Polar innervation of enteric non-cholinergic and non-adrenergic neurons in the isolated guinea-pig ileum

To study the polarity of the efferent pathway of the myenteric plexus, recordings were made of the mechanical activity of the longitudinal muscle of isolated guinea-pig ileal segments upon stimulation with an electrical field around the myenteric plexus contained within strips of longitudinal muscle (LM-MP) continuous with each end of ileal segment. The amplitude of the contractile response to stimulation of the anal LM-MP was always larger than that to the oral LM-MP. After cholinergic and adrenergic transmission was suppressed by atropine (10 microM) and guanethidine (1 microM), and the tone of the segment was enhanced by histamine (1 microM), the LM-MP stimulation produced non-cholinergic, non-adrenergic (NCNA) ascending contraction and NCNA descending relaxation. The NCNA contraction, but not the NCNA relaxation, was abolished or reduced by desensitization to substance P. The present results suggest that the NCNA innervation of the myenteric plexus participates in the polar effects observed in the guinea-pig ileum, that the NCNA excitatory response may be mediated at least in part by myenteric substance P neurons, and that the NCNA inhibitory response is mediated by non-adrenergic neurons.     

Does 5-hydroxytryptamine influence "purinergic" inhibitory neurons in the intestine?

Intrinsic inhibitory neurons to guinea pig taenia coli and small bowel circular muscle were activated by transmural electrical stimulation, and the postinhibitory contractile response of the muscle was utilized to evaluate whether or not the neuronal action of 5-hydroxytryptamine (5HT) was associated with the inhibitory neurons. The postinhibitory contractile responses of the small intestinal circular muscle were unaffected by 5HT. The 5HT antagonist methysergide also did not affect the poststimulus contractile response of the circular muscle. The amplitude and area under the contractile curve of the poststimulus contractile response of the taenia coli were reduced and the amplitude of the relaxation response to electrical stimulation was increased in one-half of the preparations after application of 5HT. Methysergide did not alter the poststimulus contractile response of the taenia coli. 5HT is implicated as a neurotransmitter substance for slow synaptic excitation within the enteric nervous system of the guinea pig small intestine; however, the 5HT synapses do not appear to be present on the "purinergic" inhibitory neurons nor on neurons that synaptically influence the inhibitory neurons.     

Analysis of purinergic and cholinergic fast synaptic transmission to identified myenteric neurons

Types and projections of neurons that received cholinergic, purinergic and other fast excitatory synaptic inputs in myenteric ganglia of the guinea-pig distal colon were identified using combined electrophysiological recording, application of selective antagonists, marker dye filling via the recording microelectrode, and immunohistochemical characterisation. Fast synaptic inputs were recorded from all major subtypes of uniaxonal neurons including Dogiel type I neurons, filamentous interneurons, circular muscle motor neurons and longitudinal muscle motor neurons. Fast excitatory postsynaptic potentials were completely blocked by the nicotinic receptor antagonists hexamethonium or mecamylamine in 62% of neurons tested and were partially inhibited in the remaining neurons. The P2 purine receptor antagonist, pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid, reduced the amplitudes of fast excitatory postsynaptic potentials in 20% of myenteric neurons. The 5-hydroxytryptamine(3) receptor antagonist granisetron reduced the amplitude of fast excitatory postsynaptic potentials in only one of 15 neurons tested. In five of five neurons tested, the combination of a nicotinic antagonist, pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid, granisetron and 6-cyano-7-nitroquinoxaline-2,3-dione did not completely block the fast excitatory postsynaptic potentials. Immunohistochemical studies of the neurons that had been identified electrophysiologically and morphologically imply that P2X(2) receptors may mediate fast transmission in some neurons, and that other P2X receptor subtypes may also be involved in fast synaptic transmission to myenteric neurons of the guinea-pig distal colon. Neurons with nicotinic and pyridoxal-phosphate-6-azophenyl-2',4'-disulfonic acid-sensitive fast excitatory postsynaptic potentials were present in both ascending and descending pathways in the distal colon. Thus, neither cholinergic nor mixed cholinergic/purinergic synaptic responses are confined to a particular class of neuron. The results indicate that acetylcholine and ATP are the major fast excitatory neurotransmitters in guinea-pig distal colon myenteric ganglia.     

