ABCB1 p.Gly1063Ala
| Predicted by SNAP2: | A: D (71%), C: D (63%), D: D (85%), E: D (80%), F: D (85%), H: D (80%), I: D (80%), K: D (91%), L: D (80%), M: D (80%), N: D (71%), P: D (91%), Q: D (71%), R: D (80%), S: D (71%), T: D (80%), V: D (80%), W: D (85%), Y: D (85%), |
| Predicted by PROVEAN: | A: D, C: D, D: D, E: D, F: D, H: D, I: D, K: D, L: D, M: D, N: D, P: D, Q: D, R: D, S: D, T: D, V: D, W: D, Y: D, |
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[hide] Genetic polymorphisms of ATP-binding cassette tran... Expert Opin Pharmacother. 2005 Nov;6(14):2455-73. Sakurai A, Tamura A, Onishi Y, Ishikawa T
Genetic polymorphisms of ATP-binding cassette transporters ABCB1 and ABCG2: therapeutic implications.
Expert Opin Pharmacother. 2005 Nov;6(14):2455-73., [PMID:16259577]
Abstract [show]
Pharmacogenomics, the study of the influence of genetic factors on drug action, is increasingly important for predicting pharmacokinetics profiles and/or adverse reactions to drugs. Drug transporters, as well as drug metabolism play pivotal roles in determining the pharmacokinetic profiles of drugs and their overall pharmacological effects. There is an increasing number of reports addressing genetic polymorphisms of drug transporters. However, information regarding the functional impact of genetic polymorphisms in drug transporter genes is still limited. Detailed functional analysis in vitro may provide clear insight into the biochemical and therapeutic significance of genetic polymorphisms. This review addresses functional aspects of the genetic polymorphisms of human ATP-binding cassette transporters, ABCB1 and ABCG2, which are critically involved in the pharmacokinetics of drugs.
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No. Sentence Comment
115 For this purpose, ABCB1 cDNA cloned from a human liver cDNA library was prepared, and several variant forms (i.e., N183S, S400N, R492C, R669C, I849M, A893T, M986V, A999T, P1051A and G1063A) were generated by site-directed mutagenesis.
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ABCB1 p.Gly1063Ala 16259577:115:182
status: NEW124 The variant forms (i.e., N183S, S400N, R492C, R669C, I849M, A893T, M986V, A999T, P1051A and G1063A), as well as the wild type, of ABCB1 exhibited the verapamil-enhanced ATPase activity.
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ABCB1 p.Gly1063Ala 16259577:124:92
status: NEW129 N21D M89T N44S H2N F103L E108K N183S G185V I261V S400N R492C A599T L662R R669C V801M A893S/T I829V I849M M986V A999T G1063A P1051A Q1107P W1108R I1145M S1141T V1251I T1256K COOH ATP-binding site ATP-binding site EXTRACELLULAR INTRACELLULAR A80E Figure 2.
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ABCB1 p.Gly1063Ala 16259577:129:117
status: NEW[hide] High-speed screening of human ATP-binding cassette... Methods Enzymol. 2005;400:485-510. Ishikawa T, Sakurai A, Kanamori Y, Nagakura M, Hirano H, Takarada Y, Yamada K, Fukushima K, Kitajima M
High-speed screening of human ATP-binding cassette transporter function and genetic polymorphisms: new strategies in pharmacogenomics.
Methods Enzymol. 2005;400:485-510., [PMID:16399366]
Abstract [show]
Drug transporters represent an important mechanism in cellular uptake and efflux of drugs and their metabolites. Hitherto a variety of drug transporter genes have been cloned and classified into either solute carriers or ATP-binding cassette (ABC) transporters. Such drug transporters are expressed in various tissues such as the intestine, brain, liver, kidney, and, importantly, cancer cells, where they play critical roles in the absorption, distribution, and excretion of drugs. We developed high-speed functional screening and quantitative structure-activity relationship analysis methods to study the substrate specificity of ABC transporters and to evaluate the effect of genetic polymorphisms on their function. These methods would provide powerful and practical tools for screening synthetic and natural compounds, and the deduced data can be applied to the molecular design of new drugs. Furthermore, we demonstrate a new "SNP array" method to detect genetic polymorphisms of ABC transporters in human samples.
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167 For this purpose, we have prepared several variant forms (i.e., N183S, S400N, R492C, R669C, I849M, A893T, M986V, A999T, P1051A, and G1063A) by site‐ directed mutagenesis.
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ABCB1 p.Gly1063Ala 16399366:167:132
status: NEW[hide] Clinical pharmacogenetics and potential applicatio... Curr Drug Metab. 2008 Oct;9(8):738-84. Zhou SF, Di YM, Chan E, Du YM, Chow VD, Xue CC, Lai X, Wang JC, Li CG, Tian M, Duan W
Clinical pharmacogenetics and potential application in personalized medicine.
Curr Drug Metab. 2008 Oct;9(8):738-84., [PMID:18855611]
Abstract [show]
The current 'fixed-dosage strategy' approach to medicine, means there is much inter-individual variation in drug response. Pharmacogenetics is the study of how inter-individual variations in the DNA sequence of specific genes affect drug responses. This article will highlight current pharmacogenetic knowledge on important drug metabolizing enzymes, drug transporters and drug targets to understand interindividual variability in drug clearance and responses in clinical practice and potential use in personalized medicine. Polymorphisms in the cytochrome P450 (CYP) family may have had the most impact on the fate of pharmaceutical drugs. CYP2D6, CYP2C19 and CYP2C9 gene polymorphisms and gene duplications account for the most frequent variations in phase I metabolism of drugs since nearly 80% of drugs in use today are metabolised by these enzymes. Approximately 5% of Europeans and 1% of Asians lack CYP2D6 activity, and these individuals are known as poor metabolizers. CYP2C9 is another clinically significant drug metabolising enzyme that demonstrates genetic variants. Studies into CYP2C9 polymorphism have highlighted the importance of the CYP2C9*2 and CYP2C9*3 alleles. Extensive polymorphism also occurs in a majority of Phase II drug metabolizing enzymes. One of the most important polymorphisms is thiopurine S-methyl transferases (TPMT) that catalyzes the S-methylation of thiopurine drugs. With respect to drug transport polymorphism, the most extensively studied drug transporter is P-glycoprotein (P-gp/MDR1), but the current data on the clinical impact is limited. Polymorphisms in drug transporters may change drug's distribution, excretion and response. Recent advances in molecular research have revealed many of the genes that encode drug targets demonstrate genetic polymorphism. These variations, in many cases, have altered the targets sensitivity to the specific drug molecule and thus have a profound effect on drug efficacy and toxicity. For example, the beta (2)-adrenoreceptor, which is encoded by the ADRB2 gene, illustrates a clinically significant genetic variation in drug targets. The variable number tandem repeat polymorphisms in serotonin transporter (SERT/SLC6A4) gene are associated with response to antidepressants. The distribution of the common variant alleles of genes that encode drug metabolizing enzymes, drug transporters and drug targets has been found to vary among different populations. The promise of pharmacogenetics lies in its potential to identify the right drug at the right dose for the right individual. Drugs with a narrow therapeutic index are thought to benefit more from pharmacogenetic studies. For example, warfarin serves as a good practical example of how pharmacogenetics can be utilized prior to commencement of therapy in order to achieve maximum efficacy and minimum toxicity. As such, pharmacogenetics has the potential to achieve optimal quality use of medicines, and to improve the efficacy and safety of both prospective and licensed drugs.
