Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.5.1.3 (dihydrofolate reductase)
 5,819 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The role of the enzyme poly(adenosine diphosphate-ribose) polymerase (PADPRP) in DNA repair at the level of the gene was investigated with human HeLa cells in which PADPRP antisense transcripts are inducible with dexamethasone. After such induction, the cellular content of PADPRP is reduced by 90%. DNA damage and its repair was studied in the essential dihydrofolate reductase (DHFR) gene after exposure of the cells to either ultraviolet (UV) irradiation or the alkylating agent nitrogen mustard. The expression of the antisense construct had no effect on gene-specific repair of UV-induced pyrimidine dimers. In contrast, induced antisense cells were deficient in the gene-specific repair of nitrogen mustard-induced lesions. Dexamethasone itself did not inhibit gene-specific repair in control cells. Thus, PADPRP appears to participate in the gene-specific repair of alkylation damage, but not in the repair of UV-induced pyrimidine dimers. Clonal survival assays revealed that cells depleted of PADPRP showed an increased susceptibility to nitrogen mustard, supporting the notion that repair of essential genes is critical for cellular survival.
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PMID:Inhibition of gene-specific repair of alkylation damage in cells depleted of poly(ADP-ribose) polymerase. 798 10

We have measured the DNA damage formation and repair in the ribosomal and the dihydrofolate reductase (DHFR) genes after treatment of hamster cells with different types of DNA damaging agents. In mammalian cells, the ribosomal DNA (rDNA) is transcribed by RNA polymerase I, whereas the DHFR is transcribed by RNA polymerase II, whereas the DHFR is transcribed by RNA polymerase II. Cells were treated with agents that induce different types of lesions, and that are known to be repaired via different pathways. We used UV (254 nm) irradiation, treatment with cisplatin and treatment with the alkylating agents nitrogen mustard (HN2) and methyl methanesulphonate (MMS). UV induced pyrimidine dimers were detected with the enzyme T4 endonuclease V, which creates nicks at the dimer sites; the breaks are then resolved and identified by denaturing electrophoresis and Southern blot. Intrastrand adducts formed by the alkylating agents HN2 and MMS were quantitated by generating strand breaks at abasic sites after neutral depurination. Interstrand crosslinks (ICL) formed by HN2 and cisplatin were detected by a denaturation-reannealing reaction before neutral agarose gel-electrophoresis. We find that the repair of the pyrimidine dimers is significantly less efficient in the RNA polymerase I transcribed rDNA genes than in RNA polymerase II transcribed DHFR gene at 8 and 24 h after irradiation. ICL and intrastrand adducts induced by HN2 are also removed more slowly from the rDNA than from the DHFR gene. In contrast, MMS induced intrastrand adducts and cisplatin induced ICL are repaired equally efficiently in the RNA polymerase I and RNA polymerase II transcribed genes. We conclude that for some types of DNA damage, there is less repair in the ribosomal genes than in the DHFR; but for other DNA lesions there is no difference. The difference in repair efficiency between the rDNA and the DHFR genes may reflect the different RNA polymerase involved in their transcription. It may, however, alternatively, reflect the different nuclear localization of these genes.
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PMID:Repair of ribosomal RNA genes in hamster cells after UV irradiation, or treatment with cisplatin or alkylating agents. 835 43

Using specific inhibitors we have assessed the role of topoisomerases I and II in DNA repair of the overall genome and in both strands of an essential gene, the dihydrofolate reductase (DHFR) gene in chinese hamster ovary (CHO) cells. In these studies we have: (1) used inhibitors of topoisomerases during the repair incubation and (2) studied the DNA repair in cells with altered levels of topoisomerase activity. When cells were allowed to repair after UV irradiation, the gene-specific DNA repair was not affected by either topoisomerase I or topoisomerase II inhibitors alone. However, when topoisomerase I and topoisomerase II inhibitors were added simultaneously the gene- and strand-specific DNA repair were markedly inhibited. In contrast, the overall genome DNA repair was only marginally affected. This suggests that topoisomerases are involved in gene-specific DNA repair and that one type may substitute for the other in the repair process. That concept is further supported by our findings using a mutant cell line with a decreased level of topoisomerase I: gene-specific DNA repair can be inhibited by a topoisomerase II inhibitor alone. By analyzing the steady-state expression of the DHFR gene we find that inhibition of repair in the DHFR gene is not ascribed to an obvious change in the messenger level. Furthermore, using agents other than UV, we observe that the inhibitors have no effect on gene-specific repair of DNA damage introduced by the chemotherapeutic agents cisplatin and nitrogen mustard.
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PMID:Studies on the role of topoisomerases in general, gene- and strand-specific DNA repair. 840 8

