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Biological rules

December 08, 2023

A biological rule or biological law is a generalized law, principle, or rule of thumb formulated to describe patterns observed in living organisms. Biological rules and laws are often developed as succinct, broadly applicable ways to explain complex phenomena or salient observations about the ecology and biogeographical distributions of plant and animal species around the world, though they have been proposed for or extended to all types of organisms. Many of these regularities of ecology and biogeography are named after the biologists who first described them.[1][2]

The pygmy mammoth is an example of insular dwarfism, a case of Foster's rule, its unusually small body size an adaptation to the limited resources of its island home.

From the birth of their science, biologists have sought to explain apparent regularities in observational data. In his biology, Aristotle inferred rules governing differences between live-bearing tetrapods (in modern terms, terrestrial placental mammals). Among his rules were that brood size decreases with adult body mass, while lifespan increases with gestation period and with body mass, and fecundity decreases with lifespan. Thus, for example, elephants have smaller and fewer broods than mice, but longer lifespan and gestation.[3] Rules like these concisely organized the sum of knowledge obtained by early scientific measurements of the natural world, and could be used as models to predict future observations. Among the earliest biological rules in modern times are those of Karl Ernst von Baer (from 1828 onwards) on embryonic development,[4] and of Constantin Wilhelm Lambert Gloger on animal pigmentation, in 1833.[5] There is some scepticism among biogeographers about the usefulness of general rules. For example, J.C. Briggs, in his 1987 book Biogeography and Plate Tectonics, comments that while Willi Hennig's rules on cladistics "have generally been helpful", his progression rule is "suspect".[6]

List of biological rules edit

 
Bergmann's rule states that body mass increases with colder climate, as here in Swedish moose.[7]
  • Allen's rule states that the body shapes and proportions of endotherms vary by climatic temperature by either minimizing exposed surface area to minimize heat loss in cold climates or maximizing exposed surface area to maximize heat loss in hot climates. It is named after Joel Asaph Allen who described it in 1877.[8][9]
  • Bateson's rule states that extra legs are mirror-symmetric with their neighbours, such as when an extra leg appears in an insect's leg socket. It is named after the pioneering geneticist William Bateson who observed it in 1894. It appears to be caused by the leaking of positional signals across the limb-limb interface, so that the extra limb's polarity is reversed.[10]
  • Bergmann's rule states that within a broadly distributed taxonomic clade, populations and species of larger size are found in colder environments, and species of smaller size are found in warmer regions. It applies with exceptions to many mammals and birds. It was named after Carl Bergmann who described it in 1847.[11][12][13][14][15]
  • Cope's rule states that animal population lineages tend to increase in body size over evolutionary time. The rule is named for the palaeontologist Edward Drinker Cope.[16][17]
  • Deep-sea gigantism, noted in 1880 by Henry Nottidge Moseley,[18] states that deep-sea animals are larger than their shallow-water counterparts. In the case of marine crustaceans, it has been proposed that the increase in size with depth occurs for the same reason as the increase in size with latitude (Bergmann's rule): both trends involve increasing size with decreasing temperature.[12]
 
Dollo's law of irreversibility asserts that once an organism has evolved in a certain way, it will not return exactly to a previous form.
  • Dollo's law of irreversibility, proposed in 1893[19] by French-born Belgian paleontologist Louis Dollo states that "an organism never returns exactly to a former state, even if it finds itself placed in conditions of existence identical to those in which it has previously lived ... it always keeps some trace of the intermediate stages through which it has passed."[20][21][22]
  • Eichler's rule states that the taxonomic diversity of parasites co-varies with the diversity of their hosts. It was observed in 1942 by Wolfdietrich Eichler, and is named for him.[23][24][25]
     
