Earl Julia E, Chaney Jordan C, Sutton William B, Lillard Carson E, Kouba Andrew J, Langhorne Cecilia, Krebs Jessi, Wilkes Rebecca P, Hill Rachel D, Miller Debra L, Gray Matthew J
Department of Natural Resource Ecology and Management, Oklahoma State University, Stillwater, OK, 74078, USA.
Center for Wildlife Health, Department of Forestry, Wildlife and Fisheries, University of Tennessee, Knoxville, TN, 37996, USA.
Oecologia. 2016 Oct;182(2):611-23. doi: 10.1007/s00442-016-3682-6. Epub 2016 Jun 25.
There is growing evidence that pathogens play a role in population declines and species extinctions. For small populations, disease-induced extinction may be especially probable. We estimated the susceptibility of two amphibian species of conservation concern (the dusky gopher frog [Lithobates sevosus] and boreal toad [Anaxyrus boreas boreas]) to an emerging pathogen (ranavirus) using laboratory challenge experiments, and combined these data with published demographic parameter estimates to simulate the potential effects of ranavirus exposure on extinction risk. We included effects of life stage during pathogen exposure, pathogen exposure interval, hydroperiod of breeding habitat, population carrying capacity, and immigration in simulations. We found that both species were highly susceptible to ranavirus when exposed to the pathogen in water at environmentally relevant concentrations. Dusky gopher frogs experienced 100 % mortality in four of six life stages tested. Boreal toads experienced 100 % mortality when exposed as tadpoles or metamorphs, which were the only life stages tested. Simulations showed population declines, greater extinction probability, and faster times to extinction with ranavirus exposure. These effects were more evident with more frequent pathogen exposure intervals and lower carrying capacity. Immigration at natural rates did little to mitigate effects of ranavirus exposure unless immigration occurred every 2 years. Our results demonstrate that disease-induced extinction by emerging pathogens, such as ranavirus, is possible, and that threat may be especially high for species with small population sizes. For the species in this study, conservation organizations should incorporate ranavirus surveillance into monitoring programs and devise intervention strategies in the event that disease outbreaks occur.
越来越多的证据表明,病原体在种群数量下降和物种灭绝中发挥作用。对于小种群而言,疾病导致的灭绝可能尤其容易发生。我们通过实验室挑战实验估算了两种受保护两栖动物(暗地鼠蛙[Lithobates sevosus]和北美蟾蜍[Anaxyrus boreas boreas])对一种新出现病原体(蛙病毒)的易感性,并将这些数据与已发表的种群统计学参数估计值相结合,以模拟接触蛙病毒对灭绝风险的潜在影响。在模拟中,我们纳入了病原体暴露期间的生命阶段、病原体暴露间隔、繁殖栖息地的水淹期、种群承载能力和迁入的影响。我们发现,当在与环境相关的浓度下于水中接触病原体时,这两个物种对蛙病毒都高度易感。在测试的六个生命阶段中的四个阶段,暗地鼠蛙的死亡率达100%。北美蟾蜍在作为蝌蚪或变态期个体接触时死亡率达100%,这是测试的仅有的生命阶段。模拟结果显示,接触蛙病毒会导致种群数量下降、灭绝概率增加以及灭绝时间加快。病原体暴露间隔越频繁且承载能力越低,这些影响就越明显。以自然速率的迁入几乎无法减轻接触蛙病毒的影响,除非每两年发生一次迁入。我们的结果表明,由新出现的病原体(如蛙病毒)导致的疾病灭绝是可能的,而且对于种群规模较小的物种,这种威胁可能尤其高。对于本研究中的物种,保护组织应将蛙病毒监测纳入监测计划,并在疾病爆发时制定干预策略。
