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Sex determination in Silene

From Wikipedia, the free encyclopedia
Silene dioica, female flower
Silene dioica male flowers (etamins) with anthers
Silene noctiflora, bisexual flower

Silene is a flowering plant genus that has evolved a dioecious reproductive system. This is made possible through heteromorphic sex chromosomes expressed as XY.[1][2] Silene recently evolved sex chromosomes 5-10 million years ago and are widely used by geneticists and biologists to study the mechanisms of sex determination since they are one of only 39 species across 14 families of angiosperm that possess sex-determining genes.[3] Silene are studied because of their ability to produce offspring with a plethora of reproductive systems. The common inference drawn from such studies is that the sex of the offspring is determined by the Y chromosome.

Evolution of sex chromosomes

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Biologists have found that sex chromosomes in plants originated from pairs of autosomes. As these chromosomes diverge from their autosomal ancestor and from each other as a homologous pair, they have the potential to increase or decrease in size due to mutation and recombination. In the case of Silene, the pair of automsomal chromosomes are transformed into heteromorphic sex-determining chromosomes expressed as XY. It is important to recognize that not all species of Silene have this sex determination system. A few, such as S. colpophylla, possess homomorphic sex chromosomes.[4]

Plants with sex-determining chromosomes, like Silene, can develop uni-sexual reproductive structures because of the loss and gain of sex-determining genes. Mutations can cause female sterility, male sterility, or adverse combinations of genes that can lead to monoecy, gynodioecy, and dioecy.[4]

Species of Silene with different reproductive systems

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The mechanisms involved in the sex determination of Silene are complex and can lead to various reproductive systems among the offspring. The table below provides only a few examples of these possible systems. Those which are most commonly found within this genus are hermaphroditism (monoecious plant with both staminate and pistillate), dioecy (male and female reproductive systems found in separate morphs), and gynodioecy (existence of female and hermaphroditic reproductive systems among the individuals of the population). [citation needed]

Sexual systems vary across species most silene species are hermaphroditic representing 58.2% of silene species, 14.3% are dioecious, 13.3%  gynodioecious, and 12.2% being both gynodioecious and gynomonoecious. Trioecy, andromonoecy, and gynomonoecy have also been reported but are extremely rare.[5]

Species Name[6] Reproductive System(s)[6]
S. latifolia dioecy
S. dioica dioecy
S. diclinis dioecy
S. pendula gynodioecy
S. noctiflora gynodioecy, hermaphrodite
S. acaulis trioecy
S. saxifraga gynodioecy, andromonoecy
S. vulgaris gynodioecy, trioecy
S. gallica hermaphrodite
S. inaperta hermaphrodite

Genetics

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Out of 300,000 species of angiosperm, Silene are among the 5 to 10 percent whose individual offspring can be of different sexes.[7][8] Hetermorphic sex-determining chromosomes are very infrequent in plant genera; some notable examples that possess them, other than Silene, are Rumex, Humulus, and Cannabis.[9]

All species of Silene that are diploid possess the same number of chromosomes (n=12); males possess sex-determining Y chromosomes that are much larger than the X chromosomes.[4][10] Recombination generally occurs only when two X chromosomes (XX) pair during female meiosis. Contrastingly, recombination is suppressed across most of the Y chromosomes during pairing in male meiosis (XY).[11] When recombination does occur in XY chromosomes, it is confined to the tips of the chromosome, leaving most of the genetic material in the Y chromosome intact. [citation needed]

Importance of Y-chromosome

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Several studies concentrated on Silene latifolia have shown a correlation between loci on the Y chromosome and the sex that is expressed phenotypically in the flower. Two of these sex-linked genes "promote maleness" (male fertility and male promotion) and one of them codes for female suppression.[4][7] Therefore, the Y chromosome carries three dominant genes that determine the sexual expression in a Silene offspring. If there are deletions and mutations in the Y chromosome during reproduction, then different sex-linked genes are lost. The different combinations of possible sex-related genes that an individual Silene can have in one Y chromosome are what creates the rich variation of sexual phenotypes throughout this genus. [citation needed]

This diagram illustrates the different gene combinations that can appear on the Y chromosome of Silene latifolia. Each combination of genes leads to a distinct sexual expression. Adapted from "Silene latifolia : The Classical Model to Study Heteromorphic Sex Chromosomes" by E. Kejnovsky and B. Vyskot.[7]

Sexual expression

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The system for determining sex in Silene latifolia is close to that found in humans because in both cases the Y chromosome determines what reproductive mechanisms will be expressed in the offspring. They differ because there are multiple sex determining genes on the Y chromosome of S. latifolia, while in humans the presence or absence of the Y chromosome strictly determines whether the offspring is male or female.

