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Selective Elimination of Soilborne Plant Pathogens and Enhancement of Antagonists by Steaming, Sublethal Fumigation and Soil Solarization

  • E. C. Tjamos
Part of the NATO ASI Series book series (NSSA, volume 230)

Abstract

Soilborne plant pathogens constitute a real menace to world agriculture due to their ability to form long-lived, dormant resting structures able to resist adverse environmental conditions even for several years but capable of resuming activity rapidly when favourable conditions return to normalcy. Soil disinfestation when applicable is almost the sole solution in controlling a wide range of them. Soil fumigation in particular drastically affects survival of soilborne plant pathogens but may concomitantly induce biological vacuum with certain serious disadvantages. Alternative solution to the problem could be the application of sublethal fumigation mostly in combination with non-chemical methods such as soil solarization (Katan, 1981). Soil solarization applied singly or in combination with reduced doses of soil fumigants showed a remarkable destructive effect on most soilborne plant pathogens. In addition to the thermal death, the debilitation of the fungal propagules induced by sublethal heating constitutes another interesting characteristic of the technique. In contrary to soil fumigation or steaming, recent data clearly demonstrate survival, increase and prevalence of heat tolerant fungal antagonists in solarized soils. This review refers to the current disinfestation methods (steaming, sublethal fumigation and soil solarization) with special emphasis on their effect on the ecology and survival of soilborne pathogens and their potential natural antagonists and the consequent effect in controlling soilborne plant diseases.

Keywords

Fusarium Oxysporum Fusarium Wilt Verticillium Wilt Methyl Bromide Verticillium Dahliae 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

