| First Author | Pinto VI | Year | 2015 |
| Journal | Biochim Biophys Acta | Volume | 1853 |
| Issue | 10 Pt A | Pages | 2526-38 |
| PubMed ID | 26025676 | Mgi Jnum | J:233929 |
| Mgi Id | MGI:5788386 | Doi | 10.1016/j.bbamcr.2015.05.019 |
| Citation | Pinto VI, et al. (2015) PAK1 is involved in sensing the orientation of collagen stiffness gradients in mouse fibroblasts. Biochim Biophys Acta 1853(10 Pt A):2526-38 |
| abstractText | Migrating cells sense variations of stiffness in connective tissue matrices but how cells detect and respond to stiffness orientation is not defined. We examined cell extension formation on collagen with underlying support (vertical stiffness gradient) or on collagen laterally supported by nylon (lateral stiffness gradient). At 6 h after plating, cells plated on laterally-supported collagen exhibited >2-fold more abundant and ~2-fold longer cell extensions than cells plated on collagen with underlying support. We examined whether p21-activated kinase 1 (PAK1) influences extension formation that is dependent on the orientation of support. At 6 h after plating on collagen with underlying support, wild-type cell extensions were 40% shorter than PAK1 knockdown cells. In contrast, on laterally-supported collagen, wild-type cell extensions were 2-fold longer than PAK1 knockdown cells. In cells plated on laterally-supported collagen, there were ~2-fold reductions of collagen fiber alignment and compaction in PAK1 knockdown cells compared with wild-type cells. PAK1 knockdown did not affect collagen fiber alignment or compaction by cells plated on collagen with underlying support. Wild-type cells with lateral support of collagen exhibited 3-fold increases of phospho-myosin staining at 6h, which was 2-fold lower in PAK1 knockdown cells. In contrast, cells on collagen with underlying support showed no increase of phospho-myosin staining at any times. PAK1 knockdown did not affect alpha2 or beta1 integrin expression or function. We conclude that PAK1 is involved in the ability of cells to sense the orientation of stiffness in collagen substrates and generate contractile forces that affect cell extension formation. |
