Your search keyword '"Garner TWJ"' showing total 46 results

1. Amphibian chytridiomycosis outbreak dynamics are linked with host skin bacterial community structure

Author

Bates, KA, Clare, FC, O’Hanlon, S, Bosch, J, Brookes, L, Hopkins, K, McLaughlin, EJ, Daniel, O, Garner, TWJ, Fisher, MC, and Harrison, XA

Subjects

Microbial ecology, Ecological epidemiology, Herpetology, Science, lcsh:Q, lcsh:Science

Abstract

© The Author(s)., Host-associated microbes are vital for combatting infections and maintaining health. In amphibians, certain skin-associated bacteria inhibit the fungal pathogen Batrachochytrium dendrobatidis (Bd), yet our understanding of host microbial ecology and its role in disease outbreaks is limited. We sampled skin-associated bacteria and Bd from Pyrenean midwife toad populations exhibiting enzootic or epizootic disease dynamics. We demonstrate that bacterial communities differ between life stages with few shared taxa, indicative of restructuring at metamorphosis. We detected a significant effect of infection history on metamorph skin microbiota, with reduced bacterial diversity in epizootic populations and differences in community structure and predicted function. Genome sequencing of Bd isolates supports a single introduction to the Pyrenees and reveals no association between pathogen genetics and epidemiological trends. Our findings provide an ecologically relevant insight into the microbial ecology of amphibian skin and highlight the relative importance of host microbiota and pathogen genetics in predicting disease outcome., K.A.B. was funded by a CASE studentship from NERC; M.C.F. and T.W. J.G. were funded by the NERC award NE/E006701/1 and the Biodiversa project RACE: Risk Assessment of Chytridiomycosis to European Amphibian Biodiversity.

Published

2018

2. Occurrence of Batrachochytrium dendrobatidis in Sweden: higher infection prevalence in southern species

Author

Meurling, S, primary, Kärvemo, S, additional, Chondrelli, N, additional, Cortazar Chinarro, M, additional, Åhlen, D, additional, Brookes, L, additional, Nyström, P, additional, Stenberg, M, additional, Garner, TWJ, additional, Höglund, J, additional, and Laurila, A, additional

Published

2020

3. Development and worldwide use of non-lethal, and minimal population-level impact, protocols for the isolation of amphibian chytrid fungi

Author

Fisher, MC, Ghosh, P, Shelton, JMG, Bates, K, Brookes, L, Wierzbicki, C, Rosa, GM, Farrer, RA, Aanensen, DM, Alvarado-Rybak, M, Bataille, A, Berger, L, Boell, S, Bosch, J, Clare, FC, Courtois, EA, Crottini, A, Cunningham, AA, Doherty-Bone, TM, Gebresenbet, F, Gower, DJ, Hoglund, J, James, TY, Jenkinson, TS, Kosch, TA, Lambertini, C, Laurila, A, Lin, C-F, Loyau, A, Martel, A, Meurling, S, Miaud, C, Minting, P, Ndriantsoa, S, O'Hanlon, SJ, Pasmans, F, Rakotonanahary, T, Rabemananjara, FCE, Ribeiro, LP, Schmeller, DS, Schmidt, BR, Skerratt, L, Smith, F, Soto-Azat, C, Tessa, G, Toledo, LF, Valenzuela-Sanchez, A, Verster, R, Voeroes, J, Waldman, B, Webb, RJ, Weldon, C, Wombwell, E, Zamudio, KR, Longcore, JE, Garner, TWJ, Fisher, MC, Ghosh, P, Shelton, JMG, Bates, K, Brookes, L, Wierzbicki, C, Rosa, GM, Farrer, RA, Aanensen, DM, Alvarado-Rybak, M, Bataille, A, Berger, L, Boell, S, Bosch, J, Clare, FC, Courtois, EA, Crottini, A, Cunningham, AA, Doherty-Bone, TM, Gebresenbet, F, Gower, DJ, Hoglund, J, James, TY, Jenkinson, TS, Kosch, TA, Lambertini, C, Laurila, A, Lin, C-F, Loyau, A, Martel, A, Meurling, S, Miaud, C, Minting, P, Ndriantsoa, S, O'Hanlon, SJ, Pasmans, F, Rakotonanahary, T, Rabemananjara, FCE, Ribeiro, LP, Schmeller, DS, Schmidt, BR, Skerratt, L, Smith, F, Soto-Azat, C, Tessa, G, Toledo, LF, Valenzuela-Sanchez, A, Verster, R, Voeroes, J, Waldman, B, Webb, RJ, Weldon, C, Wombwell, E, Zamudio, KR, Longcore, JE, and Garner, TWJ

Abstract

Parasitic chytrid fungi have emerged as a significant threat to amphibian species worldwide, necessitating the development of techniques to isolate these pathogens into culture for research purposes. However, early methods of isolating chytrids from their hosts relied on killing amphibians. We modified a pre-existing protocol for isolating chytrids from infected animals to use toe clips and biopsies from toe webbing rather than euthanizing hosts, and distributed the protocol to researchers as part of the BiodivERsA project RACE; here called the RML protocol. In tandem, we developed a lethal procedure for isolating chytrids from tadpole mouthparts. Reviewing a database of use a decade after their inception, we find that these methods have been applied across 5 continents, 23 countries and in 62 amphibian species. Isolation of chytrids by the non-lethal RML protocol occured in 18% of attempts with 207 fungal isolates and three species of chytrid being recovered. Isolation of chytrids from tadpoles occured in 43% of attempts with 334 fungal isolates of one species (Batrachochytrium dendrobatidis) being recovered. Together, these methods have resulted in a significant reduction and refinement of our use of threatened amphibian species and have improved our ability to work with this group of emerging pathogens.

Published

2018

4. Disease mediated changes to life history and demography threaten the survival of European amphibian populations

Author

Lena Wilfert, Benjamin C. Scheele, Giulia Tessa, Garner Twj, Lewis J. Campbell, Xavier A. Harrison, and Amber G. F. Griffiths

Subjects

Amphibian, education.field_of_study, biology, biology.animal, Threatened species, Population projection, Population, European common frog, Skeletochronology, Disease, education, Demography, Life history theory

Abstract

Infectious diseases can influence the life history strategy of their hosts and such influences subsequently impact the demography of infected populations, reducing viability independently of increased mortality or morbidity. Amphibians are the most threatened group of vertebrates and emerging infectious diseases play a large role in their population declines. Viruses of genus Ranavirus are responsible for one of the deadliest of these diseases. To date no work has evaluated the impact of ranaviruses on host life-history post metamorphosis or population demographic structure at the individual level. In this study, we used skeletochronology and morphology to evaluate the impact of ranaviruses on the demography of populations of European common frog (Rana temporaria) in the United Kingdom. We compared ecologically similar populations that differed only in their historical presence or absence of ranaviral disease. Our results suggest that ranaviruses are associated with shifts in the age structure of infected populations, potentially caused by increased adult mortality and associated shifts in the life history of younger age classes. Population projection models indicate that such age truncation could heighten the vulnerability of frog populations to stochastic environmental challenges. Our individual level data provide further compelling evidence that the emergence of infectious diseases can alter host demography, subsequently increasing population vulnerability to additional stressors.

Published

2017

5. Host Microbiome Richness Predicts Resistance to Disturbance by Pathogenic Infection in a Vertebrate Host

Author

Leung Wtm, Kevin Hopkins, Xavier A. Harrison, Stephen J. Price, Chris Sergeant, and Garner Twj

Subjects

Resistance (ecology), Host (biology), Ecology (disciplines), biology.animal, Ranavirus, Zoology, Vertebrate, Disease, Species richness, Microbiome, Biology, biology.organism_classification

Abstract

Environmental heterogeneity is known to modulate the interactions between pathogens and hosts. However, the impact of environmental heterogeneity on the structure of host-associated microbial communities, and how these communities respond to pathogenic exposure remain poorly understood. Here we use an experimental framework to probe the links between environmental heterogeneity, skin microbiome structure and infection by the emerging pathogenRanavirusin a vertebrate host, the European common frog (Rana temporaria). We provide evidence that environmental complexity directly influences the diversity and structure of the host skin microbiome, and that more diverse microbiomes are more resistant to perturbation associated with exposure toRanavirus. Our data also indicate that host microbiome diversity covaries with survival following exposure toRanavirus. Our study highlights the importance of extrinsic factors in driving host-pathogen dynamics in vertebrate hosts, and suggests that environment-mediated variation in the structure of the host microbiome may covary with observed differences in host susceptibility to disease in the wild.

