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Entomopathogenic nematodes including Steinernema riobrave and Heterorhabditis indica were evalusted against a small hive beetle Aethina tumida Murray (Coleoptera: Nitidulidae) in the field. According to Ellis et al. (2010) both nematode species caused over 76% mortality of hive beetles. Shapiro-Ilan et al. (2010) tested efficacy of H. indica and Steinernema carpocapsae against hive beetles and demonstrated that both nematode species when applied through infected host cadavers can cause up to 78% control in hive beetles. This suggests that entomopathogenic nematodes have a potential to use as biological control agents against hive beetles.

Read following papers for detail information on effect of entomopathogenic nematodes on the small hive beetles.

Ellis, J.D., Spiewok, S., Delaplane, K.S., Buchholz, S., Neumann, P. and Tedders, W.L. 2010.  Susceptibility of Aethina tumida (Coleoptera: Nitidulidae) larvae and pupae to entomopathogenic nematodes. Journal of Economic Entomology. 103: 1-9.

Shapiro-Ilan, D.I., Morales-Ramos, J.A., Rojas, M.G. and Tedders, W.L. 2010.  Effects of a novel entomopathogenic nematode-infected host formulation on cadaver integrity, nematode yield, and suppression of Diaprepes abbreviatus and Aethina tumida. Journal of Invertebrate Pathology. 103: 103-108.

An entomopathogenic nematode in a soil sample collected from a natural forest in Mato Grosso do Sul state, Brazil was described using both morphological and molecular characteristics as a new species “Steinernema brazilense (Rhabditida: Steinernematidae)” (Nguyen et al., 2010).

Reference:

Nguyen, K.B., Ginarte, C.M.A., Leite, L.G., dos Santos, J.M. and Harakava, R. 2010. Steinernema brazilense n. sp (Rhabditida: Steinernematidae), a new entomopathogenic nematode from Mato Grosso, Brazil. Journal of Invertebrate Pathology. 103: 8-20.

How to apply nematodes

Insect-parasitic nematodes can be easily applied using conventional pesticide and fertilizer sprayers that have up to 300 PSI pressures.  However, nematodes will be easily damaged, if they are agitated through excessive recirculation of spray mix or if the temperature in the tank increases beyond 86 degrees F. Nematodes can also be applied through different types of irrigation systems but pumps should have proper pressure to avoid damage to nematodes and screen sizes should be larger than 50 mesh so that nematodes will pass through them live. Watering cans are used to apply nematodes in small areas including vegetable and ornamental gardens.

How many nematodes should be applied

For the suscessful control most of the soil dweling insect pests, the optimal rate of 1 billion infective juvenile nematodes in 100 to 260 gallons of water per acre is generally recommended.

Optimal soil and environmental condtions to apply nematodes

All nematodes require proper soil moisture for their optimal movement and infectivity. The activity and infectivity of nematodes can be enhanced by maintaining optimum moisture levels in the soil before and after their application.  In case of nematode application in turf, turf should be irrigated immediately after applicationwith at least 1/2 inch of water to rinse off nematodes from the folliage and move them into the soil and thatch. As nematodes are very sensitiv to heat and cold, their infectivity will be reduced if soil temperature is below 4 degrees C and above 35 degrees C. Soil temperatures between 20 to 30 degrees C are considered favourable for application of majority of nematode species and their virulence.  Nematode survival and activity also influenced by soil type.  Both survival and activity of nematodes is higher in sandy-loam soils than in heavy clay soils.

When to apply nematodes

Since nematodes are very sensitive to UV light, they will die within a minute or two when exposed to full sun. Therefore, nematodes should be applied early in the morning or late in the evening to avoid exposure to UV light.

