An In Vitro Investigation of the Flow Fields Through Bileaflet and Polymeric Prosthetic Heart Valves

Leo, Hwa Liang

05 May 2005

Current designs of bileaflet mechanical heart valves (BMHVs) and trileaflet polymeric heart valves(TPHVs) are plagued by unacceptable levels of hemolysis and thrombus formation in critical areas thereby producing mediocre clinical performance. The objective of this study is: (1) to investigate the influence of BMHV designs on hinge flow characteristics, (2) to quantify the influence of hinge gap width tolerance in a BMHV design, and (3) to investigate the influence of TPHV design on flow characteristics. St. Jude Medical (SJM) provided four transparent mitral BMHVs: one 23 mm CarboMedics (CM), one 27 mm SJM Standard and two 27 mm prototype BHMVs with altered hinge gap widths. Aortech Inc. provided three 23 mm aortic prototype TPHVs. Laser Doppler velocimetry and Particle Image velocimetry were used to measure flow velocity inside these valve prostheses. The flows through the valves were maintained within physiological limits. All valves revealed Reynolds shear stress (RSS) levels greater than 200 Pa far exceeding the threshold for platelet activation and hemolysis. MHV hinge flows in the mitral position were characterized by a strong recirculation during ventricular diastole while leakage jets over and adjacent to leaflets were prominent during ventricular systole. CM hinge flow had higher RSS than in the SJM hinge. The large gap width hinge had the largest leakage jet size and highest RSS (>400 Pa) during ventricular diastole. The Standard gap width hinge showed better washout during systole and provided optimum hemodynamic performance than the prototype designs. In aortic prototype PHVs, elevated RSS conducive to hemolysis was observed along the central jet during systole and the leakage jet at the high central region inside the valve during diastole. This study showed that hinge geometry designs and hinge gap width tolerance governed the success of the bileaflet MHV design. Also the performance of the three aortic PHVs is dependent on commissural designs and leaflet thicknesses. Owing to the critical nature flow fields on clinical outcomes studies such as the current study should be conducted in the pre-clinical evaluation phase for all new MHV or PHVs.

High central region

Hinge

Commissural region

Hemodynamics

Reynolds shear stress

Roles of Planar Cell Polarity Proteins in CoPA Axon Pathfinding

Purdy, Ashley Morgan

01 January 2016

In zebrafish, CoPA (Commissural Primary Ascending) is the first among ascending commissural axons to pathfind anteriorly and form the spinal commissure. One pathway that guides their anterior growth is the planar cell polarity (PCP) signaling pathway, but it is not fully known how PCP signaling regulates anterior guidance. We examined CoPA pathfinding in various PCP mutants to determine if anterior-posterior (A-P) guidance of CoPAs is dependent on PCP signaling. We found that certain PCP mutants exhibited anterior pathfinding defects, with approximately half of all affected CoPAs migrating incorrectly posteriorly. By using a translation-blocking DCC (Deleted in Colorectal Cancer) morpholino to prevent CoPA midline crossing, we discovered that CoPA axons in Fzd3a and Scribble mutants show severe defects in A-P guidance, which suggest that PCP influences A-P guidance of CoPAs prior to and after midline crossing.

