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Enzyme
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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)
Expression of the
multidrug-resistance protein
gene
MRP
, which confers non-
P-glycoprotein
-mediated multidrug resistance, has been found in many drug-resistant variants and tumor samples. Recent studies have demonstrated that
MRP
functions as an ATP-dependent transporter functionally related to the previously described glutathione-conjugate (GS-X) pump. We have shown recently that the
MRP
and gamma-glutamylcysteine synthetase (gamma-GCS) heavy subunit mRNA levels are coordinately overexpressed in cisplatin (CP)-resistant human leukemia cells (Ishikawa et al., J Biol Chem 271: 14981-14988, 1996) and frequently co-elevated in human colorectal tumors (Kuo et al., Cancer Res 56: 3642-3644, 1996). In the present study, we showed the coexpression patterns of thirteen additional human drug-resistant cell lines representing different tumor cell origins selected with different agents, except for one doxorubicin-selected line which demonstrated minor elevation in
MRP
mRNA with no detectable increase in gamma-GCS mRNA, suggesting that the increase of
MRP
mRNA preceded the increase in gamma-GCS mRNA. Furthermore, in seventeen randomly selected untreated tumor cell lines, the overall correlation coefficient between
MRP
and gamma-GCS mRNA levels was 0.861. In normal mice, the correlation coefficient of mrp and gamma-gcs mRNA was 0.662 in fourteen tissues (kidney and liver were not included) analyzed. Kidney and liver expressed low levels of mrp relative to gamma-gcs; however, these two tissues expressed high levels of a functionally related mrp homologue, mrp2 (cMoat or cMrp), which may have compensated for the underexpressed mrp in maintaining the total GS-X pump activities. Altogether, these results demonstrated the frequent coexpression of these two genes in various cell settings.
...
PMID:Frequent coexpression of MRP/GS-X pump and gamma-glutamylcysteine synthetase mRNA in drug-resistant cells, untreated tumor cells, and normal mouse tissues. 951 71
ABC transporters are a large superfamily of integral membrane proteins involved inATP-dependent transport across biological membranes. Members of this superfamily play roles in a number of phenomena of biomedical interest, including cystic fibrosis (CFTR) and multidrug resistance (
P-glycoprotein
,
MRP
). Most ABC transporters are predicted to consist of four domains, two membrane-spanning domains and two cytoplasmic domains. The latter contain conserved nucleotide-binding motifs. Attempts to determine the structure of ABC transporters and of their separate domains are in progress but have not yet been successful. To aid structure determination and possibly learn more about the domain boundaries, we set out to model nucleotide-binding domains (NBDs) of ABC transporters based on a known structure. Previous attempts to predict the 3D structure of NBDs were based solely on sequence similarity with known nucleotide-binding folds. We have analyzed the sequences of a number of nucleotide-binding domains with the algorithm THREADER, developed by D.T. Jones, and a possible fold was found in the structure of aspartate aminotransferase. We present a model for the N-terminal NBD of CFTR, based on the large domain of the A chain of aspartate aminotransferase. The model is refined using multiple sequence alignment, secondary structure prediction, and 3D-1D profiles. Our model seems to be in good agreement with known properties of nucleotide-binding domains and has some appealing characteristics compared with the previous models.
...
