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Living systems

October 21, 2023

Living systems are open self-organizing life forms that interact with their environment. These systems are maintained by flows of information, energy and matter. Multiple theories of living systems have been proposed. Such theories attempt to map general principles for how all living systems work.

Context Edit

Some scientists have proposed in the last few decades that a general theory of living systems is required to explain the nature of life.[1] Such a general theory would arise out of the ecological and biological sciences and attempt to map general principles for how all living systems work. Instead of examining phenomena by attempting to break things down into components, a general living systems theory explores phenomena in terms of dynamic patterns of the relationships of organisms with their environment.[2]

Theories Edit

Miller's open systems Edit

James Grier Miller's living systems theory is a general theory about the existence of all living systems, their structure, interaction, behavior and development, intended to formalize the concept of life. According to Miller's 1978 book Living Systems, such a system must contain each of twenty "critical subsystems" defined by their functions. Miller considers living systems as a type of system. Below the level of living systems, he defines space and time, matter and energy, information and entropy, levels of organization, and physical and conceptual factors, and above living systems ecological, planetary and solar systems, galaxies, etc.[3][4][5] Miller's central thesis is that the multiple levels of living systems (cells, organs, organisms, groups, organizations, societies, supranational systems) are open systems composed of critical and mutually-dependent subsystems that process inputs, throughputs, and outputs of energy and information.[6][7][8] Seppänen (1998) says that Miller applied general systems theory on a broad scale to describe all aspects of living systems.[9] Bailey states that Miller's theory is perhaps the "most integrative" social systems theory,[10] clearly distinguishing between matter–energy-processing and information-processing, showing how social systems are linked to biological systems. LST analyzes the irregularities or "organizational pathologies" of systems functioning (e.g., system stress and strain, feedback irregularities, information–input overload). It explicates the role of entropy in social research while it equates negentropy with information and order. It emphasizes both structure and process, as well as their interrelations.[11]

Lovelock's Gaia hypothesis Edit

Main article: Gaia hypothesis

The idea that Earth is alive is found in philosophy and religion, but the first scientific discussion of it was by the Scottish geologist James Hutton. In 1785, he stated that Earth was a superorganism and that its proper study should be physiology.[12]: 10  The Gaia hypothesis, proposed in the 1960s by James Lovelock, suggests that life on Earth functions as a single organism that defines and maintains environmental conditions necessary for its survival.[13][14]

Piast's self-maintainable information Edit

 
According to the theory of self-maintainable information, entities can be ranked by how alive they are, gaining the ability to evolve and maintaining distinctness.

All living entities possess genetic information that maintains itself by processes called cis-actions.[15] Cis-action is any action that has an impact on the initiator, and in chemical systems is known as the autocatalytic set. In living systems, all the cis-actions have generally a positive influence on the system as those with negative impact are eliminated by natural selection. Genetic information acts as an initiator, and it can maintain itself via a series of cis-actions like self-repair or self-production (the production of parts of the body to be distinguished from self-reproduction, which is a duplication of the entire entity). Various cis-actions give the entity additional traits to be considered alive. Self-maintainable information is a basic requirement - a level zero for gaining lifeness and it can be obtained by any cis-action like self-repair (like a gene coding a protein that fixes alteration to a nucleic acid caused by UV radiation). Subsequently, if the entity is able to perform error-prone self-reproduction it gains the trait of evolution and belongs to a continuum of self-maintainable information - it becomes part of the living world in meaning of phenomenon but not yet a living individual. For this upgrade, the entity has to process the trait of distinctness, understood as an ability to define itself as a separate entity with its own fate. There are two possible ways of reaching distinctness: 1) maintaining an open-system (a cell) or/and 2) maintaining a transmission process (for obligatory parasites). Fulfiling any of these cis-actions raises the entity to a level of living individual - a distinct element of the self-maintainable information's continuum. The final level regards the state of the entity as dead or alive and requires the trait of functionality.[15] This approach provides a ladder-like hierarchy of entities depending on their ability to maintain themselves, their evolvability, and their distinctness. It distinguishes between life as a phenomenon, a living individual, and an alive individual.[15]

Morowitz's property of ecosystems Edit

A systems view of life treats environmental fluxes and biological fluxes together as a "reciprocity of influence,"[16] and a reciprocal relation with environment is arguably as important for understanding life as it is for understanding ecosystems. As Harold J. Morowitz (1992) explains it, life is a property of an ecological system rather than a single organism or species.[17] He argues that an ecosystemic definition of life is preferable to a strictly biochemical or physical one. Robert Ulanowicz (2009) highlights mutualism as the key to understand the systemic, order-generating behaviour of life and ecosystems.[18]

