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Autogamy

February 15, 2024

"Selfing" redirects here. For self-pollination specifically in flowering plants, see Self-pollination.

Autogamy or self-fertilization refers to the fusion of two gametes that come from one individual. Autogamy is predominantly observed in the form of self-pollination, a reproductive mechanism employed by many flowering plants. However, species of protists have also been observed using autogamy as a means of reproduction. Flowering plants engage in autogamy regularly, while the protists that engage in autogamy only do so in stressful environments.

Occurrence edit

Protists edit

Paramecium aurelia edit

Paramecium aurelia is the most commonly studied protozoan for autogamy. Similar to other unicellular organisms, Paramecium aurelia typically reproduce asexually via binary fission or sexually via cross-fertilization. However, studies have shown that when put under nutritional stress, Paramecium aurelia will undergo meiosis and subsequent fusion of gametic-like nuclei.[1] This process, defined as hemixis, a chromosomal rearrangement process, takes place in a number of steps. First, the two micronuclei of P. aurelia enlarge and divide two times to form eight nuclei. Some of these daughter nuclei will continue to divide to create potential future gametic nuclei. Of these potential gametic nuclei, one will divide two more times. Of the four daughter nuclei arising from this step, two of them become anlagen, or cells that will form part of the new organism. The other two daughter nuclei become the gametic micronuclei that will undergo autogamous self-fertilization.[2] These nuclear divisions are observed mainly when the P. aurelia is put under nutritional stress. Research shows that P. aurelia undergo autogamy synchronously with other individuals of the same species.

Clonal aging and rejuvenation edit

In Paramecium tetraurelia, vitality declines over the course of successive asexual cell divisions by binary fission. Clonal aging is associated with a dramatic increase in DNA damage.[3][4][5] When paramecia that have experienced clonal aging undergo meiosis, either during conjugation or automixis, the old macronucleus disintegrates and a new macronucleus is formed by replication of the micronuclear DNA that had just experienced meiosis followed by syngamy. These paramecia are rejuvenated in the sense of having a restored clonal lifespan. Thus it appears that clonal aging is due in large part to the progressive accumulation of DNA damage, and that rejuvenation is due to repair of DNA damage during meiosis that occurs in the micronucleus during conjugation or automixis and reestablishment of the macronucleus by replication of the newly repaired micronuclear DNA.

Tetrahymena rostrata edit

Similar to Paramecium aurelia, the parasitic ciliate Tetrahymena rostrata has also been shown to engage in meiosis, autogamy and development of new macronuclei when placed under nutritional stress.[6] Due to the degeneration and remodeling of genetic information that occurs in autogamy, genetic variability arises and possibly increases an offspring's chances of survival in stressful environments.

Allogromia laticollaris edit

Allogromia laticollaris is perhaps the best-studied foraminiferan amoeboid for autogamy. A. laticollaris can alternate between sexual reproduction via cross-fertilization and asexual reproduction via binary fission. The details of the life cycle of A. laticollaris are unknown, but similar to Paramecium aurelia, A. laticollaris is also shown to sometimes defer to autogamous behavior when placed in nutritional stress. As seen in Paramecium, there is some nuclear dimorphism observed in A. laticollaris. There are often observations of macronuclei and chromosomal fragments coexisting in A. laticollaris. This is indicative of nuclear and chromosomal degeneration, a process similar to the subdivisions observed in P. aurelia. Multiple generations of haploid A. laticollaris individuals can exist before autogamy actually takes place.[7] The autogamous behavior in A. laticollaris has the added consequence of giving rise to daughter cells that are substantially smaller than those rising from binary fission.[8] It is hypothesized that this is a survival mechanism employed when the cell is in stressful environments, and thus not able to allocate all resources to creating offspring. If a cell was under nutritional stress and not able to function regularly, there would be a strong possibility of its offspring's fitness being sub-par.