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No. Sentence Comment
532 Nucleotide change rs number Amino acid change 49T>C rs28381804 F17L 61A>G rs61615398; rs9282564 N21D 131A>G rs1202183 N44S 178A>C rs41315618 I60L 239C>A rs9282565 A80E 266T>C Rs35810889 M89T 431T>C rs61607171 I144T 502G>A rs61122623 V168I 548A>G rs60419673 N183S 554G>T rs1128501 G185V 781A>G rs36008564 I261V 1199G>A rs2229109 S400N 1696G>A rs28381902 E566K 1777C>T rs28381914 R593C 1778G>A rs56107566 R593H 1795G>A rs2235036 A599T 1837G>T rs57001392 D613Y 1985T>G rs61762047 L662R 2005C>T rs35023033 R669C 2207A>T rs41316450 I736K 2398G>A rs41305517 D800N 2401G>A rs2235039 V801M 2485A>G rs2032581 I829V 2506A>G rs28381967 I836V 2547A>G rs36105130 I849M 2677T>A/G rs2032582 S893A/T 2975G>A rs56849127 S992N 3151C>G rs28401798 P1051A 3188G>C rs2707944 G1063A 3262G>A rs57521326 D1088N 3295A>G rs41309225 K1099E 3320A>C rs55852620 Q1107P 3322T>C rs35730308 W1108R 3410G>T rs41309228 S1137I 3421T>A rs2229107 S1141T 3502A>G rs59241388 K1168E 3669A>T rs41309231 E1223D 3751G>A rs28364274 V1251I 3767C>A r35721439 T1256K Data are from NCBI dbSNP (access date: 2 August 2008).
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ABCB1 p.Gly1063Ala 18855611:532:753
status: NEW[hide] Quantitative structure--activity relationship anal... Biochemistry. 2007 Jul 3;46(26):7678-93. Epub 2007 Jun 9. Sakurai A, Onishi Y, Hirano H, Seigneuret M, Obanayama K, Kim G, Liew EL, Sakaeda T, Yoshiura K, Niikawa N, Sakurai M, Ishikawa T
Quantitative structure--activity relationship analysis and molecular dynamics simulation to functionally validate nonsynonymous polymorphisms of human ABC transporter ABCB1 (P-glycoprotein/MDR1).
Biochemistry. 2007 Jul 3;46(26):7678-93. Epub 2007 Jun 9., 2007-07-03 [PMID:17559192]
Abstract [show]
Several preclinical and clinical studies suggest the importance of naturally occurring polymorphisms of drug transporters in the individual difference of drug response. To functionally validate the nonsynonymous polymorphisms of ABCB1 (P-glycoprotein/MDR1) in vitro, we generated SNP variant forms (i.e., S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A) and expressed them in Sf9 cells. The kinetic properties (Km and Vmax) of those variants were analyzed by measuring the ATPase activity to obtain the ATPase profile for each variant toward structurally unrelated substrates. On the basis of the experimental data, we determined the substrate specificity of ABCB1 WT and its variants by the quantitative structure-activity relationship (QSAR) analysis method. While several SNP variants appeared to influence the substrate specificity of ABCB1, the nonsynonymous polymorphisms of 2677G > T, A, or C at amino acid position 893 (Ala > Ser, Thr, or Pro) have great impacts on both the activity and the substrate specificity of ABCB1. The A893P variant (2677G > C), a rare mutation, exhibited markedly high activity of ATPase toward different test compounds. Molecular dynamics (MD) simulation based on a three-dimensional structural model of human ABCB1 revealed that multiple kinks are formed in the intracellular loop between transmembrane domains 10 and 11 of the A893P variant (2677G > C) protein. The polymorphisms of 2677G, 2677T, and 2677A exhibit wide ethnic differences in the allele frequency, and these nonsynonymous polymorphisms are suggested to be clinically important because of their altered ATPase activity and substrate specificity toward different drugs.
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No. Sentence Comment
1 To functionally validate the nonsynonymous polymorphisms of ABCB1 (P-glycoprotein/MDR1) in vitro, we generated SNP variant forms (i.e., S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A) and expressed them in Sf9 cells.
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ABCB1 p.Gly1063Ala 17559192:1:211
status: NEW38 For this purpose, ABCB1 cDNA cloned from a human liver cDNA library was prepared, and several variant forms (i.e., S400N, R492C, R669C, I849M, A893S, A893T, A893P, M986V, A999T, P1051A, and G1063A) were generated by site-directed mutagenesis.
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ABCB1 p.Gly1063Ala 17559192:38:190
status: NEW53 SNP data were obtained from the NCBI dbSNP database and recent publications: S400N (6, 7, 29, 31); R492C (7); R669C (16); I849M (16); A893P (NCBI dbSNP, rs2032582); A893S (8, 16, 23, 29-31); A893T (8, 16, 23, 29-31); M986V (30); A999T (28); P1051A (16); G1063A (NCBI dbSNP, rs2707944).
