ABCC2 p.Thr1273Ala
| Predicted by SNAP2: | A: N (66%), C: D (59%), D: N (53%), E: D (59%), F: D (75%), G: N (53%), H: D (53%), I: D (66%), K: N (53%), L: D (80%), M: D (59%), N: N (61%), P: D (80%), Q: D (53%), R: D (63%), S: N (78%), V: D (63%), W: D (80%), Y: D (71%), |
| Predicted by PROVEAN: | A: N, C: N, D: N, E: N, F: N, G: N, H: N, I: N, K: N, L: N, M: N, N: N, P: N, Q: N, R: N, S: N, V: N, W: N, Y: N, |
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[hide] Pharmacogenomics of MRP transporters (ABCC1-5) and... Drug Metab Rev. 2008;40(2):317-54. Gradhand U, Kim RB
Pharmacogenomics of MRP transporters (ABCC1-5) and BCRP (ABCG2).
Drug Metab Rev. 2008;40(2):317-54., [PMID:18464048]
Abstract [show]
Elucidation of the key mechanisms that confer interindividual differences in drug response remains an important focus of drug disposition and clinical pharmacology research. We now know both environmental and host genetic factors contribute to the apparent variability in drug efficacy or in some cases, toxicity. In addition to the widely studied and recognized genes involved in the metabolism of drugs in clinical use today, we now recognize that membrane-bound proteins, broadly referred to as transporters, may be equally as important to the disposition of a substrate drug, and that genetic variation in drug transporter genes may be a major contributor of the apparent intersubject variation in drug response, both in terms of attained plasma and tissue drug level at target sites of action. Of particular relevance to drug disposition are members of the ATP Binding Cassette (ABC) superfamily of efflux transporters. In this review a comprehensive assessment and annotation of recent findings in relation to genetic variation in the Multidrug Resistance Proteins 1-5 (ABCC1-5) and Breast Cancer Resistance Protein (ABCG2) are described, with particular emphasis on the impact of such transporter genetic variation to drug disposition or efficacy.
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101 Several molecular defects in MRP2 have been suggested to result in DJS including those which produce deficient protein maturation (Hashimoto et al., 2002; Keitel et al., 2003), proteasomal degradation (Keitel, 2003), impaired membrane sorting (Hashimoto et al., 2002; Mor-Cohen et al., 2001), loss in transport activity (Mor-Cohen et al., 2001), Figure 2 Predicted membrance topology of MRP2 (ABCC2) based on hydrophobicity analysis. Locations of the non-synonymous polymorphisms are indicated with arrows. See Table 2 for allele frequencies and description of funtional consequences. NH2 COOH NBD NBD in out Membrane Pro19Leu Phe39Tyr Arg100* Arg100Gln Ser281Asn Ser325* Asp333Gly Arg353His Arg412Gly Val417Ile Lys430Arg Thr486Ile Gly676Arg Trp709Arg Asn718Ser Ser789Phe Arg768Trp Asp833Asn Glu893Gln Leu927Arg Lys961Arg Tyr967* Phe981Leu Gln1019His Arg1066* Arg1150His Arg1100Cys Arg1100His Ile1137Phe Ile1173Phe Val1188Glu Arg1174His Arg1181Leu Asn1244Lys Thr1273Ala Pro1291Leu Lys1299Gln Arg1310* Ser1367Cys Gln1382Arg Arg1392del Met1393del Ala1450Thr Thr1476Met Cys1515Tyr MRP2 (ABCC2) NBD NBD Asp833Asn Glu893Gln Leu927Arg Lys961Arg Tyr967* NBD NBDNBD Asp833Asn Glu893Gln Leu927Arg Lys961Arg