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Biological control and holistic plant-health care in agriculture

Published online by Cambridge University Press:  30 October 2009

R. James Cook
R. James Cook
Affiliation:
Plant pathologist with the Root Disease and Biological Control Research Unit, Agricultural Research Service, U.S. Department of Agriculture, Washington State University, Pullman, WA 99164.
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Abstract

Biological control is defined broadly as the “use of natural or modified organisms, genes, or gene products” to reduce the effects of pests and diseases. Physical control is the use of tillage, open-field burning, heat-treatment (pasteurization), and other physical methods, usually to eliminate pests or separate them from the crop. Chemical control is the use of synthetic chemical pesticides to eliminate pests or reduce their effects. The many approaches to biological control can be categorized conceptionally into 1) regulation of the pest population (the classical approach), 2) exclusionary systems of protection (a living barrier of microorganisms on the plant or animal that deters infection or pest attack), and 3) systems of self-defense (resistance and immunization). The agents of biological control include the pest- or disease-agent itself (sterile males or avirulent strains of pathogens), antagonists or natural enemies, or the plant or animal managed or manipulated (immunized) to defend itself. The methods range from 1) conserving and making maximum use of indigenous (resident) biological control through cultural practices, 2) making one-time or occasional introductions of genes or natural enemies that are more or less self-sustaining and 3) making repeated introductions of a biocontrol agent (e.g. a microbial pesticide). Biological, physical, and chemical treatments and pest controls can be integrated into holistic plant-health care also known as integrated crop and pest management. Eight principles of plant health care are offered: 1) know the production limits of the agroecosystem; 2) rotate the crops; 3) maintain soil organic matter; 4) use clean planting material; 5) plant well-adapted, pest-resistant cultivars; 6) minimize environmental and nutritional stresses; 7) maximize the effects of beneficial organisms; and 8) protect with pesticides as necessary.

Keywords

plant diseasesfungibacteriavirusesnematodesplant breedingcultural practicestillageplanting datenon-pathogensbiocontrol agents
Type
Articles
Information
American Journal of Alternative Agriculture , Volume 3 , Issue 2-3 , Spring-Summer 1988 , pp. 51 - 62
Copyright
Copyright © Cambridge University Press 1988

