Structure and functional relationships in human pur H.

1. The human pur H (ATIC) gene encoding a bifunctional protein, hPurH, which carries the penultimate and final enzymatic activities of the purine nucleotide synthesis pathway, AICARFT & IMPCH, has been cloned and sequenced. The gene product, hPurH has been overexpressed in E. coli, purified to homogeneity and crystallized. 2. The human pur H gene lies on chromosome 2, between band q34 and q35. There is at least one intron of 278 bp near the 5' end. 3. Truncation mutant studies demonstrate two non-overlapping functional domains in the protein arranged as indicated in Figure 5. The existence of a linker or interaction region between the catalytic domains remains to be established. 4. Cleland-type kinetic inhibition experiments indicate that the AICARFT reaction is of the ordered, sequential type with the reduced folate cofactor binding first. 5. The reaction has a broad pH optimum in the alkaline range, with a maximum at about pH 8.2. 6. Preliminary transient phase kinetic studies show the presence of a "burst" indicating that a late step in the reaction sequence is rate limiting. 7. A PurH crystal structure is that of a dimer, with a putative single binding site for the reduced folate cofactor formed using elements from each of the monomer subunits. Probable binding sites for AICAR and FAICAR can be identified on each monomer. 8. Equilibrium sedimentation studies show hPurH apoprotein to be a monomer:dimer equilibrium mixture with a kD of 0.55 uM. 9. The crystal structure has permitted identification of a number of candidate amino acid residues likely to be involved in catalysis and/or substrate binding. Among these, we have thus far completed studies on two, Lysine 265 and Histidine 266. These appear to be critically involved in the AICARFT reaction, although whether their role(s) are in catalysis or binding remains to be determined.

LY231514, a pyrrolo[2,3-d]pyrimidine-based antifolate that inhibits multiple folate-requiring enzymes.

N-[4-[2-(2-amino-3,4-dihydro-4-oxo-7H-pyrrolo[2,3-d]pyrimidin-5-yl)ethyl ]-benzoyl]-L-glutamic acid (LY231514) is a novel pyrrolo[2,3-d]pyrimidine-based antifolate currently undergoing extensive Phase II clinical trials. Previous studies have established that LY231514 and its synthetic gamma-polyglutamates (glu3 and glu5) exert potent inhibition against thymidylate synthase (TS). We now report that LY231514 and its polyglutamates also markedly inhibit other key folate-requiring enzymes, including dihydrofolate reductase (DHFR) and glycinamide ribonucleotide formyltransferase (GARFT). For example, the Ki values of the pentaglutamate of LY231514 are 1.3, 7.2, and 65 nM for inhibition against TS, DHFR, and GARFT, respectively. In contrast, although a similar high level of inhibitory potency was observed for the parent monoglutamate against DHFR (7.0 nM), the inhibition constants (Ki) for the parent monoglutamate are significantly weaker for TS (109 nM) and GARFT (9,300 nM). The effects of LY231514 and its polyglutamates on aminoimidazole carboxamide ribonucleotide formyltransferase, 5,10-methylenetetrahydrofolate dehydrogenase, and 10-formyltetrahydrofolate synthetase were also evaluated. The end product reversal studies conducted in human cell lines further support the concept that multiple enzyme-inhibitory mechanisms are involved in cytotoxicity. The reversal pattern of LY231514 suggests that although TS may be a major site of action for LY231514 at concentrations near the IC50, higher concentrations can lead to inhibition of DHFR and/or other enzymes along the purine de novo pathway. Studies with mutant cell lines demonstrated that LY231514 requires polyglutamation and transport via the reduced folate carrier for cytotoxic potency. Therefore, our data suggest that LY231514 is a novel classical antifolate, the antitumor activity of which may result from simultaneous and multiple inhibition of several key folate-requiring enzymes via its polyglutamated metabolites.

The human purH gene product, 5-aminoimidazole-4-carboxamide ribonucleotide formyltransferase/IMP cyclohydrolase. Cloning, sequencing, expression, purification, kinetic analysis, and domain mapping.

