ABCD1 p.Ala294Thr
| Predicted by SNAP2: | C: D (91%), D: D (95%), E: D (95%), F: D (95%), G: D (91%), H: D (95%), I: D (95%), K: D (95%), L: D (95%), M: D (95%), N: D (95%), P: D (95%), Q: D (95%), R: D (95%), S: D (85%), T: D (91%), V: D (95%), W: D (95%), Y: D (95%), |
| Predicted by PROVEAN: | C: D, D: D, E: D, F: D, G: D, H: D, I: D, K: D, L: D, M: D, N: D, P: D, Q: D, R: D, S: D, T: D, V: D, W: D, Y: D, |
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[hide] Mutational and protein analysis of patients and he... Am J Hum Genet. 1996 Jun;58(6):1135-44. Feigenbaum V, Lombard-Platet G, Guidoux S, Sarde CO, Mandel JL, Aubourg P
Mutational and protein analysis of patients and heterozygous women with X-linked adrenoleukodystrophy.
Am J Hum Genet. 1996 Jun;58(6):1135-44., [PMID:8651290]
Abstract [show]
X-linked adrenoleukodystrophy (ALD), a neurodegenerative disorder associated with impaired beta-oxidation of very-long-chain fatty acids (VLCFA), is due to mutations in a gene encoding a peroxisomal ATP-binding cassette (ABC) transporter (ALD protein [ALDP]). We analyzed the open reading frame of the ALD gene in 44 French ALD kindred by using SSCP or denaturing gradient-gel electrophoresis and studied the effect of mutations on ALDP by immunocytofluorescence and western blotting of fibroblasts and/or white blood cells. Mutations were detected in 37 of 44 kindreds and were distributed over the whole protein-coding region, with the exception of the C terminus encoded in exon 10. Except for two mutations (delAG1801 and P560L) observed four times each, nearly every ALD family has a different mutation. Twenty-four of 37 mutations were missense mutations leading to amino acid changes located in or close to putative transmembrane segments (TMS 2, 3, 4, and 5), in the EAA-like motif and in the nucleotide fold of the ATP-binding domain of ALDP. Of 38 ALD patients tested, 27 (71%) lacked ALDP immunoreactivity in their fibroblasts and/or white blood cells. More than half of missense mutations studied (11 of 21) resulted in a complete lack of ALDP immunoreactivity, and six missense mutations resulted in decreased ALDP expression. The fibroblasts and/or white blood cells of 15 of 15 heterozygous carrier from ALD kindred with no ALDP showed a mixture of positive- and negative-ALDP immunoreactivity due to X-inactivation. Since 5%-15% of heterozygous women have normal VLCFA levels, the immunodetection of ALDP in white blood cells can be applicable in a majority of ALD kindred, to identify heterozygous women, particularly when the ALD gene mutation has not yet been identified.
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No. Sentence Comment
76 58:1135-1144, 1996 Table 2 Mutations in the ALD Gene in Studied Patients AMINO ACID MUTATIONSb HOMOLOGUE INd KINDRED CLINICAL LOCALIZATION AMINO ACID ALDP BY NUMBER PHENOTYPEa DNA CpG Exon IN PROTEINC ALTERATION h/m ALDRP hPMP70 IF/WB' CALD, AMN CALD CALD CALD, AS AD CALD, AMN CALC AD AD AD ALMD CALD CALD, AMN CALD CALD, AMN, AD AMN ALMD CALD ALMD CALD AMN ALD AD, AMN, AS CALD, AS CALD CALD AD CALD AMN, ALMD CALD CALD AMN, ALMD CALD CALD, AMN, ALMD CALD CALD, ALMD, AS ALMD CALD AMN CALD, AMN AD AD AMN CALD G416A Ins T524 C679T C679T C700T C709G G732A A829G C840T Del TA927-28 A928G A985T A1048G DeIGC1080-81 C1174T G1266A ins C1521 1636delC DelAG 1801-02 DelAG 1801-02 DelAG 1801-02 DelAG 1801-02 ins TGG 1848 G 1920 A C1938T C1938T G1950A C2065T C2065T C2065T C2065T C2065G G 2166+1 A T2202C DelGC 2335 C2364T C2364T No mutation found No mutation found No mutation found No mutation found No mutation found No mutation found No mutation found 1 1 + 1 + 1 1 1 + 1 1 + 1 1 1 1 1 1 1 + 1 3 4 S 5 S S S 6 + 6 + 6 6 + 7 + 7 + 7 + 7 + 7 + 7 8 9 9 9 W10 X Frameshift at L46 TMS2 S98L TMS2 S98L T1OSI S108W G116R TMS3 N148S TMS3 R152C Frameshift at Y180 Y181C TMS4 D200V TMS4 D221G Frameshift at R231 P263L EAA-like A294T Frameshift at V378 Frameshift at T416 Frameshift at E471 Frameshift at E471 Frameshift at E471 Frameshift at E471 ins val 491 Walker A G512S Walker A R518W Walker A R518W G 522 W P560L P560L P560L P560L P56OR Splice at G593 Walker B S606P Frameshift at D649 R660W R660W Absent Not done S A Present S A Present T T Absent S D Decreased G T Absent N N Present R K Present Absent Y Y Not done D D Not done D D Absent Absent P R Decreased A A Not done Absent Absent Absent Absent Absent Absent Absent G G Absent R R Absent R R Decreased G E Absent P P Decreased P P Decreased P P Decreased P P Absent P P Absent Not done S S Absent Absent R R Absent R R Absent Not done Absent Absent Absent Present Absent Absent a CALD = cerebral ALD (5-15 years); AMN = adrenomyeloneuropathy; ALMD = adrenomyeloneuropathy with cerebral involvement; AD = Addison disease; AS = Asymptomatic.
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ABCD1 p.Ala294Thr 8651290:76:1215
status: NEW146 One missense mutation (A294T) was found in an EAA-like motif that is highly conserved in ALDP, ALDPR, and PMP70 proteins (Shani et al. 1995) and whose mutations can cause loss of transporter function of an ABC protein (Koster and Braun 1992).
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ABCD1 p.Ala294Thr 8651290:146:23
status: NEW75 58:1135-1144, 1996 Table 2 Mutations in the ALD Gene in Studied Patients AMINO ACID MUTATIONSb HOMOLOGUE INd KINDRED CLINICAL LOCALIZATION AMINO ACID ALDP BY NUMBER PHENOTYPEa DNA CpG Exon IN PROTEINC ALTERATION h/m ALDRP hPMP70 IF/WB' CALD, AMN CALD CALD CALD, AS AD CALD, AMN CALC AD AD AD ALMD CALD CALD, AMN CALD CALD, AMN, AD AMN ALMD CALD ALMD CALD AMN ALD AD, AMN, AS CALD, AS CALD CALD AD CALD AMN, ALMD CALD CALD AMN, ALMD CALD CALD, AMN, ALMD CALD CALD, ALMD, AS ALMD CALD AMN CALD, AMN AD AD AMN CALD G416A Ins T524 C679T C679T C700T C709G G732A A829G C840T Del TA927-28 A928G A985T A1048G DeIGC1080-81 C1174T G1266A ins C1521 1636delC DelAG 1801-02 DelAG 1801-02 DelAG 1801-02 DelAG 1801-02 ins TGG 1848 G 1920 A C1938T C1938T G1950A C2065T C2065T C2065T C2065T C2065G G 2166+1 A T2202C DelGC 2335 C2364T C2364T No mutation found No mutation found No mutation found No mutation found No mutation found No mutation found No mutation found 1 1 + 1 + 1 1 1 + 1 1 + 1 1 1 1 1 1 1 + 1 3 4 S 5 S S S 6 + 6 + 6 6 + 7 + 7 + 7 + 7 + 7 + 7 8 9 9 9 W10 X Frameshift at L46 TMS2 S98L TMS2 S98L T1OSI S108W G116R TMS3 N148S TMS3 R152C Frameshift at Y180 Y181C TMS4 D200V TMS4 D221G Frameshift at R231 P263L EAA-like A294T Frameshift at V378 Frameshift at T416 Frameshift at E471 Frameshift at E471 Frameshift at E471 Frameshift at E471 ins val 491 Walker A G512S Walker A R518W Walker A R518W G 522 W P560L P560L P560L P560L P56OR Splice at G593 Walker B S606P Frameshift at D649 R660W R660W Absent Not done S A Present S A Present T T Absent S D Decreased G T Absent N N Present R K Present Absent Y Y Not done D D Not done D D Absent Absent P R Decreased A A Not done Absent Absent Absent Absent Absent Absent Absent G G Absent R R Absent R R Decreased G E Absent P P Decreased P P Decreased P P Decreased P P Absent P P Absent Not done S S Absent Absent R R Absent R R Absent Not done Absent Absent Absent Present Absent Absent a CALD = cerebral ALD (5-15 years); AMN = adrenomyeloneuropathy; ALMD = adrenomyeloneuropathy with cerebral involvement; AD = Addison disease; AS = Asymptomatic.