Rosen's complex systems biology Edit

Main article: Complex systems biology

Robert Rosen devoted a large part of his career, from 1958[19] onwards, to developing a comprehensive theory of life as a self-organizing complex system, "closed to efficient causation". He defined a system component as "a unit of organization; a part with a function, i.e., a definite relation between part and whole." He identified the "nonfractionability of components in an organism" as the fundamental difference between living systems and "biological machines." He summarised his views in his book Life Itself.[20]

Complex systems biology is a field of science that studies the emergence of complexity in functional organisms from the viewpoint of dynamic systems theory.[21] The latter is also often called systems biology and aims to understand the most fundamental aspects of life. A closely related approach, relational biology, is concerned mainly with understanding life processes in terms of the most important relations, and categories of such relations among the essential functional components of organisms; for multicellular organisms, this has been defined as "categorical biology", or a model representation of organisms as a category theory of biological relations, as well as an algebraic topology of the functional organisation of living organisms in terms of their dynamic, complex networks of metabolic, genetic, and epigenetic processes and signalling pathways.[22][23] Related approaches focus on the interdependence of constraints, where constraints can be either molecular, such as enzymes, or macroscopic, such as the geometry of a bone or of the vascular system.[24]

Bernstein, Byerly and Hopf's Darwinian dynamic Edit

Main article: Evolutionary dynamics

Harris Bernstein and colleagues argued in 1983 that the evolution of order in living systems and certain physical systems obeys a common fundamental principle termed the Darwinian dynamic. This was formulated by first considering how macroscopic order is generated in a simple non-biological system far from thermodynamic equilibrium, and then extending consideration to short, replicating RNA molecules. The underlying order-generating process was concluded to be basically similar for both types of systems.[25][26]

Gerard Jagers' operator theory Edit

Gerard Jagers' operator theory proposes that life is a general term for the presence of the typical closures found in organisms; the typical closures are a membrane and an autocatalytic set in the cell[27] and that an organism is any system with an organisation that complies with an operator type that is at least as complex as the cell.[28][29][30][31] Life can be modelled as a network of inferior negative feedbacks of regulatory mechanisms subordinated to a superior positive feedback formed by the potential of expansion and reproduction.[32]

Kauffman's multi-agent system Edit

Stuart Kauffman defines a living system as an autonomous agent or a multi-agent system capable of reproducing itself or themselves, and of completing at least one thermodynamic work cycle.[33] This definition is extended by the evolution of novel functions over time.[34]

Budisa, Kubyshkin and Schmidt's four pillars Edit

 
Definition of cellular life according to Budisa, Kubyshkin and Schmidt

Budisa, Kubyshkin and Schmidt defined cellular life as an organizational unit resting on four pillars/cornerstones: (i) energy, (ii) metabolism, (iii) information and (iv) form. This system is able to regulate and control metabolism and energy supply and contains at least one subsystem that functions as an information carrier (genetic information). Cells as self-sustaining units are parts of different populations that are involved in the unidirectional and irreversible open-ended process known as evolution.[35]

See also Edit

  • Artificial life – Field of study
  • Autonomous Agency Theory – viable system theory
  • Autopoiesis – Systems concept which entails automatic reproduction and maintenance
  • Biological organization – Hierarchy of complex structures and systems within biological sciences
  • Biological systems – Complex network which connects several biologically relevant entities
  • Complex systems – System composed of many interacting components
  • Earth system science – Scientific study of the Earth's spheres and their natural integrated systems
  • Extraterrestrial life – Life that did not originate on Earth
  • Information metabolism – Psychological theory of interaction between biological organisms and their environment
  • Spome – Hypothetical matter-closed, energy-open life support system
  • Systems biology – Computational and mathematical modeling of complex biological systems
  • Systems theory – Interdisciplinary study of systems
  • Viable System Theory – concerns cybernetic processes in relation to the development/evolution of dynamical systems