We report here the cloning and sequencing of the cDNA, purification, steady state kinetic analysis, and truncation mapping studies of the human 5-aminoimidazole- 4-carboxamide ribonucleotide formyltransferase/IMP cyclohydrolase (AICARFT/IMPCHase). These steps of de novo purine biosynthesis, respectively. In all species of both prokaryotes and eukaryotes studied, these two activities are present on a single bifunctional polypeptide encoded on the purH gene. The human purH cDNA is 1776 base pairs in length encoding for a 591-amino acid polypeptic (Mr = 64,425). The human and avian purH cDNAs are 75 and 81% similar on the nucleotide and amino acid sequence level, respectively. The Km values for AICAR and (6R,6S)10-formyltetrahydrofolate are 16.8 microM +/- 1.5 and 60.2 microM +/- 5.0, respectively, for the cloned, purified human enzyme. A 10-amino acid sequence within the COOH-terminal portion of human AICARFT/IMPCHase has some degree of homology to a previously noted "folate binding site." Site directed mutagenesis studies indicate that this sequence plays no role in enzymatic activity. We have constructed truncation mutants which demonstrate that each of the two enzyme activities can be expressed independent of the other. IMPCHase and AICARFT activities are located within the NH2-terminal 223 and COOH-terminal 406 amino acids, respectively. The truncation mutant possessing AICARFT activity displays steady state kinetic parameters identical to those of the holoenzyme.

Multifactorial resistance to 5,10-dideazatetrahydrofolic acid in cell lines derived from human lymphoblastic leukemia CCRF-CEM.

5,10-dideaza-5,6,7,8-terrahydrofolic acid (DDATHF) is a potent antiproliferative agent in cell culture systems and in vivo in a number of murine and human xenograft tumors. In contrast to classical antifolates, which are dihydrofolate reductase inhibitors, DDATHF primarily inhibits GAR transformylase, the first folate-dependent enzyme along the pathway of de novo purine biosynthesis. The (6R) diastereomer of DDATHF (Lometrexol), currently undergoing clinical investigation, was used to develop CCRF-CEM human leukemia sublines resistant to increasing concentrations of the drug. Three cell lines were selected for ability to grow in medium containing 0.1 microM, 1.0 microM, and 10 microM of (6R)DDATHF, respectively. Impaired polyglutamylation was identified as a common mechanism of resistance in all three cell lines. A progressive decrease in the level of polyglutamylation was associated with diminished folylpolyglutamate synthetase activity and paralleled increasing levels of resistance to the drug. However, the expression of folylpolyglutamate synthetase RNA was not altered in the resistant cell lines compared to the parent cells. The most resistant cell subline also displayed an increased activity of gamma-glutamyl hydrolase. The sublines were scrutinized for other possible mechanisms of resistance. No alterations in drug transport or in purine economy were found. Modest increases were found in the activity of methylene tetrahydrofolate dehydrogenase but no alterations of other folate-dependent enzymes were observed. Increases in accumulation and conversion of folic acid to reduced forms, particularly 10-formyltetrahydrofolate, was also seen. The resistant cell lines were sensitive to dihydrofolate reductase inhibitors, methotrexate and trimetrexate, for a 72-h exposure period but showed cross-resistance to methotrexate for 4 and 24 h exposures. Cross-resistance was also shown toward other deazafolate analogues for both short- and long-term exposures.

5,10-Dideazatetrahydrofolic acid (DDATHF) transport in CCRF-CEM and MA104 cell lines.

