ABCMdb

ABCC1 p.Ser1512Leu

Predicted by SNAP2:	A: N (82%), C: D (71%), D: N (57%), E: N (66%), F: D (91%), G: D (53%), H: D (53%), I: D (71%), K: N (53%), L: N (53%), M: D (85%), N: N (61%), P: D (75%), Q: N (66%), R: D (63%), T: N (72%), V: D (63%), W: D (91%), Y: D (85%),
Predicted by PROVEAN:	A: N, C: D, D: N, E: N, F: D, G: N, H: D, I: D, K: N, L: D, M: N, N: N, P: D, Q: N, R: N, T: N, V: N, W: D, Y: D,

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[hide] Role of pharmacogenetics of ATP-binding cassette t... Pharmacol Ther. 2006 Nov;112(2):457-73. Cascorbi I
Role of pharmacogenetics of ATP-binding cassette transporters in the pharmacokinetics of drugs.
Pharmacol Ther. 2006 Nov;112(2):457-73., [PMID:16766035]

Abstract [show]
Interindividual differences of drug response are an important cause of treatment failures and adverse drug reactions. The identification of polymorphisms explaining distinct phenotypes of drug metabolizing enzymes contributed in part to the understanding of individual variations of drug plasma levels. However, bioavailability also depends on a major extent from the expression and activity of drug transport across biomembranes. In particular efflux transporters of the ATP-binding cassette (ABC) family such as ABCB1 (P-glycoprotein, P-gp), the ABCC (multidrug resistance-related protein, MRP) family and ABCG2 (breast cancer resistance protein, BCRP) have been identified as major determinants of chemoresistance in tumor cells. They are expressed in the apical membranes of many barrier tissue such as the intestine, liver, blood-brain barrier, kidney, placenta, testis and in lymphocytes, thus contributing to plasma, liquor, but also intracellular drug disposition. Since expression and function exhibit a broad variability, it was hypothesized that hereditary variances in the genes of membrane transporters could explain at least in part interindividual differences of pharmacokinetics and clinical outcome of a variety of drugs. This review focuses on the functional significance of single nucleotide polymorphisms (SNP) of ABCB1, ABCC1, ABCC2, and ABCG2 in in vitro systems, in vivo tissues and drug disposition, as well as on the clinical outcome of major indications.

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831 R1058Q and S1512L was performed recently by Letourneau et al. (2005) in transfected HEK293T cells. Login to comment
852 Table 5 Frequency of ABCC1 genetic variants in different populations, position on DNA, putative effect, and frequencies (according to Le Saux et al., 2000; Ito et al., 2001; Moriya et al., 2002; Conrad et al., 2002; Oselin et al., 2003b; Wang et al., 2004) Position/ Nucleotide Aminoacid or effect Orientals Caucasians Function 128G>C C43S 0.01 - elevateda 218C>T T73I 0.00-0.04 - 257C>T S92F 0.00 0.00 decreaseda 350C>T T117M - 0.02 (decreased)a 689G>A R230N 0.00 0.00 (decreased)a 816G>A synonymous - 0.04 825T>C synonymous - 0.30 1057G>A V353M 0.00 0.005 elevateda 1299G>T R433S - 0.01 elevated Vmax of doxorubicin, decreased transport of LTC4 a,b 1684T>C synonymous - 0.80 1898G>A R633Q - 0.01 (decreased)a 2012G>T G671V - 0.03 doxorubicine-induced cardiomyopathyc 2168G>A R723Q 0.01-0.07 - decreaseda 2965G>A A989T 0.00 0.005 (decreased)a 3140G>C C1047S 0.00 0.00 3173G>A R1058Q 0.01 - 4002G>A synonymous - 0.28 4535C>T S1512L - 0.03 decreaseda a Letourneau et al. (2005). Login to comment

[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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71 Letourneau et al. (2005) studied the influence of 10 non-synonymous variations (Thr73Ile, Ser92Phe, Thr117Met, Arg230Gln, Arg633Gln, Arg723Gln, Ala989Thr, Cys1047Ser, Arg1056Gln, and Ser1512Leu) on MRP1 expression using membrane vesicles isolated from transfected cells and assesed transport activity for 3 known MRP1 substrates (LTC4, estradiol-17-β-glucuronide, and methotrexate). Login to comment
81 MRP1 (ABCC1) NH2 NBD NBD in out Membrane Cys43Ser Ser92Phe Thr117Met Arg230Gln Val353Met Arg633Gln Gly671Val Arg723Gln Arg433Ser Ala989Thr Cys1047Ser Val1146Ile Arg1058Gln Thr1401Met Ser1512Leu Thr73Ile COOH NBD NBD COOH NBD COOH NBD NBD Table1MRP1(ABCC1)singlenucleotidepolymorphisms.Location,allelefrequencyandfunctionaleffects. Positionin codingsequence Aminoacid exchangeLocation Allelefrequency EffectNCBIIDReferenceAfCaJpothers 128G>CCys43SerExon2--1[1]-Decreaseinvincristineresistance[2]rs41395947 Disruptedplasmamembranetraffickingin transfectedcells[2] 218C>TThr73IleExon2--1[1]3.7Chinese[3]Noinfluenceonexpressionandtransportin membranevesicles[4] rs41494447 257C>TSer92PheExon30a 0a 0a 0Chinese[3]Noinfluenceonexpressionandtransportin membranevesicles[4] 350C>TThr117MetExon3-100[5]--Noinfluenceonexpressionandtransportin membranevesicles[4] 689G>AArg230GlnExon70a 0a 0a 0Chinese[3]Noinfluenceonexpressionandtransportin membranevesicles[4] 1057G>AVal353MetExon90a 0.5a 0a -- 1299G>TArg433SerExon10-1.4[6]--Changesintransportandresistance[7] 1898G>AArg633GlnExon13-[8]--Noinfluenceonexpressionandtransportin membranevesicles[4] 2012G>TGly671ValExon16-2.8[6]--Noinfluenceonexpressionandtransportin membranevesicles[6] Associatedwithanthracycline-induced cardiotoxicity[9] 2168G>AArg723GlnExon17--7.3[1]5.6Chinese[3]Noinfluenceonexpressionandtransportin membranevesicles[4]noinfluenceonmRNA expressioninenterocytes(n=1)[10] rs4148356 2965G>AAla989ThrExon220a 0.5a 0a -Noinfluenceonexpressionandtransportin membranevesicles(non-significantreduction inE17βGtransport)[4] 323 3140G>CCys1047SerExon234.5a 0a 0a -Noinfluenceonexpressionandtransportin membranevesicles[4] rs13337489 3173G>AArg1058GlnExon23--1[1]-Noinfluenceonexpressionandtransportin membranevesicles[4] rs41410450 3436G>AVal1146IleExon24-----rs28706727 4102C>TThr1401MetExon29-----rs8057331 4535C>TSer1512LeuExon31-[5]--Noinfluenceonexpressionandtransportin membranevesicles[4] ReferencewithoutfrequencymeansthatSNPwasdetectedbutnofrequencydetermined. Login to comment

