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Classical biological control of an invasive forest pest: a world perspective of the management of Sirex noctilio using the parasitoid Ibalia leucospoides (Hymenoptera: Ibaliidae)

Published online by Cambridge University Press:  13 June 2014

D. Fischbein*
Affiliation:
Grupo de Ecología de Poblaciones de Insectos, Instituto Nacional de Tecnología Agropecuaria, Estación Experimental San Carlos de Bariloche, Bariloche, Argentina
J.C. Corley
Affiliation:
Grupo de Ecología de Poblaciones de Insectos, Instituto Nacional de Tecnología Agropecuaria, Estación Experimental San Carlos de Bariloche, Bariloche, Argentina
*
*Author for correspondence Phone: +54 294 442-2731 Fax: +54 294-4422731 E-mail: [email protected]

Abstract

Classical biological control is a key method for managing populations of pests in long-lived crops such as plantation forestry. The execution of biological control programmes in general, as the evaluation of potential natural enemies remains, to a large extent, an empirical endeavour. Thus, characterizing specific cases to determine patterns that may lead to more accurate predictions of success is an important goal of the much applied ecological research. We review the history of introduction, ecology and behaviour of the parasitoid Ibalia leucospoides. The species is a natural enemy of Sirex noctilio, one of the most important pests of pine afforestation worldwide. We use an invasion ecology perspective given the analogy between the main stages involved in classical biological control and the biological invasion processes. We conclude that success in the establishment, a common reason of failure in biocontrol, is not a limiting factor of success by I. leucospoides. A mismatch between the spread capacity of the parasitoid and that of its host could nevertheless affect control at a regional scale. In addition, we suggest that given its known life history traits, this natural enemy may be a better regulator than suppressor of the host population. Moreover, spatial and temporal refuges of the host population that may favour the local persistence of the interaction probably reduce the degree to which S. noctilio population is suppressed by the parasitoid. We emphasize the fact that some of the biological attributes that promote establishment may negatively affect suppression levels achieved. Studies on established non-native pest–parasitoid interactions may contribute to defining selection criteria for classical biological control which may prove especially useful in integrated pest management IPM programmes of invasive forest insects.

Type
Research Papers
Copyright
Copyright © Cambridge University Press 2014 

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References

Bain, J., Sopow, S.L. & Bulman, L.S. (2012) The Sirex woodwasp in New Zealand: history and current status. pp. 167173 in Slippers, B., de Groot, P. & Wingfield, M.J. (Eds) The Sirex Woodwasp and its Fungal Symbiont: Research and Management of a Worldwide Invasive Pest. Dordrecht, Netherlands, Springer.Google Scholar
Beddington, J.R., Free, C.A. & Lawton, J.H. (1978) Characteristics of successful natural enemies in models of biological control of insect pests. Nature 273, 513519.Google Scholar
Beèche, M., Lanfranco, D., Zapata, M. & Ruiz, C. (2012) Surveillance and control of the Sirex woodwasp: the chilean experience. pp. 229245 in Slippers, B., de Groot, P. & Wingfield, M.J. (Eds) The Sirex Woodwasp and its Fungal Symbiont: Research and Management of a Worldwide Invasive Pest. Dordrecht, Netherlands, Springer.Google Scholar
Bernstein, C. & Jervis, M.A. (2008) Food-searching in parasitoids: the dilemma of choosing between ‘immediate’ or future fitness gains. pp. 129171 in Wajnberg, E., Bernstein, C. & Van Alphen, J.J.M. (Eds) Behavioral Ecology of Insect Parasitoids: from Theoretical Approaches to Field Applications. Oxford, UK, Blackwell Publishing.Google Scholar
