Sep. 10, 2013 — Dingoes have
been unjustly blamed for the extinctions on the Australian mainland of
the Tasmanian tiger (or thylacine) and the Tasmanian devil, a University
of Adelaide study has found.
"Perhaps because the public perception of dingoes as 'sheep-killers'
is so firmly entrenched, it has been commonly assumed that dingoes
killed off the thylacines and devils on mainland Australia," says
researcher Dr Thomas Prowse, Research Associate in the School of Earth
and Environmental Sciences and the Environment Institute.
"There was anecdotal evidence too: both thylacines and devils lasted for over 40,000 years following the arrival of humans in Australia; their mainland extinction about 3000 years ago was just after dingoes were introduced to Australia; and the fact that thylacines and devils persisted on Tasmania, which was never colonised by dingoes.
"However, and unfortunately for the dingo, most people have overlooked that about the same time as dingoes came along, the climate changed rather abruptly and Aboriginal populations were going through a major period of intensification in terms of population growth and technological advances."
The researchers built a complex series of mathematical models to recreate the dynamic interaction between the main potential drivers of extinction (dingoes, climate and humans), the long-term response of herbivore prey, and the viability of the thylacine and devil populations.
The models included interactions and competition between predators as well as the influence of climate on vegetation and prey populations.
The simulations showed that while dingoes had some impact, growth and development in human populations, possibly intensified by climate change, was the most likely extinction driver.
"Our multi-species models showed that dingoes could reduce thylacine and devil populations through both competition and direct predation, but there was low probability that they could have been the sole extinction driver," Dr Prowse says.
"Our results support the notion that thylacines and devils persisted on Tasmania not because the dingo was absent, but because human density remained low there and Tasmania was less affected by abrupt climate changes."
The study 'An ecological regime shift resulting from disrupted predator-prey interactions in Holocene Australia' also involved Professors Corey Bradshaw and Barry Brook from the University of Adelaide's Environment Institute and Professor Chris Johnson from the University of Tasmania.
"There was anecdotal evidence too: both thylacines and devils lasted for over 40,000 years following the arrival of humans in Australia; their mainland extinction about 3000 years ago was just after dingoes were introduced to Australia; and the fact that thylacines and devils persisted on Tasmania, which was never colonised by dingoes.
"However, and unfortunately for the dingo, most people have overlooked that about the same time as dingoes came along, the climate changed rather abruptly and Aboriginal populations were going through a major period of intensification in terms of population growth and technological advances."
The researchers built a complex series of mathematical models to recreate the dynamic interaction between the main potential drivers of extinction (dingoes, climate and humans), the long-term response of herbivore prey, and the viability of the thylacine and devil populations.
The models included interactions and competition between predators as well as the influence of climate on vegetation and prey populations.
The simulations showed that while dingoes had some impact, growth and development in human populations, possibly intensified by climate change, was the most likely extinction driver.
"Our multi-species models showed that dingoes could reduce thylacine and devil populations through both competition and direct predation, but there was low probability that they could have been the sole extinction driver," Dr Prowse says.
"Our results support the notion that thylacines and devils persisted on Tasmania not because the dingo was absent, but because human density remained low there and Tasmania was less affected by abrupt climate changes."
The study 'An ecological regime shift resulting from disrupted predator-prey interactions in Holocene Australia' also involved Professors Corey Bradshaw and Barry Brook from the University of Adelaide's Environment Institute and Professor Chris Johnson from the University of Tasmania.
Story Source:
The above story is based on materials provided by University of Adelaide.
Note: Materials may be edited for content and length. For further information, please contact the source cited above.
Journal Reference:
- Thomas A. A. Prowse, Christopher N. Johnson, Corey James Alexander Bradshaw, Barry William Brook. An ecological regime shift resulting from disrupted predator-prey interactions in Holocene Australia. Ecology, 2013; : 130812173528003 DOI: 10.1890/13-0746.1
University of Adelaide (2013, September 10). Dingo wrongly blamed for extinctions. ScienceDaily. Retrieved September 11, 2013, from http://www.sciencedaily.com /releases/2013/09/130910095413.htm
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