ABCC2 p.Arg1230Ala
| Predicted by SNAP2: | A: D (85%), C: D (85%), D: D (91%), E: D (91%), F: D (91%), G: D (85%), H: D (75%), I: D (85%), K: D (53%), L: D (85%), M: D (85%), N: D (91%), P: D (91%), Q: D (80%), S: D (71%), T: D (85%), V: D (85%), W: D (91%), Y: D (85%), |
| Predicted by PROVEAN: | A: D, C: D, D: D, E: D, F: D, G: D, H: D, I: D, K: N, L: D, M: D, N: D, P: D, Q: D, S: D, T: D, V: D, W: D, Y: D, |
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[hide] Insight in eukaryotic ABC transporter function by ... FEBS Lett. 2006 Feb 13;580(4):1064-84. Epub 2006 Jan 19. Frelet A, Klein M
Insight in eukaryotic ABC transporter function by mutation analysis.
FEBS Lett. 2006 Feb 13;580(4):1064-84. Epub 2006 Jan 19., 2006-02-13 [PMID:16442101]
Abstract [show]
With regard to structure-function relations of ATP-binding cassette (ABC) transporters several intriguing questions are in the spotlight of active research: Why do functional ABC transporters possess two ATP binding and hydrolysis domains together with two ABC signatures and to what extent are the individual nucleotide-binding domains independent or interacting? Where is the substrate-binding site and how is ATP hydrolysis functionally coupled to the transport process itself? Although much progress has been made in the elucidation of the three-dimensional structures of ABC transporters in the last years by several crystallographic studies including novel models for the nucleotide hydrolysis and translocation catalysis, site-directed mutagenesis as well as the identification of natural mutations is still a major tool to evaluate effects of individual amino acids on the overall function of ABC transporters. Apart from alterations in characteristic sequence such as Walker A, Walker B and the ABC signature other parts of ABC proteins were subject to detailed mutagenesis studies including the substrate-binding site or the regulatory domain of CFTR. In this review, we will give a detailed overview of the mutation analysis reported for selected ABC transporters of the ABCB and ABCC subfamilies, namely HsCFTR/ABCC7, HsSUR/ABCC8,9, HsMRP1/ABCC1, HsMRP2/ABCC2, ScYCF1 and P-glycoprotein (Pgp)/MDR1/ABCB1 and their effects on the function of each protein.
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No. Sentence Comment
492 An inhibitor, cyclosporine A, failed to inhibit R1230A specifically, indicating the existence of its binding site within TM16 [238].
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ABCC2 p.Arg1230Ala 16442101:492:48
status: NEW[hide] ABCC2/Abcc2: a multispecific transporter with domi... Drug Metab Rev. 2010 Aug;42(3):402-36. Jemnitz K, Heredi-Szabo K, Janossy J, Ioja E, Vereczkey L, Krajcsi P
ABCC2/Abcc2: a multispecific transporter with dominant excretory functions.
Drug Metab Rev. 2010 Aug;42(3):402-36., [PMID:20082599]
Abstract [show]
ABCC2/Abcc2 (MRP2/Mrp2) is expressed at major physiological barriers, such as the canalicular membrane of liver cells, kidney proximal tubule epithelial cells, enterocytes of the small and large intestine, and syncytiotrophoblast of the placenta. ABCC2/Abcc2 always localizes in the apical membranes. Although ABCC2/Abcc2 transports a variety of amphiphilic anions that belong to different classes of molecules, such as endogenous compounds (e.g., bilirubin-glucuronides), drugs, toxic chemicals, nutraceuticals, and their conjugates, it displays a preference for phase II conjugates. Phenotypically, the most obvious consequence of mutations in ABCC2 that lead to Dubin-Johnson syndrome is conjugate hyperbilirubinemia. ABCC2/Abcc2 harbors multiple binding sites and displays complex transport kinetics.