    Emery's rule states that insect social parasites like cuckoo bumblebees choose closely related hosts, in this case other bumblebees.
  • Emery's rule, noticed by Carlo Emery, states that insect social parasites are often closely related to their hosts, such as being in the same genus.[26][27]
  • Foster's rule, the island rule, or the island effect states that members of a species get smaller or bigger depending on the resources available in the environment.[28][29][30] The rule was first stated by J. Bristol Foster in 1964 in the journal Nature, in an article titled "The evolution of mammals on islands".[31]
  • Gause's law or the competitive exclusion principle, named for Georgy Gause, states that two species competing for the same resource cannot coexist at constant population values. The competition leads either to the extinction of the weaker competitor or to an evolutionary or behavioral shift toward a different ecological niche.[32]
  • Gloger's rule states that within a species of endotherms, more heavily pigmented forms tend to be found in more humid environments, e.g. near the equator. It was named after the zoologist Constantin Wilhelm Lambert Gloger, who described it in 1833.[5][33]
  • Haldane's rule states that if in a species hybrid only one sex is sterile, that sex is usually the heterogametic sex. The heterogametic sex is the one with two different sex chromosomes; in mammals, this is the male, with XY chromosomes. It is named after J.B.S. Haldane.[34]
  • Hamilton's rule states that genes should increase in frequency when the relatedness of a recipient to an actor, multiplied by the benefit to the recipient, exceeds the reproductive cost to the actor. This is a prediction from the theory of kin selection formulated by W. D. Hamilton.[35]
  • Harrison's rule states that parasite body sizes co-vary with those of their hosts. He proposed the rule for lice,[36] but later authors have shown that it works equally well for many other groups of parasite including barnacles, nematodes,[37][38] fleas, flies, mites, and ticks, and for the analogous case of small herbivores on large plants.[39][40][41]
  • Hennig's progression rule states that when considering a group of species in cladistics, the species with the most primitive characters are found within the earliest part of the area, which will be the center of origin of that group. It is named for Willi Hennig, who devised the rule.[6][42]
  • Jordan's rule states that there is an inverse relationship between water temperature and meristic characteristics such as the number of fin rays, vertebrae, or scale numbers, which are seen to increase with decreasing temperature. It is named after the father of American ichthyology, David Starr Jordan.[43]
     
    Lack's principle matches clutch size to the largest number of young the parents can feed
  • Lack's principle, proposed by David Lack, states that "the clutch size of each species of bird has been adapted by natural selection to correspond with the largest number of young for which the parents can, on average, provide enough food".[44]
  • Rapoport's rule states that the latitudinal ranges of plants and animals are generally smaller at lower latitudes than at higher latitudes. It was named after Eduardo H. Rapoport by G. C. Stevens in 1989.[45]
  • Rensch's rule states that, across animal species within a lineage, sexual size dimorphism increases with body size when the male is the larger sex, and decreases as body size increases when the female is the larger sex. The rule applies in primates, pinnipeds (seals), and even-toed ungulates (such as cattle and deer).[46] It is named after Bernhard Rensch, who proposed it in 1950.[47]
  • Schmalhausen's law, named after Ivan Schmalhausen, states that a population at the extreme limit of its tolerance in any one aspect is more vulnerable to small differences in any other aspect. Therefore, the variance of data is not simply noise interfering with the detection of so-called "main effects", but also an indicator of stressful conditions leading to greater vulnerability.[48]
  • Thorson's rule states that benthic marine invertebrates at low latitudes tend to produce large numbers of eggs developing to pelagic (often planktotrophic [plankton-feeding]) and widely dispersing larvae, whereas at high latitudes such organisms tend to produce fewer and larger lecithotrophic (yolk-feeding) eggs and larger offspring, often by viviparity or ovoviviparity, which are often brooded.[49] It was named after Gunnar Thorson by S. A. Mileikovsky in 1971.[50]
     
