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Japanese fire-bellied newt

February 26, 2023

The Japanese fire-bellied newt or Japanese fire-bellied salamander (Cynops pyrrhogaster) is a species of newt endemic to Japan. The skin on its upper body is dark and its lower regions bright red, although coloration varies with age, genetics, and region. Adults are 8 to 15 cm (3.1 to 5.9 in) long. To deter predators, Japanese fire-bellied newts contain high levels of tetrodotoxin, a neurotoxin accumulated mainly from their diet.

Japanese fire-bellied newt
Temporal range: 13.75–0 Ma Middle MiocenePresent
Female Japanese fire-bellied newt
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Amphibia
Order: Urodela
Family: Salamandridae
Genus: Cynops
Species:
C. pyrrhogaster
Binomial name
Cynops pyrrhogaster
(Boie, 1826)
Synonyms[2]

Molge pyrrhogaster Boie, 1826

The species is found on many Japanese islands, including Honshu, Shikoku, and Kyushu. Their habitats include both natural and artificial bodies of water, as well as forests and grasslands. They breed from spring to the beginning of summer, both sexes producing pheromones when ready to mate. Eggs are laid separately, hatching after about three weeks. They grow from larval to juvenile form in between five and six months. Juveniles eat soil-dwelling prey, and adults eat a wide variety of insects, tadpoles, and the eggs of their own species. They have several adaptations to avoid predators, although which they use depends on where they live. Several aspects of their biology have been studied, including their ability to regrow missing body parts.

The Japanese fire-bellied newt first diverged from its closest relative in the Middle Miocene, before splitting into four distinct varieties, each with a mostly separate range, although all four are formally recognized as composing a single species. Currently, their population is declining, and they face threats from disease and the pet trade. They can be successfully kept in captivity.

Etymology and taxonomy

The species was first scientifically described by German zoologist Heinrich Boie in 1826 as Molge pyrrhogaster,[note 1] based on specimens brought from Japan to Europe. He compared it to the smooth newt, saying he would have mistaken the former for the latter, had he not known it was from Japan. None of the specimens he studied were fully mature.[3][4] Pyrrhogaster is derived from Greek, purrhos lit.'fire' and gastēr lit.'belly'.[5] Salamandra subcristata was described by Coenraad Jacob Temminck and Hermann Schlegel in 1838 and transferred to Cynops later that year by Swiss naturalist Johann Jakob von Tschudi,[6][2] and in 1850, Cynops subcristata and Molge pyrrhogaster were synomized as Cynops pyrrhogaster by the British zoologist John Edward Gray.[7][2] A study of mitochondrial DNA in 2001 indicated that its supposed fellow members of Cynops, C. cyanurus and C. wolterstorffi, may belong to a different genus.[8]

The Integrated Taxonomic Information System lists sixteen synonyms for Cynops pyrrhogaster.[9] Common names of the species include Japanese fire-bellied newt,[1] red-bellied newt,[10] and Japanese fire-bellied salamander.[11] Studies examining morphological and geographic variation had formerly recognized six races: Tohoku, Kanto, Atsumi, intermediate, Sasayama, and Hiroshima,[12] one of which, the Sasayama, was described as a subspecies in 1969 by Robert Mertens as Triturus pyrrhogaster sasayamae, which is now considered a synonym of C. pyrrhogaster.[2] Modern molecular analysis supports the division of C. pyrrhogaster into four clades instead.[12] In particular, the validity of the Sasayama and intermediate races has never been proven, with one study finding no behavioral differences between the two supposed forms.[13]

 
Illustration of various salamanders. Bottom right is C. pyrrhogaster.
Phylogenetic tree detail:[12]

Triturus species

Pachytriton species

Paramesotriton species

Chinese fire belly newt (C. orientalis)

Chuxiong fire-bellied newt (C. cyanurus)

Sword-tailed newt (C. ensicauda)

Japanese fire‑bellied newt

Northern clade

Central clade

Southern clade

Western clade

(C. pyrrhogaster)


Cynops pyrrhogaster diverged from its close relative C. ensicauda about 13.75 million years ago (during the Middle Miocene). The common ancestor of the two species would have lived in an area of the Eurasian mainland which is today the East China Sea and the central Ryukyu Islands. The land that would become the Japanese islands – connected to the mainland at that time – likely had a subtropical climate, which may have caused the Japanese fire-bellied newt's ancestors to migrate northward for desirable habitat. As time progressed, C. pyrrhogaster split into four clades: northern, southern, western, and central. The northern diverged first, at around 9.68 million years ago, then the central around 8.23 MYA (million years ago), then finally the southern and western around 4.05 MYA. The ranges of all but the southern clade declined during the Last Glacial Period, but expanded again afterwards. The study that identified them concluded that the four clades represent separate taxonomic units, although their exact relationship is unclear. It also noted their extreme genetic differences, unusually large for any one species.[12] The ranges of the central and western varieties meet in Chugoku in western Japan to form a hybrid zone (an area where the two clades interbreed to produce hybrids). The central type has begun to move west, which has caused the hybrid zone to shift. It is expected to eventually cause the genome of the western form to be diluted by increasing hybridization.[14]