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Literature Cited

  1. Adams, P. B., 1990, The potential of mycoparasites for biological control of plant diseases, Annu. Rev. Phytopathol., 28: 59.PubMedCrossRefGoogle Scholar
  2. Arora, D. K., and Pandey, A. K., 1989, Effects of soil solarization on Fusarium wilt of chickpea, J. Phytopathol., 124: 13.CrossRefGoogle Scholar
  3. Ashworth, L. J. Jr., and Gaona, S. A., 1982, Evaluation of clear polyethylene mulch for controlling Verticillium wilt in established pistachio nut groves, Phytopathology, 72: 243.CrossRefGoogle Scholar
  4. Ben-Yephet, Y., 1988, Control of sclerotia and apothecia of Sclerotinia sclerotiorum by metham-sodium, methyl bromide and soil solarization, Crop Prot., 7: 25.CrossRefGoogle Scholar
  5. Ben-Yephet, Y., Malero-Vara, J. M., and DeVay, J. E., 1988, Interaction of soil solarization and metham-sodium in the destruction of Verticillium dahliae and Fusarium oxysporum f. sp. vasinfectum, Crop Prot., 7: 327.CrossRefGoogle Scholar
  6. Ben-Yephet, Y., Stapleton, J. J., Wakeman, R. J., and DeVay, J. E., 1987, Comparative effects of soil solarization with single and double layers of polyethylene film on survival of Fusarium oxysporum f. sp. vasinfectum, Phytoparasitica, 15: 181.CrossRefGoogle Scholar
  7. Bigre, J. P., 1980, Phytophthora on gerbera and Fusarium on carnation, Rev. Hortic. (Paris), 205: 13.Google Scholar
  8. Bollen, G. J., 1974, Fungal recolonization of heat-treated glasshouse soils, Ecosystems, 1: 139.CrossRefGoogle Scholar
  9. Cartia, G., 1989, Soil solarization: experiments in Sicily, La solarizzazione del terreno: esperienze maturate in Sicilia, Inf. Fitopatol., 39: 49.Google Scholar
  10. Cartia, G., Cipriano, T., and Quartarone, G., 1987, Use of soil solarization and fumigants against underground parasites of carrot in Sicily, Inf. Fitopatol., 37: 43.Google Scholar
  11. Cenis, J. L., Martinez, P. F., Gonzalez-Benavente, A., and Aragon, R., 1988, Control trials against Verticillium dahliae and Rhizoctonia solani using solar disinfection in the field at Cartagena, in: Comun. del III Congreso Nacional de Fitopatologia, 107, Llobet L. G. J., ed., La Laguna, Spain.Google Scholar
  12. Davis, J. R., and Sorensen, L. H., 1986, Influence of soil solarization at moderate temperatures on potato genotypes with differing resistance to Verticillium dahliae, Phytopathology, 76: 1021.CrossRefGoogle Scholar
  13. Dwivedi, R. S., and Dubey, R. C., 1987, Effect of soil solarization on the population dynamics of Macrophomina phaseolina (Tassi) Goid and general soil mycoflora, Int. J. of Trop. Plant Dis., 5: 67.Google Scholar
  14. Elena, K., and Tjamos, E. C., 1992, Control of Fusarium wilt of carnation by soil solarization singly or in combination with fungal or bacterial biocontrol agents, (this volume).Google Scholar
  15. Fahima, T., and Henis, Y., 1990, Interaction between pathogen, host and biocontrol agent: Multiplication of Trichoderma hamatum and Talaromyces flavus on roots of diseased and healthy hosts, pages 165–180, in: “Biological control of soilborne plant pathogens”, D. Hornby, ed., C.A.B. International, London.Google Scholar
  16. Fravel, D. R., 1988, Role of antibiosis in the biocontrol of plant diseases, Annu. Rev. Phytopathol., 26: 75.CrossRefGoogle Scholar
  17. Fravel, D. R., 1990, Effect of sublethal metham-sodium on microsclerotia of Verticillium dahliae, Phytopathology, 80: 670.Google Scholar
  18. Fravel, D. R., Kim, K. K., and Papavizas, G. C., 1987, Viability of microsclerotia of Verticillium dahliae reduced by a metabolite produced by Talaromyces flavus, Phytopathology, 77: 616.CrossRefGoogle Scholar
  19. Fravel, D. R., and Roberts, D. P., 1991, In situ evidence for the role of glucose oxidase in the biocontrol of Verticillium wilt by Talaromyces flavus, Biocontrol Sci. Technol., (in press).Google Scholar
  20. Freeman, S., and Katan, J., 1988, Weakening effect on propagules of Fusarium by sublethal heating, Phytopathology, 78: 1656.CrossRefGoogle Scholar
  21. Freeman, S., Sztejnberg, A., Shabi, E., and Katan, J., 1990, Long-term effect of soil solarization for the control of Rosellinia necatrix in apple, Crop Prot., 9: 312.CrossRefGoogle Scholar
