The dUTPase nucleotide-binding sites incorporate some features of other nucleotide-binding proteins and protein kinases, but seem distinct in sequence and architecture. The novel nucleic acid base recognition motif appears ancient; higher order structures, such as the ribosome, may have evolved from a motif of this kind. These uracil-beta-hairpin interactions are an obvious way for peptides to become early coenzymes in an RNA world, providing a plausible link to the protein-DNA world. Within the beta hairpin, there is a tyrosine corner motif that normally specifies beta-arch connections; this tyrosine motif was apparently recruited to discriminate against ribonucleotides, more recently than the evolution of the beta hairpin itself.
dUTP pyrophosphatase (dUTPase; EC 3.6.1.23) catalyses the hydrolysis of dUTP to dUMP and PPi and thereby prevents the incorporation of uracil into DNA during replication. Although it is widely believed that dUTPase is essential for cell viability because of this role, direct evidence supporting this assumption has not been presented for any eukaryotic system. We have analysed the role of dUTPase (DUT1) in the life cycle of yeast. Using gene disruption and tetrad analysis, we find that DUT1 is necessary for the viability of S. cerevisiae; however, under certain conditions dut1 null mutants survive if supplied with exogenous thymidylate (dTMP). Analyses with isogenic uracil‐DNA‐glycosylase (UNG1) deficient or proficient strains indicate that in the absence of dUTPase, cell death results from the incorporation of uracil into DNA and the attempted repair of this damage by UNG1‐mediated excision repair. However, in dut1 ung1 double mutants, starvation for dTMP causes dividing cells to arrest and die in all phases of the cell cycle. This latter effect suggests that the extensive stable substitution of uracil for thymine in DNA leads to a general failure in macromolecular synthesis. These results are in general agreement with previous models in thymine‐less death that implicate dUTP metabolism. They also suggest an alternative approach for chemotherapeutic drug design.
Comparison of the 5'-flanking regions of several cell cycle-regulated DNA replication genes of Saccharomyces cerevisiae has revealed the presence of a common sequence, 5'-ACGCGT-3', which is upstream and proximal to mapped transcription initiation sites. This sequence, which is the cleavage site for the restriction endonuclease MluI, is present twice in the upstream region of the yeast thymidylate synthase gene TMPI. Previous studies have implicated these MluI sites as critical components in the cell cycle-dependent transcription of TMPI. In this study, we examined more closely the importance of the ACGCGT sequences for the transcription of this gene. Using site-directed mutagenesis in combination with deletion analysis and subcloning experiments, we found that (i) while both of the TMPI MIuI sites contribute to the total transcription of this gene, the distal site is predominant and (ii) the 9-bp sequence ACGCGTTAA encompassing the distal MluI site exhibits properties of a cell cycle-stage dependent upstream activation sequence element. The results of this study support the notion that the ACGCGT sequence is an integral component of a transcription system which coordinates the cell cycle-dependent expression of DNA replication genes in S. cerevisiae.
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