Your search keyword '"Danielle Stokeld"' showing total 18 results

1. Mapping terrestrial groundwater‐dependent ecosystems in arid Australia using Landsat‐8 time‐series data and singular value decomposition

Author

Jayne Brim Box, Ian Leiper, Catherine Nano, Danielle Stokeld, Peter Jobson, Adrian Tomlinson, Dale Cobban, Tim Bond, Debbie Randall, and Paul Box

Subjects

Ecology, Computers in Earth Sciences, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Published

2022

2. No mammal recovery from feral cat experimental exclusion trials in Kakadu National Park

Author

Danielle Stokeld, Alaric Fisher, Tim Gentles, Brydie M. Hill, John C. Z. Woinarski, and Graeme R. Gillespie

Subjects

Management, Monitoring, Policy and Law, Ecology, Evolution, Behavior and Systematics

Abstract

Context Small and medium-sized native mammals have declined precipitously across northern Australia. Feral cats have been implicated in causing declines and ongoing suppression of populations. Aims The aim of the present study was to evaluate the response of small and medium-sized native mammal populations when cat predation was removed. Methods A field experiment was conducted in a tropical savanna environment of northern Australia. Three experimental treatments were applied to six plots to compare and contrast responses of native mammals to predator exclusion and the additive effects of frequent fire. Plots were monitored regularly between 2013 and 2017. Key results After 4 years of monitoring, no significant difference in capture rates of native mammals was detected between cat-accessible plots and those where they were excluded. Conclusions There was no evidence of population recovery of native mammals in response to predator exclusion. There was some evidence that frequent burning, independent of cat exclusion, adversely affects native mammal diversity. Implications Although predation by feral cats is a major threat to small and medium-sized native mammals, disturbance from fire, and grazing by introduced herbivores, have been shown to significantly impede native mammal population recovery in tropical savanna ecosystems. Management programs that solely focus on suppressing feral cat populations may be inadequate in ameliorating ongoing mammal declines in landscapes with other significant disturbance regimes.

Published

2021

3. Variation in feral cat density between two large adjacent islands in Australia’s monsoon tropics

Author

Tiwi Land Rangers, Hugh F. Davies, Graeme R. Gillespie, Matthew W. Rees, Anna C. Miller, Danielle Stokeld, and Brett P. Murphy

Subjects

0106 biological sciences, Herbivore, Ecology, Biodiversity, Tropics, Monsoon, 010603 evolutionary biology, 01 natural sciences, Population density, Predation, 010601 ecology, Geography, Feral cat, Mammal, Nature and Landscape Conservation

Abstract

Despite contributing to the ongoing collapse of native mammal populations across northern Australian savannas, we have limited understanding of the ecological constraints of feral cat population density in this system. Addressing such knowledge gaps is a crucial step towards mitigating the impacts of feral cats, and is particularly important for the large islands off northern Australia that remain as strongholds for numerous species vulnerable to cat predation. Here, we investigated cat density across Melville and Bathurst Island, two large islands in Australia’s monsoon tropics. We deployed large grids (~13 km2) of 70 camera-traps at four locations to investigate how feral cat density varies under different combinations of fire frequency, and feral herbivore presence. Using spatially-explicit capture-recapture models, we estimated feral cat density on Melville Island to be 0.15 cats km−2. We did not record any cat detections on Bathurst Island. Using simulations, we predicted that if cat density on Bathurst Island was equal to that on Melville Island, we would have expected to record 27.9 detections of 9.9 individual cats. Our results, coupled with other recent surveys, suggest that the density of cats is much lower on Bathurst Island than the adjacent Melville Island. The absence of feral herbivores on Bathurst Island may have contributed to this variation in cat density. Management that enhances understorey vegetation density, through feral herbivore control, as well as fire management, could help mitigate the impact of feral cats on northern Australian savanna biodiversity.

Published

2021

4. Habitat structural complexity explains patterns of feral cat and dingo occurrence in monsoonal Australia

Author

Alaric Fisher, Brydie M. Hill, Alyson M. Stobo-Wilson, T. Mahney, Alys Stevens, Danielle Stokeld, Luke D. Einoder, Hugh F. Davies, Brett P. Murphy, Warddeken Rangers, Graeme R. Gillespie, John C. Z. Woinarski, and Bawinanga Rangers

Subjects

Geography, Habitat, biology, Ecology, Northern australia, biology.animal, Feral cat, Dingo, Monsoon, Ecology, Evolution, Behavior and Systematics, Apex predator, Structural complexity, Predation

