Lamin A/C phosphorylation at serine 22 is a conserved heat shock response to regulate nuclear adaptation during stress

Abstract

ABSTRACTThe heat shock (HS) response is crucial for cell survival in harmful environments. Nuclear lamin A/C, encoded by LMNA gene, has been shown to contribute towards altered gene expression during heat shock, but the underlying mechanisms are poorly understood. Here we show that reversible lamin A/C phosphorylation at Ser22 upon HS is an evolutionary conserved stress response that is triggered in concert with HSF1 activation in human and mouse cells and can also be observed in D. melanogaster in vivo. Consequently, the phosphorylation increase facilitated nucleoplasmic localization of lamin A/C and nuclear rounding in response to HS. The importance of lamin phosphorylation equilibria in HS was confirmed by lamin A/C knock-out (KO) cells that showed deformed nuclei after HS and were rescued by ectopic expression of wild-type, but not by a phosphomimetic (S22D) lamin A mutant. Furthermore, HS triggered release of lamina-associated protein 2α (Lap2α) from its association with lamin A/C and concurrently its downregulation, a response that was perturbed in lamin A/C KO cells and in LMNA mutant patient fibroblasts. The abrogated Lap2α response resulted in impaired cell cycle arrest under HS and compromised survival at the recovery. Taken together, our results suggest that the altered phosphorylation stoichiometry of lamin A/C provides an evolutionary conserved mechanism to regulate lamin structure and serve nuclear adaptation and cell survival during HS.