Nuclear lamins play central roles at the intersection between cytoplasmic signalling and nuclear events. Here, we show that at least two N- and C-terminal lamin epitopes are not accessible at the basal side of the nuclear envelope under environmental conditions known to upregulate cell contractility. The conformational epitope on the Ig-domain of A-type lamins is more buried in the basal than apical nuclear envelope of human mesenchymal stem cells undergoing osteogenesis (but not adipogenesis), and in fibroblasts adhering to rigid (but not soft) polyacrylamide hydrogels. This structural polarization of the lamina is promoted by compressive forces, emerges during cell spreading, and requires lamin A/C multimerization, intact nucleoskeleton-cytoskeleton linkages (LINC), and apical-actin stress-fibre assembly. Notably, the identified Igepitope overlaps with emerin, DNA and histone binding sites, and comprises various laminopathy mutation sites. Our findings should help deciphering how the physical properties of cellular microenvironments regulate nuclear events.
Specific interactions of protein side chains and lipid membranes regulate the localization, orientation, and activity of many peripheral proteins. Here, we introduce a modification of the coarse-grained MARTINI protein model, called 'side chain fix' (scFix), that was necessary and sufficient to correctly sample the side chain dynamics of β-strands in several globular proteins. When compared to μs long atomistic simulations or previous experimental findings, scFix MARTINI simulations reproduced all key interactions between the well-studied PLC-δ1 pleckstrin homology domain and a phosphatidylinositol-4,5-bisphosphate (PIP2) containing lipid membrane. Moreover, the extended runtime and higher sampling speed enabled the systematic mapping of the protein's rolling motion at the membrane, the identification of short-lived and stable binding orientations, as well as the verification and prediction of already known and of novel transient PIP2 binding sites. scFix also showed promise to maintain proper side chain orientation in other secondary structural motifs of the α-spectrin SH3 domain, the B1 domain of protein G, and the villin headpiece. This suggests that scFix improves on the predictive power of MARTINI simulations regarding protein-lipid and protein-ligand interactions.
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