Heterochromatic DNA repeats in <Emphasis Type="Italic">Drosophila</Emphasis> and unusual gene silencing in yeast cells

The 1.25-kb heterochromatic Stellate repeats of Drosophila melanogaster are capable of stably persisting in transgenic constructs and silencing the white reporter gene (mosaic position effect variegation). This system reveals an unusual form of silencing, which is insensitive to known modifiers of position effect variegation. The unusual form of silencing was studied with yeast Saccharomyces cerevisiae, a simple eukaryotic model. To be transferred into yeast cells, the D. melanogaster Stellate repeats were cloned in the pYAC4 centromeric vector (CEN4, URA3, TRP1, HIS3). The HIS3 and/or URA3 genes could be inactive in plasmids consisting of pYAC4 and the Stellate insert in yeast cells. Deletion of D. melanogaster DNA from the plasmid was found to activate the URA3 and HIS3 genes. It was assumed that the genes were repressed rather than damaged in the presence of the Stellate repeats and that a new form of gene silencing was revealed in.     

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.     

Dot1 and histone H3K79 methylation in natural telomeric and HM silencing

The expression of genes residing near telomeres is attenuated through telomere position-effect variegation (TPEV). By using a URA3 reporter located at TEL-VII-L of Saccharomyces cerevisiae, it was proposed that the disruptor of telomeric silencing-1 (Dot1) regulates TPEV by catalyzing H3K79 methylation. URA3 reporter assays also indicated that H3K79 methylation is required for HM silencing. Surprisingly, a genome-wide expression analysis of H3K79 methylation-defective mutants identified only a few telomeric genes, such as COS12 at TEL-VII-L, to be subject to H3K79 methylation-dependent natural silencing. Consistently, loss of Dot1 did not globally alter Sir2 or Sir3 occupancy in subtelomeric regions, but only led to some telomere-specific changes. Furthermore, H3K79 methylation by Dot1 did not play a role in the maintenance of natural HML silencing. Therefore, commonly used URA3 reporter assays may not report on natural PEV, and therefore, studies concerning the epigenetic mechanism of silencing in yeast should also employ assays reporting on natural gene expression patterns.     

The ubiquitin-conjugating enzyme Rad6 (Ubc2) is required for silencing in Saccharomyces cerevisiae.

It has been previously shown that genes transcribed by RNA polymerase II (RNAP II) are subject to position effect variegation when located near yeast telomeres. This telomere position effect requires a number of gene products that are also required for silencing at the HML and HMR loci. Here, we show that a null mutation of the DNA repair gene RAD6 reduces silencing of the HM loci and lowers the mating efficiency of MATa strains. Likewise, rad6-delta reduces silencing of the telomere-located RNAP II-transcribed genes URA3 and ADE2. We also show that the RNAP III-transcribed tyrosyl tRNA gene, SUP4-o, is subject to position effect variegation when located near a telomere and that this silencing requires the RAD6 and SIR genes. Neither of the two known Rad6 binding factors, Rad18 and Ubr1, is required for telomeric silencing. Since Ubrl is the recognition component of the N-end rule-dependent protein degradation pathway, this suggests that N-end rule-dependent protein degradation is not involved in telomeric silencing. Telomeric silencing requires the amino terminus of Rad6. Two rad6 point mutations, rad6(C88A) and rad6(C88S), which are defective in ubiquitin-conjugating activity fail to complement the silencing defect, indicating that the ubiquitin-conjugating activity of RAD6 is essential for full telomeric silencing.     

Regulation of HIS4-lacZ fusions in Saccharomyces cerevisiae.

The beginning of the Saccharomyces cerevisiae HIS4 gene has been fused to the structural gene for Escherichia coli beta-galactosidase. This construction, which contains HIS4 DNA from -732 to +30 relative to the translation initiation codon, has been integrated into the yeast genome at two chromosomal locations, HIS4 and URA3. At both locations, this 762-base-pair stretch of DNA is sufficient for initiating expression of beta-galactosidase activity in S. cerevisiae and confers upon this activity the regulatory response normally found for HIS4.     

New selectable marker/auxotrophic host strain combinations for molecular genetic manipulation of Pichia pastoris

We describe the isolation and characterization of three new biosynthetic genes-ARG4, ADE1, and URA3-from the methylotrophic yeast Pichia pastoris. The predicted products of the genes share significant sequence similarity to their Saccharomyces cerevisiae counterparts, namely argininosuccinate lyase, PR-aminoimidazolesuccinocarboxamide synthase, and orotidine-5'-phosphate decarboxylase, respectively. Along with the previously described HIS4 gene, each gene was incorporated as the yeast selectable marker into a set of shuttle vectors designed to express foreign genes in P. pastoris. In addition, we have constructed a series of host strains containing all possible combinations of ade1, arg4, his4, and ura3 auxotrophies to be used with these new vectors.     

