Frog

A frog is any member of a diverse and largely carnivorous group of short-bodied, tailless amphibians composing the order Anura (literally without tail in Ancient Greek). The oldest fossil "proto-frog" appeared in the early Triassic of Madagascar, but molecular clock dating suggests their origins may extend further back to the Permian, 265 million years ago. Frogs are widely distributed, ranging from the tropics to subarctic regions, but the greatest concentration of species diversity is in tropical rainforest. There are over 6,300 recorded species, accounting for around 88% of extant amphibian species. They are also one of the five most diverse vertebrate orders. Warty frog species tend to be called toads, but the distinction between frogs and toads is informal, not from taxonomy or evolutionary history. All toads are frogs, but not all frogs are toads.[1]

Frogs
Temporal range:
Early JurassicPresent, 200–0 Ma
Various types of frogs.
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Amphibia
Clade: Salientia
Order: Anura
Duméril, 1806 (as Anoures)
Suborders

Archaeobatrachia
Mesobatrachia
Neobatrachia
 
List of Anuran families

Native distribution of frogs (in green)
Variegated golden frog (Mantella baroni) in the Ranomafana National Park of Madagascar

An adult frog has a stout body, protruding eyes, anteriorly-attached tongue, limbs folded underneath, and no tail (except in tailed frogs). Frogs have glandular skin, with secretions ranging from distasteful to toxic. Their skin varies in colour from well-camouflaged dappled brown, grey and green to vivid patterns of bright red or yellow and black to show toxicity and ward off predators. Adult frogs live in fresh water and on dry land; some species are adapted for living underground or in trees.

Frogs typically lay their eggs in water. The eggs hatch into aquatic larvae called tadpoles that have tails and internal gills. They have highly specialized rasping mouth parts suitable for herbivorous, omnivorous or planktivorous diets. The life cycle is completed when they metamorphose into adults. A few species deposit eggs on land or bypass the tadpole stage. Adult frogs generally have a carnivorous diet consisting of small invertebrates, but omnivorous species exist and a few feed on plant matter. Frog skin has a rich microbiome which is important to their health. Frogs are extremely efficient at converting what they eat into body mass. They are an important food source for predators and part of the food web dynamics of many of the world's ecosystems. The skin is semi-permeable, making them susceptible to dehydration, so they either live in moist places or have special adaptations to deal with dry habitats. Frogs produce a wide range of vocalizations, particularly in their breeding season, and exhibit many different kinds of complex behaviours to attract mates, to fend off predators and to generally survive.

Frogs are valued as food by humans and also have many cultural roles in literature, symbolism and religion. They are also seen as environmental bellwethers, with declines in frog populations often viewed as early warning signs of environmental damage. Frog populations have declined significantly since the 1950s. More than one third of species are considered to be threatened with extinction and over 120 are believed to have become extinct since the 1980s. The number of malformations among frogs is on the rise and an emerging fungal disease, chytridiomycosis, has spread around the world. Conservation biologists are working to understand the causes of these problems and to resolve them.

Etymology and taxonomy

The use of the common names "frog" and "toad" has no taxonomic justification. From a classification 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 and have smooth, moist skins; the term "toad" generally refers to species that are terrestrial with dry, warty skins.[2][3] There are numerous exceptions to this rule. The European fire-bellied toad (Bombina bombina) has a slightly warty skin and prefers a watery habitat[4] whereas the Panamanian golden frog (Atelopus zeteki) is in the toad family Bufonidae and has a smooth skin.[5]

Etymology

The origin of the order name Anura — and its original spelling Anoures — is the Ancient Greek "alpha privative" prefix ἀν- (an-) "without", and οὐρά (ourá), meaning "animal tail". It refers to the tailless character of these amphibians.[6][7][8]

The origins of the word frog are uncertain and debated.[9] The word is first attested in Old English as frogga, but the usual Old English word for the frog was frosc (with variants such as frox and forsc), and it is agreed that the word frog is somehow related to this. Old English frosc remained in dialectal use in English as frosh and frosk into the nineteenth century,[10] and is paralleled widely in other Germanic languages, with examples in the modern languages including German Frosch, Icelandic froskur, and Dutch (kik)vors.[9] These words allow us to reconstruct a Common Germanic ancestor *froskaz.[11] The third edition of the Oxford English Dictionary finds that the etymology of *froskaz is uncertain, but agrees with arguments that it could plausibly derive from a Proto-Indo-European base along the lines of *preu = "jump".[9][12]

How Old English frosc gave rise to frogga is, however, uncertain, as the development does not involve a regular sound-change. Instead, it seems that there was a trend in Old English to coin nicknames for animals ending in -g, with examples—themselves all of uncertain etymology—including dog, hog, pig, stag, and (ear)wig. Frog appears to have been adapted from frosc as part of this trend.[9]

Meanwhile, the word toad, first attested as Old English tādige, is unique to English and is likewise of uncertain etymology.[13] It is the basis for the word tadpole, first attested as Middle English taddepol, apparently meaning 'toad-head'.[14]

Taxonomy

About 88% of amphibian species are classified in the order Anura.[15] These include over 7,100 species in 55 families, of which the Craugastoridae (850 spp.), Hylidae (724 spp.), Microhylidae (688 spp.), and Bufonidae (621 spp.) are the richest in species.[16]

European fire-bellied toad (Bombina bombina)

The Anura include all modern frogs and any fossil species that fit within the anuran definition. The characteristics of anuran adults include: 9 or fewer presacral vertebrae, the presence of a urostyle formed of fused vertebrae, no tail, a long and forward-sloping ilium, shorter fore limbs than hind limbs, radius and ulna fused, tibia and fibula fused, elongated ankle bones, absence of a prefrontal bone, presence of a hyoid plate, a lower jaw without teeth (with the exception of Gastrotheca guentheri) consisting of three pairs of bones (angulosplenial, dentary, and mentomeckelian, with the last pair being absent in Pipoidea),[17] an unsupported tongue, lymph spaces underneath the skin, and a muscle, the protractor lentis, attached to the lens of the eye.[18] The anuran larva or tadpole has a single central respiratory spiracle and mouthparts consisting of keratinous beaks and denticles.[18]

Panamanian golden frog (Atelopus zeteki).

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 families of modern frogs, including most common species throughout the world. The suborder Neobatrachia is further divided into the two superfamilies Hyloidea and Ranoidea.[19] 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.[20]

Some species of anurans hybridize readily. For instance, the edible frog (Pelophylax esculentus) is a hybrid between the pool frog (P. lessonae) and the marsh frog (P. ridibundus).[21] The fire-bellied toads Bombina bombina and B. variegata are similar in forming hybrids. These are less fertile than their parents, giving rise to a hybrid zone where the hybrids are prevalent.[22]

Evolution

The origins and evolutionary relationships between the three main groups of amphibians are hotly debated. A molecular phylogeny based on rDNA analysis dating from 2005 suggests that salamanders and caecilians are more closely related to each other than they are to frogs and the divergence of the three groups took place in the Paleozoic or early Mesozoic before the breakup of the supercontinent Pangaea and soon after their divergence from the lobe-finned fishes. This would help account for the relative scarcity of amphibian fossils from the period before the groups split.[23] Another molecular phylogenetic analysis conducted about the same time concluded that lissamphibians first appeared about 330 million years ago and that the temnospondyl-origin hypothesis is more credible than other theories. The neobatrachians seemed to have originated in Africa/India, the salamanders in East Asia and the caecilians in tropical Pangaea.[24] Other researchers, while agreeing with the main thrust of this study, questioned the choice of calibration points used to synchronise the data. They proposed that the date of lissamphibian diversification should be placed in the Permian, rather less than 300 million years ago, a date in better agreement with the palaeontological data.[25] A further study in 2011 using both extinct and living taxa sampled for morphological, as well as molecular data, came to the conclusion that Lissamphibia is monophyletic and that it should be nested within Lepospondyli rather than within Temnospondyli. The study postulated that Lissamphibia originated no earlier than the late Carboniferous, some 290 to 305 million years ago. The split between Anura and Caudata was estimated as taking place 292 million years ago, rather later than most molecular studies suggest, with the caecilians splitting off 239 million years ago.[26]

A fossilized frog from the Czech Republic, possibly Palaeobatrachus gigas.

In 2008, Gerobatrachus hottoni, a temnospondyl with many frog- and salamander-like characteristics, was discovered in Texas. It dated back 290 million years and was hailed as a missing link, a stem batrachian close to the common ancestor of frogs and salamanders, consistent with the widely accepted hypothesis that frogs and salamanders are more closely related to each other (forming a clade called Batrachia) than they are to caecilians.[27][28] However, others have suggested that Gerobatrachus hottoni was only a dissorophoid temnospondyl unrelated to extant amphibians.[29]

Salientia (Latin salere (salio), "to jump") is the name of the total group that includes modern frogs in the order Anura as well as their close fossil relatives, the "proto-frogs" or "stem-frogs". The common features possessed by these proto-frogs include 14 presacral vertebrae (modern frogs have eight or 9), a long and forward-sloping ilium in the pelvis, the presence of a frontoparietal bone, and a lower jaw without teeth. The earliest known amphibians that were more closely related to frogs than to salamanders are Triadobatrachus massinoti, from the early Triassic period of Madagascar (about 250 million years ago), and Czatkobatrachus polonicus, from the Early Triassic of Poland (about the same age as Triadobatrachus).[30] The skull of Triadobatrachus is frog-like, being broad with large eye sockets, but the fossil has features diverging from modern frogs. These include a longer body with more vertebrae. The tail has separate vertebrae unlike the fused urostyle or coccyx in modern frogs. The tibia and fibula bones are also separate, making it probable that Triadobatrachus was not an efficient leaper.[30]

The earliest known "true frogs" that fall into the anuran lineage proper all lived in the early Jurassic period.[2][31] One such early frog species, Prosalirus bitis, was discovered in 1995 in the Kayenta Formation of Arizona and dates back to the Early Jurassic epoch (199.6 to 175 million years ago), making Prosalirus somewhat more recent than Triadobatrachus.[32] Like the latter, Prosalirus did not have greatly enlarged legs, but had the typical three-pronged pelvic structure of modern frogs. Unlike Triadobatrachus, Prosalirus had already lost nearly all of its tail[33] and was well adapted for jumping.[34] Another Early Jurassic frog is Vieraella herbsti, which is known only from dorsal and ventral impressions of a single animal and was estimated to be 33 mm (1.3 in) from snout to vent. Notobatrachus degiustoi from the middle Jurassic is slightly younger, about 155–170 million years old. The main evolutionary changes in this species involved the shortening of the body and the loss of the tail. The evolution of modern Anura likely was complete by the Jurassic period. Since then, evolutionary changes in chromosome numbers have taken place about 20 times faster in mammals than in frogs, which means speciation is occurring more rapidly in mammals.[35]

According to genetic studies, the families Hyloidea, Microhylidae, and the clade Natatanura (comprising about 88% of living frogs) diversified simultaneously some 66 million years ago, soon after the Cretaceous–Paleogene extinction event associated with the Chicxulub impactor. All origins of arboreality (e.g. in Hyloidea and Natatanura) follow from that time and the resurgence of forest that occurred afterwards.[36][37]

Frog fossils have been found on all of the earth's continents.[38][39] In 2020, it was announced that 40 million year old helmeted frog fossils had been discovered by a team of vertebrate paleontologists in Seymour Island on the Antarctic Peninsula, indicating that this region was once home to frogs related to those now living in South American Nothofagus forest.[40]

Phylogeny

A cladogram showing the relationships of the different families of frogs in the clade Anura can be seen in the table below. This diagram, in the form of a tree, shows how each frog family is related to other families, with each node representing a point of common ancestry. It is based on Frost et al. (2006),[41] Heinicke et al. (2009)[42] and Pyron and Wiens (2011).[43]

Anura

Leiopelmatidae

Ascaphidae

Bombianura
Costata

Bombinatoridae

Alytidae

Discoglossidae

Pipanura
Xenoanura

Pipidae

Rhinophrynidae

Acosmanura
Anomocoela

Scaphiopodidae

Pelodytidae

Pelobatoidea

Pelobatidae

Megophryidae

Neobatrachia

Heleophrynidae

Phthanobatrachia
Sooglossoidea

Sooglossidae

Nasikabatrachidae

Notogaeanura
Australobatrachia

Calyptocephalellidae

Myobatrachidae

Limnodynastidae

Nobleoanura
Brachycephaloidea

Ceuthomantidae

Brachycephalidae

Eleutherodactylidae

Craugastoridae

(Terrarana)

Hemiphractidae

Athesphatanura

Hylidae

Leptodactyliformes
Agastorophrynia

Bufonidae

Aromobatidae

Dendrobatidae

Diphyabatracea

Leptodactylidae

Allophrynidae

Centrolenidae

Ceratophryidae

Odontophrynidae

Cycloramphidae

Alsodidae

Hylodidae

Telmatobiidae

Batrachylidae

Rhinodermatidae

Ranoides
Allodapanura

Microhylidae

Afrobatrachia
Xenosyneunitanura

Brevicipitidae

Hemisotidae

Laurentobatrachia

Hyperoliidae

Arthroleptidae

Natatanura

Ptychadenidae

Victoranura

Micrixalidae

Phrynobatrachidae

Conrauidae

Pyxicephaloidea

Petropedetidae

Pyxicephalidae

Nyctibatrachidae

Ceratobatrachidae

Saukrobatrachia

Ranixalidae

Dicroglossidae

Aglaioanura

Rhacophoridae

Mantellidae

Ranidae

Morphology and physiology

Skeleton of Pelophylax esculentus showing bones of the head, vertebral column, ribs, pectoral and pelvic girdles, and limbs.

Frogs have no tail, except as larvae, and most have long hind legs, elongated ankle bones, webbed toes, no claws, large eyes, and a smooth or warty skin. They have short vertebral columns, with no more than 10 free vertebrae and fused tailbones (urostyle or coccyx).[44] Like other amphibians, oxygen can pass through their highly permeable skins. This unique feature allows them to remain in places without access to the air, respiring through their skins.[45] Ribs are generally absent, so the lungs are filled by buccal pumping and a frog deprived of its lungs can maintain its body functions without them.[45] For the skin to serve as a respiratory organ, it must remain moist. This makes frogs susceptible to various substances they may encounter in the environment, some of which may be toxic and can dissolve in the water film and be passed into their bloodstream. This may be one of the causes of the worldwide decline in frog populations.[46][47][48][49]

Frogs range in size from Paedophryne amauensis of Papua New Guinea that is 7.7 mm (0.30 in) in snout–to–vent length[50] to the up to 32 cm (13 in) and 3.25 kg (7.2 lb) goliath frog (Conraua goliath) of central Africa.[51] There are prehistoric, extinct species that reached even larger sizes.[52] The skin hangs loosely on the body because of the lack of loose connective tissue. Frogs have three eyelid membranes: one is transparent to protect the eyes underwater, and two vary from translucent to opaque. They have a tympanum on each side of their heads which is involved in hearing and, in some species, is covered by skin. True toads completely lack teeth, but most frogs have them, specifically pedicellate teeth in which the crown is separated from the root by fibrous tissue. These are on the edge of the upper jaw and vomerine teeth are also on the roof of their mouths. No teeth are in the lower jaw and frogs usually swallow their food whole. The teeth are mainly used to grip the prey and keep it in place until swallowed, a process assisted by retracting the eyes into the head.[53] The African bullfrog (Pyxicephalus), which preys on relatively large animals such as mice and other frogs, has cone shaped bony projections called odontoid processes at the front of the lower jaw which function like teeth.[15]

A bullfrog skeleton, showing elongated limb bones and extra joints. Red marks indicate bones which have been substantially elongated in frogs and joints which have become mobile. Blue indicates joints and bones which have not been modified or only somewhat elongated.

