Hox11 Function Is Required for Region-Specific Fracture Repair.

The processes that govern fracture repair rely on many mechanisms that recapitulate embryonic skeletal development. Hox genes are transcription factors that perform critical patterning functions in regional domains along the axial and limb skeleton during development. Much less is known about roles for these genes in the adult skeleton. We recently reported that Hox11 genes, which function in zeugopod development (radius/ulna and tibia/fibula), are also expressed in the adult zeugopod skeleton exclusively in PDGFRα+/CD51+/LepR+ mesenchymal stem/stromal cells (MSCs). In this study, we use a Hoxa11eGFP reporter allele and loss-of-function Hox11 alleles, and we show that Hox11 expression expands after zeugopod fracture injury, and that loss of Hox11 function results in defects in endochondral ossification and in the bone remodeling phase of repair. In Hox11 compound mutant fractures, early chondrocytes are specified but show defects in differentiation, leading to an overall deficit in the cartilage production. In the later stages of the repair process, the hard callus remains incompletely remodeled in mutants due, at least in part, to abnormal bone matrix organization. Overall, our data supports multiple roles for Hox11 genes following fracture injury in the adult skeleton. © 2017 American Society for Bone and Mineral Research.

Hox11 genes regulate postnatal longitudinal bone growth and growth plate proliferation.

Hox genes are critical regulators of skeletal development and Hox9-13 paralogs, specifically, are necessary for appendicular development along the proximal to distal axis. Loss of function of both Hoxa11 and Hoxd11 results in severe malformation of the forelimb zeugopod. In the radius and ulna of these mutants, chondrocyte development is perturbed, growth plates are not established, and skeletal growth and maturation fails. In compound mutants in which one of the four Hox11 alleles remains wild-type, establishment of a growth plate is preserved and embryos develop normally through newborn stages, however, skeletal phenotypes become evident postnatally. During postnatal development, the radial and ulnar growth rate slows compared to wild-type controls and terminal bone length is reduced. Growth plate height is decreased in mutants and premature growth plate senescence occurs along with abnormally high levels of chondrocyte proliferation in the reserve and proliferative zones. Compound mutants additionally develop an abnormal curvature of the radius, which causes significant distortion of the carpal elements. The progressive bowing of the radius appears to result from physical constraint caused by the disproportionately slower growth of the ulna than the radius. Collectively, these data are consistent with premature depletion of forelimb zeugopod progenitor cells in the growth plate of Hox11 compound mutants, and demonstrate a continued function for Hox genes in postnatal bone growth and patterning.