Edge effects created by fenced conservation reserves benefit an invasive mesopredator

2020 ◽  
Vol 47 (8) ◽  
pp. 677
Author(s):  
Hugh McGregor ◽  
John Read ◽  
Christopher N. Johnson ◽  
Sarah Legge ◽  
Brydie Hill ◽  
...  
Keyword(s):  
Prey Availability ◽  
South Australia ◽  
Management Tool ◽  
Gps Tracking ◽  
Source Population ◽  
Detection Rates ◽  
Feral Cats ◽  
Movement Data ◽  
Invasive Predators ◽  
Surrounding Landscape

Abstract ContextFenced reserves from which invasive predators are removed are increasingly used as a conservation management tool, because they provide safe havens for susceptible threatened species, and create dense populations of native wildlife that could act as a source population for recolonising the surrounding landscape. However, the latter effect might also act as a food source, and promote high densities of invasive predators on the edges of such reserves. AimsOur study aimed to determine whether activity of the feral cat is greater around the edges of a fenced conservation reserve, Arid Recovery, in northern South Australia. This reserve has abundant native rodents that move through the fence into the surrounding landscape. MethodsWe investigated (1) whether feral cats were increasingly likely to be detected on track transects closer to the fence over time as populations of native rodents increased inside the reserve, (2) whether native rodents were more likely to be found in the stomachs of cats caught close to the reserve edge, and (3) whether individual cats selectively hunted on the reserve fence compared with two other similar fences, on the basis of GPS movement data. Key resultsWe found that (1) detection rates of feral cats on the edges of a fenced reserve increased through time as populations of native rodents increased inside the reserve, (2) native rodents were far more likely to be found in the stomach of cats collected at the reserve edge than in the stomachs of cats far from the reserve edge, and (3) GPS tracking of cat movements showed a selection for the reserve fence edge, but not for similar fences away from the reserve. ConclusionsInvasive predators such as feral cats are able to focus their movements and activity to where prey availability is greatest, including the edges of fenced conservation reserves. This limits the capacity of reserves to function as source areas from which animals can recolonise the surrounding landscape, and increases predation pressure on populations of other species living on the reserve edge. ImplicationsManagers of fenced conservation reserves should be aware that increased predator control may be critical for offsetting the elevated impacts of feral cats attracted to the reserve fence.

Applying home-range and landscape-use data to design effective feral-cat control programs

2012 ◽  
Vol 39 (3) ◽  
pp. 258 ◽  
Author(s):  
Andrew J. Bengsen ◽  
John A. Butler ◽  
Pip Masters
Keyword(s):  
Home Range ◽  
Habitat Preferences ◽  
South Australia ◽  
Gps Tracking ◽  
Feral Cat ◽  
Feral Cats ◽  
Small Areas ◽  
Control Programs ◽  
Spatial Coverage ◽  
Landscape Use

Context Effective feral-cat (Felis silvestris catus) management requires a sound understanding of the ways cats use their environment. Key characteristics of landscape use by cats vary widely among different regions and different conditions. Aims The present study aimed to describe the most important characteristics of landscape use by feral cats on a large, human-populated island, and to use this information to guide the development of feral-cat management programs. Methods We used GPS tracking collars to record the movements of 13 feral cats at two sites on Kangaroo Island, South Australia, for between 20 and 106 days. We described home-range extents by using local convex hulls, and derived management suggestions from examination of home-range and movement data. Key results Median feral-cat home range was 5.11 km2, and this did not differ between sexes or sites. Cats at a fragmented pastoral site tended to favour woody vegetation over open paddocks, but habitat preferences were less clear at a bushland site. Cats that preferentially used treelines at the pastoral site were almost twice as likely to be recorded close to a tree-line junction as expected. Conclusions Control programs for feral cats on Kangaroo Island should deploy control devices at a density no less than 1.7 devices km–2. Spatial coverage should be as large as practicable or repeated frequently. Infrequent programs covering small areas can be expected only to provide short-term reductions in cat abundance. Implications The information gained from the present study will contribute to the development of strategic sustained management plans for feral cats on Kangaroo Island. The principles from which we inferred management guidelines are applicable to other regions and species.

scholarly journals Long-Distance Movements of Feral Cats in Semi-Arid South Australia and Implications for Conservation Management