Published

2017

6. Itraconazole and thiophanate-methyl fail to clear tadpoles naturally infected with the hypervirulent lineage of Batrachochytrium dendrobatidis

Author

Fernández-Loras, A, primary, Martín-Beyer, B, additional, Garner, TWJ, additional, and Bosch, J, additional

Published

2018

7. Delayed metamorphosis of amphibian larvae facilitates Batrachochytrium dendrobatidis transmission and persistence

Author

Medina, D, primary, Garner, TWJ, additional, Carrascal, LM, additional, and Bosch, J, additional

Published

2015

8. Multiple emergences of amphibian chytridiomycosis include a globalised hypervirulent recombinant lineage

Author

Farrer RA, Weinert LA, Bielby J, Garner TWJ, Balloux F, Clare F, Bosch J, Cunningham AA, Weldon C, du Preez LH, Anderson L, Kosakovsky Pond SL, Shahar-Golan R, Henk DA and MC Fisher

Published

2011

9. Polygyny, census and effective population size in the threatened frog, Rana latastei

Author

FICETOLA, GENTILE FRANCESCO, PADOA SCHIOPPA, EMILIO, Wang, J, Garner, TWJ, Ficetola, G, PADOA SCHIOPPA, E, Wang, J, and Garner, T

Subjects

Social plasticity, Genetic compensation, Reproductive succe, Mating system, BIO/07 - ECOLOGIA, Conservation genetic, Genetic diversity, BIO/05 - ZOOLOGIA

Abstract

Effective population size (Ne) is a key determinant of genetic diversity of populations. In amphibians, the ratio effective population size/census size (Ne/N) is often very low, raising concerns for the long-term persistence of genetic diversity in isolated populations. It has been proposed that the phenomenon of 'genetic compensation' increases the ratio Ne/N in small populations, but the underlying mechanisms are poorly understood. Polygyny can decrease Ne/N because of the negative relationship between polygyny and Ne. We used genetic information (microsatellites) to evaluate the relationship between census size, polygyny and Ne in populations of the threatened Italian agile frog Rana latastei. We reconstructed parentage in tadpoles from nine populations with eight to 32 breeding females, using a likelihood-based method; we analysed simulated datasets with known properties to confirm the reliability of this approach in reconstructing polygyny. Furthermore, we estimated Ne using approximate Bayesian computation. The level of polygyny differed strongly among populations (average number of mates per breeding male: 2-6.4). Polygyny was greater in populations with larger census sizes. Moreover, variance in male mating success was larger in large populations. Effective population size increased with population size, but was negatively related to polygyny; as polygyny increased in large populations, this was associated with reduced Ne/N. In polygynous species, increasing levels of polygyny in large populations may explain the low Ne/N values, with important implications for the conservation of genetic diversity and for long-term population persistence. © 2009 The Authors. Journal compilation © 2009 The Zoological Society of London.

Published

2010

10. Polygyny, census and effective population size in the threatened frog, Rana latastei

Author

Ficetola, G, PADOA SCHIOPPA, E, Wang, J, Garner, T, FICETOLA, GENTILE FRANCESCO, PADOA SCHIOPPA, EMILIO, Garner, TWJ, Ficetola, G, PADOA SCHIOPPA, E, Wang, J, Garner, T, FICETOLA, GENTILE FRANCESCO, PADOA SCHIOPPA, EMILIO, and Garner, TWJ

Abstract

Effective population size (Ne) is a key determinant of genetic diversity of populations. In amphibians, the ratio effective population size/census size (Ne/N) is often very low, raising concerns for the long-term persistence of genetic diversity in isolated populations. It has been proposed that the phenomenon of 'genetic compensation' increases the ratio Ne/N in small populations, but the underlying mechanisms are poorly understood. Polygyny can decrease Ne/N because of the negative relationship between polygyny and Ne. We used genetic information (microsatellites) to evaluate the relationship between census size, polygyny and Ne in populations of the threatened Italian agile frog Rana latastei. We reconstructed parentage in tadpoles from nine populations with eight to 32 breeding females, using a likelihood-based method; we analysed simulated datasets with known properties to confirm the reliability of this approach in reconstructing polygyny. Furthermore, we estimated Ne using approximate Bayesian computation. The level of polygyny differed strongly among populations (average number of mates per breeding male: 2-6.4). Polygyny was greater in populations with larger census sizes. Moreover, variance in male mating success was larger in large populations. Effective population size increased with population size, but was negatively related to polygyny; as polygyny increased in large populations, this was associated with reduced Ne/N. In polygynous species, increasing levels of polygyny in large populations may explain the low Ne/N values, with important implications for the conservation of genetic diversity and for long-term population persistence. © 2009 The Authors. Journal compilation © 2009 The Zoological Society of London.

Published

2010

11. Determining Causality and Controlling Disease is Based on Collaborative Research involving Multidisciplinary Approaches

Author

Skerratt, LF, Garner, TWJ, Hyatt, AD, Skerratt, LF, Garner, TWJ, and Hyatt, AD

Abstract

Understanding the causes of infectious disease to facilitate better control requires observational and experimental studies. Often these must be conducted at many scales such as at the molecular, cellular, organism, and population level. Studies need to consider both intrinsic and extrinsic factors affecting the pathogen/host interaction. They also require a combination of study methods covered by disciplines such as pathology, epidemiology, microbiology, and ecology. Therefore, it is important that disciplines work together when designing and conducting studies. Finally, we need to integrate and interpret data across levels and disciplines to better formulate control strategies. This requires another group of specialists with broad cross-disciplinary training in epidemiology and an ability to readily work with others.

Published

2009

12. Using itraconazole to clear Batrachochytrium dendrobatidis infection, and subsequent depigmentation of Alytes muletensis tadpoles

Author

Garner, TWJ, primary, Garcia, G, additional, Carroll, B, additional, and Fisher, MC, additional

Published

2009

13. Environmental detection of Batrachochytrium dendrobatidis in a temperate climate

Author

Walker, SF, primary, Baldi Salas, M, additional, Jenkins, D, additional, Garner, TWJ, additional, Cunningham, AA, additional, Hyatt, AD, additional, Bosch, J, additional, and Fisher, MC, additional

Published

2007

14. Infections on the move: how transient phases of host movement influence disease spread

Author

Daversa, DR, Fenton, A, Dell, AI, Garner, TWJ, and Manica, A

Subjects

spatial modelling, networks, host–parasite interactions, Animals, epidemiology, Animals, Wild, 15. Life on land, movement, Animal Distribution, Models, Biological, metapopulations, Animal Diseases, Host-Parasite Interactions

Abstract

Animal movement impacts the spread of human and wildlife diseases, and there is significant interest in understanding the role of migrations, biological invasions and other wildlife movements in spatial infection dynamics. However, the influence of processes acting on infections during transient phases of host movement is poorly understood. We propose a conceptual framework that explicitly considers infection dynamics during transient phases of host movement to better predict infection spread through spatial host networks. Accounting for host transient movement captures key processes that occur while hosts move between locations, which together determine the rate at which hosts spread infections through networks. We review theoretical and empirical studies of host movement and infection spread, highlighting the multiple factors that impact the infection status of hosts. We then outline characteristics of hosts, parasites and the environment that influence these dynamics. Recent technological advances provide disease ecologists unprecedented ability to track the fine-scale movement of organisms. These, in conjunction with experimental testing of the factors driving infection dynamics during host movement, can inform models of infection spread based on constituent biological processes.

15. Infections on the move: how transient phases of host movement influence disease spread

Author

Twj Garner, Andrea Manica, Andy Fenton, Daversa, Anthony I. Dell, Daversa, DR [0000-0002-8984-8897], Garner, TWJ [0000-0002-0336-9706], Manica, A [0000-0003-1895-450X], and Apollo - University of Cambridge Repository

Subjects

0106 biological sciences, 0301 basic medicine, Animal Distribution, spatial modelling, Wildlife, Metapopulation, Animals, Wild, Disease, Review Article, Biology, 010603 evolutionary biology, 01 natural sciences, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Animal Diseases, Host-Parasite Interactions, 03 medical and health sciences, host–parasite interactions, Animals, Transient (computer programming), Review Articles, General Environmental Science, General Immunology and Microbiology, Movement (music), Ecology, General Medicine, 15. Life on land, 030104 developmental biology, networks, Infection dynamics, epidemiology, movement, General Agricultural and Biological Sciences, Host (network), metapopulations

Abstract

Animal movement impacts the spread of human and wildlife diseases, and there is significant interest in understanding the role of migrations, biological invasions and other wildlife movements in spatial infection dynamics. However, the influence of processes acting on infections during transient phases of host movement is poorly understood. We propose a conceptual framework that explicitly considers infection dynamics during transient phases of host movement to better predict infection spread through spatial host networks. Accounting for host transient movement captures key processes that occur while hosts move between locations, which together determine the rate at which hosts spread infections through networks. We review theoretical and empirical studies of host movement and infection spread, highlighting the multiple factors that impact the infection status of hosts. We then outline characteristics of hosts, parasites and the environment that influence these dynamics. Recent technological advances provide disease ecologists unprecedented ability to track the fine-scale movement of organisms. These, in conjunction with experimental testing of the factors driving infection dynamics during host movement, can inform models of infection spread based on constituent biological processes.

