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Bergmann's rule

January 01, 1970

Bergmann's rule is an ecogeographical rule that states that within a broadly distributed taxonomic clade, populations and species of larger size are found in colder environments, while populations and species of smaller size are found in warmer regions. The rule derives from the relationship between size in linear dimensions meaning that both height and volume will increase in colder environments. Bergmann's rule only describes the overall size of the animals, but does not include body proportions like Allen's rule does.

Bergmann's rule - Penguins on the Earth (mass m, height h)[1]

Although originally formulated in relation to species within a genus, it has often been recast in relation to populations within a species. It is also often cast in relation to latitude. It is possible that the rule also applies to some plants, such as Rapicactus.

The rule is named after nineteenth century German biologist Carl Bergmann, who described the pattern in 1847, although he was not the first to notice it. Bergmann's rule is most often applied to mammals and birds which are endotherms, but some researchers have also found evidence for the rule in studies of ectothermic species,[2][3] such as the ant Leptothorax acervorum. While Bergmann's rule appears to hold true for many mammals and birds, there are exceptions.[4][5][6]

Larger-bodied animals tend to conform more closely to Bergmann's rule than smaller-bodied animals, at least up to certain latitudes. This perhaps reflects a reduced ability to avoid stressful environments, such as by burrowing.[7] In addition to being a general pattern across space, Bergmann's rule has been reported in populations over historical and evolutionary time when exposed to varying thermal regimes.[8][9][10] In particular, temporary, reversible dwarfing of mammals has been noted during two relatively brief upward excursions in temperature during the Paleogene: the Paleocene-Eocene thermal maximum[11] and the Eocene Thermal Maximum 2.[12]

Examples edit

 
Bergmann's rule is an ecologic principle stating that body mass increases with colder climate. Data illustrating such a relationship are shown for moose (Eurasian elk) in Sweden.[13]

Humans edit

Human populations near the poles, including the Inuit, Aleut, and Sami people, are on average heavier than populations from mid-latitudes, consistent with Bergmann's rule.[14] They also tend to have shorter limbs and broader trunks, consistent with Allen's rule.[14] According to Marshall T. Newman in 1953, Native American populations are generally consistent with Bergmann's rule although the cold climate and small body size combination of the Eastern Inuit, Canoe Nation, Yuki people, Andes natives and Harrison Lake Lillooet runs contrary to the expectations of Bergmann's rule.[15] Newman contends that Bergmann's rule holds for the populations of Eurasia, but it does not hold for those of sub-Saharan Africa.[15]

Human populations also show a decrease in stature with an increase in mean annual temperature.[16] Bergmann's rule holds for Africans with the pygmy phenotype and other pygmy peoples. These populations show a shorter stature and smaller body size due to an adaptation to hotter and more humid environments.[17] With elevated environmental humidity, evaporative cooling (sweating) is a less effective way to dissipate body heat, but a higher surface area to volume ratio should provide a slight advantage through passive convective heat loss.

Birds edit

A 2019 study of changes in the morphology of migratory birds used bodies of birds which had collided with buildings in Chicago from 1978 to 2016. The length of birds' lower leg bones (an indicator of body size) shortened by an average of 2.4% and their wings lengthened by 1.3%. A similar study published in 2021 used measurements of 77 nonmigratory bird species captured live for banding in lowland Amazon rainforest. Between 1979 and 2019, all study species have gotten smaller on average, by up to 2% per decade. The morphological changes are regarded as resulting from global warming, and may demonstrate an example of evolutionary change following Bergmann's rule.[18][19][20][21]

Reptiles edit

Bergmann's rule has been reported to be vaguely followed by female crocodilians.[22][23] However, for turtles[24] or lizards[25] the rule's validity has not been supported.

