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User:Samsara/Frog/Stable

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For other uses, see Frog (disambiguation).

Frogs
White's Tree Frog (Litoria caerulea)
Scientific classification
Kingdom:
Animalia
Phylum:
Chordata
Class:
Amphibia
Order:
Anura

Suborders

Archaeobatrachia
Mesobatrachia
Neobatrachia
-
Full list of families

Distribution of frogs (in black)

Frog is the common name for amphibians in the order Anura. Adult frogs are characterised by long hind legs, a short body, webbed digits, protruding eyes and the absence of a tail. Most frogs move by jumping or climbing. Most frogs have a semi-aquatic lifestyle. They typically lay their eggs in puddles, ponds or lakes, and their larvae, called tadpoles, have gills and develop in water. Adult frogs follow a carnivorous diet, mostly of arthropods, annelids and gastropods. Frogs are most noticeable through their call, which can be widely heard during the mating season.

The distribution of frogs ranges from tropic to subarctic regions, with most of the species found in tropical rainforests. With over 5,000 species described, they are among the most diverse groups of vertebrates. However, their declining numbers are increasingly giving cause for concern.

A distinction is often made between frogs and toads on the basis of their appearance, prompted by the convergent adaptation of so-called toads to dry environments; however, this distinction has no taxonomic basis. The only family exclusively given the common name "toad" is Bufonidae, but many species from other families are also called "toads". "True frogs" are of the family Ranidae.

Taxonomy

 
European Fire-bellied Toad (Bombina bombina)
Further information: Anura (family list)

The order Anura contains some 5,250 species in 33 families, whereof the Leptodactylidae (1100 spp.), Hylidae (800 spp.) and Ranidae (750 spp.) are the most speciose. More than 80% of amphibian species are frogs.

The use of the common names "frog" and "toad" has no real taxonomic justification. From a taxonomic perspective, all members of the order Anura are frogs, but only members of the family Bufonidae are considered "true toads". The use of the term "frog" in common names usually refers to species that are aquatic or semi-aquatic with smooth or moist skins, and the term "toad" generally refers to species that tend to be terrestrial with dry, warty skin. An exception is the Fire-bellied toad (Bombina bombina): while its skin is slightly warty, it prefers a watery habitat.

Frogs and toads are broadly classified into three suborders: Archaeobatrachia (which includes four families of primitive frogs), Mesobatrachia (which includes five families of more evolutionary intermediate frogs), and Neobatrachia (by far the largest group, which contains the remaining 24 families of "modern" frogs, including most common species throughout the world). The Neobatrachia is further divided into the Hyloidea and Ranoidea [1]. This classification is based on such morphological features as the number of vertebrae, the structure of the pectoral girdle, and the morphology of tadpoles. While this classification is largely accepted, relationships among families of frogs are still debated. Future studies of molecular genetics should soon provide further insights to the evolutionary relationships among frog families [2].

Some species of anurans hybridise readily. For instance, the Edible Frog (Rana esculenta) is a hybrid of the Pool Frog (R. lessonae) and the Marsh Frog (R. ridibunda). Bombina bombina and Bombina variegata similarly form hybrids, although these are less fertile, giving rise to a hybrid zone.

Morphology and physiology

Further information: Frog zoology

The morphology of frogs is unique among amphibians. Compared with the other two groups of amphibians, (salamanders and caecilians), frogs are unusual because they lack tails as adults and their legs are more suited to jumping than walking. The physiology of frogs is generally like that of other amphibians (and differs from other terrestrial vertebrates) because oxygen may pass through their highly permeable skin. This unique feature allows frogs to "breathe" largely through their skin. Because the oxygen is dissolved in an aqueous film on the skin and passes from there to the blood, the skin must remain moist at all times; this makes frogs susceptible to many toxins in the environment, some of which can similarly dissolve in the layer of water and be passed into their bloodstream (also see Decline in frog populations).

