Lipids Are Involved in Heterochromatin Condensation: A Quantitative Raman and Brillouin Microscopy Study

Chromatin, a fundamental component of eukaryotic genomes, is categorized into euchromatin and heterochromatin, which play distinct roles in gene regulation. Although these two chromatin states are distinguished by their degree of condensation, quantitatively measuring the degree of chromatin condensation, as well as the physical properties of chromatin in living cells, remains challenging. In this study, label-free in situ quantitative imaging was performed using a Raman-Brillouin microscope to visualize the spatial distribution of molecular concentration and viscoelasticity within the nuclear environment of a living cell. A quantitative concentration distribution image of each intracellular biomolecule was obtained by combining Raman imaging with multivariate curve resolution analysis, using a water Raman band as an internal standard. Simultaneous Raman-Brillouin imaging enables the quantitative visualization of viscoelasticity within a cell. Using this approach, we found that, in addition to DNA, heterochromatin is enriched in lipids and that lipids play a critical role in heterochromatin formation, determining its mechanical properties. These findings provide new insights into the mechanism of heterochromatin formation and its chemical and physical properties, leading to a comprehensive understanding of gene regulation and nuclear organization.