Project description:The regulation of flocculation, surface adhesion and invasive growth in the fission yeast Schizosaccharomyces pombe has focused primarily at the transcriptional level, but little is known with regards to posttranscriptional control. Here, we identified the Pumilio protein Pfr1 as a novel posttranscriptional regulator of these processes. Deletion of pfr1+ prevented flocculation, surface adhesion and invasive growth under inducing conditions, while overexpression of pfr1+ was sufficient to trigger flocculation. The flocculent phenotype of pfr1+ overexpression was dependent on the presence of the Gsf2 flocculin, but not on the Mbx2, Cbf12 and Adn3 transcription factors. In addition, we used RNA immunoprecipitation and expression microarrays to identify pvg1+ and SPBPB7E8.01, which encode a galactose pyruvyltransferase and glycophosphatidylinositol membrane protein, respectively, as putative mRNA targets potentially degraded by Pfr1. The mRNAs of these genes were upregulated and downregulated in the pfr1 deletion and overexpression strains, respectively, and contained putative binding sites in the 3’-untranslated region. We also discovered that ccr4+ and ste13+, which encode components of the mRNA decay machinery, were required for these processes, but did not suppress the pfr1+ overexpression flocculent phenotype when deleted. This data suggest that these processes in S. pombe involve multiple posttranscriptional-regulatory pathways of which one requires Pfr1.

Project description:In the fission yeast Schizosaccharomyces pombe, the transcriptional-regulatory network that governs flocculation remains poorly understood. Here, we systematically screened an array of transcription factor deletion and overexpression strains for flocculation and performed microarray expression profiling and ChIP-chip analysis to identify the flocculin target genes. We identified five transcription factors that displayed novel roles in the activation or inhibition of flocculation (Rfl1, Adn2, Adn3, Sre2, and Yox1), in addition to the previously-known Mbx2, Cbf11 and Cbf12 regulators. Overexpression of mbx2+ and deletion of rfl1+ resulted in strong flocculation and transcriptional upregulation of gsf2+/pfl1+ and several other putative flocculin genes (pfl2+-pfl9+). Overexpression of the pfl+ genes singly was sufficient to trigger flocculation, and enhanced flocculation was observed in several combinations of double pfl+ overexpression. Among the pfl1+ genes, only loss of gsf2+ abrogated the flocculent phenotype of all the transcription factor mutants and prevented flocculation when cells were grown in inducing medium containing glycerol and ethanol as the carbon source, thereby indicating that Gsf2 is the dominant flocculin. In contrast, the mild flocculation of adn2+ or adn3+ overexpression was likely mediated by the transcriptional activation of cell wall-remodeling genes including gas2+, psu1+, and SPAC4H3.03c. We also discovered that Rfl1, Mbx2, and Cbf12 displayed transcriptional autoregulation, and Rfl1 repressed gsf2+ expression in an inhibitory feed-forward loop involving mbx2+. These results reveal that flocculation in S. pombe is regulated by a complex network of multiple transcription factors and target genes encoding flocculins and cell wall-remodeling enzymes. Moreover, comparisons between the flocculation transcriptional regulatory networks of Saccharomyces cerevisiae and S. pombe indicate substantial rewiring of transcription factors and cis-regulatory sequences. We generated 2 overexpression microarrays and 1 deletion microarray with dye swaps, 2 overexpression single replicate microarray experiments, 3 deletion single replicate microarray experiments, and 3 single replicate ChIP-chip experiments. The effect of the mutant strains were all compared to wild type or empty vector strains.

Project description:Gene regulation in response to intracellular calcium is mediated by the calcineurin-activated transcription factor Prz1 in the fission yeast Schizosaccharomyces pombe. Genome-wide studies of the Crz1 and CrzA fungal orthologs have uncovered numerous target genes involved in conserved and species-specific cellular processes. In contrast, very few target genes of Prz1 have been published. This paper identified an extensive list of genes using transcriptome and ChIP-chip analyses under inducing conditions of Prz1, including CaCl2, and tunicamycin treatment, as well as a ∆pmr1 genetic background. We identified 165 upregulated putative target genes of Prz1 in which the majority contained a calcium-dependent response element in their promoters, similar to that of the Saccharomyces cerevisiae ortholog Crz1. These genes were functionally enriched for Crz1-conserved processes such as cell wall biosynthesis. Overexpression of prz1+ increased resistance to the cell wall degradation enzyme zymolyase, likely from upregulation of the O-mannosyltransferase encoding gene omh1+. Loss of omh1+ abrogates this phenotype. We uncovered a novel inhibitory role in flocculation for Prz1. Loss of prz1+ resulted in constitutive flocculation and upregulation of genes encoding the flocculins Gsf2 and Pfl3, as well as the transcription factor Cbf12. The constitutive flocculation of the ∆prz1 strain was abrogated by the loss of gsf2+ or cbf12+. This study reveals that Prz1 functions as a positive and negative transcriptional regulator of genes involved in cell wall biosynthesis and flocculation, respectively. Moreover, comparison of target genes between Crz1/CrzA and Prz1 indicate some conservation in DNA-binding specificity, but also substantial rewiring of the calcineurin-mediated transcriptional-regulatory network. We generated 3 overexpression microarrays and 2 deletion microarrays with dye swaps, and 2 deletion microarrays with drug treatments with dye swaps, each with a biological replicate performed as a dye swap. The effect of the mutant strains were all compared to wild type or empty vector strains, except for one experiment where the prz1 deletion mutant was compared to the pmr1 deletion mutant.

