Agriculture Reference
In-Depth Information
Madden, L.V. (1980) Quantification of disease progression.
Protection Ecology,
2
, 159-176.
Mazzola, M. and Gu, Y.-H. (2002) Wheat genotype-specific induction of soil microbial communities
suppressive to to
Rhizoctonia solani
AG-5 and AG-8.
Phytopathology,
92
, 1300-1307.
Mazzola, M. (2004) Assessment and management of soil microbial community structure for disease
suppression.
Annual Review of Phytopathology,
42
, 35-59.
Meyer, R.L., Kjaer, T. and Revsbech, N.P. (2002) Nitrification and denitrification near a soil-manure
interface studied with a nitrate-nitrite biosensor.
Soil Science Society of America Journal,
66
, 498-
506.
Meynard, J.-M. and Sebillotte, M. (1994) L'élaboration du rendement du blé, base pour l'étude des
autres céréales à talles, in
Un point sur… Elaboration du rendement des principales cultures
annuelles
, (eds L. Combe and D. Picard). INRA Editions, Paris, pp. 31-51.
Otten, W. and Gilligan, C.A. (1998) Effect of physical conditions on the spatial and temporal dynamics of
the soil-borne fungal pathogen
Rhizoctonia solani
.
New Phytologist,
138
, 629-637.
Rengel, Z. (1997) Root exudation and microflora populations in the rhizosphaere of crop genotypes
differing in tolerance to micronutrient deficiency.
Plant and Soil,
196
, 255-260.
Reynolds, H.L., Packer, A., Bever, J.D.,
et al
. (2003) Grassroots ecology: Plant-microbe-soil interactions
as drivers of plant community structure and dynamics.
Ecology,
84
, 2281-2291.
Rothrock, C.S. (1988). Relative susceptibility of small grains to take-all.
Plant Disease,
72
, 883-886.
Sarniguet, A., Lucas, P. and Lucas, M. (1992a) Relationships between take-all, soil conduciveness to the
disease, populations of fluorescent pseudomonads and nitrogen fertilizers.
Plant and Soil,
145
, 17-27.
Sarniguet, A., Lucas, P., Lucas, M.
et al.
(1992b) Soil conduciveness to take-all of wheat: Influence of the
nitrogen fertilizers on the structure of populations of fluorescent pseudomonads.
Plant and Soil,
145
,
29-36.
Schoeny, A. and Lucas, P. (1999) Modeling of take-all epidemics to evaluate the efficacy of a new seed-
treatment fungicide on wheat.
Phytopathology,
89
, 954-961.
Schoeny, A, Jeuffroy, M.H. and Lucas, P. (2001) Influence of take-all epidemics on winter wheat yield
formation and yield loss.
Phytopathology,
91
, 694-701.
Schoeny, A., Devienne-Barret, F., Jeuffroy, M.H.
et al.
(2003) Effect of take-all root infections on nitrate
uptake in winter wheat.
Plant Pathology,
52
, 52-59.
Slope, D.B. and Etheridge, J. (1971) Grain yield and incidence of take-all (
Ophiobolus graminis
Sacc.) in
wheat grown in different crop sequences.
Annals of Applied Biology,
67
, 13-22.
Smiley, R.W. and Cook, R.J. (1973) Relationships between take-all of wheat and rhizosphere pH in soils
fertilized with ammonium vs nitrate nitrogen.
Phytopathology,
63
, 882-890.
Smiley, R.W. (1978a) Antagonists of
Gaeumannomyces graminis
from the rhizoplane of wheat in soils
fertilized with ammonium or nitrate nitrogen.
Soil Biology and Biochemistry,
10
, 169-174.
Smiley, R.W. (1978b) Colonization of wheat roots by
Gaeumannomyces
graminis
inhibited by specific
soils, microorganisms and ammonium-nitrogen.
Soil Biology and Biochemistry,
10
, 175-179.
Smiley, R.W., Ogg, A.G. and Cook, R.J. (1992) Influence of glyphosate on Rhizoctonia root rot, growth,
and yield of barley.
Plant Disease
,
76
, 937-942.
Timonin, M.I. (1965) Interaction of higher plants and soil microorganisms, in
Microbiology and Soil
Fertility
, (eds C.M. Gilmore and O.N. Allen). Oregon State University Press, Corvallis, pp. 135-138.
Truscott, J.E. and Gilligan, C.A. (2001) The effect of cultivation on the size, shape, and persistence of
disease patches in fields.
Proceedings of the National Academy of Sciences,
98
, 7128-7133.
Zadoks, J.C., Chang, T.T. and Konzak, C.F. (1974) A decimal code for the growth stages of cereals.
Weed Research
,
14
, 415-421.
Zadoks, J.C. (1999) Reflections on space, time, and diversity.
Annual Review of Phytopathology,
37
,
1-17.