Published

2020

5. Introduced cats (Felis catus) eating a continental fauna: The number of mammals killed in Australia

Author

Stuart C. Brown, Gavin J Trewella, Joanna Riley, Dan Harley, Sarah Legge, Jeff M. Turpin, Chris R. Dickman, John L. Read, Leigh-Ann Woolley, Russell Palmer, Sarah Comer, Cecilia Myers, Charlie Eager, Peter J. McDonald, Hayley M. Geyle, Hugh W. McGregor, Tim S. Doherty, Katherine E. Moseby, Brett P. Murphy, Glenn A. Edwards, John Augusteyn, Danielle Stokeld, Damien A. Fordham, and John C. Z. Woinarski

Subjects

0106 biological sciences, education.field_of_study, Extinction, CATS, animal diseases, 010604 marine biology & hydrobiology, Fauna, Population, Zoology, Introduced species, Biology, 010603 evolutionary biology, 01 natural sciences, Predation, Feral cat, Mammal, education, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Predation by cats (Felis catus) is implicated in the decline and extinction of many Australian mammal species. We estimate the number of mammals killed by cats across Australia through meta-analysis of data on the frequency of mammals in cat diet samples from 107 studies. For feral cats in largely natural landscapes, the spatially-weighted mean frequency of mammals in diet samples was 70% (44% for native species, 34% for introduced species). Frequency was significantly higher on the mainland, and in areas of low temperature and topographic ruggedness. Geographic patterns varied markedly between native and introduced mammals, with native mammals most frequent in northern Australia. We estimate that: (i) 815 million individuals yr-1 are killed by feral cats in natural landscapes, 56% of which are native species; (ii) 149 million individuals yr-1 are killed by unowned cats in highly modified landscapes; and (iii) 180 million individuals yr-1 are killed by pet cats. For the latter two components, mainly introduced species are killed. Collectively, across the three components of the cat population, 1,144 million individuals yr-1 are killed by cats, of which, at least 40% (459 million individuals yr-1) are native species. It remains challenging to interpret this tally in terms of its impact on population viability for Australian mammals, because demographic information is not available for most species. However, our estimate of annual mammal mortality due to cat predation is substantially higher than that due to another key threatening process, land clearing.

Published

2019

6. Introduced catsFelis catuseating a continental fauna: inventory and traits of Australian mammal species killed

Author

Peter J. McDonald, Dan Harley, Brett P. Murphy, Tim S. Doherty, Cecilia Myers, John L. Read, Glenn A. Edwards, Hugh W. McGregor, Katherine E. Moseby, Joanna Riley, Danielle Stokeld, Sarah Legge, Ian Leiper, Hayley M. Geyle, Chris R. Dickman, Russell Palmer, John Augusteyn, John C. Z. Woinarski, Charlie Eager, Jeff M. Turpin, Leigh-Ann Woolley, and Sarah Comer

Subjects

0106 biological sciences, Range (biology), Zoology, Biology, 01 natural sciences, Agricultural and Biological Sciences (miscellaneous), Predation, 010601 ecology, Feral animal, Habitat, Abundance (ecology), parasitic diseases, Threatened species, IUCN Red List, Animal Science and Zoology, Mammal, Ecology, Evolution, Behavior and Systematics

Abstract

Mammals comprise the bulk of the diet of free-ranging domestic cats Felis catus (defined as including outdoor pet cats, strays, and feral cats) in most parts of their global range. In Australia, predation by introduced feral cats has been implicated in the extinction of many mammal species, and in the ongoing decline of many extant species. Here, we collate a wide range of records of predation by cats (including feral and pet cats) on Australian mammals and model traits of extant, terrestrial, native mammal species associated with the relative likelihood of cat predation. We explicitly seek to overcome biases in such a continental-scale compilation by excluding possible carrion records for larger species and accounting for differences in the distribution and abundance of potential prey species, as well as study effort, throughout each species’ range. For non-volant species, the relative likelihood of predation by cats was greatest for species in an intermediate weight range (peaking at ca. 400 g), in lower rainfall areas and not dwelling in rocky habitats. Previous studies have shown the greatest rates of decline and extinction in Australian mammals to be associated with these traits. As such, we provide the first continental-scale link between mammal decline and cat predation through quantitative analysis. Our compilation of cat predation records for most extant, terrestrial, native mammal species (151 species, or 52% of the Australian species’ complement) is substantially greater than previously reported (88 species) and includes 50 species listed as threatened by the IUCN or under Australian legislation (57% of Australia's 87 threatened terrestrial mammal species). We identify the Australian mammal species most likely to be threatened by predation by cats (mulgaras Dasycercus spp., kowari Dasyuroides byrnei, many smaller dasyurids and medium-sized to large rodents, among others) and hence most likely to benefit from enhanced mitigation of cat impacts, such as translocations to predator-free islands, the establishment of predator-proof fenced exclosures, and broad-scale cat poison baiting.

