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Biological organisation

February 16, 2024

"Hierarchy of life" and "Levels of organization" redirect here. For the hierarchical ordering and organization of all organisms, see Biological classification. For the evolutionary hierarchy of organisms and interspecial relationships, see Phylogenetic tree.

Biological organisation is the organisation of complex biological structures and systems that define life using a reductionistic approach.[1] The traditional hierarchy, as detailed below, extends from atoms to biospheres. The higher levels of this scheme are often referred to as an ecological organisation concept, or as the field, hierarchical ecology.

A population of bees shimmers in response to a predator.

Each level in the hierarchy represents an increase in organisational complexity, with each "object" being primarily composed of the previous level's basic unit.[2] The basic principle behind the organisation is the concept of emergence—the properties and functions found at a hierarchical level are not present and irrelevant at the lower levels.

The biological organisation of life is a fundamental premise for numerous areas of scientific research, particularly in the medical sciences. Without this necessary degree of organisation, it would be much more difficult—and likely impossible—to apply the study of the effects of various physical and chemical phenomena to diseases and physiology (body function). For example, fields such as cognitive and behavioral neuroscience could not exist if the brain was not composed of specific types of cells, and the basic concepts of pharmacology could not exist if it was not known that a change at the cellular level can affect an entire organism. These applications extend into the ecological levels as well. For example, DDT's direct insecticidal effect occurs at the subcellular level, but affects higher levels up to and including multiple ecosystems. Theoretically, a change in one atom could change the entire biosphere.

Levels edit

See also: Integrative level
 
The simplest unit in this hierarchy is the atom, like oxygen. Two or more atoms is a molecule, like a dioxide. Many small molecules may combine in a chemical reaction to make up a macromolecule, such as a phospholipid. Multiple macromolecules form a cell, like a club cell. A group of cells functioning together as a tissue, for example, Epithelial tissue. Different tissues make up an organ, like a lung. Organs work together to form an organ system, such as the Respiratory System. All of the organ systems make a living organism, like a lion. A group of the same organism living together in an area is a population, such as a pride of lions. Two or more populations interacting with each other form a community, for example, lion and zebra populations interacting with each other. Communities interacting not only with each other but also with the physical environment encompass an ecosystem, such as the Savanna ecosystem. All of the ecosystems make up the biosphere, the area of life on Earth.

The simple standard biological organisation scheme, from the lowest level to the highest level, is as follows:[1]

For levels smaller than atoms see Subatomic particle
Acellular level
and
Pre-cellular level		 Atoms
Molecule Groups of atoms
Biomolecular complex Groups of (bio)molecules
Sub-cellular level Organelle Functional groups of biomolecules, biochemical reactions and interactions
Cellular level Cell Basic unit of all life and the grouping of organelles
Super-cellular level
(Multicellular level)		 Tissue Functional groups of cells
Organ Functional groups of tissues
Organ system Functional groups of organs
Ecological levels Organism The basic living system, a functional grouping of the lower-level components, including at least one cell
Population Groups of organisms of the same species
Guild Interspecific groups of organisms carrying the same ecological function (i.e. herbivores).
Community
(or biocoenosis)		 Guilds from all biological domains, and their interactions in a specific location.
Ecosystem Groups of organisms in conjunction with the physical (abiotic) environment.
Biome Continental scale (climatically and geographically contiguous areas with similar climatic conditions) grouping of ecosystems.
Biosphere or
Ecosphere		 All life on Earth or all life plus the physical (abiotic) environment[3]
For levels larger than Biosphere or Ecosphere, see Earth's location in the Universe

More complex schemes incorporate many more levels. For example, a molecule can be viewed as a grouping of elements, and an atom can be further divided into subatomic particles (these levels are outside the scope of biological organisation). Each level can also be broken down into its own hierarchy, and specific types of these biological objects can have their own hierarchical scheme. For example, genomes can be further subdivided into a hierarchy of genes.[4]

Each level in the hierarchy can be described by its lower levels. For example, the organism may be described at any of its component levels, including the atomic, molecular, cellular, histological (tissue), organ and organ system levels. Furthermore, at every level of the hierarchy, new functions necessary for the control of life appear. These new roles are not functions that the lower level components are capable of and are thus referred to as emergent properties.

