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Ecology, management and conservation in natural and modified habitats
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REVIEW
Contents Vol 37(4)

Evaluating habitat quality of vertebrates using conservation physiology tools

Jessica A. Homyack
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Virginia Tech, Department of Fisheries and Wildlife Sciences, Blacksburg, VA 24061, USA.
Current address: Weyerhaeuser NR Company, 1785 Weyerhaeuser Road, Vanceboro, NC 28586, USA.
Email: jessica.homyack@weyerhaeuser.com

Wildlife Research 37(4) 332-342 https://doi.org/10.1071/WR08093
Submitted: 16 June 2008  Accepted: 19 April 2010   Published: 28 June 2010

Abstract

Studies examining how wildlife populations perceive and respond to habitat are common, and many attempt to understand how the quality of available habitats influences population processes such as survival and recruitment. Traditional methods to estimate habitat quality (e.g. population density) have not led to great advancement in our understanding of relationships between habitat and fitness in recent years. Metrics from the discipline of conservation physiology could help researchers to address these difficulties and to meet the challenges that habitat alteration poses to biodiversity. Incorporating physiological metrics that relate energetics or environmental stress to habitats may be powerful measures of habitat quality. By quantifying field metabolic rates, body condition, or concentrations of stress hormones in individual organisms, researchers may identify mechanisms associated with habitat that underlie observed patterns in vital rates (survival and fecundity). Physiological metrics offer useful tools that may identify mechanisms of habitat quality and detect the causes of declines in biodiversity. However, integration among physiologists, ecologists and conservation biologists will require new partnerships and approaches to respond to complex ecological issues.

Additional keywords: biotelemetry, body condition, endocrine response, energetics, habitat selection, stress.


Acknowledgements

The comments of anonymous reviewers, T. Gorman, C. Haas, J. Litvaitis, D. Stauffer, and especially W. Hopkins greatly improved this manuscript. I was supported by an AdvanceVT Doctoral Fellowship (Grant Number SBE-0244916) and a USDA-NRI grant to C. Haas et al. (2005–35101–15363) while writing this paper.


References

Austin, D. , Bowen, W. D. , McMillan, J. I. , and Boness, D. J. (2006). Stomach temperature telemetry reveals temporal patterns of foraging success in a free-ranging marine mammal. Journal of Animal Ecology 75, 408–420.
Crossref | GoogleScholarGoogle Scholar | PubMed | Duncan M. B. (2008). The use of bioelectrical impedance analysis for estimating the body composition of various fish species. M.Sc. Thesis, Virginia Tech, Blacksburg, VA, USA.

Fretwell, S. D. , and Lucas, H. L. (1969). On territorial behavior and other factors influencing habitat distribution in birds. I. Theoretical development. Acta Biotheoretica 19, 16–36.
Crossref | GoogleScholarGoogle Scholar | Garshelis D. L. (2000). Delusions in habitat evaluation: measuring use, selection, and importance. In ‘Research Techniques in Animal Ecology: Controversies and Consequences’. (Eds L. Boitani and T. K. Fuller.) pp. 111–164. (Columbia University Press: New York.)

Good, T. , Khan, M. Z. , and Lynch, J. W. (2003). Biochemical and physiological validation of a corticosteroid radioimmunoassay for plasma and fecal samples in oldfield mice (Peromyscus polionotus). Physiology & Behavior 80, 405–411.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed | Gordon M. S. , and Bartol S. M. (2004). ‘Experimental approaches to conservation biology.’ (University of California Press: Los Angeles.)

Green, A. J. (2001). Mass/length residuals: measures of body condition or generators of spurious results? Ecology 82, 1473–1483.
Crossref | GoogleScholarGoogle Scholar | Hanks J. (1981). Characterization of population condition. In ‘Dynamics of Large Mammal Populations’. (Eds C. Fowler and T. Smith.) pp. 47–73. (John Wiley: New York.)

Hayes J. , and Shonkwiler J. (2001). Morphometric indicators of body condition: worthwhile or wishful thinking? In ‘Body Composition Analysis of Animals’. (Ed. J. Speakman.) pp. 8–38. (Cambridge University Press: New York.)

Hellgren, E. C. , Rogers, L. L. , and Seal, U. S. (1993). Serum chemistry and hematology of black bears: physiological indices of habitat quality or seasonal patterns? Journal of Mammalogy 74, 304–315.
Crossref | GoogleScholarGoogle Scholar | Homyack J. (2009). Effects of forest regeneration methods on salamander populations in Central Appalachia. Ph.D. Thesis, Virginia Tech, Blacksburg, VA, USA.

