Vagal preganglionic axons arborize in the myenteric plexus into two types: nitrergic and non-nitrergic postganglionic motor pools?

Vagal preganglionic neurons innervate myenteric ganglia. These autonomic efferents are distributed so densely within the ganglia that it has been impractical to track individual vagal axons through the myenteric plexus with tracer labeling. To evaluate whether vagal efferent axons evidence selectivity, particularly for nitrergic or non-nitrergic myenteric neurons within the plexus, we limited the numbers and volumes of brainstem dextran biotin tracer injections per animal. Reduced labeling and the use of immunohistochemistry generated cases in which some individual axons could be distinguished and traced in three dimensions (Neurolucida) within and among successive (up to 46) myenteric ganglia. In the myenteric plexus of all stomach regions, the majority (∼86%) of vagal efferents were organized into two distinct subtypes. One subtype (∼24% of dextran-labeled efferents, designated "primarily nitrergic") selectively contacted and linked-both within and between ganglia-nitric oxide synthase positive (nNOS+) neurons into presumptive motor modules. A second subtype (∼62% of efferents, designated "primarily non-nitrergic") appeared to selectively contact and link-both within and between ganglia-non-nitrergic enteric neurons into a second type of effector ensemble. A third candidate type (∼14% of labeled preganglionics), appeared to lack "nitrergic selectivity" and to contact both nNOS+ and nNOS- enteric neurons. In addition to the quantitative assessment of the efferent axons in stomach, qualitative observations of the proximal duodenum indicated similar selective vagal efferent projections, in proportions comparable with those evaluated in the stomach. Limited injections of tracer, three-dimensional (3-D) tracing of individual axons, and histochemistry of myenteric neurons might distinguish additional efferent phenotypes.NEW & NOTEWORTHY The present study highlights the following: 1) one type of vagal efferent axon selectively innervates nitrergic upper gastrointestinal myenteric neurons; 2) a second type of vagal efferent selectively innervates non-nitrergic gastrointestinal myenteric neurons; and 3) the two types of vagal efferents might modulate peristalsis reciprocally and cooperatively.

Vagus nerve stimulation promotes gastric emptying by increasing pyloric opening measured with magnetic resonance imaging.

BACKGROUND: Vagus nerve stimulation (VNS) is an emerging electroceutical therapy for remedying gastric disorders that are poorly managed by pharmacological treatments and/or dietary changes. Such therapy seems promising as the vagovagal neurocircuitry modulates the enteric nervous system to influence gastric functions. METHODS: Here, the modulatory effects of left cervical VNS on gastric emptying in rats were quantified using a (i) feeding protocol in which the animal voluntarily consumed a postfast, gadolinium-labeled meal and (ii) a non-invasive imaging method to measure antral motility, pyloric activity and gastric emptying based on contrast-enhanced magnetic resonance imaging (MRI) and computer-assisted image processing pipelines. KEY RESULTS: Vagus nerve stimulation significantly accelerated gastric emptying (sham vs VNS: 29.1% ± 1.5% vs 40.7% ± 3.9% of meal emptied per 4 hours), caused a greater relaxation of the pyloric sphincter (sham vs VNS: 1.5 ± 0.1 vs 2.6 ± 0.4 mm2 cross-sectional area of lumen), and increased antral contraction amplitude (sham vs VNS: 23.3% ± 3.0% vs 32.5% ± 3.0% occlusion), peristaltic velocity (sham vs VNS: 0.50 ± 0.02 vs 0.67 ± 0.03 mm s-1 ), but not its contraction frequency (sham vs VNS: 6.1 ± 0.2 vs 6.4 ± 0.2 contractions per minute, P = .22). The degree to which VNS relaxed the pylorus was positively correlated with gastric emptying rate (r = .5887, P < .001). CONCLUSIONS & INFERENCES: The MRI protocol employed in this study is expected to enable advanced preclinical studies to understand stomach pathophysiology and its therapeutics. Results from this study suggest an electroceutical treatment approach for gastric emptying disorders using cervical VNS to control the degree of pyloric sphincter relaxation.

