Gaps in our understanding of how vagal afferents to the small intestinal mucosa detect luminal stimuli.

Vagal afferents to the gastrointestinal tract are crucial for regulation of food intake, signaling negative feedback that contributes to satiation and positive feedback that produces appetition and reward. Vagal afferents to the small intestinal mucosa contribute to this regulation by sensing luminal stimuli and reporting this information to the brain. These afferents respond to mechanical, chemical, thermal, pH, and osmolar stimuli and to bacterial products and immunogens. Surprisingly little is known about how these stimuli are transduced by vagal mucosal afferents, or how their transduction is organized among these afferents' terminals. Further, the effects of stimulus concentration ranges or physiological stimuli on vagal activity have not been examined for some of these stimuli. And, detection of luminal stimuli has rarely been examined in rodents, which are most frequently employed for studying small intestinal innervation. Here we review what is known about stimulus detection by vagal mucosal afferents and illustrate the complexity of this detection using nutrients as an exemplar. The accepted model proposes nutrients bind to taste receptors on enteroendocrine cells (EECs), which excites them, causing release of hormones that stimulate vagal mucosal afferents. Evidence is reviewed that suggests while this model accounts for many aspects of vagal signaling about nutrients, it cannot account for all aspects. A major goal of this review therefore is to evaluate what is known about nutrient absorption and detection and based on this evaluation to identify candidate mucosal cells and structures that could cooperate with EECs and vagal mucosal afferents in stimulus detection.

Intestinal enteroendocrine cells rely on ryanodine and IP3 calcium store receptors for mechanotransduction.

Enteroendocrine cells (EECs) are specialized sensors of luminal forces and chemicals in the gastrointestinal (GI) epithelium that respond to stimulation with a release of signalling molecules such as serotonin (5-HT). For mechanosensitive EECs, force activates Piezo2 channels, which generate a very rapidly activating and inactivating (∼10 ms) cationic (Na+ , K+ , Ca2+ ) receptor current. Piezo2 receptor currents lead to a large and persistent increase in intracellular calcium (Ca2+ ) that lasts many seconds to sometimes minutes, suggesting signal amplification. However, intracellular calcium dynamics in EEC mechanotransduction remain poorly understood. The aim of this study was to determine the role of Ca2+ stores in EEC mechanotransduction. Mechanical stimulation of a human EEC cell model (QGP-1) resulted in a rapid increase in cytoplasmic Ca2+ and a slower decrease in ER stores Ca2+ , suggesting the involvement of intracellular Ca2+ stores. Comparing murine primary colonic EECs with colonocytes showed expression of intercellular Ca2+ store receptors, a similar expression of IP3 receptors, but a >30-fold enriched expression of Ryr3 in EECs. In mechanically stimulated primary EECs, Ca2+ responses decreased dramatically by emptying stores and pharmacologically blocking IP3 and RyR1/3 receptors. RyR3 genetic knockdown by siRNA led to a significant decrease in mechanosensitive Ca2+ responses and 5-HT release. In tissue, pressure-induced increase in the Ussing short circuit current was significantly decreased by ryanodine receptor blockade. Our data show that mechanosensitive EECs use intracellular Ca2+ stores to amplify mechanically induced Ca2+ entry, with RyR3 receptors selectively expressed in EECs and involved in Ca2+ signalling, 5-HT release and epithelial secretion. KEY POINTS: A population of enteroendocrine cells (EECs) are specialized mechanosensors of the gastrointestinal (GI) epithelium that respond to mechanical stimulation with the release of important signalling molecules such as serotonin. Mechanical activation of these EECs leads to an increase in intracellular calcium (Ca2+ ) with a longer duration than the stimulus, suggesting intracellular Ca2+ signal amplification. In this study, we profiled the expression of intracellular Ca2+ store receptors and found an enriched expression of the intracellular Ca2+ receptor Ryr3, which contributed to the mechanically evoked increases in intracellular calcium, 5-HT release and epithelial secretion. Our data suggest that mechanosensitive EECs rely on intracellular Ca2+ stores and are selective in their use of Ryr3 for amplification of intracellular Ca2+ . This work advances our understanding of EEC mechanotransduction and may provide novel diagnostic and therapeutic targets for GI motility disorders.

Neurotrophin-4 is essential for survival of the majority of vagal afferents to the mucosa of the small intestine, but not the stomach.

Vagal afferents form the primary gut-to-brain neural axis, communicating signals that regulate gastrointestinal (GI) function and promote satiation, appetition and reward. Neurotrophin-4 (NT-4) is essential for the survival of vagal smooth muscle afferents of the small intestine, but not the stomach. Here we took advantage of near-complete labeling of GI vagal mucosal afferents in Nav1.8cre-Rosa26tdTomato transgenic mice to determine whether these afferents depend on NT-4 for survival. We quantified the density and distribution of vagal afferent terminals in the stomach and small intestine mucosa and their central terminals in the solitary tract nucleus (NTS) and area postrema in NT-4 knockout (KO) and control mice. NT-4KO mice exhibited a 75% reduction in vagal afferent terminals in proximal duodenal villi and a 55% decrease in the distal ileum, whereas, those in the stomach glands remained intact. Vagal crypt afferents were also reduced in some regions of the small intestine, but to a lesser degree. Surprisingly, NT-4KO mice exhibited an increase in labeled terminals in the medial NTS. These findings, combined with previous results, suggest NT-4 is essential for survival of a large proportion of all classes of vagal afferents that innervate the small intestine, but not those that supply the stomach. Thus, NT-4KO mice could be valuable for distinguishing gastric and intestinal vagal afferent regulation of GI function and feeding. The apparent plasticity of central vagal afferent terminals - an increase in their density - could have compensated for loss of peripheral terminals by maintaining near-normal levels of satiety signaling.

Abdominal vagotomy reveals majority of small intestinal mucosal afferents labeled in nav 1.8cre-rosa26tdTomato mice are vagal in origin.

Vagal afferents innervating the small intestinal mucosa regulate feeding, gastrointestinal (GI) digestive, and immune functions. Their anatomical-functional characterization has been impeded by the inability to selectively label and manipulate them. Nav 1.8-Cre-tdTomato mice label 80% of nodose and dorsal root ganglia neurons. Here, the origin of these neuron's terminals and their distribution in the small intestinal mucosa were examined by quantitatively comparing tdTomato-labeled innervation in nonoperated (control), subdiaphragmatic vagotomy (VAGX), and sham-operated mice. Control mice exhibited a large proximal-to-distal decrease and a moderate mesentery-to-antimesentery decrease in villus innervation. VAGX reduced this innervation to a greater degree proximally (91-93%) than distally (65-72%), resulting in flat proximal-distal distributions. Therefore, estimates of vagal villus afferent distributions (control minus VAGX) paralleled control distributions, but were slightly reduced in magnitude. Compared with villus afferents, crypt innervation exhibited a muted proximal-to-distal decrease in control mice and a smaller loss after VAGX (45-48%). Sham-operated mice exhibited similar distributions of villus and crypt afferents as control mice, suggesting surgery did not contribute to the effects of VAGX. Most crypt and villus afferent terminals along the entire proximal-distal small intestinal axis had similar morphology to those previously reported in the proximal duodenum, but the density of terminal branches varied. Our findings suggest the majority of small intestinal mucosal innervation labeled in Nav 1.8-Cre-tdTomato mice is vagal in origin. Therefore, these mice will be valuable for studying vagal mucosal afferent morphology, interactions with other GI elements, plasticity, and function.