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Efficacy of the aqueous crude seed extract of Millettia ferruginea (Fabaceae) on the maize stemborer Busseola fusca (Lepidoptera: Noctuidae) in the field

Published online by Cambridge University Press:  07 October 2013

Beniam Tilahun
Affiliation:
Department of Plant Science, Dilla University, PO Box 419, Dilla, Ethiopia
Ferdu Azerefegne*
Affiliation:
Department of Plant and Horticultural Sciences, Hawassa University, PO Box 770, Hawassa, Ethiopia
*
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Abstract

The efficacy of different aqueous dilutions of crude seed extract of Millettia ferruginea (Hochst.) Baker (1, 3, 5 and 10%) was evaluated under field conditions in terms of the level of damage and yield loss of maize caused by the maize stemborer Busseola fusca (Fuller) in Hawassa, southern Ethiopia. The insecticide lambda-cyhalothrin 5EC, applied at a rate of 16 g active ingredient/hectare, was used as the reference product. The experiment was carried out in a randomized complete block design with four replications. The maize variety A511 was planted in individual plots of 60 m2. Data on stand count, leaf infestation, bored stem and dead heart were collected weekly. Plots sprayed with the 5% concentration of Millettia showed low levels of damage (9–11% leaf infestation, 0.4% dead heart, 14–17% bored stem and < 0.2% bored ear), compared with plots sprayed with lambda-cyhalothrin. The treatments with 1 and 3% concentrations of Millettia were inferior to those with lambda-cyhalothrin and 5 and 10% concentrations of Millettia. In contrast, the treatment with the 10% concentration of Millettia led to the death of plants, thereby lowering the yield. About 80% of the total length of individual maize stalks from the untreated plots was internally tunnelled by the feeding larvae, while the internal stem tunnelling was low ( < 7%) in plants treated with Millettia at concentrations of 3, 5 and 10%. Among the treatments with Millettia, higher yields (37–48 decitonnes/hectare) were obtained from maize plots treated with 5% concentration. The use of the aqueous crude seed extract of M. ferruginea at a concentration of 5% applied two to three times is recommended for the control of B. fusca in maize.