Berryman, A.A. (1987) The theory and classification of outbreaks. pp. 330 in Barbosa, P. & Schultz, J. (Eds) Insect Outbreaks. San Diego, USA, Academic Press.Google Scholar
Boissin, E., Hurley, B., Wingfield, M.J., Vasaitis, R., Stenlid, J., Davis, C., Stenlid, J., Davis, C., de Groot, P., Ahumada, R., Carnegie, A., Goldarazena, A., Klasmer, P., Wermelinger, B. & Slippers, B. (2012) Retracing the routes of introduction of invasive species: the case of the Sirex noctilio woodwasp. Molecular Ecology 21, 57285744.Google Scholar
Bruzzone, O.A., Villacide, J.M., Bernstein, C. & Corley, J.C. (2009) Flight variability in the woodwasp Sirex noctilio (Hymenoptera: Siricidae): an analysis of flight data using wavelets. The Journal of Experimental Biology 212, 731737.Google Scholar
Cameron, E.A. (2012) Parasitoids in the management of Sirex noctilio: looking back and looking ahead. pp. 103117 in Slippers, B., de Groot, P. & Wingfield, M.J. (Eds) The Sirex Woodwasp and its Fungal Symbiont: Research and Management of a Worldwide Invasive Pest. Dordrecht, Netherlands, Springer.CrossRefGoogle Scholar
Carnegie, A.J., Eldridge, R.H. & Waterson, D.G. (2005) History and management of Sirex woodwasp in pine plantations in New South Wales, Autralia. New Zealand Journal of Forestry Science 35, 324.Google Scholar
Collett, N.G. & Elms, S. (2009) The control of Sirex wood wasp using biological control agents in Victoria, Australia. Agricultural and Forest Entomology 11, 283294.Google Scholar
Corley, J.C. & Bruzzone, O.A. (2009) Delayed emergence and the success of parasitoids in biological control. Biological Control 51, 471474.Google Scholar
Corley, J.C. & Jervis, M.A. (2012) Forest pest management. A global challenge. International Journal of Pest Management 58, 193194.Google Scholar
Corley, J.C. & Villacide, J.M. (2012) Population dynamics of Sirex noctilio: influence of diapause, spatial aggregation and flight potential on outbreaks and spread. pp. 5164 in Slippers, B., de Groot, P. & Wingfield, M.J. (Eds) The Sirex Woodwasp and its Fungal Symbiont: Research and Management of a Worldwide Invasive Pest. Dordrecht, Netherlands, Springer.Google Scholar
Corley, J.C., Capurro, A.F. & Bernstein, C. (2004) Prolonged diapause and the stability of host – parasitoid interactions. Theoretical Population Biology 65, 193203.Google Scholar
Corley, J.C., Villacide, J.M. & Bruzzone, O.A. (2007) Spatial dynamics of a Sirex noctilio woodwasp population within a pine plantation in Patagonia, Argentina. Entomologia Experimentalis et Applicata 125, 231236.CrossRefGoogle Scholar
Corley, J.C., Villacide, J.M. & Nouhuys, S. (2010) Patch time allocation by a parasitoid: the influence of con-specifics, host abundance and distance to the patch. Journal of Insect Behavior 23, 431440.Google Scholar
Coutts, M.P. (1969) The mechanism of pathogenicity of Sirex noctilio on Pinus radiata. II. Effects of S. noctilio mucus. Australian Journal of Biological Sciences 22, 11531161.Google Scholar
Desouhant, E., Driessen, G., Amat, I. & Bernstein, C. (2005) Host and food searching in a parasitic wasp Venturia canescens: a trade-off between current and future reproduction? Animal Behaviour 70, 145152.Google Scholar
de Groot, P., Nystrom, K. & Scarr, T. (2007) Discovery of Sirex noctilio (Hymenoptera: Siricidae) in Ontario, Canada. Great Lakes Entomologist 39, 4953.Google Scholar
Ellers, J., Van Alphen, J.J.M. (1997) Life history evolution in Asobara tabida: plasticity in allocation of fat reserves to survival and reproduction. Journal of Evolutionary Biology 10, 771785.Google Scholar
Engelkes, T. & Mills, N.J. (2011) A conceptual framework for understanding arthropod predator and parasitoid invasions. BioControl 56, 383393.Google Scholar
Eskiviski, E.R., Núñez Cresto, M., Olmedo, D. & del Rosario de Coll, O. (2004) Biological aspect of Sirex noctilio F. and Ibalia leucospoides H. parasitism in forest plantations of Pinus sp. in Santo Tome, Corrientes. in XI Jornadas Técnicas Forestales y Ambientales, UNaM, EEA INTA Montecarlo. Argentina.Google Scholar
