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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 human MDR1 gene encodes the multidrug transporter (
P-glycoprotein
), a multidrug efflux pump. The highly homologous MDR2 gene product does not appear to be a functional multidrug pump. We have constructed a
chimeric protein
in which the first intracytoplasmic loop and the third and fourth transmembrane domains of the MDR1 protein were replaced by the analogous region of MDR2. Substitution of the MDR2 sequences encompassing amino acid residues 140 to 229 resulted in 17 amino acid changes, 10 in the intracytoplasmic loop (amino acids 141-188) and 7 in the transmembrane regions. This
chimeric protein
was expressed on the surface of NIH 3T3 cells where it bound [3H]azidopine but did not confer drug resistance. When only 4 residues, 165, 166, 168, and 169, were changed back to MDR1 amino acids, a functional drug transporter was recovered. When residues 165, 166, 168, and 169 from MDR2 were substituted into a functional MDR1 cDNA, the resulting construction was not able to confer drug resistance. These results indicate that the major functional differences between MDR1 and MDR2 in this region of
P-glycoprotein
reside in a small segment of the first intracytoplasmic loop. We also independently analyzed the effect of replacing Asn183 of MDR1 with Ser which occurs in MDR2. Substitution of Ser at position 183 in combination with Val at position 185 in
P-glycoprotein
resulted in a relative increase in resistance to actinomycin D, vinblastine, and doxorubicin in transfected NIH 3T3 cells. These results emphasize the importance of the first intracytoplasmic loop in
P-glycoprotein
in determining function and relative drug specificity of the transporter.
...
PMID:Identification of residues in the first cytoplasmic loop of P-glycoprotein involved in the function of chimeric human MDR1-MDR2 transporters. 136 Sep 83
Human MDR1 encodes an ATP-binding cassette transporter,
P-glycoprotein
, that mediates multiple drug resistance (MDR) to antitumor agents. It has been previously shown that photoaffinity drug-labeling sites reside within, or near, the last transmembrane loop of each cassette within
P-glycoprotein
(transmembrane domains (TM) 5-6 and 11-12). A genetic approach was used to determine if the drug-labeling site in the second cassette contains functionally important amino acids. Since human MDR3 is 77% identical to MDR1 but does not mediate MDR, the region from TM10 to the C terminus of MDR1 was replaced with the corresponding sequences from MDR3. The resultant
chimeric protein
was expressed but not functional. By using progressively smaller replacements, we show that replacements limited to TM12 markedly impaired resistance to actinomycin D, vincristine, and doxorubicin, but not to colchicine. The phenotype was associated with an impaired ability to photoaffinity label the chimeric
P-glycoprotein
with [125I]iodoaryl azidoprazosin. In contrast, replacement of the loop between TM11 and 12 appears to create a more efficient drug pump for actinomycin D, colchicine, and doxorubicin, but not vincristine. These results suggest that, similar to voltage-gated ion channels, amino acids within and immediately N-terminal to the last transmembrane domain of
P-glycoprotein
compose part of the drug-binding pocket and are in close proximity to photoaffinity drug-labeling domains.
...
PMID:Functional evidence that transmembrane 12 and the loop between transmembrane 11 and 12 form part of the drug-binding domain in P-glycoprotein encoded by MDR1. 789 Jun 59
Understanding how the multidrug resistance phenotype is manifest in human cancer cells will require insight into the mechanism of assembly, transmembrane topology, and intracellular trafficking of human
P-glycoprotein
(MDR1). Previously, we showed that MDR1 amino terminus biogenesis occurred through an unexpected interaction between novel topogenic sequence subtypes and that transmembrane topology of corresponding amino and carboxy halves was not equivalent. We now investigate topology and topogenic activities of the third and fourth transmembrane regions (TM3 and TM4) of human MDR1 using protease protection of defined reporter epitopes expressed in Xenopus laevis oocytes. As was previously observed for TM1 and TM2, determinants in TM3 and TM4 exhibited cooperativity in directing proper assembly and transmembrane orientation. The signal sequence encompassing TM3 required residues from TM4 to reinitiate translocation of the MDR1 chain into the endoplasmic reticulum (ER) lumen. Remaining residues from TM4 terminated translocation and established a polytopic transmembrane topology in which TM3 and TM4 both spanned the membrane in the orientation predicted by hydropathy-based models. Remarkably, when translocating sequentially into the ER lumen, neither TM4 alone nor TM4 together with TM3 efficiently terminated translocation. Thus, MDR1 biogenesis required both the presence of these sequences and their proper orientation with respect to the ER translocation apparatus. This conclusion was supported by experiments in which TM3 and TM4 topology was reproduced in a defined
chimeric protein
which mimicked native MDR1 presentation. These additional variations on simple themes of protein topogenesis utilized by MDR1 demonstrate that events of complex protein biogenesis may be dissected and studied using protein chimeras with defined translocation properties.
