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Batrachochytrium dendrobatidis

February 15, 2024

Batrachochytrium dendrobatidis (/bəˌtrkˈkɪtriəm ˈdɛndrbətdɪs/ bə-TRAY-koh-KIT-ree-əm DEN-droh-bə-ty-dis), also known as Bd or the amphibian chytrid fungus, is a fungus that causes the disease chytridiomycosis in amphibians.

Batrachochytrium dendrobatidis
Zoosporangia of B. dendrobatidis growing on a freshwater arthropod (a) and algae (b); scale bars = 30 µm
Scientific classification
Domain: Eukaryota
Kingdom: Fungi
Division: Chytridiomycota
Class: Chytridiomycetes
Order: Rhizophydiales
Family: Batrachochytriaceae
Genus: Batrachochytrium
Species:
B. dendrobatidis
Binomial name
Batrachochytrium dendrobatidis
Longcore, Pessier & D.K. Nichols (1999)

Since its discovery in 1998 by Lee Berger,[1] the disease devastated amphibian populations around the world, in a global decline towards multiple extinctions, part of the Holocene extinction. A recently described second species, B. salamandrivorans, also causes chytridiomycosis and death in salamanders.

The fungal pathogens that cause the disease chytridiomycosis ravage the skin of frogs, toads, and other amphibians, throwing off their balance of water and salt and eventually causing heart failure, Nature reports. Some amphibian species appear to have an innate capacity to withstand chytridiomycosis infection due to symbiosis with Janthinobacterium lividum. Even within species that generally succumb, some populations survive, possibly demonstrating that these traits or alleles of species are being subjected to evolutionary selection.

Etymology edit

The generic name is derived from the Greek words batrachos (frog) and chytra (earthen pot), while the specific epithet is derived from the genus of frogs from which the original confirmation of pathogenicity was made (Dendrobates),[2] dendrobatidis is from the Greek dendron, "tree" and bates, "one who climbs", referring to a genus of poison dart frogs.[3]

Systematics edit

Batrachochytrium dendrobatidis was until recently considered the single species of the genus Batrachochytrium. The initial classification of the pathogen as a chytrid was based on zoospore ultrastructure. DNA analysis of the SSU-rDNA has corroborated the view, with the closest match to Chytridium confervae. A second species of Batrachochytrium was discovered in 2013: B. salamandrivorans, which mainly affects salamanders and also causes chytridiomycosis.[4] B. salamandrivorans differs from B. dendrobatidis primarily in the formation of germ tubes in vitro, the formation of colonial thalli with multiple sporangia in vivo, and a lower thermal preference.[4]

Morphology edit

 
Scanning electron micrograph of a frozen intact zoospore and sporangia of the chytrid fungus (Batrachochytrium dendrobatidis), CSIRO

B. dendrobatidis infects the keratinized skin of amphibians. The fungus in the epidermis has a thallus bearing a network of rhizoids and smooth-walled, roughly spherical, inoperculate (without an operculum) sporangia. Each sporangium produces a single tube to discharge spores.

Zoospore structure edit

Zoospores of B. dendrobatidis, which are typically 3–5 µm in size, have an elongate–ovoidal body with a single, posterior flagellum (19–20 µm long), and possess a core area of ribosomes often with membrane-bound spheres of ribosomes within the main ribosomal mass.[2] A small spur has been observed, located at the posterior of the cell body, adjacent to the flagellum, but this may be an artifact in the formalin-fixed specimens. The core area of ribosomes is surrounded by a single cisterna of endoplasmic reticulum, two to three mitochondria, and an extensive microbody–lipid globule complex. The microbodies closely appose and almost surround four to six lipid globules (three anterior and one to three laterally), some of which appear bound by a cisterna. Some zoospores appear to contain more lipid globules (this may have been a result of a plane-of-sectioning effect, because the globules were often lobed in the zoospores examined). A rumposome has not been observed.[2]

Flagellum structure edit

A nonfunctioning centriole lies adjacent to the kinetosome. Nine interconnected props attach the kinetosome to the plasmalemma, and a terminal plate is present in the transitional zone. An inner ring-like structure attached to the tubules of the flagellar doublets within the transitional zone has been observed in transverse section. No roots associated with the kinetosome have been observed. In many zoospores, the nucleus lies partially within the aggregation of ribosomes and was invariably situated laterally. Small vacuoles and a Golgi body with stacked cisternae occurred within the cytoplasm outside the ribosomal area. Mitochondria, which often contain a small number of ribosomes, are densely staining with discoidal cristae.[2]

Life cycle edit

 
B. dendrobatidis sporangia in the skin of an Atelopus varius. The arrows indicate discharge tubes through which zoospores exit the host cell. Scale bar = 35 µm.