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No. Sentence Comment
97 Mutant Predicted location Substrate Activity changes Reference Human MRP2 Δ1-188 TMD0 LTC4 ↓ Fernandez et al., 2002 K316A JC, TM6 GMF ↔ Ryu et al., 2000 K324A TM6 GMF ↓ Ryu et al., 2000 K329A TM6 GMF ↔ Ryu et al., 2000 R412G DJ IC MTX ↓ Hulot et al., 2005 W417I IC, TM7-TM8 E2-17βG ↓ Hirouchi et al., 2004 LTC4 ↓ DNP-SG ↓ H439A TM8 GMF ↔ Ryu et al., 2000 K483A IC, JM, TM9 GMF ↓ Ryu et al., 2000 K590A JC, TM11 GMF ↔ Ryu et al., 2000 S789F NBD1 E2-17βG ↓ Hirouchi et al., 2004 LTC4 ↓ DNP-SG ↓↓ R1023A EC, JM, TM13 GMF ↔ Ryu et al., 2000 H1042A TM13 GMF ↔ Ryu et al., 2000 R1100A JC, TM14 GMF ↔ Ryu et al., 2000 P1158A IC, JM, TM15 LTC4 ↓↓ Letourneau et al., 2007 E2-17βG ↔ MTX ↔ Table 1. continued on next page Mutant Predicted location Substrate Activity changes Reference I1173F DJ IC, TM15-16 LTC4 No act Keitel et al., 2003 E2-17βG No act R1210A EC, JC, TM16 GMF ↓↓ Ryu et al., 2000 R1230A TM16 GMF ↔ R1257A JC, TM17 GMF ↓↓ W1254A JC, TM17 E2-17βG ↓↓ Ito et al., 2001a W1254C ↓↓ W1254F ↔ W1254Y ↔ W1254A JC, TM17 LTC4 ↓↓ Ito et al., 2001b W1254C ↓↓↓ W1254F ↓↓ W1254Y ↓↓ W1254A JC, TM17 MTX ↓↓ Ito et al., 2001a W1254C ↓↓ W1254F ↓↓ W1254Y ↓↓↓ A1450T NBD2 E2-17βG ↓↓ Hirouchi et al., 2004 LTC4 ↓↓ DNP-SG ↓↓ Rat Mrp2 K308M IC, JM, TM6 TLC-S ↔ Ito et al., 2001b DNP-G ↑ LTC4 ↓ E3040G ↔ K320M TM6 TLC-S ↑ DNP-G ↑ LTC4 ↓ E3040G ↑ K325M TM6 TLC-S ↓* DNP-G ↓↓↓* LTC4 ↓↓↓* E3040G ↓ D329N TM6 TLC-S ↔ DNP-G ↓ LTC4 ↓↓↓* E3040G ↓ R586L TM11 TLC-S ↓ DNP-G ↓↓* LTC4 ↓↓* E3040G ↔ R1019M IC, JM, TM13 TLC-S ↔ DNP-G ↑* LTC4 ↔ E3040G ↔ R1096L TM14 TLC-S ↑ DNP-G ↑ LTC4 ↔ E3040G ↔ EC, extracellular; IC, intracellular; JC, near the cytosol in the membrane; JM, juxtamembrane; TLC-S, tauro-litocholate-sulfate; GMF, glutathione- methyl-fluorescein; ↑, activity over control>1.2; ↔, 1.2>activity over control>0.8; ↓, 0.8>activity over control>0.5; ↓↓, 0.5>activity over control>0.1; ↓↓↓, 0.1>activity over control.
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ABCC2 p.Arg1230Ala 20082599:97:1087
status: NEW[hide] Identification of basic residues involved in drug ... J Biol Chem. 2000 Dec 15;275(50):39617-24. Ryu S, Kawabe T, Nada S, Yamaguchi A
Identification of basic residues involved in drug export function of human multidrug resistance-associated protein 2.
J Biol Chem. 2000 Dec 15;275(50):39617-24., [PMID:10978330]
Abstract [show]
Multidrurg resistance-associated protein 2 (MRP2)/canalicular multispecific organic anion transporter (cMOAT) is involved in the ATP-dependent export of organic anions across the bile canalicular membrane. To identify functional amino acid residues that play essential roles in the substrate transport, each of 13 basic residues around transmembrane regions (TMs) 6-17 were replaced with alanine. Wild type and mutant proteins were expressed in COS-7 cells, and the transport activity was measured as the excretion of glutathione-methylfluorescein. Four mutants, K324A (TM6), K483A (TM9), R1210A (TM16), and R1257A (TM17), showed decreased transport activity, and another mutant, K578A (TM11), showed decreased protein expression. These five mutants were normally delivered to the cell surface similar to the other fully active mutants and wild type MRP2. The importance of TM6, TM16, and TM17 in the transport function of MRP2 is consistent with the previous observation indicating the importance of the corresponding TM1, TM11, and TM12 on P-glycoprotein (Loo, T. W., and Clarke, D. M. (1999) J. Biol. Chem. 274, 35388-35392). Another observation that MRP2 inhibitor, cyclosporine A, failed to inhibit R1230A specifically, indicated the existence of its binding site within TM16.
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No. Sentence Comment
7 Another observation that MRP2 inhibitor, cyclosporine A, failed to inhibit R1230A specifically, indicated the existence of its binding site within TM16.
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ABCC2 p.Arg1230Ala 10978330:7:75
status: NEW43 The other six mutants, R1023A, H1042A, R1100A, R1210A, R1230A, and R1257A, were generated by the method of Kunkel (30).
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ABCC2 p.Arg1230Ala 10978330:43:55
status: NEW126 In R1230A mutant, the MRP2-mediated transport activity was not inhibited by CsA, whereas the other active mutants were suppressed on their transport activity up to 50% (Fig. 11).
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ABCC2 p.Arg1230Ala 10978330:126:3
status: NEW184 In most active mutants excretion of GS-MF was inhibited by CsA as well as wild type MRP2, whereas in R1230A mutant excretion of GS-MF was not influenced (Fig. 11).
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ABCC2 p.Arg1230Ala 10978330:184:101
status: NEW