Published

2017

16. Archival mitogenomes identify invasion by the Batrachochytrium dendrobatidis CAPE lineage caused an African amphibian extinction in the wild.

Author

Sewell TR, van Dorp L, Ghosh PN, Wierzbicki C, Caroe C, Lyakurwa JV, Tonelli E, Bowkett AE, Marsden S, Cunningham AA, Garner TWJ, Gilbert TP, Moyer D, Weldon C, and Fisher MC

Subjects

Animals, Anura microbiology, Tanzania, Bufonidae microbiology, Chytridiomycota physiology, Batrachochytrium, Mycoses veterinary, Mycoses epidemiology, Mycoses microbiology, Extinction, Biological, Genome, Mitochondrial

Abstract

Outbreaks of emerging infectious diseases are influenced by local biotic and abiotic factors, with host declines occurring when conditions favour the pathogen. Deterioration in the population of the micro-endemic Tanzanian Kihansi spray toad ( Nectophrynoides asperginis ) occurred after the construction of a hydropower dam, implicating habitat modification in this species decline. Population recovery followed habitat augmentation; however, a subsequent outbreak of chytridiomycosis caused by Batrachochytrium dendrobatidis ( Bd ) led to the spray toad's extinction in the wild. We show using spatiotemporal surveillance and mitogenome assembly of Bd from archived toad mortalities that the outbreak was caused by invasion of the Bd CAPE lineage and not the panzootic lineage Bd GPL. Molecular dating reveals an emergence of Bd CAPE across southern Africa overlapping with the timing of the spray toad's extinction. That our post-outbreak surveillance of co-occurring amphibian species in the Udzungwa Mountains shows widespread infection by Bd CAPE yet no signs of ill-health or decline suggests these other species can tolerate Bd when environments are stable. We conclude that, despite transient success in mitigating the impact caused by dams' construction, invasion by Bd CAPE caused the ultimate die-off that led to the extinction of the Kihansi spray toad.

Published

2024

17. Environment predicts Batrachochytrium dendrobatidis lineage distribution and zones of recombination in South Africa.

Author

Verster R, Ghosh PN, Sewell TR, Garner TWJ, Fisher MC, Muller W, Cilliers D, and Weldon C

Abstract

The amphibian-infecting chytrid fungus, Batrachochytrium dendrobatidis ( Bd ), is widespread throughout Africa and is linked to declines of populations and species across the continent. While it is well established that the lineage of Bd encodes traits which determine disease severity, knowledge around how lineages are distributed according to environmental envelope is unclear. We here studied the distribution of Bd in South Africa based on the two lineages found, Bd GPL and Bd CAPE, in terms of their genome and environmental envelope statistically associated with their distribution. We used Bd surveillance data from published studies, as well as data collected during fieldwork from across South Africa, Lesotho, and eSwatini with samples collected along a transect spanning most of South Africa from Lesotho to the west coast. We utilized lineage-typing qPCR to resolve the spatial distribution of Bd GPL and Bd CAPE across South Africa and used the resulting surveillance data to create a predictive ecological niche model for Bd lineages in South Africa. Phylogenomic analyses were performed on isolates sourced from across the transect. We show that Bd GPL demonstrates a strong isolation by distance suggestive of stepping-stone dispersal, while Bd CAPE showed two distinct clusters within their genomic structure that appear geographically and temporally clustered, indicating two separate invasions. Our predictive niche model revealed that the two lineages tended to occur in different ecotypes; Bd GPL was associated with lower altitude, arid regions while Bd CAPE occurred across cooler, higher altitude environs. Niche predictions identified a zone of lineage contact, where genomics identified inter-lineage recombinants. We argue that this zone of recombination should be prioritized for disease surveillance as it is a potential hotspot for the evolution of variants of amphibian chytrid with novel traits that may be epidemiologically relevant., (© 2024 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2024

18. Non-Lethal Detection of Frog Virus 3 -Like (RUK13) and Common Midwife Toad Virus -Like (PDE18) Ranaviruses in Two UK-Native Amphibian Species.

Author

Ford CE, Brookes LM, Skelly E, Sergeant C, Jordine T, Balloux F, Nichols RA, and Garner TWJ

Subjects

Animals, Anura, United Kingdom, Ranavirus genetics, DNA Virus Infections diagnosis, DNA Virus Infections veterinary, DNA Virus Infections epidemiology

Abstract

Ranaviruses have been involved in amphibian mass mortality events worldwide. Effective screening to control this pathogen is essential; however, current sampling methods are unsuitable for the detection of subclinical infections. Non-lethal screening is needed to prevent both further spread of ranavirus and losses of at-risk species. To assess non-lethal sampling methods, we conducted two experiments: bath exposing common frogs to RUK13 ranavirus at three concentrations, and exposing common toads to RUK13 or PDE18. Non-lethal sampling included buccal, digit, body and tank swabs, along with toe clips and stool taken across three time-points post-exposure. The presence/load of ranavirus was examined using quantitative PCR in 11 different tissues obtained from the same euthanised animals (incl. liver, gastro-intestinal tract and kidney). Buccal swab screening had the highest virus detection rate in both species (62% frogs; 71% toads) and produced consistently high virus levels compared to other non-lethal assays. The buccal swab was effective across multiple stages of infection and differing infection intensities, though low levels of infection were more difficult to detect. Buccal swab assays competed with, and even outperformed, lethal sampling in frogs and toads, respectively. Successful virus detection in the absence of clinical signs was observed (33% frogs; 50% toads); we found no difference in detectability for RUK13 and PDE18. Our results suggest that buccal swabbing could replace lethal sampling for screening and be introduced as standard practice for ranavirus surveillance., Competing Interests: The authors declare no conflicts of interest.

Published

2022

19. Climate anomalies and competition reduce establishment success during island colonization.

Author

Nicholson DJ, Knell RJ, McCrea RS, Neel LK, Curlis JD, Williams CE, Chung AK, McMillan WO, Garner TWJ, Cox CL, and Logan ML

Abstract

Understanding the factors that facilitate or constrain establishment of populations in novel environments is crucial for conservation biology and the study of adaptive radiation. Important questions include: (1) Does the timing of colonization relative to stochastic events, such as climatic perturbations, impact the probability of successful establishment? (2) To what extent does community context (e.g., the presence of competitors) change the probability of establishment? (3) How do sources of intrapopulation variance, such as sex differences, affect success at an individual level during the process of establishment? Answers to these questions are rarely pursued in a field-experimental context or on the same time scales (months to years) as the processes of colonization and establishment. We introduced slender anole lizards ( Anolis apletophallus ) to eight islands in the Panama Canal and tracked them over multiple generations to investigate the factors that mediate establishment success. All islands were warmer than the mainland (ancestral) environment, and some islands had a native competitor. We transplanted half of these populations only 4 months before the onset of a severe regional drought and the other half 2 years (two generations) before the drought. We found that successful establishment depended on both the intensity of interspecific competition and the timing of colonization relative to the drought. The islands that were colonized shortly before the drought went functionally extinct by the second generation, and regardless of time before the drought, the populations on islands with interspecific competition declined continuously over the study period. Furthermore, the effect of the competitor interacted with sex, with males suffering, and females benefitting, from the presence of a native competitor. Our results reveal that community context and the timing of colonization relative to climactic events can combine to determine establishment success and that these factors can generate opposite effects on males and females., Competing Interests: All authors declare no competing interests., (© 2022 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2022

20. Host Identity Matters-Up to a Point: The Community Context of Batrachochytrium dendrobatidis Transmission.

Author

Daversa DR, Bosch J, Manica A, Garner TWJ, and Fenton A

Subjects

Animals, Anura, Batrachochytrium, Bufonidae microbiology, Larva microbiology, Urodela, Chytridiomycota

Abstract

AbstractThe level of detail on host communities needed to understand multihost parasite invasions is an unresolved issue in disease ecology. Coarse community metrics that ignore functional differences between hosts, such as host species richness, can be good predictors of invasion outcomes. Yet if host species vary in the extent to which they maintain and transmit infections, then explicitly accounting for those differences may be important. Through controlled mesocosm experiments and modeling, we show that interspecific differences between host species are important for community-wide infection dynamics of the multihost fungal parasite of amphibians ( Batrachochytrium dendrobatidis [ Bd ]), but only up to a point. The most abundant host species in our system, fire salamander larvae ( Salamandra salamandra ), did not maintain or transmit infections. Rather, two less abundant "auxiliary" host species, Iberian tree frog ( Hyla molleri ) and spiny toad ( Bufo spinosus ) larvae, maintained and transmitted Bd . Frogs had the highest mean rates of Bd shedding, giving them the highest contributions to the basic reproduction number, R 0 . Toad contributions to R 0 were substantial, however, and when examining community-level patterns of infection and transmission, the effects of frogs and toads were similar. Specifying more than just host species richness to distinguish salamanders from auxiliary host species was critical for predicting community-level Bd prevalence and transmission. Distinguishing frogs from toads, however, did not improve predictions. These findings demonstrate limitations to the importance of host species identities in multihost infection dynamics. Host species that exhibit different functional traits, such as susceptibility and infectiousness, may play similar epidemiological roles in the broader community.