Body plan

 
Skeleton of Rana

Many characteristics are not shared by all of the approximately 5,250 described species of frogs. However, some general characteristics distinguish them from other amphibians. Frogs are usually well suited to jumping, with long hind legs with elongated ankle bones. They have a short vertebral column, with no more than ten free vertebrae, followed by a fused tail bone (urostyle or coccyx), typically resulting in a tailless phenotype.

Frogs range in size from 10 mm (Psyllophryne didactyla of Brazil and Eleutherodactylus iberia of Cuba) to 300 mm (Goliath frog, Conraua goliath, of Cameroon). The skin hangs loosely on the body because of the lack of loose connective tissue. Skin texture varies: it can be smooth, warty or folded. Frogs have three eyelid membranes: one is transparent to protect the eyes underwater, and two vary from translucent to opaque. Frogs have a tympanum on each side of the head, which is involved in hearing and, in some species, is covered by skin.

Feet and legs

The structure of the feet and legs varies greatly among frog species, depending in part on whether they live primarily on the ground, in water or in trees. Frogs must be able to move quickly through their environment to catch prey and escape predators, and numerous adaptations help them do so.

File:L tyleri.jpg
Tyler's Tree Frog (Litoria tyleri), illustrating large toe pads and webbed feet.

Many frogs, especially those that live in water, have webbed toes. The degree to which the toes are webbed is directly proportional to the amount of time the species lives in the water. For example, the completely aquatic African dwarf frog (Hymenochirus sp.) has fully webbed toes, whereas the toes of White's tree frog, an arboreal species, are only a half or a quarter webbed.

Arboreal frogs have "toe pads" to help grip vertical surfaces. These pads, located on the ends of the toes, do not work by suction. Rather, the surface of the pad consists of interlocking cells, with a small gap between adjacent cells. When the frog applies pressure to the toe pads, the interlocking cells grip irregularities on the substrate. The small gaps between the cells drain away all but a thin layer of moisture on the pad, and maintain a grip through capillarity. This allows the frog to grip smooth surfaces, and does not function when the pads are excessively wet. [3]

In many arboreal frogs, a small "intercalary structure" in each toe increases the surface area touching the substrate. Furthermore, since hopping through trees can be dangerous, many arboreal frogs have hip joints that allow both hopping and walking. Some frogs that live high in trees even possess an elaborate degree of webbing between their toes, as do aquatic frogs. But in these arboreal frogs, the webs allow the frogs to "parachute" or control their glide from one position in the canopy to another. [4]

Ground-dwelling frogs generally lack the adaptations of aquatic and arboreal frogs. Most have smaller toe pads, if any, and little webbing. Some burrowing frogs have a toe extension—a metatarsal tubercle—that helps them to burrow. The hind legs of ground dwellers are more muscular than those of aqueous and tree-dwelling frogs.

Skin

 
Common Eastern Froglet (Crinia signifera) camouflaged against leaf litter.

Many frogs are able to absorb water directly through the skin, especially around the pelvic area. However, the permeability of a frog's skin can also result in water loss. Some tree frogs reduce water loss with a waterproof layer of skin. Others have adapted behaviours that conserve water, including engaging in nocturnal activity and resting in a water-conserving position. This position involves the frog lying with its toes and fingers tucked under its body and chin, respectively, with no gap between the body and substrate. These adaptations only reduce water loss enough for a predominately arboreal existence, and are not suitable for arid conditions.

Camouflage is a common defensive mechanism in frogs. Most camouflaged frogs are nocturnal, which adds to their ability to hide. Nocturnal frogs usually find the ideal camouflaged position during the day to sleep. Some frogs have the ability to change colour. However, this is usually restricted to shades of one or two colours. For example, White's tree frog (Litoria caerulea) varies in shades of green and brown. Features such as warts and skin folds are usually found on ground-dwelling frogs, where a smooth skin would not disguise them effectively. Arboreal frogs usually have smooth skin, enabling them to disguise themselves as leaves.

Certain frogs change colour between night and day, as light and moisture stimulate the pigment cells and cause them to expand or contract.

Poison

 
Dendrobates pumilio contains numerous alkaloids which deter predators.

