ABCC7 p.Gly424Ser
| CF databases: |
c.1270G>A
,
p.Gly424Ser
(CFTR1)
?
, This sequence variation was detected by DGGE and identified by direct sequencing. This missense mutation was not found in 100 other non-[delta]F508 CF chromosomes and 200 non CF chromosomes tested. This mutation was observed in a male subject with bronchiectasis. The other mutation is unknown.
|
| Predicted by SNAP2: | A: N (53%), C: D (63%), D: N (53%), E: N (53%), F: D (71%), H: N (57%), I: D (71%), K: D (63%), L: D (71%), M: D (66%), N: N (78%), P: D (59%), Q: N (61%), R: D (59%), S: N (72%), T: N (61%), V: D (66%), W: D (75%), Y: D (75%), |
| Predicted by PROVEAN: | A: N, C: N, D: N, E: N, F: N, H: N, I: N, K: N, L: N, M: N, N: N, P: N, Q: N, R: N, S: N, T: N, V: N, W: N, Y: N, |
[switch to compact view]
Comments [show]
None has been submitted yet.
[hide] A combined analysis of the cystic fibrosis transme... Mol Biol Evol. 2001 Sep;18(9):1771-88. Chen JM, Cutler C, Jacques C, Boeuf G, Denamur E, Lecointre G, Mercier B, Cramb G, Ferec C
A combined analysis of the cystic fibrosis transmembrane conductance regulator: implications for structure and disease models.
Mol Biol Evol. 2001 Sep;18(9):1771-88., [PMID:11504857]
Abstract [show]
Over the past decade, nearly 1,000 variants have been identified in the cystic fibrosis transmembrane conductance regulator (CFTR) gene in classic and atypical cystic fibrosis (CF) patients worldwide, and an enormous wealth of information concerning the structure and function of the protein has also been accumulated. These data, if evaluated together in a sequence comparison of all currently available CFTR homologs, are likely to refine the global structure-function relationship of the protein, which will, in turn, facilitate interpretation of the identified mutations in the gene. Based on such a combined analysis, we had recently defined a "functional R domain" of the CFTR protein. First, presenting two full-length cDNA sequences (termed sCFTR-I and sCFTR-II) from the Atlantic salmon (Salmo salar) and an additional partial coding sequence from the eastern gray kangaroo (Macropus giganteus), this study went further to refine the boundaries of the two nucleotide-binding domains (NBDs) and the COOH-terminal tail (C-tail), wherein NBD1 was defined as going from P439 to G646, NBD2 as going from A1225 to E1417, and the C-tail as going from E1418 to L1480. This approach also provided further insights into the differential roles of the two halves of CFTR and highlighted several well-conserved motifs that may be involved in inter- or intramolecular interactions. Moreover, a serious concern that a certain fraction of missense mutations identified in the CFTR gene may not have functional consequences was raised. Finally, phylogenetic analysis of all the full-length CFTR amino acid sequences and an extended set of exon 13--coding nucleotide sequences reinforced the idea that the rabbit may represent a better CF model than the mouse and strengthened the assertion that a long-branch attraction artifact separates the murine rodents from the rabbit and the guinea pig, the other Glires.
Comments [show]
None has been submitted yet.
No. Sentence Comment
591 Similarly, the missense mutations occurring in evolutionarily divergent regions, for example, N418S, G424S, Q890R, and K1177R, may also represent neutral polymorphisms.
X
ABCC7 p.Gly424Ser 11504857:591:101
status: NEW[hide] Missense, nonsense, and neutral mutations define j... J Biol Chem. 2003 Jul 18;278(29):26580-8. Epub 2003 May 5. Pagani F, Buratti E, Stuani C, Baralle FE
Missense, nonsense, and neutral mutations define juxtaposed regulatory elements of splicing in cystic fibrosis transmembrane regulator exon 9.
J Biol Chem. 2003 Jul 18;278(29):26580-8. Epub 2003 May 5., 2003-07-18 [PMID:12732620]
Abstract [show]
Exonic sequence variations may induce exon inclusion or exclusion from the mature mRNA by disrupting exonic regulatory elements and/or by affecting a nuclear reading frame scanning mechanism. We have carried out a systematic study of the effect on cystic fibrosis transmembrane regulator exon 9 splicing of natural and site-directed sequence mutations. We have observed that changes in the splicing pattern were not related to the creation of premature termination codons, a fact that indicates the lack of a significant nuclear check of the reading frame in this system. In addition, the splice pattern could not be predicted by available Ser/Arg protein matrices score analysis. An extensive site-directed mutagenesis of the 3' portion of the exon has identified two juxtaposed splicing enhancer and silencer elements. The study of double mutants at these regulatory elements showed a complex regulatory activity. For example, one natural mutation (146C) enhances exon inclusion and overrides all of the downstream silencing mutations except for a C to G transversion (155G). This unusual effect is explained by the creation of a specific binding site for the inhibitory splicing factor hnRNPH. In fact, on the double mutant 146C-155G, the silencing effect is dominant. These results indicate a strict dependence between the two juxtaposed enhancer and silencer sequences and show that many point mutations in these elements cause changes in splicing efficiency by different mechanisms.