For the last several decades, entomopathogenic nematodes have been successfully used for the management of insect pests of many economically important crops (Grewal et al., 2005).  As an additional benefit, several researchers including Fallon et al. (2002), Gouge et al. (1997), Grewal et al. (1997; 1999), Jagdale et al. (2002), Jagdale and Grewal (2008), LaMondia and Cowles (2002), Lewis et al. (2001), Lewis and Grewal (2005), Molina et al. (2007), Nyczepir et al. (2004), Perez and Lewis (2002), Perry et al. (1998) and Shapiro et al. (2006) have demonstrated that entomopathogenic nematodes can also be used as biological control agents to control plant-parasitic nematodes infesting different crops in the fields and greenhouses . To control plant- parasitic nematodes, entomopathogenic nematodes can be applied using standard spraying equipments used for application of chemical pesticides. Entomopathogenic nematodes are generally applied against plant-parasitic nematodes at the rate of 1 billion infective juveniles per acre but this rate can vary with both entomopathogenic nematode and plant- parasitic nematode species.  Following are the examples of different species of entomopathogenic nematode that found to be successful in suppressing the population of different species of plant- parasitic nematodes.  Steinernema carpocapsae can reduce the population of ring nematodes (Mesocriconema spp., Criconemoides spp.) by 65%.  S. carpocapsae can reduce the population of stubby root nematodes (Paratrichodorus spp.) by 60%.  S. carpocapsae can reduce the population of potato cyst nematodes (Globodera rostochiensis).  S. carpocapsae can reduce the populations of foliar nematode Aphelenchoides fragariae.  Steinernema riobrave can reduce the population of stunt nematodes (Tylenchorynchu spp.) by 85%.  S. riobrave can reduce the population of lance nematodes (Hoplolaimus spp.).  S. riobrave can reduce the population of root-knot nematodes (Meloidogyne spp.) by 83%.  S. riobrave reduced egg masses of root-knot nematodes (Meloidogyne spp.).  S. riobrave can reduce the population of sting nematodes (Belonolaimus longocaudatus).  Steinernema feltiae can inhibit hatching root-knot nematode eggs and infection by hatched infective juveniles of root-knot nematodes (Meloidogyne spp.).  S. feltiae reduced egg masses of root-knot nematodes (Meloidogyne spp.) .  S. feltiae can reduce the population of root-knot nematodes (Meloidogyne spp.).  Steinernema glaseri reduced egg masses of root-knot nematodes (Meloidogyne spp.).  Heterorhabditis bacteriophora can reduce the population of ring nematodes (Mesocriconema spp., Criconemoides spp.) by 80%.  H. bacteriophora can reduce the population of stunt nematodes (Tylenchorynchus spp.) by 60%.  H. bacteriophora can reduce the population of lesion nematodes (Pratylenchus pratensis).   H. baujardi can inhibit hatching root-knot nematode eggs and infection by hatched infective juveniles of root-knot nematodes (Meloidogyne mayaguensis).

Read following literature for more information on interaction between entomopathogenic nematodes and plant- parasitic nematodes:

1. Fallon, D.J., Kaya, H.K., Gaugler, R., Sipes, B.S., 2002. Effects of entomopathogenic nematodes on Meloidogyne javanica on tomatoes and soybeans. Journal of Nematology 34, 239-245.

2. Fallon, D.J., Kaya, H.K., Sipes, B.S., 2006. Enhancing Steinernema spp. suppression of Meloidogyne javanica. Journal of Nematology 38, 270-271.

3. Grewal, P.S., Ehlers, R.-U., Shapiro-Ilan, D.I. (Eds.), 2005. Nematodes As Biocontrol Agents. CABI Publishing, CAB International, Oxon, U.K.,

4. Grewal, P.S., Lewis, E.E., Venkatachari, S., 1999. Allelopathy: a possible mechanism of suppression of plant-parasitic nematodes by entomopathogenic nematodes. Nematology. 1, 735-743.

5. Grewal, P.S., Martin, W.R., Miller, R.W., Lewis E.E., 1997. Suppression of plant-parasitic nematode populations in turfgrass by application of entomopathogenic nematodes. Biocontrol Science and Technology 7, 393-399.

6. Jagdale, G.B., Grewal, P.S., 2008. Influence of the entomopathogenic nematode Steinernema carpocapsae in host cadavers or extracts from cadavers on the foliar nematode Aphelenchoides fragariae on Hosta. Biological Control 44, 13-23.

7. Jagdale, G.B., Somasekhar, N., Grewal, P.S., Klein, M.G., 2002. Suppression of plant parasitic nematodes by application of live and dead entomopathogenic nematodes on Boxwood (Buxus spp). Biological Control. 24, 42-49.