planar cell polarity

axon guidance

commissural neurons

Biology

Developmental Biology

Developmental Neuroscience

Neuronal Networks of Movement : Slc10a4 as a Modulator & Dmrt3 as a Gait-keeper

Larhammar, Martin

January 2014

Nerve cells are organized into complex networks that comprise the building blocks of our nervous system. Neurons communicate by transmitting messenger molecules released from synaptic vesicles. Alterations in neuronal circuitry and synaptic signaling contribute to a wide range of neurological conditions, often with consequences for movement. Intrinsic neuronal networks in the spinal cord serve to coordinate vital rhythmic motor functions. In spite of extensive efforts to address the organization of these neural circuits, much remains to be revealed regarding the identity and function of specific interneuron cell types and how neuromodulation tune network activity. In this thesis, two novel genes initially identified as markers for spinal neuronal populations were investigated: Slc10a4 and Dmrt3. The orphan transporter SLC10A4 was found to be expressed on synaptic vesicles of the cholinergic system, including motor neurons, as well as in the monoaminergic system, including dopaminergic, serotonergic and noradrenergic nuclei. Thus, it constitutes a novel molecular denominator shared by these classic neuromodulatory systems. SLC10A4 was found to influence vesicular transport of dopamine and affect neuronal release and reuptake efficiency in the striatum. Mice lacking Slc10a4 displayed impaired monoamine homeostasis and were hypersensitive to the drugs amphetamine and tranylcypromine. These findings demonstrate that SLC10A4 is capable of modulating the modulatory systems of the brain with potential clinical relevance for neurological and mental disorders. The transcription factor encoded by Dmrt3 was found to be expressed in a population of inhibitory commissural interneurons originating from the dorsal interneuron 6 (dI6) domain in the spinal cord. In parallel, a genome-wide association study revealed that a non-sense mutation in horse DMRT3 is permissive for the ability to perform pace among other alternate gaits. Further analysis of Dmrt3 null mutant mice showed that Dmrt3 has a central role for spinal neuronal network development with consequences for locomotor behavior. The dI6 class has been suggested to take part in motor circuits but remains one of the least studied classes due to lack of molecular markers. To further investigate the Dmrt3-derived neurons, and the dI6 population in general, a Dmrt3Cre mouse line was generated which allowed for characterization on the molecular, cellular and  behavioral level. It was found that Dmrt3 neurons synapse onto motor neurons, receive extensive synaptic inputs from various neuronal sources and are rhythmically active during fictive locomotion. Furthermore, silencing of Dmrt3 neurons in Dmrt3Cre;Viaatlx/lx mice led to impaired motor coordination and alterations in gait, together demonstrating the importance of this neuronal population in the control of movement.

Synaptic vesicle transporter

Neuromodulation

Dopamine

Central Pattern Generator

Locomotion

Gait

Horse

Mouse

Commissural Inhibitory Interneuron

Guidage axonal commissural : mécanismes de sensibilisation au signal de la ligne médiane Sémaphorine 3B / Commissural axon guidance : mechanism underlying the gain of sensitivity the midline signal Semaphorin 3B