Every organism is organised, though not necessarily to the same degree.[5] An organism can not be organised at the histological (tissue) level if it is not composed of tissues in the first place.[6]

Emergence of biological organisation edit

Biological organisation is thought to have emerged in the early RNA world when RNA chains began to express the basic conditions necessary for natural selection to operate as conceived by Darwin: heritability, variation of type, and competition for limited resources. Fitness of an RNA replicator (its per capita rate of increase) would likely have been a function of adaptive capacities that were intrinsic (in the sense that they were determined by the nucleotide sequence) and the availability of resources.[7][8] The three primary adaptive capacities may have been (1) the capacity to replicate with moderate fidelity (giving rise to both heritability and variation of type); (2) the capacity to avoid decay; and (3) the capacity to acquire and process resources.[7][8] These capacities would have been determined initially by the folded configurations of the RNA replicators (see "Ribozyme") that, in turn, would be encoded in their individual nucleotide sequences. Competitive success among different RNA replicators would have depended on the relative values of these adaptive capacities. Subsequently, among more recent organisms competitive success at successive levels of biological organisation, presumably continued to depend, in a broad sense, on the relative values of these adaptive capacities.

Fundamentals edit

Empirically, a large proportion of the (complex) biological systems we observe in nature exhibit hierarchical structure. On theoretical grounds we could expect complex systems to be hierarchies in a world in which complexity had to evolve from simplicity. System hierarchies analysis performed in the 1950s,[9][10] laid the empirical foundations for a field that would be, from the 1980s, hierarchical ecology.[11][12][13][14][15]

The theoretical foundations are summarized by thermodynamics. When biological systems are modeled as physical systems, in its most general abstraction, they are thermodynamic open systems that exhibit self-organised behavior,[16] and the set/subset relations between dissipative structures can be characterized in a hierarchy.

A simpler and more direct way to explain the fundamentals of the "hierarchical organisation of life", was introduced in Ecology by Odum and others as the "Simon's hierarchical principle";[17] Simon[18] emphasized that hierarchy "emerges almost inevitably through a wide variety of evolutionary processes, for the simple reason that hierarchical structures are stable".

To motivate this deep idea, he offered his "parable" about imaginary watchmakers.

Parable of the Watchmakers

There once were two watchmakers, named Hora and Tempus, who made very fine watches. The phones in their workshops rang frequently; new customers were constantly calling them. However, Hora prospered while Tempus became poorer and poorer. In the end, Tempus lost his shop. What was the reason behind this?

The watches consisted of about 1000 parts each. The watches that Tempus made were designed such that, when he had to put down a partly assembled watch (for instance, to answer the phone), it immediately fell into pieces and had to be reassembled from the basic elements.

Hora had designed his watches so that he could put together subassemblies of about ten components each. Ten of these subassemblies could be put together to make a larger sub-assembly. Finally, ten of the larger subassemblies constituted the whole watch. Each subassembly could be put down without falling apart.

See also edit

Notes edit

  1. ^ a b Solomon, Berg & Martin 2002, pp. 9–10
  2. ^ Pavé 2006, p. 40
  3. ^ Huggett 1999
  4. ^ Pavé 2006, p. 39
  5. ^ Postlethwait & Hopson 2006, p. 7
  6. ^ Witzany, G (2014). "Biological Self-organization". International Journal of Signs and Semiotic Systems. 3 (2): 1–11. doi:10.4018/IJSSS.2014070101.
  7. ^ a b Bernstein, H; Byerly, HC; Hopf, FA; Michod, RA; Vemulapalli, GK (1983). "The Darwinian Dynamic". Quarterly Review of Biology. 58 (2): 185–207. doi:10.1086/413216. JSTOR 2828805. S2CID 83956410.
  8. ^ a b Michod RE. (2000) Darwinian Dynamics: Evolutionary Transitions in Fitness and Individuality. Princeton University Press, Princeton, New Jersey ISBN 0691050112
  9. ^ Evans 1951
  10. ^ Evans 1956
  11. ^ Margalef 1975
  12. ^ O'Neill 1986
  13. ^ Wicken & Ulanowicz 1988
  14. ^ Pumain 2006
  15. ^ Jordan & Jørgensen 2012
  16. ^ Pokrovskii, Vladimir (2020). Thermodynamics of Complex Systems: Principles and applications. IOP Publishing, Bristol, UK.
  17. ^ Simon 1969, pp. 192–229
  18. ^ Simon's texts at doi:10.1207/S15327809JLS1203_4, polaris.gseis.ucla.edu/pagre/simon July 5, 2015, at the Wayback Machine or johncarlosbaez/2011/08/29 transcriptions 2015-05-31 at the Wayback Machine

