Agriculture Reference
In-Depth Information
winter wheat as a function of cropping practices, soil, and
climate. Eur. J. Plant Pathol. 118:127-143.
Farr, D.F., A.Y. Rossman, M.E. Palm, and E.B. McCray.
2007. Fungal databases [Online]. USDA-ARS, Beltsville,
MD. Available at http://nt.ars-grin.gov/fungaldatabases/
(verifi ed 13 June 2008).
Fedel-Moen, R., and J.R. Harris. 1987. Stratifi ed distribution
of
Fusarium
and
Bipolaris
on wheat and barley with dryland
root rot in South Australia. Plant Pathol. 36:447-454.
Fernandez, M.R., and Y. Chen. 2005. Pathogenicity of
Fusarium species on different plant parts of spring wheat
under controlled conditions. Plant Dis. 89:164-169.
Fernandez, M.R., and R.P. Zentner. 2005. The impact of
crop rotation and N fertilizer on common root rot of spring
wheat in the Brown soil zone of western Canada. Can.
J. Plant Sci. 85:569-575.
Fitt, B.D.L., A. Goulds, and R.W. Polley. 1988. Eyespot
(
Pseudocercosporella herpotrichoides
) epidemiology in rela-
tion to prediction of disease severity and yield loss in
winter wheat—A review. Plant Pathol. 37:311-328.
Freeman, J., and H. Ward. 2004.
Gaeumannomyces graminis
,
the take-all fungus and its relatives. Mol. Plant Pathol.
5:235-252.
Fukui, R., G.S. Campbell, and R.J. Cook. 1994. Factors
infl uencing the incidence of embryo infection by
Pythium
spp. during germination of wheat seeds in soils. Phytopa-
thology 84:695-702.
Gac, M.L., F. Montfort, and N. Cavelier. 1996a. An assay
based on the Polymerase Chain Reaction for the detection
of N- and L-types of
Pseudocercosporella herpotricoides
in
wheat. J. Phytopathol. 144:513-518.
Gac, M.L., F. Montfort, N. Cavelier, and A. Sailland. 1996b.
Comparative study of morphological, cultural and molecu-
lar markers for the characterization of
Pseudocercosporella
herpotrichoides
isolates. Eur. J. Plant Pathol. 102:325-337.
Gams, W. 2000.
Phialophora
and some similar morphologi-
cally little-differentiated anamorphs of divergent ascomy-
cetes. Stud. Mycol. 45:187-199.
Garrett, S.D. 1970. Pathogenic root-infecting fungi. Cam-
bridge Univ. Press, Cambridge, UK.
Gill, J.S., K. Sivasithamparam, and K.R.J. Smettem. 2000.
Soil types with different texture affects development of
Rhizoctonia root rot of wheat seedlings. Plant Soil
221:113-120.
Gill, J.S., K. Sivasithamparam, and K.R.J. Smettem. 2001a.
Infl uence of depth of soil disturbance on root growth
dynamics of wheat seedlings associated with
Rhizoctonia
solani AG-8
disease severity in sandy and loamy sand soils
of Western Australia. Soil Tillage Res. 62:73-83.
Gill, J.S., K. Sivasithamparam, and K.R.J. Smettem. 2001b.
Soil moisture affects disease severity and colonisation of
wheat roots by
Rhizoctonia solani AG-8
. Soil Biol. Biochem.
33:1363-1370.
Gill, J.S., K. Sivasithamparam, and K.R.J. Smettem. 2001c.
Effect of soil moisture at different temperatures on
Rhizoctonia root rot of wheat seedlings. Plant Soil
231:91-96.
Gill, J.S., K. Sivasithamparam, and K.R.J. Smettem. 2002.
Size of bare-patches in wheat caused by
Rhizoctonia solani
AG-8
is determined by the established mycelial network
at sowing. Soil Biol. Biochem. 34:889-893.
González, D., D.E. Carling, S. Kuninaga, R. Vilgalys, and
M.A. Cubeta. 2001. Ribosomal DNA systematics of
Cera-
tobasidium
and
Thanatephorus
with
Rhizoctonia
anamorphs.
Mycologia 93:1138-1150.
González, D., M.A. Cubeta, and R. Vilgalys. 2006.
Phylogenetic utility of indels within ribosomal DNA
and beta-tubulin sequences from fungi in the
Rhizoctonia
solani s
pecies complex. Mol. Phylogenet. Evol.
40:459-470.
Gosme, M., L. Willocquet, and P. Lucas. 2007. Size, shape
and intensity of aggregation of take-all disease during
natural epidemics in second wheat crops. Plant Pathol.
56:87-96.
Grewal, H.S., R.D. Graham, and Z. Rengel. 1996. Genotypic
variation in zinc effi ciency and resistance to crown rot
disease (
Fusarium graminearum
Schw. Group 1) in wheat.
Plant Soil 186:219-226.
Griffi n, D.M. 1972. Ecology of soil fungi. Syracuse Univ.
Press, Syracuse, NY.
Gutteridge, R.J., J.P. Zhang, J.F. Jenkyn, and G.L. Bateman.
2005. Survival and multiplication of
Gaeumannomyces
graminis
var.
tritici
(the wheat take-all fungus) and related
fungi on different wild and cultivated grasses. Appl. Soil
Ecol. 29:143-154.
Hall, R., and J.C. Sutton. 1998. Relation of weather, crop,
and soil variables to the prevalence, incidence, and severity
of basal infections of winter wheat in Ontario. Can. J. Plant
Pathol. 20:69-80.
Hendrix, F.F., and W.A. Campbell. 1970. Distribution of
Phytophthora
and
Pythium
species in soils in the continen-
tal United States. Can. J. Bot. 48:377-384.
Herdina, and D.K. Roget. 2000. Prediction of take-all disease
risk in fi eld soils using a rapid and quantitative DNA soil
assay. Plant Soil 227:87-98.
Hering, T.F., R.J. Cook, and W.H. Tang. 1987. Infection of
wheat embryos by
Pythium
species during seed germina-
tion and the infl uence of seed age and soil matric potential.
Phytopathology 77:1104-1108.
Higginbotham, R.W, K.K. Kidwell, and T.C. Paulitz. 2004a.
Evaluation of adapted wheat cultivars for tolerance to
Pythium root rot. Plant Dis. 88:1027-1032.
Higginbotham, R.W., T.C. Paulitz, and K.K. Kidwell.
2004b. Virulence of
Pythium
species isolated from
wheat fi elds in eastern Washington. Plant Dis. 88:1021-
1026.
Hollins, T.W., K.D. Lockley, J.A. Blackman, P.R. Scott, and
J. Bingham. 1988. Field performance of Rendezvous, a
wheat cultivar with resistance to eyespot (
Pseudocerco-
sporella herpotrichoides
) derived from
Aegilops ventricosa
.
Plant Pathol. 37:251-260.
Hornby, D. 1978. The problems of trying to forecast take-all.
p. 151-158.
In
P.R. Scott and A. Bainbridge (ed.) Plant
disease epidemiology. Blackwell Scientifi c Publications,
Oxford, UK.
Hornby, D. 1979. Take-all decline: A theorist's paradise. p.
133-156.
In
B. Schippers and W. Gams (ed.) Soil-borne
plant pathogens. Academic Press, London, UK.
