Plant sexuality

Close-up of an Echinopsis spachiana flower, showing both carpels (only the styles and stigmas are visible) and stamens, making it a complete flower.

Plant sexuality covers the wide variety of sexual reproduction systems found across the plant kingdom. This article describes morphological aspects of sexual reproduction of plants.

Among all living organisms, flowers, which are the reproductive structures of angiosperms, are the most varied physically and show the greatest diversity in methods of reproduction of all biological systems.[1] Carolus Linnaeus (1735 and 1753) proposed a system of classification of flowering plants based on plant structures, since plants employ many different morphological adaptations involving sexual reproduction, flowers played an important role in that classification system. Later on Christian Konrad Sprengel (1793) studied plant sexuality and called it the "revealed secret of nature" and for the first time it was understood that the pollination process involved both biotic and abiotic interactions (Charles Darwin's theories of natural selection utilized this work to promote his idea of evolution). Plants that are not flowering plants (green alga, mosses, liverworts, hornworts, ferns and gymnosperms) also have complex interplays between morphological adaptation and environmental factors in their sexual reproduction. The breeding system, or how the sperm from one plant fertilizes the ovals of another, is the single most important determinant of the mating structure of nonclonal plant populations. The mating structure or morphology of the flower parts and their arrangement on the plant in turn controls the amount and distribution of genetic variation, a central element in the evolutionary process.[2]

Flower, showing both carpels (only the styles and stigmas are visible) and stamens, making it a complete flower.

Contents

History

Unlike animals, plants are immobile and cannot seek out sexual partners for reproduction. The first plants used abiotic means to transport sperm for reproduction, utilizing water and wind. The first plants were aquatic and released sperm freely into the water to be carried by the currents. As plants moved onto land they used a thin film of water or water droplets like liverworts and ferns, in which mobile sperm swam from the male reproduction organs to the female organs. As plants became more complex and developed vascular systems enabling them to grow taller, they used alternation of generations like in ferns or the wind to move spores. In the Paleozoic era progymnosperms reproduced by using spores dispersed on the wind, 350 million years ago the seed plants evolved, including seed ferns, conifers and cordaites all were gymnosperms. Pollen grains, the male gametophyte, developed for protection of the sperm during the process of transfer from male to female parts. It is believed that insects feed on the pollen and plants evolved to use insects to actively carry pollen from one plant to the next. Seed producing plants, which include the angiosperms and the gymnosperms, have hetromorphic alternation of generations with large sporophytes containing much reduced gametophytes. Angiosperms have distinctive reproductive organs called flowers with carpels and the gametophyte is greatly reduced to a female embryo sac with as few as eight cells and the male gametophyte develop from the pollen grains. The sperm of seed plants are non motile except for two older groups of plants the Cycadophyta and the Ginkgophyta which have flagellated sperm.

Terminology

The flowers of angiosperms are determinate shoots that have sporophylls. The parts of flowers are named by scientists and show great variation in shape, these flower parts include sepals, petals, stamens and carpels. As a group the sepals form the calyx and as a group the petals form the corolla, together the corolla and the calyx is called the perianth. The stamens collectively are called the androecuim and the carpels collectively are called the gynoecium.

The complexity of the systems and devices used by plants to achieve sexual reproduction has resulted in botanists and evolutionary biologists using numerous terms to describe physical structures and functional strategies. Dellaporta and Calderon-Urrea (1993) list and define a variety of terms used to describe the modes of sexuality at different levels in flowering plants. This list is reproduced here [3], generalized to fit more than just plants that have flowers, and expanded to include other terms and more complete definitions.

The Alder is monoecious. Shown here: maturing male flower catkins on right, last year's female catkins on left

Individual reproductive unit (a flower in angiosperms)

Adaptations

Plants with wind pollinated flowers tend to have flowers without petals or sepals. Typically large amounts of pollen are produced and pollination often occurs early in the growing season before leaves can interfere with the dispersal of the pollen. Many trees and all grasses and sedges are wind pollinated, as such they have no need for large fancy flowers. In plants that use insects or other animals to move pollen from one flower to the next, plants have developed greatly modified flower parts to attract pollinators and to facilitate the movement of pollen from one flower to the insect and from the insect back to the next flower. Plants have a number of different means to attract pollinators including color, scent, heat, nectar glands, eatable pollen and flower shape. Along with modifications involving the above structures two other conditions play a very important role in the sexual reproduction of flowering plants, the first is timing of flowering and the other is the size or number of flowers produced. Often plant species have a few large, very showy flower while others produce many small flower, often flowers are collected together into large inflorescences to maximize their visual effect, becoming more noticeable to passing by pollinators. Flowers are attraction strategies and sexual expressions are functional strategies used to produce the next generation of plants, with pollinators and plants having co-evolved, often to some extraordinary degrees, very often mutually benefiting both.

