Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0023418 (leukemia)
93,477 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Transport of reduced folates in murine leukemia cells is mediated by the bidirectional reduced folate carrier (RFC1) and independent unidirectional exit pumps. RFC1 has been proposed to be intrinsically equilibrating, generating transmembrane gradients by exchange with inorganic and organic anions. This paper defines the role of high level carrier expression, through transfection with RFC1 cDNA, on concentrative transport of the folate analog, methotrexate (MTX) in murine L1210 leukemia cells. RFC1 was expressed in the MTXrA line, which lacks a functional endogenous carrier to obtain the MTXrA-R16 clonal derivative. Influx was increased approximately 9-fold in MTXrA-R16 cells without a change in Km. The efflux rate constant was increased by a factor of 5.1 relative to L1210 cells, and this resulted in only a 2.1-fold increase in the steady-state level of free intracellular MTX, [MTX]i, when [MTX]e was 1 microM. The concentrative advantage for RFC1 (the ratio of [MTX]i in MTXrA-R16 to L1210 cells) increased from 1.8 at 0.1 microM MTX to 3.8 at an [MTX]e level of 30 microM. Augmented transport in MTXrA-R16 cells was accompanied by a 2-fold increase in accumulation of MTX polyglutamate derivatives and a approximately 50% decrease in the EC50 for 5-formyltetrahydrofolate and folic acid and the MTX IC50 relative to L1210 cells. These alterations paralleled changes in [MTX]i and not the much larger change in influx at low [MTX]e levels, consistent with the critical role that free intracellular folates and drug play in meeting cellular needs for folates and as a determinant of antifolate activity, respectively. The data indicate that RFC1 produces a large and near symmetrical increase in the bidirectional fluxes of MTX resulting in only a small increase in the transmembrane chemical gradient at low extracellular folate levels. Hence, increased expression of RFC1, alone, may not be an efficient adaptive response to folate deprivation, and other factors may come into play to account for the marked increases in concentrative folate transport which occur when cells are subjected to low folate-selective pressure.
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PMID:Impact of overexpression of the reduced folate carrier (RFC1), an anion exchanger, on concentrative transport in murine L1210 leukemia cells. 926 Nov 28

Prolonged cell culture of human leukemia cells at folate concentrations in the (sub)physiological range (1-5 nM) rather than at 'standard' supraphysiological concentrations of 2-10 microM folic acid elicited a number of regulatory aspects of the reduced folate carrier (RFC), the membrane transport protein for natural reduced folate cofactors and folate-based chemotherapeutic drugs such as methotrexate (MTX). One subline of human CCRF-CEM leukemia cells grown under folate-restricted conditions (CEM-7A) exhibited a 95-fold increased Vmax for uptake of [3H]-MTX. The increased uptake of MTX in CEM-7A cells is based on at least two factors: (a) a constitutive 10-fold overexpression of the RFC1 gene and RFC1 message; and (b) a 7-9-fold up-regulation of RFC transport activity under low intracellular reduced folate concentrations. This second component appeared to be regulatable by changes in the cellular folate, purine and methylation status as judged from a 7-9 fold down-regulation of RFC transport activity after short term (1-2 hr) incubation of CEM-7A cells with reduced folate cofactors (25 nM LV), purines (100 microM adenosine) or S-adenosylmethionine (100 microM), respectively. Gradual folate restriction in the cell culture medium of CEM/MTX cells, a subline of CCRF-CEM resistant to MTX due to defective transport via the RFC, revealed the up-regulated expression of an altered RFC protein that is characterized by a 35-fold decreased Km for folic acid and a 10-fold decreased Km for the reduced folate cofactor LV compared to the RFC expressed in CCRF-CEM and CEM-7A cells. As a result of the markedly increased efficiency of folic acid uptake in CEM/MTX cells, intracellular folate pools were 7-fold higher than in CCRF-CEM cells when both cell lines were incubated in the presence of 2 microM folic acid. The high intracellular folate pools in CEM/MTX cells appeared to impair the polyglutamylation of antifolates and confer resistance to ZD1694, an antifolate drug that depends on polyglutamylation for its biological activity. Collectively, these studies provide a better insight into the basic regulation of RFC-mediated membrane transport of clinically active antifolates. In addition, these studies may also provide an opportunity to exploit the transport system as a target for biochemical modulation by which it may contribute to an improved efficacy of folate-based chemotherapy in a clinical setting.
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PMID:Regulation of carrier-mediated transport of folates and antifolates in methotrexate-sensitive and-resistant leukemia cells. 938 86