References Edit

  1. ^ Clealand, Carol E.; Chyba, Christopher F. (8 October 2007). "Does 'Life' Have a Definition?". In Woodruff, T. Sullivan; Baross, John (eds.). Planets and Life: The Emerging Science of Astrobiology. Cambridge University Press. In the absence of such a theory, we are in a position analogous to that of a 16th-century investigator trying to define 'water' in the absence of molecular theory. [...] Without access to living things having a different historical origin, it is difficult and perhaps ultimately impossible to formulate an adequately general theory of the nature of living systems
  2. ^ Brown, Molly Young (2002). . Archived from the original on 8 January 2009. Retrieved 27 June 2009.
  3. ^ Miller, James Grier (1978). Living Systems. New York: McGraw-Hill. ISBN 978-0070420151.
  4. ^ Seppänen, Jouko (1998). "Systems ideology in human and social sciences". In Altmann, G.; Koch, W.A. (eds.). Systems: New paradigms for the human sciences. Berlin: Walter de Gruyter. pp. 180–302.
  5. ^ Járos, György (2000). "Living Systems Theory of James Grier Miller and teleonics". Systems Research and Behavioral Science. Wiley. 17 (3): 289–300. doi:10.1002/(sici)1099-1743(200005/06)17:3<289::aid-sres333>3.0.co;2-z. ISSN 1092-7026.
  6. ^ (Miller, 1978, p. 1025)
  7. ^ Parent, Elaine (1996). "The Living Systems Theory of James Grier Miller". The Primer Project. Retrieved 20 September 2023.
  8. ^ "The Earth as a System". Primer project ISSS. Retrieved 20 September 2023.
  9. ^ Seppänen 1998, pp. 197–198.
  10. ^ Kenneth D. Bailey 2006, pp.292–296.
  11. ^ Kenneth D. Bailey, 1994, pp. 209–210.
  12. ^ Lovelock, James (1979). Gaia: A New Look at Life on Earth. Oxford University Press. ISBN 978-0-19-286030-9.
  13. ^ Lovelock, J.E. (1965). "A physical basis for life detection experiments". Nature. 207 (7): 568–570. Bibcode:1965Natur.207..568L. doi:10.1038/207568a0. PMID 5883628. S2CID 33821197.
  14. ^ Lovelock, James. . Papers by James Lovelock. Archived from the original on 6 May 2007. Retrieved 1 October 2009.
  15. ^ a b c Piast, Radosław W. (June 2019). "Shannon's information, Bernal's biopoiesis and Bernoulli distribution as pillars for building a definition of life". Journal of Theoretical Biology. 470: 101–107. Bibcode:2019JThBi.470..101P. doi:10.1016/j.jtbi.2019.03.009. PMID 30876803. S2CID 80625250. from the original on 15 December 2019. Retrieved 1 January 2023.
  16. ^ Fiscus, Daniel A. (April 2002). . Bulletin of the Ecological Society of America. Archived from the original on 6 August 2009. Retrieved 28 August 2009.
  17. ^ Morowitz, Harold J. (1992). Beginnings of cellular life: metabolism recapitulates biogenesis. Yale University Press. ISBN 978-0-300-05483-5.
  18. ^ Ulanowicz, Robert W.; Ulanowicz, Robert E. (2009). A third window: natural life beyond Newton and Darwin. Templeton Foundation Press. ISBN 978-1-59947-154-9.
  19. ^ Rosen, Robert (1958). "A relational theory of biological systems". The Bulletin of Mathematical Biophysics. 20 (3): 245–260. doi:10.1007/bf02478302.
  20. ^ Robert, Rosen (1991). Life Itself: A Comprehensive Inquiry into the Nature, Origin, and Fabrication of Life. New York: Columbia University Press. ISBN 978-0-231-07565-7.
  21. ^ Baianu, I.C. (2006). "Robert Rosen's Work and Complex Systems Biology". Axiomathes. 16 (1–2): 25–34. doi:10.1007/s10516-005-4204-z. S2CID 4673166.
