The effect of enriched environment on gene expression and stroke recovery

Rönnbäck, Annica

January 2004

<p>Stroke is the third leading cause of death and the major course of long-term disabilities in industrialized countries. Most surviving stroke patients show some degree of spontaneous recovery, but persistent symptoms in sensorimotor and cognitive functions are common. The symptoms can be reproduced in experimental stroke models in rats by occlusion of the middle cerebral artery. Housing rats in an enriched environment (EE), i.e. group housing in a large cage with toys that are changed daily, increases neuronal plasticity in healthy rats and can also improve functional recovery after experimental stroke. </p><p> The present thesis investigates the effect of EE on the recovery of sensorimotor and cognitive functions one month after focal cerebral ischemia in rats, with emphasis on the underlying molecular mechanisms. Furthermore, EE-induced effect on gene expression in healthy rats was investigated after different periods of EE-housing and at different time points of the day. </p><p> We show an improved recovery of both sensorimotor and cognitive functions in rats housed in EE for one month after focal cerebral ischemia. The recovery of sensorimotor function correlated significantly to mRNA expression of the plasticity associated transcription factors NGFI-A and NGFI-B in hippocampus and cortical regions outside the infarct. Social interaction seems to be an important component for the beneficial effects of EE after focal cerebral ischemia. Microarray analysis of hippocampal gene expression after one month of postischemic environmental enrichment revealed no confirmable EE-induced changes that could explain the improved recovery in spatial memory. Interestingly, healthy rats housed in EE showed increased mRNA expression of NGFI-A and Krox-20 exclusively during the dark period of the day compared to rats housed in isolation. In addition, EE housed rats had a substantial diurnal variation in NGFI-A, Krox-20 and NGFI-B mRNA expression; this was absent in single-housed rats. EE-induced changes in gene expression are more evident during the dark period of the day, when rats are more active and can benefit from the stimulating environment. This is important to consider in future investigation of putative mediators of the EE-induced neuronal plasticity. </p><p> In summary, these findings may contribute to an increased understanding of the underlying molecular mechanisms behind improved functional recovery in rats housed in enriched environment after focal cerebral ischemia.</p>

Medicine

experimental stroke

recovery

memory

inducible transcription factors

Medicin

The effect of enriched environment on gene expression and stroke recovery

Rönnbäck, Annica

January 2004

Stroke is the third leading cause of death and the major course of long-term disabilities in industrialized countries. Most surviving stroke patients show some degree of spontaneous recovery, but persistent symptoms in sensorimotor and cognitive functions are common. The symptoms can be reproduced in experimental stroke models in rats by occlusion of the middle cerebral artery. Housing rats in an enriched environment (EE), i.e. group housing in a large cage with toys that are changed daily, increases neuronal plasticity in healthy rats and can also improve functional recovery after experimental stroke. The present thesis investigates the effect of EE on the recovery of sensorimotor and cognitive functions one month after focal cerebral ischemia in rats, with emphasis on the underlying molecular mechanisms. Furthermore, EE-induced effect on gene expression in healthy rats was investigated after different periods of EE-housing and at different time points of the day. We show an improved recovery of both sensorimotor and cognitive functions in rats housed in EE for one month after focal cerebral ischemia. The recovery of sensorimotor function correlated significantly to mRNA expression of the plasticity associated transcription factors NGFI-A and NGFI-B in hippocampus and cortical regions outside the infarct. Social interaction seems to be an important component for the beneficial effects of EE after focal cerebral ischemia. Microarray analysis of hippocampal gene expression after one month of postischemic environmental enrichment revealed no confirmable EE-induced changes that could explain the improved recovery in spatial memory. Interestingly, healthy rats housed in EE showed increased mRNA expression of NGFI-A and Krox-20 exclusively during the dark period of the day compared to rats housed in isolation. In addition, EE housed rats had a substantial diurnal variation in NGFI-A, Krox-20 and NGFI-B mRNA expression; this was absent in single-housed rats. EE-induced changes in gene expression are more evident during the dark period of the day, when rats are more active and can benefit from the stimulating environment. This is important to consider in future investigation of putative mediators of the EE-induced neuronal plasticity. In summary, these findings may contribute to an increased understanding of the underlying molecular mechanisms behind improved functional recovery in rats housed in enriched environment after focal cerebral ischemia.

Medicine

experimental stroke

recovery

memory

inducible transcription factors

Medicin

Influence de la microglie et du BDNF sur l'induction de la neuroplasticité après un accident vasculaire cérébral ischémique / Microglial and BDNF impact on the induction of the post ischemic neuroplasticity

