Apomixis Explained

In botany, apomixis is asexual development of seed or embryo without fertilization. However, other definitions include replacement of the seed by a plantlet or replacement of the flower by bulbils.

Apomictically produced offspring are genetically identical to the parent plant, except in nonrecurrent apomixis. Its etymology is Greek for "away from" + "mixing".

Normal asexual reproduction of plants, such as propagation from cuttings or leaves, has never been considered to be apomixis. In contrast to parthenocarpy, which involves seedless fruit formation without fertilization, apomictic fruits have viable seeds containing a proper embryo, with asexual origin.

In flowering plants, the term "apomixis" is used in a restricted sense to mean agamospermy, i.e. clonal reproduction through seeds. Although agamospermy could theoretically occur in gymnosperms, it appears to be absent in that group.

Apogamy is a related term that has had various meanings over time. In plants with independent gametophytes (notably ferns), the term is still used interchangeably with "apomixis", and both refer to the formation of sporophytes by parthenogenesis of gametophyte cells.

Male apomixis (paternal apomixis) involves replacement of the genetic material of an egg by the genetic material of the pollen.

Some authors included all forms of asexual reproduction within apomixis, but that generalization of the term has since died out.[1]

Evolution

Because apomictic plants are genetically identical from one generation to the next, each lineage has some of the characters of a true species, maintaining distinctions from other apomictic lineages within the same genus, while having much smaller differences than is normal between species of most genera. They are therefore often called microspecies. In some genera, it is possible to identify and name hundreds or even thousands of microspecies, which may be grouped together as species aggregates, typically listed in floras with the convention "Genus species agg." (such as the bramble, Rubus fruticosus agg.). In some plant families, genera with apomixis are quite common, for example in Asteraceae, Poaceae, and Rosaceae. Examples of apomixis can be found in the genera Crataegus (hawthorns), Amelanchier (shadbush), Sorbus (rowans and whitebeams), Rubus (brambles or blackberries), Poa (meadow grasses), Nardus stricta (matgrass), Hieracium (hawkweeds) and Taraxacum (dandelions). Apomixis is reported to occur in about 10% of globally extant ferns.[2] Among polystichoid ferns, apomixis evolved several times independently in three different clades.

Although the evolutionary advantages of sexual reproduction are lost, apomixis can pass along traits fortuitous for evolutionary fitness. As Jens Clausen put it:[3]

The apomicts actually have discovered the effectiveness of mass production long before Mr. Henry Ford applied it to the production of the automobile. ... Facultative apomixis ... does not prevent variation; rather, it multiplies certain varietal products.

Facultative apomixis means that apomixis does not always occur, i.e., sexual reproduction can also happen. It appears likely that all apomixis in plants is facultative;[4] [5] in other words, that "obligate apomixis" is an artifact of insufficient observation (missing uncommon sexual reproduction).

Apogamy and apospory in non-flowering plants

The gametophytes of bryophytes, and less commonly ferns and lycopods can develop a group of cells that grow to look like a sporophyte of the species but with the ploidy level of the gametophyte, a phenomenon known as apogamy. The sporophytes of plants of these groups may also have the ability to form a plant that looks like a gametophyte but with the ploidy level of the sporophyte, a phenomenon known as apospory.[6] [7]

See also androgenesis and androclinesis described below, a type of male apomixis that occurs in a conifer, Cupressus dupreziana.

In flowering plants (angiosperms)

Agamospermy, asexual reproduction through seeds, occurs in flowering plants through many different mechanisms[4] and a simple hierarchical classification of the different types is not possible. Consequently, there are almost as many different usages of terminology for apomixis in angiosperms as there are authors on the subject. For English speakers, Maheshwari 1950[8] is very influential. German speakers might prefer to consult Rutishauser 1967.[9] Some older text books[10] on the basis of misinformation (that the egg cell in a meiotically unreduced gametophyte can never be fertilized) attempted to reform the terminology to match the term parthenogenesis as it is used in zoology, and this continues to cause much confusion.