[hide] Pharmacogenetics of ATP-binding cassette transport... Methods Mol Biol. 2010;596:95-121. Cascorbi I, Haenisch S
Pharmacogenetics of ATP-binding cassette transporters and clinical implications.
Methods Mol Biol. 2010;596:95-121., [PMID:19949922]

Abstract [show]
Drug resistance is a severe limitation of chemotherapy of various malignancies. In particular efflux transporters of the ATP-binding cassette family such as ABCB1 (P-glycoprotein), the ABCC (multidrug resistance-associated protein) family, and ABCG2 (breast cancer resistance protein) have been identified as major determinants of chemoresistance in tumor cells. Bioavailability depends not only on the activity of drug metabolizing enzymes but also to a major extent on the activity of drug transport across biomembranes. They are expressed in the apical membranes of many barrier tissues such as the intestine, liver, blood-brain barrier, kidney, placenta, testis, and in lymphocytes, thus contributing to plasma, liquor, but also intracellular drug disposition. Since expression and function exhibit a broad variability, it was hypothesized that hereditary variances in the genes of membrane transporters could explain at least in part interindividual differences of pharmacokinetics of a variety of anticancer drugs and many others contributing to the clinical outcome of certain leukemias and further malignancies.

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135 R1058Q, and S1512L was performed by Létourneau et al. Login to comment
155 ABCC2 (Multidrug Resistance-Associated Protein 2) Table 6.5 Frequency of ABCC1 genetic variants in different populations, position on DNA, putative effect, and frequencies (according to (33, 77-80, 136)) Position Amino acid or effect Orientals Caucasians Function c.128G>C C43S 0.01 - Elevateda c. 218C>T T73I 0.00-0.04 - c. 257C>T S92F 0.00 0.00 Decreaseda c. 350C>T T117M - 0.02 (Decreased)a c. 689G>A R230N 0.00 0.00 (Decreased)a c. 816G>A Synonymous - 0.04 c. 825T>C Synonymous - 0.30 c. 1057G>A V353M 0.00 0.005 Elevateda c. 1299G>T R433S - 0.01 Elevated vmax of doxorubicin, decreased transport of LTC4 a,b c. 1684T>C Synonymous - 0.80 c. 1898G>A R633Q - 0.01 (Decreased)a c. 2012G>T G671V - 0.03 Doxorubicine-induced cardiomyopathyc c. 2168G>A R723Q 0.01-0.07 - Decreaseda c. 2965G>A A989T 0.00 0.005 (Decreased)a c. 3140G>C C1047S 0.00 0.00 c. 3173G>A R1058Q 0.01 - c. 4002G>A Synonymous - 0.28 c. 4535C>T S1512L - 0.03 Decreaseda References: a [81], b [77], c [84] an inducible expression of ABCC2, which contributes also to the phenomenon of drug resistance. Login to comment

[hide] Pharmacogenetics of membrane transporters: an upda... Mol Biotechnol. 2010 Feb;44(2):152-67. Sissung TM, Baum CE, Kirkland CT, Gao R, Gardner ER, Figg WD
Pharmacogenetics of membrane transporters: an update on current approaches.
Mol Biotechnol. 2010 Feb;44(2):152-67., [PMID:19950006]

Abstract [show]
This review provides an overview of the pharmacogenetics of membrane transporters including selected ABC transporters (ABCB1, ABCC1, ABCC2, and ABCG2) and OATPs (OATP1B1 and OATP1B3). Membrane transporters are heavily involved in drug clearance and alters drug disposition by actively transporting substrate drugs between organs and tissues. As such, polymorphisms in the genes encoding these proteins may have significant effects on the absorption, distribution, metabolism and excretion of compounds, and may alter pharmacodynamics of many agents. This review discusses the techniques used to identify substrates and inhibitors of these proteins and subsequently to assess the effect of genetic mutation on transport, both in vitro and in vivo. A comprehensive list of substrates for the major drug transporters is included. Finally, studies linking transporter genotype with clinical outcomes are discussed.

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67 Those studied include C43S, T73I, S92F, T117M, R230Q, V353M, R433S, R633Q, G671V, R723Q, A989T, C1047S, R1058Q, A1337T, and S1512L. Login to comment

[hide] Polymorphisms of MRP1 (ABCC1) and related ATP-depe... Pharmacogenet Genomics. 2005 Aug;15(8):523-33. Conseil G, Deeley RG, Cole SP
Polymorphisms of MRP1 (ABCC1) and related ATP-dependent drug transporters.
Pharmacogenet Genomics. 2005 Aug;15(8):523-33., [PMID:16006996]

Abstract [show]
Genetic variations in drug metabolizing enzymes and targets are established determinants of adverse drug reactions and interactions, but less is known about the role of genetic polymorphisms in membrane transport proteins. MRP1 (ABCC1) is one of 13 polytopic membrane proteins that comprise the 'C' subfamily of the ATP-binding cassette (ABC) superfamily of transport proteins. MRP1 and related ABCC family members, including MRP2, 3, 4 and 5 (ABCC2, 3, 4 and 5), each have a distinctive pattern of tissue expression and substrate specificity. Together, these five transporters play important roles in the disposition and elimination of drugs and other organic anions, and in maintenance of blood-tissue barriers, as confirmed by enhanced chemosensitivity of respective knockout mice. Moreover, Mrp2 (Abcc2) deficient animals display mild conjugated hyperbilirubinemia, corresponding to a human condition known as Dubin-Johnson syndrome (DJS). Naturally occurring mutations in MRP/ABCC-related drug transporters have been reported, some of which are non-synonymous single nucleotide polymorphisms. The consequences of the resulting amino acid changes can sometimes be predicted from in vitro site-directed mutagenesis studies or from knowledge of mutations of analogous (conserved) residues in ABCC proteins that cause DJS, Pseudoxanthoma elasticum (ABCC6), cystic fibrosis (CFTR/ABCC7) or persistent hyperinsulinemic hypoglycemia of infancy (SUR1/ABCC8). Continual updating of databases of sequence variants and haplotype analysis, together with in vitro biochemical validation assays and pharmacological studies in knockout animals, should make it possible to determine how genetic variation in the MRP-related transporters contributes to the range of responses to drugs and chemicals observed in different human populations.

