Co-adaptation

In biology, co-adaptation is the process by which two or more species, genes or phenotypic traits undergo adaptation as a pair or group. This occurs when two or more interacting characteristics undergo natural selection together in response to the same selective pressure or when selective pressures alter one characteristic and consecutively alter the interactive characteristic. These interacting characteristics are only beneficial when together, sometimes leading to increased interdependence. Co-adaptation and coevolution, although similar in process, are not the same; co-adaptation refers to the interactions between two units, whereas co-evolution refers to their evolutionary history. Co-adaptation and its examples are often seen as evidence for co-evolution.[1]

Genes and Protein Complexes

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At genetic level, co-adaptation is the accumulation of interacting genes in the gene pool of a population by selection. Selection pressures on one of the genes will affect its interacting proteins, after which compensatory changes occur.[2][1]

Proteins often act in complex interactions with other proteins and functionally related proteins often show a similar evolutionary path.[1][3] A possible explanation is co-adaptation.[1] An example of this is the interaction between proteins encoded by mitochondrial DNA (mtDNA) and nuclear DNA (nDNA). MtDNA has a higher rate of evolution/mutation than nDNA, especially in specific coding regions.[2][3] However, in order to maintain physiological functionality, selection for functionally interacting proteins, and therefore co-adapted nDNA will be favourable.[2]

Co-adaptation between mtDNA and nDNA sequences has been studied in the copepod Tigriopus californicus.[2] The mtDNA of COII coding sequences among conspecific populations of this species diverges extensively.[2] When mtDNA of one population was placed in a nuclear background of another population, cytochrome c oxidase activity is significantly decreased, suggesting co-adaptation. Results show an unlikely relationship between the variation in mtDNA and environmental factors. A more likely explanation is the neutral evolution of mtDNA with compensatory changes by the nDNA driven by neutral evolution of mtDNA (random mutations over time in isolated populations).[2]

Bacteria and bacteriophage

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Gene blocks in bacterial genomes are sequences of genes, co-located on the chromosome, that are evolutionarily conserved across numerous taxa.[4] Some conserved blocks are operons, where the genes are cotranscribed to polycistronic mRNA, and such operons are often associated with a single function such as a metabolic pathway or a protein complex.[4] The co-location of genes with related function and the preservation of these relationships over evolutionary time indicates that natural selection has been operating to maintain a co-adaptive benefit.

As the early mapping of genes on the bacteriophage T4 chromosome progressed, it became evident that the arrangement of the genes is far from random.[5] Genes with like functions tend to fall into clusters and appear to be co-adapted to each other. For instance genes that specify proteins employed in bacteriophage head morphogenesis are tightly clustered.[6] Other examples of apparently co-adapted clusters are the genes that determine the baseplate wedge, the tail fibers, and DNA polymerase accessory proteins.[6] In other cases where the structural relationship of the gene products is not as evident, a co-adapted clustering based on functional interaction may also occur. Thus Obringer[7] proposed that a specific cluster of genes, centered around the imm and spackle genes encodes proteins adapted for competition and defense at the DNA level.

Organs

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Similar to traits on a genetic level, aspects of organs can also be subject to co-adaptation. For example, slender bones can have similar performance in regards to bearing daily loads as thicker bones, due to slender bones having more mineralized tissue. This means that slenderness and the level of mineralization have probably been co-adapted. However, due to being harder than thick bones, slender bones are generally less pliant and more prone to breakage, especially when subjected to more extreme load conditions.[8]

Weakly electric fish are capable of creating a weak electric field using an electric organ. These electric fields can be used to communicate between individuals through electric organ discharges (EOD), which can be further modulated to create context-specific signals called ‘chirps’. Fish can sense these electric fields and signals using electroreceptors. Research on ghost knifefish[9] indicates that the signals produced by electric fish and the way they are received might be co-adapted, as the environment in which the fish resides (both physical and social) influences selection for the chirps, EODs, and detection. Interactions between territorial fish favour different signal parameters than interactions within social groups of fish.

Behaviour

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The behaviour of parents and their offspring during feeding is influenced by one another. Parents feed depending on how much their offspring begs, while the offspring begs depending on how hungry it is. This would normally lead to a conflict of interest between parent and offspring, as the offspring will want to be fed as much as possible, whereas the parent can only invest a limited amount of energy into parental care. As such, selection would occur for the combination of begging and feeding behaviours that leads to the highest fitness, resulting in co-adaptation.[10] Parent-offspring co-adaptation can be further influenced by information asymmetry, such as female blue tits being exposed more to begging behaviour in nature, resulting in them responding more than males to similar levels of stimuli.[11]

Partial and antagonistic co-adaptation

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It is also possible for related traits to only partially co-adapt due to traits not developing at the same speed, or contradict each other entirely. Research on Australian skinks[12] revealed that diurnal skinks have a high temperature preference and can sprint optimally at higher temperatures, while nocturnal skinks have a low preferred temperature and optimum temperature. However, the differences between high and low optimal temperatures were much smaller than between preferred temperatures, which means that nocturnal skinks sprint slower compared to their diurnal counterparts. In the case of Eremiascincus, the optimum temperature and preferred temperature diverged from one another in opposite directions, creating antagonistic co-adaptation.

