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!!Academia Europaea\\The Academy of Europe

__The Academia Europaea are pleased to award an Erasmus Medal to the internationally renowned Neuroscientist
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!![Professor Jean-Pierre Changeux|Member/Changeux_Jean-Pierre] MAE

__''The Erasmus Medal of the Academia Europaea, is awarded to a European scholar who has maintained over a sustained period of time an outstanding level of international scholarship as recognised by peers. It is perhaps the highest recognition for purely scholarly achievements that the Academy can bestow on a scholar. The Medal is awarded at the Annual Conference of the Academy and on that occasion the recipient will give the Annual Erasmus Lecture.''__
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__Professor Changeux__  will receive the medal and will deliver the accompanying Academia Europaea - Heinz-Nixdorf Erasmus Lecture at the annual conference of the __Academia Europaea__, Munich, on October 9 - 11, 2023.
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[{Image src='Changeux_Jean_Pierre.jpg' caption='Professor Jean-Pierre Changeux MAE' height='220' alt='Jean-Pierre Changeux' align='center'}] 

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!!TITLE OF THE 2023 HEINZ-NIXDORF LECTURE
!!“The brain as a chemical machine: importance of allosteric receptors”
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__ABSTRACT:__ The human brain, the most complex organ of the body, cannot be simply regarded as an electrical machine or a mechanical computer. Understanding the chemistry of the brain is a prerequisite for the understanding if its basic functions - from the intercellular communications up to the higher cognitive level - together with their pathological alterations. The billions of neurons in the brain make ''discontinuous'' networks that are bound together by chemical signals: the neurotransmitters. There are over a hundred of neurotransmitters that mediate information processing in the brain, and thus, all the operations it performs. The discovery of the molecules and molecular mechanisms involved in the signal transduction elicited by neurotransmitters has thus created a “paradigmatic change” in the history of brain sciences leading to considerable progress in the understanding of drugs action in the brain, their possible side effects and among them drug addiction with its known devastating consequences at the social level, and, most of all, their potential therapeutic action. 
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At the early stages, a critical role was played by the concept of allostery to qualify the interaction between topographically distinct sites on regulatory proteins - ie an active site and a regulatory site - and its mediation by a conformational change of the molecule (1961). Through their cooperative organisation, allosteric proteins would behave as “molecular switches” (1965). Early on the concept was extended to brain communications and the receptors for neurotransmitters (1964,1967). Then, the first neurotransmitter receptor was identified (1970): the nicotinic acetylcholine receptor. It was soon demonstrated to be a bona fide allosteric protein carrying several binding sites for the neurotransmitter acetylcholine, an ion channel, together with multiple allosteric ''modulatory sites''.  The elucidation, today at the atomic level, of the allosteric mechanism through which drugs modulate receptor efficacy opens revolutionary new avenues in the field of drug discovery.  \\
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Moreover, the multiple regulations to which acetylcholine receptors have access – together with thousands of subsequently discovered receptors in the brain – further extends the “paradigmatic change” to neuronal brain circuits in general, to their contribution to the short and long-term synaptic changes (ie those engaged in learning and memory), up to higher cognitive functions and - last but not least – to conscious processing. The consequences in the understanding neuropsychiatric diseases and their therapeutics are immense.
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!Erasmus Medal Citation

Jean-Pierre Changeux has been the leader in the field of receptor research and neuroscience for the past half a century. His thorough dissection of the nicotinic acetylcholine receptors is a landmark in modern biology. The extension of the allosteric theory to membrane proteins provided a mechanistic explanation for the process of signal transduction by ligands. It has vast implications in several fields of biology, including receptor biology, cellular communications, drug design and development, and neuroscience. Due to his pioneering and seminal activities, Changeux is one of the key founders of modern molecular pharmacology and neuroscience.
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As a graduate student in the laboratories of Nobel Laureates Jacques Monod and François Jacob, Changeux’s studies provided a fundamental mechanism of protein regulation, the allostery model,  with a profound impact on the biology of living organisms. He further proposed that allosteric regulation in membrane receptors plays a key role in the transmission of chemical signals in the nervous system. He hypothesized that the acetylcholine receptor could be envisioned as a membrane macromolecule in which the acetylcholine binding site regulates by an allosteric conformational change, the gating of an ion channel. His subsequent career strategically and comprehensively validated this pioneering insight, resulting in a series of important discoveries.
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Changeux’s seminal work on the nicotinic receptor forged new fields of research in signal transduction mechanisms, molecular pharmacology, and pathological modifications of chemical communications in the nervous system, including the subsequent molecular identification of brain ionotropic glutamate and GABA receptors. Following Changeux’s pioneering work, the notion that receptor activity is controlled by allosteric mechanisms has been extended to G protein-coupled receptors and growth-factor receptors. It is now well-established that ligand binding triggers an allosteric transition that activate or inhibit the G proteins or activate receptor tyrosine kinases.
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Subsequently, Changeux used his knowledge of the nicotinic receptors to investigate higher levels of brain organization, in particular the way these receptors participate in reward and cognition. Moving from the molecules and the isolated neurons or muscle cells to the development of neuronal networks, Jean-Pierre Changeux made an outreaching contribution by proposing the theory that long-term epigenesis of neuronal networks occurs by the selective stabilization and elimination of developing synapses. In parallel, he proposed, with his collaborators, theoretical models for defined cognitive tasks that bridge the gap between molecular biology and cognitive science. In these models, allosteric receptors play a key role in the regulation of synaptic efficacy. Changeux and his colleagues further proposed an original hypothesis describing a neuronal mechanism for conscious access, implicating a “global neuronal workspace” composed of a brain-scale horizontal network of reciprocally connected long axon pyramidal neurons.
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Finally, throughout his career, Jean-Pierre Changeux has been concerned by the ethical consequences of neuroscience for medicine and for society in general. He has written a number of books, including the iconic “L’homme neuronal”, which not only reveals his status as a leading contemporary figure in neuroscience but also one of the leading thinkers of our times and a worthy contemporary heir of the French Encyclopaedists of the 18th century. 
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Based on his distinguished scientific achievements, his contributions to European  scientific culture and his commitment to __Academia Europaea__ as one of its founding members (membership number: 63), __Academia Europaea__ is pleased and honoured to award the __2022 Academia Europaea Erasmus Medal__ to Professor Jean-Pierre Changeux.