Hopkins, W. A. , Mendonça, M. T. , and Congdon, J. D. (1997). Increased circulating levels of testosterone and corticosterone in southern toads, Bufo terrestris, exposed to coal combustion wastes. General and Comparative Endocrinology 108, 237–246.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed | Jones D. R. , Southwood A. L. , and Andrews R. D. (2004). Energetics of leatherback sea turtles: A step toward conservation. In ‘Experimental approaches to conservation biology’. (Eds M. S. Gordon and S. M. Bartol.) pp. 66–82. (University of California Press: Los Angeles.)

Kanda, L. , Fuller, T. , and Friedland, K. (2005). Temperature sensor evaluation of opossum winter activity. Wildlife Society Bulletin 33, 1425–1431.
Crossref | GoogleScholarGoogle Scholar | Moen A. N. (1973). ‘Wildlife ecology: an analytical approach.’ (W. H. Freeman: San Francisco.)

Morris, D. W. (2003). Toward an ecological synthesis: a case for habitat selection. Oecologia 136, 1–13.
Crossref | GoogleScholarGoogle Scholar | PubMed | Rome L. C. , Stevens E. D. , and John-Adler H. B. (1992). The influence of temperature and thermal acclimation on physiological function. In Environmental physiology of the amphibians’. (Eds M. E. Feder and W. W. Burggren.) pp. 183–205. (University of Chicago Press: Chicago.)

Romero, L. (2004). Physiological stress in ecology: lessons from biomedical research. Trends in Ecology & Evolution 19, 249–255.
Crossref | GoogleScholarGoogle Scholar | Scott I. , Selman C. , Mitchell P. I. , and Evans P. R. (2001). The use of total body electrical conductivity (TOBEC) to determine body composition in vertebrates. In ‘Body Composition Analysis of Animals’. (Ed. J. Speakman.) pp. 127–160. (Cambridge University Press: New York.)

Seal U. S. (1978). Assessment of habitat condition by measurement of biochemical and endocrine indicators of the nutritional, reproductive, and disease status of free-ranging animal populations. In ‘Proceedings of a National Symposium: Classification, Inventory, and Analysis of Fish and Wildlife Habitat’. (Chair, A. Marmelstein.) pp. 305–329. (U.S. Department of the Interior, Fish and Wildlife Service: Washington, DC.)

Speakman J. R. (2001). Introduction. In ‘Body Composition Analysis of Animals’. (Ed. J. R. Speakman.) pp. 1–7. (Cambridge University Press: New York.)

Speakman, J. R. , and Racey, P. A. (1986). The influence of body condition on sexual development of male brown long-eared bats (Plecotus auritus) in the wild. Journal of Zoology 210, 515–525.
Van Marken Lichtenbelt W. (2001). The use of bioelectrical impedance analysis (BIA) for estimation of body composition. In ‘Body Composition Analysis of Animals’. (Ed. J. R. Speakman.) pp. 161–187. (Cambridge University Press: New York.)

von der Ohe, C. , and Servheen, C. (2002). Measuring stress in mammals using fecal glucocoticoids: opportunities and challenges. Wildlife Society Bulletin 30, 1215–1225.
Williams G. C. (1966). ‘Adaptation and Natural Selection.’ (Princeton University Press: Princeton.)

Wilson E. O. (1999). ‘The Diversity of Life.’ (W. W. Norton: New York.)

Wingfield J. C. , Hunt K. , Brueuner C. , Dunlap K. , Fowler G. S. , Freed L. , and Lepson J. (1997). Environmental stress, field endocrinology, and conservation biology. In ‘Behavioral Approaches to Conservation in the Wild’. (Eds J. R. Clements and R. Buchholz.) pp. 95–131. (Cambridge University Press: New York.)

Wingfield, J. C. , Maney, D. L. , Breuner, C. W. , Jacobs, J. D. , Lynn, S. , Ramenofsky, M. , and Richardson, R. D. (1998). Ecological bases of hormone-behavior interactions: The “emergency life history stage”. American Zoologist 38, 191–206.
CAS |

Wirsing, A. , Steury, T. , and Murray, D. (2002). Noninvasive estimation of body conditions in small mammals: A comparison of conductive and morphometric techniques. Physiological and Biochemical Zoology 75, 489–497.
Crossref | GoogleScholarGoogle Scholar | PubMed |

Young, J. L. , Bornik, Z. B. , Marcotte, M. L. , Charlie, K. N. , Wagner, G. N. , Hinch, S. G. , and Cooke, S. J. (2006). Integrating physiology and life history to improve fisheries management and conservation. Fish and Fisheries 7, 262–283.
Crossref | GoogleScholarGoogle Scholar |