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Tracking trends and analyzing new and reemerging infectious disease issues around the world PDF

117 Pages·1999·2.47 MB·English
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Daszak et al. Population Declines......................................735 Development of Orphan Vaccines: J. Lang and An Industry Perspective...............................749 S.C. Wood Synopsis Antimicrobial Resistance with G.V. Doern et al. Streptococcus pneumoniae in the United States, 1997–98.................................757 Research Epidemiologic Studies of Cyclospora C. Bern et al. Cover: Amanda Hyatt. Frogs, Glorious Frogs (1999). Reprinted with cayetanensis in Guatemala .........................766 permission of the artist, Geelong, Australia. Serologic Evidence of Human Monocytic A. Keysary et al. and Granulocytic Ehrlichiosis in Israel.......775 Letters Supplementing Tuberculosis Surveillance D.S. Yokoe et al. with Automated Data from Swine as a Potential Reservoir Health Maintenance Organizations ............779 of Shiga Toxin-Producing Escherichia coli O157:H7 in Using Automated Pharmacy Records G.S. Subramanyan Japan .................................833 to Assess the Management et al. M. Nakazawa et. al of Tuberculosis..............................................788 Hospitalizations for Rotavirus Gastroenteritis in Gipuzkoa Hantavirus Reservoir Hosts Associated G. Calderón (Basque Country), Spain ...834 with Peridomestic Habitats G. Cilla et al. in Argentina..................................................792 Israeli Spotted Fever Rickettsia (Rickettsia conorii Complex) Dispatches Associated with Human Disease in Portugal............835 Large, Persistent Epidemic of Adenovirus K.M. McNeill et al. F. Bacellar et al. Type 4-Associated Acute Respiratory Disease in U.S. Army Trainees ....................798 The opinions expressed by authors contributing to this journal do not necessarily reflect the opinions of the Changes in Antimicrobial Resistance among M.A. Davis et al. Centers for Disease Control and Salmonella enterica Serovar Typhimurium Prevention or the institutions with Isolates from Humans and Cattle in the which the authors are affiliated. Northwestern United States, 1982–1997....802 Volume 5, Number 6 November–December 1999 Letters Dispatches Avoiding Misdiagnosis of Toxic Shock Syndrome in the U.S.: R.A. Hajjeh et al. Malaria: A Novel Automated Surveillance Update, 1979-1996..................807 Method Allows Specific Diagnosis, even in the absence New Rickettsiae in Ticks Collected in E. Rydkina et al. of Clinical Suspicion ..........836 Territories of the Former Soviet Union ......811 T. Hänscheid et al. The First Reported Case Computer-Generated Dot Maps as S.B. Eng et al. of Aerococcus Bacteremia an Epidemiologic Tool: Investigating in a Patient with an Outbreak of Toxoplasmosis.....................815 HIV Infection.....................838 J.H. Razeq et al. HIV Infection as a Risk Factor J.T. Baer et al. ew for Shigellosis................................................820 Proficiency in Detecting Vancomycin Resistance in Enterococci among Dengue Seroconversion among Israeli I. Potasman et al. Clinical Laboratories in Travelers to Tropical Countries...................824 Santiago, Chile...................839 J.A. Labarca et al. Effectiveness of Pneumococcal Polysaccharide A.E. Fiore et al. Vaccine for Preschool-Age Children Food-Related Illness and Death with Chronic Disease ...................................828 in the United States ..........840 C. Hedberg Commentary Food-Related Illness and Death in the United States—Reply to Dr. Hedberg........................841 Stimulating the Development B. Schwartz and P.S. Mead et al. of Orphan (and Other) Vaccines..................832 N.R. Rabinovich Specimen Collection for Electron Microscopy ..........842 J.A. Marshall and M.G. Catton News and Notes Upcoming Keystone Symposia...........................843 The journal is distributed electronically and in hard copy and is available at no charge. Applied Epidemiology YES, I would like to receive Emerging Infectious Diseases. Course ...............................843 Please print your name and International Conference business address in the box and on Nosocomial and return