References edit

  • Evans, F. C. (1951), "Ecology and urban areal research", Scientific Monthly (73)
  • Evans, F. C. (1956), "Ecosystem as basic unit in ecology", Science, 123 (3208): 1127–8, Bibcode:1956Sci...123.1127E, doi:10.1126/science.123.3208.1127, PMID 17793430
  • Huggett, R. J. (1999). "Ecosphere, biosphere, or Gaia? What to call the global ecosystem. ECOLOGICAL SOUNDING". Global Ecology and Biogeography. 8 (6): 425–431. doi:10.1046/j.1365-2699.1999.00158.x. ISSN 1466-822X.
  • Jordan, F.; Jørgensen, S. E. (2012), Models of the Ecological Hierarchy: From Molecules to the Ecosphere, ISBN 9780444593962
  • Margalef, R. (1975), "External factors and ecosystem stability", Schweizerische Zeitschrift für Hydrologie, 37 (1): 102–117, Bibcode:1975AqSci..37..102M, doi:10.1007/BF02505181, hdl:10261/337692, S2CID 20521602
  • O'Neill, R. V. (1986), A Hierarchical Concept of Ecosystems, ISBN 0691084378
  • Pavé, Alain (2006), "Biological and Ecological Systems Hierarchical organization", in Pumain, D. (ed.), Hierarchy in Natural and Social Sciences, New York, New York: Springer-Verlag, ISBN 978-1-4020-4126-6
  • Postlethwait, John H.; Hopson, Janet L. (2006), Modern Biology, Holt, Rinehart and Winston, ISBN 0-03-065178-6
  • Pumain, D. (2006), Hierarchy in Natural and Social Sciences, ISBN 978-1-4020-4127-3
  • Simon, H. A. (1969), "The architecture of complexity", The Sciences of the Artificial, Cambridge, Massachusetts: MIT Press
  • Solomon, Eldra P.; Berg, Linda R.; Martin, Diana W. (2002), Biology (6th ed.), Brooks/Cole, ISBN 0-534-39175-3, LCCN 2001095366
  • Wicken, J. S.; Ulanowicz, R. E. (1988), "On quantifying hierarchical connections in ecology", Journal of Social and Biological Systems, 11 (3): 369–377, doi:10.1016/0140-1750(88)90066-8

External links edit

  •   Cell physiology (in Human Physiology) at Wikibooks
  •   Characteristics of life and the nature of molecules (in General Biology) at Wikibooks
  •   organization within the biosphere (in Ecology) at Wikibooks
  • .

