Bone remodeling is performed by osteoclasts and osteoblasts at the bone surface. Inside of bone is a network of numerous osteocytes, whose specific function has remained an enigma. Here we describe a transgenic mouse model in which inducible and specific ablation of osteocytes is achieved in vivo through targeted expression of diphtheria toxin (DT) receptor. Following a single injection of DT, approximately 70%-80% of the osteocytes, but apparently no osteoblasts, were killed. Osteocyte-ablated mice exhibited fragile bone with intracortical porosity and microfractures, osteoblastic dysfunction, and trabecular bone loss with microstructural deterioration and adipose tissue proliferation in the marrow space, all of which are hallmarks of the aging skeleton. Strikingly, these "osteocyte-less" mice were resistant to unloading-induced bone loss, providing evidence for the role of osteocytes in mechanotransduction. Thus, osteocytes represent an attractive target for the development of diagnostics and therapeutics for bone diseases, such as osteoporosis.
The mammalian Chk2 kinase is thought to mediate ATM‐dependent signaling in response to DNA damage. The physiological role of mammalian Chk2 has now been investigated by the generation of Chk2‐deficient mice. Although Chk2−/− mice appeared normal, they were resistant to ionizing radiation (IR) as a result of the preservation of splenic lymphocytes. Thymocytes and neurons of the developing brain were also resistant to IR‐induced apoptosis. The IR‐induced G1/S cell cycle checkpoint, but not the G2/M or S phase checkpoints, was impaired in embryonic fibroblasts derived from Chk2−/− mice. IR‐induced stabilization of p53 in Chk2−/− cells was 50–70% of that in wild‐type cells. Caffeine further reduced p53 accumulation, suggesting the existence of an ATM/ATR‐dependent but Chk2‐independent pathway for p53 stabilization. In spite of p53 protein stabilization and phosphorylation of Ser23, p53‐dependent transcriptional induction of target genes, such as p21 and Noxa, was not observed in Chk2−/− cells. Our results show that Chk2 plays a critical role in p53 function in response to IR by regulating its transcriptional activity as well as its stability.
Osteoclasts are acid-secreting polykaryons that have high energy demands and contain abundant mitochondria. How mitochondrial biogenesis is integrated with osteoclast differentiation is unknown. We found that the transcription of Ppargc1b, which encodes peroxisome proliferator-activated receptor-gamma coactivator 1beta (PGC-1beta), was induced during osteoclast differentiation by cAMP response element-binding protein (CREB) as a result of reactive oxygen species. Knockdown of Ppargc1b in vitro inhibited osteoclast differentiation and mitochondria biogenesis, whereas deletion of the Ppargc1b gene in mice resulted in increased bone mass due to impaired osteoclast function. We also observed defects in PGC-1beta-deficient osteoblasts. Owing to the heightened iron demand in osteoclast development, transferrin receptor 1 (TfR1) expression was induced post-transcriptionally via iron regulatory protein 2. TfR1-mediated iron uptake promoted osteoclast differentiation and bone-resorbing activity, associated with the induction of mitochondrial respiration, production of reactive oxygen species and accelerated Ppargc1b transcription. Iron chelation inhibited osteoclastic bone resorption and protected against bone loss following estrogen deficiency resulting from ovariectomy. These data establish mitochondrial biogenesis orchestrated by PGC-1beta, coupled with iron uptake through TfR1 and iron supply to mitochondrial respiratory proteins, as a fundamental pathway linked to osteoclast activation and bone metabolism.
Phosphorylation of IkappaB by the IkappaB kinase (IKK) complex is a critical step leading to IkappaB degradation and activation of transcription factor NF-kappaB. The IKK complex contains two catalytic subunits, IKKalpha and IKKbeta, the latter being indispensable for NF-kappaB activation by pro-inflammatory cytokines. Although IKK is activated by phosphorylation of the IKKbeta activation loop, the physiological IKK kinases that mediate responses to extracellular stimuli remain obscure. Here we describe an IKK-related kinase, named NAK (NF-kappaB-activating kinase), that can activate IKK through direct phosphorylation. NAK induces IkappaB degradation and NF-kappaB activity through IKKbeta. Endogenous NAK is activated by phorbol ester tumour promoters and growth factors, whereas catalytically inactive NAK specifically inhibits activation of NF-kappaB by protein kinase C-epsilon (PKCepsilon). Thus, NAK is an IKK kinase that may mediate IKK and NF-kappaB activation in response to growth factors that stimulate PKCepsilon activity.
Members of the Foxo family, Foxo1 (Fkhr), Foxo3 (Fkhrl1), and Foxo4 (Afx), are mammalian homologs of daf-16, which influences life span and energy metabolism in Caenorhabditis elegans. Mammalian FOXO proteins also play important roles in cell cycle arrest, apoptosis, stress resistance, and energy metabolism. In this study, we generated Foxo1-deficient mice to investigate the physiological role of FOXO1. The Foxo1-deficient mice died around embryonic day 11 because of defects in the branchial arches and remarkably impaired vascular development of embryos and yolk sacs. In vitro differentiation of embryonic stem cells demonstrated that endothelial cells derived from wild-type and Foxo1-deficient embryonic stem cells were able to produce comparable numbers of colonies supported by a layer of OP9 stromal cells. Although the morphology of the endothelial cell colonies was identical in both genotypes in the absence of exogenous vascular endothelial growth factor (VEGF), Foxo1-deficient endothelial cells showed a markedly different morphological response compared with wild-type endothelial cells in the presence of exogenous VEGF. These results suggest that Foxo1 is essential to the ability of endothelial cells to respond properly to a high dose of VEGF, thereby playing a critical role in normal vascular development.
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