Abstract
Registered hunters harvested over 1.3 million non-native invasive green iguanas (Iguana iguana) on Grand Cayman between October 2018 and August 2021. We used islandwide post-reproduction survey-based abundance estimates in August 2014–2021 and model-based abundance predictions for August 2022–2030 to assist natural resource managers with reassessment and modification of the harvest strategy due to diminishing returns to hunters paid per green iguana harvested. We need harvest rates > 0.600 for desired abundance ≤ 50,000 and > 0.700 for desired abundance ≤ 10,000 green iguanas. With harvest rates < 0.600, the population would likely remain above desired abundance. Without harvesting, the green iguana population would likely reach carrying capacity by August 2026.
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Introduction
The non-native invasive green iguana (Iguana iguana) was first noticed on Grand Cayman in the early 1990s (F. Burton, personal observation). Estimated abundance surpassed 1.3 million in August 2018 (see Rivera-Milán and Haakonsson 2020: Table 2). Concerned about the negative impacts of overabundance, natural resource managers from the Cayman Islands Government contracted the services of a private company and registered hunters to harvest green iguanas. Registered hunters harvested over 1.3 million green iguanas on Grand Cayman between October 2018 and August 2021. However, the total number of green iguanas harvested per month decreased from 154,829 in November 2018 to 7200 in August 2021 (https://doe.ky/green-iguana-cull-updates/). To boost hunting activity, natural resource managers wanted to reassess and modify the harvest strategy from a bounty system where hunters are paid per green iguana harvested to a system in which contracted hunter teams are paid for the total number of hunting hours per week (F. Burton, personal communication). In addition, based on islandwide post-reproduction surveys in August 2020 and 2021, they wanted to lower desired abundance from ≤ 50,000 to ≤ 10,000 green iguanas, and they wanted to simulate the population trajectory without harvesting and with variable harvest rates. Here, we provide that information using abundance estimates from islandwide post-reproduction surveys conducted annually in August 2014–2021. Our objectives were to (1) fit a Bayesian state-space logistic model with August 2014–2021 survey-based abundance estimates, (2) update posterior estimates of population carrying capacity (K), maximum intrinsic rate of population growth (rmax) and maximum sustained harvest rate (hmsy = rmax/2), and (3) predict future post-reproduction abundance in August without harvesting and with harvest rates between 0.001 and 0.900 during 2022–2030.
Methods
We counted hatchlings, juveniles and adults at 157–212 fixed point locations along and away from roads surveyed annually on Grand Cayman in August 2014–2021 (see Rivera-Milán and Haakonsson 2020: Fig. 1). We used distance sampling and N-mixture models to estimate abundance (Buckland et al. 2015; Kéry and Royle 2016). We fit a Bayesian state-space logistic model with abundance estimates, corrected for changes in detection probability due to observer detectability and green iguana availability (see Rivera-Milán and Haakonsson 2020: Table 1). The Bayesian state-space logistic model accounted for observation error (e.g., due to imperfect detection and partial control over harvesting) and process variance (e.g., due to environmental stochasticity and incomplete understanding of population dynamics).
Grand Cayman green iguana survey-based abundance estimates (crosses with vertical lines for means and standard errors) and model-based posterior estimates of predicted abundance (circles with vertical lines for means and standard deviations and dashed lines for medians and 2.5–97.5th percentiles) with a harvest rate h ~ Uniform (0.701, 0.900) and b without harvesting during 2022–2030
In the model (see Rivera-Milán and Haakonsson 2020: Eq. 2), parameter K represents the abundance above which the green iguana population tends to decline due to density dependence (e.g., competition for limited space to reproduce). Parameter rmax is the exponential rate of increase of the population at low density and under favorable conditions (e.g., with plenty of space and other resources needed to maximize reproductive output). Parameter Nt is the true unknown abundance state of the population and Ht is the total number of green iguanas harvested in time period t. That is, total harvest (Ht) = Ntht, where ht is the harvest rate generated as part of the Markov chain Monte Carlo algorithm using uniform prior distributions for six hypothetical harvesting scenarios: h ~ Uniform (0.001, 0.100), (0.101, 0.300), (0.301, 0.500), (0.501, 0.700), (0.701, 0.900), and (0.001, 0.900). Based on previous modeling simulations presented in Rivera-Milán and Haakonsson (2020, Table 3), we also used uniform priors to update posterior estimates of parameters K ~ Uniform (900,000, 2,000,000) and rmax ~ Uniform (0.500, 2.000). For additional information about population monitoring and modeling methods, see Rivera-Milán and Haakonsson (2020).