An immunohistochemical study of the distribution of enteric GABA-containing neurons in the rat and guinea-pig intestine

gamma-Aminobutyric acid (GABA) antiserum was applied to sections of rat and guinea-pig intestine which were subsequently processed to reveal any immunoreactivity using either fluorescence or peroxidase techniques. Immunopositive fibres were demonstrated in stomach, duodenum, ileum and colon of rat and guinea-pig intestine. Myenteric ganglia and nerve bundles in the circular muscle contained immunopositive nerve fibres, while the longitudinal muscle, submucosa and mucosa were only rarely innervated. In favourable sections, immunopositive fibres could be seen running from the myenteric plexus into the circular muscle, thus suggesting that the GABA-immunopositive nerves in the circular muscle originate from neurons in the myenteric plexus. In both rat and guinea-pig, immunoreactive nerve cell bodies were most numerous in the myenteric plexus of the colon. In the rat, immunopositive fibres in the circular muscle were most abundant in the ileum, whereas in the guinea-pig it was the colon circular muscle that was most richly innervated. The results demonstrate that neurons which show GABA immunoreactivity are present along the length of the gastrointestinal tract. Their distribution in both myenteric ganglia and circular muscle is heterogeneous both within and between the two species studied. It is probable that this heterogeneity reflects the diversity and specificity of function of this class of enteric neurons.     

Neurotransmitters in parasympathetic ganglionic neurons and nerves in mouse lower airway smooth muscle

In most species, including humans, lower airway smooth muscle (ASM) contains nerve terminals from two distinct populations of parasympathetic ganglionic neurons based on neurotransmitter phenotype: cholinergic and non-adrenergic non-cholinergic (NANC), causing contraction and relaxation, respectively, of ASM. Using immunohistological staining, the density and distribution of NANC-associated neurotransmitters, vasoactive intestinal peptide (VIP) and nitric oxide synthase were 6% of total nerve profiles compared to 19% cholinergic nerves in ASM in mouse (C57BL/6) central airways. The location of the NANC parasympathetic neurons innervating the tracheal ASM, as determined by retrograde neuronal tracer from the trachealis muscle, was the myenteric plexus of the esophagus, closely associated with the outer striated longitudinal muscle layers; the majority of the retrograde-labeled neurons were VIP- and NOS-IR. The results of these experiments provide the first direct evidence that VIP-IR and NOS-IR neurons intrinsic to the mouse esophagus project axons to the adjacent trachealis muscle.     

The neural regulation of the mammalian esophageal motility and its implication for esophageal diseases

In contrast to the tunica muscularis of the stomach, small intestine and large intestine, the external muscle layer of the mammalian esophagus contains not only smooth muscle but also striated muscle fibers. Although the swallowing pattern generator initiates the peristaltic movement via vagal preganglionic neurons that project to the myenteric ganglia in the smooth muscle esophagus, the progressing front of contraction is organized by a local reflex circuit composed by intrinsic neurons similarly to other gastrointestinal tracts. On the other hand, the peristalsis of the striated muscle esophagus is both initiated and organized by the swallowing pattern generator via vagal motor neurons that directly innervate the muscle fibers. The presence of a distinct ganglionated myenteric plexus in the striated muscle portion of the esophagus had been enigmatic and neglected in terms of peristaltic control for a long time. Recently, the regulatory roles of intrinsic neurons in the esophageal striated muscle have been clarified. It was reported that esophageal striated muscle receives dual innervation from both vagal motor fibers originating in the brainstem and varicose intrinsic nerve fibers originating in the myenteric plexus, which is called ‘enteric co-innervation’ of esophageal motor endplates. Moreover, a putative local neural reflex pathway that can control the motility of the striated muscle was identified in the rodent esophagus. This reflex circuit consists of primary afferent neurons and myenteric neurons, which can modulate the release of neurotransmitters from vagal motor neurons in the striated muscle esophagus. The pathogenesis of some esophageal disorders such as achalasia and gastroesophageal reflux disease might be involved in dysfunction of the neural networks including alterations of the myenteric neurons. These evidences indicate the physiological and pathological significance of intrinsic nervous system in the regulation of the esophageal motility. In addition, it is assumed that the components of intrinsic neurons might be therapeutic targets for several esophageal diseases.     

