Genome-wide analysis of mRNA lengths in Saccharomyces cerevisiae

Background  

Although the protein-coding sequences in the Saccharomyces cerevisiae genome have been studied and annotated extensively, much less is known about the extent and characteristics of the untranslated regions of yeast mRNAs.     

Genome-wide analysis of sterol-lipid storage and trafficking in Saccharomyces cerevisiae

The pandemic of lipid-related disease necessitates a determination of how cholesterol and other lipids are transported and stored within cells. The first step in this determination is the identification of the genes involved in these transport and storage processes. Using genome-wide screens, we identified 56 yeast (Saccharomyces cerevisiae) genes involved in sterol-lipid biosynthesis, intracellular trafficking, and/or neutral-lipid storage. Direct biochemical and cytological examination of mutant cells revealed an unanticipated link between secretory protein glycosylation and triacylglycerol (TAG)/steryl ester (SE) synthesis for the storage of lipids. Together with the analysis of other deletion mutants, these results suggested at least two distinct events for the biogenesis of lipid storage particles: a step affecting neutral-lipid synthesis, generating the lipid core of storage particles, and another step for particle assembly. In addition to the lipid storage mutants, we identified mutations that affect the localization of unesterified sterols, which are normally concentrated in the plasma membrane. These findings implicated phospholipase C and the protein phosphatase Ptc1p in the regulation of sterol distribution within cells. This study identified novel sterol-related genes that define several distinct processes maintaining sterol homeostasis.     

Genome-wide analysis reveals the vacuolar pH-stat of Saccharomyces cerevisiae

Protons, the smallest and most ubiquitous of ions, are central to physiological processes. Transmembrane proton gradients drive ATP synthesis, metabolite transport, receptor recycling and vesicle trafficking, while compartmental pH controls enzyme function. Despite this fundamental importance, the mechanisms underlying pH homeostasis are not entirely accounted for in any organelle or organism. We undertook a genome-wide survey of vacuole pH (pH(v)) in 4,606 single-gene deletion mutants of Saccharomyces cerevisiae under control, acid and alkali stress conditions to reveal the vacuolar pH-stat. Median pH(v) (5.27±0.13) was resistant to acid stress (5.28±0.14) but shifted significantly in response to alkali stress (5.83±0.13). Of 107 mutants that displayed aberrant pH(v) under more than one external pH condition, functional categories of transporters, membrane biogenesis and trafficking machinery were significantly enriched. Phospholipid flippases, encoded by the family of P4-type ATPases, emerged as pH regulators, as did the yeast ortholog of Niemann Pick Type C protein, implicated in sterol trafficking. An independent genetic screen revealed that correction of pH(v) dysregulation in a neo1(ts) mutant restored viability whereas cholesterol accumulation in human NPC1(-/-) fibroblasts diminished upon treatment with a proton ionophore. Furthermore, while it is established that lumenal pH affects trafficking, this study revealed a reciprocal link with many mutants defective in anterograde pathways being hyperacidic and retrograde pathway mutants with alkaline vacuoles. In these and other examples, pH perturbations emerge as a hitherto unrecognized phenotype that may contribute to the cellular basis of disease and offer potential therapeutic intervention through pH modulation.     

Genome-wide analysis of barcoded Saccharomyces cerevisiae gene-deletion mutants in pooled cultures

The availability of a near-complete (96%) collection of gene-deletion mutants in Saccharomyces cerevisiae greatly facilitates the systematic analyses of gene function in yeast. The unique 20 bp DNA 'barcodes' or 'tags' in each deletion strain enable the individual fitness of thousands of deletion mutants to be resolved from a single pooled culture. Here, we present protocols for the study of pooled cultures of tagged yeast deletion mutants with a tag microarray. This process involves five main steps: pooled growth, isolation of genomic DNA, PCR amplification of the barcodes, array hybridization and data analysis. Pooled deletion screening can be used to study gene function, uncover a compound's mode of action and identify drug targets. In addition to these applications, the general method of studying pooled samples with barcode arrays can also be adapted for use with other types of samples, such as mutant collections in other organisms, short interfering RNA vectors and molecular inversion probes.     

Genome-wide analysis of nucleotide-level variation in commonly used Saccharomyces cerevisiae strains

Ten years have passed since the genome of Saccharomyces cerevisiae-more precisely, the S288c strain-was completely sequenced. However, experimental work in yeast is commonly performed using strains that are of unknown genetic relationship to S288c. Here, we characterized the nucleotide-level similarity between S288c and seven commonly used lab strains (A364A, W303, FL100, CEN.PK, summation 1278b, SK1 and BY4716) using 25mer oligonucleotide microarrays that provide complete and redundant coverage of the approximately 12 Mb Saccharomyces cerevisiae genome. Using these data, we assessed the frequency and distribution of nucleotide variation in comparison to the sequenced reference genome. These data allow us to infer the relationships between experimentally important strains of yeast and provide insight for experimental designs that are sensitive to sequence variation. We propose a rational approach for near complete sequencing of strains related to the reference using these data and directed re-sequencing. These data and new visualization tools are accessible online in a new resource: the Yeast SNPs Browser (YSB; http://gbrowse.princeton.edu/cgi-bin/gbrowse/yeast_strains_snps) that is available to all researchers.     