Fauvergue, X. & Hopper, K.R. (2009) French wasps in the new world: experimental biological control introductions reveal a demographic Allee effect. Population Ecology 51, 385397.Google Scholar
Fauvergue, X., Vercken, E., Malausa, T. & Hufbauer, R.A. (2012) The biology of small, introduced populations, with special reference to biological control. Evolutionary Applications 5, 424443.CrossRefGoogle ScholarPubMed
Fernández-Arhex, V. & Corley, J.C. (2005) The functional response of Ibalia leucospoides (Hymenoptera: Ibaliidae), a parasitoid of Sirex noctilio (Hymenoptera: Siricidae). Biocontrol Science and Technology 15, 16.Google Scholar
Fernández-Arhex, V. & Corley, J.C. (2010) The effects of patch richness on con-specific interference in the parasitoid Ibalia leucospoides (Hymenoptera: Ibaliidae). Insect Science 17, 379385.Google Scholar
Fischbein, D., Corley, J.C., Villacide, J.M. & Bernstein, C. (2011) The influence of food and con-specifics on the flight potential of the parasitoid Ibalia leucospoides . Journal of Insect Behavior 24, 456467.Google Scholar
Fischbein, D., Bettinelli, J., Bernstein, C. & Corley, J.C. (2012) Patch choice from a distance and use of habitat information during foraging by the parasitoid Ibalia leucospoides . Ecological Entomology 37, 161168.Google Scholar
Fischbein, D., Bernstein, C. & Corley, J.C. (2013) Linking reproductive and feeding strategies in the parasitoid Ibalia leucospoides: does feeding always imply profit? Evolutionary Ecology 27, 619634.Google Scholar
Greathead, D.J., Greathead, A.H. (1992) Biological control of insect pests by insect parasitoids and predators: the BIOCAT database. Biocontrol News and Information 13, 6168.Google Scholar
Grevstad, F.S. (1999 a) Factors influencing the chance of population establishment: implications for release strategies in biocontrol. Ecological Applications 9, 14391447.Google Scholar
Grevstad, F.S. (1999 b) Experimental invasions using biological control introductions : the influence of release size on the chance of population establishment. Biological Invasions 1, 313323.Google Scholar
Haugen, D.A. (1990) Control procedures for Sirex noctilio in the Green Triangle: review from detection to severe outbreak (1977–87). Australian Forestry 53, 2432.Google Scholar
Heimpel, G.E. & Asplen, M.K. (2011) A ‘Goldilocks’ hypothesis for dispersal of biological control agents. BioControl 56, 441450.Google Scholar
Hoebeke, E.R., Haugen, D.A. & Haack, R.A. (2005) Sirex noctilio: discovery of a palearctic siricid woodwasp in New York. Newsletter of the Michigan Entomological Society 50, 2425.Google Scholar
Hopper, K.R. & Roush, R.T. (1993) Mate finding, dispersal, number released, and the success of biological control introductions. Ecological Entomology 18, 321331.Google Scholar
Hurley, B.P., Slippers, B. & Wingfield, M.J. (2007) A comparison of control results for the alien invasive woodwasp, Sirex noctilio, in the southern hemisphere. Agricultural and Forest Entomology 9, 159171.Google Scholar
Hurley, B.P., Croft, P., Verleur, M., Wingfield, M.J. & Slippers, B. (2012) The control of the Sirex woodwasp in diverse environments: the South African Experience. pp. 247264 in Slippers, B., de Groot, P. & Wingfield, M.J. (Eds) The Sirex Woodwasp and its Fungal Symbiont: Research and Management of a Worldwide Invasive Pest. Dordrecht, Netherlands, Springer.CrossRefGoogle Scholar
Iede, E.T., Penteado, S.R. & Filho, W.R. (2010) Sirex research and management in South America. pp. 3234. in Proceedings 21st U.S. Department of Agriculture Interagency Research Forum on Invasive Species. 12–15 January, Annapolis, MD, USA.Google Scholar
