Abstract
Take-all is a world-wide root-rotting disease of cereals. The causal organism of take-all of wheat is the soil-borne fungus Gaeumannomyces graminis var tritici (Ggt). No resistance to take-all, worthy of inclusion in a plant breeding programme, has been discovered in wheat but the severity of take-all is increased in host plants whose tissues are deficient for manganese (Mn). Take-all of wheat will be decreased by all techniques which lift Mn concentrations in shoots and roots of Mn-deficient hosts to adequate levels. Wheat seedlings were grown in a Mn-deficient calcareous sand in small pots and inoculated with four field isolates of Ggt. Infection by three virulent isolates was increased under conditions which were Mn deficient for the wheat host but infection by a weakly virulent isolate, already low, was further decreased. Only the three virulent isolates caused visible oxidation of Mn in vitro. The sensitivity of Ggt isolates to manganous ions in vitro did not explain the extent of infection they caused on wheat hosts. In a similar experiment four Australian wheat genotypes were grown in the same Mn-deficient calcareous sand and inoculated with one virulent isolate of Ggt. Two genotypes were inefficient at taking up manganese and were very susceptible to take-all, one was very efficient at taking up manganese and was resistant to take-all, and the fourth genotype was intermediate for both characters. All genotypes were equally resistant under Mn-adequate conditions.
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References
Asher, M J C 1981 Pathogenic variation. In Biology and Control of Take-all. Eds. M J C Asher and P J Shipton, pp 199–218. Academic Press, London.
Asher, M J C and Shipton, P J 1981 Biology and Control of Take-all. Academic Press, London.
Bromfield, S M 1956 Oxidation of manganese by soil microorganisms. Aust. J. Biol. Sci. 9, 238–252.
Bromfield, S M and Skerman, V B D 1950 Biological oxidation of manganese in soils. Soil Sci. 69, 337–348.
Casida, L E(Jr) and Thomas, S 1961 Growth response of some soil microorganisms to manganese. Soil Sci. 92, 287–297.
Foster, J W 1939 The heavy metal nutrition of fungi. Bot. Rev. 5, 207–237.
Garrett, S D 1936 Soil conditions and the take-all disease of wheat. Ann. Appl. Biol. 23, 667–674.
Germida J J, Karamanos R E and Stewart J W B 1985 A simple microbial bioassay for plant-available manganese. Soil Sci. Am. J. 1411–1415.
Graham R D 1987 Development of wheats with enhanced nutrient efficiency: Progress and potential. Proc. CIMMYT/UNDP Int. Symp. on Wheat Production Constraints in tropical environments. 19–23 January, Chiang Mai, Thailand.
Graham, R D and Rovira, A D 1984 A role for manganese in the resistance of wheat plants to take-all. Plant and Soil 78, 441–445.
Huber, D M 1987 Immobilization of Mn predisposes wheat to take-all. Phytopathology 77, 1715.
Leeper, G W 1970 Six trace elements in soils. Melbourne Univ. Press, Melbourne, Australia.
Leeper, G W and Swaby, R J 1940 The oxidation of manganous compounds by microorganisms in the soil. Soil Sci. 49, 163–169.
Marcar N E 1986 Genotypic Variation for Manganese Efficiency in Cereals. Ph. D. Thesis, Univ. Adelaide, South Australia.
Marcar, N E and Graham, R D 1986 Effect of seed manganese content on the growth of wheat (Trinicum aestivum) under mangenese deficiency. Plant and Soil 96, 165–173.
Northcote, K H 1979 A Factual Key for the Recognition of Australian Soils. 4th Ed. Rellim Technical Public, Glenside, South Australia.
Penrose, L 1985 Evidence for resistance in wheat cultivars grown in sand culture to the take-all pathogen, Gaeumannomyces graminis var tritici. Ann. Appl. Biol. 107, 105–108.
Scott, P R and Hollins, T W 1985 Role of plant breeding in controlling soil-borne diseases of cereals. In Ecology and Management of Soil-borne Plant Pathogens. Eds. C A Parker, A D Rovira, K J Moore, P T W Wong and J F Kollmorgen. pp 157–159. Am. Phytopathology Soc., MN.
Simon, A and Rovira, A D 1985 New inoculation technique for Gaeumannomyces graminis var tritici to measure dose response and resistance in wheat in field experiments. In Ecology and Management of Soil-borne Plant Pathogens. Eds. C A Parker, A D Rovira, K J Moore, P T W Wong and J F Kollmorgen. pp 183–184. Am. Phytopathology Soc., MN.
Sivasithamparam, K and Parker, C A 1981 Physiology and nutrition in culture. In Biology and Control of Take-all. Eds. M J C Asher and P J Shipton. pp 125–150. Academic Press, London.
White, N H and MacIntyre, G A 1943 The pathogenicity of single spore isolates of Ophiobolus graminis under field conditions. J. Coun. Scient. Ind. Res. Aust. 16, 93–94.
Wildermuth, G B and Rovira, A D 1977 Hyphal density as a measure of suppression of Gaeumannomyces graminis var tritici on wheat roots. Soil Biol. Biochem. 9, 203–205.
Wilhelm, N S, Graham, R D and Rovira, A D 1988 Application of different sources of manganese sulphate decreases take-all (Gaeumannomyces graminis var tritici) of wheat grown in a manganese deficient soil. Aust. J. Agric. Res. 39, 1–10.
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Wilhelm, N.S., Graham, R.D. & Rovira, A.D. Control of Mn status and infection rate by genotype of both host and pathogen in the wheat take-all interaction. Plant Soil 123, 267–275 (1990). https://doi.org/10.1007/BF00011280
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DOI: https://doi.org/10.1007/BF00011280