We have analyzed gene-specific and strand-specific DNA damage and repair in the dihydrofolate reductase gene in hamster cells. Cells were UV-irradiated or treated with two types of chemotherapeutics, alkylating agents or cisplatin. UV-induced pyrimidine dimers were detected using a previously published technique in which the T4 endonuclease V enzyme is used to create nicks at the lesion sites. 6-4 photoproducts were detected in a similar assay using ABC excinuclease after prior reversal of the pyrimidine dimers with photolyase. Adducts formed by the alkylating agents nitrogen mustard and dimethyl sulfate were quantitated by generating strand breaks at basic sites after neutral depurination. Cisplatin-induced intrastrand adducts were detected with ABC excinuclease, and cisplatin interstrand cross-links were detected using a denaturation-reannealing reaction before electrophoresis. In accord with previous reports by other investigators, we find distinct strand specificity of the repair of pyrimidine dimers after UV; the transcribed strand was much more efficiently repaired than the nontranscribed strand. In contrast, there was little or no strand bias in the repair of the 6-4 photoproducts. For alkylating agents, a slight bias toward repair in the transcribed strand was found after treatment with nitrogen mustard, but there appeared to be no bias in the repair after treatment with dimethyl sulfate. Cisplatin interstrand cross-links are repaired with equal efficiency from the two strands, but the more common cisplatin-induced lesion, the intrastrand adduct, is preferentially repaired from the transcribed strand. In conclusion, there is strand bias in the repair of pyrimidine dimers and cisplatin intrastrand adducts, but the strand specificity of repair may not be a general feature for all DNA lesions, as we found little or no strand bias in the repair of other lesions studied.
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PMID:Repair of individual DNA strands in the hamster dihydrofolate reductase gene after treatment with ultraviolet light, alkylating agents, and cisplatin. 842 Sep 40

The gene-specific formation and repair of interstrand cross-links (ICL) were measured in the dihydrofolate reductase (DHFR) gene in hamster cells. Cells were treated with two different chemotherapeutic agents, nitrogen mustard and cisplatin, and the frequency of cross-links was quantified in the active gene and in a downstream, inactive region. About 5% of total lesions induced by these agents were ICL. Whereas the frequencies of cross-links formed were similar in the gene and in the noncoding region after cisplatin treatment, there were more nitrogen mustard-induced cross-links in the inactive region than in the active gene. At low levels of cross-linking, we found preferential DNA repair in the active gene as compared to the inactive region. At higher levels of cross-linking, there was no difference in repair rates between the gene and the noncoding region due to an increase in the repair efficiency in the inactive DNA. Implications of fine structural organization of cross-link repair are discussed.
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PMID:Gene-specific DNA repair of interstrand cross-links induced by chemotherapeutic agents can be preferential. 842 41

Transcription-coupled repair of DNA adducts is an essential factor that must be considered when one is elucidating biological endpoints resulting from exposure to genotoxic agents. Alkylating agents comprise one group of chemical compounds which modify DNA by reacting with oxygen and nitrogen atoms in the bases of the double helix. To discern the role of transcription-coupled DNA repair of N-ethylpurines present in discrete genetic domains, Chinese hamster ovary cells were exposed to N-ethyl-N-nitrosourea, and the clearance of the damage from the dihydrofolate reductase gene was investigated. The results indicate that N-ethylpurines were removed from the dihydrofolate reductase gene of nucleotide excision repair-proficient Chinese hamster ovary cells; furthermore, when repair rates in the individual strands were determined, a statistically significant bias in the removal of ethyl-induced, alkali-labile sites was observed, with clearance occurring 30% faster from the transcribed strand than from its nontranscribed counterpart at early times after exposure. In contrast, removal of N-ethylpurines was observed in the dihydrofolate reductase locus in cells that lacked nucleotide excision repair, but both strands were repaired at the same rate, indicating that transcription-coupled clearance of these lesions requires the presence of active nucleotide excision repair.
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PMID:Functional nucleotide excision repair is required for the preferential removal of N-ethylpurines from the transcribed strand of the dihydrofolate reductase gene of Chinese hamster ovary cells. 900 Dec 9