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ABCB1 p.Gly1063Ala 17559192:53:254
status: NEW80 Briefly, seventy-two hours after Table 1: Data on Oligonucleotide Primers Used for Site-Directed Mutagenesis and Experimental Conditionsa SNP amino acid cDNA F/R primers primer sequence (5' f 3') primer length (bases) % GC Tm (°C) S400N 1199G > A F CAGAAATGTTCACTTCAATTACCCATCTCGAAAAG 35 36.5 77.2 R CTTTTCGAGATGGGTAATTGAAGTGAACATTTCTG 35 36.5 77.2 R492C 1474C > T F TGAAAACATTCGCTATGGCTGTGAAAATGTCACCATGG 38 42.1 81.0 R CCATGGTGACATTTTCACAGCCATAGCGAATGTTTTCA 38 42.1 81.0 R669C 2005C > T F TCTAATAAGAAAAAGATCAACTTGTAGGAGTGTCCGTGGATC 42 37.9 80.9 R GATCCACGGACACTCCTACAAGTTGATCTTTTTCTTATTAGA 42 37.9 80.9 I849M 2547A > G F GGGACAGGAATAATTATGTCCTTCATCTATGGTTGGCA 38 34.5 77.9 R TGCCAACCATAGATGAAGGACATAATTATTCCTGTCCC 38 34.5 77.9 A893P 2677G > C F AGAAAGAACTAGAAGGTCCTGGGAAGATCGCTAC 34 47.1 80.9 R GTAGCGATCTTCCCAGGACCTTCTAGTTCTTTCT 34 47.1 80.9 A893S 2677G > T F GAAAGAACTAGAAGGTTCTGGGAAGATCGCTAC 33 45.4 79.6 R GTAGCGATCTTCCCAGAACCTTCTAGTTCTTTC 33 45.4 79.6 A893T 2677G > A F GAAAGAACTAGAAGGTACTGGGAAGATCGCTAC 33 45.4 79.6 R GTAGCGATCTTCCCAGTACCTTCTAGTTCTTTC 33 45.4 79.6 M986V 2956A > G F GTCTTTGGTGCCGTGGCCGTGGGGC 25 73.8 84.7 R GCCCCACGGCCACGGCACCAAAGAC 25 73.8 84.7 A999T 2995G > A F GTTCATTTGCTCCTGACTATACCAAAGCCAAAATATCAGCAG 42 40.5 82.0 R CTGCTGATATTTTGGCTTTGGTATAGTCAGGAGCAAATGAAC 42 40.5 82.0 P1051A 3151C > G F CGACCGGACATCGCAGTGCTTCAGGG 26 60.0 80.1 R CCCTGAAGCACTGCGATGTCCGGTCG 26 60.0 80.1 G1063A 3188G > C F GAGGTGAAGAAGGCCCAGACGCTGGCTC 28 64.3 83.7 R GAGCCAGCGTCTGGGCCTTCTTCACCTC 28 64.3 83.7 a F, forward; R, reverse.
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ABCB1 p.Gly1063Ala 17559192:80:1409
status: NEW142 On the basis of the ABCB1 (WT) cDNA cloned from a human liver cDNA library, those variant forms (i.e., S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A) were generated by site-directed mutagenesis as described in Experimental Procedures.
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ABCB1 p.Gly1063Ala 17559192:142:178
status: NEW180 Figure 3 depicts the verapamil-stimulated ATPase activity of ABCB1 WT, S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A, where the verapamil-stimulated ATPase activities are normalized by considering the ABCB1 protein amounts.
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ABCB1 p.Gly1063Ala 17559192:180:146
status: NEW184 A893P, I849M, A893T, M986V, and G1063A variants showed higher Vmax values than did the WT, whereas the Vmax value of A893S was lower than that of WT.
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ABCB1 p.Gly1063Ala 17559192:184:32
status: NEW186 Sf9 plasma membranes (2 µg of protein) expressing ABCB1 WT and variants (S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A) were incubated with ATP (2 mM) and verapamil at different concentrations (0, 1, 2, 5, 10, 20, 50, and 100 µM) at 37 °C for 30 min. After the incubation, the amount of liberated phosphate was measured as described in Experimental Procedures. All activities are expressed as mean values ( SD (n ) 6).
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ABCB1 p.Gly1063Ala 17559192:186:153
status: NEW187 Table 2: Km and Vmax Values for ATPase Activity of ABCB1 WT and Variants toward Verapamila SNP Km (µM) Vmax [nmol min-1 (mg of protein)-1 ] Vmax/Km WT 5.8 ( 2.3 62.4 ( 7.8 10.8 S400N 5.8 ( 2.8 46.7 ( 5.3** 8.0 R492C 5.6 ( 1.9 49.6 ( 10.0* 8.9 R669C 3.2 ( 1.6* 64.7 ( 6.9 20.1 I849M 1.5 ( 0.7** 80.3 ( 9.5** 51.8 A893P 1.5 ( 0.5** 405.2 ( 16.5** 274.6 A893S 11.1 ( 5.4 43.1 ( 7.1** 3.9 A893T 4.3 ( 1.4 98.9 ( 9.5** 22.9 M986V 5.1 ( 1.1 114.9 ( 13.6** 22.5 A999T 2.0 ( 0.8** 143.1 ( 21.2** 70.9 P1051A 6.2 ( 3.0 52.1 ( 13.6 8.4 G1063A 6.2 ( 3.7 117.9 ( 16.4** 19.0 a Data are expressed as mean ( SD, n ) 6.
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ABCB1 p.Gly1063Ala 17559192:187:531
status: NEW189 Table 3: Km and Vmax Values for ATPase Activity of ABCB1 WT and Variants toward Nicardipinea SNP Km (µM) Vmax [nmol min-1 (mg of protein)-1 Vmax/Km WT 1.1 ( 0.6 45.2 ( 8.7 41.0 S400N 1.7 ( 0.8 39.1 ( 9.1 23.4 R492C 1.1 ( 0.5 46.6 ( 6.4 43.5 R669C 0.3 ( 0.3** 53.5 ( 13.1 164.6 I849M 0.8 ( 0.9 80.2 ( 9.6** 102.9 A893P 0.1 ( 0.0** 341.2 ( 36.6** 4858.4 A893S 2.0 ( 0.6 39.2 ( 6.0 19.5 A893T 0.4 ( 0.2** 77.0 ( 16.9** 207.8 M986V 0.7 ( 0.4 89.7 ( 17.7** 129.9 A999T 0.3 ( 0.3** 115.4 ( 21.2** 393.6 P1051A 0.9 ( 0.3 33.1 ( 8.8* 36.3 G1063A 0.8 ( 0.4 93.2 ( 27.6** 121.4 a Data are expressed as mean ( SD, n ) 6.
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ABCB1 p.Gly1063Ala 17559192:189:536
status: NEW240 On the other hand, the benzene structure linked to the other ring by a single or double bond (CFC ) M113) negatively contributed to the drug-stimulated ATPase activity of M986V, G1063A, A999T, S400N, and A893S variants and WT, whereas the activity of the other variants was not affected by this structural component.
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ABCB1 p.Gly1063Ala 17559192:240:178
status: NEW269 The present study addresses the impact of nonsynonymous polymorphisms of ABCB1 (i.e., S400N, R492C, R669C, I849M, A893S, A893T, A893P, M986V, A999T, P1051A, and G1063A) on its function.