by fax to 404-639-3075 or Health Care-Associated mail to Infections...........................844 EID Editor CDC/NCID/MS D61 Towards a Healthy 1600 Clifton Road, NE Europe for the Atlanta, GA 30333 Year 2010...........................844 Erratum.............................844 Moving? Please give us your new address (in the box) and ICEID 2000 .......................845 print the number of your old mailing label here__________ Journal Web Page .............846 PPPPPeeeeerrrrrssssspppppeeeeeccccctttttiiiiivvvvveeeeesssss Emerging Infectious Diseases and Amphibian Population Declines PPPPPeeeeettttteeeeerrrrr DDDDDaaaaassssszzzzzaaaaakkkkk,,,,,***** LLLLLeeeeeeeeee BBBBBeeeeerrrrrgggggeeeeerrrrr,,,,,†††††‡‡‡‡‡ AAAAAnnnnndddddrrrrreeeeewwwww AAAAA..... CCCCCuuuuunnnnnnnnnniiiiinnnnnggggghhhhhaaaaammmmm,,,,,§§§§§ AAAAAllllleeeeexxxxx DDDDD..... HHHHHyyyyyaaaaatttttttttt,,,,,††††† DDDDD..... EEEEEaaaaarrrrrlllll GGGGGrrrrreeeeeeeeeennnnn,,,,,¶¶¶¶¶ aaaaannnnnddddd RRRRRiiiiiccccckkkkk SSSSSpppppeeeeeaaaaarrrrreeeee‡‡‡‡‡ *Institute of Ecology, University of Georgia, Athens, Georgia, USA; †Australian Animal Health Laboratory, Commonwealth Scientific Industrial Research Organization, Geelong, Victoria, Australia; ‡School of Public Health and Tropical Medicine, James Cook University, Townsville, Queensland, Australia; §Institute of Zoology, Zoological Society of London, London, United Kingdom; and ¶National Wildlife Health Center, U.S. Geological Survey, Madison, Wisconsin, USA We review recent research on the pathology, ecology, and biogeography of two emerging infectious wildlife diseases, chytridiomycosis and ranaviral disease, in the context of host-parasite population biology. We examine the role of these diseases in the global decline of amphibian populations and propose hypotheses for the origins and impact of these panzootics. Finally, we discuss emerging infectious diseases as a global threat to wildlife populations. Emerging infectious diseases have been (12-19). While some declines are clearly due to reported increasingly as causes of death in free- habitat destruction, others are not associated living wild animals (1). These diseases are a with obvious environmental factors. Causal particular threat to wildlife species whose hypotheses include the introduction of predators population, habitat, or range has been dimin- or competitors, increased ultraviolet (UV-B) ished or artificially manipulated to promote irradiation, acid precipitation, adverse weather species survival (e.g., captive breeding, translo- patterns, environmental pollution, infectious cation, and release programs) (2-4). An early disease, or a combination of these. Transdermal example of an emerging disease panzootic was water uptake and gaseous exchange and a the introduction of rinderpest in African domestic biphasic life cycle are important aspects of cattle in 1889 (5). More recently, epizootics and amphibian biology. These factors led to the panzootics of wildlife have been increasingly hypothesis that amphibians act as sentinels for reported in terrestrial (1) and marine (6) habitats global environmental degradation (12,18). How- and are probably underreported (1,4,7-9). Recent ever, this role has yet to be demonstrated, and advances in theoretical and experimental host- many causal factors may be present (12,19,20). parasite ecology have demonstrated a major role Of particular concern are population declines for infectious agents in the population biology of in ecologically pristine areas, such as the montane wild animals (10,11). We discuss recent data on tropical rain forests of Australia and Central two newly emerging infectious diseases of America, where human impact from agriculture, amphibians and, by reference to host-parasite deforestation, or pollution is thought to be ecology, propose hypotheses to explain their negligible. Here, long-term data demonstrate origin and impact. recent and catastrophic amphibian population declines, often resulting in the complete loss of Amphibian Population Declines amphibian species (local extinction of multiple Global declines in amphibian population are species) from large swaths of habitat (20-25). perhaps one of the most pressing and enigmatic These declines include the disappearance and environmental