Macroevolution

From Wikipedia, the free encyclopedia

Macroevolution usually means the evolution of large-scale structures and traits that go significantly beyond the intraspecific variation found in microevolution (including speciation).[1][2][3] In other words, macroevolution is the evolution of taxa above the species level (genera, families, orders, etc.).[4]

Macroevolution is often thought to require the evolution of completely new structures such as entirely new organs. However, fundamentally novel structures are not necessary for dramatic evolutionary change. For instance, the evolution of mammal diversity in the past 100 million years has not required any major innovation.[5] All of this diversity can be explained by modification of existing organs, such as the evolution of elephant tusks from canine teeth.

Origin and changing meaning of the term[edit]

Philiptschenko[4] distinguished between microevolution and macroevolution because he rejected natural selection in the sense of Darwin[6] as an explanation for larger evolutionary transitions that give rise to taxa above the species level in the Linnean taxonomy. Accordingly, he restricted Darwinian "microevolution" to evolutionary changes within the boundary of given species that may lead to different races or subspecies at the most. By contrast, he referred "macroevolution" to major evolutionary changes that correspond to taxonomic differences above the species level, which in his opinion would require evolutionary processes different from natural selection. An explanatory model for macroevolution in this sense was the "hopeful monster" concept of geneticist Richard Goldschmidt, who suggested saltational evolutionary changes either due to mutations that affect the rates of developmental processes[7] or due to alterations in the chromosomal pattern.[8] Particularly the latter idea was widely rejected by the modern synthesis, but the hopeful monster concept based on Evolutionary_developmental_biology (or evo-devo) explanations found a moderate revival in recent times.[9][10] Occasionally such dramatic changes can lead to novel features that survive.

As an alternative to saltational evolution, Dobzhansky[11] suggested that the difference between macroevolution and microevolution reflects essentially a difference in time-scales, and that macroevolutionary changes were simply the sum of microevolutionary changes over geologic time. This view became broadly accepted, and accordingly, the term macroevolution has been used widely as a neutral label for the study of evolutionary changes that take place over a very large time-scale.[12]

Further, species selection[1] suggests that selection among species is a major evolutionary factor that is independent from and complementary to selection among organisms. Accordingly, the level of selection has become the conceptual basis of a third definition, which defines macroevolution as evolution through selection among interspecific variation.[3]

Macroevolutionary processes[edit]

Speciation vs macroevolution[edit]

Charles Darwin first discovered that speciation can be extrapolated so that species not only evolve into new species, but also into new genera, families and other groups of animals. In other words, macroevolution is reducible to microevolution through selection of traits over long periods of time.[13] In addition, some scholars have argued that selection at the species level is important as well.[14] The advent of genome sequencing enabled the discovery of gradual genetic changes both during speciation but also across higher taxa. For instance, the evolution of humans from ancestral primates or other mammals can be traced to numerous but individual mutations.[15]

Evolution of new organs and tissues[edit]

One of the main questions in evolutionary biology is how new structures evolve, such as new organs. As can be seen in vertebrate evolution, most "new" organs are actually not new—they are still modifications of previously existing organs. Examples are wings (modified limbs), feathers (modified reptile scales),[16] lungs (modified swim bladders, e.g. found in fish),[17][18] or even the heart (a muscularized segment of a vein).[19]

The same concept applies to the evolution of "novel" tissues. Even fundamental tissues such as bone can evolve from combining existing proteins (collagen) with calcium phosphate (specifically, hydroxy-apatite). This probably happened when certain cells that make collagen also accumulated calcium phosphate to get a proto-bone cell.[20]

Molecular macroevolution[edit]

Microevolution is facilitated by mutations, the vast majority of which have no or very small effects on gene or protein function. For instance, the activity of an enzyme may be slightly changed or the stability of a protein slightly altered. However, occasionally mutations can dramatically change the structure and functions of protein. This may be called "molecular macroevolution".

The metabolic enzyme galactokinase can be converted to a transcription factor (in yeast) by just a 2 amino-acid insertion.

Protein function. There are countless cases in which protein function is dramatically altered by mutations. For instance, a mutation in acetaldehyde dehydrogenase (EC:1.2.1.10) can change it to a 4-hydroxy-2-oxopentanoate pyruvate lyase (EC:4.1.3.39), i.e., a mutation that changes an enzyme from one to another EC class.[21] Another example is the conversion of a yeast galactokinase (Gal1) to a transcription factor (Gal3) which can be achieved by an insertion of only two amino acids.[22]

While some mutations may not change the molecular function of a protein significantly, their biological function may be dramatically changed. For instance, most brain receptors recognize specific neurotransmitters, but that specificity can easily be changed by mutations. This has been shown by acetylcholine receptors that can be changed to serotonin or glycine receptors which actually have very different functions. Their similar gene structure also indicates that they must have arisen from gene duplications.[23]