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ABCB1 p.Gly1063Ala 17559192:269:161
status: NEW273 Table 5: ABCB1 WT and Variant-Specific Descriptors and Corresponding Coefficients Deduced from QSAR Analysisa coefficients (95% reliability) for ABCB1 WT and vatiants descriptor WT S400N R492C R669C I849M A893P A893S A893T M986V A999T P1051A G1063A M532 24.3 21.2 18.5 35.9 52.7 169.8 14.0 61.2 39.4 63.0 13.9 52.1 (3.76) (5.81) (5.87) (7.68) (11.30) (18.84) (4.03) (7.75) (8.76) (9.39) (4.78) (10.94) M132 21.5 14.1 13.6 32.8 61.4 135.6 11.2 52.8 38.2 65.9 7.6 24.3 (3.89) (5.34) (5.78) (6.89) (12.66) (22.95) (4.06) (7.16) (8.62) (8.44) (5.71) (10.46) C-CHN-BT 3.3 3.8 1.7 3.5 5.7 11.6 1.2 6.1 7.1 7.3 2.0 2.8 (0.72) (0.95) (0.87) (1.08) (1.55) (2.48) (0.65) (1.29) (1.43) (1.44) (0.66) (1.86) ESTR -10.1 -12.5 (4.93) (5.00) OH-Ar -6.4 (4.03) R-CC 16.1 -4.4 (7.86) (1.73) RT -8.9 -17.7 (4.21) (8.22) -O-Ar 5.7 (3.67) D012 5.5 (4.10) G010 -15.4 (9.59) H100 4.9 (3.59) H181 -7.3 (5.04) H421 14.6 (6.84) H521 14.1 (10.42) M113 -5.8 -11.7 -7.7 -22.8 -16.4 -16.5 (3.69) (5.30) (3.70) (8.75) (8.19) (10.58) M232 -14.5 (9.38) M280 4.8 (2.65) M313 -5.2 (3.18) M332 -5.0 (3.11) M370 4.2 (3.14) M372 10.0 14.4 (5.46) (7.91) M392 73.3 10.3 (25.03) (6.38) M531 -5.1 (3.05) M540 15.8 (11.27) H7 7.3 24.0 (4.01) (10.91) H8 10.7 (4.74) L1 -6.7 (2.52) L9 13.8 (6.93) constant -12.2 -5.5 -0.2 -2.3 -24.0 -7.1 1.3 -4.3 0.9 9.0 0.6 -11.2 R2 0.934 0.847 0.853 0.906 0.893 0.981 0.782 0.954 0.915 0.956 0.836 0.831 FO(6, 29) 68.9 26.8 28.1 46.4 40.5 254.5 17.3 100.3 51.8 106.2 24.6 23.7 Q2 0.883 0.710 0.767 0.729 0.826 0.968 0.572 0.923 0.828 0.909 0.617 0.760 a R2 , correlation coefficient; FO, Fisher value (level of statistical significance).
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ABCB1 p.Gly1063Ala 17559192:273:242
status: NEW293 The values of those coefficients for WT and SNP variants (i.e., S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A) are the same as those shown in Table 5.
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ABCB1 p.Gly1063Ala 17559192:293:139
status: NEW316 Other nonsynonymous polymorphisms, such as S400N, R492C, R669C, P1051A, and G1063A occurring in intracellular loops as well as I849M, M986V, and A999T alterations in transmembrane domains, exhibited moderate changes in the kinetic properties of ABCB1.
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ABCB1 p.Gly1063Ala 17559192:316:76
status: NEW340 of samples allele frequency (%) allele frequency (%) ref S400N 1199 G > A African 111 G 100.0 A 0.0 23 African-American 100 G 99.0 A 1.0 16 German 461 G 94.5 A 5.5 29 Caucasian 85 G 87.1 A 12.9 6 Caucasian 50 G 98.0 A 2.0 31 Caucasian 100 G 97.5 A 2.5 16 Mexican-American 10 G 100.0 A 0.0 16 Asian-American 30 G 100.0 A 0.0 16 Pacific Islander 7 G 100.0 A 0.0 16 R492C 1474 C > T African-American 23 C 100.0 T 0.0 7 Caucasian 37 C 98.6 T 1.4 7 R669C 2005 C > T African-American 100 C 99.0 T 1.0 16 Caucasian 100 C 100.0 T 0.0 16 Mexican-American 10 C 100.0 T 0.0 16 Asian-American 30 C 100.0 T 0.0 16 Pacific Islander 7 C 100.0 T 0.0 16 I849M 2547 A > G African-American 100 C 100.0 T 0.0 16 Caucasian 100 C 99.5 T 0.5 16 Mexican-American 10 C 100.0 T 0.0 16 Asian-American 30 C 100.0 T 0.0 16 Pacific Islander 7 C 100.0 T 0.0 16 A893P/S/T 2677 G > T/A/C African (Beninese) 111 G 99.1 T 0.9 23 A 0.0 African-American 100 G 89.5 T 10.0 16 A 0.5 Caucasian 100 G 50.0 T 46.5 16 A 3.5 Caucasian 50 G 52.0 T 38.0 31 A 10.0 German 461 G 56.5 T 41.6 29 A 1.9 Mexican-American 10 G 60.0 T 40.0 16 A 0.0 Asian-American 30 G 33.3 T 45.0 16 A 21.7 Japanese 117 G 44.0 T 35.5 8 A 20.5 Japanese (placenta) 100 G 43.0 T 39.0 30 A 18.0 Japanese 48 G 36.5 T 41.7 30 A 21.8 Pacific Islander 7 G 28.6 T 35.7 16 A 35.7 ND ND G ND C ND NCBI dbSNP (rs2032582) M986V 2956 A > G Japanese (placenta) 100 A 99.5 G 0.5 30 Japanese 48 A 100.0 G 0.0 30 A999T 2995 G > A cell lines 36 G 94.4 A 5.6 28 P1051A 3151 C > G African-American 100 C 99.5 G 0.5 16 Caucasian 100 C 100.0 G 0.0 16 Mexican-American 10 C 100.0 G 0.0 16 Asian-American 30 C 100.0 G 0.0 16 Pacific Islander 7 C 100.0 G 0.0 16 G1063A 3188 G > A ND ND G ND A ND NCBI dbSNP (rs2707944) a ND, not determined.
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ABCB1 p.Gly1063Ala 17559192:340:1666
status: NEW[hide] Pharmacogenetics of drug transporters in the enter... Pharmacogenomics. 2011 May;12(5):611-31. Stieger B, Meier PJ
Pharmacogenetics of drug transporters in the enterohepatic circulation.
Pharmacogenomics. 2011 May;12(5):611-31., [PMID:21619426]
Abstract [show]
This article summarizes the impact of the pharmacogenetics of drug transporters expressed in the enterohepatic circulation on the pharmacokinetics and pharmacodynamics of drugs. The role of pharmacogenetics in the function of drug transporter proteins in vitro is now well established and evidence is rapidly accumulating from in vivo pharmacokinetic studies, which suggests that genetic variants of drug transporter proteins can translate into clinically relevant phenotypes. However, a large amount of conflicting information on the clinical relevance of drug transporter proteins has so far precluded the emergence of a clear picture regarding the role of drug transporter pharmacogenetics in medical practice. This is very well exemplified by the case of P-glycoprotein (MDR1, ABCB1). The challenge is now to develop pharmacogenetic models with sufficient predictive power to allow for translation into drug therapy. This will require a combination of pharmacogenetics of drug transporters, drug metabolism and pharmacodynamics of the respective drugs.
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None has been submitted yet.