Tyr967* 325 Table2MRP2(ABCC2)singlenucleotidepolymorphisms.Location,allelefrequencyandfunctionaleffects. Positionin codingsequence Amino acidexchangeLocation Allelefrequency EffectNCBIIDReferenceAfCaJpothers 56C>TPro19LeuExon2--1[1]b -- 116T>APhe39TyrExon2--0[2]--rs927344 298C>TArg100*Exon3--[3]-DJS[3] 299G>AArg100GlnExon3--1[1]b -- 842G>ASer281AsnExon7-0[4]1[1]b -- 974C>GSer325*Exon8---Malayan[5]DJS[5] 998A>GAsp333GlyExon8--0[2]--rs17222674 1058G>AArg353HisExon9--0[2]--rs7080681 1271A>GArg412GlyExon10-[6]0[2]-DJS;Decreaseinmethotrexateelimination[6] 1249G>AVal417IleExon10-22[7]13[9]-lowermRNAand(protein)expressioninpreterm placenta[11] rs2273697 26[8]16[4]noeffectonRNAandproteinininduodenum[12] 19[10]noeffectonproteininliver[8] noeffectonconjugatedbilirubinlevelinserum[13] changesinlocalizationinneuroepithelialtumors[14] possibleassociationwithtenofovir-inducedrenal proximaltubulopathy[15] 1289A>GLys430ArgExon10-4[16]0[2]-- 1457C>TThr486IleExon10-0[4]3[1]b -- 2026G>CGly676Arg--0[2]-DJS[17] 2125T>CTrp709Arg--0[2]-DJS[17] 2153A>GAsn718SerExon17-0[4]0[2]--rs3740072 2302C>TArg768TrpExon18-0[18]1[9]-DJS;deficientmaturationandimpairedsorting[19] 2366C>TSer789PheExon18-0[18]1[9]-lowerexpressionandmembranelocalization[20] noeffectonconjugatedbilirubinlevelinserum[13]/ heterozygous 2647G>AAsp883AsnExon20--1[1]b -- 2677G>CGlu893GlnExon20--0[2]--rs3740071 2780T>GLeu927ArgExon21-1[10]0[2]-- (Continued) Table2(Continued) Positionin codingsequence Aminoacid exchangeLocation Allelefrequency EffectNCBIIDReferenceAfCaJpothers 2882A>GLys961ArgExon21--1[1]b --- 2901C>ATyr967*Exon22--0[2]--rs17222547 2943C>GPhe981LeuExon22-2[21]0[2]-Noinfluenceonpravastatinkinetics[21] 3057G>TGln1019HisExon22--1[1]b -- 3196C>TArg1066*Exon23-[22]0[2]-DJS;truncatedprotein[22][23] 3298C>TArg1100CysExon24-1[10]0[2]-- 3299G>AArg1100HisExon24-1[10]0[2]-- 3449G>AArg1150HisExon25--0[2]Israeli[24]DJS;impairedtransportactivityintransfectedcells althoughnormalexpressionandlocalization[24] 3517A>TIle1173PheExon25--0[2]Israeli[24]DJS;impairedproteinmaturationandproteasomal degradation[25] lowexpression,mislocation,andimpairedtransport activityintransfectedcells[24] 3521G>AArg1174HisExon25-0[4]1[1]b -- 3542G>TArg1181LeuExon25-0[4]0[2]--rs8187692 3563T>AVal1188GluExon25-7[4]1[1]b -noeffectonnelfinaviraccumulationinPBMC[4],rs17222723 4[16]associatedwithanthracycline-induced cardiotoxicity[26] 6[8] 3732C>TAsn1244LysExon26--0[1]b -- 0[2] 3817A>GThr1273AlaExon27--0[2]--rs8187699 3872C>TPro1291LeuExon28--0[2]--rs17216317 3897A>CLys1299GlnExon28--0[2]--rs4148400 3928C>TArg1310*Exon28--0[2]-DJS[17,27] 4100C>GSer1367CysExon29--1[1]b -- 4145A>GGln1382ArgExon29--[28]-DJS;noeffectonmaturationorsorting,impaired substrate-inducedATPhydrolysis[19] 4175-80delArg1392delExon30--0[2]-DJS;deficientMRP2maturationandimpaired sortingtoapicalmembraneintransfectedcells[29] 327 4348G>AAla11450ThrExon31-0[18]1[9]-lowerexperssionandmembracelocalizationin transfectedcells[20] 4461C>TThr1476MetExon31-[30]1[2]-- 4544G>ACys1515TyrExon32-9[4]1[1]b -noeffectonnelfinaviraccumulationinPBMC[4]rs8187710 5[10]associatedwithanthracycline-induced cardiotoxicity[26] 4[16] 6[8] ReferencewithoutfrequencymeansthatSNPwasdetectedbutnofrequencydetermined.
