Proliferation of synovial Mesenchymal Stromal/Stem Cells (MSCs) leads to synovial hyperplasia (SH) following Joint Surface Injury (JSI). Uncontrolled Yap activity causes tissue overgrowth due to modulation of MSC proliferation. We hypothesised that YAP plays a role in SH following JSI. A spatiotemporal analysis of Yap expression was performed using the JSI model in C57Bl/6 mice. Synovial samples from patients were similarly analysed. Gdf5-Cre;Yap1fl/fl;Tom mice were created to determine the effect YAP1 knockout in Gdf5 lineage cells on SH after JSI. In patients, Yap expression was upregulated in activated synovium, including a subset of CD55 positive fibroblast-like synoviocytes in the synovial lining (SL). Cells staining positive for the proliferation marker Ki67 expressed active YAP. In mice, Yap was highly expressed in injured knee joint synovium compared to controls. Yap mRNA levels at 2 (p<0.05) and 8 days (p<0.001) after injury were increased. Conditional Yap1 knockout in Gdf5 progeny cells prevented hyperplasia of synovial lining (SL) after JSI. Cellularity was significantly decreased in the SL but not in the sub-lining of injured Yap1 knockout- compared to control mice. The percentage of cells in synovium that were Tom+ increased in response to JSI in control and haplo-insufficient but not in YAP1 knockout mice (p<0.05). Modulation of YAP and proliferation of MSCs in the synovium after JSI provides a system to study the role of SH after trauma in re-establishing joint homeostasis and is a potential novel therapeutic target for the treatment of post traumatic OA

Improving periprosthetic bone is essential for implant fixation and reducing peri-implant fracture risk. This studied examined the individual and combined effects of iPTH and mechanical loading at the cellular, molecular, and tissue level for periprosthetic cancellous bone. Adult rabbits had a porous titanium implant inserted bilaterally on the cancellous bone beneath a mechanical loading device on the distal lateral femur. The right femur was loaded daily, the left femur received a sham loading device, and half of the rabbits received daily PTH. Periprosthetic bone was processed up to 28 days for qPCR, histology, and uCT analysis. We observed an increase in cellular and molecular markers of osteoblast activity and decrease in adipocytic markers for both treatments, with small additional effects in the combined group. Loading and iPTH led to a decrease and increase, respectively, in osteoclast number, acting through changes in RANKL/OPG expression. Changes in SOST and beta-catenin mRNA levels suggested an integral role for the Wnt pathway. We observed strong singular effects on BV/TV of both loading (1.53 fold) and iPTH (1.54 fold). Combined treatment showed a small additive effect on bone volume. In conclusion, loading and iPTH act through a pro-osteoblastic/anti-adipocytic response and through control of bone turnover via changes in the RANKL/OPG pathway. These changes led to a small additional, but not synergistic, increase in bone volume with the combined therapy