Proximity labeling at H3K9me3 reveals VRK-1 regulate global chromatin distribution in C. elegans
Proximity labeling at H3K9me3 reveals VRK-1 regulate global chromatin distribution in C. elegans
Smith, W.; Aksianiuk, V.; Pfaendler, R.; Villasenor, R.; Siva Sankar, D.; Stumpe, M.; Lenart, P.; Askjaer, P.; Towbin, B. D.; Baubec, T.; Dengjel, J.; Meister, P.
AbstractHeterochromatin marked by histone H3 lysine 9 di- or trimethylation (H3K9me2/3) underpins transcriptional silencing and nuclear organization, yet its full complement of associated proteins remains incompletely defined. Here, we apply ChromID proximity labelling with the mouse HP1? chromodomains to map the H3K9me3-proximal proteome in Caenorhabditis elegans, recovering known heterochromatin factors alongside previously uncharacterized candidates. We pursued one such candidate, the vaccinia-related kinase VRK-1, because of its established but poorly understood links to chromatin organization. Intriguingly, VRK-1 dynamically relocates from a broad nuclear distribution to the nuclear periphery upon azide or heat stress. Following these stresses, bulk chromatin exhibits similarly increased peripheral enrichment and apparent compaction, as assessed by radial fluorescence profiles. Although VRK-1 is not necessary for stress-induced chromatin reorganization, decompaction and repositioning of chromatin away from the nuclear envelope during recovery requires VRK-1. VRK-1 depletion leads to persistent perinuclear chromatin retention and compromises post-stress survival. Furthermore, loss of VRK-1 catalytic activity results in over-retention of chromatin at the nuclear periphery under normal growth conditions; this phenotype can be reversed by depletion of a key VRK-1 substrate at the nuclear envelope BAF-1. Our findings identify VRK-1 as a key regulator that controls the interaction of chromatin with the nuclear lamina through regulation of BAF-1.