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ABCC2 p.Thr1273Ala 18464048:101:959
status: NEW[hide] Mutational analysis of ABCC2 gene in two siblings ... Clin Genet. 2010 Dec;78(6):598-600. doi: 10.1111/j.1399-0004.2010.01497.x. Pacifico L, Carducci C, Poggiogalle E, Caravona F, Antonozzi I, Chiesa C, Maggiore G
Mutational analysis of ABCC2 gene in two siblings with neonatal-onset Dubin Johnson syndrome.
Clin Genet. 2010 Dec;78(6):598-600. doi: 10.1111/j.1399-0004.2010.01497.x., [PMID:21044052]
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28 The study of allelic segregation in Letter to the Editor R100X R393W IVS6_IVS7del L441M IVS13 +2 T>A IVS15 +2 T>C G676R IVS18 +2 T>C R768W * 2748_2883del * R1066X * 3399_3400del L1173F 3615_3843del* Y1275X * R1310X Q1382R R1392_M1393del S325X W709R T1273A IVS8 +4 A>G 1256_1272delins CT 4292_4293delR1150H E1352Q * Exon 1 32 Fig. 1.
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ABCC2 p.Thr1273Ala 21044052:28:251
status: NEW[hide] The apical conjugate efflux pump ABCC2 (MRP2). Pflugers Arch. 2007 Feb;453(5):643-59. Epub 2006 Jul 18. Nies AT, Keppler D
The apical conjugate efflux pump ABCC2 (MRP2).
Pflugers Arch. 2007 Feb;453(5):643-59. Epub 2006 Jul 18., [PMID:16847695]
Abstract [show]
ABCC2 is a member of the multidrug resistance protein subfamily localized exclusively to the apical membrane domain of polarized cells, such as hepatocytes, renal proximal tubule epithelia, and intestinal epithelia. This localization supports the function of ABCC2 in the terminal excretion and detoxification of endogenous and xenobiotic organic anions, particularly in the unidirectional efflux of substances conjugated with glutathione, glucuronate, or sulfate, as exemplified by leukotriene C(4), bilirubin glucuronosides, and some steroid sulfates. The hepatic ABCC2 pump contributes to the driving forces of bile flow. Acquired or hereditary deficiency of ABCC2, the latter known as Dubin-Johnson syndrome in humans, causes an increased concentration of bilirubin glucuronosides in blood because of their efflux from hepatocytes via the basolateral ABCC3, which compensates for the deficiency in ABCC2-mediated apical efflux. In this article we provide an overview on the molecular characteristics of ABCC2 and its expression in various tissues and species. We discuss the transcriptional and posttranscriptional regulation of ABCC2 and review approaches to the functional analysis providing information on its substrate specificity. A comprehensive list of sequence variants in the human ABCC2 gene summarizes predicted and proven functional consequences, including variants leading to Dubin-Johnson syndrome.
