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African maize stalkborer
Scientific name:
Busseola fusca (Fuller)
Order/Family:
Lepidoptera: Noctuidae
Type:
pest (insect/mite)
Common names:
African maize stalk/stem borer, maize stem/stalk borer, sorghum stalk/stem borer
Host plants:
Maize  Millet  Sorghum 
General Information on Pest and Damage
Geographical Distribution of the African maize stalk borer in Africa (red marked)
Geographical information: Busseola fusca is a common pest in many African countries throughout sub-Saharan Africa. In East Africa it occurs at altitudes of 1000 to over 2700 m while in Central Africa it is the predominant pest across all altitudes. In West Africa, it is only common on sorghum in the dry-hot zones.

Introduction
Busseola fusca is indigenous to Africa. Its distribution and pest status varies with the region. In East and southern Africa it is a pest at higher altitudes (above 600 m), but in Central Africa it occurs from sea level to over 2000 m, while in West Africa it is primarily a pest of sorghum in the dry savannah zone.

Damage
Damage is caused by the caterpillars, which first feed on young leaves, but then enter into the stems. During the early stage of crop growth, the caterpillars may kill the growing points of the plant, causing what is known as dead-heart (the youngest leaves can be easily pulled off).

At a later stage of growth, they make extensive tunnels inside the stem. This disrupts the flow of nutrients to the grain. Tunnelling weakens the stem so that it breaks and falls over. In older plants the first generation caterpillars bore in the main stem but later some of the second generation bore into the maize cobs. Caterpillars also tunnel into the peduncles of sorghum and millet inflorescences, and may seriously affect grain production.

Because maize plants don't produce tillers, they are less able to tolerate stem borer attack than sorghum and pearl millet plants and the effect on grain yields is therefore greater.

Colonisation of the plant by borers, severity of infestation and damage strongly depend on the cropping system and soil fertility, which affects the nutritional status of the plant.
Stemborer damage is aggravated by the poor nutritional status of the plant.

Studies on several stemborers in Africa showed that an increase in nitrogen is related to higher pest loads and tunnel damage. However, soil nutrient levels, such as nitrogen, greatly influenced the plant's tolerance to stemborer attack as well. This is due to an increase in plant vigour, which is reflected in lower yield losses (Setamu et al., 1995).

Damage caused by stemborers can average 20 to 40%, which means between 2 to 4 bags of maize are lost out of every 10 that could be harvested.

Grains damaged by pests such as stemborers become susceptible to infection by mouldy fungi such as Aspergillus - see photo on the right side - which produce aflatoxin, a toxic by-product extremely poisonous to people and which can lead to liver cancer.

Stem damage on maize stalk by African maize stalk borer
© Anne Bruntse, BioVision
Stalkborer larvae (about 8 mm) feeding inside maize stem. Notice brown frass deposits.
© Anne Bruntse, BioVision
Maize cobs damaged by the African maize stalk borer (Busseola fusca). Note caterpillar and secondary infection by moulds
© Stemborer team, icipe


Host Range:
The main hosts of the African stalkborer are maize and sorghum. This stemborer is also a pest of pearl millet in Mali, Burkina Faso and Eritrea. It also attacks few grass species, wild sorghum species mainly, but it is rarely found in natural habitats.

Symptoms:
Young plants show small holes and 'window-panes' in the leaf whorls where tissues have been eaten away. Small dark caterpillars may be seen in the funnel. In severe attacks the central leaves die, forming the characteristic dry, withered 'dead-heart'.
Symptoms in maize plant include dead heart, plant death, dieback, internal feeding and presence of frass in the stems. Older caterpillars tunnel in stems, and eat out long frass-filled galleries, which weaken stems and cause breakages.

Early warning signs in maize: Small holes in straight lines on the youngest leaves.
Affected Plant Stages
Flowering stage vegetative growing stage and generative stage.

Affected Plant Parts
Growing points, inflorescence, leaves, seeds, grain, ear/ head, stems.

