Development and plasticity of locomotor circuits in the zebrafish spinal cord

A fundamental goal in neurobiology is to understand the development and organization of neural circuits that drive behavior. In the embryonic spinal cord, the first motor activity is a slow coiling of the trunk that is sensory-independent and therefore appears to be centrally driven. Embryos later become responsive to sensory stimuli and eventually locomote, behaviors that are shaped by the integration of central patterns and sensory feedback. In this thesis I used a simple vertebrate model, the zebrafish, to investigate in three manners how developing spinal networks control these earliest locomotor behaviors. For the first part of this thesis, I characterized the rapid transition of the spinal cord from a purely electrical circuit to a hybrid network that relies on both chemical and electrical synapses. Using genetics, lesions and pharmacology we identified a transient embryonic behavior preceding swimming, termed double coiling. I used electrophysiology to reveal that spinal motoneurons had glutamate-dependent activity patterns that correlated with double coiling as did a population of descending ipsilateral glutamatergic interneurons that also innervated motoneurons at this time. This work (Knogler et al., Journal of Neuroscience, 2014) suggests that double coiling is a discrete step in the transition of the motor network from an electrically coupled circuit that can only produce simple coils to a spinal network driven by descending chemical neurotransmission that can generate more complex behaviors. In the second part of my thesis, I studied how spinal networks filter sensory information during self-generated movement. In the zebrafish embryo, mechanosensitive sensory neurons fire in response to light touch and excite downstream commissural glutamatergic interneurons to produce a flexion response, but spontaneous coiling does not trigger this reflex. I performed electrophysiological recordings to show that these interneurons received glycinergic inputs during spontaneous fictive coiling that prevented them from firing action potentials. Glycinergic inhibition specifically of these interneurons and not other spinal neurons was due to the expression of a unique glycine receptor subtype that enhanced the inhibitory current. This work (Knogler & Drapeau, Frontiers in Neural Circuits, 2014) suggests that glycinergic signaling onto sensory interneurons acts as a corollary discharge signal for reflex inhibition during movement. v In the final part of my thesis I describe work begun during my masters and completed during my doctoral degree studying how homeostatic plasticity is expressed in vivo at central synapses following chronic changes in network activity. I performed whole-cell recordings from spinal motoneurons to show that excitatory synaptic strength scaled up in response to decreased network activity, in accordance with previous in vitro studies. At the network level, I showed that homeostatic plasticity mechanisms were not necessary to maintain the timing of spinal circuits driving behavior, which appeared to be hardwired in the developing zebrafish. This study (Knogler et al., Journal of Neuroscience, 2010) provided for the first time important in vivo results showing that synaptic patterning is less plastic than synaptic strength during development in the intact animal. In conclusion, the findings presented in this thesis contribute widely to our understanding of the neural circuits underlying simple motor behaviors in the vertebrate spinal cord.

