Expression du facteur neurotrophique HGF dans les motoneurones lombaires murins suite à la lacération et à la stimulation électrique du nerf sciatique

Roy, Andrée-Anne

09 1900

Objectifs: Hepatocyte Growth Factor (HGF) améliore la régénération axonale et la survie des motoneurones lors du développement embryonnaire. Son rôle dans la régénération des nerfs périphériques lésés chez l’adulte n’a pas encore été étudié. Notre objectif est de déterminer l’expression de HGF dans la moelle épinière murine suite à une axotomie, avec ou sans stimulation électrique, directe ou transcutanée. Méthodes: Soixante souris C57BL/6 adultes ont été divisées en 5 groupes : Contrôle (n=12), Placebo (n=12), Axotomie (n=12, lacération et réparation immédiate du nerf sciatique), Directe (n=12, lacération, réparation immédiate et stimulation électrique directe proximale du nerf sciatique, 1h, 20 Hz) et Transcutanée (n=12, lacération, réparation immédiate et stimulation électrique transcutanée proximale du nerf sciatique, 1h, 20 Hz). Les moelles épinières ont été recueillies 1, 3, 7 et 14 jours suivant l’intervention. L’expression de HGF a été évaluée par technique d’hybridation in situ. Résultats: Nos résultats démontrent une augmentation de l’expression de HGF dans les moelles épinières murines suite à l’axotomie. Cette augmentation est plus rapide suite à la stimulation électrique, autant directe que transcutanée. L’expression de HGF devient localisée aux zones motrices de la moelle épinière murine dans les groupes Axotomie, Directe et Transcutanée. Conclusions: HGF, facteur neurotrophique impliqué de le développement et la survie des motoneurones, a une expression altérée suite à la lacération du nerf sciatique. Ceci suggère fortement qu’il participe aussi à la régénération des nerfs moteurs. De plus, l’expression plus rapide de HGF suite à la stimulation électrique suggère son implication dans l’augmentation de la régénération nerveuse. / Purpose: Hepatocyte Growth Factor (HGF) plays a role in promoting axonal growth and survival of motoneurons during embryonic development. This factor might also be important in directing the regeneration of adult motoneurons following laceration. We aim to identify the expression patterns of HGF following axotomy, with or without direct or transcutaneous electrical nerve stimulation in a mouse model. Methods: Sixty adult C57BL/6 mice were divided into 5 groups: Control (n=12), Sham (n=12), Axotomy (n=12, sciatic nerve laceration and immediate repair), Direct (n=12, sciatic nerve laceration, immediate repair and application of direct electrical stimulation on the proximal nerve end, 1h, 20 Hz) and Transcutaneous (n=12, nerve laceration and immediate repair followed by proximal transcutaneous electrical stimulation, 1h, 20 Hz). Spinal cords were harvested at 1, 3, 7 and 14 days post-surgery. The expression patterns of HGF were measured using in situ hybridization. Results: Our results showed an upregulation of HGF expression in mouse spinal cords following sciatic nerve axotomy. This occurred more quickly following electrical stimulation in both Direct and Transcutaneous groups. The expression pattern of HGF became localized to the motor neuron pools in the Axotomy, Direct and Transcutaneous groups. Conclusions: HGF, a growth factor involved in directing the outgrowth of motor axons in development, has an altered expression pattern following sciatic nerve laceration, suggesting it may also play a role in directing motoneuron regeneration. Furthermore, rapid change in the expression pattern of HGF following electrical stimulation suggests it may also be involved in the upregulation of nerve regeneration following electrical stimulation.

Atteinte nerveuse

Facteurs neurotrophiques

HGF

BDNF

trkB

Stimulation électrique

Stimulation électrique transcutanée

Hybridation in situ

Modèle murin

Nerve injury

Peripheral nerve regeneration

Neurotrophic factors

Electrical stimulation

Transcutaneous electrical stimulation

In situ hybridization

Mouse model

Influência do cálcio e das proteínas Miro na mobilidade mitocondrial anteriormente e durante a agregação de proteínas envolvidas em neurodegeneração / Influence of calcium and Miro proteins on mitochondrial mobility before and during protein aggregation involved in neurodegeneration

