Live imaging of chromatin distribution in muscle nuclei reveals novel principles of nuclear architecture and chromatin compartmentalization

Abstract

AbstractPackaging of the chromatin within the nucleus serves as an important factor in the regulation of transcriptional output. However, information on chromatin architecture on nuclear scale in fully differentiated cells, under physiological conditions and in live organisms, is largely unavailable. Here, we imaged nuclei and chromatin in muscle fibers of live, intact Drosophila larvae. In contrast to the common view that chromatin is distributed throughout the nuclear volume, we show that the entire chromatin, including active and repressed regions, forms a peripheral layer underneath the nuclear lamina, leaving a chromatin-devoid compartment at the nucleus center. Importantly, visualization of nuclear compartmentalization required imaging of un-fixed nuclei embedded within their intrinsic tissue environment, with preserved nuclear volume. Upon fixation of similar muscle nuclei, we observed an average of three-fold reduction in nuclear volume caused by dehydration and evidenced by nuclear flattening. In these conditions, the peripheral chromatin layer was not detected anymore, demonstrating the importance of preserving native biophysical tissue environment. We further show that nuclear compartmentalization is sensitive to the levels of lamin C, since over-expression of lamin C-GFP in muscle nuclei resulted in detachment of the peripheral chromatin layer from the lamina and its collapse into the nuclear center. Computer simulations of chromatin distribution recapitulated the peripheral chromatin organization observed experimentally, when binding of lamina associated domains (LADs) was incorporated with chromatin self-attractive interactions. Reducing the number of LADs led to collapse of the chromatin, similarly to our observations following lamin C over-expression. Taken together, our findings reveal a novel mode of mesoscale organization of chromatin within the nucleus in a live organism, in which the chromatin forms a peripheral layer separated from the nuclear interior. This architecture may be essential for robust transcriptional regulation in fully differentiated cells.