Abstract
Anchoring of heterochromatin to the nuclear envelope appears to be an important process ensuring the spatial organization of the chromatin structure and genome function in eukaryotic nuclei. Proteins of the inner nuclear membrane (INM) mediating these interactions are able to recognize lamina-associated heterochromatin domains (termed LAD) and simultaneously bind either lamin A/C or lamin B1. One of these proteins is the lamin B receptor (LBR) that binds lamin B1 and tethers heterochromatin to the INM in embryonic and undifferentiated cells. It is replaced by lamin A/C with specific lamin A/C binding proteins at the beginning of cell differentiation and in differentiated cells. Our functional experiments in cancer cell lines show that heterochromatin in cancer cells is tethered to the INM by LBR, which is downregulated together with lamin B1 at the onset of cell transition to senescence. The downregulation of these proteins in senescent cells leads to the detachment of centromeric repetitive sequences from INM, their relocation to the nucleoplasm, and distension. In cells, the expression of LBR and LB1 is highly coordinated as evidenced by the reduction of both proteins in LBR shRNA lines. The loss of the constitutive heterochromatin structure containing LADs results in changes in chromatin architecture and genome function and can be the reason for the permanent loss of cell proliferation in senescence.
Highlights
Anchoring of heterochromatin to the nuclear envelope appears to be an important process ensuring the spatial organization of the chromatin structure and genome function in eukaryotic nuclei
We found a high fraction (>80%) of CSH in heterochromatin-rich chromosomes colocalizing with the inner nuclear membrane (INM) in these cancer cells
Even if it seems that the downregulation of lamin B receptor (LBR) and lamin B1 (LB1) is necessary for cell transition to senescence, it does not elicit this process
Summary
Cellular senescence is a cellular response to a variety of stresses [18,19,20]. It is accompanied by a set of characteristic morphological and physiological features that distinguish senescent cells from proliferating cells and from quiescent or terminally differentiated cells [19,20]. Clones of MCF7 and U2OS with reduced expression of these proteins exhibited slower proliferation compared to the parental cells, formed higher numbers of micronuclei (MN) showing higher permeability of the nuclear membrane, and were transferred to senescence by γ-irradiation to their parental cells. Even if it seems that the downregulation of LBR and LB1 is necessary for cell transition to senescence, it does not elicit this process. Processes of cell differentiation directed by a heterochromatin tether with the participation of lamin A/C are very complicated and participation of the different proteins in this process is not yet completely clear
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