Transcription of genes encoding enzymes involved in DNA synthesis during the cell cycle of Saccharomyces cerevisiae

The etiology of uracil residues in the Saccharomyces cerevisiae genomic DNA

Non-canonical residue in DNA is a major and conserved source of genome instability. The appearance of uracil residues in DNA accompanies a significant mutagenic consequence and is regulated at multiple levels, from the concentration of available dUTP in the nucleotide pool to the excision repair for removal from DNA. Recently, an interesting phenomenon of transcription-associated elevation in uracil-derived mutations was described in Saccharomyces cerevisiae genome. While trying to understand the variability in mutagenesis, we uncovered that the frequency of uracil incorporation into DNA can vary depending on the transcription rate and that the non-replicative, repair-associated DNA synthesis underlies the higher uracil density of the actively transcribed genomic loci. This novel mechanism brings together the chemical vulnerability of DNA under transcription and the uracil-associated mutagenesis, and has the potential to apply to other non-canonical residues of mutagenic importance.

SiSTL2 Is Required for Cell Cycle, Leaf Organ Development, Chloroplast Biogenesis, and Has Effects on C4 Photosynthesis in Setaria italica (L.) P. Beauv

Deoxycytidine monophosphate deaminase (DCD) is a key enzyme in the de novo dTTP biosynthesis pathway. Previous studies have indicated that DCD plays key roles in the maintenance of the balance of dNTP pools, cell cycle progression, and plant development. However, few studies have elucidated the functions of the DCD gene in Panicoideae plants. Setaria has been proposed as an ideal model of Panicoideae grasses, especially for C₄ photosynthesis research. Here, a Setaria italica stripe leaf mutant (sistl2) was isolated from EMS-induced lines of "Yugu1," the wild-type parent. The sistl2 mutant exhibited semi-dwarf, striped leaves, abnormal chloroplast ultrastructure, and delayed cell cycle progression compared with Yugu1. High-throughput sequencing and map-based cloning identified the causal gene SiSTL2, which encodes a DCD protein. The occurrence of a single-base G to A substitution in the fifth intron introduced alternative splicing, which led to the early termination of translation. Further physiological and transcriptomic investigation indicated that SiSTL2 plays an essential role in the regulation of chloroplast biogenesis, cell cycle, and DNA replication, which suggested that the gene has conserved functions in both foxtail millet and rice. Remarkably, in contrast to DCD mutants in C₃ rice, sistl2 showed a significant reduction in leaf cell size and affected C₄ photosynthetic capacity in foxtail millet. qPCR showed that SiSTL2 had a similar expression pattern to typical C₄ genes in response to a low CO₂ environment. Moreover, the loss of function of SiSTL2 resulted in a reduction of leaf ¹³C content and the enrichment of DEGs in photosynthetic carbon fixation. Our research provides in-depth knowledge of the role of DCD in the C₄ photosynthesis model S. italica and proposed new directions for further study of the function of DCD.

Ung1p-mediated uracil-base excision repair in mitochondria is responsible for the petite formation in thymidylate deficient yeast

The budding yeast CDC21 gene, which encodes thymidylate synthase, is crucial in the thymidylate biosynthetic pathway. Early studies revealed that high frequency of petites were formed in heat-sensitive cdc21 mutants grown at the permissive temperature. However, the molecular mechanism involved in such petite formation is largely unknown. Here we used a yeast cdc21-1 mutant to demonstrate that the mutant cells accumulated dUMP in the mitochondrial genome. When UNG1 (encoding uracil-DNA glycosylase) was deleted from cdc21-1, we found that the ung1Delta cdc21-1 double mutant reduced frequency of petite formation to the level found in wild-type cells. We propose that the initiation of Ung1p-mediated base excision repair in the uracil-laden mitochondrial genome in a cdc21-1 mutant is responsible for the mitochondrial petite mutations.

Somatic hypermutation at A.T pairs: polymerase error versus dUTP incorporation

Somatic hypermutation of immunoglobulin genes occurs at both C.G pairs and A.T pairs. Mutations at C.G pairs are created by activation-induced deaminase (AID)-catalysed deamination of C residues to U residues. Mutations at A.T pairs are probably produced during patch repair of the AID-generated U.G lesion, but they occur through an unknown mechanism. Here, we compare the popular suggestion of nucleotide mispairing through polymerase error with an alternative possibility, mutation through incorporation of dUTP (or another non-canonical nucleotide).