Chaves, Rodrigo dos Santos

07 October 2015

A inibição do transporte axonal é um evento que ocorre prematuramente no curso das doenças neurodegenerativas, inclusive antes da formação dos agregados proteicos, os quais estariam envolvidos no processo fisiopatológico das doenças neurodegenerativas. No presente estudo avaliou-se a hipótese de que alterações no transporte de mitocôndrias ocorrem antes da formação dos agregados proteicos envolvidos em neurodegeneração, devido a desregulação dos níveis citoplasmáticos de Ca2+ e o envolvimento da modulação do transporte mitocondrial provido pela proteína Miro neste cenário. Utilizaram-se dois modelos experimentais: o primeiro utilizando a exposição à rotenona em culturas primárias de neurônios do locus coeruleus, hipocampo e substância negra de ratos, e o segundo utilizando neurônios derivados de células tronco de pluripotência induzida (iPSC), isogênicas humanas contendo mutações que levam à deleção do exon 9 da (deltaE9) no gene da presenilina 1 (PS1), o qual apresenta aumento da síntese do peptídeo beta-amiloide com 42 aminoácidos (Abeta42), sem a formação de agregados proteicos. Os resultados mostram disfunções nos níveis citoplasmáticos de Ca2+ em ambos modelos. A mobilidade mitocondrial alterou-se no hipocampo, locus coeruleus e substância negra após exposição à rotenona. No entanto, a direção das alterações observadas não se correlacionaram com os níveis de Ca2+, de acordo com o já descrito na literatura. Não houve alteração da mobilidade mitocondrial, nem nos níveis de Miro1, nos neurônios derivados de iPSC. Em conclusão, o presente estudo demonstrou que alterações nos níveis citoplasmáticos de Ca2+ ocorrem antes e durante a formação de agregados proteicos, o que pode ser importante para a etiologia de doenças neurodegenerativas. Foi também demonstrado que mudanças na mobilidade mitocondrial, acompanhadas por alterações nas concentrações intracelulares de Ca2+, em níveis fisiológicos, ocorrem de forma independente dos níveis da proteína Miro1 em culturas de células. Porém são necessários novos estudos a fim de relacionar alterações na mobilidade mitocondrial e a indução da neurodegeneração / The axonal transport impairment occurs early in neurodegenerative diseases, even before the formation of protein aggregates, which are related with the neuropathophysiology mechanism in neurodegenerative diseases. In this study, we evaluate the hypothesis that disruptions in mitochondria transport occurs before the formation of protein aggregate related with neurodegeneration, triggered by dysregulations in cytosolic Ca2+ levels and the involvement of Miro Ca2+ dependent mechanism of mitochondria trafficking modulation. We employed two experimental models, first using rotenone exposure in primary neuronal cell cultures from locus coeruleus, substantia nigra and hippocampus of newborn rats. Second, using isogenic human neurons derived from induced pluripotent stem cells (iPSCs), harboring mutations, those induce exon 9 deletion (deltaE9) in Presenilin 1 (PS1) gene, and showing increased synthesis of amyloid beta peptide with 42 amino acids (betaA42) without the formation of protein aggregates. We found abnormalities in cytosolic Ca2+ levels in both experimental models, mitochondria trafficking were altered in hippocampus, substantia nigra and locus coeruleus. However, the pattern of mitochondria trafficking alterations did not correlate with cytosolic Ca2+ levels, accordingly with the data that was already published. We did not find alterations in mitochondria trafficking or Miro1 levels in neurons derived from iPSC. In conclusion, our finds demonstrated aberrant cytosolic Ca2+ levels before and during protein aggregation, which may be important for the etiology of neurodegenerative diseases. In addition, this dysfunction in mitochondria trafficking happens after changes in cytosolic Ca2+ levels, in physiological range, independent of Miro1 levels in primary neurons cell cultures. Therefore, new studies need to be done, aiming to elucidate the relation between mitochondria trafficking dysfunctions and the induction of neurodegeneration process.