Published

2019

7. Continental patterns in the diet of a top predator: Australia's dingo

Author

Joe Benshemesh, Charlie Pascoe, Barbara Triggs, David M. Forsyth, Naomi E. Davis, Lindy F. Lumsden, Jenny Lawrence, Georgeanna Story, Mike Wysong, Glenn A. Edwards, Russell Palmer, Dale G. Nimmo, Cecilia Myers, Thomas M. Newsome, Danielle Stokeld, Andy Sharp, Mark Venosta, Paul Story, Mike Letnic, Chris R. Dickman, Tim S. Doherty, and Euan G. Ritchie

Subjects

0106 biological sciences, biology, Ecology, business.industry, Wildlife, biology.organism_classification, Generalist and specialist species, 01 natural sciences, Agricultural and Biological Sciences (miscellaneous), Canis lupus dingo, Arid, Predation, 010601 ecology, biology.animal, parasitic diseases, Animal Science and Zoology, Livestock, Dingo, business, Ecology, Evolution, Behavior and Systematics, Apex predator

Abstract

Conserving large carnivores is controversial because they can threaten wildlife, human safety, and livestock production. Since large carnivores often have large ranges, effective management requires knowledge of how their ecology and functional roles vary biogeographically. We examine continental‐scale patterns in the diet of the dingo – Australia's largest terrestrial mammalian predator. We describe and quantify how dingo dietary composition and diversity vary with environmental productivity and across five bioclimatic zones: arid, semi‐arid, tropical, sub‐tropical, and temperate. Based on 73 published and unpublished data sets from throughout the continent, we used multivariate linear modelling to assess regional trends in the occurrence of nine food groups (arthropods, birds, reptiles, European rabbits Oryctolagus cuniculus, medium‐sized [25–125 kg] and large [169–825 kg] exotic ungulates [including livestock], and other small [

Published

2018

8. Rapid increase of Australian tropical savanna reptile abundance following exclusion of feral cats

Author

Stuart Young, Brydie M. Hill, Danielle Stokeld, Tim Gentles, John C. Z. Woinarski, Alaric Fisher, and Graeme R. Gillespie

Subjects

0106 biological sciences, Ecology, Species diversity, Biology, 010603 evolutionary biology, 01 natural sciences, Tropical savanna climate, Predation, 010601 ecology, Abundance (ecology), Feral cat, Mammal, Species richness, Relative species abundance, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Feral cats have been responsible, in part, for the extinction of many species of mammal, bird and reptile globally, especially on islands. Whilst there is extensive evidence of the predatory impacts of cats on mammals and birds, far less is known about their ecological impacts on reptiles, especially in continental situations. We conducted a field experiment to evaluate the impact of feral cats on terrestrial vertebrates in tropical savanna environments of northern Australia. Three experimental treatments were applied to six 64 ha plots to compare and contrast responses of reptile abundance and species richness to predator exclusion and the additive effects of frequent fire. Replicated pitfall-trapping was undertaken in each plot on seven sampling occasions between November 2013 and November 2015. We analysed relative abundance and species richness data using generalized linear mixed models. There was a significant increase in the abundance of reptiles over a two year period in cat-excluded plots with reptile abundance increasing at twice the rate in cat-exclusion plots compared with cat-accessible plots and there was an additive effect of time-since-fire. Cat exclusion had a positive effect on reptile species richness over time, however the evidence for this pattern was weak when seasonal variation was taken into account. Predation by cats, in synergy with other disturbance processes, could adversely impact reptile species and communities elsewhere in the world where feral cats have been established and warrants further investigation.

