ABCC7 p.His620Pro
| ClinVar: |
c.1859A>C
,
p.His620Pro
?
, not provided
c.1860T>G , p.His620Gln ? , not provided |
| CF databases: |
c.1860T>G
,
p.His620Gln
(CFTR1)
D
, The H620Q mutation was identified in a German patient with mild CF and who is heterozygous for this mutation and [delta]F508.
c.1859A>C , p.His620Pro (CFTR1) ? , The above mutation was detected by SSCP and identified by direct DNA sequencing. H620P was found in a 15-year old male CF patient who has mild CF and who is pancreatic sufficient. His parents were unavailable for testing but one is Caucasian and the other is Asian. His mother's mutation is R1158X, which this investigators have seen in one Arabic and one Greek patient. H620P was seen only once in 100 non-[delta]F508 chromosomes screened. |
| Predicted by SNAP2: | A: D (85%), C: D (91%), D: D (85%), E: D (80%), F: D (95%), G: D (85%), I: D (95%), K: D (75%), L: D (91%), M: D (85%), N: D (75%), P: D (71%), Q: D (59%), R: D (85%), S: D (80%), T: D (85%), V: D (85%), W: D (95%), Y: D (91%), |
| Predicted by PROVEAN: | A: D, C: D, D: D, E: N, F: D, G: D, I: D, K: D, L: D, M: D, N: N, P: D, Q: D, R: N, S: D, T: D, V: D, W: D, Y: D, |
[switch to compact view]
Comments [show]
None has been submitted yet.
[hide] Insight in eukaryotic ABC transporter function by ... FEBS Lett. 2006 Feb 13;580(4):1064-84. Epub 2006 Jan 19. Frelet A, Klein M
Insight in eukaryotic ABC transporter function by mutation analysis.
FEBS Lett. 2006 Feb 13;580(4):1064-84. Epub 2006 Jan 19., 2006-02-13 [PMID:16442101]
Abstract [show]
With regard to structure-function relations of ATP-binding cassette (ABC) transporters several intriguing questions are in the spotlight of active research: Why do functional ABC transporters possess two ATP binding and hydrolysis domains together with two ABC signatures and to what extent are the individual nucleotide-binding domains independent or interacting? Where is the substrate-binding site and how is ATP hydrolysis functionally coupled to the transport process itself? Although much progress has been made in the elucidation of the three-dimensional structures of ABC transporters in the last years by several crystallographic studies including novel models for the nucleotide hydrolysis and translocation catalysis, site-directed mutagenesis as well as the identification of natural mutations is still a major tool to evaluate effects of individual amino acids on the overall function of ABC transporters. Apart from alterations in characteristic sequence such as Walker A, Walker B and the ABC signature other parts of ABC proteins were subject to detailed mutagenesis studies including the substrate-binding site or the regulatory domain of CFTR. In this review, we will give a detailed overview of the mutation analysis reported for selected ABC transporters of the ABCB and ABCC subfamilies, namely HsCFTR/ABCC7, HsSUR/ABCC8,9, HsMRP1/ABCC1, HsMRP2/ABCC2, ScYCF1 and P-glycoprotein (Pgp)/MDR1/ABCB1 and their effects on the function of each protein.
Comments [show]
None has been submitted yet.
No. Sentence Comment
295 I601F, L610S, A613T, D614G, I618T, L619S, H620P, G628R and L633P resulted in aberrant processing.
X
ABCC7 p.His620Pro 16442101:295:42
status: NEW[hide] Nucleotide binding domains of human CFTR: a struct... Cell Mol Life Sci. 2005 Sep;62(18):2112-23. Eudes R, Lehn P, Ferec C, Mornon JP, Callebaut I
Nucleotide binding domains of human CFTR: a structural classification of critical residues and disease-causing mutations.
