Translocating captive female white-tailed deer
Jace R. Elliott
A * , Chad H. Newbolt A , William D. Gulsby A and Stephen S. Ditchkoff A
+ Author Affiliations
- Author Affiliations
A College of Forestry, Wildlife and Environment, Auburn University, Auburn, AL 36849, USA.
Wildlife Research 50(2) 108-119 https://doi.org/10.1071/WR22036
Submitted: 25 February 2022 Accepted: 3 October 2022 Published: 11 November 2022
© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing
Abstract
Context: Thousands of captive white-tailed deer (Odocoileus virginianus) breeding facilities exist across North America for the purpose of producing trophy-class deer (i.e. exceptionally large-antlered). Many of these deer get marketed to private landowners, with the expectation that introduced deer will enhance genetics in the population, resulting in larger-antlered male deer. Previous research suggests that survival and reproductive success of translocated wild white-tailed deer are highly variable; however, little is known about the fate of white-tailed deer translocated from captive-breeding operations.
Aims: To assess the efficacy of translocating captive female white-tailed deer for the purpose of increasing average antler size within a high-fence property.
Methods: We translocated 24 adult female deer into a private, 300-ha high-fence shooting preserve in east-central Alabama over a 3-year period. We monitored survival, reproductive success, and fawn recruitment for the translocated deer by using VHF radio collars and vaginal-implant transmitters (VITs).
Key results: We found a 12-month survival rate of 0.54 for translocated deer. We captured nine fawns throughout our study, leading to a rate of 0.9 fawns per VIT, after accounting for doe mortality and premature VIT expulsion. We found 60-day and 6-month fawn survival rates of 0.33 and 0.22 respectively.
Conclusions: Survival of translocated captive deer was comparable to rates reported in previous studies that translocated wild deer, although lower than what is found in wild populations that undergo no translocation. Translocated does produced a low number of fawns relative to the national average, although fawn recruitment was within the range of survival rates reported in studies of wild deer.
Implications: We believe our findings provide a baseline of expectations for captive-deer translocations. Given our results, we believe it is infeasible to expect increased average antler size within this study site by translocating adult female white-tailed deer.
Keywords: captive breeding, fawn recruitment, Odocoileus virginianus, reproduction, survival, telemetry, translocation, white-tailed deer.
References
Adams K, Ross M (2013) QDMA’s whitetail report 2013. Quality Deer Management, Bogart, GA, USA.Adams, KP, Murphy, BP, and Ross, MD (2016). Captive white-tailed deer industry – current status and growing threat. Wildlife Society Bulletin 40, 14–19.
| Captive white-tailed deer industry – current status and growing threat.Crossref | GoogleScholarGoogle Scholar |
Anderson DP, Frosch BJ, Outlaw JL (2007) Economic impact of the Texas deer breeding industry. Texas A&M University, Agricultural and Food Policy Center Research Report 07-3. Texas A&M, College Station, Texas, USA.
Asher, GW, Fisher, MW, and Fennessy, PF (1996). Environmental constraints on reproductive performance of farmed deer. Animal Reproduction Science 42, 35–44.
| Environmental constraints on reproductive performance of farmed deer.Crossref | GoogleScholarGoogle Scholar |
Bartsch, RC, McConnell, EE, Imes, GD, and Schmidt, JM (1977). A review of exertional rhabdomyolysis in wild and domestic animals and man. Veterinary Pathology 14, 314–324.
| A review of exertional rhabdomyolysis in wild and domestic animals and man.Crossref | GoogleScholarGoogle Scholar |
Beringer, J, Hansen, LP, Wilding, W, Fischer, J, and Sheriff, SL (1996). Factors affecting capture myopathy in white-tailed deer. The Journal of Wildlife Management 60, 373–380.
| Factors affecting capture myopathy in white-tailed deer.Crossref | GoogleScholarGoogle Scholar |
Beringer, J, Hansen, LP, Demand, JA, Sartwell, J, Wallendorf, M, and Mange, R (2002). Efficacy of translocation to control urban deer in Missouri: costs, efficiency, and outcome. Wildlife Society Bulletin 30, 767–774.