Published

2018

9. Terrestrial habitat and individual fitness increase survival of a freshwater turtle in an urban landscape

Author

Andrew J. Hamer, Lee Harrison, and Danielle Stokeld

Subjects

0106 biological sciences, geography, geography.geographical_feature_category, Ecology, biology, 010604 marine biology & hydrobiology, Biodiversity, Wetland, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, law.invention, Urban Studies, Chelodina longicollis, Urban ecology, Habitat destruction, Habitat, law, Urbanization, Turtle (robot)

Abstract

Urbanisation is causing rapid land-use change worldwide. Populations of freshwater turtles are vulnerable to impacts of urbanisation such as habitat loss, fragmentation and degradation, because many species require interconnected aquatic and terrestrial habitats. Understanding the processes that underpin survival in urban areas is critical in managing species that may vary in their responses to urbanisation. Here, we conducted a mark-recapture study of a common freshwater turtle (Chelodina longicollis) at 20 wetlands over five years across a broad geographical gradient in a large and expanding Australian city. Our aim was to examine relationships between survival and a broad suite of local and landscape environmental variables, and body condition. Using capture-recapture models, we found a positive relationship between the probability of survival of C. longicollis and the proportion of green open space in a 1-km radius around a wetland. There was a positive relationship between survival of female C. longicollis and body condition. Survival probabilities generally did not differ substantially among males, females or juveniles, or seasons. We found evidence of adult turtle mortality resulting from recreational fishing. Our results demonstrate the importance of terrestrial habitat surrounding wetlands for freshwater turtle survival in an urban environment. Our results suggest that management actions for C. longicollis in urban areas need to protect green spaces surrounding wetlands (e.g. parks and remnant vegetation) and discourage human actions that threaten turtle survival. Our study adds to mounting evidence that conserving freshwater turtle populations in urban areas requires managers to consider life cycle requirements over broad spatiotemporal scales.

Published

2017

10. Enumerating a continental-scale threat: How many feral cats are in Australia?

Author

Sarah Legge, Duncan R. Sutherland, Luke Woodford, F. Zewe, Teresa J. Eyre, Peter J. McDonald, Chris R. Dickman, Guy Ballard, Danielle Stokeld, William L. Geary, Anthony R. Rendall, Keith Morris, R. Paltridge, Hugh W. McGregor, Bronwyn A. Fancourt, Jesse Rowland, S. Hume, M. Maxwell, Euan G. Ritchie, John L. Read, Dale G. Nimmo, L. Greenwood, Maree Rich, Matthew Gentle, Rosemary Hohnen, David S. L. Ramsey, Daniel J. Ferguson, David M. Forsyth, Christopher N. Johnson, Graeme R. Gillespie, Thomas M. Newsome, John Augusteyn, Katherine E. Moseby, Brett P. Murphy, Adrian F. Wayne, Jeff Short, Marcus Baseler, Tony Buckmaster, John C. Z. Woinarski, Tom Doherty, and Glenn P. Edwards

Subjects

0106 biological sciences, education.field_of_study, Ecology, animal diseases, Home range, Fauna, Population, Wildlife, Introduced species, 15. Life on land, 010603 evolutionary biology, 01 natural sciences, Arid, 010601 ecology, 13. Climate action, Feral cat, Mainland, education, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Feral cats (Felis catus) have devastated wildlife globally. In Australia, feral cats are implicated in most recent mammal extinctions and continue to threaten native species. Cat control is a high-profile priority for Australian policy, research and management. To develop the evidence-base to support this priority, we first review information on cat presence/absence on Australian islands and mainland cat-proof exclosures, finding that cats occur across >99.8% of Australia's land area. Next, we collate 91 site-based feral cat density estimates in Australia and examine the influence of environmental and geographic influences on density. We extrapolate from this analysis to estimate that the feral cat population in natural environments fluctuates between 1.4 million (95% confidence interval: 1.0–2.3 million) after continent-wide droughts, to 5.6 million (95% CI: 2.5–11 million) after extensive wet periods. We estimate another 0.7 million feral cats occur in Australia's highly modified environments (urban areas, rubbish dumps, intensive farms). Feral cat densities are higher on small islands than the mainland, but similar inside and outside conservation land. Mainland cats reach highest densities in arid/semi-arid areas after wet periods. Regional variation in cat densities corresponds closely with attrition rates for native mammal fauna. The overall population estimate for Australia's feral cats (in natural and highly modified environments), fluctuating between 2.1 and 6.3 million, is lower than previous estimates, and Australian feral cat densities are lower than reported for North America and Europe. Nevertheless, cats inflict severe impacts on Australian fauna, reflecting the sensitivity of Australia's native species to cats and reinforcing that policy, research and management to reduce their impacts is critical.

