ABCC7 p.Arg117Pro
| ClinVar: |
c.350G>C
,
p.Arg117Pro
?
, not provided
c.349C>G , p.Arg117Gly ? , not provided c.350G>T , p.Arg117Leu ? , not provided c.349C>T , p.Arg117Cys D , Pathogenic c.350G>A , p.Arg117His D , Pathogenic |
| CF databases: |
c.350G>A
,
p.Arg117His
?
, Varying clinical consequence ; CFTR1:
c.349C>T , p.Arg117Cys D , CF-causing ; CFTR1: The haplotype is 2-1-1-2 (XV2c-KM19-D9-J44) with seven GATT repeats. The mutation creates a new Bsml site. c.349C>G , p.Arg117Gly (CFTR1) ? , Was reported previously in one study of CBAVD. R117G/UND 7T/9T (Daudin et al., Fertility and Sterility, 74:1164-1174, 2000). c.350G>C , p.Arg117Pro (CFTR1) ? , A new missense mutation was found in exon 4 : R 117 P. The mutation was detected by DGGE analysis and identified by remplacement of an arginine residue by a proline at codon 117. The mutation creates new MnlI and NlaIV sites. The mutation was identified in one french CF chromosome. The patient has a mild lung disease and is sufficient pancreatic. c.350G>T , p.Arg117Leu (CFTR1) ? , This mutation was identified by DGGE and direct sequencing and was identified on one CF chromosome of Italian origin. |
| Predicted by SNAP2: | A: D (91%), C: D (63%), D: D (95%), E: D (95%), F: D (91%), G: D (95%), H: N (53%), I: D (85%), K: D (95%), L: D (63%), M: D (85%), N: D (95%), P: D (66%), Q: D (95%), S: D (95%), T: D (95%), V: D (91%), W: D (95%), Y: D (95%), |
| Predicted by PROVEAN: | A: N, C: D, D: N, E: N, F: N, G: N, H: N, I: N, K: N, L: N, M: N, N: N, P: N, Q: N, S: N, T: N, V: N, W: N, Y: N, |
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[hide] Disease-associated mutations in the extracytoplasm... J Biol Chem. 2001 May 4;276(18):14848-54. Epub 2001 Feb 6. Hammerle MM, Aleksandrov AA, Riordan JR
Disease-associated mutations in the extracytoplasmic loops of cystic fibrosis transmembrane conductance regulator do not impede biosynthetic processing but impair chloride channel stability.
J Biol Chem. 2001 May 4;276(18):14848-54. Epub 2001 Feb 6., 2001-05-04 [PMID:11278813]
Abstract [show]
Consistent with its function as a chloride channel regulated entirely from the cytoplasmic side of the plasma membrane, the cystic fibrosis transmembrane conductance regulator (CFTR) glycoprotein exposes little of its mass on the exterior surface of cells. The first and fourth extracytoplasmic loops (ELs) contain approximately 15 and 30 residues, respectively; the other four ELs are extremely short. To examine the influence of missense mutants in ELs detected in patients with cystic fibrosis, we have expressed them in mammalian (baby hamster kidney (BHK21)) cells and assessed their biosynthetic processing and chloride channel activity. In contrast to previous findings that 18 of 30 disease-associated missense mutations in cytoplasmic loops caused retention of the nascent polypeptides in the endoplasmic reticulum, all the EL mutants studied matured and were transported to the cell surface. This pronounced asymmetry is consistent with the notion that endoplasmic reticulum quality control of nascent CFTR is exerted primarily on the cytoplasmic side of the membrane. Although this set of EL mutations has little effect on CFTR maturation, most of them seriously compromise its chloride channel activity. Substitutions at six different positions in EL1 and single positions in EL2 and EL4 all destabilized the open state, some of them severely, indicating that the ELs contribute to the stability of the CFTR ion pore.
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No. Sentence Comment
75 TABLE I Oligonucleotide primers used to generate mutations Mutation Primer S108F GGAAGAATCATAGCTTtCTATGACCCGGATAAC Y109C AGAATCATAGCTTCCTgTGACCCGGATAACAAG D110H ATCATAGCTTCCTATcACCCGGATAACAAGGAG P111A ATAGCTTCCTATGACgCGGATAACAAGGAGGAA P111L ATAGCTTCCTATGACCtGGATAACAAGGAGGAA E116K CCGGATAACAAGGAGaAACGCTCTATCGCGATT R117C GATAACAAGGAGGAAtGCTCTATCGCGATTTAT R117H GATAACAAGGAGGAACaCTCTATCGCGATTTAT R117L GATAACAAGGAGGAACtCTCTATCGCGATTTAT R117P GATAACAAGGAGGAACcCTCTATCGCGATTTAT E217G ATGGGGCTAATCTGGGgGTTGTTACAGGCGTCT T908N TATGCAGTGATTATCAaCAGCACCAGTTCGTAT P1013L GTCGCAGTTTTACAACtCTACATCTTTGTTGCA FIG. 2.
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ABCC7 p.Arg117Pro 11278813:75:435
status: NEW119 C, squares, R117C; circles, R117H; triangles, R117L; diamonds, R117P.
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ABCC7 p.Arg117Pro 11278813:119:63
status: NEW148 R117P also displayed only transient openings.
