Matrix remodeling associated 7 proteins promote cutaneous wound healing through vimentin in coordinating fibroblast functions

Wound healing depends largely on the remodeling of the extracellular matrix around and reorganization of tissue-resident cells. Matrix remodeling associated 7 (MXRA7) is a member of the matrix remodeling-associated gene family and is involved in matrix remodeling-associated processes, such as inflammatory neovascularization, liver injury, and autoimmune skin disease. To investigate whether and how MXRA7 participate in cutaneous wound healing, an ear-punching model was utilized in wild-type (WT) and MXRA7-deficient mice, and the dermal fibroblasts from these mice were further studied in vitro. Results showed that the MXRA7 deficiency impaired the wound healing process in mice. Quantitative PCR indicated that lack of MXRA7 impaired the expression of several extracellular matrix genes (e.g., MMP-2) and inhibited signaling pathways (e.g., STAT3) in healing ear tissues. In in vitro culture system, migration, contraction, or proliferation of fibroblasts was impaired upon MXRA7 deficiency. Pull-down and mass spectrum assay revealed that vimentin was among the proteins that bound MXRA7 proteins in cells, and further investigations indicate MXRA7 was an autocrine factor in fibroblasts that involved vimentin in certain ways, such as JNK and STAT3/STAT5 signaling pathways in our study. In conclusion, MXRA7 proteins promote wound healing through vimentin in coordinating fibroblast functions.

Automated summary

MXRA7 is involved in cutaneous wound healing process, and its deficiency impairs wound healing. Lack of MXRA7 impairs the expression of extracellular matrix genes (such as MMP-2) and inhibits signaling pathways (such as STAT3) in healing tissues. In vitro studies also showed that MXRA7 deficiency affects fibroblast migration, contraction, and proliferation. Further investigations revealed that MXRA7 interacts with vimentin and regulates fibroblast functions through signaling pathways like JNK and STAT3/STAT5.