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148 Fig. 3 Exon 1 2 3 MSDMSD NBD1 MSD NBD2 C4535T(S1512L) G3173A (R1058Q) G3140C (C1047S) G2965A (A989T) G2168A (R723Q) G2012T(G671V) G1898A (R633Q) G1299T(R433S) G1057A (V353M) G689A (R230Q) C350T(T117M) C257T(S92F) C218T(T73I) C128C (C43S) (TM1-5) (TM6-11) (TM12-17) 4 5 6 7 8 9101112 1314 151617 1819 20 21 22 23 242526272829 30 31 Location of non-synonymous SNPs in the coding regions of the genes in the MRP1/ABCC1 gene. Login to comment

[hide] Functional characterization of non-synonymous sing... Pharmacogenet Genomics. 2005 Sep;15(9):647-57. Letourneau IJ, Deeley RG, Cole SP
Functional characterization of non-synonymous single nucleotide polymorphisms in the gene encoding human multidrug resistance protein 1 (MRP1/ABCC1).
Pharmacogenet Genomics. 2005 Sep;15(9):647-57., [PMID:16041243]

Abstract [show]
The 190-kDa ATP-binding cassette (ABC) multidrug resistance protein 1 (MRP1) encoded by the MRP1/ABCC1 gene mediates the active cellular efflux of glucuronide, glutathione and sulfate conjugates. It can also confer resistance to a diverse spectrum of chemotherapeutic agents and transport a variety of toxicants. In the present study, we examined 10 MRP1/ABCC1 missense genetic variants [non-synonymous single nucleotide polymorphisms (SNPs)] to determine whether or not they affect expression or function of the transporter. Variants 218C>T (Thr73Ile), 257C>T (Ser92Phe), 350C>T (Thr117Met), 689G>A (Arg230Gln), 1898G>A (Arg633Gln), 2168G>A (Arg723Gln), 2965G>A (Ala989Thr), 3140G>C (Cys1047Ser), 3173G>A (Arg1058Gln) and 4535C>T (Ser1512Leu) were recreated using site-directed mutagenesis and transfected into human embryonic kidney cells. Immunoblotting experiments showed that all mutant proteins were expressed at levels comparable to wild-type MRP1. Vesicular transport assays revealed that the Ala989Thr mutation caused a significant decrease in estradiol 17beta-glucuronide transport due to a decrease in apparent affinity (Km) for this organic anion. The transport properties of the other mutants were comparable to wild-type MRP1. When the MRP1/ABCC1 non-synonymous SNPs were evaluated by the SIFT algorithm using subsets of homologs and orthologs of MRP1/ABCC1, Arg230Gln, Val353Met, Arg433Ser, Gly671Val and Arg1058 mutations were predicted to be deleterious, whereas the PolyPhen algorithm predicted Ser92Phe and Gly671Val to be potentially damaging. Thus most predictions of these algorithms were not in accordance with our experimental results. In conclusion, our data suggest that none of the MRP1/ABCC1 variants studied are likely by themselves to have major deleterious effects in healthy individuals, and the SIFT and PolyPhen algorithms appear to be poor predictors of the phenotypic consequences of these MRP1 mutations at least in vitro.

