Classical and augmentative biological control against ... - IOBC-WPRS

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Nicot et al. (Appendix for Chapter 1) Mach, R. L., Peterbauer, C. K., Payer, K., Jaksits, S., Woo, S. L., Zeilinger, S., Kullnig, C. M., Lorito, M., and Kubicek, C. P. (1999). Expression of two major chitinase genes of Trichoderma atroviride (T. harzianum P1) is triggered by different regulatory signals. Applied and Environmental Microbiology 65, 1858-1863. Machowicz-Stefaniak, Z. (1998). Antagonistic activity of epiphytic fungi from grape-vine against Botrytis cinerea Pers. Phytopathologia Polonica, 45-52. Machowicz-Stefaniak, Z., Prischepa, L. I., Zalewska, E., and Krol, E. (2004). Effect of Trichoderma spp. on some pathogens of hazel. Annales Universitatis Mariae Curie-Sklodowska. Sectio EEE, Horticultura 14, 101-110. Magnin-Robert, M., Trotel-Aziz, P., Quantinet, D., Biagianti, S., and Aziz, A. (2007). Biological control of Botrytis cinerea by selected grapevine-associated bacteria and stimulation of chitinase and beta -1,3 glucanase activities under field conditions. European Journal of Plant Pathology 118, 43-57. Mahmoud, Y. A. G., Ebrahim, M. K. H., and Aly, M. M. (2004). Influence of some plant extracts and microbioagents on some physiological traits of faba bean infected with Botrytis fabae. Turkish Journal of Botany 28, 519-528. Mamarabadi, M., Jensen, B., Jensen, D. F., and Lubeck, M. (2008). Real-time RT-PCR expression analysis of chitinase and endoglucanase genes in the three-way interaction between the biocontrol strain Clonostachys rosea IK726, Botrytis cinerea and strawberry. FEMS Microbiology Letters 285, 101-110. Marco, S. d., and Osti, F. (2007). Applications of Trichoderma to prevent Phaeomoniella chlamydospora infections in organic nurseries. Phytopathologia Mediterranea 46, 73-83. Mari, M., Guizzardi, M., and Pratella, G. C. (1996). Biological control of gray mold in pears by antagonistic bacteria. Biological Control 7, 30-37. Marquenie, D., Schenk, A., and Nicolai, B. (1999). VCBT investigates non-chemical methods to increase the storage life of strawberries and sweet cherries. Fruitteelt-nieuws 12, 18-19. Masih, E. I., Alie, I., and Paul, B. (2000). Can the grey mould disease of the grape-vine be controlled by yeast? FEMS Microbiology Letters 189, 233-237. Masih, E. I., and Paul, B. (2002). Secretion of beta -1,3-glucanases by the yeast Pichia membranaefaciens and its possible role in the biocontrol of Botrytis cinerea causing grey mould disease of the grapevine. Current Microbiology 44, 391-395. Masih, E. I., Slezack-Deschaumes, S., Marmaras, I., Barka, E. A., Vernet, G., Charpentier, C., Adholeya, A., and Paul, B. (2001). Characterisation of the yeast Pichia membranifaciens and its possible use in the biological control of Botrytis cinerea, causing the grey mould disease of grapevine. FEMS Microbiology Letters 202, 227-232. McHugh, R., and Seddon, B. (2001). Mode of action of Brevibacillus brevis - biocontrol and biorational control. Bulletin OILB/SROP 24, 17-20. McHugh, R., White, D., Schmitt, A., Ernst, A., and Seddon, B. (2002). Biocontrol of Botrytis cinerea infection of tomato in unheated polytunnels in the North East of Scotland. Bulletin OILB/SROP 25, 155- 158. Mercier, J., and Jimenez, J. I. (2004). Control of fungal decay of apples and peaches by the biofumigant fungus Muscodor albus. Postharvest Biology and Technology 31, 1-8. Mercier, J., and Jimenez, J. I. (2007). Potential of the volatile-producing fungus Muscodor albus for control of building molds. Canadian Journal of Microbiology 53, 404-410. Meszka, B., and Bielenin, A. (2004). Possibilities of integrated grey mould control on strawberry plantations in Poland. Bulletin OILB/SROP 27, 41-45. Metz, C., Oerke, E. C., and Dehne, H. W. (2002). Biological control of grey mould (Botrytis cinerea) with the antagonist Ulocladium atrum. Mededelingen - Faculteit Landbouwkundige en Toegepaste Biologische Wetenschappen, Universiteit Gent 67, 353-359. Meyer, G. d., Bigirimana, J., Elad, Y., and Hofte, M. (1998). Induced systemic resistance in Trichoderma harzianum T39 biocontrol of Botrytis cinerea. European Journal of Plant Pathology 104, 279-286. Meyer, U. M., Fischer, E., Barbul, O., and Elad, Y. (2001). Effect of biocontrol agents on antigens present in the extracellular matrix of Botrytis cinerea, which are important for pathogenesis. Bulletin OILB/SROP 24, 5-9. Meziane, H., Chernin, L., and Hofte, M. (2006). Use of Serratia plymuthica to control fungal pathogens in bean and tomato by induced resistance and direct antagonism. Bulletin OILB/SROP 29, 101-105. Migheli, Q., Gullino, M. L., Piano, S., Galliano, A., and Duverney, C. (1997). Biocontrol capability of Metschnikowia pulcherrima and Pseudomonas syringae against postharvest rots of apple under semicommercial condition. Mededelingen - Faculteit Landbouwkundige en Toegepaste Biologische Wetenschappen, Universiteit Gent 62, 1065-1070. Mikani, A., Etebarian, H. R., Aminian, H., and Alizadeh, A. (2007). Interaction between Pseudomonas fluorescens isolates and thiabendazole in the control of gray mold of apple. Pakistan Journal of Biological Sciences 10, 2172-2177. Mikani, A., Etebarian, H. R., Sholberg, P. L., O'Gorman, D. T., Stokes, S., and Alizadeh, A. (2008). Biological control of apple gray mold caused by Botrytis mali with Pseudomonas fluorescens strains. Postharvest Biology and Technology 48, 107-112. Minuto, G., Bruzzone, C., Tinivella, F., Lodovica Gullino, M., and Garibaldi, A. (2002). Biological control in cyclamen. Colture Protette 31, 85-95. Minuto, G., Minuto, A., Tinivella, F., Lodovica Gullino, M., and Garibaldi, A. (2004). Disease control on organically grown cyclamen. Bulletin OILB/SROP 27, 89-93. Mischke, S. (1998). Mycoparasitism of selected sclerotia-forming fungi by Sporidesmium sclerotivorum. Canadian Journal of Botany 76, 460-466. Mizrakci, A., and Yildiz, F. (2002). 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Appendix 1 Morandi, M. A. B., Maffia, L. A., Mizubuti, E. S. G., Alfenas, A. C., and Barbosa, J. G. (2003). Suppression of Botrytis cinerea sporulation by Clonostachys rosea on rose debris: a valuable component in Botrytis blight management in commercial greenhouses. Biological Control 26, 311-317. Morandi, M. A. B., Maffia, L. A., Mizubuti, E. S. G., Alfenas, A. C., Barbosa, J. G., and Cruz, C. D. (2006). Relationships of microclimatic variables to colonization of rose debris by Botrytis cinerea and the biocontrol agent Clonostachys rosea. Biocontrol Science and Technology 16, 619-630. Morandi, M. A. B., Maffia, L. A., and Sutton, J. C. (2001). Development of Clonostachys rosea and interactions with Botrytis cinerea in rose leaves and residues. Phytoparasitica 29, 103-113. Morandi, M. A. B., Maffia, L. A., and Tatagiba, J. S. (1999). Pathogenicity of Cladosporium spp. isolates, potential biocontrol agents of Botrytis cinerea, to rose plants. Summa Phytopathologica 25, 367-369. Morandi, M. A. B., Mattos, L. P. V., and Santos, E. R. (2007). Influence of application time on survival, establishment and ability of Clonostachys rosea to control Botrytis cinerea conidiation on rose debris. Bulletin OILB/SROP 30, 317-320. Morandi, M. A. B., Mattos, L. P. V., Santos, E. R., and Bonugli, R. C. (2008). Influence of application time on the establishment, survival, and ability of Clonostachys rosea to suppress Botrytis cinerea sporulation on rose debris. Crop Protection 27, 77-83. Morandi, M. A. B., Sutton, J. C., and Maffia, L. A. (2000a). Effects of host and microbial factors on development of Clonostachys rosea and control of Botrytis cinerea in rose. European Journal of Plant Pathology 106, 439-448. Morandi, M. A. B., Sutton, J. C., and Maffia, L. A. (2000b). Relationships of aphid and mite infestations to control of Botrytis