Perinuclear force regulates SUN2 dynamics and distribution on the nuclear envelope for proper nuclear mechanotransduction
Abstract
The trans-luminal LINC (Linker of Nucleoskeleton and Cytoskeleton) complex plays a central role in nuclear mechanotransduction by coupling the nucleus with cytoskeleton. High spatial density and active dynamics of LINC complex have hindered its precise characterization for the understanding of underlying mechanisms how the linkages sense and respond to mechanical stimuli. In this study, we focus on SUN2, a core component of LINC complex interconnecting the nuclear lamina and actin cytoskeleton and apply single molecule super-resolution imaging to reveal how SUN2 responds to actomyosin contractility. Using stochastic optical reconstruction microscopy (STORM), we quantitated the distribution pattern and density of SUN2 on the basal nuclear membrane. We found that SUN2 undergoes bidirectional translocation between ER and nuclear membrane in response to actomyosin contractility, suggesting that dynamic constrained force on SUN2 is required for its proper distribution. Furthermore, single molecule imaging unveils interesting dynamics of SUN2 molecules that are regulated by both actomyosin contractility and laminA/C network, whereas SUN2 oligomeric states are not affected by actomyosin contractility. Lastly, the mechanical response of SUN2 to actomyosin contractility was found to regulate expression of mechano-sensitive genes located in lamina-associated domains (LADs) and perinuclear heterochromatin. Taken together, our results reveal how SUN2 responds to mechanical cues at the single-molecule level, providing new insights into the mechanism of nuclear mechanotransduction.
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