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ABCC7 p.Arg117Pro 11278813:148:0
status: NEW171 For example a nucleotide binding domain mutation, G551D, precludes virtually all TABLE II Relative charge transport capacity of mutants Mutants S108F Y109C D110H P111L P111A E116K R117H R117C R117L R117P E217G T908N P1013L Imutant/Iwt 100% 11 15 27 173 105 12 80 27 5 11 10 48 170 FIG. 5.
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ABCC7 p.Arg117Pro 11278813:171:198
status: NEW[hide] Pharmacological induction of CFTR function in pati... Pediatr Pulmonol. 2005 Sep;40(3):183-96. Kerem E
Pharmacological induction of CFTR function in patients with cystic fibrosis: mutation-specific therapy.
Pediatr Pulmonol. 2005 Sep;40(3):183-96., [PMID:15880796]
Abstract [show]
CFTR mutations cause defects of CFTR protein production and function by different molecular mechanisms. Mutations can be classified according to the mechanisms by which they disrupt CFTR function. This understanding of the different molecular mechanisms of CFTR dysfunction provides the scientific basis for the development of targeted drugs for mutation-specific therapy of cystic fibrosis (CF). Class I mutations are nonsense mutations that result in the presence of a premature stop codon that leads to the production of unstable mRNA, or the release from the ribosome of a short, truncated protein that is not functional. Aminoglycoside antibiotics can suppress premature termination codons by disrupting translational fidelity and allowing the incorporation of an amino acid, thus permitting translation to continue to the normal termination of the transcript. Class II mutations cause impairment of CFTR processing and folding in the Golgi. As a result, the mutant CFTR is retained in the endoplasmic reticulum (ER) and eventually targeted for degradation by the quality control mechanisms. Chemical and molecular chaperones such as sodium-4-phenylbutyrate can stabilize protein structure, and allow it to escape from degradation in the ER and be transported to the cell membrane. Class III mutations disrupt the function of the regulatory domain. CFTR is resistant to phosphorylation or adenosine tri-phosphate (ATP) binding. CFTR activators such as alkylxanthines (CPX) and the flavonoid genistein can overcome affected ATP binding through direct binding to a nucleotide binding fold. In patients carrying class IV mutations, phosphorylation of CFTR results in reduced chloride transport. Increases in the overall cell surface content of these mutants might overcome the relative reduction in conductance. Alternatively, restoring native chloride pore characteristics pharmacologically might be effective. Activators of CFTR at the plasma membrane may function by promoting CFTR phosphorylation, by blocking CFTR dephosphorylation, by interacting directly with CFTR, and/or by modulation of CFTR protein-protein interactions. Class V mutations affect the splicing machinery and generate both aberrantly and correctly spliced transcripts, the levels of which vary among different patients and among different organs of the same patient. Splicing factors that promote exon inclusion or factors that promote exon skipping can promote increases of correctly spliced transcripts, depending on the molecular defect. Inconsistent results were reported regarding the required level of corrected or mutated CFTR that had to be reached in order to achieve normal function.
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No. Sentence Comment
58 C-D565G II DF508 D1507 S549R S549I S549N S549R S945D S945L H1054D G1061R L1065P R1066C R1066M L1077P H1085R N1303K G85E III G551D S492F V520F R553G R560T R560S Y569D IV R117H, R117C, R117P, R117L D1152H, L88S, G91R, E92K, Q98R, P205S, L206W, L227R, F311L, G314E, R334W, R334Q, I336K, T338I, L346P, R347C, R347H, R347L, R347P, L927P, R1070W, R1070Q V 3849 þ 10 kb C !
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ABCC7 p.Arg117Pro 15880796:58:183
status: NEW[hide] A new complex allele of the CFTR gene partially ex... Genet Med. 2010 Sep;12(9):548-55. Lucarelli M, Narzi L, Pierandrei S, Bruno SM, Stamato A, d'Avanzo M, Strom R, Quattrucci S
A new complex allele of the CFTR gene partially explains the variable phenotype of the L997F mutation.
Genet Med. 2010 Sep;12(9):548-55., [PMID:20706124]
Abstract [show]
PURPOSE: To evaluate the role of complex alleles, with two or more mutations in cis position, of the cystic fibrosis transmembrane conductance regulator (CFTR) gene in the definition of the genotype-phenotype relationship in cystic fibrosis (CF), and to evaluate the functional significance of the highly controversial L997F CFTR mutation. METHODS: We evaluated the diagnosis of CF or CFTR-related disorders in 12 unrelated subjects with highly variable phenotypes. According to a first CFTR mutational analysis, subjects appeared to be compound heterozygotes for a classic mutation and the L997F mutation. A further CFTR mutational analysis was conducted by means of a protocol of extended sequencing, particularly suited to the detection of complex alleles. RESULTS: We detected a new [R117L; L997F] CFTR complex allele in the four subjects with the highest sweat test values and CF. The eight subjects without the complex allele showed the most varied biochemical and clinical outcome and were diagnosed as having mild CF, CFTR-related disorders, or even no disease. CONCLUSIONS: The new complex allele partially explains the variable phenotype in CF subjects with the L997F mutation. CFTR complex alleles are likely to have a role in the definition of the genotype-phenotype relationship in CF. Whenever apparently identical CFTR-mutated genotypes are found in subjects with divergent phenotypes, an extensive mutational search is mandatory.