B. dendrobatidis has two primary life stages: a sessile, reproductive zoosporangium and a motile, uniflagellated zoospore released from the zoosporangium. The zoospores are known to be active only for a short period of time, and can travel short distances of one to two centimeters.[5] However, the zoospores are capable of chemotaxis, and can move towards a variety of molecules that are present on the amphibian surface, such as sugars, proteins and amino acids.[6] B. dendrobatidis also contains a variety of proteolytic enzymes and esterases that help it digest amphibian cells and use amphibian skin as a nutrient source.[7] Once the zoospore reaches its host, it forms a cyst underneath the surface of the skin, and initiates the reproductive portion of its life cycle. The encysted zoospores develop into zoosporangia, which may produce more zoospores that can reinfect the host, or be released into the surrounding aquatic environment.[8] The amphibians infected with these zoospores are shown to die from cardiac arrest.[9]

Besides amphibians B. dendrobatidis also infects crayfish (Procambarus alleni, P. clarkii, Orconectes virilis, and O. immunis) but not mosquitofish (Gambusia holbrooki).[10]

Physiology edit

B. dendrobatidis can grow within a wide temperature range (4-25 °C), with optimal temperatures being between 17 and 25 °C.[11] The wide temperature range for growth, including the ability to survive at 4 °C gives the fungus the ability to overwinter in its hosts, even where temperatures in the aquatic environments are low. The species does not grow well above temperatures of 25 °C, and growth is halted above 28 °C.[11] Infected red-eyed treefrogs (Litoria chloris) recovered from their infections when incubated at a temperature of 37 °C.[12]

Varying forms edit

B. dendrobatidis has occasionally been found in forms distinct from its traditional zoospore and sporangia stages. For example, before the 2003 European heat wave that decimated populations of the water frog Rana lessonae through chytridiomycosis, the fungus existed on the amphibians as spherical, unicellular organisms, confined to minute patches (80–120 micrometers across). These organisms, unknown at the time, were subsequently identified as B. dendrobatidis. Characteristics of the organisms were suggestive of encysted zoospores; they may have embodied a resting spore, a saprobe, or a parasitic form of the fungus that is non-pathogenic.[13]

Habitat and relationship to amphibians edit

The fungus grows on amphibian skin and produces aquatic zoospores.[14] It is widespread and ranges from lowland forests to cold mountain tops. It is sometimes a non-lethal parasite and possibly a saprophyte. The fungus is associated with host mortality in highlands or during winter, and becomes more pathogenic at lower temperatures.[15]

Geographic distribution edit

Main article: Chytridiomycosis

It has been suggested that B. dendrobatidis originated in Africa or Asia and subsequently spread to other parts of the world by trade in African clawed frogs (Xenopus laevis).[16] In this study, 697 archived specimens of three species of Xenopus, previously collected from 1879 to 1999 in southern Africa, were examined. The earliest case of chytridiomycosis was found in a X. laevis specimen from 1938. The study also suggests that chytridiomycosis had been a stable infection in southern Africa from 23 years prior to finding any infected outside of Africa.[16] There is more recent information that the species originated on the Korean peninsula and was spread by the trade in frogs.[17]

American bullfrogs (Lithobates catesbeianus), also widely distributed, are also thought to be carriers of the disease due to their inherent low susceptibility to B. dendrobatidis infection.[18][19] The bullfrog often escapes captivity and can establish feral populations where it may introduce the disease to new areas.[5] It has also been shown that B. dendrobatidis can survive and grow in moist soil and on bird feathers, suggesting that B. dendrobatidis may also be spread in the environment by birds and transportation of soils.[20] Infections have been linked to mass mortalities of amphibians in North America, South America, Central America, Europe and Australia.[21][22][23] B. dendrobatidis has been implicated in the extinction of the sharp-snouted day frog (Taudactylus acutirostris) in Australia.[24]

A wide variety of amphibian hosts have been identified as being susceptible to infection by B. dendrobatidis, including wood frogs (Lithobates sylvatica),[25] the mountain yellow-legged frog (Lithobates muscosa),[26] the southern two-lined salamander (Eurycea cirrigera),[27] San Marcos Salamander (Eurycea nana), Texas Salamander (Eurycea neotenes), Blanco River Springs Salamander (Eurycea pterophila), Barton Springs Salamander (Eurycea sosorum), Jollyville Plateau Salamander (Eurycea tonkawae),[28] Ambystoma jeffersonianum,[29] the western chorus frog (Pseudacris triseriata), the southern cricket frog (Acris gryllus), the eastern spadefoot toad (Scaphiopus holbrooki), the southern leopard frog (Lithobates sphenocephala),[30] the Rio Grande Leopard frog (Lithobates berlandieri),[31] and the Sardinian newt (Euproctus platycephalus).[32] and endemic frog species, the Beysehir frog in Turkey (Pelophylax caralitanus).[33]

Southeast Asia edit

While most studies concerning B. dendrobatidis have been performed in various locations across the world, the presence of the fungus in Southeast Asia remains a relatively recent development. The exact process through which the fungus was introduced to Asia is not known, however, as mentioned above, it has been suggested transportation of asymptomatic carrier species (e.g. Lithobates catesbeianus, the American Bullfrog) may be a key component in the dissemination of the fungus, at least in China.[34] Initial studies demonstrated the presence of the fungus on island states/countries such as Hong Kong,[35] Indonesia,[36] Taiwan,[30] and Japan.[37] Soon thereafter, mainland Asian countries such as Thailand,[38] South Korea,[39] and China[40] reported incidences[spelling?] of B. dendrobatidis among their amphibian populations. Much effort has been put into classifying herpetofauna in countries like Cambodia, Vietnam, and Laos where new species of frogs, toads, and other amphibians and reptiles are being discovered on a frequent basis. Scientists simultaneously are swabbing herpetofauna in order to determine if these newly discovered animals possess traces of the fungus.

