Site-specific DNA repair at the nucleosome level in a yeast minichromosome

The rate of excision repair of UV-induced pyrimidine dimers (PDs) was measured at specific sites in each strand of a yeast minichromosome containing an active gene (URA3), a replication origin (ARS1), and positioned nucleosomes. All six PD sites analyzed in the transcribed URA3 strand were repaired more rapidly (greater than 5-fold on average) than any of the nine PD sites analyzed in the nontranscribed strand. Efficient repair also occurred in both strands of a disrupted TRP1 gene (ten PD sites), containing four unstable nucleosomes, and in a nucleosome gap at the 5' end of URA3 (two PD sites). Conversely, slow repair occurred in both strands immediately downstream of the URA3 gene (12 of 14 PD sites). This region contains the ARS1 consensus sequence, a nucleosome gap, and two stable nucleosomes. Thus, modulation of DNA repair occurs in a simple yeast minichromosome and correlates with gene expression, nucleosome stability, and (possibly) control of replication.     

N-methylpurines are heterogeneously repaired in human mitochondria but not evidently repaired in yeast mitochondria

Base excision repair (BER) of dimethyl sulfate induced N-methylpurines (NMPs) was measured at nucleotide resolution in the mitochondrial DNA (mtDNA) of cultured human and yeast (Saccharomyces cerevisiae) cells. NMPs were repaired with heterogeneous rates in the human mtDNA. The nearest-neighbor nucleotides significantly affected the repair rates: NMPs between pyrimidines were repaired much faster than those between purines, and those between a purine and a pyrimidine were repaired at intermediate rates. Repair intermediates of NMPs can also be detected at certain sites of the human mtDNA, indicating an ineffectiveness of processing the intermediates at these sites by the human mitochondrial BER machinery. In contrast to the human mtDNA, the yeast mtDNA did not show detectable repair of NMPs at any sites. Furthermore, a high level of spontaneous strand breaks exists exclusively at purine sites in the yeast mtDNA. Spontaneous NMPs or oxidative lesions were unlikely to be the major causes for the spontaneous strand breaks. Rather, spontaneous depurination combined with inefficient processing of DNA nicks or single-nucleotide gaps by the yeast mitochondrial BER machinery may result in the spontaneous strand breaks. Our results unveil a striking difference in BER between human and the yeast mitochondria.     

A New Type of Fusion Analysis Applicable to Many Organisms: Protein Fusions to the URA3 Gene of Yeast

We have made constructs that join the promoter sequences and a portion of the coding region of the Saccharomyces cerevisiae HIS4 and GAL1 genes and the E. coli lacZ gene to the sixth codon of the S. cerevisiae URA3 gene (encodes orotidine-5'-phosphate (OMP) decarboxylase) to form three in frame protein fusions. In each case the fusion protein has OMP decarboxylase activity as assayed by complementation tests and this activity is properly regulated. A convenient cassette consisting of the URA3 segment plus some immediately proximal amino acids of HIS4C is available for making URA3 fusions to other proteins of interest. URA3 fusions offer several advantages over other systems for gene fusion analysis: the URA3 specified protein is small and cytosolic; genetic selections exist to identify mutants with either increased or decreased URA3 function in both yeast (S. cerevisiae and Schizosaccharomyces pombe) and bacteria (Escherichia coli and Salmonella typhimurium); and a sensitive OMP decarboxylase enzyme assay is available. Also, OMP decarboxylase activity is present in mammals, Drosophila and plants, so URA3 fusions may eventually be applicable in these other organisms as well.     

Repair of specific base pair mismatches formed during meiotic recombination in the yeast Saccharomyces cerevisiae.

Heteroduplexes formed between DNA strands derived from different homologous chromosomes are an intermediate in meiotic crossing over in the yeast Saccharomyces cerevisiae and other eucaryotes. A heteroduplex formed between wild-type and mutant genes will contain a base pair mismatch; failure to repair this mismatch will lead to postmeiotic segregation (PMS). By analyzing the frequency of PMS for various mutant alleles in the yeast HIS4 gene, we showed that C/C mismatches were inefficiently repaired relative to all other point mismatches. These other mismatches (G/G, G/A, T/T, A/A, T/C, C/A, A/A, and T/G) were repaired with approximately the same efficiency. We found that in spores with unrepaired mismatches in heteroduplexes, the nontranscribed strand of the HIS4 gene was more frequently donated than the transcribed strand. In addition, the direction of repair for certain mismatches was nonrandom.     

Nucleosome structure and repair of N-methylpurines in the GAL1-10 genes of Saccharomyces cerevisiae

Nucleosome structure and repair of N-methylpurines were analyzed at nucleotide resolution in the divergent GAL1-10 genes of intact yeast cells, encompassing their common upstream-activating sequence. In glucose cultures where genes are repressed, nucleosomes with fixed positions exist in regions adjacent to the upstream-activating sequence, and the variability of nucleosome positioning sharply increases with increasing distance from this sequence. Galactose induction causes nucleosome disruption throughout the region analyzed, with those nucleosomes close to the upstream-activating sequence being most striking. In glucose cultures, a strong correlation between N-methylpurine repair and nucleosome positioning was seen in nucleosomes with fixed positions, where slow and fast repair occurred in nucleosome core and linker DNA, respectively. Galactose induction enhanced N-methylpurine repair in both strands of nucleosome core DNA, being most dramatic in the clearly disrupted, fixed nucleosomes. Furthermore, N-methylpurines are repaired primarily by the Mag1-initiated base excision repair pathway, and nucleotide excision repair contributes little to repair of these lesions. Finally, N-methylpurine repair is significantly affected by nearest-neighbor nucleotides, where fast and slow repair occurred in sites between pyrimidines and purines, respectively. These results indicate that nucleosome positioning and DNA sequence significantly modulate Mag1-initiated base excision repair in intact yeast cells.     

