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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 interaction of etoposide (VP-16), Vinca alkaloids, and verapamil with the
P-glycoprotein
(
P-gp
) was studied in human breast (MCF-7) and Chinese hamster lung (DC3F) cell lines and the corresponding multidrug-resistant MCF-7/ADR and DC3F/
ADX
tumor cell lines, selected for resistance to Adriamycin and actinomycin D, respectively, and overexpressing
P-gp
. Verapamil (10 microM) markedly reversed resistance to vincristine (11-fold in DC3F/
ADX
and 125-fold in MCF-7/ADR; 1-hr exposure), but it had a very modest effect on resistance to VP-16 (3- to 4-fold; 1-hr exposure). Resistant cells accumulated 2- to 4-fold less VP-16 and vincristine than the parental cell lines. Verapamil (10 microM) significantly increased accumulation and retention of vincristine, but not of VP-16, in resistant cell lines. Photoaffinity labeling of resistant cell lines with radioactive analogs of verapamil [N(p-azido-3-125I-salicyl)-N'-beta-aminoethylverapamil (NASVP)] and vinblastine[N-(p-azido-3-125I-salicyl)-N'-beta-aminoethylvindesine (NASV)] showed distinctly labeled
P-gp
bands in both resistant cell lines, compared with wild-type cells. Excess nonradioactive vinblastine or verapamil effectively competed with the
P-gp
photolabeling by either NASVP or NASV, with IC50 levels of 0.6 and 10 microM, respectively. In contrast, nonradioactive VP-16 was 100- to 500-fold less potent than vinblastine in competing with
P-gp
photolabeling, suggesting that VP-16 has significantly lower affinity for
P-gp
than Vinca alkaloids have. Taken together, our data indicate that
P-gp
glycoprotein by itself may not be important in the transport/efflux of VP-16 and, thus, in the mechanism of resistance to VP-16 in these cells.
...
PMID:P-glycoprotein-independent mechanism of resistance to VP-16 in multidrug-resistant tumor cell lines: pharmacokinetic and photoaffinity labeling studies. 197 71
A radioactive photoactive dihydropyridine calcium channel blocker, [3H]azidopine, was used to photoaffinity label plasma membranes of multidrug-resistant Chinese hamster lung cells selected for resistance to vincristine (DC-3F/VCRd-5L) or actinomycin D (DC-3F/
ADX
). Sodium dodecyl sulfate-polyacrylamide gel electrophoretic fluorograms revealed the presence of an intensely radiolabeled 150-180-kDa doublet in the membranes from drug-resistant but not from the drug-sensitive parental (DC-3F) cells. A similar radiolabeled doublet was barely detected in a drug-sensitive partial revertant (DC-3F/
ADX
-U) cell line. The 150-180-kDa doublet exhibited a specific half-maximal saturable photolabeling at 1.07 X 10(-7) M [3H]azidopine. The dihydropyridine binding specificity was established by competitive blocking of specific photolabeling with nonradioactive azidopine as well as with nonphotoactive calcium channel blockers nimodipine, nitrendipine, and nifedipine. In addition, [3H]azidopine photolabeling was blocked by verapamil and diltiazem but was stimulated by excess prenylamine and bepridil suggesting a cross-specificity for up to four different classes of calcium channel blockers. The 150-180-kDa calcium channel blocker acceptor co-electrophoresed exactly with the 150-180-kDa surface membrane glycoprotein (gp150-180 or
P-glycoprotein
) Vinca alkaloid acceptor from multidrug-resistant cells and was immunoprecipitated by polyclonal antibody recognizing gp150-180. [3H]Azidopine photolabeling of the 150-180-kDa component in the presence of excess vinblastine was reduced over 90%, confirming the identity or close relationship of the calcium channel blocker acceptor and the gp150-180 Vinca alkaloid acceptor. The [3H]azidopine photolabeling of gp150-180 also was reduced by excess actinomycin D, adriamycin, or colchicine, demonstrating a broad gp150-180 drug recognition capacity. The ability of gp150-180 to recognize multiple natural product cytotoxic drugs as well as calcium channel blockers suggests a direct function for gp150-180 in the multidrug resistance phenomenon and a role in the circumvention of that resistance by calcium channel blockers.
...
