Register      Login
Australian Journal of Zoology Australian Journal of Zoology Society
Evolutionary, molecular and comparative zoology
Shopping Cart: ( empty )
You are here: Home > Journals > ZO > ZO18021
RESEARCH ARTICLE
Contents Vol 66(2)

Decline of the greater glider (Petauroides volans) in the lower Blue Mountains, New South Wales

Peter Smith https://orcid.org/0000-0002-3421-1725 A B and Judy Smith A
+ Author Affiliations
- Author Affiliations

A P & J Smith Ecological Consultants, 44 Hawkins Parade, Blaxland, NSW 2774, Australia.

B Corresponding author. Email: smitheco@ozemail.com.au

Australian Journal of Zoology 66(2) 103-114 https://doi.org/10.1071/ZO18021
Submitted: 27 March 2018  Accepted: 21 August 2018   Published: 12 September 2018

Abstract

The range of the greater glider (Petauroides volans) is predicted to contract with climate change. Following indications of a decline in the Blue Mountains, we collated records and undertook surveys in 2015–16 to assess whether a decline has occurred and whether the decline is associated with climate change or other factors. We were unable to relocate greater gliders at 35% of our study sites, even though all were in known former locations. The species is now rare at lower elevations but remains relatively common at higher elevations: about seven times more abundant above 500 m than below. Historical data suggest that in 1986–96 it occurred in similar abundance across all elevations, 80–1060 m. Nine habitat variables accounted for 84% of the variation in greater glider density between our study sites, with significant independent contributions from elevation (37%) and time since fire (23%). We found no evidence that greater gliders have been impacted by increasing numbers of owls or cockatoos or that either the fire regime or rainfall has changed in the last 20 years. The most likely cause of the decline is the direct and indirect effects of a marked increase in temperature in the Blue Mountains. Similar declines are likely throughout the distribution of the species with increasing climate change.

Additional keywords: climate change, cockatoos, eucalypt folivore, fire, global warming, owls, rainfall, temperature, world heritage area.


References

Adams-Hosking, C., Grantham, H. S., Rhodes, J. R., McAlpine, C. A., and Moss, P. (2011). Modelling climate change-induced shifts in the distribution of the koala. Wildlife Research 38, 122–130.
Modelling climate change-induced shifts in the distribution of the koala.Crossref | GoogleScholarGoogle Scholar |

Andrew, D., Koffel, D., Harvey, G., Griffiths, K., and Fleming, M. (2014). Rediscovery of the greater glider Petauroides volans (Marsupialia: Petauroidea) in the Royal National Park, NSW. Australian Zoologist 37, 23–28.
Rediscovery of the greater glider Petauroides volans (Marsupialia: Petauroidea) in the Royal National Park, NSW.Crossref | GoogleScholarGoogle Scholar |

Bannerman, S. M., and Hazelton, P. A. (1990). Soil landscapes of the Penrith 1 : 100 000 sheet. Soil Conservation Service of New South Wales, Sydney.

Bennett, A. F., Lumsden, L. F., Alexander, J. S. A., Duncan, P. E., Johnson, P. G., Robertson, P., and Silveira, C. E. (1991). Habitat use by arboreal mammals along an environmental gradient in north-eastern Victoria. Wildlife Research 18, 125–146.
Habitat use by arboreal mammals along an environmental gradient in north-eastern Victoria.Crossref | GoogleScholarGoogle Scholar |

Benson, D. H. (1992). The natural vegetation of the Penrith 1 : 100 000 map sheet. Cunninghamia 2, 541–596.

Bilney, R. J., Cooke, R., and White, J. (2006). Change in the diet of sooty owls (Tyto tenebricosa) since European settlement: from terrestrial to arboreal prey and increased overlap with powerful owls. Wildlife Research 33, 17–24.
Change in the diet of sooty owls (Tyto tenebricosa) since European settlement: from terrestrial to arboreal prey and increased overlap with powerful owls.Crossref | GoogleScholarGoogle Scholar |

Braithwaite, L. W. (1983). Studies on the arboreal marsupial fauna of eucalypt forests being harvested for woodpulp at Eden, NSW. I. The species and distribution of animals. Australian Wildlife Research 10, 219–229.
Studies on the arboreal marsupial fauna of eucalypt forests being harvested for woodpulp at Eden, NSW. I. The species and distribution of animals.Crossref | GoogleScholarGoogle Scholar |

Brereton, R., Bennett, S., and Mansergh, I. (1995). Enhanced greenhouse climate change and its potential effect on selected fauna of south-eastern Australia: a trend analysis. Biological Conservation 72, 339–354.
Enhanced greenhouse climate change and its potential effect on selected fauna of south-eastern Australia: a trend analysis.Crossref | GoogleScholarGoogle Scholar |

Bryan, J. H. (1966). Sydney 1 : 250 000 Geological Series Sheet SI 56-05. 3rd edn. Geological Survey of New South Wales, Department of Mines, Sydney.