Many frogs contain mild toxins that make them distasteful to potential predators. For example, all toads have large poison glands—the parotoid glands—located behind the eyes on the top of the head. Some frogs, such as some Poison Dart Frogs, are especially toxic. The chemical makeup of toxins in frogs varies from irritants to hallucinogens, convulsants, nerve poisons, and vasoconstrictors (which narrow the blood vessels). Many predators of frogs have adapted to tolerate high levels of these poisons. Others, including humans, may be severely affected.

Some frogs obtain poisons from the ants and other arthropods they eat[5]; others, such as the Australian Corroboree Frogs (Pseudophryne corroboree and Pseudophryne pengilleyi), can manufacture an alkaloid not derived from their diet[6]. Some native people of South America extract poison from the poison dart frogs and apply it to their darts for hunting[7], although few species are toxic enough to be used for this purpose. It was previously a misconception that the poison was placed on arrows rather than darts. The common name of these frogs was thus changed from "Poison Arrow Frog" to "Poison Dart Frog" in the early 1980s. Poisonous frogs tend to advertise their toxicity with bright colours, an adaptive strategy known as aposematism. There are at least two non-poisonous species of frogs in tropical America (Eleutherodactylus gaigei and Lithodytes lineatus) that mimic the colouration of dart poison frogs' coloration for self-protection.[8][9]

Because frog toxins are extraordinarily diverse, they have raised the interest of biochemists as a "natural pharmacy". The alkaloid epibatidine, a painkiller 200 times more potent than morphine, is found in some species of poison dart frogs. Other chemicals isolated from the skin of frogs may offer resistance to HIV infection[10]. Arrow and dart poisons are under active investigation for their potential as therapeutic drugs.[11]

Respiration and circulation

The skin of a frog is permeable to oxygen and carbon dioxide, as well as to water. There are a number of blood vessels near the surface of the skin. When a frog is underwater, oxygen is transmitted through the skin directly into the bloodstream. On land, adult frogs use their lungs to breathe. Their lungs are similar to those of humans, but the chest muscles are not involved in respiration, and there are no ribs or diaphragm to support breathing. Frogs breathe by taking air in through the nostrils (causing the throat to puff out), and compressing the floor of the mouth, which forces the air into the lungs.

Frogs are known for their three-chambered heart, which they share with all tetrapods except birds and mammals. In the three-chambered heart, oxygenated blood from the lungs and de-oxygenated blood from the respiring tissues enters by separate atria, and is directed via a spiral valve to the appropriate vessel—aorta for oxygenated blood and pulmonary vein for deoxygenated blood. This special structure is essential to keeping the mixing of the two types of blood to a minimum, which enables frogs to have higher metabolic rates, and be more active than otherwise.

Natural history

The life cycle of frogs, like that of other amphibians, consists of four main stages: egg, tadpole, metamorphosis and adult. The reliance of frogs on an aquatic environment for the egg and tadpole stages gives rise to a variety of breeding behaviours that include the well-known mating calls used by the males of most species to attract females to the bodies of water that they have chosen for breeding. Some frogs also look after their eggs—and in some cases even the tadpoles—for some time after laying.

From eggs to adults

 
Frogspawn
File:Tadpoles 10 days.JPG
10 days: Tadpoles
 
8–12 weeks: Froglet
 
12–16 weeks: Adult frog

The life cycle of a frog starts with an egg. Eggs are generally laid in water, and an individual female may lay egg masses containing thousands of eggs. The eggs are highly vulnerable to predation, so frogs have evolved many techniques to ensure the survival of the next generation. Most commonly, this involves synchronous reproduction. Many individuals will breed at the same time, overwhelming the actions of predators; the majority of the offspring will still die due to predation, but there is a greater chance that some will survive. Another way in which some species avoid the predation and pathogens eggs are exposed to in ponds is to lay eggs on leaves above the pond, with a gelatinous coating designed to retain moisture. In these species the tadpoles drop into the water upon hatching. The eggs of some species laid out of water can detect vibrations of nearby predatory wasps or snakes, and will hatch early to avoid being eaten. [12] Some species, such as the Cane Toad (Bufo marinus), lay poisonous eggs to minimise predation. While the length of the egg stage depends on the species and environmental conditions, aquatic eggs generally hatch within one week.