The largest family of flowering plants is the orchids (Orchidaceae), estimated by some specialists to include up to 35,000 species,[4] which often have highly specialized flowers used to attract insects and facilitate pollination. The stamens are modified to produce pollen in clusters called pollinium, which are attached to insects when crawling into the flower. The flower shapes are modified to force insects to pass by the pollen, which is "glued" to the insect. Some orchids are even more highly specialized, with flower shapes that mimic the shape of insects to attract them to 'mate' with the flowers, a few even have scents that mimic insect pheromones.

Flower heads showing disk and ray florets.

Another large group of flowering plants is the Asteraceae or sunflower family with close to 22,000 species,[5] which also have highly modified inflorescences that are flowers collected together in heads composed of a composite of individual flowers called florets. Heads with florets of one sex, when the flowers are pistillate or functionally staminate, or made up of all bisexual florets, are called homogamous and can include discoid and liguliflorous type heads. Some radiate heads may be homogamous too. Plants with heads that have florets of two or more sexual forms are called heterogamous and include radiate and disciform head forms, though some radiate heads may be heterogamous too.

Individual plant sexuality

Many plants have complete flowers that have both male and female parts, others only have male or female parts and still other plants have flowers on the same plant that are a mix of male and female flowers. Some plants even have mixes that include all three types of flowers, where some flowers are only male, some are only female and some are both male and female. A distinction needs to be made between arrangements of sexual parts and the expression of sexuality in single plants verses the species. Some plants also undergo what is called Sex-switching, like Arisaema triphyllum which express sexual differences at different stages of growth. In some arums smaller plants produce all or mostly male flowers and as plants grow larger over the years the male flowers are replaced by more female flowers on the same plant. Arisaema triphyllum thus covers a multitude of sexual conditions in its life time; from nonsexual juvenile plants to young plants that are all male, as plants grow larger they have a mix of both male and female flowers, to large plants that have mostly female flowers.[6] Other species have plants that produce more male flowers early in the year and as plants bloom later in the growing season they produce more female flowers. In plants like Thalictrum dioicum all the plants in the species are ether male or female.

Specific terms are used to describe the sexual expression of individual plants within a population.

Holly (Ilex aquifolium) is dioecious: (above) shoot with flowers from male plant; (top right) male flower enlarged, showing stamens with pollen and reduced, sterile stigma; (below) shoot with flowers from female plant; (lower right) female flower enlarged, showing stigma
and reduced, sterile stamens with no pollen

Plant population

Most often plants show uniform strategies across the species or in populations in their sexual expression and specific terms are used to describe the sexual expression of the species or population.

About 11% of all angiosperms are strictly dioecious or monoecious, lntermediate forms of sexual dimorphism, including gynodioecy and androdioecy, represent 7% of the species examined of a survey of 120,000 plant species. In the same survey, 10% of the species contain both unisexual and bisexual flowers.[16]

The majority of plant species use allogamy - also called cross-pollination, as a means of breeding. Many plants are self fertile and the male parts can pollinate the female parts of the same flower and/or same plant. Some plants use a method known as self-incompatibility to promote outcrossing. In these plants, the male organs cannot fertilize the female parts of the same plant, other plants produce male and female flowers at different times to promote outcrossing. Some plants have bisexual flowers but the pollen is produced before the stigma of the same flower is receptive of pollen, this promotes out crossing by greatly limiting self pollination and these types of flowers are called protandrous.

Flower morphology

A species such as the ash tree (Fraxinus excelsior L.), demonstrates the possible range of variation in morphology and functionality exhibited by flowers with respect to gender. Flowers of the ash are wind-pollinated and lack petals and sepals. Structurally, the flowers may be either male or female, or even hermaphroditic, consisting of two anthers and an ovary. A male flower can be morphologically male or hermaphroditic, with anthers and a rudimentary gynoecium. Ash flowers can also be morphologically female, or hermaphroditic and functionally female.

