Loss of Sun2 ablates nuclear mechanosensing-driven extracellular matrix production and mitigates lung fibrosis.

Fibrosis and pathological stiffening of tissue are driven by mechanical and biochemical signaling pathways. Here, we find that Sun2, an integral inner nuclear membrane component of Linker of Nucleoskeleton and Cytoskeleton (LINC) complexes, is up-regulated in the lung of patients suffering from fibrotic conditions and in fibroblasts during an injury-induced mouse model of lung fibrosis. Sun2 protein levels also increase in primary lung fibroblasts in a substrate stiffness-dependent manner. Sun2 (-/-) primary lung fibroblasts respond to TGFβ, become contractile, and express a key marker of extracellular matrix-producing fibroblasts, Cthrc1. Consistent with this, Sun2 is dispensable for myofibroblast formation and repairing the alveolar barrier after bleomycin injury. Remarkably, however, fibrosis does not develop in bleomycin-treated Sun2 (-/-) mouse lungs. This is explained by the requirement for Sun2 to up-regulate genes encoding extracellular matrix proteins. We therefore suggest that Sun2-containing LINC complexes contribute to a mechanical coincidence detection mechanism that acts in concert with canonical TGFβ signaling necessary for pathologic extracellular matrix protein production, representing a nuclear mechanosensing node for intervention in fibrotic diseases of the lung.