Your search keyword '"Hamede RK"' showing total 28 results

1. The ecology and epidemiology of devil facial tumour disease

Author

Hamede, RK

Abstract

Emerging infectious diseases are increasingly recognised as a significant threatening process in conservation biology. Empirical studies aimed at understanding the epidemiological and ecological processes underlying disease transmission and its impact on host populations are crucial for designing disease management strategies. The Tasmanian devil (Sarcophilus harrisii), is threatened with extinction by Devil Facial Tumour Disease (DFTD), a novel and fatal transmissible cancer. In this thesis, I use proximity-sensing radio collars to reveal empirical contact networks in a wild devil population and infer the role of seasonal and demographic network structure dynamics in the epidemiology of DFTD. I further use this information to build disease-simulation network models to assess the role of contact heterogeneities in epidemic behaviour. Finally, I use longitudinal data sets that followed the natural progression of DFTD to compare contact patterns, epidemiology and impact of the disease in subpopulations which differ in their genotypic structure and diversity. The results indicate increased frequency and length of male-female contacts during the mating season, compared with the non-mating season. These strong inter-sex contact preferences during the mating season suggest that the transmission dynamics of DFTD might be frequency dependent. There are strongly connected individuals in the network, but their identity changes with season, providing limited scope for targeting disease control actions to particular demographic groups. Incorporating network structure and its seasonal and demographic dynamics in disease simulation models had a modest effect on the epidemic threshold for DFTD compared to traditional compartmental disease models. Quantifying heterogeneities in contact patterns and assessing their role in disease spread do, nonetheless, represent an important step for predicting epidemic behaviour and developing approaches for managing wildlife diseases. This study has provided the first evidence of reduced impact and slow progression of DFTD in a wild population as the disease moves to a genetic subpopulation with major histocompatibility complex genes differing from those of the tumour itself. Biting patterns associated with disease transmission did not significantly differ between the two genetic subpopulations. Therefore, differences in genetic diversity in the host immune system or reduced virulence in the pathogen are proposed as plausible explanations for the epidemiological differences between subpopulations. In addition, I found that most tumours were located inside the oral cavity and devils with fewer bites were more likely to develop DFTD, which suggests that the probability of acquiring infection is higher in devils delivering bites than in those receiving bites. The findings of this study, which examined the natural progression of an emerging disease in an ecological and epidemiological context, have direct implications for designing future conservation strategies for the species, and are broadly applicable to a range of other conservation challenges posed by wildlife diseases.

Published

2023

2. Transmissible cancer influences immune gene expression in an endangered marsupial, the Tasmanian devil (Sarcophilus harrisii)

Author

Raven, N, Klaassen, Marcel, Madsen, Thomas, Thomas, F, Hamede, RK, Ujvari, Beata, Raven, N, Klaassen, Marcel, Madsen, Thomas, Thomas, F, Hamede, RK, and Ujvari, Beata

Published

2022

3. Identifying key questions in the ecology and evolution of cancer

Author

Dujon, Antoine, Aktipis, A, Alix-Panabières, C, Amend, SR, Boddy, AM, Brown, JS, Capp, JP, DeGregori, J, Ewald, P, Gatenby, R, Gerlinger, M, Giraudeau, M, Hamede, RK, Hansen, E, Kareva, I, Maley, CC, Marusyk, A, McGranahan, N, Metzger, MJ, Nedelcu, AM, Noble, R, Nunney, L, Pienta, KJ, Polyak, K, Pujol, P, Read, AF, Roche, B, Sebens, S, Solary, E, Staňková, K, Swain Ewald, H, Thomas, F, Ujvari, Beata, Dujon, Antoine, Aktipis, A, Alix-Panabières, C, Amend, SR, Boddy, AM, Brown, JS, Capp, JP, DeGregori, J, Ewald, P, Gatenby, R, Gerlinger, M, Giraudeau, M, Hamede, RK, Hansen, E, Kareva, I, Maley, CC, Marusyk, A, McGranahan, N, Metzger, MJ, Nedelcu, AM, Noble, R, Nunney, L, Pienta, KJ, Polyak, K, Pujol, P, Read, AF, Roche, B, Sebens, S, Solary, E, Staňková, K, Swain Ewald, H, Thomas, F, and Ujvari, Beata

Published

2021

4. Conservation management of Tasmanian devils in the context of an emerging, extinction-threatening disease: Devil Facial Tumor Disease

Author

Jones, ME, McCallum, HI, Jarman, PJ, Lees, CM, Hesterman, H, Hamede, RK, Mooney, NJ, Mann, D, Pukk, CE, Bergfeld, J, Jones, ME, McCallum, HI, Jarman, PJ, Lees, CM, Hesterman, H, Hamede, RK, Mooney, NJ, Mann, D, Pukk, CE, and Bergfeld, J

Abstract

An emerging infectious facial cancer threatens Tasmanian devils with extinction. The disease is likely to occur across the range of the devil within 5 years. This urgent time frame requires management options that can be implemented immediately: the establishment of insurance populations, in captivity, wild-living on islands,and aiming for eradication in areas that can be isolated. The long-term options of the spontaneous or assisted evolution of resistance or development of a field-deliverable vaccine are unlikely to be available in time. The disease’s characteristic allograft transmission through intimate contact simplifies isolation of insurance populations and breaking transmission in suppression trials. Better knowledge of contact matrices in wild devils will help focus timing and demographic targets of removals. A metapopulation approach is needed that integrates captive and wild-living island and peninsula (disease suppression) populations to minimize the loss of genetic diversity over 50 years until either extinction and reintroduction can occur, resistance evolves or a field deliverable vaccine is developed. Given the importance of the insurance populations and the low genetic diversity of devils, a conservative target for retention of 95% genetic diversity is recommended. Encouraging preliminary results of the first disease-suppression trial on a large peninsula show fewer late stage tumors and no apparent population decline. Limiting geographic spread or suppressing the disease on a broadscale are both unlikely to be feasible. Since the synergy of devil decline and impending fox establishment could have devastating consequences for Tasmanian wildlife, it is crucial to manage the dynamics of new and old predator species together.

