Summary
The direct and indirect effects of plant genetic diversity on epidemics and the influence of disease on plant competition were investigated using the wheat (Triticum aestivum)/stripe rust (Puccinia striiformis) system. Replacement series consisting of a susceptible and a resistant wheat genotype or two wheat genotypes susceptible to different races of stripe rust were grown in the presence and absence of the pathogen. Stripe rust severity, number of seed heads, seed yield, and seed weight were determined separately for each wheat genotype in the mixtures and the pure stands. The frequency of susceptible genotypes in a mixture explained up to 67% of the variation in disease severity. However, competitive interactions among plant genotypes sometimes appeared to alter susceptibility and obscured the relationship. In pure stands of single genotypes, disease severity explained between 52 and 58% of the variation in seed yield. In mixtures, coefficients of determination were only 10 and 31%, suggesting a strong influence of plant-plant interactions on seed yield. These results suggest that host-parasite coevolutionary models need to account for the strong effect that specific plant genotype combinations may have on disease severity and plant reproduction.
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References
Alexander HM (1984) Spatial patterns of disease induced by Fusarium moniliforme var. subglutinans in a population of Plantago lanceolata. Oecologia 62:141–143
Alexander HM (1988) Spatial heterogeneity and disease in natural populations. In: Jeger MJ (ed) Spatial Components of Epidemics. Prentice-Hall Englewood Cliffs, NJ, pp 144–164
Alexander HM (1991) Plant population heterogeneity and pathogen and herbivore levels: a field experiment. Oecologia 86:125–131
Alexander HM, Burdon JJ (1984) The effect of disease induced by Albugo candida (white rust) and Peronospora parasitica on the survival and reproduction of Capsella bursa-pastoris. Oecologia 64:314–318
Alexander HM, Roelfs AP, Cobbs G (1986) Effects of disease and plant competition in monocultures and mixtures of two wheat cultivars. Plant Pathol 35:457–465
Augspurger CK (1984) Seedling survival of tropical tree species: Interactions of dispersal distance, light-gaps, and pathogens. Ecology 65:1705–1712
Augspurger CK, Kelly CK (1984) Pathogen mortality of tropical tree seedlings. Experimental studies of the effects of dispersal distance, seedling density, and light conditions. Oecologia 61:211–217
Barrett JA (1978) A model of epidemic development in variety mixtures. In: Scott PR, Bainbridge A (eds) Plant Disease Epidemiology. Blackwell, Oxford, pp 129–137
Brown JF, Sharp EL (1970) The relative survival ability of pathogenic types of Puccinia striiformis in mixtures. Phytopathology 60:529–533
Browning JA (1974) Relevance of knowledge about natural ecosystems to development of pest management systems for agroecosystems. Proc Am Phytopathol Soc 1:191–199
Browning JA, Frey MJ (1969) Multiline cultivars as a means of disease control. Annu Rev Phytopathol 7:355–382
Burdon JJ (1978) Mechanisms of disease control in heterogeneous populations—an ecologists view. In: Scott PR, Bainbridge A (eds) Plant Disease Epidemiology. Blackwell, Oxford, pp 193–200
Burdon JJ (1982) The effect of fungal pathogens on plant communities. In: Newman EI (ed) The Plant Community as a Working Mechanism. Blackwell, Oxford, pp 66–112
Burdon JJ, Chilvers GA (1982) Host density as a factor in plant disease ecology. Annu Rev Phytopathol 20:143–166
Burdon JJ, Groves RH, Kaye PE, Speer SS (1984) Competition in mixtures of susceptible and resistant genotypes of Chondrialla juncaea differentially infected with rust. Oecologia 64:199–203
Chilvers GA, Brittain EG (1972) Plant competition mediated by host-specific parasites—a simple model. Aust J Biol Sci 25:749–756
Chin KM, Wolfe MS (1984) Selection on Erysiphe graminis in pure and mixed stands of barley. Plant Pathol 33:535–546
Clay K (1984) The effect of the fungus Atkinsonella hypoxylon (Clavicipitaceae) on the reproductive system and demography of the grass Danthonia spicata. New Phytol 98:165–175
Clay K (1990) The impact of parasitic and mutualistic fungi on competitive interactions among plants. In: Grace JB, Tilman D (eds) Perspectives on plant competition. Academic Press, London, New York, pp 391–412
Connell JH (1990) Apparent versus “real” competition in plants. In: Grace JB, Tilman D (eds) Perspectives on plant competition. Academic Press, London, New York, pp 9–26
Finckh MR (1991) Interactive effects of stripe rust and plant competition in heterogeneous wheat populations. Ph. D. Thesis, Oregon State University, Corvallis
Firbank LG, Watkinson AR (1985) On the analysis of competition within two-species mixtures of plants. J Appl Ecol 22:503–517
Flor HH (1953) Epidemiology of flax rust in the North Central States. Phytopathology 43:624–628
