Immunocytochemical and molecular data guide peptide identification by mass spectrometry: orcokinin and orcomyotropin-related peptides in the stomatogastric nervous system of several crustacean species.

In order to identify new orcokinin and orcomyotropin-related peptides in crustaceans, molecular and immunocytochemical data were combined with matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS). In the crayfish Procambarus clarkii, four orcokinins and an orcomyotropin-related peptide are present on the precursor. Because these peptides are highly conserved, we assumed that other species have an identical number of peptides. To identify the peptides, immunocytochemistry was used to localize the regions of the stomatogastric nervous system in which orcokinins are predominantly present. One of the regions predominantly containing orcokinins was a previously undescribed olive-shaped neuropil region within the commissural ganglia of the lobsters Homarus americanus and Homarus gammarus. MALDI-TOF MS on these regions identified peptide masses that always occur together with the known orcokinins. Seven peptide ions occurred together in the peptide massspectra of the lobsters. Mass spectrometric fragmentation by MALDI-MS post-source decay (PSD) and electrospray ionization quadrupole time-of-flight mass spectrometry (ESI Q-TOF MS) collision-induced dissociation (CID) were used in the identification of six of these masses, either as orcokinins or as orcomyotropin-related peptides and revealed three hitherto unknown peptide variants, two of which are [His13]-orcokinin ([M+H]+ = 1540.8 Da) and an orcomyotropin-related peptide FDAFTTGFGHN ([M+H]+ = 1213.5 Da). The mass of the third previously unknown orcokinin variant corresponded to that of an identified orcokinin, but PSD fragmentation did not support the suggested amino acid sequence. CID analysis allowed partial de novo sequencing of this peptide. In the crab Cancer pagurus, five orcokinins and an orcomyotropin-related peptide were unambigously identified, including the previously unknown peptide variant [Ser9-Val13]-orcokinin ([M+H]+ = 1532.8 Da).

Neuropeptide expression following constriction or section of the inferior alveolar nerve in the ferret.

Some of the sensory abnormalities that follow peripheral nerve injury may result from the development of ectopic discharge from the damaged axons. Previous studies in our laboratory have shown that, following tight ligation of the inferior alveolar nerve (IAN), there is a close association between the time-course of this neural activity and the accumulation of neuropeptides at the injury site. In this study we investigated whether the type of injury has any effect on the time-course or level of neuropeptide expression. In 36 adult ferrets, the IAN was either loosely constricted or sectioned, and the animals left to recover for 3 days, 3 weeks, or 3 months. The tissue was processed using indirect immunofluorescence and image analysis was used to quantify levels of substance P, calcitonin gene-related peptide, vasoactive intestinal polypeptide, enkephalin, galanin, and neuropeptide Y. Immunoreactivity to all of the neuropeptides was present within the injured nerve 3 days after both types of injury, and decreased to lower levels by 3 weeks and 3 months. Comparisons between the levels of neuropeptide immunoreactivity in each group revealed that the pattern of accumulation was similar following loose constriction or section, and also similar to that found in our previous study on tight ligation. For each injury the time-course of neuropeptide expression was similar to that of the spontaneous activity we had previously recorded. These data support the suggestion that neuropeptide accumulation may be linked to the development of ectopic neural activity but indicate that the type of injury has little effect on the extent of expression.

A comparative study of three cranial sensory ganglia projecting into the oral cavity: in situ hybridization analyses of neurotrophin receptors and thermosensitive cation channels.

Peripheral cranial sensory nerves projecting into the oral cavity receive food intake stimuli and transmit sensory signals to the central nervous system. To describe and compare the features of the cranial sensory ganglia that innervate the oral cavity, i.e., the trigeminal, petrosal, and geniculate ganglia (TG, PG, and GG, respectively), in situ hybridization was conducted using riboprobes for neurotrophin receptors (TrkA, TrkB, and TrkC), a neurotransmitter (substance P), and ion channels important for thermosensation (VR1 and TREK-1). In TG, all in six probes yielded positive signals to various extent in intensity and frequency. In addition, a strong correlation between the expression of VR1 and those of TrkA and substance P was observed as in the case of the dorsal root ganglia. In PG, positive signals to all six probes were also detected, and the correlation of expression was similar to that shown by TG. On the other hand, most cells in GG were positive to the TrkB probe, and a small number of cells were positive to the TrkC probe, but no significant signal was observed for the other four probes. These results indicate that TG and PG consist of cells that are heterogeneous in terms of neurotrophin requirement and somatosensory functions, and that GG seems to consist mainly of a homogeneous cell type, gustatory neurons. In conclusion, TG, PG, and GG, show gene expression characteristics intrinsic to the three ganglia. It is also concluded that TG and a portion of PG project several types of somatosensory nerves. This is consistent with the finding that GG and a portion of PG project gustatory nerves.