Nine novel 2,4-diamino-5-methyl-6-substituted-pyrido[2,3-d]pyrimidines, 2-10, were synthesized as potential inhibitors of Pneumocystis carinii dihydrofolate reductase (pcDHFR) and Toxoplasma gondii dihydrofolate reductase (tgDHFR). Compounds 2-5 were designed as conformationally restricted analogues of trimetrexate (TMQ), in which rotation around tau 3 was constrained by incorporation of the side chain nitrogen as part of an indoline or an indole ring. Analogue 6, which has an extra atom between the side chain nitrogen and the phenyl ring, has its nitrogen as part of a tetrahydroisoquinoline ring. Analogues 7-9 are epiroprim (Ro 11-8958) analogues and contain a pyrrole ring as part of the side chain substitution on the phenyl ring similar to epiroprim. These analogues were designed to investigate the role of the pyrrole substitution on the phenyl ring of 2,4-diamino-5-methyl-6-(anilinomethyl)pyrido[2,3-d]pyrimidines. Molecular modeling indicated that a pyrrole substituent in the ortho position of the side chain phenyl ring was most likely to interact with pcDHFR in a manner similar to the pyrrole moiety of epiroprim. Analogue 10, in which a phenyl ring replaced a methoxy group, was synthesized to determine the contribution of a phenyl ring on selectivity, lipophilicity, and cell penetration. The synthesis of analogues 2-4 was achieved via reductive amination of 2,4-diamino-5-methyl 6-carboxaldehyde with the appropriately substituted indolines. The indolines were obtained from the corresponding indoles via NaCNBH3 reductions. Analogues 5-10 were synthesized by nucleophilic displacement of 2,4-diamino-5-methyl-6-(bromomethyl)-pyrido[2,3-d]pyrimidine with the 5-methoxyindolyl anion, 6,7-dimethoxytetrahydroisoquinoline, the appropriately substituted pyrroloaniline or 2-methoxy-5-phenylaniline. The pyrroloanilines were synthesized in two steps by treating the substituted nitroanilines with 2,5-dimethoxy-tetrahydrofuran to afford the nitropyrrole intermediates, followed by reduction of the nitro group with Raney Ni. The analogues were more potent than trimethoprim and epiroprim and more selective than TMQ and piritrexim against pcDHFR and tgDHFR. Compounds 5 and 10 had IC50 values of 1 and 0.64 microM, respectively, for the inhibition of the growth of T. gondii cells in culture, and showed excellent culture IC50/enzyme IC50 ratios, which were correlated with their calculated log P values, indicating a direct relationship between calculated lipophilicity and cell penetration.
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PMID:Synthesis and biological evaluation of nonclassical 2,4-diamino-5-methylpyrido[2,3-d]pyrimidines with novel side chain substituents as potential inhibitors of dihydrofolate reductases. 904 38

After the recent discovery of a ribonuclease A unfolding intermediate [Kiefhaber, T., et al. (1995) Nature 375, 513-515], we investigated the unfolding pathway of hen egg white lysozyme. At pH* 4.00 with D2O at 10 degrees C and 6 M guanidinium chloride, unfolding shows a single, slow kinetic phase, with a relaxation time of 3300 s when monitored by circular dichroism (CD). Exchange of the tryptophan indole nitrogen protons shows that buried Trp residues 123, 111, and 108 lose tight packing and become solvent-exposed simultaneously, with a mean relaxation time of 3300 s, similar to the CD-monitored unfolding rate. Unfolding monitored by Trp fluorescence shows, moreover, that 90% of the amplitude change occurs in a slow phase, with a relaxation time of 2400 s. Faster-unfolding phases with minor amplitudes are detected by Trp indole hydrogen exchange and by fluorescence. It is likely that these changes are caused by Trp 62 and Trp 63, active site residues which are not buried in the hydrophobic core. Lysozyme unfolding was further monitored by the histidine 15 C epsilon1 proton, which gives resolved lines for the native and unfolded species in one-dimensional 1H-NMR spectra. The majority of the unfolding reaction, 70%, occurs in a slow phase with a relaxation time of 3600 s, but there is also a rapid unfolding phase; 30% of the His 15 C epsilon1 proton resonance intensity is found at the unfolded chemical shift within tens of seconds after the start of unfolding. The amplitude of the rapid unfolding phase increases proportionally with the concentration of GdmCl denaturant present. These results show that a partially buried residue of lysozyme, histidine 15, takes part in forming an unfolding intermediate similar to the one observed earlier for valine 63 in ribonuclease A. The tryptophan side chains buried in the hydrophobic core of lysoyzme, in contrast, do not participate in forming the unfolding intermediate, as judged by proton chemical shifts. The buried tryptophan residues of dihydrofolate reductase, monitored by 19F-NMR, do participate in forming an unfolding intermediate [Hoeltzli, S. D., & Frieden, C. (1995) Proc. Natl. Acad. Sci. U.S.A. 92, 9318-9322]; the difference between that study and ours may reside in the greater sensitivity of 19F to the detection of motional differences.
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PMID:Characterization of the unfolding pathway of hen egg white lysozyme. 906 98