An analysis of possible nervous mechanisms involved in the peristaltic reflex

1. The effects of drugs on peristalsis and on the contractions of the two muscle coats of the isolated guinea-pig ileum in response to co-axial electrical stimulation have been studied.2. Co-axial stimulation (0.1 msec pulses) never produces simultaneous contraction of both muscle coats. When one muscle contracts, the other either relaxes or remains quiescent.3. The circular muscle contraction has two components. The first is reflex in origin and is brought about either by distension of the gut with increasing intraluminal filling or by the contraction of the longitudinal muscle in response to electrical stimulation at low frequency (1/sec), provided this raises the intraluminal pressure to the threshold for eliciting the circular muscle contraction. As the circular muscle contracts, the longitudinal muscle relaxes although stimulation continues. If the circular muscle contraction is prevented by reducing the intraluminal filling, or by adding a ganglion-blocking drug, the longitudinal muscle remains contracted until withdrawal of the stimulus.4. In the presence of hyoscine, the reflex contraction of the circular muscle is unimpaired but, since the longitudinal muscle contraction is abolished, a higher intraluminal pressure is required to elicit the reflex.5. The second component of the circular muscle contraction appears in response to electrical stimulation at high frequency (3-10/sec), upon withdrawal of electrical stimulation. This delay indicates the simultaneous stimulation of a dominant inhibitory innervation.6. The excitatory nerves to the circular muscle require a higher frequency of stimulation than those to the longitudinal muscle, which respond to single shocks.7. Cholinergic blocking agents (hyoscine, morphine, hemicholinium and botulinum toxin) antagonize the responses of the longitudinal muscle to co-axial stimulation without affecting those of the circular muscle, thus suggesting that the excitatory fibres to the circular muscle are not cholinergic. Prostaglandins (E(1) and E(2)) selectively antagonize the circular muscle contractions evoked by co-axial stimulation. Tetrodotoxin blocks both longitudinal and circular muscle responses.8. Dimethylphenylpiperazinium (DMPP) and 5-hydroxytryptamine (5-HT) stimulate ganglia but have no direct action on the smooth muscle of guinea-pig ileum.9. During a maintained contraction of the longitudinal muscle in the presence of high concentrations of acetylcholine (2.5 x 10(-7) to 10(-6) g/ml.) a contraction of the circular muscle accompanied by a relaxation of the longitudinal muscle is elicited by distension of the gut, and by co-axial stimulation. Similar reciprocal responses are produced by 5-HT or by DMPP and they are finally blocked by DMPP.10. These results are consistent with the hypothesis that in the myenteric plexus there exists an arrangement of nerves which ensures that the two muscle coats of the intestine do not contract simultaneously but are activated reciprocally so that when one muscle layer contracts the other relaxes or is prevented from contracting.     

Electrical basis of contractions in the muscle layers of the pig colon

Simultaneous in vitro measurements of electrical and mechanical activities were performed, using suction electrodes and force transducers, respectively, on longitudinal and circular muscle layers of the pig proximal colon. In addition, circular muscle strips were studied with the sucrose gap technique. Spontaneous activity was present in both preparations. In the circular muscle, slow waves with superimposed spikes occurred at a variable frequency, accompanied by phasic contractions. Longitudinal muscle preparations showed a different behavior. Regular appearance of distinct slow waves as described for the circular muscle did not occur. Instead, periods of membrane potential oscillations at a frequency of 41 cycles/min and a duration of approximately 12 s were observed in this layer. Most oscillations had superimposed spikes, and each period of oscillations was associated with a contraction. Spontaneous activity in the circular layer was myogenic in nature but susceptible to innervation and stretch. In contrast, an excitatory stimulus (acetylcholine or stretch) was a prerequisite for activity in the longitudinal layer. Cholinomimetics increased and adrenergic agents decreased the frequency of the slow waves and spiking activity and frequency and force of contractions in the circular muscle. Cholinergic agents increased the activity in the longitudinal muscle into continuous electrical oscillations with spiking activity and concomitant tonic contractile activity, whereas adrenergic agents abolished electrical and mechanical activity. Spontaneous release of acetylcholine occurred, partly due to regenerative activity of myenteric cholinergic nerves. In addition, tonic activity in the noncholinergic nonadrenergic inhibitory neurons decreased circular muscle tone.     

