Investigation of general and cytoskeletal markers to estimate numbers and proportions of neurons in the human intestine.

An important requirement in pathological diagnostics in the human enteric nervous system (ENS) is the estimation of the total numbers of neurons and of proportions of distinct subpopulations. In this study, we compared the suitability of two suggested panneuronal markers, cuprolinic blue (CB) and anti-Hu-protein (HU), for staining and counting human myenteric neurons in wholemounts, derived from small and large intestinal samples. Furthermore, the proportional expression of three cytoskeletal intermediate filaments, alpha-internexin (IN), neurofilament 200 (NF) and peripherin (PE), was correlated with both CB and HU. In 8 CB- and HU-stained wholemounts, 93.3% of all neurons were double labeled, 3.3% of neurons were stained only with CB whereas 3.3% were immuno-stained only for HU. Thus, both markers were comparably reliable in representing the putative total human myenteric neuron population in our material. The wholemounts double stained for IN/CB or IN/HU revealed between 56.2 and 71.5% of neurons to be IN-reactive. Between 42.8 and 50.9% of neurons were immunoreactive for NF whereas 53.9 to 62.4% of neurons were reactive for PE. Although our sample number was too small to allow final conclusions, we suggest that the variations in proportions of intermediate filament expression we observed may be due to individual circumstances rather than to correlation with age or region. The proportions of neurons positive for IN, NF or PE but unstained by CB histochemical or HU immunohistochemical techniques was between 0 and 2.2%. We conclude that both CB and HU techniques are suitable methods for representation of almost all myenteric neurons in the human gut and that the differential expression of the cytoskeletal proteins investigated has to be included in the classification of enteric neurons in pathological diagnostics of human gastrointestinal diseases.

Morphology of VIP/nNOS-immunoreactive myenteric neurons in the human gut.

In this study, we characterized human myenteric neurons co-immunoreactive for neuronal nitric oxide synthase (nNOS) and vasoactive intestinal peptide (VIP) by their morphology and their proportion as related to the putative entire myenteric neuronal population. Nine wholemounts (small and large intestinal samples) from nine patients were triple-stained for VIP, neurofilaments (NF) and nNOS. Most neurons immunoreactive for all three markers displayed radially emanating, partly branching dendrites with spiny endings. These neurons were called spiny neurons. The spiny character of their dendrites was more pronounced in the small intestinal specimens and differed markedly from enkephalinergic stubby neurons described earlier. Exclusively in the duodenum, some neurons displayed prominent main dendrites with spiny side branches. Of the axons which could be followed from the ganglion of origin within primary strands of the myenteric plexus beyond the next ganglion (70 out of 140 traced neurons), 94.3% run anally and 5.7% orally. Very few neurons reactive for both VIP and nNOS could not be morphologically classified due to weak or absent NF-immunoreactivity. Another six wholemounts were triple-stained for VIP, nNOS and Hu proteins (HU). The proportion of VIP/nNOS-coreactive neurons in relation to the number of HU-reactive neurons was between 5.8 and 11.5% in the small and between 10.6 and 17.5% in the large intestinal specimens. We conclude that human myenteric spiny neurons co-immunoreactive for VIP and nNOS represent either inhibitory motor or descending interneurons.

Intrinsic choroidal neurons in the duck eye receive sympathetic input: anatomical evidence for adrenergic modulation of nitrergic functions in the choroid.

Intrinsic choroidal neurons (ICN) in the duck eye form an intramural ganglionic plexus that may subserve complex integrative functions. A key feature of such ganglia is an innervation by sympathetic postganglionic neurons. The present study was thus aimed at determining the sympathetic postganglionic innervation of ICN. Choroids were processed for double immunofluorescence labelling with the following markers: tyrosine-hydroxylase (TH)/nitric oxide synthase (nNOS), TH/galanin (GAL), dopamine-beta-hydroxylase (DBH)/vasoactive intestinal polypeptide (VIP), TH/DBH and DBH/alpha-smooth-muscle actin (alphaSMA), and for triple immunofluorescence labelling with VIP/DBH/TH. Epifluorescence and confocal laser scanning microscopy were used for evaluation. Immunoperoxidase staining for TH or DBH in combination with NADPH-diaphorase histochemistry was applied for electron microscopy. ICN spread over the entire choroid but were concentrated in an equatorial zone passing obliquely from naso-cranial to temporocaudal. More than 80% of nNOS-positive ICN showed close appositions of TH/DBH-immunoreactive varicose nerve fibres at the light-microscopic level, as could be confirmed by confocal laser scanning microscopy. Ultrastructurally, these appositions could be defined as both synapses or close contacts without synaptic specialisation. Vascular and non-vascular smooth muscle fibres also received TH/DBH-immunopositive innervation. Our findings suggest that most ICN receive a sympathetic input that might modulate their nitrergic effects upon vascular and non-vascular smooth muscle fibres in the choroid and that they may have more complex functions than merely being a simple parasympathetic relay.