No. Sentence Comment
91 Gene name Transporter SNP Protein Population size (n) Invitro function Ref. Intestinal uptake transporters SLC15A1 PEPT1 p.P586L 44 Reduced Vmax [81] p.F28Y 247 Increased Km [82] Intestinal efflux transporters ABCB1 MDR1 c.571G>A p.G191R N/A Reduced drug resistance [201] c.1199G>A p.S440N N/A Reduced activity (substrate dependent) [202] c.11199G>A c.1199G>t p.S440N p.S440I N/A N/A Increased drug resistance Reduced drug resistance [203] c.1292-3GT>TG p.C431L N/A Reduced drug resistance [204] c.2005C>T p.R669C N/A Reduced substrate affinity [202] c.2547A>G p.I849M N/A Increased transport activity [202] c.2677G>T p.A893S 60 Lower intracellular digoxin accumulation [205] c.2677G>T c.2677G>A p.A893S p.A893T N/A N/A Unchanged Unchanged [206] c.2677G>T p.A893S 46 No change in rhodamine 123 efflux from peripheral blood lymphocytes [207] c.2667G>T p.A893S N/A Reduced transport function [208] c.2667G>T c.2677G>A p.A893S p.A893T N/A N/A Increased transport function Increased transport function [209] c.2667G>T c.2677G>A p.A893S p.A893T N/A N/A Increased activity (substrate dependent) Increased substrate affinity and transportactivity [202] c.2667G>T p.A893S 48 No change in rhodamine 123 efflux activity in peripheral blood mononuclear cells [210] c.2956A>G p.M986V N/A Increased transport activity [202] c.2995G>A p.A999T N/A Increased substrate affinity and transportactivity [202] c.3151C>G p.P1051A N/A Increased transport activity (substratedependent) [202] c.3188G>C p.G1063A N/A Increased transport activity [202] ABCG2 ABCG2 c.34G>A p.V12M N/A Low transport protein expression invitro [211] c.34G>A p.V12M N/A Unchanged [212] c.34G>A p.V12M N/A No change in HEK-293, lowered transport activity in Sf9 cells invitro [213] c.34G>A p.V12M N/A Unchanged [214] c.421C>A p.Q141K N/A Lower transport protein expression, normal transport activity [212] c.421C>A p.Q141K N/A Reduced drug resistance and lower ATPaseactivity [213] c.421C>A p.Q141K N/A Reduced drug extrusion [215] c.421C>A p.Q141K N/A Reduced drug resistance [216] c.421C>A p.Q141K N/A Unchanged [217] c.421C>A p.Q141K N/A No change of intracellular porphyrin accumulation [218] c.421C>A p.Q141K N/A Reduced transport activity [219] c.421C>A p.Q141K N/A Reduced transport activity [55] c.421C>A p.Q141K N/A Increased Km [220] For more information on members of the SLC superfamily of transporters please consult [301] and for more information of ABC transporters please consult [302].
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ABCB1 p.Gly1063Ala 21619426:91:1481
status: NEW94 Gene name Transporter SNP Protein Population size (n) In vitro function Ref. Intestinal uptake transporters SLC15A1 PEPT1 p.P586L 44 Reduced Vmax [81] p.F28Y 247 Increased Km [82] Intestinal efflux transporters ABCB1 MDR1 c.571G>A p.G191R N/A Reduced drug resistance [201] c.1199G>A p.S440N N/A Reduced activity (substrate dependent) [202] c.11199G>A c.1199G>t p.S440N p.S440I N/A N/A Increased drug resistance Reduced drug resistance [203] c.1292-3GT>TG p.C431L N/A Reduced drug resistance [204] c.2005C>T p.R669C N/A Reduced substrate affinity [202] c.2547A>G p.I849M N/A Increased transport activity [202] c.2677G>T p.A893S 60 Lower intracellular digoxin accumulation [205] c.2677G>T c.2677G>A p.A893S p.A893T N/A N/A Unchanged Unchanged [206] c.2677G>T p.A893S 46 No change in rhodamine 123 efflux from peripheral blood lymphocytes [207] c.2667G>T p.A893S N/A Reduced transport function [208] c.2667G>T c.2677G>A p.A893S p.A893T N/A N/A Increased transport function Increased transport function [209] c.2667G>T c.2677G>A p.A893S p.A893T N/A N/A Increased activity (substrate dependent) Increased substrate affinity and transport activity [202] c.2667G>T p.A893S 48 No change in rhodamine 123 efflux activity in peripheral blood mononuclear cells [210] c.2956A>G p.M986V N/A Increased transport activity [202] c.2995G>A p.A999T N/A Increased substrate affinity and transport activity [202] c.3151C>G p.P1051A N/A Increased transport activity (substrate dependent) [202] c.3188G>C p.G1063A N/A Increased transport activity [202] ABCG2 ABCG2 c.34G>A p.V12M N/A Low transport protein expression in vitro [211] c.34G>A p.V12M N/A Unchanged [212] c.34G>A p.V12M N/A No change in HEK-293, lowered transport activity in Sf9 cells in vitro [213] c.34G>A p.V12M N/A Unchanged [214] c.421C>A p.Q141K N/A Lower transport protein expression, normal transport activity [212] c.421C>A p.Q141K N/A Reduced drug resistance and lower ATPase activity [213] c.421C>A p.Q141K N/A Reduced drug extrusion [215] c.421C>A p.Q141K N/A Reduced drug resistance [216] c.421C>A p.Q141K N/A Unchanged [217] c.421C>A p.Q141K N/A No change of intracellular porphyrin accumulation [218] c.421C>A p.Q141K N/A Reduced transport activity [219] c.421C>A p.Q141K N/A Reduced transport activity [55] c.421C>A p.Q141K N/A Increased Km [220] For more information on members of the SLC superfamily of transporters please consult [301] and for more information of ABC transporters please consult [302].
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ABCB1 p.Gly1063Ala 21619426:94:1485
status: NEW[hide] An update on ABCB1 pharmacogenetics: insights from... Pharmacogenomics J. 2011 Oct;11(5):315-25. doi: 10.1038/tpj.2011.16. Epub 2011 May 31. Wolf SJ, Bachtiar M, Wang J, Sim TS, Chong SS, Lee CG
An update on ABCB1 pharmacogenetics: insights from a 3D model into the location and evolutionary conservation of residues corresponding to SNPs associated with drug pharmacokinetics.
Pharmacogenomics J. 2011 Oct;11(5):315-25. doi: 10.1038/tpj.2011.16. Epub 2011 May 31., [PMID:21625253]
Abstract [show]
The human ABCB1 protein, (P-glycoprotein or MDR1) is a membrane-bound glycoprotein that harnesses the energy of ATP hydrolysis to drive the unidirectional transport of substrates from the cytoplasm to the extracellular space. As a large range of therapeutic agents are known substrates of ABCB1 protein, its role in the onset of multidrug resistance has been the focus of much research. This role has been of particular interest in the field of pharmacogenomics where genetic variation within the ABCB1 gene, particularly in the form of single nucleotide polymorphisms (SNPs), is believed to contribute to inter-individual variation in ABCB1 function and drug response. In this review we provide an update on the influence of coding region SNPs within the ABCB1 gene on drug pharmacokinetics. By utilizing the crystal structure of the mouse ABCB1 homolog (Abcb1a), which is 87% homologous to the human sequence, we accompany this discussion with a graphical representation of residue location for amino acids corresponding to human ABCB1 coding region SNPs. Also, an assessment of residue conservation, which is calculated following multiple sequence alignment of 11 confirmed sequences of ABCB1 homologs, is presented and discussed. Superimposing a 'heat map' of residue homology to the Abcb1a crystal structure has permitted additional insights into both the conservation of individual residues and the conservation of their immediate surroundings. Such graphical representation of residue location and conservation supplements this update of ABCB1 pharmacogenetics to help clarify the often confounding reports on the influence of ABCB1 polymorphisms on drug pharmacokinetics and response.