cinerea by Clonostachys rosea in rose (Rosa hybrida) leaves. Phytoparasitica 28, 55-64. Moreno Velandia, C. A., Cotes, A. M., and Guevara Vergara, E. (2007). Biological control of foliar diseases in tomato greenhouse crop in Colombia: selection of antagonists and efficacy tests. Bulletin OILB/SROP 30, 59-62. Moyano, C., Raposo, R., Gomez, V., and Melgarejo, P. (2003). Integrated Botrytis cinerea management in Southeastern Spanish greenhouses. Journal of Phytopathology 151, 80-85. Mukherjee, P. K., Haware, M. P., and Raghu, K. (1997). Induction and evaluation of benomyl-tolerant mutants of Trichoderma viride for biological control of Botrytis grey mould of chickpea. Indian Phytopathology 50, 485-489. Nadkarni, S. R., Triptikumar, M., Bhat, R. G., Gupte, S. V., and Sachse, B. (1998). Mathemycin A, a new antifungal macrolactone from actinomycete sp. HIL Y-8620959: I. fermentation, isolation, physicochemical properties and biological activities. Journal of Antibiotics 51, 579-581. Navazio, L., Baldan, B., Moscatiello, R., Zuppini, A., Woo, S. L., Mariani, P., and Lorito, M. (2007). Calcium-mediated perception and defense responses activated in plant cells by metabolite mixtures secreted by the biocontrol fungus Trichoderma atroviride. BMC Plant Biology 7, (30 July 2007). Nian, H., Zhang, J., Fan, L., Liu, S., Song, F., and Huang, D. (2007). Application of ARDRA technology in Pseudomonas fluorescens isolation and identification. Scientia Agricultura Sinica 40, 92-98. Nicot, P. C., Decognet, V., Bardin, M., Romiti, C., Trottin, Y., Fournier, C., and Leyre, J. M. (2003). Potential for including Microdochium dimerum, a biocontrol agent against Botrytis cinerea, into an integrated protection scheme of greenhouse tomatoes. In "Colloque international tomate sous abri, protection integree - agriculture biologique, Avignon, France, 17-18 et 19 septembre 2003", pp. 19-23. Nicot, P. C., Decognet, V., Fruit, L., Bardin, M., and Trottin, Y. (2002). Combined effect of microclimate and dose of application on the efficacy of biocontrol agents for the protection of pruning wounds on tomatoes against Botrytis cinerea. Bulletin OILB/SROP 25, 73-76. Nie, Y., Liu, Y., Li, D., Liu, Y., Luo, C., and Chen, Z. (2007). Marine bacteria with antimicrobial activity against rice sheath blight. Jiangsu Journal of Agricultural Sciences 23, 420-427. Nielsen, K., Yohalem, D. S., Green, H., and Jensen, D. F. (2000). Biological control of grey mould in onion. DJF Rapport, Havebrug, 55-61. Nobre, S. A. M., Maffia, L. A., Mizubuti, E. S. G., Cota, L. V., and Dias, A. P. S. (2005). Selection of Clonostachys rosea isolates from Brazilian ecosystems effective in controlling Botrytis cinerea. Biological Control 34, 132-143. Novikova, I. I., Litvinenko, A. I., Boikova, I. V., Yaroshenko, V. A., and Kalko, G. V. (2003). Biological activity of new microbiological preparations alirins B and S designed for plant protection against diseases. I. Biological activity of alirins against diseases of vegetable crops and potato. Mikologiya i Fitopatologiya 37, 92-98. Nunes, C., Teixido, N., Usall, J., and Vinas, I. (2001a). Biological control of major postharvest diseases on pear fruits with antagonistic bacterium Pantoea agglomerans (CPA-2). Acta Horticulturae, 403-404. Nunes, C., Usall, J., Teixido, N., Abadias, I., Asensio, A., and Vinas, I. (2007). Biocontrol of postharvest decay using a new strain of Pseudomonas syringae CPA-5 in different cultivars of pome fruits. Agricultural and Food Science 16, 56-65. Nunes, C., Usall, J., Teixido, N., Abadias, M., and Vinas, I. (2002a). Improved control of postharvest decay of pears by the combination of Candida sake (CPA-1) and ammonium molybdate. Phytopathology 92, 281-287. Nunes, C., Usall, J., Teixido, N., Fons, E., and Vinas, I. (2002b). Postharvest biological control by Pantoea agglomerans (CPA-2) on Golden Delicious apples. Journal of Applied Microbiology 92, 247-255. Nunes, C., Usall, J., Teixido, N., Torres, R., and Vinas, I. (2002c). Control of Penicillium expansum and Botrytis cinerea on apples and pears with the combination of Candida sake and Pantoea agglomerans. Journal of Food Protection 65, 178-184. Nunes, C., Usall, J., Teixido, N., and Vinas, I. (2001b). Biological control of postharvest pear diseases using a bacterium, Pantoea agglomerans CPA-2. International Journal of Food Microbiology 70, 53-61. 95