Description

 
Japanese fire-bellied newt in a human hand

On the newt's upper body, the skin is dark brown, approaching black, and covered in wartlike bumps. The underbelly and the underside of its tail are bright red, with black spots.[4] Younger juveniles have creamy coloration instead of red, although most larger juveniles have some red present.[15] Adults from smaller islands tend to have more red on their ventral (belly) regions than those from larger islands, sometimes with extremely small spots or none at all. In general males tend to have more red than females.[16] Males can also be distinguished from females by their flat, wide tails and swelling around the ventral region.[17] An entirely red variant exists: that coloration is believed to be inherited and recessive. This variant is not confined to any single population, but is more common in the western half of Japan overall.[18]

The vomeropalatine teeth, a group of teeth in the upper back of the mouth, are arranged in two series. The tongue is relatively small, half the width of the mouth. The nostrils are positioned anteriorly (toward the head), closer to each other than to the eyes and hardly visible when viewed from above. The toes of males are longer than those of females, although the females themselves are longer. The tail is tightly compressed, with fins on both the top and bottom. A smooth ridge runs from their nape to their tail.[19] The full body length of adults is 8 to 15 cm (3.1 to 5.9 in).[11] Snout–vent length can be anywhere between 43.0 and 64.0 mm (1.69 and 2.52 in) for males and 48.5 and 75.0 mm (1.91 and 2.95 in) for females. Populations from more northern and elevated regions tend to be larger than those in southern and lower-altitude regions.[20] Eggs are 2.1 to 2.3 mm (0.083 to 0.091 in) long.[17]

Distribution and habitat

Cynops pyrrhogaster is endemic to Japan, being found on several islands in the archipelago, including Honshu, Shikoku, and Kyushu.[1] It mainly dwells on the larger islands, whereas its relative, C. ensicauda, is found in the Ryukyu Islands. It has the northernmost range of any Cynops species; all other species, besides the aforementioned C. ensicauda, are native to southern China.[12] There is also an introduced population on Hachijō-jima, believed to be descended from individuals from Shikoku. Their introduction is thought to have occurred in the 1970s, although exactly how it happened is unknown.[21] It has been recorded in the United States three times, in Florida and Massachusetts. Every instance was either an escape or deliberate release, and no populations have been established.[11]

Of the four clades, the northern is found in the districts of Tohoku and Kanto. This does not overlap with the range of the central clade, which is found in Chubu, northern Kansai, and eastern Chugoku. The central's range has a small amount of overlap with the western, which is found in southern Kinki, western Chugoku, Shikoku, and central Kyushu. The western also has some overlap with the southern clade, which is found in western and southern Kyushu.[12]

The newts occur at elevations of 30 to 2,020 m (98 to 6,627 ft). Ecosystems they are found in include forests, grasslands, shrublands, wetlands, lakes, marshes, and cultivated environments. They can also dwell in humanmade bodies of water, such as aquaculture ponds.[1]

Behavior and ecology

 
A pair of C. pyrrhogaster specimens

Reproduction and life cycle

Breeding occurs in paddy fields, ponds, brooks, pools, and streams. Females accept male courtship behavior from spring to early summer.[20] Males and females both produce peptide pheromones to attract the opposite sex when ready to mate. Males produce a type known as sodefrin (from the Japanese term sodefuri, lit.'soliciting');[22] females have their own variety, named imorin by its discoverers (from the Japanese term imo, lit.'beloved woman', and rin from sodefrin). These are released from the cloaca, and were the first peptide pheromone to be identified in a vertebrate and first to be identified in a female vertebrate, respectively.[10][23]

Courtship begins when the male approaches the female, sniffing its sides or cloaca. The male then brings its tail to the female and rapidly vibrates it. The female responds by pushing the male's neck with its snout. At this point, the male slowly moves away, undulating its tail, and the female follows, touching the tail with its snout when close enough. The male then deposits two to four spermatophores, one at a time, moving several centimeters after each, which the female attempts to pick up with its cloaca, sometimes unsuccessfully.[24] Females lay eggs separately on underwater objects, such as leaves and submerged grass roots, fertilized one by one from the spermatophores they carry. They can lay up to 40 eggs in one session, and 100 to 400 eggs in a breeding season.[24]

 
A newt, staring at the camera

The young hatch from their eggs after about three weeks, as swimming, gilled larvae, with dorsal tailfins. They grow around 3 cm (1.2 in) in the first three months of their lives. At between five and six months, they stop eating and undergo metamorphosis, losing their gills and fins, and becoming juveniles. Juveniles cannot remain submerged in water like larvae or they drown.[25][26] Newts at lower altitudes mature faster than those at higher ones. Male newts of higher-altitude populations tend to live longer after reaching maturity, but their fully grown size is not as large as that of lowland newts. Wild individuals as old as twenty-three have been found.[20]

Diet

In captive settings tadpoles are known to readily eat mosquito larvae, brine shrimp, and earthworms.[25] Juveniles often consume soil-dwelling Collembola (springtails) and Acari (mite) species.[15] Adults at one particular sub-alpine moor in the Azuma Mountains of Fukushima Prefecture were found to like both live prey and carrion. They consume many insect varieties, such as members of Odonata, which include dragonflies and damselflies, whose larvae have been found whole in newt stomachs, but only pieces of adults; Brachycera, a suborder of Diptera (flies); Hymenoptera, which include sawflies, wasps, bees, and ants; and Coleoptera (beetles). They also eat Rhacophorus arboreus tadpoles and the eggs of their own kind. The makeup of their diet varies seasonally and from year to year, suggesting changes in the small animals in and around the ponds that they dwell in.[17] Similar results were found at a pond on the campus of Tokyo Metropolitan University in Hachiōji, Tokyo, the newt stomachs containing insects from many different orders, and again, the eggs of conspecifics. Like before, frog tadpoles were eaten, although these belonged to the species Rhacophorus schlegelii.[27]