Acetylcholinesterase and choline acetyltransferase staining of neurons in the opossum esophagus

The purpose of the present investigation was to identify and compare cholinergic intramural neurons in the lower esophageal sphincter and esophageal body by histochemical staining for acetylcholinesterase and the enzyme that synthesizes acetylcholine, choline acetyltransferase. Opossums were anesthetized and their abdominal cavity was opened by a midline incision to expose the esophagogastric junction. The lower esophageal sphincter was identified manometerically and localized in situ with markers. Tissues were removed, rapidly frozen in freon cooled with liquid nitrogen and serial cryostat sections were obtained from the lower esophageal sphincter and esophageal body. Sections were stained with one of the above histochemical procedures and adjacent sections were stained with Solachrome cyanin , which differentially stains nerve elements from muscle fibers. The muscle of the lower esophageal sphincter and esophageal body was stained with nonspecific cholinesterase with some selectivity of intensity of reaction in the various smooth muscle layers. All identifiable plexus neurons in the esophagus stained for nonspecific cholinesterase and acetylcholinesterase. Nerve fiber tracts were also stained for acetylcholinesterase within the longitudinal and circular layers of the tunica muscularis. Reaction for choline acetyltransferase showed no staining in the muscle layers or nerve fiber tracts of either part of the esophagus studied; however, selected neurons within the myenteric plexus of both regions (approximately 38%) were reactive. There was no significant difference in the number of positive choline acetyltransferase neurons in the lower esophageal sphincter or esophageal body.     

Tachykinins are involved in local reflex modulation of vagally mediated striated muscle contractions in the rat esophagus via tachykinin NK1 receptors

The objective of the present study was to investigate the hypothesis of the presence of a local neural reflex modulating the vagally mediated contractions of striated muscle in the rat esophagus and to determine the possible involvement of tachykinins in such a local neural reflex. Electrical stimulation of the vagus nerve evoked twitch contractile responses that were abolished by d-tubocurarine (5 microM). Capsaicin (1-100 microM) inhibited the vagally mediated twitch contractions o f the normal rat esophageal preparations concentration-dependently but not those of the neonatally capsaicin-treated ones. NG-nitro-L-arginine methyl ester (100 microM), a nitric oxide synthase inhibitor, blocked the inhibitory effect of capsaicin and exogenous application of a nitric oxide donor (1 mM) inhibited the vagally mediated twitch contractions. Capsaicin suppressed acetylcholine release from the normal rat esophageal segments evoked by vagus nerve stimulation but not that from the neonatally capsaicin-treated ones. A selective tachykinin NK1 receptor antagonist (0.1 or 1 microM) attenuated the inhibitory effect of capsaicin. However, antagonists of tachykinin NK2, tachykinin NK3 and calcitonin gene-related peptide receptors (1 microM) did not have any effect. A tachykinin NK1 receptor agonist (1 or 5 microM) inhibited the vagally mediated twitch contractions, which was prevented by NG-nitro-L-arginine methyl ester (100 microM). These data suggest that the rat esophagus might have a local neural reflex inhibiting the vagally mediated striated muscle motility, which consists of capsaicin-sensitive sensory neurons and myenteric nitrergic neurons, and that tachykinins might be involved in the neural reflex through tachykinin NK1 receptors.     