Cary, G. J., Bradstock, R. A., Gill, A. M., and Williams, R. J. (2012). Global change and fire regimes in Australia. In ‘Flammable Australia: Fire Regimes, Biodiversity and Ecosystems in a Changing World’. (Eds R. A. Bradstock, A. M. Gill and R. J. Williams.) pp. 149–169. (CSIRO Publishing: Melbourne.)

Chambers, L. (2012). Climate as a driver for change in terrestrial and marine species. In ‘Wildlife and Climate Change: Towards Robust Conservation Strategies for Australian Fauna’. (Eds D. Lunney and P. Hutchings.) pp. 3–7. (Royal Zoological Society of New South Wales: Sydney.)

Chevan, A., and Sutherland, M. (1991). Hierarchical partitioning. The American Statistician 45, 90–96.

CSIRO and Bureau of Meteorology (2015). ‘Climate Change in Australia: Technical Report.’ (CSIRO and Bureau of Meteorology: Australia.)

Cunningham, C. J. (1984). Recurring natural fire hazards: a case study of the Blue Mountains, New South Wales, Australia. Applied Geography 4, 5–27.
Recurring natural fire hazards: a case study of the Blue Mountains, New South Wales, Australia.Crossref | GoogleScholarGoogle Scholar |

Eyre, T. J. (2006). Regional habitat selection by large gliding possums at forest stand and landscape scales in southern Queensland, Australia. I. Greater glider (Petauroides volans). Forest Ecology and Management 235, 270–282.
Regional habitat selection by large gliding possums at forest stand and landscape scales in southern Queensland, Australia. I. Greater glider (Petauroides volans).Crossref | GoogleScholarGoogle Scholar |

Foley, W. J., Kehl, J. C., Nagy, K. A., Kaplan, I. R., and Boorsboom, A. C. (1990). Energy and water metabolism in free-living greater gliders Petaurus volans. Australian Journal of Zoology 38, 1–10.
Energy and water metabolism in free-living greater gliders Petaurus volans.Crossref | GoogleScholarGoogle Scholar |

Givnish, T. J., Wong, S. C., Stuart-Williams, H., Holloway-Phillips, M., and Farquhar, G. D. (2014). Determinants of maximum tree height in Eucalyptus species along a rainfall gradient in Victoria, Australia. Ecology 95, 2991–3007.
Determinants of maximum tree height in Eucalyptus species along a rainfall gradient in Victoria, Australia.Crossref | GoogleScholarGoogle Scholar |

Goldbery, R., and Bembrick, C. S. (1996). Katoomba 1 : 50 000 Geological Series Sheet 8930-I. Geological Survey of New South Wales, Department of Mineral Resources: Sydney.

Green, K., Stein, J. A., and Driessen, M. M. (2008). The predicted distributions of Mastacomys fuscus and Rattus lutreolus in southeastern Australia under a scenario of climate change: potential for enhanced competition? Wildlife Research 35, 113–119.
The predicted distributions of Mastacomys fuscus and Rattus lutreolus in southeastern Australia under a scenario of climate change: potential for enhanced competition?Crossref | GoogleScholarGoogle Scholar |

Grömping, U. (2006). Relative importance for linear regression in R: the package relaimpo. Journal of Statistical Software 17, 1–27.
Relative importance for linear regression in R: the package relaimpo.Crossref | GoogleScholarGoogle Scholar |

Grömping, U. (2015). Package ‘relaimpo’ version 2.2-2: relative importance of regressors in linear models. Available at: https://cran.r-project.org/web/packages/relaimpo/relaimpo.pdf

Hager, T., and Benson, D. (2010). The eucalypts of the Greater Blue Mountains World Heritage Area: distribution, classification and habitats of the species of Eucalyptus, Angophora and Corymbia (Family Myrtaceae) recorded in its eight conservation reserves. Cunninghamia 10, 425–444.

Hammill, K., and Tasker, L. (2010). ‘Vegetation, Fire and Climate Change in the Greater Blue Mountains World Heritage Area.’ (New South Wales Department of Environment, Climate Change and Water: Sydney.)

Howden, M., Hughes, L., Dunlop, M., Zethoven, I., Hilbert, D., and Chilcott, C. (2003). ‘Climate Change Impacts on Biodiversity in Australia.’ (Environment Australia: Canberra.)

