Reinhart Heinrich: Difference between revisions
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}}</ref>) and several works of [[lyric poetry]] for which he received the [[Brigitte Reimann|Brigitte Reimann Prize]]. Among his services to the scientific community, Reinhart was associate editor of ''[[PLoS Computational Biology]]''. |
}}</ref>) and several works of [[lyric poetry]] for which he received the [[Brigitte Reimann|Brigitte Reimann Prize]]. Among his services to the scientific community, Reinhart was associate editor of ''[[PLoS Computational Biology]]''. |
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Reinhart Heinrich was born in [[Dresden]] and lived at first in the [[Soviet Union]], growing up in [[Samara, Russia|Kuybyshev/Куйбышев (called Samara since 1991)]] where his father [[:de:Helmut Heinrich|Helmut Heinrich]] — a German mathematician turned aircraft constructor — had been taken after the [[Second World War]] to work.<ref name=BiographischeDatenbankenRH/> Having been educated as a theoretical physicist at [[Dresden University of Technology]] in [[East Germany]], Reinhart conducted his [[postdoctoral research]] in the early 1970s at the [[Charité|Charité's]] Institute of Biochemistry in East Berlin. He could not fail to notice the absence of mathematical theory from cell biology as compared with other natural sciences. [[Enzyme kinetics]] was a notable exception. However, how [[enzyme]]s affect the flux through a [[metabolic pathway]] was still discussed using the rather vague term [[rate-limiting step]]. Working with [[Tom Rapoport]] on [[mathematical model]]s of [[glycolysis]] in [[red blood cell]]s, Reinhart discovered a precise and general definition of rate limitation in metabolic pathways, for which he received in 1974 the [[Humboldt Prize]].<ref name=BiographischeDatenbankenRH/> He extended his knowledge in this area, working over one year in [[Pushchino]] with Evgeni Selkov,<ref name=BiographischeDatenbankenRH/> who also worked on |
Reinhart Heinrich was born in [[Dresden]] and lived at first in the [[Soviet Union]], growing up in [[Samara, Russia|Kuybyshev/Куйбышев (called Samara since 1991)]] where his father [[:de:Helmut Heinrich|Helmut Heinrich]] — a German mathematician turned aircraft constructor — had been taken after the [[Second World War]] to work.<ref name=BiographischeDatenbankenRH/> Having been educated as a theoretical physicist at [[Dresden University of Technology]] in [[East Germany]], Reinhart conducted his [[postdoctoral research]] in the early 1970s at the [[Charité|Charité's]] Institute of Biochemistry in East Berlin. He could not fail to notice the absence of mathematical theory from cell biology as compared with other natural sciences. [[Enzyme kinetics]] was a notable exception. However, how [[enzyme]]s affect the flux through a [[metabolic pathway]] was still discussed using the rather vague term [[rate-limiting step]]. Working with [[Tom Rapoport]] on [[mathematical model]]s of [[glycolysis]] in [[red blood cell]]s, Reinhart discovered a precise and general definition of rate limitation in metabolic pathways, for which he received in 1974 the [[Humboldt Prize]].<ref name=BiographischeDatenbankenRH/> He extended his knowledge in this area, working over one year in [[Pushchino]] with Evgeni Selkov,<ref name=BiographischeDatenbankenRH/> who also worked on mathematical modelling of metabolic processes. |
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The parallel development of metabolic control theory by [[Henrik Kacser]] and Jim Burns<ref name="kacser" /> in Edinburgh shows that the time was ripe for a quantitative understanding of metabolic regulation. Instead of postulating a single rate-limiting step, these theories evaluated the degree of flux control exerted by an individual enzyme in a linear pathway or in a more complex network. The corresponding measure, now called the flux control coefficient by general agreement,<ref> {{cite journal |
The parallel development of metabolic control theory by [[Henrik Kacser]] and Jim Burns<ref name="kacser" /> in Edinburgh shows that the time was ripe for a quantitative understanding of metabolic regulation. Instead of postulating a single rate-limiting step, these theories evaluated the degree of flux control exerted by an individual enzyme in a linear pathway or in a more complex network. The corresponding measure, now called the flux control coefficient by general agreement,<ref> {{cite journal |
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}}</ref> turned out to be a truly systemic quantity, depending not only on the kinetic parameters of the enzyme itself but also on those of other enzymes, as well as on the position of the reaction in the network. After a slow start metabolic control theory has become more widely known by biochemists. Control coefficients have been measured for many pathways, confirming the theoretical prediction that flux control is frequently shared by several reactions. This finding has become of practical importance for the genetic engineering of large [[metabolic network]]s in biotechnology. |