Self-pollination in flowering plants edit

Main article: Self-pollination

About 10–15% of flowering plants are predominantly self-fertilizing.[9] Self-pollination is an example of autogamy that occurs in flowering plants. Self-pollination occurs when the sperm in the pollen from the stamen of a plant goes to the carpels of that same plant and fertilizes the egg cell present. Self-pollination can either be done completely autogamously or geitonogamously. In the former, the egg and sperm cells that unite come from the same flower. In the latter, the sperm and egg cells can come from a different flower on the same plant. While the latter method does blur the lines between autogamous self-fertilization and normal sexual reproduction, it is still considered autogamous self-fertilization.[10]

Self-pollination can lead to inbreeding depression due to expression of deleterious recessive mutations.[11] Meiosis followed by self-pollination results in little genetic variation, raising the question of how meiosis in self-pollinating plants is adaptively maintained over an extended period in preference to a less complicated and less costly asexual ameiotic process for producing progeny. For instance, Arabidopsis thaliana is a predominantly self-pollinating plant that has an outcrossing rate in the wild estimated at less than 0.3%,[12] and self-pollination appears to have evolved roughly a million years ago or more.[13] An adaptive benefit of meiosis that may explain its long-term maintenance in self-pollinating plants is efficient recombinational repair of DNA damage.[14]

Fungi edit

There are basically two distinct types of sexual reproduction among fungi. The first is outcrossing (in heterothallic fungi). In this case, mating occurs between two different haploid individuals to form a diploid zygote, that can then undergo meiosis. The second type is self-fertilization or selfing (in homothallic fungi). In this case, two haploid nuclei derived from the same individual fuse to form a zygote than can then undergo meiosis. Examples of homothallic fungi that undergo selfing include species with an aspergillus-like asexual stage (anamorphs) occurring in many different genera,[15] several species of the ascomycete genus Cochliobolus,[16] and the ascomycete Pneumocystis jirovecii[17] (for other examples, see Homothallism). A review of evidence on the evolution of sexual reproduction in the fungi led to the concept that the original mode of sexual reproduction in the last eukaryotic common ancestor was homothallic or self-fertile unisexual reproduction.[18]

Advantages edit

There are several advantages for the self-fertilization observed in flowering plants and protists. In flowering plants, it is important for some plants not to be dependent on pollinating agents that other plants rely on for fertilization. This is unusual, however, considering that many plant species have evolved to become incompatible with their own gametes. While these species would not be well served by having autogamous self-fertilization as a reproductive mechanism, other species, which do not have self-incompatibility, would benefit from autogamy. Protists have the advantage of diversifying their modes of reproduction. This is useful for a multitude of reasons. First, if there is an unfavorable change in the environment that puts the ability to deliver offspring at risk, then it is advantageous for an organism to have autogamy at its disposal. In other organisms, it is seen that genetic diversity arising from sexual reproduction is maintained by changes in the environment that favor certain genotypes over others. Aside from extreme circumstances, it is possible that this form of reproduction gives rise to a genotype in the offspring that will increase fitness in the environment. This is due to the nature of the genetic degeneration and remodeling intrinsic to autogamy in unicellular organisms. Thus, autogamous behavior may become advantageous to have if an individual wanted to ensure offspring viability and survival. This advantage also applies to flowering plants. However, it is important to note that this change has not shown to produce a progeny with more fitness in unicellular organisms.[19] It is possible that the nutrition deprived state of the parent cells before autogamy created a barrier for producing offspring that could thrive in those same stressful environments.

Disadvantages edit

In flowering plants, autogamy has the disadvantage of producing low genetic diversity in the species that use it as the predominant mode of reproduction. This leaves those species particularly susceptible to pathogens and viruses that can harm it. In addition, the foraminiferans that use autogamy have shown to produce substantially smaller progeny as a result.[20] This indicates that since it is generally an emergency survival mechanism for unicellular species, the mechanism does not have the nutritional resources that would be provided by the organism if it were undergoing binary fission.

