HIF1 activation safeguards cortical bone formation against impaired oxidative phosphorylation
Mohd P. Khan, … , Deanne Taylor, Ernestina Schipani
Mohd P. Khan, … , Deanne Taylor, Ernestina Schipani
Published August 1, 2024
Citation Information: JCI Insight. 2024;9(18):e182330. https://doi.org/10.1172/jci.insight.182330.
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Research Article Bone biology

HIF1 activation safeguards cortical bone formation against impaired oxidative phosphorylation

Abstract

Energy metabolism, through pathways such as oxidative phosphorylation (OxPhos) and glycolysis, plays a pivotal role in cellular differentiation and function. Our study investigates the impact of OxPhos disruption in cortical bone development by deleting mitochondrial transcription factor A (TFAM). TFAM controls OxPhos by regulating the transcription of mitochondrial genes. The cortical bone, constituting the long bones’ rigid shell, is sheathed by the periosteum, a connective tissue layer populated with skeletal progenitors that spawn osteoblasts, the bone-forming cells. TFAM-deficient mice presented with thinner cortical bone, spontaneous midshaft fractures, and compromised periosteal cell bioenergetics, characterized by reduced ATP levels. Additionally, they exhibited an enlarged periosteal progenitor cell pool with impaired osteoblast differentiation. Increasing hypoxia-inducible factor 1a (HIF1) activity within periosteal cells substantially mitigated the detrimental effects induced by TFAM deletion. HIF1 is known to promote glycolysis in all cell types. Our findings underscore the indispensability of OxPhos for the proper accrual of cortical bone mass and indicate a compensatory mechanism between OxPhos and glycolysis in periosteal cells. The study opens new avenues for understanding the relationship between energy metabolism and skeletal health and suggests that modulating bioenergetic pathways may provide a therapeutic avenue for conditions characterized by bone fragility.

Authors

Mohd P. Khan, Elena Sabini, Katherine Beigel, Giulia Lanzolla, Brittany Laslow, Dian Wang, Christophe Merceron, Amato Giaccia, Fanxin Long, Deanne Taylor, Ernestina Schipani

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Figure 6

HIF1dPA largely corrects the cortical bone defects observed in TFAM mutant mice.

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HIF1dPA largely corrects the cortical bone defects observed in TFAM muta...
(A) H&E staining of longitudinal paraffin sections of p21 tibias, illustrating cortical bone at midshaft. Scale bar: 100 μm. (B) TRAP staining of longitudinal paraffin sections of p21 tibias. Scale bar: 100 μm. (C) Static histomorphometry analysis conducted on longitudinal paraffin sections of p21 tibias, quantifying cortical thickness (Ct.Th), number of periosteal osteoblast-like cells (Ps.N.Ob-like), osteoblast-like cells per bone surface (Ps.N.Ob-like/BS), number of periosteal osteoclasts (Ps.N.Oc), and osteoclast-to-bone surface ratio (Ps.N.Oc/BS). (D) Calcein labeling in transverse MMA sections of p21 tibias isolated, depicting cortical bone at midshaft. Scale bar: 200 μm. (E) Goldner’s trichrome staining of longitudinal MMA sections of p21 tibias, showing cortical bone at midshaft. White arrows indicate the presence of osteoid. Scale bar: 100 μm. (F) Dynamic histomorphometry analysis performed on transverse MMA sections of p21 tibias, quantifying periosteal double-labeled surface (Ps.dL.PM), mineralizing surface over bone surface (Ps.MS/BS), mineral apposition rate (Ps.MAR), bone formation rate over bone surface (Ps.BFR/BS), and osteoid accumulation (Ps.OS/BS). (G and H) RNAScope analysis conducted on longitudinal paraffin sections of p21 tibias, demonstrating cortical bone at midshaft. The levels of expression of Bglap (G) and Spp1 (H) mRNAs were investigated, with quantification of the signal provided in both periosteum and endosteum. Evaluations included a minimum of 5 mice per group for both mutants and their respective CTRL littermates. Scale bar: 100 μm. Data are presented as mean ± SD. Student’s 2-tailed t test was performed for statistical comparison. *P ≤ 0.05, **P ≤ 0.01.