Long Vasodilator Reflexes Projecting Through the Myenteric Plexus in Guinea-Pig Ileum

This study examined enteric neural reflexes activating submucosal cholinergic vasodilator motoneurons, which innervate the final resistance vessels regulating mucosal blood flow. Videomicroscopy was employed to monitor dilatation of submucosal arterioles in in vitro preparations from guinea-pig ileum. Balloon distension of intact lumen evoked reflex vasodilatation and flat sheet preparations were employed to separate mucosal mechanical stimulation from intestinal distension. Mucosal stroking and balloon distension of the orad segment evoked vasodilatations > 1.5 cm from the stimulating site. Mucosal stimulation was blocked by combined 5-HT₃/5HT₄ antagonists but distension-evoked responses were unaffected. Distension-evoked responses were also unaffected by nifedipine (5 μ m ) or nifedipine (1 μ m ) and wortmannin (300 n m ), suggesting stretch activation rather than stretch-activated contraction was involved. Mucosal and distension-evoked responses were completely blocked when the myenteric plexus was surgically lesioned and were significantly inhibited by hexamethonium. The muscarinic antagonist 4-DAMP, which inhibits vasodilatations evoked by submucosal cholinergic vasodilator neurons, blocked dilatations elicited by mucosal stimulation and balloon distension. Maximal dilatations evoked with either sensory modality could be further enhanced when stimulated with the second modality. Dilatations evoked by stimulation of the aborad segment were similar to those elicited in the orad segment. In conclusion, sensory mechanisms in the mucosa and muscularis propria activate vasodilator pathways in the myenteric plexus which project for significant distances in both ascending and descending directions before innervating submucosal arterioles. These reflexes could co-ordinate mucosal blood flow during multiple motor events such as peristalsis and intestinal mixing between propulsive events.     

Immunohistochemical identification of cholinergic neurons in the myenteric plexus of guinea-pig small intestine.

It is well established that acetylcholine is a neurotransmitter at several distinct sites in the mammalian enteric nervous system. However, identification of the cholinergic neurons has not been possible due to an inability to selectively label enteric cholinergic neurons. In the present study an immunohistochemical method has been developed to localize choline acetyltransferase, the synthetic enzyme for acetylcholine, in order that cholinergic neurons can be visualized. The morphology, neurochemical coding and projections of cholinergic neurons in the guinea-pig small intestine were determined using double-labelling immunohistochemistry. These experiments have revealed that many myenteric neurons are cholinergic and that they can be distinguished by their specific combinations of immunoreactivity for neurochemicals such as calretinin, neurofilament protein triplet, substance P, enkephalin, somatostatin, 5-hydroxytryptamine, vasoactive intestinal peptide and calbindin. On the basis of their previously described projections, functional roles could be attributed to each of these populations. The identified cholinergic neurons are: motorneurons to the longitudinal muscle (choline acetyltransferase/calretinin); motorneurons to the circular muscle (choline acetyltransferase/neurofilament triplet protein/substance P, choline acetyltransferase/substance P and choline acetyltransferase alone); orally directed interneurons in the myenteric plexus (choline acetyltransferase/calretinin/enkephalin); anally directed interneurons in the myenteric plexus (choline acetyltransferase/somatostatin, choline acetyltransferase/5-hydroxytryptamine, choline acetyltransferase/vasoactive intestinal peptide); secretomotor neurons to the mucosa (choline acetyltransferase/somatostatin); and sensory neurons mediating myenteric reflexes (choline acetyltransferase/calbindin). This information provides a unique opportunity to identify functionally distinct populations of cholinergic neurons and will be of value in the interpretation of physiological and pharmacological studies of enteric neuronal circuitry.     

Contractile effects of histamine in large and small respiratory airways

The described technique allows recording of circular smooth muscle activity in isolated airways approx. 1 mm in diameter (bronchioles). It also allows recording of graded contractile and relaxant responses to drugs. Bronchiolar preparations and spirally cut airways (diameters 3–6 mm) were obtained from cat, dog, guinea-pig and man.Histamine is shown to contract cat bronchioles, large airways in cat being unaffected. The contraction is blocked by brompheniramine, but not by atropine. Other contractile agents, cholinoceptor-stimulants, prostaglandin F₂, 5-hydroxy-tryptamine, and potassium contract the isolated cat airways irrespective of their size.In preparations from dog, guinea-pig and man, histamine was shown to contract both small and large respiratory airways. The effect was blocked by brompheniramine, which did not change the effect of acetylcholine or pilocarpine. Both large and small airways contracted to cholinoceptor stimulation Within species, small and large airways were similarly sensitive to the contractile agents, except for histamine in cat airways.The present findings show a size- and species-dependent effect of histamine in respiratory airways. The effect of histamine in isolated cat airways might partly explain the pulmonary effect of histamine in vivo. The importance of including both small and large airways in studies of contractile and relaxant effects is emphasized.     