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, in trees, or in burrows. Frogs must be able to move quickly through their environment to catch prey and escape predators, and numerous adaptations help them to do so. Most frogs are either proficient at jumping or are descended from ancestors that were, with much of the musculoskeletal morphology modified for this purpose. The tibia, fibula, and tarsals have been fused into a single, strong bone, as have the radius and ulna in the fore limbs (which must absorb the impact on landing). The metatarsals have become elongated to add to the leg length and allow frogs to push against the ground for a longer period on take-off. The illium has elongated and formed a mobile joint with the sacrum which, in specialist jumpers such as ranids and hylids, functions as an additional limb joint to further power the leaps. The tail vertebrae have fused into a urostyle which is retracted inside the pelvis. This enables the force to be transferred from the legs to the body during a leap.[44]

Webbed hind foot of common frog
(Rana temporaria)
Tyler's tree frog (Litoria tyleri) has large toe pads and webbed feet.

The muscular system has been similarly modified. The hind limbs of ancestral frogs presumably contained pairs of muscles which would act in opposition (one muscle to flex the knee, a different muscle to extend it), as is seen in most other limbed animals. However, in modern frogs, almost all muscles have been modified to contribute to the action of jumping, with only a few small muscles remaining to bring the limb back to the starting position and maintain posture. The muscles have also been greatly enlarged, with the main leg muscles accounting for over 17% of the total mass of frogs.[54]

Many frogs have webbed feet and the degree of webbing is directly proportional to the amount of time the species spends in the water.[55] The completely aquatic African dwarf frog (Hymenochirus sp.) has fully webbed toes, whereas those of White's tree frog (Litoria caerulea), an arboreal species, are only a quarter or half webbed.[56] Exceptions include flying frogs in the Hylidae and Rhacophoridae, which also have fully webbed toes used in gliding.

Arboreal frogs have pads located on the ends of their toes to help grip vertical surfaces. These are not suction pads, the surface consisting instead of columnar cells with flat tops with small gaps between them lubricated by mucous glands. When the frog applies pressure, the cells adhere to irregularities on the surface and the grip is maintained through surface tension. This allows the frog to climb on smooth surfaces, but the system does not function efficiently when the pads are excessively wet.[57]

In many arboreal frogs, a small "intercalary structure" on each toe increases the surface area touching the substrate. Furthermore, 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. This allows the frogs to "parachute" or make a controlled glide from one position in the canopy to another.[58]

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 such as Couch's spadefoot (Scaphiopus couchii) have a flap-like toe extension on the hind feet, a keratinised tubercle often referred to as a spade, that helps them to burrow.[59]

Sometimes during the tadpole stage, one of the developing rear legs is eaten by a predator such as a dragonfly nymph. In some cases, the full leg still grows, but in others it does not, although the frog may still live out its normal lifespan with only three limbs. Occasionally, a parasitic flatworm (Ribeiroia ondatrae) digs into the rear of a tadpole, causing a rearrangement of the limb bud cells and the frog develops one or more extra legs.[60]

Northern leopard frog (Rana pipiens) moulting and eating its skin.

Skin

A frog's skin is protective, has a respiratory function, can absorb water, and helps control body temperature. It has many glands, particularly on the head and back, which often exude distasteful and toxic substances (granular glands). The secretion is often sticky and helps keep the skin moist, protects against the entry of moulds and bacteria, and make the animal slippery and more able to escape from predators.[61] The skin is shed every few weeks. It usually splits down the middle of the back and across the belly, and the frog pulls its arms and legs free. The sloughed skin is then worked towards the head where it is quickly eaten.[62]

Being cold-blooded, frogs have to adopt suitable behaviour patterns to regulate their temperature. To warm up, they can move into the sun or onto a warm surface; if they overheat, they can move into the shade or adopt a stance that exposes the minimum area of skin to the air. This posture is also used to prevent water loss and involves the frog squatting close to the substrate with its hands and feet tucked under its chin and body.[63] The colour of a frog's skin is used for thermoregulation. In cool damp conditions, the colour will be darker than on a hot dry day. The grey foam-nest tree frog (Chiromantis xerampelina) is even able to turn white to minimize the chance of overheating.[64]

Many frogs are able to absorb water and oxygen directly through the skin, especially around the pelvic area, but the permeability of a frog's skin can also result in water loss. Glands located all over the body exude mucus which helps keep the skin moist and reduces evaporation. Some glands on the hands and chest of males are specialized to produce sticky secretions to aid in amplexus. Similar glands in tree frogs produce a glue-like substance on the adhesive discs of the feet. Some arboreal frogs reduce water loss by having a waterproof layer of skin, and several South American species coat their skin with a waxy secretion. Other frogs have adopted behaviours to conserve water, including becoming nocturnal and resting in a water-conserving position. Some frogs may also rest in large groups with each frog pressed against its neighbours. This reduces the amount of skin exposed to the air or a dry surface, and thus reduces water loss.[63] Woodhouse's toad (Bufo woodhousii), if given access to water after confinement in a dry location, sits in the shallows to rehydrate.[65] The male hairy frog (Trichobatrachus robustus) has dermal papillae projecting from its lower back and thighs, giving it a bristly appearance. They contain blood vessels and are thought to increase the area of the skin available for respiration.[66]

Some species have bony plates embedded in their skin, a trait that appears to have evolved independently several times.[67] In certain other species, the skin at the top of the head is compacted and the connective tissue of the dermis is co-ossified with the bones of the skull (exostosis).[68][69]

Camouflage is a common defensive mechanism in frogs. Most camouflaged frogs are nocturnal; during the day, they seek out a position where they can blend into the background and remain undetected. Some frogs have the ability to change colour, but this is usually restricted to a small range of colours. For example, White's tree frog (Litoria caerulea) varies between pale green and dull brown according to the temperature, and the Pacific tree frog (Pseudacris regilla) has green and brown morphs, plain or spotted, and changes colour depending on the time of year and general background colour.[70] Features such as warts and skin folds are usually on ground-dwelling frogs, for whom smooth skin would not provide such effective camouflage. Certain frogs change colour between night and day, as light and moisture stimulate the pigment cells and cause them to expand or contract.[45] Some are even able to control their skin texture.[71]

Respiration and circulation

The skin of a frog is permeable to oxygen and carbon dioxide, as well as to water. There are blood vessels near the surface of the skin and when a frog is underwater, oxygen diffuses directly into the blood. When not submerged, a frog breathes by a process known as buccal pumping. Its lungs are similar to those of humans, but the chest muscles are not involved in respiration, and no ribs or diaphragm exist to help move air in and out. Instead, it puffs out its throat and draws air in through the nostrils, which in many species can then be closed by valves. When the floor of the mouth is compressed, air is forced into the lungs.[72] The fully aquatic Bornean flat-headed frog (Barbourula kalimantanensis) is the first frog known to lack lungs entirely.[73]

Frogs have three-chambered hearts, a feature they share with lizards.[74] Oxygenated blood from the lungs and de-oxygenated blood from the respiring tissues enter the heart through separate atria. When these chambers contract, the two blood streams pass into a common ventricle before being pumped via a spiral valve to the appropriate vessel, the aorta for oxygenated blood and pulmonary artery for deoxygenated blood. The ventricle is partially divided into narrow cavities which minimizes the mixing of the two types of blood. These features enable frogs to have a higher metabolic rate and be more active than would otherwise be possible.[74]

Some species of frog have adaptations that allow them to survive in oxygen deficient water. The Titicaca water frog (Telmatobius culeus) is one such species and has wrinkly skin that increases its surface area to enhance gas exchange. It normally makes no use of its rudimentary lungs but will sometimes raise and lower its body rhythmically while on the lake bed to increase the flow of water around it.[75]

Anatomical model of a dissected frog: 1 Right atrium, 2 Lungs, 3 Aorta, 4 Egg mass, 5 Colon, 6 Left atrium, 7 Ventricle, 8 Stomach, 9 Liver, 10 Gallbladder, 11 Small intestine, 12 Cloaca

Digestion and excretion

Frogs have maxillary teeth along their upper jaw which are used to hold food before it is swallowed. These teeth are very weak, and cannot be used to chew or catch and harm agile prey. Instead, the frog uses its sticky, cleft tongue to catch flies and other small moving prey. The tongue normally lies coiled in the mouth, free at the back and attached to the mandible at the front. It can be shot out and retracted at great speed.[55] Some frogs have no tongue and just stuff food into their mouths with their hands.[55] The eyes assist in the swallowing of food as they can be retracted through holes in the skull and help push food down the throat.[55] The food then moves through the oesophagus into the stomach where digestive enzymes are added and it is churned up. It then proceeds to the small intestine (duodenum and ileum) where most digestion occurs. Pancreatic juice from the pancreas, and bile, produced by the liver and stored in the gallbladder, are secreted into the small intestine, where the fluids digest the food and the nutrients are absorbed. The food residue passes into the large intestine where excess water is removed and the wastes are passed out through the cloaca.[76] The recently discovered Prometheus Frog has been reported to sometimes eat cooked or burnt food from areas affected by forest fires.[77]

Although adapted to terrestrial life, frogs resemble freshwater fish in their inability to conserve body water effectively. When they are on land, much water is lost by evaporation from the skin. The excretory system is similar to that of mammals and there are two kidneys that remove nitrogenous products from the blood. Frogs produce large quantities of dilute urine in order to flush out toxic products from the kidney tubules.[78] The nitrogen is excreted as ammonia by tadpoles and aquatic frogs but mainly as urea, a less toxic product, by most terrestrial adults. A few species of tree frog with little access to water excrete the even less toxic uric acid.[78] The urine passes along paired ureters to the urinary bladder from which it is vented periodically into the cloaca. All bodily wastes exit the body through the cloaca which terminates in a cloacal vent.[79]

Reproductive system

In the male frog, the two testes are attached to the kidneys and semen passes into the kidneys through fine tubes called efferent ducts. It then travels on through the ureters, which are consequently known as urinogenital ducts. There is no penis, and sperm is ejected from the cloaca directly onto the eggs as the female lays them. The ovaries of the female frog are beside the kidneys and the eggs pass down a pair of oviducts and through the cloaca to the exterior.[79]

When frogs mate, the male climbs on the back of the female and wraps his fore limbs round her body, either behind the front legs or just in front of the hind legs. This position is called amplexus and may be held for several days.[80] The male frog has certain hormone-dependent secondary sexual characteristics. These include the development of special pads on his thumbs in the breeding season, to give him a firm hold.[81] The grip of the male frog during amplexus stimulates the female to release eggs, usually wrapped in jelly, as spawn.[79] In many species the male is smaller and slimmer than the female. Males have vocal cords and make a range of croaks, particularly in the breeding season, and in some species they also have vocal sacs to amplify the sound.[79]

Nervous system

Frogs have a highly developed nervous system that consists of a brain, spinal cord and nerves. Many parts of frog brains correspond with those of humans. It consists of two olfactory lobes, two cerebral hemispheres, a pineal body, two optic lobes, a cerebellum and a medulla oblongata. Muscular coordination and posture are controlled by the cerebellum, and the medulla oblongata regulates respiration, digestion and other automatic functions.[79] The relative size of the cerebrum in frogs is much smaller than it is in humans. Frogs have ten pairs of cranial nerves which pass information from the outside directly to the brain, and ten pairs of spinal nerves which pass information from the extremities to the brain through the spinal cord.[79] By contrast, all amniotes (mammals, birds and reptiles) have twelve pairs of cranial nerves.[82]

Close-up of frog's head showing eye, nostril, mouth and tympanum.

Sight

The eyes of most frogs are located on either side of the head near the top and project outwards as hemispherical bulges. They provide binocular vision over a field of 100° to the front and a total visual field of almost 360°.[83] They may be the only part of an otherwise submerged frog to protrude from the water. Each eye has closable upper and lower lids and a nictitating membrane which provides further protection, especially when the frog is swimming.[84] Members of the aquatic family Pipidae have the eyes located at the top of the head, a position better suited for detecting prey in the water above.[83] The irises come in a range of colours and the pupils in a range of shapes. The common toad (Bufo bufo) has golden irises and horizontal slit-like pupils, the red-eyed tree frog (Agalychnis callidryas) has vertical slit pupils, the poison dart frog has dark irises, the fire-bellied toad (Bombina spp.) has triangular pupils and the tomato frog (Dyscophus spp.) has circular ones. The irises of the southern toad (Anaxyrus terrestris) are patterned so as to blend in with the surrounding camouflaged skin.[84]

The distant vision of a frog is better than its near vision. Calling frogs will quickly become silent when they see an intruder or even a moving shadow but the closer an object is, the less well it is seen.[84] When a frog shoots out its tongue to catch an insect it is reacting to a small moving object that it cannot see well and must line it up precisely beforehand because it shuts its eyes as the tongue is extended.[55] Although it was formerly debated,[85] more recent research has shown that frogs can see in colour, even in very low light.[86]

Hearing

Frogs can hear both in the air and below water. They do not have external ears; the eardrums (tympanic membranes) are directly exposed or may be covered by a layer of skin and are visible as a circular area just behind the eye. The size and distance apart of the eardrums is related to the frequency and wavelength at which the frog calls. In some species such as the bullfrog, the size of the tympanum indicates the sex of the frog; males have tympani that are larger than their eyes while in females, the eyes and tympani are much the same size.[87] A noise causes the tympanum to vibrate and the sound is transmitted to the middle and inner ear. The middle ear contains semicircular canals which help control balance and orientation. In the inner ear, the auditory hair cells are arranged in two areas of the cochlea, the basilar papilla and the amphibian papilla. The former detects high frequencies and the latter low frequencies.[88] Because the cochlea is short, frogs use electrical tuning to extend their range of audible frequencies and help discriminate different sounds.[89] This arrangement enables detection of the territorial and breeding calls of their conspecifics. In some species that inhabit arid regions, the sound of thunder or heavy rain may arouse them from a dormant state.[88] A frog may be startled by an unexpected noise but it will not usually take any action until it has located the source of the sound by sight.[87]

Call

A male Dendropsophus microcephalus displaying its vocal sac during its call.

