La régénération axonale suivant l'axotomie du nerf sciatique et stimulation électrique directe et transcutanée chez la souris

Pion, Anne-Marie J.

08 1900

La stimulation électrique directe (SED), pour une heure, améliore la régénération de nerfs périphériques chez le rat après la réparation. Cliniquement, ceci augmenterait le temps opératoire, rehaussant les risques de complications périopératoires. Objectif: Cette étude examine si la stimulation électrique transcutanée (SETC) est aussi efficace à améliorer la régénération de nerfs périphériques que la stimulation électrique directe. Méthode: Le nerf sciatique droit de 28 souris a été axotomisé. Une réparation par microsuture est effectuée. Quatre groupes sont étudiés : (1) sham; (2) suture seulement; (3) suture et SED; (4) suture et SETC. La stimulation est appliquée pour 1 heure à 20 Hz. Les souris sont étudiées pour un total de 12 semaines. La récupération sciatique est évaluée aux semaines 0, 1, 2 et aux 2 semaines par la suite par analyse de démarche sur la poutre. Résultats: La cinématique post-récupération démontre un index fonctionnel sciatique et angle de décollement significativement améliorés pour les groupes SED et SETC aux semaines 8, 10 et 12. Conclusions: 12 semaines après l’axotomie du nerf sciatique, la récupération fonctionnelle est significativement améliorée avec la SED et la SETC. Donc, la SETC est aussi bénéfique pour la promotion de la régénération nerveuse et réinnervation musculaire fonctionnelle que la SED. / Direct electrical stimulation (DES) for one hour increases the rate of peripheral nerve regeneration in rats after nerve repair. Clinically, this would lengthen surgery time, increasing risks of perioperative complications. Purpose: This study examines whether transcutaneous electrical stimulation (TCES) is as effective at improving peripheral nerve regeneration as direct electrical stimulation. Methods: The right sciatic nerve was axotomized in 28 mice. End-to-end microsuture repair was undertaken. Four groups were studied: (1) sham; (2) suture only; (3) suture and DES; (4) suture and TCES. Stimulation was applied for 1 hour, at 20 Hz. The mice were studied for a total of 12 weeks. Hind-limb recovery was evaluated at weeks 0, 1, 2 and then every 2 weeks by walking-track analysis. Results: Post recovery kinematic showed significantly improved functional sciatic index and foot-base angles at weeks 8, 10 and 12 for both DES and TCES groups. Conclusions: 12 weeks after sciatic nerve axotomy, functional recovery was improved significantly in both DES and TCES groups. Therefore, TCES is as beneficial in promoting nerve regeneration and functional muscle reinnervation as is DES.

axotomie

blessure nerveuse

stimulation électrique

réparation nerveuse

régénération axonale

récupération fonctionnelle

motoneurone

cinématique

axotomy

nerve injury

electrical stimulation

nerve repair

axonal regeneration

functional recuperation

motoneuron

kinematics

Etude du développement postnatal des motoneurones lombaires de deux souches de souris transgéniques, modèles de la sclérose latérale amyotrophique / Postnanal development study of lumbar motoneurons of two trangenic mice strains, models of amyotrophic lateral sclerosis