Predators

 
Japanese fire-bellied newt on its back, with the bright red ventral region clearly visible

Newts in Mainland Japan have different antipredator behavior than newts on smaller islands. Individuals on smaller islands (for instance, Fukue Island) generally use a maneuver called the unken reflex, where they expose their bright red underbelly to attackers. As their main predators are birds, which are capable of distinguishing the color red, this technique is effective. In Mainland Japan the newts must also avoid mammalian predators, which cannot distinguish colors as well as avian hunters. This leads these populations to use the maneuver less, as it can result in death if attempted.[16]

Against snakes, newts from Fukue Island tend to perform tail-wagging displays, designed to bring a predator's attention to their replaceable tail rather than their more valuable head; those from Nagasaki Prefecture in Mainland Japan tend to simply flee. Snakes are present in both areas. This is likely because those from the mainland are adapted to escape from mammalian hunters, which are less likely to be repelled by such a display.[28]

Toxin

Wild Japanese fire-bellied newts contain high levels of the neurotoxin tetrodotoxin (TTX).[29] This toxin inhibits the activity of sodium channels in most vertebrates, discouraging predation by both birds and mammals.[28] Experiments have shown the toxin is almost entirely derived from the newt's diet. When raised in captivity with no source of TTX, 36- to 70-week-old juveniles did not contain detectable levels, but wild specimens from the same original habitat had high toxicity. In younger captive-reared newts some TTX was still detected, which was inferred to have been transferred by adult females to their eggs.[29] In a follow-up experiment by the same team captive-reared newts were given food containing the neurotoxin. They readily consumed TTX-laced bloodworms when offered, not showing any symptoms after ingesting the poison. It was detectable in their bodies afterward, further indicating food to be the source of the toxin. No TTX-producing organisms are known from their habitat, but their existence is likely, and would explain the origin of TTX in wild newts.[30]

Conservation

 
Group at Ikenokouchi Wetland in Tsuruga, Fukui Prefecture

The International Union for the Conservation of Nature (IUCN) has ranked it as near-threatened. This assessment was made in 2020,[1] a shift from 2004 when it was rated least-concern.[31] It successfully reproduces in Australian zoos.[1] One major threat that C. pyrrhogaster faces is collection for the pet trade. The IUCN states that this trade needs to be ended immediately. Their population is decreasing, particularly near areas of human habitation.[1]

Japanese fire-bellied newts with mysterious skin lesions at Lake Biwa in Japan's Shiga Prefecture were found to be suffering from infections caused by a single-celled eukaryote in the order Dermocystida. The lesions contained cysts, which were filled with spores. Nearly all the lesions were external, although one was found on the liver. Globally, diseases are one of the causes for declining amphibian populations. There is concern that this affliction could spread to other nearby species, including Zhangixalus arboreus and Hynobius vandenburghi.[32]

A variety, believed to be found exclusively on the Atsumi Peninsula, was thought to have become extinct in the 1960s. Then, in 2016, a trio of researchers discovered that newts on the Chita Peninsula were very likely the same variant due to their similar morphological traits. Both groups share a preference for cooler temperature and have smooth and soft bodies, pale dorsal regions, and yellowish undersides. Even if still alive, this form is highly threatened and will soon be wiped out without immediate protection.[33]

Interactions with humans

Research

Japanese fire-bellied newts serve as a highly useful model organism in laboratory settings, but they become more difficult to care for after metamorphosis. An experiment supported by the Japan Society for the Promotion of Science found that thiourea (TU) can prevent this process from occurring, allowing the animals to stay in their pre-metamorphosis form for as long as two years, while still capable of metamorphosizing when removed from the TU solution. This did not have any impact on their regeneration capabilities.[25]

Japanese fire-bellied newts produce motilin, a peptide that stimulates gastrointestinal contractions, identified in many vertebrates. It is created in the upper small intestine and pancreas. The discovery of the latter was the first time pancreatic motilin had been observed. The organ also produces insulin. These results represented the first discovery of motilin in amphibians, suggesting that it has a similar role for them as it does for birds and mammals. The existence of pancreatic motilin also indicated another, unknown function.[34]

This species, as well as other Urodele amphibians, is capable of regrowing missing body parts, including limbs with functional joints and the lower jaw.[35][36] When this process occurs, the regenerated tissue tends to mirror intact tissue in form.[35] It is also able to regrow missing lenses, taking thirty days to do so as a larva and eighty days as an adult. The difference in time is purely due to the size of the eye, and regenerative ability does not change; the discovery of this fact contradicted a popular claim that juvenile animals are quicker to regenerate than adults.[37]

She also stressed the need to maintain a clean tank.

In captivity

Cynops pyrrhogaster can be kept in captivity.[38]

Doctor of Veterinary Medicine Lianne McLeod described them as "low-maintenance", noting that captive newts enjoy bloodworms, brine shrimp, glass shrimp, Daphnia, and, for larger individuals, guppies.