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References

1.Abel, P., Nelson, R. S., Barun, D., Hoffman, N., Rogers, S. G., Fraley, R. T., and Beachy, R. N.. 1986. Delay of disease development in trans-genic plants that express the tobacco mosaic virus coat protein gene. Science. 232:738743.CrossRefGoogle Scholar
2.Allmaras, R. R., Kraft, J. M., and Miller, D. E.. 1988. Soil compaction and crop residue effects on root health. Ann. Rev. Phytopathol. 26:In press.CrossRefGoogle Scholar
3.Ashworth, L. J. Jr., Morgan, D. P., Gaona, S. A., and McCain, A. H.. 1982. Polyethylene tarping controls Verticillium wilt in pistachios. Calif. Agric. 36(56):1718.Google Scholar
4.Baker, K. F. 1962. Principles of heat treatment of soil and plant material. J. Aust. Inst. Agr. Sci. 28:118126.Google Scholar
5.Baker, K. F. 1987. Evolving concepts of biological control of plant pathogens. Ann. Rev. Phytopathol. 25:6785.CrossRefGoogle Scholar
6.Baker, K. F., and Cook, R. J.. 1974. Biological Control of Plant Pathogens, W. H. Freeman and Co., San Francisco, California. 433 pp. (Book, reprinted in 1982, Amer. Phytopathol. Soc., St. Paul, Minnesota).Google Scholar
7.Baker, K. F., and Linderman, R. G.. 1979. Unique features of the pathology of ornamental plants. Ann. Rev. of Phytopathol. 17:253277.CrossRefGoogle Scholar
8.Baker, R. 1985. Biological control of plant pathogens: Definitions, pp. 2539. In Hoy, M. A. and Herzog, D. C. (eds.). Biological Control in Agricultural IPM Systems. Academic Press, New York, New York. 600 pp.CrossRefGoogle Scholar
9.Beirner, B. P. 1967. Biological control and its potential. World Rev. Pest Control 6(1):720.Google Scholar
10.Biffen, R. H. 1906. Mendels law of inheritance and wheat breeding. J. Agric. Sci. 1:448.CrossRefGoogle Scholar
11.Blakeman, J. P., and Fokkema, N. J.. 1982. Potential for biological control of plant disease on the phylloplane. Ann. Rev. Phytopathol. 20:167192.CrossRefGoogle Scholar
12.Broadbent, P., and Baker, K. F.. 1975. Soils suppressive to Phytophthora root rot in eastern Australia, pp. 152157. In Bruehl, G. W. (ed.). Biology and Control of Soil-borne Plant Pathogens. Amer. Phytopathol. Soc., St. Paul, Minnesota. 216 pp.Google Scholar
13.Burke, D. W., Miller, D. W., Holmes, L. D., and Barker, A. W.. 1972. Counteracting bean root rot by loosening the soil. Phytopathology. 62:306309.CrossRefGoogle Scholar
14.Chet, I., and Baker, R.. 1981. Isolation and biocontrol potential of Trichoderma hamatum from soil naturally suppressive to Rhizoctonia solani. Phytopathology. 71:286290.CrossRefGoogle Scholar
15.Cook, R. J. 1973. Influence of low plant and soil water potentials on diseases caused by soilborne fungi. Phytopathology. 63:451457.Google Scholar
16.Cook, R. J. 1980. Fusarium foot rot of wheat and its control in the Pacific Northwest. Plant Disease. 64:10611066.CrossRefGoogle Scholar
17.Cook, R. J. 1984. Root health: Importance and Relations to Farming Systems. In Bezdicek, D. F. and Power, J. F. (eds.). Organic Farming: Current Technology and Its Role in a Sustainable Agriculture. Amer. Soc. Agron. Special Publications: No. 46, Madison, Wisconsin, pp. 111127.Google Scholar
18.Cook, R. J. 1985. Biological control of plant pathogens: theory to application. Phytopathology. 75:2529.CrossRefGoogle Scholar
19.Cook, R. J. 1986a. Interrelationships of plant health and the sustainability of agriculture, with special reference to plant diseases. Amer. J. Alter. Agri. 1:1924.CrossRefGoogle Scholar
20.Cook, R. J. 1986b. Plant health and the sustainability of agriculture, with special reference to disease control by beneficial microorganisms. Biol. Agric. and Horticulture 3:211232.CrossRefGoogle Scholar
21.Cook, R. J. 1986c. Wheat management systems in the Pacific Northwest. Plant Disease 70:894898.CrossRefGoogle Scholar
22.Cook, R. J., Chairman. 1987. Research Briefing Panel on Biological Control in Managed Ecosystems. Committee on Science, Engineering, and Public Policy, National Academy of Sciences, National Academy of Engineering, and Institute of Medicine. National Academy Press, Washington, DC. 12 pp.Google Scholar
23.Cook, R. J., and Baker, K. F.. 1983. The Nature and Practice of Biological Control of Plant Pathogens. Amer. Phytopathol. Soc., St. Paul, Minnesota. 539 pp.Google Scholar