Immunocytochemical analysis of potential neurotransmitters present in the myenteric plexus and muscular layers of the corpus of the guinea pig stomach

Recent electrophysiological studies of neurons of the myenteric plexus of the corpus of the guinea pig stomach have revealed that slow synaptic events are extremely rare. In contrast, they are commonly encountered in similar investigations of myenteric ganglia of the guinea pig small intestine. The current immunocytochemical analysis of the myenteric plexus and innervation of the muscularis externa of the corpus of the guinea pig stomach was undertaken in order to determine whether putative neurotransmitters capable of mediating slow synaptic events are present in gastric ganglia. A major difference between the small intestine and the stomach was found in the innervation of the musculature. Whereas the longitudinal muscle layer of the small intestine contains very few nerve fibers and is innervated mainly at its interface with the myenteric plexus, the longitudinal muscle of the corpus of the stomach contained as many varicose substance P (SP)-, vasocative intestinal polypeptide (VIP)-, and neuropeptide Y (NPY)-immunoreactive axons as the circular muscle layer. These putative neurotransmitters were also present in the ganglia of the myenteric plexus, where varicose SP-, VIP-, and NPY-immunoreactive fibers encircled nonimmunoreactive neurons. Varicose 5-hydroxytryptamine (5-HT)-immunoreactive terminal axons were essentially limited to the myenteric plexus and were found both in ganglia and in interganglionic connectives, where they were particularly numerous; 5-HT-immunoreactive neurons appeared to be more abundant in the stomach than in the small intestine. Tyrosine hydroxylase (TH)- and calcitonin-gene-related-peptide (CGRP)-immunoreactive axons were also more common in the myenteric plexus than in the musculature, but of these, only the TH-immunoreactive neurites tended, like those of the other putative transmitters, to encircle neurons in myenteric ganglia. Evidence was obtained that, as in the small intestine, at least some of the SP-, VIP-, NPY-, and 5-HT-immunoreactive fibers in the stomach are derived from intrinsic gastric myenteric neurons. In contrast, unlike the small intestine, gastric myenteric ganglia appeared to lack intrinsic CGRP-immunoreactive neurons; therefore, the CGRP-immunoreactive gastric axons are probably of extrinsic origin.(ABSTRACT TRUNCATED AT 400 WORDS)     

Role of galanin receptor 1 in peristaltic activity in the guinea pig ileum

Galanin effects are mediated by distinct receptors, galanin receptor 1 (GAL-R1), GAL-R2 and GAL-R3. Here, we analyzed 1) the role of GAL-R1 in cholinergic transmission and peristalsis in the guinea-pig ileum using longitudinal muscle-myenteric plexus preparations and intact segments of the ileum in organ bath, and 2) the distribution of GAL-R1 immunoreactivity in the myenteric plexus with immunohistochemistry and confocal microscopy. Galanin inhibited electrically stimulated contractions of longitudinal muscle-myenteric plexus preparations with a biphasic curve. Desensitization with 1 microM galanin suppressed the high potency phase of the curve, whereas the GAL-R1 antagonist, RWJ-57408 (1 microM), inhibited the low potency phase. Galanin (3 microM) reduced the longitudinal muscle contraction and the peak pressure, and decreased the compliance of the circular muscle. All these effects were antagonized by RWJ-57408 (1 or 10 microM). RWJ-57408 (10 microM) per se did not affect peristalsis parameters in normal conditions, nor when peristalsis efficiency was reduced by partial nicotinic transmission blockade with hexamethonium. In the myenteric plexus, GAL-R1 immunoreactivity was localized to neurons and to fibers projecting within the plexus and to the muscle. GAL-R1 was expressed mostly by cholinergic neurons and by some neurons containing vasoactive intestinal polypeptide or nitric oxide synthase. This study indicates that galanin inhibits cholinergic transmission to the longitudinal muscle via two separate receptors; GAL-R1 mediates the low potency phase. The reduced peristalsis efficiency could be explained by inhibition of the cholinergic drive, whereas the decreased compliance is probably due to inhibition of descending neurons and/or to the activation of an excitatory muscular receptor. Endogenous galanin does not appear to affect neuronal pathways subserving peristalsis in physiologic conditions via GAL-R1.     

