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.

Respiratory motor output in bilateral cranial nerves is synchronized, but the underlying synchronizing mechanisms are not clear. We used an in vitro slice preparation from newborn mice to investigate the effect of systematic transsections on respiratory activity in bilateral XII nerves. Complete transsection at the midline resulted in desynchronized rhythm with reduced XII burst amplitude and duration. Transsections in the ventral or dorsal 1/3 of the midline did not desynchronize rhythm. However, transsections in the ventral 2/3 of the midline desynchronized rhythm with characteristic amplitude correlations, where large-amplitude XII-bursts on one side was synchronized with small-amplitude XII-burst on the contralateral side. These characteristic amplitude correlations suggest that hypoglossal motoneurons receive respiratory drive from bilateral sources. Retrograde labeling confirmed that commissural fibers from the pre-Bötzinger complex cross in the mid-1/3 of the midline, and that dendrites of hypoglossal motoneurons project into the contralateral XII nucleus. In conclusion, commissural fibers crossing in the mid-1/3 of the midline are required for synchronization of respiratory activity in bilateral XII nerves. Hypoglossal motoneurons receive respiratory drive from both sides of the medulla, possibly mediated by contralaterally projecting dendrites.

In order to develop another selective marker for cholinergic cell bodies and fibres, we have raised a highly specific polyclonal antibody against a peptide derived from the C-terminus of a recently cloned putative vesicular acetylcholine transporter. This antibody recognizes the vesicular acetylcholine transporter protein on western blots of membranes from transfected monkey fibroblast COS cells as well as from various rat brain regions but not from untransfected COS cells or rat liver. In separate mapping studies, the antibody was found to stain cell bodies and fibres in all of the regions of the nervous system known to be cholinergic, including (i) the various nuclei of the basal nuclear complex and their projections to the hippocampus, amygdala, and cerebral cortex, (ii) the caudate-putamen nucleus, accumbens nucleus, olfactory tubercle, and islands of Calleja complex, (iii) the medial habenula, (iv) the mesopontine cholinergic complex and its projections to the thalamus, extrapyramidal motor nuclei, basal forebrain, cingulate cortex, raphe and reticular nuclei, and some cranial nerve nuclei, and (v) the somatic motor and autonomic nuclei of the cranial and spinal nerves. In many of these cholinergic neurons, it is possible to detect immunoreactivity for the vesicular acetylcholine transporter in proximal portions of processes and their branches, as well as in numerous puncta in close association with them. Some of these puncta are large and surround cell bodies and processes of neurons in several regions, including the somatic motor neurons of cranial nerve nuclei in the brainstem and in the ventral horn of the spinal cord. Double immunofluorescence studies indicated that neurons positive for the vesicular acetylcholine transporter also stained for the biosynthetic enzyme of acetylcholine, choline acetyltransferase. We conclude that antibody against the C-terminus of the putative vesicular acetylcholine transporter provides another marker for cholinergic neurons that, unlike in situ hybridization procedures, labels terminals as well as cell bodies. Therefore this antibody has the potential to reveal changes in number and morphology of cholinergic cell bodies and their terminal varicosities that occur in both physiologic and pathologic conditions.

Input from the three gustatory nerves of vertebrates is used to evaluate the nutritional quality of food. In some species, these cranial nerves are modified to accomplish additional specific functions. For example, the facial nerve innervated taste buds distributed over the body surface of catfish aid food search. Physiological studies indicate that this extra-oral taste pathway is more sensitive to amino acids than either the glossopharyngeal or vagal systems of the oral cavity. The current investigation seeks to determine if differences in taste cell subtypes might contribute to the observed differences in sensitivity. The distributions of five low molecular weight metabolites, L-alanine, L-aspartate, L-glutamate, GABA, taurine and the tripeptide glutathione, were examined in 2118 individual taste cells innervated by either the facial or vagal nerve of the channel catfish, Ictalurus punctatus. The metabolite profiles of these cells were determined immunocytochemically and subjected to a k-means clustering algorithm. Fifteen cell classes with quantitatively different patterns of metabolite co-localization were identified. All but one small class of two cells were found in both facial and vagal nerve-innervated taste buds. Four classes (9% of the total cells) had high, two classes (17%) had intermediate and the remaining nine classes (74%) had low levels of GABA immunoreactivity. While the functional significance of differences in metabolite profile remains to be determined, taste cell classes were not uniformly distributed across vagal and facial nerve innervated taste buds and may provide an anatomical basis for previously reported differences in gustatory sensitivity.

The rostral nucleus of the solitary tract (rNST) receives orosensory information from taste bud cells in the tongue and palate via cranial nerves VII and IX. These nerves enter the brainstem, form the solitary tract (ST) and synapse with neurons in the rNST, which then relay incoming sensory information to other brain areas to process external gustatory stimuli. Factors that direct or regulate the trajectory of the developing ST are largely unknown. We used 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI) to identify ST projections originating from cells in the geniculate ganglia of embryonic rats from embryonic day 14 through 18 (E14-E18). After identifying the ST fibers, immunolabeling for and protein expression analysis of the axon guidance molecules neuropilin-1 (Npn-1) and neuropilin-2 (Npn-2) and their binding partners, semaphorin-3A (Sema-3A) and semaphorin-3F (Sema-3F) were performed. The results detail the formation of ST projections into the gustatory brainstem and their relationship to developing rNST neurons. DiI-labeled ST fibers were present in the brainstem as early as E14. Npn-1 was expressed in the ST and in the trigeminal tract at E14, but levels of the protein declined through E18. The expression levels of the binding partner of Npn-1, Sema-3A, increased from E14 to E18. Npn-2 was expressed in the ST and, additionally, in radially oriented, tuft-like structures within the brainstem at E14. Expression levels of Npn-2 also declined through E18, in contrast to the expression levels of its binding partner, Sema-3F, which increased during this time period. For the first time, the time course and particular molecular components involved in development of the ST have been identified. These results indicate that the neuropilin and semaphorin families of axon guidance molecules are potential molecular participants in ST formation.