PMID:Identification of the multidrug resistance-related membrane glycoprotein as an acceptor for calcium channel blockers. 303 8
The main line of defense now available against parasitic protozoa--which are responsible for major diseases of humans and domestic animals--is chemotherapy. This defense is being eroded by drug resistance and, with few new drugs in the pipeline, prevention and circumvention of resistance are medical and veterinary priorities. Although studies of resistance mechanisms in parasites have lagged behind similar studies in bacteria and cancer cells, the tools to tackle this problem are rapidly improving. Transformation with exogenous DNA is now possible with all major parasitic protozoa of humans. Hence, putative resistance genes can be tested in sensitive protozoa, allowing an unambiguous reconstruction of resistance mechanisms. Gene cloning, the polymerase chain reaction, and monoclonal antibodies against resistance-related proteins have made it possible to analyze potential resistance mechanisms in the few parasites that can be obtained from infected people. Hence, the prospect of applying new knowledge about resistance mechanisms to parasites in patients is good, even though today virtually all knowledge pertains to parasites selected for resistance in the laboratory. Resistance mechanisms highlighted in this review include: 1. Decrease of drug uptake because of the loss of a transporter required for uptake. This decrease contributes to resistance to arsenicals and diamidines in African trypanosomes. 2. The export of drugs from the parasite by P-glycoproteins and other traffic ATPases. This export could potentially be an important mechanism of resistance, as these proteins are richly represented in the few protozoa analyzed. There are indications that such transmembrane transporters can be involved in resistance to emetine in Entamoeba spp., to mefloquine in Plasmodium spp., and to antimonials in Leishmania spp. 3. The possible involvement of the
P-glycoprotein
encoded by the Plasmodium falciparum pfmdr1 gene in chloroquine resistance. We present the available data that lead to the conclusion that overproduction of the wild-type version of this protein results in chloroquine hypersensitivity rather than resistance. 4. The involvement of the PgpA
P-glycoprotein
of Leishmania spp. in low-level resistance to arsenite and antimonials. We raise the possibility that this protein transports glutathione conjugates of arsenite and antimonials rather than the compounds themselves. 5. Loss of drug activation as the main mechanism of metronidazole resistance in Trichomonas and Giardia spp. Recent evidence indicates that a decrease of the proximal cellular electron donor for metronidazole activation,
ferredoxin
, is the main cause of resistance in Trichomonas. 6. Resistance arising through alteration of drug targets. The amino acid substitutions in the dihydrofolate reductase-thymidylate synthase of Plasmodium spp. are good examples of this mechanism.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:New mechanisms of drug resistance in parasitic protozoa. 856 67
P-glycoprotein
(
P-gp
) is a membranous ATPase responsible for the multidrug resistance (MDR) phenotype. Using membrane vesicles prepared from the highly resistant cell line DC-3F/
ADX
we studied the influence of
P-gp
ATPase activity of four progesterone derivatives which specifically bind to
P-gp
and reverse MDR. Progesterone and desoxycorticosterone stimulate
P-gp
ATPase activity with, respectively, apparent concentrations giving half-maximal activation of 20-25 microM and 40-50 microM, and activation factors of 2.3 (at 100 microM progesterone) and 1.8 (at 170 microM desoxycorticosterone). Hydrocortisone above 100 microM stimulates
P-gp
ATPase activity while corticosterone has no apparent stimulating effect. Our data are consistent with the location of the binding sites for the progesterone derivatives on the
P-gp
membranous domain. The effects of these steroids on verapamil-stimulated
P-gp
ATPase activity support a non-competitive mechanism, i.e. the binding sites for verapamil and steroids are mutually non-exclusive for
P-gp
ATPase modulation. A similar non-competitive inhibition of progesterone-stimulated
P-gp
ATPase activity by desoxycorticosterone or by corticosterone leads to the conclusion that these steroids, although sharing related structures, have distinct modulating sites on
P-gp
. As expected from their mutually non-exclusive interactions on
P-gp
, progesterone and verapamil when mixed induce a synergistic modulation of
P-gp
ATPase activity. Since drug transport by
P-gp
is believed to be coupled to its ATPase activity, a corresponding synergistic effect of these two modulators for the inhibition of
P-gp
-mediated drug resistance can be expected.
...