5,10-Dideazatetrahydrolic acid (DDATHF) is representative of a new class of antifolates acting through inhibition of de novo purine synthesis. We report here the transport characteristics of the diastereomers of DDATHF, which differ in configuration at C6, and comparison studies with other folate and antifolate analogs. (6R)-DDATHF showed high affinity for the influx system of CCRF-CEM cells with a Km of 1.07 microM and an influx Vmax of 4.04 pmol/min/10(7) cells. Comparative studies with methotrexate yielded an influx Km of 4.98 microM and a Vmax of 6.64 pmol/min/10(7) cells, and with 5-formyltetrahydrofolate an influx Km of 2.18 microM and a Vmax of 6.84 pmol/min/10(7) cells. Uptake of (6R)-DDATHF was competitively inhibited by (6S)-DDATHF, methotrexate (MTX), and 5-formyltetrahydrofolate, all with Ki values similar to their influx Km. The (6S)-DDATHF diastereomer had an influx Km of 1.04 microM, similar to that of (6R)-DDATHF; however, the Vmax of 1.72 pmol/min/10(7) cells was 2.3-fold lower than for (6R)-DDATHF. The transport properties of DDATHF were also studied in a mutant cell line (CEM/MTX), resistant to MTX based on impaired drug transport. In this system (6R)-DDATHF showed an influx Km of 1.49 microM and a decreased influx Vmax of 0.60 pmol/min/10(7) cells. A similar effect was shown for MTX (Km of 7.48 microM, Vmax of 1.02 pmol/min/10(7) cells). The number of binding sites in CCRF-CEM cells was similar for (6R)-DDATHF, (6S)-DDATHF, and MTX, 0.74, 0.71, and 0.76 pmol/10(7) cells, respectively. These values were slightly higher in the CEM/MTX cell line (1.07 and 1.09 pmol/10(7) cells for (6R)-DDATHF and MTX, respectively). Treatment of CCRF-CEM cells with either the N-hydroxysuccinimide ester of MTX or the corresponding N-hydroxysuccinimide ester of (6R)-DDATHF caused substantial inhibition (> 90%) of the influx of (6R)-[3H]DDATHF and [3H]MTX, respectively. These results suggest strongly that DDATHF and MTX share a common influx mechanism through the reduced folate transport system. The internalization of DDATHF by monkey kidney epithelial MA104 cells, which express a high affinity folate receptor, was also studied. Competitive binding studies using purified folate receptor and radiolabeled 5-methyltetrahydrofolate showed that (6S)- and (6R)-DDATHF both had I50 values lower than 5-methyltetrahydrofolate (12 nM). Further studies indicate that both DDATHF isomers are actively intracellularly concentrated through this route and are also rapidly converted to high chain length polyglutamates. Transport via this system was inhibited in folate-depleted cells by 10 nM folic acid.(ABSTRACT TRUNCATED AT 400 WORDS)

Biochemical and biological studies on 2-desamino-2-methylaminopterin, an antifolate the polyglutamates of which are more potent than the monoglutamate against three key enzymes of folate metabolism.

Biochemical and biological studies have been carried out with 2-desamino-2-methylaminopterin (dmAMT), which inhibits tumor cell growth in culture but is only a weak inhibitor of dihydrofolate reductase (DHFR). Since it was possible that the species responsible for growth inhibition are polyglutamylated metabolites, the di-, tri-, and tetraglutamates of dmAMT were synthesized and tested as inhibitors of purified recombinant human DHFR, murine L1210 leukemia thymidylate synthase (TS), chicken liver glycinamide ribonucleotide formyltransferase (GARFT), and murine L1210 leukemia aminoimidazolecarboxamide ribonucleotide formyltransferase (AICARFT). The compounds with three and four gamma-glutamyl residues were found to bind two orders of magnitude better than dmAMT itself to DHFR, TS, and AICARFT, with 50% inhibitory concentration values in the 200 to 300 nM range against all three enzymes. In contrast, at a concentration of 10 microM, dmAMT polyglutamates had no appreciable effect on GARFT activity. These findings support the hypothesis that dmAMT requires intracellular polyglutamylation for activity and indicate that replacement of the 2-amino group by 2-methyl is as acceptable a structural modification in antifolates targeted against DHFR as it is in antifolates targeted against TS. In growth assays against methotrexate (MTX)-sensitive H35 rat hepatoma cells and MTX-resistant H35 sublines with a transport defect, dmAMT was highly cross-resistant with MTX, but not with the TS inhibitors N10-propargyl-5,8-dideazafolic acid and N-(5-[N-(3,4-dihydro-2-methyl-4-ox-oquinazolin-6-yl)-N- methylamino]thenoyl)-L-glutamic acid, implicating DHFR rather than TS as the principal target for dmAMT polyglutamates in intact cells. On the other hand, an H35 subline resistant to 2'-deoxy-5-fluorouridine by virtue of increased TS activity was highly cross-resistant to N10-propargyl-5,8-dideazafolic acid and not cross-resistant to MTX, but showed partial cross-resistance to dmAMT. Both thymidine and hypoxanthine were required to protect H35 cells treated with concentrations of dmAMT and MTX that inhibited growth by greater than 90% relative to unprotected controls. In contrast, N10-propargyl-5,8-dideazafolic acid and N-(5-[N-(3,4-dihydro-2-methyl-4-oxoquinazolin-6-yl)-N-methylamino] thenoyl)- L-glutamic acid required only thymidine for protection. Like MTX, therefore, dmAMT appears to inhibit purine as well as pyrimidine de novo synthesis, and its effect on cell growth probably reflects the ability of dmAMT polyglutamates to not only block dihydrofolate reduction but also interfere with other steps of folate metabolism, either directly or indirectly via alteration of reduced folate pools.(ABSTRACT TRUNCATED AT 400 WORDS)

