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The structural relationships between interstitial cells of Cajal (ICC), varicose nerve fibers, and smooth muscle cells in the gastrointestinal tract have led to the suggestion that ICC may be involved in or mediate enteric neurotransmission. We characterized the distribution of ICC in the murine stomach and found two distinct classes on the basis of morphology and immunoreactivity to antibodies against c-Kit receptors. ICC with multiple processes formed a network in the myenteric plexus region from corpus to pylorus. Spindle-shaped ICC were found within the circular and longitudinal muscle layers (IC-IM) throughout the stomach. The density of these cells was greatest in the proximal stomach. IC-IM ran along nerve fibers and were closely associated with nerve terminals and adjacent smooth muscle cells. IC-IM failed to develop in mice with mutations in c-kit. Therefore, we used W/W$^{V}$ mutants to test whether IC-IM mediate neural inputs in muscles of the gastric fundus. The distribution of inhibitory nerves in the stomachs of c-kit mutants was normal, but NO-dependent inhibitory neuroregulation was greatly reduced. Smooth muscle tissues of W/W$^{V}$ mutants relaxed in response to exogenous sodium nitroprusside, but the membrane potential effects of sodium nitroprusside were attenuated. These data suggest that IC-IM play a critical serial role in NO-dependent neurotransmission: the cellular mechanism(s) responsible for transducing NO into electrical responses may be expressed in IC-IM. Loss of these cells causes loss of electrical responsiveness and greatly reduces responses to nitrergic nerve stimulation.

BackgroundVisceral pain is a primary symptom of many gastrointestinal diseases. One feature of visceral pain is its vague localization. We hypothesized that overlap in the receptive fields of spinal primary afferent neurons that innervate the gut may contribute to this vague localization. Many studies have confirmed that the proximal and distal colon are mainly innervated by spinal afferent neurons with cell bodies in thoraco-lumbar and lumbo-sacral dorsal root ganglia (DRG), respectively. However, no murine studies have examined whether individual DRG neurons simultaneously innervate both proximal and distal colon.AimsTo determine the extent of overlap in receptive fields of colon-projecting DRG neurons.MethodsC57BL/6 mice (n=8) were anesthetized, and two retrograde neuronal tracers with distinct fluorescence emission spectra (Fast blue and DiI) were injected separately into the smooth muscle layers of proximal and distal colon. Mice were left for 10–13 days for dye transport, before being euthanized. Thoraco, lumbar and lumbo-sacral DRGs (T8-13, L1-4, L5-S2) were dissected and fixed in 4% paraformaldehyde overnight. 12μm cryostat sections were obtained and analyzed using a fluorescent microscope equipped with filter cubes that detect Fast blue and DiI.ResultsWhen DiI was injected into the proximal colon, we observed labelling to be highest in T8-13 DRG with 12.6 +/- 4.5% of cell bodies labelled, followed by L1-4 was (8.2 +/- 1.4%) and in L5-S2 (6.5 +/- 0.8%). DiI injections into the distal colon resulted in labelling of similar numbers of neurons labelled in T8-13 and L1-4 ganglia, whereas half as many neurons were labelled in L5-S2 ganglia. This data shows that the majority of spinal afferent innervation of the colon originates in thoracolumbar DRG. Most importantly, 26.4% and 17.6% of thoracolumbar and lumbo-sacral DRG neurons labelled by Fast blue injection into the proximal colon were also double-labelled by DiI injected into the distal colon. Similarly, 16.6% and 13.8% of neurons in thoracolumbar and lumbosacral DRG labelled by Fast blue injection into the distal colon were double-labelled by DiI injected into the proximal colon.ConclusionsThese data reveal a surprisingly large number of DRG neurons that innervate the colon have receptive fields that cover both the proximal and distal colon, which may contribute to the poor spatial localization of pain emanating from the colon.Funding AgenciesCCC, CIHR

Abstract Background An impairment of vagally-mediated satiety signalling has been implicated in the caloric imbalance that leads to weight gain during obesity. Previous studies have suggested that a reduction in the excitability of vagal afferent neurons with cell bodies in nodose ganglia (NG) was responsible, but the cellular mechanisms are unclear. Host and bacterially derived mediators present in the small intestine and stool provide a physiologically relevant model to help elucidate the role luminal mediators play in modulating vagal afferent neuronal excitability. Aims We hypothesize that the microbiota of obese individuals and mice produce mediators that impair NG neuron excitability and satiety in mice. Methods Perforated patch clamp was used to measure the excitability of NG neurons following exposure to human and mouse fecal supernatants (FS), mouse jejunal supernatants (JS), and mice serum samples. Human FS were from ampersand:003E 5 healthy human donors or FS from ampersand:003E 5 obese donors. Mice FS, JS and serum samples were collected from ampersand:003E 5 obese mice fed a high-fat diet and ampersand:003E 5 control mice fed a normal diet. Results NG neurons incubated in FS from obese participants were significantly less excitable (rheobase was 30% higher and action potential discharge at 2x rheobase was 50% lower) than NG neurons exposed to FS from non-obese participants. NG neurons incubated in FS or JS from obese mice were also significantly less excitable (rheobase was 65% higher and action potential discharge at 2x rheobase was 50% lower) than NG neurons incubated with FS or JS from control mice. Lastly, NG neurons incubated with obese mouse serum were significantly less excitable (rheobase was 50% higher and action potential discharge at 2x rheobase was 80% lower) than NG neurons incubated with serum from control mice. We then attempted to identify mediators that may account for this inhibitory effect by using receptor antagonists that block GABA, ghrelin, and orexin signalling. Ghrelin and GABA receptor antagonists did not block the inhibitory effect of obese patients’ FS on NG neurons but the orexin receptor 1 antagonist (SB-334867;10µM) did. Following this, we incubated the orexin receptor 1 antagonist (SB-334867;10µM) on NG neurons incubated with mouse FS and JS and observed a similar blocking of inhibitory effects back to control values. Conclusions These findings suggest that the gut luminal contents of obese mice and humans contain an orexin receptor agonist that inhibits satiety and may contribute to over-eating. Funding Agencies CIHRNSERC