Course and composition of the nerves that supply the mandibular teeth of the rat.

The rodent dentition has become an important model for investigations of interactions between dental tissues and peripheral neurons. Although experimental nerve injury has been widely used for such studies, there is uncertainty about the courses of nerve fibers supplying the mandibular teeth. In order to clarify this, we used a mixture of monoclonal antibodies against neurofilament proteins to enhance demonstration of nerve fibers so that small nerves could be readily traced in serial frozen sections of mandibles of Sprague Dawley rats ranging in age from embryonic day (E) 18 to postnatal day (P) 90. The 1st molar and anterior portion of the 2nd molar were innervated by small nerves that emerged as distinct branches of the IAN trunk at or near the mandibular foramen. In contrast, the nerve supply to the 3rd molar and posterior part of the 2nd molar was a branch of the lingual nerve that bypassed the mandibular canal altogether. The IAN trunk split into the mental nerve and a large branch to the incisor about 2 mm anterior to the mandibular foramen. Thick branches of the incisor nerve descended into the incisor socket to form a dense plexus of nerve fiber bundles extending along the length of the incisor periodontium. The sparse pulpal innervation of the incisor was provided by a few thin fascicles that emerged from the caudal portion of the periodontal plexus to enter the incisor apex. The dental branches of the IAN and lingual nerve seen in the adult were well established and readily identifiable at age E18 even though their targets were limited to the follicles of the developing teeth. These studies show that the trigeminal branches that supply the mandibular teeth can be identified at a wide range of ages as distinct nerves at a considerable distance proximal to their targets. This detailed information on the courses taken by the dental nerves can provide an anatomical basis for increased precision in characterization and perturbation of neural pathways from the molars and incisor.

Neuropeptide Y expression in the trigeminal ganglion and mandibular division of the trigeminal nerve after inferior alveolar nerve axotomy in young rats.

Neuropeptide Y (NPY) is a 36-amino-acid peptide residing in sympathetic nerve terminals, originating from the superior cervical ganglion in oral tissues. NPY exerts vasoconstrictor action together with noradrenalin and has been found to inhibit the release of neurotransmitters from primary afferent fibers. During regeneration of the axotomized inferior alveolar nerve (IAN), NPY-immunoreactive (IR) nerve fibers have been shown in the odontoblast layer and dentin, an area normally innervated by afferent nerve fibers. The dynamic shift in neuropeptide expression in the trigeminal ganglion and in the dental pulp was studied by immunohistochemistry 1, 2, 3, and 8 weeks after IAN axotomy. In the ipsilateral first mandibular molar a temporal loss of pulpal sensory nerves lasting for approximately 1 week was found after axotomy. An upregulation of NPY was shown in neurons located in the mandibular area of the trigeminal ganglion, concomitant to a reduction in number of neurons expressing substance P (SP). To study an alternate and possible trigeminal origin of some of the peripheral nerve fibers IR to NPY in the dental pulp, double immunofluorescence labeling was performed for NPY and calcitonin gene-related peptide (CGRP). Coexistence of NPY and CGRP was shown in neurons located in the trigeminal ganglion and in nerve fibers in the tooth pulp during IAN regeneration. Furthermore, retrograde tracing with Fluorogold revealed NPY-IR neurons projecting to the first molar pulp 3 weeks after axotomy. Hence, we conclude that after IAN axotomy NPY is produced in trigeminal ganglion neurons and transported in afferent regenerating fibers to the dental pulp. These results add further evidence for a plasticity in peptide transcription in sensory neurons after nerve injury and indicate a trigeminal origin of at least some of the pulpal NPY-IR fibers during nerve regeneration.