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Polyploidy

Not to be confused with "polypoid", resembling a polyp.
This image shows haploid (single), diploid (double), triploid (triple), and tetraploid (quadruple) sets of chromosomes. Triploid and tetraploid chromosomes are examples of polyploidy.

Polyploidy is a condition in which the cells of an organism have more than one pair of (homologous) chromosomes. Most species whose cells have nuclei (eukaryotes) are diploid, meaning they have two complete sets of chromosomes, one from each of two parents; each set contains the same number of chromosomes, and the chromosomes are joined in pairs of homologous chromosomes. However, some organisms are polyploid. Polyploidy is especially common in plants. Most eukaryotes have diploid somatic cells, but produce haploid gametes (eggs and sperm) by meiosis. A monoploid has only one set of chromosomes, and the term is usually only applied to cells or organisms that are normally diploid. Males of bees and other Hymenoptera, for example, are monoploid. Unlike animals, plants and multicellular algae have life cycles with two alternating multicellular generations. The gametophyte generation is haploid, and produces gametes by mitosis; the sporophyte generation is diploid and produces spores by meiosis.

Polyploidy may occur due to abnormal cell division, either during mitosis, or more commonly from the failure of chromosomes to separate during meiosis or from the fertilization of an egg by more than one sperm.[1] In addition, it can be induced in plants and cell cultures by some chemicals: the best known is colchicine, which can result in chromosome doubling, though its use may have other less obvious consequences as well. Oryzalin will also double the existing chromosome content.

Among mammals, a high frequency of polyploid cells is found in organs such as the brain, liver, heart, and bone marrow.[2] It also occurs in the somatic cells of other animals, such as goldfish,[3] salmon, and salamanders. It is common among ferns and flowering plants (see Hibiscus rosa-sinensis), including both wild and cultivated species. Wheat, for example, after millennia of hybridization and modification by humans, has strains that are diploid (two sets of chromosomes), tetraploid (four sets of chromosomes) with the common name of durum or macaroni wheat, and hexaploid (six sets of chromosomes) with the common name of bread wheat. Many agriculturally important plants of the genus Brassica are also tetraploids. Sugarcane can have ploidy levels higher than octaploid.[4]

Polyploidization can be a mechanism of sympatric speciation because polyploids are usually unable to interbreed with their diploid ancestors. An example is the plant Erythranthe peregrina. Sequencing confirmed that this species originated from E. × robertsii, a sterile triploid hybrid between E. guttata and E. lutea, both of which have been introduced and naturalised in the United Kingdom. New populations of E. peregrina arose on the Scottish mainland and the Orkney Islands via genome duplication from local populations of E. × robertsii.[5] Because of a rare genetic mutation, E. peregrina is not sterile.[6]

On the other hand, polyploidization can also be a mechanism for a kind of 'reverse speciation',[7] whereby gene flow is enabled following the polyploidy event, even between lineages that previously experienced no gene flow as diploids. This has been detailed at the genomic level in Arabidopsis arenosa and Arabidopsis lyrata.[8] Each of these species experienced independent autopolyploidy events (within-species polyploidy, described below), which then enabled subsequent interspecies gene flow of adaptive alleles, in this case stabilising each young polyploid lineage.[9] Such polyploidy-enabled adaptive introgression may allow polyploids at act as 'allelic sponges', whereby they accumulate cryptic genomic variation that may be recruited upon encountering later environmental challenges.[10]

  1. ^ Solomon E (2014). Solomon/Martin/Martin/Berg, Biology. Cengage Learning. p. 344. ISBN 978-1285423586.
  2. ^ Zhang S, Lin YH, Tarlow B, Zhu H (June 2019). "The origins and functions of hepatic polyploidy". Cell Cycle. 18 (12): 1302–1315. doi:10.1080/15384101.2019.1618123. PMC 6592246. PMID 31096847.
  3. ^ Ohno S, Muramoto J, Christian L, Atkin NB (1967). "Diploid-tetraploid relationship among old-world members of the fish family Cyprinidae". Chromosoma. 23 (1): 1–9. doi:10.1007/BF00293307. S2CID 1181521.
  4. ^
    Manimekalai R, Suresh G, Govinda Kurup H, Athiappan S, Kandalam M (September 2020). "Role of NGS and SNP genotyping methods in sugarcane improvement programs". Critical Reviews in Biotechnology. 40 (6). Taylor & Francis (T&F): 865–880. doi:10.1080/07388551.2020.1765730. PMID 32508157. S2CID 219537026.
    This review cites this study:
    Vilela MM, Del Bem LE, Van Sluys MA, de Setta N, Kitajima JP, Cruz GM, et al. (February 2017). "Analysis of Three Sugarcane Homo/Homeologous Regions Suggests Independent Polyploidization Events of Saccharum officinarum and Saccharum spontaneum". Genome Biology and Evolution. 9 (2): 266–278. doi:10.1093/gbe/evw293. PMC 5381655. PMID 28082603.
  5. ^ Vallejo-Marín M, Buggs RJ, Cooley AM, Puzey JR (June 2015). "Speciation by genome duplication: Repeated origins and genomic composition of the recently formed allopolyploid species Mimulus peregrinus". Evolution; International Journal of Organic Evolution. 69 (6): 1487–1500. doi:10.1111/evo.12678. PMC 5033005. PMID 25929999.
  6. ^ Fessenden M. "Make Room for a New Bloom: New Flower Discovered". Scientific American. Retrieved 22 February 2017.
  7. ^ Schmickl, Roswitha; Yant, Levi (April 2021). "Adaptive introgression: how polyploidy reshapes gene flow landscapes". New Phytologist. 230 (2): 457–461. doi:10.1111/nph.17204. ISSN 0028-646X. PMID 33454987.
  8. ^ Marburger, Sarah; Monnahan, Patrick; Seear, Paul J.; Martin, Simon H.; Koch, Jordan; Paajanen, Pirita; Bohutínská, Magdalena; Higgins, James D.; Schmickl, Roswitha; Yant, Levi (2019-11-18). "Interspecific introgression mediates adaptation to whole genome duplication". Nature Communications. 10 (1): 5218. Bibcode:2019NatCo..10.5218M. doi:10.1038/s41467-019-13159-5. ISSN 2041-1723. PMC 6861236. PMID 31740675.
  9. ^ Seear, Paul J.; France, Martin G.; Gregory, Catherine L.; Heavens, Darren; Schmickl, Roswitha; Yant, Levi; Higgins, James D. (2020-07-15). "A novel allele of ASY3 is associated with greater meiotic stability in autotetraploid Arabidopsis lyrata". PLOS Genetics. 16 (7): e1008900. doi:10.1371/journal.pgen.1008900. ISSN 1553-7404. PMC 7392332. PMID 32667955.
  10. ^ Schmickl, Roswitha; Yant, Levi (April 2021). "Adaptive introgression: how polyploidy reshapes gene flow landscapes". New Phytologist. 230 (2): 457–461. doi:10.1111/nph.17204. ISSN 0028-646X. PMID 33454987.
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