problems of the late 20th century presumed extinction of the recently discovered golden toad (Bufo periglenes) of Costa Rica (23) Address for correspondence: Peter Daszak, Institute of Ecology, and as many as seven Australian amphibian University of Georgia, Ecology Building, Athens, GA 30602, USA; fax: 706-542-4819; e-mail: [email protected]. species, including two species of gastric-brooding Vol. 5, No. 6, November–December 1999 777773333355555 Emerging Infectious Diseases PPPPPeeeeerrrrrssssspppppeeeeeccccctttttiiiiivvvvveeeeesssss frog (Rheobatrachus spp.) (20). These data, along (26-31) have repeatedly found two diseases as the with recent findings of amphibian mass deaths in causes of amphibian mass deaths globally these areas, suggest that such local extinctions are (Table 1): chytridiomycosis in the rain forests of not normal population fluctuations or Australia and Central and South America and metapopulation dynamics. some parts of North America (28-32) and Investigations in Australia, the United iridoviral infections in the United Kingdom, the Kingdom, and North and Central America United States, and Canada (26,27,33-36). Both Table 1. Mass deaths caused by chytridiomycosis and ranaviral disease in wild populations of amphibians Locality and date of mass deaths Species affected and impacta References Chytridiomycosis E. & S. Australia Multiple montane rain forest and temperate 28-30 (1993-1999)b species. Mass deaths, local extinctions, population declines. Near-extinction of Taudactylus acutirostris. Hypothesized link with global extinction of two species of gastric brooding frog (Rheobatrachus spp.). W. Australia Multiple species, predominantly the western 29,31 (1998-1999)c green (or motorbike) frog (Litoria moorei). Mass deaths, population declines. Costa Rica Multiple montane rain forest species. 20,23, and Panama Mass deaths, local extinctions, population 28,29 (1994-99) declines. Hypothesized link with global extinction of golden toad, Bufo periglenes. Ecuador (1999) Montane rain forest Atelopus species, Telmatobius 29 niger, and Gastrothecus pseustes. Unknown impact. Arizona Leopard frog (Rana yavapiensis & 29 (1996-1997) R. chiricahuensis). Mass deaths. S. Arizona (1999) Leopard frog (Rana sp.). Mass deaths. 31,32 Colorado (1999) Boreal toad (Bufo boreas). Mass deaths. d Colorado (1970s) Leopard frog (Rana pipiens). Mass deaths. 32d Sierra Nevada, Yosemite toad (Bufo canorus). Mass deaths. 32e California (1970s) Ranaviral disease United Kingdom Common frog (Rana temporaria). Mass deaths, 5,16,26, (1992-1999f) possibly population declines. 33,34 Arizona (1995) Sonoran tiger salamander (Ambystoma tigrinum 27 stebbinsi). Mass deaths in this endangered species. N. Dakota (1998) Tiger salamander (A. tigrinum). 35 Mass deaths. Maine (1998) Tiger salamander (A. maculatum). 35 Mass deaths. Utah (1998) Tiger salamander (A. tigrinum). Mass deaths. 35 Saskatchewan, Tiger salamander (A. tigrinum diaboli). Mass deaths. 36 Canada (1997) aMass deaths did not occur in all cases of wild amphibians infected by chytridiomycosis. Bufo americanus from Maryland and Acris crepitans from Illinois have been found infected with chytridiomycosis without observed deaths (37,38). In Australia, chytridiomycosis has been reported from small numbers of amphibians without evidence of clinical signs or deaths in both upland and lowland species (R. Speare, L. Berger, unpubl. obs.). bRetrospective studies have identified chytridiomycosis as the cause of death in wild frogs in five Australian states from as early as 1989 (29). cThis recent outbreak was more than 2,000 km from the closest recorded chytridiomycosis-linked amphibian die-offs (31). It is thought that chytridiomycosis may now be enzootic in many areas of Australia, but still in the process of spreading to naïve populations. A role for chytridiomycosis in other recent W. Australian declines is suspected due to similarities in the pattern of declines and presence of the Batrachochytrium carcasses from W. Australia since 1992. dD.E. Green, unpubl. obs. eD.E. Green, unpubl. obs. Historically collected specimens recently examined histologically revealed chytridiomycosis as a contributing factor to the cause of death in 2 of 12 animals. fA.A. Cunningham, unpubl. obs. Emerging Infectious