Iede, E.T., Penteado, S.R.C. & Filho, W.R. (2012) The woodwasp Sirex noctilio in Brazil: monitoring and control. pp. 217228 in Slippers, B., de Groot, P. & Wingfield, M.J. (Eds) The Sirex Woodwasp and its Fungal Symbiont: Research and Management of a Worldwide Invasive Pest. Dordrecht, Netherlands, Springer.Google Scholar
Kidd, N.A.C. & Jervis, M.A. (2005) Population dynamics. pp. 504523 in Jervis, M.A. (Ed.) Insects as Natural Enemies: a Practical Perspective. Dordrecht, Netherlands, Springer.Google Scholar
Klasmer, P., Fritz, G., Corley, J.C. & Botto, E. (1998) Current status of research on Sirex noctilio F. in the Andean-Patagonian region in Argentina. pp. 8990. in Proceeding of a Conference: Training in the Control of Sirex noctilio by Use of Natural Enemies USDA Forest Service. Colombo, Brazil.Google Scholar
Lantschner, M.V., Villacide, J.M., Garnas, J.R., Croft, P., Carnegie, A.J., Liebhold, A.M. & Corley, J.C. (2014) Temperature explains variable spread rates of the invasive woodwasp Sirex noctilio in the Southern Hemisphere. Biological Invasions 16, 329339.Google Scholar
Lee, J.C. & Heimpel, G.E. (2008 a) Floral resources impact longevity and oviposition rate of a parasitoid in the field. Journal of Animal Ecology 77, 565572.Google Scholar
Lee, J.C. & Heimpel, G.E. (2008 b) Effect of floral nectar, water, and feeding frequency on Cotesia glomerata longevity. BioControl 53, 289294.CrossRefGoogle Scholar
Liebhold, A.M. (2012) Forest pest management in a changing world. International Journal of Pest Management 58, 289295.Google Scholar
Liebhold, A.M. & Tobin, P.C. (2008) Population ecology of insect invasions and their management. Annual Review of Entomology 53, 387408.Google Scholar
Lockwood, J.L., Cassey, P. & Blackburn, T. (2005) The role of propagule pressure in explaining species invasions. Trends in Ecology and Evolution 20, 223228.Google Scholar
Lockwood, J.L., Hoopes, M.F. & Marchetti, M.P. (Eds) (2007) Invasion Ecology. Oxford, UK, Blackwell Publishing Ltd.Google Scholar
Madden, J.L. (1968 a) Physiological aspects of host tree favourability for the woodwasp, Sirex noctilio F. Proceedings of the Ecological Society of Australia 3, 147149.Google Scholar
Madden, J.L. (1968 b) Behavioural responses of parasites to the symbiotic fungus associated. Nature 218, 189190.Google Scholar
Madden, J.L. (1981) Egg and larval development in the woodwasp Sirex noctilio F. Australian Journal of Zoology 29, 493506.Google Scholar
Madden, J.L. (1988) Sirex in Australasia. in Berryman, A.A. (Ed.) Dynamics of Forest Insect Populations: Patterns, Causes and Implications. New York, USA, Plenum Press.Google Scholar
Madden, J.L. & Coutts, M.P. (1979) The role of fungi in the biology and ecology of woodwasps (Hymenoptera: Siricidae). pp. 165174 in Batra, L.R. (Ed.) Insect–Fungus Symbiosis. Allanheld, Osmun & Co., Montclair.Google Scholar
Martínez, A.S., Fernández-Arhex, V. & Corley, J.C. (2006) Chemical information from the fungus Amylostereum areolatum and host-foraging behaviour in the parasitoid Ibalia leucospoides . Physiological Entomology 31, 336340.Google Scholar
Masciocchi, M. & Corley, J. (2012) Distribution, dispersal and spread of the invasive social wasp (Vespula germanica) in Argentina. Austral Ecology 38, 162168.Google Scholar
Menu, F., Roebuck, J.P. & Viala, M. (2000) Bet-hedging diapause strategies in stochastic environments. The American Naturalist 155, 724734.Google Scholar
Mills, N.J. (1994) Biological control: some emerging trends. pp. 213–22 in Leather, S.R., Watt, A.D., Mills, N.J. & Walters, K.F.A. (Eds) Individuals, Populations and Patterns in Ecology. Andover, UK, Intercept.Google Scholar
Mills, N.J. (2001) Factors influencing top-down control of insect pest populations in biological control systems. Basic and Applied Ecology 2, 323332.Google Scholar
Murdoch, W.W., Chesson, J. & Chesson, P.L. (1985) Biological control in theory and practice. American Naturalist 125, 344366.CrossRefGoogle Scholar
Neumann, F.G. & Minko, G. (1981) The sirex wood wasp in Australian radiata pine plantaions. Australian Forestry 44, 4663.Google Scholar