Notes

  1. ^ Occasionally misspelled as Molga pyrrhogaster by some authors, including Boie himself.[2]

References

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  35. ^ a b Tsutsumi, Rio; Inoue, Takeshi; Yamada, Shigehito; Agata, Kiyokazu (February 2015). "Reintegration of the regenerated and the remaining tissues during joint regeneration in the newt Cynops pyrrhogaster". Regeneration. 2 (1): 26–36. doi:10.1002/reg2.28. ISSN 2052-4412. PMC 4895332. PMID 27499865.
  36. ^ Kurosaka, Hiroshi; Takano-Yamamoto, Teruko; Yamashiro, Takashi; Agata, Kiyokazu (February 2008). "Comparison of molecular and cellular events during lower jaw regeneration of newt (Cynops pyrrhogaster) and West African clawed frog (Xenopus tropicalis)". Developmental Dynamics. 237 (2): 354–365. doi:10.1002/dvdy.21419. PMID 18161063. S2CID 41117859. from the original on 30 October 2022. Retrieved 30 October 2022.
  37. ^ Inoue, Takeshi; Inoue, Ryo; Tsutsumi, Rio; Tada, Kikuo; Urata, Yuko; Michibayashi, Chiaki; Takemura, Shota; Agata, Kiyokazu (October 2012). "Lens regenerates by means of similar processes and timeline in adults and larvae of the newt Cynops pyrrhogaster". Developmental Dynamics. 241 (10): 1575–1583. doi:10.1002/dvdy.23854. PMID 22930574. S2CID 6513165. from the original on 30 October 2022. Retrieved 30 October 2022.
  38. ^ McLeod, Lianne. "Fire Belly Newt: Species Profile". thesprucepets.com. from the original on 30 October 2022. Retrieved 30 October 2022.