Eggs hatch and continue life as tadpoles (occasionally known as polliwogs). Tadpoles are aquatic, lack front and hind legs, and have gills for respiration and tails with fins for swimming. Tadpoles are typically herbivorous, feeding mostly on algae, including diatoms that are filtered from the water through the gills. Some species are carnivorous at the tadpole stage, eating insects, smaller tadpoles and fish. Tadpoles are highly vulnerable to predation by fish, newts, predatory diving beetles, and birds such as kingfishers. Cannibalism has been observed among tadpoles. Poisonous tadpoles are present in many species, such as Cane Toads. The tadpole stage may be as short as a week, or tadpoles may overwinter and metamorphosis the following year in some species, such as the Midwife toad (Alytes obstetricans) and the Common Spadefoot (Pelobates fuscus).

At the end of the tadpole stage, frogs undergo metamorphosis, in which they transition into adult form. Metamorphosis involves a dramatic transformation of morphology and physiology, as tadpoles develop hind legs and then front legs, lose their gills and develop lungs. Their intestines shorten as they shift from an herbivorous to a carnivorous diet. The final stage of development from froglet to adult frog involves apoptosis (programmed cell death) of the tail.

After metamorphosis, young adults may leave the water and disperse into terrestrial habitats, or continue to live in the aquatic habitat as adults. Almost all species of frogs are carnivores as adults, eating invertebrates such as arthropods, annelids and gastropods. A few of the larger species may eat prey such as small mammals, fish and smaller frogs. Some frogs use their sticky tongues to catch fast-moving prey, while others capture their prey and force it into their mouths with their hands. However, there are a very few species of frogs that primarily eat plants[13]. Adult frogs are themselves preyed upon by birds, large fish, snakes, otters, foxes, badgers, coatis, and other animals. Frogs are also eaten by people (see section on agriculture, below).

Reproduction

Once adult frogs reach maturity, they will assemble at a water source such as a pond or stream to breed. Many frogs return to the bodies of water where they were born, often resulting in annual migrations involving thousands of frogs. In continental Europe, a large proportion of migrating frogs used to die on roads, before special fences and tunnels were built for them.

 
Male and female Common toad (Bufo bufo) in amplexus

Once at the breeding ground, male frogs call to attract a mate, collectively becoming a chorus of frogs. The call is unique to the species, and will attract females of that species. Some species have satellite males who do not call, but intercept females that are approaching a calling male.

The male and female frog then undergo amplexus. This involves the male mounting the female and gripping her tightly. Fertilization is external: the egg and sperm meet outside of the body. The female releases her eggs, which the male frog covers with a sperm solution. The eggs then swell and develop a protective coating. The eggs are typically brown or black, with a clear, gelatin-like covering.

Most temperate species of frogs reproduce between late autumn and early spring. In the UK, most common frog populations produce frogspawn in February, although there is wide variation in timing. Water temperatures at this time of year are relatively low, typically between four and 10 degrees Celsius. Reproducing in these conditions helps the developing tadpoles because dissolved oxygen concentrations in the water are highest at cold temperatures. More importantly, reproducing early in the season ensures that appropriate food is available to the developing frogs at the right time.

 
Colour plate from Ernst Haeckel's 1904 Kunstformen der Natur, depicting frog species that include two examples of parental care.