Cell Mol Life Sci. 2005 Sep;62(18):2112-23., [PMID:16132229]
Abstract [show]
Defective function of the cystic fibrosis (CF) transmembrane conductance regulator (CFTR) causes CF, the most frequent lethal inherited disease among the Caucasian population. The structure of this chloride ion channel includes two nucleotide-binding domains (NBDs), whose ATPase activity controls channel gating. Recently, the experimental structures of mouse and human CFTR NBD1 and our model of the human CFTR NBD1/NBD2 heterodimer have provided new insights into specific structural features of the CFTR NBD dimer. In the present work, we provide a structural classification of CF-causing mutations which may complement the existing functional classification. Our analysis also identified amino acid residues which may play a critical role in interdomain interaction and are located at the NBD1-NBD2 interface or on the surface of the dimer. In particular, a cluster of aromatic amino acids, which includes F508 and straddles the two NBDs, might be directly involved in the interaction of the NBD1/NBD2 heterodimer with the channel-forming membrane-spanning domains.
Comments [show]
None has been submitted yet.
No. Sentence Comment
247 (B) Ribbon representation of the NBD aa1 - aa2 segment of the three experimental MalK structures and of mCFTR NBD1, with the CFTR F508 and MalK F98 being shown in atomic details involves the exposed F508 residue, only a few missense mutations affecting these exposed aromatic residues have been reported: H484R, Y515H, H620P, H620Q and Y1307C (http://www.genet.sickkids.on.ca/cftr).
X
ABCC7 p.His620Pro 16132229:247:322
status: NEW[hide] Characterization of 19 disease-associated missense... Hum Mol Genet. 1998 Oct;7(11):1761-9. Vankeerberghen A, Wei L, Jaspers M, Cassiman JJ, Nilius B, Cuppens H
Characterization of 19 disease-associated missense mutations in the regulatory domain of the cystic fibrosis transmembrane conductance regulator.
Hum Mol Genet. 1998 Oct;7(11):1761-9., [PMID:9736778]
Abstract [show]
In order to gain a better insight into the structure and function of the regulatory domain (RD) of the cystic fibrosis transmembrane conductance regulator (CFTR) protein, 19 RD missense mutations that had been identified in patients were functionally characterized. Nine of these (I601F, L610S, A613T, D614G, I618T, L619S, H620P, G628R and L633P) resulted in aberrant processing. No or a very small number of functional CFTR proteins will therefore appear at the cell membrane in cells expressing these mutants. These mutations were clustered in the N-terminal part of the RD, suggesting that this subdomain has a folding pattern that is very sensitive to amino acid changes. Mutations that caused no aberrant processing were further characterized at the electrophysiological level. First, they were studied at the whole cell level in Xenopus laevis oocytes. Mutants that induced a whole cell current that was significantly different from wild-type CFTR were subsequently analysed at the single channel level in COS1 cells transiently expressing the different mutant and wild-type proteins. Three mutant chloride channels, G622D, R792G and E822K CFTR, were characterized by significantly lower intrinsic chloride channel activities compared with wild-type CFTR. Two mutations, H620Q and A800G, resulted in increased intrinsic chloride transport activities. Finally, T665S and E826K CFTR had single channel properties not significantly different from wild-type CFTR.
Comments [show]
None has been submitted yet.
No. Sentence Comment
1 Nine of these (I601F, L610S, A613T, D614G, I618T, L619S, H620P, G628R and L633P) resulted in aberrant processing.
X
ABCC7 p.His620Pro 9736778:1:57
status: NEW66 The mutations that gave rise to a protein that was not able to proceed to the 190 kDa form (I601F, L610S, A613T, D614G, I618T, L619S, H620P, G628R and L633P; Table 2) are therefore class two mutations (17), where the disease phenotype is caused by the absence of sufficient CFTR protein at the cell surface.
