Abstract
Cells that have been pre-exposed to mild stress (priming stress) acquire transient resistance to subsequent severe stress even under different combinations of stresses. This phenomenon is called cross-tolerance. Although it has been reported that cross-tolerance occurs in many organisms, the molecular basis is not clear yet. Here, we identified slm9(+) as a responsible gene for the cross-tolerance in the fission yeast Schizosaccharomyces pombe. Slm9 is a homolog of mammalian HIRA histone chaperone. HIRA forms a conserved complex and gene disruption of other HIRA complex components, Hip1, Hip3, and Hip4, also yielded a cross-tolerance-defective phenotype, indicating that the fission yeast HIRA is involved in the cross-tolerance as a complex. We also revealed that Slm9 was recruited to the stress-responsive gene loci upon stress treatment in an Atf1-dependent manner. The expression of stress-responsive genes under stress conditions was compromised in HIRA disruptants. Consistent with this, Pol II recruitment and nucleosome eviction at these gene loci were impaired in slm9Δ cells. Furthermore, we found that the priming stress enhanced the expression of stress-responsive genes in wild-type cells that were exposed to the severe stress. These observations suggest that HIRA functions in stress response through transcriptional regulation.
Highlights
HIRA is a conserved histone chaperone required for regulation of chromatin structure
We have demonstrated that the fission yeast HIRA complex is involved in cross-tolerance
The fission yeast HIRA has been shown to be implicated in gene silencing and the heterochromatin assembly [26, 38, 40, 56], our results showed that the fission yeast HIRA is required for the transcriptional activation of stress-responsive genes under the low-dose stress conditions
Summary
HIRA is a conserved histone chaperone required for regulation of chromatin structure. Conclusion: HIRA is involved in cross-tolerance via regulation of stress-responsive gene expression. We found that the priming stress enhanced the expression of stressresponsive genes in wild-type cells that were exposed to the severe stress These observations suggest that HIRA functions in stress response through transcriptional regulation. JK316 JK317 YT2272 MC3725 MC3749 MC3768 MC3773 MC3793 MC3795 MC3797 MC3799 MC3801 MC3849 MC4219 hϩ leu ura4-D18 hϪ leu ura4-D18 hϪ leu ura4-D18 spc1::kanMX6 hϪ leu ura4-D18 hip1::ura4ϩ hϪ leu ura4-D18 slm9::ura4ϩ hϪ leu ura4-D18 pcf1::kanMX6 hϪ leu ura4-D18 hip3::ura4ϩ hϪ leu ura4-D18 slm9–12myc (ura4ϩ) hϪ leu ura4-D18 hip1–12myc (ura4ϩ) hϪ leu ura4-D18 slm9-GFP (ura4ϩ) hϪ leu ura4-D18 hip4::ura4ϩ hϪ leu ura4-D18 spc1::ura4ϩ hϪ leu ura4-D18 nap1::ura4ϩ hϪ leu ura4-D18 slm9–12myc (ura4ϩ) atf1::hphMX6 Together, these results highlight the novel function of the fission yeast HIRA in stress response
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