Abstract
Plant chemical defences impact not only herbivores, but also organisms in higher trophic levels that prey on or parasitize herbivores. While herbivorous insects can often detoxify plant chemicals ingested from suitable host plants, how such detoxification affects endoparasitoids that use these herbivores as hosts is largely unknown. Here, we used transformed plants to experimentally manipulate the major detoxification reaction used by Plutella xylostella (diamondback moth) to deactivate the glucosinolate defences of its Brassicaceae host plants. We then assessed the developmental, metabolic, immune, and reproductive consequences of this genetic manipulation on the herbivore as well as its hymenopteran endoparasitoid Diadegma semiclausum. Inhibition of P.xylostella glucosinolate metabolism by plant-mediated RNA interference increased the accumulation of the principal glucosinolate activation products, the toxic isothiocyanates, in the herbivore, with negative effects on its growth. Although the endoparasitoid manipulated the excretion of toxins by its insect host to its own advantage, the inhibition of herbivore glucosinolate detoxification slowed endoparasitoid development, impaired its reproduction, and suppressed the expression of genes of a parasitoid-symbiotic polydnavirus that aids parasitism. Therefore, the detoxification of plant glucosinolates by an herbivore lowers its toxicity as a host and benefits the parasitoid D.semiclausum at multiple levels.
Highlights
Multitrophic interactions involving plants, insect herbivores, and their antagonists are ubiquitous in terrestrial ecosystems and underpin our understanding of the structure and function of ecological communities (Stam et al, 2014)
In apparent support of this hypothesis, the fitness of the predatory wasp Copidosoma sosares was shown to be negatively influenced by the presence of toxic furanocoumarins in the haemolymph of its host, the specialized herbivore parsnip webworm Depressaria pastinacella (Lampert, Zangerl, Berenbaum, & Ode, 2008; McGovern, Zangerl, Ode, & Berenbaum, 2006; Ode, Berenbaum, Zangerl, & Hardy, 2004), while the nicotine content in the diet of the herbivore Manduca sexta affected the endoparasitoid Cotesia congregata, and its hyperparasitoid Lysibia nana (Barbosa, Gross, & Kemper, 1991; Harvey, Van Dam, Witjes, Soler, & Gols, 2007; Thorpe & Barbosa, 1986)
Through the combination of these treatments, we investigated the effects of glucosinolate ingestion and its detoxification by the specialist herbivore both on the herbivore and on the parasitoid D. semiclausum
Summary
Larvae of Plutella xylostella (the diamondback moth, Lepidoptera: Plutellidae), a specialized herbivore that is a devastating pest of brassicaceous crops (Furlong, Wright, & Dosdall, 2013; Zalucki et al, 2012), can feed without ill effects on glucosinolate-containing plants due to the activity of glucosinolate sulphatases (GSS) These enzymes are abundant in the digestive system of this insect, and desulphate glucosinolates preventing myrosinase-catalysed hydrolysis and ITC formation (Ratzka, Vogel, Kliebenstein, Mitchell-Olds, & Kroymann, 2002). The solitar y endoparasitoid Diadegma semiclausum (Hymenoptera: Ichneumonidae) is an important natural enemy of P. xylostella, and is frequently used in biocontrol programmes against this pest (Furlong et al, 2013; Li, Eigenbrode, Stringam, & Thiagarajah, 2000) Young larvae of this parasitoid develop by feeding on the haemolymph of the caterpillar host until the parasitoid larva reaches its final instar. We examined the effects of blocking glucosinolate desulphation on the immune responses of the herbivore against parasitism
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