The call or croak of a frog is unique to its species. Frogs create this sound 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 frog calls are so loud that they can be heard up to a mile away.[90] Additionally, some species have been found to use man-made structures such as drain pipes for artificial amplification of their call.[91]

Frogs in the genera Heleioporus and Neobatrachus lack vocal sacs but can still produce a loud call. Their buccal cavity is enlarged and dome-shaped, acting as a resonance chamber that amplifies the sound. Species of frog that lack vocal sacs and that do not have a loud call tend to inhabit areas close to constantly noisy, flowing water. They need to use an alternative means to communicate. The coastal tailed frog (Ascaphus truei) lives in mountain streams in North America and does not vocalize.[92]

The main reason for calling is to allow male frogs to attract a mate. Males may call individually or there may be a chorus of sound where numerous males have converged on breeding sites. Females of many frog species, such as the common tree frog (Polypedates leucomystax), reply to the male calls, which acts to reinforce reproductive activity in a breeding colony.[93] Female frogs prefer males that produce sounds of greater intensity and lower frequency, attributes that stand out in a crowd. The rationale for this is thought to be that by demonstrating his prowess, the male shows his fitness to produce superior offspring.[94]

A different call is emitted by a male frog or unreceptive female when mounted by another male. This is a distinct chirruping sound and is accompanied by a vibration of the body.[95] Tree frogs and some non-aquatic species have a rain call that they make on the basis of humidity cues prior to a shower.[95] Many species also have a territorial call that is used to drive away other males. All of these calls are emitted with the mouth of the frog closed.[95] A distress call, emitted by some frogs when they are in danger, is produced with the mouth open resulting in a higher-pitched call. It is typically used when the frog has been grabbed by a predator and may serve to distract or disorientate the attacker so that it releases the frog.[95]

Many species of frog have deep calls. The croak of the American bullfrog (Rana catesbiana) is sometimes written as "jug o' rum".[96] The Pacific tree frog (Pseudacris regilla) produces the onomatopoeic "ribbit" often heard in films.[97] Other renderings of frog calls into speech include "brekekekex koax koax", the call of the marsh frog (Pelophylax ridibundus) in The Frogs, an Ancient Greek comic drama by Aristophanes.[98] The calls of the Concave-eared torrent frog (Amolops tormotus) are unusual in many aspects. The males are notable for their varieties of calls where upward and downward frequency modulations take place. When they communicate, they produce calls that fall in the ultrasound frequency range. The last aspect that makes this species of frog's calls unusual is that nonlinear acoustic phenomena are important components in their acoustic signals.[99]

Torpor

During extreme conditions, some frogs enter a state of torpor and remain inactive for months. In colder regions, many species of frog hibernate in winter. Those that live on land such as the American toad (Bufo americanus) dig a burrow and make a hibernaculum in which to lie dormant. Others, less proficient at digging, find a crevice or bury themselves in dead leaves. Aquatic species such as the American bullfrog (Rana catesbeiana) normally sink to the bottom of the pond where they lie, semi-immersed in mud but still able to access the oxygen dissolved in the water. Their metabolism slows down and they live on their energy reserves. Some frogs such as the wood frog or spring peeper can even survive being frozen. Ice crystals form under the skin and in the body cavity but the essential organs are protected from freezing by a high concentration of glucose. An apparently lifeless, frozen frog can resume respiration and its heartbeat can restart when conditions warm up.[100]

At the other extreme, the striped burrowing frog (Cyclorana alboguttata) regularly aestivates during the hot, dry season in Australia, surviving in a dormant state without access to food and water for nine or ten months of the year. It burrows underground and curls up inside a protective cocoon formed by its shed skin. Researchers at the University of Queensland have found that during aestivation, the metabolism of the frog is altered and the operational efficiency of the mitochondria is increased. This means that the limited amount of energy available to the comatose frog is used in a more efficient manner. This survival mechanism is only useful to animals that remain completely unconscious for an extended period of time and whose energy requirements are low because they are cold-blooded and have no need to generate heat.[101] Other research showed that, to provide these energy requirements, muscles atrophy, but hind limb muscles are preferentially unaffected.[102] Frogs have been found to have upper critical temperatures of around 41 degrees Celsius.[103]

Locomotion

Different species of frog use a number of methods of moving around including jumping, running, walking, swimming, burrowing, climbing and gliding.

Rainforest rocket frog jumping.
Jumping

Frogs are generally recognized as exceptional jumpers and, relative to their size, the best jumpers of all vertebrates.[104] The striped rocket frog, Litoria nasuta, can leap over 2 metres (6 ft 7 in), a distance that is more than fifty times its body length of 5.5 centimetres (2.2 in).[105] There are tremendous differences between species in jumping capability. Within a species, jump distance increases with increasing size, but relative jumping distance (body-lengths jumped) decreases. The Indian skipper frog (Euphlyctis cyanophlyctis) has the ability to leap out of the water from a position floating on the surface.[106] The tiny northern cricket frog (Acris crepitans) can "skitter" across the surface of a pond with a series of short rapid jumps.[107]

Slow-motion photography shows that the muscles have passive flexibility. They are first stretched while the frog is still in the crouched position, then they are contracted before being stretched again to launch the frog into the air. The fore legs are folded against the chest and the hind legs remain in the extended, streamlined position for the duration of the jump.[54] In some extremely capable jumpers, such as the Cuban tree frog (Osteopilus septentrionalis) and the northern leopard frog (Rana pipiens), the peak power exerted during a jump can exceed that which the muscle is theoretically capable of producing. When the muscles contract, the energy is first transferred into the stretched tendon which is wrapped around the ankle bone. Then the muscles stretch again at the same time as the tendon releases its energy like a catapult to produce a powerful acceleration beyond the limits of muscle-powered acceleration.[108] A similar mechanism has been documented in locusts and grasshoppers.[109]

Walking and running
Phrynomantis bifasciatus walking on a level surface

Frogs in the families Bufonidae, Rhinophrynidae, and Microhylidae have short back legs and tend to walk rather than jump.[110] When they try to move rapidly, they speed up the rate of movement of their limbs or resort to an ungainly hopping gait. The Great Plains narrow-mouthed toad (Gastrophryne olivacea) has been described as having a gait that is "a combination of running and short hops that are usually only an inch or two in length".[111] In an experiment, Fowler's toad (Bufo fowleri) was placed on a treadmill which was turned at varying speeds. By measuring the toad's uptake of oxygen it was found that hopping was an inefficient use of resources during sustained locomotion but was a useful strategy during short bursts of high-intensity activity.[112]

The red-legged running frog (Kassina maculata) has short, slim hind limbs unsuited to jumping. It can move fast by using a running gait in which the two hind legs are used alternately. Slow-motion photography shows, unlike a horse that can trot or gallop, the frog's gait remained similar at slow, medium, and fast speeds.[113] This species can also climb trees and shrubs, and does so at night to catch insects.[114] The Indian skipper frog (Euphlyctis cyanophlyctis) has broad feet and can run across the surface of the water for several metres (yards).[107]

Swimming
Common toad (Bufo bufo) swimming.

Frogs that live in or visit water have adaptations that improve their swimming abilities. The hind limbs are heavily muscled and strong. The webbing between the toes of the hind feet increases the area of the foot and helps propel the frog powerfully through the water. Members of the family Pipidae are wholly aquatic and show the most marked specialization. They have inflexible vertebral columns, flattened, streamlined bodies, lateral line systems, and powerful hind limbs with large webbed feet.[115] Tadpoles mostly have large tail fins which provide thrust when the tail is moved from side to side.[116]

Burrowing

Some frogs have become adapted for burrowing and a life underground. They tend to have rounded bodies, short limbs, small heads with bulging eyes, and hind feet adapted for excavation. An extreme example of this is the purple frog (Nasikabatrachus sahyadrensis) from southern India which feeds on termites and spends almost its whole life underground. It emerges briefly during the monsoon to mate and breed in temporary pools. It has a tiny head with a pointed snout and a plump, rounded body. Because of this fossorial existence, it was first described in 2003, being new to the scientific community at that time, although previously known to local people.[117]

Purple frog (Nasikabatrachus sahyadrensis).

The spadefoot toads of North America are also adapted to underground life. The Plains spadefoot toad (Spea bombifrons) is typical and has a flap of keratinised bone attached to one of the metatarsals of the hind feet which it uses to dig itself backwards into the ground. As it digs, the toad wriggles its hips from side to side to sink into the loose soil. It has a shallow burrow in the summer from which it emerges at night to forage. In winter, it digs much deeper and has been recorded at a depth of 4.5 m (15 ft).[118] The tunnel is filled with soil and the toad hibernates in a small chamber at the end. During this time, urea accumulates in its tissues and water is drawn in from the surrounding damp soil by osmosis to supply the toad's needs.[118] Spadefoot toads are "explosive breeders", all emerging from their burrows at the same time and converging on temporary pools, attracted to one of these by the calling of the first male to find a suitable breeding location.[119]

The burrowing frogs of Australia have a rather different lifestyle. The western spotted frog (Heleioporus albopunctatus) digs a burrow beside a river or in the bed of an ephemeral stream and regularly emerges to forage. Mating takes place and eggs are laid in a foam nest inside the burrow. The eggs partially develop there, but do not hatch until they are submerged following heavy rainfall. The tadpoles then swim out into the open water and rapidly complete their development.[120] Madagascan burrowing frogs are less fossorial and mostly bury themselves in leaf litter. One of these, the green burrowing frog (Scaphiophryne marmorata), has a flattened head with a short snout and well-developed metatarsal tubercles on its hind feet to help with excavation. It also has greatly enlarged terminal discs on its fore feet that help it to clamber around in bushes.[121] It breeds in temporary pools that form after rains.[122]

Climbing
Group of Glass frogs

Tree frogs live high in the canopy, where they scramble around on the branches, twigs, and leaves, sometimes never coming down to earth. The "true" tree frogs belong to the family Hylidae, but members of other frog families have independently adopted an arboreal habit, a case of convergent evolution. These include the glass frogs (Centrolenidae), the bush frogs (Hyperoliidae), some of the narrow-mouthed frogs (Microhylidae), and the shrub frogs (Rhacophoridae).[110] Most tree frogs are under 10 cm (4 in) in length, with long legs and long toes with adhesive pads on the tips. The surface of the toe pads is formed from a closely packed layer of flat-topped, hexagonal epidermal cells separated by grooves into which glands secrete mucus. These toe pads, moistened by the mucus, provide the grip on any wet or dry surface, including glass. The forces involved include boundary friction of the toe pad epidermis on the surface and also surface tension and viscosity.[123] Tree frogs are very acrobatic and can catch insects while hanging by one toe from a twig or clutching onto the blade of a windswept reed.[124] Some members of the subfamily Phyllomedusinae have opposable toes on their feet. The reticulated leaf frog (Phyllomedusa ayeaye) has a single opposed digit on each fore foot and two opposed digits on its hind feet. This allows it to grasp the stems of bushes as it clambers around in its riverside habitat.[125]

Gliding

During the evolutionary history of frogs, several different groups have independently taken to the air.[126] Some frogs in the tropical rainforest are specially adapted for gliding from tree to tree or parachuting to the forest floor. Typical of them is Wallace's flying frog (Rhacophorus nigropalmatus) from Malaysia and Borneo. It has large feet with the fingertips expanded into flat adhesive discs and the digits fully webbed. Flaps of skin occur on the lateral margins of the limbs and across the tail region. With the digits splayed, the limbs outstretched, and these flaps spread, it can glide considerable distances, but is unable to undertake powered flight.[127] It can alter its direction of travel and navigate distances of up to 15 m (49 ft) between trees.[128]

Life history

Life cycle of the green frog
(Rana clamitans).

Like other amphibians, the life cycle of a frog normally starts in water with an egg that hatches into a limbless larva with gills, commonly known as a tadpole. After further growth, during which it develops limbs and lungs, the tadpole undergoes metamorphosis in which its appearance and internal organs are rearranged. After this it is able to leave the water as a miniature, air-breathing frog.

Reproduction

Two main types of reproduction occur in frogs, prolonged breeding and explosive breeding. In the former, adopted by the majority of species, adult frogs at certain times of year assemble at a pond, lake or stream to breed. Many frogs return to the bodies of water in which they developed as larvae. This often results in annual migrations involving thousands of individuals. In explosive breeders, mature adult frogs arrive at breeding sites in response to certain trigger factors such as rainfall occurring in an arid area. In these frogs, mating and spawning take place promptly and the speed of larval growth is rapid in order to make use of the ephemeral pools before they dry up.[129]

Among prolonged breeders, males usually arrive at the breeding site first and remain there for some time whereas females tend to arrive later and depart soon after they have spawned. This means that males outnumber females at the water's edge and defend territories from which they expel other males. They advertise their presence by calling, often alternating their croaks with neighbouring frogs. Larger, stronger males tend to have deeper calls and maintain higher quality territories. Females select their mates at least partly on the basis of the depth of their voice.[130] In some species there are satellite males who have no territory and do not call. They may intercept females that are approaching a calling male or take over a vacated territory. Calling is an energy-sapping activity. Sometimes the two roles are reversed and a calling male gives up its territory and becomes a satellite.[129]

Male and female common toads (Bufo bufo) in amplexus.

In explosive breeders, the first male that finds a suitable breeding location, such as a temporary pool, calls loudly and other frogs of both sexes converge on the pool. Explosive breeders tend to call in unison creating a chorus that can be heard from far away. The spadefoot toads (Scaphiopus spp.) of North America fall into this category. Mate selection and courtship is not as important as speed in reproduction. In some years, suitable conditions may not occur and the frogs may go for two or more years without breeding.[129] Some female New Mexico spadefoot toads (Spea multiplicata) only spawn half of the available eggs at a time, perhaps retaining some in case a better reproductive opportunity arises later.[131]

At the breeding site, the male mounts the female and grips her tightly round the body. Typically, amplexus takes place in the water, the female releases her eggs and the male covers them with sperm; fertilization is external. In many species such as the Great Plains toad (Bufo cognatus), the male restrains the eggs with his back feet, holding them in place for about three minutes.[129] Members of the West African genus Nimbaphrynoides are unique among frogs in that they are viviparous; Limnonectes larvaepartus, Eleutherodactylus jasperi and members of the Tanzanian genus Nectophrynoides are the only frogs known to be ovoviviparous. In these species, fertilization is internal and females give birth to fully developed juvenile frogs, except L. larvaepartus, which give birth to tadpoles.[132][133][134]

Life cycle

Eggs / frogspawn

Frogspawn

Frogs' embryos are typically surrounded by several layers of gelatinous material. When several eggs are clumped together, they are collectively known as frogspawn. The jelly provides support and protection while allowing the passage of oxygen, carbon dioxide and ammonia. It absorbs moisture and swells on contact with water. After fertilization, the innermost portion liquifies to allow free movement of the developing embryo. In certain species, such as the Northern red-legged frog (Rana aurora) and the wood frog (Rana sylvatica), symbiotic unicellular green algae are present in the gelatinous material. It is thought that these may benefit the developing larvae by providing them with extra oxygen through photosynthesis.[135] Most eggs are black or dark brown and this has the advantage of absorbing warmth from the sun which the insulating capsule retains. The interior of globular egg clusters of the wood frog (Rana sylvatica) has been found to be up to 6 °C (11 °F) warmer than the surrounding water and this speeds up the development of the larvae.[136]

The shape and size of the egg mass is characteristic of the species. Ranids tend to produce globular clusters containing large numbers of eggs whereas bufonids produce long, cylindrical strings. The tiny yellow-striped pygmy eleuth (Eleutherodactylus limbatus) lays eggs singly, burying them in moist soil.[137] The smoky jungle frog (Leptodactylus pentadactylus) makes a nest of foam in a hollow. The eggs hatch when the nest is flooded, or the tadpoles may complete their development in the foam if flooding does not occur.[138] The red-eyed treefrog (Agalychnis callidryas) deposits its eggs on a leaf above a pool and when they hatch, the larvae fall into the water below.[139] The larvae developing in the eggs can detect vibrations caused by nearby predatory wasps or snakes, and will hatch early to avoid being eaten.[140] In general, the length of the egg stage depends on the species and the environmental conditions. Aquatic eggs normally hatch within one week when the capsule splits as a result of enzymes released by the developing larvae.[141]

Tadpoles

Frogspawn development.

