Homeobox genes d11–d13 and a13 control mouse autopod cortical bone and joint formation
Pablo Villavicencio-Lorini, … , Jochen Hecht, Stefan Mundlos
Pablo Villavicencio-Lorini, … , Jochen Hecht, Stefan Mundlos
Published May 10, 2010
Citation Information: J Clin Invest. 2010;120(6):1994-2004. https://doi.org/10.1172/JCI41554.
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Homeobox genes d11–d13 and a13 control mouse autopod cortical bone and joint formation

Abstract

The molecular mechanisms that govern bone and joint formation are complex, involving an integrated network of signaling pathways and gene regulators. We investigated the role of Hox genes, which are known to specify individual segments of the skeleton, in the formation of autopod limb bones (i.e., the hands and feet) using the mouse mutant synpolydactyly homolog (spdh), which encodes a polyalanine expansion in Hoxd13. We found that no cortical bone was formed in the autopod in spdh/spdh mice; instead, these bones underwent trabecular ossification after birth. Spdh/spdh metacarpals acquired an ovoid shape and developed ectopic joints, indicating a loss of long bone characteristics and thus a transformation of metacarpals into carpal bones. The perichondrium of spdh/spdh mice showed abnormal morphology and decreased expression of Runt-related transcription factor 2 (Runx2), which was identified as a direct Hoxd13 transcriptional target. Hoxd11–/–Hoxd12–/–Hoxd13–/– triple-knockout mice and Hoxd13–/–Hoxa13+/– mice exhibited similar but less severe defects, suggesting that these Hox genes have similar and complementary functions and that the spdh allele acts as a dominant negative. This effect was shown to be due to sequestration of other polyalanine-containing transcription factors by the mutant Hoxd13 in the cytoplasm, leading to their degradation. These data indicate that Hox genes not only regulate patterning but also directly influence bone formation and the ossification pattern of bones, in part via Runx2.

Authors

Pablo Villavicencio-Lorini, Pia Kuss, Julia Friedrich, Julia Haupt, Muhammed Farooq, Seval Türkmen, Denis Duboule, Jochen Hecht, Stefan Mundlos

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Figure 2

Abnormal perichondrium in spdh/spdh mice.

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Abnormal perichondrium in spdh/spdh mice. (A) Immunohistochemistry o...
(A) Immunohistochemistry of WT and spdh forelimbs at E13.5. Hoxd13 protein (green) shows abnormal distribution and reduced amount in spdh/spdh mice. Lower panel shows magnification without DAPI merge. Original magnification, ×200 (lower panels). (B) Morphology of perichondrial regions at E14.5 in WT and spdh/spdh mice (Nomarski interference contrast). Chondrocytes of spdh/spdh mice show no apparent orientation, and the flattened perichondrial cells are missing. (C) Immunolocalization and (D) in situ hybridization of Col1a1 on sections of WT and spdh/spdh metacarpals at E13.5. Col1 protein as well as mRNA is greatly reduced in mutants. Magnifications shown in the lower panel. (E) In situ hybridizations of perichondrially expressed genes Wnt5a, Crabp1, and Tsp2 at E14.5 in WT and spdh/spdh metacarpals. Note strong downregulation in spdh/spdh animals. Panels show a higher magnification of the perichondrium. Original magnification, ×400 (panels); ×1000 (insets). (F) Expression of WT but not mutant Hoxd13 in chMM results in the upregulation of perichondrially expressed genes Col1a1, Wnt5a, Postn, Crabp1, and Tsp2. Fold change values are referred to control for each gene. Data represent mean ± SD.