Published

2022

21. Challenging a host-pathogen paradigm: Susceptibility to chytridiomycosis is decoupled from genetic erosion.

Author

Smith D, O'Brien D, Hall J, Sergeant C, Brookes LM, Harrison XA, Garner TWJ, and Jehle R

Subjects

Amphibians, Animals, Humans, Chytridiomycota genetics, Mycoses epidemiology, Mycoses microbiology

Abstract

The putatively positive association between host genetic diversity and the ability to defend against pathogens has long attracted the attention of evolutionary biologists. Chytridiomycosis, a disease caused by the chytrid fungus Batrachochytrium dendrobatidis (Bd), has emerged in recent decades as a cause of dramatic declines and extinctions across the amphibian clade. Bd susceptibility can vary widely across populations of the same species, but the relationship between standing genetic diversity and susceptibility has remained notably underexplored so far. Here, we focus on a putatively Bd-naive system of two mainland and two island populations of the common toad (Bufo bufo) at the edge of the species' range and use controlled infection experiments and dd-RAD sequencing of >10 000 SNPs across 95 individuals to characterize the role of host population identity, genetic variation and individual body mass in mediating host response to the pathogen. We found strong genetic differentiation between populations and marked variation in their susceptibility to Bd. This variation was not, however, governed by isolation-mediated genetic erosion, and individual heterozygosity was even found to be negatively correlated with survival. Individual survival during infection experiments was strongly positively related to body mass, which itself was unrelated to population of origin or heterozygosity. Our findings underscore the general importance of context-dependency when assessing the role of host genetic variation for the ability of defence against pathogens., (© 2022 The Authors. Journal of Evolutionary Biology published by John Wiley & Sons Ltd on behalf of European Society for Evolutionary Biology.)

Published

2022

22. Microbiome function predicts amphibian chytridiomycosis disease dynamics.

Author

Bates KA, Sommer U, Hopkins KP, Shelton JMG, Wierzbicki C, Sergeant C, Tapley B, Michaels CJ, Schmeller DS, Loyau A, Bosch J, Viant MR, Harrison XA, Garner TWJ, and Fisher MC

Subjects

Animals, Anura genetics, Anura microbiology, RNA, Ribosomal, 16S genetics, Chytridiomycota genetics, Microbiota genetics, Mycoses microbiology, Mycoses veterinary

Abstract

Background: The fungal pathogen Batrachochytrium dendrobatidis (Bd) threatens amphibian biodiversity and ecosystem stability worldwide. Amphibian skin microbial community structure has been linked to the clinical outcome of Bd infections, yet its overall functional importance is poorly understood., Methods: Microbiome taxonomic and functional profiles were assessed using high-throughput bacterial 16S rRNA and fungal ITS2 gene sequencing, bacterial shotgun metagenomics and skin mucosal metabolomics. We sampled 56 wild midwife toads (Alytes obstetricans) from montane populations exhibiting Bd epizootic or enzootic disease dynamics. In addition, to assess whether disease-specific microbiome profiles were linked to microbe-mediated protection or Bd-induced perturbation, we performed a laboratory Bd challenge experiment whereby 40 young adult A. obstetricans were exposed to Bd or a control sham infection. We measured temporal changes in the microbiome as well as functional profiles of Bd-exposed and control animals at peak infection., Results: Microbiome community structure and function differed in wild populations based on infection history and in experimental control versus Bd-exposed animals. Bd exposure in the laboratory resulted in dynamic changes in microbiome community structure and functional differences, with infection clearance in all but one infected animal. Sphingobacterium, Stenotrophomonas and an unclassified Commamonadaceae were associated with wild epizootic dynamics and also had reduced abundance in laboratory Bd-exposed animals that cleared infection, indicating a negative association with Bd resistance. This was further supported by microbe-metabolite integration which identified functionally relevant taxa driving disease outcome, of which Sphingobacterium and Bd were most influential in wild epizootic dynamics. The strong correlation between microbial taxonomic community composition and skin metabolome in the laboratory and field is inconsistent with microbial functional redundancy, indicating that differences in microbial taxonomy drive functional variation. Shotgun metagenomic analyses support these findings, with similar disease-associated patterns in beta diversity. Analysis of differentially abundant bacterial genes and pathways indicated that bacterial environmental sensing and Bd resource competition are likely to be important in driving infection outcomes., Conclusions: Bd infection drives altered microbiome taxonomic and functional profiles across laboratory and field environments. Our application of multi-omics analyses in experimental and field settings robustly predicts Bd disease dynamics and identifies novel candidate biomarkers of infection. Video Abstract., (© 2022. The Author(s).)

Published

2022

23. Exposure to Batrachochytrium dendrobatidis affects chemical defences in two anuran amphibians, Rana dalmatina and Bufo bufo.

Author

Ujszegi J, Ludányi K, Móricz ÁM, Krüzselyi D, Drahos L, Drexler T, Németh MZ, Vörös J, Garner TWJ, and Hettyey A

Subjects

Animals, Anura, Batrachochytrium, Humans, Ranidae, Bufo bufo, Chytridiomycota

Abstract

Background: Batrachochytrium dendrobatidis (Bd) is the causative agent of chytridiomycosis, one of the major causes of worldwide amphibian biodiversity loss. Many amphibians exhibit skin-based chemical defences, which may play an important role against invading pathogens, but whether the synthesis of these chemical compounds is enhanced or suppressed in the presence of pathogens is largely unknown. Here we investigated direct and indirect effects of larval exposure to the globally distributed and highly virulent Bd-GPL strain on skin secreted chemical defences and life history traits during early ontogeny of agile frogs (Rana dalmatina) and common toads (Bufo bufo)., Results: Exposure to Bd during the larval stage did not result in enhanced synthesis of the antimicrobial peptide Brevinin-1 Da in R. dalmatina tadpoles or in increased production of bufadienolides in B. bufo tadpoles. However, exposure to Bd during the larval stage had a carry-over effect reaching beyond metamorphosis: both R. dalmatina and B. bufo froglets contained smaller quantities of defensive chemicals than their Bd-naïve conspecifics in the control treatment. Prevalence of Bd and infection intensities were very low in both larvae and metamorphs of R. dalmatina, while in B. bufo we observed high Bd prevalence and infection intensities, especially in metamorphs. At the same time, we did not find a significant effect of Bd-exposure on body mass or development rate in larvae or metamorphs in either species., Conclusions: The lack of detrimental effect of Bd-exposure on life history traits, even parallel with high infection intensities in the case of B. bufo individuals, is surprising and suggests high tolerance of local populations of these two species against Bd. However, the lowered quantity of defensive chemicals may compromise antimicrobial and antipredatory defences of froglets, which may ultimately contribute to population declines also in the absence of conspicuous mass-mortality events.

Published

2021

24. Discriminating lineages of Batrachochytrium dendrobatidis using quantitative PCR.

Author

Ghosh PN, Verster R, Sewell TR, O'Hanlon SJ, Brookes LM, Rieux A, Garner TWJ, Weldon C, and Fisher MC

Subjects

Africa, Southern, Animals, Batrachochytrium pathogenicity, Polymerase Chain Reaction, Virulence, Amphibians microbiology, Batrachochytrium genetics, Mycoses veterinary

Abstract

The ability to detect and monitor infectious disease in a phylogenetically informative manner is critical for their management. Phylogenetically informative diagnostic tests enable patterns of pathogen introduction or changes in the distribution of genotypes to be measured, enabling research into the ecology of the pathogen. Batrachochytrium dendrobatidis (Bd), a causative agent of chytridiomycosis in amphibian populations, emerged worldwide in the 21st century and is composed of six lineages which are display varying levels of virulence in their hosts. Research into the distribution, ecology and pathogenicity of these lineages has been hampered by an inability to type lineage efficiently. Here, we describe a lineage-specific TaqMan qPCR assay that differentiates the two lineages of Bd most commonly associated with chytridiomycosis: BdGPL and BdCAPE. We demonstrate how this assay can be used for the surveillance of wild populations of amphibians in Southern Africa using skin swabs, tissue samples and cultured isolates., (© 2020 The Authors. Molecular Ecology Resources published by John Wiley & Sons Ltd.)