(6R)-5,10-Dideaza-5,6,7,8-tetrahydrofolic acid effects on nucleotide metabolism in CCRF-CEM human T-lymphoblast leukemia cells.

(6R)-5,10-Dideaza-5,6,7,8-tetrahydrofolic acid [(6R)DDATHF] is a folate antimetabolite with activity specifically directed against de novo purine synthesis, primarily through inhibition of glycinamide ribonucleotide transformylase. This inhibition resulted in major changes in the size of the nucleotide pools in CCRF-CEM cells. After a 4-h incubation with 1 microM (6R)DDATHF, dramatic reductions in the ATP and GTP pools were observed, with almost no effect on CTP, UTP, and deoxyribonucleotide pools. When the incubation was continued in drug-free medium, recovery of ATP and GTP pools was protracted. ATP did not return to normal until 24-36 h, and GTP pools were only partially repleted by 48 h. The ATP and GTP pools were not affected when the initial 4-h incubation with (6R)DDATHF was conducted in the presence of 100 microM hypoxanthine. Addition of hypoxanthine to the medium after a 4-h incubation with (6R)DDATHF caused rapid recovery of the ATP and GTP pools. Similar effects were seen when the purine precursor aminoimidazole carboxamide was used in place of hypoxanthine. The effect of (6R)DDATHF on nucleotide pools and the capability of hypoxanthine or aminoimidazole carboxamide to prevent or reverse this phenomenon correlated directly with the inhibition of cell growth. Presumably as a consequence of the decrease in purine nucleotide triphosphate levels, the conversion of exogenously added uridine, thymidine, and deoxyuridine to nucleotides was markedly decreased. These effects were protracted for almost 48 h and were also reversed by hypoxanthine. Differential repletion of ATP and GTP pools after (6R)DDATHF pre-treatment demonstrated that diminished precursor phosphorylation is primarily a consequence of GTP rather than ATP starvation.

Intracellular metabolism of 5,10-dideazatetrahydrofolic acid in human leukemia cell lines.

5,10-Dideazatetrahydrofolic acid (DDATHF) is a new potent antitumor agent that specifically inhibits purine biosynthesis, primarily through inhibition of glycinamide ribonucleotide transformylase, the first of the tetrahydrofolate-requiring enzymes in the de novo synthesis pathway. DDATHF has been shown to be an excellent substrate for mouse liver folylpolyglutamate synthetase in vitro, suggesting that intracellular conversion to polyglutamates could play an important role in the action of this antifolate. In this report, metabolic studies of the 6R-diastereomer of DDATHF in the cultured human leukemia cell lines CCRF-CEM and HL-60 are presented. At both 1 and 10 microM (6R)-DDATHF was rapidly converted to polyglutamates in both cell lines. DDATHF(Glu)5 and DDATHF(Glu)6 were the main intracellular metabolites. After incubation in drug-free medium, (6R)-DDATHF polyglutamates were better retained intracellularly with increasing glutamate chain length. (6R)-DDATHF showed reduced cytotoxicity toward a folylpolyglutamate synthetase-deficient cell line, CCRF-CEM30/6 related to a dramatically diminished accumulation of polyglutamates. The activity of (6R)-DDATHF in CCRF-CEM30/6 cells was decreased after both short and prolonged exposures. These results suggest that polyglutamylation of (6R)-DDATHF not only represents a mechanism for trapping the drug inside the cells but also produces a more potent inhibitor of the target enzyme.