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139 Although all sequence variants associated with Dubin-Johnson syndrome result in the absence of a Table 3 Nucleotide sequence variants in the human ABCC2 gene (NM_000392) leading to amino acid changes in the ABCC2/MRP2 protein (NP_000383) Location Nucleotide changea Deduced effect on proteina Causing Dubin-Johnson syndromeb Predicted effect by PolyPhen databasec Experimentally proven functional consequence Average frequency of indicated nucleotide exchange in population NCBI SNP IDd and/or references Exon 2 c.56 C>Te p.P19L Probably damaging T: 0.007 [63] Exon 2 c.116 T>A p.F39Y Benign A: 0.010 rs927344 A: 0.008 rs17222603 Exon 3 c.298 C>T p.R100Xf DJS [154] Exon 3 c.299 G>Ae p.R100Q Possibly damaging A: 0.007 [63] Exon 7 c.736 A>C p.M246L Benign C: 0.002 rs8187667 C: 0.002 rs17222744 Exon 7 c.842 G>A p.S281N Benign A: 0.0060.056 [117] Exon 8 c.998 A>G p.D333G Possibly damaging G: 0.002 rs8187668 G: 0.004 rs17222674 Exon 9 c.1058 G>A p.R353H Benign A: 0.009 rs7080681 A: 0.014 rs17216205 Exon 9 c.1177 C>T p.R393W DJS Probably damaging [104, 112] Exon 10 c.1234 A>G p.R412G Probably damaging Deficient methotrexate transport function [56] Exon 10 c.1249 G>A p.V417I Benign None apparent [50] A: 0.163 rs2273697, [146] A: 0.158 rs17216184 A: 0.125 [62] A: 0.1830.312 [117] Exon 10 c.1457 C>T p.T486I Benign T: 0.002 rs8187670 T: 0.002 rs17222589 Exon 11 c.1483 A>G p.K495E Possibly damaging G: 0.002 rs8187672 G: 0.002 rs17222561 Exon 13 c.1686 T>G p.F562L Benign G: 0.002 rs8187673 G: 0.002 rs17216233 Exon 16 c.2009 T>C p.I670T Benign rs8187676 C: 0.006 rs17222632 Exon 16 c.2026 G>C p.G676R DJS Probably damaging [181] Exon 17 c.2125 T>C p.W709R DJS Probably damaging [111] Exon 17 c.2153 A>G p.N718S Possibly damaging rs3740072 Exon 17 c.2215 C>T p.L739F Probably damaging T: 0.006 [51] Exon 18 c.2302 C>T p.R768W DJS Probably damaging Deficient maturation and impaired sorting [47] T: 0.010 [62] [168, 180] Exon 18 c.2366 C>T p.S789F Probably damaging Reduced protein levels [50] T: 0.010 [62] Exon 19 c.2546 T>G p.L849R Benign G: 0.002 rs8187689 G: 0.006 rs17222617 Exon 20 c.2647 G>Ae p.D883N Benign A: 0.007 [63] Exon 20 c.2677 G>C p.E893Q Benign rs3740071 Exon 21 c.2882 A>Ge p.K961R Benign G: 0.007 [63] Exon 22 c.2901 C>A p.Y967Xf A: 0.002 rs8187683 A: 0.002 rs17222547 Exon 22 c.2944 A>G p.I982V Benign G: 0.002 rs8187684 G: 0.002 rs17222554 Exon 22 c.3057 G>Te p.Q1019H Benign T: 0.007 [63] Exon 23 c.3107 T>C p.I1036T Possibly damaging C: 0.002 rs8187685 C: 0.004 rs17216149 Exon 23 c.3188 A>G p.N1063S Benign G: 0.002 rs8187686 G: 0.002 rs17222540 Exon 23 c.3196 C>T p.R1066Xf DJS No ABCC2 protein in liver [134] Exon 25 c.3449 G>A p.R1150H DJS Probably damaging Deficient transport function A: 00.009 [117] Exon 25 c.3517 A>T p.I1173F DJS Probably damaging Deficient maturation and impaired sorting, deficient transport function T: 00.029 [117] [80, 117] Exon 25 c.3521 G>Ae p.R1174H Probably damaging A: 0.007 [63] Exon 25 c.3542 G>T p.R1181L Possibly damaging T: 0.039 rs8187692 T: 0.034 rs17222702 Exon 25 c.3563 T>A p.V1188E Benign A: 0.059 rs8187694 A: 0.059 rs17222723 Exon 26 c.3732 T>Ge p.N1244K Possibly damaging G: 0.014 [63] Exon 27 c.3817 A>G p.T1273A Benign G: 0.002 rs8187699 G: 0.004 rs17222582 Exon 27 c.3825 C>G p.Y1275Xf DJS No ABCC2 protein in liver [104] Exon 28 c.3872 C>T p.P1291L Possibly damaging T: 0.012 rs8187700 T: 0.010 rs17216317 Exon 28 c.3895 A>C p.K1299Q Benign rs4148400, [146] Exon 28 c.3928 C>T p.R1310Xf DJS [166] Exon 29 c.4100 C>Ge p.S1367C Possibly damaging G: 0.007 [63] Exon 29 c.4145 A>G p.Q1382R DJS Probably Deficient [47, 168] Table 3 (continued) Location Nucleotide changea Deduced effect on proteina Causing Dubin-Johnson syndromeb Predicted effect by PolyPhen databasec Experimentally proven functional consequence Average frequency of indicated nucleotide exchange in population NCBI SNP IDd and/or references functionally active ABCC2 protein from the canalicular membrane, their effects on the synthesis and function of the ABCC2 protein differ.