Nawabi, Homaira

11 December 2009

Les mouvements locomoteurs rythmiques nécessitent l’intervention de circuits neuronaux qui coordonnent l’activité motrice des deux parties du corps. Ces circuits sont formés majoritairement par les projections des interneurones commissuraux de la moelle épinière. Des facteurs de guidage comme la Nétrine, les Slits jouent un rôle fondamental dans la mise en place de ces projections. Une étude a également montré qu’une signalisation impliquant le récepteur Neuropiline2 (Nrp2) des signaux Sémaphorines de la classe 3 (Sema3), participe au guidage de ces projections et cela uniquement après la traversée de la ligne médiane (Zou et al. 2000). Ma thèse porte sur l’étude fonctionnelle d’un ligand de la Nrp2, la Sema3B dans le développement de ce système de projections. J’ai analysé une souris invalidée pour Sema3B et observé de nombreuses erreurs de trajectoires après la traversée de la ligne médiane. Je me suis ensuite intéressée aux mécanismes sous-jacents au gain de réponse : par une approche pharmacologique et biochimique j’ai pu montrer que le signal de la plaque du plancher inhibe une activité de dégradation dépendante de la calpaine1. L’inhibition de cette voie conduit à la stabilisation d’un co-récepteur de la Nrp2, la Plexine A1 dont l’expression est très faible dans les axones n’ayant pas encore traversé la ligne médiane. Cette régulation permet alors l’assemblage d’un complexe récepteur fonctionnel de Sema3B, comprenant cette Plexine associée à la Nrp2 au niveau des cônes de croissance. J’ai identifié la molécule d’adhérence NrCAM, et le facteur neurotrophique GDNF comme étant les facteurs de la plaque du plancher déclencheurs de la réponse / Rhythmic locomotor movements require neuronal circuits ensuring left-right coordination. Spinal commissural projections participate to left-right coordination of limb movements by mediating reciprocal inhibition in synchrony. Extensive research of the mechanisms governing the formation of commissural pathways focused on dorsally-located spinal commissural neurons, establishing a fundamental role for multiple guidance cues derived for the midline and surrounding tissues, including Netrins, Slits and various morphogens. Semaphorin (Sema2)/Neuropilin-2 (Nrp2) signaling has been proposed to contribute to the guidance of commissural projections in the spinal cord at the post- but not pre-crossing stage (Zou et al, 2000). My PhD project aimed at analyzing the role of a Nrp2 ligand, Sema3B, in the guidance of spinal commissural projections, whose expression is dynamic and restricted to some territories, including the floor plate in which axons cross the midline. Analysis of Sema3B null mice showed that the loss of Sema3B induces a range of guidance defects of post-crossing commissural pathways. I investigated the underlying mechanisms and found that the floor plate signal induces through blockade of a calpain 1-dependant pathway the stabilization of the Nrp2 co-receptor Plexin-A1, and enable the assembly of Nrp2/Plexin-A1 sub-units into functional complexes for Sema3B in post-crossing commissural growth cones. I identified the cell adhesion molecule NrCAM and the neurotrophic factor GDNF as being the floor-platederived signals triggering the gain of response

Développement

Commisure

Guidage axonal

Moelle épinière

Development

Commissural projections

Axons guidance

Spinal cord

573.8

Organization of the Commissural Projection to the Dentate Gyrus Is Unaltered by Heavy Ethanol Exposure During Gestation

Dewey, Stephen L., West, James R.

01 January 1985

The anterograde horseradish peroxidase method was used to determine if prenatal exposure to ethanol affected the development of the characteristic afferent lamination pattern of the commissural projection to the dentate gyrus. Mean ethanol consumption for the ethanol-consuming dams was 12.7 g/kg ± 0.3 g per day. Adult offspring of rats that consumed a liquid diet containing 35% ethanol-derived calories during days 1-21 of gestation, and both pair-fed and normal controls were examined. Brain weights and volumes of the ethanol and pair-fed control rats did not differ significantly from normal controls. However, body weights of ethanol-exposed rats were significantly reduced compared to normal controls. Computer-assisted image analysis of the HRP-labeling revealed that in spite of the heavy ethanol exposure there was no evidence of alterations in the spatial distribution of the commissural terminal field.