Bishop, CJ, Freddy, DJ, White, GC, Watkins, BE, Stephenson, TR, and Wolfe, LL (2007). Using vaginal implant transmitters to aid in capture of mule deer neonates. Journal of Wildlife Management 71, 945–954.
| Using vaginal implant transmitters to aid in capture of mule deer neonates.Crossref | GoogleScholarGoogle Scholar |
Bishop, CJ, Anderson, CR, Walsh, DP, Bergman, EJ, Kuechle, P, and Roth, J (2011). Effectiveness of a redesigned vaginal implant transmitter in mule deer. The Journal of Wildlife Management 75, 1797–1806.
| Effectiveness of a redesigned vaginal implant transmitter in mule deer.Crossref | GoogleScholarGoogle Scholar |
Bowman, JL, and Jacobson, HA (1998). An improved vaginal-implant transmitter for locating white-tailed deer birth sites and fawns. Wildlife Society Bulletin 26, 295–298.
Carstensen, M, DelGiudice, GD, and Sampson, BA (2003). Using doe behavior and vaginal-implant transmitters to capture neonate white-tailed deer in north-central Minnesota. Wildlife Society Bulletin 31, 634–641.
Cromwell, JA, Warren, RJ, and Henderson, DW (1999). Live-capture and small-scale relocation of urban deer on Hilton Head Island, South Carolina. Wildlife Society Bulletin 27, 1025–1031.
DelGiudice, GD, Mech, LD, Paul, WJ, and Karns, PD (1986). Effects on fawn survival of multiple immobilizations of captive pregnant white-tailed deer. Journal of Wildlife Diseases 22, 245–248.
| Effects on fawn survival of multiple immobilizations of captive pregnant white-tailed deer.Crossref | GoogleScholarGoogle Scholar |
Demarais, S, Strickland, BK, Webb, SL, Smith, T, and McDonald, C (2016). Simulated effects of releasing pen-raised deer into the wild to alter population-level antler size. Wildlife Society Bulletin 40, 41–49.
| Simulated effects of releasing pen-raised deer into the wild to alter population-level antler size.Crossref | GoogleScholarGoogle Scholar |
Dickens, MJ, Delehanty, DJ, and Romero, LM (2010). Stress: an inevitable component of animal translocation. Biological Conservation 143, 1329–1341.
Dion, JR, Haus, JM, Rogerson, JE, and Bowman, JL (2019). An initial performance review of vaginal implant transmitters paired with GPS collars. Animal Biotelemetry 7, 22.
| An initial performance review of vaginal implant transmitters paired with GPS collars.Crossref | GoogleScholarGoogle Scholar |
Ditchkoff SS (2011) Anatomy and physiology. In ‘Biology and management of white-tailed deer’. (Ed. DG Hewitt) pp. 43–73. (CRC Press: Boca Raton, FL, USA)
Donohue, RN, Hewitt, DG, Fulbright, TE, DeYoung, CA, Litt, AR, and Draeger, DA (2013). Aggressive behavior of white-tailed deer at concentrated food sites as affected by population density. The Journal of Wildlife Management 77, 1401–1408.
| Aggressive behavior of white-tailed deer at concentrated food sites as affected by population density.Crossref | GoogleScholarGoogle Scholar |
Dusek, GL, MacKie, RJ, Herriges, JD, and Compton, BB (1989). Population ecology of white-tailed deer along the Lower Yellowstone River. Wildlife Monographs 104, 1–68.
Fryxell, JM, Hussell, DJT, Lambert, AB, and Smith, PC (1991). Time lags and population fluctuations in white-tailed deer. The Journal of Wildlife Management 55, 377–385.
| Time lags and population fluctuations in white-tailed deer.Crossref | GoogleScholarGoogle Scholar |
Gaydos, JK, Davidson, WR, Elvinger, F, Mead, DG, Howerth, EW, and Stallknecht, DE (2002). Innate resistance to epizootic hemorrhagic disease in white-tailed deer. Journal of Wildlife Diseases 38, 713–719.
| Innate resistance to epizootic hemorrhagic disease in white-tailed deer.Crossref | GoogleScholarGoogle Scholar |
Green, ML, Kelly, AC, Satterthwaite-Phillips, D, Manjerovic, MB, Shelton, P, Novakofski, J, and Mateus-Pinilla, N (2017). Reproductive characteristics of female white-tailed deer (Odocoileus viginianus) in the Midwestern USA. Theriogenology 94, 71–78.
| Reproductive characteristics of female white-tailed deer (Odocoileus viginianus) in the Midwestern USA.Crossref | GoogleScholarGoogle Scholar |
Grilli, DJ, Mrázek, J, Fliegerová, K, Kopečný, J, Lama, SP, Cucchi, MEC, Sosa, MA, and Arenas, GN (2016). Ruminal bacterial community changes during adaptation of goats to fresh alfalfa forage. Livestock Science 191, 191–195.
