Department of Anatomy and Regenerative Biology, George Washington University Medical Center, Washington DC 20037, USA.
Exp Cell Res. 2010 Aug 15;316(14):2322-39. doi: 10.1016/j.yexcr.2010.05.020. Epub 2010 May 24.
Corneal scarring is a major cause of blindness worldwide and can result from the deposition of abnormal amounts of collagen fibers lacking the correct size and spacing required to produce a clear cornea. Collagen fiber formation requires a preformed fibronectin (FN) matrix. We demonstrate that the loss of syndecan1 (sdc1) in corneal stromal cells (CSC) impacts cell migration rates, the sizes and composition of focal and fibrillar adhesions, the activation of integrins, and the assembly of fibronectin into fibrils. Integrin and fibronectin expression are not altered on sdc1-null CSCs. Cell adhesion, spreading, and migration studies using low compared to high concentrations of FN and collagen I (CNI) or vitronectin (VN) with and without activation of integrins by manganese chloride show that the impact of sdc1 depletion on integrin activation varies depending on the integrin-mediated activity evaluated. Differences in FN fibrillogenesis and migration in sdc1-null CSCs are reversed by addition of manganese chloride but cell spreading differences remain. To determine if our findings on sdc1 were specific to the cornea, we compared the phenotypes of sdc1-null dermal fibroblasts with those of CSCs. We found that without sdc1, both cell types migrate faster; however, cell-type-specific differences in FN expression and its assembly into fibrils exist between these two cell types. Together, our data demonstrate that sdc1 functions to regulate integrin activity in multiple cell types. Loss of sdc1-mediated integrin function results in cell-type specific differences in matrix assembly. A better understanding of how different cell types regulate FN fibril formation via syndecans and integrins will lead to better treatments for scarring and fibrosis.
角膜瘢痕是全球范围内导致失明的主要原因,其可归因于异常数量的胶原蛋白纤维的沉积,这些胶原蛋白纤维缺乏产生透明角膜所需的正确大小和间距。胶原蛋白纤维的形成需要预先形成的纤连蛋白 (FN) 基质。我们证明,角膜基质细胞 (CSC) 中 syndecan1 (sdc1) 的缺失会影响细胞迁移率、焦点和纤维状黏附的大小和组成、整合素的激活以及纤连蛋白组装成纤维。sdc1 缺失的 CSC 中整合素和纤连蛋白的表达没有改变。使用与 FN 和胶原蛋白 I (CNI) 或 vitronectin (VN) 的低浓度与高浓度相比,以及在整合素被氯化锰激活与不激活的情况下,对 sdc1 缺失的 CSC 进行细胞黏附、铺展和迁移研究,结果表明 sdc1 耗尽对整合素激活的影响因评估的整合素介导的活性而异。sdc1 缺失的 CSC 中 FN 原纤维形成和迁移的差异通过添加氯化锰得到逆转,但细胞铺展差异仍然存在。为了确定我们在 sdc1 上的发现是否仅限于角膜,我们比较了 sdc1 缺失的真皮成纤维细胞与 CSC 的表型。我们发现,没有 sdc1,两种细胞类型的迁移速度都更快;然而,这两种细胞类型之间存在 FN 表达及其组装成纤维的细胞类型特异性差异。总之,我们的数据表明 sdc1 可调节多种细胞类型中的整合素活性。sdc1 介导的整合素功能丧失会导致基质组装出现细胞类型特异性差异。更好地了解不同细胞类型如何通过 syndecans 和整合素调节 FN 原纤维形成,将导致针对瘢痕和纤维化的更好治疗方法。