Project description:Evolution of robustness to protein mistranslation by accelerated protein turnover

Project description:A TATA binding protein regulatory network

Project description:The unfolded protein response supports cellular robustness as a broad-spectrum compensatory pathway.

Project description:Genetic reconstruction of a functional transcriptional regulatory network

Project description:Identification of genes involved in overproduction of ornithine in yeasts

Project description:To address the mechanisms of suppression, we analyzed time course of mRNA expression of four suppressed smc2-8 mutant strains. We addressed the question of genomic robustness by systematically screening genomic open reading frames, when induced for high-level expression, for their ability to suppress 55 conditional lethal mutations in yeast, and have discovered 636 suppressor genes participating in 822 novel dosage suppressor interactions.  The suppressor genes are functionally broad and are enriched for overlapping open reading frames where mutually overlapping genes tend to be co-suppressors.  Studies on suppressors of defects in chromosome condensation, telomere stability, and RNA polymerase II function suggest that adding interactions, by making significant connections where only weak or undetectable interactions were present (rewiring of gene regulatory pathways, and interaction within and between protein complexes) are frequent mechanisms of dosage suppression.

Project description:A network governing DNA integrity was identified in yeast by a global genetic analysis of synthetic fitness or lethality defect (SFL) interactions. Within this network, multiple functional modules or mini-pathways were defined according to their common patterns of global SFL interactions and available protein-protein interaction information. Modules or genes involved in DNA replication, DNA replication checkpoint signaling, and oxidative stress response were identified as the major guardians against lethal spontaneous DNA damage, efficient repair of which requires the functions of the DNA damage checkpoint signaling and multiple DNA repair pathways. This genome-wide genetic interaction network also revealed potential roles of a number of genes and modules in mitotic DNA replication and maintenance of genomic stability. These include DIA2, NPT1, HST3, HST4, and the CSM1/LRS4 module (CSM1m). Likewise, the CTF18 module (CTF18m), previously implicated in sister chromatid cohesion, was found to participate in the DNA replication checkpoint. Keywords: dose response

Project description:In response to carbon source switching from glucose to non-glucose, such as ethanol and galactose, yeast cells can directionally preprogram cellular metabolism to efficiently utilize the nutrients. However, the understanding of cellular responsive network to utilize a non-natural carbon source, such as xylose, is limited due to the incomplete knowledge on the xylose response mechanisms. Here, through optimization of the xylose assimilation pathway together with combinational evaluation of reported targets, we generated a series of mutants with varied growth ability. However, understanding how cells respond to xylose and remodel cellular metabolic network is far insufficient based on current information. Therefore, genome-scale transcriptional analysis was performed to unravel the cellular reprograming mechanisms underlying the improved growth phenotype.

Project description:Plant Viral Movement Protein-expressing Yeast Transcriptome compared with Non-Functional Plant Viral Movement Protein-expressing Yeast Transcriptome

Project description:Reprogramming a non-methylotrophic industrial host, such as Saccharomyces cerevisiae, to a synthetic methylotroph reprents a huge challenge due to the complex regulation in yeast. Through TMC strategy together with ALE strategy, we completed a strict synthetic methylotrophic yeast that could use methanol as the sole carbon source. However, how cells respond to methanol and remodel cellular metabolic network on methanol were not clear. Therefore, genome-scale transcriptional analysis was performed to unravel the cellular reprograming mechanisms underlying the improved growth phenotype.