Genetic consequences edit

Self-fertilization results in the loss of genetic variation within an individual (offspring), because many of the genetic loci that were heterozygous become homozygous. This can result in the expression of harmful recessive alleles, which can have serious consequences for the individual. The effects are most extreme when self-fertilization occurs in organisms that are usually out-crossing.[21] In plants, selfing can occur as autogamous or geitonogamous pollinations and can have varying fitness affects that show up as autogamy depression. After several generations, inbreeding depression is likely to purge the deleterious alleles from the population because the individuals carrying them have mostly died or failed to reproduce.

If no other effects interfere, the proportion of heterozygous loci is halved in each successive generation, as shown in the following table.

  • Parental  :   x   (100%), and in
  •  1 generation gives:   :  :  , which means that the frequency of heterozygotes now is 50% of the starting value.
  • By the  10 generation, heterozygotes have almost completely disappeared, and the population is polarized, with almost exclusively homozygous individuals (  and  )

Illustration model of the decrease in genetic variation in a population of self-fertilized organisms derived from a heterozygous individual, assuming equal fitness

Generation AA
(%) 		Aa
(%) 		aa
(%)
P 100
F1 25 50 25
F2 37.5 25 37.5
F3 43.75 12.5 43.75
F4 46.875 6.25 46.875
F5 48.4375 3.125 48.4375
F6 49.21875 1.5625 49.21875
F7 49.609375 0.78125 49.609375
F8 49.8046875 0.390625 49.8046875
F9 49.90234375 0.1953125 49.90234375
F10 49.995117187 ≈ 50.0 0.09765626 ≈ 0.0 49.995117187 ≈ 50.0

Evolution edit

See also: Autogamy depression

The evolutionary shift from outcrossing to self-fertilization is one of the most frequent evolutionary transitions in plants. Since autogamy in flowering plants and autogamy in unicellular species is fundamentally different, and plants and protists are not related, it is likely that both instances evolved separately. However, due to the little overall genetic variation that arises in progeny, it is not fully understood how autogamy has been maintained in the tree of life.