PMID:A model for the nucleotide-binding domains of ABC transporters based on the large domain of aspartate aminotransferase. 951 43
The overexpression of two membrane glycoproteins,
P-glycoprotein
and
multidrug-resistance protein
(MRP1) is a major cause of resistance to chemotherapeutic agents in the treatment of human cancers. Both proteins confer a similar multidrug-resistant (MDR) phenotype. 99mTc-MIBI, a myocardial imaging agent, which is also useful for the detection of a variety of tumours, has been shown to be a substrate for
P-glycoprotein
and MRP1. It thus may provide additional information about the
P-glycoprotein
and MRP1 status of tumour cells. In order to obtain information on the substrate specificity of these proteins, we have studied the transport kinetics of Tc-MIBI in two cell lines, K562/ADR and GLC4/ADR, which overexpress
P-glycoprotein
and MRP1, respectively. The mean active efflux coefficient ka, which is proportional to the ratio of maximal efflux rate VM to the apparent Michaelis-Menten constant Km, used to characterise the efficiency of the active efflux, was very similar being 1.9 +/- 0.6 x 10(-11) s(-1) x cells x ml and 1.3 +/- 0.5 x 10(-11) s(-1) x cells x ml for drug-resistant K562 and GLC4, respectively. These values are 50-100-times lower than for daunorubicin and other anthracycline derivatives, strongly suggesting that the efficiency of both transporters to pump Tc-MIBI is by far less than that to efflux anthracyclines. Our data show that (a)
P-glycoprotein
and
MRP
transporter efficiencies to wash out Tc-MIBI are similar, in spite of a different suspected mechanism of its transport and (b) that both transporters are less efficient to pump Tc-MIBI than to pump anthracyclines (the ka parameter is about 100-times lower for TC-MIBI than for anthracycline).
...
PMID:Comparison of the kinetics of active efflux of 99mTc-MIBI in cells with P-glycoprotein-mediated and multidrug-resistance protein-associated multidrug-resistance phenotypes. 952 23
Mevalonate pathway inhibitor lovastatin inhibited proliferation of human multidrug-resistant promyelocytic leukemia HL-60/ADR cells in vitro, with
MRP
-gene coded p190 mediated drug resistance, to a markedly lesser extent than that of the parental drug sensitive HL-60 cells and also that of the other human multidrug resistant (MDR-1,
P-glycoprotein
) myeloid leukemia cell line HL-60/VCR. The sensitivity of the examined human leukemia cell lines to the cytostatic activity of lovastatin correlated approximately with the potential of lovastatin to induce the characteristic cell cycle alteration (i.e. the accumulation of lovastatin-treated cells in the G0/G1 phase of the cell cycle). The
P-glycoprotein
positive HL-60/VCR cells and the parental drug sensitive HL-60 cells were more sensitive to this cell cycle alteration than the HL-60/ADR multidrug resistant leukemia cells with
MRP
drug resistance. Lovastatin (72 hours, 20 micromol) induced apoptosis and cell necrosis in HL-60 cells, apoptosis but not cell necrosis in HL-60/VCR cells and neither apoptosis nor necrosis in HL-60/ADR cells.
...
PMID:Human multidrug-resistant (MRP,p190) myeloid leukemia HL-60/ADR cells in vitro: resistance to the mevalonate pathway inhibitor lovastatin. 960 9
To evaluate the clinical significance of drug resistance mechanisms in breast cancer, we examined the expression of MDR1 and
MRP
in primary breast carcinoma and normal adjacent tissue using a highly quantitative and reproducible reverse transcription-PCR assay. Expression of both genes was observed in all specimens examined, both tumor (n = 74) and normal adjacent tissue (n = 55). The expression of MDR1, however, was low, with the level of expression being 25 times less than the drug-resistant control cell line KB 8-5. Immunohistochemical analysis of
P-glycoprotein
corroborated the PCR results; only 6% (2 of 31) were positive for JSB1 staining, and 0 of 32 were positive for for UIC2.
MRP
expression did not exceed control cell line levels, and immunohistochemistry detected moderate levels of expression. MDR1 expression was independent of grade, stage, tumor size, nodal status, metastasis, and estrogen receptor and progesterone receptor status. There was, however, a significant correlation of MDR1 expression with age and histology. Approximately twice the expression of MDR1 was observed in the < 50 age group compared to the > 50 age group, and lobular carcinoma had 4 times the expression of MDR1 of other histological types.
MRP
expression was independent of all other clinical parameters. Thus, these results show that although MDR1 expression is detectable in primary breast carcinoma by PCR, this expression as measured by quantitative reverse transcriptase-PCR is extremely low. The significance of these low levels is yet to be determined. MDR1 expression was higher in < 50 age group and lobular carcinoma, which may contribute to poor prognosis associated with young age and lobular histology.