Invertebrates edit

Evidence of Bergmann's rule has been found in marine copepods.[26]

Plants edit

Bergmann's rule cannot generally be applied to plants.[27] Regarding Cactaceae, the case of the saguaro (Carnegiea gigantea), once described as "a botanical Bergmann trend",[28] has instead been shown to depend on rainfall, particularly winter precipitation, and not temperature.[29] Members of the genus Rapicactus are larger in cooler environments, as their stem diameter increases with altitude and particularly with latitude. However, since Rapicactus grow in a distributional area in which average precipitation tends to diminish at higher latitudes, and their body size is not conditioned by climatic variables, this could suggest a possible Bergmann trend.[30]

Explanations edit

 
Bergmann's rule illustrated by red foxes from northern and southern populations

The earliest explanation, given by Bergmann when originally formulating the rule, is that larger animals have a lower surface area to volume ratio than smaller animals, so they radiate less body heat per unit of mass, and therefore stay warmer in cold climates. Warmer climates impose the opposite problem: body heat generated by metabolism needs to be dissipated quickly rather than stored within.[31]

Thus, the higher surface area-to-volume ratio of smaller animals in hot and dry climates facilitates heat loss through the skin and helps cool the body. It is important to note that when analyzing Bergmann's Rule in the field that groups of populations being studied are of different thermal environments, and also have been separated long enough to genetically differentiate in response to these thermal conditions.[31] The relationship between stature and mean annual temperature can be explained by modeling any shape that is increasing in any dimension. As you increase the height of a shape, its surface area-to-volume ratio will decrease. Modeling a person's trunk and limbs as cylinders shows a 17% decrease in surface area-to-volume ratio from a person who is five feet tall to a person who is six feet tall even at the same body mass index (BMI).

In marine crustaceans, it has been proposed that an increase in size with latitude is observed because decreasing temperature results in increased cell size and increased life span, both of which lead to an increase in maximum body size (continued growth throughout life is characteristic of crustaceans).[3] The size trend has been observed in hyperiid and gammarid amphipods, copepods, stomatopods, mysids, and planktonic euphausiids, both in comparisons of related species as well as within widely distributed species.[3] Deep-sea gigantism is observed in some of the same groups, possibly for the same reasons.[3] An additional factor in aquatic species may be the greater dissolved oxygen concentration at lower temperature. This view is supported by the reduced size of crustaceans in high-altitude lakes.[32] A further possible influence on invertebrates is reduced predation pressure at high latitude.[33] A study of shallow water brachiopods found that predation was reduced in polar areas relative to temperate latitudes (the same trend was not found in deep water, where predation is also reduced, or in comparison of tropical and temperate brachiopods, perhaps because tropical brachiopods have evolved to smaller sizes to successfully evade predation).[33]

Hesse's rule edit

In 1937 German zoologist and ecologist Richard Hesse proposed an extension of Bergmann's rule. Hesse's rule, also known as the heart–weight rule, states that species inhabiting colder climates have a larger heart in relation to body weight than closely related species inhabiting warmer climates.[34]

Criticism edit

In a 1986 study, Valerius Geist claimed Bergmann's rule to be false: the correlation with temperature is spurious; instead, Geist found that body size is proportional to the duration of the annual productivity pulse, or food availability per animal during the growing season.[35]

Because many factors can affect body size, there are many critics of Bergmann's rule. Some[who?] believe that latitude itself is a poor predictor of body mass. Examples of other selective factors that may contribute to body mass changes are the size of food items available, effects of body size on success as a predator, effects of body size on vulnerability to predation, and resource availability. For example, if an organism is adapted to tolerate cold temperatures, it may also tolerate periods of food shortage, due to correlation between cold temperature and food scarcity.[5] A larger organism can rely on its greater fat stores to provide the energy needed for survival as well being able to procreate for longer periods.

Resource availability is a major constraint on the overall success of many organisms. Resource scarcity can limit the total number of organisms in a habitat, and over time can also cause organisms to adapt by becoming smaller in body size. Resource availability thus becomes a modifying restraint on Bergmann's Rule.[36]

Some examinations of the fossil record have found contradictions to the rule. For example, during the Pleistocene, hippopotamuses in Europe tended to get smaller during colder and drier intervals.[37] Further, a 2024 study found the size of dinosaurs did not increase at northern Arctic latitudes, and that the rule was "only applicable to a subset of homeothermic animals" with regard to temperature when all other climatic variables are ignored.[38]