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No. Sentence Comment
108 Five different CFTR mutations of the 117 CFTR amino acid are known: R117C, R117G, R117H, R117L, and R117P.37 All these mutations have previously been reported to be more likely to cause CFTR-RD than CF.13,37,46,56 However, R117H and R117C have been shown to yield high sweat test values and CF, even severe, if cis-acting with the T5 variant tract in CFTR intron 8.45,46 If we bear in mind that the pH range of airway surface fluid is pH 6.7-7.0,57,58 these mutations of the R117 CFTR residue represent both conservative and nonconservative substitutions.
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ABCC7 p.Arg117Pro 20706124:108:100
status: NEW[hide] Mutations that permit residual CFTR function delay... Respir Res. 2010 Oct 8;11:140. Green DM, McDougal KE, Blackman SM, Sosnay PR, Henderson LB, Naughton KM, Collaco JM, Cutting GR
Mutations that permit residual CFTR function delay acquisition of multiple respiratory pathogens in CF patients.
Respir Res. 2010 Oct 8;11:140., [PMID:20932301]
Abstract [show]
BACKGROUND: Lung infection by various organisms is a characteristic feature of cystic fibrosis (CF). CFTR genotype effects acquisition of Pseudomonas aeruginosa (Pa), however the effect on acquisition of other infectious organisms that frequently precede Pa is relatively unknown. Understanding the role of CFTR in the acquisition of organisms first detected in patients may help guide symptomatic and molecular-based treatment for CF. METHODS: Lung infection, defined as a single positive respiratory tract culture, was assessed for 13 organisms in 1,381 individuals with CF. Subjects were divided by predicted CFTR function: 'Residual': carrying at least one partial function CFTR mutation (class IV or V) and 'Minimal' those who do not carry a partial function mutation. Kaplan-Meier estimates were created to assess CFTR effect on age of acquisition for each organism. Cox proportional hazard models were performed to control for possible cofactors. A separate Cox regression was used to determine whether defining infection with Pa, mucoid Pa or Aspergillus (Asp) using alternative criteria affected the results. The influence of severity of lung disease at the time of acquisition was evaluated using stratified Cox regression methods by lung disease categories. RESULTS: Subjects with 'Minimal' CFTR function had a higher hazard than patients with 'Residual' function for acquisition of 9 of 13 organisms studied (HR ranging from 1.7 to 3.78 based on the organism studied). Subjects with minimal CFTR function acquired infection at a younger age than those with residual function for 12 of 13 organisms (p-values ranging: < 0.001 to 0.017). Minimal CFTR function also associated with younger age of infection when 3 alternative definitions of infection with Pa, mucoid Pa or Asp were employed. Risk of infection is correlated with CFTR function for 8 of 9 organisms in patients with good lung function (>90%ile) but only 1 of 9 organisms in those with poorer lung function (<50%ile). CONCLUSIONS: Residual CFTR function correlates with later onset of respiratory tract infection by a wide spectrum of organisms frequently cultured from CF patients. The protective effect conferred by residual CFTR function is diminished in CF patients with more advanced lung disease.
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No. Sentence Comment
74 For Pa, the hazard ratio Table 1 Classification of CFTR alleles Category Mutation Specific mutations Class I Defective Protein Synthesis (nonsense, frameshift, aberrant splicing) 1078delT, 1154 insTC, 1525-2A > G, 1717-1G > A, 1898+1G > A, 2184delA, 2184 insA, 3007delG, 3120+1G > A, 3659delC, 3876delA, 3905insT, 394delTT, 4010del4, 4016insT, 4326delTC, 4374+1G > T, 441delA, 556delA, 621+1G > T, 621-1G > T, 711+1G > T, 875+1G > C, E1104X, E585X, E60X, E822X, G542X, G551D/R553X, Q493X, Q552X, Q814X, R1066C, R1162X, R553X, V520F, W1282X, Y1092X Class II Abnormal Processing and Trafficking A559T, D979A, ΔF508, ΔI507, G480C, G85E, N1303K, S549I, S549N, S549R Class III Defective Channel Regulation/Gating G1244E, G1349D, G551D, G551S, G85E, H199R, I1072T, I48T, L1077P, R560T, S1255P, S549 (R75Q) Class IV Decreased Channel Conductance A800G, D1152H, D1154G, D614G, delM1140, E822K, G314E, G576A, G622D, G85E, H620Q, I1139V, I1234V, L1335P, M1137V, P67L, R117C, R117P, R117H, R334W, R347H, R347P, R347P/ R347H, R792G, S1251N, V232D Class V Reduced Synthesis and/or Trafficking 2789+5G > A, 3120G > A, 3272-26A > G, 3849+10kbC > T, 5T variant, 621+3A > G, 711+3A > G, A445E, A455E, IVS8 poly T, P574H was increased 3 fold for those with 'Minimal` function when compared to those with 'Residual` function.
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ABCC7 p.Arg117Pro 20932301:74:977
status: NEW[hide] Membrane-integration characteristics of two ABC tr... J Mol Biol. 2009 Apr 17;387(5):1153-64. Epub 2009 Feb 21. Enquist K, Fransson M, Boekel C, Bengtsson I, Geiger K, Lang L, Pettersson A, Johansson S, von Heijne G, Nilsson I
Membrane-integration characteristics of two ABC transporters, CFTR and P-glycoprotein.
