ABCB1 p.Gly141Val
| Predicted by SNAP2: | A: N (78%), C: D (66%), D: D (75%), E: D (59%), F: D (80%), H: D (66%), I: D (75%), K: D (85%), L: D (75%), M: D (75%), N: D (71%), P: D (71%), Q: D (75%), R: D (85%), S: N (72%), T: N (66%), V: N (61%), W: D (85%), Y: D (80%), |
| Predicted by PROVEAN: | A: N, 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: N, T: D, V: D, W: D, Y: D, |
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[hide] Rapid purification of human P-glycoprotein mutants... J Biol Chem. 1995 Sep 15;270(37):21449-52. Loo TW, Clarke DM
Rapid purification of human P-glycoprotein mutants expressed transiently in HEK 293 cells by nickel-chelate chromatography and characterization of their drug-stimulated ATPase activities.
J Biol Chem. 1995 Sep 15;270(37):21449-52., 1995-09-15 [PMID:7665554]
Abstract [show]
P-glycoprotein containing 10 tandem histidine residues at the COOH end of the molecule was transiently expressed in HEK 293 cells and purified by nickel-chelate chromatography. The purified protein had an apparent mass of 170 kDa, and its verapamil-stimulated ATPase activity in the presence of phospholipid was 1.2 mumol/min/mg of P-glycoprotein. We then characterized P-glycoprotein mutants that exhibited altered drug-resistant phenotypes and analyzed the contribution of the two nucleotide binding folds to drug-stimulated ATPase activity. Mutation of residues in either nucleotide binding fold abolished drug-stimulated ATPase activity. The pattern of drug-stimulated ATPase activities of mutants, which conferred increased relative resistance to colchicine (G141V, G185V, G830V) or decreased relative resistance to all drugs (F978A), correlated with their drug-resistant phenotypes. By contrast, the ATPase activity of mutant F335A was significantly higher than that of wild-type enzyme when assayed in the presence of verapamil (3.4-fold), colchicine (9.1-fold), or vinblastine (3.7-fold), even though it conferred little resistance to vinblastine in transfected cells. These results suggest that both nucleotide-binding domains must be intact to couple drug binding to ATPase activity and that the drug-stimulated ATPase activity profile of a mutant does not always correlate with its drug-resistant phenotype.
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No. Sentence Comment
64 For example, mutants G141V or G830V conferred increased resistance to colchicine (about 3-fold) relative to that of wild-type enzyme while mutant F335A conferred decreased resistance to vinblastine.
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ABCB1 p.Gly141Val 7665554:64:21
status: NEW69 The maximal verapamil-stimulated ATPase activities of mutants G141V, G185V, and G830V were all slightly increased (1.4-1.7-fold) relative to that of wild-type enzyme (Fig. 2).
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ABCB1 p.Gly141Val 7665554:69:62
status: NEW81 Wild-type (E) and mutants G141V (å), G185V (Ⅺ), G830V (q), F335A (f), and F978A (Ç) P-glycoproteins-(His)10 were purified using Ni-NTA spin columns and reconstituted with sheep brain phosphatidylethanolamine.
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ABCB1 p.Gly141Val 7665554:81:26
status: NEW111 For mutants G141V, G185V, G830V, and F978A, the pattern of drug-stimulated ATPase correlated with their relative drug-resistant profiles in transfected cells.
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ABCB1 p.Gly141Val 7665554:111:12
status: NEW[hide] New light on multidrug binding by an ATP-binding-c... Trends Pharmacol Sci. 2006 Apr;27(4):195-203. Epub 2006 Mar 20. Shilling RA, Venter H, Velamakanni S, Bapna A, Woebking B, Shahi S, van Veen HW
New light on multidrug binding by an ATP-binding-cassette transporter.
Trends Pharmacol Sci. 2006 Apr;27(4):195-203. Epub 2006 Mar 20., [PMID:16545467]
Abstract [show]
ATP-binding-cassette (ABC) multidrug transporters confer multidrug resistance to pathogenic microorganisms and human tumour cells by mediating the extrusion of structurally unrelated chemotherapeutic drugs from the cell. The molecular basis by which ABC multidrug transporters bind and transport drugs is far from clear. Genetic analyses during the past 14 years reveal that the replacement of many individual amino acids in mammalian multidrug resistance P-glycoproteins can affect cellular resistance to drugs, but these studies have failed to identify specific regions in the primary amino acid sequence that are part of a defined drug-binding pocket. The recent publication of an X-ray crystallographic structure of the bacterial P-glycoprotein homologue MsbA and an MsbA-based homology model of human P-glycoprotein creates an opportunity to compare the original mutagenesis data with the three-dimensional structures of transporters. Our comparisons reveal that mutations that alter specificity are present in three-dimensional 'hotspot' regions in the membrane domains of P-glycoprotein.