...
PMID:Quantitative reverse transcriptase-polymerase chain reaction measured expression of MDR1 and MRP in primary breast carcinoma. 962 74
The membrane proteins mediating the ATP-dependent transport of glutathione S-conjugates and related amphiphilic anions have been identified as the multidrug resistance proteins MRP1 and MRP2. These 190-kDa membrane glycoproteins were cloned in recent years and shown to be unidirectional, ATP-driven, export pumps with an amino acid identity of 49% in humans. MRP1 is detected in the plasma membrane of many cell types, including erythrocytes; whereas MRP2, also termed canalicular
MRP
(cMRP) or canalicular multispecific organic anion transporter (cMOAT), has been localized to the apical domain of polarized epithelia, such as the hepatocyte canalicular membrane and kidney proximal tubule luminal membrane. Physiologically important substrates of both transporters include glutathione S-conjugates, such as leukotriene C4, as well as bilirubin glucuronides. 17 beta-glucuronosyl estradiol and glutathione disulfide. Both transporters have been associated with multiple drug resistance of malignant tumors because of their capacity to pump drug conjugates and drug complexes across the plasma membrane into the extracellular space. The substrate specificity of MRP1 and MRP2 studied in inside-out oriented membrane vesicles is very different from MDR1
P-glycoprotein
. MRP1 and MRP2 may be termed conjugate transporting ATPases, functioning in detoxification and, because of their role in glutathione disulfide export, in the defense against oxidative stress.
...
PMID:ATP-dependent transport of glutathione S-conjugates by the multidrug resistance protein MRP1 and its apical isoform MRP2. 967 51
Cross-resistance between different cytostatic agents which are structurally and functionally dissimilar is a common phenomenon called multidrug resistance (MDR). The best characterized mechanism of MDR involves
P-glycoprotein
. However, this does not completely explain MDR. Within the last few years, two new genes that can confer MDR have been identified (
MRP
and LRP). Furthermore, topoisomerase II has been associated with a special form of MDR. During the past several years, considerable interest has been shown in strategies to reverse MDR by using pharmacological compounds, monoclonal antibodies, immunotoxins, bispecific antibodies, antisense oligodeoxynucleotides, ribozymes, and albumin-conjugated drugs in in vitro and in vivo assays. All these experimental assays demonstrated that MDR can be circumvented. Two agents that have received the most attention in the clinic are verapamil and cyclosporin A. Despite some promising results (especially in hematological malignancies), the results obtained in the treatment of solid tumors with modulators have so far been quite disappointing. This may be explained by the fact that the MDR phenotype alone does not completely account for the resistance of human cancer. Several other resistance-related proteins (e.g., glutathione S-transferase, metallothionein, O6-alkylguanine-DNA-alkyltransferase, thymidylate synthase, dihydrofolate reductase, heat shock proteins) can be also expressed in resistant tumors. Additionally, cell proliferation, vascularization and apoptosis are involved in resistance.
...
PMID:Multidrug resistance and its reversal. 971 85
Cross resistance to multiple natural cytotoxic products represents a major obstacle in myeloblastic acute leukaemia (AML). Multidrug resistance (MDR) often involves overexpression of plasma membrane drug transporter
P-glycoprotein
(
PGP
) or the resistance associated protein (
MRP
). Recently, a protein overexpressed in a non-
PGP
MDR lung cancer cell line and termed lung resistance related protein (LRP) was identified. These proteins are known to be associated with a bad prognosis in AML. We have developed a triple indirect labelling analysed by flow cytometry to detect the coexpression of these proteins. Since no cell line expressing all three antigens is known, we mixed K562 cells (resistant to Adriblastine, PGP+,
MRP
-, LRP-) with GLC4 cells (resistant to Adriblastine,
PGP
-, MRP+, LRP+) to create a model system to test the method. The antibodies used were UIC2 for
PGP
, MRPm6 for
MRP
and LRP56 for LRP. They were revealed by Fab'2 coupled with Fluoresceine-isothiocyanate, Phycoerythrin or Tricolor with isotype specificity. Cells were fixed and permeabilized after
PGP
labelling because MRPm6 and LRP56 recognize intracellular epitopes.