Published

2017

11. Bottom-up and top-down processes influence contemporary patterns of mammal species richness in Australia's monsoonal tropics

Author

Alaric Fisher, Brett P. Murphy, Luke D. Einoder, Graeme R. Gillespie, Hugh F. Davies, Warddeken Rangers, Alyson M. Stobo-Wilson, Michael P. Scroggie, Danielle Stokeld, Alys Stevens, Bawinanga Rangers, J. C. Z. Woinarski, Brydie M. Hill, and T. Mahney

Subjects

0106 biological sciences, Herbivore, biology, Occupancy, Ecology, animal diseases, 010604 marine biology & hydrobiology, 010603 evolutionary biology, 01 natural sciences, Geography, Habitat, Abundance (ecology), biology.animal, Feral cat, Dingo, Mammal, Species richness, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

In recent decades severe mammal declines have occurred in the vast and uncleared tropical savannas of northern Australia. Mounting evidence suggests that feral cats (Felis catus), large feral herbivores and increased frequency of high-severity fires, are all contributing to declines; however, the respective influence of each threat remains unclear. There is an urgent need to quantify the relative impacts of both ‘bottom-up’ (i.e. the depletion of resources and habitat simplification from contemporary disturbance regimes) and ‘top-down’ (i.e. increased predation pressure) factors on small mammal populations to inform where, and how, remedial conservation efforts should be targeted in northern Australia. We conducted an extensive survey of mammals across ca. 370,000 km2 of monsoonal northern Australia using both camera-trapping and live-trapping methods. From multispecies occupancy models, we found that feral herbivore abundance, dingo abundance and feral cat occupancy were the best predictors of species richness of small (

Published

2020

12. Road density and wetland context alter population structure of a freshwater turtle

Author

Andrew J. Hamer, Lee Harrison, and Danielle Stokeld

Subjects

0106 biological sciences, Habitat fragmentation, geography.geographical_feature_category, Ecology, Chelidae, biology, Wildlife, Wetland, Context (language use), biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, law.invention, 010601 ecology, Chelodina longicollis, Geography, Habitat, law, Turtle (robot), human activities, Ecology, Evolution, Behavior and Systematics

Abstract

Roads are detrimental to wildlife populations that require contiguous networks of terrestrial and aquatic habitats. Many species of freshwater turtles are sensitive to habitat fragmentation caused by roads, and are susceptible to road mortality during overland migrations. The common long-necked turtle (Chelodina longicollis) is an Australian freshwater turtle that frequently moves between wetlands, and so populations may incur negative impacts from road effects. Here, we assessed the relationship between C. longicollis and road density and landscape variables within populations inhabiting 20 wetlands distributed throughout greater Melbourne, Australia. The size frequency distribution of C. longicollis at sites surrounded by high road densities was skewed towards larger individuals, but there was no difference in the frequency of juveniles between high and low road density sites. Regression modelling revealed a clear positive relationship between road density and carapace length (CL) of C. longicollis; the mean CL at a site with the highest road density was predicted to be 23% greater than mean CL at a site surrounded by no roads. Female CL was also positively related to road density. There was a clear positive relationship between wetland age and CL, although this relationship was not as strong. While there was no relationship evident between road density and the proportion of female C. longicollis at a site, more females were captured at smaller ephemeral sites surrounded by a high proportion of green open space and located near drainage lines. We did not find evidence of sex-related differences in road effects. These results suggest that roads may be affecting C. longicollis in the study area, but the direct cause of any effects is difficult to identify.

Published

2015

13. Prevalence, genetic diversity and potential clinical impact of blood-borne and enteric protozoan parasites in native mammals from northern Australia

Author

Una Ryan, Andrea Paparini, Andrea Reiss, Peter J. Irwin, Kristin S. Warren, Bethany Jackson, Amanda D. Barbosa, Graeme R. Gillespie, and Danielle Stokeld

Subjects

0301 basic medicine, Veterinary medicine, Isoodon macrourus, Parasitemia, 03 medical and health sciences, parasitic diseases, Genotype, Blood-Borne Pathogens, Animals, Quoll, Protozoan Infections, Animal, Phylogeny, Dasyurus hallucatus, General Veterinary, biology, Australia, Eukaryota, Genetic Variation, Cryptosporidium, General Medicine, 030108 mycology & parasitology, biology.organism_classification, Bandicoot, Marsupialia, Trypanosoma, Brushtail possum, Phyllachorales, Parasitology