In Cambodia, a study showed B. dendrobatidis to be prevalent throughout the country in areas near Phnom Penh (in a village <5 km), Sihanoukville (frogs collected from the local market), Kratie (frogs collected from streets around the town), and Siem Reap (frogs collected from a national preserve: Angkor Centre for Conservation of Biodiversity).[41] Another study in Cambodia questioned the potential anthropological impact in the dissemination of B. dendrobatidis on local amphibian populations in 3 different areas in relation to human interaction: low (an isolated forest atop a mountain people rarely visit), medium (a forest road ~15 km from a village that is used at least once a week), and high (a small village where humans interact with their environment on a daily basis). Using quantitative PCR, evidence of B. dendrobatidis was found in all 3 sites with the highest percentage of amphibians positive for the fungus from the forest road (medium impact; 50%), followed by the mountain forest (low impact; 44%) and village (high impact; 36%).[42] Human influence most likely explains detection of the fungus in the medium and high areas, however it does not provide an adequate explanation why even isolated amphibians were positive for B. dendrobatidis. This may go unanswered until more research is performed on transmission of the fungus across landscapes. However, recent evidence suggests mosquitoes may be a possible vector which may help spread B. dendrobatidis. Another study in French Guiana reports widespread infection, with 8 of 11 sites sampled being positive for B. dendrobatidis infection for at least one species.[43] This study suggests that Bd is more widespread than previously thought.

Effect on amphibians edit

Worldwide amphibian populations have been on a steady decline due to an increase in the disease Chytridiomycosis, caused by this Bd fungus. Bd can be introduced to an amphibian primarily through water exposure, colonizing the digits and ventral surfaces of the animal's body most heavily and spreading throughout the body as the animal matures. Potential effects of this pathogen are hyperkeratosis, epidermal hyperplasia, ulcers, and most prominently the change in osmotic regulation often leading to cardiac arrest.[44] The death toll on amphibians is dependent on a variety of factors but most crucially on the intensity of infection. Certain frogs adopt skin sloughing as a defense mechanism for B. dendrobatidis; however, this is not always effective, as mortality fluctuates between species. For example, the Fletcher frog, despite practising skin sloughing, suffers from a particularly high mortality rate when infected with the disease compared to similar species like Lim. peronii and Lim. tasmaniensis. Some amphibian species have been found to adapt to infection after an initial die-off with survival rates of infected and non-infected individuals being equal.[45]

According to a study by the Australian National University estimates that the Bd fungus has caused the decline of 501 amphibian species—about 6.5 percent of the world known total. Of these, 90 have been entirely wiped out and another 124 species have declined by more than 90 percent, and their odds of the effected species recovering to a healthy population are doubtful.[46] However, these conclusions were criticized by later studies, which proposed that Bd was not as primary a driver of amphibian declines as found by the previous study.[47]

One amphibian in particular that Batrachochytrium dendrobatidis (Bd) has affected greatly was the Lithobates clamitans. Bd kills this frog by interfering with external water exchange thereby causing an imbalance with ion exchange which leads to heart failure.

Immunity edit

Some amphibian species are actually immune to Bd, or have biological protections against the fungus.[48] One such salamander is the alpine salamander, or S. atra. These salamanders have several subspecies, but they share a common trait: toxicity. A 2012 study demonstrated that no alpine salamanders in the area had the disease, despite its prevalence in the area.[49] Alpine salamanders can produce alkaloid products[50][49] or other toxic peptides[50] that may be protective against microbes.[51]

