Abstract
The peristaltic contraction and relaxation of intestinal circular and longitudinal smooth muscles is controlled by synaptic circuit elements that impinge upon phenotypically diverse neurons in the myenteric plexus. While electrophysiological studies provide useful information concerning the properties of such synaptic circuits, they typically involve tissue disruption and do not correlate circuit activity with biochemically defined neuronal phenotypes. To overcome these limitations, mice were engineered to express the sensitive, fast Ca2+ indicator GCaMP6f selectively in neurons that express the acetylcholine (ACh) biosynthetic enzyme choline acetyltransfarse (ChAT) thereby allowing rapid activity-driven changes in Ca2+ fluorescence to be observed without disrupting intrinsic connections, solely in cholinergic myenteric ganglion (MG) neurons. Experiments with selective receptor agonists and antagonists reveal that most mouse colonic cholinergic (i.e., GCaMP6f+/ChAT+) MG neurons express nicotinic ACh receptors (nAChRs), particularly the ganglionic subtype containing α3 and β4 subunits, and most express ionotropic serotonin receptors (5-HT3Rs). Cholinergic MG neurons also display small, spontaneous Ca2+ transients occurring at ≈ 0.2 Hz. Experiments with inhibitors of Na+ channel dependent impulses, presynaptic Ca2+ channels and postsynaptic receptor function reveal that the Ca2+ transients arise from impulse-driven presynaptic activity and subsequent activation of postsynaptic nAChRs or 5-HT3Rs. Electrical stimulation of axonal connectives to MG evoked Ca2+ responses in the neurons that similarly depended on nAChRs or/and 5-HT3Rs. Responses to single connective shocks had peak amplitudes and rise and decay times that were indistinguishable from the spontaneous Ca2+ transients and the largest fraction had brief synaptic delays consistent with activation by monosynaptic inputs. These results indicate that the spontaneous Ca2+ transients and stimulus evoked Ca2+ responses in MG neurons originate in circuits involving fast chemical synaptic transmission mediated by nAChRs or/and 5-HT3Rs. Experiments with an α7-nAChR agonist and antagonist, and with pituitary adenylate cyclase activating polypeptide (PACAP) reveal that the same synaptic circuits display extensive capacity for presynaptic modulation. Our use of non-invasive GCaMP6f/ChAT Ca2+ imaging in colon segments with intrinsic connections preserved, reveals an abundance of direct and modulatory synaptic influences on cholinergic MG neurons.
Highlights
The enteric nervous system (ENS) generates circuit activity that produces peristalsis via rhythmic contraction and relaxation of intestinal circular and longitudinal smooth muscles (Costa et al, 2000)
Pre-incubation and testing in Ondansetron (20 μM) a potent 5-HT3R-selective antagonist (Machu, 2011) inhibited 5-HT induced responses in 100% of neurons tested, reducing AA,Peak by 92%. These results demonstrate that most cholinergic Myenteric ganglion (MG) neurons express nAChRs, with the majority of the response to DMPP represented by α3β4∗-nAChRs, and that most express 5-HT3Rs, thereby indicating that a sizeable fraction of the neurons likely express both receptor types
Pharmacological tests indicated that the DMPP responses were reduced by ≈70% after treatment with the generic nAChR inhibitor, Hex or with the α3β4∗-specific nAChR inhibitor, SR16584 and to a somewhat greater extent (≈90%) after treatment with the generic nAChR inhibitor dTC. These results indicate that α3β4∗-nAChRs represent the bulk of nAChRs on cholinergic MG neurons in the adult mouse colon, consistent with previous electrophysiological studies underscoring the importance of cholinergic signaling via ganglionic α3β4∗-nAChRs in mouse and guinea pig myenteric plexus (MP) neurons (Nurgali et al, 2003; Galligan and North, 2004; Gwynne and Bornstein, 2007)
Summary
The enteric nervous system (ENS) generates circuit activity that produces peristalsis via rhythmic contraction and relaxation of intestinal circular and longitudinal smooth muscles (Costa et al, 2000). Electrophysiological studies using guinea pig or mouse intestinal ex vivo preparations have shown that fast cholinergic synaptic signaling involving ACh release from presynaptic neuron terminals to activate ionotropic (i.e., nicotinic) ACh receptors (nAChRs) on postsynaptic neurons is a primary means of neurotransmission in MG (Galligan and North, 2004; Gwynne and Bornstein, 2007; reviewed by Foong et al, 2015) Such studies provide detailed information about the function of MG synapses and their component receptors, but prevailing electrophysiological approaches involve stripping away circular and mucosal plexus layers to attain electrode access, thereby disrupting intrinsic connections and limiting conclusions to the most accessible neurons receiving the most localized inputs
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