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Atmospheric change: effect on plant pests and diseases

Published online by Cambridge University Press:  23 August 2011

J.N.B. Bell ,
S. McNeill ,
G. Houlden ,
V. C. Brown  and
P. J. Mansfield
J.N.B. Bell
Affiliation:
Department of Biology, Imperial College at Silwood Park, Ascot, Berkshire SL5 7PY, UK
S. McNeill
Affiliation:
Department of Biology, Imperial College at Silwood Park, Ascot, Berkshire SL5 7PY, UK
G. Houlden
Affiliation:
Department of Biology, Imperial College at Silwood Park, Ascot, Berkshire SL5 7PY, UK
V. C. Brown
Affiliation:
Department of Biology, Imperial College at Silwood Park, Ascot, Berkshire SL5 7PY, UK
P. J. Mansfield
Affiliation:
Department of Biology, Imperial College at Silwood Park, Ascot, Berkshire SL5 7PY, UK
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Summary

The atmosphere plays a key role in plant disease, but only recently has it become understood that atmospheric pollutants can influence the response of plants to attack by pests and pathogens. This paper reviews the evidence for this phenomenon, considering impacts of sulphur dioxide, nitrogen dioxide and ozone, mainly on fungal pathogens and aphid pests. Field observations in polluted areas have indicated changes in abundance of pests and pathogens and in some cases a causal link has been demonstrated in controlled experiments. A major study is described in which consistent marked positive impacts of SO2 and NO2 have been shown on a range of British agricultural aphid pests, using four different approaches: fumigations, nitration studies, exposure along air pollution gradients and a nation-wide field survey. Ozone, in contrast, produces a more complex range of responses. These effects are apparently mediated via chemical changes in the plant. Fungal pathogens show both positive and negative responses to air pollutants. A study is described in which these opposite responses in two different fungal species were observed in a field SO2–fumigation system and confirmed in controlled laboratory fumigations. Models are presented to describe the complex pathways by which air pollutants could influence host plant performance via impacts on pests and pathogens.

Keywords

air pollutionplant pestsplant pathogens
Type
Research Article
Information
Parasitology , Volume 106 , supplement S1: Symposia of the British Society for Parasitology Volume 30 The impact of global change on disease , January 1993 , pp. S11 - S24
Copyright
Copyright © Cambridge University Press 1993