Agamospermy occurs mainly in two forms: In gametophytic apomixis, the embryo arises from an unfertilized egg cell (i.e. by parthenogenesis) in a gametophyte that was produced from a cell that did not complete meiosis. In adventitious embryony (sporophytic apomixis), an embryo is formed directly (not from a gametophyte) from nucellus or integument tissue (see nucellar embryony).

Types in flowering plants

Maheshwari[8] used the following simple classification of types of apomixis in flowering plants:

Types of gametophytic apomixis

Gametophytic apomixis in flowering plants develops in several different ways.[11] A megagametophyte develops with an egg cell within it that develops into an embryo through parthenogenesis. The central cell of the megagametophyte may require fertilization to form the endosperm, pseudogamous gametophytic apomixis, or in autonomous gametophytic apomixis endosperm fertilization is not required.

Considerable confusion has resulted because diplospory is often defined to involve the megaspore mother cell only, but a number of plant families have a multicellular archesporium and the megagametophyte could originate from another archesporium cell.

Diplospory is further subdivided according to how the megagametophyte forms:

Incidence in flowering plants

Apomixis occurs in at least 33 families of flowering plants, and has evolved multiple times from sexual relatives.[12] [13] Apomictic species or individual plants often have a hybrid origin, and are usually polyploid.[13]

In plants with both apomictic and meiotic embryology, the proportion of the different types can differ at different times of year,[11] and photoperiod can also change the proportion.[11] It appears unlikely that there are any truly completely apomictic plants, as low rates of sexual reproduction have been found in several species that were previously thought to be entirely apomictic.[11]

The genetic control of apomixis can involve a single genetic change that affects all the major developmental components, formation of the megagametophyte, parthenogenesis of the egg cell, and endosperm development.[14] However, the timing of the various developmental processes is critical to successful development of an apomictic seed, and the timing can be affected by multiple genetic factors.[14]

Related terms

The first process is a natural one. It may also be referred to as male apomixis or paternal apomixis. It involves fusion of the male and female gametes and replacement of the female nucleus by the male nucleus. This has been noted as a rare phenomenon in many plants (e.g. Nicotiana and Crepis), and occurs as the regular reproductive method in the Saharan Cypress, Cupressus dupreziana.[15] [16] [17] Recently, the first example of natural androgenesis in a vertebrate, a fish, Squalius alburnoides was discovered.[18] It is also known in invertebrates, particularly clams in the genus Corbicula, and these asexually reproducing males are noted to have a wider range than their noninvasive non-hermaphroditic cousins, more similar to hermaphroditic invasive species in the genus, indicating that this does sometimes have evolutionary benefits.[19]

The second process that is referred to as androgenesis or androclinesis involves (artificial) culture of haploid plants from anther tissue or microspores.[20] Androgenesis has also been artificially induced in fish.[21]