Alpha-synuclein expression patterns in the colonic submucosal plexus of the aging Fischer 344 rat: implications for biopsies in aging and neurodegenerative disorders?

BACKGROUND: This experiment assessed normative expression patterns of alpha-synuclein (SYNC), including ganglionic remodeling and development of SYNC pathologies, in the submucosal plexus (SMP) of the colon during healthy aging. The observations address age-associated changes in bowel function and are relevant to evaluations of SMP-containing colonic biopsies for SYNC or synucleinopathies associated with aging and peripheral neurodegenerative diseases. METHODS: Colonic submucosal whole mounts from groups of virgin male Fischer 344 rats (n ≥ 8 per group) at 4, 8, 16, and 24 months of age were processed immunohistochemically for SYNC and the pan-neuronal marker HuC/D. In addition, macrophages immunoreactive for MHCII were examined. Stereological protocols were used to generate unbiased estimates of neuron density, neurons per ganglion, neurons per ganglionic area, and neuron size. KEY RESULTS: The protein SYNC was expressed in a subpopulation of SMP neurons, in both nucleus and cytoplasm. The general age-associated pattern across different cell counts was an increase in the number of SYNC+ neurons between 4 and 8 months of age, with progressively decreasing numbers of both SYNC+ and SYNC- neurons over the remaining lifespan. The soma size of SYNC+ neurons increased progressively with age. Aggregated SYNC occurred in the aging SMP, and macrophages with alternatively activated profiles were located adjacent to pathological SYNC deposits, consistent with ongoing phagocytosis. CONCLUSIONS & INFERENCES: Changes in SYNC expression with age, including a baseline of accumulating synucleinopathies in the healthy aging SMP, need to be considered when interpreting either functional disturbances or biopsies of the aging colon.

Vagal sensory innervation of the gastric sling muscle and antral wall: implications for gastro-esophageal reflux disease?

BACKGROUND: The gastric sling muscle has not been investigated for possible sensory innervation, in spite of the key roles the structure plays in lower esophageal sphincter (LES) function and gastric physiology. Thus, the present experiment used tracing techniques to label vagal afferents and survey their projections in the lesser curvature. METHODS: Sprague-Dawley rats received injections of dextran biotin into the nodose ganglia. Fourteen days postinjection, animals were euthanized and their stomachs were processed to visualize the vagal afferent innervation. In different cases, neurons, muscle cells, or interstitial cells of Cajal (ICC) were counterstained. KEY RESULTS: The sling muscle is innervated throughout its length by vagal afferent intramuscular arrays (IMAs) associated with ICC. In addition, the distal antral attachment site of the sling muscle is innervated by a novel vagal afferent terminal specialization, an antral web ending. The muscle wall of the distal antrum is also innervated by conventional IMAs and intraganglionic laminar endings, the two types of mechanoreceptors found throughout stomach smooth muscle. CONCLUSIONS & INFERENCES: The innervation of sling muscle by IMAs, putative stretch receptors, suggests that sling sensory feedback may generate vago-vagal or other reflexes with vagal afferent limbs. The restricted distribution of afferent web endings near the antral attachments of sling fibers suggests the possibility of specialized mechanoreceptor functions linking antral and pyloric activity to the operation of the LES. Dysfunctional sling afferents could generate LES motor disturbances, or normative compensatory sensory feedback from the muscle could compromise therapies targeting only effectors.

Vagal intramuscular array afferents form complexes with interstitial cells of Cajal in gastrointestinal smooth muscle: analogues of muscle spindle organs?

Intramuscular arrays (IMAs), vagal mechanoreceptors that innervate gastrointestinal smooth muscle, have not been completely described structurally or functionally. To delineate more fully the architecture of IMAs and to consider the structure-function implications of the observations, the present experiment examined the organization of the IMA terminal arbors and the accessory tissue elements of those arbors. IMA terminal fields, labeled by injection of biotinylated dextran into the nodose ganglia, were examined in whole mounts of rat gastric smooth muscle double-labeled with immunohistochemistry for interstitial cells of Cajal (ICCs; c-Kit) and/or inputs of different neuronal efferent transmitter (markers: tyrosine hydroxylase (TH), vesicular acetylcholine transporter (VAChT), and nitric oxide synthase (NOS)) or afferent neuropeptidergic (calcitonin gene-related peptide (CGRP)) phenotypes. IMAs make extensive varicose and lamellar contacts with ICCs. In addition, axons of the multiple efferent and afferent phenotypes examined converge and articulate with IMA terminal arbors innervating ICCs. This architecture is consistent with the hypothesis that IMAs, or the multiply innervated IMA-ICC complexes they form, can function as stretch receptors. The tissue organization is also consonant with the proposal that those units can operate as functional analogues of muscle spindle organs. For electrophysiological assessments of IMA functions, experiments will need protocols that preserve both the complex architecture and the dynamic operations of IMA-ICC complexes.

