Isolation of a gene from Drosophila by complementation in yeast

Transformation of mutant yeast cells by cloned genomic DNA from a higher eukaryote has made it possible to isolate a Drosophila DNA sequence that complements a yeast adenine-8-mutation. A 0.8-kilobase poly(A)-containing RNA is transcribed from the cloned Drosophila segment in transformed yeast cells and can account for functional expression of the gene.     

Expression of a bacterial modification methylase gene in yeast

Methylation of specific cytosines in the DNA is generally believed to play some role in the regulation of gene expression in eukaryotes. However, some eukaryotes, such as Drosophila and yeast (S. Hattman, personal communication) seem not to contain 5-methylcytosine in their DNA. It would be interesting to test, how gene expression in such organisms would respond to the methylation of specific cytosines in the genome. As a first step towards this goal, we have introduced the gene encoding the Bacillus sphaericus R modification methylase, which methylates the internal cytosine within the recognition sequence 5'-GGCC, into yeast cells. Southern-type hybridization to DNAs isolated from the transformed yeast clones revealed that the yeast plasmid carrying the prokaryotic methylase gene, as well as the two chromosomal genes tested (his3 and leu2) were methylated, whereas the bulk of the yeast DNA remained largely unmethylated. This indicates that the Bacillus sphaericus modification methylase was expressed in yeast but it modified only certain parts of the yeast DNA.     

胚胎性横纹肌肉瘤中下调表达基因HumCyr61的分？…

分离和克隆胚胎性横纹肌肉瘤中下调表达基因ＨｕｍＣｙｒ６１。方法：利用计算机辅助的同源扩增策略，成功克隆一个长１８８７ｂｐ ｃＤＮＡ，并与ＧｅｎＢａｎｋ核酸数据库比较。结果：该基因与鼠生长因子诱导早期表达的Ｃｙｒ６１基因同源度为８２％，在蛋白质水平上的同源度高达９２％，其中对高级结构有重大贡献的半胱氨酸和脯氨酸等氨基酸残基高度保守。查新结果还显示，它包括在胚胎性横纹肌肉瘤细胞系ＲＤ中表达呈下调表达的     

Gadd45a promotes epigenetic gene activation by repair-mediated DNA demethylation

DNA methylation is an epigenetic modification that is essential for gene silencing and genome stability in many organisms. Although methyltransferases that promote DNA methylation are well characterized, the molecular mechanism underlying active DNA demethylation is poorly understood and controversial. Here we show that Gadd45a (growth arrest and DNA-damage-inducible protein 45 alpha), a nuclear protein involved in maintenance of genomic stability, DNA repair and suppression of cell growth, has a key role in active DNA demethylation. Gadd45a overexpression activates methylation-silenced reporter plasmids and promotes global DNA demethylation. Gadd45a knockdown silences gene expression and leads to DNA hypermethylation. During active demethylation of oct4 in Xenopus laevis oocytes, Gadd45a is specifically recruited to the site of demethylation. Active demethylation occurs by DNA repair and Gadd45a interacts with and requires the DNA repair endonuclease XPG. We conclude that Gadd45a relieves epigenetic gene silencing by promoting DNA repair, which erases methylation marks.     

盐胁迫下拟南芥去乙酰化酶调控下游基因表达的转录组分析

胁迫是指植物持续地暴露在环境的刺激下,有能力建立保护和适应的机制。组蛋白的去乙酰化作为一种表观遗传现象,在植物适应环境中发挥了重要的作用。为了探究高盐胁迫下,组蛋白的去乙酰化酶在植物抵御和适应高盐胁迫中的作用,本研究以拟南芥野生型WT和四突（h2tq,HD2四个基因的突变体）为材料,采用RNA-seq技术和生物信息学方法,对生长10d的幼苗在高盐（150 mM NaCl）处理前和后进行比较转录组分析,并结合实时荧光定量PCR验证转录组数据的可靠性。结果显示：在高盐处理前WT和hd2q共有25个差异基因,其中上调基因2个,下调基因23个。在高盐处理后,WT和hd2q共有1407个差异基因,其中上调基因772个,下调基因635个。GO和KEGG分析显示,对照的差异基因主要富集在胞外区域和响应脱落酸上,盐处理的差异基因主要富集在胞外区域和细胞壁上。植物响应盐胁迫是一个涉及不同交叉途径的复杂过程,这些结果可为研究表观遗传在盐胁迫逆境下的刺激响应提供一定参考意义。     

The yeast DNA repair gene RAD6 encodes a ubiquitin-conjugating enzyme

The RAD6 gene of the yeast Saccharomyces cerevisiae is required for a variety of cellular functions including DNA repair. The discovery that the RAD6 gene product can catalyse the covalent attachment of ubiquitin to other proteins suggests that the multiple functions of the RAD6 protein are mediated by its ubiquitin-conjugating activity.     

