ABCC7 p.Ala561Glu
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PMID: 16442101
[PubMed]
Frelet A et al: "Insight in eukaryotic ABC transporter function by mutation analysis."
No.
Sentence
Comment
313
[141] A561E protein mislocalization in the ER SDM, Tf of BHK cells, pulse chase experiments and Cl- efflux assay.
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ABCC7 p.Ala561Glu 16442101:313:6
status: NEW
PMID: 12110684
[PubMed]
DeCarvalho AC et al: "Mutations in the nucleotide binding domain 1 signature motif region rescue processing and functional defects of cystic fibrosis transmembrane conductance regulator delta f508."
No.
Sentence
Comment
241
It might, thus, be expected that these revertant mutations, identified by virtue of their effects to reverse the ⌬F508 defect, would be specific for suppression of ⌬F508. However, results by others suggest that G550E can partially rescue another processing-defective CF mutant, A561E (61).
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ABCC7 p.Ala561Glu 12110684:241:292
status: NEW242 Possibly, the ⌬F508 and A561E mutations cause misfolding in a similar manner, allowing each to be partially compensated by G550E.
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ABCC7 p.Ala561Glu 12110684:242:31
status: NEW
PMID: 12151438
[PubMed]
Wang Z et al: "Analysis by mass spectrometry of 100 cystic fibrosis gene mutations in 92 patients with congenital bilateral absence of the vas deferens."
No.
Sentence
Comment
20
Given the frequency of CF mutations, especially in the Caucasian population ( in 25), and the common request by CBAVD men to sire their own offspring by using surgical Table I. The 100 most common cystic fibrosis mutations listed by exon Mutationa Exonb Frequency (%)c G85E 3 0.1 394delTT 3 Swedish E60X 3 Belgium R75X 3 405ϩ1G→A Int 3 R117H 4 0.30 Y122X 4 French 457TAT→G 4 Austria I148T 4 Canada (French Canadian) 574delA 4 444delA 4 R117L 4 621ϩ1G→T Int 4 0.72 711ϩ1G→T Int 5 Ͼ0.1 712-1G→T Int 5 711ϩ5G→A Int 5 Italy (Caucasian) L206W 6a R347P 7 0.24 1078delT 7 Ͼ0.1 R334W 7 Ͼ0.1 1154InsTC 7 T338I 7 Italy R347H 7 Turkey Q359K/T360K 7 Israel (Georgian Jews) I336K 7 R352Q 7 G330X 7 S364P 7 A455E 9 0.20 I507 10 0.21 F508 10 66.02 1609delCA 10 Spain (Caucasian) V520F 10 Q493X 10 C524X 10 G480C 10 Q493R 10 1717-1G→A Int 10 0.58 R553X 11 0.73 G551D 11 1.64 G542X 11 2.42 R560T 11 Ͼ0.1 S549N 11 Q552X 11 Italy S549I 11 Israel (Arabs) A559T 11 African American R553G 11 R560K 11 1812-1G→A Int 11 A561E 12 E585X 12 Y563D 12 Y563N 12 1898ϩ1G→A Int 12 0.22 1898ϩ1G→C Int 12 2183AA→G 13 Italian 2184delA 13 Ͻ0.1 K710X 13 2143delT 13 Moscow (Russian) 2184InsA 13 1949del84 13 Spain (Spanish) 2176InsC 13 2043delG 13 2307insA 13 2789ϩ5G→A Int 14b Ͼ0.1 2869insG 15 S945L 15 Q890X 15 3120G→A 16 2067 Table I. continued Mutationa Exonb Frequency (%)c 3120ϩ1G→A Int 16 African American 3272-26A→G Int 17a R1066C 17b Portugal (Portugese) L1077P 17b R1070Q 17b Bulgarian W1089X 17b M1101K 17b Canada (Hutterite) R1070P 17b R1162X 19 0.29 3659delC 19 Ͼ0.1 3849G→A 19 3662delA 19 3791delC 19 3821delT 19 Russian Q1238X 19 S1235R 19 France, South S1196X 19 K1177R 19 3849ϩ10kbC→T Int 19 0.24 3849ϩ4A→G Int 19 W1282X 20 1.22 S1251N 20 Dutch, Belgian 3905insT 20 Swiss, Acadian, Amish G1244E 20 R1283M 20 Welsh W1282R 20 D1270N 20 S1255X 20 African American 4005ϩ1G→A Int 20 N1303K 21 1.34 W1316X 21 aMutations were chosen according to their frequencies (Cystic Fibrosis Genetic Analysis Consortium, 1994; Zielenski and Tsui, 1995; Estivill et al., 1997).
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ABCC7 p.Ala561Glu 12151438:20:1102
status: NEW
PMID: 15520400
[PubMed]
Niel F et al: "Rapid detection of CFTR gene rearrangements impacts on genetic counselling in cystic fibrosis."
No.
Sentence
Comment
207
Gender Current age Phenotype Genotype Origin Age at diagnosis Pancr. status Lung disease Other Sweat test Allele 1 Allele 2 rearrangement involving exon(s) Parental Geographic 1 M 10 years 1 month PI Severe 114 F508del 1 Father North eastern Italy 2 M 16 years Birth PI Severe 130 A561E 2 Father Southern Italy 3 M 10 years 1 year PI Severe + R553X 17b Mother France 4 F 13 years 4 years PI Severe NP + F508del 14b-17b Father Eastern France 5 F 24 years 1 month PI Severe 100 F508del 17a-17b Mother ND 6 F 21 years Childhood PI Moderate + F508del 17a-17b Father Eastern France 7 M 35 years 1 year PI Severe CBAVD, NP 103 F508del 17a-17b Father Eastern France 8* 2 F Deceased at 2 and 6 months Birth PI Severe ND F508del 17a-17b Father Eastern France 9 F Deceased at 15 years 5 years PI Severe 300 1812- 1GRA 3-10,14b-16À Mother Kabylie (Algeria)/ Brittany (France) 10 M 37 years 37 years PS None CBAVD ND R117H(-7T) 1-24 Mother France 11 M Deceased at 31 years 3 months PI Severe DB 90 G542X 4-8 Mother Eastern France CBAVD, congenital bilateral absence of the vas deferens; DB, disseminated bronchiectasis; del, deletion; dup, duplication; F, female; M, male; NP, nasal polyposis; Pancr., pancreatic; PI, pancreatic insufficiency; PS, pancreatic sufficiency.
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ABCC7 p.Ala561Glu 15520400:207:281
status: NEW
PMID: 17098864
[PubMed]
Roxo-Rosa M et al: "Revertant mutants G550E and 4RK rescue cystic fibrosis mutants in the first nucleotide-binding domain of CFTR by different mechanisms."
No.
Sentence
Comment
1
Here, we investigate their mechanism of action by using biochemical and functional assays to examine their effects on F508del and three CF mutations (R560T, A561E, and V562I) located within a conserved region of the first nucleotide-binding domain (NBD1) of CFTR. Like F508del, R560T and A561E disrupt CFTR trafficking.
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ABCC7 p.Ala561Glu 17098864:1:157
status: NEWX
ABCC7 p.Ala561Glu 17098864:1:288
status: NEW2 G550E rescued the trafficking defect of A561E but not that of R560T.
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ABCC7 p.Ala561Glu 17098864:2:40
status: NEW37 47 ͉ 17891-17896 and 4RK act by different mechanisms. To explore this possibility, we tested the effects of G550E and 4RK on three additional CF mutations within NBD1: R560T, A561E, and V562I.ʈ We selected for study these CF mutants because (i) these residues constitute a hot spot for disease-causing mutations (seven mutations are associated with these three residues ); (ii) A561E and R560T are the second and fourth most frequent mutations among Portuguese and Irish CF patients, respectively (28); (iii) like G550E and R555K (one of the 4RK mutants), these mutations affect residues located between the LSGGQ and Walker B motifs of NBD1, which are highly conserved across species; and (iv) they all lie within the same ␣-helix (H5; G550-Y563) within the ATP-binding cassette ␣-subdomain of NBD1 (29, 30).
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ABCC7 p.Ala561Glu 17098864:37:182
status: NEWX
ABCC7 p.Ala561Glu 17098864:37:398
status: NEW38 To test the hypothesis that G550E and 4RK act by different mechanisms, we used biochemical and functional assays to investigate how these revertants rescue F508del-, R560T-, A561E-, and V562I-CFTR.
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ABCC7 p.Ala561Glu 17098864:38:174
status: NEW41 For the reasons outlined in the Introduction, we chose to analyze the CF mutations R560T, A561E, and V562I.
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ABCC7 p.Ala561Glu 17098864:41:90
status: NEW42 Although we previously demonstrated that A561E is processed defectively (31), no trafficking data are available for mutations at R560 and V562.
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ABCC7 p.Ala561Glu 17098864:42:41
status: NEW44 Fig. 1A demonstrates that like F508del- and A561E-CFTR, R560T-CFTR generated only a discrete Ϸ145 kDa band (band B).
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ABCC7 p.Ala561Glu 17098864:44:44
status: NEW47 Next, we investigated whether the revertants G550E and 4RK rescue the defective biosynthesis of R560T- and A561E-CFTR.
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ABCC7 p.Ala561Glu 17098864:47:107
status: NEW49 Fig. 1A shows that G550E and 4RK were much less effective at rescuing A561E-CFTR compared with their effects on F508del-CFTR.
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ABCC7 p.Ala561Glu 17098864:49:70
status: NEW50 In fact, band C of both A561E-4RK- and A561E- G550E-CFTR was detected only after a 24 h incubation with 2 mM 4-phenylbutyrate (4-PB), an enhancer of CFTR expression through transcriptional activation (Fig. 1B) (32).
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ABCC7 p.Ala561Glu 17098864:50:24
status: NEWX
ABCC7 p.Ala561Glu 17098864:50:39
status: NEW51 Quantification of the data reveals that, after this treatment with 4-PB, Ϸ30% of A561E-CFTR was rescued by either revertant, whereas for F508del-CFTR the value was Ϸ65%.
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ABCC7 p.Ala561Glu 17098864:51:87
status: NEW55 The mature form of CFTR (band C) was clearly observed for F508del- and A561E-CFTR (Fig. 1D) in the presence of G550E and 4RK, but G550E failed to correct the defective biosynthesis of R560T-CFTR (Fig. 1 A and D).
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ABCC7 p.Ala561Glu 17098864:55:71
status: NEW70 (A) WB of total protein (30 g) from BHK cells stably expressing wt-, F508del-, R560T-, A561E-, or V562I-CFTR, alone or in cis with 4RK and G550E.
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ABCC7 p.Ala561Glu 17098864:70:95
status: NEW75 (D) BHK cells expressing F508del-, R560T-, or A561E-CFTR alone or in cis with the revertants 4RK and G550E were analyzed by CFTR IP after pulse-labeling for 3 h. Labeled arrows indicate the positions of bands A, B, and C. Thus, the higher steady-state levels of band C for 4RK variants of both wtand V562I-CFTR (Fig. 1A) are explained only in part by a slight (but not significant) increase in the efficiency of processing band B to band C. Surprised that the revertants did not exert stronger effects on the processing of CFTR, we wondered how they might influence CFTR Cl-channel function.