Altered mechanosensitive properties of vagal afferent fibers innervating the stomach following gastric surgery in rats.

BACKGROUND AND AIMS: Several types of gastric surgeries have been associated with early satiety, dyspepsia and food intolerances. We aimed to examine alterations in gastric vagal afferents following gastric surgery-fundus ligation. METHODS: Six week old, male Sprague-Dawley rats underwent chronic ligation (CL) of the fundus. Sham rats underwent abdominal surgery, but without ligation. Another group of rats underwent acute ligation (AL) of the fundus immediately prior to experiments. CL and sham rats were allowed to grow to age 3-4 months. Food intake and weights were recorded post-operatively. Gastric compliance and gastric wall thickness was measured at baseline and during gastric distension (GD). Extracellular recordings were made to examine response characteristics of vagal afferent fibers to GD and to map the stomach receptive field (RF). The morphological structures of afferent terminals in the stomach were examined with retrograde tracings from the nodose ganglion. RESULTS: The CL group consumed significantly less food and weighed less than sham control. The mean compliance of the CL group was significantly less than control, but higher than the AL group. The spontaneous firing and responses to GD of afferent fibers from the CL rats were significantly higher than AL rats. There was a marked expansion of the gastric RF in the CL rats with significant reorganization and regeneration of intramuscular array (IMA) terminals. There was no difference in total wall or muscle thickness among the groups. CONCLUSION: CL results in aberrant remodeling of IMAs with expansion of the gastric RF and alters the mechanotransduction properties of vagal afferent fibers. These changes could contribute to altered sensitivity following gastric surgery.

Alpha-synuclein-immunopositive myenteric neurons and vagal preganglionic terminals: autonomic pathway implicated in Parkinson's disease?

The protein alpha-synuclein is implicated in the development of Parkinson's disease. The molecule forms Lewy body aggregates that are hallmarks of the disease, has been associated with the spread of neuropathology from the peripheral to the CNS, and appears to be involved with the autonomic disorders responsible for the gastrointestinal (GI) symptoms of individuals afflicted with Parkinson's. To characterize the normative expression of alpha-synuclein in the innervation of the GI tract, we examined both the postganglionic neurons and the preganglionic projections by which the disease is postulated to retrogradely invade the CNS. Specifically, in Fischer 344 and Sprague-Dawley rats, immunohistochemistry in conjunction with injections of the tracer Dextran-Texas Red was used to determine, respectively, the expression of alpha-synuclein in the myenteric plexus and in the vagal terminals. Alpha-synuclein is expressed in a subpopulation of myenteric neurons, with the proportion of positive somata increasing from the stomach (approximately 3%) through duodenum (proximal, approximately 6%; distal, approximately 13%) to jejunum (approximately 22%). Alpha-synuclein is co-expressed with the nitrergic enzyme nitric oxide synthase (NOS) or the cholinergic markers calbindin and calretinin in regionally specific patterns: approximately 90% of forestomach neurons positive for alpha-synuclein express NOS, whereas approximately 92% of corpus-antrum neurons positive for alpha-synuclein express cholinergic markers. Vagal afferent endings in the myenteric plexus and the GI smooth muscle do not express alpha-synuclein, whereas, virtually all vagal preganglionic projections to the gut express alpha-synuclein, both in axons and in terminal varicosities in apposition with myenteric neurons. Vagotomy eliminates most, but not all, alpha-synuclein-positive neurites in the plexus. Some vagal preganglionic efferents expressing alpha-synuclein form varicose terminal rings around myenteric plexus neurons that are also positive for the protein, thus providing a candidate alpha-synuclein-expressing pathway for the retrograde transport of putative Parkinson's pathogens or toxins from the ENS to the CNS.