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References

REFERENCES

Alstad, D. N., Edmunds, G. G. & Weinstein, L. H. (1982). Effects of air pollutants on insect populations. Annual Review of Entomology 27, 369–84.CrossRefGoogle Scholar
Aminu-KANO, M. (1987). Pollution/plant/pest interactions: sulphur dioxide, winter cereals and the grain aphid Sitobion avenae (F.). PhD thesis, University of London.Google Scholar
Ashmore, M. R. (1984). Ozone. In Proceedings of an International Workshop on the Evaluation and Assessment of the Effects of Photochemical Oxidants on Human Health, Agricultural Crops, Forestry, Materials and Visibility (ed. Grennfelt, P.), pp. 92104. Gothenburg: Swedish Environmental Research Institute.Google Scholar
Ashmore, M. R., Brown, V. C., Kristiansen, C. & Shah, D. (1988). Effects of ambient air pollution, water stress and aphid pests on Vicia faba. In The European Communities Research Project on Open-Top Chambers Results on Agricultural Crops 1987-1988. Air Pollution Research Report 19 (ed. Bonte, J. & Mathy, P.). Brussels: Commission of the European Communities.Google Scholar
Bazzaz, F. A. (1990). The response of natural ecosystems to the rising global CO2 levels. Annual Review of Ecology and Systematics 21, 167–96.CrossRefGoogle Scholar
Bolsinger, M. & Fluckiger, W. (1989). Ambient air pollution induced changes in amino acid pattern of phloem sap in host plants-relevance to aphid infestation. Environmental Pollution 56, 209–35.CrossRefGoogle ScholarPubMed
Braun, S. & Fluckiger, W. (1989). Effects of ambient ozone and acid mist on aphid development. Environmental Pollution 56, 177–87.CrossRefGoogle ScholarPubMed
Brough, A., Parry, M. & Whittingham, C. P. (1978). The influence of aerial pollution on crop growth. Chemistry and Industry 21 January, 51–3.Google Scholar
Brown, V. C. & Bell, J. N. B. (1990). The value of closed chamber experiments for studying biotic interactions with plants and air pollution. In Environmental Research with Plants in Closed Chambers, Air Pollution Research Report 26 (ed. Payer, H. D., Pfirrman, T. & Mathy, P.), pp. 322–9. Brussels: Commission of the European Communities.Google Scholar
Brown, V. C., Mcneill, S. & Ashmore, M. R. (1992). The effects of ozone fumigation on the performance of the black bean aphid, Aphis fabae Scop., feeding on broad beans, Vicia faba. Agriculture, Ecosystems and Environment 38, 71–8.CrossRefGoogle Scholar
Carter, C. (1988). Summary of a Workshop Meeting on Aphids and Conifers. Farnham: Forestry Commission.Google Scholar
Decourt, N., Malphettes, C. B., Perrin, R. & Caron, D. (1980). La pollution soufrée limite-t-elle le développement de la maladie de l'écorce du hêtre? (Cryptococcus fagi, Nectria coccined). Annales des Sciences Forestieres 37, 135–45.CrossRefGoogle Scholar
Dohmen, G. P., Mcneill, S. & Bell, J. N. B. (1984). Air pollution increases Aphis fabae pest potential. Nature 307, 52–3.CrossRefGoogle Scholar
Dowding, P. (1984). Air pollutant effects on plant pathogens. In Air Pollution and Plant Metabolism (ed. Schulte-Hostede, S., Darrall, N. M., Blank, L. W. & Wellburn, A. R.), pp. 329–55. London and New York: Elsevier.Google Scholar
Evans, P. A. & Ashmore, M. R. (1992). The effects of ambient air on a semi-natural grassland community. Agriculture, Ecosystems and Environment 38, 91–7.CrossRefGoogle Scholar
Fajer, E. D., Bowers, M. D. & Bazzaz, F. A. (1991). The effect of enriched CO2 atmospheres on the buckeye butterfly, Junonia coenia. Ecology 72, 751–4.CrossRefGoogle Scholar
Fluckiger, W., Oertli, J. J. & Baltensweiler, W. (1978). Observations on aphid infestation on hawthorn in the vicinity of a motorway. Naturwissenschaften 65, 654–5.CrossRefGoogle Scholar
Grzywacz, A. & Wazny, J. (1973). The impact of industrial air pollutants on several important pathogenic fungi. European Journal of Forest Pathology 3, 129–41.CrossRefGoogle Scholar
Heagle, A. S. (1970). Effects of low-level ozone fumigation on crown rot of oats. Phytopathology 60, 252–4.CrossRefGoogle Scholar
Heagle, A. S. (1973). Interactions between air pollutants and plant parasites. Annual Review of Phytopathology 11, 365–88.CrossRefGoogle Scholar