See also edit

References edit

  1. ^ Berger, James D. "Autogamy in Paramecium cell cycle stage-specific commitment to meiosis." Experimental cell research 166.2 (1986): 475-485.
  2. ^ Diller WF (1936). "Nuclear reorganization processes in Paramecium aurelia, with descriptions of autogamy and 'hemixis'". J. Morphol. 59: 11–67. doi:10.1002/jmor.1050590103. S2CID 84511785.
  3. ^ Smith-Sonneborn J (1979). "DNA repair and longevity assurance in Paramecium tetraurelia". Science. 203 (4385): 1115–7. Bibcode:1979Sci...203.1115S. doi:10.1126/science.424739. PMID 424739.
  4. ^ Holmes GE, Holmes NR (1986). "Accumulation of DNA damages in aging Paramecium tetraurelia". Mol. Gen. Genet. 204 (1): 108–14. doi:10.1007/bf00330196. PMID 3091993. S2CID 11992591.
  5. ^ Gilley D, Blackburn EH (1994). "Lack of telomere shortening during senescence in Paramecium". Proc. Natl. Acad. Sci. U.S.A. 91 (5): 1955–8. Bibcode:1994PNAS...91.1955G. doi:10.1073/pnas.91.5.1955. PMC 43283. PMID 8127914.
  6. ^ Kaczanowski A (2016). "Cohesion of Clonal Life History, Senescence and Rejuvenation Induced by Autogamy of the Histophagous Ciliate Tetrahymena Rostrata". Protist. 167 (5): 490–510. doi:10.1016/j.protis.2016.08.003. PMID 27631279.
  7. ^ Lee JJ, McEnery ME (1970). "Autogamy in Allogromia laticollaris (Foraminifera)". The Journal of Protozoology. 17 (2): 184–195. doi:10.1111/j.1550-7408.1970.tb02354.x.
  8. ^ K., Sen Gupta B. Modern Foraminifera. Dordrecht: Kluwer Academic, 1999. Print.
  9. ^ Wright SI, Kalisz S, Slotte T (June 2013). "Evolutionary consequences of self-fertilization in plants". Proc. Biol. Sci. 280 (1760): 20130133. doi:10.1098/rspb.2013.0133. PMC 3652455. PMID 23595268.
  10. ^ Eckert CG (2000). "Contributions of Autogamy and Geitonogamy to Self-Fertilization in a Mass-Flowering, Clonal Plant". Ecology. 81 (2): 532–542. doi:10.2307/177446. JSTOR 177446.
  11. ^ Charlesworth D, Willis JH (2009). "The genetics of inbreeding depression". Nat. Rev. Genet. 10 (11): 783–96. doi:10.1038/nrg2664. PMID 19834483. S2CID 771357.
  12. ^ Abbott RJ, Gomes MF (1989). "Population genetic structure and outcrossing rate of Arabidopsis thaliana (L.) Heynh". Heredity. 62 (3): 411–418. doi:10.1038/hdy.1989.56.
  13. ^ Tang C, Toomajian C, Sherman-Broyles S, Plagnol V, Guo YL, Hu TT, Clark RM, Nasrallah JB, Weigel D, Nordborg M (2007). "The evolution of selfing in Arabidopsis thaliana". Science. 317 (5841): 1070–2. Bibcode:2007Sci...317.1070T. doi:10.1126/science.1143153. PMID 17656687. S2CID 45853624.
  14. ^ Bernstein H, Hopf FA, Michod RE (1987). "The molecular basis of the evolution of sex". Adv. Genet. Advances in Genetics. 24: 323–70. doi:10.1016/s0065-2660(08)60012-7. ISBN 9780120176243. PMID 3324702.
  15. ^ Dyer, Paul S.; O'Gorman, Céline M. (January 2012). "Sexual development and cryptic sexuality in fungi: insights from Aspergillus species". FEMS Microbiology Reviews. 36 (1): 165–192. doi:10.1111/j.1574-6976.2011.00308.x. PMID 22091779.
  16. ^ Yun, S.-H.; Berbee, M. L.; Yoder, O. C.; Turgeon, B. G. (11 May 1999). "Evolution of the fungal self-fertile reproductive life style from self-sterile ancestors". Proceedings of the National Academy of Sciences. 96 (10): 5592–5597. Bibcode:1999PNAS...96.5592Y. doi:10.1073/pnas.96.10.5592. PMC 21905. PMID 10318929.
  17. ^ Richard, S.; Almeida, J. M. G. C. F.; Cissé, O. H.; Luraschi, A.; Nielsen, O.; Pagni, M.; Hauser, P. M.; Weiss, Louis M. (20 February 2018). "Functional and Expression Analyses of the Pneumocystis MAT Genes Suggest Obligate Sexuality through Primary Homothallism within Host Lungs". mBio. 9 (1). doi:10.1128/mBio.02201-17. PMC 5821091. PMID 29463658.
  18. ^ Heitman, Joseph (December 2015). "Evolution of sexual reproduction: A view from the fungal kingdom supports an evolutionary epoch with sex before sexes". Fungal Biology Reviews. 29 (3–4): 108–117. doi:10.1016/j.fbr.2015.08.002. PMC 4730888. PMID 26834823.
  19. ^ Eckert, Christopher G., and Christopher R. Herlihy. "Using a Cost-benefit Approach to Understand the Evolution of Self-fertilization in Plants: The Perplexing Case of Aquilegia Canadensis (Ranunculaceae)." Plant Species Biology 19.3 (2004): 159-73. Web.
  20. ^ Eckert CG (2000). "Contributions of Autogamy and Geitonogamy to Self-Fertilization in a Mass-Flowering, Clonal Plant". Ecology. 81 (2): 532–542. doi:10.2307/177446. JSTOR 177446.
  21. ^ Bernstein H, Byerly HC, Hopf FA, Michod RE (September 1985). "Genetic damage, mutation, and the evolution of sex". Science. 229 (4719): 1277–81. Bibcode:1985Sci...229.1277B. doi:10.1126/science.3898363. PMID 3898363.