J Mol Biol. 2009 Apr 17;387(5):1153-64. Epub 2009 Feb 21., [PMID:19236881]
Abstract [show]
To what extent do corresponding transmembrane helices in related integral membrane proteins have different membrane-insertion characteristics? Here, we compare, side-by-side, the membrane insertion characteristics of the 12 transmembrane helices in the adenosine triphosphate-binding cassette (ABC) transporters, P-glycoprotein (P-gp) and the cystic fibrosis transmembrane conductance regulator (CFTR). Our results show that 10 of the 12 CFTR transmembrane segments can insert independently into the ER membrane. In contrast, only three of the P-gp transmembrane segments are independently stable in the membrane, while the majority depend on the presence of neighboring loops and/or transmembrane segments for efficient insertion. Membrane-insertion characteristics can thus vary widely between related proteins.
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No. Sentence Comment
113 For CFTR, we chose mutations located in TM1CFTR (F87L, G91R), TM3CFTR (P205S, L206W), TM4CFTR (C225R), TM5CFTR (DF311, G314E), TM6CFTR (R334L/W, I336K/R/D, I340N/S, L346P, R347L/H), TM8CFTR (S909I, S912L), TM9CFTR (I1005R, A1006E), TM10CFTR (Y1032N), and TM12CFTR (M1137R, ΔM1140, M1140K), or close to the TM region of TM1CFTR (R74W, L102R/P), TMF2CFTR (R117P/L, L137P), and TM11CFTR (M1101K/R).
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ABCC7 p.Arg117Pro 19236881:113:360
status: NEW109 For CFTR, we chose mutations located in TM1CFTR (F87L, G91R), TM3CFTR (P205S, L206W), TM4CFTR (C225R), TM5CFTR (DF311, G314E), TM6CFTR (R334L/W, I336K/R/D, I340N/S, L346P, R347L/H), TM8CFTR (S909I, S912L), TM9CFTR (I1005R, A1006E), TM10CFTR (Y1032N), and TM12CFTR (M1137R, ƊM1140, M1140K), or close to the TM region of TM1CFTR (R74W, L102R/P), TMF2CFTR (R117P/L, L137P), and TM11CFTR (M1101K/R).
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ABCC7 p.Arg117Pro 19236881:109:359
status: NEW[hide] Newborn screening for cystic fibrosis: Polish 4 ye... Eur J Hum Genet. 2012 Aug 15. doi: 10.1038/ejhg.2012.180. Sobczynska-Tomaszewska A, Oltarzewski M, Czerska K, Wertheim-Tysarowska K, Sands D, Walkowiak J, Bal J, Mazurczak T
Newborn screening for cystic fibrosis: Polish 4 years' experience with CFTR sequencing strategy.
Eur J Hum Genet. 2012 Aug 15. doi: 10.1038/ejhg.2012.180., [PMID:22892530]
Abstract [show]
Newborn screening for cystic fibrosis (NBS CF) in Poland was started in September 2006. Summary from 4 years' experience is presented in this study. The immunoreactive trypsin/DNA sequencing strategy was implemented. The group of 1 212 487 newborns were screened for cystic fibrosis during the programme. We identified a total of 221 CF cases during this period, including, 4 CF cases were reported to be omitted by NBS CF. Disease incidence in Poland based on the programme results was estimated as 1/4394 and carrier frequency as 1/33. The frequency of the F508del was similar (62%) to population data previously reported. This strategy allowed us to identify 29 affected infants with rare genotypes. The frequency of some mutations (eg, 2184insA, K710X) was assessed in Poland for the first time. Thus, sequencing assay seems to be accurate method for screening programme using blood spots in the Polish population.European Journal of Human Genetics advance online publication, 15 August 2012; doi:10.1038/ejhg.2012.180.
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57 Mutations D537N and P731L have not been Period of NBS CF Method The most frequent mutations in Polish population under analysis September 2006 - December 2007 Estonia Asper Biotech assay E60X, G85E, 394delTT, R117H, R117P, R117L, I148T, 621G>A, 711+1G>T, 711+5G>A, 1078delT, R334W, R347H, R347P, R347L, IVS8-T, A455E, I507del, F508del, 1717-1G>A, G542X, p.G551D, Q552X, R553X, R553G, R560T, R560K, 1898+1G>A, 1898+1G>T, 1898+1G>C, 2143delT, 2184delA, 2183AA>G, 2789+5G>A, 3120+1G>A, 3199del6, 3272-26A>G, R1162X, 3659delC, 3849+10kbC>T, 3905insT, S1235R, S1251N, W1282X, W1282C, N1303K, CFTRdele2,3 January 2007 - June 2009 Sanger sequencing of exons: 4, 7, 10, 11, 13, 21, fragment of intron 19 F508del, CFTRdele2,3, 3849+10kbC>T, R117H+IVS8-T*, R334W, R347P, 1717-1G>A, G542X, R553X, K710X, 2184insA, 2143delT, 2183AA>G, N1303K July 2009 - currently Sanger sequencing of exons: 7, 10, 11, 13, 17b, 20, 21, fragment of intron 19 F508del, CFTRdele2,3, 3849+10kbC>T, R334W, R347P, 1717-1G>A, G542X, R553X, K710X, 2184insA, 2143delT, 2183AA>G, N1303K, 3272-26A>G**, W1282X** * removed from DNA analysis since July 2009 , **added into DNA analysis since July 2009 Figure 1 NBS CF in Poland.
