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Intercropping and diverse field margin vegetation suppress bean aphid (Homoptera: Aphididae) infestation in dolichos ( Lablab purpureus L.)

Christine N. Mwani Jane Nyaanga Erick K. Cheruiyot Joshua O. Ogendo Philip K. Bett Richard Mulwa Philip C. Stevenson Sarah E.J. Arnold Steven R. Belmain
Journal of Plant Protection Research | 2021 | vol. 61 | No 3 | 290-301 | DOI: 10.24425/jppr.2021.137953
Keywords aphids dolichos field margin vegetation natural enemies
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Abstract

Dolichos ( Lablab purpureus L.) is a drought tolerant legume used as food/feed and improvement of soil fertility. The production of dolichos in Kenya, Nakuru County is however limited by insect pests like bean aphids, pod borers and whiteflies. Field studies were conducted to determine the effect of cropping systems (dolichos monocrop and maize-dolichos intercrop) and field margin vegetation on bean aphids and their natural enemies. The experiment was conducted in Njoro (high field margin vegetation) and Rongai (low field margin vegetation) during May- December 2019 and MarchNovember 2020 cropping seasons. Bean aphid percent incidence, severity of damage and abundance was assessed at seedling, early vegetative, late vegetative and flowering dolichos growth stages. The populations of natural enemies in the plots and field margin vegetation were monitored using pan traps and sweep nets. Species diversity and composition of the field margin vegetation was determined using a quadrat. Results showed that location and cropping system had significant effects on bean aphid infestations. A high bean aphid incidence (38.13%) was observed in Njoro compared to Rongai (31.10%). Dolichos monocrop had significantly higher bean aphid infestation (51.63%) than the maize-dolichos intercrop system (24.62%). A highly diverse Shannon-weaver index was observed in Rongai (1.90) compared to Njoro (1.67). Dolichos monocrop had a more diverse Shannon-weaver index (1.8) than the maize-dolichos intercrop system (1.7). Rongai had the most abundant annual and perennial field margin vegetation species. The field margin species richness and diversity were higher in Rongai (81%) than in Njoro (54%). The findings of this study have demonstrated that a maize-dolichos intercrop in Rongai can reduce bean aphid damage in dolichos.
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Authors and Affiliations

Christine N. Mwani
1
ORCID: ORCID
Jane Nyaanga
1
Erick K. Cheruiyot
1
Joshua O. Ogendo
1
Philip K. Bett
2
Richard Mulwa
1
Philip C. Stevenson
3
Sarah E.J. Arnold
3 4
Steven R. Belmain
3
  1. Crops, Horticulture and Soils, Egerton University, Kenya
  2. Biological Sciences, Egerton University, Kenya
  3. Jodrell Laboratory, Royal Botanic Gardens Kew, Richmond, UK
  4. Nelson Mandela African Institute of Science and Technology, Arusha, Tanzania

Seasonal incidence of natural enemies of key insect pests of cotton and their relationship with weather parameters

Shish Ram Dhaka Bhanwar Lal Pareek
Journal of Plant Protection Research | 2007 | vol. 47 | No 4 | 417-423
Keywords seasonal incidence natural enemies key insect pests cotton
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Abstract

The population of spider feeding on insect pests of cotton was observed throughout the growth period of the crop, being maximum in the month of July. Chrysoperla was observed from second fortnight of June to harvesting of the crop being maximum in November. The incidence of coccinellids was recorded from the middle of August to middle of September and remained till harvesting of the crop being maximum in the first fortnight of November. A positive significant effect of maximum and minimum temperature on spider and negative significant effect on population of chrysoperla and coccinellids was recorded. Evening RH exerted positive significant effect on spider and negative significant effect on coccinellids.