February 15, 2024
autogamy, selfing, redirects, here, self, pollination, specifically, flowering, plants, self, pollination, self, fertilization, refers, fusion, gametes, that, come, from, individual, predominantly, observed, form, self, pollination, reproductive, mechanism, em. Selfing redirects here For self pollination specifically in flowering plants see Self pollination Autogamy or self fertilization refers to the fusion of two gametes that come from one individual Autogamy is predominantly observed in the form of self pollination a reproductive mechanism employed by many flowering plants However species of protists have also been observed using autogamy as a means of reproduction Flowering plants engage in autogamy regularly while the protists that engage in autogamy only do so in stressful environments Contents 1 Occurrence 1 1 Protists 1 1 1 Paramecium aurelia 1 1 2 Clonal aging and rejuvenation 1 1 3 Tetrahymena rostrata 1 1 4 Allogromia laticollaris 1 2 Self pollination in flowering plants 1 3 Fungi 2 Advantages 3 Disadvantages 3 1 Genetic consequences 4 Evolution 5 See also 6 ReferencesOccurrence editProtists edit Paramecium aurelia edit Paramecium aurelia is the most commonly studied protozoan for autogamy Similar to other unicellular organisms Paramecium aurelia typically reproduce asexually via binary fission or sexually via cross fertilization However studies have shown that when put under nutritional stress Paramecium aurelia will undergo meiosis and subsequent fusion of gametic like nuclei 1 This process defined as hemixis a chromosomal rearrangement process takes place in a number of steps First the two micronuclei of P aurelia enlarge and divide two times to form eight nuclei Some of these daughter nuclei will continue to divide to create potential future gametic nuclei Of these potential gametic nuclei one will divide two more times Of the four daughter nuclei arising from this step two of them become anlagen or cells that will form part of the new organism The other two daughter nuclei become the gametic micronuclei that will undergo autogamous self fertilization 2 These nuclear divisions are observed mainly when the P aurelia is put under nutritional stress Research shows that P aurelia undergo autogamy synchronously with other individuals of the same species Clonal aging and rejuvenation edit In Paramecium tetraurelia vitality declines over the course of successive asexual cell divisions by binary fission Clonal aging is associated with a dramatic increase in DNA damage 3 4 5 When paramecia that have experienced clonal aging undergo meiosis either during conjugation or automixis the old macronucleus disintegrates and a new macronucleus is formed by replication of the micronuclear DNA that had just experienced meiosis followed by syngamy These paramecia are rejuvenated in the sense of having a restored clonal lifespan Thus it appears that clonal aging is due in large part to the progressive accumulation of DNA damage and that rejuvenation is due to repair of DNA damage during meiosis that occurs in the micronucleus during conjugation or automixis and reestablishment of the macronucleus by replication of the newly repaired micronuclear DNA Tetrahymena rostrata edit Similar to Paramecium aurelia the parasitic ciliate Tetrahymena rostrata has also been shown to engage in meiosis autogamy and development of new macronuclei when placed under nutritional stress 6 Due to the degeneration and remodeling of genetic information that occurs in autogamy genetic variability arises and possibly increases an offspring s chances of survival in stressful environments Allogromia laticollaris edit Allogromia laticollaris is perhaps the best studied foraminiferan amoeboid for autogamy A laticollaris can alternate between sexual reproduction via cross fertilization and asexual reproduction via binary fission The details of the life cycle of A laticollaris are unknown but similar to Paramecium aurelia A laticollaris is also shown to sometimes defer to autogamous behavior when placed in nutritional stress As seen in Paramecium there is some nuclear dimorphism observed in A laticollaris There are often observations