PMID:Effects of steroids and verapamil on P-glycoprotein ATPase activity: progesterone, desoxycorticosterone, corticosterone and verapamil are mutually non-exclusive modulators. 871 80
P-glycoprotein
, a plasma membrane protein overexpressed in multidrug-resistant (MDR) cells, exhibits in vitro an ATPase activity and is responsible for the energy-dependent efflux of structurally unrelated cytotoxic drugs (like vinblastine) and various MDR-reversing agents (like verapamil and progesterone) from these MDR cells. To investigate the mechanism of
P-glycoprotein
interaction with various compounds, we measured the
P-glycoprotein
ATPase activity on membrane vesicles prepared from the MDR cell line DC-3F/
ADX
, and we studied the effects of vinblastine, verapamil and progesterone on this ATPase activity. The basal
P-glycoprotein
ATPase activity is increased by verapamil and progesterone, with respective half-maximal activating concentrations of approximately 1.5 microM and approximately 25 microM, and activation factors of approximately 1.7 and approximately 2.2. Vinblastine inhibits the activation of
P-glycoprotein
ATPase induced by verapamil or progesterone with an inhibition constant approximately 0.5 microM in both cases. This demonstrates that vinblastine has a specific modulating site on
P-glycoprotein
. The combined modulation of
P-glycoprotein
ATPase by vinblastine and verapamil reveals that these two drugs are mutually exclusive. Since these two molecules have different effects both on the basal
P-glycoprotein
ATPase activity and on the MgATP concentration dependence of
P-glycoprotein
ATPase activity, they could bind
P-glycoprotein
either on different and overlapping sites, or on distant but interacting sites. In contrast, the combined modulation of
P-glycoprotein
ATPase by vinblastine and progesterone reveals a non-competitive relationship between these two drugs, and hence shows that they can independently and simultaneously bind
P-glycoprotein
on distinct sites. Since verapamil and progesterone are mutual inhibitors of
P-glycoprotein
ATPase stimulation in a non-competitive manner, these two molecules can also bind independently
P-glycoprotein
on separated sites. This is confirmed here by the observation of a synergistic effect when mixtures of verapamil and progesterone are tested for the modulation of
P-glycoprotein
ATPase. Three MDR-related molecules, taken as models for interaction with
P-glycoprotein
, appear thus to bind on at least two different separated specific sites. These results favor a multisite model rather than a universal site model to describe the broad substrate specificity characterizing
P-glycoprotein
function.
...
PMID:Competitive and non-competitive inhibition of the multidrug-resistance-associated P-glycoprotein ATPase--further experimental evidence for a multisite model. 911 38
The multidrug resistance (MDR)-associated
P-glycoprotein
(
P-gp
) is a membrane transporter which carries, at the expense of MgATP hydrolysis, many amphiphilic molecules, such as the MDR-related cytotoxic drugs vincristine and vinblastine, and the MDR-reversing agents verapamil and progesterone. We have tested the effects on
P-gp
function of bromocriptine (BCT), an ergot alkaloid known as a D2 dopaminergic receptor agonist. BCT (at 4 microM) partially reverses the
P-gp
-mediated vincristine resistance of the Chinese hamster lung fibroblasts DC-3F/
ADX
, a MDR cell line.
P-gp
containing membrane vesicles prepared from the DC-3F/
ADX
cells exhibit, in the absence of any added drug, a basal MgATPase activity due to
P-gp
. BCT inhibits this basal ATPase activity, with a half-inhibiting concentration of 0.30 +/- 0.15 microM. BCT also inhibits the verapamil-induced
P-gp
ATPase stimulation competitively (Ki approximately 0.2 microM), and the progesterone-induced
P-gp
ATPase stimulation non-competitively (Ki approximately 0.07-0.10 microM). BCT also non-competitively inhibits the vinblastine-dependent
P-gp
ATPase activity within the same concentration range. Hydroxylated metabolites of BCT have different effects on
P-gp
ATPase, only the monohydroxylated being able to modulate both the basal and the drug-stimulated ATPase activities. In conclusion, these effects of BCT on
P-gp
function can be linked to a specific interaction with
P-gp
, probably involving inhibition of
P-gp
-mediated drug transport.
...
