Asexual Asexual reproduction is a process by which organisms create genetically similar or identical copies of themselves without the contribution of genetic material from another organism. Bacteria divide asexually via
binary fission; viruses take control of host cells to produce more viruses;
Hydras (
invertebrates of the
order Hydroidea) and
yeasts are able to reproduce by
budding. These organisms often do not possess different sexes, and they are capable of "splitting" themselves into two or more copies of themselves. Most plants have the ability to reproduce asexually and the ant species
Mycocepurus smithii is thought to reproduce entirely by asexual means. Some species that are capable of reproducing asexually, like
hydra,
yeast (See
Mating of yeasts) and jellyfish, may also reproduce sexually. For instance, most plants are capable of
vegetative reproductionreproduction without seeds or sporesbut can also reproduce sexually. Likewise, bacteria may exchange genetic information by
conjugation. Other ways of asexual reproduction include
parthenogenesis,
fragmentation and
spore formation that involves only
mitosis. Parthenogenesis is the growth and development of
embryo or
seed without
fertilization. Parthenogenesis occurs naturally in some species, including lower plants (where it is called
apomixis),
invertebrates (e.g.
water fleas,
aphids, some
bees and
parasitic wasps), and
vertebrates (e.g. some reptiles, some fish, and very rarely, domestic birds).
Sexual Sexual reproduction is a
biological process that creates a new
organism by combining the
genetic material of two organisms in a process that starts with
meiosis, a specialized type of
cell division. Each of two parent organisms contributes half of the offspring's genetic makeup by creating
haploid gametes. Most organisms form two different types of gametes. In these
anisogamous species, the two sexes are referred to as male (producing
sperm or microspores) and female (producing
ova or megaspores). In
isogamous species, the gametes are similar or identical in form (
isogametes), but may have separable properties and then may be given other different names (see
isogamy). Because both gametes look alike, they generally cannot be classified as male or female. For example, in the green alga,
Chlamydomonas reinhardtii, there are so-called "plus" and "minus" gametes. A few types of organisms, such as many fungi and the
ciliate Paramecium aurelia, have more than two "sexes", called
mating types. Most animals (including humans) and plants reproduce sexually. Sexually reproducing organisms have different sets of genes for every trait (called
alleles). Offspring inherit one allele for each trait from each parent. Thus, offspring have a combination of the parents' genes. It is believed that "the masking of deleterious alleles favors the evolution of a dominant diploid phase in organisms that alternate between haploid and diploid phases" where recombination occurs freely.
Bryophytes reproduce sexually, but the larger and commonly-seen organisms are
haploid and produce
gametes. The gametes fuse to form a
zygote which develops into a
sporangium, which in turn produces haploid spores. The
diploid stage is relatively small and short-lived compared to the haploid stage, i.e.
haploid dominance. The advantage of diploidy, heterosis, only exists in the diploid life generation. Bryophytes retain sexual reproduction despite the fact that the haploid stage does not benefit from heterosis. This may be an indication that the sexual reproduction has advantages other than heterosis, such as
genetic recombination between members of the species, allowing the expression of a wider range of traits and thus making the population more able to survive environmental variation.
Allogamy Allogamy is the fertilization of flowers through cross-pollination, this occurs when a flower's ovum is fertilized by spermatozoa from the pollen of a different plant's flower. Pollen may be transferred through
pollen vectors or abiotic carriers such as wind. Fertilization begins when the pollen is brought to a female gamete through the pollen tube. Allogamy is also known as cross fertilization, in contrast to autogamy or geitonogamy which are methods of self-fertilization.
Autogamy Self-
fertilization, also known as autogamy, occurs in
hermaphroditic organisms where the two
gametes fused in fertilization come from the same individual, e.g., many
vascular plants, some
foraminiferans, some
ciliates. or within a single
monoecious gymnosperm plant.
Mitosis and meiosis Mitosis and
meiosis are types of
cell division. Mitosis occurs in
somatic cells, while meiosis occurs in
gametes.
Mitosis The resultant number of cells in mitosis is twice the number of original cells. The number of
chromosomes in the offspring cells is the same as that of the parent cell.
Meiosis The resultant number of cells is four times the number of original cells. This results in cells with half the number of
chromosomes present in the parent cell. A
diploid cell duplicates itself, then undergoes two divisions (
tetraploid to diploid to haploid), in the process forming four
haploid cells. This process occurs in two phases, meiosis I and meiosis II.
Gametogenesis Animals, including mammals, produce gametes (sperm and egg) by means of
meiosis in gonads (testicles in males and ovaries in females). Sperm are produced by
spermatogenesis and eggs are produced by
oogenesis. During gametogenesis in mammals numerous genes encoding proteins that participate in DNA repair mechanisms exhibit enhanced or specialized expression. Male
germ cells produced in the testes of animals are capable of special
DNA repair processes that function during meiosis to repair DNA damages and to maintain the integrity of the
genomes that are to be passed on to progeny. Such DNA repair processes include
homologous recombinational repair as well as
non-homologous end joining. These repair processes allow the integrity of the
genome to be maintained and offspring health to be protected. The obvious approaches, subject to a growing amount of activity, are
female sperm and
male eggs. In 2004, by altering the function of a few genes involved with imprinting, other Japanese scientists combined two mouse eggs to produce daughter mice In 2010, American scientists used genetically manipulated stem cells to produce viable mouse offspring carrying genetic contributions from two fathers. In 2018 Chinese scientists created 29 female mice from two mice mothers but were unable to produce viable offspring from two father mice. Researches noted that there is little chance these techniques would be applied to humans in the near future. In 2023, Japanese scientists created mouse pups from two mice fathers which grew into adulthood. == Strategies ==