Your search keyword '"Gratton, Alain"' showing total 5 results

1. Interhemispheric regulation of the rat medial prefrontal cortical glutamate stress response: role of local GABA- and dopamine-sensitive mechanisms.

Author

Lupinsky, Derek, Moquin, Luc, and Gratton, Alain

Subjects

PHYSIOLOGICAL effects of glutamic acid, PHYSIOLOGICAL effects of dopamine, PSYCHOLOGICAL stress, PREFRONTAL cortex, NEURAL physiology, GABA agents, LABORATORY rats

Abstract

Rationale: We previously reported that stressors increase medial prefrontal cortex (PFC) glutamate (GLU) levels as a result of activating callosal neurons located in the opposite hemisphere and that this PFC GLU stress response is regulated by GLU-, dopamine- (DA-), and GABA-sensitive mechanisms (Lupinsky et al. 2010). Objectives: Here, we examine the possibility that PFC DA regulates the stress responsivity of callosal neurons indirectly by acting at D and D receptors located on GABA interneurons. Methods: Microdialysis combined with drug perfusion (reverse dialysis) or microinjections was used in adult male Long-Evans rats to characterize D, D, and GABA receptor-mediated regulation of the PFC GABA response to tail-pinch (TP) stress. Results: We report that TP stress reliably elicited comparable increases in extracellular GABA in the left and right PFCs. SCH23390 (D antagonist; 100 μM perfusate concentration) perfused by reverse microdialysis attenuated the local GABA stress responses equally in the left and right PFCs. Intra-PFC raclopride perfusion (D antagonist; 100 μM) had the opposite effect, not only potentiating the local GABA stress response but also causing a transient elevation in basal (pre-stress) GABA. Moreover, unilateral PFC raclopride microinjection (6 nmol) attenuated the GLU response to TP stress in the contralateral PFC. Finally, intra-PFC baclofen perfusion (GABA agonist; 100 μM) inhibited the local GLU and GABA stress responses. Conclusions: Taken together, these findings implicate PFC GABA interneurons in processing stressful stimuli, showing that local D, D, and GABA receptor-mediated changes in PFC GABA transmission play a crucial role in the interhemispheric regulation of GLU stress responsivity. [ABSTRACT FROM AUTHOR]

Published

2017

2. Chronic stress alters the dendritic morphology of callosal neurons and the acute glutamate stress response in the rat medial prefrontal cortex.

Author

Luczynski, Pauline, Moquin, Luc, and Gratton, Alain

Subjects

PREFRONTAL cortex, DENDRITIC spines, GLUTAMIC acid, PHYSIOLOGICAL stress, NEUROPLASTICITY, LABORATORY rats, PHYSIOLOGY

Abstract

We have previously reported that interhemispheric regulation of medial prefrontal cortex (PFC)-mediated stress responses is subserved by glutamate (GLU)- containing callosal neurons. Evidence of chronic stress-induced dendritic and spine atrophy among PFC pyramidal neurons led us to examine how chronic restraint stress (CRS) might alter the apical dendritic morphology of callosal neurons and the acute GLU stress responses in the left versus right PFC. Morphometric analyses of retrogradely labeled, dye-filled PFC callosal neurons revealed hemisphere-specific CRS-induced dendritic retraction; whereas significant dendritic atrophy occurred primarily within the distal arbor of left PFC neurons, it was observed within both the proximal and distal arbor of right PFC neurons. Overall, CRS also significantly reduced spine densities in both hemispheres with the greatest loss occurring among left PFC neurons, mostly at the distal extent of the arbor. While much of the overall decrease in dendritic spine density was accounted by the loss of thin spines, the density of mushroom-shaped spines, despite being fewer in number, was halved. Using microdialysis we found that, compared to controls, basal PFC GLU levels were significantly reduced in both hemispheres of CRS animals and that their GLU response to 30 min of tail-pinch stress was significantly prolonged in the left, but not the right PFC. Together, these findings show that a history of chronic stress alters the dendritic morphology and spine density of PFC callosal neurons and suggest a mechanism by which this might disrupt the interhemispheric regulation of PFC-mediated responses to subsequent stressors. [ABSTRACT FROM PUBLISHER]

Published

2015

3. Imaging in vivo glutamate fluctuations with [11C]ABP688: a GLT-1 challenge with ceftriaxone.

Author

R Zimmer, Eduardo, Parent, Maxime J, Leuzy, Antoine, Aliaga, Antonio, Aliaga, Arturo, Moquin, Luc, S Schirrmacher, Esther, Soucy, Jean-Paul, Skelin, Ivan, Gratton, Alain, Gauthier, Serge, and Rosa-Neto, Pedro

Subjects

GLUTAMATE receptors, CEFTRIAXONE, BRAIN imaging, POSITRON emission tomography, MICRODIALYSIS, BINDING sites, NEUROBEHAVIORAL disorders, LABORATORY rats