...
PMID:Transmembrane orientation and topogenesis of the third and fourth membrane-spanning regions of human P-glycoprotein (MDR1). 791 95
Human
P-glycoprotein
(Pgp) confers multidrug resistance (MDR) to otherwise sensitive cells. The homologous mouse Pgps, which are encoded by mouse mdr1a (also known as mdr3) and mdr1b (also known as mdr1), confer different degrees of resistance to the same MDR drugs and inhibitors. To create recombinants for the study of sequences responsible for these differences in drug-resistance, chimeric cDNA libraries can be constructed by homologous recombination of pools of related sequences. This mutagenesis approach is called DNA shuffling. To select for chimeric Pgp with an altered resistance profile, DNA shuffling between the homologous but not identical drug interacting transmembrane domains 5 and 6 of human MDR1 and mouse mdr1a was used. The chimeric proteins were expressed in human KB-3-1 cells. One recombinant Pgp (clone 3-4) with a novel phenotype was analyzed in detail. Inhibitors of Pgp, including verapamil and cyclosporin A, were less effective in reversing resistance of the chimeric Pgp compared with wild-type Pgp, for certain drugs. However, [125I]iodoarylazidoprazosin photoaffinity labeling of the chimeric Pgp and its binding competition with cyclosporin A, showed that cyclosporin A competed for the photoaffinity labeling. The chimeric Pgp cells stained less well with human-specific anti-Pgp mAb MRK16 than wild-type Pgp, despite having the described epitopes for MRK16. Staining with human-specific mAb UIC2 was increased when the
chimeric protein
was compared with wild-type Pgp. These results suggest an alteration in exposure of human Pgp specific epitopes in this chimeric Pgp, as well as a change in the interaction of reversing agents with the
chimeric protein
.
...
PMID:Analysis of random recombination between human MDR1 and mouse mdr1a cDNA in a pHaMDR-dihydrofolate reductase bicistronic expression system. 976 4
Human
P-glycoprotein
(
P-gp
) is a cell surface drug efflux pump that contains two nucleotide binding domains (NBDs). Mutations were made in each of the Walker B consensus motifs of the NBDs at positions D555N and D1200N, thought to be involved in Mg(2+) binding. Although the mutant and wild-type P-gps were expressed equivalently at the cell surface and bound the drug analogue [(125)I]iodoarylazidoprazosin ([(125)I]IAAP) comparably, neither of the mutant proteins was able to transport fluorescent substrates nor had detectable basal nor drug-stimulated ATPase activities. The wild-type and D1200N P-gps were labeled comparably with [alpha-(32)P]-8-azido-ATP at a subsaturating concentration of 2.5 microM, whereas labeling of the D555N mutant was severely impaired. Mild trypsin digestion, to cleave the protein into two halves, demonstrated that the N-half of the wild-type and D1200N proteins was labeled preferentially with [alpha-(32)P]-8-azido-ATP. [alpha-(32)P]-8-Azido-ATP labeling at 4 degrees C was inhibited in a concentration-dependent manner by ATP with half-maximal inhibition at approximately 10-20 microM for the
P-gp
-D1200N mutant and wild-type
P-gp
. A
chimeric protein
containing two N-half NBDs was found to be functional for transport and was also asymmetric with respect to [alpha-(32)P]-8-azido-ATP labeling, suggesting that the context of the ATP site rather than its exact sequence is an important determinant for ATP binding. By use of [alpha-(32)P]-8-azido-ATP and vanadate trapping, it was determined that the C-half of wild-type
P-gp
was labeled preferentially under hydrolysis conditions; however, the N-half was still capable of being labeled with [alpha-(32)P]-8-azido-ATP. Neither mutant was labeled under vanadate trapping conditions, indicating loss of ATP hydrolysis activity in the mutants. In confirmation of the lack of ATP hydrolysis, no inhibition of [(125)I]IAAP labeling was observed in the mutants in the presence of vanadate. Taken together, these data suggest that the two NBDs are asymmetric and intimately linked and that a conformational change in the protein may occur upon ATP hydrolysis. Furthermore, these data are consistent with a model in which binding of ATP to one site affects ATP hydrolysis at the second site.
...