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ABCC2 p.Thr1273Ala 16847695:139:3188
status: NEW140 Although all sequence variants associated with Dubin-Johnson syndrome result in the absence of a Table 3 Nucleotide sequence variants in the human ABCC2 gene (NM_000392) leading to amino acid changes in the ABCC2/MRP2 protein (NP_000383) Location Nucleotide changea Deduced effect on proteina Causing Dubin-Johnson syndromeb Predicted effect by PolyPhen databasec Experimentally proven functional consequence Average frequency of indicated nucleotide exchange in population NCBI SNP IDd and/or references Exon 2 c.56 C>Te p.P19L Probably damaging T: 0.007 [63] Exon 2 c.116 T>A p.F39Y Benign A: 0.010 rs927344 A: 0.008 rs17222603 Exon 3 c.298 C>T p.R100Xf DJS [154] Exon 3 c.299 G>Ae p.R100Q Possibly damaging A: 0.007 [63] Exon 7 c.736 A>C p.M246L Benign C: 0.002 rs8187667 C: 0.002 rs17222744 Exon 7 c.842 G>A p.S281N Benign A: 0.0060.056 [117] Exon 8 c.998 A>G p.D333G Possibly damaging G: 0.002 rs8187668 G: 0.004 rs17222674 Exon 9 c.1058 G>A p.R353H Benign A: 0.009 rs7080681 A: 0.014 rs17216205 Exon 9 c.1177 C>T p.R393W DJS Probably damaging [104, 112] Exon 10 c.1234 A>G p.R412G Probably damaging Deficient methotrexate transport function [56] Exon 10 c.1249 G>A p.V417I Benign None apparent [50] A: 0.163 rs2273697, [146] A: 0.158 rs17216184 A: 0.125 [62] A: 0.1830.312 [117] Exon 10 c.1457 C>T p.T486I Benign T: 0.002 rs8187670 T: 0.002 rs17222589 Exon 11 c.1483 A>G p.K495E Possibly damaging G: 0.002 rs8187672 G: 0.002 rs17222561 Exon 13 c.1686 T>G p.F562L Benign G: 0.002 rs8187673 G: 0.002 rs17216233 Exon 16 c.2009 T>C p.I670T Benign rs8187676 C: 0.006 rs17222632 Exon 16 c.2026 G>C p.G676R DJS Probably damaging [181] Exon 17 c.2125 T>C p.W709R DJS Probably damaging [111] Exon 17 c.2153 A>G p.N718S Possibly damaging rs3740072 Exon 17 c.2215 C>T p.L739F Probably damaging T: 0.006 [51] Exon 18 c.2302 C>T p.R768W DJS Probably damaging Deficient maturation and impaired sorting [47] T: 0.010 [62] [168, 180] Exon 18 c.2366 C>T p.S789F Probably damaging Reduced protein levels [50] T: 0.010 [62] Exon 19 c.2546 T>G p.L849R Benign G: 0.002 rs8187689 G: 0.006 rs17222617 Exon 20 c.2647 G>Ae p.D883N Benign A: 0.007 [63] Exon 20 c.2677 G>C p.E893Q Benign rs3740071 Exon 21 c.2882 A>Ge p.K961R Benign G: 0.007 [63] Exon 22 c.2901 C>A p.Y967Xf A: 0.002 rs8187683 A: 0.002 rs17222547 Exon 22 c.2944 A>G p.I982V Benign G: 0.002 rs8187684 G: 0.002 rs17222554 Exon 22 c.3057 G>Te p.Q1019H Benign T: 0.007 [63] Exon 23 c.3107 T>C p.I1036T Possibly damaging C: 0.002 rs8187685 C: 0.004 rs17216149 Exon 23 c.3188 A>G p.N1063S Benign G: 0.002 rs8187686 G: 0.002 rs17222540 Exon 23 c.3196 C>T p.R1066Xf DJS No ABCC2 protein in liver [134] Exon 25 c.3449 G>A p.R1150H DJS Probably damaging Deficient transport function A: 00.009 [117] Exon 25 c.3517 A>T p.I1173F DJS Probably damaging Deficient maturation and impaired sorting, deficient transport function T: 00.029 [117] [80, 117] Exon 25 c.3521 G>Ae p.R1174H Probably damaging A: 0.007 [63] Exon 25 c.3542 G>T p.R1181L Possibly damaging T: 0.039 rs8187692 T: 0.034 rs17222702 Exon 25 c.3563 T>A p.V1188E Benign A: 0.059 rs8187694 A: 0.059 rs17222723 Exon 26 c.3732 T>Ge p.N1244K Possibly damaging G: 0.014 [63] Exon 27 c.3817 A>G p.T1273A Benign G: 0.002 