February 26, 2023
japanese, fire, bellied, newt, japanese, fire, bellied, salamander, cynops, pyrrhogaster, species, newt, endemic, japan, skin, upper, body, dark, lower, regions, bright, although, coloration, varies, with, genetics, region, adults, long, deter, predators, cont. The Japanese fire bellied newt or Japanese fire bellied salamander Cynops pyrrhogaster is a species of newt endemic to Japan The skin on its upper body is dark and its lower regions bright red although coloration varies with age genetics and region Adults are 8 to 15 cm 3 1 to 5 9 in long To deter predators Japanese fire bellied newts contain high levels of tetrodotoxin a neurotoxin accumulated mainly from their diet Japanese fire bellied newtTemporal range 13 75 0 Ma PreꞒ Ꞓ O S D C P T J K Pg N Middle Miocene PresentFemale Japanese fire bellied newtConservation statusNear Threatened IUCN 3 1 1 Scientific classificationKingdom AnimaliaPhylum ChordataClass AmphibiaOrder UrodelaFamily SalamandridaeGenus CynopsSpecies C pyrrhogasterBinomial nameCynops pyrrhogaster Boie 1826 Synonyms 2 Molge pyrrhogaster Boie 1826The species is found on many Japanese islands including Honshu Shikoku and Kyushu Their habitats include both natural and artificial bodies of water as well as forests and grasslands They breed from spring to the beginning of summer both sexes producing pheromones when ready to mate Eggs are laid separately hatching after about three weeks They grow from larval to juvenile form in between five and six months Juveniles eat soil dwelling prey and adults eat a wide variety of insects tadpoles and the eggs of their own species They have several adaptations to avoid predators although which they use depends on where they live Several aspects of their biology have been studied including their ability to regrow missing body parts The Japanese fire bellied newt first diverged from its closest relative in the Middle Miocene before splitting into four distinct varieties each with a mostly separate range although all four are formally recognized as composing a single species Currently their population is declining and they face threats from disease and the pet trade They can be successfully kept in captivity Contents 1 Etymology and taxonomy 2 Description 3 Distribution and habitat 4 Behavior and ecology 4 1 Reproduction and life cycle 4 2 Diet 4 3 Predators 4 4 Toxin 5 Conservation 6 Interactions with humans 6 1 Research 6 2 In captivity 7 Notes 8 ReferencesEtymology and taxonomy EditThe species was first scientifically described by German zoologist Heinrich Boie in 1826 as Molge pyrrhogaster note 1 based on specimens brought from Japan to Europe He compared it to the smooth newt saying he would have mistaken the former for the latter had he not known it was from Japan None of the specimens he studied were fully mature 3 4 Pyrrhogaster is derived from Greek purrhos lit fire and gaster lit belly 5 Salamandra subcristata was described by Coenraad Jacob Temminck and Hermann Schlegel in 1838 and transferred to Cynops later that year by Swiss naturalist Johann Jakob von Tschudi 6 2 and in 1850 Cynops subcristata and Molge pyrrhogaster were synomized as Cynops pyrrhogaster by the British zoologist John Edward Gray 7 2 A study of mitochondrial DNA in 2001 indicated that its supposed fellow members of Cynops C cyanurus and C wolterstorffi may belong to a different genus 8 The Integrated Taxonomic Information System lists sixteen synonyms for Cynops pyrrhogaster 9 Common names of the species include Japanese fire bellied newt 1 red bellied newt 10 and Japanese fire bellied salamander 11 Studies examining morphological and geographic variation had formerly recognized six races Tohoku Kanto Atsumi intermediate Sasayama and Hiroshima 12 one of which the Sasayama was described as a subspecies in 1969 by Robert Mertens as Triturus pyrrhogaster sasayamae which is now considered a synonym of C pyrrhogaster 2 Modern molecular analysis supports the division of C pyrrhogaster into four clades instead 12 In particular the validity of the Sasayama and intermediate races has never been proven with one study finding no behavioral differences between the two supposed forms 13 Illustration of various salamanders Bottom right is C pyrrhogaster Phylogenetic tree detail 12 Triturus speciesPachytriton speciesParamesotriton speciesChinese fire belly newt C orientalis Chuxiong fire bellied newt C cyanurus Sword tailed newt C ensicauda Japanese fire bellied newt Northern cladeCentral cladeSouthern cladeWestern clade C pyrrhogaster Cynops pyrrhogaster diverged from its close relative C ensicauda about 13 75 million years ago during the Middle Miocene The common ancestor of the two species would have lived in an area of the Eurasian mainland which is today the East China Sea and the central Ryukyu Islands The land that would become the Japanese islands connected to the mainland at that time likely had a subtropical climate which may have caused the Japanese fire bellied newt s ancestors to migrate northward for desirable habitat As time progressed C pyrrhogaster split into four clades northern southern western and central The northern diverged first at around 9 68 million years ago then the central around 8 23 MYA million years ago then finally the southern and western around 4 05 MYA The ranges of all but the southern clade declined during the Last Glacial Period but expanded again afterwards The study that identified them concluded that the four clades represent separate taxonomic units although their exact relationship is unclear It also noted their extreme genetic differences unusually large for any one species 12 The ranges of the central and western varieties meet in Chugoku in western Japan to form a hybrid zone an area where the two clades interbreed to produce hybrids The central type has begun to move west which has caused the hybrid zone to shift It is expected to eventually cause the genome of the western form to be diluted by increasing hybridization 14 Description Edit Japanese fire bellied newt in a human hand On the newt s upper body the skin is dark brown approaching black and covered in wartlike bumps The underbelly and the underside of its tail are bright red with black spots 4 Younger juveniles have creamy coloration instead of red although most larger juveniles have some red present 15 Adults from smaller islands tend to have more red on their ventral belly regions than those from larger islands sometimes with extremely small spots or none at all In general males tend to have more red than females 16 Males can also be distinguished from females by their flat wide tails and swelling around the ventral region 17 