Project description:In the fission yeast Schizosaccharomyces pombe, the transcriptional-regulatory network that governs flocculation remains poorly understood. Here, we systematically screened an array of transcription factor deletion and overexpression strains for flocculation and performed microarray expression profiling and ChIP-chip analysis to identify the flocculin target genes. We identified five transcription factors that displayed novel roles in the activation or inhibition of flocculation (Rfl1, Adn2, Adn3, Sre2, and Yox1), in addition to the previously-known Mbx2, Cbf11 and Cbf12 regulators. Overexpression of mbx2+ and deletion of rfl1+ resulted in strong flocculation and transcriptional upregulation of gsf2+/pfl1+ and several other putative flocculin genes (pfl2+-pfl9+). Overexpression of the pfl+ genes singly was sufficient to trigger flocculation, and enhanced flocculation was observed in several combinations of double pfl+ overexpression. Among the pfl1+ genes, only loss of gsf2+ abrogated the flocculent phenotype of all the transcription factor mutants and prevented flocculation when cells were grown in inducing medium containing glycerol and ethanol as the carbon source, thereby indicating that Gsf2 is the dominant flocculin. In contrast, the mild flocculation of adn2+ or adn3+ overexpression was likely mediated by the transcriptional activation of cell wall-remodeling genes including gas2+, psu1+, and SPAC4H3.03c. We also discovered that Rfl1, Mbx2, and Cbf12 displayed transcriptional autoregulation, and Rfl1 repressed gsf2+ expression in an inhibitory feed-forward loop involving mbx2+. These results reveal that flocculation in S. pombe is regulated by a complex network of multiple transcription factors and target genes encoding flocculins and cell wall-remodeling enzymes. Moreover, comparisons between the flocculation transcriptional regulatory networks of Saccharomyces cerevisiae and S. pombe indicate substantial rewiring of transcription factors and cis-regulatory sequences.

Project description:In Schizosaccharomyces pombe, over 90% of transcription factor genes are nonessential. Moreover, the majority do not exhibit significant growth defects under optimal conditions when deleted, complicating their functional characterization and target gene identification. Here, we systematically overexpressed 99 transcription factor genes with the nmt1 promoter. Screening the overexpression array revealed that 64 transcription factor genes exhibited reduced fitness when ectopically expressed. Cell cycle defects were also often observed. We further investigated three uncharacterized transcription factor genes (toe1+-toe3+) which displayed cell elongation when overexpressed. Ectopic expression of toe1+ resulted in a G1 delay while toe2+ and toe3+ overexpression produced an accumulation of septated cells with abnormalities in septum formation and nuclear segregation, respectively. Transcriptome profiling and ChIP-chip analysis of the transcription factor overexpression strains indicated that Toe1 activates target genes of the pyrimidine-salvage pathway, while Toe3 regulates target genes involved in polyamine synthesis. We also found that ectopic expression of the putative target genes SPBC3H7.05c, and dad5+ and SPAC11D3.06 could recapitulate the cell cycle phenotypes of toe2+ and toe3+ overexpression, respectively. Furthermore, the phenotypes of toe1+and toe2+ overexpression could be suppressed by deletion of the putative target genes urg2+ and SPAC1399.04c, and SPBC3H7.05c, SPACUNK4.15 and rds1+, respectively. This study implicates new transcription factors and metabolism genes in cell cycle regulation and demonstrates the potential of systematic overexpression analysis to elucidate the function and target genes of transcription factors in S. pombe. We generated 3 overexpression microarrays and 2 deletion microarray with dye swaps, 3 deletion microarrays with drug treatments with dye swaps, 1 deletion single replicate microarray experiment, and 3 single replicate chIP-chip experiments. The effect of the mutant strains were all compared to wild type or empyty vector strains except for two experiments one that looked at the toe1 mutant with and without chlorpromazine and another that looked at wild type with and without chlorpromazine.