5. Conservation management of Tasmanian devils in the context of an emerging, extinction-threatening disease: Devil Facial Tumor Disease

Author

Jones, ME, McCallum, HI, Jarman, PJ, Lees, CM, Hesterman, H, Hamede, RK, Mooney, NJ, Mann, D, Pukk, CE, Bergfeld, J, Jones, ME, McCallum, HI, Jarman, PJ, Lees, CM, Hesterman, H, Hamede, RK, Mooney, NJ, Mann, D, Pukk, CE, and Bergfeld, J

Abstract

An emerging infectious facial cancer threatens Tasmanian devils with extinction. The disease is likely to occur across the range of the devil within 5 years. This urgent time frame requires management options that can be implemented immediately: the establishment of insurance populations, in captivity, wild-living on islands,and aiming for eradication in areas that can be isolated. The long-term options of the spontaneous or assisted evolution of resistance or development of a field-deliverable vaccine are unlikely to be available in time. The disease’s characteristic allograft transmission through intimate contact simplifies isolation of insurance populations and breaking transmission in suppression trials. Better knowledge of contact matrices in wild devils will help focus timing and demographic targets of removals. A metapopulation approach is needed that integrates captive and wild-living island and peninsula (disease suppression) populations to minimize the loss of genetic diversity over 50 years until either extinction and reintroduction can occur, resistance evolves or a field deliverable vaccine is developed. Given the importance of the insurance populations and the low genetic diversity of devils, a conservative target for retention of 95% genetic diversity is recommended. Encouraging preliminary results of the first disease-suppression trial on a large peninsula show fewer late stage tumors and no apparent population decline. Limiting geographic spread or suppressing the disease on a broadscale are both unlikely to be feasible. Since the synergy of devil decline and impending fox establishment could have devastating consequences for Tasmanian wildlife, it is crucial to manage the dynamics of new and old predator species together.

6. Coevolution promotes the coexistence of Tasmanian devils and a fatal, transmissible cancer.

Author

Clement DT, Gallinson DG, Hamede RK, Jones ME, Margres MJ, McCallum H, and Storfer A

Subjects

Animals, Biological Coevolution, Biological Evolution, Tasmania, Marsupialia genetics, Facial Neoplasms veterinary, Facial Neoplasms genetics

Abstract

Emerging infectious diseases threaten natural populations, and data-driven modeling is critical for predicting population dynamics. Despite the importance of integrating ecology and evolution in models of host-pathogen dynamics, there are few wild populations for which long-term ecological datasets have been coupled with genome-scale data. Tasmanian devil (Sarcophilus harrisii) populations have declined range wide due to devil facial tumor disease (DFTD), a fatal transmissible cancer. Although early ecological models predicted imminent devil extinction, diseased devil populations persist at low densities, and recent ecological models predict long-term devil persistence. Substantial evidence supports the evolution of both devils and DFTD, suggesting coevolution may also influence continued devil persistence. Thus, we developed an individual-based, eco-evolutionary model of devil-DFTD coevolution parameterized with nearly 2 decades of devil demography, DFTD epidemiology, and genome-wide association studies. We characterized potential devil-DFTD coevolutionary outcomes and predicted the effects of coevolution on devil persistence and devil-DFTD coexistence. We found a high probability of devil persistence over 50 devil generations (100 years) and a higher likelihood of devil-DFTD coexistence, with greater devil recovery than predicted by previous ecological models. These novel results add to growing evidence for long-term devil persistence and highlight the importance of eco-evolutionary modeling for emerging infectious diseases., (© The Author(s) 2024. Published by Oxford University Press on behalf of The Society for the Study of Evolution (SSE). All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published

2024

7. Corrigendum to "Lead exposure and source attribution for a mammalian scavenger before and after a culling program" [Sci. Total Environ. 940 (2024) 173686].

Author

Jones EM, Finkelstein ME, Koch AJ, Pay JM, Jones ME, Hamede RK, and Hampton JO

Published

2024

8. Adaptive potential in the face of a transmissible cancer in Tasmanian devils.

Author

Strickland K, Jones ME, Storfer A, Hamede RK, Hohenlohe PA, Margres MJ, McCallum HI, Comte S, Lachish S, and Kruuk LEB

Subjects

Animals, Tasmania, Body Size genetics, Inbreeding Depression, Body Weight genetics, Genetic Predisposition to Disease, Genetic Variation, Selection, Genetic, Marsupialia genetics, Facial Neoplasms genetics, Facial Neoplasms veterinary, Phenotype

Abstract

Emerging infectious diseases (EIDs) not only cause catastrophic declines in wildlife populations but also generate selective pressures that may result in rapid evolutionary responses. One such EID is devil facial tumour disease (DFTD) in the Tasmanian devil. DFTD is almost always fatal and has reduced the average lifespan of individuals by around 2 years, likely causing strong selection for traits that reduce susceptibility to the disease, but population decline has also left Tasmanian devils vulnerable to inbreeding depression. We analysed 22 years of data from an ongoing study of a population of Tasmanian devils on Freycinet Peninsula, Tasmania, to (1) identify whether DFTD may be causing selection on body size, by estimating phenotypic and genetic correlations between DFTD and size traits, (2) estimate the additive genetic variance of susceptibility to DFTD, and (3) investigate whether size traits or susceptibility to DFTD were under inbreeding depression. We found a positive phenotypic relationship between head width and susceptibility to DFTD, but this was not underpinned by a genetic correlation. Conversely, we found a negative phenotypic relationship between body weight and susceptibility to DFTD, and there was evidence for a negative genetic correlation between susceptibility to DFTD and body weight. There was additive genetic variance in susceptibility to DFTD, head width and body weight, but there was no evidence for inbreeding depression in any of these traits. These results suggest that Tasmanian devils have the potential to respond adaptively to DFTD, although the realised evolutionary response will critically further depend on the evolution of DFTD itself., (© 2024 The Author(s). Molecular Ecology published by John Wiley & Sons Ltd.)