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No. Sentence Comment
58 Although mutation of only one of these residues (L975A, V981A and F983A) has no effect on the phenotype of the protein [20], double mutations either completely inhibit (V981A/F983A and L975A/V981A) or cause 50% inhibition (L975A/F983A) of Table 1.
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ABCB1 p.Gly141Val 16545467:58:338
status: NEW59 Published mutations in human and murine P-glycoprotein that alter drug transport in cells Location of mutation Mutation Refs Mutation Refs Mutation Refs Transmembrane helices H61A and others [14] I214L [60] L868W [59] G64R [15] P223A [65] I936A [21] L65R [15] S224P [60] F938A [21] Q139[H/P/R] [60] I306R [18] S939[A/C/T/Y/W/D/F] [21,22] G141V [17] F335A [16] T941A [21] G185V [61,62] V338A [66] Q942A [21] I186N [61] G338A [67,68] A943G [21] G187V [17] A339P [67,68] Y946A [21] G187E [60] G341A [66] S948A [21] A192T [60] S344[A/T/C/Y] [66] Y949A [21] F200L [60] N350I [19] C952A [21] F204S [60] P709A [65] F953A [21] R206L [60] G830V [17] L975A [20] W208G [60] I837L [23] F978A [16] K209E [60] N839I [23] V981A [20] L210I [60] I862F [19] F983A [20] T211P [60] L865F [19] F978A [16] V213A [60] P866A [65] N988D [59] Intracellular domain T169I [60] K177I [60] G288V [17] R170L [60] E180G [60] A931T [19] L171P [60] G181R [60] F934A [21] T172P [60] G183D [60] G935A [21] S176P [60] D184N [60] NBD D555N [63] K1076M [69] E1197Q [64] D558N [64] D1093N [64] D1203N [64] D592N [64] E1125Q [64] D1237N [64] E604Q [64] S1173A [70] E1249Q [64] Review TRENDS in Pharmacological Sciences Vol.27 No.
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ABCB1 p.Gly141Val 16545467:59:338
status: NEW[hide] Molecular genetic analysis and biochemical charact... Semin Cell Dev Biol. 2001 Jun;12(3):247-56. Hrycyna CA
Molecular genetic analysis and biochemical characterization of mammalian P-glycoproteins involved in multidrug resistance.
Semin Cell Dev Biol. 2001 Jun;12(3):247-56., [PMID:11428917]
Abstract [show]
A variety of human cancers become resistant or are intrinsically resistant to treatment with conventional drug therapies. This phenomenon is due in large part to the overexpression of a 170 kDa plasma membrane ATP-dependent pump known as the multidrug resistance transporter or P-glycoprotein. P-glycoprotein is a member of the large ATP binding cassette (ABC) superfamily of membrane transporters. This review focuses on the use of structure-function analyses to elucidate further the mechanism of action of mammalian P-glycoproteins. Ultimately, a complete understanding of the mechanism is important for the development of novel strategies for the treatment of many human cancers.
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No. Sentence Comment
27 List of mutations in human, mouse and hamster P-gp`s that affect substrate specificity f aaa Mutation Regionb Sourcec Reference aa 78-97 EC 1 human MDR1 78 (ABC20)d Q128He TM 2 mouse mdr3 79 R138H IC 1 mouse mdr3 79 Q139H, R IC 1 mouse mdr3 79 G141V IC 1 human MDR1 25,80 Q145H IC 1 mouse mdr3 79 E155G, K IC 1 mouse mdr3 79 F159I IC 1 mouse mdr3 79 D174G IC 1 mouse mdr3 79 S176F, P IC 1 mouse mdr3 79 K177I IC 1 mouse mdr3 79 N179S IC1 mouse mdr3 79 N183S/G185V IC 1 human MDR1 81 G183D IC1 mouse mdr3 79 G185V IC 1 human MDR1 82-84 G187V IC 1 human MDR1 80 A192T TM 3 mouse mdr3 79 F204S EC 2 mouse mdr3 79 W208G EC 2 mouse mdr3 79 K209E EC 2 mouse mdr3 79 L210I TM 4 mouse mdr3 79 T211P TM 4 mouse mdr3 79 I214T TM 4 mouse mdr3 79 P223A TM 4 human MDR1 85 K285T IC 2 human MDR1 1 G288V IC 2 human MDR1 80 I299M, T319S, L322I, TM 5, EC3, IC 3 human MDR1 86 G324K, S351N V334 TM 6 human MDR1 1 F335A TM 6 human MDR1 25 F335 TM 6 human MDR1 87 V338A TM 6 human MDR1 88 G338A, A339P TM 6 hamster PGY 1 89,90 A339P TM 6 hamster PGY 1 90 G341V TM 