CDC25
Gene Ontology Biological Process
- mitotic DNA replication checkpoint [IMP]
- peptidyl-tyrosine dephosphorylation involved in activation of protein kinase activity [IDA]
- positive regulation of cyclin-dependent protein serine/threonine kinase activity involved in G2/M transition of mitotic cell cycle [IMP]
- regulation of G2/M transition of mitotic cell cycle [IMP]
- regulation of cell size [NAS]
- signal transduction involved in intra-S DNA damage checkpoint [IMP]
Gene Ontology Molecular Function
STY1
Gene Ontology Biological Process
- G1 cell cycle arrest in response to nitrogen starvation [IMP]
- G1 to G0 transition [IMP]
- MAPK cascade in response to starvation [IMP]
- MAPK cascade involved in osmosensory signaling pathway [IDA, IMP]
- cellular response to cation stress [IGI]
- cellular response to nitrogen starvation [IMP]
- mRNA export from nucleus in response to heat stress [IMP]
- mitotic cell cycle arrest in response to nitrogen starvation [IMP]
- positive regulation of G2/M transition of mitotic cell cycle [IMP]
- positive regulation of transcription factor import into nucleus in response to oxidative stress [IMP]
- positive regulation of transcription from RNA polymerase II promoter [IMP]
- positive regulation of transcription from RNA polymerase II promoter in response to oxidative stress [IMP]
- regulation of DNA binding [IDA]
- regulation of cAMP-mediated signaling [IMP]
- regulation of cAMP-mediated signaling by regulation of transcription from RNA polymerase II promoter [IMP]
- regulation of cell shape involved in G1 to G0 transition [IMP]
- regulation of chromatin assembly [IMP]
- regulation of chromatin disassembly [IMP]
- regulation of histone acetylation [IMP]
- regulation of mRNA stability involved in cellular response to UV [IMP]
- regulation of meiotic cell cycle [IMP]
- regulation of reciprocal meiotic recombination [IMP]
- regulation of translation in response to nitrogen starvation [IDA]
- regulation of translation in response to osmotic stress [IDA, IMP]
- regulation of translation in response to oxidative stress [IDA, IMP]
- stress granule assembly [IMP]
- stress granule disassembly [IMP]
- stress-activated MAPK cascade [IMP]
Gene Ontology Molecular Function
Synthetic Lethality
A genetic interaction is inferred when mutations or deletions in separate genes, each of which alone causes a minimal phenotype, result in lethality when combined in the same cell under a given condition.
Publication
The Atf1 transcription factor is a target for the Sty1 stress-activated MAP kinase pathway in fission yeast.
The atf1+ gene of Schizosaccharomyces pombe encodes a bZIP transcription factor with strong homology to the mammalian factor ATF-2. ATF-2 is regulated through phosphorylation in mammalian cells by the stress-activated mitogen-activated protein (MAP) kinases SAPK/JNK and p38. We show here that the fission yeast Atf1 factor is also regulated by a stress-activated kinase, Sty1. The Sty1 kinase is stimulated by ... [more]
Throughput
- Low Throughput
Related interactions
| Interaction | Experimental Evidence Code | Dataset | Throughput | Score | Curated By | Notes |
|---|---|---|---|---|---|---|
| CDC25 STY1 | Dosage Growth Defect Dosage Growth Defect A genetic interaction is inferred when over expression or increased dosage of one gene causes a growth defect in a strain that is mutated or deleted for another gene. | Low | - | BioGRID | 2609088 | |
| CDC25 STY1 | Dosage Rescue Dosage Rescue A genetic interaction is inferred when over expression or increased dosage of one gene rescues the lethality or growth defect of a strain that is mutated or deleted for another gene. | Low | - | PomBase | 882980 | |
| CDC25 STY1 | Synthetic Lethality Synthetic Lethality A genetic interaction is inferred when mutations or deletions in separate genes, each of which alone causes a minimal phenotype, result in lethality when combined in the same cell under a given condition. | Low | - | PomBase | - | |
| STY1 CDC25 | Synthetic Lethality Synthetic Lethality A genetic interaction is inferred when mutations or deletions in separate genes, each of which alone causes a minimal phenotype, result in lethality when combined in the same cell under a given condition. | Low | - | BioGRID | 797454 |