24.Cook, R. James, and Rovira, A. D.. 1976. The role of bacteria in the biological control of Gaeumannomyces graminis by suppressive soils. Soil Biol. and Biochem. 8:269273.CrossRefGoogle Scholar
25.Cook, R. J., and Weller, D. M.. 1987. Management of take-all in consecutive crops of wheat or barley. In Chet, I. (ed.). Innovative Approaches to Plant Disease Control. John Wiley & Sons, Inc. pp. 4176.Google Scholar
26.Cook, R. J., Sitton, J. W., and Haglund, W. A.. 1987a. Increased growth and yield responses of wheat to reduction in the Pythium populations by soil treatments. Phytopathology 77:11921198.CrossRefGoogle Scholar
27.Cook, R. J., Weller, D. M., and Thomashow, L. S.. 1987b. Enhancement of root health and plant growth by rhizobacteria. In Molecular Strategies for Crop Protection. Alan R. Liss, Inc. pp. 125134.Google Scholar
28.Corke, A. T. K. 1978. Interactions between microorganisms. Ann. Appl. Biol. 89:8993.CrossRefGoogle Scholar
29.Costa, A. S., and Muller, G. W.. 1980. Tristeza control by cross protection: A U.S.-Brazil co-operative success. Plant Disease. 64:538541.CrossRefGoogle Scholar
30.DeBach, P., ed. 1964. Biological Control of Insect Pests and Weeds. Reinhold, New York, New York. 844 pp.Google Scholar
31.Fulton, R. W. 1986. Practices and precautions in the use of cross protection for plant virus disease control. Ann. Rev. Phytopathol. 24:6781.CrossRefGoogle Scholar
32.Gerlagh, M. 1968. Introduction of Ophiobolus graminis into new polders and its decline. Neth. Jour. Plant Pathol. 74:(Suppl. 2): 197.CrossRefGoogle Scholar
33.Grogan, R. G. 1980. Control of lettuce mosaic with virus-free seed. Plant Disease. 64:446449.CrossRefGoogle Scholar
34.Hardison, J. R. 1976. Fire and flame for plant disease control. Ann. Rev. Phytopathol. 14:355379.CrossRefGoogle Scholar
35.Hering, T. F., Cook, R. J., and Tang, W.-h.. 1987. Infection of wheat embryos by Pythium species during seed germination and the influence of seed age and soil matric potential. Phytopathology. 77:11041108.CrossRefGoogle Scholar
36.Hill, J. E. 1985. Methods for selecting beneficial Lactobacilli from swine. Advances in the Application of Microbiology to Agriculture. Pioneer Hi-Bred International, Inc., Microbial Genetics Division, Johnston, Iowa.Google Scholar
37.Holings, M. 1965. Disease control through virus-free stock. Ann. Rev. Phytopathol. 3:367389.CrossRefGoogle Scholar
38.Hwang, S. C., Chen, C. L., Lin, J. C.. 1984. Cultivation of bananas using plantlets from meristem culture. HortScience. 19:231233.CrossRefGoogle Scholar
39.Hyakumachi, M., and Ui, Tadao. 1982. Decline of damping-off of sugarbeet seedlings caused by Rhizoctonia solani AG-2-2. Ann. of the Phytopathol. Soc. of Japn. 48(5):600606.CrossRefGoogle Scholar
40.Jones, D., and Solomon, M. E., eds. 1974. Biology in Pest and Disease Control. Brit. Ecol. Soc. Symp. 13. 398 pp.Google Scholar
41.Katan, J. 1981. Solar heating (solarization of soil for control of soilborne pests). Ann. Rev. Phytopathol. 19:211236.CrossRefGoogle Scholar
42.Kerr, A. 1980. Biological control of crown gall through production of agrocin 84. Plant Disease. 64:2530.Google Scholar
43.Kuć, J. 1982. Induced immunity to plant disease. Bioscience. 32:854860.Google Scholar
44.Lindow, S. W. 1983. Methods of preventing frost injury caused by epiphytic ice nucleation active bacteria. Plant Disease. 67:327333.CrossRefGoogle Scholar
45.Lundholm, B., and Stackerud, M., eds. 1980. Environmental Protection and Biological Forms of Control of Pest Organisms. Swedish Natural Science Research Council Ecological Bulletins. 31:1171.Google Scholar
46.Lupton, F. G. H. 1984. Biological control: The plant breeder's objective. Ann. Appl. Biol. 104:116.CrossRefGoogle Scholar
47.Marx, D. H. 1972. Ectomycorrhizae as biological deterrents to pathogenic root infections. Ann. Rev. Phytopathol. 10:429454.CrossRefGoogle ScholarPubMed
48.McBeth, C. W., and Taylor, A. L.. 1944. Immune and resistant cover crops valuable in root-knot-infested peach orchards. Proc. Amer. Soc. Hort. Sci. 45:158166.Google Scholar
49.Miller, D. E., and Burke, D. W.. 1975. Effect of soil aeration on Fusarium root rot of beans. Phytopathology. 65:519523.Google Scholar
50.Papavizas, G. C., and Lumsden, R. D.. 1980. Biological control of soilborne fungal propagules. Ann. Rev. Phytopathol. 18:389413.CrossRefGoogle Scholar