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3 Variants 218C > T (Thr73Ile), 257C > T (Ser92Phe), 350C > T (Thr117Met), 689G > A (Arg230Gln), 1898G > A (Arg633Gln), 2168G > A (Arg723Gln), 2965G > A (Ala989Thr), 3140G > C (Cys1047Ser), 3173G > A (Arg1058Gln) and 4535C > T (Ser1512Leu) were recreated using site-directed mutagenesis and transfected into human embryonic kidney cells. Login to comment
28 Of these mutations, the Fig. 1 128G >C (C43S) 128G >T(T73I) 689G >A (R230Q)1057G >A (V353M) 1299G >T(R433S) 1898G >A (R633Q) 2012G >T(G671V) 2168G >A (R723Q) 3173G >A (R1058Q) 4535C >T(S1512L) 3140G >C (C1047S) 2965G >A (A989T) 350C >T(T117M) 257C >T(S92F) 313029282726252423222120181716151413121110987654321 19 MSD1 MSD1 MSD2 MSD3 MSD2 NBD1 MSD3 NBD2 TM 1 2 3 4 5 6 7 8 Val353Met Ala989Thr Cys1047Ser Arg1058Gln NBD2NBD1 Ser1512Leu Arg633Gln Arg433Ser Arg723Gln Thr73lle Thr117Met Arg230Gln Cys43Ser Ser92Phe Gly671Val 9 10 11 12 13 14 15 16 17 (a) (b) Location of reported non-synonymous single nucleotide polymorphisms (SNPs) in MRP1/ABCC1. Login to comment
46 The template for generating Table 1 Frequencies of non-synonymous single nucleotide polymorphisms in MRP1/ABCC1 Variant Amino acid substitution Allelic frequency Population References 128G > C Cys43Ser 0% (0/26) Japanese [16] 1% (1/96) Japanese [17] 218C > T Thr73Ile 0% (0/26) Japanese [16] 1% (1/96) Japanese [17] 3.7% (2/54) Chinese [37] 257C > T Ser92Phe 0% (0/220) Caucasian www.pharmGKB.org 0.5% (1/200) African-American 0% (0/60) Japanese 0% (0/14) Pacific-Islander 350C > T Thr117Met 1.6% (1/64) Caucasian [28] 689G > A Arg230Gln 0% (0/220) Caucasian www.pharmGKB.org 0.5% (1/200) African-American 0% (0/60) Japanese 0% (0/14) Pacific-Islander 1057G > A Val353Met 0.5% (1/220) Caucasian www.pharmGKB.org 0% (0/200) African-American 0% (0/60) Japanese 0% (0/14) Pacific-Islander 1299G > T Arg433Ser 1.4% (1/72) Caucasian [20] 0% (0/110) Caucasian [19] 1898G > A Arg633Gln 0.8% (2/234) Caucasian [29] 2012G > T Gly671Val 2.8% (2/72) Caucasian [20] 2.6% (6/234) Caucasian [29] 2168G > A Arg723Gln 3.8% (1/26) Japanese [16] 1% (1/96) Japanese [30] 7.3% (7/96) Japanese [17] 5.6% (3/54) Chinese [37] 2965G > A Ala989Thr 0.5% (1/220) Caucasian www.pharmGKB.org 0% (0/200) African-American 0% (0/60) Japanese 0% (0/14) Pacific-Islander 3140G > C Cys1047Ser 0% (0/220) Caucasian www.pharmGKB.org 4.5% (9/200) African-American 0% (0/60) Japanese 0% (0/14) Pacific-Islander 3173G > A Arg1058Gln 0% (0./26) Japanese [16] 1% (1/96) Japanese [17] 4535C > T Ser1512Leu 3.1% (2/24) Caucasian [28] Characterization of MRP1/ABCC1 variants in vitro Le´tourneau et al. 649 the Arg633Gln and Arg723Gln mutants was created by subcloning a HindIII fragment (1329 bp) encoding amino acids 517-959 into pGEM-3z [20]. Login to comment
48 The template for the Ser1512Leu mutant was created by subcloning a 778-bp EcoRI/KpnI fragment encoding amino acids 1295-1531 into pBluescript II KS( + ) (Stratagene). Login to comment
50 Mutagenesis was performed according to the manufacturer`s instructions with the following sense primers (substituted nucleotides for amino acid mutation are underlined, introduced or disrupted restriction sites are italicized and other silent substitutions are in lower case letters) as follows: Thr73Ile (50 -G ATG ACA CCT CTC AAC AAA ATC AAAACTGCCTTGGG-30 ); Ser92Phe (50 -GG GCA GAC CTG TTC TAC TTT TTC TGG GAA AG-30 ) (EarI); Thr117Met (50 -CTC TTG GGC ATC ACC ATG CTG CTT GCT ACC-30 ); Arg230Gln (50 -GG TTG ATT GTA CAG GGC TAC CGC C-30 ) (BsrGI); Arg633Gln (50 -GAC AGC ATC GAG CGA CAG CCT GTG AAA GAC GGC GG-30 ) (Eam1105I); Arg723Gln (50 -CAG AAT GAC TCT CTC CAA GAA AAt ATC CTT TTT GGA TGT CAG C-30 ) (PleI); Ala989Thr (50 -C ATG TGT AAC CAC GTG TCC ACG CTG GCT TCC-30 ) (PmlI); Cys1047Ser (50 - GCT TCC CGC TCT CTG CAT GTG GAC CTG C-30 ) (PmlI); Arg1058Gln (50 -CTG CTG CAC AGC ATC CTC CAG TCA CCC ATG AGC-30 ) (BstEII); and Ser1512Leu (50 -CAG GAG TAC GGA GCC CCA TTG GAC CTt CTG CAG CAG-30 ) (NarI). Login to comment
51 Following mutagenesis, the desired fragment was subcloned back into pcDNA3.1(-) MRP1k as a XbaI/BamHI fragment (865 bp) for the Thr73Ile, Ser92Phe, Thr117Met and Arg230Gln mutants; a Bsu36I/Esp3I fragment (721 bp) for the Arg633Gln and Arg723Gln mutants; a Esp3I/EcoRI fragment (1313 bp) for the Ala989Thr, Cys1047Ser, Arg1058Gln mutants; and a EcoRI/KpnI fragment (778 bp) for the Ser1512Leu mutant. Login to comment
83 Expression levels of MRP1 mutants To investigate the effect of the amino acid substitutions resulting from the non-synonymous SNPs on MRP1 protein expression and function, MRP1 expression vectors containing the mutations responsible for the substitutions (Thr73Ile, Ser92Phe, Thr117Met, Arg230Gln, Arg633Gln, Arg723Gln, Thr989Ala, Cys1047Ser, Arg1058Gln, Ser1512Leu) were generated by site-directed mutagenesis and transfected into HEK293T cells. Login to comment
87 The mutants were considered in four groups based on their location in the transporter: (a) MSD1/CL3 mutants Thr73Ile, Ser92Phe, Thr117Met and Arg230Gln; (b) NBD1 mutants Arg633Gln and Arg723Gln; (c) MSD3 mutants Ala989Thr, Cys1047Ser and Arg1058Gln; and (d) COOH-terminus mutant Ser1512Leu. Login to comment
96 However, the three SNPs located in or close to the NBDs (Arg633Gln, Arg723Gln and Ser1512Leu) caused a consistent decrease (approximately 25%) in [3 H]E217bG (Fig. 3b) and [3 H]MTX uptake when activity levels were normalized for variation in expression level (Fig. 3c). Login to comment
97 The Arg723Gln and Ser1512Leu mutations had a similar effect on [3 H]LTC4 uptake, whereas the Arg633Gln mutation did not (Fig. 3a). Login to comment
123 Previous mutagenesis and inhibition studies have Fig. 3 Cys43Ser Thr73lle Ser92Phe Thr117Met Arg230Gln Arg433Ser Arg633Gln Gly671Val Arg723Gln Ala989Thr Cys1047Ser Arg1058Gln Ser1512Leu Cys43Ser Thr73lle Ser92Phe Thr117Met Arg230Gln Arg433Ser Arg633Gln Gly671Val Arg723Gln Ala989Thr Cys1047Ser Arg1058Gln Ser1512Leu Thr73lle Ser92Phe Thr117Met Arg230Gln Arg633Gln Arg723Gln Ala989Thr Cys1047Ser Arg1058Gln Ser1512Leu LTC4 % WT-MRP1 uptake 0 25 50 75 100 125 E217βG % WT-MRP1 uptake 0 25 50 75 100 125 150 MTX % WT-MRP1 uptake 0 25 50 75 100 125 (b) (c) (a) ATP-dependent vesicular transport of organic anions by mutant MRP1 proteins. Login to comment
158 This observation may be construed as being Table 2 Conservation of the amino acids substituted by non-synonymous SNP of human MRP1/ABCC1a Protein Speciesb C43S T73I S92F T117Mc R230Q V353M R433S R633Qc G671V R723Q A989T C1047S R1058Q S1512L MRP1 Human C T S T R V R R G R A C R S Monkey C T S M R V R R G Q A C R S Dog C T S M R V R R G R A R R S Cow C A S M Q V R R G R A R R S Rat C A S M Q V R W G R A R R S Mouse C T S M H V R R G R A R R S MRP2 Human L A V T K A K R G K A I R E Monkey L A V T K A K R G K A I R E Dog L A V T K A K R G K A I Q Q Rat L A A T K V K R G K A A R E Mouse L A A T K V K V G K A T R E Rabbit L A V T K V K R G K A I R E MRP3 Human C L S M Y I R K G Q A V R A Rat C L S M L L R K G Q A L R V MRP4 Human - - - - I F K R G R Y T K Y MRP5 Human - - - - V T R S G R T R R S MRP6 Human P A A M R I R S G V A L R A CFTR Human - - - - R Y K A G K L I Q Q SUR1 Human V L L A T V Q R G E L R L E SUR2 Human V L H T Q V Q R G E I N L P Pgp Human - - - - - E K S G A G R R Q YCF1 Saccharomyces cervisiae A I L V T V K L G K S Y R G Mrp1 Caenorhabditis elegans T L D F L I R T G R G L R K Mrp2 Caenorhabditis elegans T F D I L I K T G R G I R K AtMRP2 Arabidopsis thaliana Q L R W L M S P G R R K R E AtMRP1 Arabidopsis thaliana H T A V L M S P G R R K R E a Aligned using Clustal W (http://pbil.univ-lyon1.fr/). Login to comment