| Ruminal bacterial community changes during adaptation of goats to fresh alfalfa forage.Crossref | GoogleScholarGoogle Scholar |
Grovenburg, TW, Jenks, JA, Jacques, CN, Klaver, RW, and Swanson, CC (2009). Aggressive defensive behavior by free-ranging white-tailed deer. Journal of Mammalogy 90, 1218–1223.
| Aggressive defensive behavior by free-ranging white-tailed deer.Crossref | GoogleScholarGoogle Scholar |
Hamilton J, Knox WM, Guyunn DC Jr. (1995) Harvest strategies. In ‘Quality whitetails’. (Ed. RL Marchinton, KV Miller) pp. 24–46. (Stackpole Books: Mechanicsburg, PA, USA)
Harthoorn, AM (1977). Problems relating to capture. Animal Regulated Studies 1, 23–46.
Haskell, SP, Ballard, WB, Butler, DA, Tatman, NM, Wallace, MC, Kochanny, CO, and Alcumbrac, OJ (2007). Observations on capturing and aging deer fawns. Journal of Mammalogy 88, 1482–1487.
| Observations on capturing and aging deer fawns.Crossref | GoogleScholarGoogle Scholar |
Haugen, AO (1975). Reproductive performance of white-tailed deer in Iowa. Journal of Mammalogy 56, 151–159.
| Reproductive performance of white-tailed deer in Iowa.Crossref | GoogleScholarGoogle Scholar |
Hawkins, RE, and Montgomery, GG (1969). Movements of translocated deer as determined by telemetry. The Journal of Wildlife Management 33, 196–203.
| Movements of translocated deer as determined by telemetry.Crossref | GoogleScholarGoogle Scholar |
Hayssen, V (1998). Effect of transatlantic transport on reproduction of agouti and nonagouti deer mice, Peromyscus maniculatus. Laboratory Animals 32, 55–64.
| Effect of transatlantic transport on reproduction of agouti and nonagouti deer mice, Peromyscus maniculatus.Crossref | GoogleScholarGoogle Scholar |
Hosmer DW, Lemeshow S, May S (2008) ‘Applied survival analysis: regression modeling of time to event data.’ 2nd edn. (Wiley-Interscience: New York, NY, USA)
Howze MB (2009) The effect of predation on white-tailed deer recruitment at the Joseph W. Jones Ecological Research Center. MS thesis, University of Georgia, Athens, GA, USA.
Hubbard, RD, and Nielsen, CK (2009). White-tailed deer attacking humans during the fawning season: a unique human-wildlife conflict on a university campus. Human–Wildlife Conflicts 3, 129–135.
Huegel, CN, Dahlgren, RB, and Gladfelter, HL (1985). Use of doe behavior to capture white-tailed deer fawns. Wildlife Society Bulletin 13, 287–289.
Ishmael WE, Katsma DE, Isaac TA (1995) Live-capture and translocation of suburban white-tailed deer in River Hills, Wisconsin. In ‘Urban deer: a manageable resource? Proceedings of the 55th symposium of the midwest fish and wildlife conference’. (Ed. JB McAninch) pp. 87–96. (North Central section of The Wildlife Society: Springfield, MO, USA)
Jackson, AM, and Ditchkoff, SS (2013). Survival estimates of white-tailed deer fawns at Fort Rucker, Alabama. The American Midland Naturalist 170, 184–190.
| Survival estimates of white-tailed deer fawns at Fort Rucker, Alabama.Crossref | GoogleScholarGoogle Scholar |
Jacobson HA, Lukefahr SD (1999) Genetics research on captive white-tailed deer at Mississippi State University. In ‘Proceedings of the symposium on the role of genetics in white-tailed deer management’. (Ed. D Rollins). (Texas Agricultural Extension Service, Texas A&M University: College Station, TX, USA)
Jacobson, HA, Bearden, HJ, and Whitehouse, DB (1989). Artificial insemination trials with white-tailed deer. The Journal of Wildlife Management 53, 224–227.
| Artificial insemination trials with white-tailed deer.Crossref | GoogleScholarGoogle Scholar |
Jones, JM, and Witham, JH (1990). Post-translocation survival and movements of metropolitan white-tailed deer. Wildlife Society Bulletin 18, 434–441.