Type
Research Papers
Copyright
Copyright © icipe 2013 

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References

Abebe A. M. (2004) The effect of birbira, Milletia ferruginea (Hochst) Baker on some Barbus spp. in Gumara River (Lake Tana), Ethiopia. MSc thesis, Department of Biology, Addis Ababa University, Ethiopia. 57 pp.Google Scholar
Asmare D. (2001) Evaluation of insecticides for the control of stalk borer. In The Annual Progress Report of Crop Protection Research Division at Sirinka Research Center, Northeast Amhara Region, North Wolo, Woldia. 38 pp.Google Scholar
Azene B. (2007) Useful trees and shrubs of Ethiopia: identification, propagation, and management for 17 agroclimatic zones. In Technical Manual No. 6. RELMA in ICRAF Project, Kenya. 550 pp. ISBN 978-9290592129.Google Scholar
Azerefegne A. (1991) Biology and economic importance of maize stalk borer, Busseola fusca in Awassa, Southern Ethiopia. MSc thesis, Alemaya University of Agriculture, Alemaya, Ethiopia. 89 pp.Google Scholar
Bekele A. (1988) Investigation of flavonoids from ‘birbira’. MSc thesis, Addis Ababa University, 167 pp.Google Scholar
Berhanu, A. and Amare, G. (2012) Production and characterization of biodiesel from brebra (M. ferruginea) seed non-edible oil. Biotechnology 11, 217224.Google Scholar
Berhanu A., Getachew A. and Adugna T. (2013) Millettia ferruginea: an endemic legume tree as forage for ruminants in southern and northwestern Ethiopia. Livestock Research for Rural Development, Vol. 25, Article #44. Available at: http://www.lrrd.org/lrrd25/3/alem25044.htm (retrieved 19 July 2013).Google Scholar
Dagne, E. and Bekele, A. (1990) C-Prenylated isoflavones from Millettia ferruginea. Phytochemistry 29, 26792682.Google Scholar
Damte, T. and Chichaybelu, M. (2002) The efficacy of some botanicals in controlling Adzuki bean beetle, Callosobruchus chinensis in stored chickpea. Tropical Science 42, 192195.Google Scholar
Eyob, T., Azerefegne, A., Tameru, A., Temesgen, A. and Blomme, G. (2010) Studies on the efficacy of some selected botanicals against enset root mealybug (Cataenococcus ensete) Williams and Matile-Fererro (Homptera: Pseudococcidae). Tree and Forestry Science and Biotechnology 4, 9194.Google Scholar
Gebre-Amlak, A. (1985) Survey of lepidopterous stem borers attacking maize and sorghum in Ethiopia. Ethiopian Journal of Agricultural Sciences 7, 1526.Google Scholar
Gebre-Amlak, A. and Azerefegne, F. (1999) Insecticidal activity of chinaberry, endod and pepper tree against the maize stalk borer (Lepidoptera: Noctuidae) in Southern Ethiopia. International Journal of Pest Management 45, 913.Google Scholar
Gebre-Amlak, A., Sigvald, R. and Pettersson, J. (1989) The relationship between sowing date, infestation and damage by the maize stalk borer, Busseola fusca (Noctuidae) on maize in Awassa, Ethiopia. Tropical Pest Management 35, 143145.Google Scholar
George W. W. (1980) Complete Guide to Pest Control with and Without Chemical, 2nd edn. Thomson Publications, Fresno, California. 304 pp.Google Scholar
Getahun, D. and Jembere, B. (2006) Evaluation of toxicity of crude extracts of some botanicals on different castes of Macrotermes termites. Pest Management Journal of Ethiopia 10, 1523.Google Scholar
Hien, P. P., Gortnizka, H. and Kraemer, R. (2003) Rotenone – potential and prospect for sustainable agriculture. Omonrice 11, 8392.Google Scholar
Jembere, B. (2002) Evaluation of the toxicity potential of Millettia ferruginea (Hochst) Baker against Sitophilus zeamais (Motsch.). International Journal of Pest Management 48, 2932.Google Scholar
Jembere B., Getahun D., Negash M. and Seyoum M. (2006) Toxicity of Birbira (Milletia ferruginea) seed crude extracts to some insect pests as compared to other botanical and synthetic insecticides, pp. 88–96. In Natural Products and Drug Discovery. Proceedings of the 11th NAPRECA Symposium, 9–12 August 2005, Hôtel Panorama, Antananarivo, Madagascar. A NAPRECA Publication, Nairobi, Kenya.Google Scholar
Jembere, B., Namukobe, J., Benard, T. K. and Dagne, E. (2007) Extracts of Millettia ferruginea, Tephrosia vogellii and Tephrosia pentaphylla against the bean weevil Zabrotes subfaciatus (Boheman). Sinet: Ethiopian Journal of Science 30, 4954.Google Scholar
Karunamoorthi, K., Bishaw, D. and Mulat, T. (2009) Toxic effects of traditional Ethiopian fish poisoning plant Milletia ferruginea (Hochst) seed extract on aquatic macroinvertebrates. European Review for Medical and Pharmacological Sciences 13, 179185.Google Scholar
SAS Institute Inc. (2000) SAS/STAT Guide for Personal Computers. SAS, Raleigh, North Carolina.Google Scholar
Saxena, R. C. (1983) Naturally occurring pesticides and their potential, pp. 143161. In Chemistry and Food Supplies: The New Frontiers. Proceedings of the International Conference on Chemistry and World Food Supplies “Chemrawn II”, Manila, Philippines (Edited by Shemilt, L. W.). Pergamon Press, Oxford/New York.Google Scholar
Siegenthaler H. (1980) Useful plants of Ethiopia. Jima Experimental Station Bulletin No. 14, Vol. 1. 18 pp.Google Scholar
Tadesse, H., Legesse, N. and Olsson, M. (2000) Milletia ferruginea from Southern Ethiopia: impacts on soil fertility and growth of maize. Agroforestry Systems 48, 924.Google Scholar
Takemoto, K. and Arita, M. (2009) Heterogeneous distribution of metabolites across plant species. Physica A 388, 27712780.Google Scholar
Teketay, D. and Tegineh, A. (1991) Shade trees of coffee in Hararge, Eastern Ethiopia. The International Tree Crops Journal 7, 1727.Google Scholar
Westbom, R., Ahmed, H., Negussie, M., Negussie, R., Mathiasson, L. and Björklund, E. (2008) Assessment of organochlorine pesticides pollution in Ethiopian state farm soils using selective pressurized liquid extraction. Journal of Chemosphere 72, 11811187.Google Scholar
Yitaferu, K., Gebre-Amlak, A. and Lakra, R. K. (1994) Diapause termination in maize stem borer, Busseola fusca (Fuller) larvae at Alemaya, eastern Ethiopia. International Journal of Tropical Agriculture 12, 266277.Google Scholar