Grant W. Hennig scite author profile

Interstitial cells of Cajal (ICC) generate pacemaker activity (slow waves) in gastrointestinal (GI) smooth muscles, but the mechanism(s) of pacemaker activity are controversial. Several conductances, such as Ca 2+ -activated Cl − channels (CaCC) and non-selective cation channels (NSCC) have been suggested to be involved in slow wave depolarization. We investigated the expression and function of a new class of CaCC, anoctamin 1 (ANO1), encoded by Tmem16a, which was discovered to be highly expressed in ICC in a microarray screen. GI muscles express splice variants of the Tmem16a transcript in addition to other paralogues of the Tmem16a family. ANO1 protein is expressed abundantly and specifically in ICC in all regions of the murine, non-human primate (Macaca fascicularis) and human GI tracts. CaCC blocking drugs, niflumic acid and 4,4 -diisothiocyano-2,2 -stillbene-disulfonic acid (DIDS) reduced the frequency and blocked slow waves in murine, primate, human small intestine and stomach in a concentration-dependent manner. Unitary potentials, small stochastic membrane depolarizations thought to underlie slow waves, were insensitive to CaCC blockers. Slow waves failed to develop by birth in mice homozygous for a null allele of Tmem16a (Tmem16a tm1Bdh/tm1Bdh ) and did not develop subsequent to birth in organ culture, as in wildtype and heterozygous muscles. Loss of function of ANO1 did not inhibit the development of ICC networks that appeared structurally normal as indicated by Kit antibodies. These data demonstrate the fundamental role of ANO1 in the generation of slow waves in GI ICC.

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Quantitative analysis of peristalsis in the guinea‐pig small intestine using spatio‐temporal maps

Hennig

Costa

Chen

et al. 1999

The Journal of Physiology

204

240

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The controlled progression of contents along the gastrointestinal tract is an essential part of digestion. Different patterns of intestinal movements are involved in the physiological progression of contents along the digestive tract and are the result of the interplay between spontaneous activity of intestinal smooth muscle and enteric neural circuits (Costa & Furness, 1982;Huizinga et al. 1998). Almost one hundred years ago, Bayliss and Starling (1899) revealed the presence of polarized reflex pathways in the intestine and suggested that they were responsible for the propulsion of contents. The analysis of intestinal propulsion was significantly advanced by Trendelenburg in 1917 who showed that reproducible propulsive motor patterns could be triggered in isolated segments of guinea-pig ileum by liquid distension. This form of intestinal peristalsis elicited in vitro is dependent on the activation of enteric circuits as many investigators have demonstrated (Kosterlitz, 1968;Tonini et al. 1981;Waterman et al. 1994b).Slow distension of isolated segments of guinea-pig intestine by liquid infusion produces a neurally-mediated shortening of the longitudinal muscle (Kosterlitz & Robinson, 1959) and an increase in diameter coinciding with an inhibitory reflex mechanism involving nitric oxide (intestinal accommodation; Waterman et al. 1994a). This initial response to liquid distension has been named the 'preparatory phase' (Trendelenburg, 1917;Kosterlitz, 1968). At a threshold volume or intraluminal pressure, a contraction of the circular muscle occurs at the oral end and propagates aborally to empty the segment. This propulsive event is called the 'emptying phase' and involves the activation of different enteric neural pathways (Waterman & Costa, 1994;Waterman et al. 1994b). Despite the common description of this motor behaviour as the 'peristaltic reflex' (Kosterlitz, 1968), it has become apparent that there is a sequential activation of neural

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Localized Release of Serotonin (5-Hydroxytryptamine) by a Fecal Pellet Regulates Migrating Motor Complexes in Murine Colon

et al. 2009

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Calcium activity in different classes of myenteric neurons underlying the migrating motor complex in the murine colon

