Dynamics, Persistence, and Genetic Management of the Endangered Florida Panther Population Dinámicas, Persistencia y Manejo Genético de la Población en Peligro de Extinción de Pantera de Florida

IF 4.3 1区 生物学 Q1 ECOLOGY Wildlife Monographs Pub Date : 2019-07-23 DOI:10.1002/wmon.1041
Madelon van de Kerk, David P. Onorato, Jeffrey A. Hostetler, Benjamin M. Bolker, Madan K. Oli
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Our goals were 1) to comprehensively assess the demographics of the Florida panther population using long-term (1981–2015) field data and modeling to gauge the persistence of benefits accrued via genetic introgression and 2) to evaluate the effectiveness of various potential genetic management strategies. Translocation and introduction of female pumas (<i>Puma concolor stanleyana</i>) from Texas, USA, substantially improved genetic diversity. The average individual heterozygosity of canonical (non-introgressed) panthers was 0.386 ± 0.012 (SE); for admixed panthers, it was 0.615 ± 0.007. Survival rates were strongly age-dependent (kittens had the lowest survival rates), were positively affected by individual heterozygosity, and decreased with increasing population abundance. Overall annual kitten survival was 0.32 ± 0.09; sex did not have a clear effect on kitten survival. Annual survival of subadult and adult panthers differed by sex; regardless of age, females exhibited higher survival than males. Annual survival rates of subadult, prime adult, and old adult females were 0.97 ± 0.02, 0.86 ± 0.03, and 0.78 ± 0.09, respectively. Survival rates of subadult, prime adult, and old adult males were 0.66 ± 0.06, 0.77 ± 0.05, and 0.65 ± 0.10, respectively. For panthers of all ages, genetic ancestry strongly affected survival rate, where first filial generation (F1) admixed panthers of all ages exhibited the highest rates and canonical (mostly pre-introgression panthers and their post-introgression descendants) individuals exhibited the lowest rates. The most frequently observed causes of death of radio-collared panthers were intraspecific aggression and vehicle collision. Cause-specific mortality analyses revealed that mortality rates from vehicle collision, intraspecific aggression, other causes, and unknown causes were generally similar for males and females, although males were more likely to die from intraspecific aggression than females. The probability of reproduction and the annual number of kittens produced varied by age; evidence that ancestry or abundance influenced these parameters was weak. Predicted annual probabilities of reproduction were 0.35 ± 0.08, 0.50 ± 0.05, and 0.25 ± 0.06 for subadult, prime adult, and old adult females, respectively. The number of kittens predicted to be produced annually by subadult, prime adult, and old adult females were 2.80 ± 0.75, 2.67 ± 0.43, and 2.28 ± 0.83, respectively. The stochastic annual population growth rate estimated using a matrix population model was 1.04 (95% CI = 0.72–1.41). An individual-based population model predicted that the probability that the population would fall below 10 panthers within 100 years (quasi-extinction) was 1.4% (0–0.8%) if the adverse effects of genetic erosion were ignored. However, when the effect of genetic erosion was considered, the probability of quasi-extinction within 100 years increased to 17% (0–100%). Mean times to quasi-extinction, conditioned on going quasi-extinct within 100 years, was 22 (0–75) years when the effect of genetic erosion was considered. Sensitivity analyses revealed that the probability of quasi-extinction and expected time until quasi-extinction were most sensitive to changes in kitten survival parameters. Without genetic management intervention, the Florida panther population would face a substantially increased risk of quasi-extinction. The question, therefore, is not whether genetic management of the Florida panther population is needed but when and how it should be implemented. 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引用次数: 37

Abstract

Abundant evidence supports the benefits accrued to the Florida panther (Puma concolor coryi) population via the genetic introgression project implemented in South Florida, USA, in 1995. Since then, genetic diversity has improved, the frequency of morphological and biomedical correlates of inbreeding depression have declined, and the population size has increased. Nevertheless, the panther population remains small and isolated and faces substantial challenges due to deterministic and stochastic forces. Our goals were 1) to comprehensively assess the demographics of the Florida panther population using long-term (1981–2015) field data and modeling to gauge the persistence of benefits accrued via genetic introgression and 2) to evaluate the