  22. Gamliel, A., and Katan, J., 1991, Involvement of fluorescent Pseudomonas and other microorganisms in increased growth response of plants in solarized soils, Phytopathology, 81: 494.CrossRefGoogle Scholar
  23. Gayed, S. K., 1979, The effect of steam sterilization on three pathogenic fungi in tobacco seed beds in the greenhouse, Lighter, 49: 14.Google Scholar
  24. Gerlach, W., Wendland, E., and Rintelen, J., 1978, Occurrence of Fusarium wilt of radish in glasshouses in Munich, Nachrichtenblatt des Deutschen Pflanzenschutzdienstens, 30: 28.Google Scholar
  25. Greenberger, A., Yogev, A., and Katan, J., 1987, Induced suppressiveness in solarized soils, Phytopathology, 77: 1663.Google Scholar
  26. Grinstein, A., Orion, D., Greenberger, A., and Katan, J., 1979, Soil heating of the soil for the control of Verticillium dahliae and Pratylenchus thornae in potatoes, pages 413–438, in: “Soilborne Plant Pathogens”, B. Schippers, and W. Gams, eds., Academic Press, London.Google Scholar
  27. Hartz, T. K., Carter, W. W., and Bruton, B. D., 1987, Fail of fumigation and solarization to control Macrophomina phaseolina and subsequent muskmelon vine decline, Crop Prot., 6: 261.CrossRefGoogle Scholar
  28. Hildebrand, D. M., 1985, Soil solar heating for control of dumping-off fungi and weeds at the Colorado state forest service nursery, Tree Planters’ Notes, 36: 28.Google Scholar
  29. Horiuchi, S., and Hori, M., 1983, Control of clubroot disease of crucifers with reference to the soil solarization technique, Jarq, 17: 1.Google Scholar
  30. Horiuchi, S., Hori, M., Takashi, S., and Shimizu, K., 1983, Factors responsible for the development of clubroot-suppressing effect in soil solarization, Bulletin of the Chugoku National Agricultural Experiment Station, 20: 25.Google Scholar
  31. Kaewruang, W., Sivasithamparam, K., and Hardy, G. E., 1989, Use of soil solarization to control root rots in gerberas (Gerbera jamesonii), Biology and Fertility of Soils, 8: 38.CrossRefGoogle Scholar
  32. Katan, J., 1981, Solar heating (solarization) of soil for control of soil-borne pests, Annu. Rev. Phytopathol., 19: 211.CrossRefGoogle Scholar
  33. Katan, J., 1987, Soil Solarization, pages 77–105, in: “Innovative Approaches to Plant Disease Control”, I. Chet, ed., John Wiley and Sons, New York.Google Scholar
  34. Katan, J., DeVay, J. E., and Greenberger, A., 1989, The biological control induced by soil solarization, pages 493–499, in: “Vascular wilt diseases of plants”, E. C. Tjamos, and C. H. Beckman, eds., Springer-Verlag, Berlin, Heidelberg, New York.Google Scholar
  35. Katan, J., Fishier, G., and Grinstein, A., 1983, Short-and long-term effects of soil solarization and crop sequence on Fusarium wilt and yield of cotton in Israel, Phytopathology, 73: 1215.CrossRefGoogle Scholar
  36. Keinath, A. P., Fravel, D. R., and Papavizas, G. C., 1991, Potential of Gliocladium roseum for biocontrol of Verticillium dahliae, Phytopathology, 81: 644.CrossRefGoogle Scholar
  37. Kim, K. K., Fravel, D. R., and Papavizas, G. C., 1988, Identification of a metabolite produced by Talaromyces flavus as glucose oxidase and its role in the biocontrol of Verticillium dahliae, Phytopathology, 78: 488.CrossRefGoogle Scholar
  38. Kodama, T., and Fukui, T., 1982, Solar heating in closed plastic house for control of soilborne diseases, V. Application for control of Fusarium wilt of strawberry, Ann. of the Phytopath. Soc. of Japan, 48: 570.CrossRefGoogle Scholar
  39. Kodama, T., Fukai, T., and Matsumoto, Y., 1980, Solar heating sterilization in the closed vinyl houses against soilborne diseases, III. Influence of the treatment on the population level of soil microflora and the behaviour of strawberry yellows pathogen, Fusarium oxysporum f. sp. fragariae, Bull. Nara Pref. Agric. Exp. Sta., 11: 41.Google Scholar
  40. Krijthe, J. M., 1973, Annual Report 1972, Institute for Phytopathological Research, Wageningen, The Netherlands, 63 pp.Google Scholar
  41. Martyn, R. D., and Hartz, T. K., 1986, Use of soil solarization to control Fusarium wilt of watermelon, Plant Dis., 70: 762.CrossRefGoogle Scholar