Published

2024

9. Lead exposure and source attribution for a mammalian scavenger before and after a culling program.

Author

Jones EM, Koch AJ, Pay JM, Jones ME, Hamede RK, and Hampton JO

Subjects

Animals, Environmental Pollutants, Environmental Exposure statistics & numerical data, Environmental Monitoring, Animal Culling, Lead blood, Marsupialia

Abstract

Lead-based ammunition is a significant source of environmental lead and threatens species that scavenge lead-shot carcasses, particularly in areas with intensive shooting. With the impacts of lead on avian scavengers well established, there is increasing focus on the effects of lead on mammalian scavengers. We investigated lead exposure in a morphologically specialized mammalian scavenger, the Tasmanian devil (Sarcophilus harrisii), by analyzing their blood lead levels (BLLs) before and after a marsupial culling program using linear mixed effects models. We compared lead isotope signatures in devil blood to those in the culling ammunition to inform potential source attributions. We sampled 23 devils before culling and 15 after culling, finding no significant difference in mean BLLs pre and post-culling. However, devils captured closer to forestry coupes where culling had occurred had higher BLLs, and a greater proportion of devils displayed elevated BLLs post-culling (33 % compared to 18 % pre-culling). The highest BLL (7.93 μg/dL) was found in a devil post-culling and this individual had lead isotope signatures that matched the ammunition samples analyzed, suggesting the individual was exposed to lead from scavenging on culled carcasses. While 18 % of the devil blood lead samples had isotope signatures consistent with the ammunition samples, most were measurably different, indicating other sources of lead in the landscape. BLLs in our study landscape were similar to published BLLs for wild devils across Tasmania. That said, lead isotope signatures in the blood of individual devils sampled both before and after culling shifted closer to those of ammunition samples post-culling. Our results indicate that while some individual devils may have been exposed to lead from culling, most devils in the landscape did not show evidence of recent exposure. However, even low lead levels can adversely impact wildlife health and immunity, a particular concern for devils, a species endangered by disease., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

10. Genome of the endangered eastern quoll (Dasyurus viverrinus) reveals signatures of historical decline and pelage color evolution.

Author

Hartley GA, Frankenberg SR, Robinson NM, MacDonald AJ, Hamede RK, Burridge CP, Jones ME, Faulkner T, Shute H, Rose K, Brewster R, O'Neill RJ, Renfree MB, Pask AJ, and Feigin CY

Subjects

Animals, Australia, Pigmentation genetics, Biological Evolution, Transcriptome, Endangered Species, Marsupialia genetics, Genome

Abstract

The eastern quoll (Dasyurus viverrinus) is an endangered marsupial native to Australia. Since the extirpation of its mainland populations in the 20th century, wild eastern quolls have been restricted to two islands at the southern end of their historical range. Eastern quolls are the subject of captive breeding programs and attempts have been made to re-establish a population in mainland Australia. However, few resources currently exist to guide the genetic management of this species. Here, we generated a reference genome for the eastern quoll with gene annotations supported by multi-tissue transcriptomes. Our assembly is among the most complete marsupial genomes currently available. Using this assembly, we infer the species' demographic history, identifying potential evidence of a long-term decline beginning in the late Pleistocene. Finally, we identify a deletion at the ASIP locus that likely underpins pelage color differences between the eastern quoll and the closely related Tasmanian devil (Sarcophilus harrisii)., (© 2024. The Author(s).)

Published

2024

11. Human habitat modification, not apex scavenger decline, drives isotopic niche variation in a carnivore community.

Author

Bell O, Jones ME, Ruiz-Aravena M, Hamilton DG, Comte S, Hamer R, Hamede RK, Newton J, Bearhop S, and McDonald RA

Subjects

Animals, Marsupialia, Humans, Carnivora, Ecosystem

Abstract

Top carnivores can influence the structure of ecological communities, primarily through competition and predation; however, communities are also influenced by bottom-up forces such as anthropogenic habitat disturbance. Top carnivore declines will likely alter competitive dynamics within and amongst sympatric carnivore species. Increasing intraspecific competition is generally predicted to drive niche expansion and/or individual specialisation, while interspecific competition tends to constrain niches. Using stable isotope analysis of whiskers, we studied the effects of Tasmanian devil Sarcophilus harrisii declines upon the population- and individual-level isotopic niches of Tasmanian devils and sympatric spotted-tailed quolls Dasyurus maculatus subsp. maculatus. We investigated whether time since the onset of devil decline (a proxy for severity of decline) and landscape characteristics affected the isotopic niche breadth and overlap of devil and quoll populations. We quantified individual isotopic niche breadth for a subset of Tasmanian devils and spotted-tailed quolls and assessed whether between-site population niche variation was driven by individual-level specialisation. Tasmanian devils and spotted-tailed quolls demonstrated smaller population-level isotopic niche breadths with increasing human-modified habitat, while time since the onset of devil decline had no effect on population-level niche breadth or interspecific niche overlap. Individual isotopic niche breadths of Tasmanian devils and spotted-tailed quolls were narrower in human-modified landscapes, likely driving population isotopic niche contraction, however, the degree of individuals' specialisation relative to one another remained constant. Our results suggest that across varied landscapes, mammalian carnivore niches can be more sensitive to the bottom-up forces of anthropogenic habitat disturbance than to the top-down effects of top carnivore decline., (© 2024. The Author(s).)

