ABCB1 p.Ser222Cys
| Predicted by SNAP2: | A: N (72%), C: N (72%), D: D (53%), E: D (59%), F: D (53%), G: N (57%), H: D (53%), I: N (53%), K: D (63%), L: D (59%), M: N (61%), N: N (61%), P: D (66%), Q: D (59%), R: D (63%), T: N (93%), V: N (57%), W: D (71%), Y: D (63%), |
| Predicted by PROVEAN: | A: N, C: D, D: D, E: D, F: D, G: D, H: D, I: D, K: D, L: D, M: D, N: D, P: D, Q: D, R: D, T: D, V: D, W: D, Y: D, |
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[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
78 Single-cysteine mutants in human P-glycoprotein that are protected from cross-linking to cysteine-reactive MTS substrate analogues by the non-reactive substratea P-glycoprotein residueb Corresponding residue in V. cholera MsbA Cysteine-reactive substrate I340C (6) G293 MTS-rhodamine A841C (9) A151 MTS-rhodamine L975C (12) T285 MTS-rhodamine V981C (12) M291 MTS-rhodamine V982C (12) F292 MTS-rhodamine S222C (4) A175 MTS-verapamil L339C (6) M291 MTS-verapamil A342C (6) M295 MTS-verapamil I868C (10) F180 MTS-verapamil F942C (11) Q256 MTS-verapamil T945C (11) A259 MTS-verapamil G984C (12) L294 MTS-verapamil a Data adapted from [24,2].
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ABCB1 p.Ser222Cys 16545467:78:403
status: NEW76 Single-cysteine mutants in human P-glycoprotein that are protected from cross-linking to cysteine-reactive MTS substrate analogues by the non-reactive substratea P-glycoprotein residueb Corresponding residue in V. cholera MsbA Cysteine-reactive substrate I340C (6) G293 MTS-rhodamine A841C (9) A151 MTS-rhodamine L975C (12) T285 MTS-rhodamine V981C (12) M291 MTS-rhodamine V982C (12) F292 MTS-rhodamine S222C (4) A175 MTS-verapamil L339C (6) M291 MTS-verapamil A342C (6) M295 MTS-verapamil I868C (10) F180 MTS-verapamil F942C (11) Q256 MTS-verapamil T945C (11) A259 MTS-verapamil G984C (12) L294 MTS-verapamil a Data adapted from [24,25].
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ABCB1 p.Ser222Cys 16545467:76:403
status: NEW[hide] The inhibitory and combinative mechanism of HZ08 w... Toxicol Appl Pharmacol. 2014 Jan 15;274(2):232-9. doi: 10.1016/j.taap.2013.11.019. Epub 2013 Dec 7. Zhang Y, Hu Y, Feng Y, Kodithuwakku ND, Fang W, Li Y, Huang W
The inhibitory and combinative mechanism of HZ08 with P-glycoprotein expressed on the membrane of Caco-2 cell line.
Toxicol Appl Pharmacol. 2014 Jan 15;274(2):232-9. doi: 10.1016/j.taap.2013.11.019. Epub 2013 Dec 7., [PMID:24321342]
Abstract [show]
Recently, the research and development of agents to reverse the phenomenon of multidrug resistance has been an attractive goal as well as a key approach to elevating the clinical survival of cancer patients. Although three generations of P-glycoprotein modulators have been identified, poor clearance and metabolism render these agents too toxic to be used in clinical application. HZ08, which has been under investigation for several years, shows a dramatic reversal effect with low cytotoxicity. For the first time, we aimed to describe the interaction between HZ08 and P-glycoprotein in Caco-2 cell line in which P-glycoprotein is overexpressed naturally. Cytotoxicity and multidrug resistance reversal assays, together with flow cytometry, fluorescence microscopy and siRNA interference as well as Caco-2 monolayer transport model were employed in this study to evaluate the interaction between HZ08 and P-glycoprotein. This study revealed that HZ08 was capable of reversing adriamycin resistance mediated by P-glycoprotein as a result of intracellular enhancement of adriamycin accumulation, which was found to be superior to verapamil. In addition, we confirmed that HZ08 suppressed the transport of Rhodamine123 in the Caco-2 monolayer model but had little effect on P-glycoprotein expression. The transport of HZ08 was diminished by P-glycoprotein inhibitors (verapamil and LY335979) and its accumulation was increased via siRNA targeting MDR1 in Caco-2 cells. Furthermore, considering the binding site of P-glycoprotein, verapamil performed as a competitive inhibitor with HZ08. In conclusion, as a P-glycoprotein substrate, HZ08 inhibited P-glycoprotein activity and may share the same binding site of verapamil to P-glycoprotein.
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No. Sentence Comment
251 In another research of Tip W. Loo, verapamil significantly protects residues S222C (TM4), L339 (TM6), A342 (TM6), and G984 (TM12) from inactivation by MTS-verapamil.
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ABCB1 p.Ser222Cys 24321342:251:77
status: NEW