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ABCC7 p.Ala561Glu 17098864:75:46
status: NEW79 Consistent with the biochemical data (Fig. 1), these agonists had no effect on F508del-, R560T-, or A561E-CFTR (Fig. 3 B-D) but evoked a striking efflux of I- from V562I-CFTR (Fig. 3E), which has a time course equivalent to that of wt-CFTR and 1.3-fold greater (Fig. 3F).
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ABCC7 p.Ala561Glu 17098864:79:100
status: NEW84 In contrast to F508del-CFTR, G550E did not restore CFTR function to R560T and both revertants rescued only modestly the CFTR function of A561E (Fig. 3 C, D, and F).
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ABCC7 p.Ala561Glu 17098864:84:137
status: NEW96 (A-E) Time courses of I-efflux from BHK cells stably expressing wt- (A), F508del- (B), R560T- (C), A561E- (D), and V562I- (E) CFTR in the absence and presence of the 4RK and G550E mutations.
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ABCC7 p.Ala561Glu 17098864:96:99
status: NEW127 Like F508del, R560T and A561E disrupt CFTR processing, whereas V562I traffics normally to the cell surface, forming a Cl-channel with properties indistinguishable from those of wt-CFTR.
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ABCC7 p.Ala561Glu 17098864:127:24
status: NEW128 The revertants 4RK and G550E rescue the cell surface expression of A561E, albeit not as effectively as F508del, whereas G550E is without effect on R560T.
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ABCC7 p.Ala561Glu 17098864:128:67
status: NEW129 Of note, G550E, but not 4RK, rescues the defective channel gating of F508del, suggesting that G550E and 4RK rescue the expression and function of F508del by distinct mechanisms. To understand the structural basis by which R560T and A561E disrupt the processing of CFTR (refs.
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ABCC7 p.Ala561Glu 17098864:129:232
status: NEW177 This explains the observed rescue of the cell surface expression of F508del- and A561E-CFTR by the 4RK revertant.
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ABCC7 p.Ala561Glu 17098864:177:81
status: NEW178 However, such an explanation does not imply correction of the folding defects of F508del- and A561E-CFTR.
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ABCC7 p.Ala561Glu 17098864:178:94
status: NEW
PMID: 17534127
[PubMed]
Southern KW et al: "Cystic fibrosis and formes frustes of CFTR-related disease."
No.
Sentence
Comment
60
Classes of CFTR mutations, with molecular and phenotypic consequences Class Molecular consequence Example Phenotypic consequence I nonsense or frameshift mutations that result in no significant protein product G542X typical CF phenotype II protein product does not negotiate intracellular trafficking pathways phe508del R1066C A561E typical CF phenotype III protein product transported to the cell membrane but no significant ion transport function G551D typical CF phenotype IV protein product transported to cell membrane and functions at a low level R117H R334W associated with pancreatic sufficiency V reduced mRNA expression, protein product normal 5T variant of intron poly T region.
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ABCC7 p.Ala561Glu 17534127:60:327
status: NEW
PMID: 17718859
[PubMed]
Faucz FR et al: "Cystic fibrosis in a southern Brazilian population: characteristics of 90% of the alleles."
No.
Sentence
Comment
99
The fact that the mutation spectrum is closer to that found in Italian patients than in Portuguese patients is intriguing, although the Portuguese influence could be more subtle, considering that A561E, the second most common mutation in Portugal (3.2%) (10) was also found in our series (0.9%).
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ABCC7 p.Ala561Glu 17718859:99:196
status: NEW
PMID: 19845690
[PubMed]
Moya-Quiles MR et al: "CFTR mutations in cystic fibrosis patients from Murcia region (southeastern Spain): implications for genetic testing."
No.
Sentence
Comment
17
of chromosomes Frequency (%) F508dela E.10 67 36.8 G542Xa E.11 22 12.1 A1006E E.17a 10 5.5 K710X E.13 10 5.5 2789+5G>Aa I.14b 9 4.9 L206W E.6a 7 3.8 1811+1.6kbA>G I.11 6 3.3 R334Wa E.7 5 2.7 2869insG E.15 5 2.7 I507dela E.10 4 2.2 N1303Ka E.21 4 2.2 R347Pa E.7 3 1.6 711+1G>Ta I.5 3 1.6 3849+10kbC>Ta I.19 3 1.6 Q890X E.15 3 1.6 R117Ha E.4 2 1.1 R1162Xa E.19 2 1.1 2183AA>Ga E.13 2 1.1 A561E E.12 2 1.1 R560G E.11 2 1.1 1717-1G>Aa I.10 1 0.5 E1308X E.21 1 0.5 E585X E.12 1 0.5 L997F E.17a 1 0.5 1677delTA E.10 1 0.5 R1158X E.19 1 0.5 W202X E.6a 1 0.5 R74W+D1270N E.3 + E.20 1 0.5 G576A+R668C E.12 + E.13 1 0.5 Unknown 2 1.1 Total 182 100 aCFTR mutations identified with the PCR OLA CF Genotyping Assay .
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ABCC7 p.Ala561Glu 19845690:17:386
status: NEW
PMID: 15300780
[PubMed]
Wong LJ et al: "Detection of CFTR mutations using temporal temperature gradient gel electrophoresis."
No.
Sentence
Comment
89
For example, the p.Q98X and p.Q98R mutations in exon 4; and p.S466X and p.S492F mutations in exon 10, were detected in the temperature range of 52-607C and 51- 577C, respectively. The p.G542X, p.R553X, p.S549N, and p.A559T in exon 11; p.A561E, c.189811G.A, and c.189813A.G in exon 12; and p.W1204X in exon 19; were detected in the temperature range of 51 to 567C.
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ABCC7 p.Ala561Glu 15300780:89:237
status: NEW133 Identification of rare and novel mutations and polymorphisms Base substitution Mutation Exon or intron Homozygote or heterozygote Polymorphism or mutation # Alleles identified 1 c.124_146del23bp Frameshift 1 Heterozygote Mutation 1 2 c.296+2T>A Splice Int 2 Heterozygote Mutation 1 3 c.296+28A/G Int 2 Homozygote Polymorphism 2 4 c.355CT p.R75X 3 Heterozygote Mutation 2 5 c.360_365insT Frameshift 3 Heterozygote Mutation 1 6 c.379_381insT Frameshift 3 Heterozygote Mutation 1 7 c.406-1G>A Splice Int 4 Heterozygote Mutation 2 8 c.424C.T p.Q98X 4 Heterozygote Mutation 1 9 c.425A.G p.Q98R 4 Heterozygote Mutation 3 10 c.586A.G p.M152V 4 Homozygote Mutation 2 11 c.663delT Frameshift 5 Heterozygote Mutation 3 12 c.667C>A p.Q179K 5 Heterozygote Mutation, 1 13 c.745C.T p.P205S 6a Heterozygote Mutation 5 14 c.875140A/G 6a Heterozygote Polymorphism 11 15 c.935delA Frameshift 6b Heterozygote Mutation 2 16 c.124811G.A Splice Int 7 Heterozygote Mutation 2 17 c.1285ins TA Frameshift 8 Heterozygote Mutation 4 Homozygote Mutation 2 18 c.1342+196C/T Int 8 Heterozygote Polymorphism 4 Homozygote 2 19 c.1461insAGAT Frameshift 9 Heterozygote Mutation 1 20 c.1525-61A/G 10 Heterozygote Polymorphism 22 21 c.1529C.A/G p.S466X 10 Heterozygote Mutation 1 22 c.1607C.T p.S492F 10 Heterozygote Mutation 3 23 c.1814C.T p.A561E 12 Heterozygote Mutation 1 24 c.189813A.G Splice Int 12 Heterozygote Mutation 1 25 c.18981152T/A Int 12 Heterozygote Polymorphism 5 26 c.1924del 7bp Frameshift 13 Heterozygote Mutation 1 27 c.1949del84 Frameshift 13 Heterozygote Mutation 1 28 c.2055del9toA Frameshift 13 Homozygote Mutation 2 29 c.2105_2117 Frameshift 13 Heterozygote Mutation 4 del13insAGAAA 30 c.2108delA Frameshift 13 Heterozygote Mutation 1 31 c.2184insA Frameshift 13 Heterozygote Mutation 2 32 c.2184delA Frameshift 13 Heterozygote Mutation 1 33 c.2289_2295 Frameshift 13 Heterozygote Mutation 1 del7insGT 34 c.2694T.G p.T854T 14a Heterozygote Polymorphism 10 35 c.2752+12G/C Int 14a Heterozygote Polymorphism 2 36 c.2800C.T p.Q890X 15 Homozygote Mutation 2 37 c.3171delC Frameshift 17a Heterozygote Mutation 1 38 c.3179T>C p.F1016S 17a Heterozygote Mutation 1 39 c.3199del 6bp Frameshift 17a Heterozygote Mutation 1 40 c.3212T.C p.I1027T 17a Heterozygote Mutation 1 41 c.3272-26A.G Splice Int17a Heterozygote Mutation 4 42 c.3271delGG Frameshift 17a Heterozygote Mutation 1 43 c.3313G.C p.G1061R 17b Heterozygote Mutation 1 44 c.3328C.T p.R1066C 17b Heterozygote Mutation 2 45 c.3362T.C p.L1077P 17b Heterozygote Mutation 1 46 c.3431A.C p.Q1100P 17b Heterozygote Mutation 1 47 c.3500-2A>T Splice Int 17b Heterozygote Mutation 1 48 c.3743G.A p.W1204X 19 Heterozygote Mutation 1 Homozygote Mutation 2 49 c.3601-65C/A Int 19 Heterozygote Polymorphism 14 50 c.3863G.A p.G1244E 20 Heterozygote Mutation 3 Table 3.
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ABCC7 p.Ala561Glu 15300780:133:1307
status: NEW
PMID: 17331079
[PubMed]
Alonso MJ et al: "Spectrum of mutations in the CFTR gene in cystic fibrosis patients of Spanish ancestry."
No.
Sentence
Comment
52
Mutation 0.46-0.35 9 c.1078delT #, p.R347P # 8 p.G85V, c.621 + 1G > T #, p.S549R (T > G) #, p.R553X #, c.3849 + 10kbC > T # 7 p.R347H #, c.1812-1G > A, p.R709X 0.30-0.10 6 p.H199Y, p.P205S, 5 p.R117H #, p.G551D #, p.W1089X, p.Y1092X, CFTR50kbdel 4 c.296 + 3insT, c.1717-1G > A #, c.1949del84, c.3849 + 1G > A 3 p.E92K, c.936delTA, c.1717-8G > A, c.1341G > A, p.A561E, c.2603delT, p.G1244E, [p.D1270N; p.R74W] 2 p.Q2X, p.P5L, CFTRdele2,3, p.S50P, p.E60K, c.405 + 1G > A, c.1677delTA, p.L558S, p.G673X, p.R851X, p.Y1014C, p.Q1100P, p.M1101K, p.D1152H, CFTRdele19, p.G1244V, p.Q1281X, p.Y1381X <0,1 1 c.124del23bp, p.Q30X, p.W57X, c.406-1G > A, p.Q98R, p.E115del, c.519delT, p.L159S, c.711 + 3A > T, p.W202X, c.875 + 1G > A, p.E278del, p.W361R, c.1215delG, p.L365P, p.A399D, c.1548delG, p.K536X, p.R560G, c.1782delA, p.L571S, [p.G576A; p.R668C], p.T582R, p.E585X, c.1898 + 1G > A, c.1898 + 3A > G, c.2051delTT, p.E692X, p.R851L, c.2711delT, c.2751 + 3A > G, c.2752-26A > G, p.D924N, p.S945L, c.3121-1G > A, p.V1008D, p.L1065R, [p.R1070W; p.R668C], [p.F1074L; 5T], p.H1085R, p.R1158X, c.3659delC #, c.3667del4, c.3737delA, c.3860ins31, c.3905insT #, c.4005 + 1G > A, p.T1299I, p.E1308X, p.Q1313X, c.4095 + 2T > A, rearrangements study (n = 4) Mutations identified in CF families with mixed European origin: c.182delT, p.L1254X, c.4010del4.