  22. ^ * Rosen, Robert (1958a). "A Relational Theory of Biological Systems". Bulletin of Mathematical Biophysics. 20 (3): 245–260. doi:10.1007/bf02478302.
  23. ^ * Rosen, R. (1958b). "The Representation of Biological Systems from the Standpoint of the Theory of Categories". Bulletin of Mathematical Biophysics. 20 (4): 317–341. doi:10.1007/bf02477890.
  24. ^ Montévil, Maël; Mossio, Matteo (7 May 2015). "Biological organisation as closure of constraints". Journal of Theoretical Biology. 372: 179–191. Bibcode:2015JThBi.372..179M. CiteSeerX 10.1.1.701.3373. doi:10.1016/j.jtbi.2015.02.029. PMID 25752259. S2CID 4654439. from the original on 17 November 2017.
  25. ^ Bernstein, Harris; Byerly, Henry C.; Hopf, Frederick A.; Michod, Richard A.; Vemulapalli, G. Krishna (June 1983). "The Darwinian Dynamic". The Quarterly Review of Biology. 58 (2): 185. doi:10.1086/413216. JSTOR 2828805. S2CID 83956410.
  26. ^ Michod, Richard E. (2000). Darwinian Dynamics: Evolutionary Transitions in Fitness and Individuality. Princeton: Princeton University Press. ISBN 978-0-691-05011-9.
  27. ^ Jagers, Gerard (2012). The Pursuit of Complexity: The Utility of Biodiversity from an Evolutionary Perspective. KNNV Publishing. pp. 27–29, 87–88, 94–96. ISBN 978-90-5011-443-1.
  28. ^ Jagers Op Akkerhuis, Gerard A. J. M. (2010). "Towards a Hierarchical Definition of Life, the Organism, and Death". Foundations of Science. 15 (3): 245–262. doi:10.1007/s10699-010-9177-8. S2CID 195282529.
  29. ^ Jagers Op Akkerhuis, Gerard (2011). "Explaining the Origin of Life is not Enough for a Definition of Life". Foundations of Science. 16 (4): 327–329. doi:10.1007/s10699-010-9209-4. S2CID 195284978.
  30. ^ Jagers Op Akkerhuis, Gerard A. J. M. (2012). "The Role of Logic and Insight in the Search for a Definition of Life". Journal of Biomolecular Structure and Dynamics. 29 (4): 619–620. doi:10.1080/073911012010525006. PMID 22208258. S2CID 35426048. from the original on 16 April 2021. Retrieved 16 April 2021.
  31. ^ Jagers, Gerald (2012). "Contributions of the Operator Hierarchy to the Field of Biologically Driven Mathematics and Computation". In Ehresmann, Andree C.; Simeonov, Plamen L.; Smith, Leslie S. (eds.). Integral Biomathics. Springer. ISBN 978-3-642-28110-5.
  32. ^ Korzeniewski, Bernard (7 April 2001). "Cybernetic formulation of the definition of life". Journal of Theoretical Biology. 209 (3): 275–286. Bibcode:2001JThBi.209..275K. doi:10.1006/jtbi.2001.2262. PMID 11312589.
  33. ^ Kaufmann, Stuart (2004). "Autonomous agents". In Barrow, John D.; Davies, P.C.W.; Harper, Jr., C.L. (eds.). Science and Ultimate Reality. pp. 654–666. doi:10.1017/CBO9780511814990.032. ISBN 978-0-521-83113-0.
  34. ^ Longo, Giuseppe; Montévil, Maël; Kauffman, Stuart (1 January 2012). "No entailing laws, but enablement in the evolution of the biosphere". Proceedings of the 14th annual conference companion on Genetic and evolutionary computation. GECCO '12. pp. 1379–1392. arXiv:1201.2069. Bibcode:2012arXiv1201.2069L. CiteSeerX 10.1.1.701.3838. doi:10.1145/2330784.2330946. ISBN 978-1-4503-1178-6. S2CID 15609415. from the original on 11 May 2017.
  35. ^ Budisa, Nediljko; Kubyshkin, Vladimir; Schmidt, Markus (22 April 2020). "Xenobiology: A Journey towards Parallel Life Forms". ChemBioChem. 21 (16): 2228–2231. doi:10.1002/cbic.202000141. PMID 32323410.

