Background <p>Osteonecrosis of the femoral head (ONFH) is a progressive orthopedic disorder that often culminates in femoral head collapse and joint failure. Dysfunction of bone marrow mesenchymal stem cells (BMSCs), including impaired osteogenesis, enhanced adipogenesis, and mitochondrial dysfunction, has been increasingly recognized as a central driver of ONFH pathogenesis. However, the molecular mechanisms linking metabolic stress to lineage imbalance remain poorly defined.</p> Methods <p>Paired BMSCs were isolated from necrotic femoral head regions (fhBMSCs) and the iliac crest (iBMSCs) of ONFH patients. Functional assays, RNA sequencing, and molecular analyses were performed to evaluate the effects of the hypoxia mimetic dimethyloxalylglycine (DMOG) on osteogenic–adipogenic balance, mitochondrial function, and senescence. Loss-of-function experiments targeting hypoxia-inducible factor-1α (HIF-1α) and Homer3 were conducted to elucidate mechanistic pathways.</p> Results <p>Compared with iBMSCs, fhBMSCs exhibited impaired osteogenesis, enhanced adipogenesis, mitochondrial dysfunction, and increased senescence. DMOG pretreatment restored osteogenic differentiation, suppressed adipogenesis, improved mitochondrial dynamics, reduced oxidative stress, and enhanced bioenergetic metabolism. These protective effects were dependent on HIF-1α stabilization. Transcriptomic profiling identified Homer3 as a downstream negative regulator of HIF-1α. Homer3 was aberrantly upregulated in fhBMSCs but suppressed by DMOG, and its knockdown mimicked the effects of DMOG by promoting osteogenesis, inhibiting adipogenesis, enhancing mitophagy, and restoring mitochondrial function. Conversely, silencing HIF-1α abolished DMOG-mediated benefits and reinstated Homer3 expression.</p> Conclusions <p>This study identifies the HIF-1α/Homer3 axis as a central regulator of lineage balance and mitochondrial homeostasis in ONFH-derived BMSCs. Pharmacological targeting of this pathway with DMOG or related prolyl hydroxylase inhibitors may provide a promising joint-preserving therapeutic strategy for ONFH.</p>

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DMOG pretreatment restores osteogenic–adipogenic balance and mitochondrial function in ONFH BMSCs through the HIF-1α/Homer3 pathway

  • Qiheng Chen,
  • Lingxian Yi,
  • Penghui Nie,
  • Jie Wang,
  • Jing Zhu,
  • Jiang Peng,
  • Tujun Weng

摘要

Background

Osteonecrosis of the femoral head (ONFH) is a progressive orthopedic disorder that often culminates in femoral head collapse and joint failure. Dysfunction of bone marrow mesenchymal stem cells (BMSCs), including impaired osteogenesis, enhanced adipogenesis, and mitochondrial dysfunction, has been increasingly recognized as a central driver of ONFH pathogenesis. However, the molecular mechanisms linking metabolic stress to lineage imbalance remain poorly defined.

Methods

Paired BMSCs were isolated from necrotic femoral head regions (fhBMSCs) and the iliac crest (iBMSCs) of ONFH patients. Functional assays, RNA sequencing, and molecular analyses were performed to evaluate the effects of the hypoxia mimetic dimethyloxalylglycine (DMOG) on osteogenic–adipogenic balance, mitochondrial function, and senescence. Loss-of-function experiments targeting hypoxia-inducible factor-1α (HIF-1α) and Homer3 were conducted to elucidate mechanistic pathways.

Results

Compared with iBMSCs, fhBMSCs exhibited impaired osteogenesis, enhanced adipogenesis, mitochondrial dysfunction, and increased senescence. DMOG pretreatment restored osteogenic differentiation, suppressed adipogenesis, improved mitochondrial dynamics, reduced oxidative stress, and enhanced bioenergetic metabolism. These protective effects were dependent on HIF-1α stabilization. Transcriptomic profiling identified Homer3 as a downstream negative regulator of HIF-1α. Homer3 was aberrantly upregulated in fhBMSCs but suppressed by DMOG, and its knockdown mimicked the effects of DMOG by promoting osteogenesis, inhibiting adipogenesis, enhancing mitophagy, and restoring mitochondrial function. Conversely, silencing HIF-1α abolished DMOG-mediated benefits and reinstated Homer3 expression.

Conclusions

This study identifies the HIF-1α/Homer3 axis as a central regulator of lineage balance and mitochondrial homeostasis in ONFH-derived BMSCs. Pharmacological targeting of this pathway with DMOG or related prolyl hydroxylase inhibitors may provide a promising joint-preserving therapeutic strategy for ONFH.