Pambo-Pambo, Arnaud Brice

17 December 2010

Les modèles murins de la Sclérose Latérale Amyotrophique (SLA) ont permis des avancées dans la compréhension des mécanismes pouvant conduire à la mort sélective et progressive des motoneurones (Mns) mais ils présentent des disparités dans la sévérité et le décours temporel de la maladie. Parmi les hypothèses avancées figurent des modifications des propriétés intrinsèques des motoneurones conduisant à des modifications de l’excitabilité et de l’homéostasie du calcium intracellulaire et à la mort du motoneurone.Nous avons donc étudié les propriétés électrophysiologiques des Mns lombaires de souris SOD1G85R et SOD1G93A, deux modèles à faible nombre de copies du gène humain muté, durant les deux premières semaines postnatales afin d’identifier d’éventuelles anomalies pré-symptomatiques précoces. Nos travaux ont été réalisés sur deux préparations in vitro de moelle entière isolée et de tranches de moelle épinière. Les Mns mutants présentent, sur les deux types de préparations, une altération des propriétés du potentiel d’action se traduisant par un allongement de la durée associée à une diminution des vitesses maximales de dépolarisation et repolarisation et une réduction d’amplitude. Ces altérations apparaissent entre P2-P5 dans les Mns SOD1G85R et entre P6-P10 dans les Mns SOD1G93A et suggèrent une diminution de la densité des canaux sodiques et potassiques associés au potentiel d’action. Nous avons aussi observé sur des tranches de moelle épinière entre P6-P10 que le gain de fréquence des Mns SOD1G85R diminue et celui des SOD1G93A augmente sans aucune modification des densités des courants entrants persistants sodiques et calciques. On note également que, sur tranches de moelle épinière, les Mns SOD1G93A présentent un potentiel de repos diminué. En présence d’une surcharge calcique extracellulaire, les propriétés membranaires des Mns SOD1G85R entre P6-P10 sont moins affectées que celles des Mns témoins. Les effets différentiels de cette surcharge peuvent être dus à des modifications différentes de la dépendance au voltage des canaux voltage-dépendants et/ou à la modulation de certains types de canaux activés par le calcium extracellulaire. Une arborisation dendritique plus ramifiée que celle de Mns témoins, comparable à celle précédemment décrite dans les Mns SOD1G85R, a été observée dans les Mns SOD1G93A à P8-P9 avec des altérations du potentiel d’action citées plus haut et une réduction de la rhéobase. Ces altérations morphologiques et électriques pourraient indiquer des modifications de cinétiques et/ou de densités de canaux sur des sites différents dans ces Mns. Nos travaux montrent donc, d’une part que les mutations SOD1G85R et SOD1G93A induisent dans ces deux modèles murins des altérations des propriétés des Mns lombaires comparables mais décalées dans le temps et d’autre part que certaines altérations semblent être spécifiques à une mutation SOD1 donnée. / The SOD1 murine models of Amyotrophic Lateral Sclerosis (ALS) allowed major progress in the understanding of mechanisms which could lead to a selective loss of motoneurons (Mns), but these models display differences in the severity and time course of the disease. Changes in intrinsic properties of motoneurons may induce changes in excitability and intracellular calcium homeostasis leading to motoneuron death.Therefore, we studied electrophysiological properties of lumbar Mns from SOD1G85R and SOD1G93A mice, low expressor lines, during the first two postnatal weeks in order to identify possible early presymptomatic abnormalities. Our studies were carried out on two in vitro preparations: the whole isolated spinal cord and acute spinal cord slices. Mutant Mns display, in the two preparations, a modified action potential characterized by an increased duration due to a decrease of the maximal speeds of depolarisation and repolarisation and a reduction of the spike amplitude. These alterations appeared between P2-P5 in SOD1G85R Mns and between P6-P10 in SOD1G93A Mns and suggest a decrease of the density of sodium and potassium channels related to action potential. We also showed on spinal cord slices between P6-P10 that the gain of frequency decreases for SOD1G85R Mns and increases for SOD1G93A Mns without any change in the density of persistent inward sodium or calcium currents in these different mutant Mns. We observed also that the resting membrane potential of SOD1G93A Mns on spinal cord slices is decreased. The membrane properties of SOD1G85R Mns between P6-P10 were less susceptible to changes in presence of an extracellular calcium overload. Differential effects of this extracellular calcium overload on membrane properties of WT and SOD1G85R Mns could be due to different alterations of the potential dependence of voltage-gated channels and/or to the modulation of some types of channels sensitive to extracellular calcium. An over-branching of dendritic arborization, similar to that previously described in SOD1G85R Mns, was observed in SOD1G93A at P8-P9 with the above-mentioned action potential alterations and a weak rheobasic current. These morphogical and electrical changes could indicate together alterations of kinetics and/or density of channels on different sites on these Mns. In conclusion, our work shows on one hand that SOD1G85R and SOD1G93A mutations induce similar alterations of lumbar Mns properties but time-shifted in these two murine models and on the other hand that some alterations seem to be specific to a given SOD1 mutation.

Sclérose latérale amyotrophique

Souris SOD1-G85R

Souris SOD1-G93R

Pré-symptomatique

Motoneurones

Propriétés électrophysiologiques

Développement postnatal

Morphologie

Amyotrophic lateral sclerosis

Motoneuron

Postnatal development

Presymptomatic

Electrophysiological properties

SOD1G85R mouse,

SOD1G93A mouse

Morphology

Neuroprotection and axonal regeneration after peripheral nerve injury

Welin, Dag,

January 2010

Diss. (sammanfattning) Umeå : Umeå universitet, 2010.