Madinier, Alexandre

30 September 2011

L’émergence de la notion selon laquelle la réponse inflammatoire exercerait des effets bénéfiques dans la pathologie ischémique cérébrale, en particulier au cours de la phase de récupération fonctionnelle nous a conduit à étudier l’implication des cellules microgliales dans le déclenchement des mécanismes de neuroplasticité post-ischémique. Notre étude a été réalisée chez le Rat soumis à une ischémie focale permanente induite par photothrombose. L’activation microgliale a été modulée par un traitement au 3-aminobenzamide (3-AB), un inhibiteur spécifique de la poly(ADP-ribose)polymérase-1, jouant un rôle prépondérant dans l’activation de ces cellules. Nos données montrent que le 3-AB entraîne une diminution importante de l’activation microgliale aux temps courts associée à plus long terme à une réduction de l’expression de la synaptophysine et de GAP-43, respectivement marqueurs des processus de synaptogenèse et croissance axonale. L’ensemble de ces données indique donc que les cellules microgliales constituent effectivement des acteurs cellulaires essentiels de la neuroplasticité post-ischémique. Le Brain-derived neurotrophic factor (BDNF) se révélant un candidat potentiellement capable de promouvoir de tels changements, nous avons pu mettre en évidence que ces cellules représentaient de façon précoce une source importante de BDNF. Ces résultats ont été confirmés par la nette diminution des taux de BDNF mesurés dans les zones corticales lésionnelles et péri-lésionnelles des animaux traités par le 3-AB. Dans un deuxième temps, le métabolisme complexe de cette neurotrophine à travers l’existence de deux formes, pro- et mature, aux effets biologiques opposés, nous a conduit à réaliser une étude spatio-temporelle des expressions post-ischémiques du BDNF total (ELISA), pro- et mature (Western blotting). Aux temps courts (4-24 h), les expressions du BDNF total, pro- et mature sont augmentées dans les territoires corticaux lésés, péri-lésionnels et homotopiques tandis qu’aux temps longs (8-30 j), le BDNF total reste accru dans les régions distantes de la zone infarcie (hippocampes et cortex contralatéral). Concernant les expressions des formes pro- et mature, nos résultats indiquent une augmentation entre 8 et 30 j uniquement dans les territoires hippocampiques. D’un point de vue cellulaire, le BDNF est exprimé du côté ipsilatéral dans les neurones et les cellules non neuronales tandis que du côté contralatéral, l’expression est limitée aux neurones. Nos résultats tout en faisant apparaître des divergences importantes dans les variations d’expressions du BDNF total (ELISA) et des différentes formes (Western blotting) indiquent que la mesure du BDNF total doit être couplée à une étude permettant de discriminer les deux formes. De plus, tout en confirmant l’implication de cette neurotrophine dans les mécanismes adaptatifs induits en réponse à une ischémie cérébrale, ces données suggèrent que les territoires distants de la zone lésée jouent un rôle majeur dans ces processus. / Evidences showing that under certain circumstances, inflammatory response could be neuroprotective and could also promote adult neurogenesis are growing. In this context, the objective of this work was to investigate the impact of microglial cells in the neuroplastic events. Rats were subjected to photothrombotic ischemia and microglial cells activation was blocked by the mean of poly(ADP-ribose)polymérase-1 (PARP-1) inhibition using 3- aminobenzamide (3-AB) since this protein has been shown to play a major role in this activation. Our results show that PARP-1 activity reduction was associated with a strong repression of the acute microglial activation. Beside, 3-AB treated animals exhibited a decrease in synaptophysin (synaptogenesis) and GAP-43 (axonal growth) expressions. Taken together, our data argue for a supportive role of microglial in adaptive brain plasticity events. According to the preponderant contribution of BDNF in these events, assessment of its cellular localization was performed, and confirmed that these cells represent a significant source. Beside, BDNF immunoreactivity (IR) in microglial cells and BDNF levels in the lesioned and surrounding lesioned areas were found decreased in 3-AB treated animals. However, since this neurotrophin can exert ambivalent biological actions through pro- versus mature forms, we investigate the proper effect of cerebral ischemia on total (Elisa), pro- and mature (Western blotting) expressions. Our results show that total, pro- and mature BDNF expressions are augmented in the early times (4-24h) of ischemia within the lesioned, the surrounding non lesioned and the contralateral cortical areas. At longer time points, total BDNF was still increased at 8d in regions distant from the lesion (hippocampi and contralateral cortex) while pro- and mature forms rise between 8d to 30d in hippocampic territories only. In term of cellular distribution, BDNF-IR was found in neurons but also in non neuronal cells ipsilaterally whereas in the opposite side BDNF staining was restricted to neurons. Our data while raising the question of the pertinence of total BDNF expression in a context of studying its supportive potential action indicate that such assessment has to be coupled with the discrimination of both forms. In addition, our data confirm the important role of BDNF in post-stroke adaptive mechanisms and argue in favour of an important contribution of the hippocampal territory and of the contralateral hemisphere in BDNF related post-stroke neuronal circuit remodelling suggesting that strategies targeting this hemisphere are likely to mediate functional compensation.

AVC expérimental

Microglie

Inflammation

BDNF

Neuroplasticité

Synaptogenèse

Croissance axonale

Experimental stroke

Microglia

Inflammation

BDNF

Neuroplasticity

Synaptogenesis

Axonal growth

573

616.8

Therapeutisches Potenzial und Langzeiteffekt der TLR4-Inhibition bei der fokalen zerebralen Ischämie / Therapeutic potential and long term effect of TLR4 inhibition in focal cerebral ischemia

Andresen, Lena

11 May 2016

No description available.

610

Schlaganfall

fokale zerebrale Ischämie

experimenteller Schlaganfall

MCAO

TLR4

Neuroprotektion

stroke

experimental stroke

focal cerebral ischemia

MCAO

TLR4

neuroprotection

Medizin (PPN619874732)