Parental care

Although care of offspring is poorly understood in frogs, it is estimated that up to 20% of amphibian species may care for their young in one way or another, and there is a great diversity of parental behaviours [14]. Some species of poison dart frog lay eggs on the forest floor and protect them, guarding the eggs from predation and keeping them moist. The frog will urinate on them if they become too dry. After hatching, a parent (the gender depends upon the species) will move them, on its back, to a water-holding bromeliad. The parent then feeds them by laying unfertilized eggs in the bromeliad until the young have metamorphosed. Other frogs carry the eggs and tadpoles on their hind legs or back (e.g. the midwife toads, Alytes spp.). Some frogs even protect their offspring inside their own bodies. The male Australian pouched frog (Assa darlingtoni) has pouches along its side in which the tadpoles reside until metamorphosis. The female Gastric-brooding Frogs (genus Rheobatrachus) from Australia swallows its tadpoles, which then develop in the stomach. To do this, the Gastric-brooding Frog must stop secreting stomach acid and suppress peristalsis (contractions of the stomach). Darwin's Frog (Rhinoderma darwinii) from Chile puts the tadpoles in its vocal sac for development.

Call

The call of a frog is unique to its species. Frogs call by passing air through the larynx in the throat. In most calling frogs, the sound is amplified by one or more vocal sacs, membranes of skin under the throat or on the corner of the mouth that distend during the amplification of the call.

Some frogs lack vocal sacs, such as those from the genera Heleioporus and Neobatrachus, but these species can still produce a loud call. Their buccal cavity is enlarged and dome-shaped, acting as a resonance chamber that amplifies their call. Species of frog without vocal sacs and that do not have a loud call tend to inhabit areas close to flowing water. The noise of flowing water overpowers any call, so they must communicate by other means.

The main reason for calling is to allow males to attract a mate. Males call either individually or in a group called a chorus. Females of many frog species, for example Polypedates leucomystax, produce calls reciprocal to the males', which act as the catalyst for the enhancement of reproductive activity in a breeding colony [15]. A male frog emits a release call when mounted by another male. Tropical species also have a rain call that they make on the basis of humidity cues prior to a rain shower. Many species also have a territorial call that is used to chase away other males. All of these calls are emitted with the mouth of the frog closed.

A distress call, emitted by some frogs when they are in danger, is produced with the mouth open, resulting in a higher-pitched call. The effectiveness of the call is unknown; however, it is suspected that the call intrigues the predator until another animal is attracted, distracting them enough for its escape.

Many species of frog have deep calls, or croaks. The onomatopoeic spelling is often "crrrrk" in Britain and "ribbit" in the US. This difference is due to the different species within each region (e.g., Common frog (Rana temporaria) in Britain and Leopard frog (Rana pipiens) in the US). The croak of the American bullfrog (Rana catesbiana) is sometimes spelt "jug o' rum".

Distribution and conservation status

 
Golden toad (Bufo periglenes) - last seen in 1989

Frogs are found nearly worldwide, but they do not occur in Antarctica and are not present on many oceanic islands. The greates diversity of frogs occurs in the tropical areas of the world. This is because water is readily available, which suits frogs' requirements due to their skin. Some frogs inhabit arid areas such as deserts, where water may not be easily accessible, and rely on specific adaptations to survive. The Australian genus Cyclorana and the American genus Pternohyla will bury themselves underground, create a water-impervious cocoon and hibernate during dry periods. Once it rains, they emerge, find a temporary pond and breed. Egg and tadpole development is very fast in comparison to most other frogs so that breeding is complete before the pond dries up. Some frog species are adapted to cold, like the Wood Frog which lives in the Arctic Circle, the species buries itself in the ground where in winter and its entire body freezes.

Frog populations have declined dramatically since the 1950s, with more than one third of species believed to be threatened with extinction and more than 120 species suspected to have become extinct since the 1980s.[16] Among these species are the Golden toad of Costa Rica, and the Gastric-brooding Frogs of Australia. Habitat loss is significant cause of frog population decline, as are pollutants, climate change, the introduction of non-indigenous predators/competitors, and emerging infectious diseases including chytridiomycosis. Many environmental scientists feel that amphibians, including frogs, are excellent biological indicators of broader ecosystem health because of their intermediate position in food webs, permeable skins, and typically biphasic life (aquatic larvae and terrestrial adults).[17]

Evolution

The earliest amphibian discovered is Elginerpeton, in Late Devonian rocks of Scotland dating to approximately 368 million years ago. The earliest well-known amphibian, Ichthyostega, was found in Late Devonian deposits in Greenland, dating back about 363 million years. The later Paleozoic saw a great diversity of amphibians, ranging from small, legless swimming forms (Aïstopoda) to bizarre "horned" forms (Nectridea). These first amphibians are thought to have evolved from bony fish of the class Osteichthyes, which were widespread during the period that amphibia emerged. There is, however, substantial debate over what type of bony fish was the precursor to amphibians. Suggestions include the lungfish and the Actinopterygii as the forerunners to modern amphibia.