Agregação patológica de proteínas

Alzheimer disease

Cálcio

Calcium

Doença de Alzheimer

Doença de Parkinson

Miro-1 protein human

Mitochondrias

Mitocôndrias

Nerve regeneration

Parkinson disease

Protein aggregation pathological

Protein transport

Proteína Miro-1 humana

Proteínas rho de ligação ao GTP

Regeneração nervosa

rho GTP-binding proteins

Transporte proteíco

Influência do cálcio e das proteínas Miro na mobilidade mitocondrial anteriormente e durante a agregação de proteínas envolvidas em neurodegeneração / Influence of calcium and Miro proteins on mitochondrial mobility before and during protein aggregation involved in neurodegeneration

Rodrigo dos Santos Chaves

07 October 2015

A inibição do transporte axonal é um evento que ocorre prematuramente no curso das doenças neurodegenerativas, inclusive antes da formação dos agregados proteicos, os quais estariam envolvidos no processo fisiopatológico das doenças neurodegenerativas. No presente estudo avaliou-se a hipótese de que alterações no transporte de mitocôndrias ocorrem antes da formação dos agregados proteicos envolvidos em neurodegeneração, devido a desregulação dos níveis citoplasmáticos de Ca2+ e o envolvimento da modulação do transporte mitocondrial provido pela proteína Miro neste cenário. Utilizaram-se dois modelos experimentais: o primeiro utilizando a exposição à rotenona em culturas primárias de neurônios do locus coeruleus, hipocampo e substância negra de ratos, e o segundo utilizando neurônios derivados de células tronco de pluripotência induzida (iPSC), isogênicas humanas contendo mutações que levam à deleção do exon 9 da (deltaE9) no gene da presenilina 1 (PS1), o qual apresenta aumento da síntese do peptídeo beta-amiloide com 42 aminoácidos (Abeta42), sem a formação de agregados proteicos. Os resultados mostram disfunções nos níveis citoplasmáticos de Ca2+ em ambos modelos. A mobilidade mitocondrial alterou-se no hipocampo, locus coeruleus e substância negra após exposição à rotenona. No entanto, a direção das alterações observadas não se correlacionaram com os níveis de Ca2+, de acordo com o já descrito na literatura. Não houve alteração da mobilidade mitocondrial, nem nos níveis de Miro1, nos neurônios derivados de iPSC. Em conclusão, o presente estudo demonstrou que alterações nos níveis citoplasmáticos de Ca2+ ocorrem antes e durante a formação de agregados proteicos, o que pode ser importante para a etiologia de doenças neurodegenerativas. Foi também demonstrado que mudanças na mobilidade mitocondrial, acompanhadas por alterações nas concentrações intracelulares de Ca2+, em níveis fisiológicos, ocorrem de forma independente dos níveis da proteína Miro1 em culturas de células. Porém são necessários novos estudos a fim de relacionar alterações na mobilidade mitocondrial e a indução da neurodegeneração / The axonal transport impairment occurs early in neurodegenerative diseases, even before the formation of protein aggregates, which are related with the neuropathophysiology mechanism in neurodegenerative diseases. In this study, we evaluate the hypothesis that disruptions in mitochondria transport occurs before the formation of protein aggregate related with neurodegeneration, triggered by dysregulations in cytosolic Ca2+ levels and the involvement of Miro Ca2+ dependent mechanism of mitochondria trafficking modulation. We employed two experimental models, first using rotenone exposure in primary neuronal cell cultures from locus coeruleus, substantia nigra and hippocampus of newborn rats. Second, using isogenic human neurons derived from induced pluripotent stem cells (iPSCs), harboring mutations, those induce exon 9 deletion (deltaE9) in Presenilin 1 (PS1) gene, and showing increased synthesis of amyloid beta peptide with 42 amino acids (betaA42) without the formation of protein aggregates. We found abnormalities in cytosolic Ca2+ levels in both experimental models, mitochondria trafficking were altered in hippocampus, substantia nigra and locus coeruleus. However, the pattern of mitochondria trafficking alterations did not correlate with cytosolic Ca2+ levels, accordingly with the data that was already published. We did not find alterations in mitochondria trafficking or Miro1 levels in neurons derived from iPSC. In conclusion, our finds demonstrated aberrant cytosolic Ca2+ levels before and during protein aggregation, which may be important for the etiology of neurodegenerative diseases. In addition, this dysfunction in mitochondria trafficking happens after changes in cytosolic Ca2+ levels, in physiological range, independent of Miro1 levels in primary neurons cell cultures. Therefore, new studies need to be done, aiming to elucidate the relation between mitochondria trafficking dysfunctions and the induction of neurodegeneration process.