Ultrastructural evidence for communication between intramuscular vagal mechanoreceptors and interstitial cells of Cajal in the rat fundus.

To assess whether afferent vagal intramuscular arrays (IMAs), putative gastrointestinal mechanoreceptors, form contacts with interstitial cells of Cajal of the intramuscular type (ICC-IM) and to describe any such contacts, electron microscopic analyses were performed on the external muscle layers of the fundus containing dextran-labelled diaminobenzidin (DAB)-stained IMAs. Special staining and embedding techniques were developed to preserve ultrastructural features. Within the muscle layers, IMA varicosities were observed in nerve bundles traversing major septa without contact with ICC-IM, contacting unlabelled neurites and glial cells. IMA varicosities were encountered in minor septa in contact with ICC-IM which were not necessarily in close contact with muscle cells. In addition, IMA varicosities were observed within muscle bundles in close contact with ICC-IM which were in gap junction contact with muscle cells. IMAs formed varicosities containing predominantly small agranular vesicles, occasionally large granular vesicles and prejunctional thickenings in apposition to ICC-IM processes, indicating communication between ICC and IMA via synapse-like contacts. Taken together, these different morphological features are consistent with a hypothesized mechanoreceptor role for IMA-ICC complexes. Intraganglionic laminar ending varicosities contacted neuronal somata and dendrites in the myenteric plexus of the fundus, but no contacts with ICC associated with Auerbach's plexus were encountered.

Inhibitory effects on intake of cholecystokinin-8 and cholecystokinin-33 in rats with hepatic proper or common hepatic branch vagal innervation.

The relative potencies of cholecystokinin (CCK)-8 and CCK-33 for decreasing meal size depend on the route of administration. Inhibitory potencies are equal after intraperitoneal administration, but CCK-33 is significantly more potent after intraportal administration. This suggests that CCK-33 is a more effective stimulant of hepatic afferent vagal nerves than is CCK-8. To investigate this possibility, we administered both peptides intraperitoneally in rats with abdominal vagotomies that spared only the hepatic proper vagal nerves (H) and in rats with abdominal vagotomies that spared the common hepatic branch that contains the fibers of the hepatic proper and gastroduodenal nerves (HGD). The vagal afferent innervation in H and HGD rats was verified with a wheat germ agglutinin-horseradish tracer strategy. Intraperitoneal administration of CCK-33 decreased 30-min intake of 10% sucrose in H rats as much as in sham rats, but CCK-8 decreased intake significantly less in H rats than in sham rats. The larger inhibitory effect of CCK-33 than of CCK-8 in H rats is consistent with the hypothesis that CCK-33 is a more effective stimulant of the hepatic proper vagal afferent nerves than CCK-8. In contrast to the results in H rats, the inhibitory potencies of both peptides were significantly and equivalently reduced in HGD rats compared with sham rats. This suggests that there is an inhibitory interaction between the stimulation of the gastroduodenal and hepatic proper afferent fibers by CCK-33.

Neurotrophin-4 deficient mice have a loss of vagal intraganglionic mechanoreceptors from the small intestine and a disruption of short-term satiety.

Intraganglionic laminar endings (IGLEs) and intramuscular arrays (IMAs) are the two putative mechanoreceptors that the vagus nerve supplies to gastrointestinal smooth muscle. To examine whether neurotrophin-4 (NT-4)-deficient mice, which have only 45% of the normal number of nodose ganglion neurons, exhibit selective losses of these endings and potentially provide a model for assessing their functional roles, we inventoried IGLEs and IMAs in the gut wall. Vagal afferents were labeled by nodose ganglion injections of wheat germ agglutinin-horseradish peroxidase, and a standardized sampling protocol was used to map the terminals in the stomach, duodenum, and ileum. NT-4 mutants had a substantial organ-specific reduction of IGLEs; whereas the morphologies and densities of both IGLEs and IMAs in the stomach were similar to wild-type patterns, IGLEs were largely absent in the small intestine (90 and 81% losses in duodenum and ileum, respectively). Meal pattern analyses revealed that NT-4 mutants had increased meal durations with solid food and increased meal sizes with liquid food. However, daily total food intake and body weight remained normal because of compensatory changes in other meal parameters. These findings indicate that NT-4 knock-out mice have a selective vagal afferent loss and suggest that intestinal IGLEs (1) may participate in short-term satiety, probably by conveying feedback about intestinal distension or transit to the brain, (2) are not essential for long-term control of feeding and body weight, and (3) play different roles in regulation of solid and liquid diet intake.

