Neuronal hypothalamic regulation of body metabolism and bone density is galanin dependent
Anna Idelevich, … , Francesca Gori, Roland Baron
Anna Idelevich, … , Francesca Gori, Roland Baron
Published March 29, 2018
Citation Information: J Clin Invest. 2018;128(6):2626-2641. https://doi.org/10.1172/JCI99350.
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Research Article Bone biology Metabolism

Neuronal hypothalamic regulation of body metabolism and bone density is galanin dependent

Abstract

In the brain, the ventral hypothalamus (VHT) regulates energy and bone metabolism. Whether this regulation uses the same or different neuronal circuits is unknown. Alteration of AP1 signaling in the VHT increases energy expenditure, glucose utilization, and bone density, yet the specific neurons responsible for each or all of these phenotypes are not identified. Using neuron-specific, genetically targeted AP1 alterations as a tool in adult mice, we found that agouti-related peptide–expressing (AgRP-expressing) or proopiomelanocortin-expressing (POMC-expressing) neurons, predominantly present in the arcuate nucleus (ARC) within the VHT, stimulate whole-body energy expenditure, glucose utilization, and bone formation and density, although their effects on bone resorption differed. In contrast, AP1 alterations in steroidogenic factor 1–expressing (SF1-expressing) neurons, present in the ventromedial hypothalamus (VMH), increase energy but decrease bone density, suggesting that these effects are independent. Altered AP1 signaling also increased the level of the neuromediator galanin in the hypothalamus. Global galanin deletion (VHT galanin silencing using shRNA) or pharmacological galanin receptor blockade counteracted the observed effects on energy and bone. Thus, AP1 antagonism reveals that AgRP- and POMC-expressing neurons can stimulate body metabolism and increase bone density, with galanin acting as a central downstream effector. The results obtained with SF1-expressing neurons, however, indicate that bone homeostasis is not always dictated by the global energy status, and vice versa.

Authors

Anna Idelevich, Kazusa Sato, Kenichi Nagano, Glenn Rowe, Francesca Gori, Roland Baron

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Figure 3

AP1 antagonism increases galanin expression.

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AP1 antagonism increases galanin expression. (A) Microarray and differen...
(A) Microarray and differential gene expression with pathway analysis of ENO2-ΔFosB and control hypothalami (n = 2). (B) Real-time PCR analysis of ENO2-ΔFosB mice hypothalami showing elevated galanin mRNA (n = 3). (C) Real-time PCR analysis of hypothalami from mice in which the VHT was injected with ΔFosB AAV, DNJunD AAV, or GFP AAV, showing elevated galanin mRNA (n = 6) 6 weeks after surgery. (D) Western blot of hypothalami (6 weeks after surgery) from mice in which the VHT was injected with ΔFosB AAV or GFP AAV (n = 3). (E) Real-time PCR analysis of primary hypothalamic neuronal cells isolated from WT C57BL mice and transduced with AP1 AAV (n = 4). (F) Real-time PCR analysis of hypothalami from UFosB mice (no ΔFosB or Δ2ΔFosB splices) showing suppressed galanin mRNA (n = 4). (G) AgRP-CRE (or POMC-CRE) mice were crossed with reporter R26R-Brainbow2.1 mice marking all AgRP neurons with a single, unique color (predominantly red). Recombined mice were then injected in the VHT with GFP-AAV or ΔFosB-AAV (green), and primary hypothalamic neurons were isolated and subjected to FACS sorting using PE-A filter for red fluorescence and FITC-A for green fluorescence. A population displaying both red and green represents AgRP (or POMC) neurons infected with AAV. qPCR analysis showing increased galanin expression by ΔFosB in AgRP and POMC neurons (n = 4). Statistical analysis included 1-tailed t test. *P < 0.05, **P < 0.001.