Micronuclei (MN) are cytosolic bodies that sequester acentric fragments or mis-segregated chromosomes from the primary nucleus. Spontaneous rupture of the MN envelope allows recognition by the viral receptor cyclic GMP-AMP synthase (cGAS), initiating interferon signaling downstream of DNA damage. Here, we demonstrate that MN rupture is permissive but not sufficient for cGAS localization. Chromatin characteristics such as histone 3, lysine 79 dimethylation (H3K79me2) are present in the nucleus before DNA damage, retained in ruptured MN, and regulate cGAS recruitment. cGAS is further responsive to dynamic intra-MN processes occurring prior to rupture, including transcription. MN chromatin tethering via the nucleosome acidic patch is necessary for cGAS-dependent interferon signaling. Our data suggest that both damage-antecedent nuclear chromatin status and MN-contained chromatin organizational changes dictate cGAS recruitment and the magnitude of the cGAS-driven interferon cascade. Our work defines MN as integrative signaling hubs for the cellular response to genotoxic stress.
Micronuclei (MN) are aberrant cytosolic compartments containing broken genomic fragments or whole lagging chromosomes. MN envelopes irreversibly rupture, allowing the viral receptor cGAS to localize to MN and initiate an inflammatory signalling cascade. Here, we demonstrate that MN envelope rupture is not sufficient for cGAS localization. Unlike MN that arise following ionizing radiation (IR), ruptured MN generated from acute transcription stressors DRB or siSRSF1 are refractory to cGAS localization. Recruitment of cGAS to MN is blocked by inhibiting the histone methyltransferase DOT1L prior to IR exposure, demonstrating that cGAS recruitment to MN is dictated by nuclear chromatin organization at the time of DNA damage. Loss of cGAS+ MN, caused either by acute transcription stressors or by preventing DOT1L-deposited histone methylation, corresponded to significantly decreased cGAS-dependent inflammatory signalling. These results implicate nuclear chromatin organization in micronuclear composition and activity, influencing the ability of damage-induced MN to retain cytosolic proteins upon rupture.
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