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G. Bécard, Y. Piché (1989)
Fungal Growth Stimulation by CO2 and Root Exudates in Vesicular-Arbuscular Mycorrhizal SymbiosisApplied and Environmental Microbiology, 55
J. García-Garrido, J. Ocampo (1988)
Interaction between Glomus mosseae and Erwinia carotovora and its effects on the growth of tomato plantsNew Phytologist, 110
M. Giovannetti, B. Mosse (1980)
AN EVALUATION OF TECHNIQUES FOR MEASURING VESICULAR ARBUSCULAR MYCORRHIZAL INFECTION IN ROOTSNew Phytologist, 84
B. Mosse (1962)
The establishment of vesicular-arbuscular mycorrhiza under aseptic conditions.Journal of general microbiology, 27
E. Hewitt (1966)
Sand and Water Culture Methods Used in the Study of Plant Nutrition
J. Phillips, D. Hayman (1970)
Improved procedures for clearing roots and staining parasitic and vesicular-arbuscular mycorrhizal fungi for rapid assessment of infection.Transactions of The British Mycological Society, 55
(1974)
A 1974 Studies in Mycology
J. Bissett (1991)
A revision of the genus Trichoderma. IV. Additional notes on section LongibrachiatumBotany, 69
Neville Dix, J. Webster (1995)
Fungal Ecology
A. Page (1982)
Methods of soil analysis. Part 2. Chemical and microbiological properties.
(1974)
The endogonaceae in the Pacific Nortwest
C. Mcallister, I. García-Romera, A. Godeas, J. Ocampo (1994)
Interactions between Trichoderma koningii, Fusarium solani and Glomus mosseae: Effects on plant growth, arbuscular mycorrhizas and the saprophyte inoculantsSoil Biology & Biochemistry, 26
C. Calvet, J. Barea, J. Pera (1992)
In vitro interactions between the vesicular-arbuscular mycorrhizal fungus glomus mosseae and some saprophytic fungi isolated from organic substratesSoil Biology & Biochemistry, 24
K. Domsch, W. Gams, T. Anderson (1995)
Compendium of Soil Fungi
C. Mcallister, I. García-Romera, J. Martín, A. Godeas, J. Ocampo (1995)
Interaction between Aspergillus niger van Tiegh. and Glomus mosseae. (Nicol. & Gerd.) Gerd. & Trappe.The New phytologist, 129 2
N. Claydon, M. Allan, J. Hanson, A. Avent (1987)
Antifungal alkyl pyrones of Trichoderma harzianumTransactions of The British Mycological Society, 88
(1981)
Antagonistic action
C. Calvet, J. Pera, J. Barea (2004)
Growth response of marigold (Tagetes erecta L.) to inoculation withGlomus mosseae, Trichoderma aureoviride andPythium ultimum in a peat-perlite mixturePlant and Soil, 148
J. Gerdemann (1955)
Relation of a Large Soil-Borne Spore to Phycomycetous Mycorrhizal InfectionsMycologia, 47
F. Olson (1950)
Quantitative estimates of filamentous algaeTransactions of the American Microscopical Society, 69
(1969)
A 1969 A revision of the genus
(1994)
Interaction betweenTrichoderma koningii
Trans. Br. Mycol. Soc
A. Camprubí, C. Calvet, V. Estaún (1995)
Growth enhancement of Citrus reshni after inoculation with Glomus intraradices and Trichoderma aureoviride and associated effects on microbial populations and enzyme activity in potting mixesPlant and Soil, 173
J. Tarafdar, H. Marschner (1995)
Dual inoculation with Aspergillus fumigatus and Glomus mosseae enhances biomass production and nutrient uptake in wheat (Triticum aestivum L.) supplied with organic phosphorus as Na-phytatePlant and Soil, 173
G. Hennebert (1968)
Echinobotryum, wardomyces and MammariaTransactions of The British Mycological Society, 51
Vidal Domínguez, M. Teresa. (1991)
Contribución al estudio de los factores que influencian el crecimiento in vitro de hongos de las micorrizas Va y su establecimiento en plantas micropropagadas
P. Camporota (1985)
Antagonisme in vitro de Trichoderma spp. vis-à-vis de Rhizoctonia solani KühnAgronomie, 5
A. Fitter, J. Garbaye (1994)
Interactions between mycorrhizal fungi and other soil organismsPlant and Soil, 159
(1974)
The Netherlands. 117 p
R. Finlay, B. Söderström (1992)
Mycorrhiza and carbon flow to the soil
S. Schwab, J. Menge, R. Leonard (1983)
Quantitative and qualitative effects of phosphorus on extracts and exudates of sudangrass roots in relation to vesicular-arbuscular mycorrhiza formation.Plant physiology, 73 3
V. Rendig (1966)
Sand and Water Culture Methods used in the Study of Plant NutritionSoil Science Society of America Journal, 30
J. Harley, J. Waid (1955)
A method of studying active mycelia on living roots and other surfaces in the soilTransactions of The British Mycological Society, 38
F. Tacon, F. Skinner, B. Mosse (1983)
Spore germination and hyphal growth of a vesicular–arbuscular mycorrhizal fungus, Glomus mosseae (Gerdemann and Trappe), under decreased oxygen and increased carbon dioxide concentrationsCanadian Journal of Microbiology, 29
J. Barea, P. Jeffries (1995)
Arbuscular Mycorrhizas in Sustainable Soil-Plant Systems
M. Caron, J. Fortin, C. Richard (1985)
Influence of substrate on the interaction ofGlomus intraradices andFusarium oxysporum f.sp.radicis-lycopersici on tomatoesPlant and Soil, 87
K. Mayo, R. Davis, J. Motta (1986)
STIMULATION OF GERMINATION OF SPORES OF GLOMUS VERSIFORME BY SPORE-ASSOCIATED BACTERIAMycologia, 78
The saprophytic fungi Wardomyces inflatus (Marchal) Hennebert, Paecilomyces farinosus (Holm & Gray) A. H. S. Brown & G. Sm., Gliocladium roseum Bain., sterile dark mycelium (SDM-54), Trichoderma pseudokoningii Rifai and Trichoderma harzianum Rifai were isolated from sporocarps of Glomus mosseae. The effect of saprophytic fungi on G. mosseae spore germination was tested on water agar. Wardomyces inflatus decreased the percent germination of G. mosseae spores; G. roseum, T. pseudokoningii and T. harzianum had no effect on germination; and P. farinosus and SDM-54 increased the percentage of spore germination of G. mosseae after 4 d. Wardomyces inflatus significantly decreased hyphal length of spores which germinated, but no other saprophytic fungi affected hyphal growth. Trichoderma pseudokoningii, T. harzianum, P. farinosus and SDM-54 increased the number of auxiliary cells formed by G. mosseae. The effect of saprophytic fungi on arbuscular mycorrhizal colonization of soybean was studied in a greenhouse trial. The percentage of soybean root length colonized was decreased by W. inflatus, unaffected by SDM-54 and T. harzianum, and increased by P. farinosus. Gliocladium roseum decreased root length colonized when plants were 12 wk old, and T. pseudokoningii increased colonization of roots when plants were 4 wk old. Antagonistic, synergistic and neutral actions of G. mosseae upon the saprophytic fungi were observed. The population of T. harzianum decreased and the populations of T. pseudokoningii and SDM-54 increased in the presence of G. mosseae. Our results indicate a complex interaction between G. mosseae and associated saprophytic fungi.
Plant and Soil – Springer Journals
Published: Mar 1, 1998
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