afferent commissural system

brain development

dentate gyrus

ethanol

fetal alcohol syndrome

horseradish peroxidase

prenatal

rat

Spinal Control of Locomotion : Developmental and Functional Aspects

Rabe, Nadine

January 2010

Neuronal networks are the central functional units of the nervous system. Knowledge about the identity of participating neurons and the assembly of these during development is crucial for the understanding of CNS function. A promising system to dissect the development and functionalities of a neuronal network is the central pattern generator (CPG) for locomotion. We used screening approaches to identify spinal neuronal subpopulations by their specific gene expression, potentially involved in CPG function. Amongst others we found paired-like homeodomain transcription factor 2 (Pitx2) as a cholinergic interneuron marker for partition cells, with a possible role in the spinal network for locomotion. In addition, we present two genes, Chondrolectin (Chodl) and Estrogen-related receptor beta (ERRβ) as novel markers for fast and slow motor neurons, respectively. The neuronal components of the CPG integrate three key functions; rhythm generation, ipsilateral flexors/extensors coordination and bilateral coordination over the midline. Commissural interneurons (CINs) are considered to participate in the latter. During development axons are guided to their targets by the help of axon guidance molecules. Netrin-1 and its receptor DCC (Deleted in Colorectal Cancer) have been shown to play an important role for spinal cord neurons in axon-pathfinding and migration towards the midline. We show that loss of netrin-1 functionally results in a switch from alternating to synchronous left-right locomotor activity and deletion of DCC surprisingly leads to a different phenotype, best described as uncoordination. Thus, during development, netrin-1 and DCC play a critical role for the establishment of a functional balanced CPG. Further we show a selective loss of CINs, predominantly from dorsally originating subtypes, not affecting the ventral-most V3 subtype in netrin-1 mutant mice, but a loss of CINs from all progenitor domains in Dcc mutant mice. Together, our data suggest a netrin-1-independent mechanism for DCC in axon guidance and a role of the most ventral originating CINs as part of the neuronal network controlling synchronous activities over the midline. Another pair of axon guidance molecules, EphA4 and ephrinB3, has been shown to cooperate in preventing ipsilateral interneurons from crossing the spinal midline and if either molecule is deleted in mice, this will result in a defect in left-right coordination of locomotion. We provide in vivo and in vitro evidence that the GTPase-activating protein α2-chimerin, as a downstream molecule of EphA4 signaling, is essential in axon guidance decisions involved in the correct formation of the spinal circuitry for locomotion.

neuronal network

commissural interneuron

developmental interneuron subtypes

V3

mouse genetics

Pitx2

axon guidance

netrin-1

DCC

EphA4

Neuroscience

Neurovetenskap

AXOTOMIZED SPINAL COMMISSURAL INTERNEURONS OF THE ADULT FELINE: A study of axonal growth from dendrites and cut axons

Fenrich, Keith

07 December 2009

Acquiring knowledge of the morphological, molecular, and functional changes that occur to neurons following axotomy is a key step for a comprehensive understanding of the nervous system and how it reacts to injury. Propriospinal commissural interneurons (PCIs or CINs) are a class of neuron with axons that project through the ventral commissure to the contralateral spinal cord. My goal was to examine the morphological, molecular, and functional changes that occur to adult feline PCIs following a proximal axotomy. We first determined whether proximally axotomized PCIs develop de novo axons from their dendrites. C3 PCIs were proximally axotomized and several weeks later we stained PCIs and prepared the tissue for histological evaluation. Two primary classes of axotomized PCI were identified: those with a very short axon (called permanently axotomized) and those with an axon that projected across the injury site. Permanently axotomized PCIs had processes with morphological features typical of axons that emerged from their distal dendrites. These axonal processes of the distal dendrites also had GAP-43 (an axonal marker) and lacked MAP2a/b (a dendritic marker). We concluded that permanently axotomized PCIs develop de novo axons from distal dendrites. We then determined whether the axons that crossed the lesion site were representative of spontaneous functional regeneration. First, we showed that PCI axons regenerate through an environment that is typically highly inhibitory to regenerating axons. Second, we established that the regenerated axons conduct action potentials. Finally, we found that regenerated PCI axons form functional synaptic connections with neurons in the contralateral spinal cord. Collectively, these data indicated that spinal interneurons are capable of spontaneous functional regeneration through an injured spinal cord. PCI growth cones are complex and unlike growth cones previously described in the literature. The final study of the thesis examines the morphologies of PCI growth cones within spinal cord injury sites. We found that PCI growth cones have a wide range of morphologies that is independent of their location within the lesion site. Taken together, these data indicate that PCIs have a remarkable capacity for axonal elongation and contribute to remodelling of spinal circuitry following spinal injury. / Thesis (Ph.D, Physiology) -- Queen's University, 2009-12-07 11:21:47.036

Spinal cord injury

Commissural interneuron

Axonal regeneration

Growth cone

GAP-43

MAP2a/b

Chondroitin sulfate proteoglycans

Electrophysiology

Neuroanatomy

Synaptophysin

Feline

Study of the spatio-temporal dynamics of guidance receptors during commissural axon navigation in the spinal cord / Étude de la dynamique spatio-temporelle des récepteurs de guidage au cours de la navigation des axones commissuraux de la moelle épinière