Biochemical modulation of fluoropyrimidines by antifolates and folates in an in vitro model of human leukemia.

Although 5-fluorouracil (FUra) is one of the most effective cytotoxic agents in the treatment of various solid tumors (carcinomas of the gastro-intestinal tract, breast, head and neck), remissions occur in only 20 to 30% of cases and usually are of short duration. Recently, preclinical studies have shown that the antitumor activity of FUra can be potentiated by modulating the metabolism of this drug by using other substances, in particular antifolates of folates. Pretreatment with antifolates may, by blocking de novo purine biosynthesis and consequently increasing phosphoribosyl pyrophosphate (PRPP) pools, enhance the conversion of FUra to active fluoronucleotide pools via orotate phosphoribosyltransferase. Methotrexate (MTX) pretreatment may also enhance binding of the fluoropyrimidine inhibitor, 5-fluodeoxyuridylate (FdUMP), to the target enzyme, thymidylate synthase (TS), indirectly by increasing dihydrofolate polyglutamates or directly, as MTX polyglutamates, by enhancing the formation of ternary complexes with FdUMP and TS. Exogenous folates, in particular 5-formyltetrahydrofolate (folinate, leucovorin, LV), can, by raising the intracellular levels of 5, 10-methylenetetrahydrofolate, lead to increased formation and stabilization of the ternary complex formed by TS, the folate coenzyme, and FdUMP. In vitro studies have also shown potentiation of FUra cytotoxicity by antifolates and folates against human lymphoblastic leukemia cell lines. Thus, while FUra may have little or no single agent activity in leukemias and lymphomas, it may be converted to an active drug in these neoplasms by appropriate modulation. Clinical studies of sequential MTX-FUra or combined LV-FUra based upon experimental tumor results reviewed herein, are warranted.

Amplification of a polymorphic dihydrofolate reductase gene expressing an enzyme with decreased binding to methotrexate in a human colon carcinoma cell line, HCT-8R4, resistant to this drug.

A methotrexate (MTX)-resistant human colon carcinoma cell line was obtained by growing HCT-8 cells in stepwise increasing concentrations of the drug. The resistant subline (HCT-8R4) was able to grow in the presence of 1 x 10(-4) M MTX and was found to have a 25-fold increase in the level of the target enzyme dihydrofolate reductase (DHFR), with a corresponding increase in DHFR gene copies as well as DHFR transcripts. Southern blot analysis of DNA from HCT-8R4 cells revealed the amplification of an altered gene. The amplified DHFR gene lacks an EcoRI restriction enzyme site in the coding region, normally present in other human cell lines. Sequence analysis of cDNA synthesized from transcripts in the MTX-resistant cell line revealed a base transition T----C at nucleotide position 91 resulting in a substitution of serine for phenylalanine. The dissociation constant for MTX binding to the HCT-8R4 enzyme was 1.25 nM, an 8-fold increase from the Kd 150 pM of purified wild type human DHFR. This decrease in binding of MTX to the HCT-8R4 DHFR is consistent with the predicted involvement of phenylalanine in the DHFR active site in hydrophobic interactions with MTX. This mutation plus the 25-fold increase in DHFR activity explains the high level of resistance of this subline to MTX.

A new folate antimetabolite, 5,10-dideaza-5,6,7,8-tetrahydrofolate is a potent inhibitor of de novo purine synthesis.