Page 1 and 2:
IOBC OILB WPRS SROP In te rn atio n
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Preface One of the Research Activit
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LORITO Matteo UNINA, Dip. Arboricol
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List of Tables (continued) Table 17
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Contents Chapter 1 Potential of bio
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Chapter 1 Potential of biological c
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Chapter 1 To allow for the analysis
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Chapter 1 Table 4: Microbial specie
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Chapter 1 Table 4 (continued) T. lo
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Chapter 1 Table 4 (continued) Cupri
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Chapter 1 other was aiming at ident
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Chapter 2 Table 5: References extra
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Chapter 2 Table 6: Biocontrol agent
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Table 7 (continued) Chapter 2 Hemip
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Chapter 2 Bacillus thuringiensis: 2
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Chapter 3 - financial; since the de
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Chapter 3 Pathogens and Nematodes a
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Chapter 3 [Remark: Estimating the s
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Chapter 3 100% 80% 60% P = Phytopha
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Chapter 3 0,25 4 0,20 % dedicated t
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Chapter 3 Table 9: Recent introduct
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Chapter 3 Table 9: Recent introduct
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Chapter 4 The survey was limited to
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Chapter 4 Table 11 (continued) Othe
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Chapter 4 SCLPs are included in ann
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Chapter 4 laminarin is available on
Page 53 and 54: Chapter 5 (EC) No 1109/2009. Tests
Page 55 and 56: Chapter 6 Identified difficulties a
Page 57 and 58: Chapter 6 Table 12: Evidence for, a
Page 59 and 60: Table 13: Trichoderma-based prepara
Page 61 and 62: Chapter 6 Many preparations have be
Page 63 and 64: Chapter 6 Persistence, physiologica
Page 65 and 66: Chapter 6 Harman, G. E. (2006) Over
Page 67 and 68: Chapter 6 Sharon, E., Bar-Eyal, M.,
Page 69 and 70: Chapter 7 purification, formulation
Page 71 and 72: Chapter 7 Business profitability Co
Page 73 and 74: Chapter 8 A survey was carried out
Page 75 and 76: Chapter 8 80 70 60 %of supply %of a
Page 77 and 78: Chapter 8 efficacy and the price of
Page 79 and 80: Conclusions and perspectives reduct
Page 81 and 82: Appendices For Chapter 1 Appendix 1
Page 83 and 84: Appendix 1 B O Milsana + Brevibacil
Page 85 and 86: Appendix 1 Strawberry (target patho
Page 87 and 88: Appendix 1 Fruits - postharvest (ap
Page 89 and 90: Appendix 1 Legumes (Fabaceae) (targ
Page 91 and 92: Appendix 1 Miscellaneous crops (tar
Page 93 and 94: Appendix 1 Lecanicillium muscarium
Page 95 and 96: Appendix 1 Bedini, S., Bagnoli, G.,
Page 97 and 98: Appendix 1 Dik, A., and Wubben, J.