X
ABCC7 p.His620Pro 9736778:66:134
status: NEW68 Primers used for mutagenesis Primer Sequence I601F (a1933t) 5'-CTA ACA AAA CTA GGT TTT TGG TCA CTT C-3' L610S (t1961c) 5'-CTA AAA TGG AAC ATT CAA AGA AAG CTG-3' A613T (g1969a) 5'-CAT TTA AAG AAA ACT GAC AAA ATA TTA-3' D614G (a1973g) 5'-CAT TTA AAG AAA GCT GGC AAA ATA TTA A-3' I618T (t1985c) 5'-GAC AAA ATA TTA ACT TTG CAT GAA GG-3' L619S (t1988c) 5'-GAC AAA ATA TTA ATT TCG CAT GAA GGT-3' H620P (a1991c) 5'-CAA AAT ATT AAT TTT GCC TGA AGG TAG C-3' H620Q (t1992g) 5'-AAT ATT AAT TTT GCA GGA AGG TAG CAG-3' G622D (g1997a) 5'-TTG CAT GAA GAT AGC AGC TAT TTT TAT G-3' G628R (g2014c) 5'-GCA GCT ATT TTT ATC GGA CAT TTT C-3' L633P (t2030c) 5'-CAT TTT CAG AAC CCC AAA ATC TAC AGC-3' D648V (a2075t) 5'-CTC ATG GGA TGT GTT TCT TTC GAC C-3' T665S (a2125t) 5'-CAA TCC TAA CTG AGT CCT TAC ACC G-3' F693L (t2209c) 5'-CAG ACT GGA GAG CTT GGG GAA AAA AG-3' R766M (g2429t) 5'-GCA CGA AGG ATG CAG TCT GTC CTG-3' R792G (c2506g) 5'-CAG CAT CCA CAG GAA AAG TGT CAC TG-3' A800G (c2531g) 5'-CTG GCC CCT CAG GGA AAC TTG ACT G-3' I807M (a2553g) 5'-CTG AAC TGG ATA TGT ATT CAA GAA GG-3' E822K (g2596a) 5'-GGC TTG GAA ATA AGT AAA GAA ATT AAC G-3' E826K (g2608a) 5'-GAA GAA ATT AAC AAA GAA GAC TTA AAG-3' Selection primer BstBI 5'-CTC TGG GGT CCG GAA TGA CCG AC-3' Two primers were used for each mutagenesis reaction.
X
ABCC7 p.His620Pro 9736778:68:390
status: NEW77 Mutations detected in patients (I601F, L610S, A613T, D614G, I618T, L619S, H620P, H620Q, D622G, G628R, L633P, T665S, F693L, K698R, V754M, R766M, R792G, A800G, I807M, E822K and E826K) are indicated in bold and underlined, the PKA phosphorylation sites by an arrow and the two acidic domains are boxed.
X
ABCC7 p.His620Pro 9736778:77:74
status: NEW87 Maturation pattern of RD mutations and their associated phenotype found in patients with the indicated genotype (when the mutation is associated with CF, only the pancreas status is given) Mutation A-form B-form C-form Clinical data Genotype Phenotype Reference I601F + + - I601F/G542X PS M. Schwarz, personal communication L610S + + - Unknown Unknown A613T + + - Unknown Unknown D614G + + - D614G/unknown PI 14 I618T + + - I618T/dF508 PS G.R. Cutting, personal communication L619S + + - L619S/unknown PI B. Tümmler, personal communication H620P + + - H620P/R1158X PS M. Schwarz, personal communication H620Q + + + H620Q/dF508 PI T. Dörk, personal communication G622D + + + G622D/unknown Oligospermia J. Zielenski, personal communication G628R + + - Unknown Unknown L633P + + - L633P/3659delC M. Schwarz, personal communication D648V + + + D648V/3849+10kb C/T PI C. Ferec, personal communication T665S + + + Unknown Unknown F693L + + + F693L/W1282X Healthy C. Ferec; CF Genetic Analysis Consortium R766M + + + R766M/R792G CBAVD D. Glavac, personal communication R792G + + + R766M/R792G CBAVD D. Glavac, personal communication A800G + + + A800G/unknown CBAVD 34 I807M + + + I807M/unknown CBAVD Our observation E822K + + + E822K/unknown PI 35 E826K + + + E826K/unknown Thoracic sarcoidosis C. Bombieri, personal communication +, the protein matures up to that form; -, the protein does not reach the respective maturation step.
X
ABCC7 p.His620Pro 9736778:87:545
status: NEWX
ABCC7 p.His620Pro 9736778:87:557
status: NEW109 Nine mutations caused aberrant processing: I601F, L610S, A613T, D614G, I618T, L619S, H620P, G628R and L633P.