Different combinations of the genes present in a Silene Y chromosome affect the sexual expression in the organism. For example, there are two genetic variations that can lead to male sterility in S. latifolia: if it possesses two Y chromosomes (YY) or if the Y chromosome possesses the female suppression and male promoting genes. Silene are also susceptible to a type of sexually transmitted infection that causes sterility. Another possible combination includes the presence of all three sex-linked genes (male suppressing, female suppressing, and male promoting) which produce virile male offspring. The flower is hermaphrodite when both male promoting and male fertility genes are present. Lastly, Y chromosomes carrying both female suppression and male fertility genes creates an asexual organism.[7]

See also

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References

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  1. ^ Xiong, Erhui; Wu, Xiaolin; Yang, Le; Wang, Wei (2016-01-01). Hakeem, Khalid Rehman; Tombuloğlu, Hüseyin; Tombuloğlu, Güzin (eds.). Plant Omics: Trends and Applications. Springer International Publishing. pp. 363–380. doi:10.1007/978-3-319-31703-8_15. ISBN 9783319317014.
  2. ^ Zluvova, Jitka; Georgiev, Sevdalin; Janousek, Bohuslav; Charlesworth, Deborah; Vyskot, Boris; Negrutiu, Ioan (1 September 2007). "Early Events in the Evolution of the Silene latifolia Y Chromosome: Male Specialization and Recombination Arrest". Genetics. 177 (1): 375–386. doi:10.1534/genetics.107.071175. PMC 2013713. PMID 17603119.
  3. ^ Moore, R. C.; Harkess, A. E.; Weingartner, L. A. (2016-07-01). "How to be a seXY plant model: A holistic view of sex-chromosome research". American Journal of Botany. 103 (8): 1379–1382. doi:10.3732/ajb.1600054. ISSN 0002-9122. PMID 27370315.
  4. ^ a b c d Ming, Ray; Bendahmane, Abdelhafid; Renner, Susanne S. (2011-01-01). "Sex chromosomes in land plants". Annual Review of Plant Biology. 62: 485–514. doi:10.1146/annurev-arplant-042110-103914. ISSN 1545-2123. PMID 21526970.
  5. ^ Casimiro-Soriguer, Inés; Buide, Maria L.; Narbona, Eduardo (2015-01-01). "Diversity of sexual systems within different lineages of the genus Silene". AoB Plants. 7 (plv037): plv037. doi:10.1093/aobpla/plv037. ISSN 2041-2851. PMC 4433491. PMID 25862920.
  6. ^ a b DESFEUX, CHRISTINE (2016). "Evolution of Reproductive Systems in the Genus Silene". Proceedings: Biological Sciences. 263 (1369): 409–414. JSTOR 50722.
  7. ^ a b c d Kejnovsky, Vyskot (2010). "Silene latifolia : The Classical Model to Study Heteromorphic Sex Chromosomes". Cytogenetic and Genome Research. 129 (1–3): 250–262. doi:10.1159/000314285. PMID 20551610. S2CID 42879462.
  8. ^ Käfer, J.; Talianová, M.; Bigot, T.; Michu, E.; Guéguen, L.; Widmer, A.; Žlůvová, J.; Glémin, S.; Marais, G. a. B. (2013-02-01). "Patterns of molecular evolution in dioecious and non-dioecious Silene". Journal of Evolutionary Biology. 26 (2): 335–346. doi:10.1111/jeb.12052. ISSN 1420-9101. PMID 23206219.
  9. ^ Dellaporta, S L; Calderon-Urrea, A (1993-10-01). "Sex determination in flowering plants". The Plant Cell. 5 (10): 1241–1251. doi:10.1105/tpc.5.10.1241. ISSN 1040-4651. PMC 160357. PMID 8281039.
  10. ^ Charlesworth, Deborah (2002-02-01). "Plant sex determination and sex chromosomes". Heredity. 88 (2): 94–101. doi:10.1038/sj.hdy.6800016. ISSN 0018-067X. PMID 11932767.
  11. ^ Bernasconi, G.; Antonovics, J.; Biere, A.; Charlesworth, D.; Delph, L. F.; Filatov, D.; Giraud, T.; Hood, M. E.; Marais, G. a. B. (2009-07-01). "Silene as a model system in ecology and evolution". Heredity. 103 (1): 5–14. doi:10.1038/hdy.2009.34. ISSN 1365-2540. PMID 19367316.