1,579 research outputs found

    Evaluation of Rice Cultivars for Resistance to \u3ci\u3eCnaphalocrocis medinalis\u3c/i\u3e Guenée (Lepidoptera: Pyralidae)

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    Greenhouse screening of 17,914 accessions of rice, Oryza sativa L., from 62 countries identified 115 accessions from 10 countries having resistant or moderately resistant reactions to Cnaphalocrocis medinalis Guenée. Of 264 wild rices (Oryza spp.) screened, 10 (3.7%) were resistant. Several breeding lines having “Ptb33” and “W1263” as donor parents were moderately resistant. All of the resistant accessions are from regions where C. medinalis is an important pest, except for one accession from Italy, which is beyond the range of C. medinalis distribution

    Response of Lowland Rice Plants to Simulated Insect Defoliation in West Africa

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    Field experiments were conducted to investigate the impact of simulated insect-caused defoliation on irrigated rice. Defoliation levels tested were 0% (control), 25% defoliation at 21 days after transplanting (dat), 25% defoliation at 41 dat, 25% defoliation at 21 and 42 dat, 50% defoliation at 21 dat, 50% defoliation at 42 dat, 75% defoliation at 21 dat, 75% defoliation at 42 dat, 75% defoliation at 21 and 42 dat, 100% defoliation at 21 dat, and 100% defoliation at 21 and 42 dat. Tiller height, total number of tillers, percent panicle-bearing tillers, weight of 100 grains, and grain yields were recorded. The rice plant when defoliated just before tillering or in the tillering stage has the ability to compensate for defoliation damage. No yield losses occurred at 25% defoliation. Defoliation of 100% had a significant effect on the total number of tillers and on grain yield. Yield losses at 100% defoliation over the 3 years of the study averaged 40% in the 21 dat treatment and 55% in the 21 and 42 dat treatment. The implications of the development of cultural practices to manage lowland rice defoliating insects are discussed

    Rice Insects: The Role of Host Plant Resistance in Integrated Management Systems

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    Insects are among the most important abiotic and biotic constraints to rice production. National rice research programs are in various stages in the development and implementation of integrated pest management (IPM) stratagies for rice insect control. Among the various control tactics, insect resistant cultivars are sought as the major tactic in rice IPM. Through the activities of interdisciplinary teams of scientists significant progress has been made in the development and release of insect resistant cultivars to farmers. Because of its compatibility with other control tactics insect resistance has proven to fit well into the IPM approach to rice insect control agents and minimize the need for insecticide applications. The development of biotypes which overcome the resistance in rice plants has been a significant constraint in the breeding of rice for resistance to insects. Most notable examples in Asia are the green leafhopper, Nephotettix virescens, brown planthopper, Nilaparvata lugens and the Asian rice gall midge, Orseolia oryzae. The current breeding stratege is to develop rice cultivars with durable resistance on which virulent biotypes cannot adapt. In spite of the significant progress made in the breeding of insect resistant cultivars there are still numerous important rice insect species for which host plant resistance as a control tactic has not been fully utilized. Advances in biotechnology provide promise of solving some of the problems that have limited the use of host plant resistance as a major tactic in the integrated management of rice insect pests

    A New Paradigm for Implementing Ecologically – Based Participatory IPM in a Global Context: The IPM CRSP Model

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    Integrated Pest Management (IPM) is a key component in the development of sustainable agro ecosystems. The Integrated Pest Management Collaborative Research Support Program (IPM CRSP) is a USAID funded project that is a consortium of U.S. universities working with host country national programs and other stakeholders to promote IPM globally. The IPM CRSP model is based on a Participatory Integrated Pest Management (PIPM) process that has as its goals to help reduce: agricultural losses due to pests, damage to natural eco-systems including loss of biodiversity, and pollution and contamination of food and water supplies. The IPM CRSP participatory model is based on networking, institution building, private sector interaction, research-technology development and technology transfer. The new IPM CRSP beginning in 2005 will build on the experience of the previous IPM CRSP (1992-2004). The technical approach of the New IPM CRSP is to implement an ecologically-based, participatory IPM (EP-IPM) program with a carefully-conceived strategy for local, national, regional, and global diffusion of IPM capacity and knowledge. Broad participation and communication are critical components of the strategy, along with a competitive process and a management plan designed to ensure high quality research and accountability. The approach is based on a competitive process open to U.S. universities who are expected to partner with host country national programs and other stakeholders in the development of Regional IPM Centers and on five Global IPM Themes including invasive species, insect transmitted viruses, regional diagnostic laboratories, information technologies and databases, and impact assessment. O Manejo Integrado de Pragas (MIP) é um componente essencial no desenvolvimento de agroecossistemas sustentáveis. O Programa Colaborativo de Suporte a Pesquisa em Manejo Integrado de Pragas (IPM CRSP) é financiado pela USAID, que constitui um consórcio de universidades americanas colaborando com programas nacionais de países parceiros e seus apoiadores para promover o MIP globalmente. É baseado no Manejo Integrado de Pragas Participativo (PIPM), processo que visa minimizar: perdas agrícolas devido a pragas, danos a ecossistemas naturais incluindo perda da biodiversidade, poluição e contaminação dos alimentos e água. O modelo participativo IPM CRSP é baseado em trabalho em rede, criando interações entre instituições e o setor privado, desenvolvendo e transferindo pesquisa e tecnologia. O IPM CRSP que se inicia em 2005 será baseado na experiência do IPM CRSP anterior (1992-2004). Seu objetivo é implementar um manejo integrado de pragas participativo com bases ecológicas (EP-IPM) com a estratégia concebida para difundir a capacitação e conhecimento em MIP. Participação ampla e comunicação são componentes críticos da estratégia, juntamente com um processo competitivo e um plano de gerenciamento concebido para garantir pesquisa de alta qualidade e que se justifique. O programa é aberto para as universidades americanas, as quais devem procurar parceiros nos países envolvidos através dos programas nacionais e apoiadores locais no desenvolvimento de Centros Regionais em MIP envolvidos em cinco temas globais, incluindo: espécies invasoras, viroses transmitidas por insetos, laboratórios regionais de diagnósticos, tecnologia de informação e banco de dados, e avaliação de impactos