5,10-Dideazatetrahydrofolate (DDATHF) is a new antimetabolite designed as an inhibitor of folate metabolism at sites other than dihydrofolate reductase. DDATHF was found to inhibit the growth of L1210 and CCRF-CEM cells in culture at concentrations in the range of 10-30 nM. The inhibitory effect of DDATHF on the growth of L1210 and CCRF-CEM cells was reversed by either hypoxanthine or aminoimidazole carboxamide. Growth inhibition by DDATHF was prevented by addition of both thymidine and hypoxanthine, but not by thymidine alone. 5-Formyltetrahydrofolate reversed the effects of DDATHF in a dose-dependent manner. DDATHF had no appreciable inhibitory activity against either dihydrofolate reductase or thymidylate synthase in vitro, but was found to be an excellent substrate for folylpolyglutamate synthetase. DDATHF had little or no effect on incorporation of either deoxyuridine or thymidine into DNA, in distinct contrast to the effects of the classical dihydrofolate reductase inhibitor, methotrexate. DDATHF was found to deplete cellular ATP and GTP over the same concentrations as those inhibitory to leukemic cell growth, suggesting that the locus of DDATHF action was in the de novo purine biosynthesis pathway. The synthesis of formylglycinamide ribonucleotide in intact L1210 cells was inhibited by DDATHF with the same concentration dependence as inhibition of growth. This suggested that DDATHF inhibited glycinamide ribonucleotide transformylase, the first folate-dependent enzyme of de novo purine synthesis. DDATHF is a potent folate analog which suppresses purine synthesis through direct or indirect inhibition of glycinamide ribonucleotide transformylase.

Impaired polyglutamylation of methotrexate as a cause of resistance in CCRF-CEM cells after short-term, high-dose treatment with this drug.

Two methotrexate-resistant sublines, CCRF-CEM R3/7 and CCRF-CEM R30/6, were selected from the human leukemia T-lymphoblast cell line, CCRF-CEM, after repeated exposures (7 and 6 times, respectively) for 24 h to constant concentrations (3 and 30 microM) of the drug. Analysis of the mechanism of resistance revealed no differences in levels of dihydrofolate reductase activity, its binding affinity for methotrexate, or in methotrexate transport between the CCRF-CEM parent and methotrexate-resistant cell lines. The development of resistance to methotrexate was associated with a marked decrease in the intracellular level of methotrexate polyglutamates. Although the resistant sublines were able to form substantial amounts of folate polyglutamates when measured with [3H]folic acid, the level of polyglutamates formed was decreased to about 50% of that formed by the parent cell line. No qualitative differences in folate polyglutamates formed were noted between the parental and resistant sublines. This is the first example of a cell line which displays resistance which is solely attributable to defective methotrexate polyglutamate synthesis.

Cytotoxicity of floxuridine and 5-fluorouracil in human T-lymphoblast leukemia cells: enhancement by leucovorin.

The inhibitory effects of leucovorin (LV) combined with 5-fluorouracil (FUra) or floxuridine (FdUrd) on growth of human T-lymphoblast leukemia cells (CCRF-CEM) were determined as a function of time, dose, and sequence of exposure. Exposure of CCRF-CEM cells in exponential growth to LV (1-100 microM) for 4 hours and to FUra (100 microM) or FdUrd (0.5 microM) during the last 2 hours resulted in synergistic inhibitory effects on cell growth. Synergism was dependent on LV dose (100 greater than 10 greater than 1 microM) and did not occur at 0.1 microM. No clear dependence of synergy on sequence was observed with FUra and LV combinations. With LV and FdUrd combinations, synergism was dependent on sequence of exposure (LV + FdUrd and LV----FdUrd were synergistic, but FdUrd----LV was not). Thymidine (0.1 microM), added after drug treatment, substantially rescued CCRF-CEM cells from LV----FUra cytotoxicity. Concomitant hypoxanthine (100 microM) only partially protected CCRF-CEM cells from the toxicity of this combination. These results are consistent with the hypothesis that the mechanism by which LV potentiates fluoropyrimidine cytotoxicity is the enhancement of complex formation between thymidylate synthase and 5-fluorodeoxyuridylate, presumably as a consequence of an increase of intracellular levels of 5,10-methylenetetrahydrofolate generated from LV. Also, enhanced stability of this complex in the presence of high levels of the folate coenzyme may contribute to the synergy observed. These data also provide a rationale for use of FUra and especially FdUrd and LV in the treatment of lymphoid malignancies in man.