Comments [show]
None has been submitted yet.
No. Sentence Comment
83 Four of the natural substitutions, C31T (Q414X), G61A (G424S), T122G (I444S), and C155A (A455E), significantly decreased exon 9 inclusion to 48, 30, 40, and 16%, respectively, whereas only a modest decrease was evident for N418S.
X
ABCC7 p.Gly424Ser 12732620:83:55
status: NEW221 WT sequence position AA change Nucleotide mutants Exon 9ϩ SR protein matrices above thresholds Disruption of preexisting sites New sites created by the mutations SC35 SR40 SF2 SR55 % WT 65 A 15 C 65 T 16 ⌬ 96 T 18 G 95 3.38 (13) G 19 A 52 A 20 G 80 C 31 Q414X T 50 A 43 G 62 SR40 0.28 (41) A 44 N414S G 59 46t49t 67 SR40 1.43 (41) G 61 G424S A 31 C 58 66g67a69g 68 SR40-1.01 (66) 3.21 (63) 2.24 (64) C 72 G 18 2.20 (67) A 63 2.01 (69) G 118 D443Y T 68 A 65 120g122a123g 96 2.24 (118) T 122 I444S G 40 A 144 G 55 T 40 C 145 G 85 A 87 A 146 G 92 3.02 (146) 2.66 (141) T 94 3.23 (143) Q452P C 96 3.46 (143) ⌬ 97 2.81 (142) 3.03 (141) G 147 T 97 C 98 2.70 (142) 3.00 (144) 2.53 (143) T 148 G 26 2.99 (142) 4.05 (143) C 90 2.49 (143) 2.47 (145) A 93 3.46 (145) T 149 C 82 2.99 (144) 3.53 (145) G 150 A 50 3.38 (148) C 62 T 151 A 65 C 67 3.00 (146) 3.15 (148) G 153 C 65 T 42 2.76 (153) G 154 T 18 C 20 C 155 A455E A 15 1.98 (152) G 3 T 5 G 156 T 10 3.59 (153) C 40 3.82 (153) G 157 V456F T 65 G 164ϩ ins 14 regulatory sequences derived from SR-specific score matrices, and the creation of novel enhancer and silencer controlling elements.
X
ABCC7 p.Gly424Ser 12732620:221:349
status: NEW[hide] A large-scale study of the random variability of a... Eur J Hum Genet. 2005 Feb;13(2):184-92. Modiano G, Bombieri C, Ciminelli BM, Belpinati F, Giorgi S, Georges M, Scotet V, Pompei F, Ciccacci C, Guittard C, Audrezet MP, Begnini A, Toepfer M, Macek M, Ferec C, Claustres M, Pignatti PF
A large-scale study of the random variability of a coding sequence: a study on the CFTR gene.
Eur J Hum Genet. 2005 Feb;13(2):184-92., [PMID:15536480]
Abstract [show]
Coding single nucleotide substitutions (cSNSs) have been studied on hundreds of genes using small samples (n(g) approximately 100-150 genes). In the present investigation, a large random European population sample (average n(g) approximately 1500) was studied for a single gene, the CFTR (Cystic Fibrosis Transmembrane conductance Regulator). The nonsynonymous (NS) substitutions exhibited, in accordance with previous reports, a mean probability of being polymorphic (q > 0.005), much lower than that of the synonymous (S) substitutions, but they showed a similar rate of subpolymorphic (q < 0.005) variability. This indicates that, in autosomal genes that may have harmful recessive alleles (nonduplicated genes with important functions), genetic drift overwhelms selection in the subpolymorphic range of variability, making disadvantageous alleles behave as neutral. These results imply that the majority of the subpolymorphic nonsynonymous alleles of these genes are selectively negative or even pathogenic.
Comments [show]
None has been submitted yet.