Abstract Background Abdominal pain is a debilitating symptom in patients with inflammatory bowel disease. Previously we have shown that combining sub-analgesic doses of cannabinoid 1 receptor (CB1R), but not cannabinoid 2 receptor (CB2R), and mu-opioid receptor (MOR) agonists synergistically inhibits colonic nociception in healthy mice. However, it is unknown whether this combination has analgesic efficacy in a pre-clinical model of colitis. Aims To determine the effects of combining sub-analgesic doses of CBR and MOR agonists on colonic nociception during acute colitis. Methods Colitis was induced in male and female C57BL/6 mice with 2.5% dextran sulfate sodium in drinking water. Extracellular afferent nerve recordings were obtained from ex vivo flat sheet preparations of mouse distal colon. Mechanosensitivity of single afferent axons was assessed via probing of the colon with a 1g von Frey hair before and after superfusion of agonists of CB1R or CB2R plus MOR. To examine effects in vivo, visceromotor response (VMR) to colorectal distention (volume range 20-80 µL) was measured via electromyography. Mice were injected intraperitoneally with vehicle, or a combination of CB1R or CB2R agonist plus morphine 30-minutes prior to VMR experiment. Data were analyzed using a one or two-way ANOVA with Bonferroni test. N denotes number of mice; n denotes number of single afferent axons. Results In afferent nerve recordings, in contrast to healthy mice, the CB2R agonist HU-308 (1 µM and 3 µM) inhibited colonic mechanosensitivity in mice with colitis (1 µM: p<0.01, N=5, n=12; 3 µM: p<0.01, N=7, n=10); a lower concentration (300 nM) had no effect (p=0.52, N=6, n=10). The CB1R agonist ACEA (10 µM) reduced mechanosensitivity during acute colitis (p<0.05, n=11, N=6), whereas 100 nM (p>0.99, n=7, N=5) and 1 µM (p=0.25, n=10, N=6) had no effect. A combination of sub-analgesic concentrations of ACEA (100 nM) and DAMGO (MOR agonist, 1 nM) inhibited colonic mechanosensitivity in healthy mice (p<0.01, N=4, n=8) and during acute colitis (p<0.05, N=6, n=8). While a combination of sub-analgesic concentrations of HU-308 (300 nM) and DAMGO (1 nM) had no effect in healthy mice (p=0.70, N=4, n=8), it inhibited colonic mechanosensitivity during acute colitis (p<0.01, N=8, n=15). In VMR experiments, a combination of a sub-analgesic dose of ACEA (0.3 mg/kg) with morphine (0.3 mg/kg) reduced VMR (p<0.01, N=7) during acute colitis. Similarly, a combination of a sub-analgesic dose of HU-308 (1 mg/kg) and morphine (0.3 mg/kg) reduced VMR (p<0.01, N=6) during acute colitis. Conclusions A CB2R agonist inhibits colonic nociception during acute colitis, but not in healthy mice. A sub-analgesic combination of CB1R and MOR agonists can inhibit pain in healthy and inflamed mice, while combining sub-analgesic CB2R and MOR agonists is only inhibitory during acute colitis. Funding Agencies NRC

BackgroundThe gut-brain axis is a bidirectional connection between the gastrointestinal tract (GI)and the central nervous system. The vagus nerve has been recognized as a principal component of this axis. Vagus nerve plays important role in maintaining homeostasis and normal GI functions, its afferent fibers can detect microbiota metabolites also. Many studies have demonstrated that the upper GI tract receives dense vagal innervation, which decreases distally throughout the tract. However, the distal colon sensory innervation of the vagus nerve remains controversial.AimsTo illuminate the extent to which the vagus nerve innervates the colon, to determine whether anatomical evidence exists for double-labeled vagal afferents supplying the proximal and distal colon in the nodose ganglia.MethodsC57Bl/6 mice (n=8) were injected in the proximal and distal colon with alternating solutions of retrograde tracers 1.7% Fast blue (FB) and 5% of lipophilic tracer DiI. Animals were left to recover for 10–13 days then underwent cardiac perfusion. Nodose ganglia were collected and fixed in 4% paraformaldehyde. 12 um tissue sections were then analyzed under a fluorescent microscope at 350nm and 555nm wavelength.ResultsIn total, 27% of nodose cell bodies were labeled from the entire colon. Following proximal DiI injections, the percentage of labeled cell bodies in the nodose ganglia were 24.3± 3.9%. However, we observed a lower percentage of labeled neurons from the distal colon, with 9.3± 1.4% after DiI injections. FB labelling from the distal colon was three times less than that observed for DiI. Within the nodose ganglia, 40% of all distally labelled neurons were labelled with both tracers.ConclusionsThese findings indicate that in mice, both distal and proximal colon receives visceral sensory innervation from the vagus nerve. Thus, providing evidence for a sensory anatomical connection of the vagus nerve between these two parts of the colon.Funding AgenciesCCC, CIHR