Published

2024

12. Complex associations between cancer progression and immune gene expression reveals early influence of transmissible cancer on Tasmanian devils.

Author

Raven N, Klaassen M, Madsen T, Jones M, Hamilton DG, Ruiz-Aravena M, Thomas F, Hamede RK, and Ujvari B

Subjects

Animals, Immune System pathology, Gene Expression, Facial Neoplasms genetics, Facial Neoplasms veterinary, Marsupialia genetics, Daunorubicin analogs & derivatives

Abstract

The world's largest extant carnivorous marsupial, the Tasmanian devil, is challenged by Devil Facial Tumor Disease (DFTD), a fatal, clonally transmitted cancer. In two decades, DFTD has spread across 95% of the species distributional range. A previous study has shown that factors such as season, geographic location, and infection with DFTD can impact the expression of immune genes in Tasmanian devils. To date, no study has investigated within-individual immune gene expression changes prior to and throughout the course of DFTD infection. To explore possible changes in immune response, we investigated four locations across Tasmania that differed in DFTD exposure history, ranging between 2 and >30 years. Our study demonstrated considerable complexity in the immune responses to DFTD. The same factors (sex, age, season, location and DFTD infection) affected immune gene expression both across and within devils, although seasonal and location specific variations were diminished in DFTD affected devils. We also found that expression of both adaptive and innate immune genes starts to alter early in DFTD infection and continues to change as DFTD progresses. A novel finding was that the lower expression of immune genes MHC-II, NKG2D and CD8 may predict susceptibility to earlier DFTD infection. A case study of a single devil with regressed tumor showed opposite/contrasting immune gene expression patterns compared to the general trends observed across devils with DFTD infection. Our study highlights the complexity of DFTD's interactions with the host immune system and the need for long-term studies to fully understand how DFTD alters the evolutionary trajectory of devil immunity., 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. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Raven, Klaassen, Madsen, Jones, Hamilton, Ruiz-Aravena, Thomas, Hamede and Ujvari.)

Published

2024

13. Wildlife nidoviruses: biology, epidemiology, and disease associations of selected nidoviruses of mammals and reptiles.

Author

Flies AS, Flies EJ, Fountain-Jones NM, Musgrove RE, Hamede RK, Philips A, Perrott MRF, and Dunowska M

Abstract

Wildlife is the source of many emerging infectious diseases. Several viruses from the order Nidovirales have recently emerged in wildlife, sometimes with severe consequences for endangered species. The order Nidovirales is currently classified into eight suborders, three of which contain viruses of vertebrates. Vertebrate coronaviruses (suborder Cornidovirineae ) have been extensively studied, yet the other major suborders have received less attention. The aim of this minireview was to summarize the key findings from the published literature on nidoviruses of vertebrate wildlife from two suborders: Arnidovirineae and Tornidovirineae . These viruses were identified either during investigations of disease outbreaks or through molecular surveys of wildlife viromes, and include pathogens of reptiles and mammals. The available data on key biological features, disease associations, and pathology are presented, in addition to data on the frequency of infections among various host populations, and putative routes of transmission. While nidoviruses discussed here appear to have a restricted in vivo host range, little is known about their natural life cycle. Observational field-based studies outside of the mortality events are needed to facilitate an understanding of the virus-host-environment interactions that lead to the outbreaks. Laboratory-based studies are needed to understand the pathogenesis of diseases caused by novel nidoviruses and their evolutionary histories. Barriers preventing research progress include limited funding and the unavailability of virus- and host-specific reagents. To reduce mortalities in wildlife and further population declines, proactive development of expertise, technologies, and networks should be developed. These steps would enable effective management of future outbreaks and support wildlife conservation., Competing Interests: The authors declare no conflict of interest.

Published

2023

14. Transmissible cancer influences immune gene expression in an endangered marsupial, the Tasmanian devil (Sarcophilus harrisii).

Author

Raven N, Klaassen M, Madsen T, Thomas F, Hamede RK, and Ujvari B

Subjects

Animals, Animals, Wild genetics, Gene Expression, Seasons, Facial Neoplasms epidemiology, Facial Neoplasms genetics, Facial Neoplasms veterinary, Marsupialia genetics

Abstract

Understanding the effects of wildlife diseases on populations requires insight into local environmental conditions, host defence mechanisms, host life-history trade-offs, pathogen population dynamics, and their interactions. The survival of Tasmanian devils (Sarcophilus harrisii) is challenged by a novel, fitness limiting pathogen, Tasmanian devil facial tumour disease (DFTD), a clonally transmissible, contagious cancer. In order to understand the devils' capacity to respond to DFTD, it is crucial to gain information on factors influencing the devils' immune system. By using RT-qPCR, we investigated how DFTD infection in association with intrinsic (sex and age) and environmental (season) factors influences the expression of 10 immune genes in Tasmanian devil blood. Our study showed that the expression of immune genes (both innate and adaptive) differed across seasons, a pattern that was altered when infected with DFTD. The expression of immunogbulins IgE and IgM:IgG showed downregulation in colder months in DFTD infected animals. We also observed strong positive association between the expression of an innate immune gene, CD16, and DFTD infection. Our results demonstrate that sampling across seasons, age groups and environmental conditions are beneficial when deciphering the complex ecoevolutionary interactions of not only conventional host-parasite systems, but also of host and diseases with high mortality rates, such as transmissible cancers., (© 2022 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published

2022

15. Isotopic niche variation in Tasmanian devils Sarcophilus harrisii with progression of devil facial tumor disease.

Author

Bell O, Jones ME, Cunningham CX, Ruiz-Aravena M, Hamilton DG, Comte S, Hamede RK, Bearhop S, and McDonald RA