Hume, I. D. (1999). ‘Marsupial Nutrition.’ (Cambridge University Press: Melbourne.)

IPCC (2015). Climatic Change 2014: Synthesis Report. Intergovernmental Panel on Climate Change, Geneva.

Johnson, J. W., and Lebreton, J. M. (2004). History and use of relative importance indices in organizational research. Organizational Research Methods 7, 238–257.
History and use of relative importance indices in organizational research.Crossref | GoogleScholarGoogle Scholar |

Kanowski, J. J. (2001). Effects of elevated CO2 on the foliar chemistry of seedlings of two rainforest trees from north-east Australia: implications for folivorous marsupials. Austral Ecology 26, 165–172.
Effects of elevated CO2 on the foliar chemistry of seedlings of two rainforest trees from north-east Australia: implications for folivorous marsupials.Crossref | GoogleScholarGoogle Scholar |

Kavanagh, R. P. (1988). The impact of predation by the powerful owl, Ninox strenua, on a population of the greater glider, Petauroides volans. Australian Journal of Ecology 13, 445–450.
The impact of predation by the powerful owl, Ninox strenua, on a population of the greater glider, Petauroides volans.Crossref | GoogleScholarGoogle Scholar |

Kavanagh, R. P. (2000). Effects of variable-intensity logging and the influence of habitat variables on the distribution of the greater glider Petauroides volans in montane forest, southeastern New South Wales. Pacific Conservation Biology 6, 18–30.
Effects of variable-intensity logging and the influence of habitat variables on the distribution of the greater glider Petauroides volans in montane forest, southeastern New South Wales.Crossref | GoogleScholarGoogle Scholar |

Kavanagh, R. P., and Lambert, M. J. (1990). Food selection by the greater glider: is foliar nitrogen a determinant of habitat quality? Australian Wildlife Research 17, 285–299.
Food selection by the greater glider: is foliar nitrogen a determinant of habitat quality?Crossref | GoogleScholarGoogle Scholar |

Kearney, M. R., Wintle, B. A., and Porter, W. P. (2010). Correlative and mechanistic models of species distribution provide congruent forecasts under climate change. Conservation Letters 3, 203–213.
Correlative and mechanistic models of species distribution provide congruent forecasts under climate change.Crossref | GoogleScholarGoogle Scholar |

Keith, D. A., and Benson, D. H. (1988). The natural vegetation of the Katoomba 1 : 100 000 map sheet. Cunninghamia 2, 107–143.

King, D. P. (1994). Soil landscapes of the Katoomba 1 : 100 000 sheet. Department of Conservation and Land Management, Sydney.

Lawler, L., Foley, W., Woodrow, I. E., and Cork, S. J. (1996). The effects of elevated CO2 atmospheres on the nutritional quality of Eucalyptus foliage and its interaction with soil nutrient and light availability. Oecologia 109, 59–68.
The effects of elevated CO2 atmospheres on the nutritional quality of Eucalyptus foliage and its interaction with soil nutrient and light availability.Crossref | GoogleScholarGoogle Scholar |

Lindeman, R. H., Merenda, P. F., and Gold, R. Z. (1980). ‘Introduction to Bivariate and Multivariate Analysis.’ (Scott Foresman: Glenview, IL.)

Lindenmayer, D. (2002). ‘Gliders of Australia: A Natural History.’ (University of New South Wales Press: Sydney.)

Lindenmayer, D. B., Cunningham, R. B., Tanton, M. T., Smith, A. P., and Nix, H. A. (1990). Habitat requirements of the mountain brushtail possum and the greater glider in the montane ash-type eucalypt forests of the central highlands of Victoria. Australian Wildlife Research 17, 467–478.
Habitat requirements of the mountain brushtail possum and the greater glider in the montane ash-type eucalypt forests of the central highlands of Victoria.Crossref | GoogleScholarGoogle Scholar |

Lindenmayer, D. B., Cunningham, R. B., Donnelly, C. F., Incoll, R. D., Pope, M. L., Tribolet, C. R., Viggers, K. L., and Welsh, A. H. (2001). How effective is spotlighting for detecting the greater glider (Petauroides volans)? Australian Wildlife Research 28, 105–109.
How effective is spotlighting for detecting the greater glider (Petauroides volans)?Crossref | GoogleScholarGoogle Scholar |

