Event DAS‐59122‐7 is a novel transgenic trait designed to protect the roots and yield potential of maize from the insect pest corn rootworm Diabrotica spp. (Col.: Chrysomelidae). The increased pest status of corn rootworm, exceptional efficacy of this trait, and anticipated increases in farm efficiency and grower and environmental safety will drive adoption of this trait. Strong grower acceptance of this trait highlights the importance of science‐based and practical resistance management strategies. A non‐diapause trait was introgressed into two laboratory colonies of Diabrotica virgifera virgifera collected from geographically distinct locations: Rochelle, IL and York, NE. Both colonies were divided and each reared on maize containing event DAS‐59122‐7 or its near isoline. Selected and unselected colonies were evaluated for phenotypic change in larval development, injury potential and survival to adulthood during 10 and 11 generations. The F1 generation of both selected colonies displayed increased larval development, survivorship and measurable, but economically insignificant increases in injury potential on DAS‐59122‐7 maize. Survival rates of 0.4 and 1.3% in F1 generations of both selected colonies corroborate field estimates of survival on DAS‐59122‐7 maize. Over later generations, total phenotypic variation declined gradually and irregularly. Despite the absence of random mating, the tolerance trait could not be fixed in either population after 10 or 11 generations of selection. An allele conferring major resistance to DAS‐59122‐7 was not identified in either selected colony. The assessment also concluded that major resistance gene(s) are rare in populations of D. v. virgifera in the United States, and that a minor trait(s) conferring a low level of survival on DAS‐59122‐7 maize was present. The tolerance trait identified in this study was considered minor with respect to its impact on DAS‐59122‐7 maize efficacy, and the role this trait may play in total effective refuge for major resistance genes with recessive inheritance is the basis of future work.
Susceptibility of Diabrotica virgifera virgifera (LeConte) larvae to DAS‐59122‐7 maize was evaluated using a laboratory technique that measures rootworm survival to adulthood on maize seedlings. This method produces direct measures of larval susceptibility using realistic exposure to the same range of insecticidal protein concentrations found in field‐grown DAS‐59122‐7 maize roots. First, second and third instars were reared to adulthood on DAS‐59122‐7 maize seedlings or a non‐transgenic, near‐isoline maize. Data on survival, adult gender ratio, adult weight and median emergence were collected. Overall, larval susceptibility to DAS‐59122‐7 maize was lower than earlier predictions (Storer et al. 2006). Neonate survival on DAS‐59122‐7 maize was approximately 33% of isoline survival after 17 days, and the same 33% recovered and developed to adulthood when the isoline maize was substituted. Survival rate on DAS‐59122‐7 maize increased with instar. The mean survivorship was 0.5%, 26% and 65% when exposure to DAS‐59122‐7 maize began at the first, second and third instars, respectively. Exposure to DAS‐59122‐7 maize led to sub‐lethal effects on adult gender ratio, weight and median emergence. These effects decreased when exposure to DAS‐59122‐7 maize began at later instars. The killing effect of DAS‐59122‐7 maize on rootworm larvae appeared to result from the combined chronic effects and absence of a suitable host as perceived by the larvae. The relevance of these data and the methodology of estimating rootworm susceptibility to plant‐incorporated protectants are discussed in the context of the US Environmental Protection Agency’s functional definition of ‘high dose’ and use of refuge for resistance management (EPA 1998a). Based on these results it is evident that DAS‐59122‐7 maize does not meet the functional definitions of high dose as described by EPA (1998a,b) and ILSI (1999), and the utility of refuge, refuge size and refuge placement for delaying rootworm resistance should be further investigated.