Altérations des cellules de Schwann périsynaptiques à la jonction neuromusculaire : implications pour la sclérose latérale amyotrophique

Arbour, Danielle

07 1900

No description available.

sclérose latérale amyotrophique

motoneurone

jonction neuromusculaire

cellule de Schwann périsynaptique

récepteur muscarinique

électrophysiologie

immunohistochimie

amyotrophic lateral sclerosis

motoneuron

neuromuscular junction

perisynaptic Schwann cell

muscarinic receptor

electrophysiology

immunohistochemistry

Genetische Analyse des Tyrosinkinase-Rezeptors ErbB2

Woldeyesus, Masresha Tsegaye

14 February 2001

ErbB2 gehört zu den Klasse I Rezeptor-Tyrosinkinasen und funktioniert als Ko-rezeptor bei der Vermittlung des Neuregulin-Signals. Während der Embryonal-entwicklung wird ErbB2 im Herzen, in den Neuralleistenzellen, im Muskel und in den Epithelien exprimiert (Kokai et al. 1987). Embryonen mit einer Null-Mutation im ErbB2 Gen sterben am Tag 10,5 der Embryonalentwicklung. Die Mutation bewirkt eine morphogenetische Fehlbildung des Herzens, die durch das Fehlen von ventrikulären Trabekeln gekennzeichnet ist (Lee et al. 1995). Weiterhin zeigen diese Embryonen Defekte in den Kranialganglien und in der primären sympathischen Ganglien-Kette, die von Neuralleistenzellen gebildet werden (Lee et al. 1995; Erickson et al. 1997; Britsch et al. 1998). Die herzspezifische Expression von ErbB2 cDNA ermöglicht ErbB2-/- Tieren, sich bis zur Geburt zu entwickeln. Dies erlaubte mir, spätere Funktionen des Rezeptors zu untersuchen. In den geretteten ErbB2-/- Embryonen erfolgte die Bildung der ventrikulären Trabekel, der fingerähnlichen Ausstülpungen des Myokards, zwischen dem 9. und 10. Tag in der Embryonalentwicklung. In den späteren Phasen der intrauterinen Entwicklung war das Herz der geretteten Tiere normal ausgebildet. In den ErbB2-/-R Embryonen fehlten Schwann'sche Zellen entlang der peripheren Nerven. Die Abwesenheit von Schwann'schen Zellen führte zum massiven Absterben von sensorischen und motorischen Neuronen des Rückenmarkes. Dabei zeigten sensorische Neuronen eine frühe Abhängigkeit von neurotrophen Faktoren, die von Schwann'schen Zellen produziert werden, während Motoneuronen diese Faktoren in einer späteren Phase benötigen. Zusätzlich ist bekannt, daß sensorische Neuronen und Motoneuronen neurotrophe Fakten benötigen, die von den Zielorganen, z.B. den Muskeln, produziert werden. Motoneuronen im thorakalen Rückenmark sind nur minimal betroffen, während die Degeneration von Moto-neuronen in den zervikalen und lumbalen Segmenten stark ausgeprägt ist. Verschiedene Motoneuron-Typen unterscheiden sich also in ihrer Abhängigkeit von neurotrophen Signalen. Weiterhin sind die peripheren Nerven der ErbB2-/-R Tiere defaszikuliert und ungeordnet. Der N. phrenicus, der das Diaphragma innerviert, retrahiert und ist am Tag 17 der Entwicklung vollständig degeneriert. Deshalb können die mutanten Tiere bei der Geburt nicht atmen und sterben infolgedessen. Überraschenderweise erfolgt in den geretteten ErbB2-/-R Embryonen die post-synaptische Expression und Aggregation der Acetylcholin-Rezeptoren. Die Phäno-typen der ErbB2-/-R und ErbB3-/- mutanten Tieren sind sehr ähnlich. Dies zeigt, daß ErbB2 eine essentielle Korezeptor-Funktion für ErbB3 in der Vermittlung der Neuregulin-Signale übernimmt. / ErbB2 belongs to class I of receptor tyrosine kinases and functions as a co-receptor by the transduction of the neuregulin signal. During embryonic development the ErbB2 gene is expressed in the heart, neural crest, in muscle and epithelial cells (Kokai et al. 1987). Embryos with null mutation of the ErbB2 gene die at midgestation. The mutation causes a morphogenetic defect that results in the absence of trabecules (Lee et al. 1995). In addition the mutant embryos show defects in cranial ganglia and in the primary sympathetic ganglia chain (Lee et al. 1995; Erickson et al. 1997; Britsch et al. 1998). The heart specific expression of ErbB2 cDNA allowed the mutant animals to survive till birth. This enabels me to study the late function of the receptor. In rescued ErbB2-/- embryos the ventricular trabecules, which are finger-like extensions of the myocardium, form properly between E9 and E10 of embryonic development. At late stages of intrauteral development the hearts of the rescued animals showed an overall normal growth. ErbB2-/- embryos lack Schwann cells along peripheral nerves. The absence of Schwann cells leads to enormous degeneration of sensory and motoneurons. Whereas sensory neurons show an early dependency on neurotrophic factors produced by Schwann cells, motoneurons revealed requirement of these factors during the late phase of their development. Moreover it is known that sensory and motoneurons require neurotrophic factors which are produced by their target tissues such as muscle. Motoneurons at the thoracic level of the spinal cord are minimaly affected, whereas the degeneration of motoneurons at cervical and lumbar segments of the spinal cord are pronounced. This indicates that different motoneuron types differ in their dependency on neurotrophic signals. Furthermore axons of peripheral nerves in ErbB2-/-R (rescued) animals show defasciculation and desorganization. Nervous phrenicus, that innervates the diaphragm muscle retracts and degenerates entirely at E17 of embryonic development. As a result newborn animals can not breath and die shortly after birth. Surprisingly, the expression and aggregation of AchRs (Acetylcholine Receptors) take place in rescued ErbB2-/-R embryos. The overall phenotype of ErbB2-/-R embryos is very similar to that of ErbB3-/- embryos. This substantiates the essential function of ErbB2 as the functional co-receptor for ErbB3 to transmit the neuregulin signal.