The larvae that emerge from the eggs, known as tadpoles (or occasionally polliwogs), typically have oval bodies and long, vertically flattened tails. As a general rule, free-living larvae are fully aquatic, but at least one species (Nannophrys ceylonensis) has semiterrestrial tadpoles which live among wet rocks.[142][143] Tadpoles lack eyelids and have cartilaginous skeletons, lateral line systems, gills for respiration (external gills at first, internal gills later), and vertically flattened tails they use for swimming.[116]

From early in its development, a gill pouch covers the tadpole's gills and front legs. The lungs soon start to develop and are used as an accessory breathing organ. Some species go through metamorphosis while still inside the egg and hatch directly into small frogs. Tadpoles lack true teeth, but the jaws in most species have two elongated, parallel rows of small, keratinized structures called keradonts in their upper jaws. Their lower jaws usually have three rows of keradonts surrounded by a horny beak, but the number of rows can vary and the exact arrangements of mouth parts provide a means for species identification.[141] In the Pipidae, with the exception of Hymenochirus, the tadpoles have paired anterior barbels, which make them resemble small catfish.[115] Their tails are stiffened by a notochord, but does not contain any bony or cartilaginous elements except for a few vertebrae at the base which forms the urostyle during metamorphosis. This has been suggested as an adaptation to their lifestyles; because the transformation into frogs happens very fast, the tail is made of soft tissue only, as bone and cartilage take a much longer time to be broken down and absorbed. The tail fin and tip is fragile and will easily tear, which is seen as an adaptation to escape from predators which tries to grasp them by the tail.[144]

Tadpoles are typically herbivorous, feeding mostly on algae, including diatoms filtered from the water through the gills. Some species are carnivorous at the tadpole stage, eating insects, smaller tadpoles, and fish. The Cuban tree frog (Osteopilus septentrionalis) is one of a number of species in which the tadpoles can be cannibalistic. Tadpoles that develop legs early may be eaten by the others, so late developers may have better long-term survival prospects.[145]

Tadpoles are highly vulnerable to being eaten by fish, newts, predatory diving beetles, and birds, such as kingfishers. Some tadpoles, including those of the cane toad (Bufo marinus), are poisonous. The tadpole stage may be as short as a week in explosive breeders or it may last through one or more winters followed by metamorphosis in the spring.[146]

Metamorphosis

At the end of the tadpole stage, a frog undergoes metamorphosis in which its body makes a sudden transition into the adult form. This metamorphosis typically lasts only 24 hours, and is initiated by production of the hormone thyroxine. This causes different tissues to develop in different ways. The principal changes that take place include the development of the lungs and the disappearance of the gills and gill pouch, making the front legs visible. The lower jaw transforms into the big mandible of the carnivorous adult, and the long, spiral gut of the herbivorous tadpole is replaced by the typical short gut of a predator.[141] The nervous system becomes adapted for hearing and stereoscopic vision, and for new methods of locomotion and feeding.[141] The eyes are repositioned higher up on the head and the eyelids and associated glands are formed. The eardrum, middle ear, and inner ear are developed. The skin becomes thicker and tougher, the lateral line system is lost, and skin glands are developed.[141] The final stage is the disappearance of the tail, but this takes place rather later, the tissue being used to produce a spurt of growth in the limbs.[147] Frogs are at their most vulnerable to predators when they are undergoing metamorphosis. At this time, the tail is being lost and locomotion by means of limbs is only just becoming established.[110]

Adults

After metamorphosis, young adults may disperse into terrestrial habitats or continue to live in water. Almost all frog species are carnivorous as adults, preying on invertebrates, including arthropods, worms, snails, and slugs. A few of the larger ones may eat other frogs, small mammals, and fish. Some frogs use their sticky tongues to catch fast-moving prey, while others push food into their mouths with their hands. A few species also eat plant matter; the tree frog Xenohyla truncata is partly herbivorous, its diet including a large proportion of fruit,[148] Leptodactylus mystaceus has been found to eat plants,[149][150] and folivory occurs in Euphlyctis hexadactylus, with plants constituting 79.5% of its diet by volume.[151] Adult frogs are themselves attacked by many predators. The northern leopard frog (Rana pipiens) is eaten by herons, hawks, fish, large salamanders, snakes, raccoons, skunks, mink, bullfrogs, and other animals.[152]

A trophic pyramid showing frogs as primary predators.

Frogs are primary predators and an important part of the food web. Being cold-blooded, they make efficient use of the food they eat with little energy being used for metabolic processes, while the rest is transformed into biomass. They are themselves eaten by secondary predators and are the primary terrestrial consumers of invertebrates, most of which feed on plants. By reducing herbivory, they play a part in increasing the growth of plants and are thus part of a delicately balanced ecosystem.[153]

Little is known about the longevity of frogs and toads in the wild, but some can live for many years. Skeletochronology is a method of examining bones to determine age. Using this method, the ages of mountain yellow-legged frogs (Rana muscosa) were studied, the phalanges of the toes showing seasonal lines where growth slows in winter. The oldest frogs had ten bands, so their age was believed to be 14 years, including the four-year tadpole stage.[154] Captive frogs and toads have been recorded as living for up to 40 years, an age achieved by a European common toad (Bufo bufo). The cane toad (Bufo marinus) has been known to survive 24 years in captivity, and the American bullfrog (Rana catesbeiana) 14 years.[155] Frogs from temperate climates hibernate during the winter, and four species are known to be able to withstand freezing during this time, including the wood frog (Rana sylvatica).[156]

Parental care

Male common midwife toad with eggs
(Alytes obstetricans).
Pouched frog (Assa darlingtoni)

Although care of offspring is poorly understood in frogs, up to an estimated 20% of amphibian species may care for their young in some way.[157] The evolution of parental care in frogs is driven primarily by the size of the water body in which they breed. Those that breed in smaller water bodies tend to have greater and more complex parental care behaviour.[158] Because predation of eggs and larvae is high in large water bodies, some frog species started to lay their eggs on land. Once this happened, the desiccating terrestrial environment demands that one or both parents keep them moist to ensure their survival.[159] The subsequent need to transport hatched tadpoles to a water body required an even more intense form of parental care.[158]

In small pools, predators are mostly absent and competition between tadpoles becomes the variable that constrains their survival. Certain frog species avoid this competition by making use of smaller phytotelmata (water-filled leaf axils or small woody cavities) as sites for depositing a few tadpoles.[160] While these smaller rearing sites are free from competition, they also lack sufficient nutrients to support a tadpole without parental assistance. Frog species that changed from the use of larger to smaller phytotelmata have evolved a strategy of providing their offspring with nutritive but unfertilized eggs.[158] The female strawberry poison-dart frog (Oophaga pumilio) lays her eggs on the forest floor. The male frog guards them from predation and carries water in his cloaca to keep them moist. When they hatch, the female moves the tadpoles on her back to a water-holding bromeliad or other similar water body, depositing just one in each location. She visits them regularly and feeds them by laying one or two unfertilized eggs in the phytotelma, continuing to do this until the young are large enough to undergo metamorphosis.[161] The granular poison frog (Oophaga granulifera) looks after its tadpoles in a similar way.[162]

Many other diverse forms of parental care are seen in frogs. The tiny male Colostethus subpunctatus stands guard over his egg cluster, laid under a stone or log. When the eggs hatch, he transports the tadpoles on his back to a temporary pool, where he partially immerses himself in the water and one or more tadpoles drop off. He then moves on to another pool.[163] The male common midwife toad (Alytes obstetricans) carries the eggs around with him attached to his hind legs. He keeps them damp in dry weather by immersing himself in a pond, and prevents them from getting too wet in soggy vegetation by raising his hindquarters. After three to six weeks, he travels to a pond and the eggs hatch into tadpoles.[164] The tungara frog (Physalaemus pustulosus) builds a floating nest from foam to protect its eggs from predation. The foam is made from proteins and lectins, and seems to have antimicrobial properties.[165] Several pairs of frogs may form a colonial nest on a previously built raft. The eggs are laid in the centre, followed by alternate layers of foam and eggs, finishing with a foam capping.[166]

Some frogs protect their offspring inside their own bodies. Both male and female pouched frogs (Assa darlingtoni) guard their eggs, which are laid on the ground. When the eggs hatch, the male lubricates his body with the jelly surrounding them and immerses himself in the egg mass. The tadpoles wriggle into skin pouches on his side, where they develop until they metamorphose into juvenile frogs.[167] The female gastric-brooding frog (Rheobatrachus sp.) from Australia, now probably extinct, swallows her fertilized eggs, which then develop inside her stomach. She ceases to feed and stops secreting stomach acid. The tadpoles rely on the yolks of the eggs for nourishment. After six or seven weeks, they are ready for metamorphosis. The mother regurgitates the tiny frogs, which hop away from her mouth.[168] The female Darwin's frog (Rhinoderma darwinii) from Chile lays up to 40 eggs on the ground, where they are guarded by the male. When the tadpoles are about to hatch, they are engulfed by the male, which carries them around inside his much-enlarged vocal sac. Here they are immersed in a frothy, viscous liquid that contains some nourishment to supplement what they obtain from the yolks of the eggs. They remain in the sac for seven to ten weeks before undergoing metamorphosis, after which they move into the male's mouth and emerge.[169]

Defence

The mildly toxic Ranitomeya imitator.
Strawberry poison-dart frog contains numerous alkaloids which deter predators.

At first sight, frogs seem rather defenceless because of their small size, slow movement, thin skin, and lack of defensive structures, such as spines, claws or teeth. Many use camouflage to avoid detection, the skin often being spotted or streaked in neutral colours that allow a stationary frog to merge into its surroundings. Some can make prodigious leaps, often into water, that help them to evade potential attackers, while many have other defensive adaptations and strategies.[129]

The skin of many frogs contains mild toxic substances called bufotoxins to make them unpalatable to potential predators. Most toads and some frogs have large poison glands, the parotoid glands, located on the sides of their heads behind the eyes and other glands elsewhere on their bodies. These glands secrete mucus and a range of toxins that make frogs slippery to hold and distasteful or poisonous. If the noxious effect is immediate, the predator may cease its action and the frog may escape. If the effect develops more slowly, the predator may learn to avoid that species in future.[170] Poisonous frogs tend to advertise their toxicity with bright colours, an adaptive strategy known as aposematism. The poison dart frogs in the family Dendrobatidae do this. They are typically red, orange, or yellow, often with contrasting black markings on their bodies. Allobates zaparo is not poisonous, but mimics the appearance of two different toxic species with which it shares a common range in an effort to deceive predators.[171] Other species, such as the European fire-bellied toad (Bombina bombina), have their warning colour underneath. They "flash" this when attacked, adopting a pose that exposes the vivid colouring on their bellies.[4]

A common toad adopting a defensive stance.

Some frogs, such as the poison dart frogs, are especially toxic. The native peoples of South America extract poison from these frogs to apply to their weapons for hunting,[172] although few species are toxic enough to be used for this purpose. At least two non-poisonous frog species in tropical America (Eleutherodactylus gaigei and Lithodytes lineatus) mimic the colouration of dart poison frogs for self-protection.[173][174] Some frogs obtain poisons from the ants and other arthropods they eat.[175] Others, such as the Australian corroboree frogs (Pseudophryne corroboree and Pseudophryne pengilleyi), can synthesize the alkaloids themselves.[176] The chemicals involved may be irritants, hallucinogens, convulsants, nerve poisons or vasoconstrictors. Many predators of frogs have become adapted to tolerate high levels of these poisons, but other creatures, including humans who handle the frogs, may be severely affected.[177]

Some frogs use bluff or deception. The European common toad (Bufo bufo) adopts a characteristic stance when attacked, inflating its body and standing with its hindquarters raised and its head lowered.[178] The bullfrog (Rana catesbeiana) crouches down with eyes closed and head tipped forward when threatened. This places the parotoid glands in the most effective position, the other glands on its back begin to ooze noxious secretions and the most vulnerable parts of its body are protected.[129] Another tactic used by some frogs is to "scream", the sudden loud noise tending to startle the predator. The gray tree frog (Hyla versicolor) makes an explosive sound that sometimes repels the shrew Blarina brevicauda.[129] Although toads are avoided by many predators, the common garter snake (Thamnophis sirtalis) regularly feeds on them. The strategy employed by juvenile American toads (Bufo americanus) on being approached by a snake is to crouch down and remain immobile. This is usually successful, with the snake passing by and the toad remaining undetected. If it is encountered by the snake's head, however, the toad hops away before crouching defensively.[179]

Distribution

Although frogs are most diverse in warm regions, a few species like the wood frog even live at the Arctic Circle

Frogs live on all the continents except Antarctica, but they are not present on certain islands, especially those far away from continental land masses.[180][181] Many species are isolated in restricted ranges by changes of climate or inhospitable territory, such as stretches of sea, mountain ridges, deserts, forest clearance, road construction, or other man-made barriers.[182] Usually, a greater diversity of frogs occurs in tropical areas than in temperate regions, such as Europe.[183] Some frogs inhabit arid areas, such as deserts, and rely on specific adaptations to survive. Members of the Australian genus Cyclorana bury themselves underground where they create a water-impervious cocoon in which to aestivate during dry periods. Once it rains, they emerge, find a temporary pool, and breed. Egg and tadpole development is very fast in comparison to those of most other frogs, so breeding can be completed before the pond dries up.[184] Some frog species are adapted to a cold environment. The wood frog (Rana sylvatica), whose habitat extends into the Arctic Circle, buries itself in the ground during winter. Although much of its body freezes during this time, it maintains a high concentration of glucose in its vital organs, which protects them from damage.[55]

Conservation

Golden toad (Bufo periglenes) – last seen in 1989.