See also edit

References edit

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  48. ^ Pereira, K. E.; Woodley, S. K. (2021-01-11). "Skin defenses of North American salamanders against a deadly salamander fungus". Animal Conservation. 24 (4): 552–567. doi:10.1111/acv.12666. ISSN 1367-9430. S2CID 232030040.
  49. ^ a b R, Lötters, S Kielgast, J Sztatecsny, M Wagner, N Schulte, U Werner, P Rödder, D Dambach, J Reissner, T Hochkirch, A Schmidt, B (2012-04-30). Absence of infection with the amphibian chytrid fungus in the terrestrial Alpine salamander, Salamandra atra. Deutsche Gesellschaft für Herpetologie und Terrarienkunde (DGHT). OCLC 1030045649.{{cite book}}: CS1 maint: multiple names: authors list (link)
  50. ^ a b DE MEESTER, Gilles; ŠUNJE, Emina; PRINSEN, Els; VERBRUGGEN, Erik; VAN DAMME, Raoul (2020-10-13). "Toxin variation among salamander populations: discussing potential causes and future directions". Integrative Zoology. 16 (3): 336–353. doi:10.1111/1749-4877.12492. hdl:10067/1718680151162165141. ISSN 1749-4877. PMID 32965720. S2CID 221862886.
  51. ^ Lüddecke, Tim; Schulz, Stefan; Steinfartz, Sebastian; Vences, Miguel (2018-09-04). "A salamander's toxic arsenal: review of skin poison diversity and function in true salamanders, genus Salamandra". The Science of Nature. 105 (9–10): 56. Bibcode:2018SciNa.105...56L. doi:10.1007/s00114-018-1579-4. ISSN 0028-1042. PMID 30291447. S2CID 253637272.

Further reading edit

  • Daszak, Peter; Berger L; Cunningham AA; Hyatt AD; Green DE; Speare R. (1999). "Emerging Infectious Diseases and Amphibian Population Declines". Emerging Infectious Diseases. 5 (6): 735–748. doi:10.3201/eid0506.990601. PMC 2640803. PMID 10603206.
  • Johnson, Megan L.; Speare, Richard (August 2003). "Survival of Batrachochytrium dendrobatidis in Water: Quarantine and Disease Control Implications". Emerging Infectious Diseases. 9 (8): 915–921. doi:10.3201/eid0908.030145. PMC 3020615. PMID 12967488.

External links edit

 
Wikimedia Commons has media related to Batrachochytrium dendrobatidis.
 
Wikispecies has information related to Batrachochytrium.

