Immunohistochemical techniques were used to examine the presence and co-localisation of a range of putative neurotransmitters and other neuronal markers in the myenteric plexus of the small and large intestine of the mouse. Distinct sub-populations of myenteric neurons were identified, based on the combinations of substances they contained and the distribution of their fibres. In the small intestine, there were two major classes of circular muscle motor neurons; one class was characterised by the presence of nitric oxide synthase, vasoactive intestinal peptide plus neuropeptide Y (NOS/VIP/NPY), and the second class contained calretinin plus substance P (CalR/SP). There were seven classes of neurons that innervated myenteric ganglia; these contained nos, vip, nos/vip, npy, calr/calbindin (calb), sp or 5-ht. In the large intestine, there were five major classes of motor neurons that contained nos, nos/vip, gaba, sp, or calr/sp, and seven major classes of neurons that innervated myenteric ganglia and contained nos, vip, calr/calb, calr, sp, gaba or 5-ht. Although some aspects of the patterns of co-localisation are similar to those in other species, this study re-inforces recent analyses that indicate significant species differences in neurochemical patterns in the enteric neurons of different species.
Background: The recent availability of antisera to the vesicular acetylcho-line transporter (VAChT) and choline acetyltransferase (ChAT) that demonstrate peripheral cholinergic neurons has made possible the anatomical identification of cholinergic neurons in the enteric nervous system. In this study, we localised cholinergic neurons in the mouse small and large intestine and identified which substances are found colocalised in the cholinergic neurons. Methods: Immunohistochemical single and double staining techniques were used on whole mount preparations and frozen sections to examine the localisation and chemical coding of cholinergic neurons in the small and large intestine of the mouse. Cholinergic neurons were identified using antisera to ChAT or VAChT. Results: In both the small and large intestine, numerous ChAT-immunoreactive nerve cell bodies were present in the myenteric and submu-cous ganglia, and ChAT-and VAChT-immunoreactive nerve terminals were abundant in the myenteric and submucous plexuses and the external muscle. Previous studies have identified two major classes of myenteric neurons in the small intestine of the mouse-those containing calretinin plus substance P, and those containing nitric oxide synthase (NOS) plus vasoactive intestinal peptide (VIP). Double-label studies showed that the vast majority of the calretinin/substance P neurons were cholinergic neurons, whereas only a small proportion of the NOS/VIP cells were cholinergic; the noncholinergic NOS/VIP neurons were motor neurons or interneurons, whereas the choliner-gic NOS/VIP neurons appeared to be exclusively interneurons. In the small intestine, all of the 5-HT-loaded neurons and a subpopulation of the calbindin neurons were also cholinergic. In the large intestine, there was a pattern of overlaps similar to that found in the small intestine, except that in the large intestine approximately 25% of the calretinin cells were not cholinergic. Only approximately one third of the GABA-loaded neurons in the large intestine were cholinergic. Conclusions: Large subpopulations of motor neurons and interneurons in the mouse small intestine are cholinergic neurons. Anat.
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 calretininimmunoreactivity 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\pNPY 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.
Relaxin-3 (RLN3) is a highly conserved, ancestral member of the insulin/relaxin peptide family. RLN3 mRNA is highly expressed in rat, mouse, and human brain and molecular genetic and pharmacological studies suggest that RLN3 is the cognate ligand for the relaxin family peptide-3 receptor (RXFP3). The distribution of RLN3/RXFP3 networks has been determined in rat and mouse brain, but not in higher species. In this study we describe the distribution of RLN3 neurons in the brain of macaque (Macaca fascicularis) using in situ hybridization histochemistry and immunohistochemistry. RLN3 mRNA and high levels of RLN3-like immunoreactivity (-LI) were observed in neurons within a ventromedial region of the central gray of the pons and medulla that appears to represent the primate analog of the nucleus incertus (NI) described in lower species. Nerve fibers and terminals containing RLN3-LI were observed throughout brain regions identical to those known to receive afferents from the NI in the rat, including the septum, hippocampus, entorhinal cortex, lateral, dorsomedial and ventromedial hypothalamus, supramammillary and interpeduncular nuclei, anterodorsal, paraventricular and reuniens thalamic nuclei, lateral habenula, central gray, and dorsal raphe, solitary tract, and ambiguus nuclei. Experimental studies in the rat strongly implicate a role of this neuropeptide-receptor system in arousal, feeding, and metabolism, learning and memory, and central responses to psychological stressors. These new anatomical findings support the proposition that the RLN3 system is similarly involved in the integration and modulation of behavioral activation and arousal and responses to stress in nonhuman primates and humans.