Keyser, PD, Guynn, DC, and Hill, HS (2005). Density-dependent recruitment patterns in white-tailed deer. Wildlife Society Bulletin 33, 222–232.
| Density-dependent recruitment patterns in white-tailed deer.Crossref | GoogleScholarGoogle Scholar |
Kilgo, JC, Ray, HS, Vukovich, M, Goode, MJ, and Ruth, C (2012). Predation by coyotes on white-tailed deer neonates in South Carolina. The Journal of Wildlife Management 76, 1420–1430.
| Predation by coyotes on white-tailed deer neonates in South Carolina.Crossref | GoogleScholarGoogle Scholar |
Kilgo, JC, Vukovich, M, Conroy, MJ, Ray, HS, and Ruth, C (2016). Factors affecting survival of adult female white-tailed deer after coyote establishment in South Carolina. Wildlife Society Bulletin 40, 747–753.
| Factors affecting survival of adult female white-tailed deer after coyote establishment in South Carolina.Crossref | GoogleScholarGoogle Scholar |
Larkin, JL, Maehr, DS, Cox, JJ, Wichrowski, MW, and Crank, RD (2002). Factors affecting reproduction and population growth in a restored elk Cervus elaphus nelsoni population. Wildlife Biology 8, 49–54.
| Factors affecting reproduction and population growth in a restored elk Cervus elaphus nelsoni population.Crossref | GoogleScholarGoogle Scholar |
Letty, J, Marchandeau, S, Clobert, J, and Aubineau, J (2000). Improving translocation success: an experimental study of anti-stress treatment and release method for wild rabbits. Animal Conservation 3, 211–219.
| Improving translocation success: an experimental study of anti-stress treatment and release method for wild rabbits.Crossref | GoogleScholarGoogle Scholar |
Lima, SL (1998). Stress and decision making under the risk of predation: recent developments from behavioral, reproductive, and ecological perspectives. Advances in the Study of Behavior 27, 215–290.
| Stress and decision making under the risk of predation: recent developments from behavioral, reproductive, and ecological perspectives.Crossref | GoogleScholarGoogle Scholar |
McCall, TC, Brown, RD, and DeYoung, CA (1988). Mortality of pen-raised and wild white-tailed deer bucks. Wildlife Society Bulletin 16, 380–384.
McCoy, JC, Ditchkoff, SS, Raglin, JB, Collier, BA, and Ruth, C (2013). Factors influencing survival of white-tailed deer fawns in coastal South Carolina. Journal of Fish and Wildlife Management 4, 280–289.
| Factors influencing survival of white-tailed deer fawns in coastal South Carolina.Crossref | GoogleScholarGoogle Scholar |
Miller, JE (2012). A growing threat: how deer breeding could put public trust wildlife at risk. The Wildlife Professional 6, 22–27.
Mylrea GE (1991) Reproduction in tropical species. In ‘Proceedings of a deer course for veterinarians’. pp. 249–261. (Deer Branch New Zealand Veterinary Association: Sydney, NSW, Australia)
Nixon, CM (1971). Productivity of white-tailed deer in Ohio. The Ohio Journal of Science 71, 217–225.
O’Bryan, MK, and McCullough, DR (1985). Survival of black-tailed deer following relocation in California. The Journal of Wildlife Management 49, 115–119.
| Survival of black-tailed deer following relocation in California.Crossref | GoogleScholarGoogle Scholar |
Ozoga, JJ, Verme, LJ, and Bienz, CS (1982). Parturition behavior and territoriality in white-tailed deer: impact on neonatal mortality. The Journal of Wildlife Management 46, 1–11.
| Parturition behavior and territoriality in white-tailed deer: impact on neonatal mortality.Crossref | GoogleScholarGoogle Scholar |
Powell, MC, DelGiudice, GD, and Sampson, BA (2005). Low risk of marking-induced abandonment in free-ranging white-tailed deer neonates. Wildlife Society Bulletin 33, 643–655.
| Low risk of marking-induced abandonment in free-ranging white-tailed deer neonates.Crossref | GoogleScholarGoogle Scholar |
Responsive Management and National Shooting Sports Foundation (2008) ‘The future of hunting and the shooting sports: research-based recruitment and retention strategies.’ Produced for the US Fish and Wildlife Service under Grant Agreement CT-M-6-0. (Responsive Management and National Shooting Sports Foundation: Harrisonburg, VA, USA)
Robinson, WL (1962). Social dominance and physical condition among penned white-tailed deer fawns. Journal of Mammalogy 43, 462–469.