February 15, 2024
batrachochytrium, dendrobatidis, tray, droh, also, known, amphibian, chytrid, fungus, fungus, that, causes, disease, chytridiomycosis, amphibians, zoosporangia, dendrobatidis, growing, freshwater, arthropod, algae, scale, bars, µmscientific, classificationdoma. Batrachochytrium dendrobatidis b e ˌ t r eɪ k oʊ ˈ k ɪ t r i em ˈ d ɛ n d r oʊ b e t aɪ d ɪ s be TRAY koh KIT ree em DEN droh be ty dis also known as Bd or the amphibian chytrid fungus is a fungus that causes the disease chytridiomycosis in amphibians Batrachochytrium dendrobatidisZoosporangia of B dendrobatidis growing on a freshwater arthropod a and algae b scale bars 30 µmScientific classificationDomain EukaryotaKingdom FungiDivision ChytridiomycotaClass ChytridiomycetesOrder RhizophydialesFamily BatrachochytriaceaeGenus BatrachochytriumSpecies B dendrobatidisBinomial nameBatrachochytrium dendrobatidisLongcore Pessier amp D K Nichols 1999 Since its discovery in 1998 by Lee Berger 1 the disease devastated amphibian populations around the world in a global decline towards multiple extinctions part of the Holocene extinction A recently described second species B salamandrivorans also causes chytridiomycosis and death in salamanders The fungal pathogens that cause the disease chytridiomycosis ravage the skin of frogs toads and other amphibians throwing off their balance of water and salt and eventually causing heart failure Nature reports Some amphibian species appear to have an innate capacity to withstand chytridiomycosis infection due to symbiosis with Janthinobacterium lividum Even within species that generally succumb some populations survive possibly demonstrating that these traits or alleles of species are being subjected to evolutionary selection Contents 1 Etymology 2 Systematics 3 Morphology 3 1 Zoospore structure 3 2 Flagellum structure 4 Life cycle 5 Physiology 5 1 Varying forms 5 2 Habitat and relationship to amphibians 6 Geographic distribution 6 1 Southeast Asia 7 Effect on amphibians 7 1 Immunity 8 See also 9 References 10 Further reading 11 External linksEtymology editThe generic name is derived from the Greek words batrachos frog and chytra earthen pot while the specific epithet is derived from the genus of frogs from which the original confirmation of pathogenicity was made Dendrobates 2 dendrobatidis is from the Greek dendron tree and bates one who climbs referring to a genus of poison dart frogs 3 Systematics editBatrachochytrium dendrobatidis was until recently considered the single species of the genus Batrachochytrium The initial classification of the pathogen as a chytrid was based on zoospore ultrastructure DNA analysis of the SSU rDNA has corroborated the view with the closest match to Chytridium confervae A second species of Batrachochytrium was discovered in 2013 B salamandrivorans which mainly affects salamanders and also causes chytridiomycosis 4 B salamandrivorans differs from B dendrobatidis primarily in the formation of germ tubes in vitro the formation of colonial thalli with multiple sporangia in vivo and a lower thermal preference 4 Morphology edit nbsp Scanning electron micrograph of a frozen intact zoospore and sporangia of the chytrid fungus Batrachochytrium dendrobatidis CSIROB dendrobatidis infects the keratinized skin of amphibians The fungus in the epidermis has a thallus bearing a network of rhizoids and smooth walled roughly spherical inoperculate without an operculum sporangia Each sporangium produces a single tube to discharge spores Zoospore structure edit Zoospores of B dendrobatidis which are typically 3 5 µm in size have an elongate ovoidal body with a single posterior flagellum 19 20 µm long and possess a core area of ribosomes often with membrane bound spheres of ribosomes within the main ribosomal mass 2 A small spur has been observed located at the posterior of the cell body adjacent to the flagellum but this may be an artifact in the formalin fixed specimens The core area of ribosomes is surrounded by a single cisterna of endoplasmic reticulum two to three mitochondria and an extensive microbody lipid globule complex The microbodies closely appose and almost surround four to six lipid globules three anterior and one to three laterally some of which appear bound by a cisterna Some zoospores appear to contain more lipid globules this may have been a result of a plane of sectioning effect because the globules were often lobed in the zoospores examined A rumposome has not been observed 2 Flagellum structure edit A nonfunctioning centriole lies adjacent to the kinetosome Nine interconnected props attach the kinetosome to the plasmalemma and a terminal plate is present in the transitional zone An inner ring like structure attached to the tubules of the flagellar doublets within the transitional zone has been observed in transverse section No roots associated with the kinetosome have been observed In many zoospores the nucleus lies partially within the aggregation of ribosomes and was invariably situated laterally Small vacuoles and a Golgi body with stacked cisternae occurred within the cytoplasm outside the ribosomal area Mitochondria which often contain a small number of ribosomes are densely staining with discoidal cristae 2 Life cycle edit nbsp B dendrobatidis sporangia in the skin of an Atelopus varius The arrows indicate discharge tubes through which zoospores exit the host cell Scale bar 35 µm B dendrobatidis has two primary life stages a sessile reproductive zoosporangium and a motile uniflagellated zoospore released from the zoosporangium The zoospores are known to be active only for a short period of time and can travel short distances of one to two centimeters 5 However the zoospores are capable of chemotaxis and can move towards a variety of molecules that are present on the amphibian surface such as sugars proteins and amino acids 6 B dendrobatidis also contains a variety of proteolytic enzymes and esterases that help it digest amphibian cells