X
ABCC7 p.His620Pro 9736778:109:85
status: NEW[hide] Conformational changes relevant to channel activit... J Biol Chem. 2012 Aug 17;287(34):28480-94. doi: 10.1074/jbc.M112.371138. Epub 2012 Jun 21. Hudson RP, Chong PA, Protasevich II, Vernon R, Noy E, Bihler H, An JL, Kalid O, Sela-Culang I, Mense M, Senderowitz H, Brouillette CG, Forman-Kay JD
Conformational changes relevant to channel activity and folding within the first nucleotide binding domain of the cystic fibrosis transmembrane conductance regulator.
J Biol Chem. 2012 Aug 17;287(34):28480-94. doi: 10.1074/jbc.M112.371138. Epub 2012 Jun 21., [PMID:22722932]
Abstract [show]
Deletion of Phe-508 (F508del) in the first nucleotide binding domain (NBD1) of the cystic fibrosis transmembrane conductance regulator (CFTR) leads to defects in folding and channel gating. NMR data on human F508del NBD1 indicate that an H620Q mutant, shown to increase channel open probability, and the dual corrector/potentiator CFFT-001 similarly disrupt interactions between beta-strands S3, S9, and S10 and the C-terminal helices H8 and H9, shifting a preexisting conformational equilibrium from helix to coil. CFFT-001 appears to interact with beta-strands S3/S9/S10, consistent with docking simulations. Decreases in T(m) from differential scanning calorimetry with H620Q or CFFT-001 suggest direct compound binding to a less thermostable state of NBD1. We hypothesize that, in full-length CFTR, shifting the conformational equilibrium to reduce H8/H9 interactions with the uniquely conserved strands S9/S10 facilitates release of the regulatory region from the NBD dimerization interface to promote dimerization and thereby increase channel open probability. These studies enabled by our NMR assignments for F508del NBD1 provide a window into the conformational fluctuations within CFTR that may regulate function and contribute to folding energetics.
Comments [show]
None has been submitted yet.
No. Sentence Comment
285 Because the H620Q variant displays additional peak shifts relative to those observed for compound binding, there are certainly other consequences of the mutation.
X
ABCC7 p.His620Pro 22722932:285:57
status: NEW287 Although H620Q does not affect maturation/processing, an H620P mutation does, highlighting the importance of this position and the nature of the residue in it.
X
ABCC7 p.His620Pro 22722932:287:57
status: NEW[hide] Definition of a "functional R domain" of the cysti... Mol Genet Metab. 2000 Sep-Oct;71(1-2):245-9. Chen JM, Scotet V, Ferec C
Definition of a "functional R domain" of the cystic fibrosis transmembrane conductance regulator.
Mol Genet Metab. 2000 Sep-Oct;71(1-2):245-9., [PMID:11001817]
Abstract [show]
The R domain of the cystic fibrosis transmembrane conductance regulator (CFTR) was originally defined as 241 amino acids, encoded by exon 13. Such exon/intron boundaries provide a convenient way to define the R domain, but do not necessarily reflect the corresponding functional domain within CFTR. A two-domain model was later proposed based on a comparison of the R-domain sequences from 10 species. While RD1, the N-terminal third of the R domain is highly conserved, RD2, the large central region of the R domain has less rigid structural requirements. Although this two-domain model was given strong support by recent functional analysis data, the simple observation that two of the four main phosphorylation sites are excluded from RD2 clearly indicates that RD2 still does not satisfy the requirements of a "functional R domain." Nevertheless, knowledge of the CFTR structure and function accumulated over the past decade and reevaluated in the context of a comprehensive sequence comparison of 15 CFTR homologues made it possible to define such a "functional R domain," i.e., amino acids C647 to D836. This definition is validated primarily because it contains all of the important potential consensus phosphorylation sequences. In addition, it includes the highly charged motif from E822 to D836. Finally, it includes all of the deletions/insertions in this region. This definition also aids in understanding the effects of missense mutations occurring within this domain.
Comments [show]
None has been submitted yet.
