A defective dNTP pool hinders DNA replication in cell cycle-reactivated terminally differentiated muscle cells.

Terminally differentiated cells are defined by their inability to proliferate. When forced to re-enter the cell cycle, they generally cannot undergo long-term replication. Our previous work with myotubes has shown that these cells fail to proliferate because of their intrinsic inability to complete DNA replication. Moreover, we have reported pronounced modifications of deoxynucleotide metabolism during myogenesis. Here we investigate the causes of incomplete DNA duplication in cell cycle-reactivated myotubes (rMt). We find that rMt possess extremely low levels of thymidine triphosphate (dTTP), resulting in very slow replication fork rates. Exogenous administration of thymidine or forced expression of thymidine kinase increases deoxynucleotide availability, allowing extended and faster DNA replication. Inadequate dTTP levels are caused by selective, differentiation-dependent, cell cycle-resistant suppression of genes encoding critical synthetic enzymes, chief among which is thymidine kinase 1. We conclude that lack of dTTP is at least partially responsible for the inability of myotubes to proliferate and speculate that it constitutes an emergency barrier against unwarranted DNA replication in terminally differentiated cells.

Base excision repair of both uracil and oxidatively damaged bases contribute to thymidine deprivation-induced radiosensitization.

PURPOSE: Increased cellular sensitivity to ionizing radiation due to thymidine depletion is the basis of radiosensitization with fluoropyrimidine and methotrexate. The mechanism responsible for cytotoxicity has not been fully elucidated but appears to involve both the introduction of uracil into, and its removal from, DNA. The role of base excision repair of uracil and oxidatively damaged bases in creating the increased radiosensitization during thymidine depletion is examined. METHODS AND MATERIALS: Isogenic strains of S. cerevisiae differing only at loci involved in DNA repair functions were exposed to aminopterin and sulfanilamide to induce thymidine deprivation. Cultures were irradiated and survival determined by clonogenic survival assay. RESULTS: Strains lacking uracil base excision repair (BER) activities demonstrated less radiosensitization than the parental strain. Mutant strains continued to show partial radiosensitization with aminopterin treatment. Mutants deficient in BER of both uracil and oxidatively damaged bases did not demonstrate radiosensitization. A recombination deficient rad52 mutant strain was markedly sensitive to radiation; addition of aminopterin increased radiosensitivity only slightly. Radiosensitization observed in rad52 mutants was also abolished by deletion of the APN1, NTG1, and NTG2 genes. CONCLUSION: These data suggest radiosensitization during thymidine depletion is the result of BER activities directed at both uracil and oxidatively damaged bases.

Thymidylate stress induces homologous recombination activity in mammalian cells.

We studied whether homologous recombination activity in mammalian cells could be induced by thymidylate stress (thymidylate deprivation). In vitro recombination activity in cell extracts was measured with pSV2neo-derived plasmids. When prior to the preparation of extracts, mouse FM3A cells were grown in 5-fluorodeoxyuridine (FdUrd), an inducer of thymidylate stress, the homologous recombination activity was significantly induced, as judged from an increase in the number of neomycin-resistant bacterial colonies. Maximum induction was observed in cells treated with 1 microM FUdR for 16 h. However, 3-8 h of treatment of FM3A cells with the drug followed by an additional 8-16-h incubation in its absence was sufficient to induce the recombination activity while slightly reducing their growth rates. These results indicate that thymidylate stress induces homologous recombination activity in mammalian cells as observed in Escherichia coli and in yeast.

A specialized form of chromosomal DNA degradation induced by thymidylate stress in mouse FM3A cells.

Thymidylate synthase-negative mutant mouse cells starved of thymidine or their parental FM3A cells treated with 5-fluoro-2'-deoxyuridine produced DNA fragments ranging from 50 to 200 kilobase pairs with a peak at 100 kb in length as determined by pulsed-field agarose gel electrophoresis. Accumulation of the DNA fragments following such thymidylate stress was time-dependent but their size distribution did not change in either case. Regions of the chromosomal DNA breaks seemed to be restricted to those where DNA replication was in progress as shown by pulse-labeling of the DNA synthesis. Emetine, an inhibitor of protein synthesis, blocked the accumulation of the DNA fragments when present during thymidylate stress. Cell-free extracts prepared from the thymidylate-stressed cells derived by either of the above means were capable of degrading DNA in chromatins prepared from normally growing cells in vitro. The resulting DNA fragments were similar but with a somewhat broader size distribution compared to those produced in vivo. The broader distribution of the fragments produced in the in vitro reaction became closer to the pattern obtained in vivo when ATP and 4 deoxyribonucleotides were added to the reaction.

Induction of mitotic recombination in yeast by starvation for thymine nucleotides.

The biosynthesis of thymine nucleotides in Saccharomyces cerevisiae can be inhibited either by genetic lesions in the structural gene for thymidylate synthetase (TMP1) or by drugs that prevent the methylation of dUMP to dTMP. This methylation can be blocked by folate antagonists. We find that 5-fluoro-dUMP (FdUMP) is also an effective inhibitor in vivo. Inhibition of dTMP biosynthesis by these three different routes causes thymineless death. In addition to being cytotoxic, we find that FdUMP is highly recombinagenic in yeast but does not induce nuclear gene mutations. Provision of exogenous dTMP eliminates this induced mitotic recombination and cell killing. Similar results were obtained when a thymineless condition was provoked in cells by antifolate drugs or by dTMP deprivation in strains auxotrophic for this nucleotide. These findings show that, in contrast to the situation in prokaryotes, starvation for thymine nucleotides in yeast induces genetic recombination but is not mutagenic.