The hypoxia-inducible factor α pathway couples angiogenesis to osteogenesis during skeletal development

Wang, Ying; Wan, Chao; Deng, Lianfu; Liu, Ximeng; Cao, Xuemei; Gilbert, Shawn R.; Bouxsein, Mary L.; Faugère, Marie-Claude; Guldberg, Robert E.; Gerstenfeld, Louis C.; Haase, Volker H.; Johnson, Randall S.; Schipani, Ernestina; Clemens, Thomas L.

doi:10.1172/jci31581

Cited by 628 publications

(744 citation statements)

References 43 publications

(45 reference statements)

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“…Bone formation is coupled with angiogenesis (22)(23)(24). Angiographic images of microphil-perfused femora were performed to analyze the effects of irradiation on bone marrow vasculatures.…”

Section: Resultsmentioning

confidence: 99%

Irradiation induces bone injury by damaging bone marrow microenvironment for stem cells

Cao¹,

Frassica

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

218

200

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Radiation therapy can result in bone injury with the development of fractures and often can lead to delayed and nonunion of bone. There is no prevention or treatment for irradiation-induced bone injury. We irradiated the distal half of the mouse left femur to study the mechanism of irradiation-induced bone injury and found that no mesenchymal stem cells (MSCs) were detected in irradiated distal femora or nonirradiated proximal femora. The MSCs in the circulation doubled at 1 week and increased fourfold after 4 wk of irradiation. The number of MSCs in the proximal femur quickly recovered, but no recovery was observed in the distal femur. The levels of free radicals were increased threefold at 1 wk and remained at this high level for 4 wk in distal femora, whereas the levels were increased at 1 wk and returned to the basal level at 4 wk in nonirradiated proximal femur. Free radicals diffuse ipsilaterally to the proximal femur through bone medullary canal. The blood vessels in the distal femora were destroyed in angiographic images, but not in the proximal femora. The osteoclasts and osteoblasts were decreased in the distal femora after irradiation, but no changes were observed in the proximal femora. The total bone volumes were not affected in proximal and distal femora. Our data indicate that irradiation produces free radicals that adversely affect the survival of MSCs in both distal and proximal femora. Irradiation injury to the vasculatures and the microenvironment affect the niches for stem cells during the recovery period.

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Section: Resultsmentioning

confidence: 99%

Irradiation induces bone injury by damaging bone marrow microenvironment for stem cells

Cao¹,

Frassica

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

218

200

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“…12 Wang et al showed that HIFa promotes angiogenesis and osteogenesis by elevating VEGF levels in osteoblasts. 13 In addition, VEGF has been shown to induce angiogenesis in many in vivo models. Increased VEGF mRNA expression has been shown in membranous bone fracture healing in vivo and in isolated osteoblasts stimulated by indirect and direct angiogenic growth factors in vitro.…”

Section: Discussionmentioning

confidence: 99%

Evaluating effects of deferoxamine in a rat tibia critical bone defect model

Grewal

Keller²,

Weinhold

et al. 2014

Journal of Orthopaedics

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a b s t r a c tObjectives: Evaluate the use of deferoxamine in a calcium sulfate carrier to promote fracture healing in a critical bone defect model.Methods: 43 female retired breeders were divided randomly into Control, Carrier, DFO and BMP groups and appropriate agents placed at the osteotomy site.Results: There was a significant difference in the mean gap between groups Control vs DFO and Control vs BMP. A higher mean number of cortices were bridged in the DFO group as compared to the Control group.Conclusions: Our study demonstrated that DFO helped reduce the gap in this critical tibia defect.

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“…Connective tissue Wang et al 92 OC (osteocalcin) Osteoblasts Bone modeling is increased within the first week of life but appears to decline at latter stages of development; extremely dense, heavily vascularized long bones; progressively increased vessel numbers with age; trabecular separation reduced; no detectable changes in calvarial bone morphology; upregulation of HIF-1 and HIF-2 and VEGF, serum level of VEGF was not elevated; conversely, inactivation of HIF-1a in the osteoblast produced the reverse phenotype, that is, thinner and less vascularized bones Pfander et al 69 ColII (collagen II) Growth plate/ chondrocytes…”

Section: Albuminmentioning

confidence: 99%

The VHL tumor suppressor and HIF: insights from genetic studies in mice

2008

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The von Hippel-Lindau tumor suppressor gene product, pVHL, functions as the substrate recognition component of an E3-ubiquitin ligase, which targets the oxygen-sensitive a-subunit of hypoxia-inducible factor (HIF) for rapid proteasomal degradation under normoxic conditions and as such plays a central role in molecular oxygen sensing. Mutations in pVHL can be found in familial and sporadic clear cell carcinomas of the kidney, hemangioblastomas of the retina and central nervous system, and pheochromocytomas, underscoring its gatekeeper function in the pathogenesis of these tumors. Tissue-specific gene targeting of VHL in mice has demonstrated that efficient execution of pVHL-mediated HIF proteolysis under normoxia is fundamentally important for survival, proliferation, differentiation and normal physiology of many cell types, and has provided novel insights into the biological function of individual HIF transcription factors. In this review, we discuss the role of HIF in the development of the VHL phenotype. Germ-line mutations in the von Hippel-Lindau tumor (VHL) suppressor can be found in patients with VHL disease, a rare familial tumor syndrome characterized by the development of highly vascularized tumors in multiple organs. Major clinical manifestations of VHL disease include hemangioblastomas of the retina and central nervous system (CNS), renal cysts and renal cell carcinoma of the clear cell type (CC-RCC), pancreatic cysts and tumors, as well as pheochromocytomas. 1 The VHL tumor suppressor is also mutated in the majority of sporadic CC-RCCs, 2 highlighting its critical and central role in the regulation of cell growth and differentiation of epithelial kidney cells. Although the molecular function of the VHL gene product, pVHL, was initially not known when it was first identified by positional cloning in 1993, 3 observations that oxygen-dependent regulation of hypoxia-inducible genes was lost in VHL-deficient cell lines suggested a role for pVHL in oxygen sensing. [4][5][6] In a seminal paper, Maxwell et al. 7 showed that pVHL was critical for targeting the a-subunit of hypoxia-inducible factor (HIF) for oxygen-dependent proteolysis, thus providing a direct molecular link between VHLassociated tumorigenesis and oxygen sensing via HIF. HIFs belong to the PAS (Per-arylhydrocarbon receptor nuclear translocator (ARNT)-Sim) family of basic helix-loop-helix (bHLH) transcription factors and bind DNA as heterodimers. They consist of an oxygen-sensitive a-subunit and a constitutively expressed b-subunit, also known as ARNT or HIF-b. pVHL associates with the elongins B and C, cullin2 and Rbx [8][9][10][11][12] and functions as the substrate recognition component of an E3-ubiquitin ligase that ubiquitylates HIF-a. [13][14][15][16][17][18][19] All three HIF a-subunits, HIF-1a, HIF-2a and HIF-3a interact with pVHL. 7,20 This pVHL-HIF-a interaction is highly conserved between species, requires iron-and oxygen-dependent hydroxylation of specific proline residues (Pro402 and Pro564 in human HIF-1a; Pro405 and Pro531 in ...

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The hypoxia-inducible factor α pathway couples angiogenesis to osteogenesis during skeletal development

Cited by 628 publications

References 43 publications

Irradiation induces bone injury by damaging bone marrow microenvironment for stem cells

Irradiation induces bone injury by damaging bone marrow microenvironment for stem cells

Evaluating effects of deferoxamine in a rat tibia critical bone defect model

The VHL tumor suppressor and HIF: insights from genetic studies in mice

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