Distribution of introns in frameshift-suppressor proline-tRNA genes of Saccharomyces cerevisiae

Mutations in the suf9, suf10, and suf11 genes of yeast suppress + 1 nucleotide (nt) insertions in proline codons. Nucleotide sequence analysis indicates that the suf9 and suf11 genes are members of the proline tRNA(UGG) gene family, which also includes three other previously identified genes, suf7, suf8, and trn1. All five members of this gene family contain introns. The suf9 and suf11 introns are 31 and 30 nt in length, respectively, and are similar but not identical in sequence to other introns within the family. The suf10 gene is identical in sequence to suf2, which was shown previously to encode proline tRNA(IGG). Both members of this gene family lack introns. Alleles of suf9, suf10, and suf11 that confer frameshift suppression were also analyzed. The SUF9-1 allele results in a G----U substitution at nt position 39 in the anticodon stem. The recessive suf11-1 allele is a double mutant containing the same nt position 39 alteration as in SUF9-1 plus a second U----A substitution at nt position 38 in the anticodon loop. The SUF10-1 suppressor mutation corresponds to a +1G insertion in the anticodon loop. Since the nt substitutions in suf11-1 alter the sequence of the 3' exon/intron boundary, the double mutant pre-tRNA was tested for its ability to be cleaved in vitro by tRNA-splicing endonuclease. It was found that suf11-1 pre-tRNA is cleaved with reduced efficiency at the 3' splice junction.     

Genome-wide redistribution of meiotic double-strand breaks in Saccharomyces cerevisiae

Meiotic recombination is initiated by the formation of programmed DNA double-strand breaks (DSBs) catalyzed by the Spo11 protein. DSBs are not randomly distributed along chromosomes. To better understand factors that control the distribution of DSBs in budding yeast, we have examined the genome-wide binding and cleavage properties of the Gal4 DNA binding domain (Gal4BD)-Spo11 fusion protein. We found that Gal4BD-Spo11 cleaves only a subset of its binding sites, indicating that the association of Spo11 with chromatin is not sufficient for DSB formation. In centromere-associated regions, the centromere itself prevents DSB cleavage by tethered Gal4BD-Spo11 since its displacement restores targeted DSB formation. In addition, we observed that new DSBs introduced by Gal4BD-Spo11 inhibit surrounding DSB formation over long distances (up to 60 kb), keeping constant the number of DSBs per chromosomal region. Together, these results demonstrate that the targeting of Spo11 to new chromosomal locations leads to both local stimulation and genome-wide redistribution of recombination initiation and that some chromosomal regions are inherently cold regardless of the presence of Spo11.     

Genome-wide screen for oxalate-sensitive mutants of Saccharomyces cerevisiae

Oxalic acid is an important virulence factor produced by phytopathogenic filamentous fungi. In order to discover yeast genes whose orthologs in the pathogen may confer self-tolerance and whose plant orthologs may protect the host, a Saccharomyces cerevisiae deletion library consisting of 4,827 haploid mutants harboring deletions in nonessential genes was screened for growth inhibition and survival in a rich medium containing 30 mM oxalic acid at pH 3. A total of 31 mutants were identified that had significantly lower cell yields in oxalate medium than in an oxalate-free medium. About 35% of these mutants had not previously been detected in published screens for sensitivity to sorbic or citric acid. Mutants impaired in endosomal transport, the rgp1Delta, ric1Delta, snf7Delta, vps16Delta, vps20Delta, and vps51Delta mutants, were significantly overrepresented relative to their frequency among all verified yeast open reading frames. Oxalate exposure to a subset of five mutants, the drs2Delta, vps16Delta, vps51Delta, ric1Delta, and rib4Delta mutants, was lethal. With the exception of the rib4Delta mutant, all of these mutants are impaired in vesicle-mediated transport. Indirect evidence is provided suggesting that the sensitivity of the rib4Delta mutant, a riboflavin auxotroph, is due to oxalate-mediated interference with riboflavin uptake by the putative monocarboxylate transporter Mch5.     

Alternative splicing and bioinformatic analysis of human U12-type introns

U12-type introns exist, albeit rarely, in a variety of multicellular organisms. Splicing of U12 intron-containing precursor mRNAs takes place in the U12-type spliceosome that is distinct from the major U2-type spliceosome. Due to incompatibility of these two spliceosomes, alternative splicing involving a U12-type intron may give rise to a relatively complicated impact on gene expression. We studied alternative U12-type intron splicing in an attempt to gain more mechanistic insights. First, we characterized mutually exclusive exon selection of the human JNK2 gene, which involves an unusual intron possessing the U12-type 5′ splice site and the U2-type 3′ splice site. We demonstrated that the long and evolutionary conserved polypyrimidine tract of this hybrid intron provides important signals for inclusion of its downstream alternative exon. In addition, we examined the effects of single nucleotide polymorphisms in the human WDFY1 U12-type intron on pre-mRNA splicing. These results provide mechanistic implications on splice-site selection of U12-type intron splicing. We finally discuss the potential effects of splicing of a U12-type intron with genetic defects or within a set of genes encoding RNA processing factors on global gene expression.     

番茄PPR基因家族的鉴定与生物信息学分析

PPR(Pentatricopeptide repeats)基因家族在植物中广泛存在, 其在植物生长发育过程中至关重要。文章采用生物信息学方法, 利用Pfam已鉴定的PPR保守结构域序列检索番茄(Solanum lycopersicum L.)基因组计划注释的蛋白序列, 最终确定了番茄中可能存在的471个PPR编码基因; 根据拟南芥(Arabidopsis thaliana L.)中鉴定的各个结构域的特点对其进行了蛋白结构分析、分类和保守序列分析, 并对番茄PPR基因家族进行了系统进化树构建、染色体定位、亚细胞定位预测、表达和GO分析等。结果表明：番茄PPR基因家族分为P和PLS两个亚家族, 各占序列数目的一半, PLS亚家族又分为PLS、E、E+和DYW四类, 且在进化树中形成不同的分支; 各个结构域在植物中非常保守; PPR基因家族分布在番茄12条染色体上, 且多数无内含子结构; 大部分PPR蛋白具有线粒体或叶绿体定位序列, GO分析表明PPR蛋白参与RNA相关的生物学过程