Diseases 777773333366666 Vol. 5, No. 6, November–December 1999 PPPPPeeeeerrrrrssssspppppeeeeeccccctttttiiiiivvvvveeeeesssss diseases have been classified as emerging (1). The parasitic infection recently implicated as the cause of amphibian deformities in North America has not been associated with mass deaths or population declines (31). Chytridiomycosis—an Emerging Panzootic Fungal Disease of Amphibians Chytridiomycosis is a fungal disease first described in 1998 from moribund and dead adult amphibians collected at sites of mass deaths in Australia and Panama from 1993 to 1998 (28). Here, long-term ecologic study sites reported catastrophic amphibian population declines in Big Tableland, Queensland (39,40), and Fortuna and Cerro Pando, Panama (24,25,28). No significant pathogens were found on routine parasitologic, bacteriologic, mycologic, or viro- logic examinations of tissue samples (28). Fresh skin smears and histologic sections of the epidermis, however, consistently contained large numbers of developing and mature sporangia of a new genus of chytrid fungus (phylum Chytridiomycota) (Figures 1, 2). Sporangia were also present within the keratinized mouthparts, but not the epidermis, of sympatric tadpoles (tadpoles lack epidermal keratin) (28,29). No significant morphologic differences between chytrids infecting Australian and Central Ameri- can amphibians were found by transmission electron microscopy, and the pathogen was identified as a member of the order Chytridiales by analysis of zoospore ultrastructure and 18s rDNA sequence data (28). Chytrids are ubiquitous Figure 1a: Ventral abdominal skin of Bufo haematiticus from fungi that develop without hyphae and are found western Panama. The superficial keratinized layer of epidermis in aquatic habitats and moist soil, where they (stratum corneum) contains numerous intracellular spherical- to-ovoid sporangia (spore-containing bodies) of Batrachochytrium degrade cellulose, chitin, and keratin (41). sp. The mature sporangia (sp, arrows) are 12-20 µm (n = 25) in Parasitic chytrids mainly infect plants, algae, diameter and have refractile walls 0.5-2.0 µm thick. Most protists, and invertebrates (41); the amphibian sporangia are empty, having discharged all zoospores, but a few pathogen is the only example of a chytrid sporangia contain two to nine zoospores. This stratum corneum is markedly thickened adjacent to groups of parasitized cells and parasitizing vertebrates (28). in some cases, the superficial layer has become detached. No Clinical signs of amphibian chytridiomycosis chytrids are present in the stratum spinosum, stratum basale, include abnormal posture, lethargy, and loss of dermis, dermal glands, and blood vessels. Note the absence of righting reflex. Gross lesions, which are usually hyphae and lack of an inflammatory cell response in the deeper layers of epidermis and the dermis. Hematoxylin and eosin not apparent, consist of abnormal epidermal stain. Bar = 35 µm. 1b. Ventral skin of upper hind limb of sloughing and (more rarely) epidermal ulcer- Atelopus varius from western Panama. Two sporangia ation; hemorrhages in the skin, muscle, or eye; containing numerous zoospores are visible within cells of the hyperemia of digital and ventrum skin, and stratum corneum. Each flask-shaped sporangium has a single characteristic discharge tube (arrow) at the skin surface. Exiting congestion of viscera (29). Diagnosis is by zoospores are visible in the discharge tubes of both sporangia. identification of characteristic intracellular Hyperkeratosis is minimal in this acute infection. Tissues were flask-shaped sporangia and septate thalli within fixed in neutral-buffered 10% formalin, paraffin-embedded, the epidermis (Figures 1, 2). sectioned at 6 µm thick and stained with hematoxylin and eosin. Bar = 35 µm. Vol. 5, No. 6, November–December 1999 777773333377777 Emerging Infectious Diseases PPPPPeeeeerrrrrssssspppppeeeeeccccctttttiiiiivvvvveeeeesssss captive Central American (T.Y. James, D. Porter, J.E. Longcore, pers. comm.) amphibians belong to the genus Batrachochytrium, are probably conspecific, and form a distinct monophyletic clade within the Chytridiales. Emergence of Chytridiomycosis Retrospective histologic surveys of museum specimens of montane, riparian anurans