| Social dominance and physical condition among penned white-tailed deer fawns.Crossref | GoogleScholarGoogle Scholar |
Romero, LM, and Wingfield, JC (2001). Regulation of the hypothalamic–pituitary–adrenal axis in free-living pigeons. Journal of Comparative Physiology B 171, 231–235.
| Regulation of the hypothalamic–pituitary–adrenal axis in free-living pigeons.Crossref | GoogleScholarGoogle Scholar |
Rosatte, R, Hamr, J, Ranta, B, Young, J, and Cool, N (2002). Elk restoration in Ontario, Canada: infectious disease management strategy, 1998–2001. Annals of the New York Academy of Sciences 969, 358–363.
| Elk restoration in Ontario, Canada: infectious disease management strategy, 1998–2001.Crossref | GoogleScholarGoogle Scholar |
Roseberry, JL, and Klimstra, WD (1970). Productivity of white-tailed deer on Crab Orchard National Wildlife Refuge. The Journal of Wildlife Management 34, 23–28.
| Productivity of white-tailed deer on Crab Orchard National Wildlife Refuge.Crossref | GoogleScholarGoogle Scholar |
Saalfeld, ST, and Ditchkoff, SS (2007). Survival of neonatal white-tailed deer in an exurban population. Journal of Wildlife Management 71, 940–944.
| Survival of neonatal white-tailed deer in an exurban population.Crossref | GoogleScholarGoogle Scholar |
Sapolsky RM (1992) ‘Stress, the aging brain, and the mechanisms of neuron death.’ (MIT Press: Cambridge, MA, USA)
Short J (2009) The characteristics and success of vertebrate translocations within Australia: a progress report to Department of Agriculture, Fisheries, and Forestry. Wildlife Research and Management Pty Ltd, Perth, WA, Australia.
Strickland, B, and Demarais, S (2006). Antler regulations: navigating the tangled thicket. Quality Whitetails 13, 30–34.
Taillon, J, and Côté, SD (2007). Social rank and winter forage quality affect aggressiveness in white-tailed deer fawns. Animal Behaviour 74, 265–275.
| Social rank and winter forage quality affect aggressiveness in white-tailed deer fawns.Crossref | GoogleScholarGoogle Scholar |
Tajima, K, Aminov, RI, Nagamine, T, Matsui, H, Nakamura, M, and Benno, Y (2001). Diet-dependent shifts in the bacterial population of the rumen revealed with real-time PCR. Applied and Environmental Microbiology 67, 2766–2774.
| Diet-dependent shifts in the bacterial population of the rumen revealed with real-time PCR.Crossref | GoogleScholarGoogle Scholar |
Teixeira, CP, de Azevedo, CS, Mendl, M, Cipreste, CF, and Young, RJ (2007). Revisiting translocation and reintroduction programmes: the importance of considering stress. Animal Behaviour 73, 1–13.
| Revisiting translocation and reintroduction programmes: the importance of considering stress.Crossref | GoogleScholarGoogle Scholar |
The Wildlife Society (2012) Captive cervid breeding fact sheet. Available at https://wildlife.org/wp-content/uploads/2014/05/captive-cervid-breeding.pdf
US Department of Agriculture (2014) 2012 Census of Agriculture, United States Summary and State Data. Vol. 1. USDA-NASS, Washington, DC, USA.
Williamson, NB, Morris, RS, and Anderson, GA (1978). Pregnancy rates and non-return rates following artificial and natural breeding in dairy herds. Australian Veterinary Journal 54, 111–114.
| Pregnancy rates and non-return rates following artificial and natural breeding in dairy herds.Crossref | GoogleScholarGoogle Scholar |
Zhang X (2017) Investigating the transmission of epizootic hemorrhagic disease virus (EHDV) among white-tailed deer in Alabama. MSc thesis, Auburn University, Auburn, AL, USA.
Zidon, R, Saltz, D, Shore, LS, and Motro, U (2009). Behavioral changes, stress, and survival following reintroduction of Persian fallow deer from two breeding facilities. Conservation Biology 23, 1026–1035.
| Behavioral changes, stress, and survival following reintroduction of Persian fallow deer from two breeding facilities.Crossref | GoogleScholarGoogle Scholar |
