Scientists identify key gene associated with addiction
A new study published in the journal Molecular Psychiatry by听a team led by Salah El Mestikawy, Ph.D., researcher at the Douglas Mental Health University Institute (CIUSSS de l鈥橭uest-de-l鈥櫭甽e-de-Montr茅al), professor at 平特五不中 and head of research at CNRS INSERM UPMC in Paris, opens the field to new understanding of the molecular mechanism underlying addiction in humans.
This work was accomplished through collaboration with several international research teams. Among these researchers was St茅phane Jamain (CR1 INSERM, Universit茅 de Cr茅teil, France), a French geneticist specializied in psychiatric disorders.
Communication is key
To communicate with each other, brain cells (neurons) use chemicals known as neurotransmitters. Among the classical neurotransmitters are dopamine, serotonin, acetylcholine and glutamate. Until recently, it was believed that a given neuron used only one classical neurotransmitter. Some time ago, El Mestikawy鈥檚 team contributed to the surprising discovery that subpopulations of neurons are able to use two transmitters. Unlike the vast majority of neurons, these neurons are bilingual. Most neurons in the brain respond with either 鈥測es鈥, 鈥渘o鈥 or 鈥渕aybe鈥. El Mestikawy and his colleagues found that in order to regulate our reward behaviours, a small population of neurons in our reward centre are able to respond with both 鈥測es鈥 and 鈥渘o鈥. These neurons are known as cholinergic neurons, while the reward centre is known as the nucleus accumbens.
In this new work, the researchers discovered that when they shut down one of the languages (the 鈥渘o鈥) of cholinergic neurons within the reward centre, mice showed a marked predilection for cocaine. This work explains the molecular mechanism underlying reward behaviour, while identifying an unsuspected target in the treatment of addiction.
Finally, the team found that humans with mutation of a key gene for this co-transmission were 10 times more vulnerable to very severe forms of addiction. 鈥淭hese discoveries are bringing about a major transformation in the field of addiction. We are beginning to decipher and understand the complex regulation of basic behaviours鈥 says El Mestikawy.
This work was funded by Brain Canada and ERANET Neuron.
To see the complete study: The absence of VGLUT3 predisposes to cocaine abuse by increasing dopamine and glutamate signaling in the nucleus accumbens/
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