Published

2021

25. Microbial Grazers May Aid in Controlling Infections Caused by the Aquatic Zoosporic Fungus Batrachochytrium dendrobatidis .

Author

Farthing HN, Jiang J, Henwood AJ, Fenton A, Garner TWJ, Daversa DR, Fisher MC, and Montagnes DJS

Abstract

Free-living eukaryotic microbes may reduce animal diseases. We evaluated the dynamics by which micrograzers (primarily protozoa) apply top-down control on the chytrid Batrachochytrium dendrobatidis ( Bd ) a devastating, panzootic pathogen of amphibians. Although micrograzers consumed zoospores (∼3 μm), the dispersal stage of chytrids, not all species grew monoxenically on zoospores. However, the ubiquitous ciliate Tetrahymena pyriformis , which likely co-occurs with Bd , grew at near its maximum rate ( r = 1.7 d -1 ). A functional response (ingestion vs. prey abundance) for T. pyriformis , measured using spore-surrogates (microspheres) revealed maximum ingestion ( I max ) of 1.63 × 10 3 zoospores d -1 , with a half saturation constant ( k ) of 5.75 × 10 3 zoospores ml -1 . Using these growth and grazing data we developed and assessed a population model that incorporated chytrid-host and micrograzer dynamics. Simulations using our data and realistic parameters obtained from the literature suggested that micrograzers could control Bd and potentially prevent chytridiomycosis (defined as 10 4 sporangia host -1 ). However, simulated inferior micrograzers (0.7 × I max and 1.5 × k ) did not prevent chytridiomycosis, although they ultimately reduced pathogen abundance to below levels resulting in disease. These findings indicate how micrograzer responses can be applied when modeling disease dynamics for Bd and other zoosporic fungi., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Farthing, Jiang, Henwood, Fenton, Garner, Daversa, Fisher and Montagnes.)

Published

2021

26. Significant reductions of host abundance weakly impact infection intensity of Batrachochytrium dendrobatidis.

Author

Bosch J, Carrascal LM, Manica A, and Garner TWJ

Subjects

Amphibians growth & development, Amphibians microbiology, Animals, Batrachochytrium pathogenicity, Biodiversity, Chytridiomycota genetics, Ecosystem, Larva, Mycoses genetics, Population Dynamics, Spain epidemiology, Urodela growth & development, Urodela microbiology, Amphibians genetics, Batrachochytrium genetics, Mycoses microbiology, Urodela genetics

Abstract

Infectious diseases are considered major threats to biodiversity, however strategies to mitigate their impacts in the natural world are scarce and largely unsuccessful. Chytridiomycosis is responsible for the decline of hundreds of amphibian species worldwide, but an effective disease management strategy that could be applied across natural habitats is still lacking. In general amphibian larvae can be easily captured, offering opportunities to ascertain the impact of altering the abundance of hosts, considered to be a key parameter affecting the severity of the disease. Here, we report the results of two experiments to investigate how altering host abundance affects infection intensity in amphibian populations of a montane area of Central Spain suffering from lethal amphibian chytridiomycosis. Our laboratory-based experiment supported the conclusion that varying density had a significant effect on infection intensity when salamander larvae were housed at low densities. Our field experiment showed that reducing the abundance of salamander larvae in the field also had a significant, but weak, impact on infection the following year, but only when removals were extreme. While this suggests adjusting host abundance as a mitigation strategy to reduce infection intensity could be useful, our evidence suggests only heavy culling efforts will succeed, which may run contrary to objectives for conservation., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

27. Chytrid fungi and global amphibian declines.

Author

Fisher MC and Garner TWJ

Subjects

Animals, Biodiversity, Chytridiomycota classification, Chytridiomycota pathogenicity, Genotype, Population Dynamics, Recombination, Genetic, Time Factors, Virulence, Amphibians microbiology, Chytridiomycota genetics

Abstract

Discovering that chytrid fungi cause chytridiomycosis in amphibians represented a paradigm shift in our understanding of how emerging infectious diseases contribute to global patterns of biodiversity loss. In this Review we describe how the use of multidisciplinary biological approaches has been essential to pinpointing the origins of amphibian-parasitizing chytrid fungi, including Batrachochytrium dendrobatidis and Batrachochytrium salamandrivorans, as well as to timing their emergence, tracking their cycles of expansion and identifying the core mechanisms that underpin their pathogenicity. We discuss the development of the experimental methods and bioinformatics toolkits that have provided a fuller understanding of batrachochytrid biology and informed policy and control measures.

Published

2020

28. Genetic and demographic vulnerability of adder populations: Results of a genetic study in mainland Britain.

Author

Ball S, Hand N, Willman F, Durrant C, Uller T, Claus K, Mergeay J, Bauwens D, and Garner TWJ

Subjects

Animals, Female, Genetic Variation, Genetics, Population, Loss of Heterozygosity, Male, Microsatellite Repeats, Mitochondria genetics, United Kingdom, Viperidae physiology, Inbreeding, Viperidae genetics

Abstract

Genetic factors are often overlooked in conservation planning, despite their importance in small isolated populations. We used mitochondrial and microsatellite markers to investigate population genetics of the adder (Vipera berus) in southern Britain, where numbers are declining. We found no evidence for loss of heterozygosity in any of the populations studied. Genetic diversity was comparable across sites, in line with published levels for mainland Europe. However, further analysis revealed a striking level of relatedness. Genetic networks constructed from inferred first degree relationships suggested a high proportion of individuals to be related at a level equivalent to that of half-siblings, with rare inferred full-sib dyads. These patterns of relatedness can be attributed to the high philopatry and low vagility of adders, which creates high local relatedness, in combination with the polyandrous breeding system in the adder, which may offset the risk of inbreeding in closed populations. We suggest that reliance on standard genetic indicators of inbreeding and diversity may underestimate demographic and genetic factors that make adder populations vulnerable to extirpation. We stress the importance of an integrated genetic and demographic approach in the conservation of adders, and other taxa of similar ecology., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

29. Spatiotemporal heterogeneity decouples infection parameters of amphibian chytridiomycosis.

Author

McMillan KM, Lesbarrères D, Harrison XA, and Garner TWJ

Subjects

Amphibians, Animals, Ontario epidemiology, Seasons, Chytridiomycota, Mycoses epidemiology, Mycoses veterinary

Abstract

Emerging infectious diseases are responsible for declines in wildlife populations around the globe. Mass mortality events associated with emerging infectious diseases are often associated with high number of infected individuals (prevalence) and high pathogen loads within individuals (intensity). At the landscape scale, spatial and temporal variation in environmental conditions can alter the relationship between these infection parameters and blur the overall picture of disease dynamics. Quantitative estimates of how infection parameters covary with environmental heterogeneity at the landscape scale are scarce. If we are to identify wild populations at risk of disease epidemics, we must elucidate the factors that shape, and potentially decouple, the link between pathogen prevalence and intensity of infection over complex ecological landscapes. Using a network of 41 populations of the amphibian host Rana pipiens in Ontario, Canada, we present the spatial and temporal heterogeneity in pathogen prevalence and intensity of infection of the chytrid fungus Batrachochytrium dendrobatidis (Bd), across a 3-year period. We then quantify how covariation between both infection parameters measured during late summer is modified by previously experienced spatiotemporal environmental heterogeneity across 14 repeat sampled populations. Late summer Bd infection parameters are governed, at least in part, by different environmental factors operating during separate host life-history events. Our results provide evidence for a relationship between Bd prevalence and thermal regimes prior to host breeding at the site level, and a relationship between intensity of infection and aquatic conditions (precipitation, hydroshed size and river density) throughout host breeding period at the site level. This demonstrates that microclimatic variation within temporal windows can drive divergent patterns of pathogen dynamics within and across years, by effecting changes in host behaviour which interfere with the pathogen's ability to infect and re-infect hosts. A clearer understanding of the role that spatiotemporal heterogeneity has upon infection parameters will provide valuable insights into host-pathogen epidemiology, as well as more fundamental aspects of the ecology and evolution of interspecific interactions., (© 2019 British Ecological Society.)

