The p38 MAPK pathway is essential for skeletogenesis and bone homeostasis in mice
Matthew B. Greenblatt, … , Roger Davis, Laurie H. Glimcher
Matthew B. Greenblatt, … , Roger Davis, Laurie H. Glimcher
Published June 14, 2010
Citation Information: J Clin Invest. 2010;120(7):2457-2473. https://doi.org/10.1172/JCI42285.
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Research Article Bone biology

The p38 MAPK pathway is essential for skeletogenesis and bone homeostasis in mice

Abstract

Nearly every extracellular ligand that has been found to play a role in regulating bone biology acts, at least in part, through MAPK pathways. Nevertheless, much remains to be learned about the contribution of MAPKs to osteoblast biology in vivo. Here we report that the p38 MAPK pathway is required for normal skeletogenesis in mice, as mice with deletion of any of the MAPK pathway member–encoding genes MAPK kinase 3 (Mkk3), Mkk6, p38a, or p38b displayed profoundly reduced bone mass secondary to defective osteoblast differentiation. Among the MAPK kinase kinase (MAP3K) family, we identified TGF-β–activated kinase 1 (TAK1; also known as MAP3K7) as the critical activator upstream of p38 in osteoblasts. Osteoblast-specific deletion of Tak1 resulted in clavicular hypoplasia and delayed fontanelle fusion, a phenotype similar to the cleidocranial dysplasia observed in humans haploinsufficient for the transcription factor runt-related transcription factor 2 (Runx2). Mechanistic analysis revealed that the TAK1–MKK3/6–p38 MAPK axis phosphorylated Runx2, promoting its association with the coactivator CREB-binding protein (CBP), which was required to regulate osteoblast genetic programs. These findings reveal an in vivo function for p38β and establish that MAPK signaling is essential for bone formation in vivo. These results also suggest that selective p38β agonists may represent attractive therapeutic agents to prevent bone loss associated with osteoporosis and aging.

Authors

Matthew B. Greenblatt, Jae-Hyuck Shim, Weiguo Zou, Despina Sitara, Michelle Schweitzer, Dorothy Hu, Sutada Lotinun, Yasuyo Sano, Roland Baron, Jin Mo Park, Simon Arthur, Min Xie, Michael D. Schneider, Bo Zhai, Steven Gygi, Roger Davis, Laurie H. Glimcher

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Figure 3

Impaired Runx2 activity in the absence of TAK1.

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Impaired p38 MAPK pathway activation in TAK1-deficient osteoblasts. (A) ...
(A) Primary CalvOb were isolated from Tak1fl/fl and Tak1osx pups, infected with vector, Myc-Runx2, or WT TAK1-expressing lentiviruses, and cultured for 6 days under differentiation conditions. Expression of Myc-Runx2 (upper) and TAK1 (lower) was analyzed by immunoblotting with anti-Myc antibody and quantitative PCR. (B and C) CalvOb expressing Myc-Runx2 or WT TAK1 were cultured for 6 days under differentiation conditions and ALP activity was analyzed by colorimetric assay (B) and Fast Blue staining (C). Original magnification, ×25. Values are mean + SD. (D) Primary CalvOb were isolated from Tak1fl/fl and Tak1osx pups, infected with vector or Myc-Runx2–expressing lentiviruses, and cultured for 6 days under differentiation conditions. Quantitative PCR analysis was performed for the indicated genes. (E) Tak1fl/fl CalvOb were infected by vector or cre lentivirus together with Myc-Runx2–expressing lentivirus. 2 days after transduction, cells were transfected with OG2-luc and Renilla luciferase vectors; 6 days later, luciferase activity was determined. Results were normalized to a Renilla control. Expression of Myc-Runx2 was analyzed by immunoblotting with anti-Myc antibody (upper). Values are mean + SD. (F) Tak1fl/fl CalvOb were infected by vector, cre, or TAK1-CI lentivirus as above, transfected with OG2-luciferase, and stimulated with BMP2/7. Results were normalized to a Renilla control. Values are mean + SD.