Chromatin histone modifications and rigidity affect nuclear morphology independent of lamins

Andrew D. Stephens*, Patrick Z. Liu, Edward J. Banigan, Luay M. Almassalha, Vadim Backman, Stephen A. Adam, Robert D. Goldman, John F. Marko

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

199 Scopus citations

Abstract

Nuclear shape and architecture influence gene localization, mechanotransduction, transcription, and cell function. Abnormal nuclear morphology and protrusions termed “blebs” are diagnostic markers for many human afflictions including heart disease, aging, progeria, and cancer. Nuclear blebs are associated with both lamin and chromatin alterations. A number of prior studies suggest that lamins dictate nuclear morphology, but the contributions of altered chromatin compaction remain unclear. We show that chromatin histone modification state dictates nuclear rigidity, and modulating it is sufficient to both induce and suppress nuclear blebs. Treatment of mammalian cells with histone deacetylase inhibitors to increase euchromatin or histone methyltransferase inhibitors to decrease heterochromatin results in a softer nucleus and nuclear blebbing, without perturbing lamins. Conversely, treatment with histone demethylase inhibitors increases heterochromatin and chromatin nuclear rigidity, which results in reduced nuclear blebbing in lamin B1 null nuclei. Notably, increased heterochromatin also rescues nuclear morphology in a model cell line for the accelerated aging disease Hutchinson–Gilford progeria syndrome caused by mutant lamin A, as well as cells from patients with the disease. Thus, chromatin histone modification state is a major determinant of nuclear blebbing and morphology via its contribution to nuclear rigidity.

Original languageEnglish (US)
Pages (from-to)220-233
Number of pages14
JournalMolecular biology of the cell
Volume29
Issue number2
DOIs
StatePublished - Jan 15 2018

Funding

We thank Yixian Zheng for providing us with MEF LB1–/– cells (Shimi et al., 2015) and Aaron Straight for providing us with HeLa Kyoto cells. We thank Aykut Erbaş, Sumitabha Brahmachari, Haimei Chen, and Thomas O’Halloran for helpful discussions. A.D.S. is supported by National Research Service Award postdoctoral fellowship F32GM112422 and was supported by postdoctoral fellowship from the American Heart Association 14POST20490209. A.D.S., E.J.B., and J.F.M. are supported by National Science Foundation (NSF) Grants DMR-1206868 and MCB-1022117 and by National Institutes of Health (NIH) Grants GM105847 and CA193419 and via subcontract DK107980. S.A.A. and R.D.G. are supported by NIH GM106023, GM0969, and Progeria Research Foundation PRF 2013-51. L.M.A. and V.B. are supported by NIH grants R01CA200064 and R01CA155284, NSF grant CBET-1240416, and the Lungevity Foundation. This work was funded by the Chicago Biomedical Consortium with support from the Searle Funds at the Chicago Community Trust. We thank Yixian Zheng for providing us with MEF LB1–/– cells (Shimi et al., 2015) and Aaron Straight for providing us with HeLa Kyoto cells. We thank Aykut Erba?, Sumitabha Brahmachari, Haimei Chen, and Thomas O’Halloran for helpful discussions. A.D.S. is supported by National Research Service Award postdoctoral fellowship F32GM112422 and was supported by postdoctoral fellowship from the American Heart Association 14POST20490209. A.D.S., E.J.B., and J.F.M. are supported by National Science Foundation (NSF) Grants DMR-1206868 and MCB-1022117 and by National Institutes of Health (NIH) Grants GM105847 and CA193419 and via subcontract DK107980. S.A.A. and R.D.G. are supported by NIH GM106023, GM0969, and Progeria Research Foundation PRF 2013-51. L.M.A. and V.B. are supported by NIH grants R01CA200064 and R01CA155284, NSF grant CBET-1240416, and the Lungevity Foundation. This work was funded by the Chicago Biomedical Consortium with support from the Searle Funds at the Chicago Community Trust.

ASJC Scopus subject areas

  • Molecular Biology
  • Cell Biology

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