Symptoms by affected plant part
Growing points: internal feeding; boring; external feeding; dead heart; frass visible.
Inflorescence: abnormal colour; internal feeding; frass visible.
Leaves: external feeding; frass visible.
Seeds: frass visible; empty grains.
Stems: abnormal growth; internal feeding; dead-heart; visible frass.
Whole plant: dead heart; plant dead; dieback; internal feeding; frass visible.
Biology and Ecology of the African Maize Stalk Borer
Eggs of the African maize stalkborer (Busseola fusca).
© Stemborer team, icipe
Eggs are round, flattened and about one mm in diameter. They are usually laid in batches of 30 to 100 under leaf sheaths in a long column stretching up the stem, and may slightly be compressed by pressure from the growing stem. They are white when first laid but darken as they age. Eggs hatch in about 7 to 10 days.

Caterpillars of the African maize stalkborer (Busseola fusca).
© D. Cugala, Stemborer team, icipe
Caterpillars are light or dark violet to pinkish white in colour, often with a distinctive grey tinge. They lack conspicuous hairs and look smooth and shiny, but have rows of small black spots along the body. On hatching caterpillars are blackish. They crawl up the plant into the funnel where they feed on leaves for 2 to 3 days and then either move to other plants or enter inside the maize stem.
After the caterpillars bore into the maize stems, they feed and grow within the stems for 2 to 3 weeks. They grow to a length of about 40 mm. When fully grown, they cut a hole in the side of the stem before pupating within the tunnel inside the maize stem.

The total larval period is usually 35 days when conditions are favourable during the growing season, but during dry and/or cold weather caterpillars enter into a resting period (diapause) of 6 months or more in stems, stubble and other plant residues. With the beginning of the rains, the caterpillars pupate within the stems.

Pupae are shiny yellow-brown to dark brown and about 25 mm long. After 7 to14 days the adults emerge from the pupae and come out of the stem.

Male moth of African maize stalkborer (Busseola fusca) .
© B. Le Ru, icipe
The adults have a wingspan of about 25 to 35 mm. Females are generally larger than males. The forewings are light to dark brown with darker markings and the hindwings are white to greyish-brown. There is much seasonal and geographic variation with darker colouration developing in cold wet conditions.

Adult moths of stemborers are seldom seen in fields, as they are inactive during daytime. They become active after sunset and lay their eggs during the night.

They have several generations in a year, so their numbers increase towards the end of the season.
Pest and disease Management
Pest and disease Management: General illustration of the concept of infonet-biovision
This illustration shows the methods promoted on infonet-biovision. The methods shown at the top have a long-term effect, while methods shown at the bottom have a short-term effect. In organic farming systems, methods with a long-term effect are the basis of crop production and should be of preference. On the other hand methods with a short-term effect should be used in emergencies only. On infonet we do not promote synthetic pesticides.

Further below you find concrete preventive and curative methods against African maize stalkborer.
Cultural practices

Monitoring

Scouting and early control is essential for effective management of stemborers. Check the crop regularly. First signs of stalkborer attack are small holes or 'window panes' in straight lines across the newest leaves of maize or sorghum.

Field sanitation

Destroy crop residues. This is important to kill the pupae left in old stems and stubble and to prevent carry-over populations. It also limits initial establishment of the pest on the following season's crops.

Plough and harrow. These practices help reduce borer populations by burying them deeply into the soil or by breaking the stems and exposing the caterpillars to natural enemies and to adverse weather conditions.

Slashing maize and sorghum stubble, complemented with cultivation by disking and ploughing can reduce larval populations by almost 100% (Kfir et al, 2002).
Burning crop residues is an effective way of killing stemborer caterpillars, but can create problems in farms where the organic content of soils is low and soil erosion is severe, since in many cases crop residues are the only organic matter added into soils in smallholder farms.
Alternative ways to destroy diapausing caterpillars without destroying the stems are needed in areas where stems of cereals are used as building and fencing materials, fuel, bedding for livestock, or as stakes. In this case, partial burning is recommended, while the leaves are dry but the stalks are still green. Heat generated from the burning leaves kills up to 95% of stemborer caterpillars within the stems, and at the same time cures the stalks, improving their quality as building materials and making them more resistant to termite attack.

Using crop residues for fodder and silage has also been recommended (CABI, 2000; Kfir et al, 2002).