Pignata, Aurora

10 December 2018

Les commissures forment un ensemble de connexions nerveuses assurant la communication entre les neurones de chaque hémi partie du système nerveux central des bilatériens. Au cours du développement embryonnaire, les axones des neurones commissuraux sont guidés au travers de la ligne médiane délimitant ces deux parties. Plusieurs sources de signaux de guidage attractifs et répulsifs agissent de concert pour organiser les trajectoires de ces axones. Dans la moelle épinière, les axones commissuraux traversent la ligne médiane dans un territoire ventral, la plaque du plancher (PP). Au cours de la traversée de la PP, ils acquièrent une sensibilité à des signaux répulsifs exprimés par ce territoire qui leur empêchent de rebrousser le chemin et qui les poussent hors de la PP. Plusieurs couples ligands/récepteurs médient ces forces répulsives mais les mécanismes qui sous-tendent l'acquisition de la sensibilité aux signaux répulsifs restent encore peu connus. Par exemple on ignore si les axons se sensibilisent à tous les signaux répulsifs en même temps, quand précisément ce switch de réponse se fait, et les contributions précises de chacun de ces signaux. Une spécificité fonctionnelle est suggérée par l'analyse des phénotypes d'invalidation des gènes codant pour ces récepteurs chez la souris ou encore par des manipulations d'expression chez l'embryon de poulet. L'objectif de mes travaux de thèse a été de tester l'hypothèse selon laquelle la génération de spécificités fonctionnelles pourrait résulter de contrôles précis et distincts de la dynamique spatiale et temporelle des récepteurs de guidage à la surface du cône de croissance. J'ai tout d'abord développé un dispositif de vidéomicroscopie adapté à l'enregistrement de cônes de croissance accomplissant la traversée de la PP, sur des moelles épinières en configuration de «livre ouvert». Afin de visualiser l'adressage à la surface du cône de croissance, j'ai exploité une forme de GFP sensible au pH, dont les propriétés de fluorescence à pH neutre permettent un suivi spécifique du pool de surface des protéines (Nawabi et al., 2010; Delloye-Bourgeois et al, 2014). J'ai utilisé ce paradigme pour comparer la dynamique temporelle de 4 récepteurs médiant les réponses aux divers signaux répulsifs de la PP: Nrp2, Robo1, Robo2 et PlxnA1. Les vecteurs d'expression de ces formes pHLuo de récepteurs ont été introduits dans les neurones commissuraux de la moelle épinière d'embryon de poulet par électroporation in ovo. Par des approches de microscopie à super-résolution sur les livres-ouverts, j'ai aussi étudié la distribution spatiale des récepteurs répulsifs à la surface des cônes de croissances au cours de la traversée. L'ensemble de ces expériences a pu démontrer que les récepteurs sont adressés à la membrane à différents temps de la navigation de la PP et occupent, de plus, des domaines distincts du cône de croissance. J'ai ensuite adapté la technique d'électroporation à la moelle épinière d'embryon de souris. Ces expériences ont montré que les séquences temporelles observées chez le poulet sont conservées chez la souris. J'ai également réintroduit le récepteur Robo1 dans une lignée de souris présentant une invalidation des récepteurs Robo1/2 et montré que l'altération de la traversée de la PP caractéristique de cette lignée est abolie dans la population d'axones capables d'adresser le récepteur Robo1 à la membrane. Au final, mes résultats démontrent que les axones commissuraux ne sont pas sensibilisés aux signaux répulsifs par la mise en œuvre d'un programme général. Au contraire, les récepteurs de guidage possèdent des profils de dynamiques temporelles spécifiques, et des domaines de distribution distincts dans le cône de croissance. Le contrôle de la dynamique d'adressage représente ainsi un mécanisme permettant de discriminer des signaux concomitants, en les fonctionnalisant à différents temps de la navigation de la moelle épinière / During embryonic development, commissural axons are guided through the midline, crossing from one side of the CNS to the other one at specific time points and positions to project onto contralateral neurons. Several sources of attractive cues regulate their navigation. In addition, repulsive forces act at different steps to keep the axons along their path. In the developing spinal cord, commissural axons cross the midline in a ventral territory, the floor plate (FP). Commissural axons gain sensitivity to repellents present in the FP after their crossing. The setting of these novel properties is necessary for preventing the axons to cross back and also for pushing them towards FP exit. Various ligand/receptor couples have been reported to mediate these repulsive forces. Whether commissural axons gain response to all the repulsive cues at the same time is not known. Whether these repulsive cascades have specific functions is suggested by different outcome of their invalidation in mouse models, but how are set these differences also remains unknown. We hypothesized that the generation of functional specificities could be achieved though specific controls of the spatial and temporal dynamics of guidance receptors at the growth cone surface. During my PhD, I developed a set up for time-lapse imaging of “open book” spinal cords, to monitor the dynamics of guidance receptors in axons experiencing native guidance decisions across the midline. To visualize their cell surface sorting, receptors were fused to the pH-sensitive GFP, pHLuorin, whose fluorescence at neutral pH reports membrane protein pools (Nawabi et al, 2010; Delloye-Bourgeois et al, 2014), and were expressed in spinal commissural neurons through in ovo electroporation. This paradigm revealed striking differences in the temporal dynamics of Nrp2, Robo1, Robo2 and PlexinA1, the receptors known to mediate the responsiveness to the major midline repellents referenced in vertebrates: Slit-Ns, Slit-Cs and Semaphorin3B. Moreover, using super-resolution microscopy, I could evidence that PlexinA1 and Robo1 are sorted in distinct subdomains of commissural growth cones navigating the floor plate. I also introduced the pHLuo-tagged receptors in the mouse embryo. These experiments showed that the temporal sequences established in the chick are conserved in the mouse, and that FP crossing in Robo1/2 mutant embryos was rescued in growth cones that could achieve cell surface sorting of Robo1. Thus, my results show that guidance receptors for midline repellents have highly specific spatial and temporal dynamics. The generation of a temporal sequences of cell surface sorting thus represents a mechanism whereby commissural growth cones discriminate concomitant signals by functionalizing them at different timing of their spinal cord navigation