February 16, 2024
biological, organisation, hierarchy, life, levels, organization, redirect, here, hierarchical, ordering, organization, organisms, biological, classification, evolutionary, hierarchy, organisms, interspecial, relationships, phylogenetic, tree, organisation, com. Hierarchy of life and Levels of organization redirect here For the hierarchical ordering and organization of all organisms see Biological classification For the evolutionary hierarchy of organisms and interspecial relationships see Phylogenetic tree Biological organisation is the organisation of complex biological structures and systems that define life using a reductionistic approach 1 The traditional hierarchy as detailed below extends from atoms to biospheres The higher levels of this scheme are often referred to as an ecological organisation concept or as the field hierarchical ecology source source source source A population of bees shimmers in response to a predator Each level in the hierarchy represents an increase in organisational complexity with each object being primarily composed of the previous level s basic unit 2 The basic principle behind the organisation is the concept of emergence the properties and functions found at a hierarchical level are not present and irrelevant at the lower levels The biological organisation of life is a fundamental premise for numerous areas of scientific research particularly in the medical sciences Without this necessary degree of organisation it would be much more difficult and likely impossible to apply the study of the effects of various physical and chemical phenomena to diseases and physiology body function For example fields such as cognitive and behavioral neuroscience could not exist if the brain was not composed of specific types of cells and the basic concepts of pharmacology could not exist if it was not known that a change at the cellular level can affect an entire organism These applications extend into the ecological levels as well For example DDT s direct insecticidal effect occurs at the subcellular level but affects higher levels up to and including multiple ecosystems Theoretically a change in one atom could change the entire biosphere Contents 1 Levels 2 Emergence of biological organisation 3 Fundamentals 4 See also 5 Notes 5 1 References 6 External linksLevels editSee also Integrative level nbsp The simplest unit in this hierarchy is the atom like oxygen Two or more atoms is a molecule like a dioxide Many small molecules may combine in a chemical reaction to make up a macromolecule such as a phospholipid Multiple macromolecules form a cell like a club cell A group of cells functioning together as a tissue for example Epithelial tissue Different tissues make up an organ like a lung Organs work together to form an organ system such as the Respiratory System All of the organ systems make a living organism like a lion A group of the same organism living together in an area is a population such as a pride of lions Two or more populations interacting with each other form a community for example lion and zebra populations interacting with each other Communities interacting not only with each other but also with the physical environment encompass an ecosystem such as the Savanna ecosystem All of the ecosystems make up the biosphere the area of life on Earth The simple standard biological organisation scheme from the lowest level to the highest level is as follows 1 For levels smaller than atoms see Subatomic particleAcellular levelandPre cellular level AtomsMolecule Groups of atomsBiomolecular complex Groups of bio moleculesSub cellular level Organelle Functional groups of biomolecules biochemical reactions and interactionsCellular level Cell Basic unit of all life and the grouping of organellesSuper cellular level Multicellular level Tissue Functional groups of cellsOrgan Functional groups of tissuesOrgan system Functional groups of organsEcological levels Organism The basic living system a functional grouping of the lower level components including at least one cellPopulation Groups of organisms of the same speciesGuild Interspecific groups of organisms carrying the same ecological function i e herbivores Community or biocoenosis Guilds from all biological domains and their interactions in a specific location Ecosystem Groups of organisms in conjunction with the physical abiotic environment Biome Continental scale climatically and geographically contiguous areas with similar climatic conditions grouping of ecosystems Biosphere or Ecosphere All life on Earth or all life plus the physical abiotic environment 3 For levels larger than Biosphere or Ecosphere see Earth s location in the UniverseMore complex schemes incorporate many more levels For example a molecule can be viewed as a grouping of elements and an atom can be further divided into subatomic particles these levels are outside the scope of biological organisation Each level can also be broken down into its own hierarchy and specific types of these biological objects can have their own hierarchical scheme For example genomes can be further subdivided into a hierarchy of genes 4 Each level in the hierarchy can be described by its lower levels For example the organism may be described at any of its component levels including the atomic molecular cellular histological tissue organ and organ system levels Furthermore at every level of the hierarchy new functions necessary for the control of life appear These new roles are not functions that the lower level components are capable of and are thus referred to as emergent properties Every organism is organised though not necessarily to the same degree 5 An organism can not be organised at the histological tissue level if it is not composed of tissues in the first place 6 Emergence of biological organisation editBiological organisation is thought to have emerged in the early RNA world when RNA chains began to express the basic conditions necessary for natural selection to operate as conceived by Darwin heritability variation of type and competition for limited resources Fitness of an RNA replicator its per capita rate of increase would likely have been a function of adaptive capacities that were intrinsic in the sense that they were determined by the nucleotide sequence and the availability of