51.Papendick, R. I., and Cook, R. J.. 1974. Plant water stress and development of Fusarium foot rot in wheat subjected to different cultural practices. Phytopathology 64:358361CrossRefGoogle Scholar
52.Payne, C. C. 1988. Pathogens for the control of insects-where next? In Wood, R. K. S. and Way, M. J. (eds.). Biological Control of Pests, Pathogens, and Weeds: Developments and Prospects. The Royal loc. Lond. pp. 115248.Google Scholar
53.Phillips, R. E., Bevine, R. L., Thomas, G. W., Freye, W. W., and Phillips, S. H.. 1980. Notillage agriculture. Science. 208:11081113.CrossRefGoogle ScholarPubMed
54.Reis, E. M., Cook, R. J., and McNeal, B. L.. 1982. Effect of mineral nutrition on take-all of wheat. Phytopathology. 72:224229.CrossRefGoogle Scholar
55.Rickman, R. W., Klepper, B., and Belford, R. K.. 1985. Developmental relationships among roots, leaves, and tillers in winter wheat. In Day, W. and Atkins, R. K. (eds.). Wheat Growth Modelling. Plenum Publishing, pp. 8398.Google Scholar
56.Riggs, R. D., Slack, D. A., Hamblen, M. L., and Rakes, L.. 1980. Nematode control studies in soybeans. Ark. Agric. Exp. Sta. Report series 252. 32 pp.Google Scholar
57.Rishbeth, J. 1979. Modern aspects of biological control of Fomes and Armillaria. Eur. J. For. Pathol. 9:331340.CrossRefGoogle Scholar
58.Roelfs, A. P. 1988. Genetic control of phenotypes in wheat stem rust. Ann. Rev. Phytopathol. 26:351367.CrossRefGoogle Scholar
59.Rouse, D. I. 1988. Use of crop-growth models to predict the effects of disease. Ann. Rev. Phytopathol. 26:183201.CrossRefGoogle Scholar
60.Rovira, A. D., and Simon, A.. 1982. Integrated control of Heterodera avenae. EPPO Bull. 12:517523.CrossRefGoogle Scholar
61.Russell, R. S. 1975. Plant root systems: their function and interaction with soil. McGraw Hill, London. 298 pp.Google Scholar
62.Schenck, N. C., and Kellam, M. K.. 1978. The influence of vesicular arbuscular mycorrhizae on disease development. Florida Agric. Exp. Sta. Bull. 798 (Technical):116.Google Scholar
63.Schroth, M. N., and Hancock, J. G.. 1982. Disease-suppressive soil and root-colonizing bacteria. Science. 216:13761381.CrossRefGoogle ScholarPubMed
64.Shipton, P. J. 1977. Monoculture and soilborne plant pathogens. Ann. Rev. Phytopathol. 15:387407.CrossRefGoogle Scholar
65.Siegel, M. R., Latch, G. C. M., and Johnson, M. C.. 1987. Fungal endophytes of grasses. Ann. Rev. Phytopathol. 25:293315.CrossRefGoogle Scholar
66.Slack, S. A. 1980. Pathogen-free plants by meristem culture. Plant Disease. 64:1517.Google Scholar
67.Smucker, A. J. M., and Erickson, A. E.. 1987. Anaerobic stimulation of root exudates and disease of peas. Plant Soil. 99:423433.CrossRefGoogle Scholar
68.Stolzy, L. H., Letey, J., Klotz, L. J., and Labanauskas, C. K.. 1965. Water and aeration as factors in root decay of Citrus sinensis. Phytopathology. 55:270275.Google Scholar
69.Templeton, G. D., Smith, R. J., and TeBeest, D. O.. 1986. Progress and potential of weed control with mycoherbicides. Rev. Weed Sci. 2:114.Google Scholar
70.Vaeck, M., Reynaerts, A., Hufte, H., Jansens, S., De Bueckeleer, M., Dean, C., Zabeau, M., van Montagu, M., and Leemans, J.. 1987. Transgenic plants protected from insect attack. Nature. 328:3339.CrossRefGoogle Scholar
71.Waage, J., and Greathead, D. J.. 1988. Biological control: challenges and opportunities. In Wood, R. K. S. and Way, M. J. (eds.). Biological Control of Pests, Pathogens, and Weeds: Developments and Prospects. The Royal Soc., London., pp 118.Google Scholar
72.Weinhold, A. R., Oswald, J. W., Bowman, T., Bishop, J., and Wright, D.. 1964. Influence of green manures and crop rotation on common scab of potato. Am. Potato Jour. 41:265273.CrossRefGoogle Scholar
73.Weller, D. M., and Cook, R. J.. 1983. Suppression of take-all of wheat by seed treatments with fluorescent pseudomonads. Phytopathology. 73:463469.CrossRefGoogle Scholar
74.Weller, D. M., and Cook, R. J.. 1987. Increased growth of wheat by seed treatments with fluorescent pseudomonads, and implications of Pythium control. Can. J. Plant Pathol. 8:328334.CrossRefGoogle Scholar
75.Wilson, C. L., and Pusey, P. L.. 1985. Potential for the biocontrol of postharvest plant diseases. Plant Disease. 69:375378.CrossRefGoogle Scholar
76.Zaag, D. E. van der. 1984. Reliability and significance of a simple method of estimating the potential yield of the potato crop. Potato Research. 27:5173.CrossRefGoogle Scholar