Alternation of generations
In sexual reproduction, organisms have a haploid phase with one set of chromosomes and a diploid phase with two sets of chromosomes. In animals the body (soma) is usually diploid, while the haploid stage is only the gametes.
In eukaryotes an alternation of generations may occur. This means that both the diploid and the haploid phases are multi-cellular organisms. The classic example is the mosses, where the green plant is a haploid gametophyte, and the reproductive phase is the diploid sporophyte. The two forms often occur together, as shown in the illustration on the right
The term alternation of generations refers only to the sexual cycle: organisms may have asexual reproduction as well. The term should not be confused with life cycle stages in animals, which may look very different, but where all cells have two sets of chromosomes.
The alternation of generations is an important concept in the evolution of plants. All land plants have alternation of generations.
In mosses and their relatives (Bryophytes), the haploid gametophyte is the dominant generation, and the diploid sporophytes are sporangium-bearing stalks growing from the gametophytes. In ferns, the diploid sporophyte is much larger, and the haploid gametophyte is a little plant that can grow for a long time.
The sporophyte produces spores (hence the name), by meiosis. These develop into a gametophyte. Both the spores and the resulting gametophyte are haploid, meaning they have half as many chromosomes. Later, the mature gametophyte produces male or female gametes (or both) by mitosis. The fusion of male and female gametes (fertilization) produces a diploid zygote which develops into a new sporophyte. This is the cycle which is known as alternation of generations or alternation of phases.
As a factor in plant evolutionEdit
In the landmark work Variation and evolution in plants, Stebbins discussed how alternation of generations related to the overall evolution of plants. He began:
- "The most striking difference between the sexual cycle of animals and those found in plants is that, with the exception of a few Protozoa, animals are diploid at all stages, while nearly all plants have a haploid stage of greater or lesser duration. The sequence of types of alternation of generations... is one of the best-known features of plant evolution... The diploid generation has undoubtedly evolved independently many different times".
Later Stebbins comments:
- "The diploid condition brings about an increase in flexibility because it makes possible the condition of genetic dominance and recessiveness. In a haploid organism every new mutation is immediately exposed to the action of selection... In a diploid organism, on the other hand, each new mutant arises as a heterozygote and, if recessive, is sheltered from selection".
The point is that, in diploids, new alleles are sheltered and (collectively) they are a reservoir of potential variation in the population.
Most algae have dominant gametophyte generations, but in some species the gametophytes and sporophytes are morphologically similar (isomorphic).
Bryophytes (mosses, liverworts and hornworts) have a dominant gametophyte stage on which the adult sporophyte is dependent on the gametophyte for nutrition. The sporophyte develops from the zygote inside the female sex organ, so its early development is nurtured by the gametophyte.
Early land plants had sporophytes that produced identical spores: they looked the same whichever sex they developed into. The ancestors of the gymnosperms evolved complex heterosporous life cycles: the spores producing male and female gametophytes were of different sizes. The female megaspores tending to be larger, and fewer in number, than the male microspores.
During the Devonian, several plant groups independently evolved heterospory and later endospory, in which single megaspores were kept inside the sporangia of the parent sporophyte. These endosporic megaspores had a miniature multicellular female gametophyte with female sex organs and egg cells. The ova were fertilised by free-swimming sperm produced by windborne miniaturised male gametophytes in the form of pre-pollen.
The resulting zygote developed into the next sporophyte generation while still inside the single large female megaspore in the sporangium of the parent sporophyte. The evolution of heterospory and endospory was among the earliest steps in the evolution of seeds of the kind produced by gymnosperms and angiosperms.
Similar processes in other organismsEdit
Some Chromalveolata, some fungi and some slime moulds have what seems to be genuine alternation of generations. These groups include such a wide range of different types that it is difficult to say how common the phenomenon is. Certainly slime moulds are not a monophyletic group, and that may be true of the other two groups,
- see also life cycle
Alternation of generations between a multicellular diploid and a multicellular haploid generation does not exist in animals.
In some animals, there is a life cycle with different diploid stages. This has sometimes mistakenly been called "alternation of generations", but is quite different from what happens in plants and some protists. The most common case is that there are two distinct generations, where only one has sexual reproduction. Animals where it has been found include the Cnidaria and the Tunicates. The images on the right show the case of jellyfish: The medusa looks different from the polyp; they are different phenotypes. Only the medusa reproduces sexually.
In some cases, the cycle includes more than two generations. If this is the case, only one stage uses sexual reproduction. In aphids, for example, there is one generation that reproduces sexually, and up to forty that use parthenogenesis, a type of asexual reproduction.
- "Alternation of generations: reproductive cycles in which a haploid phase alternates with a diploid phase". King R.C. Stansfield W.D. & Mulligan P.K. 2006. A dictionary of genetics. 7th ed, Oxford University Press, p18. ISBN 0-19-530761-5
- Thomas B.A. and Spicer R.A. 1987. The evolution and palaeobiology of land plants. Croom Helm, London.
- which are not now regarded as animals
- Svedelius N. 1929. An evaluation of the structural evidence for genetic relationships in plants. Algae Proc. Int. Congr. Sci. 1 457–471.
- Stebbins, G. Ledyard 1950. Variation and evolution in plants. New York: Columbia University Press. Chapter V Genetic systems as factors in evolution: p157, 174.
- Kenrick P. & Crane P.R. (1997), "The origin and early evolution of plants on land" (PDF), Nature, 389 (6646): 33–39, Bibcode:1997Natur.389...33K, doi:10.1038/37918, S2CID 3866183
- Taylor T.N. Kerp H. & Hass H. 2005. Life history biology of early land plants: deciphering the gametophyte phase. Proceedings of the National Academy of Sciences 102, 5892-5897.
- Bell P.R. & Helmsley A.R. 2000. Green plants: their origin and diversity. Cambridge University Press ISBN 0-521-64673-1
- Barnes, R.S.K.; Calow, P.; Olive, P.J.W.; Golding, D.W.; Spicer, J.I. (2001), The Invertebrates: a synthesis, Oxford; Malden, MA: Blackwell, p. 321, ISBN 978-0-632-04761-1
- Scott, Thomas (1996), Concise Encyclopedia Biology, Berlin: Walter de Gruyter, p. 35, ISBN 978-3-11-010661-9