from protected sites in Central America and Australia, conducted 1 to 10 years before the population declines, showed no evidence of chytrid infection, which suggests that chytridiomycosis has recently emerged on two continents (28). The relatively synchronous Figure 2. Scanning electron micrograph of digital discovery of chytridiomycosis in Australia and skin of a wild frog (Litoria lesueuri, from Queensland, Central America in association with amphibian Australia) that died of cutaneous chytridiomycosis. population declines is striking. The data suggest Many cells within this area of the superficial layer of that Batrachochytrium 1) may be endemic to the epidermis contain mature sporangia, and these regions and the amphibian deaths and unopened discharge tubes are visible protruding through infected cells. The skin was fixed in 2.5% declines attributed to it have only recently been glutaraldehyde, postfixed in 1% osmium tetroxide, discovered; 2) may be endemic and has recently dehydrated, critical-point-dried, sputter coated with become pathogenic (e.g., through an increase in gold, and examined with a JEOL JSM 840 scanning the organism’s prevalence or virulence, or a electron microscope at 5 kV. All specimens are from decrease in the host’s defenses), or 3) may have animals that were naturally infected and died due to been introduced recently into these geographic chytridiomycosis in montane rain forest regions of regions and is now parasitizing novel host species. Panama and Australia. Bar = 5 µm. The pattern of amphibian deaths and Photo courtesy of L. Berger, reprinted with permission from A. Campbell (29). population declines associated with chytridiomycosis is characteristic of an intro- Its occurrence solely in keratinized tissue duced virulent pathogen dispersing through a suggests that the chytrid uses amphibian naïve population (7,10,39). In Australia, a keratin as a nutrient. A hyperkeratotic and distinct geographic and temporal progression in hyperplastic response of the epidermis to population declines has occurred (20), moving infection (restricted to the stratum corneum and northward at a mean rate of 100 km per year stratum granulosum) usually coincides with the (39). In Central America, a progression from immediate location of chytrid developmental northern Costa Rica to western Panama stages. Inflammatory cell response is negligible. occurred from 1996 to 1998 (24,25). The uneven An isolate cultured from captive dendrobatid progression of declines in Australia (40) may frogs has recently been used to fulfil Koch’s reflect gaps in surveillance. Small-scale irregu- postulates as a fatal pathogen of frogs and has larities, however, characterize the epidemiology been described as a new genus and species, of many pandemics (43,44), within which Batrachochytrium dendrobatidis (42). Three individual epidemics progress at different rates mechanisms by which chytridiomycosis causes in different areas. In amphibian populations, death have been proposed (28): 1) epidermal unevenness may be due to differences in ecologic hyperplasia impairs essential cutaneous respira- factors (e.g., population density, habitat, age tion or osmoregulation; 2) a fungal toxin is structure); differences among pathogen strains; absorbed systemically (although a lack of clinical stochastic factors, such as the time of signs in infected larvae suggests otherwise); and introduction; or a combination of these factors. 3) these factors are combined (28,37). In Australia and Central America, population Comparison of histologic, ultrastructural, declines have been catastrophic, occurring over a and 18s rDNA sequence data indicates that the few months, with dramatic population loss and chytrids found in wild Australian (28) and high rates of adult deaths (20,24,25,28,39,40,45). Emerging Infectious Diseases 777773333388888 Vol. 5, No. 6, November–December 1999 PPPPPeeeeerrrrrssssspppppeeeeeccccctttttiiiiivvvvveeeeesssss Such high depopulation rates are characteristic The occurrence of chytridiomycosis in free- of introduced virulent pathogens (10). Con- living North American amphibians (Table 1) versely, in coevolved host-pathogen relation- suggests a less obvious pattern of dissemination ships, a degree of herd immunity to the pathogen than in