Animals ◽  
2021 ◽  
Vol 11 (11) ◽  
pp. 3125
Author(s):  
Jeroen Jansen ◽  
Hugh McGregor ◽  
Geoff Axford ◽  
Abbey T. Dean ◽  
Sebastien Comte ◽  
...  
Keyword(s):  
Large Scale ◽  
Control Strategies ◽  
South Australia ◽  
Arid Areas ◽  
Long Distance ◽  
Feral Cats ◽  
Control Programs ◽  
Movement Data ◽  
Study Sites ◽  
Semi Arid

Movements that extend beyond the usual space use of an animal have been documented in a range of species and are particularly prevalent in arid areas. We present long-distance movement data on five feral cats (Felis catus) GPS/VHF-collared during two different research projects in arid and semi-arid Australia. We compare these movements with data from other feral cat studies. Over a study period of three months in the Ikara-Flinders Ranges National Park, 4 out of 19 collared cats moved to sites that were 31, 41, 53 and 86 km away. Three of the cats were males, one female; their weight was between 2.1 and 4.1 kg. Two of the cats returned to the area of capture after three and six weeks. During the other study at Arid Recovery, one collared male cat (2.5 kg) was relocated after two years at a distance of 369 km from the area of collar deployment to the relocation area. The movements occurred following three years of record low rainfall. Our results build on the knowledge base of long-distance movements of feral cats reported at arid study sites and support the assertion that landscape-scale cat control programs in arid and semi-arid areas need to be of a sufficiently large scale to avoid rapid reinvasion and to effectively reduce cat density. Locally, cat control strategies need to be adjusted to improve coverage of areas highly used by cats to increase the efficiency of control operations.

Effectiveness of the Felixer grooming trap for the control of feral cats: a field trial in arid South Australia

2020 ◽  
Vol 47 (8) ◽  
pp. 599
Author(s):  
K. E. Moseby ◽  
H. McGregor ◽  
J. L. Read
Keyword(s):  
Field Trial ◽  
South Australia ◽  
Camera Traps ◽  
Specific Method ◽  
Density Estimates ◽  
Live Prey ◽  
Feral Cats ◽  
Before And After ◽  
Remote Camera ◽  
Track Counts

Abstract ContextFeral cats pose a significant threat to wildlife in Australia and internationally. Controlling feral cats can be problematic because of their tendency to hunt live prey rather than be attracted to food-based lures. The Felixer grooming trap was developed as a targeted and automated poisoning device that sprays poison onto the fur of a passing cat, relying on compulsive grooming for ingestion. AimsWe conducted a field trial to test the effectiveness of Felixers in the control of feral cats in northern South Australia where feral cats were present within a 2600-ha predator-proof fenced paddock. MethodsTwenty Felixers were set to fire across vehicle tracks and dune crossings for 6 weeks. Cat activity was recorded using track counts and grids of remote camera traps set within the Felixer Paddock and an adjacent 3700-ha Control Paddock where feral cats were not controlled. Radio-collars were placed on six cats and spatial mark–resight models were used to estimate population density before and after Felixer deployment. Key resultsNone of the 1024 non-target objects (bettongs, bilbies, birds, lizards, humans, vehicles) that passed a Felixer during the trial was fired on, confirming high target specificity. Thirty-three Felixer firings were recorded over the 6-week trial, all being triggered by feral cats. The only two radio-collared cats that triggered Felixers during the trial, died. Two other radio-collared cats appeared to avoid Felixer traps possibly as a reaction to previous catching and handling rendering them neophobic. None of the 22 individually distinguishable cats targeted by Felixers was subsequently observed on cameras, suggesting death after firing. Felixer data, activity and density estimates consistently indicated that nearly two-thirds of the cat population was killed by the Felixers during the 6-week trial. ConclusionsResults suggest that Felixers are an effective, target-specific method of controlling feral cats, at least in areas in which immigration is prevented. The firing rate of Felixers did not decline significantly over time, suggesting that a longer trial would have resulted in a higher number of kills. ImplicationsFuture studies should aim to determine the trade-off between Felixer density and the efficacy relative to reinvasion.

scholarly journals Seasonal and spatial shifts in feral cat predation on native seabirds vs. non-native rats on Mikura Island, Japan