and use amphibian skin as a nutrient source 7 Once the zoospore reaches its host it forms a cyst underneath the surface of the skin and initiates the reproductive portion of its life cycle The encysted zoospores develop into zoosporangia which may produce more zoospores that can reinfect the host or be released into the surrounding aquatic environment 8 The amphibians infected with these zoospores are shown to die from cardiac arrest 9 Besides amphibians B dendrobatidis also infects crayfish Procambarus alleni P clarkii Orconectes virilis and O immunis but not mosquitofish Gambusia holbrooki 10 Physiology editB dendrobatidis can grow within a wide temperature range 4 25 C with optimal temperatures being between 17 and 25 C 11 The wide temperature range for growth including the ability to survive at 4 C gives the fungus the ability to overwinter in its hosts even where temperatures in the aquatic environments are low The species does not grow well above temperatures of 25 C and growth is halted above 28 C 11 Infected red eyed treefrogs Litoria chloris recovered from their infections when incubated at a temperature of 37 C 12 Varying forms edit B dendrobatidis has occasionally been found in forms distinct from its traditional zoospore and sporangia stages For example before the 2003 European heat wave that decimated populations of the water frog Rana lessonae through chytridiomycosis the fungus existed on the amphibians as spherical unicellular organisms confined to minute patches 80 120 micrometers across These organisms unknown at the time were subsequently identified as B dendrobatidis Characteristics of the organisms were suggestive of encysted zoospores they may have embodied a resting spore a saprobe or a parasitic form of the fungus that is non pathogenic 13 Habitat and relationship to amphibians edit The fungus grows on amphibian skin and produces aquatic zoospores 14 It is widespread and ranges from lowland forests to cold mountain tops It is sometimes a non lethal parasite and possibly a saprophyte The fungus is associated with host mortality in highlands or during winter and becomes more pathogenic at lower temperatures 15 Geographic distribution editMain article Chytridiomycosis It has been suggested that B dendrobatidis originated in Africa or Asia and subsequently spread to other parts of the world by trade in African clawed frogs Xenopus laevis 16 In this study 697 archived specimens of three species of Xenopus previously collected from 1879 to 1999 in southern Africa were examined The earliest case of chytridiomycosis was found in a X laevis specimen from 1938 The study also suggests that chytridiomycosis had been a stable infection in southern Africa from 23 years prior to finding any infected outside of Africa 16 There is more recent information that the species originated on the Korean peninsula and was spread by the trade in frogs 17 American bullfrogs Lithobates catesbeianus also widely distributed are also thought to be carriers of the disease due to their inherent low susceptibility to B dendrobatidis infection 18 19 The bullfrog often escapes captivity and can establish feral populations where it may introduce the disease to new areas 5 It has also been shown that B dendrobatidis can survive and grow in moist soil and on bird feathers suggesting that B dendrobatidis may also be spread in the environment by birds and transportation of soils 20 Infections have been linked to mass mortalities of amphibians in North America South America Central America Europe and Australia 21 22 23 B dendrobatidis has been implicated in the extinction of the sharp snouted day frog Taudactylus acutirostris in Australia 24 A wide variety of amphibian hosts have been identified as being susceptible to infection by B dendrobatidis including wood frogs Lithobates sylvatica 25 the mountain yellow legged frog Lithobates muscosa 26 the southern two lined salamander Eurycea cirrigera 27 San Marcos Salamander Eurycea nana Texas Salamander Eurycea neotenes Blanco River Springs Salamander Eurycea pterophila Barton Springs Salamander Eurycea sosorum Jollyville Plateau Salamander Eurycea tonkawae 28 Ambystoma jeffersonianum 29 the western chorus frog Pseudacris triseriata the southern cricket frog Acris gryllus the eastern spadefoot toad Scaphiopus holbrooki the southern leopard frog Lithobates sphenocephala 30 the Rio Grande Leopard frog Lithobates berlandieri 31 and the Sardinian newt Euproctus platycephalus 32 and endemic frog species the Beysehir frog in Turkey Pelophylax caralitanus 33 Southeast Asia edit While most studies concerning B dendrobatidis have been performed in various locations across the world the presence of the fungus in Southeast Asia remains a relatively recent development The exact process through which the fungus was introduced to Asia is not known however as mentioned above it has been suggested transportation of asymptomatic carrier species e g Lithobates catesbeianus the American Bullfrog may be a key component in the dissemination of the fungus at least in China 34 Initial studies demonstrated the presence of the fungus on island states countries such as Hong Kong 35 Indonesia 36 Taiwan 30 and Japan 37 Soon thereafter mainland Asian countries such as Thailand 38 South Korea 39 and China 40 reported incidences spelling of B dendrobatidis among their amphibian populations Much effort has been put into classifying herpetofauna in countries like Cambodia Vietnam and Laos where new species of frogs toads and other amphibians and reptiles are being discovered on a frequent basis Scientists simultaneously are swabbing herpetofauna in order to determine if these newly discovered animals possess traces of the fungus In Cambodia a study showed B dendrobatidis to be prevalent throughout the country in areas near Phnom Penh in a village lt 5 km Sihanoukville frogs collected from the local market Kratie frogs collected from streets around the town and Siem Reap frogs collected