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ABCC7 p.Arg117Pro 22892530:57:216
status: NEW[hide] Genotyping microarray for the detection of more th... J Mol Diagn. 2005 Aug;7(3):375-87. Schrijver I, Oitmaa E, Metspalu A, Gardner P
Genotyping microarray for the detection of more than 200 CFTR mutations in ethnically diverse populations.
J Mol Diagn. 2005 Aug;7(3):375-87., [PMID:16049310]
Abstract [show]
Cystic fibrosis (CF), which is due to mutations in the cystic fibrosis transmembrane conductance regulator gene, is a common life-shortening disease. Although CF occurs with the highest incidence in Caucasians, it also occurs in other ethnicities with variable frequency. Recent national guidelines suggest that all couples contemplating pregnancy should be informed of molecular screening for CF carrier status for purposes of genetic counseling. Commercially available CF carrier screening panels offer a limited panel of mutations, however, making them insufficiently sensitive for certain groups within an ethnically diverse population. This discrepancy is even more pronounced when such carrier screening panels are used for diagnostic purposes. By means of arrayed primer extension technology, we have designed a genotyping microarray with 204 probe sites for CF transmembrane conductance regulator gene mutation detection. The arrayed primer extension array, based on a platform technology for disease detection with multiple applications, is a robust, cost-effective, and easily modifiable assay suitable for CF carrier screening and disease detection.
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No. Sentence Comment
51 Complete List of Mutations Detectable with the CF APEX Assay CFTR location Amino acid change Nucleotide change 1 E 1 Frameshift 175delC 2 E 2,3 Frameshift del E2, E3 3 E 2 W19C 189 GϾT 4 E 2 Q39X 247 CϾT 5 IVS 2 Possible splicing defect 296 ϩ 12 TϾC 6 E 3 Frameshift 359insT 7 E 3 Frameshift 394delTT 8 E 3 W57X (TAG) 302GϾA 9 E 3 W57X (TGA) 303GϾA 10 E 3 E60X 310GϾT 11 E 3 P67L 332CϾT 12 E 3 R74Q 353GϾA 13 E 3 R75X 355CϾT 14 E 3 G85E 386GϾA 15 E 3 G91R 403GϾA 16 IVS 3 Splicing defect 405 ϩ 1GϾA 17 IVS 3 Possible splicing defect 405 ϩ 3AϾC 18 IVS 3 Splicing defect 406 - 1GϾA 19 E 4 E92X 406GϾT 20 E 4 E92K 406GϾA 21 E 4 Q98R 425AϾG 22 E 4 Q98P 425AϾC 23 E 4 Frameshift 444delA 24 E 4 Frameshift 457TATϾG 25 E 4 R117C 481CϾT 26 E 4 R117H 482GϾA 27 E 4 R117P 482GϾC 28 E 4 R117L 482GϾT 29 E 4 Y122X 498TϾA 30 E 4 Frameshift 574delA 31 E 4 I148T 575TϾC 32 E 4 Splicing defect 621GϾA 33 IVS 4 Splicing defect 621 ϩ 1GϾT 34 IVS 4 Splicing defect 621 ϩ 3AϾG 35 E 5 Frameshift 624delT 36 E 5 Frameshift 663delT 37 E 5 G178R 664GϾA 38 E 5 Q179K 667CϾA 39 IVS 5 Splicing defect 711 ϩ 1GϾT 40 IVS 5 Splicing defect 711 ϩ 1GϾA 41 IVS 5 Splicing defect 712 - 1GϾT 42 E 6a H199Y 727CϾT 43 E 6a P205S 745CϾT 44 E 6a L206W 749TϾG 45 E 6a Q220X 790CϾT 46 E 6b Frameshift 935delA 47 E 6b Frameshift 936delTA 48 E 6b N287Y 991AϾT 49 IVS 6b Splicing defect 1002 - 3TϾG 50 E 7 ⌬F311 3-bp del between nucleotides 1059 and 1069 51 E 7 Frameshift 1078delT 52 E 7 Frameshift 1119delA 53 E 7 G330X 1120GϾT 54 E 7 R334W 1132CϾT 55 E 7 I336K 1139TϾA 56 E 7 T338I 1145CϾT 57 E 7 Frameshift 1154insTC 58 E 7 Frameshift 1161delC 59 E 7 L346P 1169TϾC 60 E 7 R347H 1172GϾA 61 E 7 R347P 1172GϾC 62 E 7 R347L 1172GϾT 63 E 7 R352Q 1187GϾA 64 E 7 Q359K/T360K 1207CϾA and 1211CϾA 65 E 7 S364P 1222TϾC 66 E 8 Frameshift 1259insA 67 E 8 W401X (TAG) 1334GϾA 68 E 8 W401X (TGA) 1335GϾA 69 IVS 8 Splicing changes 1342 - 6 poly(T) variants 5T/7T/9T 70 IVS 8 Splicing defect 1342 - 2AϾC Table 1. Continued CFTR location Amino acid change Nucleotide change 71 E 9 A455E 1496CϾA 72 E 9 Frameshift 1504delG 73 E 10 G480C 1570GϾT 74 E 10 Q493X 1609CϾT 75 E 10 Frameshift 1609delCA 76 E 10 ⌬I507 3-bp del between nucleotides 1648 and 1653 77 E 10 ⌬F508 3-bp del between nucleotides 1652 and 1655 78 E 10 Frameshift 1677delTA 79 E 10 V520F 1690GϾT 80 E 10 C524X 1704CϾA 81 IVS 10 Possible splicing defect 1717 - 8GϾA 82 IVS 10 Splicing defect 1717 - 1GϾA 83 E 11 G542X 1756GϾT 84 E 11 G551D 1784GϾA 85 E 11 Frameshift 