Subfunctionalization






Subfunctionalization is a neutral mutation process in which each paralog retains a subset of its original ancestral function. The figure illustrates that the ancestral gene (orange & blue) is capable of both functions before gene duplication. After gene duplication the functional capabilities are divided amongst the gene copies. After this divergence each paralog is capable of independently performing a distinct ancestral function.


Subfunctionalization was proposed by Stoltzfus (1999)[1] and Force et al. (1999)[2] as one of the possible outcomes of functional divergence that occurs after a gene duplication event, in which pairs of genes that originate from duplication, or paralogs, take on separate functions.[3][4][5] Subfunctionalization is a neutral mutation process; meaning that no new adaptations are formed.[6][7] During the process of gene duplication paralogs simply undergo a division of labor by retaining different parts (subfunctions) of their original ancestral function.[8] This partitioning event occurs because of segmental gene silencing leading to the formation of paralogs that are no longer duplicates, because each gene only retains a single function.[9] It is important to note that the ancestral gene was capable of performing both functions and the descendant duplicate genes can now only perform one of the original ancestral functions.[10]




Contents






  • 1 Alternative Hypothesis


  • 2 Specialization


  • 3 Gene Sharing


  • 4 Escape from adaptive conflict


  • 5 Duplication-Degeneration-Complementation


  • 6 Segregation avoidance


  • 7 Hemoglobin


  • 8 See also


  • 9 References





Alternative Hypothesis


Subfunctionalization after gene duplication is thought to be the newer model of functional divergence.[11] Before 1910, scientists were unaware that genes were capable of multifunctionalization.[12] The original thought was that each gene possessed one function, but in fact genes have independently mutable regions and possessed the ability to subfunctionalize.[13][14]Neofunctionalization, where one paralogous copy derives a new function after gene duplication, is thought to be the classical model of functional divergence.[15] Nevertheless, because of its neutral mutation process subfunctionalization seem to present a more parsimonious explanation for the retention of duplicates in a genome.[16][17][18]



Specialization


Specialization is a unique model of subfunctionalization, in which paralogs divide into various areas of specialty rather than function. In this model both gene copies perform exactly the same ancestral function. For instance, while the ancestral gene may have performed its function in all tissues, developmental stage, and environmental conditions, the paralogous genes become specialists, dividing themselves among different tissues, developmental stages, and environmental conditions.[19] For example, if the ancestral gene is responsible for both digestive and lymphatic regulatory processes, after gene duplication one of the paralogs would claim responsibility for lymphatic regulation and the other for digestive regulation.
Specialization is also unique in the fact that it is a positive rather than neutral mutation process.[20] When a gene specializes among different tissues, developmental stages, or environmental conditions it acquires an improvement in function. Isozymes are a good example of this because they are gene products of paralogs that catalyze the same biochemical reaction.[21] However, different members have evolved particular adaptations to different tissues or different developmental stages that enhance the physiological fine-tuning of the cell.[22]



Gene Sharing


Gene sharing occurs when a gene acquires a secondary function during its evolutionary process. Gene sharing is unique because the gene maintains and performs both its ancestral function and its acquired function. Gene duplication is not necessary in this model, as the addition of functionality occurs before, or often instead of gene duplication.
Gene sharing is a fairly common occurrence and is most often seen in enzymes taking on a various subfunctions such as signal transduction and transcriptional regulation.[23] The most noteworthy example of gene sharing is in the how in crystallins, the proteins responsible for transparency and diffraction in the eye lens, has also been found to serve a metabolic enzyme in other tissue.[24]



Escape from adaptive conflict


Adaptive conflict arises in gene sharing when an improvement to one gene function severely impairs another function. This occurs because selective constraints are particularly stringent in the case of gene sharing.[25] It is very difficult for either function to undergo morphological changes, due to the fact that both the ancestral and novel functions are needed. As a result of its dual function the gene is subjected to two or more independent sets of evolutionary pressure.[26] This means that positively selecting for improvements in one function is likely to cause deleterious effect in the other function. There are two solutions to the predicament of adaptive conflict. The gene can either completely lose its new function or undergo gene duplication followed by subfunctionalization,[27] also called "function splitting".[28]



Duplication-Degeneration-Complementation


In the Duplication- Degeneration- Complementation (DDC) model of subfunctionalization both gene copies are needed to perform the original ancestral function.[29] In this model after a duplication event, both paralogs suffer deleterious mutations leading to functional degradation. This degradation is so severe that neither gene copy can perform the ancestral function or any subset of that function independently. In order to be functional, the paralogs must work together to perform the ancestral task. This teamwork among paralogs is possible because the subfunction lost in one gene copy is complimented in the other gene copy.[30] This functional sharing would not be possible if both paralogs had lost identical subfunctions.
The degeneration and complementation processes make the DDC model a selectively neutral mutation process. The mutations accumulated in both paralogs would have been deleterious if they had not been complimented by the other copy.[31] On example of the DDC model is when functionally similar paralogs are expressed at such low levels that both copies are required to produce sufficient amounts of the original gene product.[32]



Segregation avoidance


Segregation avoidance occurs when an unequal crossing over event leads to a locus duplication containing two heterogeneous alleles creating a situation akin to permanent heterozygosity.[33] This occurs primarily in situations of overdominant selection where the heterozygote has increased fitness but less fit homozygotes are still retained in the population.[34]
Segregation avoidance addresses the issue of segregational load, wherein the mean fitness of the population is less than the highest possible fitness. The unequal crossing over and subsequent duplication of a locus containing heterogeneous alleles ensures the highest possible fitness. By avoiding homogeneous alleles organisms in the population can benefit from the advantages that both alleles have to offer. A prime example is the ace-1 locus in house mosquitoes, Culex pipiens.[35] Because of segregation avoidance house mosquitos are able to benefit from ace-1R pesticide resistant allele during pesticide exposure and ace-1S wild-type allele during non-exposure.[36] This duality is particularly useful, as the mutant allele causes decreased fitness during period’s non-exposure.[37]