Evolution

Angiosperms

It is thought that flowering plants evolved from a common hermaphrodite ancestor, and that dioecy evolved from hermaphroditism. Hermaphroditism is very common in flowering plants; over 85% are hermaphroditic, whereas only about 6-7% are dioecious and 5-6% are monoecious. [17] [18]

A fair degree of correlation (though far from complete) exists between dioecy/sub-dioecy and plants that have seeds dispersed by birds (both nuts and berries). It is hypothesized that the concentration of fruit in half of the plants increases dispersal efficiency; female plants can produce a higher density of fruit as they do not expend resources on pollen production, and the dispersal agents (birds) need not waste time looking for fruit on male plants. Other correlations with dioecy include: tropical distribution, woody growth form, perenniality, fleshy fruits, and small, green flowers.[19]

Plant growth regulators can be used to alter flower and plant sexuality, in cucumbers ethephon is used to delay staminate flowering and transforms monoecious lines into all-pistillate or female lines. Gibberellins also increase maleness in cucumbers. Cytokinins have been used in grapes that have undeveloped pistils to produce functional female organs and seed formation.

References

  1. Barrett, S. C. H. (2002). The evolution of plant sexual diversity. Nature Reviews Genetics 3(4): 274-284.
  2. Costich, D. E. (1995). Gender specialization across a climatic gradient: experimental comparison of monoecious and dioecious Ecballium. Ecology 76 (4): 1036-1050.
  3. Molnar, S. (2004). Plant Reproductive Systems, internet version posted February 17 2004.
  4. Orchidaceae in Flora of North America @ efloras.org
  5. Asteraceae in Flora of North America @ efloras.org
  6. Ewing, J. W., & Klein, R. M. (1982). Sex Expression in Jack-in-the-Pulpit. Bulletin of the Torrey Botanical Club 109 (1): 47-50. doi:10.2307/2484467
  7. Angiosperm sexual systems
  8. Correlation between male and female reproduction in the subdioecious herb Astilbe biternata (Saxifragaceae) - Olson and Antonovics 87 (6): 837 - American Journal of Botany
  9. Kiesselbach, T.A. (1999), The structure and reproduction of corn, Cold Spring Harbor, N.Y: Cold Spring Harbor Laboratory Press, pp. 3, ISBN 9780879695569, OCLC 245875754 
  10. http://www.ext.vt.edu/departments/envirohort/factsheets2/landsnurs/feb88pr6.html
  11. Waldbauer, Gilbert (2003), What good are bugs? : insects in the web of life, Cambridge, Mass.: Harvard University Press, pp. 33–34, ISBN 9780674010277, OCLC 50198798 
  12. Penn State Eberly College of Science - New Gene Discovered for Male Fertility in Plants
  13. Evolution of male sterility mechanisms in gynodioecious and dioecious species of Cirsium (Cynareae, Compositae) Journal Plant Systematics and Evolution Publisher Springer Wien ISSN 0378-2697 (Print) 1615-6110 (Online) Issue Volume 132, Number 4 / December, 1979 DOI 10.1007/BF00982395 Pages 327-332
  14. Males outcompete hermaphrodites for seed siring success in controlled crosses in the polygamous Fraxinus excelsior (Oleaceae) - Morand-Prieur et al. 90 (6): 949 - American Journal of Botany
  15. Barrett S.C.H.; Case A.L.; Peters G.B. Gender modification and resource allocation in subdioecious Wurmbea dioica (Colchicaceae) Journal of Ecology, Volume 87, Number 1, January 1999 , pp. 123-137(15)
  16. S. L. Dellaporta, and A. Calderon-Urrea Sex Determination in Flowering Plants Plant Cell 5: Pages 1241-1251.
  17. Rieger, R., A. Michaelis, and M.M. Green (1991). Glossary of Genetics, Fifth Edition. Springer-Verlag. ISBN 0-387-52054-6
  18. Heilbuth, J.C. (2000). Lower species richness in dioecious clades. American Naturalist 156: 221-241
  19. Vamosi, J.C., & Vamosi, S.M. (2004). The role of diversification in causing the correlates of dioecy. Evolution 58: 723-731

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