    Variable Resistance to Homopterans in Rice Cultivars

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    Rice-breeding programs in Asia have successfully provided farmers with cultivars that have genetic resistance to the major insect pests, including the leafhoppers and planthoppers. The widespread planting of resistant cultivars has resulted in the selection of hopper populations that have overcome the resistance factor(s) in the plant. Procedures to measure the degree and rate of selection for virulence on resistant cultivars have been developed, and rice-breeding strategies to increase the stability of hopper-resistant cultivars have been implemented. Resistant cultivars have been widely and successfully used in Asia and Central and South America in the management of certain rice homopterans. Rice-breeding lines with resistance to additional homopteran species are in the pipeline. To most successfully utilize the diversity of insect-resistant germplasm requires novel rice-breeding techniques and the integration of the resistant cultivars into rice insect management programs so as to provide an increased level of stability

    Resistance to the rice gall midge \u3ci\u3eOrseolia oryzae\u3c/i\u3e in rice

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    Orseolia oryzae, the rice gall midge is a major pest of rice in many areas of tropical Asia and is becoming an important pest in Africa. A chronological review of the progress made in various national programs on varietal resistance, sources of resistance and breeding for resistance is given. Many resistant varieties have been identified and have been utilized in breeding programs to develop high yielding varieties with multiple resistance to the gall midge and other insect pests and diseases. Mechanisms and inheritance of resistance in rice varieties are discussed. Rice varieties resistant in various countries and sources of resistance used in breeding programs are listed. Biotype variations in different countries and within the countries are revealed and a preliminary classification of gall midge biotypes based on varietal reactions is proposed

    Resistance to the rice gall midge \u3ci\u3eOrseolia oryzae\u3c/i\u3e in rice

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    Orseolia oryzae, the rice gall midge is a major pest of rice in many areas of tropical Asia and is becoming an important pest in Africa. A chronological review of the progress made in various national programs on varietal resistance, sources of resistance and breeding for resistance is given. Many resistant varieties have been identified and have been utilized in breeding programs to develop high yielding varieties with multiple resistance to the gall midge and other insect pests and diseases. Mechanisms and inheritance of resistance in rice varieties are discussed. Rice varieties resistant in various countries and sources of resistance used in breeding programs are listed. Biotype variations in different countries and within the countries are revealed and a preliminary classification of gall midge biotypes based on varietal reactions is proposed

    Seasonal Lipid Content of Bagworm Larvae

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    It is common knowledge to many who have attempted to control bagworms Thyridopteryx sp., that early instars are fairly easy to control, while later larval stages are less susceptible to insecticides. Studies of other insects (Bennett and Thomas 1963, Munson and Gottlieb 1953, Munson et al. 1954, Reier et al. 1953) have shown that as the lipid content increases, the susceptibility to insecticides (especially chlorinated hydrocarbons) decreases. To determine whether the lipid content of the bagworm larva increased with age a series of lipid extractions was conducted

    Integration of Host Plant Resistance and Insecticides in the Control of \u3ci\u3eNephotettix virescens\u3c/i\u3e (Homoptera: Cicadelli-dae), a Vector of Rice Tungro Virus

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    Combined effects of levels of vector resistance and insecticide application in control of rice tungro virus (RTV) were determined in three field tests. Cultivar “IR28,” with high levels of resistance to the vector, Nephotettix virescens (Distant), had low RTV infection in all treatments including the untreated check. In moderately resistant “IR36,” RTV decreased with an increase in level of insecticide but did not decrease to a level equaling the untreated “IR28.” The N. virescens-susceptible cultivar “IR22” had extremely high levels of RTV infection at all insecticide levels. Economic analysis indicated that gross profit and net gain were highest in the N. virescens-resistant “IR28,” intermediate in moderately resistant “IR36,” and lowest in susceptible “IR22.

    Parasites, Predators, and Other Arthropods Associated with \u3ci\u3eChoristoneura houstonana\u3c/i\u3e (Lepidoptera: Tortricidae) on \u3ci\u3eJuniperus\u3c/i\u3e Species in Kansas

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    One parasitic dipterous species and 27 parasitic hymenopterous species were collected. Parasites were primarily collected by mass-rearing host larvae on cut host plant foliage in the laboratory or by rearing larvae on artificial diet. The tachinid Nemorilla pyste (Walk.) and five hymenopterous species, Glypta n. sp. (Ichneumonidae), Campoplex sp. (Ichneumonidae), Agathis acrobasidis (Cushman) (Braconidae), Elasmus atratus How. (Eulophidae), and Catolaccus aeneoviridis Girault (Pteromalidae), were definite parasites, and biological notes are given. Collection data are also given for the other 22 species. One reduviid predator, Zelus socius Uhler, and six spiders were observed feeding on C. houstonana
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