No. Sentence Comment
30 Second, while I601F, L610S, A613T, D614G, I618T, L619S, H620P, G628R, and L633P resulted in aberrant processing, neither D648V or T665S caused an arrest in protein maturation (8).
X
ABCC7 p.His620Pro 11001817:30:56
status: NEW[hide] CFTR mutations spectrum and the efficiency of mole... PLoS One. 2014 Feb 26;9(2):e89094. doi: 10.1371/journal.pone.0089094. eCollection 2014. Zietkiewicz E, Rutkiewicz E, Pogorzelski A, Klimek B, Voelkel K, Witt M
CFTR mutations spectrum and the efficiency of molecular diagnostics in Polish cystic fibrosis patients.
PLoS One. 2014 Feb 26;9(2):e89094. doi: 10.1371/journal.pone.0089094. eCollection 2014., [PMID:24586523]
Abstract [show]
Cystic fibrosis (CF) is caused by mutations in the cystic fibrosis transmembrane regulator gene (CFTR). In light of the strong allelic heterogeneity and regional specificity of the mutation spectrum, the strategy of molecular diagnostics and counseling in CF requires genetic tests to reflect the frequency profile characteristic for a given population. The goal of the study was to provide an updated comprehensive estimation of the distribution of CFTR mutations in Polish CF patients and to assess the effectiveness of INNOLiPA_CFTR tests in Polish population. The analyzed cohort consisted of 738 patients with the clinically confirmed CF diagnosis, prescreened for molecular defects using INNOLiPA_CFTR panels from Innogenetics. A combined efficiency of INNOLiPA CFTR_19 and CFTR_17_TnUpdate tests was 75.5%; both mutations were detected in 68.2%, and one mutation in 14.8% of the affected individuals. The group composed of all the patients with only one or with no mutation detected (109 and 126 individuals, respectively) was analyzed further using a mutation screening approach, i.e. SSCP/HD (single strand conformational polymorphism/heteroduplex) analysis of PCR products followed by sequencing of the coding sequence. As a result, 53 more mutations were found in 97 patients. The overall efficiency of the CF allele detection was 82.5% (7.0% increase compared to INNOLiPA tests alone). The distribution of the most frequent mutations in Poland was assessed. Most of the mutations repetitively found in Polish patients had been previously described in other European populations. The most frequent mutated allele, F508del, represented 54.5% of Polish CF chromosomes. Another eight mutations had frequencies over 1%, 24 had frequencies between 1 and 0.1%; c.2052-2053insA and c.3468+2_3468+3insT were the most frequent non-INNOLiPA mutations. Mutation distribution described herein is also relevant to the Polish diaspora. Our study also demonstrates that the reported efficiency of mutation detection strongly depends on the diagnostic experience of referring health centers.
Comments [show]
None has been submitted yet.
No. Sentence Comment