Further reading Edit

  • Kenneth D. Bailey, (1994). Sociology and the new systems theory: Toward a theoretical synthesis. Albany, NY: SUNY Press.
  • Kenneth D. Bailey (2006). Living systems theory and social entropy theory. Systems Research and Behavioral Science, 22, 291–300.
  • James Grier Miller, (1978). Living systems. New York: McGraw-Hill. ISBN 0-87081-363-3
  • Miller, J.L., & Miller, J.G. (1992). Greater than the sum of its parts: Subsystems which process both matter-energy and information. Behavioral Science, 37, 1–38.
  • Humberto Maturana (1978), "Biology of language: The epistemology of reality," in Miller, George A., and Elizabeth Lenneberg (eds.), Psychology and Biology of Language and Thought: Essays in Honor of Eric Lenneberg. Academic Press: 27-63.
  • Jouko Seppänen, (1998). Systems ideology in human and social sciences. In G. Altmann & W.A. Koch (Eds.), Systems: New paradigms for the human sciences (pp. 180–302). Berlin: Walter de Gruyter.
  • James R. Simms (1999). Principles of Quantitative Living Systems Science. Dordrecht: Kluwer Academic. ISBN 0-306-45979-5

External links Edit

  • The Living Systems Theory Of James Grier Miller
  • James Grier Miller, Living Systems The Basic Concepts (1978)


