EC:3.6.3.44 - FACTA Search

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Query: EC:3.6.3.44 (P-glycoprotein)
13,344 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The liver is presented with a diverse set of nutrients, endogenous metabolites, and xenobiotics it must process for movement to their correct physiologic destinations. These compounds are transported by specific mechanisms that move their substrates, often against a concentration gradient. Several hepatic transporters have been identified such as the multispecific anion transporter, cMOAT, bile acid transporters, ion-motive ATPases, glutathione transporters, purine transporters, and the multidrug resistance-related protein, MRP. This review focuses on the hepatic regulation of the multidrug resistance genes that encode the P-glycoprotein transporters. P-glycoproteins are ATP-dependent integral membrane proteins that have diverse functions such as conferring resistance toward chemotherapeutic drugs and phospholipid movement. The expression of the multidrug resistance genes is regulated in a tissue-specific pattern and can be induced by exposure to chemotherapeutic drugs as well as cytotoxic xenobiotics. The specific molecular mechanisms that govern expression of these genes in normal and neoplastic cells are currently being unraveled.
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PMID:Hepatic canalicular membrane 4: expression of the multidrug resistance genes in the liver. 914 96

ATP-binding cassette(ABC) superfamily transporters, including P-glycoprotein and MRP, actively transport various structurally dissimilar chemotherapeutic compounds out of cancer cells and confer multidrug resistance. Members of ABC superfamily which may extrude anti-cancer drugs are still expanding, thus the importance of these proteins are further increasing for cancer chemotherapy. Multidrug resistance will be acquired either by the induction of expression of ABC superfamily transporters or by mutations of ABC superfamily genes which cause amino acids substitutions. We recently found that amino acid substitutions in the first predicted transmembrane domain of P-glycoprotein increase the ability to confer resistance to important anti-cancer drugs adriamycin and VP-16. The mechanisms for drug recognition and transport of human P-glycoprotein and MRP are discussed.
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PMID:[Multidrug resistance of cancer cells mediated by ABC superfamily transporters]. 915 47

The heterogeneous nature of an adriamycin-selected human MDR squamous lung cell line, DLKP-A, was investigated by isolating and characterising 9 of its clonal subpopulations. The DLKP-A cell line exhibits resistance to the classical MDR drugs, overexpresses P-glycoprotein and displays reduced topoisomerase II amounts. The clonal cell lines exhibit a wide range of resistance extents, with the most resistant clone displaying 9 times the extent of adriamycin resistance observed in the least resistant clone. A number of clones exhibit sensitivity to the concentration of adriamycin in which the parental cell line was selected, possibly indicating cooperation between the more and less resistant cells. Detailed analysis of 4 of the clonal subpopulations revealed broadly similar drug resistance mechanisms. Alterations in expression of the MDR-associated genes MDR1 and Topo IIalpha were observed, with no detectable changes in the expression of MDR3, MRP, GSTpi, Topo IIbeta, Topo I and CYP1A1 noted. However, each clonal cell line displayed a distinct extent of expression of MDR1 and Topo IIalpha and further characterisation of the clones indicated that other modes of drug resistance may exist in at least one of the cell lines. In particular, 2 of the clones (DLKPA6B and DLKPA11B) which have almost identical drug resistance profiles appear to have quite different mechanisms of resistance. The clonal subpopulations possess individual growth rates, amounts of adriamycin accumulation and susceptibility to toxicity-enhancement by MDR-modulating agents. It was possible to generate a cell line with a drug toxicity profile similar to DLKP-A by mixing some of the clonal subpopulations. Our results provide evidence of heterogeneity within an MDR human cell population with respect to resistance and expression of MDR-associated genes.
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PMID:Isolation from a human MDR lung cell line of multiple clonal subpopulations which exhibit significantly different drug resistance. 918 Jan 64