71 Exon / intron (legacy) Exon / intron (Ensembl) Protein change SVM value cDNA (HGVS nomenclature) gDNA (cDNA +132 bp) Number of PL CF chromosomes Reference a Mutations in trans Pathogenic mutations 1 1 L15Ffs10X c.43delC 175delC 1 CFMDB 1717-1G.A 2 2 G27V 21.92 c.80G.T 212G.T 1 Novel F508del 2 2 S18RfsX16 c.54-5940_273 +10250del21kb exon2,3del21kb 66 IL19 various CF mutations i2 i2 IVS2_Donor c.164+1G.A 296+1G.A 3 CFMDB various CF mutations 3 3 G85E 22.61 c.254G.A 386G.A 1 IL17 unknown 3 3 E60X c.178G.T 310G.T 0 IL17 x 3 3 L88IfsX22 c.262_263delTT 394delTT 0 IL17 x 4 4 E92K 21.92 c.274G.A 406G.A 2 CFMDB c.164+1G.A; c.2051- 2AA.G 4 4 L101X c.302T.G 434T.G 1 CFMDB c.3717+12191C.T 4 4 K114IfsX5 c.341_353del13bp 473del13bp 1 Novel F508del 4 4 R117H 20.35 c.350G.A 482G.A 5 IL17 F508del; 2x unknown 4 4 R117C 22.07 c.349C.T 481C.T 2 CFMDB S1206X;1x unknown 4 4 L137_L138insT c.412_413insACT L138ins 1 CFMDB F508del 4 4 R153I 22.61 c.458G.T 590G.T 2 Novel F508del; c.3527delC i4 i4 IVS4_Donor c.489+1G.T 621+1G.T 5 IL17 F508del; c.489+1G.T 5 5 L165X c.494T.A 626T.A 1 Novel F508del i5 i5 IVS5_Donor c.579+1G.T 711+1G.T 0 IL19 x i5 i5 IVS5_Donor c.579+3A.G 711+3A.G 2 CFMDB 2,3del21kb; c.2052-3insA i5 i5 IVS5_Donor c.579+5G.A 711+5G.A 0 IL17 x 7 8 F311L 20.90 c.933C.G 965C.G 2 CFMDB 2x F508 7 8 G314R 20.58 c.940G.A 1072G.A 4 CFMDB various CF mutations 7 8 F316LfsX12 c.948delT 1078delT 1 IL17 unkown 7 8 R334W 22.41 c.1000C.T 1132C.T 6 IL17 various CF mutations 7 8 I336K 22.07 c.1007T.A 1139T.A 2 CFMDB 2,3de21kb; F508del 7 8 R347P 22.27 c.1040G.C 1172G.C 11 IL17 various CF mutations i7 i8 IVS8_Donor c.1116+2T.A 1248+2T.A 1 Novel Q1412X 9 10 A455E 22.61 c.1364C.A 1496C.A 0 IL17 x i9 i10 IVS10_Donor c.1392+1G.A 1524+1G.A 1 CFMDB c.3816-7delGT 10 11 S466X c.1397C.G 1529C.G 1 CFMDB G542X 10 11 I507del c.1519_1521delATC 1651delATC 2 IL19 F508del 10 11 F508del c.1521_1523delCTT 1654delCTT 805 IL19 various CF mutations i10 i11 IVS11_Acceptor c.1585-1G.A 1717-1G.A 27 IL19 various CF mutations 11 12 G542X c.1624G.T 1756G.T 25 IL19 various CF mutations 11 12 G551D 21.24 c.1624G.T 1756G.T 5 IL19 various CF mutations 11 12 Q552X c.1654C.T 1786C.T 0 IL19 x 11 12 R553X c.1657C.T 1789C.T 14 IL19 various CF mutations 11 12 R560T 21.92 c.1679G.C 1811G.C 0 IL19 x i12 i13 IVS13_Donor c.1766+1G.A 1898+1G.A 6 IL19 various CF mutations i12 i13 IVS13_Donor c.1766+1G.C 1898+1G.C 1 CFMDB F508del 13 14 H620P 21.73 c.1859A.C 1991A.C 1 CFMDB F508del 13 14 R668C//G576A 21.61//1.73 c.2002C.T//c.1727G.C 2134C.T// 1859G.C 5 b CFMDB// rs1800098 c.1585-1G.A; 4 unknown 13 14 L671X c.2012delT 2143delT 27 IL17 various CF mutations 13 14 K684SfsX38 c.2051_2052delAAinsG 2183AA.G 10 IL17 various CF mutations 13 14 K684NfsX38 c.2052delA 2184delA 0 IL17 x 13 14 Q685TfsX4 c.2052_2053insA 2184insA 15 CFMDB various CF mutationsc , 1 unknown Table 2. Cont. Exon / intron (legacy) Exon / intron (Ensembl) Protein change SVM