Mechanical activity of frog esophagus muscle in response to electrical stimulation of intramural nerves.

Microscopic observation of intramural nerves in the frog esophagus, fixed and stained with OsO(4) and ZnI(2), revealed that nerve cell bodies and bundles connecting the nerve cell bodies formed loose and irregular networks. The nerve cell bodies were mostly lying singly in the nerve bundles, with occasional observations of two closely linked nerve cell bodies. Isolated circular and longitudinal segments of esophageal muscle were spontaneously rhythmically contractile, with a frequency of 2.2-3.0 per min. This was not altered by tetrodotoxin (TTX). In longitudinal muscle segments, transmurally applied electrical stimulation produced contractile responses which were not inhibited by atropine or guanethidine, but were reduced in amplitude by TTX, suggesting a nonadrenergic-noncholinergic (NANC) excitatory innervation in the esophagus muscle. In circular muscle segments, transmural application of brief electrical stimulation evoked two types of mechanical response: a biphasic response consisting of an initial relaxation and a following contraction (type I) and a contraction alone (type II). These mechanical responses were not modulated by either atropine or guanethidine. In the type I response, TTX abolished the relaxation component, suggesting that this was produced by non-adrenergic non-cholinergic (NANC) inhibitory nerve excitation. In about half of the type II responses, the amplitude of the contraction was significantly reduced by TTX, suggesting that a part of the contraction was produced by activation of NANC excitatory nerves. Thus, the esophageal smooth muscle of the frog demonstrates myogenic activity, and is innervated by both excitatory and inhibitory NANC nerves.     

Reticular groove and reticulum are innervated by myenteric neurons with different neurochemical codes

The reticulum and the reticular groove are functional distinct compartments within the ovine forestomach. While the reticulum takes part in various motor functions, such as mixing, retaining, and rejecting the forestomach ingesta, the reticular groove serves mainly as a bypass between the esophagus and the abomasum. To accomplish these different tasks, the compartments develop specific motility patterns that are controlled by intrinsic neural circuits. In this study the intrinsic innervation by myenteric neurons was analyzed by quadruple immunohistochemistry against cholineacetyl transferase (ChAT), nitric oxide synthase (NOS), substance P (SP), and vasoactive intestinal peptide (VIP). Four neurochemically different subpopulations of myenteric neurons were found in the reticulum and the floor of the reticular groove: ChAT/-, ChAT/SP, NOS/-, and NOS/VIP. The neuronal proportions were calculated relative to all myenteric neurons. Neurons of the reticulum were mostly immunoreactive for ChAT (89% +/- 3%), whereas neurons adjacent to the reticular groove predominantly expressed a nitrergic phenotype (62% +/- 4%). ChAT-positive neurons were also immunoreactive for SP (ChAT/SP: 64% +/- 3% reticulum; 25% +/- 1% reticular groove) or were purely cholinergic (ChAT/-: 25% +/- 4% reticulum; 13% +/- 3% reticular groove). NOS-positive neurons colocalized VIP (NOS/VIP: 10% +/- 3% reticulum; 46% +/- 1% reticular groove) or none of the other neurotransmitters (NOS/-: 1% +/- 1% reticulum; 17% +/- 3% reticular groove). Analysis of the soma sizes revealed that in both compartments the nitrergic neurons were significantly larger than the cholinergic neurons. It is suggested that the specific neurochemical code in combination with a specific morphology leads to a precise regulation of the specialized tasks of the reticulum and reticular groove by subpopulations of myenteric neurons.     

