Phase Separation-Mediated Chromatin Organization and Dynamics: From Imaging-Based Quantitative Characterizations to Functional Implications.

As an effective and versatile strategy to compartmentalize cellular components without the need for lipid membranes, phase separation has been found to underpin a wide range of intranuclear processes, particularly those involving chromatin. Many of the unique physico-chemical properties of chromatin-based phase condensates are harnessed by the cell to accomplish complex regulatory functions in a spatially and temporally controlled manner. Here, we survey key recent findings on the mechanistic roles of phase separation in regulating the organization and dynamics of chromatin-based molecular processes across length scales, packing states and intranuclear functions, with a particular emphasis on quantitative characterizations of these condensates enabled by advanced imaging-based approaches. By illuminating the complex interplay between chromatin and various chromatin-interacting molecular species mediated by phase separation, this review sheds light on an emerging multi-scale, multi-modal and multi-faceted landscape that hierarchically regulates the genome within the highly crowded and dynamic nuclear space. Moreover, deficiencies in existing studies also highlight the need for mechanism-specific criteria and multi-parametric approaches for the characterization of chromatin-based phase separation using complementary techniques and call for greater efforts to correlate the quantitative features of these condensates with their functional consequences in close-to-native cellular contexts.

Identification of putative binding interface of PI(3,5)P2 lipid on rice black-streaked dwarf virus (RBSDV) P10 protein.

Rice black-streaked dwarf virus (RBSDV) is an important reovirus that infects both plants and its transmission vector small brown planthopper, causing severe crop loss. High affinity binding between RBSDV P10 and PI(3,5)P2 lipid layer was measured using biolayer interferometry (BLI). Subcellular co-localization of PI(3,5)P2 and RBSDV P10 was observed on membranous structures in insect cells with stochastic optical reconstruction microscopy (STORM) imaging. Putative interacting sites of PI(3,5)P2 lipid on a computational predicted RBSDV P10 structure were mapped to its "C-domain" (250-470 aa), using HDXMS data. The BLI and STORM results showed binding and co-localization of RBSDV P10, and PI(3,5)P2 on vesicle-like membranous structures were corroborated with the prediction of the binding interface. Understanding the lipid binding sites on viral proteins will lead to developing strategies to block viral-lipid interaction and disrupt viral pathogenesis in insect vectors and to block virus transmission and achieve disease control of crops in the field.