PGP
and LRP were easily detected.
MRP
is expressed at relatively low levels and was more difficult to detect because in the triple labelling the non specific staining was higher than in a single labelling. Despite the increased background in the triple labelling we were able to detect coexpression of
PGP
,
MRP
, LRP by flow cytometry. This method appears to be very useful to detect coexpression of markers in AML. Such coexpression could modify the therapeutic approach with revertants.
...
PMID:Coexpression of multidrug resistance involve proteins: a flow cytometric analysis. 971 98
The measurement of rhodamine 123 (Rho123) efflux in hematological malignancies, using flow-cytometry, provides an accurate assessment of multidrug resistance (MDR) of both
P-glycoprotein
and
MRP
. While their normal counterparts display high levels of PgP and Rho123 efflux, we investigated the MDR status of marked T/NK proliferations. When diagnosed according to natural killer (NK) markers (CD16, CD56, CD57) 8 of nine NK lymphoproliferative disorders (LPD) were markedly positive (3 NK non Hodgkin's lymphomas (NHL), 1 NK lymphoproliferative disease of large granular lymphocytes (LGL), and 5 T/NK LGL). These results are in accordance with the observed response to chemotherapy in the treated cases. Mature T LPD (prolymphocytic leukemia (PLL), and NHL) cells gave varying results, as did cells from Sezary syndromes. Marked Rho123 efflux was detected in the two cases of T-PLL suggesting the expression of
MRP
as previously described. Immature T-lymphomas or leukemias (6 cases) were all negative. These data should be considered in relation to NK proliferations which clearly display an MDR phenotype and therefore raise the question, of the relevance of this phenotype in normal cells, and secondly of the negativity of immature T-LPD. The latter could indicate that MDR inhibitors may be superfluous in the initial treatment of acute lymphoblastic leukemia (ALL). Finally the resistance to treatment of T-ALL or mature T cells LPD invokes the importance of exploring other mechanisms of drug resistance such as the lung resistance related protein (LRP).
...
PMID:Multidrug resistance in aggressive lymphoproliferative disorders of T and natural-killer origin. 971 68
ATP-binding cassette (ABC), ATP-dependent transporters are a large superfamily of proteins that include the multidrug resistance proteins,
P-glycoprotein
and
MRP
(multidrug resistance protein). The ARA (anthracycline resistance-associated) gene that codes for a putative member of the ABC transporters has recently been cloned and shown to have high sequence homology to the gene for
MRP
. We have previously shown
MRP
to be deleted in a subset of inv(16) leukemic patients. The deletion of
MRP
was associated with an improved patient survival compared with inv(16) patients who did not have such a deletion. In this study, the ARA gene is mapped to 16p13.1, in the same physical interval as the inv(16) short-arm breakpoint. It is shown to be situated proximal to both MYH11, the gene involved in the primary breakpoint on the short arm of the inv(16), and
MRP
. A YAC clone has been isolated containing both
MRP
and ARA. FISH analysis of metaphase chromosomes from inv(16) patients has established the gene order as telomere-MYH11-
MRP
-ARA-centromere and demonstrated that both ARA and
MRP
are deleted in a subgroup of the inv(16) leukemias. ARA and
MRP
are both shown to be expressed in normal hematopoietic precursors including CD34(+) cells. The mapping of ARA to this region and its homology to
MRP
raises questions about its potential role in the biology of the inv(16) leukemias.
...
PMID:ARA, a novel ABC transporter, is located at 16p13.1, is deleted in inv(16) leukemias, and is shown to be expressed in primitive hematopoietic precursors. 972 Dec 17
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