See also

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References

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  1. ^ a b c d Juan, David; Pazos, Florencio; Valencia, Alfonso (2008). "Co-evolution and co-adaptation in protein networks". FEBS Letters. 582 (8): 1225–30. Bibcode:2008FEBSL.582.1225J. doi:10.1016/j.febslet.2008.02.017. hdl:10261/346627. PMID 18282476. S2CID 22702946.
  2. ^ a b c d e f Blier, Pierre U.; Dufresne, France; Burton, Ronald S. (2001). "Natural selection and the evolution of mtDNA-encoded peptides: evidence for intergenomic co-adaptation". Trends in Genetics. 17 (7): 400–6. doi:10.1016/s0168-9525(01)02338-1. PMID 11418221.
  3. ^ a b Greiner, Stephan; Bock, Ralph (2013). "Tuning a menage a trois: Co-evolution and co-adaptation of nuclear and organellar genomes in plants". BioEssays. 35 (4): 354–365. doi:10.1002/bies.201200137. PMID 23361615. S2CID 205475365.
  4. ^ a b Ream DC, Bankapur AR, Friedberg I (July 2015). "An event-driven approach for studying gene block evolution in bacteria". Bioinformatics. 31 (13): 2075–83. doi:10.1093/bioinformatics/btv128. PMC 4481853. PMID 25717195.
  5. ^ Edgar RS, Epstein RH (February 1965). "The genetics of a bacterial virus". Sci Am. 212 (2): 70–8. Bibcode:1965SciAm.212b..70E. doi:10.1038/scientificamerican0265-70. PMID 14272117.
  6. ^ a b Kutter E, Stidham T, Guttman B, Kutter E, Batts D, Peterson S, Djavakhishvili T, Arisaka F, Mesyanzhinov V, Ruger W, Mosig G (1994). "Genomic map of bacteriophage T4". In Karam J, Drake JW, Kreuzer KN, Mosig G, Hall DH, Eiserling FA, Black LW, Spicer EK, Kutter E, Carlson K, Miller ES (eds.). Molecular biology of bacteriophage T4. American Society for Microbiology. pp. 491–519. ISBN 1-55581-064-0. OCLC 30028892.
  7. ^ Obringer JW (October 1988). "The functions of the phage T4 immunity and spackle genes in genetic exclusion". Genet Res. 52 (2): 81–90. doi:10.1017/s0016672300027440. PMID 3209067.
  8. ^ Tommasini, Steven M.; Nasser, Philip; Hu, Bin; Jepsen, Karl J. (2007). "Biological Co-Adaptation of Morphological and Composition Traits Contributes to Mechanical Functionality and Skeletal Fragility". Journal of Bone and Mineral Research. 23 (2): 236–246. doi:10.1359/jbmr.071014. PMC 2665697. PMID 17922614.
  9. ^ Petzold, Jacquelyn; Marsat, Gary; Smith, G. Troy (2016). "Co-adaptation of electric organ discharges and chirps in South American ghost knifefishes (Apteronotidae)". Journal of Physiology-Paris. 110 (2): 200–215. doi:10.1016/j.jphysparis.2016.10.005. PMC 5408315. PMID 27989653.
  10. ^ Kölliker, Mathias; Brodie III, Edmund D.; Moore, Allen J. (2005). "The Coadaptation of Parental Supply and Offspring Demand" (PDF). The American Naturalist. 166 (4): 506–516. doi:10.1086/491687. PMID 16224706. S2CID 19036695.
  11. ^ Lucass, Carsten; Fresneau, Nolwenn; Eens, Marcel; Müller, Wendt (2016). "Sex roles in nest keeping – how information asymmetry contributes to parent-offspring co-adaptation". Ecology and Evolution. 6 (6): 1825–33. Bibcode:2016EcoEv...6.1825L. doi:10.1002/ece3.1976. PMC 4759049. PMID 26929817.
  12. ^ Huey RB, Bennett AF (September 1987). "Phylogenetic studies of coadaptation: preferred temperatures versus optimal performance temperatures of lizards". Evolution. 41 (5): 1098–1115. doi:10.1111/j.1558-5646.1987.tb05879.x. PMID 28563407.
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