In summary, the data suggest that E217G is transported by both MOAT and P-glycoprotein into bile, but that P-glycoprotein serves as the target site for cholestasis. We postulate that this target site may be accessed from either the intracellular compartment or the canaliculus, and that MOAT serves as the major delivery route for E217G to the canaliculus. At low, physiologic concentrations of E217G, MOAT-mediated excretion into bile is a detoxification mechanism, serving to prevent intracellular accumulation of a toxic metabolite. However, following administration of high, cholestatic doses, MOAT-mediated excretion into bile results in very high concentrations in bile, on the other of 2-3 mM (see Fig. 4). It is likely that the hydrophobic nature of E217G allows it to partition from bile into the canalicular membrane, from which it can access P-glycoprotein and thus induce cholestasis. Much work is still needed to validate this model of E217G cholestasis. Definitive evidence of P-glycoprotein-mediated transport of E217G must be obtained in cell lines transfected with P-glycoprotein where MRP is absent. More importantly, the mechanism by which interaction of E217G with P-glycoprotein influences bile flow is unknown. Higgins and colleagues have provided evidence that P-glycoprotein regulates a Cl- channel in a manner analogous to that of CFTR, the cystic fibrosis transmembrane conductance regulator. While Cl- channels have been shown to be important in the regulation of the volume of the hepatocyte in the presence of altered osmotic conditions, a role for this channel in bile flow has not been demonstrated. Nevertheless, these studies implicate a role of P-glycoprotein in the regulation of bile secretion by the liver.
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PMID:Cholestatic properties and hepatic transport of steroid glucuronides. 918 18

The use of anticancer drugs in the chemotherapeutic treatment of cancer patients frequently results in the emergence of drug resistant tumors. Selection of tumor cell lines in vitro has led to the identification of several proteins that mediate drug resistance to anticancer drugs. In this study, an immuno-dot blot method was used to isolate a monoclonal antibody (IPM96) which recognized a 40 kDa protein (or P-40) co-expressed with P-glycoprotein and MRP in several multidrug resistant cell lines (MCF-7/Adr, SKOV/VLB1.0, H69/Adr, and HL60/AR). Furthermore, P-40 levels dropped significantly in one revertant cell line (H69/PR) derived from H69/AR cells. Interestingly, the expression of P-40 was also higher in two tumor cell lines (SKTax6a and A2780CP) that were selected with paclitaxel or cisplatin but do not express P-gp or MRP. Immuno-fluorescence staining of cells with IPM96 showed both membrane and cytoplasmic staining. These results were confirmed by Western blot analysis of different subcellular fractions from MCF-7/Adr cells. The membrane bound P-40 was resistant to extraction with high salt, chelating agents, and denaturing agents, but was solubilized with 10 mM CHAPS. Taken together, the overexpression of P-40 in multidrug resistant cells has not been previously determined and therefore could be important in the expression of the drug resistance phenotype.
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PMID:Overexpression of a 40-kDa protein in human multidrug resistant cells. 924 Apr 65

In 10 human cancer cell lines, the activity of mitomycin C (MMC) was found to be determined by an interplay between activation by DT-diaphorase (DTD) and inactivation by glutathione S-transferase (GST). NADPH/cytochrome P-450 reductase was not responsible for MMC activation and expression of MDRI (Mr 170,000 P-glycoprotein), and MRP (multidrug resistance-associated protein) genes did not relate to MMC resistance. Gene expression analysis for NQO1 (DTD gene) and GSTpi predicted which enzyme activity predominated in a cell line, except K562 and K562/DOX. For tumors with DTD activity only, MMC given by itself was most active. In cell lines in which DTD action was predominant, tumor selectivity was achieved by enhancing DTD-mediated activation with m-iodobenzylguanidine and hyperglycemia, which reduced the intra-tumoral pH. KW2149, a novel MMC analogue activated by glutathione, was most active against tumors in which GSTpi predominated. These various enzyme-specific effects could be observed even in cell lines derived from tumors with multidrug resistance. Such MMC treatment based on cell enzymology may enhance significantly MMC efficacy, helping to overcome multidrug resistance.
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PMID:Molecular targeting of mitomycin C chemotherapy. 925 6