effectiveness of various potential genetic management strategies. Translocation and introduction of female pumas (Puma concolor stanleyana) from Texas, USA, substantially improved genetic diversity. The average individual heterozygosity of canonical (non-introgressed) panthers was 0.386 ± 0.012 (SE); for admixed panthers, it was 0.615 ± 0.007. Survival rates were strongly age-dependent (kittens had the lowest survival rates), were positively affected by individual heterozygosity, and decreased with increasing population abundance. Overall annual kitten survival was 0.32 ± 0.09; sex did not have a clear effect on kitten survival. Annual survival of subadult and adult panthers differed by sex; regardless of age, females exhibited higher survival than males. Annual survival rates of subadult, prime adult, and old adult females were 0.97 ± 0.02, 0.86 ± 0.03, and 0.78 ± 0.09, respectively. Survival rates of subadult, prime adult, and old adult males were 0.66 ± 0.06, 0.77 ± 0.05, and 0.65 ± 0.10, respectively. For panthers of all ages, genetic ancestry strongly affected survival rate, where first filial generation (F1) admixed panthers of all ages exhibited the highest rates and canonical (mostly pre-introgression panthers and their post-introgression descendants) individuals exhibited the lowest rates. The most frequently observed causes of death of radio-collared panthers were intraspecific aggression and vehicle collision. Cause-specific mortality analyses revealed that mortality rates from vehicle collision, intraspecific aggression, other causes, and unknown causes were generally similar for males and females, although males were more likely to die from intraspecific aggression than females. The probability of reproduction and the annual number of kittens produced varied by age; evidence that ancestry or abundance influenced these parameters was weak. Predicted annual probabilities of reproduction were 0.35 ± 0.08, 0.50 ± 0.05, and 0.25 ± 0.06 for subadult, prime adult, and old adult females, respectively. The number of kittens predicted to be produced annually by subadult, prime adult, and old adult females were 2.80 ± 0.75, 2.67 ± 0.43, and 2.28 ± 0.83, respectively. The stochastic annual population growth rate estimated using a matrix population model was 1.04 (95% CI = 0.72–1.41). An individual-based population model predicted that the probability that the population would fall below 10 panthers within 100 years (quasi-extinction) was 1.4% (0–0.8%) if the adverse effects of genetic erosion were ignored. However, when the effect of genetic erosion was considered, the probability of quasi-extinction within 100 years increased to 17% (0–100%). Mean times to quasi-extinction, conditioned on going quasi-extinct within 100 years, was 22 (0–75) years when the effect of genetic erosion was considered. Sensitivity analyses revealed that the probability of quasi-extinction and expected time until quasi-extinction were most sensitive to changes in kitten survival parameters. Without genetic management intervention, the Florida panther population would face a substantially increased risk of quasi-extinction. The question, therefore, is not whether genetic management of the Florida panther population is needed but when and how it should be implemented. Thus, we evaluated genetic and population consequences of alternative genetic introgression strategies to identify optimal management actions using individual-based simulation models. Releasing 5 pumas every 20 years would cost much less ($200,000 over 100 years) than releasing 15 pumas every 10 years ($1,200,000 over 100 years) yet would reduce the risk of quasi-extinction by comparable amount (44–59% vs. 40–58%). Generally, releasing more females per introgression attempt provided little added benefit. The positive effects of the genetic introgression project persist in the panther population after 20 years. We suggest that managers contemplate repeating genetic introgression by releasing 5–10 individuals from other puma populations every 20–40 years. We also recommend that managers continue to collect data that will permit estimation and monitoring of kitten, adult, and subadult survival. We identified these parameters via sensitivity analyses as most critical in terms of their impact on the probability of and expected times to quasi-extinction. The continuation of long-term monitoring should permit the adaptation of genetic management strategies as necessary while collecting data that have proved essential in assessing the genetic and demographic health of the population. The prospects for recovery of the panther will certainly be improved by following these guidelines. © 2019 The Authors. Wildlife Monographs published by Wiley Periodicals, Inc. on behalf of The Wildlife Society.