Guidage axonal

Cone de croissance

Neurones commissuraux

Robo1

Robo2

Nrp2

PlxnA1

Axon guidance

Growth cone

Commissural neurons

Robo1

Robo2

Nrp2

PlxnA1

570

Rôle du facteur RFX3 dans la formation du cerveau chez l'embryon de souris

Benadiba, Carine

24 October 2008

Les membres de la famille de facteur de transcription RFX sont extrêment conservés au cours de l'évolution et sont retrouvés de la levure aux mammifères. Au sein de notre laboratoire, nous disposons d'un modèle murin Rfx3. Au cours de mon doctorat, j'ai entrepris d'analyser le phénotype cérébral de ce mutant. Il est ressorti de cette étude que les souris Rfx3 présentent de multiples atteintes cérébrales au niveau de l'Organe Sous Commissural, de la Glande Pinéale, des Plexus Choroïdes et de la Commissure Postérieure. L'analyse de la formation du cerveau, chez ces mutants, a révélé qu'une mauvaise spécification de la ligne médiane dorsale du prosencéphale peut en être à l'origine. Comme RFX3, est un régulateur de la ciliogenèse, ces travaux supposent l'existence d'un nouveau rôle des cils dans la genèse cérébrale. Appuyant cette hypothèse, une des atteintes cérébrales classiquement rencontrées chez les patients souffrant de ciliopathies, qu'est l'agénésie callosale, est également retrouvée chez les mutants murins Rfx3. Et l'analyse de la région de formation du Corps Calleux, en contexte mutant, a mis en évidence des défauts cellulaires pouvant expliquer cette atteinte cérébrale majeure. L'ensemble des travaux réalisés sur ce modèle murin de ciliopathie permettent progressivement d'apporter des réponses essentielles quant aux mécanismes physiopathologiques des ciliopathies.