[hide] Genetic variations and haplotype structures of the... Drug Metab Pharmacokinet. 2007 Feb 25;22(1):48-60. Fukushima-Uesaka H, Saito Y, Tohkin M, Maekawa K, Hasegawa R, Kawamoto M, Kamatani N, Suzuki K, Yanagawa T, Kajio H, Kuzuya N, Yasuda K, Sawada J
Genetic variations and haplotype structures of the ABC transporter gene ABCC1 in a Japanese population.
Drug Metab Pharmacokinet. 2007 Feb 25;22(1):48-60., 2007-02-25 [PMID:17329911]

Abstract [show]
Multidrug resistance-related protein 1 (MRP1), an ATP-binding cassette transporter encoded by the ABCC1 gene, is expressed in many tissues, and functions as an efflux transporter for glutathione-, glucuronate- and sulfate-conjugates as well as unconjugated substrates. In this study, the 31 exons and their flanking introns of ABCC1 were comprehensively screened for genetic variations in 153 Japanese subjects to elucidate the linkage disequilibrium (LD) profiles and haplotype structures of ABCC1 that is necessary for pharmacogenetic studies of the substrate drugs. Eighty-six genetic variations including 31 novel ones were found: 1 in the 5'-flanking region, 1 in the 5'-untranslated region (UTR), 20 in the coding exons (9 synonymous and 11 nonsynonymous variations), 4 in the 3'-UTR, and 60 in the introns. Of these, eight novel nonsynonymous variations, 726G>T (Trp242Cys), 1199T>C (Ile400Thr), 1967G>C (Ser656Thr), 2530G>A (Gly844Ser), 3490G>A (Val1164Ile), 3550G>A (Glu1184Lys), 3901C>T (Arg1301Cys), and 4502A>G (Asp1501Gly), were detected with an allele frequency of 0.003. Based on the LD profiles, the analyzed regions of the gene were divided into five LD blocks (Blocks -1 and 1 to 4). The multiallelic repeat polymorphism in the 5'-UTR was defined as Block -1. For Blocks 1, 2, 3 and 4, 32, 23, 23 and 13 haplotypes were inferred, and 9, 7, 7 and 6 haplotypes commonly found on > or = 10 chromosomes accounted for > or = 91% of the inferred haplotypes in each block. Haplotype-tagging single nucleotide polymorphisms for each block were identified to capture the common haplotypes. This study would provide fundamental and useful information for the pharmacogenetic studies of MRP1-dependently effluxed drugs in Japanese.

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26 In Caucasian populations, 1299GÀT (Arg433Ser), 1898GÀA (Arg633Gln), 2012GÀT (Gly671Val), and 4535CÀT (Ser1512Leu) have been reported.79) In addition, Arg433Ser decreases the transport activity for LTC4 and estrone sulfate, but not for estradiol 17b-glucuronide, in vitro.10) Ito et al. found 16 genetic polymorphisms, including 4 nonsynonymous and 8 synonymous ones, in 48 Japanese subjects.11) An in vitro functional study showed that one of the non-synonymous variations, 2168GÀA (Arg723Gln), leads to reduced transport activity for LTC4, estradiol 17b-glucuronide and methotrexate.12) However, no haplotype analysis has been reported for the Japanese population. Login to comment
69 We also detected three known nonsynonymous variations, 218CÀT (Thr73Ile), 2168GÀA (Arg723Gln), and 3173GÀA (Arg1058Gln) at frequencies of 0.007, 0.065 and 0.003, respectively. These frequencies were similar to those found in the earlier reports for Japanese11) and Chinese.21) One of the variations, Arg723Gln, leads to reduced transport activities for LTC4, estradiol 17b-glucuronide and methotrexate.12) We did not detect three previously reported variations: 2012GÀT (Gly671Val; found with approximately 0.03 frequency in Caucasians), 3140GÀC (Cys1047Ser; 0.05 in African-Americans), and 4535CÀT (Ser1512Leu; 0.03 in Caucasians).8,9,12) These SNPs might be ethnic- specic. Login to comment