Rootworm control tactics have recently expanded to include transgenic maize, which express insecticidal proteins from Bacillus thuringiensis (Bt) to reduce larval injury and protect yield potential. Exceptional root protection, increased grower efficiency and improved safety have led to rapid adoption of this technology in the USA. As a result, there is a recognized need for resistance management programmes aimed at delaying rootworm resistance. An essential component of resistance management programmes is the development and implementation of effective resistance monitoring techniques. Five test populations of Diabrotica virgifera virgifera (LeConte) were used to evaluate the sensitivity of two techniques used to describe population susceptibility to the Bt proteins expressed in event DAS‐59122‐7 maize: a diet bioassay employing purified proteins applied to artificial diet and a novel technique using sub‐lethal measures of larval development on seedling maize. Test populations included Rochelle‐US, an unselected susceptible colony, three populations composed of 5%, 25% or 50% Rochelle‐S mixed with Rochelle‐US, and the Rochelle‐S selected colony. Rochelle‐S was derived from the same founding population as Rochelle‐US, but selected for survival on DAS‐59122‐7 maize. Selections identified a minor trait conferring increased tolerance, and greenhouse plant efficacy evaluations confirmed that after 10 generations of selection with no random mating, Rochelle‐S caused significantly more root injury to DAS‐59122‐7 than Rochelle‐US. Rochelle‐S present at 5% of the test population resulted in measurable but not significant increase in injury to DAS‐59122‐7 maize. The diet bioassay was relatively insensitive to the susceptibility differences between the Rochelle‐US and Rochelle‐S populations. Neither LC50 nor EC50 estimates produced statistically significant differentiation between test populations with 0%, 5%, 25% or 50% Rochelle‐S. The sub‐lethal assay clearly identified differences between Rochelle‐S and Rochelle‐US and an increased rate of larval development was measurable when the test population contained only 5% of Rochelle‐S.
Bacillus thuringiensis (Bt) maize was developed primarily for North American pests such as European corn borer (Ostrinia nubilalis (Hübner)). However, most Bt maize products are also cultivated outside of North America, where the primary pests may be different and may have lower susceptibility to Bt toxins. Fall armyworm (Spodoptera frugiperda JE Smith) is an important pest and primary target of Bt maize in Central and South America. S. frugiperda susceptibility to Cry1F (expressed in event TC1507) is an example of a pestby-toxin interaction that does not meet the high-dose definition. In this study, the behavioral and toxic response of S. frugiperda to Cry1F maize was investigated by measuring the percentage of time naïve third instars spent feeding during a 3-min exposure. S. frugiperdaalso were exposed as third instars to Cry1F maize for 14 d to measure weight gain and survival. S. frugiperda demonstrated an initial, postingestive aversive response to Cry1F maize, and few larvae survived the 14 d exposure. The role of susceptibility and avoidance are discussed in the context of global IRM refuge strategy development for Bt products. TC1507) is an example of a pest-by-toxin interaction that does not meet the high-dose deÞnition. In this study, the behavioral and toxic response of S. frugiperda to Cry1F maize was investigated by measuring the percentage of time naṏve third instars spent feeding during a 3-min exposure. S. frugiperda also were exposed as third instars to Cry1F maize for 14 d to measure weight gain and survival. S. frugiperda demonstrated an initial, postingestive aversive response to Cry1F maize, and few larvae survived the 14 d exposure. The role of susceptibility and avoidance are discussed in the context of global IRM refuge strategy development for Bt products.
Monitoring Susceptibility of Western Bean Cutworm (Lepidoptera: Noctuidae) Field Populations toBacillus thuringiensisCry1F Protein
Zea mays L. (maize) hybrids producing the Cry1F protein from Bacillus thuringiensis were first commercialized in the United States in 2003. These products demonstrated varying levels of moderate control, but not immunity to Striacosta albicosta (Smith) (Lepidoptera: Noctuidae) (western bean cutworm). Susceptibility of western bean cutworm to Cry1F protein was assessed in field populations collected in the mid- and western United States in 2003, 2004, 2013, and 2014 using diet bioassay. A meta-analysis of 32 western bean cutworm field collections assessed for susceptibility to Cry1F was conducted to investigate changes in susceptibility over time. Based on meta-analysis results, these data suggest a 5.2-fold increase in median lethal concentration (LC50) response to Cry1F in the 2013–2014 populations compared with collections that were assessed 10 yr earlier. Widespread use of Cry1F-producing maize hybrids over the past 10 yr may have contributed to favoring western bean cutworm populations with tolerance to the Cry1F protein.
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