1784delG 86 E 11 S549R (AϾC) 1777AϾC 87 E 11 S549I 1778GϾT 88 E 11 S549N 1778GϾA 89 E 11 S549R (TϾG) 1779TϾG 90 E 11 Q552X 1786CϾT 91 E 11 R553X 1789CϾT 92 E 11 R553G 1789CϾG 93 E 11 R553Q 1790GϾA 94 E 11 L558S 1805TϾC 95 E 11 A559T 1807GϾA 96 E 11 R560T 1811GϾC 97 E 11 R560K 1811GϾA 98 IVS 11 Splicing defect 1811 ϩ 1.6 kb AϾG 99 IVS 11 Splicing defect 1812 - 1GϾA 100 E 12 Y563D 1819TϾG 101 E 12 Y563N 1819TϾA 102 E 12 Frameshift 1833delT 103 E 12 D572N 1846GϾA 104 E 12 P574H 1853CϾA 105 E 12 T582R 1877CϾG 106 E 12 E585X 1885GϾT 107 IVS 12 Splicing defect 1898 ϩ 5GϾT 108 IVS 12 Splicing defect 1898 ϩ 1GϾA 109 IVS 12 Splicing defect 1898 ϩ 1GϾC 110 IVS 12 Splicing defect 1898 ϩ 1GϾT 111 E 13 Frameshift 1924del7 112 E 13 del of 28 amino acids 1949del84 113 E 13 I618T 1985TϾC 114 E 13 Frameshift 2183AAϾG 115 E 13 Frameshift 2043delG 116 E 13 Frameshift 2055del9ϾA 117 E 13 D648V 2075TϾA 118 E 13 Frameshift 2105-2117 del13insAGAA 119 E 13 Frameshift 2108delA 120 E 13 R668C 2134CϾT 121 E 13 Frameshift 2143delT 122 E 13 Frameshift 2176insC 123 E 13 Frameshift 2184delA 124 E 13 Frameshift 2184insA 125 E 13 Q685X 2185CϾT 126 E 13 R709X 2257CϾT 127 E 13 K710X 2260AϾT 128 E 13 Frameshift 2307insA 129 E 13 V754M 2392GϾA 130 E 13 R764X 2422CϾT 131 E 14a W846X 2670GϾA 132 E 14a Frameshift 2734delGinsAT 133 E 14b Frameshift 2766del8 134 IVS 14b Splicing defect 2789 ϩ 5GϾA 135 IVS 14b Splicing defect 2790 - 2AϾG 136 E 15 Q890X 2800CϾT 137 E 15 Frameshift 2869insG 138 E 15 S945L 2966CϾT 139 E 15 Frameshift 2991del32 140 E 16 Splicing defect 3120GϾA interrogation: ACCAACATGTTTTCTTTGATCTTAC 3121-2A3G,T S; 5Ј-ACCAACATGTTTTCTTTGATCTTAC A GTTGTTATTAATTGTGATTGGAGCTATAG-3Ј; CAACAA- TAATTAACACTAACCTCGA 3121-2A3G,T AS.
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ABCC7 p.Arg117Pro 16049310:51:900
status: NEW[hide] Spectrum of CFTR mutations in cystic fibrosis and ... Hum Mutat. 2000;16(2):143-56. Claustres M, Guittard C, Bozon D, Chevalier F, Verlingue C, Ferec C, Girodon E, Cazeneuve C, Bienvenu T, Lalau G, Dumur V, Feldmann D, Bieth E, Blayau M, Clavel C, Creveaux I, Malinge MC, Monnier N, Malzac P, Mittre H, Chomel JC, Bonnefont JP, Iron A, Chery M, Georges MD
Spectrum of CFTR mutations in cystic fibrosis and in congenital absence of the vas deferens in France.
Hum Mutat. 2000;16(2):143-56., [PMID:10923036]
Abstract [show]
We have collated the results of cystic fibrosis (CF) mutation analysis conducted in 19 laboratories in France. We have analyzed 7, 420 CF alleles, demonstrating a total of 310 different mutations including 24 not reported previously, accounting for 93.56% of CF genes. The most common were F508del (67.18%; range 61-80), G542X (2.86%; range 1-6.7%), N1303K (2.10%; range 0.75-4.6%), and 1717-1G>A (1.31%; range 0-2.8%). Only 11 mutations had relative frequencies >0. 4%, 140 mutations were found on a small number of CF alleles (from 29 to two), and 154 were unique. These data show a clear geographical and/or ethnic variation in the distribution of the most common CF mutations. This spectrum of CF mutations, the largest ever reported in one country, has generated 481 different genotypes. We also investigated a cohort of 800 French men with congenital bilateral absence of the vas deferens (CBAVD) and identified a total of 137 different CFTR mutations. Screening for the most common CF defects in addition to assessment for IVS8-5T allowed us to detect two mutations in 47.63% and one in 24.63% of CBAVD patients. In a subset of 327 CBAVD men who were more extensively investigated through the scanning of coding/flanking sequences, 516 of 654 (78. 90%) alleles were identified, with 15.90% and 70.95% of patients carrying one or two mutations, respectively, and only 13.15% without any detectable CFTR abnormality. The distribution of genotypes, classified according to the expected effect of their mutations on CFTR protein, clearly differed between both populations. CF patients had two severe mutations (87.77%) or one severe and one mild/variable mutation (11.33%), whereas CBAVD men had either a severe and a mild/variable (87.89%) or two mild/variable (11.57%) mutations.
