| Publication | Num. Conditions |
Brief Description | PubMed ID |
| Nakamura T et al., 2014 | 14 | Identification of a gene, FMP21, whose expression levels are involved in thermotolerance in Saccharomyces cerevisiae. (details) | 25177541 |
| Haitani Y et al., 2012 | 8 | Identification of an acetate-tolerant strain of Saccharomyces cerevisiae and characterization by gene expression analysis. (details) | 22841865 |
| Flom GA et al., 2012 | 6 | Identification of an Hsp90 mutation that selectively disrupts cAMP/PKA signaling in Saccharomyces cerevisiae. (details) | 22461145 |
| Scherens B et al., 2006 | 18 | Identification of direct and indirect targets of the Gln3 and Gat1 activators by transcriptional profiling in response to nitrogen availability in the short and long term. (details) | 16879428 |
| Pan Z et al., 2008 | 6 | Identification of molecular pathways affected by pterostilbene, a natural dimethylether analog of resveratrol. (details) | 18366703 |
| Noble J et al., 2015 | 2 | Identification of new Saccharomyces cerevisiae variants of the MET2 and SKP2 genes controlling the sulfur assimilation pathway and the production of undesirable sulfur compounds during alcoholic fermentation. (details) | 25947166 |
| Jaime MD et al., 2012 | 36 | Identification of yeast genes that confer resistance to chitosan oligosaccharide (COS) using chemogenomics. (details) | 22727066 |
| Tyo KE et al., 2012 | 18 | Imbalance of heterologous protein folding and disulfide bond formation rates yields runaway oxidative stress. (details) | 22380681 |
| Marton MJ et al., 1998 | 7 | Immunosuppressant response (details) | 9809554 |
| Guan Q et al., 2006 | 96 | Impact of nonsense-mediated mRNA decay on the global expression profile of budding yeast. (details) | 17166056 |
| Tesniere C et al., 2013 | 4 | Impact of nutrient imbalance on wine alcoholic fermentations: nitrogen excess enhances yeast cell death in lipid-limited must. (details) | 23658613 |
| Garcia-Rodriguez N et al., 2012 | 6 | Impaired manganese metabolism causes mitotic misregulation. (details) | 22493290 |
| Reyes LH et al., 2014 | 13 | Improving carotenoids production in yeast via adaptive laboratory evolution. (details) | 24262517 |
| Klockow C et al., 2008 | 7 | In vivo regulation of glucose transporter genes at glucose concentrations between 0 and 500 mg/L in a wild type of Saccharomyces cerevisiae. (details) | 18455824 |
| Pagano L et al., 2019 | 6 | In Vivo-In Vitro Comparative Toxicology of Cadmium Sulphide Quantum Dots in the Model Organism Saccharomyces cerevisiae. (details) | 30986968 |
| Lindgren E et al., 2014 | 27 | Inactivation of the budding yeast cohesin loader Scc2 alters gene expression both globally and in response to a single DNA double strand break. (details) | 25483075 |
| Tarrant DJ et al., 2016 | 6 | Inappropriate expression of the translation elongation factor 1A disrupts genome stability and metabolism. (details) | 27807005 |
| Dettman JR et al., 2007 | 8 | Incipient speciation by divergent adaptation and antagonistic epistasis in yeast. (details) | 17538619 |
| de Kok S et al., 2011 | 13 | Increasing free-energy (ATP) conservation in maltose-grown Saccharomyces cerevisiae by expression of a heterologous maltose phosphorylase. (details) | 21684346 |
| Vemuri GN et al., 2007 | 6 | Increasing NADH oxidation reduces overflow metabolism in Saccharomyces cerevisiae. (details) | 17287356 |
| Abe F et al., 2007 | 3 | Induction of DAN/TIR yeast cell wall mannoprotein genes in response to high hydrostatic pressure and low temperature. (details) | 17910955 |
| Ro DK et al., 2008 | 14 | Induction of multiple pleiotropic drug resistance genes in yeast engineered to produce an increased level of anti-malarial drug precursor, artemisinic acid. (details) | 18983675 |
| Talarek N et al., 2010 | 14 | Initiation of the TORC1-regulated G0 program requires Igo1/2, which license specific mRNAs to evade degradation via the 5'-3' mRNA decay pathway. (details) | 20471941 |
| Geijer C et al., 2013 | 16 | Initiation of the transcriptional response to hyperosmotic shock correlates with the potential for volume recovery. (details) | 23758973 |
| Klopf E et al., 2017 | 8 | INO80 represses osmostress induced gene expression by resetting promoter proximal nucleosomes. (details) | 28025392 |
| Worley J et al., 2013 | 55 | Inositol pyrophosphates regulate cell growth and the environmental stress response by activating the HDAC Rpd3L. (details) | 23643537 |
| Moreno AD et al., 2022 | 6 | Insights into cell robustness against lignocellulosic inhibitors and insoluble solids in bioethanol production processes. (details) | 35017613 |
| Moreno AD et al., 2019 | 6 | Insoluble solids at high concentrations repress yeast's response against stress and increase intracellular ROS levels. (details) | 31439886 |
| Chumnanpuen P et al., 2012 | 24 | Integrated analysis of transcriptome and lipid profiling reveals the co-influences of inositol-choline and Snf1 in controlling lipid biosynthesis in yeast. (details) | 22622761 |
| Chumnanpuen P et al., 2013 | 33 | Integrated analysis, transcriptome-lipidome, reveals the effects of INO-level (INO2 and INO4) on lipid metabolism in yeast. (details) | 24456840 |
Contact: sgd-helpdesk@lists.stanford.edu