     
    Williston's law states that in lineages such as the arthropods, limbs tend to become fewer and more specialised, as shown by the crayfish (right), whereas the more basal trilobites had many similar legs.
  • Van Valen's law states that the probability of extinction for species and higher taxa (such as families and orders) is constant for each group over time; groups grow neither more resistant nor more vulnerable to extinction, however old their lineage is. It is named for the evolutionary biologist Leigh Van Valen.[51]
  • von Baer's laws, discovered by Karl Ernst von Baer, state that embryos start from a common form and develop into increasingly specialised forms, so that the diversification of embryonic form mirrors the taxonomic and phylogenetic tree. Therefore, all animals in a phylum share a similar early embryo; animals in smaller taxa (classes, orders, families, genera, species) share later and later embryonic stages. This was in sharp contrast to the recapitulation theory of Johann Friedrich Meckel (and later of Ernst Haeckel), which claimed that embryos went through stages resembling adult organisms from successive stages of the scala naturae from supposedly lowest to highest levels of organisation.[52][53][4]
  • Williston's law, first noticed by Samuel Wendell Williston, states that parts in an organism tend to become reduced in number and greatly specialized in function. He had studied the dentition of vertebrates, and noted that where ancient animals had mouths with differing kinds of teeth, modern carnivores had incisors and canines specialized for tearing and cutting flesh, while modern herbivores had large molars specialized for grinding tough plant materials.[54]

