K J Kelynack1, T D Hewitson, K M Nicholls, I A Darby, G J Becker. 1. Department of Nephrology, Royal Melbourne Hospital, Parkville and. Microvascular Biology and Wound Healing Group, RMIT University, Bundoora, Victoria, Australia.
Abstract
BACKGROUND: Expression of the beta1 family of integrins allows dermal fibroblasts in wounds to contribute to the healing process through migration, adhesion, synthesis, and rearrangement of extracellular matrix. To date the ability of human renal fibroblasts to reorganize collagens and the role of cell surface receptors in this process remain unknown. METHODS: Renal fibroblasts were grown from the cortical tissue of surgically removed human kidneys. The ability of human renal fibroblasts to reorganize interstitial collagen I was examined in vitro using solidified collagen I lattices. Integrin function was blocked by incubating fibroblasts with isotype-specific antibodies prior to addition to collagen I lattices. RESULTS: Human renal fibroblasts embedded in collagen I lattices progressively decreased lattice diameter to 60.6+/-11.4% of initial diameter at 48 h post-release (P:<0.01). Fibroblasts incubated in the presence of antibody to beta1 integrin failed to contract collagen I lattices, whilst fibroblasts incubated with non-specific antibody reduced lattice diameter to 60.1+/-12.4% of initial diameter at 48 h post-release (P:<0.01). Further characterization of integrin alpha subunits showed that blocking alpha2beta1 integrin prevented lattice contraction (P:<0.05, alpha2beta1 integrin antibody vs non-specific antibody), whilst blocking of alpha5beta1, alpha3beta1 and alpha1beta1 integrins did not influence this process. CONCLUSIONS: We postulate that collagen I fibril rearrangement by human renal fibroblasts in vitro appears to be an integrin-mediated process involving the alpha2beta1 integrin.
BACKGROUND: Expression of the beta1 family of integrins allows dermal fibroblasts in wounds to contribute to the healing process through migration, adhesion, synthesis, and rearrangement of extracellular matrix. To date the ability of human renal fibroblasts to reorganize collagens and the role of cell surface receptors in this process remain unknown. METHODS: Renal fibroblasts were grown from the cortical tissue of surgically removed human kidneys. The ability of human renal fibroblasts to reorganize interstitial collagen I was examined in vitro using solidified collagen I lattices. Integrin function was blocked by incubating fibroblasts with isotype-specific antibodies prior to addition to collagen I lattices. RESULTS:Human renal fibroblasts embedded in collagen I lattices progressively decreased lattice diameter to 60.6+/-11.4% of initial diameter at 48 h post-release (P:<0.01). Fibroblasts incubated in the presence of antibody to beta1 integrin failed to contract collagen I lattices, whilst fibroblasts incubated with non-specific antibody reduced lattice diameter to 60.1+/-12.4% of initial diameter at 48 h post-release (P:<0.01). Further characterization of integrin alpha subunits showed that blocking alpha2beta1 integrin prevented lattice contraction (P:<0.05, alpha2beta1 integrin antibody vs non-specific antibody), whilst blocking of alpha5beta1, alpha3beta1 and alpha1beta1 integrins did not influence this process. CONCLUSIONS: We postulate that collagen I fibril rearrangement by human renal fibroblasts in vitro appears to be an integrin-mediated process involving the alpha2beta1 integrin.
Authors: Jonas F Eichinger; Lea J Haeusel; Daniel Paukner; Roland C Aydin; Jay D Humphrey; Christian J Cyron Journal: Biomech Model Mechanobiol Date: 2021-03-08