No. Sentence Comment
33 In the Tajima`s test,19 the null hypothesis of neutrality is rejected if a statistically significant difference between p Common and rare nonsynonymous and synonymous cSNSs G Modiano et al European Journal of Human Genetics Table 1 List of the 61 cSNSsa encountered in the present survey The random samples of genes (and the technique utilized) cSNS variants found NE Italy (DGGE) Central Italy (DGGE) Southern France (DGGE) Northern France (DHPLC) Spain (SSCA) Czechia (DGGE) Hb  104 Exon Exon Length (bp) Ref. no. SNS SASc 1st 100d 2nd 500 1st 100d 2nde 1st 100d 2nd 500 1st 100 2nde 82d 72 Abs. Freq. Total sample size q  104 se  104 NSf Sf 1g 53 0 0 0 0 0/452 0 924 2 111 1 223C4T R31C 1 1 1/500 1 1 0 0/450 0 5 (11) 1 932 (2 432) 45.23 13.61 90 2 224G4T R31L 0 0 0/500 0 0 0 1/450 0 1 1 932 5.17 5.17 10 3 257C4T S42F 0 0 1/500 0 0 0 0/450 0 1 1 932 5.17 5.17 10 3 109 4 334A4G K68E 1 0 0 0/498 0 0 0 0/452 0 0 1 2 504 3.99 3.99 8 5 352C4T R74W 0 0 0 0/498 0 0 0 1/452 0 0 1 2 504 3.99 3.99 8 6 356G4A R75Q 1 7 1 7/498 2 9 2 9/452 0 2 40 (40) 2 504 (2 544) 157.23 24.66 310 7 386G4A G85E 0 0 1 1/498 0 0 0 0/452 0 0 2 2 504 7.99 5.65 16 4 216 8 482G4A R117H 0 0 0 0/292 0 2 0 1/456 0 0 3 2 302 13.03 7.52 26 9 528T4G I132M 0 0 0 0/292 0 0 0 1/456 0 0 1 2 302 4.34 4.34 8 10 575T4C I148T 1 2 0 1/292 0 0 0 1/456 0 1 6 2 302 26.06 10.63 52 5 90 11 640C4T R170C 0 0 0 0/6 0 0 1/448 0 1 1 436 6.96 6.96 14 12 641G4A R170H 1 1 0 0/6 0 0 2/448 0 4 (4) 1 436 (1 930) 20.73 10.35 41 6a 164 0 0 0/6 0 0 0/432 0 0 992 6b 126 0 0 0/6 0 0 0/454 0 942 7 247 0 0 0/6 0 0 0/796 0 1 284 8 93 13 1281G4A L383 0 0 0 0/6 0 0 1/456 0 0 1 1 516 6.60 6.60 13 9 183 14 1402G4A G424S 0 0 0/6 0 0 1/454 0 1 940 10.64 10.64 21 15 1459G4T D443Y 0 0 0/6 0 0 1/454 0 1 940 10.64 10.64 21 10 192 16 1540A4G M470Vh 42 197 30 37/96 39 199 (i) (i) 27 571(736) 1 484 (1 912) 3849.37 111.28 4 735 17 1598C4A S489X 0 0 0 0/96 0 0 0 1/796 0 1 2 374 4.21 4.21 8 18 1648A4G I506V 1 0 0 0/96 0 0 0 0/796 0 1 2 374 4.21 4.21 8 19 1655T4G F508C 0 1 0 0/96 0 0 0 1/796 0 2 2 038 8.42 5.96 17 20 1716G4A Q528 2 16 1 0/96 0 19 i I 5 43 (58) 1 478 (2 024) 286.56 37.08 557 11 95 21 1756G4T G542X 0 2 0 0/134 0 0 0/796 0 0 2 1 984 10.08 7.12 20 22 1764T4G G544 0 0 0 0/134 0 0 1/796 0 0 1 1 984 5.04 5.04 10 23 1784G4A G551D 0 0 0 0/134 0 0 1/796 0 0 1 1 984 5.04 5.04 10 12 87 24 1816G4A V562I 0 0 0 0 1 0 0/450 0 0 1 (1) 2 004 (2 504) 3.99 3.99 8 25 1816G4C V562L 0 0 0 1 0 0 1/450 0 0 2 (3) 2 004 (2 504) 11.98 6.91 24 26 1859G4C G576A 1 2 0 1 11 0 8/450 0 0 23 (27) 2 004 (2 538) 106.38 20.36 213 13 724j 449 27 1997G4A G622D 0 0 0/80 0/96 1 0 0 0/444 0 1 2 002 5.00 5.00 10 28 2082C4T F650 1 0 0/80 0/20 0 0 0 0/444 0 1 (1) 1 926 (2 412) 4.15 4.15 8 29 2134C4T R668C 1 2 0/80 0/96 1 11 0 12/444 0 27(32) 2 002 (2 558) 