[hide] Xenobiotic, bile acid, and cholesterol transporter... Pharmacol Rev. 2010 Mar;62(1):1-96. Epub 2010 Jan 26. Klaassen CD, Aleksunes LM
Xenobiotic, bile acid, and cholesterol transporters: function and regulation.
Pharmacol Rev. 2010 Mar;62(1):1-96. Epub 2010 Jan 26., [PMID:20103563]

Abstract [show]
Transporters influence the disposition of chemicals within the body by participating in absorption, distribution, and elimination. Transporters of the solute carrier family (SLC) comprise a variety of proteins, including organic cation transporters (OCT) 1 to 3, organic cation/carnitine transporters (OCTN) 1 to 3, organic anion transporters (OAT) 1 to 7, various organic anion transporting polypeptide isoforms, sodium taurocholate cotransporting polypeptide, apical sodium-dependent bile acid transporter, peptide transporters (PEPT) 1 and 2, concentrative nucleoside transporters (CNT) 1 to 3, equilibrative nucleoside transporter (ENT) 1 to 3, and multidrug and toxin extrusion transporters (MATE) 1 and 2, which mediate the uptake (except MATEs) of organic anions and cations as well as peptides and nucleosides. Efflux transporters of the ATP-binding cassette superfamily, such as ATP-binding cassette transporter A1 (ABCA1), multidrug resistance proteins (MDR) 1 and 2, bile salt export pump, multidrug resistance-associated proteins (MRP) 1 to 9, breast cancer resistance protein, and ATP-binding cassette subfamily G members 5 and 8, are responsible for the unidirectional export of endogenous and exogenous substances. Other efflux transporters [ATPase copper-transporting beta polypeptide (ATP7B) and ATPase class I type 8B member 1 (ATP8B1) as well as organic solute transporters (OST) alpha and beta] also play major roles in the transport of some endogenous chemicals across biological membranes. This review article provides a comprehensive overview of these transporters (both rodent and human) with regard to tissue distribution, subcellular localization, and substrate preferences. Because uptake and efflux transporters are expressed in multiple cell types, the roles of transporters in a variety of tissues, including the liver, kidneys, intestine, brain, heart, placenta, mammary glands, immune cells, and testes are discussed. Attention is also placed upon a variety of regulatory factors that influence transporter expression and function, including transcriptional activation and post-translational modifications as well as subcellular trafficking. Sex differences, ontogeny, and pharmacological and toxicological regulation of transporters are also addressed. Transporters are important transmembrane proteins that mediate the cellular entry and exit of a wide range of substrates throughout the body and thereby play important roles in human physiology, pharmacology, pathology, and toxicology.

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7118 Nucleotide Change Amino Acid Change In Vitro Function Protein Expression/Localization ABCC1 MRP1 G128C C43S 1↔ Intracellular C218T T73I 1↔ Normal C257T S92F 2↔ Normal C350T T117M 2↔ Normal G689A R230Q ↔ Normal G1057A V353M N.D. N.D. G1299T R433S 2↔ Normal G1898A R633Q 2↔ Normal G2012T G671V ↔ Normal G2168A R723Q 2 Normal G2965A A989T 2↔ Normal G3140C C1047S 1↔ Normal G3173A R1058Q ↔ Normal C4535T S1512L ↔ Normal ABCC2 MRP2 C-24T N.D. N.D. G1058A R353H N.D. N.D. G1249A V417I ↔ Normal C2366T S789F 12 Intracellular T2780G L927R N.D. N.D. C3298T R1100C N.D. N.D. G3299A R1100H N.D. N.D. T3563A V1188E N.D. N.D. G4348A A1450T ↔ Normal/Intracellular G4544A C1515Y N.D. N.D. ABCC3 MRP3 G32A G11D ↔ Normal C202T H68Y N.D. N.D. G296A R99Q N.D. Normal C1037T S346F 2 Normal C1537A Q513K N.D. N.D. T1643A L548Q N.D. N.D. G1820A S607N 2 Normal C2221T Gln741STOP N.D. N.D. G2293C V765L ↔ Normal G2395A V799M N.D. N.D. C2758T P920S 1 Normal G2768A R923Q 1 Normal C3657A S1219R N.D. N.D. C3856G R1286G ↔ Normal G3890A R1297H N.D. N.D. C4042T R1348C 1 Normal A4094G Q1365R ↔ Normal C4141A R1381S ↔ Intracellular C4217T T1406M N.D. N.D. G4267A G1423R N.D. N.D. ABCC4 MRP4 C52A L18I N.D. N.D. C232G P78A 2↔ Normal T551C M184T N.D. N.D. G559T G187W 2 Reduced A877G K293E ↔ Normal G912T K304N ↔ Normal C1067T T356M N.D. N.D. C1208T P403L 2↔ Normal G1460A G487E 2 Normal A1492G K498E ↔ Normal A1875G I625M N.D. N.D. C2000T P667L N.D. N.D. A2230G M744V ↔ Normal G2269A E757K N.D. Intracellular G2459T R820I N.D. N.D. G2560T V854F N.D. N.D. G2698T V900L N.D. N.D. G2867C C956S 1↔ Normal G3211A V1071I ↔ Normal C3425T T1142M N.D. N.D. G3659A R1220Q N.D. N.D. A3941G Q1314R N.D. N.D. 2, reduced function; 1, increased function; ↔, no change in function; N.D. not determined. Login to comment
7115 Nucleotide Change Amino Acid Change In Vitro Function Protein Expression/Localization ABCC1 MRP1 G128C C43S 1࢒ Intracellular C218T T73I 1࢒ Normal C257T S92F 2࢒ Normal C350T T117M 2࢒ Normal G689A R230Q ࢒ Normal G1057A V353M N.D. N.D. G1299T R433S 2࢒ Normal G1898A R633Q 2࢒ Normal G2012T G671V ࢒ Normal G2168A R723Q 2 Normal G2965A A989T 2࢒ Normal G3140C C1047S 1࢒ Normal G3173A R1058Q ࢒ Normal C4535T S1512L ࢒ Normal ABCC2 MRP2 C-24T N.D. N.D. G1058A R353H N.D. N.D. G1249A V417I ࢒ Normal C2366T S789F 12 Intracellular T2780G L927R N.D. N.D. C3298T R1100C N.D. N.D. G3299A R1100H N.D. N.D. T3563A V1188E N.D. N.D. G4348A A1450T ࢒ Normal/Intracellular G4544A C1515Y N.D. N.D. ABCC3 MRP3 G32A G11D ࢒ Normal C202T H68Y N.D. N.D. G296A R99Q N.D. Normal C1037T S346F 2 Normal C1537A Q513K N.D. N.D. T1643A L548Q N.D. N.D. G1820A S607N 2 Normal C2221T Gln741STOP N.D. N.D. G2293C V765L ࢒ Normal G2395A V799M N.D. N.D. C2758T P920S 1 Normal G2768A R923Q 1 Normal C3657A S1219R N.D. N.D. C3856G R1286G ࢒ Normal G3890A R1297H N.D. N.D. C4042T R1348C 1 Normal A4094G Q1365R ࢒ Normal C4141A R1381S ࢒ Intracellular C4217T T1406M N.D. N.D. G4267A G1423R N.D. N.D. ABCC4 MRP4 C52A L18I N.D. N.D. C232G P78A 2࢒ Normal T551C M184T N.D. N.D. G559T G187W 2 Reduced A877G K293E ࢒ Normal G912T K304N ࢒ Normal C1067T T356M N.D. N.D. C1208T P403L 2࢒ Normal G1460A G487E 2 Normal A1492G K498E ࢒ Normal A1875G I625M N.D. N.D. C2000T P667L N.D. N.D. A2230G M744V ࢒ Normal G2269A E757K N.D. Intracellular G2459T R820I N.D. N.D. G2560T V854F N.D. N.D. G2698T V900L N.D. N.D. G2867C C956S 1࢒ Normal G3211A V1071I ࢒ Normal C3425T T1142M N.D. N.D. G3659A R1220Q N.D. N.D. A3941G Q1314R N.D. N.D. 2, reduced function; 1, increased function; ࢒, no change in function; N.D. not determined. Login to comment