See also edit

References edit

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December 08, 2023
biological, rules, biological, rule, biological, generalized, principle, rule, thumb, formulated, describe, patterns, observed, living, organisms, laws, often, developed, succinct, broadly, applicable, ways, explain, complex, phenomena, salient, observations, . A biological rule or biological law is a generalized law principle or rule of thumb formulated to describe patterns observed in living organisms Biological rules and laws are often developed as succinct broadly applicable ways to explain complex phenomena or salient observations about the ecology and biogeographical distributions of plant and animal species around the world though they have been proposed for or extended to all types of organisms Many of these regularities of ecology and biogeography are named after the biologists who first described them 1 2 The pygmy mammoth is an example of insular dwarfism a case of Foster s rule its unusually small body size an adaptation to the limited resources of its island home From the birth of their science biologists have sought to explain apparent regularities in observational data In his biology Aristotle inferred rules governing differences between live bearing tetrapods in modern terms terrestrial placental mammals Among his rules were that brood size decreases with adult body mass while lifespan increases with gestation period and with body mass and fecundity decreases with lifespan Thus for example elephants have smaller and fewer broods than mice but longer lifespan and gestation 3 Rules like these concisely organized the sum of knowledge obtained by early scientific measurements of the natural world and could be used as models to predict future observations Among the earliest biological rules in modern times are those of Karl Ernst von Baer from 1828 onwards on embryonic development 4 and of Constantin Wilhelm Lambert Gloger on animal pigmentation in 1833 5 There is some scepticism among biogeographers about the usefulness of general rules For example J C Briggs in his 1987 book Biogeography and Plate Tectonics comments that while Willi Hennig s rules on cladistics have generally been helpful his progression rule is suspect 6 List of biological rules edit nbsp Bergmann s rule states that body mass increases with colder climate as here in Swedish moose 7 Allen s rule states that the body shapes and proportions of endotherms vary by climatic temperature by either minimizing exposed surface area to minimize heat loss in cold climates or maximizing exposed surface area to maximize heat loss in hot climates It is named after Joel Asaph Allen who described it in 1877 8 9 Bateson s rule states that extra legs are mirror symmetric with their neighbours such as when an extra leg appears in an insect s leg socket It is named after the pioneering geneticist William Bateson who observed it in 1894 It appears to be caused by the leaking of positional signals across the limb limb interface so that the extra limb s polarity is reversed 10 Bergmann s rule states that within a broadly distributed taxonomic clade populations and species of larger size are found in colder environments and species of smaller size are found in warmer regions It applies with exceptions to many mammals and birds It was named after Carl Bergmann who described it in 1847 11 12 13 14 15 Cope s rule states that animal population lineages tend to increase in body size over evolutionary time The rule is named for the palaeontologist Edward Drinker Cope 16 17 Deep sea gigantism noted in 1880 by Henry Nottidge Moseley 18 states that deep sea animals are larger than their shallow water counterparts In the case of marine crustaceans it has been proposed that the increase in size with depth occurs for the same reason as the increase in size with latitude Bergmann s rule both trends involve increasing size with decreasing temperature 12 nbsp Dollo s law of irreversibility asserts that once an organism has evolved in a certain way it will not return exactly to a previous form Dollo s law of irreversibility proposed in 1893 19 by French born Belgian paleontologist Louis Dollo states that an organism never returns exactly to a former state even if it finds itself placed in conditions of existence identical to those in which it has previously lived it always keeps some trace of the intermediate stages through which it has passed 20 21 22 Eichler s rule states that the taxonomic diversity of parasites co varies with the diversity of their hosts It was observed in 1942 by Wolfdietrich Eichler and is named for him 23 24 25 nbsp Emery s rule states that insect social parasites like cuckoo bumblebees choose closely related hosts in this case other bumblebees Emery s rule noticed by Carlo Emery states that insect social parasites are often closely related to their hosts such as being in the same genus 26 27 Foster s rule the island rule or the island effect states that members of a species get smaller or bigger depending on the