Abstract

Devil facial tumor disease (DFTD) is a transmissible cancer affecting Tasmanian devils Sarcophilus harrisii . The disease has caused severe population declines and is associated with demographic and behavioral changes, including earlier breeding, younger age structures, and reduced dispersal and social interactions. Devils are generally solitary, but social encounters are commonplace when feeding upon large carcasses. DFTD tumors can disfigure the jaw and mouth and so diseased individuals might alter their diets to enable ingestion of alternative foods, to avoid conspecific interactions, or to reduce competition. Using stable isotope analysis (δ 13 C and δ 15 N) of whiskers, we tested whether DFTD progression, measured as tumor volume, affected the isotope ratios and isotopic niches of 94 infected Tasmanian devils from six sites in Tasmania, comprising four eucalypt plantations, an area of smallholdings and a national park. Then, using tissue from 10 devils sampled before and after detection of tumors and 8 devils where no tumors were detected, we examined whether mean and standard deviation of δ 13 C and δ 15 N of the same individuals changed between healthy and diseased states. δ 13 C and δ 15 N values were generally not related to tumor volume in infected devils, though at one site, Freycinet National Park, δ 15 N values increased significantly as tumor volume increased. Infection with DFTD was not associated with significant changes in the mean or standard deviation of δ 13 C and δ 15 N values in individual devils sampled before and after detection of tumors. Our analysis suggests that devils tend to maintain their isotopic niche in the face of DFTD infection and progression, except where ecological conditions facilitate a shift in diets and feeding behaviors, demonstrating that ecological context, alongside disease severity, can modulate the behavioral responses of Tasmanian devils to DFTD., Competing Interests: The authors declare no conflict of interest., (© 2021 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2021

16. Identifying key questions in the ecology and evolution of cancer.

Author

Dujon AM, Aktipis A, Alix-Panabières C, Amend SR, Boddy AM, Brown JS, Capp JP, DeGregori J, Ewald P, Gatenby R, Gerlinger M, Giraudeau M, Hamede RK, Hansen E, Kareva I, Maley CC, Marusyk A, McGranahan N, Metzger MJ, Nedelcu AM, Noble R, Nunney L, Pienta KJ, Polyak K, Pujol P, Read AF, Roche B, Sebens S, Solary E, Staňková K, Swain Ewald H, Thomas F, and Ujvari B

Abstract

The application of evolutionary and ecological principles to cancer prevention and treatment, as well as recognizing cancer as a selection force in nature, has gained impetus over the last 50 years. Following the initial theoretical approaches that combined knowledge from interdisciplinary fields, it became clear that using the eco-evolutionary framework is of key importance to understand cancer. We are now at a pivotal point where accumulating evidence starts to steer the future directions of the discipline and allows us to underpin the key challenges that remain to be addressed. Here, we aim to assess current advancements in the field and to suggest future directions for research. First, we summarize cancer research areas that, so far, have assimilated ecological and evolutionary principles into their approaches and illustrate their key importance. Then, we assembled 33 experts and identified 84 key questions, organized around nine major themes, to pave the foundations for research to come. We highlight the urgent need for broadening the portfolio of research directions to stimulate novel approaches at the interface of oncology and ecological and evolutionary sciences. We conclude that progressive and efficient cross-disciplinary collaborations that draw on the expertise of the fields of ecology, evolution and cancer are essential in order to efficiently address current and future questions about cancer., Competing Interests: The authors declare no conflict of interest., (© 2020 The Authors. Evolutionary Applications published by John Wiley & Sons Ltd.)

Published

2021

17. Infectious disease and sickness behaviour: tumour progression affects interaction patterns and social network structure in wild Tasmanian devils.

Author

Hamilton DG, Jones ME, Cameron EZ, Kerlin DH, McCallum H, Storfer A, Hohenlohe PA, and Hamede RK

Subjects

Animals, Communicable Diseases, Immunity, Humoral, Social Networking, Behavior, Animal physiology, Facial Neoplasms veterinary, Illness Behavior physiology, Marsupialia physiology

Abstract

Infectious diseases, including transmissible cancers, can have a broad range of impacts on host behaviour, particularly in the latter stages of disease progression. However, the difficulty of early diagnoses makes the study of behavioural influences of disease in wild animals a challenging task. Tasmanian devils ( Sarcophilus harrisii ) are affected by a transmissible cancer, devil facial tumour disease (DFTD), in which tumours are externally visible as they progress. Using telemetry and mark-recapture datasets, we quantify the impacts of cancer progression on the behaviour of wild devils by assessing how interaction patterns within the social network of a population change with increasing tumour load. The progression of DFTD negatively influences devils' likelihood of interaction within their network. Infected devils were more active within their network late in the mating season, a pattern with repercussions for DFTD transmission. Our study provides a rare opportunity to quantify and understand the behavioural feedbacks of disease in wildlife and how they may affect transmission and population dynamics in general.

Published

2020

18. Blood Parasites in Endangered Wildlife-Trypanosomes Discovered During a Survey of Haemoprotozoa from the Tasmanian Devil.

Author

Egan SL, Ruiz-Aravena M, Austen JM, Barton X, Comte S, Hamilton DG, Hamede RK, Ryan UM, Irwin PJ, Jones ME, and Oskam CL

Abstract

The impact of emerging infectious diseases is increasingly recognised as a major threat to wildlife. Wild populations of the endangered Tasmanian devil, Sarcophilus harrisii , are experiencing devastating losses from a novel transmissible cancer, devil facial tumour disease (DFTD); however, despite the rapid decline of this species, there is currently no information on the presence of haemoprotozoan parasites. In the present study, 95 Tasmanian devil blood samples were collected from four populations in Tasmania, Australia, which underwent molecular screening to detect four major groups of haemoprotozoa: (i) trypanosomes, (ii) piroplasms, (iii) Hepatozoon , and (iv) haemosporidia. Sequence results revealed Trypanosoma infections in 32/95 individuals. Trypanosoma copemani was identified in 10 Tasmanian devils from three sites and a second Trypanosoma sp. was identified in 22 individuals that were grouped within the poorly described T. cyclops clade. A single blood sample was positive for Babesia sp., which most closely matched Babesia lohae . No other blood protozoan parasite DNA was detected. This study provides the first insight into haemoprotozoa from the Tasmanian devil and the first identification of Trypanosoma and Babesia in this carnivorous marsupial., Competing Interests: The authors declare no conflicts of interest.