Protein structure. Although protein structures are highly conserved, sometimes one or a few mutations can dramatically change a protein. For instance, an IgG-binding, 4+ fold can be transformed into an albumin-binding, 3-α fold via a single amino-acid mutation. This example also shows that such a transition can happen with neither function nor native structure being completely lost.[24] In other words, even when multiple mutations are required to convert one protein or structure into another, the structure and function is at least partially retained in the intermediary sequences. Similarly, domains can be converted into other domains (and thus other functions). For instance, the structures of SH3 folds can evolve into OB folds which in turn can evolve into CLB folds.[25]

Examples[edit]

Stanley's rule[edit]

Macroevolution is driven by differences between species in origination and extinction rates. Remarkably, these two factors are generally positively correlated: taxa that have typically high diversification rates also have high extinction rates. This observation has been described first by Steven Stanley, who attributed it to a variety of ecological factors.[26] Yet, a positive correlation of origination and extinction rates is also a prediction of the Red Queen hypothesis, which postulates that evolutionary progress (increase in fitness) of any given species causes a decrease in fitness of other species, ultimately driving to extinction those species that do not adapt rapidly enough.[27] High rates of origination must therefore correlate with high rates of extinction.[3] Stanley's rule, which applies to almost all taxa and geologic ages, is therefore an indication for a dominant role of biotic interactions in macroevolution.

"Macromutations": Single mutations leading to dramatic change[edit]

Normal phenotype
Bithorax phenotype
Mutations in the Ultrabithorax gene lead to a duplication of wings in fruit flies.

While the vast majority of mutations are inconsequential, some can have a dramatic effect on morphology or other features of an organism. One of the best studied cases of a single mutation that leads to massive structural change is the Ultrabithorax mutation in fruit flies. The mutation duplicates the wings of a fly to make it look like a dragonfly, a different order of insect.

Evolution of multicellularity[edit]

The evolution of multicellular organisms is one of the major breakthroughs in evolution. The first step of converting a unicellular organism into a metazoan (a multicellular organism) is to allow cells to attach to each other. This can be achieved by one or a few mutations. In fact, many bacteria form multicellular assemblies, e.g. cyanobacteria or myxobacteria. Another species of bacteria, Jeongeupia sacculi, form well-ordered sheets of cells, which ultimately develop into a bulbous structure.[28][29] Similarly, unicellular yeast cells can become multicellular by a single mutation in the ACE2 gene, which causes the cells to form a branched multicellular form.[30]

Evolution of bat wings[edit]

The wings of bats have the same structural elements (bones) as any other five-fingered mammal (see periodicity in limb development). However, the finger bones in bats are dramatically elongated, so the question is how these bones became so long. It has been shown that certain growth factors such as bone morphogenetic proteins (specifically Bmp2) is over expressed so that it stimulates an elongation of certain bones. Genetic changes in the bat genome identified the changes that lead to this phenotype and it has been recapitulated in mice: when specific bat DNA is inserted in the mouse genome, recapitulating these mutations, the bones of mice grow longer.[31]

Limb loss in lizards and snakes[edit]

Limbloss in lizards can be observed in the genus Lerista which shows many intermediary steps with increasing loss of digits and toes. The species shown here, Lerista cinerea, has no digits and only 1 toe left.

Snakes evolved from lizards. Phylogenetic analysis shows that snakes are actually nested within the phylogenetic tree of lizards, demonstrating that they have a common ancestor.[32] This split happened about 180 million years ago and several intermediary fossils are known to document the origin. In fact, limbs have been lost in numerous clades of reptiles, and there are cases of recent limb loss. For instance, the skink genus Lerista has lost limbs in multiple cases, with all possible intermediary steps, that is, there are species which have fully developed limbs, shorter limbs with 5, 4, 3, 2, 1 or no toes at all.[33]

Human evolution[edit]

While human evolution from their primate ancestors did not require massive morphological changes, our brain has sufficiently changed to allow human consciousness and intelligence. While the latter involves relatively minor morphological changes it did result in dramatic changes to brain function.[34] Thus, macroevolution does not have to be morphological, it can also be functional.

Evolution of viviparity in lizards[edit]

The European Common Lizard (Zootoca vivipara) consists of populations that are egg-laying or live-bearing, demonstrating that this dramatic difference can even evolve within a species.