The earliest known (proto)frog is †Triadobatrachus massinoti, from the early Triassic of Madagascar. It is about 250 million years old, and had not yet evolved the full combination of features currently associated with frogs. The skull is frog-like, being broad with large eye sockets, but the fossil has a number of other features diverging from modern amphibia. These include a different ilium, a longer body with more vertebrae, and separate vertebrae in its tail (whereas in modern frogs, the tail vertebrae are fused, and known as the urostyle or coccyx). The tibia and fibula bones are unfused and separate, making it probable that Triadobatrachus was not an efficient leaper.

Another fossil frog, discovered in Arizona and called †Prosalirus bitis, was uncovered in 1985, and dates from roughly the same time as Triadobatrachus. Like Triadobatrachus, Prosalirus did not have greatly enlarged legs, but had the typical three-pronged pelvic structure. Unlike Triadobatrachus, Prosalirus had already lost nearly all of its tail.

The earliest true frog is †Vieraella herbsti, from the early Jurassic (188–213 mya). It is known only from the dorsal and ventral impressions of a single animal and was estimated to be 33 mm in snout-vent length. †Notobatrachus degiustoi from the middle Jurassic is slightly younger, about 155–170 million years old. It is likely that the evolution of modern anura was completed by the Jurassic period. The main evolutionary changes involved the shortening of the body and the loss of the tail.

Frog fossils have been found on all continents, including Antarctica.

Uses in agriculture and research

Frogs are raised commercially for several purposes. Dead frogs are sometimes used for dissections in high school and university anatomy classes, often after being injected with coloured plastics to enhance the contrast between the organs. This practice has declined in recent years with the increasing awareness of animal rights issues. Frogs are used as a food source; frog legs are a delicacy in China, France, and in many parts of the American South, especially Louisiana.

Frogs have served as important model organisms in the study of embryology because frog eggs lack shells characteristic of most other vertebrates, and therefore facilitate observations of early development. The African clawed frog, Xenopus laevis is an important laboratory organism. Xenopus was first widely used in laboratories in pregnancy assays in the first half of the 20th century. When human chorionic gonadotropin, a hormone found in substantial quantities in the urine of pregnant women, is injected into a female X. laevis, it induces them to lay eggs. Though alternative pregnancy assays have been developed, biologists continue to use Xenopus as a model organism in developmental biology because it is easy to raise in captivity and has a large and easily manipulable embryo. Recently, X. laevis is increasingly being displaced by its smaller relative X. tropicalis, which by its reaching reproductive age in five months rather than one to two years (as in X. laevis) [18], facilitates studies across generations. The genome project of X. tropicalis will probably be completed by 2015 at the latest [19].

Frogs in popular culture

Main article: Frogs in popular culture

Frogs feature prominently in folklore, fairy tales and popular culture. They tend to be portrayed as benign, ugly, clumsy, but with hidden talents. Examples of these stereotypes include: Michigan J. Frog, The Frog Prince and Kermit the Frog. Michigan J. Frog, featured in a Warner Brothers cartoon, only performs his singing and dancing routine for his owner. Once another person looks at him, he will return to a frog like pose, and begin calling. The Frog Prince is a fairytale of a frog who turns into a beautiful prince once kissed. Kermit the Frog, on the other hand, is a conscientious and disciplined character of Sesame Street and the Muppet Show, where he is often portrayed as cringing at the fanciful behaviour of more flamboyant characters.