of macronuclei and chromosomal fragments coexisting in A laticollaris This is indicative of nuclear and chromosomal degeneration a process similar to the subdivisions observed in P aurelia Multiple generations of haploid A laticollaris individuals can exist before autogamy actually takes place 7 The autogamous behavior in A laticollaris has the added consequence of giving rise to daughter cells that are substantially smaller than those rising from binary fission 8 It is hypothesized that this is a survival mechanism employed when the cell is in stressful environments and thus not able to allocate all resources to creating offspring If a cell was under nutritional stress and not able to function regularly there would be a strong possibility of its offspring s fitness being sub par Self pollination in flowering plants edit Main article Self pollination About 10 15 of flowering plants are predominantly self fertilizing 9 Self pollination is an example of autogamy that occurs in flowering plants Self pollination occurs when the sperm in the pollen from the stamen of a plant goes to the carpels of that same plant and fertilizes the egg cell present Self pollination can either be done completely autogamously or geitonogamously In the former the egg and sperm cells that unite come from the same flower In the latter the sperm and egg cells can come from a different flower on the same plant While the latter method does blur the lines between autogamous self fertilization and normal sexual reproduction it is still considered autogamous self fertilization 10 Self pollination can lead to inbreeding depression due to expression of deleterious recessive mutations 11 Meiosis followed by self pollination results in little genetic variation raising the question of how meiosis in self pollinating plants is adaptively maintained over an extended period in preference to a less complicated and less costly asexual ameiotic process for producing progeny For instance Arabidopsis thaliana is a predominantly self pollinating plant that has an outcrossing rate in the wild estimated at less than 0 3 12 and self pollination appears to have evolved roughly a million years ago or more 13 An adaptive benefit of meiosis that may explain its long term maintenance in self pollinating plants is efficient recombinational repair of DNA damage 14 Fungi edit There are basically two distinct types of sexual reproduction among fungi The first is outcrossing in heterothallic fungi In this case mating occurs between two different haploid individuals to form a diploid zygote that can then undergo meiosis The second type is self fertilization or selfing in homothallic fungi In this case two haploid nuclei derived from the same individual fuse to form a zygote than can then undergo meiosis Examples of homothallic fungi that undergo selfing include species with an aspergillus like asexual stage anamorphs occurring in many different genera 15 several species of the ascomycete genus Cochliobolus 16 and the ascomycete Pneumocystis jirovecii 17 for other examples see Homothallism A review of evidence on the evolution of sexual reproduction in the fungi led to the concept that the original mode of sexual reproduction in the last eukaryotic common ancestor was homothallic or self fertile unisexual reproduction 18 Advantages editThere are several advantages for the self fertilization observed in flowering plants and protists In flowering plants it is important for some plants not to be dependent on pollinating agents that other plants rely on for fertilization This is unusual however considering that many plant species have evolved to become incompatible with their own gametes While these species would not be well served by having autogamous self fertilization as a reproductive mechanism other species which do not have self incompatibility would benefit from autogamy Protists have the advantage of diversifying their modes of reproduction This is useful for a multitude of reasons First if there is an unfavorable change in the environment that puts the ability to deliver offspring at risk then it is advantageous for an organism to have autogamy at its disposal In other