Heterochronic meiotic misexpression in an interspecific yeast hybrid

Regulatory changes rapidly accumulate between species, and interspecific hybrids often misexpress genes. Hybrid misexpression, expression levels outside the range of both parental species, can result from cis- and trans-acting regulatory changes that interact abnormally in hybrids. Thus, misexpressed genes may contribute to hybrid sterility. However, in the context of a whole organism, misexpression may not result directly from cis-trans interactions but rather indirectly from differences between hybrid and parental abundance of cell types. Here we eliminate the confounding effects of cell types by examining gene expression in a sterile interspecific yeast hybrid during meiosis. We investigated gene expression of the yeasts Saccharomyces cerevisiae, S. paradoxus, and their hybrid at multiple meiotic stages. Although the hybrid and parents exhibit similar changes in expression levels across meiosis, the hybrid meiotic program occurs earlier than either parent. The timing change produces a heterochronic pattern of misexpression during midmeiosis. Coincident with the timing of misexpression, we find a transition from predominantly trans-acting to cis-acting expression divergence and an increase in the number of opposing cis-trans changes. However, we find no direct relationship between opposing cis-trans changes and misexpression. Contrary to the notion that cis-trans interactions cause misexpression, a heterochronic shift in the normal meiotic gene expression program produces patterns of misexpression in an yeast hybrid. Our results imply that temporal dynamics of single cell types is important to understanding hybrid misexpression and its relationship to cis-trans interactions.

Discovery, validation, and genetic dissection of transcription factor binding sites by comparative and functional genomics

Completing the annotation of a genome sequence requires identifying the regulatory sequences that control gene expression. To identify these sequences, we developed an algorithm that searches for short, conserved sequence motifs in the genomes of related species. The method is effective in finding motifs de novo and for refining known regulatory motifs in Saccharomyces cerevisiae. We tested one novel motif prediction of the algorithm and found it to be the binding site of Stp2; it is significantly different from the previously predicted Stp2 binding site. We show that Stp2 physically interacts with this sequence motif, and that stp2 mutations affect the expression of genes associated with the motif. We demonstrate that the Stp2 binding site also interacts genetically with Stp1, a regulator of amino acid permease genes and, with Sfp1, a key regulator of cell growth. These results illuminate an important transcriptional circuit that regulates cell growth through external nutrient uptake.

Large-scale screening of yeast mutants for sensitivity to the IMP dehydrogenase inhibitor 6-azauracil

Mutations in several genes encoding components of the RNA polymerase II elongation machinery render S. cerevisiae cells sensitive to the drug 6-azauracil (6AU), an inhibitor of IMP dehydrogenase and orotidylate decarboxylase. It is thought that a reduction in nucleotide levels following drug treatment causes transcriptional elongation to be more dependent on a fully functional RNA polymerase. To gain insight into the basis of the 6AU-sensitive phenotype and discern its specificity, we screened almost 3000 deletion mutants for growth in the presence of drug; 42 (1.5%) were reproducibly sensitive to the drug. The sensitive mutants included several missing known transcription elongation factors, but the majority were in genes involved in other cellular processes. Not all of the 6AU-sensitive strains displayed cross-sensitivity to mycophenolic acid (MPA), another drug that inhibits IMP dehydrogenase and has been employed as a screening agent for elongation mutants, showing that these two drugs are mechanistically distinct. Several of the mutants were tested for the ability to induce transcription of IMP dehydrogenase-encoding genes, in response to 6-AU and MPA treatment. As expected, mutants defective in transcriptional elongation factors were unable to fully induce IMPDH expression. However, most of the 6AU-sensitive strains had normal levels of IMPDH expression. Thus, although 6AU-sensitivity often results from defects in the elongation machinery, mutations that compromise processes other than transcription and induction of IMPDH also lead to sensitivity to this drug.

Functional profiling of the Saccharomyces cerevisiae genome

Determining the effect of gene deletion is a fundamental approach to understanding gene function. Conventional genetic screens exhibit biases, and genes contributing to a phenotype are often missed. We systematically constructed a nearly complete collection of gene-deletion mutants (96% of annotated open reading frames, or ORFs) of the yeast Saccharomyces cerevisiae. DNA sequences dubbed 'molecular bar codes' uniquely identify each strain, enabling their growth to be analysed in parallel and the fitness contribution of each gene to be quantitatively assessed by hybridization to high-density oligonucleotide arrays. We show that previously known and new genes are necessary for optimal growth under six well-studied conditions: high salt, sorbitol, galactose, pH 8, minimal medium and nystatin treatment. Less than 7% of genes that exhibit a significant increase in messenger RNA expression are also required for optimal growth in four of the tested conditions. Our results validate the yeast gene-deletion collection as a valuable resource for functional genomics.