  42. Materrazzi, A., Triolo, E., Vannacci, G., and Scaramuzzi, G., 1987, The use of soil solar heating for controlling neck rot of greenhouse lettuce, Colture Protette, 16: 51.Google Scholar
  43. Matta, A., 1976, Harmfulness of Pyrenochaeta lycopersici in tomato crops in the glasshouse on the Ligurian coast, Colture Protette, 5: 31.Google Scholar
  44. McCain, A. H., Bega, R. V., and Jenkinson, J. C., 1986, Effect of fall sowing and solar heating of soil on two conifer seedling disease, Tree Planters’ Notes, 37: 17.Google Scholar
  45. Mihail, J. D., and Alcorn, S. M., 1982, Quantitative recovery of Macrophomina phaseolina sclerotia from soil, Plant Dis., 66: 662.CrossRefGoogle Scholar
  46. Mihail, J. D., and Alcorn, S. M., 1984, Effect of soil solarization on Macrophomina phaseolina and Sclerotium rolfsii, Plant Dis., 68: 156.Google Scholar
  47. McLaren, D. L., Huang, H. C., and Rimmer, S. R., 1986, Hyperparasitism of ~lerotinia sclerotiorum by Talaromyces flavus, Can. J. Plant Pathol., 8: 43.CrossRefGoogle Scholar
  48. McLaren, D. L., Huang, H. C., Rimmer, S. R., and Kokko, E. G., 1989, Ultrastructural studies on infection of sclerotia of Sclerotinia sclerotiorum by Talaromyces flavus, Can. J. Bot., 67: 2199.CrossRefGoogle Scholar
  49. Osman, A. R., Fahim, M. M., Sahab, A. F., and Abd-Elkader, M. M., 1987, Soil solarization for the control of lupin wilt, Egypt. J. Phytopathol., 18: 75.Google Scholar
  50. Phillips, A. J., L., 1990, The effects of soil solarization on sclerotial populations of Sclerotinia sclerotiorum, Plant Pathol., 39: 38.Google Scholar
  51. Pinkas, Y., Kariv, A., and Katan, J., 1984, Soil solarization for the control of Phytophthora cinnamomi: thermal and biological effects, Phytopathology, 74: 796 (abstract).Google Scholar
  52. Porter, I. J., and Merriman, P. R., 1985, Evaluation of soil solarization for control of root diseases of row crops in Victoria, Plant Pathol., 34: 108.CrossRefGoogle Scholar
  53. Porter, I. J., Merriman, P. R., and Keane, P. J., 1989, Integrated control of pink root (Pyrenochaeta terrestris) of onions by dazomet and soil solarization, Aust. J. Agric. Res., 40: 861.CrossRefGoogle Scholar
  54. Pullman, G. S., and DeVay, J. E., 1981, Effect of soil flooding and puddy rice culture on the survival of Verticillium dahliae and incidence of Verticillium wilt of cotton, Phytopathology, 71: 1285.Google Scholar
  55. Pullman, G. S., DeVay,. J. E., and Garber, R. H., 1981, Soil solarization effects on Verticillium wilt of cotton and soil-borne populations of Verticillium dahliae, Pythium spp., Rhizoctonia solani and Thielaviopsis basicola, Phytopathology, 71: 954.Google Scholar
  56. Ragimov, U. A., and Bagirova, Sh. G., 1976, Ascochytosis and white rot of cucumber under conditions of the Kirovabad glasshouse centre, Trudy Azerb. Sel’skokhozyaistvennogo Instituta, Agron., 6: 46.Google Scholar
  57. Reuveni, R., Krikun, J., and Shani, U., 1983, The role of Monosporascus eutypoides in a collapse of melon plants in an arid area of Israel, Phytopathology, 73: 1223.CrossRefGoogle Scholar
  58. Rowe, R. C., and Farley, J. D., 1978, Control of Fusarium crown and root rot of greenhouse tomatoes by inhibiting recolonization of steam-disinfected soil with captafol drench, Phytopathology, 68: 1221.CrossRefGoogle Scholar
  59. Sewell, G. W. F., and Roberts, A. L., 1985, Replant diseases of hardy ornamentals, page 159, in: “Rep. East Mailing Res. Sta. 1984”.Google Scholar
  60. Skadow, K., 1978, Phytophthora nicotianae var. nicotianae on glasshouse tomatoes, Arch. Phytopathol. Pflanzenschutz., 14: 291.CrossRefGoogle Scholar
  61. Stapleton, J. J., and DeVay, J. E., 1985, Soil solarization as a post-plant treatment to increase growth of nursery trees, Phytopathology, 75: 1179 (abstract).Google Scholar
  62. Stapleton, J. J., DeVay, J. E., Van Rijckevorsel, H., and De Boer, G. J., 1983, Increased soluble mineral nutrients in soils as related to increased plant growth response following soil solarization, Phytopathology, 73: 814 (abstract).CrossRefGoogle Scholar