Design and rationale for novel antifolates.

The goals of new antifolate development are: 1) improved selectivity, 2) improved penetration into pharmacologic sanctuaries, and 3) effectiveness vs. tumors either with intrinsic or acquired resistance to methotrexate (MTX). The major target for antifolate development has been dihydrofolate reductase (DHFR), but other critical folate-dependent enzymes, i.e., thymidylate synthase, methionine synthetase, and folylpolyglutamate synthetase are also important targets for new antifolate development. The possibility that DHFR from tumor tissue differs significantly from normal tissue DHFR now seems improbable, and the ideas of the late Bill Baker to design specific inhibitors of the tumor enzyme vs. the normal tissue DHFR are unlikely to succeed. However, the experience with triazinate (Baker's antifol; TZT) indicates that transport of antifols could be exploited to provide selective toxicity, as well as to provide agents effective vs. MTX-resistant cells. This work led to a second generation of "nonclassical" folate antagonists, of which trimetrexate (JB-11; TMQ) is now in clinical trial. Uptake of TMQ is via an MTX-independent membrane system, and extremely high intracellular levels of this drug are achieved in human leukemia cells.

Inhibition of methionine uptake by methotrexate in mouse leukemia L1210 cells.

Methionine-auxotrophic L1210 cells were used to study the effect of methotrexate (MTX) on methionine uptake and metabolism. MTX was shown to inhibit amino acid transport systems and cause a decrease of methionine uptake into L1210 cells. Conversely, a nonmetabolizable amino acid analogue reduced MTX uptake into L1210 cells. MTX also blocked the transfer of the beta carbon from serine into methionine. Therefore, methionine deprivation may be an additional mechanism of action for MTX in methionine-auxotrophic tumor cells.

The role of methionine in methotrexate-sensitive and methotrexate-resistant mouse leukemia L1210 cells.

A mouse L1210 leukemia cell line was made 25-fold resistant to methotrexate (MTX) and had altered methionine transport and metabolism. L1210 cells resistant to methotrexate also had a 50-fold decrease in the exogenous methionine requirement for optimal cell growth compared to the parent cells. This change in methionine requirement was associated with differences in methionine metabolism between MTX-sensitive and MTX-resistant cell lines. Analysis of amino acid transport systems revealed different Kt and Vmax properties of methionine and nonmetbolizable amino acid analogues. There was a greater than twofold decrease in the initial sodium-dependent uptake of methionine in the resistant cells. Amino acid competition experiments revealed altered substrate specificities in the resistant cells. The cellular alterations occurring upon resistance may result from methotrexate-membrane interactions, and have been previously observed in cisplatinum-resistant cells. Thus modulation of methionine metabolism may provide the biochemical basis for MTX and cisplatinum collateral resistance.

Cytotoxic effects of hyperthermia, 5-fluorouracil and their combination on a human leukemia T-lymphoblast cell line, CCRF-CEM.

The cytotoxic effects of 5-fluorouracil (FUra), hyperthermia, and the combination of these treatments were examined in a human T-lymphoblast cell line, CCRF-CEM. Simultaneous exposure of exponentially growing CCRF-CEM cells to hyperthermia (39 and 42 degrees C) and FUra (10, 50, and 100 microM) for 1 or 2 hr resulted in subadditive or additive cell kill. When CCRF-CEM cells were exposed to these agents in sequence (hyperthermia----FUra and FUra----hyperthermia) for 1 and 2 hr duration additive cell kill was also observed. Enhanced cytotoxic effects were observed when a longer exposure (4 and 8 hr) to FUra (100 microM) followed heat (42 degrees C for 1 and 2 hr). Heat exposure (42 degrees C, 1 and 2 hr) induced a rapid decrease in the synthesis of DNA of CCRF-CEM cells, followed by a rebound increase at 12 hr and a new decrease at 24 hr. Flow cytometry demonstrated an accumulation of cells in the S phase at 12 hr after heat exposure, followed by a marked increase of the G + M population (maximum at 24 hr). The exposure time, and the sequence of administration of hyperthermia and FUra were critical determinants of cytotoxicity in this in vitro system and might constitute important variables of treatment when these two agents are used clinically.