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ABCC7 p.Ala561Glu 17331079:52:361
status: NEW
PMID: 21909392
[PubMed]
Roth EK et al: "The K+ channel opener 1-EBIO potentiates residual function of mutant CFTR in rectal biopsies from cystic fibrosis patients."
No.
Sentence
Comment
46
CFabsent CFresidual CFTR genotype Number of individuals CFTR genotype Number of individuals F508del/F508del 10 F508del/Y161C 1 F508del/W57X 1 F508del/V232D 1 F508del/G85E 3 F508del/R334W 2 F508del/120del23 1 F508del/T338I 1 F508del/182delT 1 F508del/I1234V 1 F508del/G542X 1 F508del/3272-26 A.G 1 F508del/A561E 1 F508del/3849+10 kb C.T 1 F508del/Y1092X 1 F508del/4005 +5727 A.G 1 F508del/N1303K 1 F508del/G576A 1 F508del/1525-1 G.A 2 N1303K/R334W 1 F508del/Q39X 1 F1052V/M1137R 1 F508del/Q552X 1 1898+3 A.G/ 1898+3 A.G 1 G85E/G85E 1 R334W/3199del6 1 Q552X/R1162X 1 R334W/X 1 A561E/A561E 2 dele2,3/X 1 R764X/1717-1 G.A 1 R1158X/2183AA.G 1 R1158X/R560T 1 doi:10.1371/journal.pone.0024445.t001 luminal and basolateral surfaces of the epithelium were perfused continuously with a solution of the following composition (mmol/ L): NaCl 145, KH2PO4 0.4, K2HPO4 1.6, D-glucose 5, MgCl2 1, Ca-gluconate 1.3, pH 7.4, at 37uC.
X
ABCC7 p.Ala561Glu 21909392:46:305
status: NEWX
ABCC7 p.Ala561Glu 21909392:46:575
status: NEWX
ABCC7 p.Ala561Glu 21909392:46:581
status: NEW
PMID: 15480987
[PubMed]
Hirtz S et al: "CFTR Cl- channel function in native human colon correlates with the genotype and phenotype in cystic fibrosis."
No.
Sentence
Comment
78
Relationship Between the CFTR Genotype and Cl- Channel Function in Native Rectal Epithelia CFTR genotype Number of individuals Sweat Cl-concentration (mmol/L)a cAMP-mediated response Carbachol-induced plateau response or maximal lumen-negative response Isc-cAMP (A/cm2) Cl- secretion (% of control) Isc-carbachol (A/cm2) Cl- secretion (% of control) Cl- secretion absent R1162X/Q552X 1 71 17.1 0 0.7 0 W1282X/3121-2AϾG 1 112 1.9 0 0.6 0 1898 ϩ 1G Ͼ T/1609delCA 2b 114, 118 25.4, 13.4 0, 0 0, 0.7 0, 0 ⌬F508/Q39X 2b 127, 129 2.6, 4.4 0, 0 1.7, 3.7 0, 0 ⌬F508/G542X 1 102 29.0 0 6.6 0 ⌬F508/R553X 3 112, 102, 109 13.1, 4.5, 23.8 0, 0, 0 1.5, 4.4, 1.0 0, 0, 0 ⌬F508/E585X 1 115 1.4 0 1.1 0 ⌬F508/Q637X 1 100 2.9 0 1.2 0 ⌬F508/Y1092X 1 119 0.0 0 -0.3 0 ⌬F508/120del23c 1 72 20.1 0 3.3 0 ⌬F508/182delT 1 116 10.8 0 5.2 0 ⌬F508/3905insT 2 88, 96 8.4, 5.6 0, 0 2.3, -1.1 0, 1 ⌬F508/V520F 1 68 1.2 0 1.7 0 ⌬F508/A561E 3 113, 146, 100 17.0, 17.0, 16.0 0, 0, 0 2.1, 1.5, 3.7 0, 0, 0 ⌬F508/R1066C 1 138 0.0 0 0.0 0 ⌬F508/N1303K 3 100, 117, 94 1.7, 4.1, 1.5 0, 0, 0 -0.6, 2.2, 0.8 0, 0, 0 A561E/A561E 2 101, 116 6.6, 2.0 0, 0 7.3, 3.3 0, 0 Residual Cl- secretiond G542X/I148N 1 75 -50.1 54 -22.2 12 1898 ϩ 3A Ͼ G/1898 ϩ 3A Ͼ G 1 82 -36.8 39 -12.9 7 ⌬F508/3272-26A Ͼ G 1 116 -17.8 19 -27.2 14 ⌬F508/S108F 1 118 -15.8 17 -12.3 7 ⌬F508/R117H 1 90 -35.9 38 -207.7 109 ⌬F508/Y161Cc 1 44 -35.1 37 -45.9 25 ⌬F508/P205S 1 80 -23.3 25 -10.4 5 ⌬F508/V232D 1 120 -16.9 18 -26.9 14 ⌬F508/R334W 1 92 -22.1 23 -21.1 11 ⌬F508/R334W 1 101 -24.5 26 -37.4 20 ⌬F508/T338I 1 73 -44.4 47 -79.4 42 ⌬F508/G576A 1 40 -16.9 18 -115.5 61 ⌬F508/I1234V 1 113 -13.6 15 -8.6 5 G576A/G85E 1 95 -26.1 28 -61.6 32 F1052V/M1137R 1 47 -36.7 39 -146.6 77 M1101K/M1101K 1 94 -11.1 12 -4.8 3 S1159F/S1159F 1 67 -47.9 51 -38.7 21 N1303K/R334W 1 91 -30.3 32 -47.7 25 NOTE. CFTR Cl- channel function was determined in rectal epithelia from Cl- secretory responses induced by IBMX/forskolin (Isc-cAMP) and after co-activation with carbachol (Isc-carbachol).
X
ABCC7 p.Ala561Glu 15480987:78:1015
status: NEWX
ABCC7 p.Ala561Glu 15480987:78:1202
status: NEWX
ABCC7 p.Ala561Glu 15480987:78:1208
status: NEW101 Functional Classification and Protein Location of CFTR Mutations Mutation type Severe mutations (protein location) Mild mutations (protein location) Missense V520F, A561E (NBD1) G85E (MSD1, TM1) R1066C (MSD2, CL4) S108F, R117H (MSD1, EL1) N1303K (NBD2) I148N, Y161Ca (MSD1, CL1) P205S (MSD1, TM3) V232D (MSD1, TM4) R334W, T338I (MSD1, TM6) G576A (NBD1) I1234V (NBD2) F1052V, M1101K (MSD2, CL4) M1137R (MSD2, TM12) S1159F (pre-NBD2) Splice 1898 ϩ 1G Ͼ T (R domain) 1898 ϩ 3A Ͼ G (R domain) 3121-2A Ͼ G (MSD2, TM9) 3272-26A Ͼ G (MSD2, TM10) Single amino acid deletion ⌬F508 (NBD1) Nonsense Q39X (N-terminus) G542X, Q552X, R553X, E585X (NBD1) Q637X (R domain) Y1092X (MSD2, CL4) R1162X (pre-NBD2) W1282X (NBD2) Frameshift 120del23a 182delT (N-terminus) 1609delCA (NBD1) 3905insT (NBD2) NOTE. Severe mutation, Cl- secretion absent; mild mutation, residual cAMP-mediated Cl- secretion.
X
ABCC7 p.Ala561Glu 15480987:101:165
status: NEW114 CFTR-mediated Cl- secretion was absent (or below the level of detection) in all CF patients compound heterozygous for class I and II mutations, including ⌬F508, nonsense, frameshift, and missense mutations that result in defective processing (A561E, R1066C, Table 3.
X
ABCC7 p.Ala561Glu 15480987:114:250
status: NEW
PMID: 10923036
[PubMed]
Claustres M et al: "Spectrum of CFTR mutations in cystic fibrosis and in congenital absence of the vas deferens in France."
No.
Sentence
Comment
108
g D44G, 300delA, W57X, 405+1G>A, D110H, E116K, 541del4, 542del7, L137R, 621+2T>G, I175V, H199R, H199Y, C225X, V232D, Q290X, E292X, G314V, T338I, 1221delCT, W401X, Q452P, I502T, 1716+2T>C, G544S, R560S, A561E, V562I, Y569D, 1898+3A>G, 1898+5G>A, G628R(G>A), 2143delT, G673X, R851X, Q890X, S977F, 3129del4, 3154delG, 3271+1G>A, G1061R, R1066L, R1070W, 3601-17T>C, S1196X, 3732delA, G1249R, 3898insC, 4374+1G>A, del25kb.
X
ABCC7 p.Ala561Glu 10923036:108:202
status: NEW
PMID: 9439669
[PubMed]
Casals T et al: "High heterogeneity for cystic fibrosis in Spanish families: 75 mutations account for 90% of chromosomes."
No.
