Poeciliidae
Poeciliidae | |
---|---|
Green swordtail, Xiphophorus hellerii | |
Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Animalia |
Phylum: | Chordata |
Class: | Actinopterygii |
Order: | Cyprinodontiformes |
Superfamily: | Poecilioidea |
Family: | Poeciliidae Bonaparte, 1831[1] |
Subfamilies & Genera | |
See text |
The Poeciliidae are a
Live-bearing
Although the whole family Poeciliidae is known as "live bearers" (viviparous), some species are egg-scattering with external fertilization. All African species are egg-layers, and (with the exception of the members of the genus Tomeurus), all American species are live-bearers. Among the three subfamilies, the Aplocheilichthyinae are restricted to Africa, the Poeciliinae are primarily from the Americas (the only exception is the African Rhexipanchax), and the Procatopodinae are mainly from Africa (the South American Fluviphylax and Pseudopoecilia are the only exceptions). This distribution suggests that the Poeciliidae antedate the split between Africa and South America 100 million years ago, and that live-bearing subsequently evolved in South America. Poeciliids colonized North America through the Antilles, while they were connected 44 million years ago. Poeciliids then moved to Central America by the Aves land bridge on the Caribbean Plate. When South America connected to Central America three million years ago, some further dispersal southward occurred, but South American species did not move into Central America.[3]
Among the live-bearing species, differences are seen in the mode and degree of support the female gives the developing larvae. Many members of the family Poeciliidae are considered to be
Members of the genus Poeciliopsis, for example, show variable reproductive life history adaptations. Poeciliopsis monacha, P. lucida, and P. prolifica form part of the same clade within that genus. However, their modes of maternal provisioning vary greatly. P. monacha can be considered to be lecithotrophic because it does not really provide any resources for its offspring after fertilization - the pregnant female is basically a swimming egg sac. P. lucida shows an intermediate level of matrotrophy, meaning that to a certain extent the offspring's metabolism can actually affect the mother's metabolism, allowing for increased nutrient exchange. P. prolifica is considered to be highly matrotrophic, and almost all of the nutrients and materials needed for fetal development are supplied to the oocyte after it has been fertilized. This level of matrotrophy allows Poeciliopsis to carry several broods at different stages of development, a phenomenon known as superfetation. Because the space for developing embryos is limited, viviparity reduces brood size. Superfetation can compensate for this loss by keeping embryos at various stages and sizes during development.[5]
P. elongata, P. turneri, and P. presidionis form another clade that could be considered an outgroup to the P. monacha, P.lucida, and P. prolifica clade. These three species are very highly matrotrophic - so much so that in 1947, C. L. Turner described the follicular cells of P. turneri as "pseudo-placenta, pseudo-chorion, and pseudo-allantois".[citation needed] The greater degree of matrotrophy in a species is linked with a higher degree of placentation, including "a thicker maternal follicle, higher degree of vascularization, and greater number of villi in the placenta".[4]
The reason for placental evolution in Poeciliids is controversial, and involves two major groups of hypotheses, adaptive and conflict hypotheses.[6] Adaptive hypotheses, including the locomotor hypothesis,[7] Trexler-DeAngelis Model[8] (reproductive allotment), and life-history facilitation,[9][6] broadly suggest that the placenta evolved to facilitate the evolution of another advantageous trait in the fish's environment. The conflict hypothesis suggests the placenta is a nonadaptive byproduct of genetic "tug-o-war" between the mother and the offspring for resources.[10]
Subfamilies and tribes
The family is divided into subfamilies and tribes as follows:[1][11]
- Subfamily Aplocheilichythinae Myers, 1928 (Banded lampeyes)
- Genus Aplocheilichthys Bleeker, 1863
- Genus Hylopanchax Poll & J. G. Lambert,1958
- Genus
- Subfamily Procatopodinae Fowler, 1916 (Lampeyes)
- Tribe Fluviphylacini Roberts, 1970
- Genus Fluviphylax Whitley, 1920
- Tribe Procatopodini Fowler, 1916
- Genus Laciris Huber, 1981
- Genus Micropanchax Myers, 1924
- Genus Lacustricola Myers, 1924
- Genus Poropanchax Clausen, 1967
- Genus Platypanchax Ahl, 1928
- Genus Lamprichthys Regan1911
- Genus Pantanodon Myers, 1955
- Genus Hypsopanchax Myers, 1924
- Genus Procatopus Boulenger, 1904
- Genus Plataplochilus Ahl, 1928
- Genus Rhexipanchax Huber, 1999
- Tribe
- Subfamily Poeciliinae Bonaparte, 1831 (Livebearers)
- Tribe Alfarini Hubbs, 1924
- Tribe Gill, 1889
- Genus Belonesox Kner, 1860
- Genus Brachyrhaphis Regan, 1913
- Genus Gambusia Poey, 1854
- Genus Heterophallus Regan, 1914
- Genus
- Tribe Heterandriini Hubbs, 1924
- Genus Heterandria Agassiz, 1853
- Genus Neoheterandria Henn 1916
- Genus Poeciliopsis Regan 1913
- Genus Priapichthys Regan 1913
- Genus Pseudopoecilia Regan 1913
- Genus XenophallusHubbs, 1924
- Tribe Poeciliini Bonaparte, 1831
- Genus Limia Poey, 1854
- Genus Micropoecilia Hubbs, 1926
- Genus Pamphorichthys Regan, 1913
- Genus Phallichthys Hubbs, 1924
- Genus Poecilia Bloch & Schneider, 1801
- Genus Xiphophorus Heckel, 1848
- Tribe Cnesterodontini Hubbs, 1924
- Genus Cnesterodon Garman, 1895
- Genus Phalloceros Eigenmann, 1907
- Genus Phalloptychus Eigenmann, 1907
- Genus Phallotorynus Henn, 1916
- Genus Tomeurus Eigenmann, 1909
- Tribe Scolichthyini Rosen, 1967
- Genus Scolichthys Rosen, 1967
- Tribe XenodexiniHubbs, 1950
- Genus Xenodexia Hubbs, 1950
- Tribe
References
- Froese, Rainer, and Daniel Pauly, eds. (2004). "Poeciliidae" in FishBase. October 2004 version.
- "Poeciliidae". Integrated Taxonomic Information System. Retrieved 4 June 2004.
- ^ PMID 25543675.
- ^ "Archived copy" (PDF). Archived from the original (PDF) on 2013-05-09. Retrieved 2013-07-26.
{{cite web}}
: CS1 maint: archived copy as title (link) - ^ Hrbek, T., J. Seekinger, and A. Meyer. 2007. A phylogenetic and biogeographic perspective on the evolution of poeciliid fishes. Molecular Phylogenetics and Evolution 43:986-998.
- ^ S2CID 10946526.
- ^ Thibault, R. E., and R. J. Schultz. 1978. Reproductive adaptations among viviparous fishes (Cyprinodontiformes Poeciliidae). Evolution 32:320-333.
- ^ S2CID 232093911.
- PMID 28563744.
- S2CID 23879988.
- ISSN 0269-8463.
- S2CID 13491275.
- ISBN 978-1-118-34233-6.