N(alpha)-(4-Amino-4-deoxypteroyl)-N(delta)-hemiphthaloyl-L-o rnithine (PT523) is an unusually tight-binding dihydrofolate reductase (DHFR) inhibitor and is efficiently taken up into cells via the reduced folate carrier (RFC). Unlike classical DHFR inhibitors with a glutamate side chain, such as methotrexate and aminopterin, PT523 cannot form polyglutamates. Thus, it resembles lipophilic antifolates such as trimetrexate in not requiring metabolic activation by folylpolyglutamate synthetase in order to produce its antifolate effect. However, in contrast to trimetrexate, PT523 retains growth inhibitory activity in cells with the multidrug resistance phenotype. As part of the preclinical development of this drug, we have performed systematic modification of several regions of the PT523 molecule, with the aim of defining the optimal structural features for DHFR binding, influx into cells via the RFC, and the ability to inhibit cell growth. The following structure-activity correlations have emerged from this ongoing investigation, and are discussed: (1) the hemiphthaloylornithine side chain has the optimal length; (2) the preferred location of the aromatic carboxyl group is the ortho position; and (3) replacement of the phenyl ring of the para-aminobenzoic acid moiety by naphthalene, of nitrogen at the 10-position of the bridge by carbon, and of nitrogen at the 5- and/or 8-position of the B-ring by carbon are all well tolerated. Several of the second generation analogs of PT523 are more potent DHFR inhibitors and better RFC substrates than PT523 itself, and are more potent inhibitors of tumor cell growth in culture.
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PMID:The effect of side-chain, para-aminobenzoyl region, and B-ring modifications on dihydrofolate reductase binding, influx via the reduced folate carrier, and cytotoxicity of the potent nonpolyglutamatable antifolate N(alpha)-(4-amino-4-deoxypteroyl)-N(delta)-hemiphthaloyl-L- ornithine. 1073 74

The three-dimensional structure of the human dihydrofolate reductase (DHFR), methotrexate tetrazole, and NADPH ternary complex was used to model the corresponding ternary complexes with methotrexate tetrazole replaced by methotrexate, methotrexate-polyglutamate with three glutamyl residues, and 5,10-deazaaminopterin, respectively. Each complex was solvated in a 60-angstrom cube of explicit water and subjected to structural minimization followed by interaction energy analyses. Interaction energy calculations were performed for the antifolate interaction with water, NADPH, the DHFR binding site residues, the entire DHFR protein, and the solvated NADPH:DHFR complex. These studies revealed that methotrexate-polyglutamate exhibited the most stable interactions and that approximately one half of antifolate:DHFR stability could be accounted for by the interaction of the antifolate with the binding site residues. The antifolate structures were also subdivided into heterocyclic, phenyl, and glutamyl substructural regions. Interaction energies were subsequently calculated for the interactions of the subregions with water, NADPH, the DHFR binding site residues, the DHFR protein, and the solvated NADPH:DHFR complex. The glutamyl substructural region showed the greatest contribution to overall antifolate binding stability due to its interaction with the DHFR protein. The heterocyclic and phenyl substructural regions generally showed much less stable interactions. These results suggest that the primary stabilizing factor of the antifolate interaction is the interaction of glutamyl with the DHFR protein. Additionally, interaction energy analyses were performed for specific groups of atoms within the substructural regions. These studies indicated that the stability of the glutamyl interaction is due to the interaction of glutamyl oxygen atoms with the DHFR protein. In the case of the methotrexate tetrazole complex, the tetrazole nitrogens also contribute significantly to the stability of the glutamyl interaction. The carbon atoms of the heterocyclic and phenyl groups both showed more stable interactions with NADPH than with water, while the nitrogen atoms showed more stable interactions with water than with NADPH. Collectively, these results indicate that the glutamyl region is the most important in antifolate binding stability.
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PMID:Interaction energy analyses of folate analog binding to human dihydrofolate reductase: contribution of the antifolate substructural regions to complex stability. 1096 43


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