2010

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The spontaneous colonic migrating motor complex (CMMC) is a cyclical contractile and electrical event that is the primary motor pattern underlying fecal pellet propulsion along the murine colon. We have combined Ca 2+ imaging with immunohistochemistry to determine the role of different classes of myenteric neurons during the CMMC. Between CMMCs, myenteric neurons usually displayed ongoing but uncoordinated activity. Stroking the mucosa at the oral or anal end of the colon resulted in a CMMC (latency: ∼6 to 10 s; duration: ∼28 s) that consisted of prolonged increases in activity in many myenteric neurons that was correlated to Ca 2+ transients in and displacement of the muscle. These neurons were likely excitatory motor neurons. Activity in individual neurons during the CMMC was similar regardless of whether the CMMC occurred spontaneously or was evoked by anal or oral mucosal stimulation. This suggests that convergent interneuronal pathways exist which generate CMMCs. Interestingly, Ca 2+ transients in a subset of NOS +ve neurons were substantially reduced during the CMMC. These neurons are likely to be inhibitory motor neurons that reduce their activity during a complex (disinhibition) to allow full excitation of the muscle. Local stimulation of the mucosa evoked synchronized Ca 2+ transients in Dogiel Type II (mitotracker/calbindin-positive) neurons after a short delay (∼1-2 s), indicating they were the sensory neurons underlying the CMMC. These local responses were observed in hexamethonium, but were blocked by ondansetron (5-HT 3 antagonist), suggesting Dogiel Type II neurons were activated by 5-HT release from enterochromaffin cells in the mucosa. In fact, removal of the mucosa yielded no spontaneous CMMCs, although many neurons (NOS +ve and NOS −ve) exhibited ongoing activity, including Dogiel Type II neurons. These results suggest that spontaneous or evoked 5-HT release from the mucosa is necessary for the activation of Dogiel Type II neurons that generate CMMCs.

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The mechanisms underlying the generation of the colonic migrating motor complex in both wild-type and nNOS knockout mice

Dickson

Heredia

McCann

et al. 2010

American Journal of Physiology-Gastrointestinal and Liver Physi

144

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Colonic migrating motor complexes (CMMCs) propel fecal contents and are altered in diseased states, including slow-transit constipation. However, the mechanisms underlying the CMMCs are controversial because it has been proposed that disinhibition (turning off of inhibitory neurotransmission) or excitatory nerve activity generate the CMMC. Therefore, our aims were to reexamine the mechanisms underlying the CMMC in the colon of wild-type and neuronal nitric oxide synthase (nNOS)(-/-) mice. CMMCs were recorded from the isolated murine large bowel using intracellular recordings of electrical activity from circular muscle (CM) combined with tension recording. Spontaneous CMMCs occurred in both wild-type (frequency: 0.3 cycles/min) and nNOS(-/-) mice (frequency: 0.4 cycles/min). CMMCs consisted of a hyperpolarization, followed by fast oscillations (slow waves) with action potentials superimposed on a slow depolarization (wild-type: 14.0 +/- 0.6 mV; nNOS(-/-): 11.2 +/- 1.5 mV). Both atropine (1 microM) and MEN 10,376 [neurokinin 2 (NK2) antagonist; 0.5 microM] added successively reduced the slow depolarization and the number of action potentials but did not abolish the fast oscillations. The further addition of RP 67580 (NK1 antagonist; 0.5 microM) blocked the fast oscillations and the CMMC. Importantly, none of the antagonists affected the resting membrane potential, suggesting that ongoing tonic inhibition of the CM was maintained. Fecal pellet propulsion, which was blocked by the NK2 or the NK1 antagonist, was slower down the longer, more constricted nNOS(-/-) mouse colon (wild-type: 47.9 +/- 2.4 mm; nNOS(-/-): 57.8 +/- 1.4 mm). These observations suggest that excitatory neurotransmission enhances pacemaker activity during the CMMC. Therefore, the CMMC is likely generated by a synergistic interaction between neural and interstitial cells of Cajal networks.

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Grant W. Hennig

Expression of anoctamin 1/TMEM16A by interstitial cells of Cajal is fundamental for slow wave activity in gastrointestinal muscles

Quantitative analysis of peristalsis in the guinea‐pig small intestine using spatio‐temporal maps

Localized Release of Serotonin (5-Hydroxytryptamine) by a Fecal Pellet Regulates Migrating Motor Complexes in Murine Colon

Calcium activity in different classes of myenteric neurons underlying the migrating motor complex in the murine colon

The mechanisms underlying the generation of the colonic migrating motor complex in both wild-type and nNOS knockout mice

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