An entirely red variant exists that coloration is believed to be inherited and recessive This variant is not confined to any single population but is more common in the western half of Japan overall 18 The vomeropalatine teeth a group of teeth in the upper back of the mouth are arranged in two series The tongue is relatively small half the width of the mouth The nostrils are positioned anteriorly toward the head closer to each other than to the eyes and hardly visible when viewed from above The toes of males are longer than those of females although the females themselves are longer The tail is tightly compressed with fins on both the top and bottom A smooth ridge runs from their nape to their tail 19 The full body length of adults is 8 to 15 cm 3 1 to 5 9 in 11 Snout vent length can be anywhere between 43 0 and 64 0 mm 1 69 and 2 52 in for males and 48 5 and 75 0 mm 1 91 and 2 95 in for females Populations from more northern and elevated regions tend to be larger than those in southern and lower altitude regions 20 Eggs are 2 1 to 2 3 mm 0 083 to 0 091 in long 17 Distribution and habitat EditCynops pyrrhogaster is endemic to Japan being found on several islands in the archipelago including Honshu Shikoku and Kyushu 1 It mainly dwells on the larger islands whereas its relative C ensicauda is found in the Ryukyu Islands It has the northernmost range of any Cynops species all other species besides the aforementioned C ensicauda are native to southern China 12 There is also an introduced population on Hachijō jima believed to be descended from individuals from Shikoku Their introduction is thought to have occurred in the 1970s although exactly how it happened is unknown 21 It has been recorded in the United States three times in Florida and Massachusetts Every instance was either an escape or deliberate release and no populations have been established 11 Of the four clades the northern is found in the districts of Tohoku and Kanto This does not overlap with the range of the central clade which is found in Chubu northern Kansai and eastern Chugoku The central s range has a small amount of overlap with the western which is found in southern Kinki western Chugoku Shikoku and central Kyushu The western also has some overlap with the southern clade which is found in western and southern Kyushu 12 The newts occur at elevations of 30 to 2 020 m 98 to 6 627 ft Ecosystems they are found in include forests grasslands shrublands wetlands lakes marshes and cultivated environments They can also dwell in humanmade bodies of water such as aquaculture ponds 1 Behavior and ecology Edit A pair of C pyrrhogaster specimens Reproduction and life cycle Edit Breeding occurs in paddy fields ponds brooks pools and streams Females accept male courtship behavior from spring to early summer 20 Males and females both produce peptide pheromones to attract the opposite sex when ready to mate Males produce a type known as sodefrin from the Japanese term sodefuri lit soliciting 22 females have their own variety named imorin by its discoverers from the Japanese term imo lit beloved woman and rin from sodefrin These are released from the cloaca and were the first peptide pheromone to be identified in a vertebrate and first to be identified in a female vertebrate respectively 10 23 Courtship begins when the male approaches the female sniffing its sides or cloaca The male then brings its tail to the female and rapidly vibrates it The female responds by pushing the male s neck with its snout At this point the male slowly moves away undulating its tail and the female follows touching the tail with its snout when close enough The male then deposits two to four spermatophores one at a time moving several centimeters after each which the female attempts to pick up with its cloaca sometimes unsuccessfully 24 Females lay eggs separately on underwater objects such as leaves and submerged grass roots fertilized one by one from the spermatophores they carry They can lay up to 40 eggs in one session and 100 to 400 eggs in a breeding season 24 A newt staring at the camera The young hatch from their eggs after about three weeks as swimming gilled larvae with dorsal tailfins They grow around 3 cm 1 2 in in the first three months of their lives At between five and six months they stop eating and undergo metamorphosis losing their gills and fins and becoming juveniles Juveniles cannot remain submerged in water like larvae or they drown 25 26 Newts at lower altitudes mature faster than those at higher ones Male newts of higher altitude populations tend to live longer after reaching maturity but their fully grown size is not as large as that of lowland newts Wild individuals as old as twenty three have been found 20 Diet Edit In captive settings tadpoles are known to readily eat mosquito larvae brine shrimp and earthworms 25 Juveniles often consume soil dwelling Collembola springtails and Acari mite species 15 Adults at one particular sub alpine moor in the Azuma Mountains of Fukushima Prefecture were found to like both live prey and carrion They consume many insect varieties such as members of Odonata which include dragonflies and damselflies whose larvae have been found whole in newt stomachs but only pieces of adults Brachycera a suborder of Diptera flies Hymenoptera which include sawflies wasps bees and ants and Coleoptera beetles They also eat Rhacophorus arboreus tadpoles and the eggs of their own kind The makeup of their diet varies seasonally and from year to year suggesting changes in the small animals in and around the ponds that they dwell in 17 Similar results were found at a pond on the campus of Tokyo Metropolitan University in Hachiōji Tokyo the newt stomachs containing insects from many different orders and again the eggs of conspecifics Like before frog tadpoles were eaten although these belonged to the species Rhacophorus schlegelii 27 Predators Edit Japanese fire bellied newt on its back with the bright red ventral region clearly visible Newts in Mainland Japan have different antipredator behavior than newts on smaller islands Individuals on smaller islands for instance Fukue Island generally use a maneuver called the unken reflex where they expose their bright red underbelly to attackers As their main predators are birds which are capable of distinguishing the color red this technique is effective In Mainland Japan the newts must also avoid mammalian predators which cannot distinguish colors as well as avian hunters This leads these populations to use the maneuver less as it can result in death if attempted 16 Against snakes newts from Fukue Island tend to perform tail wagging displays designed to bring