Central America and Australia. This and lower virulence (infectivity and death rates) irregularity may be due to a paucity of data, the are normally observed. The low host specificity of pathogen’s being enzootic to the United States, amphibian chytridiomycosis (more than 30 or the pathogen’s introduction a number of years species of wild amphibians from seven families in before. Historical reports of declines in the Central America and Australia [28,29]) also United States include postmetamorphic death suggests that the disease was not enzootic in syndrome, which progressed in waves through those montane rain-forest populations. Ability to populations of amphibians, causing 90% to 100% infect a range of host species is a characteristic of death rates in recently metamorphosed animals many invading pathogens (10) and is less and low death rates in larvae (50). Recent reports common in endemic microparasites that have of chytridiomycosis-linked die-offs in Bufo boreas coevolved with their hosts. markedly resemble these previous die-offs. This The most parsimonious hypothesis for the observation and the finding that chytridiomycosis origin of chytridiomycosis panzootics in Austra- caused similar die-offs (of B. canorus and lia and Central America is the introduction of R. pipiens) in the 1970s (Table 1) (32), support disease into populations of previously unexposed the last of the above hypotheses. In the United amphibians. Introduction of pathogens, termed States an amphibian pathogen (histologically pathogen pollution (1), is increasingly recog- very similar to Batrachochytrium but identified nized as a significant threat to global biodiversity as Basidiobolus ranarum) has been described in (1,6,46) and forms an integral part of human wild Wyoming toads (Bufo hemiophrys baxteri) history (10,47). There are precedents for the (51) and captive dwarf African clawed frogs introduction of fungal pathogens (including (Hymenochirus curtipes) (52). As the latter chytrid parasites) that cause high death rates species was widely introduced in ornamental (41,48). Mechanisms by which wildlife patho- garden ponds throughout the United States in gens can be introduced are common; for example, the late 1980s, it may be involved in the a consequence of the increasing mobility of dissemination of Batrachochytrium. humans is the global translocation of wildlife, plants, soil, and ballast water (1,4,49,50). Chytridiomycosis as the Freshwater fish and amphibians are also Cause of Population Declines transported globally. In Australia, chytridiomycosis- The ability of a pathogen to cause local infected cane toads (Bufo marinus), a recently population declines resulting in local host introduced species, have been found (29), and in extinction requires a mechanism of persistence North America, bullfrogs (Rana catesbeiana) at low host densities. In epidemiologic models, and other species of amphibians have been highly virulent parasites rapidly suppress the translocated or introduced widely. Some host population density below a threshold value authors have suggested that tourists or fieldworkers required to maintain transmission, resulting in surveying amphibian populations may have the pathogen’s extinction and recovery of the facilitated the dissemination of Batrachochytrium host population (7,10). Microparasites such as (19), although this has not been demonstrated. Batrachochytrium, with their relatively short Batrachochytrium may have coevolved with some duration of infection and high death rates, have amphibians (e.g., lowland) species, populations of an increased threshold population density and which remain unaffected. Recent disturbances of are usually less able to persist. Many parasites rain forest habitats may have introduced this have evolved life history strategies for persis- parasite into naïve populations in Central America tence (10) and the presence of reservoir hosts and Australia, leading to mass deaths. This range may augment the impact of other introduced of disease outcomes parallels many diseases of wildlife diseases on host populations (46). The humans, e.g., measles and smallpox, which aclinical presence of Batrachochytrium in the produce a range of effects on persons in disease- keratinized mouthparts of amphibian larvae