Variable reptile responses to introduced predator control in southern Australia
Yang Hu
A C , Graeme Gillespie B and Tim S. Jessop A
+ Author Affiliations
- Author Affiliations
A Centre for Integrative Ecology, Deakin University, Waurn Ponds, Geelong, Vic. 3216, Australia.
B Department of Environment and Natural Resources, Palmerston, NT 0830, Australia.
C Corresponding author. Email: yhu0855@yahoo.com
Wildlife Research 46(1) 64-75 https://doi.org/10.1071/WR18047
Submitted: 13 March 2018 Accepted: 24 October 2018 Published: 21 January 2019
Abstract
Context: Australia harbours an immense diversity of reptiles, which are generally expected to have frequent and diverse trophic interactions with introduced mammalian carnivores. Nevertheless, the potential for predatory or competitive interactions is likely to be contingent on multiple processes, including the importance of reptiles in the diet of introduced predators, alongside overlaps in their body sizes and ecological niches that would influence the strength of their interactions. In Australia’s temperate and relatively productive mesic environments there is little understanding of how introduced mammalian predators affect reptile assemblages.
Aims: The aim was to investigate the effects that a European red fox (Vulpes vulpes; 5–7 kg) suppression program had on the abundance and species richness of a reptile community, with species ranging in size from the largest local ectothermic predator, the lace monitor (Varanus varius; 4–7 kg), to small terrestrial reptiles (mostly 10–150 g).
Methods: We utilised two sampling designs (baited camera monitoring stations and pitfall trapping) to evaluate the effects of fox suppression and other site-level ecological covariates (fire regime and habitat vegetation characteristics) on the lace monitor and small terrestrial reptiles. Reptile abundance and richness at site level were estimated from count-related abundance models.
Key results: For lace monitors, significantly higher abundances occurred in poison-baited areas relative to control areas. This suggests that fox suppression can affect the populations of the lace monitor via mesopredator release arising from reduced competition and, possibly, predation. For small terrestrial reptiles, neither abundance nor species richness were influenced by fox suppression. Individual abundances of the three most common small reptile species matched the overall pattern, as only responses to structural parameters of the habitat were detected.
Conclusions: Fox suppression can have different impacts for different reptile taxa, pending their ecological niche, as only the largest species was affected.
Implications: Increase in lace monitor abundance may change food web dynamics in fox-suppressed sites, such as by increasing predation pressure on arboreal marsupials.
Additional keywords: exotic pest, varanid lizards, skinks, herpetofauna.
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