a predator s attention to their replaceable tail rather than their more valuable head those from Nagasaki Prefecture in Mainland Japan tend to simply flee Snakes are present in both areas This is likely because those from the mainland are adapted to escape from mammalian hunters which are less likely to be repelled by such a display 28 Toxin Edit Wild Japanese fire bellied newts contain high levels of the neurotoxin tetrodotoxin TTX 29 This toxin inhibits the activity of sodium channels in most vertebrates discouraging predation by both birds and mammals 28 Experiments have shown the toxin is almost entirely derived from the newt s diet When raised in captivity with no source of TTX 36 to 70 week old juveniles did not contain detectable levels but wild specimens from the same original habitat had high toxicity In younger captive reared newts some TTX was still detected which was inferred to have been transferred by adult females to their eggs 29 In a follow up experiment by the same team captive reared newts were given food containing the neurotoxin They readily consumed TTX laced bloodworms when offered not showing any symptoms after ingesting the poison It was detectable in their bodies afterward further indicating food to be the source of the toxin No TTX producing organisms are known from their habitat but their existence is likely and would explain the origin of TTX in wild newts 30 Conservation Edit Group at Ikenokouchi Wetland in Tsuruga Fukui Prefecture The International Union for the Conservation of Nature IUCN has ranked it as near threatened This assessment was made in 2020 1 a shift from 2004 when it was rated least concern 31 It successfully reproduces in Australian zoos 1 One major threat that C pyrrhogaster faces is collection for the pet trade The IUCN states that this trade needs to be ended immediately Their population is decreasing particularly near areas of human habitation 1 Japanese fire bellied newts with mysterious skin lesions at Lake Biwa in Japan s Shiga Prefecture were found to be suffering from infections caused by a single celled eukaryote in the order Dermocystida The lesions contained cysts which were filled with spores Nearly all the lesions were external although one was found on the liver Globally diseases are one of the causes for declining amphibian populations There is concern that this affliction could spread to other nearby species including Zhangixalus arboreus and Hynobius vandenburghi 32 A variety believed to be found exclusively on the Atsumi Peninsula was thought to have become extinct in the 1960s Then in 2016 a trio of researchers discovered that newts on the Chita Peninsula were very likely the same variant due to their similar morphological traits Both groups share a preference for cooler temperature and have smooth and soft bodies pale dorsal regions and yellowish undersides Even if still alive this form is highly threatened and will soon be wiped out without immediate protection 33 Interactions with humans EditResearch Edit Japanese fire bellied newts serve as a highly useful model organism in laboratory settings but they become more difficult to care for after metamorphosis An experiment supported by the Japan Society for the Promotion of Science found that thiourea TU can prevent this process from occurring allowing the animals to stay in their pre metamorphosis form for as long as two years while still capable of metamorphosizing when removed from the TU solution This did not have any impact on their regeneration capabilities 25 Japanese fire bellied newts produce motilin a peptide that stimulates gastrointestinal contractions identified in many vertebrates It is created in the upper small intestine and pancreas The discovery of the latter was the first time pancreatic motilin had been observed The organ also produces insulin These results represented the first discovery of motilin in amphibians suggesting that it has a similar role for them as it does for birds and mammals The existence of pancreatic motilin also indicated another unknown function 34 This species as well as other Urodele amphibians is capable of regrowing missing body parts including limbs with functional joints and the lower jaw 35 36 When this process occurs the regenerated tissue tends to mirror intact tissue in form 35 It is also able to regrow missing lenses taking thirty days to do so as a larva and eighty days as an adult The difference in time is purely due to the size of the eye and regenerative ability does not change the discovery of this fact contradicted a popular claim that juvenile animals are quicker to regenerate than adults 37 source source source source source source source source source source source source source source She also stressed the need to maintain a clean tank In captivity Edit Cynops pyrrhogaster can be kept in captivity 38 Doctor of Veterinary Medicine Lianne McLeod described them as low maintenance noting that captive newts enjoy bloodworms brine shrimp glass shrimp Daphnia and for larger individuals guppies Notes Edit Occasionally misspelled as Molga pyrrhogaster by some authors including Boie himself 2 References Edit a b c d e f g IUCN SSC Amphibian Specialist Group 2021 Cynops pyrrhogaster IUCN Red List of Threatened Species 2021 e T59444A177224976 doi 10 2305 IUCN UK 2021 1 RLTS T59444A177224976 en Retrieved 12 November 2021 a b c d e Frost Darrel R 2023 Cynops pyrrhogaster Boie 1826 Amphibian Species of the World An Online Reference doi 10 5531 db vz 0001 Archived from the original on 2 May 2021 Retrieved 8 January 2023 Oken Lorenz 1826 Isis von Oken Expedition der Isis in German 203 204 Archived from the original on 10 January 2023 Retrieved 8 January 2023 a b Boie Heinrich 1827 Kenteekenen van eenige Japansche Amphibien in Dutch Joh F Snelleman pp 30 31 OCLC 727216017 Archived from the original on 28 October 2022 Retrieved 28 October 2022 Jobling James A 2010 The Helm dictionary of scientific bird names electronic resource from aalge to zusii Christopher Helm p 326 ISBN 978 1 4081 3326 2 Retrieved 13 November 2022 Tschudi Johann Jakob von Agassiz Louis 1838 Classification der Batrachier mit Berucksichtigung der fossilen Thiere dieser Abtheilung der Reptilien von J J Tschudi in German Universite de Neuchatel p 94 OCLC 964903266 Archived from the original on 28 October 2022 Retrieved 28 October 2022 Gray John Edward 1850 Catalogue of the Specimens of Amphibia in the Collection of the British Museum Part II Batrachia gradientia etc Printed by order of the Trustees p 25 OCLC 3183646 Archived from the original on 28 October 2022 Retrieved 28 October 2022 Chan Lauren M Zamudio Kelly R Wake David B December 