The resistance to folate-based antifolates is associated with impaired function of the reduced folate carrier (RFC), one of the major routes of folate transport into cancer cells. To clarify the importance of RFC functions in the antifolate resistance, we have examined the expression of RFC1 and its phenotype as a folate transporter in human leukemia cell lines resistant to various antifolates. MOLT-3 cells resistant to ZD9331 (a thymidylate synthase (TS) inhibitor that utilizes the RFC for cell entry) (MOLT-3/ZD9331) showed decreased expression of RFC1 concomitant with diminished cellular uptake of [3H]methotrexate (MTX). K562 cells resistant to raltitrexed (ZD1694, another TS inhibitor that utilizes the RFC for cell entry) (K562/ ZD1694 x C) scarcely expressed RFC1, which is in accordance with the impaired uptake of folate analogs and the high degree of resistance to ZD1694 and MTX. On the other hand, no apparent decrease of RFCI1 expression was found in transport-deficient MTX-resistant MOLT-3 cells (MOLT-3/MTX10000) though its phenotype showed defective transport of MTX or ZD1694. In these cell lines with impaired RFC function, [3H]leucovorin (LV) uptake was only moderately decreased as compared to [3H]MTX or [3H]ZD1694 uptake. These cells grew with a minimal retardation in folate-free medium supplemented with 10 nM LV, suggesting that these cell lines with impaired RFC function had enough folate transporters to transport LV. In contrast to downregulation of RFC, the much greater uptake of [3H]MTX was observed in the MOLT-3/trimetrexate (TMQ)800-MTX10000 in parallel with increased RFC1 expression. These cell lines with the altered expression of RFC1 may serve as models useful for investigating the regulation of RFC1 expression and for understanding the molecular mechanism(s) behind the transport-mediated antifolate resistance.
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PMID:Variable expression of RFC1 in human leukemia cell lines resistant to antifolates. 950 Feb 2

With 5-formyltetrahydrofolate (5-CHO-THF) as the folate source a methotrexate (MTX) transport-deficient murine leukemia cell line, L1210-G1a, was isolated after chemical mutagenesis and MTX selection. This cell line was 10-fold resistant to MTX in comparison to parental L1210 cells, yet the EC50 for 5-CHO-THF was increased by a factor of only 2. The initial uptake of MTX, at a concentration of 1 microM, was decreased by a factor of 40, whereas influx of 5-CHO-THF dropped by a factor of only 8. This difference in initial uptake rates was attributed solely to changes in influx Vmax without a significant change in Km. Whereas the RFC1 mRNA level in L1210-G1a cells was indistinguishable from that of parental L1210 cells, a serine to asparagine substitution was identified at amino acid 46 within the first predicted transmembrane domain. This was a result of a homozygous mutation of G-->A in the genome. Transfection of the mutated RFC1 cDNA into MTXrA cells, which lack functional endogenous carrier, resulted in a clonal derivative MTXrA-S46N. The increase in influx of 5-CHO-THF and 5-CH3THF was 5 and 13 times greater than that for MTX in the transfectant, consistent with the influx ratio in the L1210-G1a line. The functional expression of the mutated RFC1 reduced the growth requirement for 5-CHO-THF by a factor of 30, compared with only a 3-fold decrease in the MTX IC50. This represents the first reported RFC1 mutation that confers resistance to MTX due to a markedly impaired influx with relative conservation of reduced folate transport. The kinetic changes are consistent with a substrate-dependent alteration in carrier mobility that favors reduced folates over MTX. These changes may account for the development of MTX resistance due to impaired drug transport in vivo, allowing tumor cells to meet their folate requirement with 5-CH3THF, the predominant blood folate.
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PMID:A reduced folate carrier mutation produces substrate-dependent alterations in carrier mobility in murine leukemia cells and methotrexate resistance with conservation of growth in 5-formyltetrahydrofolate. 952 81