Sentence
Comment
33
Eight mutations have frequencies 366 Table 1 Seventy-five CFTR mutations identified in 640 Spanish families with cystic fibrosis (CF) Mutation Exon/intron CF alleles % ∆F508 E.10 681 53.20 G542X E.11 108 8.43 N1303K E.21 34 2.65 1811+1.6kbA→Ga I.11 24 1.87 711+1G→T I.5 22 1.71 R1162Xa E.19 21 1.64 R334Wa E.7 21 1.64 R1066C E.17b 14 1.09 1609delCAa E.10 13 1.01 Q890X E.15 13 1.01 G85E E.3 12 0.94 712-1G→Ta I.5 11 0.86 2789+5G→A I.14b 11 0.86 ∆I507 E.10 10 0.78 W1282X E.20 10 0.78 2869insGa E.15 9 0.70 L206W E.6a 7 0.54 R709X E.13 7 0.54 621+1G→T I.4 6 0.47 3272-26A→G I.17a 6 0.47 R347H E.7 5 0.39 2183AA→G E.13 5 0.39 K710X E.13 5 0.39 2176insC E.13 5 0.39 3849+10kbC→T I.19 5 0.39 P205Sa E.6a 4 0.31 1078delT E.7 4 0.31 R553X E.11 4 0.31 G551D E.11 4 0.31 1812-1G→Aa I.11 4 0.31 CFdel#1a E.4-7/11-18 4 0.31 V232D E.6a 3 0.23 936delTAa E.6b 3 0.23 1717-8G→A I.10 3 0.23 1949del84 E.13 3 0.23 W1089X E.17b 3 0.23 R347P E.7 3 0.23 del E.3a E.3 2 0.16 R117H E.4 2 0.16 L558S E.11 2 0.16 A561E E.12 2 0.16 2603delT E.13 2 0.16 Y1092X E.17b 2 0.16 Q1100Pa E.17b 2 0.16 M1101K E.17b 2 0.16 delE.19a E.19 2 0.16 G1244E E.20 2 0.16 P5La E.1 1 0.08 Q30Xa E.2 1 0.08 G85Va E.3 1 0.08 E92Ka E.4 1 0.08 A120Ta E.4 1 0.08 I148T E.4 1 0.08 711+3A→Ta I.5 1 0.08 H199Y E.6a 1 0.08 875+1G→A I.6a 1 0.08 Table 1 (continued) Mutation Exon/intron CF alleles % 1717-1G→A I.10 1 0.08 L571S E.12 1 0.08 T582Ra E.12 1 0.08 E585X E.12 1 0.08 1898+3A→G I.12 1 0.08 G673X E.13 1 0.08 E692Xa E.13 1 0.08 R851X E.14a 1 0.08 R851La E.14a 1 0.08 A1006E E.17a 1 0.08 L1065Ra E.17b 1 0.08 F1074La E.17b 1 0.08 R1158X E.19 1 0.08 3667del4a E.19 1 0.08 3860ins31a E.20 1 0.08 3905insT E.20 1 0.08 4005+1G→A I.20 1 0.08 Q1281Xa E.20 1 0.08 Q1313X E.21 1 0.08 Known mutations (75) 1155 90.23 Unknown mutations 125 9.77 a Mutations discovered by the CF group of the Medical and Molecular Genetics Centre - IRO, Barcelona, Spain that range between 0.5% and 0.9%, representing 6.0% of the CF chromosomes.
X
ABCC7 p.Ala561Glu 9439669:33:1074
status: NEW
PMID: 14623323
[PubMed]
Mendes F et al: "Unusually common cystic fibrosis mutation in Portugal encodes a misprocessed protein."
No.
Sentence
Comment
0
Unusually common cystic fibrosis mutation in Portugal encodes a misprocessed protein Filipa Mendes,a M o onica Roxo Rosa,a,c Anca Dragomir,b Carlos M. Farinha,a,c Godfried M. Roomans,b Margarida D. Amaral,a,c and Deborah Penquea,* a Centro de Gen e etica Humana, Instituto Nacional de Sa u ude Dr Ricardo Jorge, Lisboa 1649-016, Portugal b Department of Medical Cell Biology, University of Uppsala, Uppsala, Sweden c Departamento de Qu mica e Bioqu mica, Faculdade de Ci^ e encias, Universidade de Lisboa, Portugal Received 8 October 2003 Abstract A561E, a novel cystic fibrosis (CF) associated mutation in the first nucleotide binding domain of CFTR, is the second most common CF mutation in Portugal.
X
ABCC7 p.Ala561Glu 14623323:0:579
status: NEW1 Properties of the A561E-CFTR protein were studied by immunoblotting, pulse-chase, immunocytochemistry, and MQAE halide-efflux assay in stably transfected BHK cells.
X
ABCC7 p.Ala561Glu 14623323:1:18
status: NEW2 Altogether, results presented here suggest that A561E causes protein mislocalization in the endoplasmic reticulum where the mutant protein must be trapped by the quality control mechanism.
X
ABCC7 p.Ala561Glu 14623323:2:48
status: NEW3 We conclude that A561E originates a protein trafficking defect, thus belonging to class II of CFTR mutations.
X
ABCC7 p.Ala561Glu 14623323:3:17
status: NEW4 As it is the case for F508del-CFTR (the most common CF mutant), low temperature treatment partially rescues a functional A561E-CFTR channel, suggesting that substitution of glutamic acid for alanine at position 561 does not completely abolish CFTR function.
X
ABCC7 p.Ala561Glu 14623323:4:121
status: NEWX
ABCC7 p.Ala561Glu 14623323:4:173
status: NEW5 Pharmacological strategies previously reported for treatment of CF patients with the F508del mutation could thus be also effective in CF patients bearing the A561E mutation.
X
ABCC7 p.Ala561Glu 14623323:5:158
status: NEW7 Keywords: Cystic fibrosis; CFTR; A561E mutation; Classes of CFTR mutations Cystic fibrosis (CF) is a common autosomal recessive inherited disorder in the Caucasian population [1,2].
X
ABCC7 p.Ala561Glu 14623323:7:33
status: NEW12 One of them is the novel CF missense mutation A561E, in which alanine is replaced by glutamic acid at position 561 of the CFTR polypeptide (http://www.genet.sickkids.on.ca/cftr).
X
ABCC7 p.Ala561Glu 14623323:12:46
status: NEW13 The A561E mutation accounts for 3% of Portuguese CF genes, being the second most frequent CF mutation in Portugal.
X
ABCC7 p.Ala561Glu 14623323:13:4
status: NEW26 The aim of the present work was to classify the A561E mutation into one of the functional defect classes of CFTR mutations.
X
ABCC7 p.Ala561Glu 14623323:26:48
status: NEW27 Therefore, we have stably overexpressed A561E CFTR in a heterologous expression system, baby hamster kidney (BHK) cell lines, and analysed them by immunoblotting, pulse-chase, halide sensitive fluorescent dye assay, and immunocytochemistry in order to characterize the molecular mechanism of the A561E mutation.
X
ABCC7 p.Ala561Glu 14623323:27:40
status: NEWX
ABCC7 p.Ala561Glu 14623323:27:296
status: NEW28 The classification of A561E mutation into one of the classes of CFTR mutations will allow a better understanding of the relationship between the functional alterations and disease phenotype and pave the way for designing appropriate pharmacological interventions in CF patients bearing this particular mutation.
X
ABCC7 p.Ala561Glu 14623323:28:22
status: NEW31 A561E mutation was created in pBQ 4.7 using Muta-gene phagemid in vitro mutagenesis Kit (BioRad Laboratories, Hercules, CA, USA) according to manufacturer`s recommendations.
X
ABCC7 p.Ala561Glu 14623323:31:0
status: NEW32 The oligonucleotide 50 -CTTTAGCAAGAGAAG TATACAAAGATGC-30 was used to produce A561E mutation and the mutants were subsequently confirmed by DNA sequence analysis.
X
ABCC7 p.Ala561Glu 14623323:32:77
status: NEW33 Full-length fragment cut off from A561E CFTR cDNA/pBQ4.7 was subcloned into the eukaryotic expression vector pNUT (kindly provided by J. Riordan, Scottsdale, USA).
X
ABCC7 p.Ala561Glu 14623323:33:34
status: NEW35 Baby hamster kidney (BHK) cells were stably transfected with A561E-CFTR pNUT recombinant vector by using DOTAP (Boehringer Mannheim GmbH, Mannheim, Germany) following the manufacturer`s recommendations.
X
ABCC7 p.Ala561Glu 14623323:35:61
status: NEW38 BHK cells stably expressing wild-type (wt)-, F508del-CFTR (both kindly provided by G. Lukacs, Toronto, Canada) or A561E-CFTR were cultivated as described [9,10].
X
ABCC7 p.Ala561Glu 14623323:38:114
status: NEW72 Results A561E-CFTR is a misprocessed protein The A561E mutation was subcloned into the higher eukaryotic expression vector pNUT and the recombinant vector was stably expressed in BHK cell lines.
X
ABCC7 p.Ala561Glu 14623323:72:8
status: NEWX
ABCC7 p.Ala561Glu 14623323:72:49
status: NEW74 Fig. 1A shows the Western blotting of a total protein extract from one of these BHK cell clones stably expressing A561E analysed in parallel with extracts of BHK cells expressing wt- or F508del-CFTR as controls.
X
ABCC7 p.Ala561Glu 14623323:74:114
status: NEW75 Like F508del-CFTR (Fig. 1A, lane 3), A561E-CFTR is only detected as an immature, ER core-glycosylated form of CFTR (band B), of 150 kDa in this heterologous expression cell system (Fig. 1A, lane 4).
X
ABCC7 p.Ala561Glu 14623323:75:37
status: NEW76 No mature complex-glycosylated forms (band C) of 170-180 kDa were detected for A561E-CFTR.
X
ABCC7 p.Ala561Glu 14623323:76:79
status: NEW78 Immunolocalization studies revealed that in contrast to the wt-CFTR, which is essentially detected in the cell membrane (Fig. 2A), A561E-CFTR shows the same prominent ER localization (Fig. 2C) as F508del-CFTR (Fig. 2B).
X
ABCC7 p.Ala561Glu 14623323:78:131
status: NEW79 To assess whether a small amount of A561E-CFTR, below the biochemical and immunocytochemical detection limits, traverses the Golgi to the plasma membrane, we employed the more sensitive single-cell membrane halide permeability assay using the Cl indicator MQAE.
X
ABCC7 p.Ala561Glu 14623323:79:36
status: NEW81 By contrast, no measurable cAMP-stimulated Cl channel activity was detected in cells expressing A561E- or F508del-CFTR (Fig. 3A, middle and lower panels, respectively).
X
ABCC7 p.Ala561Glu 14623323:81:97
status: NEW82 Taken together, these data demonstrate that A561E-CFTR is misprocessed and retained intracellularly, thus failing both to localize correctly and to function at the plasma membrane.
X
ABCC7 p.Ala561Glu 14623323:82:44
status: NEW83 Like F508del, the A561E should thus be included into class II of defective processing CFTR mutations.
X
ABCC7 p.Ala561Glu 14623323:83:18
status: NEW85 Western-blotting analysis of BHK cells stably expressing wt-, F508del- or A561E-CFTR.
X
ABCC7 p.Ala561Glu 14623323:85:74
status: NEW87 Cell lysates were prepared (see Materials and methods) from BHK cells non-transfected (50 lg, lane 1), or stably transfected with wt- (30 lg, lane 2), F508del- (50 lg, lane 2) or A561E-CFTR cDNA cloned into pNUT vector (50 lg, lane 4), and resolved on a 6% SDS-polyacrylamide gel before electrophoretic transfer to nitrocellulose for immunodetection of CFTR, using M3A7 anti-CFTR antibody (1:1000).
X
ABCC7 p.Ala561Glu 14623323:87:179
status: NEW88 The complex-glycosylated forms of CFTR (band C, see arrow) are absent in cells expressing A561E or F508del-CFTR.
X
ABCC7 p.Ala561Glu 14623323:88:90
status: NEW89 (B) Effect of low temperature on the trafficking defect of A561E- and F508del-CFTR.
X
ABCC7 p.Ala561Glu 14623323:89:59
status: NEW90 BHK cells stably expressing F508del- or A561E-CFTR were incubated at 26 &#b0;C for 24 h (100 lg/per lane, lanes 3 and 6, respectively) or for 48 h (100 lg/lane, lanes 4 and 7, respectively) prior to evaluation by Western-blotting (as described in (A)), for the presence of mature or immature A561E- or F508del-CFTR.