}}</ref> turned out to be a truly systemic quantity, depending not only on the kinetic parameters of the enzyme itself but also on those of other enzymes, as well as on the position of the reaction in the network. After a slow start metabolic control theory has become more widely known by biochemists. Control coefficients have been measured for many pathways, confirming the theoretical prediction that flux control is frequently shared by several reactions. This finding has become of practical importance for the genetic engineering of large [[metabolic network]]s in biotechnology. |
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The dual approach — |
The dual approach — modelling concrete cellular processes and, at the same time, searching for general laws — has been a characteristic of Reinhart's work. The areas he worked in were amazingly diverse, including metabolic control, [[osmoregulation]], cell shapes, [[signal transduction]], [[vesicular transport]], protein translation and transport, as well as the population dynamics of [[malaria parasite]]s. |
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Perhaps the questions that interested him the most were those of evolution.<ref>{{cite journal |
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| title = Expanding metabolic networks: Scopes of compounds, robustness, and evolution |
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⚫ | | doi = 10.1007/s00239-005-0027-1}}</ref> To understand the kinetic design of enzymes and [[enzymatic reaction]] networks, Reinhart strove to rationalize, in mathematical terms, the selective pressures and [[Physical chemistry|physico–chemical]] constraints that these systems were subjected to. Reinhart's work on this topic is full of original insight and makes specific predictions, some of which have begun to be tested successfully in recent years. |
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Reinhart was author of more than 160 research articles and, together with [[Stefan Schuster]], the book ''The Regulation of Cellular Systems'',<ref>{{cite book |
Reinhart was author of more than 160 research articles and, together with [[Stefan Schuster]], the book ''The Regulation of Cellular Systems'',<ref>{{cite book |
Revision as of 14:49, 11 September 2020
Reinhart Heinrich | |
---|---|
Born | |
Died | October 23, 2006 | (aged 60)
Nationality | German |
Alma mater | Dresden University of Technology |
Known for | metabolism, signal transduction |
Awards | Humboldt Prize, Brigitte Reimann Prize |
Scientific career | |
Fields | Systems biology, biophysics |
Institutions | Humboldt University of Berlin Charité |
Reinhart Heinrich (24 April 1946 – 23 October 2006) was a German biophysicist.[1]
He was professor at the Humboldt University of Berlin, and best known as one of the founders, with Tom Rapoport, of metabolic control theory [2] in parallel with similar ideas developed at about the same time by Henrik Kacser and Jim Burns[3]. His far-reaching theoretical work on metabolism, signal transduction, and other cellular processes has made him one of the most influential forerunners of present-day systems biology. Reinhart's many talents made him appear as a modern Renaissance man. He played the violin, and published an autobiographic novel (Jenseits von Babel [4]) and several works of lyric poetry for which he received the Brigitte Reimann Prize. Among his services to the scientific community, Reinhart was associate editor of PLoS Computational Biology.
Reinhart Heinrich was born in Dresden and lived at first in the Soviet Union, growing up in Kuybyshev/Куйбышев (called Samara since 1991) where his father Helmut Heinrich — a German mathematician turned aircraft constructor — had been taken after the Second World War to work.[1] Having been educated as a theoretical physicist at Dresden University of Technology in East Germany, Reinhart conducted his postdoctoral research in the early 1970s at the Charité's Institute of Biochemistry in East Berlin. He could not fail to notice the absence of mathematical theory from cell biology as compared with other natural sciences. Enzyme kinetics was a notable exception. However, how enzymes affect the flux through a metabolic pathway was still discussed using the rather vague term rate-limiting step. Working with Tom Rapoport on mathematical models of glycolysis in red blood cells, Reinhart discovered a precise and general definition of rate limitation in metabolic pathways, for which he received in 1974 the Humboldt Prize.[1] He extended his knowledge in this area, working over one year in Pushchino with Evgeni Selkov,[1] who also worked on mathematical modelling of metabolic processes.