[hide] Identification of novel polymorphisms in the pM5 a... Hum Mutat. 2001;17(1):74-5. Perdu J, Germain DP
Identification of novel polymorphisms in the pM5 and MRP1 (ABCC1) genes at locus 16p13.1 and exclusion of both genes as responsible for pseudoxanthoma elasticum.
Hum Mutat. 2001;17(1):74-5., [PMID:11139250]

Abstract [show]
Pseudoxanthoma elasticum (PXE) is an inherited systemic disorder of connective tissue, characterized by progressive calcification of the elastic fibers in the eye, the skin, and the cardiovascular system. The PXE locus has been mapped to chromosome 16p13.1, and was recently further refined to a 500 kb-region, containing four candidate genes : MRP1 (ABCC1), MRP6 (ABCC6), pM5, and two copies of an unknown gene, the later we subsequently found to be identical to the gene encoding the Nuclear Pore Interacting Protein (NPIP). In a comprehensive mutational screening, we have analysed the entire coding region of the pM5, MRP1, and NPIP genes in 7 patients affected with pseudoxanthoma elasticum, but failed to find evidence of disease-causing defects in any of these three genes. Five synonymous (G232G, P395P, A862A, G912G, D1106D), and five non synonymous (V404I, N458K, D490N, F1141I, G1195R) polymorphisms were found in the pM5 gene, for which we also corrected errors in the published cDNA sequence. Analysis of the MRP1 transcript lead to the discovery of two polymorphisms (T117M, S1512L). No variant was evidenced during our screening of the NPIP gene. Our data exclude the responsibility of the pM5, MRP1 and NPIP genes in PXE, and strongly suggest that mutations in the last remaining candidate gene, MRP6, which encodes a 1503 amino-acid ABC membrane transporter, are the genetic defect responsible for PXE.

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5 Analysis of the MRP1 transcript lead to the discovery of two polymorphisms (T117M, S1512L). Login to comment
50 Allele designation Codon change Predicted amino acid change Frequency in population* pM5 gene c696C>G GGC > GGG G232G 0.50 c1185A>G CCA > CCG P395P 0.50 c1210G>A GTT > ATT V404I 0.50 c1374C>A AAC > AAA N458K 0.22 c1468G>A GAC > AAC D490N 0.16 c2586G>A GCG > GCA A862A 0.50 c2736A>C GGA > GGC G912G 1 c3318T>C GAT > GAC D1106D ND c3421T>A TTC > ATC F1141I 1 c3583G>C GGC > CGC G1195R 0.50 MRP1 gene c350T>C ACG > ATG T117M 1 c4535C>T TCG > CAG S1512L ND *based on screening of 25 normal control individuals, ND: not determined. Login to comment
62 Another C to T transition was detected at position 4535 in the cDNA sequence, changing the codon (TCG) for serine to the codon (TTG) for leucine (S1512L). Login to comment

[hide] Importance of ABCC1 for cancer therapy and prognos... Drug Metab Rev. 2014 Aug;46(3):325-42. doi: 10.3109/03602532.2014.901348. Epub 2014 Mar 26. Kunicka T, Soucek P
Importance of ABCC1 for cancer therapy and prognosis.
Drug Metab Rev. 2014 Aug;46(3):325-42. doi: 10.3109/03602532.2014.901348. Epub 2014 Mar 26., [PMID:24670052]

Abstract [show]
Multidrug resistance presents one of the most important causes of cancer treatment failure. Numerous in vitro and in vivo data have made it clear that multidrug resistance is frequently caused by enhanced expression of ATP-binding cassette (ABC) transporters. ABC transporters are membrane-bound proteins involved in cellular defense mechanisms, namely, in outward transport of xenobiotics and physiological substrates. Their function thus prevents toxicity as carcinogenesis on one hand but may contribute to the resistance of tumor cells to a number of drugs including chemotherapeutics on the other. Within 48 members of the human ABC superfamily there are several multidrug resistance-associated transporters. Due to the well documented susceptibility of numerous drugs to efflux via ABC transporters it is highly desirable to assess the status of ABC transporters for individualization of treatment by their substrates. The multidrug resistance associated protein 1 (MRP1) encoded by ABCC1 gene is one of the most studied ABC transporters. Despite the fact that its structure and functions have already been explored in detail, there are significant gaps in knowledge which preclude clinical applications. Tissue-specific patterns of expression and broad genetic variability make ABCC1/MRP1 an optimal candidate for use as a marker or member of multi-marker panel for prediction of chemotherapy resistance. The purpose of this review was to summarize investigations about associations of gene and protein expression and genetic variability with prognosis and therapy outcome of major cancers. Major advances in the knowledge have been identified and future research directions are highlighted.