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ABCD1 p.Ala294Thr 8651290:75:1215
status: NEW[hide] Mutational analysis and genotype-phenotype correla... Arch Neurol. 1999 Mar;56(3):295-300. Takano H, Koike R, Onodera O, Sasaki R, Tsuji S
Mutational analysis and genotype-phenotype correlation of 29 unrelated Japanese patients with X-linked adrenoleukodystrophy.
Arch Neurol. 1999 Mar;56(3):295-300., [PMID:10190819]
Abstract [show]
BACKGROUND: X-linked adrenoleukodystrophy (ALD) is an inherited disease characterized by progressive neurologic dysfunction, occasionally associated with adrenal insufficiency. The classic form of ALD usually has onset in childhood (childhood cerebral ALD), with rapid neurologic deterioration leading to a vegetative state. Adult-onset cerebral ALD also presents with rapidly progressive neurologic dysfunction. Milder phenotypes such as adrenomyeloneuropathy and Addison disease only also have been recognized. Despite discovery of the causative gene, a molecular basis for the diverse clinical presentations remains to be elucidated. OBJECTIVES: To conduct mutational analyses in 29 Japanese patients with ALD from 29 unrelated families, to obtain knowledge of the spectrum of mutations in this gene, and to study genotype-phenotype correlations in Japanese patients. METHODS: The 29 patients comprised 13 patients with childhood cerebral ALD, 11 patients with adult-onset cerebral ALD, and 5 patients with adrenomyeloneuropathy. We conducted detailed mutational analyses of 29 unrelated Japanese patients with ALD by genomic Southern blot analysis and direct nucleotide sequence analysis of reverse transcriptase-polymerase chain reaction products derived from total RNA that was extracted from cultured skin fibroblasts, lymphoblastoid cells, or peripheral blood leukocytes. RESULTS: Three patients with adult-onset cerebral ALD were identified as having large genomic rearrangements. The remaining 26 patients were identified as having 21 independent mutations, including 12 novel mutations resulting in small nucleotide alterations in the ALD gene. Eighteen (69%) of 26 mutations were missense mutations. Most missense mutations involved amino acids conserved in homologous gene products, including PMP70, mALDRP, and Pxa1p. The AG dinucleotide deletion at position 1081-1082, which has been reported previously to be the most common mutation in white patients (12%-17%), was also identified as the most common mutation in Japanese patients (12%). All phenotypes were associated with mutations resulting in protein truncation or subtle amino acid changes. There were no differences in phenotypic expressions between missense mutations involving conserved amino acids and those involving nonconserved amino acids. CONCLUSIONS: There are no obvious correlations between the phenotypes of patients with ALD and their genotypes, suggesting that other genetic or environmental factors modify the phenotypic expressions of ALD.
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No. Sentence Comment
87 Review of previous publications indicated that 14 missense mutations are associated exclu- sivelywithAMNorAddisondiseaseonly,includingC696T (R104C),33,34 G697A(R104H),42 C700T(T105I),45 G832A (S149N),35 C918G(Q178E),42 T1045C(L220P),35 C1137T (T254M),37 G1266A(A294T),45 C1551G(R389G),37 G1552A (R389H),33,35 C1638T (R418W),37 C1930T (S515F),38 T2084A(M566K),33 andG2211A(E606K).35,37 Analysisof these mutations may provide important insights into the mechanisms involved in variable phenotypic expressions in ALD.
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ABCD1 p.Ala294Thr 10190819:87:261
status: NEW