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Authors and Affiliations

Shish Ram Dhaka
Bhanwar Lal Pareek

Failure control of Plutella xylostella (Lepidoptera: Plutellidae) and selectivity of their natural enemies to different insecticides

Leandro Bacci Jander Fagundes Rosado Marcelo Coutinho Picanço Alfredo Henrique Rocha Gonring Galdino Tarcísio Visintin da Silva Julio Claudio Martins
Journal of Plant Protection Research | 2018 | vol. 58 | No 2 | DOI: 10.24425/122931
Keywords Brassica crops diamondback moth insecticide selectivity natural enemies biological control
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Abstract

Control failure of pests and selectivity of insecticides to beneficial arthropods are key data for the implementation of Integrated Pest Management (IPM) programs. Therefore, the aim of this study was to assess the control failure likelihood of Plutella xylostella and the physiological selectivity active ingredients to parasitoid Oomyzus sokolowskii (Hymenoptera: Eulophidae) and to predators Polybia scutellaris (Hymenoptera: Vespidae) and Lasiochilus sp. (Hemiptera: Anthocoridae). In bioassays, P. xylostella larvae and O. sokolowskii, P. scutellaris and Lasiochilus sp. adults were used. Concentration-mortality curves of six insecticides for P. xylostella were established. These curves were used to estimate the mortality of P. xylostella at the recommended concentration, in order to check a control failure of insecticides to this pest. Furthermore, the lethal concentration for 90% of populations (LC90) and the half of LC90 were used in bioassays with the natural enemies to determine the selectivity of these insects to insecticides. All tested insecticides showed control failure to P. xylostella, indicated by high LC90 and low estimated mortalities (less than 80%). The cartap insecticide was selective in half of LC90 to Lasiochilus sp. and moderately selective in LC90 and the half of LC90, to Lasiochilus sp. and P. scutellaris, respectively. Deltamethrin was moderately selective in the half of LC90 to predator Lasiochilus sp. Cartap, carbaryl, and deltamethrin reduced the mortality of Lasiochilus sp. in the half LC90. The results also showed that the insecticides methamidophos, carbaryl, parathion methyl and permethrin were not selective to any of the tested natural enemies. The role of insecticides in IPM systems of Brassica crops is discussed based on their control failures to P. xylostella and selectivity to their natural enemies.
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Authors and Affiliations

Leandro Bacci
Jander Fagundes Rosado
Marcelo Coutinho Picanço
Alfredo Henrique Rocha Gonring
Galdino Tarcísio Visintin da Silva
Julio Claudio Martins

Relative toxicity of some bio-rational insecticides to second instar larvae and adults of onion thrips (Thrips tabaci Lind.) and their predator Orius albidipennis under laboratory and field conditions

Mahmoud Farag Mahmoud Mohamed A.M. Osman
Journal of Plant Protection Research | 2007 | vol. 47 | No 4 | 391-400
Keywords bio-rational insecticides onion thrips Thrips tabaci natural enemies Orius albidipennis dose-mortality residual effect
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Abstract

Studies on the relative toxicity of different bio-rational insecticides against second instar larvae and adults of onion thrips, Thrips tabaci were carried out on Experimental Farm and in the laboratory, Faculty of Agriculture, University of Suez Canal. Eight insecticides Dipel 2x, BioFly, Agrin, BioGuard, Spinosad, Neemix, Mectin and Match were all evaluated for their relative toxicity towards T. tabaci with recommended dose, half of recommended dose and quarter of recommended dose in the laboratory and only recommended dose under field conditions. Spinosad was the most toxic among the tested insecticides followed by Mectin, Match and Agrin when used against thrips adults. The respective values of LC50 of those insecticides were 0.048 cm/l, 0.070 cm/l, 0.079 cm/l and 0.137 g/l. Also, Spinosad was the most effective insecticide against second instar larvae followed descendingly by: Agrin, Match and Dipel 2x. Toxicity index values at LC50 level show such superior efficiency of Spinosad (100%) when applied against adults and second instar larvae of onion thrips under labora tory conditions. All insecticides under field conditions caused reduction of infestations of thrips. For the residual effect post application, all insecticides gave significant reductions in thrips numbers at the 21 day post treatment except for: Agrin and Match. Spinosad, Mectin, Neemix and BioFly gave the best control and continued to suppress thrips populations till 21 days after treatment. Spinosad was non harmful and Dipel 2x, Agrin were slightly harmful, BioGuard was significantly harmful whereas BioFly, Match and Mectin were very harmful to Orius albidipennis.

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Authors and Affiliations

Mahmoud Farag Mahmoud
Mohamed A.M. Osman

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