Destruction of wild sorghum, which would act as alternative host, may help to reduce population upsurge.

For these cultural measures to be effective, the cooperation of farmers in a region is required because moths emerging from untreated fields can infest adjacent crops.

Improvement of soil fertility

Maintaining soil fertility or practices that increase nitrogen use efficiency in maize production are important for management of the African stalkborer. Thus, in studies in Cameroon, soil application of nitrogen improved the nutritional status of maize, which consequently enhanced its tolerance to the African maize stemborer attack (Chabi-Olaye et al; 2008). However, if nitrogen is applied at rates greater than required for maximum yield, plant biomass increases at expenses of yield.

Technologies to restore soil fertility include cereal-legume rotations, use of farmyard manure and green manure cover crops, among others. Legume cultivation and rotation are highly efficient in improving the supply of nitrogen in the soil.

Crop rotation

Maize-legume rotation sequences improve the supply of nitrogen in the soil and the nutritional status of maize, which compared to maize-maize sequences. This influences the maize susceptibility to pests and diseases.

The use of short duration fallows with leguminous cover crops and grain legumes have been useful in reducing yield losses due to borers in the subsequent crop. Rotation with grain legumes (cowpea and soybean) or leguminous cover crop pigeon pea and mucuna (Mucuna pririens) improved the supply of nitrogen in the soil and enhanced the yield of subsequent maize crop in the humid forest of Cameroon.

An improved nutritional status of the plant led to an increase in attacks by the African stalkborer at the early stages of the plant growth, but also improved plant vigour, resulting finally in a net benefit for the plant and grain yield (Chabby-Olaye et al., 2005).

Intercropping and habitat management

The importance of plant biodiversity in maize agroecosystems for reducing borer's infestation on maize has been recognised in sub-Sahara Africa.
Maize intercropped with non-host crops (e.g. cassava and grain legumes) have significantly lowered stemborer damage and had higher yield than monocrop maize. The effect is variable, if the crop to be protected is not planted after the companion crops. In studies in Cameroon, maize monocrops had 3 to 9 times more stems tunnelled and 1 to 3 times more cob damage than maize intercropped with non-host crops such as cowpea, cassava and soybean, which resulted in a higher yield in the intercropped maize.
In the mixed cropping system maize was planted 12 to 14 days after the non-host plants. Two plant arrangements were used:
1. One maize plant was followed by a non-host plant and 2. Strip planting in which two rows of maize were followed by two rows of a non-host crop and with one row of non-host plants as borders.

Maize yield losses due to stemborers were about 2 to 3 times higher in monocrops than in intercrops. In addition land-productivity was higher than with monocrops. The maize-cassava intercrop was the most effective in terms of land use and the most productive compared to pure maize stand with pesticide application. The net production of mixed cropping systems was economically superior to controlling stemborers with insecticide in monocropped maize (Chabi-Olaye et al, 2005; Chabi-Olaye et al, 2006).

Studies in Kenya suggested that intercropping maize and/or sorghum with cowpeas reduced damage caused by the African stalkborer (Amoako-Atta and Omolo, 1983; Reddy and Masyanga, 1988). Trials in Eritrea showed that sorghum intercropped with haricot beans, cowpea, desmodium and Dolichos lablab had much lower deadheart damage compared to pure stand sorghum (ICIPE, 2005).

'Push-Pull Strategy'

Push-Pull is a simple cropping strategy, whereby farmers use Napier grass and Desmodium legume (silverleaf and greenleaf Desmodium) as intercrops. For a more detailed description on push-pull click here

Farmer practices

Application of baits at first signs of stalkborer attack (small holes in straight lines across the newest leaves of maize or sorghum) - one pinch per affected plant applied inside the funnel of maize plants.
Examples of bait: Pymack (byproduct of pyrethrum production sold as cattle feed in Kenya) provides some control, maize flour or bran mixed with pyrethrum extract reportedly provides good control.
Scouting and early control is essential for this method to have any effect.
Caution: Application of too much bait inside maize and sorghum funnels can kill the growing point - a pinch of bait per plant is enough.