Page 99 and 100: Appendix 1 Gerlagh, M., Amsing, J.
Page 101 and 102: Appendix 1 Jing, W., Tu, K., Shao,
Page 103: Appendix 1 Li, G. Q., Huang, H. C.,
Page 107 and 108: Appendix 1 Rabea, E. I., Badawy, M.
Page 109 and 110: Appendix 1 Sutton, J. C., Liu, W.,
Page 111 and 112: Appendix 1 Zahavi, T., Cohen, L., W
Page 113 and 114: Appendix 2 Powdery mildew on grapes
Page 115 and 116: Appendix 2 Powdery mildew on cucurb
Page 117 and 118: Appendix 2 Askary, H. (1998). Patho
Page 119 and 120: Appendix 2 Malathrakis, N. E. (2002
Page 121 and 122: Appendix 3. Inventory of biocontrol
Page 123 and 124: Appendix 3 References on biocontrol
Page 125 and 126: Appendix 4. Inventory of biocontrol
Page 127 and 128: Appendix 4 Grapes (target pathogen
Page 129 and 130: Appendix 4 References on biocontrol
Page 131 and 132: Appendix 4 Robak, J., and Ostrowska
Page 133 and 134: Appendix 5 Cherry (target pathogens
Page 135 and 136: Appendix 5 Successful inhibition in
Page 137 and 138: Appendix 5 Smilanick, J. L., Denis-
Page 139 and 140: Appendix 6 showed protein content o
Page 141 and 142: Appendix 6 El-Khallal, S. M. (2007)
Page 143 and 144: Appendix 6 Liu, Q., J. C. Yu, et al
Page 145 and 146: Appendix 6 of tomato wilt pathogen
Page 147 and 148: Appendix 6 incognita, respectively.
Page 149 and 150: Appendix 7. Number of references re
Page 151 and 152: Appendix 8. Collection of data on a
Page 153 and 154: Appendix 8 Camporese & Duso, 1996 T
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Appendix 8 8.5 Fungi [5 species] Re
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Appendix 8 Berner & Schnetter, 2002
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Appendix 8 Morandi-Filho et al., 20
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Appendix 8 Marshall D.B. & Lester P
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Appendix 9 9.2. Details on the use
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Appendix 9 References 1. Abd-Rabou
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Appendix 9 50. Gariepy TD, Kuhlmann
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Appendix 9 97. Langewald J, Neuensc
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Appendix 9 146. Roltsch WJ, Meyerdi
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Appendix 10. Substances included in
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Appendix 10 Chemical Dimoxystrobin
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Appendix 10 Chemical Prosulfocarb '
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Appendix 10 Natural other Abamectin
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Appendix 11. Invertebrate beneficia
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Appendix 11 11.2. Invertebrate bioc
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Appendix 11 Coccinella septempuncta
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Appendix 11 Trichogramma brassicae
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Page 193 and 194:
Appendix 11 Diglyphus isaea Digline
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