064Trp 25062064:230:27
status: NEW231 (Arg1064Trp) G1203 3608G.A G1203D Missense 25 p.
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ABCC6 p.Arg1064Trp 25062064:231:1
status: NEW