Role of EFNBs and EphB4 in T cell development and function

Eph kinases are the largest family of cell surface receptor tyrosine kinases. The ligands of Ephs, ephrins (EFNs), are also cell surface molecules. Ephs interact with EFNs and the receptors and ligands transmit signals in both directions, i.e., from Ephs to EFNs and from EFNs to Ephs. Ephs and EFNs are widely involved in various developmental, physiological pathophysiological processes. Our group and others have reported the roles of Ephs/EFNs in the immune system. To further investigate the function of EphBs/EFNBs in T cell development and responses, we generated EFNB1, EFNB2, EphB4 conditional gene knockout (KO) mice and EFNB1/2 double KO mice. In the projects using EFNB1 and EFNB2 knockout mice, we specifically deleted EFNB1 or EFNB2 in T cells. The mice had normal size and cellularity of the thymus and spleen as well as normal T cell subpopulations in these organs. The bone marrow progenitors from KO mice and WT mice repopulated the host lymphoid organs to similar extents. The activation and proliferation of KO T cells was comparable to that of control mice. Naïve KO CD4 cells differentiated into Th1, Th2, Th17 and Treg cells similar to naïve control CD4 cells. In EFNB2 KO mice, we observed a significant relative increase of CD4CD8 double negative thymocytes in the thymus. Flowcytometry analysis revealed that there was a moderate increase in the DN3 subpopulation in the thymus. This suggests that EFNB2 is involved in thymocyte development. Our results indicate that the functions of EFNB1 and EFNB2 in the T cell compartment could be compensated by each other or by other members of the EFN family, and that such redundancy safeguards the pivotal roles of EFNB1 and EFNB2 in T cell development and function. In the project using EFNB1/B2 double knockout (dKO) model, we revealed a novel regulatory function of EFNb1 and EFNb2 in stabilizing IL-7Rα expression on the T cell surface. IL-7 plays important roles in thymocyte development, T cell homeostasis and survival. IL-7Rα undergoes internalization upon IL-7 binding. In the dKO mice, we observed reduced IL-7Rα expression in thymocytes and T cells. Moreover, the IL-7Rα internalization was accelerated in dKO CD4 cells upon IL-7 stimulation. In T cell lymphoma cell line, EL4, over-expression of either EFNB1 or EFNB2 retarded the internalization of IL-7Rα. We further demonstrated compromised IL-7 signaling and homeostatic proliferation of dKO T cells. Mechanism study using fluorescence resonance energy transfer and immunoprecipitation demonstrated that physical interaction of EFNB1 and EFNB2 with IL-7Rα was likely responsible for the retarded IL-7Rα internalization. In the last project, using medullary thymic epithelial cell (mTEC)-specific EphB4 knockout mice, we investigated T cell development and function after EphB4 deletion in mTEC. EphB4 KO mice demonstrated normal thymic weight and cellularity. T cell development and function were not influenced by the EphB4 deletion. Lastly, the KO mice developed normal delayed type hypersensitivity. Overall, our results suggest that comprehensive cross interaction between Eph and EFN family members could compensate function of a given deleted member in the T cell development, and only simultaneous deletion of multiple EFNBs will reveal their true function in the immune system. In fact, such redundancy signifies vital roles of Ephs and EFNs in the immune system.

Noticeability of corrective feedback, L2 development and learner beliefs

Cette étude quasi-expérimentale a pour but de 1) comparer la prise en compte et les effets de trois conditions rétroactives, à savoir la reformulation, l’incitation et un mélange des deux techniques, 2) déterminer le lien entre la prise en compte et l’apprentissage, et 3) identifier l’effet des perceptions des apprenants quant à la rétroaction corrective sur la prise en compte et l’apprentissage. Quatre groupes d’apprenants d’anglais langue seconde ainsi que leurs enseignants provenant d’un CEGEP francophone de l’île de Montréal ont participé à cette étude. Chaque enseignant a été assigné à une condition rétroactive expérimentale qui correspondait le plus à ses pratiques rétroactives habituelles. La chercheure a assuré l’intervention auprès du groupe contrôle. L’utilisation du passé et de la phrase interrogative était ciblée durant l’intervention expérimentale. Des protocoles de pensée à haute voie ainsi qu’un questionnaire ont été utilisés pour mesurer la prise en compte de la rétroaction corrective. Des tâches de description d’images et d’identification des différences entre les images ont été administrées avant l’intervention (pré-test), immédiatement après l’intervention (post-test immédiat) et 8 semaines plus tard (post-test différé) afin d’évaluer les effets des différentes conditions rétroactives sur l’apprentissage des formes cibles. Un questionnaire a été administré pour identifier les perceptions des apprenants quant à la rétroaction corrective. En termes de prise en compte, les résultats indiquent que les participants sont en mesure de remarquer la rétroaction dépendamment de la forme cible (les erreurs dans l’utilisation du passé sont détectées plus que les erreurs d’utilisation de la phrase interrogative) et de la technique rétroactive utilisée (l’incitation et le mélange d’incitation et de reformulations sont plus détectés plus que la reformulation). En ce qui a trait à l’apprentissage, l’utilisation du passé en général est marquée par plus de développement que celle de la phrase interrogative, mais il n'y avait aucune différence entre les groupes. Le lien direct entre la prise en compte et l’apprentissage ne pouvait pas être explicitement établi. Pendant que la statistique inférentielle a suggéré une relation minimale entre la prise en compte du passé et son apprentissage, mais aucune relation entre la prise en compte de la phrase interrogative et son apprentissage, les analyses qualitatives ont montrés à une association entre la prise en compte et l’apprentissage (sur les deux cibles) pour certains étudiants et augmentations sans prise en compte pour d'autres. Finalement, l’analyse factorielle du questionnaire indique la présence de quatre facteurs principaux, à savoir l’importance de la rétroaction corrective, la reformulation, l’incitation et les effets affectifs de la rétroaction. Deux de ces facteurs ont un effet modérateur sur la prise en compte de la rétroaction sans, toutefois, avoir d’impact sur l’apprentissage.