Diego V. Bohórquez scite author profile

The brain is thought to sense gut stimuli only via the passive release of hormones.This is because no connection has been described between the vagus and the putative gut epithelial sensor cell—the enteroendocrine cell. However, these electrically excitable cells contain several features of epithelial transducers. Using a mouse model, we found that enteroendocrine cells synapse with vagal neurons to transduce gut luminal signals in milliseconds by using glutamate as a neurotransmitter. These synaptically connected enteroendocrine cells are referred to henceforth as neuropod cells. The neuroepithelial circuit they form connects the intestinal lumen to the brainstem in one synapse, opening a physical conduit for the brain to sense gut stimuli with the temporal precision and topographical resolution of a synapse.

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A Neural Circuit for Gut-Induced Reward

Han

Téllez

Perkins

et al. 2018

Cell

517

396

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The gut is now recognized as a major regulator of motivational and emotional states. However, the relevant gut-brain neuronal circuitry remains unknown. We show that optical activation of gut-innervating vagal sensory neurons recapitulates the hallmark effects of stimulating brain reward neurons. Specifically, right, but not left, vagal sensory ganglion activation sustained self-stimulation behavior, conditioned both flavor and place preferences, and induced dopamine release from Substantia nigra. Cell-specific transneuronal tracing revealed asymmetric ascending pathways of vagal origin throughout the central nervous system. In particular, transneuronal labeling identified the glutamatergic neurons of the dorsolateral parabrachial region as the obligatory relay linking the right vagal sensory ganglion to dopamine cells in Substantia nigra. Consistently, optical activation of parabrachio-nigral projections replicated the rewarding effects of right vagus excitation. Our findings establish the vagal gut-to-brain axis as an integral component of the neuronal reward pathway. They also suggest novel vagal stimulation approaches to affective disorders.

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Neuroepithelial circuit formed by innervation of sensory enteroendocrine cells

Bohórquez¹,

Shahid²,

Erdmann³

et al. 2015

J. Clin. Invest.

376

335

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A Neural Circuit for Gut-Induced Reward

Han¹,

Téllez²,

Perkins³

et al. 2018

Cell

212

208

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In our paper, we map a gut-to-brain neural circuit linking sensory neurons in the upper gut to striatal dopamine release. It has come to our attention that during the preparation of Figure 4, we inadvertently duplicated the left image of panel 4M as 4N (depicting the CGRP-positive neurons and rabies-infected fields within the PBNdl and PBNel of DAT-ires-Cre and VGat-ires-Cre mice, respectively). Upon discovering this error, we returned to the original images. During the revision process to improve the data representation, the fluorescent signals were re-colored, and we realized that we mistakenly added the same panel twice when assembling the figures for resubmission. We have generated accurate versions of Figure 4M and 4N from the original data files, which are shown below. This error, which has been corrected online and in the print version, in no way affects the results of the paper or the interpretation of the data, and we have carefully evaluated all the images in the manuscript to ensure no other errors occurred. We apologize for any confusion or inconvenience this error may have caused.

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An Enteroendocrine Cell – Enteric Glia Connection Revealed by 3D Electron Microscopy

Bohórquez

Samsa

Roholt³

et al. 2014

PLoS ONE

207

171

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The enteroendocrine cell is the cornerstone of gastrointestinal chemosensation. In the intestine and colon, this cell is stimulated by nutrients, tastants that elicit the perception of flavor, and bacterial by-products; and in response, the cell secretes hormones like cholecystokinin and peptide YY – both potent regulators of appetite. The development of transgenic mice with enteroendocrine cells expressing green fluorescent protein has allowed for the elucidation of the apical nutrient sensing mechanisms of the cell. However, the basal secretory aspects of the enteroendocrine cell remain largely unexplored, particularly because a complete account of the enteroendocrine cell ultrastructure does not exist. Today, the fine ultrastructure of a specific cell can be revealed in the third dimension thanks to the invention of serial block face scanning electron microscopy (SBEM). Here, we bridged confocal microscopy with SBEM to identify the enteroendocrine cell of the mouse and study its ultrastructure in the third dimension. The results demonstrated that 73.5% of the peptide-secreting vesicles in the enteroendocrine cell are contained within an axon-like basal process. We called this process a neuropod. This neuropod contains neurofilaments, which are typical structural proteins of axons. Surprisingly, the SBEM data also demonstrated that the enteroendocrine cell neuropod is escorted by enteric glia – the cells that nurture enteric neurons. We extended these structural findings into an in vitro intestinal organoid system, in which the addition of glial derived neurotrophic factors enhanced the development of neuropods in enteroendocrine cells. These findings open a new avenue of exploration in gastrointestinal chemosensation by unveiling an unforeseen physical relationship between enteric glia and enteroendocrine cells.

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