2020 ◽  
Author(s):  
Sarara Azumi ◽  
Yuya Watari ◽  
Nariko Oka ◽  
Tadashi Miyashita
Keyword(s):  
Native Species ◽  
Control Strategies ◽  
Interspecific Interactions ◽  
Rattus Rattus ◽  
Large Body ◽  
Effective Control ◽  
Alternative Prey ◽  
Feral Cat ◽  
Feral Cats ◽  
Invasive Predators

Abstract Understanding how invasive predators impact native species is essential for the development of effective control strategies, especially in insular environments where alternative non-native prey species exist. We examined seasonal and spatial shifts in diet of feral cat Felis silvestris catus focusing on the predation on native streaked shearwaters, Calonectris leucomelas, and introduced rats, Rattus rattus and R. norvegicus, which are alternative prey to shearwaters, on Mikura Island, Japan. Streaked shearwaters breed at low elevations on the island from spring to autumn, whereas rats inhabit the island throughout the year, which makes them an alternative prey when native shearwaters are absent. Fecal analysis revealed that feral cats dramatically shifted their diets from introduced rats in winter to streaked shearwaters in seabird-season in low elevation areas of the island, while cats preyed on rats throughout the year at high altitudes on the island. This finding suggests that feral cats selectively prey on shearwaters. This is probably because of their large body size and less cautious behavior, and because introduced rats sustain the cat population when shearwaters are absent. The number of streaked shearwaters killed was estimated to be 313 individuals per cat per year, which represents an indication of top-down effects of feral cats on streaked shearwaters. Further studies on the demographic parameters and interspecific interactions of the three species are required to enable effective cat management for the conservation of streaked shearwaters on this island.

Evidence of significantly higher island feral cat abundance compared with the adjacent mainland

2019 ◽  
Vol 46 (5) ◽  
pp. 378 ◽  
Author(s):  
Patrick L. Taggart ◽  
Bronwyn A. Fancourt ◽  
Andrew J. Bengsen ◽  
David E. Peacock ◽  
Patrick Hodgens ◽  
...  
Keyword(s):  
Relative Abundance ◽  
Spatial Model ◽  
Native Species ◽  
Prey Species ◽  
South Australia ◽  
Camera Trap ◽  
Feral Cat ◽  
Feral Cats ◽  
Continental Scale ◽  
Scale Models

Context Feral cats (Felis catus) impact the health and welfare of wildlife, livestock and humans worldwide. They are particularly damaging where they have been introduced into island countries such as Australia and New Zealand, where native prey species evolved without feline predators. Kangaroo Island, in South Australia, is Australia’s third largest island and supports several threatened and endemic species. Cat densities on Kangaroo Island are thought to be greater than those on the adjacent South Australian mainland, based on one cat density estimate on the island that is higher than most estimates from the mainland. The prevalence of cat-borne disease in cats and sheep is also higher on Kangaroo Island than the mainland, suggesting higher cat densities. A recent continental-scale spatial model of cat density predicted that cat density on Kangaroo Island should be about double that of the adjacent mainland. However, although cats are believed to have severe impacts on some native species on the island, other species that are generally considered vulnerable to cat predation have relatively secure populations on the island compared with the mainland. Aims The present study aimed to compare feral cat abundance between Kangaroo Island and the adjacent South Australian mainland using simultaneous standardised methods. Based on previous findings, we predicted that the relative abundance of feral cats on Kangaroo Island would be approximately double that on the South Australian mainland. Methods Standardised camera trap surveys were used to simultaneously estimate the relative abundance of feral cats on Kangaroo Island and the adjacent South Australian mainland. Survey data were analysed using the Royle–Nichols abundance-induced heterogeneity model to estimate feral cat relative abundance at each site. Key results Cat abundance on the island was estimated to be over 10 times greater than that on the adjacent mainland. Conclusions Consistent with predictions, cat abundance on the island was greater than on the adjacent mainland. However, the magnitude of this difference was much greater than expected. Implications The findings show that the actual densities of cats at local sites can vary substantially from predictions generated by continental-scale models. The study also demonstrates the value of estimating abundance or density simultaneously across sites using standardised methods.