Negative regulation of G1 and G2 by S-phase cyclins of Saccharomyces cerevisiae

Cell cycle progression in the budding yeast Saccharomyces cerevisiae is controlled by the Cdc28 protein kinase, which is sequentially activated by different sets of cyclins. Previous genetic analysis has revealed that two B-type cyclins, Clb5 and Clb6, have a positive role in DNA replication. In the present study, we show, in addition, that these cyclins negatively regulate G1- and G2-specific functions. The consequences of this negative regulation were most apparent in clb6 mutants, which had a shorter pre-Start G1 phase as well as a shorter G2 phase than congenic wild-type cells. As a consequence, clb6 mutants grew and proliferated more rapidly than wild-type cells. It was more difficult to assess the role of Clb5 in G1 and G2 by genetic analysis because of the extreme prolongation of S phase in clb5 mutants. Nevertheless, both Clb5 and Clb6 were shown to be responsible for down-regulation of the protein kinase activities associated with Cln2, a G1 cyclin, and Clb2, a mitotic cyclin, in vivo. These observations are consistent with the observed cell cycle phase accelerations associated with the clb6 mutant and are suggestive of similar functions for Clb5. Genetic evidence suggested that the inhibition of mitotic cyclin-dependent kinase activities was dependent on and possibly mediated through the CDC6 gene product. Thus, Clb5 and Clb6 may stabilize S phase by promoting DNA replication while inhibiting other cell cycle activities.

MluI site-dependent transcriptional regulation of the Candida albicans dUTPase gene

The Candida albicans dUTP pyrophosphatase (dUTPase) gene DUT1 has been isolated by genetic complementation in S. cerevisiae. It was found to encode a 17-kDa protein similar in amino-acid sequence to dUTPases isolated from other systems. The gene was adapted for expression in E. coli and yielded a soluble and highly-active enzyme which is easily purified. The 5' flanking sequence of DUT1 contains an MluI site typical of MCB cell-cycle-dependent UAS elements of budding and fission yeast. We found the gene to be cell-cycle-regulated when expressed in S. cerevisiae, and deletion of the MluI site resulted in a large reduction of DUT1 transcription in C. albicans. These results suggest that MCB elements are functionally conserved in this pathogenic fungus. Based on the vital role that dUTPase plays in DNA replication, the C. albicans enzyme may be a potentially useful target for the development of novel anti-fungal compounds.

International Commission for Protection Against Environmental Mutagens and Carcinogens. Deoxyribonucleoside triphosphate levels: a critical factor in the maintenance of genetic stability

DNA precursor pool imbalances can elicit a variety of genetic effects and modulate the genotoxicity of certain DNA-damaging agents. These and other observations indicate that the control of DNA precursor concentrations is essential for the maintenance of genetic stability, and suggest that factors which offset this control may contribute to environmental mutagenesis and carcinogenesis. In this article, we review the biochemical and genetic mechanisms responsible for regulating the production and relative amounts of intracellular DNA precursors, describe the many outcomes of perturbations in DNA precursor levels, and discuss implications of such imbalances for sensitivity to DNA-damaging agents, population monitoring, and human diseases.

Expression of DNA replication genes in the yeast cell cycle

In recent years, numerous studies using a wide variety of systems have clearly established some of the fundamental components of eukaryotic cell-division control. These include p34cdc2 protein kinases (henceforth referred to as p34) and closely related proteins (p33cdc2), and the members of the cyclin gene family which, through interaction with the p34 (and p33) kinases, regulate transitions from one stage of the cell cycle to the next. The function of these proteins in the cell cycle has been conserved to the extent that p34 protein kinase and cyclin genes are, in some cases, interchangeable between organisms. Despite the tremendous insight that studies on p34 and the cyclins have provided, many questions remain about the details of the molecular events which allow these proteins to govern cell division. One question of particular interest concerns the means by which p34 interaction with G1 phase cyclins promotes G1 to S phase transition in the cell cycle. This is of primary importance since entry into the cell cycle is regulated, for most cells, by passage from G1 (or G0) into S phase. Recent findings in the yeast Saccharomyces cerevisiae point to a potential link between the p34/G1 cyclin protein kinase complex and the regulation of DNA replication genes during the cell cycle. This paper reviews studies dealing with the transcriptional control of DNA replication genes in yeast and also briefly discusses the potential role of G1 cyclins in this process. A similar review of this subject has also been given by Johnston and Lowndes (1992).

MCB elements and the regulation of DNA replication genes in yeast

In eukaryotic organisms, genes involved in DNA replication are often subject to some form of cell cycle control. In the yeast Saccharomyces cerevisiae, most of the DNA replication genes that have been characterized to date are regulated at the transcriptional level during G1 to S phase transition. A cis-acting element termed the MluI cell cycle box (or MCB) conveys this pattern of regulation and is common among more than 20 genes involved in DNA synthesis and repair. Recent findings indicate that the MCB element is well conserved among fungi and may play a role in controlling entry into the cell division cycle. It is evident from studies in higher systems, however, that transcriptional regulation is not the only form of control that governs the cell-cycle-dependent expression of DNA replication genes. Moreover, it is unclear why this general pattern of regulation exists for so many of these genes in various eukaryotic systems. This review summarizes recent studies of the MCB element in yeast and briefly discusses the purpose of regulating DNA replication genes in the eukaryotic cell cycle.