Comments [show]
None has been submitted yet.
No. Sentence Comment
109 h M1K, K14X, W19X, 211delG, G27E, R31C, 237insA, 241delAT, Q39X, 244delTA, 296+2T>C, 297-3C>T, W57X+F87L, 306delTAGA, P67L, A72D, 347delC, R75Q, 359insT, 394delT, 405+4A>G, Q98R, 457TAT>G, R117H+5T, R117H+I1027T, R117L, R117P, H139R, A141D, M152V, N186K, D192N, D192del, E193X, 711+1G>A, 711+3A>G, 712-1G>T, L206F, W216X, C225R, Q237E, G241R, 852del22, 876-14del12, 905delG, 993del5, E292K, Y304X, F311del, 1161delC, R347L, R352Q, W361R, 1215delG, S364P, S434X, D443Y, S466X, C491R, T501A, I506T, F508C, I507del+F508C, F508del+L467F, 1774delCT, R553G, 1802delC, 1806delA, A559E, Y563N, 1833delT, Y569C, Y569H, Y569X, G576X, G576A, T582I, 1898+3A>G+186-13C>G, 1918delGC, R600G, L610S, G628R, 2043delG, 2118del4, E664X, 2174insA, Q689X, K698R, K716X, L732X, 2347delG, 2372del8, R764X, 2423delG, S776X, 2634insT, 2640delT, C866Y, 2752-1G>T, W882X, Y913C, V920M, 2896insAG, H939D, H939R, D979V, D985H, D993Y, 3120G>A, I1005R, 3195del6, 3293delA, 3320ins5, W1063X, A1067T, 3359delCT, T1086I, W1089X, Y1092X+S1235R, W1098X, E1104X, R1128X, 3532AC>GTA, 3548TCAT>G, M1140del, 3600G>A, R1162L, 3667ins4, 3732delA+K1200E, S1206X, 3791delC, S1235R+5T, Q1238R, Q1238X, 3849+4A>G, T1246I, 3869insG, S1255P, R1283K, F1286S, 4005+1G>T, 4006-8T>A, 4015delA, N1303H, N1303I, 4172delGC, 4218insT, 4326delTC, Q1382X, 4375-1C>T, 4382delA, D1445N, CF40kbdel4-10, Cfdel17b.
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ABCC7 p.Arg117Pro 10923036:109:220
status: NEW[hide] A comprehensive CFTR mutation analysis of German c... Hum Mol Genet. 1993 Jun;2(6):809-11. Reiss J, Ellermeyer U, Rininsland F, Ballhausen P, Lenz U, Wagner S, Schlosser M
A comprehensive CFTR mutation analysis of German cystic fibrosis patients.
Hum Mol Genet. 1993 Jun;2(6):809-11., [PMID:7689013]
Abstract [show]
Comments [show]
None has been submitted yet.
No. Sentence Comment
12 Since a variety of mutations were reported in exons 4, 17b and 19 (e.g. 10, 4, 5, 11), these exons were chosen for direct sequence analysis. This revealed one novel mutation in exon 4 (R117P) and two novel mutations in exon 17b (E1104X, M1101K).
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ABCC7 p.Arg117Pro 7689013:12:185
status: NEW13 R117P (CGC-CCQ was found in the patient with the G542X allele and confirmed by family analysis. This mutation is the only novel one we have found in the 5' part of the CFTR gene and replaces the same nucleotide as the former described mutation R117H (10).
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ABCC7 p.Arg117Pro 7689013:13:0
status: NEW15 This mechanism cannot be held responsible for the R117P substitution CGC-CCC.
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ABCC7 p.Arg117Pro 7689013:15:50
status: NEW66 Novel CFTR mutations Mutation R117P (CGC-CCQ 2789+5G-A 3121-2A-G M1101K (ATG-AAG) E11O4X (GAA-TAA) 4382ddA Exon 4 14b(a) 17a(b) 17b 17b 24 Ethnic origin German Spanish German German Arabian Italian (a) Splice site mutation downstream of exon 14b.
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ABCC7 p.Arg117Pro 7689013:66:30
status: NEW[hide] Identification and frequencies of cystic fibrosis ... Clin Biochem. 2015 Oct 21. pii: S0009-9120(15)00473-7. doi: 10.1016/j.clinbiochem.2015.10.007. Pepermans X, Mellado S, Chialina S, Wagener M, Gallardo L, Lande H, Bordino W, Baran D, Bours V, Leal T
Identification and frequencies of cystic fibrosis mutations in central Argentina.
Clin Biochem. 2015 Oct 21. pii: S0009-9120(15)00473-7. doi: 10.1016/j.clinbiochem.2015.10.007., [PMID:26500004]
Abstract [show]
Comments [show]
None has been submitted yet.