Results and discussion
In Table 1 and Fig. 1a, b, we provide survey-based abundance estimates for August 2014–2021. Green iguana abundance declined from 103,020 (SE = 42,925) in August 2019 to 25,259 (SE = 9,485) in August 2020. However, abundance increased to 87,751 (SE = 34,706) in August 2021. Harvest rates declined from 0.629 between October 2018 and July 2019 to 0.568 in August 2019, 0.374 in August 2020, and 0.082 in August 2021. Green iguana abundance increased between 2020 and 2021 as harvesting declined due to diminishing returns to hunters paid a per green iguana harvested (Fig. 2). In addition to diminishing returns, hunters did not report harvested green iguanas in April 2020 due to a government-mandated coronavirus pandemic 40-day lockdown (Fig. 2). As expected from previous modeling simulations with harvest rates < 0.600 (see Rivera-Milán and Haakonsson 2020: Fig. 2a), the population recovered rapidly and surpassed 50,000 green iguanas between the August 2020 and 2021 surveys (Table 1).
Based on modeling simulations with h ~ Uniform (0.001, 0.900) to account for the possibility of highly variable harvest rates during 2022–2030, the mean posterior estimate of parameter K was 1,378,259 (SD = 298,802, median = 1,338,280, 2.5–97.5th percentiles = 927,055–1,953,958), the mean posterior estimate of parameter rmax was 1.323 (SD = 0.415, median = 1.354, 2.5–97.5th percentiles = 0.548–1.965), and the mean posterior estimate of parameter hmsy was 0.661 (SD = 0.207, median = 0.677, 2.5–97.5th percentiles = 0.274–0.983). Despite additional abundance estimates from the August 2020 and 2021 surveys, the posterior estimates of parameters K, rmax and hmsy were highly variable but similar to those reported by Rivera-Milán and Haakonsson (2020, Table 3). Model-based abundance predictions were also highly variable but similar to those previously reported (see Rivera-Milán and Haakonsson 2020: Fig. 2a). Therefore, based on modeling simulations, we need to keep harvest rates > 0.600 for desired abundance ≤ 50,000 green iguanas (Rivera-Milán and Haakonsson 2020), and we need to keep harvest rates > 0.700 for desired abundance ≤ 10,000 green iguanas (Table 2, Fig. 1a).
More specifically, based on modeling simulations with h ~ Uniform (0.701, 0.900), we predict a green iguana abundance decline to 12,448 (SD = 54,571, median = 3027, 2.5–97.5th percentiles = 102–77,761) in August 2023 and 1470 (SD = 19,441, median = 18, 2.5–97.5th percentiles = 0–8442) in August 2030 (Table 2, Fig. 1a). In contrast, without harvesting (Fig. 1b), we predict a green iguana abundance increase to 417,026 (SD = 153,639, median = 392,866, 2.5–97.5th percentiles = 196,216–787,324) in August 2023 and 1,702,805 (SD = 302,447, median = 1,676,052, 2.5–97.5th percentiles = 1,676,052–2,390,200) in August 2029. Moreover, an unharvested green iguana population would likely reach and fluctuate around carrying capacity levels between August 2026 and 2029, lowering abundance predictability in August 2030 (i.e., mean = 1,387,508, SD = 1,614,523, median = 951,513, 2.5–97.5th percentiles = 1–5,480,424; Fig. 1b).
Management implications and recommendations
Based on rmax 2.5–97.5th percentiles, the green iguana population has a doubling time of 4–15 months (i.e., T = ln[2]/rmax × 12). Therefore, with desired abundance ≤ 10,000 and estimated abundance averaging 87,751 in August 2021 (Table 1), we recommend keeping harvest rates > 0.700, which would imply harvesting > 61,426 green iguanas before the August 2022 survey. In addition, to assess population response to harvesting above hmsy (i.e., h > rmax/2), we recommend monitoring twice per year, with a pre-reproduction survey in February and a post-reproduction survey in August 2023–2030. Long-term population monitoring and modeling are essential to guide decision-making and adapt the harvest strategy based on estimated and predicted abundance.
Data availability
Not applicable.
References
Buckland ST, Rexstad EA, Marques TA, Oedekoven CS (2015) Distance sampling: methods and applications. Springer, New York
Kéry M, Royle JA (2016) Applied hierarchical modeling in ecology. Elsevier, California
Rivera-Milán FF, Haakonsson J (2020) Monitoring, modeling and harvest management of non-native invasive green iguanas on Grand Cayman Cayman Islands. Biol Invasions. https://doi.org/10.1007/s10530-020-02233-5
Acknowledgements
The study was possible thanks to the support given by G. Ebanks, T. Austin and F. Burton from the Cayman Islands Department of Environment. Thanks to J. Olynik for assisting with mapping, J. Harvey, S. Brenkus, L. Collyer and S. Poznansky for assisting with fieldwork, and Cornwall Consulting Company for assisting with harvest and disposal operations. F. Burton reviewed the first version of the manuscript before submission and the second version after revision. The findings, conclusions and recommendations are those of the authors and do not necessarily represent the views, determinations or policies of their respective government agencies. The use of trade, firm or product names does not imply endorsement by the government agencies.
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Rivera-Milán, F.F., Haakonsson, J., Bodden, V. et al. Monitoring and modeling non-native invasive green iguana population response to harvesting on Grand Cayman, Cayman Islands. Biol Invasions 24, 2993–2996 (2022). https://doi.org/10.1007/s10530-022-02828-0
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DOI: https://doi.org/10.1007/s10530-022-02828-0