X
ABCC7 p.Ala561Glu 14623323:90:40
status: NEWX
ABCC7 p.Ala561Glu 14623323:90:292
status: NEW92 As controls, cell lysates from BHK cells expressing wt- (30 lg, lane 1), F508del- (50 lg, lane 2) or A561E-CFTR (50 lg, lane 5) grown at 37 &#b0;C were also analysed in parallel.
X
ABCC7 p.Ala561Glu 14623323:92:101
status: NEW93 The abundance of complex-glycosylated forms of wt-, F508del-, and A561E-CFTR persisting in the cell (indicated by arrows) was calculated from densitometry of immunoblots.
X
ABCC7 p.Ala561Glu 14623323:93:66
status: NEW95 Immunolocalization of CFTR in BHK cells expressing wt-, F508del-, or A561E-CFTR.
X
ABCC7 p.Ala561Glu 14623323:95:69
status: NEW97 At normal temperature of cell culture (37 &#b0;C), A561E-CFTR (C) is detected strictly in the area around the nuclei of the cells like F508del-CFTR (B); while wt-CFTR (A,D) is predominantly located at the plasma membrane.
X
ABCC7 p.Ala561Glu 14623323:97:51
status: NEW98 At low temperature (26 &#b0;C), some A561E- and F508del-CFTR are rescued to the cell surface (see arrows head in (E) and (F)).
X
ABCC7 p.Ala561Glu 14623323:98:37
status: NEW101 (A) Characteristic records of MQAE fluorescence (thin lines) and corresponding intracellular Cl concentration (thick lines) in BHK cells stably expressing wt-, F508del- or A561E-CFTR.
X
ABCC7 p.Ala561Glu 14623323:101:173
status: NEW104 (B) Effect of low temperature on Cl concentration and efflux in BHK cells stably expressing wt-, F508del- or A561E-CFTR.
X
ABCC7 p.Ala561Glu 14623323:104:110
status: NEW110 The turnover rates of A561E-CFTR are similar to those of F508del-CFTR To study whether A561E-CFTR and F508del-CFTR have the same biogenesis and kinetics degradation, we analysed these two mutants and the wt-protein by pulse-chase technique.
X
ABCC7 p.Ala561Glu 14623323:110:22
status: NEWX
ABCC7 p.Ala561Glu 14623323:110:87
status: NEW113 The newly synthesized immature form of A561E-CFTR migrates with the same molecular mass of wtand F508del-CFTR (Fig. 4A).
X
ABCC7 p.Ala561Glu 14623323:113:39
status: NEW117 Here, we observed the same phenomenon for A561E-CFTR.
X
ABCC7 p.Ala561Glu 14623323:117:42
status: NEW118 Multiple pulse-chase experiments (n &#bc; 3) indicate that the t1=2 of immature core-glycosylated A561E-CFTR was very similar to that of F508del-CFTR, around 40 min, which is slightly lower than that of the wt CFTR in BHK cells as described by Luckas et al. [11,14] (Fig. 4C).
X
ABCC7 p.Ala561Glu 14623323:118:98
status: NEW119 As the immature A561E-CFTR is not converted into band C, its turnover corresponds solely to protein degradation.
X
ABCC7 p.Ala561Glu 14623323:119:16
status: NEW120 Therefore, we suggest that the A561E mutation does not significantly alter the susceptibility to degradation of the newly synthesized protein.
X
ABCC7 p.Ala561Glu 14623323:120:31
status: NEW121 Low temperature partially restores A561E-CFTR trafficking defect Reduced temperature is thought to partially revert the folding defect of F508del-CFTR and thus promote the traffic of functional channels to the cell surface [15-18].
X
ABCC7 p.Ala561Glu 14623323:121:35
status: NEW122 To examine whether the processing defect of A561E-CFTR can be overcome by low temperature treatment, similar to F508del-CFTR, BHK cells overexpressing this mutant were incubated at 26 &#b0;C for 24 or 48 h and analysed by Western blotting (Fig. 1B).
X
ABCC7 p.Ala561Glu 14623323:122:44
status: NEW124 Fig. 1B shows that mature forms of A561E and F508del-CFTR (band C) were readily detected in cells incubated at 26 &#b0;C for 24 and 48 h (lanes 6/7 and 3/4, respectively).
X
ABCC7 p.Ala561Glu 14623323:124:35
status: NEW125 Densitometric analysis revealed that the amount of rescued band C of either A561E or F508del does not increase upon longer incubation (48 h) at 26 &#b0;C.
X
ABCC7 p.Ala561Glu 14623323:125:76
status: NEW127 At low temperature, some A561E-CFTR and F508del-CFTR were also detectable by immunocyto- Fig. 4.
X
ABCC7 p.Ala561Glu 14623323:127:25
status: NEW128 Turnover rates of Wt, F508del- and A561E-CFTR in BHK cells.
X
ABCC7 p.Ala561Glu 14623323:128:35
status: NEW129 (A) Pulse-chase experiments followed by immunoprecipitation of wt-, F508del-, and A561E-CFTR.
X
ABCC7 p.Ala561Glu 14623323:129:82
status: NEW130 F508del- and A561E-CFTR proteins are synthesized as 140 kDa precursors that are very rapidly (t1=2 < 30 min) degraded with no apparent conversion to mature forms (fully glycosylated) in contrast to wt-CFTR.
X
ABCC7 p.Ala561Glu 14623323:130:13
status: NEW131 (B) Quantification of fluorographic data of F508del-CFTR and A561E-CFTR experiments (n &#bc; 3/each).
X
ABCC7 p.Ala561Glu 14623323:131:61
status: NEW133 No significant differences are found between the turnover kinetics of immature forms of both F508del- and A561E-CFTR.
X
ABCC7 p.Ala561Glu 14623323:133:106
status: NEW135 Additionally, the MQAE fluorescence assay also demonstrates that cells expressing A561E- or F508del-CFTR generate cAMP-stimulated Cl efflux after incubation at low temperature for 24 or 48 h (Fig. 3B), albeit to a lesser extent than that observed for wt-CFTR (Fig. 3C).
X
ABCC7 p.Ala561Glu 14623323:135:82
status: NEW137 However, the difference in the amplitude of response to cAMP agonists between the cells expressing wt-CFTR and cells expressing CFTR mutants remains significant, even following growth at low temperature suggesting that low thermal treatment only partially corrects the trafficking defect of both A561E- and F508del-CFTR.
X
ABCC7 p.Ala561Glu 14623323:137:296
status: NEW138 Taken together all data strongly indicate that A561E-CFTR is a temperature-sensitive traffic mutant.
X
ABCC7 p.Ala561Glu 14623323:138:47
status: NEW139 Functional cAMP-stimulated A561E-CFTR Cl channel activity in the plasma membrane can be promoted by reduced temperature treatment.
X
ABCC7 p.Ala561Glu 14623323:139:27
status: NEW140 The substitution of glutamic acid for alanine at position 561 of CFTR does not completely abolish CFTR function once the trafficking defect is corrected.
X
ABCC7 p.Ala561Glu 14623323:140:20
status: NEW145 The novel missense mutation A561E, located in exon 12, is part of a cluster of missense mutations that affect the highly conserved amino acid residues, between the signature (C) and Walker B motifs within the NBD1 of CFTR (Fig. 5).
X
ABCC7 p.Ala561Glu 14623323:145:28
status: NEW146 In Portugal, A561E is the second most frequent CF mutation, accounting for 3% of CF alleles.
X
ABCC7 p.Ala561Glu 14623323:146:13
status: NEW147 To date, 14 patients carrying A561E were identified in Portugal; nine are compound heterozygotes with F508del, one with G542X and four are homozygous for A561E mutation (Pacheco et al., personal communication and manuscript in preparation).
X
ABCC7 p.Ala561Glu 14623323:147:30
status: NEWX
ABCC7 p.Ala561Glu 14623323:147:154
status: NEW149 Functional assessment of native colonic epithelia of patients, including one homozygote for A561E and another compound heterozygote for A561E and F508del, showed that CFTR-mediated Cl secretion is absent in the colon of these patients (Hirtz et al. 2003, submitted for publication) [21].
X
ABCC7 p.Ala561Glu 14623323:149:92
status: NEWX
ABCC7 p.Ala561Glu 14623323:149:136
status: NEW150 In order to explore the molecular mechanism that leads to defective Cl transport in A561E patients we have studied the processing, localization, and function of A561E-CFTR stably overexpressed in BHK cell lines.
X
ABCC7 p.Ala561Glu 14623323:150:85
status: NEWX
ABCC7 p.Ala561Glu 14623323:150:162
status: NEW151 The results presented here clearly demonstrate that A561E has a trafficking defect when heterologously expressed in these cells.
X
ABCC7 p.Ala561Glu 14623323:151:52
status: NEW152 Like F508del, A561E-CFTR is not processed correctly and, as a consequence, is not delivered to the plasma membrane of these cells.
X
ABCC7 p.Ala561Glu 14623323:152:14
status: NEW153 Therefore, A561E mutation belongs to the class II of CFTR mutations.
X
ABCC7 p.Ala561Glu 14623323:153:11
status: NEW154 In BHK cells, A561E-CFTR must not acquire its fully folded native conformation.
X
ABCC7 p.Ala561Glu 14623323:154:14
status: NEW155 Indeed, placing the A561 residue in the homology model of CFTR NBD1, Dorwart et al. [22] recently suggested that this residue is deeply buried in this domain and that the A561E mutation probably disrupts its efficient folding.
X
ABCC7 p.Ala561Glu 14623323:155:171
status: NEW156 The core-glycosylated immature form of A561E-CFTR must thus be retained in the ER by its quality control from where it is degraded.
X
ABCC7 p.Ala561Glu 14623323:156:39
status: NEW157 The properties of A561E-CFTR revert towards those of wt-CFTR as the incubation temperature is reduced to 26 &#b0;C.
X
ABCC7 p.Ala561Glu 14623323:157:18
status: NEW158 When the processing defect is (partially) corrected, functional cAMP-regulated Cl channels appear in the plasma membrane, indicating that A561E mutation does not completely abolish CFTR function.
X
ABCC7 p.Ala561Glu 14623323:158:139
status: NEW159 Based on the results reported here, we hypothesize that A561E-CFTR can be also re-directed to the normal protein trafficking pathway by manipulation of chaperone protein/CFTR interactions, with chemical chaperones or other drugs that affect gene regulation such as genistein and xanthine derivatives [20].
X
ABCC7 p.Ala561Glu 14623323:159:56
status: NEW160 Thus, the pharmacological therapies that have been tried for CF patients bearing F508del could be also useful to those with the A561E mutation.
X
ABCC7 p.Ala561Glu 14623323:160:128
status: NEW162 F508del- and A561E-CFTR mutations in NBD1.
X
ABCC7 p.Ala561Glu 14623323:162:13
status: NEW
PMID: 23891399
[PubMed]
Van Goor F et al: "Effect of ivacaftor on CFTR forms with missense mutations associated with defects in protein processing or function."
No.