Directing phenotype of vascular smooth muscle cells using electrically stimulated conducting polymer

Vascular smooth muscle cells (VSMCs) isolated from rabbit aorta and immortalised A7r5 cells were cultured on conducting polypyrrole (PPy) substrates and were subjected to a 50muA sinusoidal electrical stimulation at 0.05, 5 and 500 Hz. These substrates were doped with hyaluronic acid and coated with collagen IV followed by Matrigel in order to mimic the basement membrane and encourage cell attachment. Increased proliferation and expression of smooth muscle phenotype markers (smooth muscle alpha-actin and smooth muscle myosin heavy chain) were observed in cultures stimulated at 5 and 500 Hz. This increased proliferation and expression of contractile proteins were found to be significantly decreased when L-type voltage-gated calcium channels (VGCC) were blocked with the drug nifedipine. To the best of our knowledge, this is the first work that demonstrates that VSMCs cultured on a conducting polymer substrate and subject to electrical stimulation not only exhibit enhanced proliferation but can be simultaneously encouraged to increase contractile protein expression. This behaviour is somewhat contrary to the classical definition of smooth muscle contractile and synthetic phenotypes that, in general, requires a modulation in phenotype as a prerequisite for smooth muscle proliferation. This interesting result highlights both the inherent plasticity of vascular smooth muscle cells and the potential of electrical stimulation via conducting polymer substrates to manipulate their behaviour.     

Projections of chemically identified myenteric neurons of the small and large intestine of the mouse

The projections of different subpopulations of myenteric neurons in the mouse small and large intestine were examined by combining immunohistological techniques with myotomy and myectomy operations. The myotomies were used to examine the polarity of neurons projecting within the myenteric plexus and showed that neurons containing immunoreactivity for nitric oxide synthase (NOS), vasoactive intestinal peptide (VIP), calbindin and 5-HT projected anally, while neurons with substance P (SP)-immunoreactivity projected orally, in both the small and large intestine. Neurons containing neuropeptide Y (NPY)- and calretinin-immunoreactivity projected locally. In the large intestine, GABA-immunoreactive neurons projected both orally and anally, with more axons tending to project anally. Myectomy operations revealed that circular muscle motor neurons containing NOS/VIP/±NPY and calretinin neurons projected anally both in the small and large intestine, while SP-immunoreactive circular muscle motor neurons projected orally. In the large intestine, GABA-IR circular muscle motor neurons projected both orally and anally. This study showed that although some neurons, such as the NOS/VP inhibitory motor neurons and interneurons, SP excitatory motor neurons and 5-HT interneurons had similar projections to those in other species, the projections of other chemical classes of neurons in the mouse intestine differed from those reported in other species.     

Differentiation between pre- and postjunctional α-receptors in guinea pig ileum and rabbit aorta

Electric stimulation of proximal and terminal guinea pig ileum induced contractions which were mediated by stimulation of cholinergic neurons. After blocking β-receptors, prejunctional α-receptors mediating inhibition could be studied in these neurons. In proximal ileum the order of potencies of the following agonists was: clonidine (8)* < epinephrine (3) < oxymetazoline (2)< norepinephrine (1)< phenylephrine (0.02). The intrinsic activities of clonidine and phenylephrine were not maximal. In electrically stimulated terminal ileum practically identical results were obtained on the prejunctional α-receptor except that phenylephrine was ineffective; the drug instead acted as a competitive blocker against norepinephrine. After blocking cholinergic receptors with atropine, excitatory α-receptors located postjunctionally in the smooth muscle cells of terminal ileum could be studied. Under these conditions the order of potencies of the agonists was: oxymetazoline (40)< epinephrine (7) < phenylephrine (4)<norepinephrine (1)< clonidine (0.2). In contracting postjunctional α-receptors in rabbit aorta the order of potencies was: oxymetazoline (5) < norepinephrine (1) < epinephrine (0.7) < phenylephrine (0.2) > clonidine (0.04). On the postjunctional α-receptor in terminal guinea pig ileum phentolamine was 55 fold more effective in blocking the response of norepinephrine than it was on blocking the response on the prejunctional receptor of the same preparation. Phenoxybenzamine (4 times 10^-8 M) was ineffective on the prejunctional α-receptor of the cholinergic neuron, while it blocked the postjunctional α-receptor of smooth muscle in guinea pig terminal ileum noncompetitively. It is suggested that the differences in the activities of clonidine and phenylephrine between prejunctional α-receptors located to cholinergic neurons and postjunctional α-receptors located to smooth muscle cells was due to a pharmacological difference between the receptors. The results obtained with the blockers support this suggestion.