6 human MDR1 88 K536R,Q N-NBD human MDR1 91 ERGA→DKGT N-NBD mouse mdr3 92 (aa 522-525) T578C N-NBD mouse mdr3 92 G812V IC 4 human MDR1 80 G830V IC 4 human MDR1 25,80 P866A TM 10 human MDR1 85 F934A TM 11 mouse mdr3 93 G935A TM 11 mouse mdr3 93 I936A TM 11 mouse mdr3 93 F938A TM 11 mouse mdr3 93 S939A TM 11 mouse mdr3 93 S939F TM 11 mouse mdr3 94,95 S941F TM 11 mouse mdr1 94,95 T941A TM 11 mouse mdr3 93 Q942A TM 11 mouse mdr3 93 Table 1-continued aaa Mutation Regionb Sourcec Reference A943G TM 11 mouse mdr3 93 Y946A TM 11 mouse mdr3 93 S948A TM 11 mouse mdr3 93 Y949A TM 11 mouse mdr3 93 C952A TM 11 mouse mdr3 93 F953A TM 11 mouse mdr3 93 F983A TM 12 human MDR1 96 L975A, V981A, F983A TM 12 human MDR1 96 M986A, V988A, TM 12 human MDR1 96 Q990A, V991A V981A, F983A TM 12 human MDR1 96 L975A, F983A TM 12 human MDR1 96 L975A, V981A TM 12 human MDR1 96 F978 TM 12 human MDR1 1 F978A TM 12 human MDR1 25 a aa, amino acid.
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ABCB1 p.Gly141Val 11428917:27:244
status: NEW[hide] How does P-glycoprotein recognize its substrates? Semin Cancer Biol. 1997 Jun;8(3):151-9. Ueda K, Taguchi Y, Morishima M
How does P-glycoprotein recognize its substrates?
Semin Cancer Biol. 1997 Jun;8(3):151-9., [PMID:9441945]
Abstract [show]
We review how P-glycoprotein recognizes a wide variety of compounds and how it carries its substrates across membranes. Amino acid substitutions that affect the substrate specificity of P-glycoprotein have been found scattered throughout the molecule. In particular, some amino acid residues in the putative transmembrane domain (TM) 1 together with TM5-6 and TM11-12 may help to govern substrate specificity. The features that substrates for P-glycoprotein share are also discussed. The amphipathy of a substrate may decide whether the substrate can be intercalated into the lipid bilayer of the membrane. In addition, only certain molecular volumes and tertiary structures may make it possible for the substrate to fit into the substrate-binding site(s) of P-glycoprotein.
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No. Sentence Comment
98 The effects of amino acid substitutions on substrate specificity of P-glycoprotein can generally be classified into two groups.46 The first group is of mutations Gly185-to-Val, 51,52 Gly141-to-Val, and Gly187- to-Val,54 all in the first cytoplasmic loop; Gly288-to- Val54 in the second cytoplasmic loop; Phe335-to-Ala 39 and Val338-to-Ala 40 in TM6; Gly812-to-Val and Gly830-to-Val 54 in the fourth cytoplasmic loop.
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ABCB1 p.Gly141Val 9441945:98:183
status: NEW[hide] The catalytic cycle of P-glycoprotein. FEBS Lett. 1995 Dec 27;377(3):285-9. Senior AE, al-Shawi MK, Urbatsch IL
The catalytic cycle of P-glycoprotein.
FEBS Lett. 1995 Dec 27;377(3):285-9., [PMID:8549739]
Abstract [show]
P-glycoprotein is a plasma-membrane glycoprotein which confers multidrug-resistance on cells and displays ATP-driven drug-pumping in vitro. It contains two nucleotide-binding domains, and its structure places it in the 'ABC transporter' family. We review recent evidence that both nucleotide-sites bind and hydrolyse Mg-ATP. The two catalytic sites interact strongly. A minimal scheme for the MgATP hydrolysis reaction is presented. An alternating catalytic sites scheme is proposed, in which drug transport is coupled to relaxation of a high-energy catalytic site conformation generated by the hydrolysis step. Other ABC transporters may show similar catalytic features.
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No. Sentence Comment
68 G141V, G185V and G830V caused relative changes in degree of activation of ATPase by vinblastine, verapamil and colchic- inc.
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ABCB1 p.Gly141Val 8549739:68:0
status: NEW