The Pasteur Museum is housed in the apartment where Louis Pasteur spent his final seven years and offers a rare behind-the-scenes look at the living and working environment of the world-renowned scientist. Visitors can gain a unique insight into his everyday life alongside his wife and can admire his rich and diverse scientific work.
The Institut Pasteur’s scientific strategy focuses on developing original and innovative topics and promoting interdisciplinary and multidisciplinary cooperation and approaches. The Institut Pasteur teams have access to the technological resources needed to speed up and further improve the quality of their outstanding research.
Ever since the introduction of the world’s first "Technical Microbiology" course in 1889, teaching has been a priority for the Institut Pasteur. The Institut Pasteur has an international reputation for quality teaching that attracts students from all over the world who come to further their training or top up their degree programs.
The mission of the Industrial Partnership team is to detect, promote, assist and protect the inventive activities from research (inventions, know-how and biological materials) conducted at the Institut Pasteur (and in some Institutes of its international network), and transfer there to industrial and/or institutional partners, in order to serve the patient needs and for the benefit of the society, as well as to contribute to sustainability of the Institut Pasteur’s resources.
With international courses, PhD and postdoctoral traineeship, each institute of the Institut Pasteur International Network (RIIP) contributes to the transmission of knowledge with the training of young researchers all around the world. In this context, doctoral and postdoctoral programmes, study and traineeship fellowships are available to scientists. Alongside training, dynamism and attractiveness of RIIP will result in the creation of 4-year group for the young researchers.
Carriers of a genetic mutation show
increased dependence on tobacco
Scientists at the Institut Pasteur, the French National Center for Scientific Research (CNRS) and Pierre and Marie Curie University (UPMC) have recently proven that, in mice, nicotine intake – nicotine is the main addictive substance in tobacco – is heavily regulated by a genetic mutation that is very common in humans. This mutation affects the neuronal nicotinic receptor, disrupting its function and resulting in partial inactivation of the "reward circuit". Carriers of this mutation therefore have to increase their consumption to feel the effects of tobacco. These results, published online on December 3, 2013 in Molecular Psychiatry, pave the way for the development of new smoking cessation treatments that target carriers of this mutation.
Paris, December 12, 2013
During tobacco consumption, nicotine binds to nicotinic receptors, thus activating the "reward circuit", a neuronal system responsible for a number of responses – including a feeling of well-being – during normal function. The effect of nicotine on the brain compensates for withdrawal symptoms felt by smokers when they are deprived of tobacco. As a result, a person's tobacco consumption is closely linked to the sensitivity of these nicotinic receptors.
The teams led by Uwe Maskos, who heads the Integrative Neurobiology of Cholinergic Systems Unit at the Institut Pasteur / CNRS, and by CNRS scientist Philippe Faure, who manages the Neurobiology of Adaptive Processes laboratory (CNRS / UPMC), have recently made a discovery proving that nicotine addiction may be influenced by an individual's genetic heritage. These scientists show that, in mice, a genetic mutation resulted in a marked reduction in sensitivity to nicotine. Carriers of this gene therefore require a higher dose of tobacco than non-carriers in order to obtain the same amount of pleasure - somewhere on the order of three times more.
The mutation characterized by the scientists affects part of the nicotinic receptor. The presence of this mutation disrupts the normal function of the nicotinic receptor, partially inactivating the "reward circuit".
This mutation occurs frequently in humans. Other studies suggest that it is present in 35% of Europeans, and in nearly 90% of heavy smokers.
These discoveries pave the way for the development of "personalized" smoking cessation treatments for individuals who carry this genetic mutation.
The genetic mutation in humans that regulates nicotine dependence is expressed here in mice that have undergone modifications to a specific region of the cortex (in green). Cell nuclei in blue. Confocal laser scanning microscopy.
Nicotine consumption is regulated by a human polymorphism in dopamine neurons, Molecular Psychiatry, December 3, 2013.
C Morel (1,9), L Fattore (2,9), S Pons (3), YA Hay (4), F Marti (1), B Lambolez (4), M De Biasi (5), M Lathrop (6,7), W Fratta (8), U Maskos (3,9) and P Faure (1,9)
(1) Neurobiologie des Processus Adaptatifs, CNRS UMR 7102, Equipe Neurophysiologie et comportement (NPC), Université P. et M. Curie, Paris, France
(2) CNR Neuroscience Institute, Cagliari, National Research Council, Italy, Cittadella Universitaria, Monserrato, Italy
(3) Institut Pasteur, Unité Neurobiologie intégrative des systèmes cholinergiques, CNRSUMR 3571, Paris, France
(4) Université P. et M. Curie, CNRS UMR 7102, Neurobiologie des Processus Adaptatifs, Equipe Réseau cortical et couplage neurovasculaire, Paris, France
(5) Department of Psychiatry, Perelman School of Medicine at the University of Pennsylvania, Philadelphia, PA, USA
(6) McGill University and Genome Quebec Innovation Centre,Montréal, QC, Canada
(7) Fondation Jean Dausset, CEPH, Paris, France
(8) Department of Biomedical Sciences, University of Cagliari Cittadella Universitaria, Monserrato, Italy.
(9) These authors contributed equally to this work.