endemic regions and cause massive deaths when implicates this life-cycle stage as a reservoir host introduced into naïve populations (48). for the pathogen. This form of infection may Vol. 5, No. 6, November–December 1999 777773333399999 Emerging Infectious Diseases PPPPPeeeeerrrrrssssspppppeeeeeccccctttttiiiiivvvvveeeeesssss enable Batrachochytrium to persist in reduced well known (42). Furthermore, the ability to amphibian populations (Figure 3). In both develop and reproduce saprophytically is Australia and Central America, chytrid infection common to many other fungal (54) (including was observed in larval mouthparts months after chytrid [41]) and bacterial (55) pathogens. An initial adult deaths: the larvae of many tropical epidemiologic model of a host-parasite system for amphibian species survive 12 to 18 months—and pathogens that can reproduce saprophytically some temperate species as long as 3 years— clearly shows a lowering of the host threshold before metamorphosing. Examples of larval infection population, allowing the pathogen to drive the enhancing pathogen-mediated population declines host to extinction (55). Development of and leading to host population extinctions have Batrachochytrium for even short periods outside been reported for invertebrates (53). its amphibian host may greatly increase its Persistence may be further enhanced by impact and accelerate population declines. Long- saprophytic development (Figure 3). term presence as a saprophyte may explain the Batrachochytrium can be cultured in vitro on lack of recolonization of streams from which tryptone agar without the addition of keratin or amphibians have been extirpated in both its derivatives (37,42), and it will grow for at least Australia (29) and Central America (24,25). one generation on cleaned epidermal keratin or The impact of chytridiomycosis may be on amphibians that have died of the infection enhanced by the ecologic characteristics of (42). Batrachochytrium may survive and certain host species. In Australia, reproduce as a saprophytic organism in the chytridiomycosis-linked deaths have occurred in environment, at least for short periods. Keratin both declining and nondeclining species (28,29). (from decaying carcasses, shed skin, and other Species with declining populations belong to a sources) is widely distributed in the environ- similar ecologic guild: regionally endemic rain ment, and chytrids that use this substrate are forest specialists with low fecundity that Figure 3. Diagrammatic representation of the range of disease outcomes in populations of amphibians affected by a Batrachochytrium-like pathogen. Factors that hypothetically predispose some amphibian populations to declines are illustrated. In this model, host ecologic traits (left side of pyramid) and parasite biologic traits (right side of pyramid) combine to produce declines in a specific group of amphibian species that have low fecundity, are stream-breeding habitat specialists, and occur in montane regions. These characteristics predispose them to population declines after introduction of a waterborne pathogen with a low preferred developmental temperature and ability to persist at low host population densities.1 1Note that the relative number of mass deaths decreases with increasing impact on population. Emerging Infectious Diseases 777774444400000 Vol. 5, No. 6, November–December 1999 PPPPPeeeeerrrrrssssspppppeeeeeccccctttttiiiiivvvvveeeeesssss reproduce in streams and live at high altitudes may have allowed chytridiomycosis to cause (22). These characteristics, which are largely substantial deaths (57). Further work is required shared by declining Central American amphib- to test this hypothesis, since a drier climate ians (24,25), are predictors of increased impact would also predict a lower overall impact from from chytridiomycosis. Species that reproduce in chytridiomycosis—a disease transmitted by streams are probably more susceptible to a flagellated, waterborne zoospores. The evidence waterborne pathogen than terrestrial breeders. suggests that cofactors are not required for Low fecundity (56) and habitat specialization chytridiomycosis to cause amphibian mass indicate a reduced ability to recover from deaths. Chytridiomycosis is highly pathogenic to population