Posted on Mar 8, 2018 by Nick Seiter

Managing Corn Rootworm Populations in Illinois: Considerations for 2018


Authors: Nick Seiter, Joe Spencer, and Kelly Estes

Rootworm management is a yearly consideration for most corn producers in central and northern Illinois. Western corn rootworm (Fig. 1) is the primary pest species throughout most of the state, but areas in northern IL can experience pest pressure from the northern corn rootworm (Fig. 2) as well. Adult population densities have been low in recent years compared with historical averages, although they did creep up a bit in 2017. The overall reduction in corn rootworm pressure is likely due to a combination of unfavorable weather (or at least unfavorable to rootworm larvae) and widespread adoption of corn hybrids expressing combinations of Bt toxins for rootworm control.

Fig. 1. Western corn rootworm adult. Photo: J. Spencer

Over the last few years, western corn rootworm populations with resistance to Cry3Bb1 and mCry3A (two commonly expressed toxins in Bt corn hybrids) have been documented in Illinois. Research published in 2016 on Iowa1 and Minnesota2 western corn rootworm populations showed that resistance to these toxins also confers resistance to the structurally-similar eCry3.1Ab toxin.  Cross-resistance among these “Cry3” Bt toxins should be expected for Illinois western corn rootworm populations.  Resistance to pest control practices in the western corn rootworm is nothing new; this insect is notorious for developing resistance to control tactics such as insecticides and crop rotation. Part of the concern with these recent developments is that there are relatively few Bt toxins available to combat corn rootworm. Furthermore, all available hybrids with pyramided traits for corn rootworm use either Cry3Bb1 or mCry3A in combination with a second toxin (either Cry34/35Ab1 or eCry3.1Ab). This means that, where resistance is present in the population, there might in fact be at best only one effective toxin at work. (If you have trouble keeping all of these toxins straight, a good resource is the “Handy Bt Trait Table” produced by Dr. Chris DiFonzo at Michigan State University:

Fig. 2. Northern corn rootworm adult. Photo: J. Spencer.

There are steps producers can take to manage corn rootworm and hopefully slow the further development of resistance. The best way to delay resistance to any control tactic is to reduce exposure of the target insect to that tactic in the environment. Specific ways to accomplish this with Bt toxins include:

Finally, an important step is to monitor the performance of your control methods. While lodging is often the cue we look out for to identify rootworm damage, keep in mind that (1) corn can take a lot of damage without lodging depending on soil type and weather conditions and (2) plenty of factors other than rootworm damage can lead plants to lodge. The best approach to evaluating rootworm damage is to dig a representative sample of roots in late July and evaluate them for feeding damage: unpleasant work, but necessary if we want to understand the true extent of the damage.  Consider planting a small area or a portion of a row with a non-Bt/untreated hybrid as a check strip. Having an untreated patch in your field will allow you to compare the efficacy of your management tactic vs. the background level of damage where no rootworm protection was used. Finally, if you experience greater damage than expected in Bt corn hybrids in 2018, please let us know at the email address below; your reports will help us to document the status of resistance in Illinois and provide updated information to producers.


Nick Seiter: Research Assistant Professor, Field Crop Entomologist,University of Illinois Department of Crop Sciences

Joe Spencer: Principal Research Scientist and Research Program Leader in Insect Behavior, University of Illinois, Illinois Natural History Survey
1Jakka, S.R.K., et al. Scientific Reports 6: 27860. DOI: 10.1038/srep27860

2Zukoff, S. N. et al. 2016. Journal of Economic Entomology 109: 1387-1398. DOI: 10.1093/jee/tow073

3Dunbar, M. W. and Gassmann, A. J. 2013. Journal of Economic Entomology 106: 168-180. DOI: 10.1603/EC11291

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