See also edit

References edit

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  2. ^ Olalla-Tárraga, Miguel Á.; Rodríguez, Miguel Á.; 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. Bibcode:2006JBiog..33..781O. doi:10.1111/j.1365-2699.2006.01435.x. S2CID 59440368.
  3. ^ a b c d 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.
  4. ^ Meiri, S.; Dayan, T. (2003-03-20). "On the validity of Bergmann's rule". Journal of Biogeography. 30 (3): 331–351. Bibcode:2003JBiog..30..331M. doi:10.1046/j.1365-2699.2003.00837.x. S2CID 11954818.
  5. ^ a b 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.
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  16. ^ Roberts, DF (1954). "Body weight, race and climate". American Journal of Physical Anthropology. 11 (4): 533–558. doi:10.1002/ajpa.1330110404. PMID 13124471.
  17. ^ Dominy, Nathaniel; Perry, George (February 25, 2009). "Evolution of the human pygmy phenotype".
  18. ^ Vlamis, K. (4 December 2019). "Birds 'shrinking' as the climate warms". BBC News. Retrieved 5 December 2019.
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  23. ^ Georgiou, A. (12 March 2020). "Crocodilians, Which Have Walked Earth for Nearly 100 Million Years, Are Survivors of Mass Extinctions and May Be Able to Adapt to Climate Change". newsweek.com. Newsweek. Retrieved 2020-03-13.
  24. ^ Angielczyk, K.D.; Burroughs, R.W.; Feldman, C.R. (2015). "Do turtles follow the rules? Latitudinal gradients in species richness, body size, and geographic range area of the world's turtles". Journal of Experimental Zoology Part B: Molecular and Developmental Evolution. 324 (3): 270–294. Bibcode:2015JEZB..324..270A. doi:10.1002/jez.b.22602. PMID 25588662.
  25. ^ Pincheira-Donoso, D.; Hodgson, D.J.; Tregenza, T. (2008). "The evolution of body size under environmental gradients in ectotherms: why should Bergmann's rule apply to lizards?". BMC Evolutionary Biology. 8 (68): 68. Bibcode:2008BMCEE...8...68P. doi:10.1186/1471-2148-8-68. PMC 2268677. PMID 18304333.
  26. ^ Campbell, M.D.; et al. (2021-08-21). "Testing Bergmann's Rule in marine copepods". Ecography. 44 (9): 1283–1295. Bibcode:2021Ecogr..44.1283C. doi:10.1111/ecog.05545. hdl:10072/407178. S2CID 238701490.
  27. ^ Moles, A. T.; Warton, D. I.; Warman, L.; Swenson, N. G.; Laffan, S. W.; Zanne, A. E.; Pitman, A.; Hemmings, F. A.; Leishman, M. R. (2009-09-01). "Global patterns in plant height". Journal of Ecology. 97 (5): 923–932. Bibcode:2009JEcol..97..923M. doi:10.1111/j.1365-2745.2009.01526.x.
  28. ^ Niering, W.A.; Whittaker, R.H.; Lowe, C.H. (1963). "The saguaro: a population in relation to environment". Science. 142 (3588): 15–23. Bibcode:1963Sci...142...15N. doi:10.1126/science.142.3588.15. PMID 17812501.
  29. ^ Drezner, T. D. (2003-03-01). "Revisiting Bergmann's rule for saguaros (Carnegiea gigantea (Engelm.) Britt. and Rose): stem diameter patterns over space". Journal of Biogeography. 30 (3): 353–359. doi:10.1046/j.1365-2699.2003.00834.x. S2CID 82276407.
  30. ^ Donati, D.; Bianchi, C.; Pezzi, G.; Conte, L.; Hofer, A.; Chiarucci, A. (2016). "Biogeography and ecology of the genus Turbinicarpus (Cactaceae): environmental controls of taxa richness and morphology". Systematics and Biodiversity. 15 (4): 361–371. doi:10.1080/14772000.2016.1251504. S2CID 90330480.
  31. ^ a b Brown, James H.; Lee, Anthony K. (January 1969). "Bergmann's Rule and Climatic Adaptation in Woodrats (Neotoma)". Evolution. 23 (2): 329–338. doi:10.2307/2406795. JSTOR 2406795. PMID 28562890.
  32. ^ Peck, L. S.; Chapelle, G. (2003). "Reduced oxygen at high altitude limits maximum size". Proceedings of the Royal Society of London. Series B: Biological Sciences. 270 (suppl. 2): S166–S167. doi:10.1098/rsbl.2003.0054. PMC 1809933. PMID 14667371.
  33. ^ a b Harper, E. M.; Peck, L. S. (2016). "Latitudinal and depth gradients in marine predation pressure". Global Ecology and Biogeography. 25 (6): 670–678. Bibcode:2016GloEB..25..670H. doi:10.1111/geb.12444.
  34. ^ Baum, Steven (January 20, 1997). . Glossary of Oceanography and the Related Geosciences with References. Texas Center for Climate Studies, Texas A&M University. Archived from the original on December 22, 2010. Retrieved 2011-01-09.
  35. ^ Geist, Valerius (April 1987). "Bergmann's rule is invalid". Canadian Journal of Zoology. 65 (4): 1035–1038. doi:10.1139/z87-164.
  36. ^ Clauss, Marcus; Dittmann, Marei T.; Müller, Dennis W. H.; et al. (October 2013). "Bergmann′s rule in mammals: A cross-species interspecific pattern" (PDF). Oikos. 122 (10): 1465–1472. Bibcode:2013Oikos.122.1465C. doi:10.1111/j.1600-0706.2013.00463.x. S2CID 44183222.
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  38. ^ Grimes, Marmian; Fairbanks, University of Alaska. "Dinosaur study challenges Bergmann's rule". phys.org. Retrieved 2024-04-09.