Biological pest control

Natural enemies


Many natural enemies of the African stalk borer have been recorded in Africa. The most important are predatory ants, parasitic wasps and parasitic flies. Parasitic wasps may attack eggs (e.g. Trichogramma spp. and Telenomus spp.) or caterpillars (e.g. Bracon spp and Cotesia sesamiae). Tachinid flies parasitise caterpillars. Cotesia sesamiae is the most common larval parasitoid (attack caterpillars) of this stemborer on maize in eastern Africa.
For more information on natural enemies click here.

Biopesticides and physical methods

Neem

Simple neem products are reported to be effective for control of stemborers, including the African maize stalkborer. It is recommended that a small amount of neem powder (ground neem seeds) mixed with dry clay or sawdust at a rate of 1:1 be placed in the funnel of the plant. One kg powder should be sufficient to treat 1500 to 2000 plants. In this method rainwater dissolves the active substances in neem powder as it gathers in the funnel and washes out the powder. Where rainfall is irregular a liquid neem seed extract can be sprayed into the funnel.

The treatment should be repeated every 8 to 10 days during the sensitive growing phase. Thus, roughly three treatments are required per crop. This recommendation applies only for young plants before flowering and not for older plants. Neem powder should be always applied as a mixture with inert materials (sawdust, rice hulls or dry fine clay), as the powder alone can be phytotoxic (harm the plants) owing to its oil content (Dreyer, 1986).

In studies in Tanzania, aqueous seed extracts combined with extracted ground neem seeds and sawdust, applied twice to the whorl of maize leaves was as effective in controlling the African stalkborer as endosulfan. The extract was prepared by soaking 120g of neem seeds and 120 g of sawdust in three litre of water for 12 hours. The mixture was filtered and the residue and the aqueous extract were then applied separately to the maize plants (Hellpap, C., 1995). For more information on neem click here.

Information Source Links
  • Chabi-Olaye, A., Schulthess, F. and Borgemeister, C. (2008). Effects of Nitrogen and Potassium Combinations on Yields and Infestations of Maize by Busseola fusca (Lepidoptera: Noctuidae) in the Humid Forest of Cameroon. Journal of Economic Entomology 101(1): 90-98t
  • Chabi-Olaye, A., Nolte, C., Schulthess, F. and Borgemeister, C. (2005a). Relationships of intercropped maize, stem borer damage to maize yield and land-use efficiency in the humid forest of Cameroon. Bulletin of Entomological Research. 95, 417-427.
  • Chabi-Olaye, A., Nolte, C., Schulthess, F. and Borgemeister, C. (2005b). Effects of grain legumes and cover crops on maize yield and plant damage by Busseola fusca (Lepidoptera: Noctuidae) in the humid forest of southern Cameroon. Agriculture, Ecosystems & Environment. 108, 17-28. Available online at www.sciencedirect.com
  • Chabi-Olaye, A., Nolte, C., Schulthess, F. and Borgemeister, C. (2006). Relationships of soil fertility and stem borers damage to yield in maize-based cropping system in Cameroon. Ann. Soc. Entomol. Fr. 42:471-479.
  • Dryer, M. (1987). Field and laboratory trials with simple neem products as protectans against pests of vegetables and field crops in Togo. Proc. 3rd International Neem Conference (Nairobi, Kenya, 1986). Pp 431-447.
  • GTZ. Neem a Natural Insecticide. Gewinnung natürlicher Insektizide aus tropischen Planzen. Deutsche Gesellschaft für Technische Zusammenarbeit. Postfach 5180. 6236 Eschborn 1. Deutschland.
  • Hellpap, C., (1995). Practical results with neem products against insect pests, and probability of development of resistance. Pest of selected field crops. Corn. In The Neem tree- Source of Unique Natural Products for Integrated Pest Management, Medicine, Industry and Other Purposes. Edited by H. Schmutterer. pp 385-389. ISBN: 3-527-30054-6.
  • Hill, D. S. (1983). Agricultural Insect pests of the tropics and their control. Second edition. Cambridge University Press. pp 746. ISBN: 0-521-24638-5.
  • ICIPE (2005). A Primer on Planting and Managing 'Push-Pull' Fields for Stemborer and Striga Control in Maize - A Step-by-Step Guide for Farmers. By Z.R. Khan, F.N. Muyekho, E Njuguna, J.A. Pickett, L.J. Wadhams, N.Dibogo, A. Ndiege, G.Genga and C. Luswetti
  • ICIPE Biennial Scientific Report 2004-2005. Biocontrol cereal pests in Africa. Pdf. www.icipe.org
  • Sétamou, M., Schulthess, F., Bosque-Pérez, N. A. and Thomas-Odjo, A. (1995). The effect of stem and cob borers on maize subjected to different nitrogen treatments. Entomol. Exp. Appl. 77: 205-210.
Contact links
ICIPE and her partners: 'Push-Pull' Technology for the Control of Stemborers and Striga weed. www.push-pull.net
Caterpillars of the African maize stalkborer (Busseola fusca).
Diameter
Thickness or width.
Biodiversity
is the variety of life forms and ecosystem types on earth. Includes genetic diversity (i.e. the number and variety of species) and ecosystems diversity (total number of ecosystem types).
Farmyard manure
Droppings and beddings of farm animals, usually of cattle.
Synthetic
Manufactured by chemical and industrial processes. May include products not found in nature, or simulation of products from natural sources (but not extracted from natural raw materials).
Inflorescence
A group of flowers growing from a common stem, often in a characteristic arrangement. Also called flower cluster.
Green manure
A crop grown before or between the main crop rows, cut before maturation and subsequently ploughed in or used as mulch. It provides nutrients to the main crop through decomposition and helps to build up humus in the soil.
organic
Refers to the farming system and products described in the IFOAM standard and not to 'organic chemistry'.
Fungi
Occurring worldwide, most fungi are largely invisible to the naked eye, living for the most part in soil, dead matter, and as symbionts of plants, animals, or other fungi. They perform an essential role in all ecosystems in decomposing organic matter and are indispensable in nutrient cycling and exchange. Some fungi become noticeable when fruiting, either as mushrooms or molds.

