2014 Awardees

Project Title  
Early versus late-emerging Bt-resistant western corn rootworms in the rotation-resistant zone: seeking an optimum management strategy.  

Primary Investigator (PI)  
Joseph L. Spencer, University of Illinois

Project Summary

Documentation of western corn rootworm (WCR) resistance to Cry3Bb1 corn in 2011 revealed a threat to the primary tool used to protect U.S. corn from its most costly pest. In August 2013, we were alerted to severe corn rootworm injury and lodging in producers’ rotated cornfields in central and northeastern Illinois. Subsequent visits to these first-year cornfields confirmed excessive WCR injury on the roots of Cry3Bb1-expressing corn hybrids leading to the testable hypothesis that some WCR populations are resistant to both crop rotation and the Cry3Bb1 protein expressed in certain Bt corn rootworm hybrids. The presence of suspected Bt resistance among rotation-resistant WCR links two very significant pest management challenges and threatens management strategies used across an important portion of the Corn Belt.

We will work directly on-farm with producers to evaluate several management approaches including early vs. late broadcast applications of insecticides to soybean fields in combination with soil insecticides and Bt rootworm hybrids in rotated corn. WCR adults will be collected from rotated corn and adjacent soybean fields and Bt resistance bioassays performed on the offspring to test our hypothesis and document possible variation in resistance among early and late-emerging WCR adults. This research will answer fundamental questions about resistance and evaluate practical management options of interest to corn growers. Testing management approaches and measuring resistance will improve understanding of CRW management tactics and support the development and deployment of more effectively-targeted management strategies.


Project Title
Characterizing Resistance Evolution to Pyrethroid Insecticides

Primary Investigator (PI)
Blair Siegfried University of Nebraska-Lincoln

Project Summary

The western corn rootworm (Diabrotica virgifera virgifera LeConte) has continuously challenged our ability to develop sustainable pest management solutions. Resistance to chemical pesticides, crop rotation, and most recently transgenic plants that express toxins derived from Bacillus thuringiensis have been well documented among rootworm populations. Resistance to Bt corn hybrids has resulted in a substantial return to the use of both soil insecticides at planting and/or foliar application of adulticides later in the growing season and have increasingly relied on pyrethroid insecticides. The use of pyrethroids for adult and larval control has become an important component of best management practices designed to protect plants from rootworm injury in areas where control failures with Bt plants have been observed. Given the rootworm’s propensity to evolve resistance, sampling and bioassays of rootworm populations from across the Corn Belt were initiated in 2013 and have shown that some populations exhibit reduced susceptibility to the pyrethroid insecticide, bifenthrin. We believe that these preliminary data are indicative of a response to selection from repeated exposure to pyrethroid insecticides and reflect a possible decline in efficacy of both adult management programs and potentially some soil insecticides. As a consequence, we are proposing a set of studies to confirm resistance and document heritability, to determine the impact of such resistance on larval susceptibility, and to identify the mechanisms of resistance and associated molecular markers that can be used to characterize allele frequencies among field populations. This information is critical to developing effective resistance management and mitigation strategies.


Project Title  
The genetics of emerging resistance to Cry3Bb1 corn

Primary Investigator (PI)  
Nicholas Miller, University of Nebraska, Lincoln

Project Summary

Our research concerns a significant threat to biotechnology-based management of corn rootworms: the emergence of western corn rootworm (WCR) populations that are resistant to Cry3Bb1-expressing corn. We will characterize the genetic basis of resistance by addressing several important, unanswered questions: 1) Is the same genetic mechanism present among populations that have evolved resistance in different locations? 2) How many genes are involved in resistance?

We will use innovative population genetic methods and QTL mapping, two distinct approaches with complementary strengths to achieve our research objectives:

  1. Identify the genes that have responded to selection by Cry3Bb1, leading to resistance in the field.
  2. Map QTL for field-evolved resistance to Cry3Bb1.
  3. Identify selection-responsive genetic markers located within QTL that could be used to survey or monitor for resistance alleles.

The results of our research will have a significant impact on the future of corn rootworm resistance management. The knowledge we generate will inform the development of more effective resistance management and mitigation strategies to preserve the efficacy of Cry3Bb1 corn. The genetic markers for resistance will provide tools to survey or monitor for resistance alleles.


Project Title  
Teaching Corn Rootworm Resistance Management Strategies Through Interactive Mobile and Web-based Educational Modules

Primary Investigator (PI)  
Douglas Golick, University of Nebraska, Lincoln

Project Summary

We seek to develop a series of mobile and web-based interactive learning experiences for producers, consultants, extension educators, and post-secondary students teaching fundamental concepts related to resistance management strategies of the corn rootworm. These modules will teach science-based concepts related to current knowledge on corn rootworm biology, behavior, IPM strategies, resistance management strategies, toxicology, and population genetics through modern mobile, Web 2.0, and adaptive learning approaches.