In 2006, of 4,035 species of amphibians that depend on water during some lifecycle stage, 1,356 (33.6%) were considered to be threatened. This is likely to be an underestimate because it excludes 1,427 species for which evidence was insufficient to assess their status.[185] Frog populations have declined dramatically since the 1950s. More than one-third of frog species are considered to be threatened with extinction, and more than 120 species are believed to have become extinct since the 1980s.[186] Among these species are the gastric-brooding frogs of Australia and the golden toad of Costa Rica. The latter is of particular concern to scientists because it inhabited the pristine Monteverde Cloud Forest Reserve and its population crashed in 1987, along with about 20 other frog species in the area. This could not be linked directly to human activities, such as deforestation, and was outside the range of normal fluctuations in population size.[187] Elsewhere, habitat loss is a significant cause of frog population decline, as are pollutants, climate change, increased UVB radiation, and the introduction of non-native predators and competitors.[188] A Canadian study conducted in 2006 suggested heavy traffic in their environment was a larger threat to frog populations than was habitat loss.[189] Emerging infectious diseases, including chytridiomycosis and ranavirus, are also devastating populations.[190][191]

Many environmental scientists believe amphibians, including frogs, are good biological indicators of broader ecosystem health because of their intermediate positions in food chains, their permeable skins, and typically biphasic lives (aquatic larvae and terrestrial adults).[192] It appears that species with both aquatic eggs and larvae are most affected by the decline, while those with direct development are the most resistant.[193]

Deformed mink frog with an extra left leg

Frog mutations and genetic defects have increased since the 1990s. These often include missing legs or extra legs. Various causes have been identified or hypothesized, including an increase in ultraviolet radiation affecting the spawn on the surface of ponds, chemical contamination from pesticides and fertilizers, and parasites such as the trematode Ribeiroia ondatrae. Probably all these are involved in a complex way as stressors, environmental factors contributing to rates of disease, and vulnerability to attack by parasites. Malformations impair mobility and the individuals may not survive to adulthood. An increase in the number of frogs eaten by birds may actually increase the likelihood of parasitism of other frogs, because the trematode's complex lifecycle includes the ramshorn snail and several intermediate hosts such as birds.[194][195]

In a few cases, captive breeding programs have been established and have largely been successful.[196][197] The World Association of Zoos and Aquariums named 2008 as the "Year of the Frog" in order to draw attention to the conservation issues faced by them.[198]

The cane toad (Bufo marinus) is a very adaptable species native to South and Central America. In the 1930s, it was introduced into Puerto Rico, and later various other islands in the Pacific and Caribbean region, as a biological pest control agent.[199] In 1935, 3000 toads were liberated in the sugar cane fields of Queensland, Australia, in an attempt to control cane beetles such as Dermolepida albohirtum, the larvae of which damage and kill the canes. Initial results in many of these countries were positive, but it later became apparent that the toads upset the ecological balance in their new environments. They bred freely, competed with native frog species, ate bees and other harmless native invertebrates, had few predators in their adopted habitats, and poisoned pets, carnivorous birds, and mammals. In many of these countries, they are now regarded both as pests and invasive species, and scientists are looking for a biological method to control them.[200]

Uses

Culinary

French cuisses de grenouille.

Frog legs are eaten by humans in many parts of the world. French cuisses de grenouille or frog legs dish is a traditional dish particularly served in the region of the Dombes (département of Ain). The dish is also common in French-speaking parts of Louisiana, particularly the Cajun areas of Southern Louisiana as well as New Orleans, United States. In Asia, frog legs are consumed in China, Vietnam, Thailand and Indonesia. Chinese edible frog and pig frogs are farmed and consumed on a large scale in some areas of China. Frog legs are part of Chinese Sichuan and Cantonese cuisine. In Indonesia, frog-leg soup is known as swikee or swike. Indonesia is the world's largest exporter of frog meat, exporting more than 5,000 tonnes of frog meat each year, mostly to France, Belgium and Luxembourg.[201]

Originally, they were supplied from local wild populations, but overexploitation led to a diminution in the supply. This resulted in the development of frog farming and a global trade in frogs.[202] The main importing countries are France, Belgium, Luxembourg, and the United States, while the chief exporting nations are Indonesia and China.[202] The annual global trade in the American bullfrog (Rana catesbeiana), mostly farmed in China, varies between 1200 and 2400 tonnes.[203]

The mountain chicken frog, so-called as it tastes of chicken is now endangered, in part due to human consumption and was a major food choice of the Dominicans.[204]

Coon, possum, partridges, prairie hen, and frogs were among the fare Mark Twain recorded as part of American cuisine.[205]

Scientific research

Frogs are used for dissections in high school and university anatomy classes, often first being injected with coloured substances to enhance contrasts among the biological systems. This practice is declining due to animal welfare concerns, and "digital frogs" are now available for virtual dissection.[206]

Frogs have served as experimental animals throughout the history of science. Eighteenth-century biologist Luigi Galvani discovered the link between electricity and the nervous system by studying frogs.[207] In 1852, H. F. Stannius used a frog's heart in a procedure called a Stannius ligature to demonstrate the ventricle and atria beat independently of each other and at different rates.[208] The African clawed frog or platanna (Xenopus laevis) was first widely used in laboratories in pregnancy tests in the first half of the 20th century. A sample of urine from a pregnant woman injected into a female frog induces it to lay eggs, a discovery made by English zoologist Lancelot Hogben. This is because a hormone, human chorionic gonadotropin, is present in substantial quantities in the urine of women during pregnancy.[209] In 1952, Robert Briggs and Thomas J. King cloned a frog by somatic cell nuclear transfer. This same technique was later used to create Dolly the sheep, and their experiment was the first time a successful nuclear transplantation had been accomplished in higher animals.[210]

Frogs are used in cloning research and other branches of embryology. Although alternative pregnancy tests have been developed, biologists continue to use Xenopus as a model organism in developmental biology because their embryos are large and easy to manipulate, they are readily obtainable, and can easily be kept in the laboratory.[211] Xenopus laevis is increasingly being displaced by its smaller relative, Xenopus tropicalis, which reaches its reproductive age in five months rather than the one to two years for X. laevis,[212] thus facilitating faster studies across generations.

Genomes of Xenopus laevis, X. tropicalis, Rana catesbeiana, Rhinella marina, and Nanorana parkeri have been sequenced and deposited in the NCBI Genome database.[213]

Pharmaceutical

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 made by some species of poison dart frogs, although it can also cause death by lung paralysis. Other chemicals isolated from the skins of frogs may offer resistance to HIV infection.[214] Dart poisons are under active investigation for their potential as therapeutic drugs.[215]

It has long been suspected that pre-Columbian Mesoamericans used a toxic secretion produced by the cane toad as a hallucinogen, but more likely they used substances secreted by the Colorado River toad (Bufo alvarius). These contain bufotenin (5-MeO-DMT), a psychoactive compound that has been used in modern times as a recreational drug. Typically, the skin secretions are dried and then smoked.[216] Illicit drug use by licking the skin of a toad has been reported in the media, but this may be an urban myth.[217]

Golden poison frog (Phyllobates terribilis).

Exudations from the skin of the golden poison frog (Phyllobates terribilis) are traditionally used by native Colombians to poison the darts they use for hunting. The tip of the projectile is rubbed over the back of the frog and the dart is launched from a blowgun. The combination of the two alkaloid toxins batrachotoxin and homobatrachotoxin is so powerful, one frog contains enough poison to kill an estimated 22,000 mice.[218] Two other species, the Kokoe poison dart frog (Phyllobates aurotaenia) and the black-legged dart frog (Phyllobates bicolor) are also used for this purpose. These are less toxic and less abundant than the golden poison frog. They are impaled on pointed sticks and may be heated over a fire to maximise the quantity of poison that can be transferred to the dart.[218]

Cultural beliefs

Moche frog sculpture

Frogs feature prominently in folklore, fairy tales, and popular culture. They tend to be portrayed as benign, ugly, and clumsy, but with hidden talents. Examples include Michigan J. Frog, "The Frog Prince", and Kermit the Frog. The Warner Brothers cartoon One Froggy Evening features Michigan J. Frog, that will only dance and sing for the demolition worker who opens his time capsule, but will not perform in public.[219] "The Frog Prince" is a fairy tale about a frog that turns into a handsome prince after he has rescued a princess's golden ball and she has taken him into her palace.[220] Kermit the Frog is a conscientious and disciplined character from The Muppet Show and Sesame Street; while openly friendly and greatly talented, he is often portrayed as cringing at the fanciful behavior of more flamboyant characters.[221]

The Moche people of ancient Peru worshipped animals, and often depicted frogs in their art.[222] In Panama, local legend held that good fortune would come to anyone who spotted a Panamanian golden frog. Some believed when one of these frogs died, it would turn into a golden talisman known as a huaca. Today, despite being extinct in the wild, Panamanian golden frogs remain an important cultural symbol and are illustrated on decorative cloth molas made by the Kuna people. They also appear as part of the inlaid design on a new overpass in Panama City, on T-shirts, and even on lottery tickets.[223]

gollark: Currently it's Void, Alpine, Void.
gollark: I have a *unique* setup with three Linux-running systems on which I flip between about four distros every year.
gollark: btw you should use arch
gollark: <@!573969030080233497> Do a clean Windows install.
gollark: https://security.stackexchange.com/questions/76100/how-to-find-processes-that-are-hidden-from-task-manager