Comments [show]
None has been submitted yet.
No. Sentence Comment
48 Four of the 12 associated nsSNPs (E3/61A4G, E5/266C4T, E17/1985T4C and E17/2005C4T) cannot be mapped to the mouse crystal Table 1 Genetic conservation of amino acids corresponding to ABCB1 coding region SNPs 1 - rs28381804 E3/49T>C (F17L) F17 W16 S16 Y17 Y35 F39 - A42 - - G11 - - 2 - rs41304191 E3/55C>T (L19L) L19 M18 M18 I19 G37 P41 - E44 - - L13 - - 3 - rs76199854 E3/57G>A (L19L) L19 M18 M18 I19 G37 P41 - E44 - - L13 - - --51I--64H-34K93N12N02K02K12N)D12N(G>A16/3E4652829sr-4 7.832.8105P12A01K88D61D18T07T55S34G34N44N)S44N(G>A131/5E3812021sr1sn5 6 ns2 rs41315618 E5/178A>C (I60L) I60 I59 I59 A71 I86 A97 G32 G104 K26 N37 L66 27.3 46.6 1.924.6368N75G64N421Y25G711I601I19V97A97A08A)E08A(A>C932/5E5652829sr3sn7 8 - rs35810889 E5/266C>T (M89T) - M89 F89 S85 T96 I112 - - - - - - - - 9 ns4 rs61607171 E7/431T>C (I144T) TM2 I144 I145 I140 V152 N168 I176 A98 A172 L93 V97 L124 36.4 40.9 2.645.45841G121T711V691A221T002S291S671A461V961V861V)I861V(A>G205/7E32622116sr5sn01 11 s1 rs1128500 E8/540C>T (S180S) S180 S181 S176 S188 E204 S212 L136 N208 E129 E133 E160 27.3 42.0 12 ns6 rs60419673 E8/548A>G (N183S) N183 N184 N179 N191 K207 E215 Q139 Q211 K132 A136 S163 27.3 39.9 9.045.54561G831S431F312G141F712G902G391G181G681G581G)V581G(T>G455/8E1058211sr7sn31 14 s2 rs1128502 E8/555A>T (G185G) G185 G186 G181 G193 G209 G217 F141 G213 F134 S138 G165 45.5 40.9 15 s3 rs2235022 E9/729A>G (E243E) E243 E244 E239 E251 E267 E275 I199 Q271 R192 M196 S223 18.2 33.3 16 s4 rs28381867 E9/738G>A (A246A) A246 A247 A242 A254 R270 M278 E202 V274 A195 T199 Y226 9.1 34.5 17 ns8 rs36008564 E9/781A>G (I261V) C-NBD (Internal) I261 I262 I257 V267 I285 I293 V217 I289 I210 H214 I241 36.4 50.3 18 s5 rs80153317 E10/879T>C (I293I) TM5 I293 I294 I289 I301 L317 M325 L249 I321 R242 S246 F273 18.2 36.3 19 ns9 rs2229109 E12/1199G>A (S400N) N-NBD (Internal) S400 S401 S396 N408 T424 Q439 T355 V428 Q348 T350 H386 18.2 60.7 20 s6 rs1128503 E13/1236C>T (G412G) N-NBD (External) G412 G413 G408 G420 G436 K451 D367 N440 D359 N361 D398 27.3 55.9 21 s7 rs35068177 E13/1308A>G (T436T) T436 T437 T432 T44 I460 C475 V391 I464 L383 I385 I422 54.5 64.6 22 s8 rs41311775 E15/1326G>A (R442R) R442 R443 R438 R450 R466 R481 R397 R470 R389 R391 R428 100.0 54.5 23 s9 rs35633772 E15/1617C>T (I539I) I539 I540 I535 I547 I563 I578 I494 I576 L486 I489 I571 90.9 65.8 24 s10 rs60247941 E15/1632C>T (A544A) A544 A545 A540 A552 A568 A583 A499 A581 I491 A494 A576 63.6 65.1 25 s11 rs2235012 E15/1662G>C (L554L) L554 L555 L550 L562 L578 L593 L509 L591 L501 L504 L586 100.0 73.6 26 s12 rs56871767 E15/1674G>A (T558T) T558 T559 T554 T566 T582 T597 T513 T595 T505 T508 T590 100.0 78.7 27 s13 rs59697741 E15/1695C>T (S565S) S565 S566 S561 S573 S589 S604 S520 S602 S512 S515 S597 100.0 75.4 28 ns10 rs28381902 E15/1696G>A (E566K) E566 E567 E562 E574 E590 E605 E521 E603 E513 E516 E598 100.0 76.6 29 ns11 rs28381914 E16/1777C>T (R593C) R593 R594 R589 R601 R617 R632 R548 R630 T540 E543 R627 54.5 67.3 30 ns12 rs56107566 E16/1778G>A (R593H ) R593 R594 R589 R601 R617 R632 R548 R630 T540 E543 R627 54.5 67.3 31 s14 rs28381915 E16/1794C>T (I598I) I598 I599 I594 I606 I622 I637 I553 I635 I545 I548 I632 100.0 65.5 32 ns13 rs2235036 E16/1795G>A (A599T) A599 A600 A595 A607 I623 V638 C554 V636 V546 V549 F633 54.5 63.6 33 ns14 rs57001392 E16/1837G>T (D613Y) N-NBD (External) D613 D614 D609 S621 R637 Q652 E568 N650 R560 N563 D677 45.5 60.5 -0.0637E--807A516E896K496M176E856L366L266L)R266L(C>T5891/71E06975653sr-43 35 - rs35023033 E17/2005C>T (R669C) R669 R670 R665 R678 I702 D705 S662 T715 - - N743 0.0 - 36 - rs59340265 E17/2037C>T (D679D) D679 D680 D675 N688 D712 N715 S632 N725 - - E753 9.1 - 37 ns15 rs41316450 E18/2207T>A (I736K) TM7 I736 I737 V732 I745 M779 I771 V682 I820 I37 L48 V814 72.7 36.7 38 ns16 rs77144566 E19/2281A>C (A761S) TM8 A761 V763 I757 A769 V802 I796 G706 I844 I647 G655 L836 63.6 42.1 39 ns17 rs41305517 E21/2398G>A (D800N) C-NBD (Internal) D800 D801 D796 D808 H841 D835 E745 D883 S108 P112 E875 9.1 45.4 40 ns18 rs2235039 E21/2401G>A (V801M) C-NBD (External) V801 V802 V797 M809 I842 V836 V746 V884 A109 V113 M876 63.6 47.6 2.035.54409L931S531I219S447V468T078I738T528T038I928I)V928I(G>A5842/22E1852302sr91sn14 42 s15 rs28381966 E22/2505A>G (V835V) V835 V836 V831 L843 T876 T870 L780 T918 N141 T145 F911 45.5 33.0 43 ns20 rs28381967 E22/2506A>G (I836V) I836 I837 I832 I844 V877 I871 L781 V919 I142 V146 F911 63.6 28.5 7.448.18429M951M551I239L497I488D098I758I548I058I948I)M948I(G>A7452/22E03150163sr12sn44 45 s16 rs9282563 E22/2650C>T (L884L) L884 L885 L880 K892 V925 M919 R829 E967 R190 K194 I959 27.3 31.2 7.535.54289P302V991V679S838S829C439S109A988S498A398S)T/A398S(A/T>G7762/22E2852302sr22sn64 4.834.631801M203T892V5701F739G7201L5301T0001S889S399S299S)N299S(A>G5792/52E72194865sr32sn74 5.633.729801E903Q503T2801T449V4301Q2401A7001A599A0001A999A)T999A(A>G5992/52E48725527sr42sn84 49 s17 rs2235044 E26/3084G>A (P1028P) P1028 P1029 P1024 P1036 - P1063 P973 V1111 P332 V334 I1117 0.0 33.0 50 ns25 rs28401798 E26/3151C>G (P1051A) P1051 P1052 P1047 K1059 E1093 Q1086 I996 K1135 P355 P357 P1142 18.2 57.6 51 ns26 rs2707944 E26/3188G>C (G1063A) G1063 G1064 G1059 G1071 G1105 G1098 G1008 G1147 G367 G369 K1154 45.5 53.8 52 s18 rs2707943 E26/3189C>G (G1063G) G1063 G1064 G1059 G1071 G1105 G1098 G1008 G1147 G367 G369 K1154 45.5 53.8 53 ns27 rs74755520 E26/3222A>C (C1074W) C-NBD (Internal) C1074 C1075 C1070 C1082 C1116 C1109 S1019 C1158 G378 S380 S1165 63.6 67.8 54 ns28 rs57521326 E26/3262G>A (D1088N) D1088 D1089 D1084 D1096 D1130 D1123 D1033 D1172 D392 D394 D1179 100.0 53.9 55 ns29 rs41309225 E27/3295A>G (K1099E) K1099 K1100 K1095 I1107 S1141 C1134 R1044 V1183 H403 H405 I1237 18.2 38.5 56 ns30 rs55852620 E27/3320A>C (Q1107P) Q1107 Q1108 Q1103 Q1115 E1149 T1142 R1052 N1191 G411 A413 R1245 27.3 43.7 57 ns31 rs35730308 E27/3322T>C (W1108R) W1108 Q1109 W1104 Q1116 H1150 N1143 S1053 D1192 S412 S414 D1246 27.3 43.5 58 s19 rs34748655 E27/3396C>T (A1132A) C-NBD (Internal) A1132 A1133 A1128 A1140 I1174 S1167 M1077 V1216 L436 A438 K1270 27.3 56.8 59 ns32 rs41309228 E27/3410G>T (S1137I ) S1137 S1138 S1133 S1145 P1179 A1172 S1082 S1220 P440 E443 - 18.2 41.8 60 ns33 rs2229107 E27/3421T>A (S1141T) S1141 S1142 S1137 S1149 T1183 T1176 D1086 S1224 D444 R447 T1277 45.5 50.9 61 s20 rs1045642 E27/3435C>T (I1145I) C-NBD (Internal) I1145 I1146 I1141 I1153 V1187 I1180 I1090 M1228 V447 I450 V1281 72.7 57.6 62 ns34 rs59241388 E28/3502A>G (K1168E) K1168 R1169 R1164 R1176 R1210 R1203 C1113 L1251 E470 V473 N1304 27.3 61.9 63 ns35 rs41309231 E29/3669A>T (E1223D) E1223 E1224 E1219 E1231 E1265 E1258 V1168 Q1306 K525 K528 D1359 27.3 60.2 64 s21 rs2235051 E29/3747C>G (G1249G) C-NBD (Internal) G1249 G1250 G1245 G1257 G1291 G1284 G1194 G1332 G551 G554 T1392 63.6 63.0 65 ns36 rs45456698 E29/3751G>A (V1251I) V1251 V1252 V1247 V1259 I1293 V1286 V1196 I1334 I553 I556 V1394 81.8 59.2 4.957.279931T165T855T9331T1021N1921D8921T4621T2521T7521T6521T)K6521T(A>C7673/92E93412753sr73sn66 C-NBD (External) C-NBD (External) C-NBD (External) C-NBD (External) TM4 - TM9 TM10 - TM1 S. aureus TM12 N-NBD (Internal) N-NBD (External) N-NBD (Internal) C-NBD (External) TM3 C. elegans D. melanoga ster A. thaliana S. pombe # SNP (amino acid substitution) Mapped to Abcb1a domain (internal/external surface) rsNo Conservation (%)a H. Sapiens C. l. Familiaris M. Musculus G. gallus P. falciparum Amino acid residue housing SNP Individual Regional 3 structure E. coli a The conservation of residues corresponding to all coding regions SNPs was obtained following multiple sequence alignment of 11 confirmed ABCB1 homolog protein sequences.
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ABCB1 p.Gly1063Ala 21625253:48:5089
status: NEW[hide] Emerging new technologies in Pharmacogenomics: rap... Pharmacol Ther. 2010 Apr;126(1):69-81. Epub 2010 Feb 4. Ishikawa T, Sakurai A, Hirano H, Lezhava A, Sakurai M, Hayashizaki Y
Emerging new technologies in Pharmacogenomics: rapid SNP detection, molecular dynamic simulation, and QSAR analysis methods to validate clinically important genetic variants of human ABC Transporter ABCB1 (P-gp/MDR1).