C-Kit mutant mice have a selective loss of vagal intramuscular mechanoreceptors in the forestomach.

Intramuscular arrays are one of two major classes of vagal afferent mechanoreceptors that innervate the smooth muscle wall of the proximal gastrointestinal tract. They consist of rectilinear telodendria that distribute in the muscle sheets, parallel to the long axes of muscle fibers. Intramuscular arrays appear to make direct contact with the muscle fibers, but they also course on, and form appositions with, intramuscular interstitial cells of Cajal. These complexes formed by intramuscular arrays and intramuscular interstitial cells of Cajal suggest that intramuscular arrays might require either structural or trophic support of the interstitial cells of Cajal for normal differentiation and/or maintenance. To evaluate this hypothesis, we have examined the morphology and distribution of vagal afferent endings in the c-Kit mutant mouse that lacks intramuscular interstitial cells of Cajal. Vagal afferents were labeled by nodose ganglion injection of either wheat germ agglutinin-horseradish peroxidase conjugate or a tagged dextran, and the labeled afferent terminals in the stomach were mapped using a standardized quantitative sampling scheme. Intramuscular arrays were dramatically reduced (in circular muscle by 63%; in longitudinal muscle by 78%) in the c-Kit mutant mice relative to their wild-type littermates. Additionally, a substantial number of the surviving axons and terminals in the mutant stomachs were morphologically aberrant. Moreover, the loss of intramuscular arrays in mutants appeared to be selective: the structure, distribution and density of intraganglionic laminar endings, i.e., the other vagal mechanoreceptors in smooth muscle, were not significantly altered. Finally, the conspicuous decrease in intramuscular array density in mutants was associated with a non-significant trend toward loss of nodose ganglion neurons. Collectively these findings suggest that interstitial cells are required for the normal development or maintenance of vagal intramuscular arrays. Therefore, the c-Kit mutant mouse will be valuable for determining the role(s) of interstitial cells in intramuscular array development as well as for providing an animal model with the intramuscular array class of vagal afferents selectively ablated.

Gastrointestinal projection maps of the vagus nerve are specified permanently in the perinatal period.

The vagal innervation of the proximal gastrointestinal (GI) tract is lateralized. To determine whether this pattern is specified as early as the perinatal period, neonatal rat pups were given unilateral cervical vagotomies. Separate groups received (1) transections below the left nodose ganglion, (2) left cervical resections that included removal of the nodose ganglion, or (3) sham surgeries. At 4 months of age, each animal's vagal afferent projections from the unoperated side were mapped by injecting the nodose with WGA-HRP, preparing the stomach as wholemounts, and processing the tissue with tetramethyl benzidine. The two types of vagal afferent endings in GI smooth muscle, namely intraganglionic laminar endings and intramuscular arrays, were surveyed separately, and their regional distributions were mapped. Changes in the nucleus of the solitary tract (NST) and dorsal motor nucleus of the vagus (DMNX) were assessed with cell counts and area measurements. Neonatal loss of the vagus innervating one side of the GI tract, with or without ganglionectomy, did not cause the unoperated vagus to sprout to the denervated side. In addition, removal of the projections to the one side of the target organ did not produce a reorganization of the projection maps of the unoperated vagus within its normal or ipsilateral wall of the GI tract. Although the regional patterns of the unoperated ipsilateral vagus were not affected, the packing densities of both types of afferents supplied by this trunk were moderately reduced. The DMNX of the vagotomized side displayed extensive (approximately 83%) neuronal loss; the DMNX on the unoperated side as well as the NST on both sides exhibited limited (approximately 20--25%) losses. The lack of a peripheral projection field reorganization -- except for a moderate down-regulation -- after complete unilateral denervation suggests that both the laterality and the afferent terminal phenotypes (or target tissues) of the vagus in the proximal GI tract are specified by postnatal day one in the rat. The present results, taken together with other observations, also suggest that three different combinations of signals orchestrate the commitments of vagal afferents respectively to (1) the side of the organ, (2) the region within the organ wall, and (3) the accessory and innervated tissues that complex with the fully differentiated ending.