Published

2020

19. Age-related variation in the trophic characteristics of a marsupial carnivore, the Tasmanian devil Sarcophilus harrisii .

Author

Bell O, Jones ME, Ruiz-Aravena M, Hamede RK, Bearhop S, and McDonald RA

Abstract

Age-related changes in diet have implications for competitive interactions and for predator-prey dynamics, affecting individuals and groups at different life stages. To quantify patterns of variation and ontogenetic change in the diets of Tasmanian devils Sarcophilus harrisii , a threatened marsupial carnivore, we analyzed variation in the stable isotope composition of whisker tissue samples taken from 91 individual devils from Wilmot, Tasmania from December 2014 to February 2017. Both δ 13 C and δ 15 N decreased with increasing age in weaned Tasmanian devils, indicating that as they age devils rely less on small mammals and birds, and more on large herbivores. Devils <12 months old had broader group isotopic niches, as estimated by Bayesian standard ellipses (SEA B mode = 1.042) than devils from 12 to 23 months old (mode = 0.541) and devils ≥24 months old (mode = 0.532). Devils <24 months old had broader individual isotopic niches (SEA B mode range 0.492-1.083) than devils ≥24 months old (mode range 0.092-0.240). A decrease in δ 15 N from the older whisker sections to the more recently grown sections in devils <24 months old likely reflects the period of weaning in this species, as this pattern was not observed in devils ≥24 months old. Our data reveal changes in the isotopic composition of devil whiskers with increasing age, accompanied by a reduction in isotopic variation both among population age classes and within individuals, reflecting the effect of weaning in early life, and a likely shift from an initially diverse diet of small mammals, birds, and invertebrates towards increasing consumption of larger herbivores in adulthood., Competing Interests: None declared., (© 2020 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2020

20. Contemporary Demographic Reconstruction Methods Are Robust to Genome Assembly Quality: A Case Study in Tasmanian Devils.

Author

Patton AH, Margres MJ, Stahlke AR, Hendricks S, Lewallen K, Hamede RK, Ruiz-Aravena M, Ryder O, McCallum HI, Jones ME, Hohenlohe PA, and Storfer A

Subjects

Animals, Female, Demography methods, Genome, Genomics methods, Genomics standards, Marsupialia genetics

Abstract

Reconstructing species' demographic histories is a central focus of molecular ecology and evolution. Recently, an expanding suite of methods leveraging either the sequentially Markovian coalescent (SMC) or the site-frequency spectrum has been developed to reconstruct population size histories from genomic sequence data. However, few studies have investigated the robustness of these methods to genome assemblies of varying quality. In this study, we first present an improved genome assembly for the Tasmanian devil using the Chicago library method. Compared with the original reference genome, our new assembly reduces the number of scaffolds (from 35,975 to 10,010) and increases the scaffold N90 (from 0.101 to 2.164 Mb). Second, we assess the performance of four contemporary genomic methods for inferring population size history (PSMC, MSMC, SMC++, Stairway Plot), using the two devil genome assemblies as well as simulated, artificially fragmented genomes that approximate the hypothesized demographic history of Tasmanian devils. We demonstrate that each method is robust to assembly quality, producing similar estimates of Ne when simulated genomes were fragmented into up to 5,000 scaffolds. Overall, methods reliant on the SMC are most reliable between ∼300 generations before present (gbp) and 100 kgbp, whereas methods exclusively reliant on the site-frequency spectrum are most reliable between the present and 30 gbp. Our results suggest that when used in concert, genomic methods for reconstructing species' effective population size histories 1) can be applied to nonmodel organisms without highly contiguous reference genomes, and 2) are capable of detecting independently documented effects of historical geological events., (© The Author(s) 2019. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2019

21. Individual and temporal variation in pathogen load predicts long-term impacts of an emerging infectious disease.

Author

Wells K, Hamede RK, Jones ME, Hohenlohe PA, Storfer A, and McCallum HI

Subjects

Animals, Bayes Theorem, Humans, Retrospective Studies, Communicable Diseases, Emerging, Facial Neoplasms epidemiology, Marsupialia

Abstract

Emerging infectious diseases increasingly threaten wildlife populations. Most studies focus on managing short-term epidemic properties, such as controlling early outbreaks. Predicting long-term endemic characteristics with limited retrospective data is more challenging. We used individual-based modeling informed by individual variation in pathogen load and transmissibility to predict long-term impacts of a lethal, transmissible cancer on Tasmanian devil (Sarcophilus harrisii) populations. For this, we employed approximate Bayesian computation to identify model scenarios that best matched known epidemiological and demographic system properties derived from 10 yr of data after disease emergence, enabling us to forecast future system dynamics. We show that the dramatic devil population declines observed thus far are likely attributable to transient dynamics (initial dynamics after disease emergence). Only 21% of matching scenarios led to devil extinction within 100 yr following devil facial tumor disease (DFTD) introduction, whereas DFTD faded out in 57% of simulations. In the remaining 22% of simulations, disease and host coexisted for at least 100 yr, usually with long-period oscillations. Our findings show that pathogen extirpation or host-pathogen coexistence are much more likely than the DFTD-induced devil extinction, with crucial management ramifications. Accounting for individual-level disease progression and the long-term outcome of devil-DFTD interactions at the population-level, our findings suggest that immediate management interventions are unlikely to be necessary to ensure the persistence of Tasmanian devil populations. This is because strong population declines of devils after disease emergence do not necessarily translate into long-term population declines at equilibria. Our modeling approach is widely applicable to other host-pathogen systems to predict disease impact beyond transient dynamics., (© 2019 by the Ecological Society of America.)