Notes edit

  • Bergmann, Carl (1847). "Über die Verhältnisse der Wärmeökonomie der Thiere zu ihrer Grösse". Göttinger Studien. 3 (1): 595–708.
  • Roberts DF (1953). "Body weight, race and climate". American Journal of Physical Anthropology. 11 (4): 533–558. doi:10.1002/ajpa.1330110404. PMID 13124471.
  • Roberts DF (1978). Climate and Human Variability (2nd ed.). Menlo Park, CA: Cummings. ISBN 9780846566250.
  • Ruff CB (1994). "Morphological adaptation to climate in modern and fossil hominids". Yearbook of Physical Anthropology. 37: 65–107. doi:10.1002/ajpa.1330370605.
  • Schreider E (1950). "Geographical distribution of the body-weight/body-surface ratio". Nature. 165 (4190): 286. Bibcode:1950Natur.165..286S. doi:10.1038/165286b0. PMID 15410342.

January 01, 1970
bergmann, rule, ecogeographical, rule, that, states, that, within, broadly, distributed, taxonomic, clade, populations, species, larger, size, found, colder, environments, while, populations, species, smaller, size, found, warmer, regions, rule, derives, from,. Bergmann s rule is an ecogeographical rule that states that within a broadly distributed taxonomic clade populations and species of larger size are found in colder environments while populations and species of smaller size are found in warmer regions The rule derives from the relationship between size in linear dimensions meaning that both height and volume will increase in colder environments Bergmann s rule only describes the overall size of the animals but does not include body proportions like Allen s rule does Bergmann s rule Penguins on the Earth mass m height h 1 Although originally formulated in relation to species within a genus it has often been recast in relation to populations within a species It is also often cast in relation to latitude It is possible that the rule also applies to some plants such as Rapicactus The rule is named after nineteenth century German biologist Carl Bergmann who described the pattern in 1847 although he was not the first to notice it Bergmann s rule is most often applied to mammals and birds which are endotherms but some researchers have also found evidence for the rule in studies of ectothermic species 2 3 such as the ant Leptothorax acervorum While Bergmann s rule appears to hold true for many mammals and birds there are exceptions 4 5 6 Larger bodied animals tend to conform more closely to Bergmann s rule than smaller bodied animals at least up to certain latitudes This perhaps reflects a reduced ability to avoid stressful environments such as by burrowing 7 In addition to being a general pattern across space Bergmann s rule has been reported in populations over historical and evolutionary time when exposed to varying thermal regimes 8 9 10 In particular temporary reversible dwarfing of mammals has been noted during two relatively brief upward excursions in temperature during the Paleogene the Paleocene Eocene thermal maximum 11 and the Eocene Thermal Maximum 2 12 Contents 1 Examples 1 1 Humans 1 2 Birds 1 3 Reptiles 1 4 Invertebrates 1 5 Plants 2 Explanations 3 Hesse s rule 4 Criticism 5 See also 6 References 7 NotesExamples edit nbsp Bergmann s rule is an ecologic principle stating that body mass increases with colder climate Data illustrating such a relationship are shown for moose Eurasian elk in Sweden 13 Humans edit Human populations near the poles including the Inuit Aleut and Sami people are on average heavier than populations from mid latitudes consistent with Bergmann s rule 14 They also tend to have shorter limbs and broader trunks consistent with Allen s rule 14 According to Marshall T Newman in 1953 Native American populations are generally consistent with Bergmann s rule although the cold climate and small body size combination of the Eastern Inuit Canoe Nation Yuki people Andes natives and Harrison Lake Lillooet runs contrary to the expectations of Bergmann s rule 15 Newman contends that Bergmann s rule holds for the populations of Eurasia but it does not hold for those of sub Saharan Africa 15 Human populations also show a decrease in stature with an increase in mean annual temperature 16 Bergmann s rule holds for Africans with the pygmy phenotype and other pygmy