125.10 21.98 247 275 30 2377C4T L748 0 0 0/6 0 1 1 388 25.77 25.77 52 14a 129 31 2670G4A W846X 0 0 0/6 0 1 0/452 0/80 0 1 1 010 9.90 9.90 20 32 2694T4G T854 33 23 0/6 33 38 149/452 14/80 11 301 1 010 2980.20 143.92 4 184 33 2695G4A V855I 0 0 0/6 0 0 1/452 0/80 0 1 1 010 9.90 9.90 20 14b 38 0 0 0 0/520 0 0 0 0/446 0 2 448 15 251 34 2816G4C S895T 0 0 0/6 0 0 2/436 0 0 2 996 20.08 14.18 40 35 2831A4C N900T 0 0 0/6 0 0 1/436 0 0 1 996 10.04 10.04 20 36 2988G4C M952I 0 0 0/6 0 0 1/436 0 0 1 996 10.04 10.04 20 37 3030G4A T966 (2)k (1)k 0 6/436 0 6 (25)k 618 (1814)k 137.82 27.37 272 38 3032T4C L967S 0 0 0/6 0 0 1/436 0 0 1 996 10.04 10.04 20 16 80 0 0 0/498 0 0 0/450 0 0 1 502 17a 151 39 3123G4C L997F 0 2 2 1/494 0 7 1 4/454 0 0 17 2 502 67.95 16.42 135 40 3157G4A A1009T 0 2 0 0/494 0 0 0 0/454 0 0 2 2 502 7.99 5.65 16 41 3212T4C I1027T 1 0 0 0/494 0 0 0 0/454 0 0 1 2 502 4.00 4.00 8 17b 228 42 3286T4G F1052V 1 1 0 1/194 0 0 0 0/452 0 0 3 (3) 2 200 (2 240) 13.39 7.73 27 43 3337G4A G1069R 0 1 0 0/194 0 0 0 0/452 0 0 1 2 200 4.55 4.55 9 CommonandrarenonsynonymousandsynonymouscSNSs GModianoetal 186 EuropeanJournalofHumanGenetics 44 3345G4T Q1071H 0 0 0 0/194 0 1 0 0/452 0 0 1 2 200 4.55 4.55 9 45 3417A4T T1995 1 3 0 0/194 1 1 0 0/452 0 0 6 (8) 2 200 (2 506) 31.92 11.27 64 46 3419T4G L1096R 0 0 0 0/194 1 0 0 0/452 0 0 1 2 200 4.55 4.55 9 47 3477C4A T1115 0 0 0 0/194 0 0 0 1/452 0 0 1 2 200 4.55 4.55 9 18 101 48 3523A4G I1131V 0 0 1 0/10 0 0 0/448 0 0 1 (2) 1 512 (1 908) 10.48 7.07 21 49 3586G4C D1152H 0 0 0 0/10 0 0 1/448 0 0 1 1 512 6.61 6.61 13 19 249 50 3617G4T R1162L 0 0 1 1/494 0 0/260 0 0/454 0 0 2 2 262 8.84 6.25 18 51 3690A4G Q1186 0 0 0 0/494 0 0/260 0 0/454 1 0 1 2 262 4.42 4.42 9 52 3813A4G L1227 0 1 0 0/494 0 0/260 0 0/454 0 0 1 2 262 4.42 4.42 9 53 3837T4G S1235R 1 1 0 1/494 0 4/260 0 7/454 0 1 15 (15) 2 262 (2 310) 69.94 16.71 140 20 156 54 4002A4G P1290 2 3 0/6 3 5 18/454 3/80 2 36 1 012 357.73 58.22 690 21 90 55 4009G4A V1293I 0 0 0/6 0 0/300 0 1/456 0 0 1 1 316 7.60 7.60 15 56 4029A4G T1299 1 0 0/6 0 1/300 0 1/456 0 0 3 (8) 1 316 (2 330) 34.33 12.12 69 57 4041C4G N1303K 1 0 0/6 0 0/300 0 0/456 0 0 1 1 316 7.60 7.60 15 58 4085T4C V1318A 0 0 0/6 0 0/300 0 1/456 0 0 1 1 316 7.60 7.60 15 22 173 0 0 0/18 0 0 0/450 0 0 1 022 23 106 0 0 0 0/6 0 0 0/448 0 1 436 24l 198+3 59 4404C4T Y1424 1 0 0/6 1 2 5/420 0 2 11 (32) 980 (2 516) 127.19 22.34 251 60m 4521G4A Q1463 (21) (16) (3/32) (14/80) (30) (94/420) 15/76 (17) 15 (227) 76 (1052) 2142.86 131.07 3 367 61 4563T4C D1477 0 0 0/6 0 1 0/420 0 0 1 980 10.20 10.20 20 Totals 6 525 9 584 16 109 The bracketed figures include also the RFLP analysis data (see Materials and methods); the NE Italy, Central Italy, Southern and Northern France are each subdivided into two samples where the 1st is made up of 100 genes.