See also

  •  Frogs portal

References

  1. "General Amphibian Facts | Scholastic". www.scholastic.com. Retrieved 2020-04-23.
  2. Cannatella, David C. (1997). "Salientia". Tree of Life Web Project. Retrieved 2012-08-07.
  3. Badger, D.; Netherton, J. (1995). Frogs. Airlife Publishing. p. 19. ISBN 978-1-85310-740-5.
  4. Kuzmin, Sergius L. (1999-09-29). "Bombina bombina". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-06-15.
  5. Lips, K; Solís, F.; Ibáñez, R.; Jaramillo, C.; Fuenmayor, Q. (2010). "Atelopus zeteki". IUCN Red List of Threatened Species. 2010. Retrieved 2012-08-02.
  6. Bailly, Anatole (1981-01-01). Abrégé du dictionnaire grec français. Paris: Hachette. ISBN 978-2010035289. OCLC 461974285.
  7. Bailly, Anatole. "Greek-french dictionary online". www.tabularium.be. Retrieved December 9, 2018.
  8. anuran, n. and adj OED Online, Oxford University Press, March 2019
  9. "frog, n.1 and adj." OED Online, Oxford University Press, March 2019, www.oed.com/view/Entry/74855. Accessed 9 March 2019.
  10. "frosh | frosk, n.1." OED Online, Oxford University Press, March 2019, www.oed.com/view/Entry/74960. Accessed 9 March 2019.
  11. Jerzy Wełna, 'Metathetic and Non-Metathetic Form Selection in Middle English', Studia Anglica Posnaniensia, 30 (2002), 501–18 (p. 504).
  12. Harper, Douglas. "Frog". Online Etymology Dictionary. Retrieved 2012-10-02.
  13. "toad, n." OED Online, Oxford University Press, March 2019, www.oed.com/view/Entry/202700. Accessed 9 March 2019.
  14. "tadpole, n.1." OED Online, Oxford University Press, March 2019, www.oed.com/view/Entry/196984. Accessed 9 March 2019.
  15. Pough, F. H.; Andrews, R. M.; Cadle, J. E.; Crump, M. L.; Savitsky, A. H.; Wells, K. D. (2003). Herpetology: Third Edition. Benjamin Cummings. ISBN 978-0-13-100849-6.
  16. Frost, Darrel R. (2019). "Anura Fischer von Waldheim, 1813". Amphibian Species of the World: an Online Reference. Version 6.0. American Museum of Natural History. Retrieved 7 April 2019.
  17. Duellman, William E. Biology of Amphibians, p. 319, at Google Books
  18. Cannatella, David (2008-01-11). "Anura". Tree of Life web project. Retrieved 2012-08-08.
  19. Ford, L.S.; Cannatella, D. C. (1993). "The major clades of frogs". Herpetological Monographs. 7: 94–117. doi:10.2307/1466954. JSTOR 1466954.
  20. Faivovich, J.; Haddad, C. F. B.; Garcia, P. C. A.; Frost, D. R.; Campbell, J. A.; Wheeler, W. C. (2005). "Systematic review of the frog family Hylidae, with special reference to Hylinae: Phylogenetic analysis and revision". Bulletin of the American Museum of Natural History. 294: 1–240. CiteSeerX 10.1.1.470.2967. doi:10.1206/0003-0090(2005)294[0001:SROTFF]2.0.CO;2.
  21. Kuzmin, S. L. (1999-11-10). "Pelophylax esculentus". Retrieved 2012-10-12.
  22. Köhler, S. (2003). "Mechanisms for partial reproductive isolation in a Bombina hybrid zone in Romania" (PDF). Dissertation for thesis. Retrieved 2012-06-05.
  23. San Mauro, Diego; Vences, Miguel; Alcobendas, Marina; Zardoya, Rafael; Meyer, Axel (2005). "Initial Diversification of living amphibians predated the breakup of Pangaea". The American Naturalist. 165 (5): 590–599. doi:10.1086/429523. JSTOR 429523. PMID 15795855.(subscription required)
  24. Zhang, Peng; Zhou, Hui; Chen, Yue-Qin; Liu, Yi-Fei; Qu, Liang-Hu (2005). "Mitogenomic perspectives on the origin and phylogeny of living amphibians". Systematic Biology. 54 (3): 391–400. doi:10.1080/10635150590945278. PMID 16012106.
  25. Marjanović, David; Laurin, Michel (2007). "Fossils, molecules, divergence times, and the origin of lissamphibians". Systematic Biology. 56 (3): 369–388. doi:10.1080/10635150701397635. PMID 17520502.
  26. Pyron, R. Alexander (2011). "Divergence time estimation using fossils as terminal taxa and the origins of Lissamphibia". Systematic Biology. 60 (4): 466–481. doi:10.1093/sysbio/syr047. PMID 21540408.
  27. Casselman, Anne (2008-05-21). ""Frog-amander" fossil may be amphibian missing link". National Geographic News. Retrieved 2012-07-05.
  28. Anderson, Jason S.; Reisz, Robert R.; Scott, Diane; Fröbisch, Nadia B.; Sumida, Stuart S. (2008). "A stem batrachian from the Early Permian of Texas and the origin of frogs and salamanders". Nature. 453 (7194): 515–518. Bibcode:2008Natur.453..515A. doi:10.1038/nature06865. PMID 18497824.
  29. Marjanović, D.; Laurin, M. (2009). "The origin(s) of modern amphibians: a commentary". Evolutionary Biology. 36 (3): 336–338. doi:10.1007/s11692-009-9065-8.
  30. Cannatella, David (1995). "Triadobatrachus massinoti". Tree of Life. Retrieved 2008-06-26.
  31. Roček, Z. (2000). "14. Mesozoic Amphibians" (PDF). In Heatwole, H.; Carroll, R. L. (eds.). Amphibian Biology: Paleontology: The Evolutionary History of Amphibians. 4. Surrey Beatty & Sons. pp. 1295–1331. ISBN 978-0-949324-87-0.
  32. Weishampel, D. B.; Dodson, P.; Osmólska, H., eds. (2004). Dinosaur distribution (Early Jurassic, North America): The Dinosauria (2nd edition). University of California Press. pp. 530–532. ISBN 978-0-520-24209-8.
  33. Shubin, N. H.; Jenkins, F. A. Jr (1995). "An Early Jurassic jumping frog". Nature. 377 (6544): 49–52. Bibcode:1995Natur.377...49S. doi:10.1038/377049a0.
  34. Foster, J. (2007). "Anura (Frogs)". Jurassic west: the dinosaurs of the Morrison Formation and their world. Indiana University Press. pp. 135–136. ISBN 978-0-253-34870-8.
  35. Wilson, A. C.; Sarich, V. M.; Maxson, L. R. (1974). "The importance of gene rearrangement in evolution: evidence from studies on rates of chromosomal, protein, and anatomical evolution" (PDF). Proceedings of the National Academy of Sciences. 71 (8): 3028–3030. Bibcode:1974PNAS...71.3028W. doi:10.1073/pnas.71.8.3028. PMC 388613. PMID 4528784.
  36. "Frog evolution linked to dinosaur asteroid strike". BBC News. 3 July 2017. Retrieved 3 July 2017.
  37. Feng, Yan-Jie; Blackburn, David C.; Liang, Dan; Hillis, David M.; Wake, David B.; Cannatella, David C.; Zhang, Peng (2017). "Phylogenomics reveals rapid, simultaneous diversification of three major clades of Gondwanan frogs at the Cretaceous–Paleogene boundary". Proceedings of the National Academy of Sciences of the United States of America. 114 (29): E5864–E5870. doi:10.1073/pnas.1704632114. PMC 5530686. PMID 28673970.
  38. Evans, S. E.; Jones, M. E. H.; Krause, D. W. (2008). "A giant frog with South American affinities from the Late Cretaceous of Madagascar". Proceedings of the National Academy of Sciences. 105 (8): 2951–2956. Bibcode:2008PNAS..105.2951E. doi:10.1073/pnas.0707599105. PMC 2268566. PMID 18287076.
  39. Mörs, Thomas; Reguero, Marcelo; Vasilyan, Davit (2020). "First fossil frog from Antarctica: implications for Eocene high latitude climate conditions and Gondwanan cosmopolitanism of Australobatrachia". Scientific Reports. 10 (1). doi:10.1038/s41598-020-61973-5.
  40. Joel, Lucas (2020-04-23). "Fossil Shows Cold-Blooded Frogs Lived on Warm Antarctica". The New York Times. ISSN 0362-4331. Retrieved 2020-05-13.
  41. Frost, D. R.; Grant, T.; Faivovich, J. N.; Bain, R. H.; Haas, A.; Haddad, C. L. F. B.; De Sá, R. O.; Channing, A.; Wilkinson, M.; Donnellan, S. C.; Raxworthy, C. J.; Campbell, J. A.; Blotto, B. L.; Moler, P.; Drewes, R. C.; Nussbaum, R. A.; Lynch, J. D.; Green, D. M.; Wheeler, W. C. (2006). "The Amphibian Tree of Life". Bulletin of the American Museum of Natural History. 297: 1–291. doi:10.1206/0003-0090(2006)297[0001:TATOL]2.0.CO;2. hdl:2246/5781.
  42. Heinicke M. P.; Duellman, W. E.; Trueb, L.; Means, D. B.; MacCulloch, R. D.; Hedges, S. B. (2009). "A new frog family (Anura: Terrarana) from South America and an expanded direct-developing clade revealed by molecular phylogeny" (PDF). Zootaxa. 2211: 1–35. doi:10.11646/zootaxa.2211.1.1.
  43. R. Alexander Pyron; John J. Wiens (2011). "A large-scale phylogeny of Amphibia including over 2800 species, and a revised classification of extant frogs, salamanders, and caecilians". Molecular Phylogenetics and Evolution. 61 (2): 543–583. doi:10.1016/j.ympev.2011.06.012. PMID 21723399.
  44. Flam, F. (1995). "Finding earliest true frog will help paleontologists understand how frog evolved its jumping ability". Knight Ridder/Tribune News Service via HighBeam Research. Archived from the original on 2013-05-13. Retrieved 2012-06-10.
  45. Burton, Maurice (1972). The Observer's Book of British Wild Animals. Frederick Warne & Co. pp. 204–209. ISBN 978-0-7232-1503-5.
  46. Relyea, R. A. (2004). "The impact of insecticides and herbicides on the biodiversity and productivity of aquatic communities". Ecological Applications. 15 (2): 618–627. doi:10.1890/03-5342.
  47. Relyea, R.A. (2005). "The lethal impact of Roundup on aquatic and terrestrial amphibians". Ecological Applications. 15 (4): 1118–1124. doi:10.1890/04-1291.
  48. Hayes, T. B.; Collins, A.; Lee, M.; Mendoza, M.; Noriega, N.; Stuart, A. A.; Vonk, A. (2002). "Hermaphroditic, demasculinized frogs after exposure to the herbicide atrazine at low ecologically relevant doses". Proceedings of the National Academy of Sciences of the United States of America. 99 (8): 5476–5480. Bibcode:2002PNAS...99.5476H. doi:10.1073/pnas.082121499. PMC 122794. PMID 11960004.
  49. Johnson, P. T. J.; Chase, J. M.; Dosch, K. L.; Hartson, R. B.; Gross, J. A.; Larson, D. J.; Sutherland, D. R.; Carpenter, S. R. (2007). "Aquatic eutrophication promotes pathogenic infection in amphibians". Proceedings of the National Academy of Sciences of the United States of America. 104 (40): 15781–15786. Bibcode:2007PNAS..10415781J. doi:10.1073/pnas.0707763104. PMC 2000446. PMID 17893332.
  50. "Tiny frog claimed as world's smallest vertebrate". The Guardian. 2012-01-12. Retrieved 2012-09-28.
  51. Sabater-Pi, J. (1985). "Contribution to the biology of the Giant Frog (Conraua goliath, Boulenger)". Amphibia-Reptilia. 6 (1): 143–153. doi:10.1163/156853885x00047.
  52. Otero, R.A.; P. Jimenez-Huidobro; S. Soto-Acuña; R.E.Yury-Yáñez (2014). "Evidence of a giant helmeted frog (Australobatrachia, Calyptocephalellidae) from Eocene levels of the Magallanes Basin, southernmost Chile". Journal of South American Earth Sciences. 55: 133–140. doi:10.1016/j.jsames.2014.06.010.
  53. Levine, R. P.; Monroy, J. A.; Brainerd, E. L. (2004-03-15). "Contribution of eye retraction to swallowing performance in the northern leopard frog, Rana pipiens". Journal of Experimental Biology. 207 (Pt 8): 1361–1368. doi:10.1242/jeb.00885. PMID 15010487.
  54. Minott, Kevin (2010-05-15). "How frogs jump". National Geographic. Archived from the original on 2012-08-17. Retrieved 2012-06-10.
  55. Tesler, P. (1999). "The amazing adaptable frog". Exploratorium:: The museum of science, art and human perception. Retrieved 2012-06-04.
  56. Vincent, L. (2001). "Litoria caerulea" (PDF). James Cook University. Archived from the original (PDF) on 2004-04-22. Retrieved 2012-08-03.
  57. Emerson, S. B.; Diehl, D. (1980). "Toe pad morphology and mechanisms of sticking in frogs". Biological Journal of the Linnean Society. 13 (3): 199–216. doi:10.1111/j.1095-8312.1980.tb00082.x.
  58. Harvey, M. B.; Pemberton, A. J.; Smith, E. N. (2002). "New and poorly known parachuting frogs (Rhacophoridae : Rhacophorus) from Sumatra and Java". Herpetological Monographs. 16: 46–92. doi:10.1655/0733-1347(2002)016[0046:NAPKPF]2.0.CO;2.
  59. "Couch's spadefoot (Scaphiopus couchi)". Arizona-Sonora Desert Museum. Retrieved 2012-08-03.
  60. Walker, M. (2009-06-25). "Legless frogs mystery solved". BBC News.
  61. Stebbins, Robert C.; Cohen, Nathan W. (1995). A Natural History of Amphibians. Princeton University Press. pp. 10–14. ISBN 978-0-691-03281-8.
  62. Frost, S. W. (1932). "Notes on feeding and molting in frogs". The American Naturalist. 66 (707): 530–540. doi:10.1086/280458. JSTOR 2456779.
  63. Badger, D.; Netherton, J. (1995). Frogs. Airlife Publishing. p. 27. ISBN 978-1-85310-740-5.
  64. Smyth, H. R. (1962). Amphibians and Their Ways. Macmillan. ISBN 978-0-02-612190-3.
  65. Dickerson, M. C. (1969). The Frog Book: North American Frogs and Toads. Dover Publications. ISBN 978-0-486-21973-8.
  66. Blackburn, D. C. (2002-11-14). "Trichobatrachus robustus". AmphibiaWeb. Retrieved 2012-08-18.
  67. Ruibal, Rodolfo; Shoemaker, Vaughan (1985). "Osteoderms in Anurans". Journal of Herpetology. 18 (3): 313–328. doi:10.2307/1564085. JSTOR 1564085.
  68. Vitt, Laurie J.; Caldwell, Janalee P. (2013). Herpetology: An Introductory Biology of Amphibians and Reptiles. Academic Press. p. 50. ISBN 9780123869203.
  69. Jared, C.; Antoniazzi, M. M.; Navas, C. A.; Katchburian, E.; Freymüller, E.; Tambourgi, D. V.; Rodrigues, M. T. (2005). "Head co-ossification, phragmosis and defence in the casque-headed tree frog Corythomantis greeningi". Journal of Zoology. 265 (1): 1–8. doi:10.1017/S0952836904005953.
  70. Wente, W. H.; Phillips, J. B. (2003). "Fixed green and brown color morphs and a novel color‐changing morph of the Pacific tree frog Hyla regilla". The American Naturalist. 162 (4): 461–473. doi:10.1086/378253. JSTOR 10.1086/378253. PMID 14582008.
  71. Guayasamin, Juan M.; Krynak, Tim; Krynak, Katherine; Culebras, Jaime; Hutter, Carl R. (2015). "Phenotypic plasticity raises questions for taxonomically important traits: a remarkable new Andean rainfrog ( Pristimantis ) with the ability to change skin texture: Phenotypic plasticity in Andean rainfrog". Zoological Journal of the Linnean Society. 173 (4): 913–928. doi:10.1111/zoj.12222.
  72. Kimball, John (2010). "Vertebrate Lungs: Frog Lungs". Kimball's Biology Pages. Archived from the original on 2012-08-19. Retrieved 2012-07-09.
  73. Boisvert, Adam (2007-10-23). "Barbourula kalimantanensis". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-07-09.
  74. Kimball, John (2010). "Animal Circulatory Systems: Three Chambers: The Frog and Lizard". Kimball's Biology Pages. Retrieved 2012-07-09.
  75. Lee, Deborah (2010-04-23). "Telmatobius culeus". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-07-09.
  76. "Frog Digestive System". TutorVista.com. 2010. Retrieved 2012-08-04.
  77. "Greek heroic deity Prometheus now has a namesake in a new tiny rain frog from Ecuador". ScienceDaily. Retrieved 2019-11-19.
  78. Dorit, R. L.; Walker, W. F.; Barnes, R. D. (1991). Zoology. Saunders College Publishing. p. 849. ISBN 978-0-03-030504-7.
  79. "Frog's internal systems". TutorVista.com. 2010. Retrieved 2012-06-04.
  80. Duellman, W. E. and L. Trueb (1986). Biology of Amphibians. New York: McGraw-Hill Publishing Company.
  81. Sever, David M.; Staub, Nancy L. "Hormones, sex accessory structures, and secondary sexual characteristics in amphibians" (PDF). Hormones and Reproduction of Vertebrates – Vol 2: Amphibians. pp. 83–98. Retrieved 2012-08-04.
  82. Laurin, Michel; Gauthier, Jacques A. (2012). "Amniota". Tree of Life Web Project. Retrieved 2012-08-04.
  83. Howard, Ian, P.; Rogers, Brian J. (1995). Binocular Vision and Stereopsis. Oxford University Press. p. 651. ISBN 978-0195084764.
  84. Badger, David; Netherton, John (1995). Frogs. Airlife Publishing Ltd. pp. 31–35. ISBN 978-1-85310-740-5.
  85. Muntz, W. R. A.; Scientific American Offprints (1964). Vision in frogs. W. H. Freeman. p. 10. ASIN B0006RENBO. OCLC 15304238.
  86. Kelber, Almut; Yovanovich, Carola; Olsson, Peter (2017-04-05). "Thresholds and noise limitations of colour vision in dim light". Philosophical Transactions of the Royal Society B: Biological Sciences. 372 (1717): 20160065. doi:10.1098/rstb.2016.0065. ISSN 0962-8436. PMC 5312015. PMID 28193810.
  87. Badger, David; Netherton, John (1995). Frogs. Airlife Publishing. p. 38. ISBN 978-1-85310-740-5.
  88. Stebbins, Robert C.; Cohen, Nathan W. (1995). A Natural History of Amphibians. Princeton University Press. pp. 67–69. ISBN 978-0-691-03281-8.
  89. Armstrong, Cecilia E.; Roberts, William M. (1998). "Electrical properties of frog saccular hair cells: distortion by enzymatic dissociation". Journal of Neuroscience. 18 (8): 2962–2973. doi:10.1523/JNEUROSCI.18-08-02962.1998. PMID 9526013.
  90. "Bullfrog". Ohio Department of Natural Resources. Retrieved 2012-06-19.
  91. Tan, W.-H.; Tsai, C.-G.; Lin, C.; Lin, Y. K. (2014-06-05). "Urban canyon effect: storm drains enhance call characteristics of the Mientien tree frog". Journal of Zoology. 294 (2): 77–84. doi:10.1111/jzo.12154. ISSN 0952-8369.
  92. Nafis, Gary (2012). "Ascaphus truei: Coastal Tailed Frog". California Herps. Retrieved 2012-06-19.
  93. Roy, Debjani (1997). "Communication signals and sexual selection in amphibians" (PDF). Current Science. 72: 923–927. Archived from the original (PDF) on 2012-09-23.
  94. Gerhardt, H. C. (1994). "The evolution of vocalization in frogs and toads". Annual Review of Ecology and Systematics. 25: 293–324. doi:10.1146/annurev.es.25.110194.001453.
  95. Badger, David; Netherton, John (1995). Frogs. Airlife Publishing Ltd. pp. 39–44. ISBN 978-1-85310-740-5.
  96. Hilton, Bill Jr. (1986). Jug-o-Rum: Call of the Amorous Bullfrog. The Piedmont Naturalist. 1. Hilton Pond Center for Piedmont Natural History.
  97. Nash, Pat (February 2005). "The RRRRRRRRiveting Life of Tree Frogs". Archived from the original on 2012-03-09. Retrieved 2012-08-04.
  98. Aristophanes. "The Frogs". Archived from the original on 2012-05-13. Retrieved 2012-06-19.
  99. Suthers, R.A.; Narins, P.M.; Lin, W; Schnitzler, H; Denzinger, A; Xu, C; Feng, A.S. (2006). "Voices of the dead: complex nonlinear vocal signals from the larynx of an ultrasonic frog". Journal of Experimental Biology. 209 (24): 4984–4993. doi:10.1242/jeb.02594.CS1 maint: multiple names: authors list (link)
  100. Emmer, Rick (1997-11-24). "How do frogs survive winter? Why don't they freeze to death?". Scientific American. Retrieved 2012-06-15.
  101. Kayes, Sara M.; Cramp, Rebecca L.; Franklin, Craig E. (2009). "Metabolic depression during aestivation in Cyclorana alboguttata". Comparative Biochemistry and Physiology – Part A: Molecular & Integrative Physiology. 154 (4): 557–563. doi:10.1016/j.cbpa.2009.09.001. PMID 19737622.
  102. Hudson, N. J.; Lehnert, S. A.; Ingham, A. B.; Symonds, B.; Franklin, C. E.; Harper, G. S. (2005). "Lessons from an estivating frog: sparing muscle protein despite starvation and disuse". AJP: Regulatory, Integrative and Comparative Physiology. 290 (3): R836–R843. doi:10.1152/ajpregu.00380.2005. PMID 16239372.
  103. Wilmer, Pat (2009). Environmental Physiology of Animals. Wiley. pp. 188. ISBN 9781405107242.
  104. "Top 10 best jumper animals". Scienceray. Archived from the original on 2012-08-10. Retrieved 2012-06-11.
  105. James, R. S.; Wilson, R. S. (2008). "Explosive jumping: extreme morphological and physiological specializations of Australian rocket frogs (Litoria nasuta)" (PDF). Physiological and Biochemical Zoology. 81 (2): 176–185. doi:10.1086/525290. PMID 18190283.
  106. Nauwelaerts, S.; Schollier, J.; Aerts, P. (2004). "A functional analysis of how frogs jump out of water". Biological Journal of the Linnean Society. 83 (3): 413–420. doi:10.1111/j.1095-8312.2004.00403.x.
  107. Badger, David; Netherton, John (1995). Frogs. Airlife Publishing. p. 51. ISBN 978-1-85310-740-5.
  108. Astley, H. C.; Roberts, T. J. (2011). "Evidence for a vertebrate catapult: elastic energy storage in the plantaris tendon during frog jumping". Biology Letters. 8 (3): 386–389. doi:10.1098/rsbl.2011.0982. PMC 3367733. PMID 22090204.
  109. Scott, J. (2005). "The locust jump: an integrated laboratory investigation". Advances in Physiology Education. 29 (1): 21–26. doi:10.1152/advan.00037.2004. PMID 15718379.
  110. Zug, George R.; Duellman, William E. (2014-05-14). "Anura". Encyclopædia Britannica Online. Retrieved 2015-04-26.
  111. Fitch, H. S. (1956). "An ecological study of the collared lizard (Crotaphytus collaris)". University of Kansas Publications. 8: 213–274.
  112. Walton, M.; Anderson, B. D. (1988). "The aerobic cost of saltatory locomotion in the fowler's toad (Bufo woodhousei fowleri)". Journal of Experimental Biology. 136 (1): 273–288. PMID 3404074.
  113. Ahn, A. N.; Furrow, E.; Biewener, A. A. (2004). "Walking and running in the red-legged running frog, Kassina maculata". Journal of Experimental Biology. 207 (Pt 3): 399–410. doi:10.1242/jeb.00761. PMID 14691087.
  114. Pickersgill, M.; Schiøtz, A.; Howell, K.; Minter, L. (2004). "Kassina maculata". IUCN Red List of Threatened Species. 2004. Retrieved 2012-06-11.
  115. "Pipidae". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-06-14.