As the gut ages: timetables for aging of innervation vary by organ in the Fischer 344 rat.

To explore the effects of aging on the vagal innervation of the gastrointestinal (GI) tract, male Fischer 344 rats at 3 and 24 months of age were injected in the left nodose ganglion with 3 microl of either 4% wheat germ agglutinin-horseradish peroxidase (to label sensory endings) or 1% cholera toxin subunit B-horseradish peroxidase (to label motor endings). The stomach and duodenum were prepared as wholemounts and processed with tetramethyl benzidine. In addition, to study age-related changes in the myenteric plexus, the stomachs, small intestines, and large intestines from 3-, 12-, 21-, 24- and 27-month-old rats were prepared as wholemounts and processed with Cuprolinic Blue (to stain the neurons). Vagal afferent endings, motor terminal profiles, and myenteric neurons were counted and mapped with a sampling grid. In the stomach, both the vagal and myenteric innervation were stable between the ages of 3 and 24 months; however, a decrease in the number of myenteric neurons in the forestomach was noted at 27 months. In the small and large intestines, myenteric cell loss occurred by 12 months of age, progressed with age, and appeared to be governed by several general principles: (1) the rate of cell loss was organ-specific, with a gradient of increasing severity from proximal to distal in the gut; (2) within organs of the GI tract, the rate of cell loss differed between regions; and (3) for given regions, cell losses progressed linearly with increasing age. The findings suggest that a positive relationship exists between the density of vagal extrinsic innervation and myenteric neuron survival; however, whether this results from the vagal innervation and/or other factor(s) protecting or rescuing myenteric neurons from age-related attrition remains to be determined.

Vagal afferent innervation of smooth muscle in the stomach and duodenum of the mouse: morphology and topography.

Intraganglionic laminar endings (IGLEs) and intramuscular arrays (IMAs), the two putative mechanoreceptors that the vagus nerve supplies to the gastrointestinal smooth muscle, have been characterized almost exclusively in the rat. To provide normative inventories of these afferents for the mouse, the authors examined the endings in the stomach and small intestine of three strains used as backgrounds for gene manipulations (i.e., C57, 129/SvJ, and WBB6). Animals received nodose ganglion injections of wheat germ agglutinin-horseradish peroxidase or dextran-tetramethylrhodamine conjugated to biotin. The horseradish peroxidase tissue was processed with tetramethylbenzidine and was used to map the distributions and densities of the two endings; the dextran material was counterstained with c-Kit immunohistochemistry to assess interactions between intramuscular arrays and interstitial cells of Cajal. IGLEs and IMAs constituted the vagal innervation of mouse gastric and duodenal smooth muscle. IGLE morphology and distributions, with peak densities in the corpus-antrum, were similar in the three strains of mice and comparable to those observed in rats. IMAs varied in complexity from region to region but tended to be simpler (fewer telodendria) in mice than in rats. IMAs were most concentrated in the forestomach and sphincters in mice, as in rats, but the topographic distributions of the endings varied both between strains of mice (subtly) and between species (more dramatically). IMAs appeared to make appositions with both interstitial cells and smooth muscle fibers. This survey should make it practical to assay the effects of genetic (e.g., knockout) and experimental (e.g., regeneration) manipulations affecting visceral afferents and their target tissues.

Tension and stretch receptors in gastrointestinal smooth muscle: re-evaluating vagal mechanoreceptor electrophysiology.

