Hypothalamic and brainstem glucose-dependent insulinotropic polypeptide receptor neurons employ distinct mechanisms to affect feeding
Alice Adriaenssens, Johannes Broichhagen, Anne de Bray, Julia Ast, Annie Hasib, Ben Jones, Alejandra Tomas, Natalie Figueredo Burgos, Orla Woodward, Jo Lewis, Elisabeth O’Flaherty, Kimberley El, Canqi Cui, Norio Harada, Nobuya Inagaki, Jonathan Campbell, Daniel Brierley, David J. Hodson, Ricardo Samms, Fiona Gribble, Frank Reimann
Alice Adriaenssens, Johannes Broichhagen, Anne de Bray, Julia Ast, Annie Hasib, Ben Jones, Alejandra Tomas, Natalie Figueredo Burgos, Orla Woodward, Jo Lewis, Elisabeth O’Flaherty, Kimberley El, Canqi Cui, Norio Harada, Nobuya Inagaki, Jonathan Campbell, Daniel Brierley, David J. Hodson, Ricardo Samms, Fiona Gribble, Frank Reimann
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Research Article Metabolism Neuroscience

Hypothalamic and brainstem glucose-dependent insulinotropic polypeptide receptor neurons employ distinct mechanisms to affect feeding

Abstract

Central glucose-dependent insulinotropic polypeptide (GIP) receptor (GIPR) signaling is critical in GIP-based therapeutics’ ability to lower body weight, but pathways leveraged by GIPR pharmacology in the brain remain incompletely understood. We explored the role of Gipr neurons in the hypothalamus and dorsal vagal complex (DVC) — brain regions critical to the control of energy balance. Hypothalamic Gipr expression was not necessary for the synergistic effect of GIPR/GLP-1R coagonism on body weight. While chemogenetic stimulation of both hypothalamic and DVC Gipr neurons suppressed food intake, activation of DVC Gipr neurons reduced ambulatory activity and induced conditioned taste avoidance, while there was no effect of a short-acting GIPR agonist (GIPRA). Within the DVC, Gipr neurons of the nucleus tractus solitarius (NTS), but not the area postrema (AP), projected to distal brain regions and were transcriptomically distinct. Peripherally dosed fluorescent GIPRAs revealed that access was restricted to circumventricular organs in the CNS. These data demonstrate that Gipr neurons in the hypothalamus, AP, and NTS differ in their connectivity, transcriptomic profile, peripheral accessibility, and appetite-controlling mechanisms. These results highlight the heterogeneity of the central GIPR signaling axis and suggest that studies into the effects of GIP pharmacology on feeding behavior should consider the interplay of multiple regulatory pathways.

Authors

Alice Adriaenssens, Johannes Broichhagen, Anne de Bray, Julia Ast, Annie Hasib, Ben Jones, Alejandra Tomas, Natalie Figueredo Burgos, Orla Woodward, Jo Lewis, Elisabeth O’Flaherty, Kimberley El, Canqi Cui, Norio Harada, Nobuya Inagaki, Jonathan Campbell, Daniel Brierley, David J. Hodson, Ricardo Samms, Fiona Gribble, Frank Reimann

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Figure 6

Transcriptomic characterization of Gipr-expressing cells in the hindbrain.

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Transcriptomic characterization of Gipr-expressing cells in the hindbrai...
Gipr cells were isolated from single-cell digests of hindbrain sections from GiprEYFP mice via FACS, and their transcriptomes were characterized via scRNA-Seq followed by clustering analysis. (A) Uniform Manifold Approximation and Projection (UMAP) visualization of GiprEYFP+ cells. Cell types were assigned according to expression of marker genes (Peri.1, Peri.2 = pericytes; EC.1, EC.2 = endothelial cells; OD.ma = mature ODs; OD.my = myelinating ODs; OD.3 = ODs, SMC.1, SMC.2 = smooth muscle cells; VLMC = vascular leptomenigeal cells; Neuron = neurons; Ast/Ep = astroependymal cells; MG = microglia) (B). (C) Dual-label FISH showing colocalization of Gipr (green) and Syt1 (red) transcript in coronal sections of mouse brain stem tissue from C57BL/6 mice. Nuclei are counterstained with DAPI (blue). Gipr/Syt1 coexpression was quantified in sections from 3 mice. Scale bar: 20 μm. Arrows indicate cells expressing both Gipr and Syt1. (D) Principal component analysis of GiprEYFP+ versus Glp1rEYFP+ neurons (left). Dot plot of selected differentially expressed genes in GiprEYFP+ versus Glp1rEYFP+ neurons (right).