Lindenmayer, D. B., Blanchard, W., McBurney, L., Blair, D., Banks, S. C., Driscoll, D., Smith, A. L., and Gill, A. M. (2013). Fire severity and landscape context effects on arboreal marsupials. Biological Conservation 167, 137–148.
Fire severity and landscape context effects on arboreal marsupials.Crossref | GoogleScholarGoogle Scholar |

Lunney, D. (1987). Effects of logging, fire and drought on possums and gliders in the coastal forests near Bega, N.S.W. Australian Wildlife Research 14, 263–274.
Effects of logging, fire and drought on possums and gliders in the coastal forests near Bega, N.S.W.Crossref | GoogleScholarGoogle Scholar |

Lunney, D., and Hutchings, P. (Eds) (2012). ‘Wildlife and Climate Change: Towards Robust Conservation Strategies for Australian Fauna.’ (Royal Zoological Society of New South Wales: Sydney.)

Lunney, D., Crowther, M. S., Wallis, I., Foley, W. J., Lemon, J., Wheeler, R., Madani, G., Orscheg, C., Griffith, J. E., Krockenberger, M., Retamales, M., and Stalenberg, E. (2012). Koalas and climate change: a case study on the Liverpool Plains, north-west New South Wales. In ‘Wildlife and Climate Change: Towards Robust Conservation Strategies for Australian Fauna’. (Eds D. Lunney, and P. Hutchings.) pp. 150–168. (Royal Zoological Society of New South Wales: Sydney.)

Lunney, D., Stalenberg, E., Santika, T., and Rhodes, J. R. (2014). Extinction in Eden: identifying the role of climate change in the decline of the koala in south-eastern NSW. Wildlife Research 41, 22–34.
Extinction in Eden: identifying the role of climate change in the decline of the koala in south-eastern NSW.Crossref | GoogleScholarGoogle Scholar |

Mac Nally, R. (2002). Multiple regression and inference in ecology and conservation biology: further comments on identifying important predictor variables. Biodiversity and Conservation 11, 1397–1401.
Multiple regression and inference in ecology and conservation biology: further comments on identifying important predictor variables.Crossref | GoogleScholarGoogle Scholar |

Mackaness, G. (Ed.) (1951). ‘Fourteen Journeys over the Blue Mountains of New South Wales, 1813–41.’ Australian Historical Monographs, New Series, Vols 22–24. (George Mackaness: Sydney.)

Matusick, G., Ruthrof, K. K., Brouwers, N. C., Dell, B., and Hardy, G. E. StJ. (2013). Sudden forest canopy collapse corresponding with extreme drought and heat in a mediterranean-type eucalypt forest in southwestern Australia. European Journal of Forest Research 132, 497–510.
Sudden forest canopy collapse corresponding with extreme drought and heat in a mediterranean-type eucalypt forest in southwestern Australia.Crossref | GoogleScholarGoogle Scholar |

McKay, G. M. (2008). Greater glider Petauroides volans. In ‘The Mammals of Australia’. 3rd edn. (Eds S. Van Dyck, and R. Strahan.) pp. 240–242. (Reed New Holland: Sydney.)

Meynecke, J.-O. (2004). Effects of global climate change on geographic distribution of vertebrates in north Queensland. Ecological Modelling 174, 347–357.
Effects of global climate change on geographic distribution of vertebrates in north Queensland.Crossref | GoogleScholarGoogle Scholar |

Moore, B. D., Wallis, I. R., Marsh, K. J., and Foley, W. J. (2004). The role of nutrition in the conservation of the marsupial folivores of eucalypt forests. In ‘Conservation of Australia’s Forest Fauna’. 2nd edn. (Ed. D. Lunney.) pp. 549–575. (Royal Zoological Society of New South Wales: Sydney.)

NSW National Parks and Wildlife Service (2009). Greater Blue Mountains World Heritage Area Strategic Plan. Department of Environment and Climate Change, Sydney.

Olea, P. P., Mateo-Tomás, P., and de Frutos, Á. (2010). Estimating and modelling bias of the hierarchical partitioning public-domain software: implications in environmental management and conservation. PLoS One 5, e11698.
Estimating and modelling bias of the hierarchical partitioning public-domain software: implications in environmental management and conservation.Crossref | GoogleScholarGoogle Scholar |

Pitman, A. J., Narisma, G. T., and McAneney, J. (2007). The impact of climate change on the risk of forest and grassland fires in Australia. Climatic Change 84, 383–401.
The impact of climate change on the risk of forest and grassland fires in Australia.Crossref | GoogleScholarGoogle Scholar |

Pope, M. L., Lindenmayer, D. B., and Cunningham, R. B. (2004). Patch use by the greater glider (Petauroides volans) in a fragmented forest ecosystem. I. Home range size and movements. Wildlife Research 31, 559–568.
Patch use by the greater glider (Petauroides volans) in a fragmented forest ecosystem. I. Home range size and movements.Crossref | GoogleScholarGoogle Scholar |

Rencher, A. C., and Schaalje, G. B. (2008). ‘Linear Models in Statistics.’ 2nd edn. (John Wiley and Sons: Hoboken, NJ.)

