Organic management of Mexican bean beetle (Epilachna varivestis Mulsant) in snap bean (Phaseolus vulgaris L.)

Fess, Tiffany L.

January 2008

Thesis (M.S.)--West Virginia University, 2008. / Title from document title page. Document formatted into pages; contains vi, 98 p. : col. ill., col. maps. Includes abstract. Includes bibliographical references (p. 81-84).

Resistance of beans (Phaseolus, Glycine max, Vigna sinensis, Vicia faba, and Dolichos lablab) to the Mexican bean beetle and the potato leafhopper /

Wolfenbarger, Dan

January 1961

No description available.

Biology

Beans

Mexican bean beetle

Leafhoppers

Population Dynamics for Key Pests in Organic Soybean Fields in Ohio and Suceptibility Differences Between Organic and Conventional Soybean

May, Colleen Elizabeth

08 September 2008

No description available.

Entomology

bean leaf beetle

soybean aphid

mexican bean beetle

organic

Studies on host plant selection by the Mexican bean beetle, Epilachna varivestis Muls /

Augustine, Mithra Gandham

January 1962

No description available.

Biology

Mexican bean beetle

Host-parasite relationships

Beans

A genetic and biochemical study of the antibiosis mechanism of host-plant resistance in soybeans to the Mexican bean beetle /

Rufener, George Keith

January 1987

No description available.

Agriculture

Mexican bean beetle--Host plants

Soybean--Disease and pest resistance

Antibiosis

Development and Evaluation of Integrated Approaches for Managing of Mexican Bean Beetle, Epilachna varivestis Mulsant

Nottingham, Louis B.

31 January 2017

The Mexican bean beetle, Epilachna varivestis Mulsant, is a major pest of snap beans, Phaseolus vulgaris L. in the Central Appalachian region of the United States. To develop pertinent research objectives, background information on this pest was gathered from literature sources and personal communications with growers, extension agents and other agricultural professionals. In objective one, Mexican bean beetle preference, developmental success and plant injury were compared among three snap bean and three lima bean cultivars in field and greenhouse trials. The cultivar 'Dragon's Tongue' was the most preferred, suitable for development, and prone to injury. Growers may benefit from growing less susceptible cultivars, or by using 'Dragon's Tongue' in trap cropping or push-pull strategies. In objective two, Mexican bean beetle densities, feeding injury, and yield were compared among snap beans grown on metallized plastic (highly reflective), white plastic, black plastic, and bare soil. Metallized plastic provided the greatest level of control, and resulted in the highest yields. Managing Mexican bean beetle by growing beans on metallized plastic may be used as a stand-alone method, or in a push-pull strategy. In the final objective, the effects of snap beans grown from thiamethoxam (a neonicotinoid insecticide)-treated seeds on Mexican bean beetle were assessed in greenhouse and field experiments. Thiamethoxam-treated plants killed 40 to 50% of Mexican bean beetle adults and larvae up to 16 days after planting. In the field, thiamethoxam-treated plants mitigated Mexican bean beetle densities and damage in one out of five experiments, resulting in a yield increase. In none of the five field experiments were differences detected in predatory arthropod species between thiamethoxam and non-insecticide treated beans. In summary, the results of this project suggest that non-chemical management methods, such as cultivar selection and planting beans on reflective mulch, can provide effective control of Mexican bean beetle. Thiamethoxam-treated seed may also provide control of this pest, but only within two to three weeks after planting; otherwise, there is typically no effect on beetles, injury or yield. This doctoral research has laid a foundation for an integrated pest management approach for Mexican bean beetle. / Ph. D. / Integrated pest management (IPM) is an economical and environmentally-sensible approach to pest management that considers numerous control and decision-making strategies. This dissertation examined non-chemical strategies and the use of an insecticide seedtreatment for management of Mexican bean beetle, a major pest of green beans in the Central Appalachian region of the United States. To develop pertinent research objectives, background information on this pest was gathered from literature sources and personal communications with growers, extension agents and other agricultural professionals. In objective one, Mexican bean beetle preference, developmental success and plant injury were compared among various bean cultivars in field and greenhouse trials. The cultivar ‘Dragon’s Tongue’ was the most suitable host for Mexican bean beetle, and consequently incurred the greatest injury. Growers in high risk areas for Mexican bean beetle may benefit from growing less susceptible cultivars. In objective two, Mexican bean beetle severity and yield were compared among green beans grown on reflective metallized plastic, white plastic, black plastic, and bare soil. Metallized plastic provided the greatest level of control, and resulted in the largest yields. Our results suggest that growing beans on reflective surfaces may be an effective, chemical-free management strategy for Mexican bean beetle. In the final objective, the effects of green beans grown from thiamethoxam (a neonicotinoid insecticide)-coated seeds was examined on Mexican bean beetle severity, non-pest arthropods, and crop performance in greenhouse and field experiments. Bean plants grown from insecticide-coated seeds were highly-toxic to Mexican bean beetle for about 16 days after planting. In one out of five experiments, thiamethoxam-treated plants reduced pest levels, resulting in increased yields. More often, Mexican bean beetles arrived after the insecticide had disappeared from plants and there was no effect. There were no detectable effects from the thiamethoxam treatment on non-pest arthropods in any experiment. Overall, seed-treatments may provide occasional control of Mexican bean beetle, but non-chemical methods may be as effective and more practical. This doctoral research project has provided a foundation for an integrated pest management approach for Mexican bean beetle.

Integrated pest management (IPM)

Mexican bean beetle

Epilachna varivestis

Phaseolus

snap bean

lima bean

agroecosystem

cultivars

susceptible

cultural management

seed-treatment

thiamethoxam

natural enemies

Podisus maculiventris