Yakob Laith, Kiss Istvan Z, Bonsall Michael B
Program in Public Health, University of California, Hewitt Hall, Irvine, CA 92697, USA.
Theor Popul Biol. 2008 Dec;74(4):324-31. doi: 10.1016/j.tpb.2008.09.003. Epub 2008 Sep 24.
Historically, models of the invasion and biological control of insect pests have omitted heterogeneities in the spatial structure of the targeted populations. In this study, we use stochastic network simulations to examine explicitly population heterogeneity as a function of landscape structure and insect behavior. We show that when insects are distributed non-randomly across a heterogeneous landscape, control can be significantly hindered. However, when insect populations are clustered as a result of limited dispersal, genetic control efficiency can be enhanced. In developing the model, we relax a key assumption of previous theoretical studies of genetic control: that released genetic control insects remain homogenously distributed irrespective of the spatial structure of the wild type populations. Here, this behavior (termed the 'coverage proportion') is parameterized and its properties are explored. We show that landscape heterogeneity and limited dispersal have little effect on the critical coverage proportion necessary for control.
从历史上看,害虫入侵和生物防治模型忽略了目标种群空间结构的异质性。在本研究中,我们使用随机网络模拟来明确检验作为景观结构和昆虫行为函数的种群异质性。我们表明,当昆虫在异质景观中呈非随机分布时,防治可能会受到显著阻碍。然而,当昆虫种群由于扩散受限而聚集时,遗传防治效率可以提高。在开发该模型时,我们放宽了先前遗传防治理论研究的一个关键假设:即释放的遗传防治昆虫无论野生型种群的空间结构如何都保持均匀分布。在这里,这种行为(称为“覆盖比例”)被参数化并探索了其特性。我们表明,景观异质性和有限扩散对防治所需的临界覆盖比例影响很小。