from a national preserve Angkor Centre for Conservation of Biodiversity 41 Another study in Cambodia questioned the potential anthropological impact in the dissemination of B dendrobatidis on local amphibian populations in 3 different areas in relation to human interaction low an isolated forest atop a mountain people rarely visit medium a forest road 15 km from a village that is used at least once a week and high a small village where humans interact with their environment on a daily basis Using quantitative PCR evidence of B dendrobatidis was found in all 3 sites with the highest percentage of amphibians positive for the fungus from the forest road medium impact 50 followed by the mountain forest low impact 44 and village high impact 36 42 Human influence most likely explains detection of the fungus in the medium and high areas however it does not provide an adequate explanation why even isolated amphibians were positive for B dendrobatidis This may go unanswered until more research is performed on transmission of the fungus across landscapes However recent evidence suggests mosquitoes may be a possible vector which may help spread B dendrobatidis Another study in French Guiana reports widespread infection with 8 of 11 sites sampled being positive for B dendrobatidis infection for at least one species 43 This study suggests that Bd is more widespread than previously thought Effect on amphibians editWorldwide amphibian populations have been on a steady decline due to an increase in the disease Chytridiomycosis caused by this Bd fungus Bd can be introduced to an amphibian primarily through water exposure colonizing the digits and ventral surfaces of the animal s body most heavily and spreading throughout the body as the animal matures Potential effects of this pathogen are hyperkeratosis epidermal hyperplasia ulcers and most prominently the change in osmotic regulation often leading to cardiac arrest 44 The death toll on amphibians is dependent on a variety of factors but most crucially on the intensity of infection Certain frogs adopt skin sloughing as a defense mechanism for B dendrobatidis however this is not always effective as mortality fluctuates between species For example the Fletcher frog despite practising skin sloughing suffers from a particularly high mortality rate when infected with the disease compared to similar species like Lim peronii and Lim tasmaniensis Some amphibian species have been found to adapt to infection after an initial die off with survival rates of infected and non infected individuals being equal 45 According to a study by the Australian National University estimates that the Bd fungus has caused the decline of 501 amphibian species about 6 5 percent of the world known total Of these 90 have been entirely wiped out and another 124 species have declined by more than 90 percent and their odds of the effected species recovering to a healthy population are doubtful 46 However these conclusions were criticized by later studies which proposed that Bd was not as primary a driver of amphibian declines as found by the previous study 47 One amphibian in particular that Batrachochytrium dendrobatidis Bd has affected greatly was the Lithobates clamitans Bd kills this frog by interfering with external water exchange thereby causing an imbalance with ion exchange which leads to heart failure Immunity edit Some amphibian species are actually immune to Bd or have biological protections against the fungus 48 One such salamander is the alpine salamander or S atra These salamanders have several subspecies but they share a common trait toxicity A 2012 study demonstrated that no alpine salamanders in the area had the disease despite its prevalence in the area 49 Alpine salamanders can produce alkaloid products 50 49 or other toxic peptides 50 that may be protective against microbes 51 See also editPathogenic fungi Decline in amphibian populations RanavirusReferences edit Berger L Speare R Daszak P Green DE Cunningham AA Goggin CL Slocombe R Ragan MA Hyatt AD McDonald KR Hines HB Lips KR Marantelli G Parkes H July 1998 Chytridiomycosis causes amphibian mortality associated with population declines in the rain forests of Australia and Central America Proceedings of the National Academy of Sciences of the United States of America 95 15 9031 6 Bibcode 1998PNAS 95 9031B doi 10 1073 pnas 95 15 9031 PMC 21197 PMID 9671799 a b c d Longcore JE Pessier AP Nichols DK 1999 Batrachochytrium Dendrobatidis gen et sp nov a chytrid pathogenic to amphibians Mycologia 91 2 219 227 doi 10 2307 3761366 JSTOR 3761366 Etymologia Batrachochytrium salamandrivorans Emerg Infect Dis 22 7 1282 July 2016 doi 10 3201 eid2207 ET2207 PMC 4918143 a b Martel A Spitzen van der Sluijs A Blooi M Bert W Ducatelle R Fisher M C Woeltjes A Bosman W Chiers K Bossuyt F Pasmans F 2013 Batrachochytrium salamandrivorans sp nov causes lethal chytridiomycosis in amphibians Proceedings of the National Academy of Sciences of the United States of America 110 38 15325 15329 Bibcode 2013PNAS 11015325M doi 10 1073 pnas 1307356110 PMC 3780879 PMID 24003137 a b Garner TW Perkins MW Govindarajulu P Seglie D Walker S Cunningham AA Fisher MC September 2006 The emerging amphibian pathogen Batrachochytrium dendrobatidis globally infects introduced populations of the North American bullfrog Lithobates catesbeiana Biol Lett 2 3 455 9 doi 10 1098 rsbl 2006 0494 PMC 1686185 PMID 17148429 permanent dead link Moss AS Reddy NS Dortaj IM San Francisco MJ 2008 Chemotaxis of the amphibian pathogen Batrachochytrium dendrobatidis and its response to a variety of attractants Mycologia 100 1 1 5 doi 10 3852 mycologia 100 1 1 PMID 18488347 Symonds EP Trott DJ Bird PS Mills P 2008 Growth characteristics and enzyme activity in Batrachochytrium dendrobatidis isolates Mycopathologia 166 3 143 147 doi 10 1007 s11046 008 9135 y PMID 18568420 S2CID 8545084 Berger L Hyatt AD Speare R Longcore JE December 2005 Life cycle stages of the amphibian chytrid