Characterization of sheep (Ovis aries) palatine tonsil innervation

Palatine tonsils (PTs), together with ileal Peyer's patches, rank among the first colonization sites for infectious prions. After replicating in these lymphoid tissues, prions undertake the process of "neuroinvasion," which is likely mediated by the peripheral nerves connecting lymphoid tissues to the central nervous system (CNS). To study the connections between the tonsils and the CNS, we injected fluorescent tracers into the PTs of lambs; the highest number of Fast Blue (FB)-labeled neurons was found in cranial cervical ganglia (CCG), whereas a progressively decreasing number of cells were detected in proximal glossopharyngeal, proximal vagal, trigeminal, pterygopalatine, and cervicothoracic ganglia. Immunohistochemistry was carried out on tonsil and ganglia cryosections. Immunoreactivity (IR) for tyrosine hydroxylase (TH), dopamine beta-hydroxylase (DBH), neuronal nitric oxide synthase (nNOS), calcitonin gene-related peptide (CGRP), substance P (SP), and calcium-binding protein S100 (S100), was observed in the fibers around and within PT lymphoid nodules. In the trigeminal, proximal glossopharyngeal and vagal ganglia the retrogradely-labeled neurons showed nNOS-, SP- and CGRP-IR. In all ganglia some retrogradely-labeled neurons showed nNOS-, SP- and CGRP-IR co-localization. It is worth noting that only 66+/-19% and 75+/-13% of retrogradely-labeled neurons in CCG showed TH- and DBH-IR, respectively. The present results allow us to attribute PT innervation mainly to the sympathetic component and to the glossopharyngeal, vagal and trigeminal cranial nerves. Furthermore, these data also provide a plausible anatomic route through which infectious agents, such as prions, may access the CNS, i.e. by traveling along several cranial and sympathetic nerves, as well as by migration via glial cells.[...

Intrinsic innervation of the ileocaecal junction in the horse: Preliminary study

Reason for performing study: In horses, morpho-functional studies related to the enteric nervous system (ENS) controlling the sphincters are lacking. Objectives: To investigate immunohistochemically the morphology, distribution, density, phenotypes and projections of neurons controlling the ileocaecal junction (ICJ). Methods: Two young horses were anaesthetised and underwent midline laparotomy. The neuronal retrograde fluorescent tracer Fast Blue (FB) was injected into the wall of the ICJ. A post surgical survival time of 30 days was used. Following euthanasia, the ileum and a small portion of caecum were removed. Cryosections were used to investigate the immunoreactivity (IR) of the neurons innervating the ICJ for choline acetyltransferase (ChAT), neuronal nitric oxide synthase (nNOS), substance P (SP), calcitonin gene-related peptide (CGRP) and neurofilament NF200kDa (NF). Results: Ileal FB-labelled neurons innervating the ICJ were located in the myenteric plexus (MP) and submucosal plexus (SMP) up to 48 cm and 28 cm, respectively, from the point of the FB injections. Descending MP and SMP neurons were nitrergic (54 ± 11% and 68 ± 4%, respectively), cholinergic (60 ± 19% and 82 ± 11%, respectively), NF-IR (54 ± 9% and 78 ± 21%, respectively), and SP-IR (about 20% in both the plexuses). CGRP-IR was expressed only by SMP descending neurons (45 ± 21%). In both the plexuses descending neurons coexpressing nNOSand ChAT-IR were also observed (25 ± 11% and 61 ± 27%, respectively). Conclusions: The presence of ileal long projecting neurons innervating the ICJ suggests that they are critical for its modulation. Consequently, in bowel diseases in which the resection of the terminal jejunum and proximal ileum are required, it is preferable, whenever possible, to conserve the major portion of the ileum. Potential relevance: The knowledge of the phenotype of ENS neurons of the ileum might be helpful for developing pharmaceutical treatment of the ICJ motility disorders

Innervazione delle tonsille palatine nella pecora

Palatine tonsils (PTs) are replication sites for infectious prions (PrPSc). From the PTs PrPSc take part to neuroinvasion. To study the connections between PTs, central and peripheral nervous system, we injected in the lamb PTs the tracer Fast Blue (FB). FB-labelled neurons were observed in the sympathetic cervical cranial ganglia (CCG), vagal and glossopharingeal ganglia, and trigeminal ganglia (TG). Immunohistochemistry was performed on PTs and ganglia cryosections. FB-labeled sensory neurons expressed NOS-, CGRP-, and SPIR. CCG FB-labeled neurons expressed DBH-IR, but FB-labeled neurons DBH-negative were also observed. The present results provide a plausible anatomic basis through which infectious prions may gain access to the CNS. Immunoreactivity for dopamine-beta-hydroxylase (DBH), nitric oxide synthase (NOS), calcitonin gene-related peptide (CGRP), and substance P (SP) was observed in PTs fibres

Properties of cholinergic and non-cholinergic submucosal neurons along the mouse colon

Submucosal neurons are vital regulators of water and electrolyte secretion and local blood flow in the gut. Due to the availability of transgenic models for enteric neuropathies, the mouse has emerged as the research model of choice, but much is still unknown about the murine submucosal plexus. The progeny of choline acetyltransferase (ChAT)-Cre × ROSA26(YFP) reporter mice, ChAT-Cre;R26R-yellow fluorescent protein (YFP) mice, express YFP in every neuron that has ever expressed ChAT. With the aid of the robust YFP staining in these mice, we correlated the neurochemistry, morphology and electrophysiology of submucosal neurons in distal colon. We also examined whether there are differences in neurochemistry along the colon and in neurally mediated vectorial ion transport between the proximal and distal colon. All YFP(+) submucosal neurons also contained ChAT. Two main neurochemical but not electrophysiological groups of neurons were identified: cholinergic (containing ChAT) or non-cholinergic. The vast majority of neurons in the middle and distal colon were non-cholinergic but contained vasoactive intestinal peptide. In the distal colon, non-cholinergic neurons had one or two axons, whereas the cholinergic neurons examined had only one axon. All submucosal neurons exhibited S-type electrophysiology, shown by the lack of long after-hyperpolarizing potentials following their action potentials and fast excitatory postsynaptic potentials (EPSPs). Fast EPSPs were predominantly nicotinic, and somatic action potentials were mediated by tetrodotoxin-resistant voltage-gated channels. The size of submucosal ganglia decreased but the proportion of cholinergic neurons increased distally along the colon. The distal colon had a significantly larger nicotinic ion transport response than the proximal colon. This work shows that the properties of murine submucosal neurons and their control of epithelial ion transport differ between colonic regions. There are several key differences between the murine submucous plexus and that of other animals, including a lack of conventional intrinsic sensory neurons, which suggests there is an incomplete neuronal circuitry within the murine submucous plexus