resources available in the environment 28 29 30 The rule was first stated by J Bristol Foster in 1964 in the journal Nature in an article titled The evolution of mammals on islands 31 Gause s law or the competitive exclusion principle named for Georgy Gause states that two species competing for the same resource cannot coexist at constant population values The competition leads either to the extinction of the weaker competitor or to an evolutionary or behavioral shift toward a different ecological niche 32 Gloger s rule states that within a species of endotherms more heavily pigmented forms tend to be found in more humid environments e g near the equator It was named after the zoologist Constantin Wilhelm Lambert Gloger who described it in 1833 5 33 Haldane s rule states that if in a species hybrid only one sex is sterile that sex is usually the heterogametic sex The heterogametic sex is the one with two different sex chromosomes in mammals this is the male with XY chromosomes It is named after J B S Haldane 34 Hamilton s rule states that genes should increase in frequency when the relatedness of a recipient to an actor multiplied by the benefit to the recipient exceeds the reproductive cost to the actor This is a prediction from the theory of kin selection formulated by W D Hamilton 35 Harrison s rule states that parasite body sizes co vary with those of their hosts He proposed the rule for lice 36 but later authors have shown that it works equally well for many other groups of parasite including barnacles nematodes 37 38 fleas flies mites and ticks and for the analogous case of small herbivores on large plants 39 40 41 Hennig s progression rule states that when considering a group of species in cladistics the species with the most primitive characters are found within the earliest part of the area which will be the center of origin of that group It is named for Willi Hennig who devised the rule 6 42 Jordan s rule states that there is an inverse relationship between water temperature and meristic characteristics such as the number of fin rays vertebrae or scale numbers which are seen to increase with decreasing temperature It is named after the father of American ichthyology David Starr Jordan 43 nbsp Lack s principle matches clutch size to the largest number of young the parents can feed Lack s principle proposed by David Lack states that the clutch size of each species of bird has been adapted by natural selection to correspond with the largest number of young for which the parents can on average provide enough food 44 Rapoport s rule states that the latitudinal ranges of plants and animals are generally smaller at lower latitudes than at higher latitudes It was named after Eduardo H Rapoport by G C Stevens in 1989 45 Rensch s rule states that across animal species within a lineage sexual size dimorphism increases with body size when the male is the larger sex and decreases as body size increases when the female is the larger sex The rule applies in primates pinnipeds seals and even toed ungulates such as cattle and deer 46 It is named after Bernhard Rensch who proposed it in 1950 47 Schmalhausen s law named after Ivan Schmalhausen states that a population at the extreme limit of its tolerance in any one aspect is more vulnerable to small differences in any other aspect Therefore the variance of data is not simply noise interfering with the detection of so called main effects but also an indicator of stressful conditions leading to greater vulnerability 48 Thorson s rule states that benthic marine invertebrates at low latitudes tend to produce large numbers of eggs developing to pelagic often planktotrophic plankton feeding and widely dispersing larvae whereas at high latitudes such organisms tend to produce fewer and larger lecithotrophic yolk feeding eggs and larger offspring often by viviparity or ovoviviparity which are often brooded 49 It was named after Gunnar Thorson by S A Mileikovsky in 1971 50 nbsp nbsp Williston s law states that in lineages such as the arthropods limbs tend to become fewer and more specialised as shown by the crayfish right whereas the more basal trilobites had many similar legs Van Valen s law states that the probability of extinction for species and higher taxa such as families and orders is constant for each group over time groups grow neither more resistant nor more vulnerable to extinction however old their lineage is It is named for the evolutionary biologist Leigh Van Valen 51 von Baer s laws discovered by Karl Ernst von Baer state that embryos start from a common form and develop into increasingly specialised forms so that the diversification of embryonic form mirrors the taxonomic and phylogenetic tree Therefore all animals in a phylum share a similar early embryo animals in smaller taxa classes orders families genera species share later and later embryonic stages This was in sharp contrast to the recapitulation theory of Johann Friedrich Meckel and later of Ernst Haeckel which claimed that embryos went through stages resembling adult