Cascading effects of a specialist parasitoid on plant biomass in a <Emphasis Type="Italic">Citrus</Emphasis> agroecosystem

We studied a specialist parasitoid (Coccobius fulvus Compere et Annecke; Hymenoptera: Aphelinidae), its host (the arrowhead scale, Unaspis yanonensis Kuwana; Hemiptera: Diaspididae) and the host plant (Citrus unshiu Marc; Rutaceae) to examine the indirect effects, via host–parasitoid interactions, of the parasitoid on plant biomass. We compared plant biomass and herbivore abundance in a system of two trophic levels (plants and herbivores) with a system of three trophic levels (plants, herbivores and parasitoids) using enclosure experiments in an agricultural setting. Each of eight young Citrus trees was infested with 40 scales and placed in an enclosure. We introduced three female parasitoids into half of the enclosures and monitored temporal changes in scale density and cumulative parasitism for the subsequent 11months. Plant biomass was then compared between treatment groups (parasitoids added) and controls (parasitoids excluded). During the experiment, cumulative parasitism increased rapidly in the parasitoid-addition enclosures to a maximum of 89%, and the number of live scales in the control enclosures was approximately 10-fold that in the treatment enclosures. At the end of the experiment, plant biomass was threefold higher in the parasitoid-addition enclosures than in the control enclosures. These results have two implications for terrestrial communities. First, specialist parasitoids, which are the principal natural enemies of most herbivorous insects, can trigger trophic cascades in the same way that generalist predators can. Second, cascading effects can be detected by observing changes in plant biomass. The latter finding is contrary to recent conclusions about top-down cascades (i.e. that trophic cascades are less likely to be observed when plant biomass, rather than plant damage, is considered as the plant-response variable).