peoples These populations show a shorter stature and smaller body size due to an adaptation to hotter and more humid environments 17 With elevated environmental humidity evaporative cooling sweating is a less effective way to dissipate body heat but a higher surface area to volume ratio should provide a slight advantage through passive convective heat loss Birds edit A 2019 study of changes in the morphology of migratory birds used bodies of birds which had collided with buildings in Chicago from 1978 to 2016 The length of birds lower leg bones an indicator of body size shortened by an average of 2 4 and their wings lengthened by 1 3 A similar study published in 2021 used measurements of 77 nonmigratory bird species captured live for banding in lowland Amazon rainforest Between 1979 and 2019 all study species have gotten smaller on average by up to 2 per decade The morphological changes are regarded as resulting from global warming and may demonstrate an example of evolutionary change following Bergmann s rule 18 19 20 21 Reptiles edit Bergmann s rule has been reported to be vaguely followed by female crocodilians 22 23 However for turtles 24 or lizards 25 the rule s validity has not been supported Invertebrates edit Evidence of Bergmann s rule has been found in marine copepods 26 Plants edit Bergmann s rule cannot generally be applied to plants 27 Regarding Cactaceae the case of the saguaro Carnegiea gigantea once described as a botanical Bergmann trend 28 has instead been shown to depend on rainfall particularly winter precipitation and not temperature 29 Members of the genus Rapicactus are larger in cooler environments as their stem diameter increases with altitude and particularly with latitude However since Rapicactus grow in a distributional area in which average precipitation tends to diminish at higher latitudes and their body size is not conditioned by climatic variables this could suggest a possible Bergmann trend 30 Explanations edit nbsp Bergmann s rule illustrated by red foxes from northern and southern populations The earliest explanation given by Bergmann when originally formulating the rule is that larger animals have a lower surface area to volume ratio than smaller animals so they radiate less body heat per unit of mass and therefore stay warmer in cold climates Warmer climates impose the opposite problem body heat generated by metabolism needs to be dissipated quickly rather than stored within 31 Thus the higher surface area to volume ratio of smaller animals in hot and dry climates facilitates heat loss through the skin and helps cool the body It is important to note that when analyzing Bergmann s Rule in the field that groups of populations being studied are of different thermal environments and also have been separated long enough to genetically differentiate in response to these thermal conditions 31 The relationship between stature and mean annual temperature can be explained by modeling any shape that is increasing in any dimension As you increase the height of a shape its surface area to volume ratio will decrease Modeling a person s trunk and limbs as cylinders shows a 17 decrease in surface area to volume ratio from a person who is five feet tall to a person who is six feet tall even at the same body mass index BMI In marine crustaceans it has been proposed that an increase in size with latitude is observed because decreasing temperature results in increased cell size and increased life span both of which lead to an increase in maximum body size continued growth throughout life is characteristic of crustaceans 3 The size trend has been observed in hyperiid and gammarid amphipods copepods stomatopods mysids and planktonic euphausiids both in comparisons of related species as well as within widely distributed species 3 Deep sea gigantism is observed in some of the same groups possibly for the same reasons 3 An additional factor in aquatic species may be the greater dissolved oxygen concentration at lower temperature This view is supported by the reduced size of crustaceans in high altitude lakes 32 A further possible influence on invertebrates is reduced predation pressure at high latitude 33 A study of shallow water