organisms it is seen that genetic diversity arising from sexual reproduction is maintained by changes in the environment that favor certain genotypes over others Aside from extreme circumstances it is possible that this form of reproduction gives rise to a genotype in the offspring that will increase fitness in the environment This is due to the nature of the genetic degeneration and remodeling intrinsic to autogamy in unicellular organisms Thus autogamous behavior may become advantageous to have if an individual wanted to ensure offspring viability and survival This advantage also applies to flowering plants However it is important to note that this change has not shown to produce a progeny with more fitness in unicellular organisms 19 It is possible that the nutrition deprived state of the parent cells before autogamy created a barrier for producing offspring that could thrive in those same stressful environments Disadvantages editIn flowering plants autogamy has the disadvantage of producing low genetic diversity in the species that use it as the predominant mode of reproduction This leaves those species particularly susceptible to pathogens and viruses that can harm it In addition the foraminiferans that use autogamy have shown to produce substantially smaller progeny as a result 20 This indicates that since it is generally an emergency survival mechanism for unicellular species the mechanism does not have the nutritional resources that would be provided by the organism if it were undergoing binary fission Genetic consequences edit Self fertilization results in the loss of genetic variation within an individual offspring because many of the genetic loci that were heterozygous become homozygous This can result in the expression of harmful recessive alleles which can have serious consequences for the individual The effects are most extreme when self fertilization occurs in organisms that are usually out crossing 21 In plants selfing can occur as autogamous or geitonogamous pollinations and can have varying fitness affects that show up as autogamy depression After several generations inbreeding depression is likely to purge the deleterious alleles from the population because the individuals carrying them have mostly died or failed to reproduce If no other effects interfere the proportion of heterozygous loci is halved in each successive generation as shown in the following table Parental P displaystyle P nbsp A a displaystyle Aa nbsp x A a displaystyle Aa nbsp 100 and in F displaystyle F nbsp 1 generation gives 1 A A displaystyle 1AA nbsp 2 A a displaystyle 2Aa nbsp 1 a a displaystyle 1aa nbsp which means that the frequency of heterozygotes now is 50 of the starting value By the F displaystyle F nbsp 10 generation heterozygotes have almost completely disappeared and the population is polarized with almost exclusively homozygous individuals A A displaystyle AA nbsp and a a displaystyle aa nbsp Illustration model of the decrease in genetic variation in a population of self fertilized organisms derived from a heterozygous individual assuming equal fitness Generation AA Aa aa P 100 F1 25 50 25F2 37 5 25 37 5F3 43 75 12 5 43 75F4 46 875 6 25 46 875F5 48 4375 3 125 48 4375F6 49 21875 1 5625 49 21875F7 49 609375 0 78125 49 609375F8 49 8046875 0 390625 49 8046875F9 49 90234375 0 1953125 49 90234375F10 49 995117187 50 0 0 09765626 0 0 49 995117187 50 0Evolution editSee also Autogamy depression The evolutionary shift from outcrossing to self fertilization is one of the most frequent evolutionary transitions in plants Since autogamy in flowering plants and autogamy in unicellular species is fundamentally different and plants and protists are not related it is likely that both instances evolved separately However due to the little overall genetic variation that arises in progeny it is not fully understood how autogamy has been maintained in the tree of life See also editEffective selfing model Parthenogenesis Inbreeding Outcrossing Inbreeding depression Outbreeding depression Sequential hermaphroditism the organism spends part of its life as a female and part as a male self fertilization is not possible References edit Berger