Abstract
Molecular regulators of osteoclast formation and function are an important area of research due to the central role of osteoclasts in bone resorption. Transcription factors such as MITF are essential for osteoclast generation by regulating expression of the genes required for cellular differentiation and resorptive function. We recently reported that histone deacetylase 7 (HDAC7) binds to and represses the transcriptional activity of MITF in osteoclasts, and that loss of HDAC7 in vitro accelerated osteoclastogenesis. In the current study, we extend this initial observation by showing that conditional deletion of HDAC7 in osteoclasts of mice leads to an in vivo enhancement in osteoclast formation, associated with increased bone resorption and lower bone mass. Expression of multiple MITF target genes is increased in bone marrow derived osteoclast cultures from the HDAC7 knockout mice. Interestingly, multiple regions of the HDAC7 amino-terminus can bind to MITF or exert repressive activity. Moreover, mutation or deletion of the HDAC7 conserved deacetylase catalytic domain had little effect on repressive function. These observations identify HDAC7 in osteoclasts as an important molecular regulator of MITF activity and bone homeostasis, but also highlight a gap in our understanding of exactly how HDAC7 functions as a corepressor.
Highlights
The formation and maintenance of the skeleton is conducted by two cell types- osteoblasts, which build bone, and osteoclasts, which resorb or degrade bone
Toward further testing the importance of MITF-histone deacetylase 7 (HDAC7) interaction, we found that suppression of MITF in cultures of HDAC7 knockout osteoclasts largely corrected the heightened osteoclast formation caused by HDAC7 deletion
Hdac7flox/+; LysM-Cre males and Hdac7flox/+ females from the initial cross or from subsequent generations were mated to generate +/+; LysM-Cre mice designated as wild type (WT), Hdac7flox/+; LysM-Cre designated as conditional heterozygotes (HET) and Hdac7flox/HDAC7flox; LysM-Cre designated as conditional knockouts (KO)
Summary
The formation and maintenance of the skeleton is conducted by two cell types- osteoblasts, which build bone, and osteoclasts, which resorb or degrade bone. Coordinated local and systemic changes to their relative activities are responsible for increased bone formation during physiological bone growth and modeling, and proper responses to mechanical stresses or trauma. Unbalanced osteoclast formation or activity leads to pathological bone loss in many conditions. Understanding the molecular regulators that control osteoclast differentiation or resorptive function is important in the development of new diagnostic or therapeutic strategies to manage pathological bone destruction.
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