October 21, 2023
living, systems, open, self, organizing, life, forms, that, interact, with, their, environment, these, systems, maintained, flows, information, energy, matter, multiple, theories, living, systems, have, been, proposed, such, theories, attempt, general, princip. Living systems are open self organizing life forms that interact with their environment These systems are maintained by flows of information energy and matter Multiple theories of living systems have been proposed Such theories attempt to map general principles for how all living systems work Contents 1 Context 2 Theories 2 1 Miller s open systems 2 2 Lovelock s Gaia hypothesis 2 3 Piast s self maintainable information 2 4 Morowitz s property of ecosystems 2 5 Rosen s complex systems biology 2 6 Bernstein Byerly and Hopf s Darwinian dynamic 2 7 Gerard Jagers operator theory 2 8 Kauffman s multi agent system 2 9 Budisa Kubyshkin and Schmidt s four pillars 3 See also 4 References 5 Further reading 6 External linksContext EditSome scientists have proposed in the last few decades that a general theory of living systems is required to explain the nature of life 1 Such a general theory would arise out of the ecological and biological sciences and attempt to map general principles for how all living systems work Instead of examining phenomena by attempting to break things down into components a general living systems theory explores phenomena in terms of dynamic patterns of the relationships of organisms with their environment 2 Theories EditMiller s open systems Edit James Grier Miller s living systems theory is a general theory about the existence of all living systems their structure interaction behavior and development intended to formalize the concept of life According to Miller s 1978 book Living Systems such a system must contain each of twenty critical subsystems defined by their functions Miller considers living systems as a type of system Below the level of living systems he defines space and time matter and energy information and entropy levels of organization and physical and conceptual factors and above living systems ecological planetary and solar systems galaxies etc 3 4 5 Miller s central thesis is that the multiple levels of living systems cells organs organisms groups organizations societies supranational systems are open systems composed of critical and mutually dependent subsystems that process inputs throughputs and outputs of energy and information 6 7 8 Seppanen 1998 says that Miller applied general systems theory on a broad scale to describe all aspects of living systems 9 Bailey states that Miller s theory is perhaps the most integrative social systems theory 10 clearly distinguishing between matter energy processing and information processing showing how social systems are linked to biological systems LST analyzes the irregularities or organizational pathologies of systems functioning e g system stress and strain feedback irregularities information input overload It explicates the role of entropy in social research while it equates negentropy with information and order It emphasizes both structure and process as well as their interrelations 11 Lovelock s Gaia hypothesis Edit Main article Gaia hypothesis The idea that Earth is alive is found in philosophy and religion but the first scientific discussion of it was by the Scottish geologist James Hutton In 1785 he stated that Earth was a superorganism and that its proper study should be physiology 12 10 The Gaia hypothesis proposed in the 1960s by James Lovelock suggests that life on Earth functions as a single organism that defines and maintains environmental conditions necessary for its survival 13 14 Piast s self maintainable information Edit nbsp According to the theory of self maintainable information entities can be ranked by how alive they are gaining the ability to evolve and maintaining distinctness All living entities possess genetic information that maintains itself by processes called cis actions 15 Cis action is any action that has an impact on the initiator and in chemical systems is known as the autocatalytic set In living systems all the cis actions have generally a positive influence on the system as those with negative impact are eliminated by natural selection Genetic information acts as an initiator and it can maintain itself via a series of cis actions like self repair or self production the production of parts of the body to be distinguished from self reproduction which is a duplication of the entire entity Various cis actions give the entity additional traits to be considered alive Self maintainable information is a basic requirement a level zero for gaining lifeness and it can be obtained by any cis action like self repair like a gene coding a protein that fixes alteration to a nucleic acid caused by UV radiation Subsequently if the entity is able to perform error prone self reproduction it gains the trait of evolution and belongs to a continuum of self maintainable information it becomes part of the living world in meaning of phenomenon but not yet a living individual For this upgrade the entity has to process the trait of distinctness understood as an ability to define itself as a separate entity with its own fate There are two possible ways of reaching distinctness 1 maintaining an open system a cell or and 2 maintaining a transmission process for obligatory parasites Fulfiling any of these cis actions raises the entity to a level of living individual a distinct element of the self maintainable information s continuum The final level regards the state of the entity as dead or alive and requires the trait of functionality 15 This approach provides a ladder like hierarchy of entities depending on their ability to maintain themselves their evolvability and their distinctness It distinguishes between life as a phenomenon a living individual and an alive individual 15 Morowitz s property of ecosystems Edit A systems view of life treats environmental fluxes and biological fluxes together as a reciprocity of influence 16 and a reciprocal relation with environment is arguably as important for understanding life as it is for understanding ecosystems As Harold J Morowitz 1992 explains it life is a property of an ecological system rather than a