The nucleus is a mechanically stable compartment of the cell that contains the genome and performs many essential functions. Nuclear mechanical components chromatin and lamins maintain nuclear shape, compartmentalization, and function by resisting antagonistic actin contraction and confinement. However, studies have yet to compare chromatin and lamins perturbations side-by-side as well as modulated actin contraction while holding confinement constant. To accomplish this, we used NLS-GFP to measure nuclear shape and rupture in live cells with chromatin decompaction (VPA), loss of lamin B1 (LMNB1-/-), and loss of lamin A/C (LMNA-/-). We then modulated actin contraction while maintaining actin confinement measured by nuclear height. Wild type, chromatin decompaction, and lamin B1 null present bleb-based nuclear deformations and ruptures dependent on actin contraction and independent of actin confinement. Inhibition of actin contraction by Y27632 decreased nuclear blebbing and ruptures to near 0% of cells while activation of actin contraction by CN03 increased the frequency of ruptures by nearly two-fold. However, lamin A/C null results in overall abnormal shape, but similar blebs and ruptures as wild type which were unaffected by actin contraction modulation. Actin contraction control of nuclear shape and ruptures showed that DNA damage levels were more correlated with perturbed nuclear shape than they were with changes in nuclear ruptures. We reveal that lamin B1 is a chromatin decompaction phenotype because using GSK126, which mimics the loss of facultative heterochromatin in lamin B1 null, is sufficient to phenocopy increased nuclear blebbing and ruptures. Furthermore, even though blebs and ruptures in lamin A/C null cells are insensitive to actin contraction, they do have the capacity to form increased levels of nuclear blebs and bleb-based ruptures, shown by treating with VPA. Thus, nuclear bleb formation and bleb-based nuclear ruptures are driven by actin contraction and independent of changes in actin confinement.
Chromatin is an essential component of nuclear mechanical response and shape that maintains nuclear compartmentalization and function. The biophysical properties of chromatin alter nuclear shape and stability, but little is known about whether or how major genomic functions can impact the integrity of the nucleus. We hypothesized that transcription might affect cell nuclear shape and rupture through its effects on chromatin structure and dynamics. To test this idea, we inhibited transcription with the RNA polymerase II inhibitor alpha-amanitin in wild type cells and perturbed cells that present increased nuclear blebbing. Transcription inhibition suppresses nuclear blebbing for several cell types, nuclear perturbations, and transcription inhibitors. Furthermore, transcription is necessary for robust nuclear bleb formation, bleb stabilization, and bleb-based nuclear ruptures. These morphological effects appear to occur through a novel biophysical pathway, since transcription does not alter either chromatin histone modification state or nuclear rigidity, which typically control nuclear blebbing. We find that active/phosphorylated RNA pol II Ser5, marking transcription initiation, is enriched in nuclear blebs relative to DNA. Thus, transcription initiation is a hallmark of nuclear blebs. Polymer simulations suggest that motor activity within chromatin, such as that of RNA pol II, can generate active forces that deform the nuclear periphery, and that nuclear deformations depend on motor dynamics. Our data provide evidence that the genomic function of transcription impacts nuclear shape stability, and suggests a novel mechanism, separate and distinct from chromatin rigidity, for regulating large-scale nuclear shape and function.
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