A chemical genomics approach toward understanding the global functions of the target of rapamycin protein (TOR)

The target of rapamycin protein (TOR) is a highly conserved ataxia telangiectasia-related protein kinase essential for cell growth. Emerging evidence indicates that TOR signaling is highly complex and is involved in a variety of cellular processes. To understand its general functions, we took a chemical genomics approach to explore the genetic interaction between TOR and other yeast genes on a genomic scale. In this study, the rapamycin sensitivity of individual deletion mutants generated by the Saccharomyces Genome Deletion Project was systematically measured. Our results provide a global view of the rapamycin-sensitive functions of TOR. In contrast to conventional genetic analysis, this approach offers a simple and thorough analysis of genetic interaction on a genomic scale and measures genetic interaction at different possible levels. It can be used to study the functions of other drug targets and to identify novel protein components of a conserved core biological process such as DNA damage checkpoint/repair that is interfered with by a cell-permeable chemical compound.

Systematic analysis of S. cerevisiae chromosome VIII genes

To begin genome-wide functional analysis, we analysed the consequences of deleting each of the 265 genes of chromosome VIII of Saccharomyces cerevisiae. For 33% of the deletion strains a growth phenotype could be detected: 18% of the genes are essential for growth on complete glucose medium, and 15% grow significantly more slowly than the wild-type strain or exhibit a conditional phenotype when incubated under one of 20 different growth conditions. Two-thirds of the mutants that exhibit conditional phenotypes are pleiotropic; about one-third of the mutants exhibit only one phenotype. We also measured the level of expression directed by the promoter of each gene. About half of the promoters direct detectable transcription in rich glucose medium, and most of these exhibited only low or medium activity. Only 1% of the genes are expressed at about the same level as ACT1. The number of active promoters increased to 76% upon growth on a non-fermentable carbon source, and to 93% in minimal glucose medium. The majority of promoters fluctuated in strength, depending on the medium.

Functional characterization of the S. cerevisiae genome by gene deletion and parallel analysis

The functions of many open reading frames (ORFs) identified in genome-sequencing projects are unknown. New, whole-genome approaches are required to systematically determine their function. A total of 6925 Saccharomyces cerevisiae strains were constructed, by a high-throughput strategy, each with a precise deletion of one of 2026 ORFs (more than one-third of the ORFs in the genome). Of the deleted ORFs, 17 percent were essential for viability in rich medium. The phenotypes of more than 500 deletion strains were assayed in parallel. Of the deletion strains, 40 percent showed quantitative growth defects in either rich or minimal medium.

Genetic and physical maps of Saccharomyces cerevisiae

Genetic and physical maps for the 16 chromosomes of Saccharomyces cerevisiae are presented. The genetic map is the result of 40 years of genetic analysis. The physical map was produced from the results of an international systematic sequencing effort. The data for the maps are accessible electronically from the Saccharomyces Genome Database (SGD: http://genome-www.stanford. edu/Saccharomyces/).

The nucleotide sequence of Saccharomyces cerevisiae chromosome XII

The yeast Saccharomyces cerevisiae is the pre-eminent organism for the study of basic functions of eukaryotic cells. All of the genes of this simple eukaryotic cell have recently been revealed by an international collaborative effort to determine the complete DNA sequence of its nuclear genome. Here we describe some of the features of chromosome XII.