Published

2019

22. Conserving adaptive potential: lessons from Tasmanian devils and their transmissible cancer.

Author

Hohenlohe PA, McCallum HI, Jones ME, Lawrance MF, Hamede RK, and Storfer A

Abstract

Maintenance of adaptive genetic variation has long been a goal of management of natural populations, but only recently have genomic tools allowed identification of specific loci associated with fitness-related traits in species of conservation concern. This raises the possibility of managing for genetic variation directly relevant to specific threats, such as those due to climate change or emerging infectious disease. Tasmanian devils (Sarcophilus harrisii) face the threat of a transmissible cancer, devil facial tumor disease (DFTD), that has decimated wild populations and led to intensive management efforts. Recent discoveries from genomic and modeling studies reveal how natural devil populations are responding to DFTD, and can inform management of both captive and wild devil populations. Notably, recent studies have documented genetic variation for disease-related traits and rapid evolution in response to DFTD, as well as potential mechanisms for disease resistance such as immune response and tumor regression in wild devils. Recent models predict dynamic persistence of devils with or without DFTD under a variety of modeling scenarios, although at much lower population densities than before DFTD emerged, contrary to previous predictions of extinction. As a result, current management that focuses on captive breeding and release for maintaining genome-wide genetic diversity or demographic supplementation of populations could have negative consequences. Translocations of captive devils into wild populations evolving with DFTD can cause outbreeding depression and/or increases in the force of infection and thereby the severity of the epidemic, and we argue that these risks outweigh any benefits of demographic supplementation in wild populations. We also argue that genetic variation at loci associated with DFTD should be monitored in both captive and wild populations, and that as our understanding of DFTD-related genetic variation improves, considering genetic management approaches to target this variation is warranted in developing conservation strategies for Tasmanian devils.

Published

2019

23. Sex bias in ability to cope with cancer: Tasmanian devils and facial tumour disease.

Author

Ruiz-Aravena M, Jones ME, Carver S, Estay S, Espejo C, Storfer A, and Hamede RK

Subjects

Animals, Facial Neoplasms epidemiology, Facial Neoplasms pathology, Female, Male, Selection, Genetic, Sex Factors, Tasmania epidemiology, Facial Neoplasms veterinary, Marsupialia physiology

Abstract

Knowledge of the ecological dynamics between hosts and pathogens during the initial stages of disease emergence is crucial to understanding the potential for evolution of new interspecific interactions. Tasmanian devil ( Sarcophilus harrisii ) populations have declined precipitously owing to infection by a transmissible cancer (devil facial tumour disease, DFTD) that emerged approximately 20 years ago. Since the emergence of DFTD, and as the disease spreads across Tasmania, the number of devils has dropped up to 90% across 80% of the species's distributional range. As a result, the disease is expected to act as a strong selective force on hosts to develop mechanisms of tolerance and/or resistance to the infection. We assessed the ability of infected devils to cope with infection, which translates into host tolerance to the cancer, by using the reaction norm of the individual body condition by tumour burden. We found that body condition of infected hosts is negatively affected by cancer progression. Males and females presented significant differences in their tolerance levels to infection, with males suffering declines of up to 25% of their body condition, in contrast to less than 5% in females. Sex-related differences in tolerance to cancer progression may select for changes in life-history strategies of the host and could also alter the selective environment for the tumours., (© 2018 The Author(s).)

Published

2018

24. Untangling the model muddle: Empirical tumour growth in Tasmanian devil facial tumour disease.

Author

Hamede RK, Beeton NJ, Carver S, and Jones ME

Subjects

Animals, Female, Male, Tasmania epidemiology, Animal Diseases epidemiology, Animal Diseases pathology, Facial Neoplasms pathology, Facial Neoplasms veterinary, Marsupialia physiology

Abstract

A pressing and unresolved topic in cancer research is how tumours grow in the absence of treatment. Despite advances in cancer biology, therapeutic and diagnostic technologies, there is limited knowledge regarding the fundamental growth and developmental patterns in solid tumours. In this ten year study, we estimated growth curves in Tasmanian devil facial tumours, a clonal transmissible cancer, in males and females with two different karyotypes (diploid, tetraploid) and facial locations (mucosal, dermal), using established differential equation models and model selection. Logistic growth was the most parsimonious model for diploid, tetraploid and mucosal tumours, with less model certainty for dermal tumours. Estimates of daily proportional tumour growth rate per day (95% Bayesian CIs) varied with ploidy and location [diploid 0.016 (0.014-0.020), tetraploid 0.026 (0.020-0.033), mucosal 0.013 (0.011-0.015), dermal 0.020 (0.016-0.024)]. Final tumour size (cm 3 ) also varied, particularly the upper credible interval owing to host mortality as tumours approached maximum volume [diploid 364 (136-2,475), tetraploid 172 (100-305), dermal 226 (134-471)]. To our knowledge, these are the first empirical estimates of tumour growth in the absence of treatment in a wild population. Through this animal-cancer system our findings may enhance understanding of how tumour properties interact with growth dynamics in other types of cancer.

Published

2017

25. Infection of the fittest: devil facial tumour disease has greatest effect on individuals with highest reproductive output.