Hemoglobin


Human hemoglobin provides a variety of subfunctionalization examples. For instance, the gene for hemoglobin α-chain is undoubtedly derived from a duplicate copy of hemoglobin β-chain.[38] However, neither chain can function independently to form a monomeric hemoglobin molecule, that is a molecule consisting entirely of α-chains or entirely of β-chains.[39] Conversely, hemoglobin consists of both α and β chains, with α2-β2 being among the most efficient forms of hemoglobin in the human genome. This is a prime example of subfunctionalization.
Another good example is the emergence of fetal hemoglobin from embryonic hemoglobin after duplication of the hemoglobin γ- chain.[40] This example of subfunctionalization illustrates how different forms of hemoglobin are present at various developmental stages. In fact, there is distinct hemoglobin at each developmental stage: ζ2-ε2 and α2-ε2 in the embryo, α2-γ2 in the fetus, and α2-β2 and α2-δ2 in adults.[41] Each type of hemoglobin has advantages that are particular to the developmental stage in which it thrives. For example, embryonic and fetal hemoglobin have higher oxygen affinity than adult hemoglobin giving them improved functionality in hypoxic environments such as the uterus.[42]



See also


  • Neofunctionalization


References





  1. ^ Stoltzfus, Arlin. "On the possibility of constructive neutral evolution." Journal of Molecular Evolution 49.2 (1999): 169-181.


  2. ^ Force, Allan, et al. "Preservation of duplicate genes by complementary, degenerative mutations." Genetics 151.4 (1999): 1531-1545.


  3. ^ “ScienceDirect Ad,” Chaos, Solitons & Fractals, vol. 15, no. 5. p. II, Mar-2003


  4. ^ S. Rastogi and D. A. Liberles, “Subfunctionalization of duplicated genes as a transition state to neofunctionalization,” BMC Evolutionary Biology, vol. 5, no. 1, p. 28, 2005


  5. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007.


  6. ^ S. Ohno, Evolution by Gene Duplication. New York, Heidelberg, Berlin: Springer-Verlag, 1970, pp. 59-87


  7. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  8. ^ M. Sémon and K. H. Wolfe, “Preferential subfunctionalization of slow-evolving genes after allopolyploidization in Xenopus laevis.,” Proceedings of the National Academy of Sciences of the United States of America, vol. 105, no. 24, pp. 8333-8, Jun. 2008


  9. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  10. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  11. ^ R. De Smet and Y. Van de Peer, “Redundancy and rewiring of genetic networks following genome-wide duplication events.,” Current Opinion in Plant Biology, pp. 1-9, Feb. 2012


  12. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  13. ^ J. G. Ruby, A. Stark, W. K. Johnston, M. Kellis, D. P. Bartel, and E. C. Lai, “Evolution, biogenesis, expression, and target predictions of a substantially expanded set of Drosophila microRNAs.,” Genome research, vol. 17, no. 12, pp. 1850-64, Dec. 2007


  14. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  15. ^ J. G. Ruby, A. Stark, W. K. Johnston, M. Kellis, D. P. Bartel, and E. C. Lai, “Evolution, biogenesis, expression, and target predictions of a substantially expanded set of Drosophila microRNAs.,” Genome research, vol. 17, no. 12, pp. 1850-64, Dec. 2007


  16. ^ S. Rastogi and D. A. Liberles, “Subfunctionalization of duplicated genes as a transition state to neofunctionalization,” BMC Evolutionary Biology, vol. 5, no. 1, p. 28, 2005


  17. ^ D. (University of H. Graur and W.-H. (University of C. Li, Fundamentals of Molecular Evolution, Second. Sinauer Associates, Inc.,, 2000


  18. ^ G. D. Amoutzias, Y. He, J. Gordon, D. Mossialos, S. G. Oliver, and Y. Van de Peer, “Posttranslational regulation impacts the fate of duplicated genes.,” Proceedings of the National Academy of Sciences of the United States of America, vol. 107, no. 7, pp. 2967-71, Feb. 2010


  19. ^ H. Innan, “Population genetic models of duplicated genes.,” Genetica, vol. 137, no. 1, pp. 19-37, Sep. 2009


  20. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  21. ^ H. Innan, “Population genetic models of duplicated genes.,” Genetica, vol. 137, no. 1, pp. 19-37, Sep. 2009


  22. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  23. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  24. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  25. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  26. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  27. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  28. ^ Altenberg, Lee. "Genome growth and the evolution of the genotype-phenotype map." Evolution and biocomputation. Springer Berlin Heidelberg, 1995. 205-259.


  29. ^ R. De Smet and Y. Van de Peer, “Redundancy and rewiring of genetic networks following genome-wide duplication events.,” Current Opinion in Plant Biology, pp. 1-9, Feb. 2012


  30. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  31. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  32. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  33. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  34. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  35. ^ A. Hughes, Adaptive Evolution of Genes and Genomes. New York: Oxford University Press, 1999


  36. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  37. ^ A. Hughes, Adaptive Evolution of Genes and Genomes. New York: Oxford University Press, 1999


  38. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  39. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  40. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  41. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007


  42. ^ B. Conrad and S. E. Antonarakis, “Gene duplication: a drive for phenotypic diversity and cause of human disease.,” Annual Review of Genomics and Human Genetics, vol. 8, pp. 17-35, Jan. 2007









Popular posts from this blog

Italian cuisine

Bulgarian cuisine

Carrot