organisms from successive stages of the scala naturae from supposedly lowest to highest levels of organisation 52 53 4 Williston s law first noticed by Samuel Wendell Williston states that parts in an organism tend to become reduced in number and greatly specialized in function He had studied the dentition of vertebrates and noted that where ancient animals had mouths with differing kinds of teeth modern carnivores had incisors and canines specialized for tearing and cutting flesh while modern herbivores had large molars specialized for grinding tough plant materials 54 See also editAristotle s biologyReferences edit Jorgensen Sven Erik 2002 Explanation of ecological rules and observation by application of ecosystem theory and ecological models Ecological Modelling 158 3 241 248 doi 10 1016 S0304 3800 02 00236 3 Allee W C Schmidt K P 1951 Ecological Animal Geography 2nd ed Joh Wiley amp sons pp 457 460 472 Leroi Armand Marie 2014 The Lagoon How Aristotle Invented Science Bloomsbury p 408 ISBN 978 1 4088 3622 4 a b Lovtrup Soren 1978 On von Baerian and Haeckelian Recapitulation Systematic Zoology 27 3 348 352 doi 10 2307 2412887 JSTOR 2412887 a b Gloger Constantin Wilhelm Lambert 1833 5 Abanderungsweise der einzelnen einer Veranderung durch das Klima unterworfenen Farben Das Abandern der Vogel durch Einfluss des Klimas The Evolution of Birds Through the Impact of Climate in German Breslau August Schulz pp 11 24 ISBN 978 3 8364 2744 9 OCLC 166097356 a b Briggs J C 1987 Biogeography and Plate Tectonics Elsevier p 11 ISBN 978 0 08 086851 6 Sand Hakan K Cederlund Goran R Danell Kjell June 1995 Geographical and latitudinal variation in growth patterns and adult body size of Swedish moose Alces alces Oecologia 102 4 433 442 Bibcode 1995Oecol 102 433S doi 10 1007 BF00341355 PMID 28306886 S2CID 5937734 Allen Joel Asaph 1877 The influence of Physical conditions in the genesis of species Radical Review 1 108 140 Lopez Barry Holstun 1986 Arctic Dreams Imagination and Desire in a Northern Landscape Scribner ISBN 978 0 684 18578 1 Held Lewis I Sessions Stanley K 2019 Reflections on Bateson s rule Solving an old riddle about why extra legs are mirror symmetric Journal of Experimental Zoology Part B Molecular and Developmental Evolution 332 7 219 237 doi 10 1002 jez b 22910 ISSN 1552 5007 PMID 31613418 S2CID 204704335 Olalla Tarraga Miguel A Rodriguez Miguel A Hawkins Bradford A 2006 Broad scale patterns of body size in squamate reptiles of Europe and North America Journal of Biogeography 33 5 781 793 doi 10 1111 j 1365 2699 2006 01435 x S2CID 59440368 a b Timofeev S F 2001 Bergmann s Principle and Deep Water Gigantism in Marine Crustaceans Biology Bulletin of the Russian Academy of Sciences 28 6 646 650 doi 10 1023 A 1012336823275 S2CID 28016098 Meiri S Dayan T 2003 03 20 On the validity of Bergmann s rule Journal of Biogeography 30 3 331 351 doi 10 1046 j 1365 2699 2003 00837 x S2CID 11954818 Ashton Kyle G Tracy Mark C Queiroz Alan de October 2000 Is Bergmann s Rule Valid for Mammals The American Naturalist 156 4 390 415 doi 10 1086 303400 JSTOR 10 1086 303400 PMID 29592141 S2CID 205983729 Millien Virginie Lyons S Kathleen Olson Link et al May 23 2006 Ecotypic variation in the context of global climate change Revisiting the rules Ecology Letters 9 7 853 869 doi 10 1111 j 1461 0248 2006 00928 x PMID 16796576 S2CID 13803040 Rensch B September 1948 Histological Changes Correlated with Evolutionary Changes of Body Size Evolution 2 3 218 230 doi 10 2307 2405381 JSTOR 2405381 PMID 18884663 Stanley S M March 1973 An Explanation for Cope s Rule Evolution 27 1 1 26 doi 10 2307 2407115 JSTOR 2407115 PMID 28563664 McClain Craig 2015 01 14 Why isn t the Giant Isopod larger Deep Sea News Retrieved 1 March 2018 Dollo Louis 1893 Les lois de l evolution PDF Bull Soc Belge Geol Pal Hydr VII 164 166 Gould Stephen J 1970 Dollo on Dollo s law irreversibility and the status of evolutionary laws Journal of the History of Biology 3 2 189 212 doi 10 1007 BF00137351 PMID 11609651 S2CID 45642853 Goldberg Emma E Boris Igic 2008 On phylogenetic tests of irreversible evolution Evolution 62 11 2727 2741 doi 10 1111 j 1558 5646 2008 00505 x PMID 18764918 S2CID 30703407 Collin Rachel Maria Pia Miglietta 2008 Reversing opinions on Dollo s Law Trends in Ecology amp Evolution 23 11 602 609 doi 10 1016 j tree 2008 06 013 PMID 18814933 Eichler Wolfdietrich 1942 Die Entfaltungsregel und andere Gesetzmassigkeiten in den parasitogenetischen Beziehungen der Mallophagen und anderer standiger Parasiten zu ihren Wirten PDF Zoologischer Anzeiger 136 77 83 Archived from the original PDF on 2017 03 04 Retrieved 2018 04 06 Klassen G J 1992 Coevolution a history of the macroevolutionary approach to studying host parasite associations Journal of Parasitology 78 4 573 87 doi 10 2307 3283532 JSTOR 3283532 PMID 1635016 Vas Z Csorba G Rozsa L 2012 Evolutionary co variation of host and parasite diversity the first test of Eichler s rule using parasitic lice Insecta Phthiraptera PDF Parasitology Research 111 1 393 401 doi 10 1007 s00436 012 2850 