X
ABCC7 p.Gly424Ser 15536480:33:1679
status: NEW[hide] Mutations of the cystic fibrosis gene in patients ... Ann Rheum Dis. 2011 Apr;70(4):653-9. Epub 2010 Dec 3. Puechal X, Bienvenu T, Genin E, Berthelot JM, Sibilia J, Gaudin P, Marcelli C, Lasbleiz S, Michou L, Cornelis F, Kahan A, Dusser DJ
Mutations of the cystic fibrosis gene in patients with bronchiectasis associated with rheumatoid arthritis.
Ann Rheum Dis. 2011 Apr;70(4):653-9. Epub 2010 Dec 3., [PMID:21131649]
Abstract [show]
OBJECTIVES: In cystic fibrosis, mutations of the CFTR gene lead to diffuse bronchiectasis (DB). DB is also associated with other diseases including rheumatoid arthritis (RA) in which the role of genetic factors in the predisposition to DB remains unclear. METHODS: A family-based association study was carried out to determine whether the frequency of CFTR mutations was higher in patients with RA-associated DB and to determine whether a causal relationship could be established between the variant and the disease by evaluating its cosegregation with DB within families. Families of probands with RA-DB were included if one first-degree relative had RA and/or DB. The controls comprised healthy subjects requesting genetic counselling because their partner had cystic fibrosis. RESULTS: The frequency of CFTR mutations was higher in family members with RA-DB or DB only than in unaffected relatives (p<0.005 for each comparison) and in unrelated healthy controls (p<0.001 for each comparison) but not in family members with RA only. CFTR mutations were more frequent in family members with RA-DB than in those with RA only (OR 5.30, 95% CI 2.48 to 11.33; p<5x10(-5)). They cosegregated with RA-DB in the families (sib-TDT=10.82, p=0.005). CONCLUSIONS: RA-DB should be added to the list of phenotypes in which CFTR mutations are pathogenic. CFTR mutation is the first genetic defect linked to an extra-articular feature of RA to be described. CFTR mutations in patients with RA appear to be an important marker of the risk of associated DB, which has been linked to a less favourable prognosis.
Comments [show]
None has been submitted yet.
No. Sentence Comment
61 Table 1 CFTR genotypes of the family population Family (N=24) CFTR genotypes RA-DB (N=30) DB only (N=8) RA only (N=24) Unaffected individuals (N=76) 1 c.1584G>A (p.Glu528Glu ):- 1 -:- 1 2 p.Gly424Ser+p.Gly576Ala 1 p.Gly424Ser:- 1 p.Arg75Gln:- 1 1 3 p.Phe508del (c.1521_1523delCTT)+5T (c.1210-12[5]) 1 p.Phe508del:- 1 2 2 5T (c.1210-12[5]):- 1 -:- 1 4 5T (c.1210-12[5]):- 1 1 2 -:- 1 2 1 p.Phe1052Val:- 1 5 5T (c.1210-12[5]):- 1 6 p.Phe508del+p.Ser977Phe-5T (c.1210-12[5]) 1 1 1 p.Phe508del:- 1 p.Ser977Phe-5T (c.1210-12[5]):- 3 7 p.Arg75Gln:- 2 8 p.Asp1152His+c.262_263delTT 1 1 p.Asp1152His+c.-7G>C 1 c.262_263delTT:- 1 9 c.1584G>A (p.Glu528Glu ):- 1 p.Arg75Gln:- 1 -:- 1 5 10 10 c.-7G>C:- 1 -:- 1 8 11 p.Ser1235Arg:- 1 1 -:- 1 12 p.Ala923Ala:- 1 1 13 c.1584G>A (p.Glu528Glu ):- 1 1 1 p.Ala923Ala:- 1 14 c.1584G>A (p.Glu528Glu ):- 2 1 -:- 1 3 15 -:- 1 1 5 16 -:- 1 1 7 17 -:- 2 1 3 18 -:- 1 1 19 -:- 1 1 2 20 -:- 1 1 21 -:- 1 1 3 22 -:- 1 1 6 23 -:- 1 1 3 24 -:- 1 1 7 Total no.
X
ABCC7 p.Gly424Ser 21131649:61:216
status: NEW