8. Lewis, E.E., Grewal, P.S., 2005. Interactions with plant-parasitic nematodes. In: Grewal, P.S., Ehlers, R.-U., Shapiro-Ilan, D.I. (Eds.), Nematodes As Biocontrol Agents. CABI Publishing, CAB International, Oxon, U.K., pp. 349-362.

9. Perry, R.N., Homonick, W.M., Beane, J., Briscose, B., 1998. Effects of the entomopathogenic nematodes, Steinernema feltiae and S. carpocapsae, on the potato cyst nematode, Globodera rostochiensis, in pot trials. Biocontrol Science and Technology 8:175 – 180.

10. Shapiro, D.I., Nyczepir, A.P., Lewis, E.E., 2006. Entomopathogenic nematodes and bacteria applications for control of the pecan root-knot nematode, Meloidogyne partityla in the greenhouse. Journal of Nematology 38, 449-454.

Pulse (legume) grains are considered as the important sources of protein, fats, carbohydrates, sugar and vitamin. B.  In developing countries pulses are a cheaper protein source than meat.  Many insect pests including red flour beetle Tribolium castaneum (Herbst), India meal moth Plodia interpunctella, Mediterranean flour moth Ephestia kuehniella (Zeller), saw thoothed grain beetle Oryzaephilus surinomensis (L.), yellow mealworm Tenebrio molitor (L.) and the ware house beetle Trogoderma variable (Ballion) cause a serious damage to these crops in the field and grains in the storage.  The efficacy of entomopathogenic nematodes against many stored grain/product pests have been studied by many researchers (Athanassiou et al., 2008; Moris, 1985; Romos-Rodriguez et al., 2006).  In the laboratory, an entomopathogenic nematode, Steinernema feltiae when applied at the rate 900 infective juveniles per insect caused over 66% mortality of both adults and larvae of T. confusum. This nematode when applied at the same rate also caused over 52% mortality of E. kuehniella. (Athanassiou et al., 2008)  Under laboratory conditions, another species of nematode, S. riobrave can cause about 70% mortality of T. castaneum (Ramos-Rodríguez et al., 2007). It has also been demonstrated that nematodes including S. carpocapsae, Heterorhabditis bacteriophora and H. megidis have a potential to control the adults of two stored grain pests including, Sitophilus granarius and O. surinamensis (Tradan, 2006). Mbata and Shapiro-IIan (2005) also showed that various heterorhabditis nematodes including H. bacteriophora (HP88, Lewiston, and Oswego strains); H. indica (Homl strain); H. marelatus (Point Reyes strain); H. megidis (UK211 strain); and H. zealandica (NZH3 strain) have potential to kill larvae and adults of P. interpunctella.

For more information on biological control of stored grain pets with entomopathogenice nematodes; please read following research papers:

Athanassiou CG, Palyvos NE, Kakoull-Duarte T. 2008. Insecticidal effect of Steinernema feltiae (Filipjev) (Nematoda : Steinernematidae) against Tribolium confusum du Val (Coleoptera : Tenebrionidae) and Ephestia kuehniella (Zeller) (Lepidoptera: Pyralidae) in stored wheat  Journal of Stored Products Research. 44: 52-57.

Mbata, G.N., and Shapiro-Ilan, D.I. 2005. Laboratory evaluation of virulence of heterorhabditid nematodes to Plodia interpunctella Hübner (Lepidoptera: Pyralidae). Environmental Entomology 34: 676 – 682.

Ramos-Rodríguez, O., Campbell, J. F., and Ramaswamy, S. 2006. Pathogenicity of three species of entomopathogenic nematodes to some major stored- product insect pest. Journal of Stored Product Research 42: 241 – 252.

Ramos-Rodríguez,O.,Campbell, J. F.,and Ramaswamy, S. 2007. Efficacy of the   entomopathogenic nematodes Steinernema riborave against the stored-product pests Tribolium castaneum and Plodia interpunctella. Biological Control 40:15 -21.

Tradan, S., Vidric, M., and Valic, N. 2006. Activity of four entomopathogenic nematodes against young adult of Sitophilus granarious (Coleptera: Curculionidae ) and Oryzophilus surinamensis ( Coleoptera: Silvanidae ) under laboratory condition. Plant Disease and Protection. 113: 168 – 173.