Neurodegeneration

Rezeptor-Tyrosinkinase

ErbB2

ErbB3

Neuregulin

Schwann'sche Zellen

Motoneurone

Sensorische Neurone

Neuromuskuläre Endplatten

Defaszikulierung

Neuralleistenzellen

receptor tyrosin kinase

ErbB2

ErbB3

Neuregulin

Schwann cell

motoneuron

sensory neuron

neuromuscular junction

neurodegeneration

defasiculation neural crest cells

570 Biowissenschaften, Biologie

32 Biologie

WE 5240

ddc:570

Shining new light on motoneurons: characterization of motoneuron dendritic spines using light microscopy and novel analytical methods

McMorland, Angus John Cathcart

January 2009

Dendritic spines are fundamental units of information processing within the nervous system, responsible for independent modulation of synaptic input to neurons. Filopodia, often morphologically indistinguishable from spines, are involved in formation of synapses during neuronal development. Despite the importance of these structures for neuronal function, no detailed study of their presence on motoneurons has yet been made. Here, the presence of spines on hypoglossal motoneurons (HMs) is described at three developmental stages: at P0–2 and P9–11, spines are present at an average density of ~0.1 spines/micron, but at P19 spine density becomes negligible. In P0–2 and P9–11, spines are nonuniformly distributed, occuring in clusters, and at lower density in the most proximal and distal regions to the soma than at intermediate regions. HM spines coincide with a decrease in cell input resistance, which reduces excitability during development. Thus one may speculate that these spines are involved in the formation of new synapses required to maintain adequate excitatory drive. A major difficulty for the study of spines is their small size, which complicates measurement using optical methods. Here, I present a novel method for reconstructing spine morphology using geometric models based on a priori knowledge of spine structure. Tests of the technique using simulated data indicate that it has a resolving capability of up to 40 nm (limited by noise). The technique has been used to measure dendritic spines on HMs, showing that these structures have necks as small as 0.22 micron. For purely passive modulation of synaptic strength, spine necks need to be <~ 0.15 micron. These data suggest that if modulation of synaptic input occurs, biochemical and/or active electrical processes are needed. The methods developed in this Thesis, which have here been applied to HMs, are generally applicable to the study of spine morphology, and its effect on synaptic processing, in all classes of neurons.

neuroscience

microscopy

dendritic spines

high resolution

two-photon

fluorescence

mice

motoneuron

Identification and characterization of molecular mechanisms driving the functional specification of motor neurons The Delta like homolog 1 protein / Molekulare Mechanismen der Motoneuronspezifizierung - Das Delta like homolog 1 Protein

Müller, Daniel

16 March 2011

No description available.

570 Biowissenschaften

Biologie

Motoneuronentwicklung

Motoneuron

ALS

Muskelfasern

funktionelle Motoneurontypen

Rückenmark

spinale Motoneuronen

Motor neuron development

motor neuron

ALS

muscle fiber types

functional motor neurons types

spinal cord

spinal motor neurons

42.13

WF 20

Einfluss des Proteinaggregationshemmstoffs anle138b auf Beginn und Verlauf der Amyotrophen Lateralsklerose im transgenen hSOD1-Mausmodell / Influence of the protein aggregation inhibitor anle138b on the beginning and progression of amyotrophic lateral sclerosis in the transgenic hSOD1 mouse model

Thyssen, Stella

24 June 2014

No description available.