Heagle, A. S. (1982). Interactions between air pollutants and parasitic plant disease. In Effects of Gaseous Air Pollution in Agriculture and Horticulture (ed. Unsworth, M. H. & Ormrod, D. P.), pp. 333–48. London: Butterworths.CrossRefGoogle Scholar
Heagle, A. S. & Strickland, A. (1972). Reaction of Erysiphe graminis f.sp. hordei to low levels of ozone. Phytopathology 62, 1144–8.CrossRefGoogle Scholar
Hibben, C. R. & Taylor, M. P. (1975). Ozone and sulphur dioxide effects on the lilac powdery mildew fungus. Environmental Pollution 9, 107–14.Google Scholar
Hibben, C. R. & Walker, J. T. (1966). A leaf roll-necroses complex of lilacs in an urban environment. Journal of the American Society for Horticultural Science 89, 636–42.Google Scholar
Hiltbrunner, E. & Fluckiger, W. (1992). Altered feeding preference of beech weevil Rhynchaenus fagi L. for beech foliage under ambient pollution. Environmental Pollution 75, 333–6.CrossRefGoogle Scholar
Houlden, G., Bell, J. N. B. & Mcneill, S. (1993a). Air pollution and agricultural aphid pests. III. Field transect studies along air pollution gradients. Environmental Pollution (in preparation).Google Scholar
Houlden, G., Mcneill, S., Aminu-KANO, M. & Bell, J. N. B. (1990). Air pollution and agricultural aphid pests. I. Fumigation experiments with SO2 and NO2 67, 305–14.Google ScholarPubMed
Houlden, G., Mcneill, S. & Bell, J. N. B. (1993b). Air pollution and agricultural aphid pests. IV. An extensive field survey of aphids in relation to revailing SO2 concentrations. Environmental Pollution (in preparation).Google Scholar
Houlden, G., Mcneill, S., Craske, A. & Bell, J. N. B. (1991). Air pollution and agricultural aphid pests. II. Chamber filtration experiments. Environmental Pollution 72, 4555.CrossRefGoogle ScholarPubMed
Hughes, P. R. & Laurence, J. A. (1984). Relationship of biochemical effects of air pollutants on plants to environmental problems: insect and microbial interactions. In Gaseous Air Pollutants and Plant Metabolism (ed. Koziol, M. J. & Whatley, F. R.), pp. 361–77. London: Butterworths.CrossRefGoogle Scholar
James, R. L., Cobb, F. W., Miller, P. R. & Parmeter, J. R. (1980). Effects of oxidant air pollution on susceptibility of pine roots to Fomes annosus. Phytopathology 70, 560–3.CrossRefGoogle Scholar
Kock, G. (1935). Eichenmeltau und Rauchgasschaden. Zeitschrift für Pflanzenkrankheiten 45, 44–5.Google Scholar
Kvist, K. (1986). Fungal pathogens interacting with air pollutants in agricultural crop production. In How are the Effects of Air Pollutants on Agricultural Crops Influenced by the Interaction with Other Limiting Factors? pp. 6778. Brussels: Commission of the European Communities.Google Scholar
Laurence, J. A. (1981). Effect of air pollutants on plant-pathogen interactions. Zeitschrift für Pflanzenkrankheiten und Pflanzenschutz, 87, 156–72.Google Scholar
Laurence, J. A., Weinstein, L. H., Mccune, D. C. & Aluisio, A. L. (1979). Effects of sulfur dioxide on southern corn leaf blight of maize and stem rust of wheat. Plant Disease Reporter 63, 975–8.Google Scholar
Mcleod, A. R., Roberts, T. M., Alexander, K. & Cribb, D. M. (1991). The yield of winter cereals exposed to sulphur dioxide under field conditions. Agriculture Ecosystems and Environment 33, 193213.CrossRefGoogle Scholar
Mcneill, S. & Whittaker, J. B. (1990). Air pollution and tree-dwelling aphids. In Population Dynamics of Forest Insects (ed. Watt, A. D., Leather, S. R., Hunter, M. D. & Kidd, N. A. C.), pp. 195208. Andover: Intercept.Google Scholar
Manning, W. J., Feder, W. A. & Perkins, I. (1970). Ozone and infection of geranium flowers by Botrytis cinerea. Phytopathology 60, 1302.CrossRefGoogle Scholar
Manning, W. J., Feder, W. A., Perkins, I. & Gluckman, M. (1969). Ozone injury and infection to potato leaves by Botrytis cinerea. Plant Disease Reporter 53, 691–3.Google Scholar
Manning, W. J. & Keane, K. D. (1988). Effects of air pollutants on interactions between plants, insects and pathogens. In Assessment of Crop Loss from Air Pollutants (ed. Heck, W. W., Taylor, O. C. & Tingey, D. T.), pp. 365–86. London and New York: Elsevier.CrossRefGoogle Scholar
Mansfield, P. J. (1989). Interactions of atmospheric sulphur dioxide with fungal diseases of winter barley. PhD thesis, University of London.Google Scholar