  116. Duellman, W. E.; Zug, G. R. "Anura: From tadpole to adult". Encyclopædia Britannica. Retrieved 2012-07-13.
  117. Radhakrishnan, C.; Gopi, K. C. (2007). "Extension of range of distribution of Nasikabatrachus sahyadrensis Biju & Bossuyt ( Amphibia : Anura : Nasikabatrachidae ) along Western Ghats, with some insights into its bionomics" (PDF). Current Science. 92 (2): 213–216. ISSN 0011-3891.
  118. Farrar, Eugenia; Hey, Jane. "Spea bombifrons". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-06-16.
  119. "Scaphiopodidae". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-06-16.
  120. Roberts, Dale; Hero, Jean-Marc (2011). "Heleioporus albopunctatus". IUCN Red List of Threatened Species. 2011. Retrieved 2012-06-16.
  121. Staniszewski, Marc (1998-09-30). "Madagascan Burrowing Frogs: Genus: Scaphiophryne (Boulenger, 1882)". Retrieved 2012-06-16.
  122. Venesci, M; Raxworthy, C. J.; Nussbaum, R. A.; Glaw, F. (2003). "A revision of the Scaphiophryne marmorata complex of marbled toads from Madagascar, including the description of a new species" (PDF). Herpetological Journal. 13: 69–79.
  123. Federle, W.; Barnes, W. J. P.; Baumgartner, W.; Drechsler, P.; Smith, J. M. (2006). "Wet but not slippery: boundary friction in tree frog adhesive toe pads". Journal of the Royal Society Interface. 3 (10): 689–697. doi:10.1098/rsif.2006.0135. PMC 1664653. PMID 16971337.
  124. Cochran, Doris Mabel (1961). Living Amphibians of the World. Doubleday. p. 112. ISBN 978-0-241-90338-4.
  125. "Phyllomedusa ayeaye". AmphibiaWeb. Retrieved 2012-06-14.
  126. Emerson, Sharon B.; Koehl, M. A. R. (1990). "The interaction of behavioral and morphological change in the evolution of a novel locomotor type: "flying frogs". Evolution. 44 (8): 1931–1946. doi:10.2307/2409604. JSTOR 2409604. PMID 28564439.
  127. Shah, Sunny; Tiwari, Rachna (2001-11-29). "Rhacophorus nigropalmatus". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-06-11.
  128. "Wallace's Flying Frog Rhacophorus nigropalmatus". National Geographic: Animals. 2010-09-10. Retrieved 2012-06-05.
  129. Stebbins, Robert C.; Cohen, Nathan W. (1995). A Natural History of Amphibians. Princeton University Press. pp. 154–162. ISBN 978-0-691-03281-8.
  130. Davies, N. B.; Halliday, T. R. (1978). "Deep croaks and fighting assessment in toads Bufo bufo". Nature. 274 (5672): 683–685. Bibcode:1978Natur.274..683D. doi:10.1038/274683a0.
  131. Long, David R. (1989). "Energetics and reproduction in female Scaphiopus multiplicatus from Western Texas". Journal of Herpetology. 23 (2): 176–179. doi:10.2307/1564026. JSTOR 1564026.
  132. Iskandar, D. T.; Evans, B. J.; McGuire, J. A. (2014). "A Novel Reproductive Mode in Frogs: A New Species of Fanged Frog with Internal Fertilization and Birth of Tadpoles". PLoS ONE. 9 (12): e115884. Bibcode:2014PLoSO...9k5884I. doi:10.1371/journal.pone.0115884. PMC 4281041. PMID 25551466.
  133. Channing, Alan; Howell, Kim M. (2006). Amphibians of East Africa. Comstock Publishing. pp. 104–117. ISBN 978-0-8014-4374-9.
  134. Sandberger, L.; Hillers, A.; Doumbia, J.; Loua, N-S.; Brede C.; Rödel, M-O. (2010). "Rediscovery of the Liberian Nimba toad, Nimbaphrynoides liberiensis (Xavier, 1978) (Amphibia: Anura: Bufonidae), and reassessment of its taxonomic status" (PDF). Zootaxa. 4355: 56–68. doi:10.11646/zootaxa.2355.1.3. ISSN 1175-5334.
  135. Gilbert, Perry W. (1942). "Observations on the eggs of Ambystoma maculatum with especial reference to the green algae found within the egg envelopes". Ecology. 23 (2): 215–227. doi:10.2307/1931088. JSTOR 1931088.
  136. Waldman, Bruce; Ryan, Michael J. (1983). "Thermal advantages of communal egg mass deposition in wood frogs (Rana sylvatica)". Journal of Herpetology. 17 (1): 70–72. doi:10.2307/1563783. JSTOR 1563783.
  137. Estrada, Alberto R.; Hedges, S. Blair (1996). "At the lower size limit in tetrapods: a new diminutive frog from Cuba (Leptodactylidae: Eleutherodactylus)". Copeia. 1996 (4): 852–859. doi:10.2307/1447647. JSTOR 1447647.
  138. Whittaker, Kellie; Chantasirivisal, Peera (2005-12-02). "Leptodactylus pentadactylus". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-07-19.
  139. Whittaker, Kellie (2007-06-27). "Agalychnis callidryas". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-07-19.
  140. Warkentin, K.M. (1995). "Adaptive plasticity in hatching age: a response to predation risk trade-offs". Proceedings of the National Academy of Sciences. 92 (8): 3507–3510. Bibcode:1995PNAS...92.3507W. doi:10.1073/pnas.92.8.3507. PMC 42196. PMID 11607529.
  141. Stebbins, Robert C.; Cohen, Nathan W. (1995). A Natural History of Amphibians. Princeton University Press. pp. 179–194. ISBN 978-0-691-03281-8.
  142. Wickramasinghe, Deepthi D.; Oseen, Kerri L.; Wassersug, Richard J. (2007). "Ontogenetic Changes in Diet and Intestinal Morphology in Semi-Terrestrial Tadpoles of Nannophrys ceylonensis (Dicroglossidae)". Copeia. 2007 (4): 1012–1018. doi:10.1643/0045-8511(2007)7[1012:ocidai]2.0.co;2. JSTOR 25140719.
  143. Janzen, Peter (2005-05-10). "Nannophrys ceylonensis". AmphibiaWeb. University of California, Berkeley. Retrieved 2012-07-20.
  144. Hoff, K. vS.; Wassersug, R. J. (1 February 2000). "Tadpole Locomotion: Axial Movement and Tail Functions in a Largely Vertebraeless Vertebrate". Integrative and Comparative Biology. 40 (1): 62–76. doi:10.1093/icb/40.1.62.
  145. Crump, Martha L. (1986). "Cannibalism by younger tadpoles: another hazard of metamorphosis". Copeia. 1986 (4): 1007–1009. doi:10.2307/1445301. JSTOR 1445301.
  146. Stebbins, Robert C.; Cohen, Nathan W. (1995). A Natural History of Amphibians. Princeton University Press. pp. 173–175. ISBN 978-0-691-03281-8.
  147. Balinsky, Boris Ivan. "Animal development: Metamorphosis". Encyclopædia Britannica. Retrieved 2012-08-10.
  148. Da Silva, H. R.; De Britto-Pereira, X. C. (2006). "How much fruit do fruit-eating frogs eat? An investigation on the diet of Xenohyla truncata (Lissamphibia: Anura: Hylidae)". Journal of Zoology. 270 (4): 692–698. doi:10.1111/j.1469-7998.2006.00192.x.
  149. "Diet of the Neotropical frog Leptodactylus mystaceus" (PDF).
  150. Camera, Bruno F.; Krinski, Diones; Calvo, Isabella A. (2014-02-04). "Diet of the Neotropical frog Leptodactylus mystaceus (Anura: Leptodactylidae)" (PDF). Herpetology Notes. 7: 31–36. Retrieved 2015-04-26.
  151. Das, I. (April 1996). "Folivory and seasonal changes in diet in Rana hexadactyla (Anura: Ranidae)". Journal of Zoology. 238 (4): 785–794. doi:10.1111/j.1469-7998.1996.tb05430.x.
  152. Graham, Donna. "Northern leopard frog (Rana pipiens)". An Educator's Guide to South Dakota's Natural Resources. Archived from the original on 2012-10-17. Retrieved 2012-08-04.
  153. Pimm, Stuart L. (1979). "The structure of food webs" (PDF). Theoretical Population Biology. 16 (2): 144–158. doi:10.1016/0040-5809(79)90010-8. PMID 538731. Archived from the original (PDF) on September 27, 2011.
  154. Matthews, K. R.; Miaud, C. (2007). "A skeletochronological study of the age structure, growth, and longevity of the mountain yellow-legged frog, Rana muscosa, in the Sierra Nevada, California". Copeia. 2007 (4): 986–993. doi:10.1643/0045-8511(2007)7[986:ASSOTA]2.0.CO;2. ISSN 0045-8511.(subscription required)
  155. Slavens, Frank; Slavens, Kate. "Frog and toad index". Longevity. Archived from the original on 2012-08-18. Retrieved 2012-07-04.
  156. Storey, KB (1990). "Life in a frozen state: adaptive strategies for natural freeze tolerance in amphibians and reptiles". American Journal of Physiology. 258 (3 Pt 2): 559–568. doi:10.1152/ajpregu.1990.258.3.R559. PMID 2180324.
  157. Crump, M. L. (1996). "Parental care among the Amphibia". Parental Care: Evolution, Mechanisms, and Adaptive Significance. Advances in the Study of Behavior. 25. pp. 109–144. doi:10.1016/S0065-3454(08)60331-9. ISBN 978-0-12-004525-9.
  158. Brown, J. L.; Morales, V.; Summers, K. (2010). "A key ecological trait drove the evolution of biparental care and monogamy in an amphibian". American Naturalist. 175 (4): 436–446. doi:10.1086/650727. PMID 20180700.
  159. Sheridan, Jennifer A.; Ocock, Joanne F. (2008). "Parental care in Chiromantis hansenae (Anura: Rhacophoridae)". Copeia. 2008 (4): 733–736. doi:10.1643/CH-07-225.
  160. Brown, J. L.; Morales, V.; Summers, K. (2008a). "Divergence in parental care, habitat selection and larval life history between two species of Peruvian poison frogs: An experimental analysis". Journal of Evolutionary Biology. 21 (6): 1534–1543. doi:10.1111/j.1420-9101.2008.01609.x. PMID 18811668.
  161. Grant, T.; Frost, D. R.; Caldwell, J. P.; Gagliardo, R.; Haddad, C. F. B.; Kok, P. J. R.; Means, D. B.; Noonan, B. P.; Schargel, W. E.; Wheeler, W. (2006). "Phylogenetic systematics of dart-poison frogs and their relatives (Amphibia, Athesphatanura, Dendrobatidae)" (PDF). Bulletin of the American Museum of Natural History. 299: 1–262. CiteSeerX 10.1.1.693.8392. doi:10.1206/0003-0090(2006)299[1:PSODFA]2.0.CO;2. hdl:2246/5803. ISSN 0003-0090. Archived from the original (PDF) on 2016-04-04. Retrieved 2017-11-13.
  162. van Wijngaarden, René; Bolaños, Federico (1992). "Parental care in Dendrobates granuliferus (Anura: Dendrobatidae), with a description of the tadpole". Journal of Herpetology. 26 (1): 102–105. doi:10.2307/1565037. JSTOR 1565037.
  163. Fandiño, María Claudia; Lüddecke, Horst; Amézquita, Adolfo (1997). "Vocalisation and larval transportation of male Colostethus subpunctatus (Anura: Dendrobatidae)". Amphibia-Reptilia. 18 (1): 39–48. doi:10.1163/156853897X00297.
  164. "Common midwife toad, Alytes obstetricans". Repties et Amphibiens de France. Retrieved 2012-07-30.
  165. "Proteins of frog foam nests". University of Glasgow. Retrieved 2012-08-24.
  166. Dalgetty, Laura; Kennedy, Malcolm W. (2010). "Building a home from foam—túngara frog foam nest architecture and three-phase construction process". Biology Letters. 6 (3): 293–296. doi:10.1098/rsbl.2009.0934. PMC 2880057. PMID 20106853.
  167. "Assa darlingtoni". Frogs Australia Network. 2005. Retrieved 2012-08-05.
  168. Semeyn, E. (2002). "Rheobatrachus silus". Animal Diversity Web. University of Michigan Museum of Zoology. Retrieved 2012-08-05.
  169. Sandmeier, Fran (2001-03-12). "Rhinoderma darwinii". AmphibiaWeb. Retrieved 2012-08-05.
  170. Barthalmus, George T.; Zielinski, William J. (1988). "Xenopus skin mucus induces oral dyskinesias that promote escape from snakes". Pharmacology Biochemistry and Behavior. 30 (4): 957–959. doi:10.1016/0091-3057(88)90126-8. PMID 3227042.
  171. Darst, Catherine R.; Cummings, Molly E. (2006). "Predator learning favours mimicry of a less-toxic model in poison frogs". Nature. 440 (7081): 208–211. Bibcode:2006Natur.440..208D. doi:10.1038/nature04297. PMID 16525472.
  172. Myers, C. W.; Daly, J. W. (1983). "Dart-poison frogs". Scientific American. 248 (2): 120–133. Bibcode:1983SciAm.248b.120M. doi:10.1038/scientificamerican0283-120. PMID 6836257.
  173. Savage, J. M. (2002). The Amphibians and Reptiles of Costa Rica. University of Chicago Press. ISBN 978-0-916984-16-8.
  174. Duellman, W. E. (1978). "The Biology of an Equatorial Herpetofauna in Amazonian Ecuador" (PDF). University of Kansas Museum of Natural History Miscellaneous Publication. 65. Archived from the original (PDF) on July 4, 2011.
  175. Saporito, R.A.; Garraffo, H. M.; Donnelly, M. A.; Edwards, A. L.; Longino, J. T.; Daly, J. W. (2004). "Formicine ants: an arthropod source for the pumiliotoxin alkaloids of dendrobatid poison frogs". Proceedings of the National Academy of Sciences. 101 (21): 8045–8050. Bibcode:2004PNAS..101.8045S. doi:10.1073/pnas.0402365101. PMC 419554. PMID 15128938.
  176. Smith, B. P.; Tyler, M. J.; Kaneko, T.; Garraffo, H. M.; Spande, T. F.; Daly, J. W. (2002). "Evidence for biosynthesis of pseudophrynamine alkaloids by an Australian myobatrachid frog (Pseudophryne) and for sequestration of dietary pumiliotoxins". Journal of Natural Products. 65 (4): 439–47. doi:10.1021/np010506a. PMID 11975476.
  177. Grant, T. "Poison Dart Frog Vivarium". American Museum of Natural History. Retrieved 2012-07-07.
  178. Arnold, Nicholas; Ovenden, Denys (2002). Reptiles and Amphibians of Britain and Europe. Harper Collins Publishers. pp. 73–74. ISBN 978-0-00-219964-3.
  179. Hayes, Floyd E. (1989). "Antipredator behavior of recently metamorphosed toads (Bufo a. americanus) during encounters with garter snakes (Thamnophis s. sirtalis)". Copeia. 1989 (4): 1011–1015. doi:10.2307/1445987. JSTOR 1445987.
  180. "Freaky Frogs". National Geographic Explorer. Retrieved 2012-07-13.
  181. Ferrell, Vance (2012-03-04). "Geographical Distribution". Evolution Encyclopedia. 3. Evolution Facts. Retrieved 2012-07-13.
  182. Ryan, Paddy (2011-09-25). "Story: Frogs". The Encyclopedia of New Zealand. Retrieved 2012-08-20.
  183. Dahl, Chris; Novotny, Vojtech; Moravec, Jiri; Richards, Stephen J. (2009). "Beta diversity of frogs in the forests of New Guinea, Amazonia and Europe: contrasting tropical and temperate communities". Journal of Biogeography. 36 (5): 896–904. doi:10.1111/j.1365-2699.2008.02042.x.
  184. "Cyclorana platycephala". Frogs Australia Network. 2005-02-23. Retrieved 2012-07-20.
  185. Hoekstra, J. M.; Molnar, J. L.; Jennings, M.; Revenga, C.; Spalding, M. D.; Boucher, T. M.; Robertson, J. C.; Heibel, T. J.; Ellison, K. (2010). "Number of Globally Threatened Amphibian Species by Freshwater Ecoregion". The Atlas of Global Conservation: Changes, Challenges, and Opportunities to Make a Difference. The Nature Conservancy. Retrieved 2012-09-05.
  186. Stuart, S. N.; Chanson, J. S.; Cox, N. A.; Young, B. E.; Rodrigues, A. S. L.; Fischman, D. L.; Waller, R. W. (2004). "Status and trends of amphibian declines and extinctions worldwide" (PDF). Science. 306 (5702): 1783–1786. Bibcode:2004Sci...306.1783S. CiteSeerX 10.1.1.225.9620. doi:10.1126/science.1103538. PMID 15486254. Archived from the original (PDF) on 2017-10-27. Retrieved 2017-10-27.
  187. Pounds, J. Alan; Fogden, Michael P. L.; Savage, Jay M.; Gorman, George C. (1997). "Tests of null models for amphibian declines on a tropical mountain". Conservation Biology. 11 (6): 1307–1322. doi:10.1046/j.1523-1739.1997.95485.x.
  188. "Worldwide Amphibian Declines: How big is the problem, what are the causes and what can be done?". AmphibiaWeb. 2009-01-22. Retrieved 2012-10-15.
  189. "Frog population decrease mostly due to traffic". New Scientist. 2006-07-07. Retrieved 2012-07-13.
  190. Voordouw, M. J.; Adama, D.; Houston, B.; Govindarajulu, P. (2010). "Prevalence of the pathogenic chytrid fungus, Batrachochytrium dendrobatidis, in an endangered population of northern leopard frogs, Rana Pipiens". BMC Ecology. 10 (6): 6. doi:10.1186/1472-6785-10-6. PMC 2846871. PMID 20202208.
  191. Harp, Elizabeth M.; Petranka, James W. (2006). "Ranavirus in wood frogs (Rana sylvatica): Potential sources of transmission within and between ponds". Journal of Wildlife Diseases. 42 (2): 307–318. doi:10.7589/0090-3558-42.2.307. PMID 16870853.
  192. Phillips, Kathryn (1994). Tracking the Vanishing Frogs. Penguin Books. ISBN 978-0-14-024646-9.
  193. Lips, Karen R. (2008). "Decline of a tropical montane amphibian fauna". Conservation Biology. 12 (1): 106–117. doi:10.1111/j.1523-1739.1998.96359.x. JSTOR 2387466.
  194. Blaustein, Andrew R.; Johnson, Pieter T. J. (2003). "The complexity of deformed amphibians" (PDF). Frontiers in Ecology and the Environment. 1 (2): 87–94. doi:10.1890/1540-9295(2003)001[0087:TCODA]2.0.CO;2. Archived from the original (PDF) on 2013-10-29.
  195. Burkhart, J. G.; Ankley, G.; Bell, H.; Carpenter, H.; Fort, D.; Gardiner, D.; Gardner, H.; Hale, R.; Helgen, J. C.; Jepson, P.; Johnson, D.; Lannoo, M.; Lee, D.; Lary, J.; Levey, R.; Magner, J.; Meteyer, C.; Shelby, M. D.; Lucier, G. (2000). "Strategies for assessing the implications of malformed frogs for environmental health". Environmental Health Perspectives. 108 (1): 83–90. doi:10.2307/3454299. JSTOR 3454299. PMC 1637865. PMID 10620528.
  196. Black, Richard (2005-10-02). "New frog centre for London Zoo". BBC News. Retrieved 2008-11-03.
  197. "National recovery plan for the Southern Corroboree Frog (Pseudophryne corroboree): 5. Previous recovery actions". Environment.gov.au. Archived from the original on 2008-05-12. Retrieved 2008-11-03.
  198. "2008: Year of the Frog". 2008-01-15. Archived from the original on 2012-10-17. Retrieved 2012-07-13.
  199. Tyler, Michael J. (1989). Australian Frogs. Penguin Books. p. 111. ISBN 978-0-670-90123-4.
  200. Cameron, Elizabeth (2012-09-06). "Cane toad". Australian Museum. Retrieved 2012-09-12.
  201. ̺Brahic, Catherine (January 20, 2009). "Appetite For Frogs' Legs Harming Wild Populations". abc news.
  202. Warkentin, I. G.; Bickford, D.; Sodhi, N. S.; Corey, J. A. (2009). "Eating frogs to extinction". Conservation Biology. 23 (4): 1056–1059. doi:10.1111/j.1523-1739.2008.01165.x. PMID 19210303.
  203. "Cultured Aquatic Species Information Programme: Rana catesbeiana". FAO: Fisheries and Aquaculture Department. Retrieved 2012-07-05.
  204. Ryan Schuessler (January 28, 2016). "The Mountain Chicken Frog's First Problem: It Tastes Like..." National Geographic News.
  205. Mark Twain; Charles Dudley Warner (1904). The Writings of Mark Twain [pseud.].: A tramp abroad. Harper & Bros. p. 263.
  206. "California Schools Leading Race to Stop Dissections". Animal Welfare Institute. 2011-04-25. Retrieved 2012-06-17.
  207. Wells, David Ames (1859). The science of common things: a familiar explanation of the first principles of physical science. For schools, families, and young students. Ivison, Phinney, Blakeman. p. 290.
  208. "Stannius ligature". Biology online. 2005-10-03. Retrieved 2012-08-05.
  209. Sarkar, S. (1996). "Lancelot Hogben, 1895–1975". Genetics. 142 (3): 655–660. PMC 1207007. PMID 8849876.
  210. Brownlee, Christen. "Nuclear Transfer: Bringing in the Clones". Proceedings of the National Academy of Sciences of the United States of America. Archived from the original on 2012-10-14. Retrieved 2012-10-21.
  211. Browder, L.; Iten, L. (Eds.) (1998). "Xenopus as a Model System in Developmental Biology". Dynamic Development. University of Calgary. Retrieved 2012-06-17.CS1 maint: multiple names: authors list (link) CS1 maint: extra text: authors list (link)
  212. Klein, S. "Developing the potential of Xenopus tropicalis as a genetic model". Trans-NIH Xenopus Working Group. Retrieved 2006-03-09.
  213. "Genome List – Genome – NCBI". www.ncbi.nlm.nih.gov. Retrieved 2019-04-07.
  214. VanCompernolle, S. E.; Taylor, R. J.; Oswald-Richter, K.; Jiang, J.; Youree, B. E.; Bowie, J. H.; Tyler, M. J.; Conlon, M.; Wade, D.; et al. (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 (18): 11598–11606. doi:10.1128/JVI.79.18.11598-11606.2005. PMC 1212620. PMID 16140737.
  215. Phillipe, G.; Angenot, L. (2005). "Recent developments in the field of arrow and dart poisons". Journal of Ethnopharmacology. 100 (1–2): 85–91. doi:10.1016/j.jep.2005.05.022. PMID 15993556.
  216. Lyttle, T.; Goldstein, D.; Gartz, J. (1996). "Bufo toads and bufotenine: fact and fiction surrounding an alleged psychedelic". Journal of Psychoactive Drugs. 28 (3): 267–290. CiteSeerX 10.1.1.688.5926. doi:10.1080/02791072.1996.10472488. PMID 8895112.
  217. Lyttle, T. (1993). "Misuse and legend in the "toad licking" phenomenon". International Journal of Addictions. 28 (6): :521–538. doi:10.3109/10826089309039645. PMID 8486435.
  218. Myers, Charles W.; Daly, John W.; Malkin, Borys (1978). "A dangerously toxic new frog (Phyllobates) used by Emberá Indians of western Colombia, with discussion of blowgun fabrication and dart poisoning". Bulletin of the American Museum of Natural History. 161: 307–366. hdl:2246/1286.
  219. Ebert, Roger (2006-01-15). "Chuck Jones: Three Cartoons (1953–1957)". Chicago Sun-Times. Retrieved 2015-04-26.
  220. Brothers Grimm. "The Frog Prince". East of the Web. Retrieved 2012-06-30.
  221. "Walk of Fame, Kermit the Frog awarded with a star on the Hollywood Walk of Fame, December 1, 2002". Walkoffame.com. Retrieved 2012-06-30.
  222. Berrin, Katherine; Larco Museum (1997). The Spirit of Ancient Peru: Treasures from the Museo Arqueológico Rafael Larco Herrera. New York: Thames and Hudson. ISBN 978-0-500-01802-6.
  223. Gratwicke, B. (2009). "The Panamanian Golden Frog". Panama Amphibian Rescue and Conservation Project.