Molecular and karyological analysis of methotrexate-resistant and -sensitive human leukemic CCRF-CEM cells.

A methotrexate-resistant subline, CCRF-CEM/R1, was selected stepwise from the human leukemic lymphoblast T-cell line, CCRF-CEM, and maintained in 0.2 microM methotrexate. The development of resistance to methotrexate (75-fold) was associated with a 20-fold increase of dihydrofolate reductase activity. The affinity of dihydrofolate reductase from the resistant cells for methotrexate did not vary significantly as compared to the enzyme from the parent cells. Southern blot analysis of DNA from parent and CCRF-CEM/R1 cells demonstrated amplification of the dihydrofolate reductase gene in the resistant line. Quantitative dot-blot DNA hybridization demonstrated the presence of about 18 reductase gene copies in the R1 cells. The human dihydrofolate reductase gene contained at least 4 intervening sequences and was about 30 kilobases in size. Northern blot analysis demonstrated an increase in dihydrofolate reductase messenger RNA species, the predominant message was 3.8 kilobases. Cytogenetic analysis of CCRF-CEM/R1 cells revealed an elongated marker chromosome containing a homogeneous staining region not present in the parent line. This chromosome appeared to be derived from chromosome 21.

Cytotoxic effects of folate antagonists against methotrexate-resistant human leukemic lymphoblast CCRF-CEM cell lines.

A human T-lymphoblast cell line, CCRF-CEM/R1, resistant to methotrexate by virtue of increased dihydrofolate reductase activity, was grown in stepwise increasing concentrations of methotrexate. This additional selection pressure resulted in a cell line, CCRF-CEM/R2, resistant to methotrexate by virtue of both an elevation of dihydrofolate reductase activity and a marked decrease in methotrexate transport. The R1 and R2 cells were approximately 70- and 350-fold more resistant to methotrexate than were the parent cells. The effects of three folate antagonists were studied on these cell lines and also on CCRF-CEM/R3 cells, characterized by impaired methotrexate transport but normal levels of dihydrofolate reductase. The elevated reductase subline CCRF-CEM/R1 was cross-resistant to triazinate [Baker's antifol, NSC 139105; ethanesulfonic acid compounded with alpha-(2-chloro-4-[4,6-diamino-2,2-dimethyl-S-triazine-1-(2H)-yl] phenoxyl)-N,N-dimethyl-m-toluamide (1:1)] and trimetrexate (NSC 249008, JB-11, TMQ; 2,4-diamino-6-[(3,4,5-trimethoxyanilino)methyl]quinazoline), two nonclassical folate antagonists. In contrast, the transport defective subline, CCRF-CEM/R3 was not cross-resistant to these two compounds. In cells resistant to MTX by virtue of both mechanisms, CCRF-CEM/R2, triazinate, and trimetrexate were partially cross-resistant. All three methotrexate-resistant sublines showed minor cross-resistance to isoaminohydroxyquinazoline (IAHQ, NSC 289517; 5,8-dideazaisopteroylglutamate), a folate antagonist inhibitor of thymidylate synthase. These data demonstrate that methotrexate-resistant tumor cells may be effectively inhibited by antifolates with different route of entry into cells or with different enzyme targets.

Methotrexate resistant cells as targets for selective chemotherapy.

Strategies that are selective for eradicating methotrexate resistant cells are described. These strategies have been developed based on knowledge of the mechanism of drug resistance encountered in experimental systems and in the clinic. Drug resistance to methotrexate in experimental tumors is commonly due to either gene amplification (dihydrofolate reductase) or to impaired transport of methotrexate. While no effective drugs or methods to prevent gene amplification have been described, the concept of developing "pro drugs", i.e. a drug that is selectively reduced by dihydrofolate reductase to an inhibitor of another critical folate enzyme (thymidylate synthase, methionine synthetase, folylpolyglutamate synthetase) remains worthwhile. Second generation antifolates such as trimetrexate which are effective vs methotrexate transport resistant cells have already been developed and are in clinical trial.