Mansfield, P. J., Bell, J. N. B., Mcleod, A. R. & Wheeler, B. E. J. (1991). Effects of sulphur dioxide on the development of fungal diseases of winter barley in an open-air fumigation system. Agriculture, Ecosystems and Environment 33, 215–32.CrossRefGoogle Scholar
Mattson, W. T. (1980). Herbivory in relation to plant nitrogen content. Annual Review of Ecological Systematics 11, 119–61.CrossRefGoogle Scholar
Port, G. R. (1981). Auchenorrhynca on roadside verges. A preliminary survey. Acta Entomologica Fennica 38, 29.Google Scholar
Port, G. R. & Thompson, J. R. (1980). Outbreak of insect herbivores on plants along motorways in the United Kingdom. Journal of Applied Ecology 17, 649–56.CrossRefGoogle Scholar
Przybylski, Z. (1967). Results of consecutive observations of effect of SO2, SO3 and H2SO4 on fruit trees and some harmful insects near the sulfur mine and sulfur processing plant at Machrowner Tarnobrzega. Advances in Agricultural Science, Warsaw 14, 111–18.Google Scholar
Przybylski, Z. (1979). The effects of automobile gases on the arthropods of cultivated plants. Environmental Pollution 19, 157–61.Google Scholar
Rich, S. & Tomlinson, H. (1968). Effects of ozone on conidiophores and conidia of Alternaria solani. Phytopathology 58, 444-6.Google ScholarPubMed
Riemer, J. & Whittaker, J. B. (1989). Air pollution and insect herbivores: observed interactions and possible mechanisms. Insect Plant Interactions 1, 73105.Google Scholar
Rosen, P. M. & Runeckles, V. C. (1976). Interaction of ozone and greenhouse whitefly in plant injury. Environmental Conservation 3, 70–1.CrossRefGoogle Scholar
Sanders, G. E., Colls, J. J., Clark, A. G., Galalup, S., Bonte, J. & Cantvel, J. (1992). Phaseolus vulgaris and ozone: results from open-top chamber experiments in France and England. Agriculture, Ecosystems and Environment 38, 3140.CrossRefGoogle Scholar
Saunders, P. J. W. (1966). The toxicity of sulphur dioxide to Diplocarpon rosae Wolf causing black spot on roses. Annals of Applied Biology 58, 103–14.CrossRefGoogle Scholar
Scheffer, T. C. & Hedgecock, G. G. (1955). Injury to North-western Forest Trees by Sulfur Dioxide from Smelters. U.S. Department of Agriculture, Technical Bulletin No. 1117.Google Scholar
Schenone, G. & Lorenzini, G. (1992). Effects of regional air pollution on crops in Italy. Agriculture, Ecosystems and Environment 38, 51–9.CrossRefGoogle Scholar
Stark, R. W., Miller, P. R., Cobb, F. W., Wood, D. L. & Parmeter, J. R. (1968). Incidence of bark beetle infestation in injured trees. Hilgardia 39, 121–6.CrossRefGoogle Scholar
Szerzen, J. (1981). Comparative study of phytopathogenic fungal microflora in three regions differing in the degree of pollution with industrial emissions. Polish Ecological Studies 7, 107–16.Google Scholar
Villemant, C. (1981). Influence de la pollution atmospherique sur les populations d'aphides du pin sylvestre en Foret de Roumare (Seine-Maritime). Environmental Pollution (Series A) 24, 245–62.CrossRefGoogle Scholar
Volz, A. & Kley, D. (1988). Evaluation of the Monsouris series of ozone measurements made in the nineteenth century. Nature 332, 240–2.CrossRefGoogle Scholar
Warrington, S., Cottam, D. A. & Whittaker, J. B. (1989). Effects of insect damage on photosynthesis, transpiration and SO2 uptake by sycamore. Oecologia 80, 136–9.CrossRefGoogle ScholarPubMed
Weidensaul, T. C. & Darling, S. L. (1979). Effects of ozone and sulphur dioxide on the host-pathogen relationship of Scotch pine and Scirrhia acicola. Phytopathology 69, 939–41.CrossRefGoogle Scholar
Weinstein, L. H., Mccune, D. C., Aluisio, M A. L. & Leuken, P. (1975). The effect of sulphur dioxide on the incidence and severity of bean root and early blight of tomato. Environmental Pollution 9, 145–55.Google Scholar
Wentzel, K. F. (1965). Insekten als Immissions Folgeschadingle. Naturwissenschaften 52, 113.CrossRefGoogle Scholar
Whittaker, J. B. & Warrington, S. (1990). Effects of atmospheric pollutants on interactions between insect pests and their food plants. In Pests, Pathogens and Plant Communities (ed. Burdon, J. J. & Leather, S. R.), pp. 97110. Oxford: Blackwell Scientific Publications.Google Scholar