Étude anatomique de la relation entre les neurones exprimant l’hormone de relâche des gonadotrophines et le nerf terminal lors du développement postnatal de l’opossum (Monodelphis domestica)

Hour, Naussicca Lakena

01 1900

Quoique très immature à la naissance, l’opossum grimpe de l’orifice urogénital de la mère jusqu’à une tétine à laquelle il s’accroche pour poursuivre sa maturation. Des informations sensorielles sont nécessaires pour que l’animal atteigne la tétine et que le réflexe d’attachement soit déclenché. Une modalité sensorielle envisagée est l’olfaction. Or, des expériences physiologiques effectuées au laboratoire sur des préparations in vitro suggèrent que le système olfactif central est trop immature pour influencer les comportements moteurs. Une étude immunohistochimique employant un marqueur de maturité axonique (NF200) a montré une absence de marquage dans le cerveau antérieur, à l’exception d’un mince faisceau reliant les bulbes olfactifs aux régions caudales du cerveau. L’implication de l’olfaction dans les comportements du nouveau-né est donc peu probable, mais la présence de ce faisceau est intrigante et l’étude de son développement est approfondie dans le présent travail. Le développement du faisceau exprimant NF200 est décrit de la naissance jusqu’à la fin de la 2e semaine postnatale, âge auquel le marquage NF200 n’est plus observé à ce niveau. Il est aussi montré que le trajet de ce faisceau se superpose à celui de fibres nerveuses exprimant GnRH1, une neurohormone exprimée par des neurones hypothalamiques chez l’adulte. Les résultats indiquent que ce faisceau est le nerf terminal et pourrait servir de voie pionnière pour la croissance des fibres GnRH1. Aucun marquage NF200 dans le cortex olfactif n’est observé avant P15, supportant l’idée que le système olfactif n’influence pas les comportements de l’opossum nouveau-né. / While quite immature at birth, the opossum is nevertheless able to crawl from the urogenital opening to a mother's nipple to which it attaches to pursue its development. Sensory information are required to guide the newborn to the nipple and induce attachment. Olfaction is one of the sensory modalities often proposed. However, recent physiological experiments in the laboratory using in vitro preparations suggest that the olfactory system is too immature to influence the newborn behaviors. Furthermore, an immunohistochemical study using a marker of axonal maturity (neurofilament 200kDa, NF200) has shown that the prosencephalon is nearly devoid of mature fibers except for a thin fascicle running from the olfactory bulbs to more caudal areas of the brain. Olfaction is thus unlikely to guide the locomotion of the newborn, but the presence of this fascicle is intriguing and its development is studied in the present thesis. This fascicle is described from the day of birth to the end of the second postnatal week, when NF200 labeling is no more visible in this region. It is also shown that this fascicle superpose with fibers expressing GnRH1, a neurohormone characterizing hypothalamic neurons in the adult. The results indicate that this fascicle is the terminal nerve, and might serve as a pioneer pathway to GnRH1 fibers cells. Until P15, the olfactory cortex was devoid of NF200 projections, supporting that the olfactory systems is too immature to influence the behavior of newborn opossums.

GnRH1

NF200

Terminal nerve

Olfactory system

Nerf terminal

Système olfactif

Opossum

Defining neurochemical properties and functions of primary sensory neurons in the rat trigeminal ganglion

Triner, Joceline Clare

January 2013

The trigeminal ganglion (TG) is a complex sensory structure and multiple lines of evidence suggest that significant differences exist in anatomical, neurochemical and physiological properties between it and its equivalent structure in the somatosensory system, the dorsal root ganglion (DRG). This is likely to be a reflection, first on the unique areas of tissue innervation of the TG and second, on the unusual responses to injury which give rise to distinct pain symptoms such as toothache, migraine and temporomandibular joint disorders. In an attempt to address this disparity in knowledge, we have carried out an in-depth in vivo study investigating neurochemical populations and cell size distributions of sensory neurons within the rat TG. We have performed a detailed analysis of expression patterns for receptor components of important inflammatory mediators, NGF (TrkA), TNFα (p55) and IL-6 (gp130), along with the thermo-transducers TRPV1 and TRPM8. For each analysis we have compared our findings with those of the rat DRG. We have shown a significantly larger population of NF200+ neurons within the TG (51%) compared to the DRG (40%), and most interestingly, the majority of NF200+ neurons in the TG were within the small to medium cell size range, conferring a nociceptive phenotype. We have for the first time, determined expression of p55 and gp130 protein levels within neurochemically defined subpopulations of the TG. We show that a large proportion (33%) of TG neurons, in particular 27% of NF200+ neurons co-express p55, and thereby have the potential to respond directly to TNFα. Furthermore, we have observed gp130 protein expression to be ubiquitous within the TG, suggesting all neurons, including non-nociceptors, could respond to IL-6. In addition, we have utilised biochemical and electrophysiological techniques in vitro to measure the functional outcome of exposure of TG neurons to IL-6. We have demonstrated that IL-6 activates the JAK/STAT signalling pathway, preferentially within NF200+ neurons. Furthermore, we have shown that IL-6 sensitises the response of TG neurons to the TRPV1 agonist capsaicin, altering the gating properties and prolonging the opening time of the channel. Taken together, our findings support the emerging picture of a complex combinatorial pattern of co-expression of sensory neurochemicals, transducers and receptor components that help to define TG neuronal modality and function. We would advocate caution in making generalisations across sensory ganglia in particular in extrapolating data from the DRG to the trigeminal ganglion.

612.8