References

Cited references

  1. ^ Emerson, S.B. (1980). "Toe pad morphology and mechanisms of sticking in frogs". Biol. J. Linn. Soc. 13 (3): 199–216. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  2. ^ "New and poorly known parachuting frogs (Rhacophoridae : Rhacophorus) from Sumatra and Java". Herpetological Monographs. 16: 46–92. 2002. {{cite journal}}: |first= missing |last= (help); Unknown parameter |coauthors= ignored (|author= suggested) (help); Unknown parameter |lsat= ignored (help)
  3. ^ Saporito, R.A. (2004). "Formicine ants: An arthropod source for the pumiliotoxin alkaloids of dendrobatid poison frogs". Proceedings of the National Academy of Science. 101: 8045–8050. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  4. ^ Smith, B. P. (2002). "Evidence for biosynthesis of pseudophrynamine alkaloids by an Australian myobatrachid frog (pseudophryne) and for sequestration of dietary pumiliotoxins". J Nat Prod. 65 (4): 439–47. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  5. ^ Myers, C.W. (1983). "Dart-poison frogs". Scientific American. 248: 120–133. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  6. ^ Savage, J. M. (2002). The Amphibians and Reptiles of Costa Rica. University of Chicago Press, Chicago.
  7. ^ Duellman, W. E. (1978). "The Biology of an Equatorial Herpetofauna in Amazonian Ecuador". University of Kansas Museum of Natural History Miscellaneous Publication. 65: 1–352.
  8. ^ VanCompernolle, S. E. (2005). "Antimicrobial peptides from amphibian skin potently inhibit Human Immunodeficiency Virus infection and transfer of virus from dendritic cells to T cells". Journal of Virology. 79: 11598–11606. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  9. ^ Warkentin, K.M. (1995). "Adaptive plasticity in hatching age: a response to predation risk trade-offs". Proceedings of the National Academy of Sciences. 92: 3507–3510.
  10. ^ Silva, H. R. (1989). "Frugivory and Seed Dispersal by Hyla truncata, a Neotropical Treefrog". Copeia. 1989(3): 781–783. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  11. ^ Phillipe, G. (2005). "Recent developments in the field of arrow and dart poisons". J Ethnopharmacol. 100(1-2): 85–91. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  12. ^ Crump, M.L. (1996). "Parental care among the Amphibia". Advances in the Study of Behavior. 25: 109–144.
  13. ^ Stuart, S.N. (2004). "Status and trends of amphibian declines and extinctions worldwide". Science. 306: 1783–1786. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  14. ^ Phillips, Kathryn (1994). Tracking the Vanishing Frogs. New York: Penguin Books. ISBN 0140246460.
  15. ^ Roy, Debjani (1997). "Communication signals and sexual selection in amphibians". Current Science. 72: 923–927.
  16. ^ Ford, L.S. (1993). "The major clades of frogs". Herpetological Monographs. 7: 94–117. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  17. ^ Faivovich, J. "Systematic review of the frog family Hylidae, with special reference to Hylinae: Phylogenetic analysis and taxonomic revision". Bulletin of the American Museum of Natural History. 294: 1–240. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  18. ^ "Developing the potential of Xenopus tropicalis as a genetic model" (HTML). Retrieved 2006-03-09.
  19. ^ "Joint Genome Institute - Xenopus tropicalis Home" (HTML). Retrieved 2006-03-03.

General references

  • Cogger, H.G. (2004). Encyclopedia of Reptiles & Amphibians Second Edition. Fog City Press. ISBN 1877019690. {{cite book}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  • Estes, R., and O. A. Reig. (1973). "The early fossil record of frogs: a review of the evidence." pp. 11-63 In J. L. Vial (Ed.), Evolutionary Biology of the Anurans: Contemporary Research on Major Problems. University of Missouri Press, Columbia.
  • Holman, J. A (2004). Fossil Frogs and Toads of North America. Indiana University Press. ISBN 0253342805.
  • Tyler, M. J. (1994). Australian Frogs A Natural History. Reed Books. ISBN 0730104680.

External links

 
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