!General biography

[Jean-Pierre Changeux MAE|Member/Changeux_Jean-Pierre]\\
[https://research.pasteur.fr/en/member/jean-pierre-changeux]
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!Short synopsis

Professor Changeux was elected to the Academia Europaea in 1988 and is one of the founder members.
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__1) Academic training__
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Ecole Normale Supérieure (rue d'Ulm, Paris) (1955) and Licence de Sciences Naturelles (1956, 1957) at Paris University. Diplôme d'Etudes Supérieures (Mention Très Bien et Félicitations du Jury) (1958). Agrégé des Sciences Naturelles (received first) (1958). Doctorat d'Etat de Sciences Naturelles, Paris (Mention Très Honorable et Félicitations du Jury), under the supervision of Pr. Jacques Monod, Institut Pasteur (1964).
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__2) Academic positions__
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Agrégé-préparateur of Zoology, Ecole Normale Supérieure, 1958 ; Postdoctoral fellow, [University of California|https://www.berkeley.edu], Berkeley, 1965-1966 (with J Gerhart & H Schachman); visiting Assistant Professor [Columbia University College of Physicians & Surgeons|https://www.vagelos.columbia.edu], New-York (with D Nachmansohn), 1966-1967; Sous-Directeur, [Collège de France|https://www.college-de-france.fr], Paris (Chaire de Biologie Moléculaire), 1967; Director of the Unit of Molecular Neurobiology, [Institut Pasteur|https://www.pasteur.fr/en], Paris, 1972-2006; Professor [Collège de France|https://www.college-de-france.fr], 1975-2006; Professor [Institut Pasteur|https://www.pasteur.fr/en], 1975-2006, emeritus since 2007; Skaggs distinguished visiting professor in Pharmacology, [University of California San Diego|https://ucsd.edu] 2008-2012 (with P Taylor); International Faculty, [Kavli Institute for Brain & Mind|https://kibm.ucsd.edu], [University of California San Diego|https://ucsd.edu] 2012-2022 (with R Greenspan).
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__3) Scientific prizes and awards__
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Gairdner Foundation International Award, "In recognition of his pioneering work in purifying and elucidating the mechanisms of the cholinergic receptor." Toronto, Canada, 1978.\\
Richard Lounsbery Prize, National Academy of Sciences, Washington (USA) and Académie des Sciences, Paris, 1983.\\
Wolf Foundation Prize in Medicine, for “the isolation, purification and characterization of the acetylcholine receptor”. Jerusalem, Israel, 1982.\\
Prix Broquette-Gonin, Académie Française, for “l'Homme Neuronal", 1983 (nomination by Claude Levi-Strauss).\\
F.O. Schmitt medal and prize, Neuroscience Research Program, Rockefeller University, New York, 1986.\\
Rita Levi-Montalcini Award, Fidia Research Foundation, Washington, 1988.\\
Bristol-Myers-Squibb Award in Neuroscience, New York, 1990.\\
Carl-Gustaf Bernhard medal, Swedish Royal Academy of Sciences, Stockholm, 1991.\\
Science for Art, Prix d'Honneur LVMH, Paris, 1992.\\
Médaille d'Or, Centre National de la Recherche Scientifique, Paris, 1992.\\
Louis Jeantet Prize for Medicine, for “his work in structural biology”, Geneva, 1993.\\
Thudichum medal, Biochemical Society, London 1993.\\
Goodman and Gilman Award in drug receptor pharmacology, American Society for Pharmacology\\
and Experimental Therapeutics, Anaheim, California, 1994.\\
Camillo Golgi medal, Accademia Nazionale dei Lincei, Rome 1994.\\
Sir Hans Krebs medal, FEBS, Helsinki, 1994; Max-Delbrück medal, in Molecular Medicine, Berlin, 1996.\\
Grand Prix de la Fondation pour la Recherche Médicale, Paris, 1997; Linus Pauling medal, 1998/1999, Stanford, USA.\\
Eli Lilly award in preclinical Neuroscience, European College of Neuropsychopharmacology, London, 1999.\\
Balzan Prize for Cognitive Neuroscience, for “establishing a new direction for the study of cognitive functions by rooting them at the molecular level”. Berne, 2001.\\
American Philosophical Society’s Karl Spencer Lashley Award in neuroscience, “In recognition of his pioneering, comprehensive studies into the fundamental molecular mechanisms underlying interneuronal communication and their role in network formation, learning, and reward” Philadelphia, 2002.\\
Lewis Thomas Prize for Writing about Science, Rockefeller University, New-York, 2005.\\
Golden Eurydice Award from International Forum of Biophilosophy, Bruxelles, 2006.\\
National Academy of Sciences Award in the Neurosciences USA, for “his seminal discoveries elucidating cellular and molecular bases for synaptic plasticity in the brain”, Washington, 2007.\\
Neuronal plasticity prize, IPSEN Foundation, Geneva, 2008.\\
Japanese Society for the Promotion of Science Award for Eminent Scientists,Tokyo, 2012.\\
Italian Society for Neuroethics Award Medal, Padova, 2015.\\
The Olav Thon international research award in biomedicine, to “''honour a researcher who has connected a deep understanding of molecules and their regulation to new insights into the functions and diseases of the brain''”. Oslo, Norway, 2016.\\
Albert Einstein World Award of Science, for "exceptional scientific achievements and leadership in the field of neuroscience and especially for his pioneering contributions to the science and understanding of neuroreceptors for the past 50 years". Hong Kong, 2018.\\
Goldman-Rakic Prize for “Outstanding Achievements in Cognitive Neuroscience”, New-York, & Yale 2018.\\
Elevated Lead scientist of the Human Brain program SGA3, Brussels-Lausanne 2020.\\
Clarivate citation laureate in Physiology or medicine 2021, London.\\
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__Number of papers:__ 675\\
__Sum of the Times Cited:__ 108 925\\
__h-index:__ 164
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__DOCUMENTS:__
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*[Erasmus lecture 2023|Erasmus lecture 2023 (Changeux) document.pdf]
*[Erasmus medal 2022|Erasmus medal 2022 - Jean-Pierre Changeux.pdf]
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!Press enquiries to The Executive Secretary at AE HQ, London