Large-scale analysis of the yeast genome by transposon tagging and gene disruption

Economical methods by which gene function may be analysed on a genomic scale are relatively scarce. To fill this need, we have developed a transposon-tagging strategy for the genome-wide analysis of disruption phenotypes, gene expression and protein localization, and have applied this method to the large-scale analysis of gene function in the budding yeast Saccharomyces cerevisiae. Here we present the largest collection of defined yeast mutants ever generated within a single genetic background--a collection of over 11,000 strains, each carrying a transposon inserted within a region of the genome expressed during vegetative growth and/or sporulation. These insertions affect nearly 2,000 annotated genes, representing about one-third of the 6,200 predicted genes in the yeast genome. We have used this collection to determine disruption phenotypes for nearly 8,000 strains using 20 different growth conditions; the resulting data sets were clustered to identify groups of functionally related genes. We have also identified over 300 previously non-annotated open reading frames and analysed by indirect immunofluorescence over 1,300 transposon-tagged proteins. In total, our study encompasses over 260,000 data points, constituting the largest functional analysis of the yeast genome ever undertaken.     

A dynamin-like protein encoded by the yeast sporulation gene SPO15.

The tightly centromere-linked gene SPO15 is essential for meiotic cell division in the yeast Saccharomyces cerevisiae. Diploid cells without the intact SPO15 gene product are able to complete premeiotic DNA synthesis and genetic recombination, but are unable to traverse the division cycles. Electron microscopy of blocked cells reveals a duplicated but unseparated spindle-pole body. Thus cells are unable to form a bipolar spindle. Sequence analysis of SPO15 DNA reveals an open reading frame that predicts a protein of 704 amino acids. This protein is identical to VPS1, a gene involved in vacuolar protein sorting in yeast which has significant sequence homology (45% overall, 66% over 300 amino acids) to the microtubule bundling-protein, dynamin. The SPO15 gene product expressed in Escherichia coli can be affinity-purified with microtubules. SPO15 encodes a protein that is likely to be involved in a microtubule-dependent process required for the timely separation of spindle-pole bodies in meiosis.     

Isolation and characterization of the gene for a yeast mitochondrial import receptor

We have previously identified an integral membrane protein (p32) from Saccharomyces cerevisiae as a receptor for protein import into mitochondria, and have localized it to the mitochondrial outer membrane at contact sites. Here we report isolation of the corresponding mitochondrial import receptor gene, termed MIR1. The deduced amino-acid sequence of p32 shows roughly 40% identity with proteins of bovine heart and rat liver that have been suggested to be mitochondrial phosphate carriers. Haploid cells carrying a disrupted MIR1 allele were unable to grow on a non-fermentable carbon source but grew in media containing glucose, indicating that the MIR1 protein is essential for mitochondrial function. Compared with wild type, amounts of some mitochondrial proteins were markedly reduced in cells containing a disrupted MIR1 allele, whereas levels of others were unchanged. This indicates that yeast contains more than one pathway for protein import into mitochondria.     

The yeast ubiquitin gene: head-to-tail repeats encoding a polyubiquitin precursor protein

Ubiquitin, a 76-residue protein, occurs in cells either free or covalently joined to a variety of protein species, from chromosomal histones to cytoplasmic proteins. Conjugation of ubiquitin to proteolytic substrates is essential for the selective degradation of intracellular proteins in higher eukaryotes. We show here that a protein homologous to human ubiquitin exists in the yeast Saccharomyces cerevisiae, and that yeast extracts conjugate human ubiquitin to a variety of endogenous proteins in an ATP-dependent reaction. We have isolated the S. cerevisiae ubiquitin gene and found it to contain six consecutive ubiquitin-coding repeats in a found it to contain six consecutive ubiquitin-coding repeats in a head-to-tail arrangement. This apparently unique gene organization suggests that yeast ubiquitin is generated by processing of a precursor protein in which several exact repeats of the ubiquitin amino acid sequence are joined directly via Gly-Met peptide bonds between the last and first residues of mature ubiquitin, respectively. Ubiquitin-coding yeast DNA repeats are restricted to a single genomic locus; although the sequenced repeats differ in up to 27 of 228 bases per repeat, they encode identical amino acid sequences. As this predicted amino acid sequence differs in only 3 of 76 residues from that of ubiquitin in higher eukaryotes, ubiquitin is apparently the most conserved of known proteins.