brachiopods found that predation was reduced in polar areas relative to temperate latitudes the same trend was not found in deep water where predation is also reduced or in comparison of tropical and temperate brachiopods perhaps because tropical brachiopods have evolved to smaller sizes to successfully evade predation 33 Hesse s rule editIn 1937 German zoologist and ecologist Richard Hesse proposed an extension of Bergmann s rule Hesse s rule also known as the heart weight rule states that species inhabiting colder climates have a larger heart in relation to body weight than closely related species inhabiting warmer climates 34 Criticism editIn a 1986 study Valerius Geist claimed Bergmann s rule to be false the correlation with temperature is spurious instead Geist found that body size is proportional to the duration of the annual productivity pulse or food availability per animal during the growing season 35 Because many factors can affect body size there are many critics of Bergmann s rule Some who believe that latitude itself is a poor predictor of body mass Examples of other selective factors that may contribute to body mass changes are the size of food items available effects of body size on success as a predator effects of body size on vulnerability to predation and resource availability For example if an organism is adapted to tolerate cold temperatures it may also tolerate periods of food shortage due to correlation between cold temperature and food scarcity 5 A larger organism can rely on its greater fat stores to provide the energy needed for survival as well being able to procreate for longer periods Resource availability is a major constraint on the overall success of many organisms Resource scarcity can limit the total number of organisms in a habitat and over time can also cause organisms to adapt by becoming smaller in body size Resource availability thus becomes a modifying restraint on Bergmann s Rule 36 Some examinations of the fossil record have found contradictions to the rule For example during the Pleistocene hippopotamuses in Europe tended to get smaller during colder and drier intervals 37 Further a 2024 study found the size of dinosaurs did not increase at northern Arctic latitudes and that the rule was only applicable to a subset of homeothermic animals with regard to temperature when all other climatic variables are ignored 38 See also editAnimal migration Biogeography Gene flow GigantothermyReferences edit FRYDRYSEK Karel 2019 Biomechanika 1 Ostrava Czech Republic VSB Technical University of Ostrava Faculty of Mechanical Engineering Department of Applied Mechanics pp 337 338 ISBN 978 80 248 4263 9 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 Bibcode 2006JBiog 33 781O doi 10 1111 j 1365 2699 2006 01435 x S2CID 59440368 a b c d 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 Bibcode 2003JBiog 30 331M doi 10 1046 j 1365 2699 2003 00837 x S2CID 11954818 a b 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 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exposed to climate driven body size changes Boreas 42 1 194 209 doi 10 1111 j 1502 3885 2012 00285 x ISSN 0300 9483 S2CID 128992364 Retrieved 20 January 2024 via Wiley Online Library Grimes Marmian Fairbanks University of Alaska Dinosaur study challenges Bergmann s rule phys org Retrieved 2024 04 09 Notes editBergmann Carl 1847 Uber die Verhaltnisse der Warmeokonomie der Thiere zu ihrer Grosse Gottinger Studien 3 1 595 708 Roberts DF 1953 Body weight race and climate American Journal of Physical Anthropology 11 4 533 558 doi 10 1002 ajpa 1330110404 PMID 13124471 Roberts DF 1978 Climate and Human Variability 2nd ed Menlo Park CA Cummings ISBN 9780846566250 Ruff CB 1994 Morphological adaptation to climate in modern and fossil hominids Yearbook of Physical Anthropology 37 65 107 doi 10 1002 ajpa 1330370605 Schreider E 1950 Geographical distribution of the body weight body surface ratio Nature 165 4190 286 Bibcode 1950Natur 165 286S doi 10 1038 165286b0 PMID 15410342 Retrieved from https en wikipedia org w index php title Bergmann 27s rule amp oldid 1218252445, wikipedia, wiki, book, books, library,

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