See also

Further reading

Notes and References

  1. Bicknell. Ross A.. Koltunow. Anna M.. Anna Koltunow. 2004. Understanding Apomixis: Recent Advances and Remaining Conundrums. The Plant Cell. 16. suppl 1. S228–S245. 10.1105/tpc.017921. 2643386. 15131250.
  2. Liu . Hong-Mei . Dyer . Robert J. . Guo . Zhi-You . Meng . Zhen . Li . Jian-Hui . Schneider . Harald . The Evolutionary Dynamics of Apomixis in Ferns: A Case Study from Polystichoid Ferns . Journal of Botany . 2012 . 2012-11-05 . 2090-0120 . 10.1155/2012/510478 . 1–11 . free .
  3. Clausen. J.. 1954. Partial apomixis as an equilibrium system. Caryologia. 1954, Supplement. 469–479.
  4. Book: Savidan, Y.H.. 2000. Plant Breeding Reviews. Apomixis: genetics and breeding. 18. 13–86. 10.1002/9780470650158.ch2. 9780470650158.
  5. free.
  6. Steil, W.N. . 1939 . Apogamy, apospory, and parthenogenesis in the Pteridophytes . The Botanical Review . 5 . 8 . 433–453 . 10.1007/bf02878704. 1939BotRv...5..433S . 19209851 .
  7. Book: Niklas, K.J. . 1997 . The evolutionary biology of plants . The University of Chicago press . Chicago . 9780226580838 .
  8. Maheshwari, P. 1950. An introduction to the embryology of the angiosperms. McGraw-Hill, New York.
  9. Rutishauser, A. 1969. Embryologie und Fortpflanzungsbiologie der Angiospermen: eine Einführung. Springer-Verlag, Wien.
  10. Fitting, H., et al. 1930. Textbook of botany (Strasburger's textbook of botany, rewritten). Macmillan, London.
  11. Nogler, G.A. 1984. Gametophytic apomixis. In Embryology of angiosperms. Edited by B.M. Johri. Springer, Berlin, Germany. pp. 475–518.
  12. Carman, J.G.. 1997. Asynchronous expression of duplicate genes in angiosperms may cause apomixis, bispory, tetraspory, and polyembryony. Biological Journal of the Linnean Society. 61. 1. 51–94. 10.1111/j.1095-8312.1997.tb01778.x. free.
  13. Book: Nygren, A. . 1967 . Handbuch der Pflanzenphysiologie . Apomixis in the angiosperms . Springer-Verlag . Berlin. W. Ruhland . 551–596. 18.
  14. Koltunow, A.M. . Johnson, S.D. . Bicknell, R.A. . 2000. Apomixis is not developmentally conserved in related, genetically characterized Hieracium plants of varying ploidy. Sexual Plant Reproduction. 12. 5. 253–266. 10.1007/s004970050193. 23186733 .
  15. Christian Pichot . Benjamin Liens . Juana L. Rivera Nava . Julien B. Bachelier . Mohamed El Maâtaoui . January 2008 . Cypress Surrogate Mother Produces Haploid Progeny From Alien Pollen . Genetics. 178 . 1 . 379–383 . 10.1534/genetics.107.080572 . 18202380 . 2206086.
  16. Christian Pichot. Bruno Fady. Isabelle Hochu. 2000. Lack of mother tree alleles in zymograms of Cupressus dupreziana A. Camus embryos. Annals of Forest Science. 57. 1 . 17–22. 10.1051/forest:2000108. 2000AnFSc..57...17P . free.
  17. Pichot, C. . El Maataoui, M. . Raddi, S. . Raddi, P. . 2001. Conservation: Surrogate mother for endangered Cupressus. Nature. 412. 6842. 39. 10.1038/35083687. 11452293 . 39046191 . free.
  18. Morgado-Santos . Miguel . Carona . Sara . Vicente . Luís . Collares-Pereira . Maria João . First empirical evidence of naturally occurring androgenesis in vertebrates . Royal Society Open Science . 2017 . 4 . 5 . 170200 . 10.1098/rsos.170200 . 28573029 . 5451830 . 2017RSOS....470200M . free .
  19. Pigneur . L.-M. . Hedtke . S. M. . Etoundi . E. . Van Doninck . K. . Androgenesis: a review through the study of the selfish shellfish Corbicula spp . Heredity . June 2012 . 108 . 6 . 581–591 . 10.1038/hdy.2012.3 . 22473310 . 3356815 . 1365-2540. free .
  20. Solntzeva . M.P. . 2003 . About some terms of apomixis: pseudogamy and androgenesis . Biologia . 58 . 1. 1–7 .
  21. Grunina . A. S. . Recoubratsky . A. V. . Induced Androgenesis in Fish: Obtaining Viable Nucleocytoplasmic Hybrids . Russian Journal of Developmental Biology . 1 July 2005 . 36 . 4 . 208–217 . 10.1007/s11174-005-0035-5 . 16208936 . 11750658 . en . 1608-3326.
  22. Defining species: a sourcebook from antiquity to today, by John S. Wilkins,, 2009, pp. 122, 194