James D Autogamy in Paramecium cell cycle stage specific commitment to meiosis Experimental cell research 166 2 1986 475 485 Diller WF 1936 Nuclear reorganization processes in Paramecium aurelia with descriptions of autogamy and hemixis J Morphol 59 11 67 doi 10 1002 jmor 1050590103 S2CID 84511785 Smith Sonneborn J 1979 DNA repair and longevity assurance in Paramecium tetraurelia Science 203 4385 1115 7 Bibcode 1979Sci 203 1115S doi 10 1126 science 424739 PMID 424739 Holmes GE Holmes NR 1986 Accumulation of DNA damages in aging Paramecium tetraurelia Mol Gen Genet 204 1 108 14 doi 10 1007 bf00330196 PMID 3091993 S2CID 11992591 Gilley D Blackburn EH 1994 Lack of telomere shortening during senescence in Paramecium Proc Natl Acad Sci U S A 91 5 1955 8 Bibcode 1994PNAS 91 1955G doi 10 1073 pnas 91 5 1955 PMC 43283 PMID 8127914 Kaczanowski A 2016 Cohesion of Clonal Life History Senescence and Rejuvenation Induced by Autogamy of the Histophagous Ciliate Tetrahymena Rostrata Protist 167 5 490 510 doi 10 1016 j protis 2016 08 003 PMID 27631279 Lee JJ McEnery ME 1970 Autogamy in Allogromia laticollaris Foraminifera The Journal of Protozoology 17 2 184 195 doi 10 1111 j 1550 7408 1970 tb02354 x K Sen Gupta B Modern Foraminifera Dordrecht Kluwer Academic 1999 Print Wright SI Kalisz S Slotte T June 2013 Evolutionary consequences of self fertilization in plants Proc Biol Sci 280 1760 20130133 doi 10 1098 rspb 2013 0133 PMC 3652455 PMID 23595268 Eckert CG 2000 Contributions of Autogamy and Geitonogamy to Self Fertilization in a Mass Flowering Clonal Plant Ecology 81 2 532 542 doi 10 2307 177446 JSTOR 177446 Charlesworth D Willis JH 2009 The genetics of inbreeding depression Nat Rev Genet 10 11 783 96 doi 10 1038 nrg2664 PMID 19834483 S2CID 771357 Abbott RJ Gomes MF 1989 Population genetic structure and outcrossing rate of Arabidopsis thaliana L Heynh Heredity 62 3 411 418 doi 10 1038 hdy 1989 56 Tang C Toomajian C Sherman Broyles S Plagnol V Guo YL Hu TT Clark RM Nasrallah JB Weigel D Nordborg M 2007 The evolution of selfing in Arabidopsis thaliana Science 317 5841 1070 2 Bibcode 2007Sci 317 1070T doi 10 1126 science 1143153 PMID 17656687 S2CID 45853624 Bernstein H Hopf FA Michod RE 1987 The molecular basis of the evolution of sex Adv Genet Advances in Genetics 24 323 70 doi 10 1016 s0065 2660 08 60012 7 ISBN 9780120176243 PMID 3324702 Dyer Paul S O Gorman Celine M January 2012 Sexual development and cryptic sexuality in fungi insights from Aspergillus species FEMS Microbiology Reviews 36 1 165 192 doi 10 1111 j 1574 6976 2011 00308 x PMID 22091779 Yun S H Berbee M L Yoder O C Turgeon B G 11 May 1999 Evolution of the fungal self fertile reproductive life style from self sterile ancestors Proceedings of the National Academy of Sciences 96 10 5592 5597 Bibcode 1999PNAS 96 5592Y doi 10 1073 pnas 96 10 5592 PMC 21905 PMID 10318929 Richard S Almeida J M G C F Cisse O H Luraschi A Nielsen O Pagni M Hauser P M Weiss Louis M 20 February 2018 Functional and Expression Analyses of the Pneumocystis MAT Genes Suggest Obligate Sexuality through Primary Homothallism within Host Lungs mBio 9 1 doi 10 1128 mBio 02201 17 PMC 5821091 PMID 29463658 Heitman Joseph December 2015 Evolution of sexual reproduction A view from the fungal kingdom supports an evolutionary epoch with sex before sexes Fungal Biology Reviews 29 3 4 108 117 doi 10 1016 j fbr 2015 08 002 PMC 4730888 PMID 26834823 Eckert Christopher G and Christopher R Herlihy Using a Cost benefit Approach to Understand the Evolution of Self fertilization in Plants The Perplexing Case of Aquilegia Canadensis Ranunculaceae Plant Species Biology 19 3 2004 159 73 Web Eckert CG 2000 Contributions of Autogamy and Geitonogamy to Self Fertilization in a Mass Flowering Clonal Plant Ecology 81 2 532 542 doi 10 2307 177446 JSTOR 177446 Bernstein H Byerly HC Hopf FA Michod RE September 1985 Genetic damage mutation and the evolution of sex Science 229 4719 1277 81 Bibcode 1985Sci 229 1277B doi 10 1126 science 3898363 PMID 3898363 Retrieved from https en wikipedia org w index php title Autogamy amp oldid 1197714215, wikipedia, wiki, book, books, library,

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