Abstract
Grazing‐induced changes in plant quality have been suggested to drive the negative delayed density dependence exhibited by many herbivore species, but little field evidence exists to support this hypothesis. We tested a key premise of the hypothesis that reciprocal feedback between vole grazing pressure and the induction of anti‐herbivore silicon defenses in grasses drives observed population cycles in a large‐scale field experiment in northern England. We repeatedly reduced population densities of field voles (Microtus agrestis) on replicated 1‐ha grassland plots at Kielder Forest, northern England, over a period of 1 year. Subsequently, we tested for the impact of past density on vole life history traits in spring, and whether these effects were driven by induced silicon defenses in the voles’ major over‐winter food, the grass Deschampsia caespitosa. After several months of density manipulation, leaf silicon concentrations diverged and averaged 22% lower on sites where vole density had been reduced, but this difference did not persist beyond the period of the density manipulations. There were no significant effects of our density manipulations on vole body mass, spring population growth rate, or mean date for the onset of spring reproduction the following year. These findings show that grazing by field voles does induce increased silicon defenses in grasses at a landscape scale. However, at the vole densities encountered, levels of plant damage appear to be below those needed to induce changes in silicon levels large and persistent enough to affect vole performance, confirming the threshold effects we have previously observed in laboratory‐based studies. Our findings do not support the plant quality hypothesis for observed vole population cycles in northern England, at least over the range of vole densities that now prevail here.
Highlights
Delayed density-dependence drives multiannual cyclic fluctuations in abundance of many herbivore populations, such that current population densities are partly regulated by past ones
While the negative impacts of herbivore density on the quantity of food may not be evident, except in arctic and subarctic systems, where plant regrowth after herbivory is slow (Krebs, Cowcill, Boonstra, & Kenney, 2010; Turchin, Oksanen, Ekerholm, Oksanen, & Henttonen, 2000), it is well established that herbivory-induced reductions in plant quality do have the potential to underlie the delayed density dependence of cyclic herbivore populations (Reynolds et al, 2012; Turchin, 2003; Underwood & Rausher, 2002)
Theoretical studies have suggested that such density-dependent impacts on breeding season length alone have the potential to generate population cycles in seasonal environments (Smith, White, Lambin, Sherratt, & Begon, 2006), while in the field, voles transplanted at the start of winter between grassland areas differing in the phase of their cycle have been shown to take on the characteristics of vole populations in their new environment (Ergon, Lambin, & Stenseth, 2001)
Summary
Delayed density-dependence drives multiannual cyclic fluctuations in abundance of many herbivore populations, such that current population densities are partly regulated by past ones. Theoretical studies have suggested that such density-dependent impacts on breeding season length alone have the potential to generate population cycles in seasonal environments (Smith, White, Lambin, Sherratt, & Begon, 2006), while in the field, voles transplanted at the start of winter between grassland areas differing in the phase of their cycle have been shown to take on the characteristics of vole populations in their new environment (Ergon, Lambin, & Stenseth, 2001) This demonstrates that the mechanisms driving vole demography must arise from interactions within their immediate environment ( see Klemola, Korpimäki, & Koivula, 2002). We expected these impacts on vole mass and breeding would occur once silicon levels on the control sites exceed these levels
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