Most lizards are egg-laying and thus need an environment that is warm enough to incubate their eggs. However, some species have evolved viviparity, that is, they give birth to live young, as almost all mammals do. In several clades of lizards, egg-laying (oviparous) species have evolved into live-bearing ones, apparently with very little genetic change. For instance, a European common lizard, Zootoca vivipara, is viviparous throughout most of its range, but oviparous in the extreme southwest portion.[35][36] That is, within a single species, a radical change in reproductive behavior has happened. Similar cases are known from South American lizards of the genus Liolaemus which have egg-laying species at lower altitudes, but closely related viviparous species at higher altitudes, suggesting that the switch from oviparous to viviparous reproduction does not require many genetic changes.[37]

Behavior: Activity pattern in mice[edit]

Most animals are either active at night or during the day. However, some species switched their activity pattern from day to night or vice versa. For instance, the African striped mouse (Rhabdomys pumilio), transitioned from the ancestrally nocturnal behavior of its close relatives to a diurnal one. Genome sequencing and transcriptomics revealed that this transition was achieved by modifying genes in the rod phototransduction pathway, among others.[38]

Research topics[edit]

Subjects studied within macroevolution include:[39]

See also[edit]

References[edit]

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  15. ^ Foley, Nicole M.; Mason, Victor C.; Harris, Andrew J.; Bredemeyer, Kevin R.; Damas, Joana; Lewin, Harris A.; Eizirik, Eduardo; Gatesy, John; Karlsson, Elinor K.; Lindblad-Toh, Kerstin; Zoonomia Consortium‡; Springer, Mark S.; Murphy, William J.; Andrews, Gregory; Armstrong, Joel C. (28 April 2023). "A genomic timescale for placental mammal evolution". Science. 380 (6643): eabl8189. doi:10.1126/science.abl8189. ISSN 0036-8075. PMC 10233747. PMID 37104581.
  16. ^ Wu, Ping; Yan, Jie; Lai, Yung-Chih; Ng, Chen Siang; Li, Ang; Jiang, Xueyuan; Elsey, Ruth M; Widelitz, Randall; Bajpai, Ruchi; Li, Wen-Hsiung; Chuong, Cheng-Ming (21 November 2017). "Multiple Regulatory Modules Are Required for Scale-to-Feather Conversion". Molecular Biology and Evolution. 35 (2): 417–430. doi:10.1093/molbev/msx295. ISSN 0737-4038. PMC 5850302. PMID 29177513.
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  19. ^ Jensen, Bjarke; Wang, Tobias; Christoffels, Vincent M.; Moorman, Antoon F. M. (1 April 2013). "Evolution and development of the building plan of the vertebrate heart". Biochimica et Biophysica Acta (BBA) - Molecular Cell Research. Cardiomyocyte Biology: Cardiac Pathways of Differentiation, Metabolism and Contraction. 1833 (4): 783–794. doi:10.1016/j.bbamcr.2012.10.004. ISSN 0167-4889. PMID 23063530. S2CID 28787569.
  20. ^ Wagner, Darja Obradovic; Aspenberg, Per (1 August 2011). "Where did bone come from?". Acta Orthopaedica. 82 (4): 393–398. doi:10.3109/17453674.2011.588861. ISSN 1745-3674. PMC 3237026. PMID 21657973.
  21. ^ Tyzack, Jonathan D; Furnham, Nicholas; Sillitoe, Ian; Orengo, Christine M; Thornton, Janet M (1 December 2017). "Understanding enzyme function evolution from a computational perspective". Current Opinion in Structural Biology. Protein–nucleic acid interactions • Catalysis and regulation. 47: 131–139. doi:10.1016/j.sbi.2017.08.003. ISSN 0959-440X. PMID 28892668.
  22. ^ Platt, A.; Ross, H. C.; Hankin, S.; Reece, R. J. (28 March 2000). "The insertion of two amino acids into a transcriptional inducer converts it into a galactokinase". Proceedings of the National Academy of Sciences of the United States of America. 97 (7): 3154–3159. Bibcode:2000PNAS...97.3154P. doi:10.1073/pnas.97.7.3154. ISSN 0027-8424. PMC 16208. PMID 10737789.
  23. ^ Uetz, Peter; Abdelatty, Fawzy; Villarroel, Alfredo; Rappold, Gudrun; Weiss, Birgit; Koenen, Michael (21 February 1994). "Organisation of the murine 5-HT 3 receptor gene and assignment tohuman chromosome 11". FEBS Letters. 339 (3): 302–306. doi:10.1016/0014-5793(94)80435-4. PMID 8112471. S2CID 28979681.