RFX

Cil

Ciliopathies

cerveau

souris

Télencéphale

Diencéphale

Corps Calleux

Commmissure Hippocampique

Organe Sous Commissural

Glande Pinéale

Commissure Postérieure

Prosencéphale

Ligne médiane

Mécanismes moléculaires de polarisation des projections neuronales dans l'axe droite-gauche / Molecular mechanisms of polarisation of neuronal projections in the left-right axis

Charoy, Camille

10 June 2014

Les circuits nerveux s'organisent autour des grands axes de polarité du corps. Au cours du développement, la navigation ainsi que l'arrangement spatial des projections au sein de leurs territoires cibles sont contrôlés par de nombreux facteurs de guidage. Pendant ma thèse je me suis intéressée à deux modèles de formation des circuits neuronaux présentant une polarité dans l'axe droite-gauche. Le premier concerne la mise en place des projections des interneurones commissuraux de la moelle épinière, un modèle de navigation orientée et le second, porte sur l'innervation des motoneurones phréniques, un modèle d'organisation asymétrique dans le territoire cible. Les mouvements comme la marche, la course ou la nage font intervenir des circuits neuronaux particuliers dédiés à la coordination des deux côtés du corps. Ces circuits sont formés majoritairement par les projections des interneurones commissuraux de la moelle épinière. Au cours du développement, ces interneurones élaborent un axone qui traverse la ligne médiane partageant les deux moitiés du système nerveux central pour se connecter aux motoneurones ou à d'autres interneurones de l'hémi-moelle opposée. De nombreux travaux ont porté sur les mécanismes de traversée de la ligne médiane et ont mis en évidence un rôle fondamental de facteurs de guidage comme la Nétrine, les Slit et les Sémaphorines. Ces molécules sont secrétées par les cellules de la plaque du plancher (PP) environnant la ligne médiane ventrale. Lors de leur traversée les axones commissuraux sont tout d'abord attirés par les signaux attractifs secrétés par les cellules de la PP. Une fois que les axones ont traversé la ligne médiane, ils perdent leur sensibilité aux facteurs attractifs et développent des nouvelles sensibilités pour des facteurs répulsifs qui les guident hors de la PP. Une étude menée par mon équipe a permis de montrer que les axones commissuraux acquièrent une réponse à la Sémaphorine3B seulement après avoir traversé la ligne médiane. Dans cette étude, l'équipe a montré que pendant la phase qui précède la traversée de la PP, une protéase, la Calpaine-1, dégrade la Plexine-A1, le corécepteur de Sema3B (Nawabi et al., 2010). L'inhibition de cette voie pendant la traversée de la PP conduit à la stabilisation de la PlexineA1 à la surface du cône de croissance et la formation d'un complexe récepteur de Sema3B fonctionnel composé de la Plexine-A1 et de la sous-unité de liaison de Sema3B, la Neuropiline2. La suppression de l'activité Calpaine est contrôlée par des signaux de la PP dont la nature n'était pas connue. Au cours de ma thèse j'ai identifié et caractérisé les contributions fonctionnelles de deux signaux de la PP qui sont responsables de la suppression de l'activité Calpaine et la sensibilisation des axones à Sema3B après la traversée. Ces résultats ont permis d'élargir les fonctions du facteur neurotrophique gdnf, et d'apporter de nouveaux éléments sur les voies de contrôle de la signalisation Sémaphorine, les processus de traversée et les modulations post-traductionnelles des récepteurs Plexines. Dans un deuxième projet, je me suis intéressée aux asymétries droite-gauche du système nerveux, par l'étude d'un nouvel exemple de circuit neuronal asymétrique : l'innervation motrice du diaphragme. Le diaphragme est un muscle indispensable à la respiration, il est composé d'une région centrale tendineuse et de deux muscles latéraux. Ces muscles sont innervés par un groupe particulier de motoneurones provenant de la moelle épinière cervicale, qui forment les nerfs phréniques droits (D) et gauches (G). Malgré une position centrale dans l'organisme et une morphologie apparente symétrique, nous avons découvert que le diaphragme présente une asymétrie musculaire