Published

2020

30. Response to Comment on "Amphibian fungal panzootic causes catastrophic and ongoing loss of biodiversity".

Author

Scheele BC, Pasmans F, Skerratt LF, Berger L, Martel A, Beukema W, Acevedo AA, Burrowes PA, Carvalho T, Catenazzi A, De la Riva I, Fisher MC, Flechas SV, Foster CN, Frías-Álvarez P, Garner TWJ, Gratwicke B, Guayasamin JM, Hirschfeld M, Kolby JE, Kosch TA, La Marca E, Lindenmayer DB, Lips KR, Longo AV, Maneyro R, McDonald CA, Mendelson J 3rd, Palacios-Rodriguez P, Parra-Olea G, Richards-Zawacki CL, Rödel MO, Rovito SM, Soto-Azat C, Toledo LF, Voyles J, Weldon C, Whitfield SM, Wilkinson M, Zamudio KR, and Canessa S

Subjects

Amphibians, Animals, Biodiversity, Retrospective Studies, Chytridiomycota, Mycoses

Abstract

Lambert et al question our retrospective and holistic epidemiological assessment of the role of chytridiomycosis in amphibian declines. Their alternative assessment is narrow and provides an incomplete evaluation of evidence. Adopting this approach limits understanding of infectious disease impacts and hampers conservation efforts. We reaffirm that our study provides unambiguous evidence that chytridiomycosis has affected at least 501 amphibian species., (Copyright © 2020, American Association for the Advancement of Science.)

Published

2020

31. Diversity-Stability Dynamics of the Amphibian Skin Microbiome and Susceptibility to a Lethal Viral Pathogen.

Author

Harrison XA, Price SJ, Hopkins K, Leung WTM, Sergeant C, and Garner TWJ

Abstract

Variation among animals in their host-associated microbial communities is increasingly recognized as a key determinant of important life history traits including growth, metabolism, and resistance to disease. Quantitative estimates of the factors shaping the stability of host microbiomes over time at the individual level in non-model organisms are scarce. Addressing this gap in our knowledge is important, as variation among individuals in microbiome stability may represent temporal gain or loss of key microbial species and functions linked to host health and/or fitness. Here we use controlled experiments to investigate how both heterogeneity in microbial species richness of the environment and exposure to the emerging pathogen Ranavirus influence the structure and temporal dynamics of the skin microbiome in a vertebrate host, the European common frog ( Rana temporaria ). Our evidence suggests that altering the bacterial species richness of the environment drives divergent temporal microbiome dynamics of the amphibian skin. Exposure to ranavirus effects changes in skin microbiome structure irrespective of total microbial diversity, but individuals with higher pre-exposure skin microbiome diversity appeared to exhibit higher survival. Higher diversity skin microbiomes also appear less stable over time compared to lower diversity microbiomes, but stability of the 100 most abundant ("core") community members was similar irrespective of microbiome richness. Our study highlights the importance of extrinsic factors in determining the stability of host microbiomes over time, which may in turn have important consequences for the stability of host-microbe interactions and microbiome-fitness correlations., (Copyright © 2019 Harrison, Price, Hopkins, Leung, Sergeant and Garner.)

Published

2019

32. Effects of historic and projected climate change on the range and impacts of an emerging wildlife disease.

Author

Price SJ, Leung WTM, Owen CJ, Puschendorf R, Sergeant C, Cunningham AA, Balloux F, Garner TWJ, and Nichols RA

Subjects

Animals, Animals, Wild, Climate Change, Reptiles, DNA Virus Infections, Ranavirus

Abstract

The global trend of increasing environmental temperatures is often predicted to result in more severe disease epidemics. However, unambiguous evidence that temperature is a driver of epidemics is largely lacking, because it is demanding to demonstrate its role among the complex interactions between hosts, pathogens, and their shared environment. Here, we apply a three-pronged approach to understand the effects of temperature on ranavirus epidemics in UK common frogs, combining in vitro, in vivo, and field studies. Each approach suggests that higher temperatures drive increasing severity of epidemics. In wild populations, ranavirosis incidents were more frequent and more severe at higher temperatures, and their frequency increased through a period of historic warming in the 1990s. Laboratory experiments using cell culture and whole animal models showed that higher temperature increased ranavirus propagation, disease incidence, and mortality rate. These results, combined with climate projections, predict severe ranavirosis outbreaks will occur over wider areas and an extended season, possibly affecting larval recruitment. Since ranaviruses affect a variety of ectothermic hosts (amphibians, reptiles, and fish), wider ecological damage could occur. Our three complementary lines of evidence present a clear case for direct environmental modulation of these epidemics and suggest management options to protect species from disease., (© 2019 John Wiley & Sons Ltd.)

Published

2019

33. Outbreaks of an Emerging Viral Disease Covary With Differences in the Composition of the Skin Microbiome of a Wild United Kingdom Amphibian.

Author

Campbell LJ, Garner TWJ, Hopkins K, Griffiths AGF, and Harrison XA

Abstract

There is growing appreciation of the important role of commensal microbes in ensuring the normal function and health of their hosts, including determining how hosts respond to pathogens. A range of infectious diseases are threatening amphibians worldwide, and evidence is accumulating that the host-associated bacteria that comprise the microbiome may be key in mediating interactions between amphibian hosts and infectious pathogens. We used 16S rRNA amplicon sequencing to quantify the skin microbial community structure of over 200 individual wild adult European common frogs ( Rana temporaria ), from ten populations with contrasting history of the lethal disease ranavirosis, caused by emerging viral pathogens belonging to the genus Ranavirus . All populations had similar species richness irrespective of disease history, but populations that have experienced historical outbreaks of ranavirosis have a distinct skin microbiome structure (beta diversity) when compared to sites where no outbreaks of the disease have occurred. At the individual level, neither age, body length, nor sex of the frog could predict the structure of the skin microbiota. Our data potentially support the hypothesis that variation among individuals in skin microbiome structure drive differences in susceptibility to infection and lethal outbreaks of disease. More generally, our results suggest that population-level processes are more important for driving differences in microbiome structure than variation among individuals within populations in key life history traits such as age and body size.

Published

2019

34. Modelling Ranavirus Transmission in Populations of Common Frogs ( Rana temporaria ) in the United Kingdom.

Author

Duffus ALJ, Garner TWJ, Nichols RA, Standridge JP, and Earl JE

Subjects

Animal Diseases transmission, Animals, DNA Virus Infections transmission, DNA Virus Infections virology, United Kingdom, Animal Diseases virology, DNA Virus Infections veterinary, Disease Transmission, Infectious, Models, Statistical, Rana temporaria, Ranavirus isolation & purification

Abstract

Ranaviruses began emerging in common frogs ( Rana temporaria ) in the United Kingdom in the late 1980s and early 1990s, causing severe disease and declines in the populations of these animals. Herein, we explored the transmission dynamics of the ranavirus(es) present in common frog populations, in the context of a simple susceptible-infected (SI) model, using parameters derived from the literature. We explored the effects of disease-induced population decline on the dynamics of the ranavirus. We then extended the model to consider the infection dynamics in populations exposed to both ulcerative and hemorrhagic forms of the ranaviral disease. The preliminary investigation indicated the important interactions between the forms. When the ulcerative form was present in a population and the hemorrhagic form was later introduced, the hemorrhagic form of the disease needed to be highly contagious, to persist. We highlighted the areas where further research and experimental evidence is needed and hope that these models would act as a guide for further research into the amphibian disease dynamics.

Published

2019

35. Amphibian fungal panzootic causes catastrophic and ongoing loss of biodiversity.

Author

Scheele BC, Pasmans F, Skerratt LF, Berger L, Martel A, Beukema W, Acevedo AA, Burrowes PA, Carvalho T, Catenazzi A, De la Riva I, Fisher MC, Flechas SV, Foster CN, Frías-Álvarez P, Garner TWJ, Gratwicke B, Guayasamin JM, Hirschfeld M, Kolby JE, Kosch TA, La Marca E, Lindenmayer DB, Lips KR, Longo AV, Maneyro R, McDonald CA, Mendelson J 3rd, Palacios-Rodriguez P, Parra-Olea G, Richards-Zawacki CL, Rödel MO, Rovito SM, Soto-Azat C, Toledo LF, Voyles J, Weldon C, Whitfield SM, Wilkinson M, Zamudio KR, and Canessa S

Subjects

Americas epidemiology, Animals, Anura classification, Australia epidemiology, Mycoses epidemiology, Anura microbiology, Anura physiology, Biodiversity, Chytridiomycota, Extinction, Biological, Mycoses veterinary

Abstract

Anthropogenic trade and development have broken down dispersal barriers, facilitating the spread of diseases that threaten Earth's biodiversity. We present a global, quantitative assessment of the amphibian chytridiomycosis panzootic, one of the most impactful examples of disease spread, and demonstrate its role in the decline of at least 501 amphibian species over the past half-century, including 90 presumed extinctions. The effects of chytridiomycosis have been greatest in large-bodied, range-restricted anurans in wet climates in the Americas and Australia. Declines peaked in the 1980s, and only 12% of declined species show signs of recovery, whereas 39% are experiencing ongoing decline. There is risk of further chytridiomycosis outbreaks in new areas. The chytridiomycosis panzootic represents the greatest recorded loss of biodiversity attributable to a disease., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2019

36. Common midwife toad ranaviruses replicate first in the oral cavity of smooth newts (Lissotriton vulgaris) and show distinct strain-associated pathogenicity.