The parallel development of metabolic control theory by Henrik Kacser and Jim Burns[3] in Edinburgh shows that the time was ripe for a quantitative understanding of metabolic regulation. Instead of postulating a single rate-limiting step, these theories evaluated the degree of flux control exerted by an individual enzyme in a linear pathway or in a more complex network. The corresponding measure, now called the flux control coefficient by general agreement,[5] turned out to be a truly systemic quantity, depending not only on the kinetic parameters of the enzyme itself but also on those of other enzymes, as well as on the position of the reaction in the network. After a slow start metabolic control theory has become more widely known by biochemists. Control coefficients have been measured for many pathways, confirming the theoretical prediction that flux control is frequently shared by several reactions. This finding has become of practical importance for the genetic engineering of large metabolic networks in biotechnology.
The dual approach — modelling concrete cellular processes and, at the same time, searching for general laws — has been a characteristic of Reinhart's work. The areas he worked in were amazingly diverse, including metabolic control, osmoregulation, cell shapes, signal transduction, vesicular transport, protein translation and transport, as well as the population dynamics of malaria parasites.
Perhaps the questions that interested him the most were those of evolution.[6] To understand the kinetic design of enzymes and enzymatic reaction networks, Reinhart strove to rationalize, in mathematical terms, the selective pressures and physico–chemical constraints that these systems were subjected to. Reinhart's work on this topic is full of original insight and makes specific predictions, some of which have begun to be tested successfully in recent years.
Reinhart was author of more than 160 research articles and, together with Stefan Schuster, the book The Regulation of Cellular Systems,[7] which has become a classic of cell systems biology. In addition to this large body of original work, he was a gifted mentor of young scientists and for more than ten years ran the highly successful interdisciplinary graduate program Dynamics and Evolution of Cellular Processes at Humboldt University, Berlin. In 1996 he received an Honorary degree from the University of Bordeaux.
References
- Höfer T (2007) In Remembrance: Reinhart Heinrich 1946–2006. PLoS Comput Biol 3(1): e18. doi:10.1371/journal.pcbi.0030018
- Jacobasch, Gisela (2007) Nachruf. Prof Dr. Dr. h.c. Reinhart Heinrich. geb. 24.04.1946, gest. 23.10.2006. Sitzungsberichte der Leibniz-Sozietät 88, pp. 183–184
- Kirschner, Marc W. (2006) Obituary: Reinhart Heinrich (1946–2006), Nature 444, 700 (7 December 2006) | doi:10.1038/444700a
- His homepage at Humboldt University Berlin
- ^ a b c d Dieter Hoffmann. "Heinrich, Reinhart * 24.4.1946, † 23.10.2006 Biophysiker" (in German). Bundesstiftung zur Aufarbeitung der SED-Diktatur: Biographische Datenbanken. Retrieved 13 May 2015.
- ^ Heinrich, R; Rapoport, TA. "A linear steady-state theory of enzymatic chains: general properties, control and effector strength". European Journal of Biochemistry. 42: 89–95.
- ^ a b Kacser, H; Burns, JA. "The control of flux". Symposia of the Society for Experimental Biology. 27: 341–366.
- ^ Heinrich, Reinhart (1987). Jenseits von Babel (Beyond Babel) (in German). Berlin: New life publishing house.
- ^ Burns, JA; Cornish-Bowden, A; Groen, AK; Heinrich, R; Kacser, H; Porteous, JW; Rapoport, SM; Rapoport, TA; Stucki, JW; Tager, JM; Wanders, RJA; Westerhoff, HV. "Control analysis of metabolic systems". Trends in Biochemical Sciences. 10: 16.
- ^ Handorf, T; Ebenhoh, O; Heinrich, R. "Expanding metabolic networks: Scopes of compounds, robustness, and evolution". Journal of Molecular Evolution. 61 (4): 498–512. doi:10.1007/s00239-005-0027-1.
- ^ Heinrich, Reinhart; Schuster, S (1996). The Regulation of Cellular Systems. New York: Chapman and Hall.