Electrophysiological and morphological analyses of vagal mechanoreceptors in the gut wall suggest conflicting conclusions. Electrophysiology has distinguished a single general class of ending in smooth muscle, one characterized as an 'in series' tension receptor. Morphology, in contrast, has characterized two distinct specializations of vagal afferent endings in the muscle wall of the gastrointestinal (GI) tract. These two structures differ in terms of their target tissues, terminal architectures and regional distributions; they also develop on different ontogenetic timetables and depend on different trophic support in the muscle wall. On the basis of these features, we have proposed that one of the putative mechanoreceptors, the intraganglionic laminar ending (IGLE), has characteristics of a tension receptor and the other, the intramuscular array (IMA), has features of a stretch or length receptor. In a functional analogy with striated muscle proprioceptors, IGLEs should have similarities to Golgi tendon organs, whereas IMAs should have equivalencies with muscle spindle afferents. The present survey re-examines the recording analyses in light of the structural observations. This review indicates that previous electrophysiological studies are too inconclusive to refute the inference that the vagus supplies two distinct types of mechanoreceptors to the muscle wall of the GI tract. Multiple methodological constraints and sources of variance have limited the resolution of electrophysiological experiments. Specifically, these experiments have conventionally used distension stimuli that confound tension and stretch. In addition, sampling strategies have biased recording experiments towards a focus on one type of ending, the IGLE. Furthermore, putative functional properties (e.g., broad tuning) of vagal mechanoreceptors suggest that distinguishing two recording patterns will require exacting protocols. Combining a recognition of the methodological difficulties that have limited electrophysiological analyses with an understanding of the structural features of the endings, however, suggests several critical electrophysiological experiments with the resolution to distinguish two classes of response profiles. Until such experiments can be conducted, sensory physiology's axiom that 'function varies with form', taken together with a re-assessment of the existing data, suggests that the vagus nerve supplies stretch receptors as well as tension receptors to the wall of the GI tract.

Nucleus ambiguus projections to cardiac ganglia of rat atria: an anterograde tracing study.

We injected the anterograde fluorescent tracer 1,1;-dioleyl-3,3,3;, 3;-tetramethylindocarbocyanine methanesulfonate (DiI) into the nucleus ambiguus (NA) and used confocal microscopy to inventory NA fibers and axon terminals in whole-mounts of rat atrial tissues. Both the axons projecting to cardiac ganglia and the innervated principal neurons (PNs) were counted. Rats were injected unilaterally in the NA with DiI, either at four sites (between 600 microm rostral and 600 microm caudal to the obex) or at nine sites (1,600 microm rostral to 1,600 microm caudal). Fluoro-Gold was administered intraperitoneally to retrogradely label neurons of the dorsal motor nucleus of the vagus (DmnX), NA, and cardiac ganglia. To verify that the DiI-labeled fibers examined in the atria originated exclusively from the NA, neurons of the DmnX and the nodose ganglia were surveyed for DiI labeling. Our observations established that (1) NA fibers in the cardiac branches of the vagus numbered in the range of 82-151, left; or 60-122, right. (2) Both left and right NA supplied substantial numbers of fibers to each of the three major cardiac ganglionic plexuses. (3) NA axons terminated in dense basket, or calyx, endings around individual PNs. (4) By issuing divergent collaterals, individual NA fibers supplied numerous PNs with these calyx endings. (5) Labeled axons innervated 2,248 (left vagus) and 1,784 (right), or at least 56% and 45%, of the cardiac PNs. (6) Divergence (i.e., NA axons:PNs innervated) averaged between 1:27 (left vagus) and 1:30 (right vagus). Several features of these NA projections to cardiac ganglia contrasted sharply with those of DmnX projections that we have recently characterized with the same tracing protocol: (1) NA fibers did not innervate small intensely fluorescent cell clusters in cardiac ganglia, whereas DmnX axons did. (2) NA efferent fascicles contained more large fibers (presumably B-type), whereas the DmnX issued more fine caliber fibers (presumably C-type). (3) NA fibers diverged about three times as extensively as did DmnX axons. Taken together, our data strongly suggest that vagal control of the heart involves the convergence and integration of distinct NA and DmnX projections within the cardiac plexuses.

Topographic inventories of vagal afferents in gastrointestinal muscle.

