Abstract
Brown adipose tissue (BAT) plays critical thermogenic, metabolic and endocrine roles in mammals, and aberrant BAT function is associated with metabolic disorders including obesity and diabetes. The major BAT depots are clustered at the neck and forelimb levels, and arise largely within the dermomyotome of somites, from a common progenitor with skeletal muscle. However, many aspects of BAT embryonic development are not well understood. Hoxa5 patterns other tissues at the cervical and brachial levels, including skeletal, neural and respiratory structures. Here, we show that Hoxa5 also positively regulates BAT development, while negatively regulating formation of epaxial skeletal muscle. HOXA5 protein is expressed in embryonic preadipocytes and adipocytes as early as embryonic day 12.5. Hoxa5 null mutant embryos and rare, surviving adults show subtly reduced iBAT and sBAT formation, as well as aberrant marker expression, lower adipocyte density and altered lipid droplet morphology. Conversely, the epaxial muscles that arise from a common dermomyotome progenitor are expanded in Hoxa5 mutants. Conditional deletion of Hoxa5 with Myf5/Cre can reproduce both BAT and epaxial muscle phenotypes, indicating that HOXA5 is necessary within Myf5-positive cells for proper BAT and epaxial muscle development. However, recombinase-based lineage tracing shows that Hoxa5 does not act cell-autonomously to repress skeletal muscle fate. Interestingly, Hoxa5-dependent regulation of adipose-associated transcripts is conserved in lung and diaphragm, suggesting a shared molecular role for Hoxa5 in multiple tissues. Together, these findings establish a role for Hoxa5 in embryonic BAT development.
Highlights
Brown adipose tissue (BAT) mediates non-shivering thermogenesis in mammals
At E14.5, HOXA5 protein was highly expressed throughout BAT when the latter first becomes morphologically distinct from epaxial muscle (Figure 1A)
Hoxa5 Plays a Non-redundant Role in BAT Development
Summary
Brown adipose tissue (BAT) mediates non-shivering thermogenesis in mammals It is an endocrine and immune organ that regulates metabolism and lipid storage both via endocrine and paracrine signaling, and through its own high metabolic activity (Jung et al, 2019). BAT is highly vascularized, permitting high oxygen levels necessary for its metabolic activity and facilitating rapid heat transfer through the circulation This non-shivering form of thermogenesis is critical for temperature regulation in most mammals, including in human infants. Communication between BAT and white adipose tissue (WAT), in part through insulin signaling, has been linked to obesity in human adults, and WAT can undergo conversion to BAT under cold stress and adrenergic stimulation, a phenomenon known as browning (Srivastava and Veech, 2019) For these reasons, BAT has become a target of investigation for therapies to treat obesity, diabetes, and other metabolic syndromes
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