Further reading

  • Beltz, Ellin (2005). Frogs: Inside their Remarkable World. Firefly Books. ISBN 978-1-55297-869-6.
  • Cogger, H. G.; Zweifel, R. G.; Kirschner, D. (2004). "Encyclopedia of Reptiles and Amphibians". Encyclopedia of Reptiles & Amphibians (2nd ed.). Fog City Press. ISBN 978-1-877019-69-2.
  • 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.
  • Gissi, Carmela; San Mauro, Diego; Pesole, Graziano; Zardoya, Rafael (February 2006). "Mitochondrial phylogeny of Anura (Amphibia): A case study of congruent phylogenetic reconstruction using amino acid and nucleotide characters". Gene. 366 (2): 228–237. doi:10.1016/j.gene.2005.07.034. PMID 16307849.
  • Holman, J. A. (2004). Fossil Frogs and Toads of North America. Indiana University Press. ISBN 978-0-253-34280-5.
  • San Mauro, Diego; Vences, Miguel; Alcobendas, Marina; Zardoya, Rafael; Meyer, Axel (May 2005). "Initial diversification of living amphibians predated the breakup of Pangaea". American Naturalist. 165 (5): 590–599. doi:10.1086/429523. PMID 15795855.
  • Tyler, M. J. (1994). Australian Frogs A Natural History. Reed Books. ISBN 978-0-7301-0468-1.

Media


This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.