A chemical-genetic approach for stress-independent activation of the fission yeast stress-activated protein kinase pathway
A chemical-genetic approach for stress-independent activation of the fission yeast stress-activated protein kinase pathway
Sawin, K. E.; Gupta, A.; Dudnakova, T.; Bayrak, B.; Kovac, A.; Modaffari, D.; Rodriguez-Rodriguez, A. I.; Scott, M. L.; Tay, Y. D.
AbstractBackgroundThe fission yeast stress-activated protein kinase (SAPK) pathway includes a conserved mitogen-activated protein (MAP) kinase cascade that regulates multiple cellular processes and is activated by several types of external stress. Understanding how Sty1, the MAP kinase in the SAPK pathway, controls these processes is complicated by the fact that different stressors can have stressor-specific effects that may be difficult to separate from the effects of Sty1 activation itself. Moreover, upon stress, Sty1 activation is usually short-lived. Previously, we developed a fission yeast strain, SISA, in which Sty1 kinase activity can be switched on in a sustained manner in the absence of external stress. This required combining multiple mutations in the SAPK pathway, including an analog-sensitive version of Sty1. When SISA cells are grown in the presence of analog-sensitive kinase inhibitors, Sty1 is inhibited, but when inhibitor is removed, Sty1 becomes hyperactive. While this strain was useful, it had several limitations. ResultsHere we describe and validate a more rationally-designed strain, SISA4, that retains the features of the original SISA strain while overcoming its limitations. SISA4 is more stable genetically than SISA, easier to use in genetic crosses, and easy to identify by phenotype or genotyping. We show that analog-sensitive kinase inhibitors 4-Amino-1-tert-butyl-3-(1-naphthylmethyl)pyrazolo[3,4-d]pyrimidine (1-NM-PP1) and 4-Amino-1-tert-butyl-3-(3-bromobenzyl)pyrazolo[3,4-d]pyrimidine (3-BrB-PP1) are equally potent for inhibiting analog-sensitive Sty1 in vivo, and we determine optimal inhibitor concentrations for converting SISA4 cells from a Sty1-inhibited state to a Sty1-hyperactive state. We also find that both 1-NM-PP1 and 3-BrB-PP1 have measurable off-target effects in wild-type cells, although these are modest and generally do not affect interpretation of experiments. Finally, using SISA4, we show that the Sty1-activated transcription factor Atf1 plays an unexpected role in maintaining cell-polarity disruption after Sty1 hyperactivation. ConclusionsSISA4 will be useful for investigating how SAPK pathway activation regulates diverse cellular processes.