''The AE-Erasmus medal is the highest award that the Academia Europaea can bestow on eminent scholars. It recognises sustained achievement and contributions to scholarship over a career period. The prize category is awarded on an annual rotation of the four academic classes of our academy. Each cycle is overseen by an expert multidisciplinary committee drawn from the academic Sections of the relevant Class and convened by the Class chair”. The [call for nominations|Acad_Main/News2_Archive/CALL FOR NOMINATIONS FOR THE 2022 ERASMUS MEDAL] is open to members and to non-members”.
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Information about the __Erasmus medal__ and a list of past winners can be found on our [website|Acad_Main/Activities/Awards_and_Prizes/Erasmus_Medal].
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!!The Award is sponsored by the Heinz-Nixdorf Stiftung
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[{Image src='heinz_nixdorf.jpg' caption='' height='30' alt='' align='center'}]
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1. Heinz Nixdorf Stiftung is - together with Stiftung Westfalen - one of the two non profit foundations, which have been established from the assets of the estate of the entrepreneur Heinz Nixdorf, who died in 1986. The foundation promotes the following purposes:
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a) the (advanced) professional education, especially in the field of modern technology\\
b) the sciences in respect of research and teaching, especially in the field of information technology,\\
c) the liberal and democratic governmental system, especially the "Soziale Marktwirtschaft"\\
d) public health,\\
e) sports.
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The foundation realizes its purposes primarily in cooperation with other non profit institutions.
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Heinz Nixdorf Stiftung promotes among others the Heinz Nixdorf MuseumsForum in Paderborn. This is a non profit istitution combining in a unique way the classic historic dimension of a museum with the current and future-oriented topics of a forum.
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Heinz Nixdorf MuseumsForum is the largest computer museum of the world.
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!Further information about the Heinz-Nixdorf Stiftung can be found at [http://www.heinz-nixdorf-stiftung.de]
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