Biomechanics Research Today is a free monthly online journal that collates and summarizes the latest research about Biomechanics, including details on mechanics of living organisms, movement, locomotion, prosthetic limbs.

Skeletal unloading induces osteoblast apoptosis and targets alpha5beta1-PI3K-Bcl-2 signaling in rat bone.

Dufour C, Holy X, Marie PJ

Unit 606 INSERM, Laboratory of Osteoblast Biology and Pathology, University Paris 7, France.

The mechanisms underlying the altered osteoblastogenesis and bone loss in response to disuse are incompletely understood. Using the rat tail suspension model, we studied the effect of skeletal unloading on osteoblast and osteocyte apoptosis. Tail suspension for 2 to 7 days decreased tibial bone mass and induced early apoptotic loss of osteoblasts and delayed apoptotic loss of osteocytes. Surrenal gland weight and plasma corticosterone levels did not differ in loaded and unloaded rats at any time point, indicating that osteoblast/osteocyte apoptosis occurred independently of endogenous glucocorticoids. The mechanistic basis for the disuse-induced osteoblast/osteocyte apoptosis was examined. We found that alpha5beta1 integrin and phosphorylated phosphatidyl-inositol-3 kinase (p-PI3K) protein levels were transiently decreased in unloaded metaphyseal long bone compared to loaded bones. In contrast, p-FAK and p-ERK p42/44 levels were not significantly altered. Interestingly, the reduced p-PI3K levels in unloaded long bone was associated with decreased levels of the survival protein Bcl-2 with unaltered Bax levels, causing increased Bax/Bcl-2 levels. The results indicate that skeletal unloading in rats induces a glucocorticoid-independent, immediate increase in osteoblast apoptosis associated with decreased alpha5beta1-PI3K-Bcl-2 survival pathway in rat bone, which may contribute to the altered osteoblastogenesis and osteopenia induced by unloading.

Published 12 January 2007 in Exp Cell Res, 313(2): 394-403.
Full-text of this article is available online (may require subscription).

© 2005-2008 Biomechanics Research Today. All Rights Reserved.