Abstract

A molecular survey was conducted to provide baseline information on the prevalence, genetic diversity and potential clinical impacts of blood-borne and enteric protozoans in native wild mammals from the Northern Territory (NT). A total of 209 blood and 167 faecal samples were collected from four target species; the northern brown bandicoot (Isoodon macrourus), common brushtail possum (Trichosurus vulpecula), northern quoll (Dasyurus hallucatus) and brush-tailed rabbit-rat (Conilurus penicillatus). Blood samples were screened by PCR at the 18S rRNA gene for trypanosomes, piroplasms and haemogregarines, with faecal samples tested for Cryptosporidium spp. at the 18S rRNA locus, and for Giardia spp. at the glutamate dehydrogenase (gdh) and 18S rRNA loci. The potential clinical impact was investigated by associating clinical, haematological and biochemical parameters with presence or absence of infection. Overall, 22.5% (95% CI: 17.0-28.8%) of the animals tested were positive for haemoprotozoans. Trypanosomes were found in 26.6% (95% CI: 18.7-35.7%) of the bandicoots and were identified as Trypanosoma vegrandis G6, except for one unique genotype, most similar to T. vegrandis G3 (genetic distance=7%). The prevalence of trypanosomes in possums was 23.7% (95% CI: 11.4-40.2%), and the genotypes identified clustered within the T. noyesi clade. The presence of Babesia sp. and Hepatozoon sp. was confirmed in bandicoots only, both at a prevalence of 9.7% (95% CI: 2.7-9.2%). The total prevalence of intestinal protozoan parasites observed was relatively low (3%; 95% CI: 1.0-6.9%). No evidence of clinical disease associated with protozoan parasitic infection was observed, however bandicoots positive for Trypanosoma exhibited a significantly lower packed cell volume (PCV) compared to negative bandicoots (p=0.046). To the authors' knowledge, this is the first research conducted in the NT to characterise protozoan parasites in threatened native mammals using both molecular and morphological tools; and to assess the potential clinical impacts of these agents. The absence of clear signs of major morbidity in infected animals seems to exclude a direct association between infections with these agents and possible population decline events in northern Australian native mammals. However until the cause(s) of population decline are ascertained for each individual mammal species, further studies are required. The outcome of the present investigation may be used to inform wildlife conservation and zoonotic disease programs.

Published

2017

14. Investigation into High Barmah Forest Virus Disease Case Numbers Reported in the Northern Territory, Australia in 2012-2013

Author

Steven Davis, Rowena Boyd, Richard Weir, Peter Markey, Nina Kurucz, Allan Warchot, Anthony D. K. Draper, Lorna Melville, and Danielle Stokeld

Subjects

Veterinary medicine, Medical entomology, Virus isolation, 030231 tropical medicine, Disease, Alphavirus, Antibodies, Viral, Microbiology, 03 medical and health sciences, 0302 clinical medicine, Virology, medicine, Northern Territory, Animals, Humans, False Positive Reactions, 030212 general & internal medicine, Alphavirus infection, Northern territory, biology, Alphavirus Infections, biology.organism_classification, medicine.disease, Insect Vectors, Infectious Diseases, Culicidae, Immunoglobulin M, Vector (epidemiology), Public Health, Barmah Forest virus

Abstract

Between October 2012 and October 2013, unprecedented high numbers of Barmah Forest virus (BFV) disease cases were reported in the Northern Territory (NT). An investigation was launched by the NT Department of Health in cooperation with the Department of Primary Industry and Fisheries and the Department of Land Resource Management to investigate possible causes for this phenomenon. The investigation included virus isolations from mosquitoes collected in Darwin urban areas, BFV antibody testing in peri-urban small mammals and a human BFV disease case series investigation of recent cases. No BFV was isolated from the 4641 mosquitoes tested, none of the mammals tested positive for BFV antibodies, and the high BFV disease case numbers did not correlate with the relatively low mosquito vector numbers trapped in 2012-2013. It was estimated that up to 89% of the 79 human cases investigated did not have an acute arboviral illness and therefore had tested falsely positive. An Alere PanBio BFV immunoglobulin M enzyme-linked immunosorbent assay test kit is generally used to test for BFV, with the BFV disease case definition based on immunoglobulin M positives only. Other jurisdictions in Australia also reported high numbers of BFV disease cases, with the majority of the cases suspected to be false positives. Therefore, current testing methods need to be revised to reflect the true numbers of BFV disease cases occurring in Australia and to provide correct diagnoses for patients.