Rübsamen, K., Hume, I. D., Foley, W. J., and Rübsamen, U. (1984). Implications of the large surface area to body mass ratio on the heat balance of the greater glider Petauroides volans. Journal of Comparative Physiology B: Biochemical, Systemic, and Environmental Physiology 154, 105–111.
Implications of the large surface area to body mass ratio on the heat balance of the greater glider Petauroides volans.Crossref | GoogleScholarGoogle Scholar |

Skovsgaard, J. P., and Vanclay, J. K. (2008). Forest site productivity: a review of the evolution of dendrometric concepts for even-aged stands. Forestry 81, 13–31.
Forest site productivity: a review of the evolution of dendrometric concepts for even-aged stands.Crossref | GoogleScholarGoogle Scholar |

Smith, G. C., Mathieson, M., and Hogan, L. (2007). Home range and habitat use of a low-density population of greater gliders, Petauroides volans (Pseudocheiridae: Marsupialia), in a hollow-limiting environment. Wildlife Research 34, 472–483.
Home range and habitat use of a low-density population of greater gliders, Petauroides volans (Pseudocheiridae: Marsupialia), in a hollow-limiting environment.Crossref | GoogleScholarGoogle Scholar |

Smith, J., and Smith, P. (1990). ‘Fauna of the Blue Mountains.’ (Kangaroo Press: Sydney.)

Steffen, W., Burbidge, A. A., Hughes, L., Kitching, R., Lindenmayer, D., Musgrave, W., Stafford Smith, M., and Werner, P. A. (2009). ‘Australia’s Biodiversity and Climate Change.’ (CSIRO Publishing: Melbourne.)

Threatened Species Scientific Committee (2016). Approved conservation advice for Petauroides volans (greater glider), 24 May 2016. Department of the Environment, Canberra. Available at: http://www.environment.gov.au/biodiversity/threatened/species/pubs/254-conservation-advice-20160525.pdf

Tyndale-Biscoe, H., and Renfree, M. (1987). ‘Reproductive Physiology of Marsupials.’ (Cambridge University Press: Melbourne.)

Tyndale-Biscoe, C. H., and Smith, R. F. C. (1969a). Studies on the marsupial glider, Schoinobates volans (Kerr): II. Population structure and regulatory measures. Journal of Animal Ecology 38, 637–650.
Studies on the marsupial glider, Schoinobates volans (Kerr): II. Population structure and regulatory measures.Crossref | GoogleScholarGoogle Scholar |

Tyndale-Biscoe, C. H., and Smith, R. F. C. (1969b). Studies on the marsupial glider, Schoinobates volans (Kerr): III. Response to habitat destruction. Journal of Animal Ecology 38, 651–659.
Studies on the marsupial glider, Schoinobates volans (Kerr): III. Response to habitat destruction.Crossref | GoogleScholarGoogle Scholar |

Urban, M. C. (2015). Accelerating extinction risk from climate change. Science 348, 571–573.
Accelerating extinction risk from climate change.Crossref | GoogleScholarGoogle Scholar |

van der Ree, R., Ward, S. J., and Handasyde, K. A. (2004). Distribution and conservation status of possums and gliders in Victoria. In ‘The Biology of Australian Possums and Gliders’. (Eds R. L. Goldingay, and S. M. Jackson.) pp. 91–110. (Surrey Beatty: Sydney.)

Venables, W. N., Smith, D. M., and the R Core Team (2017). An introduction to R version 3.4.3. Available at: https://cran.r-project.org/doc/manuals/R-intro.pdf

Waller, N. L., Gynther, I. C., Freeman, A. B., Lavery, T. H., and Leung, L. K.-P. (2017). The Bramble Cay melomys Melomys rubicola (Rodentia: Muridae): a first mammalian extinction caused by human-induced climate change? Wildlife Research 44, 9–21.
The Bramble Cay melomys Melomys rubicola (Rodentia: Muridae): a first mammalian extinction caused by human-induced climate change?Crossref | GoogleScholarGoogle Scholar |

Walsh, C., and Mac Nally, R. (2015). Package ‘hier.part’ version 1.0-4: hierarchical partitioning. https://cran.r-project.org/web/packages/hier.part/hier.part.pdf