Project Goals

  • Create research-based educational modules teaching corn rootworm resistance management strategies for use by growers, consultants, and university students
  • Employ both modern technology-enhanced (website, Mini-Online Open Courses, mobile smartphone application) and traditional instructional techniques (quick sheets, whitepapers, seminars) to reach a wide-audience
  • Create educational tools for professionals that work with growers to aid in decision making related to corn rootworm IPM and resistance management strategies
  • Evaluate short and long-term impacts of the educational materials on growers’ farm practices
  • Behavioral outcomes for growers
  • Learn basic principles of resistance management and IPM in the corn rootworm system
  • The ability to assess corn rootworm damage to determine immediate and future farming practices
  • Application of science-based resistance management practices on their farms
  • Behavioral outcomes for consultants, extension educators, seed salespersons, and industry agronomists
  • Use project’s educational tools to educate growers on resistance management issues
  • Use educational tools in the field for making management decisions


Project Title  
Estimating Dispersal And Modeling Its Impact On Resistance Remediation In Western Corn Rootworm

Primary Investigator (PI)  
Michael A. Caprio, Mississippi State University

Project Summary

Western corn rootworm (WCR) is the most serious pest of corn throughout the Corn Belt. Multiple Bt toxins have been commercialized in corn hybrids that have been effective at managing WCR populations. Recently, there have been reports of field populations with confirmed or suspected resistance to two of those toxins (Cry3Bb1 and mCry3A). Declining efficacy among Bt corn hybrids is problematic for growers, industry, scientists and regulators. There are few modeling resources for remediation of WCR Bt-resistance and virtually no theoretical framework to guide decision-making. We have identified knowledge gaps in WCR biology, particularly related to adult dispersal, critical to providing reliable models to address resistance, remediation and the optimal use of compromised traits. We will use molecular methods, field studies and two different models to address these issues relevant to program area: Characterization of the biochemical, genetic, and molecular aspects of insect resistance. DNA markers will be used to estimate typical per-generation dispersal from the natal field in Obj. 1. We will observe and measure how patterns of adult cornfield abundance and intrafield movement translate into subsequent patterns of injury and emergence and also document patterns and measure characteristics and proportions of dispersing WCR engaged in interfield movement in Obj. 2. These Obj. 1-2 data will be synthesized under Obj. 3, culminating in the modeling completed under Obj. 3-4 that will provide science-based guidance for the mitigation of developing resistance and optimal strategic deployment of compromised traits to maximize the benefit of WCR control technology to society.

 


Project Title  
Profitability of Alternative Management Strategies for Western Corn Rootworm

Primary Investigator (PI)  
Paul Mitchell, University of Wisconsin - Madison

Project Summary

The long‐term outcome this project seeks is increased farmer adoption of economically viable rootworm management strategies, including resistance management. The project’s long‐term goal is to develop interactive map‐based apps that integrate spatial databases to estimate the field‐specific profitability of rootworm management practices to help farmers improve rootworm management. We will assemble and analyze existing rootworm data to estimate infestation intensities, efficacy of alternative control methods, and yield loss functions. Second, we will combine estimated functions with yield, price and cost information to create partial budgets of net returns for different rootworm management strategies. Third, we will conduct on‐farm research trials to gather economic data under real world conditions and to receive farmer feedback on project activities and results. Finally, we will integrate these partial budgets with large, long‐term spatial databases to create a map‐based smartphone app that reports net returns for different rootworm management practices and allows farmers to enter their own data to generate field‐specific net return estimates.


Project Title  
Rootworm Refuge Function: An Empirical Field Test

Primary Investigator (PI)  
Christian Krupke, Purdue University

Project Summary

Recent reports of high rootworm damage and emergence from Bt corn hybrids have underscored the importance of effective refuges in IRM plans. Current plans were designed to facilitate random mating between susceptible and putatively resistant individuals, but there is no empirical evidence that refuges actually succeed in accomplishing this purpose. Given the intense selection pressure imposed by Bt corn, it is reasonable to re-assess whether WCR mating patterns in the field match our initial expectations. In fact, there is a growing body of evidence that rootworm mating in Bt/refuge corn fields is not random – undermining a key assumption of the current resistance management model. The overall goal of this research is to further our understanding of WCR mating behavior in Bt/refuge environments. The objectives of this proposal are to determine the influence of larval diet (Bt vs. refuge corn) on the mate choice and mating success in adult beetles, and determine the extent to which non-random mating occurs in the field. We will also collect morphometric and weight data from beetles to determine if these factors explain some of the mating patterns observed (for example, size-based assortative mating as a mechanism). Our work will generate data that can be incorporated into existing and future models of gene flow among WCR populations to enhance durability of current refuges and those for future in-plant toxins targeting WCR.