declines caused by stochastic events, captive-bred amphibians exposed in captivity including disease introduction. Laurance, where control animals remained healthy (28,42). McDonald, and Speare (39) suggested that the Further experimental infections using extremely relation between high-altitude populations and small inocula (100 zoospores) also proved fatal (29). declines may be due to a pathogen with a lower Some deaths among wild amphibians have preferred developmental temperature. Prelimi- been attributed to immunosuppression, predis- nary data on cultured Batrachochytrium are posing them to infectious disease (13,32). In the consistent with this hypothesis: it develops most chytridiomycosis-related deaths, chytridiomycosis rapidly at 23oC in culture, with slower growth at was consistently found as the cause of death, and 28oC and reversible cessation of growth at 29oC the range of opportunistic infections expected to (42). The growth rate of Batrachochytrium in the occur in immunocompromised animals was not skin (and therefore virulence) and the survival of found (28,29). An increase in UV-B irradiation zoospores outside the host (and therefore may influence amphibian declines (58), but in transmission rate) are likely to be lower in the subtropical regions of Australia and Central amphibians from the warmer lowland regions. America, data demonstrate no significant The ability of the pathogen to survive increase in UV irradiation (29,59). Even so, the saprophytically in the environment and for the potentional effect of increased irradiation on disease to persist may also be enhanced in the montane riparian rain forest amphibians is cooler montane regions. These laboratory data uncertain, since these animals lay eggs under may explain why chytridiomycosis has been rocks or in sand banks and adults are rarely associated with population declines in North exposed to direct sunlight (24,29). Furthermore, American amphibians in montane localities in these regions, the species most likely to be (31,32) and after periods of cool weather at many affected by UV increases (arboreal amphibians, U.S. and Australian sites (29,31). which bask or lay exposed eggs) are not in decline (20). Despite extensive research, chemical Potential Environmental Cofactors in the pollution (20,25), habitat destruction (22), or Emergence of Chytridiomycosis climate change (57) have not, so far, been Multiple factors (host, pathogen, environ- causally linked either to the Australian declines mental) may be involved in chytridiomycosis or to those at Central American sites other than emergence. Some authors have hypothesized Monteverde. No other possible cofactors, such as that infectious disease is only the proximate sympatric pathogens, have been found. cause of declines and that environmental factors such as increased UV-B, chemical pollution, Emerging Viral Diseases of Amphibians climate change, or stress may have predisposed Iridoviruses have been implicated as the amphibian populations to opportunistic patho- cause of amphibian mass deaths worldwide, with gens (13,32,57). Recent work at Monteverde, novel iridoviruses of amphibians recently identi- Costa Rica, suggests that atmospheric warming, fied from a number of regions (Tables 1, 2). The with a resultant elevation of the average altitude Iridoviridae encompass five recognized genera: of the base of the orographic cloud bank and an Iridovirus, Chloriridovirus, Ranavirus, increase in dry periods, is causally linked to Lymphocystivirus, and goldfish virus 1-like amphibian declines at this site (57). Although no viruses (71). Of these, the genus Ranavirus pathologic studies of amphibians were under- contains pathogens of fish, amphibians, and taken, overcrowding during periods of drought reptiles (Table 2; Figure 4). Vol. 5, No. 6, November–December 1999 777774444411111 Emerging Infectious Diseases

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reported in terrestrial (1) and marine (6) habitats and are Transdermal . A role for chytridiomycosis in other recent W. Australian declines is suspected due to similarities in the pattern of .. with feed from fish farms (77). tive wetlands in the Kakadu National Park. The .. A model of insect-pa
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