Marker-disruptive gene integration and URA3 recycling for multiple gene manipulation in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

The introduction of several kinds of genes into the yeast chromosome is a powerful tool in many fields from fundamental study to industrial application. Here, we describe a general strategy for one-step gene integration and a marker recycling method. Forty base pairs of a short sequence derived from a region adjacent to the HIS3 locus were placed between cell surface displaying β-glucosidase (BGL) and URA3 marker genes. HIS3 deletion and BGL–URA3 fragment integration were achieved via a PCR fragment consisting of the BGL–URA3 fragment attached to homology sequences flanked by the HIS3 targeting locus. The obtained his3::URA3 disruptants were plated on a 5-FOA plate to select for the URA3 deletion due to repeated sequences at both sides of URA3 gene. In all selected colonies, BGL genes were integrated at the targeted HIS3 locus and URA3 was completely deleted. In addition, introduced BGL was efficiently expressed, and the transformants fermented cellobiose to ethanol effectively. As our strategy creates next transformation markers continuously together with gene integration, this method can serve as a simple and powerful tool for multiple genetic manipulations in yeast engineering.     

The regulatory protein GAL80 is a determinant of the chromatin structure of the yeast GAL1-10 control region

Chromatin in the regions between the upstream activator sequence and the 5' ends of the yeast GAL1 and GAL10 genes has been analyzed by DNase I chromosomal footprinting and micrococcal nuclease digestion using the indirect end-labeling approach. Comparison of wild type chromatin digests to naked DNA digests shows that there are specific regions of these upstream sequences which are strongly protected in chromatin. Comparison to chromatin digests from cells disrupted for the positive regulatory gene, GAL4, or the negative regulatory gene, GAL80, and thus lacking GAL4 or GAL80 function, shows that these regions of protection in wild type chromatin are GAL80-dependent but not GAL4-dependent. The protected regions include DNA lying on (GAL10) or near (GAL1) the respective TATA boxes. These protections are present in both noninduced and induced cells. Both DNA strands are equally protected. Upstream of GAL1 there is a second protected region. This protection shows considerable expression and strand dependence. These observations provide the first evidence that the GAL80 function influences chromatin structure and suggest possible mechanisms by which GAL80 modulates the GAL1 and 10 promoters in induced cells. Micrococcal nuclease digests also suggest a role for GAL80 in a distinctive higher order organization of the intergenic region, perhaps involving multiprotein complexes.     

Genetic selection for reciprocal translocation at chosen chromosomal sites in Saccharomyces cerevisiae.

We have constructed viable Saccharomyces cerevisiae strains containing a reciprocal translocation between the URA2 site of chromosome X and the HIS3 site of chromosome XV. Our methodology is an extension of the method originally developed to introduce an altered cloned sequence at the chromosomal location from which the parent sequence was derived (S. Scherer and R.W. Davis, Proc. Natl. Acad. Sci. U.S.A. 76:4951-4955, 1979). It comprises three essential steps. First, a nonreverting ura2- strain was constructed by deleting a 3.7-kilobase fragment from the coding sequence of the wild-type URA2 gene. Second, part of the coding sequence of the wild-type URA2 gene (without promotor) was inserted at the HIS3 locus of the ura2- strain. Third, after several generations of growth on uracil-supplemented medium, ura2+ colonies were selected which resulted from mitotic recombination between the nonoverlapping deletions of URA2 located on chromosomes X and XV.     

High-resolution Digital Mapping of N-Methylpurines in Human Cells Reveals Modulation of Their Induction and Repair by Nearest-neighbor Nucleotides

N-Methylpurines (NMPs), including N⁷-methylguanine (7MeG) and N³-methyladenine (3MeA), can be induced by environmental methylating agents, chemotherapeutics, and natural cellular methyl donors. In human cells, NMPs are repaired by the multi-step base excision repair pathway initiated by human alkyladenine glycosylase. Repair of NMPs has been shown to be affected by DNA sequence contexts. However, the nature of the sequence contexts has been poorly understood. We developed a sensitive method, LAF-Seq (Lesion-Adjoining Fragment Sequencing), which allows nucleotide-resolution digital mapping of DNA damage and repair in multiple genomic fragments of interest in human cells. We also developed a strategy that allows accurate measurement of the excision kinetics of NMP bases in vitro. We demonstrate that 3MeAs are induced to a much lower level by the S_N2 methylating agent dimethyl sulfate and repaired much faster than 7MeGs in human fibroblasts. Induction of 7MeGs by dimethyl sulfate is affected by nearest-neighbor nucleotides, being enhanced at sites neighbored by a G or T on the 3′ side, but impaired at sites neighbored by a G on the 5′ side. Repair of 7MeGs is also affected by nearest-neighbor nucleotides, being slow if the lesions are between purines, especially Gs, and fast if the lesions are between pyrimidines, especially Ts. Excision of 7MeG bases from the DNA backbone by human alkyladenine glycosylase in vitro is similarly affected by nearest-neighbor nucleotides, suggesting that the effect of nearest-neighbor nucleotides on repair of 7MeGs in the cells is primarily achieved by modulating the initial step of the base excision repair process.