Colony relocation of Greater Crested Terns Thalasseus bergii in Bass Strait, south-eastern Australia

2020 ◽  
Vol 37 ◽  
pp. 166-171
Author(s):  
Aymeric Fromant ◽  
◽  
Yonina Eizenberg ◽  
Rosalind Jessop ◽  
Arnaud Lec’hvien ◽  
...  
Keyword(s):  
Prey Availability ◽  
South Australia ◽  
Barrier Islands ◽  
Breeding Population ◽  
Storm Events ◽  
Jack Mackerel ◽  
Seabird Species ◽  
Eastern Australia ◽  
Environmental Variations ◽  
The Impact

A newly established Greater Crested Tern Thalasseus bergii colony was observed on Kanowna Island, northern Bass Strait, in December 2019 and was monitored through January 2020. A maximum of 532 ± 28 nests was counted,representing ~15–20% of the known northern Bass Strait breeding population. Resightings of 69 leg-banded individuals (from 3 to 24 years of age) demonstrated that founding individuals originated from colonies in Victoria [The Nobbies on Phillip Island (54%), Corner Inlet Barrier Islands (39%), Mud Islands in Port Phillip Bay (6%)] and one individual from South Australia. Breeding began 2 months later than usual for northern Bass Strait, perhaps because the birds only moved to Kanowna Island after failed nesting attempts elsewhere (Corner Inlet and Phillip Island). Individuals were observed to mainly feed their chicks with Barracouta Thyrsites atun and Jack Mackerel Trachurus declivis, contrasting with the usual predominance of Australian Anchovy Engraulis australis in the diet of this species in the Bass Strait region. This relocation may result from local changes in prey availability and/or a combination of potential human disturbance, predation and storm events. The recent 50% decrease in the number of breeding Greater Crested Terns in Victoria suggests substantial changes in the regional environmental conditions, highlighting the importance of understanding the impact of environmental variations on seabird species.

The use of poison baits to control feral cats and red foxes in arid South Australia I. Aerial baiting trials

2011 ◽  
Vol 38 (4) ◽  
pp. 338 ◽  
Author(s):  
K. E. Moseby ◽  
B. M. Hill
Keyword(s):  
Arid Zone ◽  
South Australia ◽  
Red Foxes ◽  
Local Conditions ◽  
Feral Cats ◽  
Wildlife Species ◽  
Delivery Times ◽  
Poison Baiting ◽  
Dry Conditions

Context Feral cats and foxes pose a significant threat to native wildlife in the Australian arid zone and their broadscale control is required for the protection of threatened species. Aims The aim of this research was to trial aerial poison baiting as a means of controlling feral cats and foxes in northern South Australia. Methods Eradicat baits or dried meat baits containing 1080 poison were distributed by air over areas of 650 to 1800 km2 in trials from 2002 to 2006. Different baiting density, frequency, bait type and area were trialled to determine the optimum baiting strategy. Baiting success was determined through mortality of radio-collared animals and differences in the track activity of cats and foxes in baited and unbaited areas. Key results Quarterly aerial baiting at a density of 10 baits per square km successfully controlled foxes over a 12-month period, while annual baiting led to reinvasion within four months. Despite the majority of radio-collared cats dying after baiting, a significant decline in cat activity was only recorded during one of the eight baiting events. This event coincided with extremely dry conditions and low rabbit abundance. Rabbit activity increased significantly in baited areas over the study period in comparison with control areas. Conclusions Despite trialling different baiting density, frequency and area over a five-year period, a successful long-term baiting strategy for feral cats could not be developed using Eradicat baits or dried meat baits. Implications Broadscale control of feral cats in the arid zone remains a significant challenge and may require a combination of control methods with flexible delivery times dependent on local conditions. However, it is doubtful that current methods, even used in combination, will enable cat numbers to be reduced to levels where successful reintroductions of many threatened wildlife species can occur.

scholarly journals Golden Eagle Abundance in Alaska: Migration Counts and Movement Data Generate a Conservative Population Estimate

2021 ◽  
Author(s):  
Travis L. Booms ◽  
Neil A. Paprocki ◽  
Joseph M. Eisaguirre ◽  
Chris P. Barger ◽  
Stephen B. Lewis ◽  
...  
Keyword(s):  
Management Strategies ◽  
Survival Rates ◽  
Credible Interval ◽  
Population Estimate ◽  
Gps Tracking ◽  
Golden Eagle ◽  
Movement Data ◽  
South Central ◽  
Golden Eagles ◽  
Migration Corridor