The sequence of a nearly unclonable 22.8 kb segment on the left arm chromosome VII from Saccharomyces cerevisiae reveals ARO2, RPL9A, TIP1, MRF1 genes and six new open reading frames

The nucleotide sequence of 22,803 bp on the left arm of chromosome VII was determined by polymerase chain reaction-based approaches to compensate for the unstable character of cosmid clones from this region of the chromosome. The coding density of the sequence is particularly high (more than 83%). Twelve open reading frames (ORFs) longer than 300 bp were found, two of which (at the left side) have been described previously (James et al., 1995) after sequencing of an overlapping cosmid. Four other ORFs correspond to published sequences of the known genes ARO2, RPL9A, TIP1 and MRF1. ARO2 codes for chorismate synthetase. RPL9A for protein L9 of the large ribosomal subunit and MRF1 for a mitochondrial translation release factor. The TIP1 product interacts with Sec20p and is thus involved in transport from endoplasmic reticulum to Golgi. Five of the remaining ORFs have not been identified previously, while the sixth (YGL142c) has been partially sequenced as it lies 5' upstream of MRF1. These six ORFs are relatively large (between 933 and 3657 nucleotides). YGL146c, YGL142c, YGL140c and YGL139w have no significant homology to any protein sequence presently available in the public databases, but show two, nine, nine and eight putative transmembrane spans, respectively. YGL144c has a serine active site signature of lipases. YGL141w has limited homology to several human proteins, one of which mediates complex formation between papillomavirus E6 oncoprotein and tumor suppressor protein p53.

Green fluorescent protein as a marker for gene expression and subcellular localization in budding yeast

The green fluorescent protein (GFP) from the jellyfish Aequorea victoria has attracted much attention as a tool to study a number of biological processes. This study describes the use of GFP as a vital reporter molecule for localization and expression studies in Saccharomyces cerevisiae. Construction of GFP expression vectors which allow N- or C-terminal fusion of the gfp gene to a gene of interest allowed the generation of fusion proteins whose subcellular localization was followed by fluorescence microscopy in living yeast cells. Analysis of three unknown open reading frames obtained from the budding yeast chromosome XIV resulted in distinct staining patterns, allowing prediction of the cellular localization of these unknown proteins. Furthermore, GFP was used to construct a gene replacement cassette which, after homologous integration into the genomic locus, placed the gfp gene behind a promoter of interest. The amount of GFP produced from this promoter was then quantified in living yeast cells by flow cytometry. With this novel replacement cassette a gene of interest can be deleted and at the same time its expression level studied under various growth conditions. The experiments presented here suggest that GFP represents a convenient fluorescent marker for localization studies as well as gene expression studies in budding yeast. Systematic studies of a large number of genes should benefit from such assays.

Mapping of DBR1 and YPK1 suggests a major revision of the genetic map of the left arm of Saccharomyces cerevisiae Chromosome XI

The Saccharomyces cerevisiae dbr1 mutation has been mapped on the left arm of chromosome XI. XIL is a chromosome arm that was until now rather sparsely populated with accurately mapped markers. On the basis of physical data, the overall order of markers is inverted relative to the existing genetic map of XI. We present tetrad analyses using a variety of markers on XI that indicate that the existing genetic map of XIL should be inverted, at least for the strains in which our mapping was carried out, and probably for other S. cerevisiae strains.

Physical maps of the six smallest chromosomes of Saccharomyces cerevisiae at a resolution of 2.6 kilobase pairs

Physical maps of the six smallest chromosomes of Saccharomyces cerevisiae are presented. In order of increasing size, they are chromosomes I, VI, III, IX, V and VIII, comprising 2.49 megabase pairs of DNA. The maps are based on the analysis of an overlapping set of lambda and cosmid clones. Overlaps between adjacent clones were recognized by shared restriction fragments produced by the combined action of EcoRI and HindIII. The average spacing between mapped cleavage sites is 2.6 kb. Five of the six chromosomes were mapped from end to end without discontinuities; a single internal gap remains in the map of chromosome IX. The reported maps span an estimated 97% of the DNA on the six chromosomes; nearly all the missing segments are telomeric. The maps are fully cross-correlated with the previously published SfiI/NotI map of the yeast genome by A. J. Link and M. V. Olson. They have also been cross-correlated with the yeast genetic map at 51 loci.

Nonsense mutations in essential genes of Saccharomyces cerevisiae

A new method for isolating nonsense mutations in essential yeast genes has been used to develop a collection of 115 ochre mutations that define 94 complementation groups. The mutants are isolated in a genetic background that includes an ochre suppressor on a metastable plasmid and a suppressible colony-color marker on a chromosome. When the parental strain is plated on a rich medium, the colonies display a pattern of red, plasmid-free sectors on a white background. Mutants containing an ochre mutation in any essential yeast gene give rise to nonsectoring, white colonies, since cell growth is dependent on the presence of the plasmid-borne suppressor. Analysis of the data suggests that mutations are being recovered from a pool of approximately 250 genes.