Project description:In oenological conditions, yeasts are exposed to several stresses and Saccharomyces cerevisiae strains respond modifying their transcriptional program. Yeast flocculation is a social trait that permits to the cells to escape to hostile conditions by sedimentation. This behaviour is mainly due to the presence in the genome of FLO greenbeards genes. In order to understand the role of flocculation in stress response a flocculent S. cerevisiae wine strain and his FLO5 deleted strain were submitted to standard and second fermentation. At the middle of these two processes a genome wide expression analysis was performed. Results showed that while the FLO5 deleted strain was engaged to a re-organization of cell wall and to find a different way to adhere, flocculent yeast presented a proteic stress response and an up-regulation of genes involved in superior alcohols production. Obtained data confirmed the importance of FLO5 in flocculation phenotype and highlight the role of flocculation in stress response.

Project description:Changes in gene expression are hallmarks of cellular differentiation. Sexual differentiation in fission yeast (Schizosaccharomyces pombe) provides a model system for gene expression programs accompanying and driving cellular specialization. The expression of hundreds of genes is modulated in successive waves during meiosis and sporulation in S. pombe, and several known transcription factors are critical for these processes. We used DNA microarrays to investigate meiotic gene regulation by examining transcriptomes after genetic perturbations (gene deletion and/or overexpression) of rep1, mei4, atf21 and atf31, which encode known transcription factors controlling sexual differentiation. This analysis reveals target genes at a genome-wide scale and uncovers combinatorial control by Atf21p and Atf31p. We also studied two transcription factors that are upregulated during meiosis but had not been previously implicated in sexual differentiation : Rsv2p induces stress-related genes during spore formation, while Rsv1p acts as a repressor for glucose-metabolism genes. Our data further reveal negative feedback interactions: both Rep1p and Mei4p not only activate specific gene expression waves (early and middle genes, respectively), but are also required for repression of genes induced in the previous waves (Ste11p-dependent and early genes, respectively).

Project description:Changes in gene expression are hallmarks of cellular differentiation. Sexual differentiation in fission yeast (Schizosaccharomyces pombe) provides a model system for gene expression programs accompanying and driving cellular specialization. The expression of hundreds of genes is modulated in successive waves during meiosis and sporulation in S. pombe, and several known transcription factors are critical for these processes. We used DNA microarrays to investigate meiotic gene regulation by examining transcriptomes after genetic perturbations (gene deletion and/or overexpression) of rep1, mei4, atf21 and atf31, which encode known transcription factors controlling sexual differentiation. This analysis reveals target genes at a genome-wide scale and uncovers combinatorial control by Atf21p and Atf31p. We also studied two transcription factors that are upregulated during meiosis but had not been previously implicated in sexual differentiation : Rsv2p induces stress-related genes during spore formation, while Rsv1p acts as a repressor for glucose-metabolism genes. Our data further reveal negative feedback interactions: both Rep1p and Mei4p not only activate specific gene expression waves (early and middle genes, respectively), but are also required for repression of genes induced in the previous waves (Ste11p-dependent and early genes, respectively).

Project description:Changes in gene expression are hallmarks of cellular differentiation. Sexual differentiation in fission yeast (Schizosaccharomyces pombe) provides a model system for gene expression programs accompanying and driving cellular specialization. The expression of hundreds of genes is modulated in successive waves during meiosis and sporulation in S. pombe, and several known transcription factors are critical for these processes. We used DNA microarrays to investigate meiotic gene regulation by examining transcriptomes after genetic perturbations (gene deletion and/or overexpression) of rep1, mei4, atf21 and atf31, which encode known transcription factors controlling sexual differentiation. This analysis reveals target genes at a genome-wide scale and uncovers combinatorial control by Atf21p and Atf31p. We also studied two transcription factors that are upregulated during meiosis but had not been previously implicated in sexual differentiation : Rsv2p induces stress-related genes during spore formation, while Rsv1p acts as a repressor for glucose-metabolism genes. Our data further reveal negative feedback interactions: both Rep1p and Mei4p not only activate specific gene expression waves (early and middle genes, respectively), but are also required for repression of genes induced in the previous waves (Ste11p-dependent and early genes, respectively).

Project description:Posttranscriptional Control of Flocculation, Surface Adhesion and Invasive Growth by the Pumilio gene pfr1+ in Schizosaccharomyces pombe