Abstract

Molecular imaging offers unprecedented opportunities for investigating dynamic changes underlying neuropsychiatric conditions. Here, we evaluated whether [11C]ABP688, a positron emission tomography (PET) ligand that binds to the allosteric site of the metabotropic glutamate receptor type 5 (mGluR5), is sensitive to glutamate fluctuations after a pharmacological challenge. For this, we used ceftriaxone (CEF) administration in rats, an activator of the GLT-1 transporter (EAAT2), which is known to decrease extracellular levels of glutamate. MicroPET [11C]ABP688 dynamic acquisitions were conducted in rats after a venous injection of either saline (baseline) or CEF 200 mg/kg (challenge). Binding potentials (BPND) were obtained using the simplified reference tissue method. Between-condition statistical parametric maps indicating brain regions showing the highest CEF effects guided placement of microdialysis probes for subsequent assessment of extracellular levels of glutamate. The CEF administration increased [11C]ABP688 BPND in the thalamic ventral anterior (VA) nucleus bilaterally. Subsequent microdialysis assessment revealed declines in extracellular glutamate concentrations in the VA. The present results support the concept that availability of mGluR5 allosteric binding sites is sensitive to extracellular concentrations of glutamate. This interesting property of mGluR5 allosteric binding sites has potential applications for assessing the role of glutamate in the pathogenesis of neuropsychiatric conditions. [ABSTRACT FROM AUTHOR]

Published

2015

4. Interhemispheric Regulation of the Medial Prefrontal Cortical Glutamate Stress Response in Rats.

Author

Lupinsky, Derek, Moquin, Luc, and Gratton, Alain

Subjects

PREFRONTAL cortex, PHYSIOLOGICAL stress, MICRODIALYSIS, PHARMACODYNAMICS, LABORATORY rats

Abstract

While stressors are known to increase medial prefrontal cortex (PFC) glutamate (GLU) levels, the mechanism(s) subserving this response remain to be elucidated. We used microdialysis and local drug applications to investigate, in male Long-Evans rats, whether the PFCGLU stress response might reflect increased interhemispheric communication by callosal projection neurons. We report here that tail-pinch stress (20 min) elicited comparable increases in GLU in the left and right PFC that were sodium and calcium dependent and insensitive to local glial cystine-GLU exchanger blockade. Unilateral ibotenate-induced PFC lesions abolished the GLU stress response in the opposite hemisphere, as did contralateral mGlu2/3 receptor activation. Local dopamine (DA) D1 receptor blockade in the left PFC potently enhanced the right PFC GLU stress response, whereas the same treatment applied to the right PFC had a much weaker effect on the left PFC GLU response. Finally, the PFC GLU stress response was attenuated and potentiated, respectively, following α1-adrenoreceptor blockade and GABAB receptor activation in the opposite hemisphere. These findings indicate that the PFC GLU stress response reflects, at least in part, activation of callosal neurons located in the opposite hemisphere and that stress-induced activation of these neurons is regulated by GLU-, DA-, norepinephrine-, and GABA-sensitive mechanisms. In the case of DA, this control is asymmetrical, with a marked regulatory bias of the left PFC DA input over the right PFC GLU stress response. Together, these findings suggest that callosal neurons and their afferentation play an important role in the hemispheric specialization of PFC-mediated responses to stressors. [ABSTRACT FROM AUTHOR]

Published

2010

5. Uninterrupted in vivo cerebral microdialysis measures of the acute neurochemical response to a single or repeated concussion in a rat model combining force and rotation.

Author

Massé, Ian, Moquin, Luc, Bouchard, Caroline, Gratton, Alain, and De Beaumont, Louis

Subjects

*LABORATORY rats, *BRAIN injuries, *BRAIN concussion, *MICRODIALYSIS, *GLUTAMINE, *ANIMAL disease models

Abstract

[Display omitted] • Unveils acute neurochemical changes in concussions using microdialysis in rats. • Demonstrates significant glutamate and taurine increase after a single concussion. • Reveals less neurochemical changes, aggravated symptoms after repeated concussions. • Introduces a novel rat model combining force and rotation for concussion studies. • Suggests new insights into neurochemical dynamics after traumatic brain injuries. Altered extracellular amino acid concentrations following concussion or mild traumatic brain injury can result in delayed neuronal damage through overactivation of NMDA glutamatergic receptors. However, the consequences of repeated concussions prior to complete recovery are not well understood. In this study, we utilized in vivo cerebral microdialysis and a weight-drop model to investigate the acute neurochemical response to single and repeated concussions in adult rats that were fully conscious. A microdialysis probe was inserted into the hippocampus and remained in place during impact. Primary outcomes included concentrations of glutamate, GABA, taurine, glycine, glutamine, and serine, while secondary outcomes were righting times and excitotoxic indices. Compared to sham injury, the first concussion resulted in significant increases in glutamate, GABA, taurine, and glycine levels, longer righting times, and higher excitotoxic indices. Following the second concussion, righting times were significantly longer, suggesting cumulative effects of repeated concussion while only partial increases were observed in glutamate and taurine levels. GABA and glycine levels, and excitotoxic indices were comparable to sham injury. These findings suggest that single and repeated concussions may induce acute increases in several amino acids, while repeated concussions could exacerbate neurological symptoms despite less pronounced neurochemical changes. [ABSTRACT FROM AUTHOR]

Published

2024