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濒危佛罗里达黑豹种群的动态、持久性和遗传管理佛罗里达黑豹种群的动态、持久性和遗传管理
大量证据支持1995年在美国南佛罗里达实施的遗传渗入项目给佛罗里达黑豹(Puma concolor coryi)种群带来的益处。从那时起,遗传多样性得到了改善,近交抑郁的形态学和生物医学相关频率有所下降,种群规模有所增加。然而,由于确定性和随机力量的影响,黑豹的数量仍然很小,并且孤立存在,面临着巨大的挑战。我们的目标是:1)利用长期(1981-2015年)的野外数据和建模来全面评估佛罗里达黑豹种群的人口统计数据,以衡量通过遗传渗入积累的利益的持久性;2)评估各种潜在遗传管理策略的有效性。美国德克萨斯州雌性美洲狮(Puma concolor stanleyana)的易位和引进,极大地提高了遗传多样性。典型黑豹(非渐渗)个体平均杂合度为0.386±0.012 (SE);混合黑豹为0.615±0.007。存活率强烈依赖于年龄(小猫的存活率最低),受个体杂合度的积极影响,并随着种群丰度的增加而下降。小猫年总体存活率为0.32±0.09;性别对小猫的存活率没有明显的影响。亚成体和成体黑豹的年存活率存在性别差异;不论年龄大小,雌性的存活率都高于雄性。亚成虫、壮年成虫和老年成虫的年存活率分别为0.97±0.02、0.86±0.03和0.78±0.09。亚成虫、壮年成虫和老年成虫的存活率分别为0.66±0.06、0.77±0.05和0.65±0.10。对于所有年龄段的黑豹来说,遗传祖先都强烈影响其存活率,其中所有年龄段的第一代(F1)混合黑豹的存活率最高,而典型个体(主要是前渗入黑豹及其后渗入后代)的存活率最低。无线电项圈黑豹最常见的死亡原因是种内攻击和车辆碰撞。原因特异性死亡率分析显示,男性和女性因车辆碰撞、种内攻击、其他原因和未知原因导致的死亡率大致相似,尽管男性比女性更容易死于种内攻击。繁殖概率和年产仔数因年龄而异;祖先或丰度影响这些参数的证据很弱。亚成虫、壮年成虫和老年成虫的年繁殖概率分别为0.35±0.08、0.50±0.05和0.25±0.06。亚成年母猫、初级成年母猫和老年成年母猫预计年产仔数分别为2.80±0.75、2.67±0.43和2.28±0.83。使用矩阵种群模型估计的随机年种群增长率为1.04 (95% CI = 0.72-1.41)。基于个体的种群模型预测,如果忽略遗传侵蚀的不利影响,100年内种群数量下降到10只以下(准灭绝)的概率为1.4%(0-0.8%)。而考虑遗传侵蚀的影响,100年内的准灭绝概率增加到17%(0 ~ 100%)。考虑遗传侵蚀的影响,以100年内准灭绝为条件的准灭绝平均时间为22(0 ~ 75)年。敏感性分析表明,准灭绝概率和准灭绝预期时间对小猫生存参数的变化最为敏感。如果没有基因管理干预,佛罗里达黑豹种群将面临更大的准灭绝风险。因此,问题不在于是否需要对佛罗里达黑豹种群进行遗传管理,而在于何时以及如何实施。因此,我们利用基于个体的模拟模型评估了替代遗传渗入策略的遗传和种群后果,以确定最佳管理行动。每20年释放5只美洲狮的成本(100年20万美元)要比每10年释放15只美洲狮的成本(100年120万美元)少得多,但却能降低类似灭绝的风险(44-59%对40-58%)。一般来说,每次基因渗入尝试释放更多的雌性几乎没有额外的好处。遗传渗入工程的积极影响在黑豹种群中持续了20年。我们建议管理者考虑通过每20-40年从其他美洲狮种群中释放5-10只来重复基因渗入。我们还建议管理人员继续收集数据,以便对小猫、成虫和亚成虫的存活率进行估计和监测。 我们通过敏感性分析确定了这些参数,因为它们对准灭绝的概率和预期时间的影响最为关键。继续进行长期监测应能在收集已证明对评估人口的遗传和人口健康至关重要的数据的同时,酌情调整遗传管理战略。遵循这些指导方针,黑豹的恢复前景肯定会得到改善。©2019作者。Wiley期刊公司代表野生动物协会出版的野生动物专著。
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来源期刊
Wildlife Monographs
Wildlife Monographs 生物-动物学
CiteScore
9.10
自引率
0.00%
发文量
3
审稿时长
>12 weeks
期刊介绍: Wildlife Monographs supplements The Journal of Wildlife Management with focused investigations in the area of the management and conservation of wildlife. Abstracting and Indexing Information Academic Search Alumni Edition (EBSCO Publishing) Agricultural & Environmental Science Database (ProQuest) Biological Science Database (ProQuest) CAB Abstracts® (CABI) Earth, Atmospheric & Aquatic Science Database (ProQuest) Global Health (CABI) Grasslands & Forage Abstracts (CABI) Helminthological Abstracts (CABI) Natural Science Collection (ProQuest) Poultry Abstracts (CABI) ProQuest Central (ProQuest) ProQuest Central K-543 Research Library (ProQuest) Research Library Prep (ProQuest) SciTech Premium Collection (ProQuest) Soils & Fertilizers Abstracts (CABI) Veterinary Bulletin (CABI)
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