Gates DJ, Westcott M, Burdon JJ, Alexander HM (1986) Competition and stability in plant mixtures in the presence of disease. Oecologia 68:559–566
Jarosz AM, Levy M (1988) Effects of habitat and population structure on powdery mildew epidemics in experimental phlox populations. Phytopathology 78:358–362
Jarosz AM, Burdon JJ, Mueller WJ (1989) Longterm effects of disease epidemics. J Appl Ecol 26:725–733
Johnson R (1978) Induced resistance to fungal disease with special reference to yellow rust of wheat. Ann Appl Biol 89:107–110
Johnson T, Green GJ, Samborski DJ (1967) The world situation of the cereal rusts. Annu Rev Phytopathol 5:183–200
Jolliffe PA, Minjas AN, Runeckles VC (1984) A reinterpretation of yield relationships in replacement series experiments. J Appl Ecology 21:227–243
Leonard KJ (1969) Factors affecting rates of stem rust increase in mixed plantings of susceptible and resistant oat varieties. Phytopathology 59:1845–1850
Leonard KJ, Czochor EJ (1980) Theory of genetic interactions among populations of plants and their pathogens. Annu Rev Phytopathol 18:337–358
May RM, Anderson RM (1983a) Epidemiology and genetics in the coevolution of parasites and hosts. Royal Soc. London, Proc Ser. B 219:281–313
May RM, Anderson RM (1983b) Parasite-host coevolution. In: Futuyma DJ, Slatkin M (eds) Coevolution. Sinauer. pp 186–206
McDonald BA, Allard RW, Webster RK (1988) Responses of two-, three-, and four-component barley mixtures to a variable pathogen population. Crop Sci 28:447–452
McDonald BA, McDermott JM, Allard RW, Webster RK (1989) Coevolution of host and pathogen population in the Hordeum vulgare-Rhynchosporium secalis pathosystem. Proc Nat Acad Sci 86:3924–3927
Mode CJ (1958) A mathematical model for the co-evolution of obligate parasites and their hosts. Evolution 12:158–165
Mode CJ (1961) A generalized model of a host-pathogen system. Biometrics 17:386–404
Mundt CC (1989) Modeling disease increase in host mixtures. In: Leonard KJ, Fry W (eds) Plant Disease Epidemiology Vol II. McGraw-Hill, New York, pp 150–181
Mundt CC, Browning JA (1985a) Genetic diversity and cereal rust management. In: Roelfs AP, Bushnell WR (eds) The Cereal Rusts. Vol II. Academic Press, Orlando, pp 527–559
Mundt CC, Browning JA (1985b) Development of crown rust epidemics in genetically diverse oat populations: Effect of genotype unit area. Phytopathology 75:607–610
Mundt CC, Leonard KJ (1986) Effect of host genotype unit area on development of focal epidemics of bean rust and common maize rust in mixtures of resistant and susceptible plants. Phytopat ology 76:895–900
Ouchi S (1983) Induction of resistance and susceptibility. Annu Rev Phytopathol 21:289–315
Parker MA (1989) Disease impact and local genetic diversity in the clonal plant Podophyllum peltatum. Evolution 43:540–547
Paul ND (1989) The effects of Puccinia lagenophorae on Senecio vulgaris in competition with Euphorbia peplus. J Ecol 77:552–564
Paul ND, Ayres PG (1986a) Interference between healthy and rusted groundsel within mixed populations of different densities and proportions. New Phytol 104:257–269
Paul ND, Ayres PG (1986b) The impact of pathogen (Puccinia lagenophorae) on populations of groundsel (Senecio vulgaris) overwintering in the field; I. Mortality, vegetative growth and the development of size hierarchies. J Ecol 74:1069–1084
Paul ND, Ayres PG (1986c) The impact of a pathogen (Puccinia lagenophorae) on populations of groundsel (Senecio vulgaris) overwintering in the field; II. Reproduction. J Ecol 74:1085–1094
Paul ND, Ayres PG (1987a) Survival, growth and reproduction of groundsel (Senecio vulgaris) infected by rust (Puccinia lagenophorae) in the field during summer. J Ecol 75:61–71
Paul ND, Ayres PG (1987b) Effects of rust infection of Senecio vulgaris on competition with lettuce. Weed Res 27:431–441
Richards FJ (1969) The quantitative analysis of growth. In: Steward FC (ed) Plant Physiology, Vol 5A, Academic Press, New York, pp 3–76
SAS Institute Inc (1988) SAS/STAT User's Guide Ed. 6.03. SAS Institute, Cary, NC. 1029 pp
Spitters CJT (1983) An alternative approach to the analysis of mixed cropping experiments. I. Estimation of competition effects. Neth J Agric Sci 31:1–11
Wahl I (1970) Prevalence and geographic distribution of resistance to crown rust in Avena sterilis. Phytopathology 60:746–749
Wolfe MS (1985) The current status and prospects of multiline cultivars and variety mixtures for disease resistance. Ann Rev Phytopathol 23:251–273
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Paper No. 9818 of the journal series of the Oregon Agricultural Experiment Station
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Finckh, M.R., Mundt, C.C. Plant competition and disease in genetically diverse wheat populations. Oecologia 91, 82–92 (1992). https://doi.org/10.1007/BF00317245
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DOI: https://doi.org/10.1007/BF00317245