ABSTRACT Estimating species density and abundance is challenging but important for establishing conservation and management strategies. Significant progress has been made toward estimating Golden Eagle (Aquila chrysaetos) abundance in the conterminous United States of America (USA) but much less is known about eagle abundance in Alaska. Here, we paired migration count and GPS-tracking data collected near Gunsight Mountain, Alaska, in a Bayesian framework to estimate the number of Golden Eagles in south-central Alaska. We estimated 1204 (95% credible interval: 866, 1526) potentially breeding (≥4 yr old) Golden Eagles annually moved through the Gunsight Mountain migration corridor and summered over an area of 150,325 km2 in south-central Alaska, equating to a density of 0.80 potentially breeding eagles/100 km2. By extrapolating across the species' nesting range in Alaska (1,180,489 km2) and incorporating published productivity and age-specific survival rates for eagles <4 yr old into our hierarchical model, we estimated 12,717 (95% credible interval: 9043, 16,349) Golden Eagles of all ages occur in Alaska, annually. We propose this as a conservative statewide population estimate because we used methods that likely underestimated population size. Even so, our estimate is three to five times larger than previous estimates and likely represents about one quarter of the USA's population.

scholarly journals Accounting for imperfect detection when evaluating the effectiveness of invasive species control

2014 ◽  
Vol 67 ◽  
pp. 320-320
Author(s):  
J.L. Moore ◽  
E. Gurarie
Keyword(s):  
Invasive Plant ◽  
Plant Size ◽  
Gps Tracking ◽  
Imperfect Detection ◽  
Detection Rates ◽  
Invasive Species Control ◽  
People Search ◽  
Search And Destroy

Many invasive plant species are sparsely distributed across large areas Management of these species is often undertaken using a search and destroy approach where people search the landscape and treat (destroy) any individuals found However detection is imperfect and so these searches need to be undertaken on multiple occasions Given limited resources an explicit objective is to optimize efforts by targeting those areas for follow up visits that have the highest predicted abundance In order to simultaneously estimate both abundances and detection rates from data on search and destroy efforts it is necessary to have a good model of the detection process itself In a case study of invasive willow control across 120 km2 in alpine Australia intensively monitored sample plots were used to characterise how detection rates depend on perceived abundance for three groups of willow control contractors Bayesian models were used to fit an exponential detection function where the detection rate varied with plant size between contractors with the total number of willows treated and on features of the contractors movements It was found that detection rates decreased with increasing abundance but areas with high abundance were subject to greater search effort These models were combined with GPS tracking data representing 6 weeks of search and destroy missions to predict the remaining abundance of willows across the landscape and hence areas that are priorities for follow up control were identified

scholarly journals Fishing for Feral Cats in a Naturally Fragmented Rocky Landscape Using Movement Data

2021 ◽  
Vol 13 (23) ◽  
pp. 4925
Author(s):  
Sandra D. Williamson ◽  
Richard van Dongen ◽  
Lewis Trotter ◽  
Russell Palmer ◽  
Todd P. Robinson
Keyword(s):  
Species Distribution ◽  
Species Distribution Models ◽  
Brownian Bridge ◽  
Control Strategies ◽  
Population Level ◽  
Home Ranges ◽  
Distribution Models ◽  
Control Effort ◽  
Feral Cats ◽  
Movement Data

Feral cats are one of the most damaging predators on Earth. They can be found throughout most of Australia’s mainland and many of its larger islands, where they are adaptable predators responsible for the decline and extinction of many species of native fauna. Managing feral cat populations to mitigate their impacts is a conservation priority. Control strategies can be better informed by knowledge of the locations that cats frequent the most. However, this information is rarely captured at the population level and therefore requires modelling based on observations of a sample of individuals. Here, we use movement data from collared feral cats to estimate home range sizes by gender and create species distribution models in the Pilbara bioregion of Western Australia. Home ranges were estimated using dynamic Brownian bridge movement models and split into 50% and 95% utilisation distribution contours. Species distribution models used points intersecting with the 50% utilisation contours and thinned by spacing points 500 m apart to remove sampling bias. Male cat home ranges were between 5 km2 (50% utilisation) and 34 km2 (95% utilisation), which were approximately twice the size of the female cats studied (2–17 km2). Species distribution modelling revealed a preference for low-lying riparian habitats with highly productive vegetation cover and a tendency to avoid newly burnt areas and topographically complex, rocky landscapes. Conservation management can benefit by targeting control effort in preferential habitat.

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