ainsi qu'une asymétrie nerveuse. Etonnamment les motoneurones phréniques établissent un motif de connexion typique et différent sur les muscles droit et gauche du diaphragme [etc...] / The nervous circuits have stereotype positions within the major body axes. During development, axonal navigation and special positioning of the axon tracts in the target territories are regulated by many axon guidance factors. During my thesis I have been interested in two models of neuronal circuit formation that present a leftright polarity. The first one concerns the formation of the spinal commissural neurons projections, a model of oriented navigation along the left-right axis and the second one is the innervation of the phrenic motoneurons, a novel model of left-right asymmetric innervation pattern. Rhythmic locomotor movements like walking, running or swimming require neuronal circuits ensuring left-right coordination. Central components of these circuits are commissural neurons of the spinal cord. During development theses neurons are projecting axons across the midline that divides the nervous system in two parts, which connect the contralateral side of the spinal cord. Extensive work focused on the mechanisms controlling midline crossing. These study revealed a fundamental role of guidance factors secreted by floor plate cells at the ventral midline such as Netrins, Slits and Semaphorins. They also revealed that before crossing, axons are attracted towards the floor plate, and navigating by the floor plate they lose responsiveness to these attractive factors and develop a new sensitivity to repulsive cues that drive them out of the floor plate. In a previous study, my team showed that commissural axons gain response to Sema3B only after floor plate crossing (Nawabi et al., 2010). Before crossing, Plexin-A1 the Sema3B receptor is processed by a protease: the Calpain1. During crossing suppression of this pathway enable Plexin-A1 expression at growth cone surface, leading to sensitization to Sema3B. The suppression of Calpain activity was found controlled by floor plate signals, which remained unknown. During my thesis I have identified and characterized the functional contribution of two floor plate signals that are responsible for the inhibition of Calpain activity and axon sensitization to Sema3B after midline crossing: the neurotrophic factor gdnf and the cell adhesion molecule NrCAM. My results bring new elements on the control of midline crossing processes, Semaphorin signaling, and post-translational modifications of the Plexins receptors. In my second project, I have been interested in left-right asymmetries of the nervous system through the study of a new model of left-right asymmetry: the diaphragm innervation. The diaphragm is a muscle essential for breathing, it is composed of one central tendinous region and two lateral muscles. These muscles are innervated by a subset of cervical spinal cord motoneurons which forms the left and right phrenic nerves. Despite its central disposition in the organism and its apparent symmetry, we noticed that the diaphragm presents nervous and muscular asymmetries. Surprisingly phrenic motoneurons present typical and different nerve patterns on the left and right diaphragm muscles. Diverse left-right characteristic have been documented in the brain but none concerned yet the spinal cord or peripheral projections. My thesis work has been dedicated to the identification of the mechanisms that control the asymmetry of the diaphragm innervation. My work showed that this asymmetry is set up very early during development via a molecular pathway that is known to control the visceral organ asymmetry. This work opens numerous perspectives and brings new information on the molecular diversity of spinal neurons that could shed a new light on the mechanisms of motoneuron physiopathology

Développement

Moelle épinière

Neurones

Guidage axonal

Neurones commissuraux

Moto-neurones

Diaphragme

Nerfs phrénique

Development

Spinal cord

Neuron

Axon guidance

Commissural neuron

Motor-neuron

Diaphragm

Phrenic nerves

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