2001 Relationships of the salamandrid genera Paramesotriton Pachytriton and Cynops based on mitochondrial DNA sequences Copeia 2001 4 997 1009 doi 10 1643 0045 8511 2001 001 0997 ROTSGP 2 0 CO 2 ISSN 0045 8511 S2CID 46994906 Archived from the original on 28 October 2022 Retrieved 28 October 2022 Cynops pyrrhogaster itis gov Archived from the original on 30 October 2022 Retrieved 30 October 2022 a b Nakada Tomoaki Toyoda Fumiyo Matsuda Kouhei Nakakura Takashi Hasunuma Itaru Yamamoto Kazutoshi Onoue Satomi Yokosuka Makoto Kikuyama Sakae 25 January 2017 Imorin a sexual attractiveness pheromone in female red bellied newts Cynops pyrrhogaster Scientific Reports 7 1 41334 Bibcode 2017NatSR 741334N doi 10 1038 srep41334 ISSN 2045 2322 PMC 5264602 PMID 28120945 a b c Cynops pyrrhogaster usgs gov Archived from the original on 28 October 2022 Retrieved 27 October 2022 a b c d e f Tominaga Atsushi Matsui Masafumi Yoshikawa Natsuhiko Nishikawa Kanto Hayashi Terutake Misawa Yasuchika Tanabe Shingo Ota Hidetoshi March 2013 Phylogeny and historical demography of Cynops pyrrhogaster Amphibia Urodela Taxonomic relationships and distributional changes associated with climatic oscillations Molecular Phylogenetics and Evolution 66 3 654 667 doi 10 1016 j ympev 2012 10 015 PMID 23103571 Retrieved 28 October 2022 Tagami Masataka Horie Chikako Kawai Toshimasa Sakabe Ai Shimada Tomohiko 2015 The Mating behavior of Cynops pyrrhogaster from Gifu and Aichi Prefectures Central Japan in captivity Current Herpetology 34 1 12 18 doi 10 5358 hsj 34 12 S2CID 86006031 Archived from the original on 30 October 2022 Retrieved 30 October 2022 Tominaga Atsushi Matsui Masafumi Yoshikawa Natsuhiko Eto Koshiro Nishikawa Kanto 16 March 2018 Genomic displacement and shift of the hybrid zone in the Japanese fire bellied newt Journal of Heredity 109 3 232 242 doi 10 1093 jhered esx085 PMID 29566204 Archived from the original on 29 October 2022 Retrieved 29 October 2022 a b Matsui Kumi Mochida Koji Nakamura Masahisa July 2003 Food habit of the juvenile of the Japanese newt Cynops pyrrhogaster Zoological Science 20 7 855 859 doi 10 2108 zsj 20 855 PMID 12867714 S2CID 40530531 Archived from the original on 18 November 2022 Retrieved 29 October 2022 a b Mochida Koji 23 June 2009 A parallel geographical mosaic of morphological and behavioural aposematic traits of the newt Cynops pyrrhogaster Urodela Salamandridae parallel variation in aposematic traits Biological Journal of the Linnean Society 97 3 613 622 doi 10 1111 j 1095 8312 2008 01182 x Archived from the original on 29 October 2022 Retrieved 29 October 2022 a b c Ihara Sadao February 2014 Food habits of the adult Japanese newt Current Herpetology 33 1 38 45 doi 10 5358 hsj 33 38 ISSN 1345 5834 S2CID 83534797 Archived from the original on 30 October 2022 Retrieved 30 October 2022 Matsui Kumi Marunouchi Junsuke Nakamura Masahisa 2003 Red variants of the Japanese newt Cynops pyrrhogaster Amphibia Salamandridae review of records and captive observations on the heredity of coloration Current Herpetology 22 1 37 42 doi 10 5358 hsj 22 37 S2CID 89239218 Archived from the 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Beyond sodefrin evidence for a multi component pheromone system in the model newt Cynops pyrrhogaster Salamandridae Scientific Reports 6 1 21880 Bibcode 2016NatSR 621880V doi 10 1038 srep21880 ISSN 2045 2322 PMC 4776240 PMID 26935790 Kikuyama S Toyoda F Ohmiya Y Matsuda K Tanaka S Hayashi H 1995 Sodefrin A female attracting peptide pheromone in newt cloacal glands Science 267 5204 1643 1645 Bibcode 1995Sci 267 1643K doi 10 1126 science 7886452 ISSN 0036 8075 JSTOR 2886746 PMID 7886452 S2CID 38424857 Archived from the original on 29 October 2022 Retrieved 29 October 2022 a b Kutsuki Takako Hasegawa Eisuke September 2016 Female preference for both behavior and morphology traits of the male Japanese newt Cynops pyrrhogaster Journal of Ethology 34 3 337 342 doi 10 1007 s10164 016 0480 x S2CID 11330345 Archived from the original on 30 October 2022 Retrieved 30 October 2022 a b c Chiba Chikafumi Yamada Shouta Tanaka Hibiki Inae Chiba Maiko Miura Tomoya Casco Robles Martin Miguel Yoshikawa 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30 October 2022 Kawahara Go Takayama Yuta Sugiyama Makoto Ikadai Hiromi Hashimoto Osamu 2022 Dermocystid infection in Japanese fire bellied newt Cynops pyrrhogaster Journal of Veterinary Medical Science 84 10 1410 1416 doi 10 1292 jvms 22 0233 PMC 9586028 PMID 36047163 S2CID 251945249 Archived from the original on 29 October 2022 Retrieved 29 October 2022 Shimada Tomohiko Maeda Syota Sakakibara Masaki February 2016 A morphological study of Cynops pyrrhogaster from the Chita Peninsula rediscovery of the extinct Atsumi race endemic to peninsular regions of Aichi Prefecture Central Japan Current Herpetology 35 1 38 52 doi 10 5358 hsj 35 38 ISSN 1345 5834 S2CID 88355202 Archived from the original on 30 October 2022 Retrieved 30 October 2022 Matsumoto Mio Takemi Shota Sakai Takafumi Sakata Ichiro July 2022 Identification of motilin in Japanese fire bellied newt General and Comparative Endocrinology 323 324 114031 doi 10 1016 j ygcen 2022 114031 PMID 35331740 S2CID 247653195 Archived from the original on 29 October 2022 Retrieved 29 October 2022 a b Tsutsumi Rio Inoue Takeshi Yamada Shigehito Agata Kiyokazu February 2015 Reintegration of the regenerated and the remaining tissues during joint regeneration in the newt Cynops pyrrhogaster Regeneration 2 1 26 36 doi 10 1002 reg2 28 ISSN 2052 4412 PMC 4895332 PMID 27499865 Kurosaka Hiroshi Takano Yamamoto Teruko Yamashiro Takashi Agata Kiyokazu February 2008 Comparison of molecular and cellular events during lower jaw regeneration of newt Cynops pyrrhogaster and West African clawed frog Xenopus tropicalis Developmental Dynamics 237 2 354 365 doi 10 1002 dvdy 21419 PMID 18161063 S2CID 41117859 Archived from the original on 30 October 2022 Retrieved 30 October 2022 Inoue Takeshi Inoue Ryo Tsutsumi Rio Tada Kikuo Urata Yuko Michibayashi Chiaki Takemura Shota Agata Kiyokazu October 2012 Lens regenerates by means of similar processes and timeline in adults and larvae of the newt Cynops pyrrhogaster Developmental Dynamics 241 10 1575 1583 doi 10 1002 dvdy 23854 PMID 22930574 S2CID 6513165 Archived from the original on 30 October 2022 Retrieved 30 October 2022 McLeod Lianne Fire Belly Newt Species Profile thesprucepets com Archived from the original on 30 October 2022 Retrieved 30 October 2022 Retrieved from https en wikipedia org w index php title Japanese fire bellied newt amp oldid 1141679551, wikipedia, wiki, book, books, library,

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