Published

2016

15. What do predator diets tell us about mammal declines in Kakadu National Park?

Author

Barbara Triggs, Alaric Fisher, Brydie M. Hill, Danielle Stokeld, Tim Gentles, Graeme R. Gillespie, and John C. Z. Woinarski

Subjects

0106 biological sciences, Herbivore, National park, Ecology, animal diseases, Context (language use), Management, Monitoring, Policy and Law, Biology, 010603 evolutionary biology, 01 natural sciences, Predation, 010601 ecology, biology.animal, Grazing, Threatened species, Mammal, Dingo, Ecology, Evolution, Behavior and Systematics

Abstract

Context Small- and medium-sized native mammals have suffered severe declines in much of northern Australia, including within protected areas such as Kakadu National Park. Several factors have been implicated in these declines but predation, particularly by feral cats (Felis catus), has been identified as potentially the most direct cause of decline for many species. Aims We evaluated how prey frequency changed in cat and dingo scats in Kakadu from the early 1980s to 2013–15, with this period spanning a severe decline in the small- and medium-sized mammal fauna. Methods Chi-square test of independence and Fisher’s exact test were used to compare prey frequencies between dingoes and cats, and among years to assess significance of temporal change. Key results Small-sized native mammals were the prey item occurring at the highest frequency in scats for both dingoes and cats in the 1980s. Prey content in dingo and cat scats differed in the 2010s with macropods predominating in the scats of dingoes, and medium-sized native mammals predominating in cat scats. The frequency of occurrence of small-sized native mammals declined in both dingo and cat scats between the 1980s and 2010 sampling periods, while the frequency of occurrence of medium-sized native mammals remained constant in dingo scats and increased in cat scats. Conclusions Small mammals were a major component of the diets of both dingoes and cats in Kakadu in the 1980s, when small mammals were much more abundant. Despite marked reduction from the 1980s to the 2010s in the capture rates of both small- and medium-sized native mammals, some species continue to persist in the diets of cats and dingoes at disproportionally high frequencies. Both predators continue to exert predatory pressure on mammal populations that have already experienced substantial declines. Implications Although predation by feral cats is a major threat to small- and medium-sized native mammals, dingoes may also play an important role in limiting their recovery. Disturbance from fire and grazing by introduced herbivores has been shown to augment predatory impacts of feral cats on native mammals. Predation more generally, not just by feral cats, may be exacerbated by these disturbance processes. Management programs that solely focus on mitigating the impact of feral cats to benefit threatened species may be inadequate in landscapes with other significant disturbance regimes and populations of predators.

Published

2018

16. How many reptiles are killed by cats in Australia?

Author

A. Nankivell, John L. Read, Sarah Legge, John C. Z. Woinarski, Russell Palmer, Danielle Stokeld, Tim S. Doherty, Glenn P. Edwards, Chris R. Dickman, and Brett P. Murphy

Subjects

0106 biological sciences, education.field_of_study, biology, Vulpes, Ecology, Fauna, Population, Biodiversity, Context (language use), Management, Monitoring, Policy and Law, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Predation, 010601 ecology, Threatened species, Feral cat, education, Ecology, Evolution, Behavior and Systematics

Abstract

Context Feral cats (Felis catus) are a threat to biodiversity globally, but their impacts upon continental reptile faunas have been poorly resolved. Aims To estimate the number of reptiles killed annually in Australia by cats and to list Australian reptile species known to be killed by cats. Methods We used (1) data from >80 Australian studies of cat diet (collectively >10 000 samples), and (2) estimates of the feral cat population size, to model and map the number of reptiles killed by feral cats. Key results Feral cats in Australia’s natural environments kill 466 million reptiles yr–1 (95% CI; 271–1006 million). The tally varies substantially among years, depending on changes in the cat population driven by rainfall in inland Australia. The number of reptiles killed by cats is highest in arid regions. On average, feral cats kill 61 reptiles km–2 year–1, and an individual feral cat kills 225 reptiles year–1. The take of reptiles per cat is higher than reported for other continents. Reptiles occur at a higher incidence in cat diet than in the diet of Australia’s other main introduced predator, the European red fox (Vulpes vulpes). Based on a smaller sample size, we estimate 130 million reptiles year–1 are killed by feral cats in highly modified landscapes, and 53 million reptiles year–1 by pet cats, summing to 649 million reptiles year–1 killed by all cats. Predation by cats is reported for 258 Australian reptile species (about one-quarter of described species), including 11 threatened species. Conclusions Cat predation exerts a considerable ongoing toll on Australian reptiles. However, it remains challenging to interpret the impact of this predation in terms of population viability or conservation concern for Australian reptiles, because population size is unknown for most Australian reptile species, mortality rates due to cats will vary across reptile species and because there is likely to be marked variation among reptile species in their capability to sustain any particular predation rate. Implications This study provides a well grounded estimate of the numbers of reptiles killed by cats, but intensive studies of individual reptile species are required to contextualise the conservation consequences of such predation.