Batrachochytrium dendrobatidis Dis Aquat Org 68 1 51 63 doi 10 3354 dao068051 PMID 16465834 Voyles J Young S Berger L Campbell C Voyles WF Dinudom A Cook D Webb R Alford RA Skerratt LF Speare R 2009 Pathogenesis of chytridiomycosis a 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amphibian Leptodactylus ocellatus Anura Leptodactylidae in Argentina Diseases of Aquatic Organisms 64 3 247 52 doi 10 3354 dao064247 PMID 15997823 Schloegel LM Hero JM Berger L Speare R McDonald K Daszak P 2006 The decline of the sharp snouted day frog Taudactylus acutiostris the first documented case of extinction by infection in a free ranging wildlife species EcoHealth 3 35 40 CiteSeerX 10 1 1 602 3591 doi 10 1007 s10393 005 0012 6 S2CID 11114174 Reeves MK 2008 Batrachochytrium dendrobatidis in wood frogs Lithobates sylvatica from Three National Wildlife Refuges in Alaska USA Herpetological Review 39 1 68 70 Andre SE Parker J Briggs CJ 2008 Effect of temperature on host response to Batrachochytrium dendrobatidis infection in the mountain yellow legged frog Lithobates muscosa Journal of Wildlife Diseases 44 3 716 720 doi 10 7589 0090 3558 44 3 716 PMID 18689660 Byrne MW Davie EP Gibbons JW 2008 Batrachochytrium dendrobatidis occurrence in Eurycea cirrigera Southeastern Naturalist 7 3 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in Southern Sardinia Italy Journal of Wildlife Diseases 44 3 712 715 doi 10 7589 0090 3558 44 3 712 PMID 18689659 Erismis UC Konuk M Yoldas T Agyar P Yumuk D Korcan SE 2014 Survey of Turkey s endemic amphibians for chytrid fungus Batrachochytrium dendrobatidis in Turkey PDF Journal of Wildlife Diseases 111 2 153 157 doi 10 3354 dao02742 PMID 25266902 Bai C T W Garner amp Y Li 2010 First evidence of Batrachochytrium dendrobatidis in China discovery of chytridiomycosis in introduced American bullfrogs and native amphibians in the Yunnan Province China Dis Aquat Org 92 1 241 244 doi 10 1007 s10393 010 0307 0 PMID 20372969 S2CID 24321977 Rowley J Chan SK Tang WS Speare R Skerratt LF Alford RA Cheung KS Ho CY Campbell R 2007 Survey for the amphibianchytrid Batrachochytrium dendrobatidis in Hong Kong in native amphibians and in the international amphibian trade Diseases of Aquatic Organisms 78 2 87 95 doi 10 3354 dao01861 PMID 18286805 Kusrini MD Skerratt LF Garland S Berger L Endarwin W 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Heilongjiang Province China Dis Aquat Org 92 3 241 244 doi 10 3354 dao02172 PMID 21268987 Gaertner JP Mendoza JA Forstner MR Neang T Hahn D 2011 Detection of Batrachochytrium dendrobatidis in frogs from different locations in Cambodia Herpetological Review 42 546 548 Mendoza JA Gaertner JP Holden J Forstner MR Hahn D 2011 Detection of Batrachochytrium dendrobatidis on amphibians in Pursat Province Cambodia Herpetological Review 42 542 545 Courtois EA Gaucher P Chave J Schmeller DS 2015 Widespread Occurrence of Bd in French Guiana South America PLOS ONE 10 4 e0125128 Bibcode 2015PLoSO 1025128C doi 10 1371 journal pone 0125128 PMC 4406614 PMID 25902035 Chytridiomycosis www amphibiaweb org Retrieved 2016 05 27 DiRenzo Graziella Zipkin Elise Grant Evan Campbell Royle J Andrew Longo Ana Zamudio Kelly Lips Karen 3 October 2018 Eco evolutionary rescue promotes host pathogen coexistence Ecological Applications 28 8 1948 1962 doi 10 1002 eap 1792 PMID 30368999 Yong Ed 2019 03 28 The Worst Disease Ever Recorded The Atlantic Retrieved 2019 03 28 Lambert Max R Womack Molly C Byrne Allison Q Hernandez Gomez Obed Noss Clay F Rothstein Andrew P Blackburn David C Collins James P Crump Martha L Koo Michelle S Nanjappa Priya 2020 03 20 Comment on Amphibian fungal panzootic causes catastrophic and ongoing loss of biodiversity Science 367 6484 eaay1838 doi 10 1126 science aay1838 ISSN 0036 8075 PMID 32193293 Pereira K E Woodley S K 2021 01 11 Skin defenses of North American salamanders against a deadly salamander fungus Animal Conservation 24 4 552 567 doi 10 1111 acv 12666 ISSN 1367 9430 S2CID 232030040 a b R Lotters S Kielgast J Sztatecsny M Wagner N Schulte U Werner P Rodder D Dambach J Reissner T Hochkirch A Schmidt B 2012 04 30 Absence of infection with the amphibian chytrid fungus in the terrestrial Alpine salamander Salamandra atra Deutsche Gesellschaft fur Herpetologie und Terrarienkunde DGHT OCLC 1030045649 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link a b DE MEESTER Gilles SUNJE Emina PRINSEN Els VERBRUGGEN Erik VAN DAMME Raoul 2020 10 13 Toxin variation among salamander populations discussing potential causes and future directions Integrative Zoology 16 3 336 353 doi 10 1111 1749 4877 12492 hdl 10067 1718680151162165141 ISSN 1749 4877 PMID 32965720 S2CID 221862886 Luddecke Tim Schulz Stefan Steinfartz Sebastian Vences Miguel 2018 09 04 A salamander s toxic arsenal review of skin poison diversity and function in true salamanders genus Salamandra The Science of Nature 105 9 10 56 Bibcode 2018SciNa 105 56L doi 10 1007 s00114 018 1579 4 ISSN 0028 1042 PMID 30291447 S2CID 253637272 Further reading editDaszak Peter Berger L Cunningham AA Hyatt AD Green DE Speare R 1999 Emerging Infectious Diseases and Amphibian Population Declines Emerging Infectious Diseases 5 6 735 748 doi 10 3201 eid0506 990601 PMC 2640803 PMID 10603206 Johnson Megan L Speare Richard August 2003 Survival of Batrachochytrium dendrobatidis in Water Quarantine and Disease Control Implications Emerging Infectious Diseases 9 8 915 921 doi 10 3201 eid0908 030145 PMC 3020615 PMID 12967488 External links edit nbsp Wikimedia Commons has media related to Batrachochytrium dendrobatidis nbsp Wikispecies has information related to Batrachochytrium Chytrid Fungi Online at University of Alabama Batrachochytrium dendrobatidis in MycoBank Batrachochytrium dendrobatidis in Index Fungorum Retrieved from https en wikipedia org w index php title Batrachochytrium dendrobatidis amp oldid 1196243654, wikipedia, wiki, book, books, library,

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