Drug accumulation studies with the anticancer agents adriamycin and vincristine were carried out on the MDR variant of the human lung cell lines DLKP, DLKP-A10 which overexpresses the MDR associated P-glycoprotein efflux pump. Reduced cellular accumulation of both agents was observed in the resistant variant. The subsequent addition of verapamil and cyclosporin A resulted in partial restoration of cellular accumulation of both drugs in the DLKP-A10 resistant variant while complete restoration of cellular drug levels was observed in the SKMES-1/ADR cell line. These results suggested that the accumulation defect observed in the SKMES-1/ADR cell line was P-glycoprotein mediated and that accordingly, the cells exhibited characteristics consistent with the classical MDR phenotype. In contrast, while P-glycoprotein also appears to mediate a reduction in cellular drug accumulation in the DLKP-A10 cells, an alternative transport mechanism may also be present. No significant increase in the expression of either the MRP or LRP transport proteins was observed in the resistant cells. Metabolic inhibition by antimycin A (but not sodium azide or 2-deoxy-D-glucose) resulted in complete restoration of drug accumulation suggesting the presence of an alternative energy dependent transport mechanism. Fluorescent microscopy studies indicated different cellular localisation of the drug within the parental and resistant cells despite equivalent intracellular concentrations. These studies also revealed the presence of an ATP-dependent, vesicular sequestration mechanism which may be involved in the reduction of nuclear adriamycin accumulation in the DLKP-A10 cell line. This was indicated by observation of the disruption of cytoplasmic vesicles by antimycin A and also inhibition of cytoplasmic drug sequestration by the carboxylic ionophores, monensin and nigericin, accompanied by increased adriamycin accumulation and redistribution of the drug from the cytoplasm to the nucleus.
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PMID:The multidrug-resistant human lung tumour cell line, DLKP-A10, expresses novel drug accumulation and sequestration systems. 926 Aug 77

Multidrug resistance (MDR) describes the phenomenon of simultaneous resistance to unrelated drugs. It has been a decade since the P-glycoprotein (Pgp) gene, which is associated with a form of MDR caused by reduced drug accumulation, was cloned. Thus, this would seem to be an appropriate time to evaluate our understanding of this form of MDR. The two MDR genes identified in humans to date (the MDR-associated protein [MRP] and Pgp genes) are structurally similar and both are members of the ATP-binding cassette (ABC) transporter family. Although the physiological role of MRP is not yet understood, one Pgp gene (mdr1) plays an important role in the blood-tissue barrier and the other (mdr2/3) is involved in phospholipid transport in the liver. A variety of compounds (chemosensitizing agents) can interfere with Pgp and MRP function; such agents may improve the efficacy of conventional therapy when used in combination with such regimens. Determining the roles cellular MDR mechanisms play in patients' response to chemotherapy is a major challenge. Using Pgp and MRP as molecular markers to detect MDR tumor cells is technically demanding, and solid tumors in particular contain heterogeneous cell populations. Since MDR requires Pgp or MRP gene expression, clinically relevant gene expression thresholds need to be established; sequential samples from individual patients are valuable for correlating MDR gene expression with the clinical course of disease. Studies in leukemias, myelomas, and some childhood cancers show that Pgp expression correlates with poor response to chemotherapy. However, in some cases, inclusion of a reversing or chemosensitizing agent such as verapamil or cyclosporin A has improved clinical efficacy. Such agents may inactivate Pgp in tumor cells or affect Pgp function in normal cells, resulting in altered pharmacokinetics. It would be interesting to determine whether patients who fail treatment in the presence of chemosensitizing agents acquire other MDR mechanisms. The ABC transporter superfamily in prokaryotes and eukaryotes is involved in the transport of substrates ranging from ions to large proteins. Of the 15 or more ABC transporter genes characterized in human cells, two (Pgp and MRP) cause MDR. Therefore, it would be relevant to determine the number of such genes present in the human genome; however, extrapolating from the number of ABC transporter genes in bacteria, the human gene probably contains a minimum of 200 ABC transporter superfamily members. Thus, tumor cells can potentially use many ABC transporters to mount resistance to known and future therapeutic agents. The challenge will be to determine which ABC transporters are clinically relevant. Despite the potential of tumor cells to protect themselves, a variety of malignancies can be successfully treated with chemotherapy. This may provide unique insights.
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PMID:Multidrug resistance: molecular mechanisms and clinical relevance. 927 26