Published

2018

17. Multiple cameras required to reliably detect feral cats in northern Australian tropical savanna: an evaluation of sampling design when using camera traps

Author

Alys Stevens, Terrance Mahney, Brydie M. Hill, Jenni L. Choy, Djelk Rangers, Anke S. K. Frank, Warddeken Rangers, Graeme R. Gillespie, Danielle Stokeld, and Stuart Young

Subjects

Geography, Occupancy, Ecology, Sampling design, Wildlife, Camera trap, Sampling (statistics), Context (language use), Management, Monitoring, Policy and Law, Ecology, Evolution, Behavior and Systematics, Tropical savanna climate, Wildlife conservation

Abstract

Context Feral cats are a major cause of mammal declines and extinctions in Australia. However, cats are elusive and obtaining reliable ecological data is challenging. Although camera traps are increasingly being used to study feral cats, their successful use in northern Australia has been limited. Aims We evaluated the efficacy of camera-trap sampling designs for detecting cats in the tropical savanna of northern Australia. We aimed to develop a camera-trapping method that would yield detection probabilities adequate for precise occupancy estimates. Methods First, we assessed the influence of two micro-habitat placements and three lure types on camera-trap detection rates of feral cats. Second, using multiple camera traps at each site, we examined the relationship between sampling effort and detection probability by using a multi-method occupancy model. Key results We found no significant difference in detection rates of feral cats using a variety of lures and micro-habitat placement. The mean probability of detecting a cat on one camera during one week of sampling was very low (p = 0.15) and had high uncertainty. However, the probability of detecting a cat on at least one of five cameras deployed concurrently on a site was 48% higher (p = 0.22) and had a greater precision. Conclusions The sampling effort required to achieve detection rates adequate to infer occupancy of feral cats by camera trap is considerably higher in northern Australia than has been observed elsewhere in Australia. Adequate detection of feral cats in the tropical savanna of northern Australia will necessitate inclusion of more camera traps and a longer survey duration. Implications Sampling designs using camera traps need to be rigorously trialled and assessed to optimise detection of the target species for different Australian biomes. A standard approach is suggested for detecting feral cats in northern Australian savannas.

Published

2015

18. Factors influencing occurrence of a freshwater turtle in an urban landscape: a resilient species?

Author

Andrew J. Hamer, Vincent Pettigrove, Danielle Stokeld, Rodney van der Ree, and Graeme R. Gillespie

Subjects

geography.geographical_feature_category, Occupancy, biology, Ecology, Wetland, Management, Monitoring, Policy and Law, biology.organism_classification, Chelodina longicollis, Geography, Habitat, Abundance (ecology), Urbanization, Landscape ecology, Ecology, Evolution, Behavior and Systematics, Wildlife conservation

Abstract

Context Species vary broadly in their ability to adapt to urbanisation. Freshwater turtles are vulnerable to the loss and degradation of terrestrial and aquatic habitat in urban environments. There have been few publications investigating impacts of urbanisation on freshwater turtles in Australia. Aims We investigated the effects of urbanisation on the distribution and abundance of the eastern long-necked turtle (Chelodina longicollis) in greater Melbourne. Methods We examined occurrence and relative abundance of C. longicollis at 55 wetlands across an urban–rural gradient in relation to site- and landscape-level factors. Occupancy was modelled using the program PRESENCE, and incorporated landscape and habitat covariates. A negative binomial regression model was used to examine the influence of landscape and habitat factors on relative abundance by using WinBUGS. Key results C. longicollis occupied 85% of the 55 wetlands we surveyed, and we found no evidence that wetland occupancy was influenced by the variables we measured. However, relative abundance was highest at wetlands with low water conductivity and heavy metal pollution, and in wetlands furthest from rivers. Conclusions C. longicollis appears to be resilient to urbanisation and is likely to persist in urban landscapes, possibly because of the creation of new wetlands in Australian cities. However, long-term studies focussed on demographic parameters, or survivorship, may elucidate as yet undetected effects of urbanisation. Although no specific management recommendations may be necessary for C. longicollis in urban areas at this time, this species may be in decline in non-urban areas as a result of climatic changes and wetland drying. Implications Our findings suggest that caution is required before drawing generalised conclusions on the impacts of urbanisation on turtles, as the effects are likely to be species-specific, dependent on specific ecology and life-history requirements. Further studies are required to ascertain these relationships for a wider array of species and over longer time spans.

Published

2014