Abstract
The particular location of myenteric neurons, sandwiched between the 2 muscle layers of the gut, implies that their somata and neurites undergo mechanical stress during gastrointestinal motility. Existence of mechanosensitive enteric neurons (MEN) is undoubted but many of their basic features remain to be studied. In this study, we used ultra-fast neuroimaging to record activity of primary cultured myenteric neurons of guinea pig and human intestine after von Frey hair evoked deformation of neurites and somata. Independent component analysis was applied to reconstruct neuronal morphology and follow neuronal signals. Of the cultured neurons 45% (114 out of 256, 30 guinea pigs) responded to neurite probing with a burst spike frequency of 13.4 Hz. Action potentials generated at the stimulation site invaded the soma and other neurites. Mechanosensitive sites were expressed across large areas of neurites. Many mechanosensitive neurites appeared to have afferent and efferent functions as those that responded to deformation also conducted spikes coming from the soma. Mechanosensitive neurites were also activated by nicotine application. This supported the concept of multifunctional MEN. 14% of the neurons (13 out of 96, 18 guinea pigs) responded to soma deformation with burst spike discharge of 17.9 Hz. Firing of MEN adapted rapidly (RAMEN), slowly (SAMEN), or ultra-slowly (USAMEN). The majority of MEN showed SAMEN behavior although significantly more RAMEN occurred after neurite probing. Cultured myenteric neurons from human intestine had similar properties. Compared to MEN, dorsal root ganglion neurons were activated by neurite but not by soma deformation with slow adaptation of firing. We demonstrated that MEN exhibit specific features very likely reflecting adaptation to their specialized functions in the gut.
Highlights
Mechanosensitivity plays a key role in a variety of reflexes in the intestines that constantly contract and relax
Reacting to external environmental changes and modulating gastrointestinal motility in response to different meals are examples of situations that require an adequate response to Abbreviations: AH, after-spike hyperpolarization; AI, adaptation index; CCD, charge coupled device; dorsal root ganglion (DRG), dorsal root ganglia; ENS, enteric nervous system; ICA, independent component analysis; IPAN, intrinsic primary afferent neuron; LMMP, longitudinal muscle—myenteric plexus; Mechanosensitive enteric neurons (MEN), mechanosensitive enteric neurons; RAMEN, rapidly adapting mechanosensitive enteric neurons; SAMEN, slowly adapting mechanosensitive enteric neurons; TTX, tetrodotoxin; USAMEN, ultra-slowly adapting mechanosensitive enteric neurons
Applying ICA to discriminate between different spike discharge patterns we were able to distinguish the responses of somata and neurites between different neurons (Figures 1, 2)
Summary
Mechanosensitivity plays a key role in a variety of reflexes in the intestines that constantly contract and relax. IPANs in the guinea pig ileum have characteristic features: they show slow after-spike hyperpolarization (AH), lack fast excitatory synaptic input and express the calcium binding protein calbindin It is these neurons which responded to sustained distension of the gut wall and behave like slowly adapting mechanosensors (Kunze et al, 1998; Quinson et al, 2001; Clerc and Furness, 2004). Neurite deformation enhanced while soma compression inhibited spike discharge (Kunze et al, 2000) These experiments have been performed in intact tissue by probing interganglionic fiber tracts or ganglionic regions with von Frey hairs. We studied the behavior of primary cultured mechanosensitive myenteric neurons This allowed us to perform targeted mechanical stimulation of a single soma and neurite with an ultra-fine carbon fiber which served as a von Frey hair. DRG nerve endings have with well-established mechanosensitive properties transmitting information from the periphery to higher centers
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