Human RFC1 (hRFC1) transfected in transport-deficient methotrexate MTXR(R)ZR-75-1 human breast carcinoma cells (MTX(R)ZR-75/RFC) were used to investigate the impact of hRFC1 overexpression on influx and concentrative transport of methotrexate (MTX). Eight-fold overexpression of hRFC1, as determined by northern analysis, resulted in a 4-fold increase in MTX influx accompanied by a 2.4-fold increase in the steady-state level of free drug as compared with wild-type ZR-75-1 cells when the extracellular MTX level was 0.5 microM. When extracellular MTX was increased to 10 microM, the increase in influx equaled the increase in the transmembrane chemical gradient for MTX in the transfectant relative to wild-type cells. By 50 min, approximately 16-20 and 25% of the intracellular 3H represented MTX polyglutamates by HPLC analysis at [MTX]e = 0.5 and 10 microM in wild-type and transfected cells, respectively. Overexpression of hRFC1 enhanced sensitivity to MTX in MTX(R)ZR-75-1 cells by more than 250-fold. The data indicate that overexpression of hRFC1 in human cells results in comparable increases in influx and transmembrane gradients. This is different from what was reported when mouse RFC1 was transfected into murine leukemia cells, resulting in large, more symmetrical increases in the MTX bidirectional transport kinetics with a much smaller change in steady-state levels. The changes in the human cells transfected with hRFC1 however, were similar to what has been observed by other investigators when RFC1 expression is increased by low folate selective pressure.
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PMID:Concentrating capacity of the human reduced folate carrier (hRFC1) in human ZR-75 breast cancer cell lines. 963 5

CEM/MTX is a subline of human CCRF-CEM leukemia cells which displays >200-fold resistance to methotrexate (MTX) due to defective transport via the reduced folate carrier (RFC). CEM/MTX-low folate (LF) cells, derived by a gradual deprivation of folic acid from 2.3 microM to 2 nM (LF) in the cell culture medium of CEM/MTX cells, resulted in a >20-fold overexpression of a structurally altered RFC featuring; 1) a wild type Km value for MTX transport but a 31-fold and 9-fold lower Km values for folic acid and leucovorin, respectively, relative to wild type RFC; 2) a 10-fold RFC1 gene amplification along with a >20-fold increased expression of the main 3.1-kilobase RFC1 mRNA; 3) a marked stimulation of MTX transport by anions (i.e. chloride); and 4) a G --> A mutation at nucleotide 227 of the RFC cDNA in both CEM/MTX-LF and CEM/MTX, resulting in a lysine for glutamate substitution at amino acid residue 45 predicted to reside within the first transmembrane domain of the human RFC. Upon transfer of CEM/MTX-LF cells to folate-replete medium (2.3 microM folic acid), the more efficient folic acid uptake in CEM/MTX-LF cells resulted in a 7- and 24-fold elevated total folate pool compared with CEM and CEM/MTX cells, respectively (500 versus 69 and 21 pmol/mg of protein, respectively). This markedly elevated intracellular folate pool conferred a novel mechanism of resistance to polyglutamatable (e.g. ZD1694, DDATHF, and AG2034) and lipophilic antifolates (e.g. trimetrexate and pyrimethamine) by abolishing their polyglutamylation and circumventing target enzyme inhibition.
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PMID:A structurally altered human reduced folate carrier with increased folic acid transport mediates a novel mechanism of antifolate resistance. 980 75

Chemical mutagenesis with N-methyl-N-nitrosourea was employed to study the pattern of mutations in the reduced folate carrier (RFC1) that results in transport-related methotrexate resistance and to identify amino acid residues that are critical to carrier structure and/or function. Thirty-four methotrexate transport-defective L1210 leukemia cell lines were isolated with folic acid as the sole folate source under antifolate selective pressure. The RFC1 mRNA levels were comparable with, or not substantially decreased, in most of these cell lines relative to wild-type L1210 cells. The molecular basis for the transport defects was investigated by sequencing multiple RFC1 cDNA clones isolated from these mutants by reverse transcription-polymerase chain reaction, which encompassed the entire coding region. The mutations identified were further confirmed either by direct sequencing or, when applicable, by restriction analysis of total reverse transcription-polymerase chain reaction products. The majority of mutations (21) led to single amino acid substitutions that were in, or near, 9 of 12 predicted transmembrane domains, with the highest frequencies in the first, fifth, and eighth. There were no mutations in the sixth, ninth, and twelfth transmembrane domains. Glycine, serine, and arginine were the most frequently mutated residues. These data suggest that several transmembrane domains, rather than the amino- and carboxyl-termini, and the large intracellular loop between the sixth and seventh transmembrane domains play key roles as sites for RFC1 inactivation because of single point mutations. This panel of mutated cell lines offers an important resource for studies on RFC1 structure-function and for the evaluation of transport-related cross-resistance patterns with new-generation antifolate inhibitors of tetrahydrofolate cofactor-dependent enzymes.
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PMID:Pattern of mutations that results in loss of reduced folate carrier function under antifolate selective pressure augmented by chemical mutagenesis. 1038 85

