Abstract
Nonshivering thermogenesis is essential for mammals to maintain body temperature. According to the canonical view, temperature is sensed by cutaneous thermoreceptors and nerve impulses transmitted to the hypothalamus, which generates sympathetic signals to ß-adrenergic receptors in brown adipocytes. The energy for heat generation is primarily provided by the oxidation of fatty acids derived from triglyceride hydrolysis and cellular uptake. Fatty acids also activate the uncoupling protein, UCP1, which creates a proton leak that uncouples mitochondrial oxidative phosphorylation from ATP production, resulting in energy dissipation as heat. Recent evidence supports the idea that in response to mild cold, ß-adrenergic signals stimulate not only lipolysis and fatty acid oxidation, but also act through the mTORC2-Akt signaling module to stimulate de novo lipogenesis. This opposing anabolic effect is thought to maintain lipid fuel stores during increased catabolism. We show here, using brown fat-specific Gs-alpha knockout mice and cultured adipocytes that, unlike mild cold, severe cold directly cools brown fat and bypasses ß-adrenergic signaling to inhibit mTORC2. This cell-autonomous effect both inhibits lipogenesis and augments UCP1 expression to enhance thermogenesis. These findings suggest a novel mechanism for overriding ß-adrenergic-stimulated anabolic activities while augmenting catabolic activities to resolve the homeostatic crisis presented by severe cold.
Highlights
Research into the signaling mechanisms that mediate the effects of ambient temperature on brown fat metabolism has focused primarily on the role of the sympathetic nervous system (SNS), which acts through catecholamine-activated ß-adrenergic receptors to stimulate G-protein alpha-S (Gs-alpha; gene name, Gnas)-dependent activation of adenylyl cyclase, increase cellular cAMP levels, and activate protein kinase A (PKA) [9]
It is well established that BAT—like white adipose tissue—responds to anabolic signals, which act through the mTORC2-Akt signaling module to phosphorylate and activate ATP-citrate lyase (ACLY), a key enzyme in de novo lipogenesis (DNL)
The interscapular brown adipose tissue (iBAT) response to severe cold was biphasic over time, with an initial rapid increase in Akt/pS473 and ACLY/pS455, followed by marked inhibition beginning at 30–60 min (Fig. S1, F–H). p-PKA substrate levels increased rapidly and remained elevated even as Akt/pS473 and ACLY/ pS455 were inhibited (Fig. S1, F, L, and M)
Summary
Divergent effects of mild and severe cold on mTORC2 signaling in response to BAT temperature Direct comparison of mild and severe cold at a fixed time (1 h) further confirmed that the temperature responses of Akt/pS473 and ACLY/ pS455 were biphasic, as well (Fig. 1, G–I).
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