Nuttall, M.J. (1970) Rearing and liberation of parasites of Sirex noctilio 1966–1970. New Zealand Forestry Research Institute, Institute Forest Entomology, Report No. 26, 1970 (unpublished).Google Scholar
Nuttall, M.J. (1972) Culture, liberation and establishment of Ibalia leucospoides in New Zealand. New Zealand Forest Service, Forest Research Institute, Forest Entomology Report No. 31, 1972 (unpublished).Google Scholar
Pietrantuono, A.L., Fernández-Arhex, V., Jofré, N. & Corley, J.C. (2012) Food and host searching decisions made by Ibalia leucospoides (Hymenoptera: Ibaliidae), a parasitoid of Sirex noctilio (Hymenoptera: Siricidae). Journal of Insect Behavior 25, 320327.Google Scholar
Rawlings, G.B. (1951) The establishment of Ibalia leucospoides in New Zealand. New Zealand Forestry Research Notes 1, 114.Google Scholar
Rawlings, G.B. (1952) Progress in establishment of Ibalia leucospoides, a parasite of Sirex noctilio, the horntail borer of pine. New Zealand Science Review 10, 107108.Google Scholar
Ryan, K. & Hurley, B.P. (2012) Life history and biology of Sirex noctilio . pp. 1530 in Slippers, B., de Groot, P. & Wingfield, M.J. (Eds) The Sirex Woodwasp and its Fungal Symbiont: Research and Management of a Worldwide Invasive Pest. Dordrecht, Netherlands, Springer.Google Scholar
Siekmann, G., Tenhumberg, B. & Keller, M.A. (2001) Feeding and survival in parasitic wasps: sugar concentration and timing matter. Oikos 95, 425430.Google Scholar
Simberloff, D. (2009) The role of propagule pressure in biological invasions. Annual Review of Ecology, Evolution and Systematics 40, 81102.Google Scholar
Slippers, B., Hurley, B.P., Mlonyeni, O.X., de Groot, P. & Wingfield, M.J. (2012) Factors affecting the efficacy of Deladenus siricidicola in biological control systems. pp. 119133. in Slippers, B., de Groot, P. & Wingfield, M.J. (Eds) The Sirex Woodwasp and its Fungal Symbiont: Research and Management of a Worldwide Invasive Pest. Dordrecht, Netherlands, Springer.Google Scholar
Spradbery, J.P. (1974) The responses of Ibalia species (Hymenoptera: Ibaliidae) to the fungal symbionts of siricid woodwasp hosts. Journal of Entomology 48, 217222.Google Scholar
Spradbery, J.P. & Kirk, A.A. (1978) Aspects of the ecology of siricid woodwasps (Hymenoptera: Siricidae) in Europe, North Africa and Turkey with special reference to the biological control of Sirex noctilio F. in Australia. Bulletin of Entomological Research 68, 341359.Google Scholar
Taylor, K.L. (1967) The introduction, culture, liberation, and recovery of parasites of Sirex noctilio in Tasmania, 1962–67. Technical Paper 8. CSIRO Division of Entomology, Australia.Google Scholar
Taylor, K.L. (1976) The introduction and establishment of insect parasitoids to control Sirex noctilio in Australia. Entomophaga 21, 429440.Google Scholar
Taylor, K.L. (1978) Evaluation of the insect parasitoids of Sirex noctilio (Hymenoptera: Siricidae) in Tasmania. Oecologia 32, 110.CrossRefGoogle ScholarPubMed
Tribe, G.D. & Cillié, J. (2004) The spread of Sirex noctilio Fabricius (Hymenoptera: Siricidae) in South African pine plantations and the introduction and establishment of its biological control agents. African Entomology 12, 917.Google Scholar
van den Bosch, R. (1971) Biological control of insects. Annual Review of Ecology and Systematics 2, 4566.Google Scholar
Villacide, J.M. & Corley, J.C. (2003) Distribución potencial del parasitoide Ibalia leucospoides (Hymenoptera : Ibaliidae) en la Argentina. Quebracho 10, 713.Google Scholar
Villacide, J.M. & Corley, J.C. (2012) Ecology of the woodwasp Sirex noctilio: tackling the challenge of successful pest management. International Journal of Pest Management 58, 249256.Google Scholar
Zondag, R. (1959) Progress report on the establishmnet in New Zealand of Ibalia leucospoides, a parasite of Sirex noctilio . New Zealand Forestry Research Notes 20, 111.Google Scholar