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 histone deacetylase inhibitor trichostatin A reduces nickel-induced gene silencing in yeast and mammalian cells

We have previously reported that nickel (Ni)-silenced expression of the URA3 gene in yeast (Saccharomyces cerevisiae) and gpt transgene in G12 Chinese hamster cells. In both cases, close proximity to a heterochromatic region was required for gene silencing. Yeast exposed to Ni exhibited reduced acetylation of the lysine residues in the N-terminal tail of histone H4. Ni-induced silencing of the gpt gene in mammalian cells involved hypermethylation of promoter region DNA. Yeast do not employ DNA methylation to silence gene expression. To determine if histone deacetylation participates in Ni-induced silencing of the URA3 and gpt genes, we exposed yeast and G12 hamster cells to the histone deacetylase inhibitor trichostatin A (TSA) prior to and concurrently with Ni. Treatment of yeast cells with 0.2-0.6mM NiCl(2) resulted in reduced expression of the URA3 gene as assessed by increased resistance to 1g/l 5-fluorotic acid (5-FOA). This effect was lessened when yeast were pre-treated with 50 microg TSA/ml. Similarly, treatment of G12 cells with 5 ng/ml TSA during and after exposure to 0.3 microg Ni(3)S(2)/cm(2) reduced silencing of the gpt gene as gauged by resistance to 10 microg/ml 6-thioguanine (6-TG). The ability of TSA alone and in combination with the DNA-demethylating agent (5-AzaC) to reactivate the gpt gene in Ni-silenced variants was also assessed. Although treatment with 100 ng/ml TSA for 48 h was partially effective in reactivating the gpt gene, treatment with 5 microM 5-AzaC was more efficacious. The greatest gpt gene reversion frequencies were observed following a sequential 5-AzaC/TSA treatment. Taken all together, our data from mammalian cells suggests that both DNA methylation and histone deacetylation participate in Ni-induced silencing of the gpt gene with DNA hypermethylation playing the more dominant role in maintaining the silenced state.     

酿酒酵母TRK1和TRK2钾吸收缺陷型菌株的构建

为更好的进行钾素营养有关基因表达调控和功能性研究, 我们采用同源重组法通过重叠引物扩增分别将URA3和HIS3基因替代酿酒酵母的TRK1和TRK2基因, 并以酿酒酵母的尿嘧啶合成酶URA3基因和组氨酸合成酶HIS3为标记基因, 在不含尿嘧啶和组氨酸的基本培养基筛选转化子获得了钾离子转运蛋白TRK1和TRK2基因缺失的酿酒酵母钾素营养缺陷型菌株, 该菌株在低K+培养基中导入拟南芥K+转运体基因AtKuP1可恢复正常生长。     

酿酒酵母TRK1和TRK2钾吸收缺陷型菌株的构建

为更好的进行钾素营养有关基因表达调控和功能性研究,我们采用同源重组法通过重叠引物扩增分别将URA3和HIS3基因替代酿酒酵母的TRK1和TRK2基因,并以酿酒酵母的尿嘧啶合成酶URA3基因和组氨酸合成酶HIS3力标记基因,在不舍尿嘧啶和组氨酸的基本培养基筛选转化子获得了钾离子转运蛋白TRK1和TRK2基因缺失的酿酒酵母钾素营养缺陷型菌株,该菌株在低K 培养基中导入拟南芥K 转运体基因AtKuP1可恢复正常生长.     

Intrachromosomal movement of genetically marked Saccharomyces cerevisiae transposons by gene conversion.

In this paper, we describe the movement of a genetically marked Saccharomyces cerevisiae transposon. Ty912(URA3), to new sites in the S. cerevisiae genome. Ty912 is an element present at the HIS4 locus in the his4-912 mutant. To detect movement of Ty912, this element has been genetically marked with the S. cerevisiae URA3 gene. Movement of Ty912(URA3) occurs by recombination between the marked element and homologous Ty elements elsewhere in the S. cerevisiae genome. Ty912(URA3) recombines most often with elements near the HIS4 locus on chromosome III, less often with Ty elements elsewhere on chromosome III, and least often with Ty elements on other chromosomes. These recombination events result in changes in the number of Ty elements present in the cell and in duplications and deletions of unique sequence DNA.