rs8187699 G: 0.004 rs17222582 Exon 27 c.3825 C>G p.Y1275Xf DJS No ABCC2 protein in liver [104] Exon 28 c.3872 C>T p.P1291L Possibly damaging T: 0.012 rs8187700 T: 0.010 rs17216317 Exon 28 c.3895 A>C p.K1299Q Benign rs4148400, [146] Exon 28 c.3928 C>T p.R1310Xf DJS [166] Exon 29 c.4100 C>Ge p.S1367C Possibly damaging G: 0.007 [63] Exon 29 c.4145 A>G p.Q1382R DJS Probably Deficient [47, 168] Table 3 (continued) Location Nucleotide changea Deduced effect on proteina Causing Dubin-Johnson syndromeb Predicted effect by PolyPhen databasec Experimentally proven functional consequence Average frequency of indicated nucleotide exchange in population NCBI SNP IDd and/or references functionally active ABCC2 protein from the canalicular membrane, their effects on the synthesis and function of the ABCC2 protein differ.
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ABCC2 p.Thr1273Ala 16847695:140:3188
status: NEW[hide] Identification of a novel 974C-->G nonsense mutati... Am J Gastroenterol. 2006 Oct;101(10):2427-32. Epub 2006 Sep 4. Corpechot C, Ping C, Wendum D, Matsuda F, Barbu V, Poupon R
Identification of a novel 974C-->G nonsense mutation of the MRP2/ABCC2 gene in a patient with Dubin-Johnson syndrome and analysis of the effects of rifampicin and ursodeoxycholic acid on serum bilirubin and bile acids.
Am J Gastroenterol. 2006 Oct;101(10):2427-32. Epub 2006 Sep 4., [PMID:16952291]
Abstract [show]
Rifampicin (RIF) and ursodeoxycholic acid (UDCA) therapies have beneficial effects in chronic cholestatic diseases. These may result in part from the induction of multidrug-resistance protein 2 (MRP2/ABCC2) expression in the liver and kidney. However, the precise mechanisms by which RIF and UDCA act in cholestasis remain unclear. In the present study, we report the effects of chronic administration of both drugs in a patient with Dubin-Johnson syndrome (DJS), an inherited autosomal recessive disorder characterized by the absence of functional MRP2 protein at the canalicular hepatocyte membrane. A novel 974C-->G nonsense mutation was identified in the MRP2 gene sequence from this patient. RIF induced further increase in conjugated bilirubinemia, whereas concomitant administration of RIF and UDCA led to a dramatic rise in serum bile acid concentrations. These biochemical effects, which are in marked contrast to those observed in cholestatic settings, were concomitant with an increased MRP3, but not MRP4, expression on basolateral hepatocyte membrane. Such findings highlight the key role of MRP2 in the pharmacological properties of RIF and UDCA and suggest that both drugs should be used with caution in pathologic settings in which MRP2 expression may be downregulated, as in advanced stage of cholestatic diseases.
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No. Sentence Comment
45 Two point mutations were identified: a nonsense mutation, 974C→G (Ser325X), located in exon 8, and a missense mutation, 3817A→G (Thr1273Ala), positioned in exon 27.
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ABCC2 p.Thr1273Ala 16952291:45:141
status: NEW83 This nucleotide variant is predicted to substitute threonine1273 with alanine in the last cytoplasmic domain of the protein.
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ABCC2 p.Thr1273Ala 16952291:83:51
status: NEW