Pharmacol Ther. 2010 Apr;126(1):69-81. Epub 2010 Feb 4., [PMID:20138191]
Abstract [show]
Pharmacogenomics, the study of the influence of genetic factors on drug action, is increasingly important for predicting pharmacokinetics profiles and/or adverse reactions to drugs. Drug transporters as well as drug-metabolism play pivotal roles in determining the pharmacokinetic profiles of drugs and, by extension, their overall pharmacological effects. There are an increasing number of reports addressing genetic polymorphisms of drug transporters. A key requirement for the development of individualized medicine or personalized therapy is the ability to rapidly and conveniently test patients for genetic polymorphisms and/or mutations. We have recently developed a rapid and cost-effective method for single nucleotide polymorphism (SNP) detection, named Smart Amplification Process 2 (SmartAmp2), which enables us to detect genetic polymorphisms or mutations in 30 to 45min under isothermal conditions without DNA isolation and PCR amplification. Furthermore, high-speed functional screening, quantitative structure-activity relationship (QSAR) analysis, and molecular dynamic (MD) simulation methods have been developed to study the substrate specificity of ABC transporters and to evaluate the effect of genetic polymorphisms on their function and substrate specificity. These methods would provide powerful and practical tools for screening synthetic and natural compounds, and the deduced data can be applied to the molecular design of new drugs. This review addresses such new methods for validating genetic polymorphisms of human ABC transporter ABCB1 (P-gp/MDR1) which is critically involved in the pharmacokinetics of drugs.
Comments [show]
None has been submitted yet.
No. Sentence Comment
478 To functionally validate the non-synonymous polymorphisms of ABCB1 (P-glycoprotein/MDR1) in vitro, we generated SNP variant forms (i.e., S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A; refer to Fig. 6) and expressed them in Sf9 cells.
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ABCB1 p.Gly1063Ala 20138191:478:212
status: NEW500 SNP Km Vmax Vmax / Km (µM) (nmol/min/mg protein) WT 5.8±2.3 62.4±7.8 10.8 S400N 5.8±2.8 46.7±5.3⁎⁎ 8.0 R492C 5.6±1.9 49.6±10.0⁎ 8.9 R669C 3.2±1.6⁎ 64.7±6.9 20.1 I849M 1.5±0.7⁎⁎ 80.3±9.5⁎⁎ 51.8 A893P 1.5±0.5⁎⁎ 405.2±16.5⁎⁎ 274.6 A893S 11.1±5.4 43.1±7.1⁎⁎ 3.9 A893T 4.3±1.4 98.9±9.5⁎⁎ 22.9 M986V 5.1±1.1 114.9±13.6⁎⁎ 22.5 A999T 2.0±0.8⁎⁎ 143.1±21.2⁎⁎ 70.9 P1051A 6.2±3.0 52.1±13.6 8.4 G1063A 6.2±3.7 117.9±16.4⁎⁎ 19.0 Data are expressed as mean±S.D., n=6.
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ABCB1 p.Gly1063Ala 20138191:500:652
status: NEW533 The values of those coefficients for WT and SNP variants (i.e., S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A) are shown in Sakurai et al. (2007).
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ABCB1 p.Gly1063Ala 20138191:533:139
status: NEW476 To functionally validate the non-synonymous polymorphisms of ABCB1 (P-glycoprotein/MDR1) in vitro, we generated SNP variant forms (i.e., S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A; refer to Fig. 6) and expressed them in Sf9 cells.
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ABCB1 p.Gly1063Ala 20138191:476:212
status: NEW498 SNP Km Vmax Vmax / Km (&#b5;M) (nmol/min/mg protein) WT 5.8&#b1;2.3 62.4&#b1;7.8 10.8 S400N 5.8&#b1;2.8 46.7&#b1;5.3Ìe;Ìe; 8.0 R492C 5.6&#b1;1.9 49.6&#b1;10.0Ìe; 8.9 R669C 3.2&#b1;1.6Ìe; 64.7&#b1;6.9 20.1 I849M 1.5&#b1;0.7Ìe;Ìe; 80.3&#b1;9.5Ìe;Ìe; 51.8 A893P 1.5&#b1;0.5Ìe;Ìe; 405.2&#b1;16.5Ìe;Ìe; 274.6 A893S 11.1&#b1;5.4 43.1&#b1;7.1Ìe;Ìe; 3.9 A893T 4.3&#b1;1.4 98.9&#b1;9.5Ìe;Ìe; 22.9 M986V 5.1&#b1;1.1 114.9&#b1;13.6Ìe;Ìe; 22.5 A999T 2.0&#b1;0.8Ìe;Ìe; 143.1&#b1;21.2Ìe;Ìe; 70.9 P1051A 6.2&#b1;3.0 52.1&#b1;13.6 8.4 G1063A 6.2&#b1;3.7 117.9&#b1;16.4Ìe;Ìe; 19.0 Data are expressed as mean&#b1;S.D., n=6.
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ABCB1 p.Gly1063Ala 20138191:498:607
status: NEW502 Descriptor Coefficients (95% reliability) for ABCB1 WT and vatiants WT S400N R492C R669C I849M A893P A893S A893T M986V A999T P1051A G1063A M532 24.3 (3.76) 21.2 (5.81) 18.5 (5.87) 35.9 (7.68) 52.7 (11.30) 169.8 (18.84) 14.0 (4.03) 61.2 (7.75) 39.4 (8.76) 63.0 (9.39) 13.9 (4.78) 52.1 (10.94) M132 21.5 (3.89) 14.1 (5.34) 13.6 (5.78) 32.8 (6.89) 61.4 (12.66) 135.6 (22.95) 11.2 (4.06) 52.8 (7.16) 38.2 (8.62) 65.9 (8.44) 7.6 (5.71) 24.3 (10.46) C-CHN-BT 3.3 (0.72) 3.8 (0.95) 1.7 (0.87) 3.5 (1.08) 5.7 (1.55) 11.6 (2.48) 1.2 (0.65) 6.1 (1.29) 7.1 (1.43) 7.3 (1.44) 2.0 (0.66) 2.8 (1.86) ESTR -10.1 (4.93) -12.5 (5.00) OH-Ar -6.4 (4.03) R-CC 16.1 (7.86) -4.4 (1.73) RT -8.9 (4.21) -17.7 (8.22) -O-Ar 5.7 (3.67) D012 5.5 (4.10) G010 -15.4 (9.59) H100 4.9 (3.59) H181 -7.3 (5.04) H421 14.6 (6.84) H521 14.1 (10.42) M113 -5.8 (3.69) -11.7 (5.30) -7.7 (3.70) -22.8 (8.75) -16.4 (8.19) -16.5 (10.58) M232 -14.5 (9.38) M280 4.8 (2.65) M313 -5.2 (3.18) M332 -5.0 (3.11) M370 4.2 (3.14) M372 10.0 (5.46) 14.4 (7.91) M392 73.3 (25.03) 10.3 (6.38) M531 -5.1 (3.05) M540 15.8 (11.27) H7 7.3 (4.01) 24.0 (10.91) H8 10.7 (4.74) L1 -6.7 (2.52) L9 13.8 (6.93) Const.
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ABCB1 p.Gly1063Ala 20138191:502:132
status: NEW534 The values of those coefficients for WT and SNP variants (i.e., S400N, R492C, R669C, I849M, A893P, A893S, A893T, M986V, A999T, P1051A, and G1063A) are shown in Sakurai et al. (2007).
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ABCB1 p.Gly1063Ala 20138191:534:139
status: NEW