Sphinxolides, a newly described family of cytotoxins from the New Caledonian sponge Neosiphonia superstes, bear structural resemblance to scytophycins. We now demonstrate that the cytotoxicity of sphinxolides is associated with cell cycle arrest in G2-M and induction of apoptosis. Like scytophycins and cytochalasins, sphinxolides caused rapid loss of microfilaments in cultured cells, without affecting microtubule organization. Microfilament reassembly was very slow after removal of the sphinxolide, consistent with the slow recovery of cellular proliferation. Sphinxolides potently inhibited actin polymerization in vitro and the microfilament-dependent ATPase activity of purified actomyosin, indicating a direct effect on actin. Importantly, sphinxolides were equally cytotoxic toward MCF-7 human breast carcinoma cells and a subline which overexpresses P-glycoprotein (MCF-7/ADR). Similarly, overexpression of the multidrug resistance-associated protein MRP by HL-60 cells did not confer resistance to the sphinxolides. These studies demonstrate that sphinxolides are potent new antimicrofilament compounds that circumvent multidrug resistance mediated by overexpression of either P-glycoprotein or MRP. Therefore, these agents may be useful in the treatment of drug-resistant tumors.
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PMID:Microfilament depletion and circumvention of multiple drug resistance by sphinxolides. 928 83

Primary human hepatocytes were immortalized by stable transfection with a recombinant plasmid containing the early region of simian virus (SV) 40. The cells were cultured in serum-free, hormonally defined medium during the immortalization procedure. Foci of dividing cells were seen after 3 months. Albumin- and fibrinogen-secreting cells were selected and cloned by limiting dilution to obtain homologous cell populations. The established IHH (immortalized human hepatocyte) cell lines were evaluated for their usefulness in studying the regulation of cell growth and of certain differentiated hepatocyte functions. IHH cells retain several differentiated features of normal hepatocytes. They display albumin secretion at a level comparable to cultured primary human hepatocytes (30 micrograms albumin/ml per day). A portion of the IHH cells are polarized, forming bile canaliculi-like vacuoles where exogeneous organic anions accumulate. The multidrug resistance (MDR) P-glycoprotein, known to be localized at the canalicular membrane, is also present in these vacuoles. The polarized features allowed the use of IHH cells for the study of localization of the newly characterized multidrug resistance protein MRP1. The homologues of MRP were found in hepatocytes, MRP1 and MRP2 (cMOAT), both functioning in ATP-dependent excretion of anionic conjugates. In differentiated hepatocytes, MRP1 expression is extremely low. In contrast, MRP1 is highly expressed in proliferating IHH cells, where it is localized in lateral membranes. A highly differentiated feature of short-term cultured primary hepatocytes which is not detectable in IHH cells is active uptake of the bile salt taurocholate. Furthermore, IHH cells secrete triglyceride (TG)-rich lipoproteins, apolipoprotein B (0.6 microgram/ml per day), and apolipoprotein A-I (1 microgram/ml per day). However, they secrete apoB-containing TG-rich lipoproteins mainly in the LDL density range, while short-term cultured primary hepatocytes mainly secrete TG-rich lipoproteins in the VLDL density range. In conclusion, functions that are rapidly lost in short-term hepatocyte cultures are, in general, not displayed by IHH cells. Immortalized human hepatocytes provide a valuable tool for studying the regulation of hepatocyte proliferation-related phenomena.
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PMID:Immortalized human hepatocytes as a tool for the study of hepatocytic (de-)differentiation. 929 58

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