Author

Saucedo B, Garner TWJ, Kruithof N, Allain SJR, Goodman MJ, Cranfield RJ, Sergeant C, Vergara DA, Kik MJL, Forzán MJ, van Beurden SJ, and Gröne A

Subjects

Animals, Feces virology, Mouth virology, Netherlands, Polymerase Chain Reaction, Ranavirus physiology, Virus Replication, Virus Shedding, DNA Virus Infections veterinary, Host-Pathogen Interactions physiology, Ranavirus pathogenicity, Salamandridae virology

Abstract

Ranavirus is the second most common infectious cause of amphibian mortality. These viruses affect caudates, an order in which information regarding Ranavirus pathogenesis is scarce. In the Netherlands, two strains (CMTV-NL I and III) were suspected to possess distinct pathogenicity based on field data. To investigate susceptibility and disease progression in urodeles and determine differences in pathogenicity between strains, 45 adult smooth newts (Lissotriton vulgaris) were challenged via bath exposure with these ranaviruses and their detection in organs and feces followed over time by PCR, immunohistochemistry and in situ hybridization. Ranavirus was first detected at 3 days post infection (p.i.) in the oral cavity and upper respiratory mucosa. At 6 days p.i, virus was found in connective tissues and vasculature of the gastrointestinal tract. Finally, from 9 days p.i onwards there was widespread Ranavirus disease in various organs including skin, kidneys and gonads. Higher pathogenicity of the CMTV-NL I strain was confirmed by higher correlation coefficient of experimental group and mortality of challenged animals. Ranavirus-exposed smooth newts shed virus in feces intermittently and infection was seen in the absence of lesions or clinical signs, indicating that this species can harbor subclinical infections and potentially serve as disease reservoirs.

Published

2019

37. Discussing the future of amphibians in research.

Author

Brod S, Brookes L, and Garner TWJ

Subjects

Animals, Congresses as Topic, Research organization & administration, Amphibians, Models, Animal

Published

2019

38. An emerging viral pathogen truncates population age structure in a European amphibian and may reduce population viability.

Author

Campbell LJ, Garner TWJ, Tessa G, Scheele BC, Griffiths AGF, Wilfert L, and Harrison XA

Abstract

Infectious diseases can alter the demography of their host populations, reducing their viability even in the absence of mass mortality. Amphibians are the most threatened group of vertebrates globally, and emerging infectious diseases play a large role in their continued population declines. Viruses belonging to the genus Ranavirus are responsible for one of the deadliest and most widespread of these diseases. To date, no work has used individual level data to investigate how ranaviruses affect population demographic structure. We used skeletochronology and morphology to evaluate the impact of ranaviruses on the age structure of populations of the European common frog ( Rana temporaria ) in the UK. We compared ecologically similar populations that differed most notably in their historical presence or absence of ranavirosis (the acute syndrome caused by ranavirus infection). Our results suggest that ranavirosis may truncate the age structure of R. temporaria populations. One potential explanation for such a shift might be increased adult mortality and subsequent shifts in the life history of younger age classes that increase reproductive output earlier in life. Additionally, we constructed population projection models which indicated that such increased adult mortality could heighten the vulnerability of frog populations to stochastic environmental challenges., Competing Interests: Xavier A Harrison serves as an Academic Editor for PeerJ. Amber G F Griffiths is a director of FoAM Kernow (FoAM Kernow is an affiliated studio of FoAM, which is a multinational, not for profit, network of transdisciplinary labs at the intersection of art, science, nature and everyday life).

Published

2018

39. Long-term monitoring of an amphibian community after a climate change- and infectious disease-driven species extirpation.

Author

Bosch J, Fernández-Beaskoetxea S, Garner TWJ, and Carrascal LM

Subjects

Animal Diseases microbiology, Animals, Chytridiomycota physiology, Mycoses microbiology, Spain, Amphibians, Animal Diseases epidemiology, Biodiversity, Climate Change, Mycoses epidemiology

Abstract

Infectious disease and climate change are considered major threats to biodiversity and act as drivers behind the global amphibian decline. This is, to a large extent, based on short-term studies that are designed to detect the immediate and strongest biodiversity responses to a threatening process. What few long-term studies are available, although typically focused on single species, report outcomes that often diverge significantly from the short-term species responses. Here, we report the results of an 18-year survey of an amphibian community exposed to both climate warming and the emergence of lethal chytridiomycosis. Our study shows that the impacts of infectious disease are ongoing but restricted to two out of nine species that form the community, despite the fact all species can become infected with the fungus. Climate warming appears to be affecting four out of the nine species, but the response of three of these is an increase in abundance. Our study supports a decreasing role of infectious disease on the community, and an increasing and currently positive effect of climate warming. We caution that if the warming trends continue, the net positive effect will turn negative as amphibian breeding habitat becomes unavailable as water bodies dry, a pattern that already may be underway., (© 2018 John Wiley & Sons Ltd.)

Published

2018

40. Development and worldwide use of non-lethal, and minimal population-level impact, protocols for the isolation of amphibian chytrid fungi.

Author

Fisher MC, Ghosh P, Shelton JMG, Bates K, Brookes L, Wierzbicki C, Rosa GM, Farrer RA, Aanensen DM, Alvarado-Rybak M, Bataille A, Berger L, Böll S, Bosch J, Clare FC, A Courtois E, Crottini A, Cunningham AA, Doherty-Bone TM, Gebresenbet F, Gower DJ, Höglund J, James TY, Jenkinson TS, Kosch TA, Lambertini C, Laurila A, Lin CF, Loyau A, Martel A, Meurling S, Miaud C, Minting P, Ndriantsoa S, O'Hanlon SJ, Pasmans F, Rakotonanahary T, Rabemananjara FCE, Ribeiro LP, Schmeller DS, Schmidt BR, Skerratt L, Smith F, Soto-Azat C, Tessa G, Toledo LF, Valenzuela-Sánchez A, Verster R, Vörös J, Waldman B, Webb RJ, Weldon C, Wombwell E, Zamudio KR, Longcore JE, and Garner TWJ

Subjects

Animals, Information Dissemination, Larva microbiology, Software, Amphibians microbiology, Chytridiomycota isolation & purification, Endangered Species

Abstract

Parasitic chytrid fungi have emerged as a significant threat to amphibian species worldwide, necessitating the development of techniques to isolate these pathogens into culture for research purposes. However, early methods of isolating chytrids from their hosts relied on killing amphibians. We modified a pre-existing protocol for isolating chytrids from infected animals to use toe clips and biopsies from toe webbing rather than euthanizing hosts, and distributed the protocol to researchers as part of the BiodivERsA project RACE; here called the RML protocol. In tandem, we developed a lethal procedure for isolating chytrids from tadpole mouthparts. Reviewing a database of use a decade after their inception, we find that these methods have been applied across 5 continents, 23 countries and in 62 amphibian species. Isolation of chytrids by the non-lethal RML protocol occured in 18% of attempts with 207 fungal isolates and three species of chytrid being recovered. Isolation of chytrids from tadpoles occured in 43% of attempts with 334 fungal isolates of one species (Batrachochytrium dendrobatidis) being recovered. Together, these methods have resulted in a significant reduction and refinement of our use of threatened amphibian species and have improved our ability to work with this group of emerging pathogens.

Published

2018

41. Recent Asian origin of chytrid fungi causing global amphibian declines.

Author

O'Hanlon SJ, Rieux A, Farrer RA, Rosa GM, Waldman B, Bataille A, Kosch TA, Murray KA, Brankovics B, Fumagalli M, Martin MD, Wales N, Alvarado-Rybak M, Bates KA, Berger L, Böll S, Brookes L, Clare F, Courtois EA, Cunningham AA, Doherty-Bone TM, Ghosh P, Gower DJ, Hintz WE, Höglund J, Jenkinson TS, Lin CF, Laurila A, Loyau A, Martel A, Meurling S, Miaud C, Minting P, Pasmans F, Schmeller DS, Schmidt BR, Shelton JMG, Skerratt LF, Smith F, Soto-Azat C, Spagnoletti M, Tessa G, Toledo LF, Valenzuela-Sánchez A, Verster R, Vörös J, Webb RJ, Wierzbicki C, Wombwell E, Zamudio KR, Aanensen DM, James TY, Gilbert MTP, Weldon C, Bosch J, Balloux F, Garner TWJ, and Fisher MC

Subjects

Africa, Americas, Animals, Asia, Australia, Chytridiomycota classification, Chytridiomycota genetics, Chytridiomycota isolation & purification, Chytridiomycota pathogenicity, Europe, Genes, Fungal, Genetic Variation, Hybridization, Genetic, Korea, Phylogeny, Sequence Analysis, DNA, Virulence, Amphibians microbiology, Extinction, Biological

Abstract

Globalized infectious diseases are causing species declines worldwide, but their source often remains elusive. We used whole-genome sequencing to solve the spatiotemporal origins of the most devastating panzootic to date, caused by the fungus Batrachochytrium dendrobatidis , a proximate driver of global amphibian declines. We traced the source of B. dendrobatidis to the Korean peninsula, where one lineage, Bd ASIA-1, exhibits the genetic hallmarks of an ancestral population that seeded the panzootic. We date the emergence of this pathogen to the early 20th century, coinciding with the global expansion of commercial trade in amphibians, and we show that intercontinental transmission is ongoing. Our findings point to East Asia as a geographic hotspot for B. dendrobatidis biodiversity and the original source of these lineages that now parasitize amphibians worldwide., (Copyright © 2018 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2018

42. A novel approach to wildlife transcriptomics provides evidence of disease-mediated differential expression and changes to the microbiome of amphibian populations.