single organism or species 17 He argues that an ecosystemic definition of life is preferable to a strictly biochemical or physical one Robert Ulanowicz 2009 highlights mutualism as the key to understand the systemic order generating behaviour of life and ecosystems 18 Rosen s complex systems biology Edit Main article Complex systems biology Robert Rosen devoted a large part of his career from 1958 19 onwards to developing a comprehensive theory of life as a self organizing complex system closed to efficient causation He defined a system component as a unit of organization a part with a function i e a definite relation between part and whole He identified the nonfractionability of components in an organism as the fundamental difference between living systems and biological machines He summarised his views in his book Life Itself 20 Complex systems biology is a field of science that studies the emergence of complexity in functional organisms from the viewpoint of dynamic systems theory 21 The latter is also often called systems biology and aims to understand the most fundamental aspects of life A closely related approach relational biology is concerned mainly with understanding life processes in terms of the most important relations and categories of such relations among the essential functional components of organisms for multicellular organisms this has been defined as categorical biology or a model representation of organisms as a category theory of biological relations as well as an algebraic topology of the functional organisation of living organisms in terms of their dynamic complex networks of metabolic genetic and epigenetic processes and signalling pathways 22 23 Related approaches focus on the interdependence of constraints where constraints can be either molecular such as enzymes or macroscopic such as the geometry of a bone or of the vascular system 24 Bernstein Byerly and Hopf s Darwinian dynamic Edit Main article Evolutionary dynamics Harris Bernstein and colleagues argued in 1983 that the evolution of order in living systems and certain physical systems obeys a common fundamental principle termed the Darwinian dynamic This was formulated by first considering how macroscopic order is generated in a simple non biological system far from thermodynamic equilibrium and then extending consideration to short replicating RNA molecules The underlying order generating process was concluded to be basically similar for both types of systems 25 26 Gerard Jagers operator theory Edit Gerard Jagers operator theory proposes that life is a general term for the presence of the typical closures found in organisms the typical closures are a membrane and an autocatalytic set in the cell 27 and that an organism is any system with an organisation that complies with an operator type that is at least as complex as the cell 28 29 30 31 Life can be modelled as a network of inferior negative feedbacks of regulatory mechanisms subordinated to a superior positive feedback formed by the potential of expansion and reproduction 32 Kauffman s multi agent system Edit Stuart Kauffman defines a living system as an autonomous agent or a multi agent system capable of reproducing itself or themselves and of completing at least one thermodynamic work cycle 33 This definition is extended by the evolution of novel functions over time 34 Budisa Kubyshkin and Schmidt s four pillars Edit nbsp Definition of cellular life according to Budisa Kubyshkin and SchmidtBudisa Kubyshkin and Schmidt defined cellular life as an organizational unit resting on four pillars cornerstones i energy ii metabolism iii information and iv form This system is able to regulate and control metabolism and energy supply and contains at least one subsystem that functions as an information carrier genetic information Cells as self sustaining units are parts of different populations that are involved in the unidirectional and irreversible open ended process known as evolution 35 See also EditArtificial life Field of study Autonomous Agency Theory viable system theoryPages displaying wikidata descriptions as a fallback Autopoiesis Systems concept which entails automatic reproduction and maintenance Biological organization Hierarchy of complex structures and systems within biological sciencesPages displaying short descriptions of redirect targets Biological systems Complex network which connects several biologically relevant entitiesPages displaying short descriptions of redirect targets Complex systems System composed of many interacting componentsPages displaying short descriptions of redirect targets Earth system science Scientific study of the Earth s spheres and their natural integrated systems Extraterrestrial life Life that did not originate on Earth Information metabolism Psychological theory of interaction between biological organisms and their environment Spome Hypothetical matter closed energy open life support system Systems biology Computational and mathematical modeling of complex biological systems Systems theory Interdisciplinary study of systems Viable System Theory concerns cybernetic processes in relation to the development evolution of dynamical systemsPages displaying wikidata descriptions as a fallbackReferences Edit Clealand Carol E Chyba Christopher F 8 October 2007 Does Life Have a Definition In Woodruff T Sullivan Baross John eds Planets and Life The Emerging Science of Astrobiology Cambridge University Press In the absence of such a theory we are in a position analogous to that of a 16th century investigator trying to define water in the absence of molecular theory Without access to living things having a different historical origin it is difficult and perhaps ultimately impossible to formulate an adequately general theory of the nature of living systems Brown Molly Young 2002 Patterns Flows and Interrelationship Archived from the original on 8 January 2009 Retrieved 27 June 2009 Miller James Grier 1978 Living Systems New York McGraw Hill ISBN 978 0070420151 Seppanen Jouko 1998 Systems ideology in human and social sciences In Altmann G Koch W A eds Systems New paradigms for the human sciences Berlin Walter de Gruyter pp 180 302 Jaros Gyorgy 2000 Living Systems Theory of James Grier Miller and teleonics Systems Research and Behavioral Science