Efficacy of stored grain insecticides against 2 pest beetles in rough rice.

Insecticidal grain protectants can provide control of pest insects during grain storage, but studies which directly compare the efficacy of insecticides in rough rice are few. We examined methoprene, deltamethrin, commercial formulations of methoprene + deltamethrin, ß-cyfluthrin, and diatomaceous earth applied to rough rice over a 6-month period for control of lesser grain borers, Rhyzopertha dominica (F.) (Coleoptera: Bostrichidae), and rice weevils, Sitophilus oryzae (L.) (Coleoptera: Curculionidae). We found that methoprene, deltamethrin, or a combination of the 2 were the most effective controls of both beetles in 22.7-liter metal containers. Damage mass and beetle mass in methoprene-treated rice were reduced by 38% and 55%, respectively, when compared to the nontreated control. Similarly, the mixture of deltamethrin and methoprene reduced damage mass by 32% and total beetle mass by 45% below that of the nontreated control. Deltamethrin reduced total beetle mass by 38% relative to the nontreated rice. In vial assays, only the combination of deltamethrin and methoprene provided control of R. dominica. Diatomaceous earth had the greatest impact upon S. oryzae, but it did not affect R. dominica. Based on these results, a commercial formulation of deltamethrin and methoprene is likely to provide the best overall control of stored grain beetles, though diatomaceous earth may be effective when use of chemical insecticides is undesirable or when S. oryzae is the sole pest present.

Entomology beyond research and education: 2022 student debates.

The 2022 student debates of the Entomological Society of America (ESA) happened during the Joint Annual Meeting of the Entomological Societies of America, Canada, and British Columbia in Vancouver, BC, and addressed entomological aspects beyond research and education. The Student Debates Subcommittee of the ESA Student Affairs Committee and the participating student team members communicated for 8 months and prepared for the debates. The theme of the ESA meeting in 2022 was "Entomology as inspiration: Insects through art, science, and culture". There were 2 unbiased speakers who introduced the debate topics as well as 4 teams who debated the following 2 topics: (i) Is forensic entomology viable in criminal case investigations and court cases today? and (ii) Are insects being treated ethically in scientific research? The teams prepared for about 8 months, debated their arguments, and shared their thoughts with the audience. The teams were judged by a panel and the winners were recognized at the ESA Student Awards Session during the annual meeting.

In Planta Localization of Endophytic Cordyceps fumosorosea in Carrizo Citrus.

Entomopathogenic fungi can be a useful resource for controlling insect vectors of citrus plant pathogens, such as the Asian citrus psyllid (Diaphorina citri) associated with huanglongbing or the citrus root weevil (Diaprepes abbreviatus) associated with the spread of Phytophtora spp. In this study, Cordyceps fumosorosea (Cfr) was investigated in planta as a potential endophytic entomopathogenic fungus and various inoculation techniques were used to determine if it would colonize the Carrizo citrange (Citrus × insitorum) seeds and plants. The four inoculation methodologies evaluated were seed soaking, stem injection, foliar spray, and soil drench. Seed immersion trials demonstrated that the roots of the Carrizo citrange plant can be inoculated successfully with Cfr. Stem injection, foliar spray, and soil drench also provided successful inoculation of Cfr. However, this fungus was only endophytic in the plant stem. Sand cores indicated that Cfr moved down through the sand column and was able to inoculate the roots. Given the prevalence of Cfr in the soil during the drench experiment, and that the fungus was able to colonize Carrizo citrange roots through seed immersion, this finding provides evidence of the potential endophytism of this fungus when applied to citrus plant species.

Turfgrass Cultivar Diversity Provides Associational Resistance in the Absence of Pest Resistant Cultivars.

Turfgrasses are ubiquitous in urban landscapes and can provide numerous ecosystem services. However, most warm season turfgrasses are produced, planted, and maintained as cultivar monocultures, which may predispose them to herbivore attack and reduce the services lawns provide. Though rarely done, host plant resistance can be used as a strategy to reduce herbivory and preserve beneficial services. Increasing turfgrass cultivar diversity may provide similar or greater benefits through associational resistance, whereas conserving desirable maintenance and aesthetic traits. However, no studies have examined this in warm season turfgrasses. To address this, we evaluated host plant resistance to fall armyworm (Spodoptera frugiperda [J.E. Smith] [Lepidoptera: Noctuidae]) in commercially available cultivars of St. Augustinegrass (Stenotaphrum secundatum [(Walt.) Kuntz] [Lepidoptera: Noctuidae]) and then investigated if the resistance or susceptibility of St. secundatum cultivars carried over in mixed cultivar plantings. Through a no-choice experiment and a limited-choice experiment, we detected no host plant resistance in monocultures of St. secundatum cultivars. However, we did find that as cultivar diversity increased, female Sp. frugiperda larval weight and herbivory decreased. Additionally, choice tests indicated that larvae prefer less diverse stands of St. secundatum cultivars. Interestingly, our results suggest that in the absence of host plant resistance, warm season turfgrass cultivar diversity may reduce herbivore pest fitness and damage. These results demonstrate that warm season turfgrass cultivar diversity may be a viable integrated pest management tool that warrants further investigation.