Intrinsic choroidal neurons in the duck eye express galanin.

Recently, it has been shown that the choroid of the duck eye harbours approximately 1,000 intrinsic choroidal neurons positive for vasoactive intestinal polypeptide and neuronal nitric oxide synthase. Their connections and functional significance are largely unknown. This study was performed to establish a typical chemical code for these neurons and to define their targets by using immunocytochemistry and confocal laser scanning microscopy. Almost all intrinsic choroidal neurons coexpressed galanin (GAL), vasoactive intestinal polypeptide (VIP), and neuronal nitric oxide synthase (nNOS)/NADPH-diaphorase. A few stained for GAL and/or nNOS only. Among extrinsic ganglia, GAL/VIP/nNOS coexpressing neurons were only found in the pterygopalatine ganglion where they accounted for approximately 30% of the neuronal population. Thus, GAL/VIP/nNOS-positive nerve fibres around branches of the ciliary artery and within the nonvascular smooth muscle stroma of the choroid may originate mainly from intrinsic neurons and to some extent in a subpopulation of pterygopalatine ganglionic neurons exhibiting the same chemical coding. Close contacts of GAL-positive fibres upon intrinsic choroidal neurons may indicate reciprocal connections between them. Thus, intrinsic choroidal neurons may represent peripherally displaced pterygopalatine ganglion neurons forming a local network for regulation of vascular and nonvascular smooth muscle tone in the duck choroid. They may be integrated in the neuronal circuitry controlling intraocular pressure, choroidal thickness, accommodation, and axial bulbus length.

Mucosal projections of enteric neurons in the porcine small intestine.

In the present study, a combination of immunohistochemistry and retrograde 1,1;-didodecyl-3,3,3;,3;-tetramethylindocarbocyanine perchlorate (DiI) tracing was used to unravel the morphology, distribution, and neurochemical coding of submucous and myenteric neurons with axonal projections to the mucosa of the porcine small intestine. The majority of traced neurons was located in the inner submucous plexus (ISP; 78%), whereas the remaining part was distributed between the outer submucous plexus (OSP; 10%) and myenteric plexus (MP; 12%). Among these traced neurons, some distinct neuronal populations could be distinguished according to their morphologic and neurochemical properties. In the ISP, several types of traced neurons were detected: 1) morphologic type II neurons expressing choline acetyltransferase (ChAT) immunoreactivity, calcitonin gene-related peptide (CGRP) immunoreactivity, and substance P (SP) immunoreactivity; 2) ChAT/SP-immunoreactive (-IR) small neurons; 3) vasoactive intestinal polypeptide (VIP) -IR small neurons; and 4) multidendritic ChAT/somatostatin (SOM) -IR neurons. The traced neuronal populations of the OSP and MP were similar to each other. In both plexuses, the following DiI-labelled neurons were found: 1) ChAT/CGRP/(SP)-IR type II neurons; 2) multidendritic ChAT/SP-IR neurons; and 3) multidendritic ChAT/SOM-IR neurons. Comparison of the present findings with previously obtained data concerning the mucosal innervation pattern of the intestine of small mammals, revealed significant species differences with respect to the morphologic and neurochemical features of the involved enteric neuronal classes. Although not identical, a closer resemblance between pig and human enteric nervous system seems to be at hand, as far as the anatomic organization and the presence of neurochemically identified neuronal subtypes within the enteric nervous system are concerned.