  63. Stapleton, J. J., and Garza-Lopez, J. G., 1988, Mulching of soils with transparent (solarization) and black polyethylene films to increase growth of annual and perennial crops in southwestern Mexico, Trop. Agric., 65: 29.Google Scholar
  64. Stapleton, J. J., and DeVay, J. E., 1982, Effect of soil solarization on populations of selected soilborne microorganisms and growth of deciduous fruit tree seedlings, Phytopathology, 72: 323.Google Scholar
  65. Stapleton, J. J., and DeVay, J. E., 1984, Thermal components of soil solarization as related to changes in soil and root microflora and increased plant growth response, Phytopathology, 74: 255.CrossRefGoogle Scholar
  66. Szejnberg, A., Freeman, S., Chet, I., and Katan, J., 1987, Control of Rosellinia necatrix in soil and in apple orchard by solarization and Trichoderma harzianum, Plant Dis., 71: 365.CrossRefGoogle Scholar
  67. Tamietti, G., and Lento, G., 1986, Basal rot of tomatoes caused by Fusarium oxysporum f. sp. radicis-lycopersici in Italy, Inf. Fitopatol., 56: 59.Google Scholar
  68. Tamietti, G., and Garibaldi, A., 1989, The use of solarization against Rhizoctonia under greenhouse conditions in Liguria, Inf. Fitopatol., 39: 43.Google Scholar
  69. Thomas, W., 1973, Control of Olpidium brassicae, the vector of cucumber necrosis and bean stipple streak virus diseases, New Zealand J. Expt. Agric., 1: 92.CrossRefGoogle Scholar
  70. Tjamos, E. C., 1984, Control of Pyrenochaeta lycopersici by combined soil solarization and low dose of methyl bromide in Greece, Acta Hortic. (The Hague), 152: 253.Google Scholar
  71. Tjamos, E. C., Biris, D. A., and Paplomatas, E. J., 1991, Recovery of olive trees from Verticillium wilt after individual application of soil solarization in established olive orchards, Plant Dis., 75: 557.CrossRefGoogle Scholar
  72. Tjamos, E. C., Karapapas, V., and Bardas, D., 1989, Low cost application of soil solarization in covered plastic houses for the control of Verticillium wilt of tomatoes in Greece, Acta Hortic. (The Hague), 255: 139.Google Scholar
  73. Tjamos, E. C., and Makrynakis, N., 1990, Control of fungal wilt diseases of melon by application of soil solarization in the field, pages 423425, in: “Proc. 8th Congr. Mediterr. Phytopath.” Un. Agadir, Morroco.Google Scholar
  74. Tjamos, E. C., and Paplomatas, E. J., 1987, Effect of soil solarization on the survival of fungal antagonists of Verticillium dahliae, Eur. Mediterr. Plant Prot. Organ. Bull., 17: 645.Google Scholar
  75. Tjamos, E. C., and Paplomatas, E. J., 1988, Long-term effect of soil solarization in controlling Verticillium wilt of globe artichokes in Greece, Plant Pathol., 37: 507.CrossRefGoogle Scholar
  76. Tjamos, E. C., and Skretis, L., 1990, Establishment of applied or increase of natural Verticillium dahliae antagonists in solarized or untreated soils, page 87, in: Abstracts of the 5th International Verticillium Symposium Lenigrand, USSR, June 1990.Google Scholar
  77. Triolo, E., Vannacci, G., and Materazzi, A., 1988, Solar heating of soil in vegetable production, Part 2. Studies on possible mechanisms of the effect, Colture Protette, 17: 59.Google Scholar
  78. Usmani, S. M. H., and Chaffar, A., 1981, Polyethylene mulching of soil to reduce viability of sclerotia of Sclerotium oryzae, Soil Biol. Biochem., 14: 203.CrossRefGoogle Scholar
  79. Vannacci, G., Triolo, E., and Materazzi, A., 1988, Survival of Sclerotinia minor sclerotia in solarized soil, Plant Soil, 109: 49.CrossRefGoogle Scholar
  80. Wendland, E. J., 1976, On the control of radish blacking with some results of experiments, Gemusse, 12: 78.Google Scholar
  81. Westeijn, G., 1973, Soil sterilization and glasshouse disinfection to control Fusarium oxysporum f. sp. lycopersici in tomatoes in the Netherlands, Neth. J. Plant Pathol., 79: 36.Google Scholar
  82. Wicks, T. J., 1988, Effect of solarization on the control of Phytophthora cambivora in almond and cherry, Aust. J. Exp. Agric., 28: 539.Google Scholar

Copyright information

© Springer Science+Business Media New York 1992

Authors and Affiliations

  • E. C. Tjamos
    • 1
  1. 1.Laboratory of Plant PathologyAgricultural University of AthensAthensGreece

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