610

Amyotrophe Lateralsklerose

Neurodegenerative Erkrankung

Motoneuron

Familiäre ALS

Sporadische ALS

Superoxiddismutase 1

Proteinaggregation

hSOD1-Mausmodell

Anle 138b

Griffkraft

Rotarod

Laufrad

Amyotrophic lateral sclerosis

Neurodegenerative disease

Motor neuron

Familiar ALS

Sporadic ALS

Superoxiddismutase 1

Protein aggregation

hSOD1 mouse model

Anle 138b

Grip Strength

Rotarod

Running Wheel

GOK-MEDIZIN

GOK-MEDIZIN

Shining new light on motoneurons: characterization of motoneuron dendritic spines using light microscopy and novel analytical methods

McMorland, Angus John Cathcart

January 2009

Dendritic spines are fundamental units of information processing within the nervous system, responsible for independent modulation of synaptic input to neurons. Filopodia, often morphologically indistinguishable from spines, are involved in formation of synapses during neuronal development. Despite the importance of these structures for neuronal function, no detailed study of their presence on motoneurons has yet been made. Here, the presence of spines on hypoglossal motoneurons (HMs) is described at three developmental stages: at P0–2 and P9–11, spines are present at an average density of ~0.1 spines/micron, but at P19 spine density becomes negligible. In P0–2 and P9–11, spines are nonuniformly distributed, occuring in clusters, and at lower density in the most proximal and distal regions to the soma than at intermediate regions. HM spines coincide with a decrease in cell input resistance, which reduces excitability during development. Thus one may speculate that these spines are involved in the formation of new synapses required to maintain adequate excitatory drive. A major difficulty for the study of spines is their small size, which complicates measurement using optical methods. Here, I present a novel method for reconstructing spine morphology using geometric models based on a priori knowledge of spine structure. Tests of the technique using simulated data indicate that it has a resolving capability of up to 40 nm (limited by noise). The technique has been used to measure dendritic spines on HMs, showing that these structures have necks as small as 0.22 micron. For purely passive modulation of synaptic strength, spine necks need to be <~ 0.15 micron. These data suggest that if modulation of synaptic input occurs, biochemical and/or active electrical processes are needed. The methods developed in this Thesis, which have here been applied to HMs, are generally applicable to the study of spine morphology, and its effect on synaptic processing, in all classes of neurons.

neuroscience

microscopy

dendritic spines

high resolution

two-photon

fluorescence

mice

motoneuron

Shining new light on motoneurons: characterization of motoneuron dendritic spines using light microscopy and novel analytical methods

McMorland, Angus John Cathcart

January 2009

Dendritic spines are fundamental units of information processing within the nervous system, responsible for independent modulation of synaptic input to neurons. Filopodia, often morphologically indistinguishable from spines, are involved in formation of synapses during neuronal development. Despite the importance of these structures for neuronal function, no detailed study of their presence on motoneurons has yet been made. Here, the presence of spines on hypoglossal motoneurons (HMs) is described at three developmental stages: at P0–2 and P9–11, spines are present at an average density of ~0.1 spines/micron, but at P19 spine density becomes negligible. In P0–2 and P9–11, spines are nonuniformly distributed, occuring in clusters, and at lower density in the most proximal and distal regions to the soma than at intermediate regions. HM spines coincide with a decrease in cell input resistance, which reduces excitability during development. Thus one may speculate that these spines are involved in the formation of new synapses required to maintain adequate excitatory drive. A major difficulty for the study of spines is their small size, which complicates measurement using optical methods. Here, I present a novel method for reconstructing spine morphology using geometric models based on a priori knowledge of spine structure. Tests of the technique using simulated data indicate that it has a resolving capability of up to 40 nm (limited by noise). The technique has been used to measure dendritic spines on HMs, showing that these structures have necks as small as 0.22 micron. For purely passive modulation of synaptic strength, spine necks need to be <~ 0.15 micron. These data suggest that if modulation of synaptic input occurs, biochemical and/or active electrical processes are needed. The methods developed in this Thesis, which have here been applied to HMs, are generally applicable to the study of spine morphology, and its effect on synaptic processing, in all classes of neurons.

neuroscience

microscopy

dendritic spines

high resolution

two-photon

fluorescence

mice

motoneuron