To inventory and characterize the two types of vagal afferents (both putative mechanoreceptors) in the muscle of the gastrointestinal tract, the authors injected wheat germ agglutinin-horseradish peroxidase into the nodose ganglia of rats that had received unilateral ventral rhizotomies to eliminate efferents. The gut, from the oral esophagus to the distal colon, was divided into wholemounts, processed with tetramethylbenzidine, and surveyed to establish normative topographic maps of afferents. Vagal intraganglionic laminar endings (IGLEs) were ubiquitous, with concentrations varying on a longitudinal gradient (higher rostrally). This overall gradient was punctuated by denser condensations of endings in the oral esophagus, gastric corpus, and distal ileum. In regional specializations, IGLEs were fused into conspicuous, dense networks in the laryngeal esophagus and the antrum. Intramuscular arrays (IMAs) had restricted distributions, including the walls of the stomach and the sphincters throughout the gut. In the forestomach, a singular concentration of orthogonally crossed IMAs was organized into a lattice or "fovea." IMAs displayed variations in morphology, with one specialization consisting of short, terminal processes associated with sphincters and a more widespread form consisting of long, rectilinear processes in the forestomach, along the greater curvature, and in limited intestinal regions. On the basis of their topographic patterns and structural specializations, the two putative mechanoreceptors may have different functions: IGLEs appear situated to integrate intramural tension, and perhaps myenteric neuronal activity, into rhythmical, propagated motor programs, such as swallowing, peristalsis, and emptying. IMAs are distributed strategically and appear to satisfy structural requirements for stretch receptors tuned to tonic or more aperiodic events that may affect central nervous system processing as well as local gastrointestinal coordination.

Regenerating vagal afferents reinnervate gastrointestinal tract smooth muscle of the rat.

Peripheral projections of the vagus are known to regenerate after subdiaphragmatic vagotomy, but neither the question of whether the regenerating axons are motor or sensory nor the issue of whether the fibers reinnervate their original targets have been addressed. To determine whether vagal afferents regenerate and whether they differentiate into normal terminal specializations in the reinnervated target organ, male Sprague-Dawley rats underwent complete subdiaphragmatic vagotomies and were injected 18 weeks later with 3 microl of 4% wheat germ agglutinin-horseradish peroxidase (WGA-HRP) in the left nodose ganglion. To provide a comparison group, an unoperated group (controls) was injected with WGA-HRP in the left nodose ganglion. The esophagus, the entire stomach, the first 8 cm of the duodenum, and the hilus of the liver were prepared as wholemounts and processed with tetramethyl benzidine. Vagal afferents were found to have regenerated and reinnervated the esophagus, stomach, duodenum, and liver. Bundles (two or more axons), individual vagal axons, and terminals in the stomach were counted and mapped with a sampling grid. At 18 weeks postvagotomy, the reinnervated stomach and duodenum contained normal terminals as well as aberrant endings and growth cone profiles. The ingrowing axons reestablished ipsilateral and contralateral projections in the same proportions seen in controls, although the overall density of the different regenerating elements had reached only 7-39% of control values. These findings demonstrate that the gastrointestinal tract and liver can undergo dramatic afferent reinnervation after vagotomy. The presence of differentiated endings at 18 weeks suggests that some afferent function(s) may be restored, and the expression of growth cones suggests that additional regeneration may be ongoing.

Vagal circuitry mediating cephalic-phase responses to food.

The dorsal vagal complex in the medulla oblongata is the hub of the central nervous system network that produces vagal cephalic-phase reflexes. The preganglionic motor neurons controlling these cephalic responses of digestion and metabolism are organized topographically in longitudinal columnar subnuclei in the dorsal motor nucleus of the vagus. Gustatory and other visceral afferent inputs project into different subnuclei of the nucleus of the solitary tract capping the dorsal motor nucleus. Descending projections from more rostral stations of the neuroaxis project to the nuclei of the dorsal vagal complex, providing input both from exteroceptive senses, such as olfaction and vision, and from forebrain areas that modulate reflex strength. Recent structural analyses of the dorsal vagal complex, as well as characterizations of the region's inputs and neurochemistry, have provided a more complete understanding of the neural basis of cephalic-phase responses.