Sentence
Comment
44
None M1V A46D E56K P67L R74W G85E E92K D110E D110H R117C R117H E193K L206W R334W I336K T338I S341P R347H R347P R352Q A455E L467P S492F F508del V520F A559T R560S R560T A561E Y569D D579G R668C L927P S945L S977F L997F F1052V H1054D K1060T L1065P R1066C R1066H R1066M A1067T R1070Q R1070W F1074L L1077P H1085R M1101K D1152H S1235R D1270N N1303K 0 100 200 300 400 500 600 * * * CFTR Mutation mRNA (% Normal CFTR) Fig. 1.
X
ABCC7 p.Ala561Glu 23891399:44:167
status: NEW64 Mutant CFTR form CFTR processing Mature/total % Normal CFTR Normal 0.89 &#b1; 0.01 100.0 &#b1; 18.5 G85E -0.05 &#b1; 0.04 -1.0 &#b1; 0.9 R560S 0.00 &#b1; 0.00 0.0 &#b1; 0.0 R1066C 0.02 &#b1; 0.01 0.0 &#b1; 0.0 S492F 0.00 &#b1; 0.00 0.1 &#b1; 0.1 R560T 0.01 &#b1; 0.01 0.2 &#b1; 0.1 V520F 0.05 &#b1; 0.03 0.3 &#b1; 0.2 M1101K 0.05 &#b1; 0.03 0.3 &#b1; 0.1 A561E 0.08 &#b1; 0.04 0.5 &#b1; 0.2 R1066M 0.02 &#b1; 0.02 0.5 &#b1; 0.4 N1303K 0.02 &#b1; 0.02 0.5 &#b1; 0.3 A559T 0.16 &#b1; 0.09 0.6 &#b1; 0.2 M1V 0.06 &#b1; 0.06 0.7 &#b1; 0.6 Y569D 0.11 &#b1; 0.04 0.6 &#b1; 0.2 R1066H 0.08 &#b1; 0.02a 0.7 &#b1; 0.2a L1065P 0.05 &#b1; 0.05 1.0 &#b1; 0.8 L467P 0.10 &#b1; 0.07 1.2 &#b1; 0.8 L1077P 0.08 &#b1; 0.04 1.5 &#b1; 0.6 A46D 0.21 &#b1; 0.08 1.9 &#b1; 0.5a E92K 0.06 &#b1; 0.05 1.9 &#b1; 1.3 H1054D 0.09 &#b1; 0.04 1.9 &#b1; 0.8 F508del 0.09 &#b1; 0.02a 2.3 &#b1; 0.5a H1085R 0.06 &#b1; 0.01a 3.0 &#b1; 0.7a I336K 0.42 &#b1; 0.05a 6.5 &#b1; 0.7a L206W 0.35 &#b1; 0.10a 6.8 &#b1; 1.7a F1074L 0.52 &#b1; 0.03a 10.9 &#b1; 0.6a A455E 0.26 &#b1; 0.10a 11.5 &#b1; 2.5a E56K 0.29 &#b1; 0.04a 12.2 &#b1; 1.5a R347P 0.48 &#b1; 0.04a 14.6 &#b1; 1.8a R1070W 0.61 &#b1; 0.04a 16.3 &#b1; 0.6a P67L 0.36 &#b1; 0.04a 28.4 &#b1; 6.8a R1070Q 0.90 &#b1; 0.01a 29.5 &#b1; 1.4a S977F 0.97 &#b1; 0.01a 37.3 &#b1; 2.4a A1067T 0.78 &#b1; 0.03a 38.6 &#b1; 6.1a D579G 0.72 &#b1; 0.02a 39.3 &#b1; 3.1a D1270N 1.00 &#b1; 0.00a,c 40.7 &#b1; 1.2a S945L 0.65 &#b1; 0.04a 42.4 &#b1; 8.9a L927P 0.89 &#b1; 0.01a,b 43.5 &#b1; 2.5a,b R117C 0.87 &#b1; 0.02a,b 49.1 &#b1; 2.9a,b T338I 0.93 &#b1; 0.03a,b 54.2 &#b1; 3.7a,b L997F 0.90 &#b1; 0.04a,b 59.8 &#b1; 10.4a,b D110H 0.97 &#b1; 0.01a,b 60.6 &#b1; 1.5a,b S341P 0.79 &#b1; 0.02a 65.0 &#b1; 4.9a,b R668C 0.94 &#b1; 0.03a,b 68.5 &#b1; 1.9a,b R74W 0.78 &#b1; 0.01a 69.0 &#b1; 2.7a,b D110E 0.92 &#b1; 0.05a,b 87.5 &#b1; 9.5a,b R334W 0.91 &#b1; 0.05a,b 97.6 &#b1; 10.0a,b K1060T 0.87 &#b1; 0.02a,b 109.9 &#b1; 28.0a,b R347H 0.96 &#b1; 0.02a,c 120.7 &#b1; 2.8a,b S1235R 0.96 &#b1; 0.00a,c 139.0 &#b1; 9.0a,b E193K 0.84 &#b1; 0.02a,b 143.0 &#b1; 17.1a,b R117H 0.86 &#b1; 0.01a,b 164.5 &#b1; 34.2a,b R352Q 0.98 &#b1; 0.01a,b 179.9 &#b1; 8.0a,c F1052V 0.90 &#b1; 0.01a,b 189.9 &#b1; 33.1a,b D1152H 0.96 &#b1; 0.02a,c 312.0 &#b1; 45.5a,b Notes to Table 1: Quantification of steady-state CFTR maturation expressed as the mean (&#b1;SEM; n = 5-9) ratio of mature CFTR to total CFTR (immature plus mature) or level of mature mutant CFTR relative to mature normal-CFTR (% normal CFTR) in FRT cells individually expressing CFTR mutations.
X
ABCC7 p.Ala561Glu 23891399:64:355
status: NEW74 Because the level of CFTR mRNA was similar across the panel of cell lines tested, the range in baseline activity and ivacaftor response likely reflects the severity of the functional defect and/or the 0 50 100 150 200 S341P R347P L467P S492F A559T A561E Y569D L1065P R1066C R1066M L1077P M1101K N1303K R560S L927P R560T H1085R V520F E92K M1V F508del H1054D I336K A46D G85E R334W T338I R1066H R352Q R117C L206W R347H S977F S945L A455E F1074L E56K P67L R1070W D110H D579G D110E R1070Q L997F A1067T E193K R117H R74W K1060T R668C D1270N D1152H S1235R F1052V Baseline With ivacaftor * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * Chloride transport (% Normal) Mutant CFTR form 0 100 200 300 400 S341P R347P L467P S492F A559T A561E Y569D L1065P R1066C R1066M L1077P M1101K N1303K R560S L927P R560T H1085R V520F E92K M1V F508del H1054D I336K A46D G85E R334W T338I R1066H R352Q R117C L206W R347H S977F S945L A455E F1074L P67L E56K R1070W D110H D579G D110E R1070Q L997F A1067T E193K R117H R74W K1060T R668C D1270N D1152H S1235R F1052V * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * Mature CFTR (% Normal) Mutant CFTR form A B Fig. 2.
X
ABCC7 p.Ala561Glu 23891399:74:248
status: NEWX
ABCC7 p.Ala561Glu 23891399:74:741
status: NEW82 Mutation Patientsa Chloride transport (bc;A/cm2 ) Chloride transport (% normal) EC50 Baseline With ivacaftor Baseline With ivacaftor Fold increase over baselineb Normal 204.5 &#b1; 33.3 301.3 &#b1; 33.8c 100.0 &#b1; 16.3 147.3 &#b1; 16.5c 1.5 266 &#b1; 42 G551D 1282 1.5 &#b1; 0.7 113.2 &#b1; 13.0c 1.0 &#b1; 0.5 55.3 &#b1; 6.3c 55.3 312 &#b1; 73 F1052V 12 177.3 &#b1; 13.7 410.2 &#b1; 11.3c 86.7 &#b1; 6.7 200.7 &#b1; 5.6c 2.3 177 &#b1; 14 S1235R ND 160.6 &#b1; 25.7 352.1 &#b1; 43.4c 78.5 &#b1; 12.6 172.2 &#b1; 21.2c 2.2 282 &#b1; 104 D1152H 185 117.3 &#b1; 23.0 282.7 &#b1; 46.9c 57.4 &#b1; 11.2 138.2 &#b1; 22.9c 2.4 178 &#b1; 67 D1270N 32 109.5 &#b1; 20.5 209.5 &#b1; 27.4c 53.6 &#b1; 10.0 102.4 &#b1; 13.4c 1.9 254 &#b1; 56 R668C 45 99.0 &#b1; 9.4 217.6 &#b1; 11.7c 48.4 &#b1; 4.6 106.4 &#b1; 5.7c 2.2 517 &#b1; 105 K1060T ND 89.0 &#b1; 9.8 236.4 &#b1; 20.3c 43.5 &#b1; 4.8 115.6 &#b1; 9.9c 2.7 131 &#b1; 73 R74W 25 86.8 &#b1; 26.9 199.1 &#b1; 16.8c 42.5 &#b1; 13.2 97.3 &#b1; 8.2c 2.3 162 &#b1; 17 R117H 739 67.2 &#b1; 13.3 274.1 &#b1; 32.2c 32.9 &#b1; 6.5 134.0 &#b1; 15.7c 4.1 151 &#b1; 14 E193K ND 62.2 &#b1; 9.8 379.1 &#b1; 1.1c 30.4 &#b1; 4.8 185.4 &#b1; 1.0c 6.1 240 &#b1; 20 A1067T ND 55.9 &#b1; 3.2 164.0 &#b1; 9.7c 27.3 &#b1; 1.6 80.2 &#b1; 4.7c 2.9 317 &#b1; 214 L997F 27 43.7 &#b1; 3.2 145.5 &#b1; 4.0c 21.4 &#b1; 1.6 71.2 &#b1; 2.0c 3.3 162 &#b1; 12 R1070Q 15 42.0 &#b1; 0.8 67.3 &#b1; 2.9c 20.6 &#b1; 0.4 32.9 &#b1; 1.4c 1.6 164 &#b1; 20 D110E ND 23.3 &#b1; 4.7 96.4 &#b1; 15.6c 11.4 &#b1; 2.3 47.1 &#b1; 7.6c 4.1 213 &#b1; 51 D579G 21 21.5 &#b1; 4.1 192.0 &#b1; 18.5c 10.5 &#b1; 2.0 93.9 &#b1; 9.0c 8.9 239 &#b1; 48 D110H 30 18.5 &#b1; 2.2 116.7 &#b1; 11.3c 9.1 &#b1; 1.1 57.1 &#b1; 5.5c 6.2 249 &#b1; 59 R1070W 13 16.6 &#b1; 2.6 102.1 &#b1; 3.1c 8.1 &#b1; 1.3 49.9 &#b1; 1.5c 6.2 158 &#b1; 48 P67L 53 16.0 &#b1; 6.7 88.7 &#b1; 15.7c 7.8 &#b1; 3.3 43.4 &#b1; 7.7c 5.6 195 &#b1; 40 E56K ND 15.8 &#b1; 3.1 63.6 &#b1; 4.4c 7.7 &#b1; 1.5 31.1 &#b1; 2.2c 4.0 123 &#b1; 33 F1074L ND 14.0 &#b1; 3.4 43.5 &#b1; 5.4c 6.9 &#b1; 1.6 21.3 &#b1; 2.6c 3.1 141 &#b1; 19 A455E 120 12.9 &#b1; 2.6 36.4 &#b1; 2.5c 6.3 &#b1; 1.2 17.8 &#b1; 1.2c 2.8 170 &#b1; 44 S945L 63 12.3 &#b1; 3.9 154.9 &#b1; 47.6c 6.0 &#b1; 1.9 75.8 &#b1; 23.3c 12.6 181 &#b1; 36 S977F 9 11.3 &#b1; 6.2 42.5 &#b1; 19.1c 5.5 &#b1; 3.0 20.8 &#b1; 9.3c 3.8 283 &#b1; 36 R347H 65 10.9 &#b1; 3.3 106.3 &#b1; 7.6c 5.3 &#b1; 1.6 52.0 &#b1; 3.7c 9.8 280 &#b1; 35 L206W 81 10.3 &#b1; 1.7 36.4 &#b1; 2.8c 5.0 &#b1; 0.8 17.8 &#b1; 1.4c 3.6 101 &#b1; 13 R117C 61 5.8 &#b1; 1.5 33.7 &#b1; 7.8c 2.9 &#b1; 0.7 16.5 &#b1; 3.8c 5.7 380 &#b1; 136 R352Q 46 5.5 &#b1; 1.0 84.5 &#b1; 7.8c 2.7 &#b1; 0.5 41.3 &#b1; 3.8c 15.2 287 &#b1; 75 R1066H 29 3.0 &#b1; 0.3 8.0 &#b1; 0.8c 1.5 &#b1; 0.1 3.9 &#b1; 0.4c 2.6 390 &#b1; 179 T338I 54 2.9 &#b1; 0.8 16.1 &#b1; 2.4c 1.4 &#b1; 0.4 7.9 &#b1; 1.2c 5.6 334 &#b1; 38 R334W 150 2.6 &#b1; 0.5 10.0 &#b1; 1.4c 1.3 &#b1; 0.2 4.9 &#b1; 0.7c 3.8 259 &#b1; 103 G85E 262 1.6 &#b1; 1.0 1.5 &#b1; 1.2 0.8 &#b1; 0.5 0.7 &#b1; 0.6 NS NS A46D ND 2.0 &#b1; 0.6 1.1 &#b1; 1.1 1.0 &#b1; 0.3 0.5 &#b1; 0.6 NS NS I336K 29 1.8 &#b1; 0.2 7.4 &#b1; 0.1c 0.9 &#b1; 0.1 3.6 &#b1; 0.1c 4 735 &#b1; 204 H1054D ND 1.7 &#b1; 0.3 8.7 &#b1; 0.3c 0.8 &#b1; 0.1 4.2 &#b1; 0.1c 5.3 187 &#b1; 20 F508del 29,018 0.8 &#b1; 0.6 12.1 &#b1; 1.7c 0.4 &#b1; 0.3 5.9 &#b1; 0.8c 14.8 129 &#b1; 38 M1V 9 0.7 &#b1; 1.4 6.5 &#b1; 1.9c 0.4 &#b1; 0.7 3.2 &#b1; 0.9c 8.0 183 &#b1; 85 E92K 14 0.6 &#b1; 0.2 4.3 &#b1; 0.8c 0.3 &#b1; 0.1 2.1 &#b1; 0.4c 7.0 198 &#b1; 46 V520F 58 0.4 &#b1; 0.2 0.5 &#b1; 0.2 0.2 &#b1; 0.1 0.2 &#b1; 0.1 NS NS H1085R ND 0.3 &#b1; 0.2 2.1 &#b1; 0.4 0.2 &#b1; 0.1 1.0 &#b1; 0.2 NS NS R560T 180 0.3 &#b1; 0.3 0.5 &#b1; 0.5 0.1 &#b1; 0.1 0.2 &#b1; 0.2 NS NS L927P 15 0.2 &#b1; 0.1 10.7 &#b1; 1.7c 0.1 &#b1; 0.1 5.2 &#b1; 0.8c 52.0 313 &#b1; 66 R560S ND 0.0 &#b1; 0.1 -0.2 &#b1; 0.2 0.0 &#b1; 0.0 -0.1 &#b1; 0.1 NS NS N1303K 1161 0.0 &#b1; 0.0 1.7 &#b1; 0.3 0.0 &#b1; 0.0 0.8 &#b1; 0.2 NS NS M1101K 79 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 NS NS L1077P 42 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 NS NS R1066M ND 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 NS NS R1066C 100 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 NS NS L1065P 25 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 NS NS Y569D 9 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 NS NS A561E ND 0.0 &#b1; 0.1 0.0 &#b1; 0.1 0.0 &#b1; 0.0 0.0 &#b1; 0.1 NS NS A559T 43 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 NS NS S492F 16 0.0 &#b1; 0.0 1.7 &#b1; 1.2 0.0 &#b1; 0.0 0.8 &#b1; 0.6 NS NS L467P 16 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 NS NS R347P 214 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 0.0 &#b1; 0.0 NS NS S341P 9 0.0 &#b1; 0.0 0.2 &#b1; 0.2 0.0 &#b1; 0.0 0.1 &#b1; 0.1 NS NS a Number of individuals with the individual mutation in the CFTR-2 database (www.CFTR2.org).
X
ABCC7 p.Ala561Glu 23891399:82:4397
status: NEW
PMID: 24932877
[PubMed]
Bell SC et al: "New pharmacological approaches for cystic fibrosis: promises, progress, pitfalls."
No.
Sentence
Comment
493
Class II mutations which besides F508del, include R560T (Roxo-Rosa et al., 2006), A561E (Mendes et al., 2003), R1066C (Seibert et al., 1996) and N1303K (Gregory et al., 1991) amongst others, affect CFTR protein processing due to misfolding which is recognized by endoplasmic reticulum (ER) quality control retention and which targets proteins with abnormal conformations to degradation (Amaral, 2004).
X
ABCC7 p.Ala561Glu 24932877:493:82
status: NEW544 Mutation Alternative name Allele frequency (% of total known) in ECFSPR 2010 Allele frequency (% of total known mutations) in 2010 ECFSPR F508del 64.5 Most frequent mutation worldwide Southeast to Northwest increasing prevalence in Europe IL 25.5 to DK 82.6 Mutations with an overall EU prevalence above 1% G542X Mediterranean mutation 2.5 GR 6.7, ES 6.0 N1303K Ancient Phoenician mutation 1.9 IT 4.2 W1282X Jewish Ashkenazi mutation 1.2 IL 22.4 G551D Celtic mutation 1.1 IE 7.3 1717-1GNA Italian mutation 1.0 IT 3.7 Mutations with an overall EU prevalence below 0.5% G85E PT 3.5 A455E Dutch mutation NL 3.5 CFTR dele 2,3 Slavic mutation CZ 5.2, BY 6.7 394delTT Nordic mutation SE 7.9, DK 2.0 3905insT Swiss mutation CH 2.4 R1162X Italian mutation IT 7.8 A561E Portuguese mutation PT 3.2 Abbreviations ECFSPR - European Cystic Fibrosis Society Patient Registry.
X
ABCC7 p.Ala561Glu 24932877:544:755
status: NEW547 Class Type of defect List of mutations attributed to this class Class I Defective protein production Nonsense mutations: G542X, R1162X, RW1282X Deletions and insertions: CFTRdele2,3; 1078delT; 1717-1G A; 3659delC; 621+1G N T Class II Defective protein processing G85E, F508del, I507del, R560T, A561E, R1066C, N1303K Class III Defective protein regulation (gating) G178R, S549N, S549R, G551D, G551S, G970R, G1244E, S1251N, S1255P, G1349D Class IV Defective protein conductance R334W, R347P, R117H Class V Reduced amount of functioning protein 2789+5G A, 3272-26ANG, 3849+10KbC T, A455E Class VI Reduced cell surface stability Rescued F508del, c.120del23 Unclassified All other mutations, including those unknown a F508del-CFTR pocket (at NBD1:ICL4 interface) (Farinha et al., 2013).
X
ABCC7 p.Ala561Glu 24932877:547:302
status: NEW
PMID: 25287046
[PubMed]
Mornon JP et al: "Full-open and closed CFTR channels, with lateral tunnels from the cytoplasm and an alternative position of the F508 region, as revealed by molecular dynamics."
No.
Sentence
Comment
357
Moreover, a large ''hot spot`` region for natural CFTR mutations is located at the NBD1:ICL4 interface, involving (1) six ICL4 positions (H1054D, G1061R, L1065P, R1066H/R1066C, F1074L, and L1077P), which line the path followed by F508 during the MD1 conformational transition from its initial to its final position, and (2) seven positions in NBD1 (S492F, I507del, F508del, V520F, A559T, R560K/R560T, and A561E) (Fig. 7c).
X
ABCC7 p.Ala561Glu 25287046:357:405
status: NEW
PMID: 26137539
[PubMed]
Awatade NT et al: "Measurements of Functional Responses in Human Primary Lung Cells as a Basis for Personalized Therapy for Cystic Fibrosis."
No.
Sentence
Comment
3
Methods: The effect of lumacaftor was investigated in primary HBE cells from non-CF and CF patients with F508del/F508del, A561E/A561E, N1303K/G542X, F508del/G542X and F508del/Y1092X genotypes by measurements of Forskolin plus Genistein-inducible equivalent short-circuit current (Ieq-SC-Fsk + Gen) in perfused open-circuit Ussing chambers.
X
ABCC7 p.Ala561Glu 26137539:3:122
status: NEWX
ABCC7 p.Ala561Glu 26137539:3:128
status: NEW4 Efficacy of corrector C18 was also assessed on A561E/A561E and F508del/F508del cells.
X
ABCC7 p.Ala561Glu 26137539:4:47
status: NEWX
ABCC7 p.Ala561Glu 26137539:4:53
status: NEW5 Results: Our data indicate that A561E (when present in both alleles) responds positively to lumacaftor treatment at equivalent efficacy of F508del in primary HBE cells. Similarly, lumacaftor has a positive impact on Y1092X, but not on N1303K.
X
ABCC7 p.Ala561Glu 26137539:5:32
status: NEW8 Compound C18 failed to rescue A561E-CFTR but not in F508del-CFTR, thus plausibly it has a different mechanism of action distinct from lumacaftor.
X
ABCC7 p.Ala561Glu 26137539:8:30
status: NEW9 Conclusions: CF patients with A561E (and likely also those with Y1029X) can potentially benefit from lumacaftor.
X
ABCC7 p.Ala561Glu 26137539:9:30
status: NEW34 Mutations tested here include: A561E, quite frequent in Southern-European and South-American countries like in Portugal (Mendes et al., 2003), Spain (Moya-Quiles et al., 2009) and Brazil (Servidoni et al., 2013) and N1303K, linked to ancient Mediterranean populations (Bobadilla et al., 2002).
X
ABCC7 p.Ala561Glu 26137539:34:31
status: NEW36 Our data in primary HBE cells show that lumacaftor rescues A561E at equivalent efficacy of F508del, but N1303K is not significantly rescued.
X
ABCC7 p.Ala561Glu 26137539:36:59
status: NEW38 Compound C18 (lumacaftor analogue, also reported to rescue F508del) failed to rescue A561E-CFTR, thus plausibly rescuing CFTR by a different mechanism of action than lumacaftor.