  24. ^ Alexander, Patrick A.; He, Yanan; Chen, Yihong; Orban, John; Bryan, Philip N. (15 December 2009). "A minimal sequence code for switching protein structure and function". Proceedings of the National Academy of Sciences. 106 (50): 21149–21154. doi:10.1073/pnas.0906408106. ISSN 0027-8424. PMC 2779201. PMID 19923431.
  25. ^ Alvarez-Carreño, Claudia; Gupta, Rohan J.; Petrov, Anton S.; Williams, Loren Dean (27 December 2022). "Creative destruction: New protein folds from old". Proceedings of the National Academy of Sciences. 119 (52): e2207897119. Bibcode:2022PNAS..11907897A. doi:10.1073/pnas.2207897119. ISSN 0027-8424. PMC 9907106. PMID 36534803. S2CID 254907939.
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  29. ^ Mizuno, Kouhei; Maree, Mais; Nagamura, Toshihiko; Koga, Akihiro; Hirayama, Satoru; Furukawa, Soichi; Tanaka, Kenji; Morikawa, Kazuya (11 October 2022). Goldstein, Raymond E; Weigel, Detlef (eds.). "Novel multicellular prokaryote discovered next to an underground stream". eLife. 11: e71920. doi:10.7554/eLife.71920. ISSN 2050-084X. PMC 9555858. PMID 36217817.
  30. ^ Ratcliff, William C.; Fankhauser, Johnathon D.; Rogers, David W.; Greig, Duncan; Travisano, Michael (May 2015). "Origins of multicellular evolvability in snowflake yeast". Nature Communications. 6 (1): 6102. Bibcode:2015NatCo...6.6102R. doi:10.1038/ncomms7102. ISSN 2041-1723. PMC 4309424. PMID 25600558.
  31. ^ Sears, Karen E.; Behringer, Richard R.; Rasweiler, John J.; Niswander, Lee A. (25 April 2006). "Development of bat flight: Morphologic and molecular evolution of bat wing digits". Proceedings of the National Academy of Sciences. 103 (17): 6581–6586. Bibcode:2006PNAS..103.6581S. doi:10.1073/pnas.0509716103. ISSN 0027-8424. PMC 1458926. PMID 16618938.
  32. ^ Streicher, Jeffrey W.; Wiens, John J. (30 September 2017). "Phylogenomic analyses of more than 4000 nuclear loci resolve the origin of snakes among lizard families". Biology Letters. 13 (9): 20170393. doi:10.1098/rsbl.2017.0393. PMC 5627172. PMID 28904179.
  33. ^ Skinner, Adam; Lee, Michael SY; Hutchinson, Mark N (2008). "Rapid and repeated limb loss in a clade of scincid lizards". BMC Evolutionary Biology. 8 (1): 310. doi:10.1186/1471-2148-8-310. ISSN 1471-2148. PMC 2596130. PMID 19014443.
  34. ^ Serrelli, Emanuele; Gontier, Nathalie (2015). Macroevolution: explanation, interpretation and evidence. Cham. ISBN 978-3-319-15045-1. OCLC 903489046.{{cite book}}: CS1 maint: location missing publisher (link)
  35. ^ Heulin, Benoît (1 May 1990). "Étude comparative de la membrane coquillère chez les souches ovipare et vivipare du lézard Lacerta vivipara". Canadian Journal of Zoology. 68 (5): 1015–1019. doi:10.1139/z90-147. ISSN 0008-4301.
  36. ^ Arrayago, Maria-Jesus; Bea, Antonio; Heulin, Benoit (1996). "Hybridization Experiment between Oviparous and Viviparous Strains of Lacerta vivipara: A New Insight into the Evolution of Viviparity in Reptiles". Herpetologica. 52 (3): 333–342. ISSN 0018-0831. JSTOR 3892653.
  37. ^ Ii, James A. Schulte; Macey, J. Robert; Espinoza, Robert E.; Larson, Allan (January 2000). "Phylogenetic relationships in the iguanid lizard genus Liolaemus: multiple origins of viviparous reproduction and evidence for recurring Andean vicariance and dispersal". Biological Journal of the Linnean Society. 69 (1): 75–102. doi:10.1111/j.1095-8312.2000.tb01670.x.
  38. ^ Richardson, Rose; Feigin, Charles Y.; Bano-Otalora, Beatriz; Johnson, Matthew R.; Allen, Annette E.; Park, Jongbeom; McDowell, Richard J.; Mereby, Sarah A.; Lin, I-Hsuan; Lucas, Robert J.; Mallarino, Ricardo (August 2023). "The genomic basis of temporal niche evolution in a diurnal rodent". Current Biology. 33 (15): 3289–3298.e6. doi:10.1016/j.cub.2023.06.068. ISSN 0960-9822. PMC 10529858. PMID 37480852.
  39. ^ Grinin, L., Markov, A. V., Korotayev, A. Aromorphoses in Biological and Social Evolution: Some General Rules for Biological and Social Forms of Macroevolution / Social evolution & History, vol.8, num. 2, 2009 [1]

Further reading[edit]

External links[edit]