value cDNA (HGVS nomenclature) gDNA (cDNA +132 bp) Number of PL CF chromosomes Reference a Mutations in trans 13 14 L732X c.2195T.G 2327T.G 1 CFMDB F508del 14A 15 R851X c.2551C.T 2683C.T 3 CFMDB various CF mutations 14A 15 I864SfsX28 c.2589_2599del11bp 2721del11bp 2 CFMDB F508del; 2,3del21kb i14B i16 IVS16_Donor c.2657+2_2657+3insA 2789+2insA 1 CFMDB F508del i14B i16 IVS16_Donor c.2657+5G.A 2789+5G.A 0 IL17 unkown 15 17 Y919C 21.02 c.2756A.G 2888A.G 1 CFMDB unknown 15 17 H939HfsX27 c.2817_2820delTACTC 2949delTACTC 1 Novel unkown i15 i17 IVS17_Donor c.2908+3A.C 3040+3A.C 1 Novel F508del i16 i18 IVS18_Donor c.2988+1G.A 3120+1G.A 0 IL19 x 17A 19 I1023_V1024del c.3067_3072delATAGTG 3199del6 0 IL19 x i17A i19 IVS19 c.3140-26A.G 3272-26A.G 9 IL19 various CF mutations 17B 20 L1065R 21.90 c.3194T.G 3326T.G 1 CFMDB F508del 17B 20 Y1092X c.3276C.A 3408C.A 1 CFMDB R334W i18 i21 IVS21_Donor c.3468+2_3468+3insT 3600+2insT 11 CFMDB various CF mutationsd , 1 unknown 18 21 E1126EfsX7 c.3376_3379delGAAG 3508delGAAG 1 Novel F508del 19 22 R1158X c.3472C.T 3604C.T 2 CFMDB F508del; R553X 19 22 R1162X c.3484C.T 3616C.T 1 IL17 F508del 19 22 L1177SfsX15 c.3528delC 3659delC 4 IL17 various CF mutations 19 22 S1206X c.3617C.A 3749C.A 1 CFMDB R117C i19 i22 IVS22 c.3717+12191C.T 3849+10kbC.T 58 IL17 various CF mutations 20 23 G1244R 22.62 c.3730G.C 3862G.C 1 CFMDB F508del 20 23 S1251N 22.28 c.3752G.A 3884G.A 0 IL19 x 20 23 L1258FfsX7 c.3773_3774insT 3905insT 0 IL19 x 20 23 V1272VfsX28 c.3816_3817delGT 3944delGT 1 CFMDB c.1392+1G.A 20 23 W1282X c.3846G.A 3978G.A 9 IL19 various CF mutations 21 24 N1303K 22.62 c.3909C.G 4041C.G 18 IL19 various CF mutations 22 25 V1327X c.3979delG 4111delG 1 Novel F508del 22 25 S1347PfsX13 c.4035_4038dupCCTA c.4167dupCCTA 1 CFMDB 2,3del21kb 23 26 Q1382X c.4144C.T 4276C.T 1 CFMDB F508del 23 26 Q1412X c.4234C.T 4366C.T 2 CFMDB F508del; c.1116+2T.A i23 i26 IVS26_Donor c.4242+1G.T 4374+1G.T 1 CFMDB F508del Sequence changes of uncertain pathogenic effect, tentatively counted as mutations 6A 6 E217G 0.30 c.650A.G 782A.G 1 CFMDB; rs1219109046 unknown 7 8 R352Q 20.01 c.1055G.A 1187G.A 1 CFMDB; rs121908753 F508del 7 8 Q359R 0.33 c.1076A.G 1208A.G 1 CFMDB F508del i8 i9 IVS9 c.1210-12T5_1210- 34_35 (TG)12 1332-12Tn_- 34TGm 6 CFMDB F508del; 3x unknown i8 i9 IVS9 c.1210-12T5_1210- 34_35 (TG)13 1332-12Tn_- 34TGm 2 CFMDB 2143delT; 1x unknown i8 i9 IVS9 c.1210-12T8 1332-12Tn 1 Novel unknown 10 11 I506V 20.21 c.1516A.G 1648A.G 1 CFMDB; rs1800091 unknown 12 13 V562L 0.79 c.1684G.C 1816G.C 1 CFMDB; rs1800097 unknown 13 14 G723V 0.44 c.2168G.T 2300G.T 1 CFMDB; rs200531709 unknown 15 17 D924N 0.03 c.2770G.A 2902G.A 1 CFMDB; rs201759207 unknown patient with F508del on another allele) was not supported by the SVM value (+0.35); the patient was PS and had ambiguous chloride values (45, 64 and 83 mmol/L).
X
ABCC7 p.His620Pro 24586523:71:2401
status: NEW