From the Cover: Field-evolved resistance by western corn rootworm to multiple Bacillus thuringiensis toxins in transgenic maize

The widespread planting of crops genetically engineered to produce insecticidal toxins derived from the bacterium Bacillus thuringiensis (Bt) places intense selective pressure on pest populations to evolve resistance. Western corn rootworm is a key pest of maize, and in continuous maize fields it is often managed through planting of Bt maize. During 2009 and 2010, fields were identified in Iowa in which western corn rootworm imposed severe injury to maize producing Bt toxin Cry3Bb1. Subsequent bioassays revealed Cry3Bb1 resistance in these populations. Here, we report that, during 2011, injury to Bt maize in the field expanded to include mCry3A maize in addition to Cry3Bb1 maize and that laboratory analysis of western corn rootworm from these fields found resistance to Cry3Bb1 and mCry3A and cross-resistance between these toxins. Resistance to Bt maize has persisted in Iowa, with both the number of Bt fields identified with severe root injury and the ability western corn rootworm populations to survive on Cry3Bb1 maize increasing between 2009 and 2011. Additionally, Bt maize targeting western corn rootworm does not produce a high dose of Bt toxin, and the magnitude of resistance associated with feeding injury was less than that seen in a high-dose Bt crop. These first cases of resistance by western corn rootworm highlight the vulnerability of Bt maize to further evolution of resistance from this pest and, more broadly, point to the potential of insects to develop resistance rapidly when Bt crops do not achieve a high dose of Bt toxin.The global area devoted to transgenic crops producing insecticidal toxins derived from the bacterium Bacillus thuringiensis (Bt) has increased rapidly over the past 15 y, with Bt crops covering more than 69 million hectares in 2012 (1). Most of this area was planted in Bt cotton and Bt maize (1). Benefits of Bt crops include effective management of target pests, decreased use of conventional insecticides, and reduced harm to nontarget organisms (2–5). However, the evolution of resistance could diminish these benefits. The western corn rootworm, Diabrotica virgifera virgifera LeConte (Coleoptera: Chrysomelidae), is a major pest of maize, with larval feeding on maize roots and associated management costs causing economic losses in excess of $1 billion per year (6). Through 2013, three Bt toxins have been used in transgenic maize for management of western corn rootworm: Cry3Bb1, mCry3A, and Cry34/35Ab1 (7).In the United States and elsewhere, commercial registration of a Bt crop is accompanied by a resistance-management plan to delay the onset of pest resistance. Resistance management for Bt crops has focused on the refuge strategy, in which refuges of non-Bt crops allow the survival of Bt-susceptible insects, which may mate with resistant insects that survive on the Bt crop (8). To the extent that the heterozygous progeny from these matings have lower fitness on a Bt crop than their Bt-resistant parent, delays in resistance may be achieved, and these delays in resistance increase with the quantity of refuge (9). Additionally, refuges are far more effective in delaying resistance when Bt crops achieve a high dose of toxin against a target pest. High-dose Bt crops kill more than 99.99% of susceptible insects and render resistance a functionally recessive trait (9, 10). None of the currently commercialized Bt maize targeting the western corn rootworm is high dose, so the risk of resistance is increased (11, 12).In 2003, Cry3Bb1 maize was registered by the United States Environmental Protection Agency (US EPA) for management of western corn rootworm larvae (7). In 2009, farmers in Iowa observed severe injury to Cry3Bb1 maize by larval western corn rootworm in the field, and subsequent laboratory assays revealed that this injury was associated with Cry3Bb1 resistance (13). More fields with Cry3Bb1 resistance were identified in 2010 (14), and research in fields identified in 2009 as harboring Cry3Bb1-resistant western corn rootworm found no difference in survival for this pest between non-Bt maize and Cry3Bb1 maize (11). Current threats to Bt maize include the spread of Bt-resistant western corn rootworm and the loss of additional Bt toxins through the presence of cross-resistance. In this paper we report that injury to Cry3Bb1 maize in the field has persisted through 2011 and expanded to include mCry3A maize. Analysis of western corn rootworm collected in 2011 revealed that (i) severe injury to Cry3Bb1 maize and mCry3A maize in the field was associated with resistance, and (ii) cross-resistance between Cry3Bb1 and mCry3A was present. These results demonstrate that insects can evolve resistance rapidly to Bt crops that are not high dose and raise concerns about the adequacy of current resistance-management strategies.