Fungi are responsible for a range of serious plant diseases such as blight, grey mould, bunts, powdery mildew, and downy mildew. Crops of all kinds often suffer heavy losses.

Fungal plant diseases are usually managed with applications of chemical fungicides or heavy metals. In some cases, conventional breeding has provided fungus resistantcultivars.

Besides combatting yield losses, preventing fungal infection keeps crops free of toxic compounds produced by some pathogenic fungi. These compounds, often referred to as mycotoxins, can affect affect the immune system and disrupt hormone balances. Some mycotoxins are carcinogenic.
Predator
Animal that attacks and feeds on other animals, such as an insect (e.g. ladybird beetle), bird or spider feeding on pest insects.
Border crop
Crop grown at the edge of organic fields bordering conventionally managed fields in order to reduce drift of pesticide sprays.
Resistance
Ability of a living organism not to get affected by a disease or pest; or of a pest not to be affected by a pesticide.

Pesticide Resistance is the ability of a life form to develop a tolerance to a pesticide. Pests (weeds, insects, mites, diseases, etc.) that become resistant to a pesticide will not be affected by the pesticide. When pests are resistant, it is more difficult to control the pest. Therefore, it is important to try to prevent pesticide resistance.
Resistance
Ability of a living organism not to get affected by a disease or pest; or of a pest not to be affected by a pesticide.

Pesticide Resistance is the ability of a life form to develop a tolerance to a pesticide. Pests (weeds, insects, mites, diseases, etc.) that become resistant to a pesticide will not be affected by the pesticide. When pests are resistant, it is more difficult to control the pest. Therefore, it is important to try to prevent pesticide resistance.
Biennial
Plant with a life cycle extending over two growing seasons.
Cultivar
Cultivar is a plant variety. It is a group of similar plants which through their structural features and performance can be identified from other varieties within the same species.
Intercropping
Intercropping is the planting of two or more crops in the same field, usually planted in alternating rows or sections.
IPM
A combination of chemical and biological control methods, based on the concept of economic tresholds. Pest management in organic farming uses many biological control methods developed as par of IPM.