9 PMID 22350674 S2CID 14923342 Richard Deslippe 2010 Social Parasitism in Ants Nature Education Knowledge Retrieved 2010 10 29 In 1909 the taxonomist Carlo Emery made an important generalization now known as Emery s rule which states that social parasites and their hosts share common ancestry and hence are closely related to each other Emery 1909 Emery Carlo 1909 Uber den Ursprung der dulotischen parasitischen und myrmekophilen Ameisen Biologisches Centralblatt in German 29 352 362 Juan Luis Arsuaga Andy Klatt The Neanderthal s Necklace In Search of the First Thinkers Thunder s Mouth Press 2004 ISBN 1 56858 303 6 ISBN 978 1 56858 303 7 p 199 Jean Baptiste de Panafieu Patrick Gries Evolution Seven Stories Press 2007 ISBN 1 58322 784 9 ISBN 978 1 58322 784 8 p 42 Lomolino Mark V February 1985 Body Size of Mammals on Islands The Island Rule Reexamined The American Naturalist 125 2 310 316 doi 10 1086 284343 JSTOR 2461638 S2CID 84642837 Foster J B 1964 The evolution of mammals on islands Nature 202 4929 234 235 Bibcode 1964Natur 202 234F doi 10 1038 202234a0 S2CID 7870628 Hardin Garrett 1960 The competitive exclusion principle PDF Science 131 3409 1292 1297 Bibcode 1960Sci 131 1292H doi 10 1126 science 131 3409 1292 PMID 14399717 Archived from the original PDF on 2017 11 17 Retrieved 2017 01 10 Zink R M Remsen J V 1986 Evolutionary processes and patterns of geographic variation in birds Current Ornithology 4 1 69 Turelli M Orr H Allen May 1995 The Dominance Theory of Haldane s Rule Genetics 140 1 389 402 doi 10 1093 genetics 140 1 389 PMC 1206564 PMID 7635302 Queller D C Strassman J E 2002 Quick Guide Kin Selection Current Biology 12 24 R832 doi 10 1016 s0960 9822 02 01344 1 PMID 12498698 Harrison Launcelot 1915 Mallophaga from Apteryx and their significance with a note on the genus Rallicola PDF Parasitology 8 88 100 doi 10 1017 S0031182000010428 S2CID 84334233 Archived from the original PDF on 2017 11 07 Retrieved 2018 04 06 Morand S Legendre P Gardner SL Hugot JP 1996 Body size evolution of oxyurid Nematoda parasites the role of hosts Oecologia 107 2 274 282 Bibcode 1996Oecol 107 274M doi 10 1007 BF00327912 PMID 28307314 S2CID 13512689 Morand S Sorci G 1998 Determinants of life history evolution in nematodes Parasitology Today 14 5 193 196 doi 10 1016 S0169 4758 98 01223 X PMID 17040750 Harvey P H Keymer A E 1991 Comparing life histories using phylogenies Philosophical Transactions of the Royal Society B 332 1262 31 39 Bibcode 1991RSPTB 332 31H doi 10 1098 rstb 1991 0030 Morand S Hafner M S Page R D M Reed D L 2000 Comparative body size relationships in pocket gophers and their chewing lice Zoological Journal of the Linnean Society 70 2 239 249 doi 10 1111 j 1095 8312 2000 tb00209 x Johnson K P Bush S E Clayton D H 2005 Correlated evolution of host and parasite body size tests of Harrison s rule using birds and lice Evolution 59 8 1744 1753 doi 10 1111 j 0014 3820 2005 tb01823 x PMID 16329244 Centers of Origin Vicariance Biogeography The University of Arizona Geosciences Retrieved 12 October 2016 McDowall R M March 2008 Jordan s and other ecogeographical rules and the vertebral number in fishes Journal of Biogeography 35 3 501 508 doi 10 1111 j 1365 2699 2007 01823 x Lack David 1954 The regulation of animal numbers Clarendon Press Stevens G C 1989 The latitudinal gradients in geographical range how so many species co exist in the tropics American Naturalist 133 2 240 256 doi 10 1086 284913 S2CID 84158740 Fairbairn D J 1997 Allometry for Sexual Size Dimorphism Pattern and Process in the Coevolution of Body Size in Males and Females Annu Rev Ecol Syst 28 1 659 687 doi 10 1146 annurev ecolsys 28 1 659 Rensch Bernhard 1950 Die Abhangigkeit der relativen Sexualdifferenz von der Korpergrosse Bonner Zoologische Beitrage 1 58 69 Lewontin Richard Levins Richard 2000 Schmalhausen s Law Capitalism Nature Socialism 11 4 103 108 doi 10 1080 10455750009358943 S2CID 144792017 Thorson G 1957 Bottom communities sublittoral or shallow shelf In Treatise on Marine Ecology and Palaeoecology Ed J W Hedgpeth pp 461 534 Geological Society of America Mileikovsky S A 1971 Types of larval development in marine bottom invertebrates their distribution and ecological significance a reevaluation Marine Biology 19 193 213 Leigh Van Valen evolutionary theorist and paleobiology pioneer 1935 2010 University of Chicago 20 October 2010 Opitz John M Schultka Rudiger Gobbel Luminita 2006 Meckel on developmental pathology American Journal of Medical Genetics Part A 140A 2 115 128 doi 10 1002 ajmg a 31043 PMID 16353245 S2CID 30513424 Garstang Walter 1922 The Theory of Recapitulation A Critical Re statement of the Biogenetic Law Journal of the Linnean Society of London Zoology 35 232 81 101 doi 10 1111 j 1096 3642 1922 tb00464 x Williston Samuel Wendall 1914 Water Reptiles of the Past and Present Chicago University of Chicago Press Retrieved from https en wikipedia org w index php title Biological rules amp oldid 1179893022, wikipedia, wiki, book, books, library,

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