No. Sentence Comment
99 rs name HGVS p. name HGVS c. name Legacy name n (%) Screening panel CFTR1 database CFTR2 database rs199826652 p.Phe508del c.1521_1523delCTT F508del 94 (56.6) Yes Yes CF-causing rs113993959 p.Gly542* c.1624G N T G542X 7 (4.2) Yes Yes CF-causing No p.Asn1303Lys c.3909C N G N1303K 5 (3) Yes Yes CF-causing rs74767530 p.Arg1162* c.3484C N T R1162X 4 (2.4) Yes Yes CF-causing rs75961395 p.Gly85Glu c.254G N A G85E 3 (1.8) Yes Yes CF-causing rs78756941 NA c.489 + 1G N T 621 + 1G N T 3 (1.8) Yes Yes CF-causing rs76713772 NA c.1585-1G N A 1717-1G N A 3 (1.8) Yes Yes CF-causing No p.Lys684Serfs*38 c.2051_2052delAAinsG 2183AA N G 3 (1.8) Yes Yes CF-causing rs397508173 p.Ser4* c.11C N A S4X 2 (1.2) No Yes No rs121909011 p.Arg334Trp c.1000C N T R334W 2 (1.2) Yes Yes CF-causing rs77010898 p.Trp1282* c.3846G N A W1282X 2 (1.2) Yes Yes CF-causing rs397508141 p.Leu34_Gln39del c.100_117delTTGTCAGACATATACCAA 232del18 1 (0.6) No Yes No No p.Leu49Pro c.146 T N C L49P &#a7; 1 (0.6) No No No rs77834169 p.Arg117Cys c.349C N T R117C 1 (0.6) Yes Yes CF-causing No p.Arg117Pro c.350G N C R117P 1 (0.6) No Yes No rs80282562 p.Gly178Arg c.532G N A G178R 1 (0.6) Yes Yes CF-causing rs121908803 p.Pro205Ser c.613C N T P205S 1 (0.6) No Yes CF-causing rs121908752 p.Leu206Trp c.617 T N G L206W 1 (0.6) Yes Yes CF-causing No p.Arg347Pro c.1040G N C R347P 1 (0.6) Yes Yes CF-causing rs397508155 p.Tyr362* c.1086 T N A Y362X 1 (0.6) No Yes No rs74597325 p.Arg553* c.1657C N T R553X 1 (0.6) Yes Yes CF-causing rs1800098 + rs1800100 p.[Gly576Ala(;)Arg668Cys] c.
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ABCC7 p.Arg117Pro 26500004:99:1054
status: NEWX
ABCC7 p.Arg117Pro 26500004:99:1075
status: NEW126 Genotype N Frequency (%) Total N Total frequency (%) Category I: p.Phe508del/p.Phe508del p.Phe508del/p.Phe508del 30 36.1 30 36.1 Category II: p.Phe508del/Other p.Phe508del/p.Gly542* 5 6 p.Phe508del/p.Asn1303Lys 3 3.6 p.Phe508del/p.Gly85Glu 2 2.4 p.Phe508del/c.1585-1G N A 2 2.4 p.Phe508del/c.2051_2052delAAinsG 2 2.4 p.Phe508del/p.Trp1282* 2 2.4 p.Phe508del/p.Arg117Pro 1 1.2 p.Phe508del/p.Pro205Ser 1 1.2 p.Phe508del/p.Leu206Trp 1 1.2 p.Phe508del/p.Arg553* 1 1.2 p.Phe508del/p.Ser589Ile 1 1.2 p.Phe508del/p.Ser737Phe 1 1.2 p.Phe508del/p.Arg1162* 1 1.2 p.Phe508del/c.1766 + 1G N A 1 1.2 p.Phe508del/p.Leu34_Gln39del 1 1.2 p.Phe508del/p.Leu812Phefs*11 1 1.2 p.Phe508del/c.3140-26A N G 1 1.2 p.Phe508del/c.3873 + 1G N A 1 1.2 p.Phe508del/p.Ser1297Phefs*5 1 1.2 p.Phe508del/c.4242_4242 + 1delGGinsTT 1 1.2 p.Phe508del/c.489 + 1G N T 1 1.2 31 37.5 Category III: Other/other p.Gly542*/p.Asn1303Lys 1 1.2 p.Asn1303Lys/p.Gly85Glu 1 1.2 c.489 + 1G N T/p.Lys684Serfs*38 1 1.2 c.489 + 1G N T/p.Gly542* 1 1.2 p.Arg1162*/p.Ser4* 1 1.2 p.Arg1162*/p.Tyr362* 1 1.2 p.Arg334Trp/c.1585-1G N A 1 1.2 p.Arg334Trp/p.Ser821Argfs*4 1 1.2 p.Arg347Pro/p.Ser4* 1 1.2 c.2657 + 5G N A/p.Tyr852Leufs*44 # 1 1.2 p.Arg1162*/p.Leu49Pro # 1 1.2 11 13.2 Category IV: A single mutation p.Phe508del/WT 3 3.6 c.2988 + 1G N A/WT 1 1.2 p.Arg117Cys/WT 1 1.2 p.Gly178Arg/WT 1 1.2 p.[Gly576Ala(;)Arg668Cys]/TG11-5T 1 1.2 7 8.4 Category V: Wild type 4 4.8 #: new mutation submitted to CFTR1 database [1]; other = other mutation than p.Phe508del.
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ABCC7 p.Arg117Pro 26500004:126:360
status: NEW