Alternation of Generations

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alternation of generations:

see gametophytegametophyte
, phase of plant life cycles in which the gametes, i.e., egg and sperm, are produced. The gametophyte is haploid, that is, each cell contains a single complete set of chromosomes, and arises from the germination of a haploid spore.
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; reproductionreproduction,
capacity of all living systems to give rise to new systems similar to themselves. The term reproduction may refer to this power of self-duplication of a single cell or a multicellular animal or plant organism.
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Alternation of Generations


in some invertebrates, for example, hydroids, the alternation of two or more generations differing in morphological characteristics, mode of life, and type of reproduction. The developmental cycle of most plants is marked by the alternation of two generations, or phases: one forms the organs of sexual reproduction, and the other has organs of asexual reproduction.

Alternation of Generations


a regular succession of generations differing in mode of reproduction.

Animals may have primary or secondary alternation of generations. A primary alternation of generations, which characterizes many protozoans, is the alternation of a sexual generation with a generation reproducing by asexual cells (agametes). In foraminifers, for example, the alternating generations consist of sexual and asexual individuals—gamonts and agamonts (schizonts), respectively. By repeated division of the nucleus, the gamonts form gametes, which copulate in pairs to form a zygote, which in turn develops into an agamont. The agamont divides into agametes—future gamonts—as a result of schizogony. Since reduction division, or meiosis, occurs before agametes form, the sexual generation, like the gametes, is haploid, whereas the zygote and agamonts are diploid. In sporozoans and flagellates only the zygote is diploid, because meiosis is effected during the first division. In heliozoans, some flagellates, and infusorians meiosis is associated with the formation of gametes, the only haploid stage in the life cycle. This pattern typifies all multicellular animals.

A secondary alternation of generations occurs in two forms in animals. The alternation of different forms of sexual reproduction, for example, the normal sexual process with parthogenesis, is called heterogony. The alternation of sexual and asexual reproduction by means of multicellular vegetative bodies or by transverse division is called metagenesis. Heterogony is characteristic of trematodes, some roundworms, rotifers, and some arthropods (including water fleas, aphids, gallflies, and some gall midges). Metagenesis is very characteristic of tunicates (salpae, Doliolidae, ascidians, and pyrosomes) and coelenterates (hydrozoans and scyphozoans) in which the sexual generation consists of single free-swimming medusae and the asexual generation consist of sessile polyps, which often form colonies. Metagenesis in the broad sense should also include polyembryony, since embryos that reproduce vegetatively more or less constitute an underdeveloped asexual generation.


Miasoedov, S. V. Iavleniia razmnozhenüa i pola v organicheskom mire. Tomsk, 1935.
Hartmann, M. Obshchaia biologiia, 2nd ed. Moscow-Leningrad, 1936. (Translated from German.)
Dogel’, V. A. Zoologiia bespozvonochnykh, 6th ed. Moscow, 1975.
The alternation of generations in plants usually refers to the alternation of diploid and haploid phases in the developmental cycles. It is characteristic of plants in which both the diploid phase (diplont) and the haploid phase (haplont) are multicellular. The diplont forms sporangia, in which spores result from meiosis (hence a diplont is also called a sporophyte); the haplont forms gametangia, whose gametes are formed without reduction division (a haplont is also called a gametophyte). A sporophyte develops from a zygote, and a gametophyte from a spore. In some plants, for example, the algae Ulva and Dictiota, the sporophyte and gametophyte develop equally. In others, however, there is dominance of either the gametophyte (some brown algae [for example, Cutleria] and all bryophytes) or the sporophyte (some brown algae [for example, Laminaria] and all ferns and seed plants). In many green and, possibly, in some red algae only the zygotes that divide by meiosis are diploid, whereas in Siphonales, diatoms, and some brown algae only the gametes are haploid, as in the great majority of animals. These plants do not actually have an alternation of generations, although there is a succession of nuclear phases.
The sporophytes, or sporogonia, of bryophytes develop on the gametophytes. The gametophytes of ferns exist independently, whereas those of seed plants develop on the sporophytes. The gametophytes of isosporous plants are monoecious; those of heterosporous plants are dioecious and more reduced (especially males) than those of isoporous plants. In angiosperms the male gametophyte is the pollen grain, and the female gametophyte the embryo sac.


Takhtadzhian, A. L. Vysshie rasteniia, vol. 1: Ot psilofitovykh do khvoinykh. Moscow-Leningrad, 1956.
Poddubnaia-Arnol’di, V. A. Tsitoembriologiia pokrytosemennykh rastenii. Moscow, 1976.


alternation of generations

[‚ȯl·tər′nā·shən əv ‚jen·ə′rā·shənz]
References in periodicals archive ?
Celakovsky's (1874) purpose was to present an accurate classification of the alternation of generations (Generationswechsel).
Pringsheim (1876b) presented a contrary interpretation of the connection between alternation of generations in thallophytes and mosses.
Bower (1890) viewed the alternation of generations of archegoniates as arising from the adaptation of an initially aquatic organism for the land.
Here, Scott referred to recent discoveries that had shaken a strictly morphological interpretation of the alternation of generations, and that had "dropped as a bombshell" (Bower, 1935; p.
An argument often put forward in favor of the homologous theory of alternation of generations (and sporophyte origin) is the alleged "evidence" of algae with isomorphic (morphologically identical or very similar) gametophytes and sporophytes, such as Ulva, Cladophora suhriana, Chaetomorpha (cf.
246) presented an easy-to-follow "flow diagram" of the evolution of meiosis, life cycles, alternation of generations, and so forth; their tracings led first to eukaryotes (after the development of mitosis and meiosis), and then to several major eukaryotic lineages and sublineages, including land plants based on the timing of meiosis in the life cycle and the supposed development of alternating generations.
South and Whittick speculated that this alternation of generations in algae, connecting to land-plant origins, would be heteromorphic (they did not name a specific group of algae).

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