Agregação patológica de proteínas

Cálcio

Doença de Alzheimer

Doença de Parkinson

Mitocôndrias

Proteína Miro-1 humana

Proteínas rho de ligação ao GTP

Regeneração nervosa

Transporte proteíco

Alzheimer disease

Calcium

Miro-1 protein human

Mitochondrias

Nerve regeneration

Parkinson disease

Protein aggregation pathological

Protein transport

rho GTP-binding proteins

Use of a novel peripheral nerve conduit to support sciatic nerve regeneration in an animal model

Lan Chun Yang, Timothy

06 1900

Introduction : Les conduits nerveux synthétiques représentent une alternative chirurgicale aux autogreffes dans la réparation des traumatismes aux nerfs périphériques. Afin d’améliorer la régénération nerveuse périphérique, plusieurs biomatériels, tels que la multicouche polyélectrolyte de soie (MPE), et modèles ont été étudiés. Dans le cadre de ma maitrise, nos objectifs de recherche sont d’établir si la MPE de soie permet d’améliorer la régénération nerveuse périphérique in vivo et si notre nouveau modèle de conduit (« jelly roll ») peut mener à une meilleure régénération du nerf sciatique chez le rat que le modèle de conduit creux. Méthodes : Dans cette étude, une technique chirurgicale in vivo de lacération et de réparation du nerf sciatique chez le rat fut utilisé. Cinq conditions expérimentales de conduits (autogreffe, conduit creux avec et sans MPE de soie et « jelly roll » avec et sans MPE de soie) furent implantées (n= 2 rats par condition). Après 4 semaines, les conduits furent récupérés et marqués par immunohistochimie avec le neurofilament et la protéine basique de la myéline (MBP). La performance de chaque conduit fut évaluée par sa capacité à supporter l’excroissance axonale à travers le long du conduit et à travers la largeur de ce dernier à divers endroits. Résultats : Chaque condition expérimentale a supporté une régénération axonale avec différents degrés de succès. Globalement, l’autogreffe a supporté une plus longue croissance de fibres. De plus, la surface de fibres obtenue était plus large que les autres conditions. Les conduits avec la MPE de soie ont eu une performance similaire à leurs homologues sans soie. De plus, le modèle de conduit creux a mené à une meilleure régénération axonale que le modèle du « jelly roll ». Conclusion : L’autogreffe demeure le meilleur conduit pour supporter la régénération nerveuse périphérique. Les conduits avec la MPE de soie peuvent supporter une régénération nerveuse similaire aux conduits sans soie tandis que le modèle de « jelly roll » a généré des performances inférieures au modèle de conduit creux. / Background: Synthetic nerve conduits constitute alternative surgical options to autografts in the repair of peripheral nerve injuries. Silk polyelectrolyte multilayer (PEM) as a biomaterial and novel conduit designs have been proposed to improve peripheral nerve regeneration. In my master’s project, my objective is to assess whether silk PEM can improve peripheral nerve regeneration in vivo and to assess whether our novel conduit design (“jelly roll”) can better support rat sciatic nerve regeneration than a hollow conduit design. Methods: In this study, an in vivo rat model of sciatic nerve laceration and repair was used. Five experimental conduit conditions (autograft, hollow conduit with and without silk PEM, and jelly roll with and without silk PEM) were implanted (n=2 rats per condition). After 4 weeks, the conduits were harvested and immuno-stained for neurofilament and myelin basic protein (MBP). Conduit performance was assessed by its ability to support axonal outgrowth throughout the conduit’s length and at various locations along its width. Results: Each condition supported axonal regeneration at varying levels of success. Overall, the autograft group outperformed all other groups by supporting the longest and widest occupying regenerating fibers. Conduits with silk PEM performed similarly to conduits without silk PEM. In addition, the hollow conduit design demonstrated better regenerative outcomes than the jelly roll design. Conclusion: The autograft remains the superior conduit to support peripheral nerve regeneration. Conduits with silk PEM support nerve regeneration in the same capacity as non silk-coated conduits while the jelly roll design underperformed in comparison to the hollow conduit design.

peripheral nerve regeneration

nerve guidance conduit

nerve autograft

silk polyelectrolyte multilayer

hollow nerve conduit

jelly roll

peripheral nerve surgery

peripheral nerve injuries

axonal outgrowth

régénération nerveuse périphérique

conduit de guidage nerveux

autogreffe nerveuse

multicouche polyélectrolyte de soie

conduit nerveux creux

chirurgie du nerf périphérique

lésions nerveuses périphériques

excroissance axonale