Wiley 17 3 289 300 doi 10 1002 sici 1099 1743 200005 06 17 3 lt 289 aid sres333 gt 3 0 co 2 z ISSN 1092 7026 Miller 1978 p 1025 Parent Elaine 1996 The Living Systems Theory of James Grier Miller The Primer Project Retrieved 20 September 2023 The Earth as a System Primer project ISSS Retrieved 20 September 2023 Seppanen 1998 pp 197 198 Kenneth D Bailey 2006 pp 292 296 Kenneth D Bailey 1994 pp 209 210 Lovelock James 1979 Gaia A New Look at Life on Earth Oxford University Press ISBN 978 0 19 286030 9 Lovelock J E 1965 A physical basis for life detection experiments Nature 207 7 568 570 Bibcode 1965Natur 207 568L doi 10 1038 207568a0 PMID 5883628 S2CID 33821197 Lovelock James Geophysiology Papers by James Lovelock Archived from the original on 6 May 2007 Retrieved 1 October 2009 a b c Piast Radoslaw W June 2019 Shannon s information Bernal s biopoiesis and Bernoulli distribution as pillars for building a definition of life Journal of Theoretical Biology 470 101 107 Bibcode 2019JThBi 470 101P doi 10 1016 j jtbi 2019 03 009 PMID 30876803 S2CID 80625250 Archived from the original on 15 December 2019 Retrieved 1 January 2023 Fiscus Daniel A April 2002 The Ecosystemic Life Hypothesis Bulletin of the Ecological Society of America Archived from the original on 6 August 2009 Retrieved 28 August 2009 Morowitz Harold J 1992 Beginnings of cellular life metabolism recapitulates biogenesis Yale University Press ISBN 978 0 300 05483 5 Ulanowicz Robert W Ulanowicz Robert E 2009 A third window natural life beyond Newton and Darwin Templeton Foundation Press ISBN 978 1 59947 154 9 Rosen Robert 1958 A relational theory of biological systems The Bulletin of Mathematical Biophysics 20 3 245 260 doi 10 1007 bf02478302 Robert Rosen 1991 Life Itself A Comprehensive Inquiry into the Nature Origin and Fabrication of Life New York Columbia University Press ISBN 978 0 231 07565 7 Baianu I C 2006 Robert Rosen s Work and Complex Systems Biology Axiomathes 16 1 2 25 34 doi 10 1007 s10516 005 4204 z S2CID 4673166 Rosen Robert 1958a A Relational Theory of Biological Systems Bulletin of Mathematical Biophysics 20 3 245 260 doi 10 1007 bf02478302 Rosen R 1958b The Representation of Biological Systems from the Standpoint of the Theory of Categories Bulletin of Mathematical Biophysics 20 4 317 341 doi 10 1007 bf02477890 Montevil Mael Mossio Matteo 7 May 2015 Biological organisation as closure of constraints Journal of Theoretical Biology 372 179 191 Bibcode 2015JThBi 372 179M CiteSeerX 10 1 1 701 3373 doi 10 1016 j jtbi 2015 02 029 PMID 25752259 S2CID 4654439 Archived from the original on 17 November 2017 Bernstein Harris Byerly Henry C Hopf Frederick A Michod Richard A Vemulapalli G Krishna June 1983 The Darwinian Dynamic The Quarterly Review of Biology 58 2 185 doi 10 1086 413216 JSTOR 2828805 S2CID 83956410 Michod Richard E 2000 Darwinian Dynamics Evolutionary Transitions in Fitness and Individuality Princeton Princeton University Press ISBN 978 0 691 05011 9 Jagers Gerard 2012 The Pursuit of Complexity The Utility of Biodiversity from an Evolutionary Perspective KNNV Publishing pp 27 29 87 88 94 96 ISBN 978 90 5011 443 1 Jagers Op Akkerhuis Gerard A J M 2010 Towards a Hierarchical Definition of Life the Organism and Death Foundations of Science 15 3 245 262 doi 10 1007 s10699 010 9177 8 S2CID 195282529 Jagers Op Akkerhuis Gerard 2011 Explaining the Origin of Life is not Enough for a Definition of Life Foundations of Science 16 4 327 329 doi 10 1007 s10699 010 9209 4 S2CID 195284978 Jagers Op Akkerhuis Gerard A J M 2012 The Role of Logic and Insight in the Search for a Definition of Life Journal of Biomolecular Structure and Dynamics 29 4 619 620 doi 10 1080 073911012010525006 PMID 22208258 S2CID 35426048 Archived from the original on 16 April 2021 Retrieved 16 April 2021 Jagers Gerald 2012 Contributions of the Operator Hierarchy to the Field of Biologically Driven Mathematics and Computation In Ehresmann Andree C Simeonov Plamen L Smith Leslie S eds Integral Biomathics Springer ISBN 978 3 642 28110 5 Korzeniewski Bernard 7 April 2001 Cybernetic formulation of the definition of life Journal of Theoretical Biology 209 3 275 286 Bibcode 2001JThBi 209 275K doi 10 1006 jtbi 2001 2262 PMID 11312589 Kaufmann Stuart 2004 Autonomous agents In Barrow John D Davies P C W Harper Jr C L eds Science and Ultimate Reality pp 654 666 doi 10 1017 CBO9780511814990 032 ISBN 978 0 521 83113 0 Longo Giuseppe Montevil Mael Kauffman Stuart 1 January 2012 No entailing laws but enablement in the evolution of the biosphere Proceedings of the 14th annual conference companion on Genetic and evolutionary computation GECCO 12 pp 1379 1392 arXiv 1201 2069 Bibcode 2012arXiv1201 2069L CiteSeerX 10 1 1 701 3838 doi 10 1145 2330784 2330946 ISBN 978 1 4503 1178 6 S2CID 15609415 Archived from the original on 11 May 2017 Budisa Nediljko Kubyshkin Vladimir Schmidt Markus 22 April 2020 Xenobiology A Journey towards Parallel Life Forms ChemBioChem 21 16 2228 2231 doi 10 1002 cbic 202000141 PMID 32323410 Further reading EditKenneth D Bailey 1994 Sociology and the new systems theory Toward a theoretical synthesis Albany NY SUNY Press Kenneth D Bailey 2006 Living systems theory and social entropy theory Systems Research and Behavioral Science 22 291 300 James Grier Miller 1978 Living systems New York McGraw Hill ISBN 0 87081 363 3 Miller J L amp Miller J G 1992 Greater than the sum of its parts Subsystems which process both matter energy and information Behavioral Science 37 1 38 Humberto Maturana 1978 Biology of language The epistemology of reality in Miller George A and Elizabeth Lenneberg eds Psychology and Biology of Language and Thought Essays in Honor of Eric Lenneberg Academic Press 27 63 Jouko Seppanen 1998 Systems ideology in human and social sciences In G Altmann amp W A Koch Eds Systems New paradigms for the human sciences pp 180 302 Berlin Walter de Gruyter James R Simms 1999 Principles of Quantitative Living Systems Science Dordrecht Kluwer Academic ISBN 0 306 45979 5External links EditThe Living Systems Theory Of James Grier Miller James Grier Miller Living Systems The Basic Concepts 1978 Retrieved from https en wikipedia org w index php title Living systems amp oldid 1177357057, wikipedia, wiki, book, books, library,

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