resources 7 8 The three primary adaptive capacities may have been 1 the capacity to replicate with moderate fidelity giving rise to both heritability and variation of type 2 the capacity to avoid decay and 3 the capacity to acquire and process resources 7 8 These capacities would have been determined initially by the folded configurations of the RNA replicators see Ribozyme that in turn would be encoded in their individual nucleotide sequences Competitive success among different RNA replicators would have depended on the relative values of these adaptive capacities Subsequently among more recent organisms competitive success at successive levels of biological organisation presumably continued to depend in a broad sense on the relative values of these adaptive capacities Fundamentals editEmpirically a large proportion of the complex biological systems we observe in nature exhibit hierarchical structure On theoretical grounds we could expect complex systems to be hierarchies in a world in which complexity had to evolve from simplicity System hierarchies analysis performed in the 1950s 9 10 laid the empirical foundations for a field that would be from the 1980s hierarchical ecology 11 12 13 14 15 The theoretical foundations are summarized by thermodynamics When biological systems are modeled as physical systems in its most general abstraction they are thermodynamic open systems that exhibit self organised behavior 16 and the set subset relations between dissipative structures can be characterized in a hierarchy A simpler and more direct way to explain the fundamentals of the hierarchical organisation of life was introduced in Ecology by Odum and others as the Simon s hierarchical principle 17 Simon 18 emphasized that hierarchy emerges almost inevitably through a wide variety of evolutionary processes for the simple reason that hierarchical structures are stable To motivate this deep idea he offered his parable about imaginary watchmakers Parable of the WatchmakersThere once were two watchmakers named Hora and Tempus who made very fine watches The phones in their workshops rang frequently new customers were constantly calling them However Hora prospered while Tempus became poorer and poorer In the end Tempus lost his shop What was the reason behind this The watches consisted of about 1000 parts each The watches that Tempus made were designed such that when he had to put down a partly assembled watch for instance to answer the phone it immediately fell into pieces and had to be reassembled from the basic elements Hora had designed his watches so that he could put together subassemblies of about ten components each Ten of these subassemblies could be put together to make a larger sub assembly Finally ten of the larger subassemblies constituted the whole watch Each subassembly could be put down without falling apart See also editAbiogenesis Cell theory Cellular differentiation Composition of the human body Evolution of biological complexity Evolutionary biology Gaia hypothesis Hierarchy theory Holon philosophy Human ecology Level of analysis Living systems Self organization Spontaneous order Structuralism biology Timeline of the evolutionary history of lifeNotes edit a b Solomon Berg amp Martin 2002 pp 9 10 Pave 2006 p 40 Huggett 1999 Pave 2006 p 39 Postlethwait amp Hopson 2006 p 7 Witzany G 2014 Biological Self organization International Journal of Signs and Semiotic Systems 3 2 1 11 doi 10 4018 IJSSS 2014070101 a b Bernstein H Byerly HC Hopf FA Michod RA Vemulapalli GK 1983 The Darwinian Dynamic Quarterly Review of Biology 58 2 185 207 doi 10 1086 413216 JSTOR 2828805 S2CID 83956410 a b Michod RE 2000 Darwinian Dynamics Evolutionary Transitions in Fitness and Individuality Princeton University Press Princeton New Jersey ISBN 0691050112 Evans 1951 Evans 1956 Margalef 1975 O Neill 1986 Wicken amp Ulanowicz 1988 Pumain 2006 Jordan amp Jorgensen 2012 Pokrovskii Vladimir 2020 Thermodynamics of Complex Systems Principles and applications IOP Publishing Bristol UK Simon 1969 pp 192 229 Simon s texts at doi 10 1207 S15327809JLS1203 4 polaris gseis ucla edu pagre simon Archived July 5 2015 at the Wayback Machine or johncarlosbaez 2011 08 29 transcriptions Archived 2015 05 31 at the Wayback Machine References edit Evans F C 1951 Ecology and urban areal research Scientific Monthly 73 Evans F C 1956 Ecosystem as basic unit in ecology Science 123 3208 1127 8 Bibcode 1956Sci 123 1127E doi 10 1126 science 123 3208 1127 PMID 17793430 Huggett R J 1999 Ecosphere biosphere or Gaia What to call the global ecosystem ECOLOGICAL SOUNDING Global Ecology and Biogeography 8 6 425 431 doi 10 1046 j 1365 2699 1999 00158 x ISSN 1466 822X Jordan F Jorgensen S E 2012 Models of the Ecological Hierarchy From Molecules to the Ecosphere ISBN 9780444593962 Margalef R 1975 External factors and ecosystem stability Schweizerische Zeitschrift fur Hydrologie 37 1 102 117 Bibcode 1975AqSci 37 102M doi 10 1007 BF02505181 hdl 10261 337692 S2CID 20521602 O Neill R V 1986 A Hierarchical Concept of Ecosystems ISBN 0691084378 Pave Alain 2006 Biological and Ecological Systems Hierarchical organization in Pumain D ed Hierarchy in Natural and Social Sciences New York New York Springer Verlag ISBN 978 1 4020 4126 6 Postlethwait John H Hopson Janet L 2006 Modern Biology Holt Rinehart and Winston ISBN 0 03 065178 6 Pumain D 2006 Hierarchy in Natural and Social Sciences ISBN 978 1 4020 4127 3 Simon H A 1969 The architecture of complexity The Sciences of the Artificial Cambridge Massachusetts MIT Press Solomon Eldra P Berg Linda R Martin Diana W 2002 Biology 6th ed Brooks Cole ISBN 0 534 39175 3 LCCN 2001095366 Wicken J S Ulanowicz R E 1988 On quantifying hierarchical connections in ecology Journal of Social and Biological Systems 11 3 369 377 doi 10 1016 0140 1750 88 90066 8External links edit nbsp Cell physiology in Human Physiology at Wikibooks nbsp Characteristics of life and the nature of molecules in General Biology at Wikibooks nbsp organization within the biosphere in Ecology at Wikibooks 2011 s theoretical mathematical discussion Portals nbsp Biology nbsp Earth sciences nbsp Environment Retrieved from https en wikipedia org w index php title Biological organisation amp oldid 1202256839, wikipedia, wiki, book, books, library,

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