X
ABCC7 p.Ala561Glu 26137539:38:85
status: NEW39 We conclude that CF patients with the A561E mutation can potentially benefit from lumacaftor and personalized medicine is the way forward to tackle CF.
X
ABCC7 p.Ala561Glu 26137539:39:38
status: NEW42 Culture Conditions of Primary Human Bronchial Epithelial Cells Human lung tissues from CF donors with the F508del/F508del (2 donors), A561E/A561E, N1303K/G542X, F508del/G542X and F508del/ Y1092X genotypes, were obtained from the Cardio-Thoracic Surgery Department (University Hospital la Fe, Valencia, Spain) after receiving patient's written consent and approval by the hospital Ethics Committee.
X
ABCC7 p.Ala561Glu 26137539:42:134
status: NEWX
ABCC7 p.Ala561Glu 26137539:42:140
status: NEW58 Response to lumacaftor for Class II Mutants Assessed by CFTR-Mediated Chloride Secretion The effects of 24 h-treatment with lumacaftor were assessed here by determining CFTR-mediated Cl-secretion in HBE cells from CF donors with the following genotypes (Fig. 1): wt/wt control (a, b); F508del/F508del-Donor 1 (c, d); F508del/F508del-Donor 2 (e, f); A561E/A561E (Fig. 1g, h) and also on the additional genotypes (Fig. 2): N1303K/G542X (a, b), F508del/G542X (c, d); F508del/ Y1092X (e, f).
X
ABCC7 p.Ala561Glu 26137539:58:349
status: NEWX
ABCC7 p.Ala561Glu 26137539:58:355
status: NEW61 These results show that Fsk + Gen responses of F508del/F508del (2 donors), A561E/A561E F508del/G542X and F508del/Y1092X cells after VX-809/lumacaftor treatment were significantly different from those under DMSO, while that of N1303K/G542X cells was not significantly different (Fig. 3b).
X
ABCC7 p.Ala561Glu 26137539:61:75
status: NEWX
ABCC7 p.Ala561Glu 26137539:61:81
status: NEW63 Effect of lumacaftor (VX-809) on cAMP-induced Isc-eq in primary cultures of HBE cells from CF patients with class II mutations. Original Ussing chamber (open-circuit) recordings showing transepithelial voltage measurements (Vte) obtained for CF primary airway HBE monolayers with different CFTR genotypes: wt/wt control (a, b); F508del/F508del-donor 1 (c, d); F508del/F508del-donor 2 (e, f); and A561E/A561E (g, h).
X
ABCC7 p.Ala561Glu 26137539:63:396
status: NEWX
ABCC7 p.Ala561Glu 26137539:63:402
status: NEW69 These data again clearly show a positive effect of VX-809 on HBE cells with genotypes F508del/ F508del (both donors), A561E/A561E, F508del/G542X and F508del/ Y1092X but not on N1303K/G542X cells.
X
ABCC7 p.Ala561Glu 26137539:69:118
status: NEWX
ABCC7 p.Ala561Glu 26137539:69:124
status: NEW83 Original tracings and summary of the effect of C18 in A561E/A561E and F508del/F508del primary HBE cells.
X
ABCC7 p.Ala561Glu 26137539:83:54
status: NEWX
ABCC7 p.Ala561Glu 26137539:83:60
status: NEW84 (a, b) represent original Ussing chamber (open-circuit) recordings obtained for the analysis of CF primary airway HBE monolayers with A561E/A561E and F508del/F508del treated with 5 bc;M C18 for 24 h.
X
ABCC7 p.Ala561Glu 26137539:84:134
status: NEWX
ABCC7 p.Ala561Glu 26137539:84:140
status: NEW88 Response of A561E/A561E HBE Cells to lumacaftor and Compound C18 A561E/A561E HBE cells were also treated with C18 compound, described as a lumacaftor analogue (Eckford et al., 2014).
X
ABCC7 p.Ala561Glu 26137539:88:12
status: NEWX
ABCC7 p.Ala561Glu 26137539:88:18
status: NEWX
ABCC7 p.Ala561Glu 26137539:88:65
status: NEWX
ABCC7 p.Ala561Glu 26137539:88:71
status: NEW89 As demonstrated by the original tracing in Fig. 4a, the responses elicited by either Fsk or Fsk + Gen in A561E/A561E cells pre-incubated with C18 are lower than those in F508del/F508del cells (Fig. 4b) and this difference is statistically different (Fig. 4c).
X
ABCC7 p.Ala561Glu 26137539:89:105
status: NEWX
ABCC7 p.Ala561Glu 26137539:89:111
status: NEW90 Moreover, the response of A561E/ A561E cells after C18 treatment is also significantly lower than that in lumacaftor-treated cells, while those of F508del/F508del cells after C18 and VX-809 are similar (Fig. 1c, Table S4).
X
ABCC7 p.Ala561Glu 26137539:90:26
status: NEWX
ABCC7 p.Ala561Glu 26137539:90:33
status: NEW91 Indeed, the Fold rescue of Ieq-sc-Fsk + Gen in A561E/A561E cells after C18 treatment was 1.93&#d7;, while this value was 6.51&#d7; F508del/F508del cells. Similarly, the percentages of rescue by C18 vs non-CF cells (wt/wt) were ~0.8% and ~5.0% for A561E/A561E F508del/F508del cells, respectively.
X
ABCC7 p.Ala561Glu 26137539:91:47
status: NEWX
ABCC7 p.Ala561Glu 26137539:91:53
status: NEWX
ABCC7 p.Ala561Glu 26137539:91:247
status: NEWX
ABCC7 p.Ala561Glu 26137539:91:253
status: NEW92 These data also indicate that the response of A561/A561E HBE cells to C18 is lower than to lumacaftor, when these cells are stimulated by Gen, but interestingly, not when stimulated only by Fsk.
X
ABCC7 p.Ala561Glu 26137539:92:51
status: NEW93 To confirm these data, Western blot was performed in BHK cells stably expressing F508del or A561E mutant protein.
X
ABCC7 p.Ala561Glu 26137539:93:92
status: NEW94 Data show that VX-809 rescues both F508del and A561E-CFTR, while C18 failed to rescue A561E-CFTR but not in F508del-CFTR protein (Fig. S2).
X
ABCC7 p.Ala561Glu 26137539:94:47
status: NEWX
ABCC7 p.Ala561Glu 26137539:94:86
status: NEW95 These data are thus consistent with those obtained for A561E/A561E cells treated with C18.
X
ABCC7 p.Ala561Glu 26137539:95:55
status: NEWX
ABCC7 p.Ala561Glu 26137539:95:61
status: NEW103 Our data show that the effect of lumacaftor on A561E/A561E HBE cells was equivalent to that of this investigational drug in F508del/ F508del cells.
X
ABCC7 p.Ala561Glu 26137539:103:47
status: NEWX
ABCC7 p.Ala561Glu 26137539:103:53
status: NEW104 Indeed, after the incubation of A561E/A561E cells with 3 bc;M lumacaftor for 24 h, responses obtained in the Ussing chamber were 7-fold higher than when cells were incubated with DMSO-vehicle, representing ~6% of rescue vs non-CF cells.
X
ABCC7 p.Ala561Glu 26137539:104:32
status: NEWX
ABCC7 p.Ala561Glu 26137539:104:38
status: NEW106 These data seem to indicate that the previously characterized trafficking defect of the A561E-CFTR protein (Mendes et al., 2003) can be, as least partially, corrected by lumacaftor.
X
ABCC7 p.Ala561Glu 26137539:106:88
status: NEW107 Interestingly, a previous study showed that A561E-CFTR can be rescued to the cell surface by the same genetic revertants as F508del-CFTR (Roxo-Rosa et al., 2006).
X
ABCC7 p.Ala561Glu 26137539:107:44
status: NEW108 In another more recent study, the A561E-CFTR channel was also described to have similar mechanisms of dysfunction and response to potentiators as F508del-CFTR (Wang et al., 2014).
X
ABCC7 p.Ala561Glu 26137539:108:34
status: NEW111 Our data also lead to the conclusion that the A561E responses to lumacaftor and its analogue C18 do not totally overlap, as observed from the significantly lower Fsk + Gen response of A561E/A561E cells pre-incubated with C18 vs those under lumacaftor.
X
ABCC7 p.Ala561Glu 26137539:111:46
status: NEWX
ABCC7 p.Ala561Glu 26137539:111:184
status: NEWX
ABCC7 p.Ala561Glu 26137539:111:190
status: NEW113 Noticeably, however, the Fsk-response of C18-treated A561E/A561E cells is significantly higher than in the DMSO-treated cells (Fig. 4c).
X
ABCC7 p.Ala561Glu 26137539:113:53
status: NEWX
ABCC7 p.Ala561Glu 26137539:113:59
status: NEW115 Nonetheless, C18 also failed to rescue A561E-CFTR as assessed by Western blot, while VX-809 induces a detectable levels of mature A561E-CFTR (Fig. S2).
X
ABCC7 p.Ala561Glu 26137539:115:39
status: NEWX
ABCC7 p.Ala561Glu 26137539:115:130
status: NEW117 In contrast to the effect on A561E/A561E HBE cells, the magnitude of the response of lumacaftor-treated N1303K/G542X cells was just slightly higher by ~2-fold (both under Fsk and Gen) and not statistically different from that in DMSO-treated cells.
X
ABCC7 p.Ala561Glu 26137539:117:29
status: NEWX
ABCC7 p.Ala561Glu 26137539:117:35
status: NEW120 Firstly, N1303K located in the second nucleotide binding domain (NBD2) of CFTR protein, may cause a different structural defect from that of F508del or A561E, both located in NBD1.
X
ABCC7 p.Ala561Glu 26137539:120:152
status: NEW123 Secondly, it is possible that the response of a single copy of N1303K (the other CFTR allele is G542X, a "null" variant) may be insufficient to observe an effect similar in magnitude to that of A561E/A561E or F508del/F508del cells.
X
ABCC7 p.Ala561Glu 26137539:123:194
status: NEWX
ABCC7 p.Ala561Glu 26137539:123:200
status: NEW130 In conclusion, our data suggest that CF patients bearing the A561E mutation, which is associated with a severe clinical phenotype and quite common in some countries (Mendes et al., 2003), can potentially benefit from lumacaftor treatment.
X
ABCC7 p.Ala561Glu 26137539:130:61
status: NEW
PMID: 26137547
[PubMed]
Becq F et al: "Predicting CFTR activity with front-runner cystic fibrosis drugs."
No.
Sentence
Comment
20
The authors evaluated and compared the efficacy of correctors lumacaftor (VX-809) and its analogue C18 on epithelial cell preparations obtained from donors with different CF genotypes - homozygous for F508del, A561E or heterozygous N1303K/ G542X, F508del/G542X, F508del/Y1092X.
X
ABCC7 p.Ala561Glu 26137547:20:210
status: NEW22 Although they observed great variability in VX-809 responses among patients, they were able to discriminate CFTR mutants positively responding to the correctors such as A561E and Y1092X and those that failed to respond, such as N1303K.
X
ABCC7 p.Ala561Glu 26137547:22:169
status: NEW
admin on 2016-08-19 15:16:22