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Should I stay or should I go? On the importance of aversive memories and the endogenous cannabinoid system

Memory is not a simple box of souvenirs; it is also, and most importantly, a safety system for organisms. With the help of negative memories, known as “aversive” memories, we can avoid a threat that we have already confronted. Researchers from Inserm and University of Bordeaux have just discovered that the cannabinoid receptors of the brain control these memories that are crucial for survival. This study is published in Neuron.Mouse

© Charlie Padgett

When confronted by danger, every individual has to make a crucial choice. This type of “simple” decision may determine his/her destiny: if the fire alarm goes off, we have learned to heed it and flee, and not to ignore it. In the same way, we avoid food and drinks that might have made us sick in the past.

The body is thus equipped with neurological mechanisms that help it to adjust its behaviour in response to a stimulus. Such is the case with aversive memories, a key survival process, which prepares the body to avoid these potential dangers effectively. These memories are accompanied by physiological responses (fright and flight) that enable one to get away from a dangerous situation.

Although the role of the habenula, a central region of the brain, in this phenomenon has received a great deal of attention in recent years, the same is not true of the endogenous cannabinoid system of the habenular neurons, on which Giovanni Marsicano and his team (particularly Edgar Soria-Gomez) have focused. This system involves the type 1 cannabinoid receptors. These receptors, the activity of which is normally regulated by endocannabinoids – the body’s own molecules – are the target of the main psychoactive components of cannabis.

The researchers conditioned mice so that they reacted to certain danger signals (sounds or smells). When they exposed them to these signals, mice that were deficient in cannabinoid receptors in the habenula expressed neither the fear nor the repulsion observed in normal mice. Interestingly, this impaired reaction did not apply to neutral or positive memories, which remained unchanged in these mice.

At molecular level, the scientists observed that, although the functioning of the habenula normally involves two molecules (acetylcholine and glutamate), the defect observed in these mice is caused by an imbalance in neurotransmission involving only acetylcholine.

“These results demonstrate that the endogenous cannabinoid system in the habenula exclusively controls the expression of aversive memories, without influencing neutral or positive memories, and does so by selectively modulating acetylcholine in the neural circuits involved,” explains Giovanni Marsicano, Inserm Research Director.

The control of these particular memories is an integral part of diseases associated with the emotional process, such as depression, anxiety or drug addiction. As a consequence, the endogenous cannabinoid system of the habenula might represent a new therapeutic target in the management of these conditions.

Medias
Researcher Contact
Giovanni Marsicano
Directeur de recherche Inserm
Unité Inserm 862 « Neurocentre Magendie »
+ 33 (0) 5 57 57 37 56
Tvbinaav.znefvpnab@vafrez.se

Edgar Soria-Gomez
Unité Inserm 862 « Neurocentre Magendie »
+ 33 (0) 5 57 56 37 42
rqtne.fbevn@vafrez.se
Press Contact
cerffr@vafrez.se
Sources
Habenular CB1 receptors control the expression of aversive memories Edgar Soria-Gómez1,2, Arnau Busquets-Garcia1,2, Fei Hu3, Amine Mehidi1,2, AstridCannich1,2, Liza Roux1,2, Ines Louit1,2, Lucille Alonso1,2, Theresa Wiesner1,2, FrancoisGeorges2,4, Danièle Verrier1,2, Peggy Vincent1,2, Guillaume Ferreira2,5, Minmin Luo3,Giovanni Marsicano1,2 1INSERM, U862 NeuroCentre Magendie, Bordeaux 33077, France; 2University of Bordeaux, France; 3National Institute of Biological Sciences, Beijing 100875, China; 4CNRS, UMR 5297 Interdisciplinary Institute for Neuroscience, Bordeaux 33077, France; 5INRA, Nutrition et Neurobiologie Intégrée, UMR 1286, Bordeaux 33077, France.
Neuron, 24 septembre 2015
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