Letcher Benjamin H, Schueller Paul, Bassar Ronald D, Nislow Keith H, Coombs Jason A, Sakrejda Krzysztof, Morrissey Michael, Sigourney Douglas B, Whiteley Andrew R, O'Donnell Matthew J, Dubreuil Todd L
S.O. Conte Anadromous Fish Research Center, US Geological Survey/Leetown Science Center, Turners Falls, MA, 01376, USA.
Program in Organismic and Evolutionary Biology, University of Massachusetts, Amherst, MA, 01003-4210, USA.
J Anim Ecol. 2015 Mar;84(2):337-52. doi: 10.1111/1365-2656.12308. Epub 2014 Dec 3.
Modelling the effects of environmental change on populations is a key challenge for ecologists, particularly as the pace of change increases. Currently, modelling efforts are limited by difficulties in establishing robust relationships between environmental drivers and population responses. We developed an integrated capture-recapture state-space model to estimate the effects of two key environmental drivers (stream flow and temperature) on demographic rates (body growth, movement and survival) using a long-term (11 years), high-resolution (individually tagged, sampled seasonally) data set of brook trout (Salvelinus fontinalis) from four sites in a stream network. Our integrated model provides an effective context within which to estimate environmental driver effects because it takes full advantage of data by estimating (latent) state values for missing observations, because it propagates uncertainty among model components and because it accounts for the major demographic rates and interactions that contribute to annual survival. We found that stream flow and temperature had strong effects on brook trout demography. Some effects, such as reduction in survival associated with low stream flow and high temperature during the summer season, were consistent across sites and age classes, suggesting that they may serve as robust indicators of vulnerability to environmental change. Other survival effects varied across ages, sites and seasons, indicating that flow and temperature may not be the primary drivers of survival in those cases. Flow and temperature also affected body growth rates; these responses were consistent across sites but differed dramatically between age classes and seasons. Finally, we found that tributary and mainstem sites responded differently to variation in flow and temperature. Annual survival (combination of survival and body growth across seasons) was insensitive to body growth and was most sensitive to flow (positive) and temperature (negative) in the summer and fall. These observations, combined with our ability to estimate the occurrence, magnitude and direction of fish movement between these habitat types, indicated that heterogeneity in response may provide a mechanism providing potential resilience to environmental change. Given that the challenges we faced in our study are likely to be common to many intensive data sets, the integrated modelling approach could be generally applicable and useful.
模拟环境变化对种群的影响是生态学家面临的一项关键挑战,尤其是随着变化速度的加快。目前,建模工作受到难以在环境驱动因素与种群反应之间建立稳健关系的限制。我们开发了一个综合捕获-再捕获状态空间模型,利用来自河流网络中四个地点的溪鳟(Salvelinus fontinalis)的长期(11年)、高分辨率(个体标记、季节性采样)数据集,来估计两个关键环境驱动因素(水流和温度)对种群统计学率(身体生长、移动和存活)的影响。我们的综合模型提供了一个有效的框架来估计环境驱动因素的影响,因为它通过估计缺失观测值的(潜在)状态值充分利用了数据,因为它在模型组件之间传播不确定性,还因为它考虑了对年生存率有贡献的主要种群统计学率和相互作用。我们发现水流和温度对溪鳟种群统计学有强烈影响。一些影响,比如夏季低水流和高温导致的存活率降低,在不同地点和年龄组中是一致的,这表明它们可能是易受环境变化影响的有力指标。其他存活影响在年龄、地点和季节间有所不同,这表明在这些情况下水流和温度可能不是存活的主要驱动因素。水流和温度也影响身体生长率;这些反应在不同地点是一致的,但在年龄组和季节间有显著差异。最后,我们发现支流和干流地点对水流和温度变化的反应不同。年生存率(各季节存活和身体生长的综合)对身体生长不敏感,在夏季和秋季对水流(正向)和温度(负向)最为敏感。这些观察结果,再加上我们估计鱼类在这些栖息地类型之间移动的发生、幅度和方向的能力,表明反应的异质性可能提供了一种对环境变化具有潜在恢复力的机制。鉴于我们在研究中面临的挑战可能在许多密集数据集里都很常见,这种综合建模方法可能具有普遍适用性和实用性。
