Role of chromatin condensates in tuning nuclear mechano-sensing in Kabuki Syndrome

The human genome is characterized by an extent of functions that act further than its genetic role. Indeed, the genome can also affect cellular processes by nongenetic means through its physical and structural properties, specifically by exerting mechanical forces that shape nuclear morphology and architecture. The balancing between two chromatin compartments with antagonist functions, namely Transcriptional and Polycomb condensates, is required for preserving nuclear mechanical properties and its perturbation is causative of the pathogenic condition Kabuki syndrome (KS) (Fasciani et al., 2020). KS is a rare monogenic disease caused by the haploinsufficiency in the KMT2D gene encoding for MLL4, a H3K4-specific methyltransferase important for the regulation of gene expression. By interrogating the effect of KMT2D haploinsufficiency in Mesenchymal Stem Cells (MSCs) we discovered that MLL4 loss of function (LoF) impaired Polycomb-dependent chromatin compartmentalization, altering the nuclear architecture and the cell mechanoresponsiveness during differentiation (Fasciani et al., 2020). These results suggest that altered nuclear mechanics rely on chromatin architecture and could potentially lead to changes in cell responses to external mechanical stimuli. In the present work, we investigated the role of Transcriptional and Polycomb condensates in tuning nuclear responses to different external mechano-physical conditions. To affect nuclear mechanics, we employed the use of several mechanical devices (e. g. substrate stiffness, microchannels with constrictions, and cell confinement). We found that Polycomb and Transcriptional condensates are modulated by changes in substrate rigidity in healthy conditions and that MLL4 LoF impairs the MSCs nuclear condensates-driven mechanical response. Furthermore, we observed that MLL4 LoF impacts nuclear adaptation to confined spaces by incrementing susceptibility to nuclear envelope rupture. We also showed that the increased nuclear fragility in MLL4 LoF is accompanied by an alteration of cell migratory capacity and survival rate. Altogether these findings suggest that MLL4 LoF impairs cell responses to external mechanical stimuli, shedding light on the pathological connection between the altered cell mechanoresponsiveness during differentiation and KS phenotype in terms of skeletal and cartilage anomalies.