PMID:Both ATP sites of human P-glycoprotein are essential but not symmetric. 1052 34
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
The t(12;21)(p12;q22) chromosomal aberration, which is frequently observed in pediatric precursor B-cell acute lymphoblastic leukemia (ALL), generates the TEL/AML1 chimeric gene and protein. TEL/AML1-positive ALL has a favorable prognosis, and one possible reason is that this subtype of ALL rarely shows drug resistance. AML1/ETO, another AML1-containing
chimeric protein
, has been shown to transcriptionally repress the activity of the multidrug resistance-1 (MDR-1) gene promoter; thus, we examined whether TEL/AML1 also represses MDR-1 gene expression, possibly preventing the emergence of multidrug resistance. In this study, we show that the TEL/AML1 protein binds to the consensus AML1 binding site in the MDR-1 promoter and transcriptionally represses its activity. Following transient transfection of TEL/AML1 protein into Adriamycin-resistant K562/Adr cells, we also demonstrate that TEL/AML1 can down-regulate the expression of
P-glycoprotein
, a product of the MDR-1 gene, and restore the chemosensitivity to the cells. Furthermore, we report that MDR-1 mRNA levels in leukemic cells obtained from TEL/AML1-positive ALL patients are lower than those from TEL/AML1-negative ALL patients. Thus, TEL/AML1 protein acts as a transcriptional repressor of MDR-1 gene expression, and although TEL/AML1 has been implicated in leukemogenesis, its effects on the MDR-1 gene may contribute to the excellent prognosis of TEL/AML1-positive ALL with current therapy.
...
PMID:TEL/AML1 overcomes drug resistance through transcriptional repression of multidrug resistance-1 gene expression. 1523 9
In cancer and AIDS, overexpression of the MDR1 gene has important implications in the design of chemotherapy protocols because of the ability of its product, the ATP-dependent drug efflux pump
P-glycoprotein
(Pgp), to confer selective advantage to tumor and HIV-infected cells in the form of multidrug resistance. To study Pgp expression and physiology, we designed a translational fusion between the MDR1 and enhanced green fluorescent protein (EGFP) genes. The
chimeric protein
, Pgp-EGFP, was concentrated mainly in the plasma membrane and in the Golgi when expressed in drug-sensitive KB-3-1 cells. Doxorubicin, daunorubicin and rhodamine-123 efflux assays confirmed function of the chimeric pump. Also, at the single-cell level, an inverse relationship between Pgp-EGFP expression and nuclear doxorubicin accumulation was demonstrated. Polarized Pgp expression on the apical cell surface was confirmed by transfection of the MDR-EGFP fusion gene into MDCK cells. However, after colchicine selection, Pgp-EGFP was also detectable in the lateral domain of the transfected MDCK monolayers. These results indicate that drug selection affects not only expression, but cellular localization of Pgp. Furthermore, using a tet-based inducible expression system for Pgp-EGFP, we confirmed the stable nature of Pgp (t(1/2 total Pgp-EGFP) = 2.2 days), but revealed that surface-Pgp acquires extra stability as an active pump (t(1/2 surface Pgp-EGFP) = 3.7 days).
...
PMID:An MDR-EGFP gene fusion allows for direct cellular localization, function and stability assessment of P-glycoprotein. 1630 69
The effects of YB-1 gene on the expression level of
P-glycoprotein
and drug resistance of tumor cells were studied in cultured HCT116 colon cancer cells. Transitory transfection of chimeric YB-1/GFP gene rendered HCT116 cells a selective advantage in a medium with vinblastine, which caused translocation of the
chimeric protein
into cell nuclei. This was paralleled by an increase in the expression of
P-glycoprotein
(multiple drug resistance protein).
...
PMID:Development of drug resistance in the population of colon cancer cells under the effect of multifunctional protein YB-1. 1821 1
One of the main problems of conventional anticancer therapy is multidrug resistance (MDR), whereby cells acquire resistance to structurally and functionally unrelated drugs following chemotherapeutic treatment. One of the main causes of MDR is overexpression of the
P-glycoprotein
transporter. In addition to extruding the chemotherapeutic drugs, it also inhibits apoptosis through the inhibition of caspases. To overcome MDR, we constructed a novel
chimeric protein
, interleukin (IL)-2 granzyme A (IGA), using IL-2 as a targeting moiety and granzyme A as a killing moiety, fused at the cDNA level. IL-2 binds to the high-affinity IL-2 receptor that is expressed in an array of abnormal cells, including malignant cells. Granzyme A is known to cause caspase 3-independent cell death. We show here that the IGA
chimeric protein
enters the target sensitive and MDR cancer cells overexpressing IL-2 receptor and induces caspase 3-independent cell death. Specifically, after its entry, IGA causes a decrease in the mitochondrial potential, triggers translocation of nm23-H1, a granzyme A-dependent DNase, from the cytoplasm to the nucleus, where it causes single-strand DNA nicks, thus causing cell death. Moreover, IGA is able to overcome MDR and kill cells resistant to chemotherapeutic drugs. We believe that overcoming MDR with targeted molecules such as IGA
chimeric protein
that causes caspase-independent apoptotic cell death could be applied to many other resistant types of tumors using the appropriate targeting moiety. Thus, this novel class of targeted molecules could open up new vistas in the fight against human cancer.
...
PMID:IL-2-granzyme A chimeric protein overcomes multidrug resistance (MDR) through a caspase 3-independent apoptotic pathway. 2056 5
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