Author

Campbell LJ, Hammond SA, Price SJ, Sharma MD, Garner TWJ, Birol I, Helbing CC, Wilfert L, and Griffiths AGF

Subjects

Animals, Animals, Wild microbiology, DNA Virus Infections virology, Microbiota genetics, Rana temporaria genetics, Sequence Analysis, RNA, United Kingdom, Animals, Wild genetics, DNA Virus Infections genetics, Rana temporaria virology, Ranavirus pathogenicity

Abstract

Ranaviruses are responsible for a lethal, emerging infectious disease in amphibians and threaten their populations throughout the world. Despite this, little is known about how amphibian populations respond to ranaviral infection. In the United Kingdom, ranaviruses impact the common frog (Rana temporaria). Extensive public engagement in the study of ranaviruses in the UK has led to the formation of a unique system of field sites containing frog populations of known ranaviral disease history. Within this unique natural field system, we used RNA sequencing (RNA-Seq) to compare the gene expression profiles of R. temporaria populations with a history of ranaviral disease and those without. We have applied a RNA read-filtering protocol that incorporates Bloom filters, previously used in clinical settings, to limit the potential for contamination that comes with the use of RNA-Seq in nonlaboratory systems. We have identified a suite of 407 transcripts that are differentially expressed between populations of different ranaviral disease history. This suite contains genes with functions related to immunity, development, protein transport and olfactory reception among others. A large proportion of potential noncoding RNA transcripts present in our differentially expressed set provide first evidence of a possible role for long noncoding RNA (lncRNA) in amphibian response to viruses. Our read-filtering approach also removed significantly more bacterial reads from libraries generated from positive disease history populations. Subsequent analysis revealed these bacterial read sets to represent distinct communities of bacterial species, which is suggestive of an interaction between ranavirus and the host microbiome in the wild., (© 2018 The Authors. Molecular Ecology Published by John Wiley & Sons Ltd.)

Published

2018

43. Infections on the move: how transient phases of host movement influence disease spread.

Author

Daversa DR, Fenton A, Dell AI, Garner TWJ, and Manica A

Subjects

Animal Diseases parasitology, Animals, Models, Biological, Animal Diseases transmission, Animal Distribution, Animals, Wild physiology, Host-Parasite Interactions

Abstract

Animal movement impacts the spread of human and wildlife diseases, and there is significant interest in understanding the role of migrations, biological invasions and other wildlife movements in spatial infection dynamics. However, the influence of processes acting on infections during transient phases of host movement is poorly understood. We propose a conceptual framework that explicitly considers infection dynamics during transient phases of host movement to better predict infection spread through spatial host networks. Accounting for host transient movement captures key processes that occur while hosts move between locations, which together determine the rate at which hosts spread infections through networks. We review theoretical and empirical studies of host movement and infection spread, highlighting the multiple factors that impact the infection status of hosts. We then outline characteristics of hosts, parasites and the environment that influence these dynamics. Recent technological advances provide disease ecologists unprecedented ability to track the fine-scale movement of organisms. These, in conjunction with experimental testing of the factors driving infection dynamics during host movement, can inform models of infection spread based on constituent biological processes., (© 2017 The Authors.)

Published

2017

44. From fish to frogs and beyond: Impact and host range of emergent ranaviruses.

Author

Price SJ, Ariel E, Maclaine A, Rosa GM, Gray MJ, Brunner JL, and Garner TWJ

Subjects

Animals, Biological Evolution, Ranavirus pathogenicity, Virulence, Amphibians virology, Fishes virology, Host Specificity, Ranavirus isolation & purification, Ranavirus physiology

Abstract

Ranaviruses are pathogens of ectothermic vertebrates, including amphibians. We reviewed patterns of host range and virulence of ranaviruses in the context of virus genotype and postulate that patterns reflect significant variation in the historical and current host range of three groups of Ranavirus: FV3-like, CMTV-like and ATV-like ranaviruses. Our synthesis supports previous hypotheses about host range and jumps: FV3s are amphibian specialists, while ATVs are predominantly fish specialists that switched once to caudate amphibians. The most recent common ancestor of CMTV-like ranaviruses and FV3-like forms appears to have infected amphibians but CMTV-like ranaviruses may circulate in both amphibian and fish communities independently. While these hypotheses are speculative, we hope that ongoing efforts to describe ranavirus genetics, increased surveillance of host species and targeted experimental assays of susceptibility to infection and/or disease will facilitate better tests of the importance of hypothetical evolutionary drivers of ranavirus virulence and host range., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

45. A quantitative-PCR based method to estimate ranavirus viral load following normalisation by reference to an ultraconserved vertebrate target.

Author

Leung WTM, Thomas-Walters L, Garner TWJ, Balloux F, Durrant C, and Price SJ

Subjects

Animals, Capsid Proteins genetics, DNA Virus Infections virology, Fishes virology, Host Specificity, RNA, Untranslated genetics, Ranavirus genetics, Ranavirus growth & development, Ranavirus physiology, Reproducibility of Results, Sensitivity and Specificity, Amphibians virology, DNA Virus Infections veterinary, Fish Diseases virology, Ranavirus isolation & purification, Real-Time Polymerase Chain Reaction standards, Reptiles virology, Viral Load

Abstract

Ranaviruses are important pathogens of amphibians, reptiles and fish. To meet the need for an analytical method for generating normalised and comparable infection data for these diverse host species, two standard-curve based quantitative-PCR (qPCR) assays were developed enabling viral load estimation across these host groups. A viral qPCR targeting the major capsid protein (MCP) gene was developed which was specific to amphibian-associated ranaviruses with high analytical sensitivity (lower limit of detection: 4.23 plasmid standard copies per reaction) and high reproducibility across a wide dynamic range (coefficient of variation below 3.82% from 3 to 3×10 8 standard copies per reaction). The comparative sensitivity of the viral qPCR was 100% (n=78) based on agreement with an established end-point PCR. Comparative specificity with the end-point PCR was also 100% (n=94) using samples from sites with no history of ranavirus infection. To normalise viral quantities, a host qPCR was developed which targeted a single-copy, ultra-conserved non-coding element (UCNE) of vertebrates. Viral and host qPCRs were applied to track ranavirus growth in culture. The two assays offer a robust approach to viral load estimation and the host qPCR can be paired with assays targeting other pathogens to study infection burdens., (Copyright © 2017 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2017

46. Microscopic aquatic predators strongly affect infection dynamics of a globally emerged pathogen.

Author

Schmeller DS, Blooi M, Martel A, Garner TWJ, Fisher MC, Azemar F, Clare FC, Leclerc C, Jäger L, Guevara-Nieto M, Loyau A, and Pasmans F

Subjects

Animals, Anura microbiology, Mycoses, Water, Water Microbiology, Chytridiomycota isolation & purification

Abstract

Research on emerging infectious wildlife diseases has placed particular emphasis on host-derived barriers to infection and disease. This focus neglects important extrinsic determinants of the host/pathogen dynamic, where all barriers to infection should be considered when ascertaining the determinants of infectivity and pathogenicity of wildlife pathogens. Those pathogens with free-living stages, such as fungi causing catastrophic wildlife declines on a global scale, must confront lengthy exposure to environmental barriers before contact with an uninfected host. Hostile environmental conditions therefore have the ability to decrease the density of infectious particles, reducing the force of infection and ameliorating the impact as well as the probability of establishing an infection. Here we show that, in nature, the risk of infection and infectious burden of amphibians infected by the chytrid fungus Batrachochytrium dendrobatidis (Bd) have a significant, site-specific component, and that these correlate with the microfauna present at a site. Experimental infections show that aquatic microfauna can rapidly lower the abundance and density of infectious stages by consuming Bd zoospores, resulting in a significantly reduced probability of infection in anuran tadpoles. Our findings offer new perspectives for explaining the divergent impacts of Bd infection in amphibian assemblages and contribute to our understanding of ecosystem resilience to colonization by novel pathogens., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014