Author

Wells K, Hamede RK, Kerlin DH, Storfer A, Hohenlohe PA, Jones ME, and McCallum HI

Subjects

Animals, Animals, Wild, Facial Neoplasms veterinary, Marsupialia, Reproduction

Abstract

Emerging infectious diseases rarely affect all members of a population equally and determining how individuals' susceptibility to infection is related to other components of their fitness is critical to understanding disease impacts at a population level and for predicting evolutionary trajectories. We introduce a novel state-space model framework to investigate survival and fecundity of Tasmanian devils (Sarcophilus harrisii) affected by a transmissible cancer, devil facial tumour disease. We show that those devils that become host to tumours have otherwise greater fitness, with higher survival and fecundity rates prior to disease-induced death than non-host individuals that do not become infected, although high tumour loads lead to high mortality. Our finding that individuals with the greatest reproductive value are those most affected by the cancer demonstrates the need to quantify both survival and fecundity in context of disease progression for understanding the impact of disease on wildlife populations., (© 2017 John Wiley & Sons Ltd/CNRS.)

Published

2017

26. Transmissible cancer in Tasmanian devils: localized lineage replacement and host population response.

Author

Hamede RK, Pearse AM, Swift K, Barmuta LA, Murchison EP, and Jones ME

Subjects

Age Distribution, Animals, Bites and Stings epidemiology, Clonal Evolution, Facial Neoplasms epidemiology, Karyotype, Longitudinal Studies, Prevalence, Tasmania epidemiology, Facial Neoplasms genetics, Facial Neoplasms veterinary, Major Histocompatibility Complex genetics, Marsupialia genetics, Ploidies

Abstract

Tasmanian devil facial tumour disease (DFTD) is a clonally transmissible cancer threatening the Tasmanian devil (Sarcophilus harrisii) with extinction. Live cancer cells are the infectious agent, transmitted to new hosts when individuals bite each other. Over the 18 years since DFTD was first observed, distinct genetic and karyotypic sublineages have evolved. In this longitudinal study, we investigate the associations between tumour karyotype, epidemic patterns and host demographic response to the disease. Reduced host population effects and low DFTD infection rates were associated with high prevalence of tetraploid tumours. Subsequent replacement by a diploid variant of DFTD coincided with a rapid increase in disease prevalence, population decline and reduced mean age of the population. Our results suggest a role for tumour genetics in DFTD transmission dynamics and epidemic outcome. Future research, for this and other highly pathogenic emerging infectious diseases, should focus on understanding the evolution of host and pathogen genotypes, their effects on susceptibility and tolerance to infection, and their implications for designing novel genetic management strategies. This study provides evidence for a rapid localized lineage replacement occurring within a transmissible cancer epidemic and highlights the possibility that distinct DFTD genetic lineages may harbour traits that influence pathogen fitness., (© 2015 The Author(s).)

Published

2015

27. Biting injuries and transmission of Tasmanian devil facial tumour disease.

Author

Hamede RK, McCallum H, and Jones M

Subjects

Aging, Animals, Endangered Species, Facial Neoplasms pathology, Female, Male, Seasons, Tasmania, Wounds and Injuries pathology, Bites and Stings, Facial Neoplasms veterinary, Marsupialia injuries, Wounds and Injuries veterinary

Abstract

The Tasmanian devil is threatened with extinction by devil facial tumour disease (DFTD), a unique infectious cancer in which the tumour cells themselves, which derive from a single long-dead host devil, are the infective agent and the tumour is an infectious parasitic cell line. Transmission is thought to occur via direct inoculation of tumour cells when susceptible and infected individuals bite each other or by fomitic transfer of tumour cells. The nature of transmission and the extent to which biting behaviour and devil ecology is associated with infection risk remains unclear. Until our recent study in north-west Tasmania showed reduced population and individual impacts, DFTD had caused massive population declines in all populations monitored. In this paper, we investigate seasonal patterns of injuries resulting from bites between individuals, DFTD infection status and tumour location in two populations to determine whether the number of bites predicts the acquisition of DFTD and to explore the possibility that the reduced impacts of DFTD in north-west Tasmania are attributed to reduced bite rates. Devils with fewer bites were more likely to develop DFTD and primary tumours occurred predominantly inside the oral cavity. These results are not consistent with transmission occurring from the biter to the bitten animal but suggest that dominant individuals delivering bites, possibly by biting the tumours of other devils, are at higher risk of acquiring infection than submissive individuals receiving bites. Bite rates, which were higher during autumn and winter, did not differ between sites, suggesting that the reduced population impacts in north-west Tasmania cannot be explained by lower bite rates. Our study emphasizes the importance of longitudinal studies of individually marked animals for understanding the ecology and transmission dynamics of infectious diseases and parasites in wild populations., (© 2012 The Authors. Journal of Animal Ecology © 2012 British Ecological Society.)

Published

2013

28. Contact networks in a wild Tasmanian devil (Sarcophilus harrisii) population: using social network analysis to reveal seasonal variability in social behaviour and its implications for transmission of devil facial tumour disease.

Author

Hamede RK, Bashford J, McCallum H, and Jones M

Subjects

Animals, Female, Male, Disease Transmission, Infectious veterinary, Marsupialia physiology, Neoplasms veterinary, Seasons, Sexual Behavior, Animal, Social Behavior

Abstract

The structure of the contact network between individuals has a profound effect on the transmission of infectious disease. Using a novel technology--proximity sensing radio collars--we described the contact network in a population of Tasmanian devils. This largest surviving marsupial carnivore is threatened by a novel infectious cancer. All devils were connected in a single giant component, which would permit disease to spread throughout the network from any single infected individual. Unlike the contact networks for many human diseases, the degree distribution was not highly aggregated. Nevertheless, the empirically derived networks differed from random networks. Contact networks differed between the mating and non-mating seasons, with more extended male-female associations in the mating season and a greater frequency of female-female associations outside the mating season. Our results suggest that there is limited potential to control the disease by targeting highly connected age or sex classes.

Published

2009