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134 Letourneau et al. (2005) studied the influence of 10 DOI: 10.3109/03602532.2014.901348 ABCC1 and cancer therapy and prognosis non-synonymous SNPs - Cys43Ser (G128C, rs41395947), Thr73Ile (C218T, rs41494447), Ser92Phe (C257T, rs8187844), Thr117Met (C350T, no rs number available), Arg230Gln (G689A, rs8187848), Arg633Gln (G1898A, rs112282109), Arg723Gln (G2168A, rs4148356), Ala989Thr (G2965A, rs35529209), Cys1047Ser (G3140C, rs13337489), Arg1058Gln (G3173A, rs41410450) and Ser1512Leu (C4535T, rs369410659) - on ABCC1 expression using membrane vesicles isolated from transfected cells and assessed transport activity for three known ABCC1 substrates. Login to comment
159 NCBI ID Reference Amino acid exchange Nucleotide exchange Location Function MAFa rs41395947 Cys43Ser G128C Exon 2 Non-synonymous Unknown rs41494447 Thr73Ile C218T Exon 2 Non-synonymous T &#bc; 0.003 rs8187844 Ser92Phe C257T Exon 3 Non-synonymous T &#bc; 0.004 rs8187848 Arg230Gln G689A Exon 7 Non-synonymous A &#bc; 0.009 rs2230669 Pro272Pro G816A Exon 8 Synonymous A &#bc; 0.037 rs246221 Val275Val T825C Exon 8 Synonymous C &#bc; 0.301 rs35592 non-coding T-176C Intron 9 Non-coding C &#bc; 0.257 rs60782127 Arg433Ser G1299T Exon 10 Non-synonymous T &#bc; 0.004 rs35605 Leu562Leu T1684C Exon 13 Synonymous T &#bc; 0.173 rs112282109 Arg633Gln G1898A Exon 14 Non-synonymous A &#bc; 0.004 rs45511401 Gly671Val G2012T Exon 16 Non-synonymous T &#bc; 0.050 rs4148356 Arg723Gln G2168A Exon17 Non-synonymous A &#bc; 0.027 rs35529209 Ala989Thr G2965A Exon 22 Non-synonymous Unknown rs13337489 Cys1047Ser G3140C Exon 23 Non-synonymous C &#bc; 0.000 rs41410450 Arg1058Gln G3173A Exon 23 Non-synonymous Unknown rs2238476 non-coding G-1960A Intron 23 Non-coding T &#bc; 0.062 rs2230671 Ser1334Ser G4002A Exon 28 Synonymous T &#bc; 0.208 rs28364006 Thr1337Ala A4009G Exon 28 Non-synonymous Unknown rs369410659 Ser1512Leu C4535T Exon 31 Non-synonymous Unknown a Minor allele frequencies for Caucasinans in dbSNP based on HapMap-CEU population or 1000 genomes. Login to comment

[hide] Non-coding polymorphisms in nucleotide binding dom... PLoS One. 2014 Jul 31;9(7):e101740. doi: 10.1371/journal.pone.0101740. eCollection 2014. Kunicka T, Vaclavikova R, Hlavac V, Vrana D, Pecha V, Raus K, Trnkova M, Kubackova K, Ambrus M, Vodickova L, Vodicka P, Soucek P
Non-coding polymorphisms in nucleotide binding domain 1 in ABCC1 gene associate with transcript level and survival of patients with breast cancer.
PLoS One. 2014 Jul 31;9(7):e101740. doi: 10.1371/journal.pone.0101740. eCollection 2014., [PMID:25078270]

Abstract [show]
OBJECTIVES: ATP-Binding Cassette (ABC) transporters may cause treatment failure by transporting of anticancer drugs outside of the tumor cells. Multidrug resistance-associated protein 1 coded by the ABCC1 gene has recently been suggested as a potential prognostic marker in breast cancer patients. This study aimed to explore tagged haplotype covering nucleotide binding domain 1 of ABCC1 in relation with corresponding transcript levels in tissues and clinical phenotype of breast cancer patients. METHODS: The distribution of twelve ABCC1 polymorphisms was assessed by direct sequencing in peripheral blood DNA (n = 540). RESULTS: Tumors from carriers of the wild type genotype in rs35623 or rs35628 exhibited significantly lower levels of ABCC1 transcript than those from carriers of the minor allele (p = 0.003 and p = 0.004, respectively). The ABCC1 transcript levels significantly increased in the order CT-GT>CC-GT>CC-GG for the predicted rs35626-rs4148351 diplotype. Chemotherapy-treated patients carrying the T allele in rs4148353 had longer disease-free survival than those with the GG genotype (p = 0.043). On the other hand, hormonal therapy-treated patients with the AA genotype in rs35628 had significantly longer disease-free survival than carriers of the G allele (p = 0.012). CONCLUSIONS: Taken together, our study shows that genetic variability in the nucleotide binding domain 1 has a significant impact on the ABCC1 transcript level in the target tissue and may modify survival of breast cancer patients.

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215 Ten other non-synonymous SNPs leading to amino acid substitutions (Cys43Ser (G128C, rs41395947), Thr73Ile (C218T, rs41494447), Ser92Phe (C257T, rs8187844), Thr117Met (C350T, no rs number available), Arg230Gln (G689A, rs8187848), Arg633Gln (G1898A, rs112282109), Ala989Thr (G2965A, rs35529209), Cys1047Ser (G3140C, rs13337489), Arg1058Gln (G3173A, rs41410450), and Ser1512Leu (C4535T, rs369410659)) followed earlier had no effect on ABCC1 expression either, indicating that single amino acid substitutions may not necessarily influence the activity of the final protein [44]. Login to comment