The reduced folate carrier (RFC1) is a major transporter for both natural reduced folates and antifolate chemotherapeutics. Using polyclonal antibodies targeted to epitopes at the loop between the sixth and seventh predicted transmembrane domains or the distal C-terminus, we were able to demonstrate by Western blot analysis that the molecular size of RFC1 expressed in murine leukemia L1210 cells is 58 kDa as predicted by the open reading frame of its cDNA. 46- and 38-kDa proteins detected only in plasma membrane preparations were proteolytic degradation products that appeared during membrane preparation or treatment with the conventional SDS-PAGE loading buffer. These data resolve discrepancies reported previously for the molecular size of RFC1.
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PMID:The reduced folate carrier in L1210 murine leukemia cells is a 58-kDa protein. 1082 25

A murine leukemia cell line was identified that is highly resistant to methotrexate (MTX), due to impaired transport, but fully sensitive to 5,10-dideazatetrahydrofolate (DDATHF). A valine-to-methionine substitution at amino acid 104 in the reduced folate carrier (RFC1) explains this disparity in drug resistance. Transfection of the V104M cDNA into an RFC1-deficient cell line markedly increased DDATHF influx (32x) but only modestly increased influx of MTX and 5-formyltetrahydrofolate (4- and 6-fold, respectively). The growth inhibition or growth requirements for these folates fell by factors of 18, 2, and 4, respectively, in the transfectant. Preservation of DDATHF influx in cells with V104M RFC1 resulted in even greater preservation (60%) of the exchangeable drug level. Another major element in the preservation of DDATHF activity was the impact of the mutated carrier on cellular folate pools. For folic acid, folate pools were essentially unchanged but DDATHF polyglutamate levels decreased in lines that express the V104M carrier. However, with 5-formyltetrahydrofolate as the growth source, there was a marked decrease in folate pools in the lines carrying the mutated carrier, and DDATHF polyglutamate levels were unchanged. Hence, DDATHF activity was preserved in cells with V104M RFC1 due to (a) relative conservation of DDATHF transport, and (b) depletion of cellular THF cofactors with diminishing folate cofactor competition at folylpolyglutamate synthetase and possibly glycinamide ribonucleotide formyltransferase. Hence, resistance to one antifolate, in this case MTX, because of a loss of RFC1 transport activity need not exclude the subsequent utility of another antifolate that uses the same carrier.
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PMID:Sensitivity to 5,10-dideazatetrahydrofolate is fully conserved in a murine leukemia cell line highly resistant to methotrexate due to impaired transport mediated by the reduced folate carrier. 1095 17

The thiamin transporter encoded by SLC19A2 and the reduced folate carrier (RFC1) share 40% homology at the protein level, but the thiamin transporter does not mediate transport of folates. By using murine leukemia cell lines that express no, normal, or high levels of RFC1, we demonstrate that RFC1 does not mediate thiamin influx. However, high level RFC1 expression substantially reduced accumulation of the active thiamin coenzyme, thiamin pyrophosphate (TPP). This decreased level of TPP, synthesized intracellularly from imported thiamin, resulted from RFC1-mediated efflux of TPP. This conclusion was supported by the following observations. (i) Efflux of intracellular TPP was increased in cells with high expression of RFC1. (ii) Methotrexate inhibits TPP influx. (iii) TPP competitively inhibits methotrexate influx. (iv) Loading cells, which overexpress RFC1 to high levels of methotrexate to inhibit competitively RFC1-mediated TPP efflux, augment TPP accumulation. (v) There was an inverse correlation between thiamin accumulation and RFC1 activity in cells grown at a physiological concentration of thiamin. The modulation of thiamin accumulation by RFC1 in murine leukemia cells suggests that this carrier may play a role in thiamin homeostasis and could serve as a modifying factor in thiamin nutritional deficiency as well as when the high affinity thiamin transporter is mutated.
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PMID:Impact of the reduced folate carrier on the accumulation of active thiamin metabolites in murine leukemia cells. 1103 62


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