Identification of a gene encoding the predicted ribosomal protein L7b divergently transcribed from POL1 in fission yeast Schizosaccharomyces pombe

A 0.85 Kb RNA molecule is transcribed in the region upstream from the 5'-end of the S. pombe POL1 gene encoding the catalytic subunit of DNA polymerase alpha. The nucleotide sequence of the DNA region hybridizing with the 0.85 Kb transcript allowed us to identify an open reading frame coding for a predicted peptide which shows 50% identity with the rat ribosomal protein L7 and which is transcribed divergently from POL1. We have named this gene RPL7b because of the existence in S. pombe of a different sequence, named RPL7, which also codes for a putative protein showing homology with the rat ribosomal protein L7. The RPL7b gene includes a 291 bp-long intron containing the sequences necessary for intron excision and RNA splicing in S. pombe. The precise location of the intron was established by amplification and sequencing of a partial cDNA copy of the mRNA, whereas the initiation site of transcription was determined by reverse transcription of the 5' region of the mRNA. The 320 bp separating the starting methionine codons of RPL7b and POL1 genes should contain the signals necessary for their divergent transcription and regulation. The sequence 5'-AAGACAGTCACA-3', whose primary structure is homologous to a conserved block present in the 5'-untranscribed regions of other S. pombe genes of ribosomal proteins, is located about 50 bp upstream the transcription initiation site of RPL7b.

The effect of DNA replication on mutation of the Saccharomyces cerevisiae CDC8 gene

Incubation in YPD medium under permissive conditions when DNA replication is going on, strongly stimulates the induction of cdc+ colonies of UV-irradiated cells of yeast strains HB23 (cdc8-1/cdc8-3), HB26 (cdc8-3/cdc8-3) and HB7 (cdc8-1/cdc8-1). Inhibition of DNA replication by hydroxyurea, araCMP, cycloheximide or caffeine or else by incubation in phosphate buffer pH 7.0, abolishes this stimulation. Thus the replication of DNA is strongly correlated with the high induction of cdc+ colonies by UV irradiation. It is postulated that these UV-induced cdc+ colonies arise as the result infidelity in DNA replication.

Expression of the yeast DNA primase gene, PRI1, is regulated within the mitotic cell cycle and in meiosis

Mitotic cultures synchronised either by a feed-starve protocol or by elutriation have been used to show that the Saccharomyces cerevisiae DNA primase I gene is periodically expressed in the cell cycle. The transcript increases many-fold in late G1 and reaches a peak at the same time as four other genes essential for DNA synthesis, CDC8, CDC9, CDC21 and POL1. The primase I transcript is also regulated in meiosis, reaching maximal levels during premeiotic DNA synthesis.

Transcriptional regulation of the cell cycle-dependent thymidylate synthase gene of Saccharomyces cerevisiae

We have previously shown that transcript levels expressed from the yeast TMP1 gene fluctuate periodically during the yeast cell cycle. However, it was not known whether periodic expression resulted from a regulatory mechanism acting at the level of transcription or a regulatory mechanism acting at the level of cell cycle stage-dependent changes in the stability of the TMP1 transcript. In this report we now show that the periodic expression of TMP1 transcript is primarily controlled at the level of its transcription by sequences which are upstream of its transcription initiation sites. We also localized the upstream sequences necessary for periodic transcription to a 150-base-pair region and show that this region encodes an element(s) with the properties of a periodic upstream activating sequence. The regulatory region defined in this study apparently does not contain consensus sequences similar to those reported for the cell cycle-regulated HO endonuclease or for the histone H2A and H2B genes of Saccharomyces cerevisiae.

The yeast gene, DBF4, essential for entry into S phase is cell cycle regulated

The DBF4 gene of Saccharomyces cerevisiae, required for events preceding DNA replication, was isolated and located to 2.8 kb of DNA from chromosome IV. Genetic mapping showed the gene to be linked to TRP1. The DBF4 transcript is 2.4 kb in length and shows periodic regulation within the cell cycle. The peak of expression occurs late in G1, coincident with several genes involved in DNA synthesis. The behavior of the message is consistent with that expected for a stable, cell cycle regulated transcript.