During development, the external muscle of the mouse esophagus undergoes a transdifferentiation from smooth to striated muscle (Patapoutian et al. [1995] Science 270:1818-1821). We now report on the development of the innervation accompanying the change in phenotype of the external muscle of the mouse esophagus. The phenotype of the muscle was monitored by using light and electron microscopy. Nicotinic acetylcholine receptors were localised by using a fluorescence conjugate of alpha-bungarotoxin, and neural elements were localised by using antisera to synaptophysin (a synaptic vesicle protein that was used to label all nerve terminals), the vesicular acetylcholine transporter (VAChT), calcitonin gene-related peptide (CGRP), nitric oxide synthase (NOS), and vasoactive intestinal peptide (VIP). CGRP and VAChT were co-localised in the terminals of vagal motoneurons that innervate the external muscle, and NOS and VIP were co-localised in intrinsic (enteric) neurons, which provide some terminals that are associated with motor endplates. Cells exhibiting striations were first observed in the outer layers of the most rostral regions of the esophagus of embryonic day 15 (E15) mice. Clusters of nicotinic acetylcholine receptors were also first observed at the rostral end of the esophagus of E15 mice, and developed in a rostrocaudal progression that coincided with the appearance of striations within the muscle cells. Synaptophysin-, VAChT- and NOS-immunoreactive nerve terminals were present within the external muscle prior to the formation of receptor clusters, and their appearance did not follow any apparent rostrocaudal sequence. Surprisingly, not all of the receptor clusters at E15 had synaptophysin- and VAChT-immunoreactive nerve terminals closely associated with them. However, from E18 on, almost all of the clusters had synaptophysin-immunoreactive nerve terminals in close association. At late embryonic and early postnatal stages, there was a rostrocaudal gradient in the proportion of receptor clusters having VAChT-immunoreactive nerve terminals associated with them. Nerve terminals associated with nicotinic receptor clusters did not show detectable CGRP-immunoreactivity until one to two weeks after the appearance of synaptophysin- and VAChT-immunoreactivity. The NOS-immunoreactive neurons did not show detectable VIP-immunoreactivity until three days after NOS could be detected. These results show that the appearance of clusters of nicotinic receptors in the external muscle of the esophagus coincides with the expression of a striated muscle phenotype, but not with the presence of ingrowing nerve terminals. However, many of the receptor clusters that were observed first were apparently uninnervated.
Understanding the transcriptional response to neuronal injury after trauma is a necessary prelude to formulation of therapeutic strategies. We used Serial Analysis of Gene Expression (SAGE) to identify 50,000 sequence tags representing 18,000 expressed genes in the cortex 2 h after traumatic brain injury (TBI). A similar tag library was obtained from sham-operated cortex. The SAGE data were validated on biological replicates using quantitative real-time-PCR on multiple samples at 2, 6, 12, and 24 h after TBI. This analysis revealed that the vast majority of genes showed a downward trend in their pattern of expression over 24 h. This was confirmed for a subset of genes using in situ hybridization and immunocytochemistry on brain sections. Of the overexpressed genes in the trauma library, Nedd4-WW (neural precursor cell expressed, developmentally downregulated) domain-binding protein 5 (N4WBP5) (also known as Ndfip1) is strongly expressed in surviving neurons around the site of injury. Overexpression of N4WBP5 in cultured cortical neurons increased the number of surviving neurons after gene transfection and growth factor starvation compared with control transfections. These results identify N4WBP5 as a neuroprotective protein and, based on its known interaction with the ubiquitin ligase Nedd4, would suggest protein ubiquitination as a possible survival strategy in neuronal injury.
Background:The recent availability of antisera to the vesicular acetylcholine transporter (VAChT) and choline acetyltransferase (ChAT) that demonstrate peripheral cholinergic neurons has made possible the anatomical identification of cholinergic neurons in the enteric nervous system. In this study, we localised cholinergic neurons in the mouse small and large intestine and identified which substances are found colocalised in the cholinergic neurons.Methods: Immunohistochemical single and double staining techniques were used on whole mount preparations and frozen sections to examine the localisation and chemical coding of cholinergic neurons in the small and large intestine of the mouse. Cholinergic neurons were identified using antisera to ChAT or VAChT.Results: In both the small and large intestine, numerous ChATimmunoreactive nerve cell bodies were present in the myenteric and submucous ganglia, and ChAT-and VAChT-immunoreactive nerve terminals were abundant in the myenteric and submucous plexuses and the external muscle. Previous studies have identified two major classes of myenteric neurons in the small intestine of the mouse-those containing calretinin plus substance P, and those containing nitric oxide synthase (NOS) plus vasoactive intestinal peptide (VIP). Double-label studies showed that the vast majority of the calretinin/substance P neurons were cholinergic neurons, whereas only a small proportion of the NOS/VIP cells were cholinergic; the noncholinergic NOS/VIP neurons were motor neurons or interneurons, whereas the cholinergic NOS/VIP neurons appeared to be exclusively interneurons. In the small intestine, all of the 5-HT-loaded neurons and a subpopulation of the calbindin neurons were also cholinergic. In the large intestine, there was a pattern of overlaps similar to that found in the small intestine, except that in the large intestine approximately 25% of the calretinin cells were not cholinergic. Only approximately one third of the GABA-loaded neurons in the large intestine were cholinergic.Conclusions: Large subpopulations of motor neurons and interneurons in the mouse small intestine are cholinergic neurons. Anat.
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