- Defining characteristics 1
- Etymology and usage 2
- Mammalian female 3
- Symbol 4
Sex determination 5
- Genetic determination 5.1
- Environmental determination 5.2
- See also 6
- Sources 7
- References 8
The sexually and asexually.
There is no single genetic mechanism behind sex differences in different species and the existence of two sexes seems to have evolved multiple times independently in different evolutionary lineages. Patterns of sexual reproduction include
- isogamous species with two or more mating types with gametes of identical form and behavior (but different at the molecular level),
- anisogamous species with gametes of male and female types,
- oogamous species in which the female gamete is very much larger than the male and has no ability to move. There is an argument that this pattern was driven by the physical constraints on the mechanisms by which two gametes get together as required for sexual reproduction.
Other than the defining difference in the type of gamete produced, differences between males and females in one lineage cannot always be predicted by differences in another. The concept is not limited to sporophytes that give rise to male and female plants.
Etymology and usage
The word female comes from the Latin femella, the diminutive form of femina, meaning "woman". It is not etymologically related to the word male, but in the late 14th century the spelling was altered in English to parallel the spelling of male.
A distinguishing characteristic of the vestigial in the male of the species.
Most mammalian females have two copies of the X chromosome as opposed to the male which carries only one X and one smaller Y chromosome (but some mammals, such as the Platypus, have different combinations). To compensate for the difference in size, one of the female's X chromosomes is randomly inactivated in each cell. In birds and reptiles, by contrast, it is the female which is heterozygous and carries a Z and a W chromosome whilst the male carries two Z chromosomes. Intersex conditions can also give rise to other combinations, but this usually results in sterility.
Mammalian females bear live young (with the rare exception of monotremes, which lay eggs). Some non-mammalian species, such as guppies, have analogous reproductive structures; and some other non-mammals, such as sharks, whose eggs hatch inside their bodies, also have the appearance of bearing live young.
A common symbol used to represent the female sex is ♀ (Unicode: U+2640 Alt codes: Alt+12), a circle with a small cross underneath. According to Schott, the most established view is that the male and female symbols "are derived from contractions in Greek script of the Greek names of these planets, namely Thouros (Mars) and Phosphoros (Venus). These derivations have been traced by Renkama who illustrated how Greek letters can be transformed into the graphic male and female symbols still recognised today." Thouros was abbreviated by θρ, and Phosphoros by Φκ, which were contracted into the modern symbols.
The hermaphroditic animals have both male and female reproductive organs.
The young of some species develop into one sex or the other depending on local environmental conditions, e.g. many crocodilians' sex is influenced by the temperature of their eggs. Other species (such as the goby) can transform, as adults, from one sex to the other in response to local reproductive conditions (such as a shortage of males).
Ayers, Donald M. English Words from Latin and Greek Elements. Second Edition. 1986. University of Arizona Press. United States.
- Dusenbery, David B. (2009). Living at Micro Scale, Chapter 20. Harvard University Press, Cambridge, Mass. ISBN 978-0-674-03116-6.
- Online Etymology Dictionary - Female (n.) Retrieved 2010-11-21
- Schott GD. Sex, drugs, and rock and roll: Sex symbols ancient and modern: their origins and iconography on the pedigree.BMJ 2005;331:1509-1510 (24 December), doi:10.1136/bmj.331.7531.1509
- Renkema HW. Oorspong, beteekenis en toepassing van de in de botanie gebuikelijke teekens ter aanduiding van het geslacht en den levensduur. In: Jeswiet J, ed. Gedendenkboek J Valckenier Suringar. Wageningen: Nederlandsche Dendrologische Vereeniging, 1942: 96-108.