Microgravity modulation of syncytin-A expression enhance osteoclast formation.

Microgravity (µXg) experienced by astronauts during space flights causes accelerated bone loss. However, the molecular basis of µXg induced bone loss in space is unclear. Osteoclast (OCL) is the primary bone-resorbing cell. We previously demonstrated that simulated µXg promotes OCL formation. In this study, we identified that µXg induces syncytin-A expression in RAW264.7 preosteoclast cells without RANKL stimulation. We further tested the effect of osteotropic factors such as CXCL5 and 1,25(OH)2 D3 to regulate the syncytin-A expression in preosteoclast cells subjected to µXg compared to ground based (Xg) cultures. CXCL5 (25 ng/mL) and 1,25(OH)2 D3 (10 ng/mL) increased syncytin-A expression under Xg conditions. However, µXg alone upregulates syncytin-A expression compared to Xg control preosteoclast cells. Confocal microscopy using Lyso-Tracker identified syncytin-A expression co-localized with lysosomes in preosteoclast cells. Acridine orange staining showed RANKL elevated autophagy activity in these cells. Further, siRNA suppression of syncytin-A significantly inhibits autophagy activity in RAW264.7 cells. In addition, knockdown of syncytin-A expression inhibits µXg increased OCL formation in mouse bone marrow cultures. Thus, our findings suggest that targeting syncytin-A expression may be an effective countermeasure to control bone loss under microgravity conditions.

Inducible knockout of syncytin-a leads to poor placental glucose transport in mice.

INTRODUCTION: Cell-cell fusion of cytotrophoblasts into the syncytiotrophoblast layer is a key process in placental development. Syncytin, an endogenous retroviral envelope protein, is expressed in placental trophoblasts and specifically mediates syncytiotrophoblast layer formation. Syncytin deficiency has been observed in fetal growth-restricted placentas. Abnormal fetal growth, especially fetal growth restriction, is associated with the decreased expression of glucose transporters. Here, we aimed to determine the role of syncytin in fetal growth restriction in placental glucose transport capacity. METHODS: To better explore the function of syncytin in fetal growth-restricted placenta, we generated an inducible knockout mouse model of syncytin-a gene. The expression levels of glucose transporters in BeWo cells were measured before and after HERV-W knockdown. RESULTS: Syncytin-A disruption was associated with significant abnormalities in placental and fetal development in mice. Syncytin-A destruction causes extensive abnormalities in the maternal-fetal exchange structures in the labyrinth, including an extremely reduced number and dramatically irregular distribution of fetal vessels. Moreover, glucose transporter 1, glucose transporters 3, and connexin 26 expression levels decreased after E14.5. Consistently, low glucose transporter 1, glucose transporter 3, and connexin 26 levels were observed in HERV-W-silenced BeWo cells. DISCUSSION: Syncytin-A is crucial for both syncytiotrophoblast layer development and morphogenesis, suggesting that syncytin-A disruption leads to fetal growth restriction associated with abnormalities in the maternal-fetal exchange barrier and decreased glucose transport.