PMID:Bromocriptine modulates P-glycoprotein function. 951 44
P-Glycoprotein, the plasma membrane protein responsible for the multidrug resistance of some tumour cells, is an active transporter of a number of structurally unrelated hydrophobic drugs. We have characterized the modulation of its ATPase activity by a multidrug-resistance-related cytotoxic drug, vinblastine, and different multidrug-resistance-reversing agents, verapamil and the dihydropyridines nicardipine, nimodipine, nitrendipine, nifedipine and azidopine. P-Glycoprotein ATPase activity was measured by using native membrane vesicles containing large amounts of
P-glycoprotein
, prepared from the highly multidrug-resistant lung fibroblasts DC-3F/
ADX
. P-Glycoprotein ATPase is activated by verapamil and by nicardipine but not by vinblastine. Among the five dihydropyridines tested, the higher the hydrophobicity, the higher was the activation factor with respect to the basal activity and the lower was the half-maximal activating concentration. The vinblastine-specific binding on
P-glycoprotein
is reported by the inhibitions of the verapamil- and the nicardipine-stimulated ATPase. These inhibitions are purely competitive, which means that the bindings of vinblastine and verapamil, or vinblastine and nicardipine, on
P-glycoprotein
are mutually exclusive. In contrast, verapamil and nicardipine display mutually non-competitive interactions. This demonstrates the existence of two distinct specific sites for these two
P-glycoprotein
modulators on which they can bind simultaneously and separately to the vinblastine site. The nicardipine-stimulated ATPase activity in the presence of the other dihydropyridines shows mixed-type inhibitions. These dihydropyridines have thus different binding sites that interact mutually to decrease their respective, separately determined affinities. This could be due to steric constraints between sites close to each other. This is supported by the observation that vinblastine binding is not mutually exclusive with nifedipine or nitrendipine binding, whereas it is mutually exclusive with nicardipine. Moreover, verapamil binding also interacts with the five dihydropyridines by mixed inhibitions, with different destabilization factors. On the whole our enzymic data show that
P-glycoprotein
has distinct but interacting binding sites for various modulators of its ATPase function.
...
PMID:Multidrug resistance transporter P-glycoprotein has distinct but interacting binding sites for cytotoxic drugs and reversing agents. 965 75
P-glycoprotein
(
P-gp
), a plasma membrane glycoprotein associated with the multidrug resistance phenotype, is responsible for the ATP-dependent efflux of various amphiphilic drugs. Using membrane vesicles prepared from the multidrug resistant cell line DC-3F/
ADX
, we studied the perturbation of the basal (i.e. in the absence of drug) and verapamil-dependent
P-gp
ATPase activities induced by various detergents, at non-solubilizing, as well as at solubilizing, concentrations. The progressive membrane solubilization with increasing detergent concentration was monitored by light scattering and centrifugation experiments. For non-solubilizing detergent concentrations, all tested detergents except DOC induced a partial inhibition of
P-gp
ATPase activity, which was not correlated with the amount of the various tested detergents incorporated in the membranes. Analysis of the verapamil-induced
P-gp
activation reveals that
P-gp
ATPase activity is differently modulated by the various detergents at non-solubilizing concentrations. Thus, specific interactions between
P-gp
and detergents are more likely to occur rather than a global membrane perturbation. After solubilization by the various tested detergents, the basal
P-gp
ATPase activity was virtually completely inhibited, except in the presence of CHAPS which was able to preserve this activity at a level comparable to that measured in native membranes. However, the verapamil-induced
P-gp
ATPase activation was lost during
P-gp
solubilization by CHAPS, but recovered after dilution of CHAPS below its critical micellar concentration. These observations indicate specific interactions between
P-gp
and CHAPS molecules within the mixed micelles. On the whole, our data evidencing specific interactions
P-gp
/detergents are consistent with the location of the drug transport sites on
P-gp
transmembrane domains.
...
PMID:Effects of detergents on P-glycoprotein atpase activity: differences in perturbations of basal and verapamil-dependent activities. 992 70
The multidrug resistant cell line DC-3F/ADII was obtained by stepwise selection for growth in actinomycin D (ActD). Compared with parental cells, it displays high resistance to ActD and vincristine and low resistance to colchicine and daunorubicin. These cells overexpress a form of
P-glycoprotein
(Pgp1) containing a double mutation, I837L and N839I, in transmembrane domain (TM) 9; when transfected into DC-3F, this mutation confers the DC-3F/ADII phenotype. We have shown previously that another cell line, DC-3F/
ADX
, also displays this phenotype and overexpresses a mutant form of Pgp1 containing a double mutation in TM6 (G338A, A339P). Hence, mutations in TM9 and TM6 are independently capable of conferring the same cross-resistance phenotype. The TM6 mutations inhibit the ability of cyclosporin A to reverse cross-resistance and to block labeling of the protein by [125I]iodoarylazidoprazosin (IAAP), whereas the TM9 mutations do not show similar effects. A chimeric protein containing both pairs of mutations confers twice the level of resistance to ActD than expected from the sum of the individual mutations, but it cannot be labeled to detectable levels with [125I]IAAP. Thus, TM9 represents a novel site that cooperates with TM6 to mediate drug resistance and [125I]IAAP labeling.
...
PMID:Transmembrane domain (TM) 9 represents a novel site in P-glycoprotein that affects drug resistance and cooperates with TM6 to mediate [125I]iodoarylazidoprazosin labeling. 1145 11