Transcriptional regulation of the cell cycle-dependent thymidylate synthase gene of Saccharomyces cerevisiae

We have previously shown that transcript levels expressed from the yeast TMP1 gene fluctuate periodically during the yeast cell cycle. However, it was not known whether periodic expression resulted from a regulatory mechanism acting at the level of transcription or a regulatory mechanism acting at the level of cell cycle stage-dependent changes in the stability of the TMP1 transcript. In this report we now show that the periodic expression of TMP1 transcript is primarily controlled at the level of its transcription by sequences which are upstream of its transcription initiation sites. We also localized the upstream sequences necessary for periodic transcription to a 150-base-pair region and show that this region encodes an element(s) with the properties of a periodic upstream activating sequence. The regulatory region defined in this study apparently does not contain consensus sequences similar to those reported for the cell cycle-regulated HO endonuclease or for the histone H2A and H2B genes of Saccharomyces cerevisiae.

Differential regulation of the yeast CDC7 gene during mitosis and meiosis

The product of the CDC7 gene of Saccharomyces cerevisiae is known to be required in the mitotic cell cycle for the initiation of DNA replication. We show that changes in transcript levels do not account for this stage-specific function, since the steady-state mRNA concentration remains constant at 1 copy per cell throughout the cell cycle. By measuring the cell division capacity of a cdc7::URA3 mutant after loss of a single-copy plasmid containing the CDC7 gene, we show that the CDC7 protein is present in at least 200-fold excess of the amount required for a single cell division. These results appear to exclude periodic transcription or translation as a means by which CDC7 function is regulated. In contrast, the CDC7 protein is known to be dispensable for meiotic S phase, but is required for synaptonemal complex formation and recombination. We found that the CDC7 transcript level does vary during meiosis, reaching a maximum near the time at which recombination occurs. Meiotic spores containing a cdc7 null allele germinate but fail to complete cell division. Apparently the excess CDC7 product present in mitotic cells is physically excluded from the spores (or becomes inactivated) and must be produced de novo after germination. The cdc7-1 allele had previously been shown to confer a reduction in the rate of induced mutation. We show that the cloned wild-type CDC7 gene not only complements this defect, but that when the CDC7 gene is on a multiple copy plasmid, induced mutagenesis is increased. Therefore, in contrast to the excess CDC7 activity for cell division, the level of activity for some error-prone repair process may be normally limiting.

Differential regulation of the yeast CDC7 gene during mitosis and meiosis

The product of the CDC7 gene of Saccharomyces cerevisiae is known to be required in the mitotic cell cycle for the initiation of DNA replication. We show that changes in transcript levels do not account for this stage-specific function, since the steady-state mRNA concentration remains constant at 1 copy per cell throughout the cell cycle. By measuring the cell division capacity of a cdc7::URA3 mutant after loss of a single-copy plasmid containing the CDC7 gene, we show that the CDC7 protein is present in at least 200-fold excess of the amount required for a single cell division. These results appear to exclude periodic transcription or translation as a means by which CDC7 function is regulated. In contrast, the CDC7 protein is known to be dispensable for meiotic S phase, but is required for synaptonemal complex formation and recombination. We found that the CDC7 transcript level does vary during meiosis, reaching a maximum near the time at which recombination occurs. Meiotic spores containing a cdc7 null allele germinate but fail to complete cell division. Apparently the excess CDC7 product present in mitotic cells is physically excluded from the spores (or becomes inactivated) and must be produced de novo after germination. The cdc7-1 allele had previously been shown to confer a reduction in the rate of induced mutation. We show that the cloned wild-type CDC7 gene not only complements this defect, but that when the CDC7 gene is on a multiple copy plasmid, induced mutagenesis is increased. Therefore, in contrast to the excess CDC7 activity for cell division, the level of activity for some error-prone repair process may be normally limiting.

Molecular characterization of the Saccharomyces cerevisiae dihydrofolate reductase gene (DFR1)

The complete nucleotide sequence of a 1957 bp DNA fragment containing the dihydrofolate reductase gene (DFR1) of the yeast Saccharomyces cerevisiae is presented. Within this region a single open reading frame of 633 base pairs was found which is capable of encoding a 211 amino acid residue protein with a calculated Mr of 24,233. The amino acid sequence derived from the yeast DFR1 gene shows limited homology with sequences from both eukaryotic and non-eukaryotic DHFR enzymes. Northern blot hybridization reveals that the mRNA from this gene is a 900 base polyadenylated transcript. Yeast strains containing the cloned DFR1 gene on multicopy number shuttle vector plasmids show dramatically enhanced methotrexate resistance. Consensus DNA sequences responsible for RNA polymerase II interaction and general amino acid control in S. cerevisiae are located within the 5'-noncoding region with respect to the open reading frame. The DNA fragment containing these sequences has been shown to be necessary for DFR1 gene expression in both S. cerevisiae and E. coli.