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Control of Virus Diseases of Plants 171Prasad, V. and Srivastava, S. (2001) Induciblemechanisms of plant resistance to virusinfections. Journal of Plant Biology 28,13–23.Parveen, S., Tripathi, A., and Varma, A.,(2001). Isolation and characterization ofan inducer protein (Crip-31) from Clerodendruminerme leaves responsible forinduc tion of systemic resistance againstviruses. Plant Science 161, 453–459.Picard, Daniel C. Cheng Kao; Katalin A.Hudak, (2005). Pokeweed antiviral proteininhibits Brome Mosaic Virus replicationin plant cells. Journal of BiologicalChemistry 280, 20069–20075.Ragetli, H.W.J. (1957). Behaviour and natureof virus inhibitor occurring in Dianthuscaryophyllus L. Tijdschr. Planteziekten, 61,245–344.Ragetli, H.W.J. and Weintraub, M. (1962)Purification and characteristics of avirus inhibitor from Dianthus caryophyllusI. Purification and activity. Virology,18, 232–240.Ragetli, H.W.J. and Weintraub, M. (1962) Purificationand characteristics of a virusinhibitor from Dianthus caryophyllus II.Characterization and mode of action.Virology, 18, 241–248.Rajamohan, F., Venkatachalam, T.K., Irvin, J.D.and Uckun, F.M. (1999) Pokeweed antiviralprotein isoforms PAP-I, PAP-II andPAP-III depurinate RNA of humanimmunodeficiency virus (HIV)-I. Biochemicaland biophysical research communications260, 453–458.Reddy, M.P., Brown, D.T. and Robertus, J.D.(1986) Extra cellular localization of pokeweedantiviral protein. Proceedings ofNational Academy of Sciences USA 83,5053–5056.Reisbig, R.R. and Bruland, O. (1983) Diathin30 and 32 from Dianthus caryophyllus: twoinhibitors of plant protein synthesis andtheir tissue distribution. Archives of Biochemistryand Biophysics 224, 700–706.Rodes, T.L. and Irvin, J.D. (1981) Reversal ofthe inhibitory effects of the pokeweedantiviral protein upon protein upon proteinsynthesis. Biochimica et BiophysicaActa 652, 160–167.Ross, A.F. (1961a) Localized acquired resistanceto plant virus infection inhypersensitive host. Virology 14, 329–339.Ross, A.F. (1961b) Systemic acquired resistanceinduced by localized virusinfections in plants. Virology 14, 340–358.Ryals, J., Uknes, S. and Ward, E. (1994)Systemic Acquired Resistance. PlantPhysiology 104, 1109–1112.Sela, I., and Applebaum, S.W. (1962) Occurrenceof antiviral factor in virus infectedplants. Virology 17, 543–548.Sela, I., Harpez, I. and Birk, Y. (1964) Seperationof a highly active antiviral factorfrom virus infected plants. Virology 22,446–451.Sela, I., Harpez, I. and Birk, Y. (1966) Identificationof the active component of an antiviralfactor isolated from virus infectedplants. Virology 28, 71-78.Singh, A.K. (2006) Comparative studies oncontrol of certain ailments of plants, miceand cancer cell lines and in vitro stimulationof growth of plants and virusresistance using phytoproteins fromBoerhaavia diffusa and Clerodendrum aculeatum.Ph.D. Thesis, Lucknow University,Lucknow, India.Srivastava, A. (1999) Micropropagation ofClerodendrum aculeatum and isolation ofvirus inhibitory substance from culturecells inducing systemic resistance in susceptiblehost. Ph.D. Thesis, LucknowUniversity, Lucknow, India.Srivastava, A., Gupta, R.K. and Verma, H.N.(2004) Micro Propagation of Clerodendrumaculeatum through adventitiousshoot induction and production of consistentamount of virus resistance inducingprotein. Indian Journal of ExperimentalBiology 42, 1200–1207.Srivastava, A., Trivedi, S., Krishna, S., Verma,H.N. and Prasad, V. (2008) Suppressionof papaya ringspot virus infection inCarica papaya with CAP. European Journalof Plant Pathology, DOI: 10.1007 / s10658-008-9358-2.Srivastava, A., Trivedi, S., Krishna, S.K.,Verma, H.N. and Prasad, V. (2009).Supression of Papaya ring spot virus infectionin Carica papaya with CAP-34, a
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NATURAL PRODUCTS IN PLANT PESTMANAG
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CABI is a trading name of CAB Inter
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viContents7. Potency of Plant Produ
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viiiContributorsJ.C. Pretorius, Dep
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xPrefaceantimicrobials owing to var
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1 Global Scenario on theApplication
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Global Scenario and Natural Product
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2 Plant Products in the Control ofM
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Control of Mycotoxins and Mycotoxig
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Natural Products from Plants 43an e
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Natural Products from Plants 45a pl
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Natural Products from Plants 47Chry
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Natural Products from Plants 493.3
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Natural Products from Plants 51Trit
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Natural Products from Plants 53Tetr
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Natural Products from Plants 55Phen
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Natural Products from Plants 57of c
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Natural Products from Plants 59inhi
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HOCH 2Compound 3Natural Products fr
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Natural Products from Plants 63iden
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Natural Products from Plants 65in a
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Natural Products from Plants 67in p
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Natural Products from Plants 69fung
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Natural Products from Plants 71arti
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Natural Products from Plants 73agen
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Natural Products from Plants 75in t
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Natural Products from Plants 77In a
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Natural Products from Plants 79( Te
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Natural Products from Plants 81OHOH
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Natural Products from Plants 83Band
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Natural Products from Plants 85Ferr
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Natural Products from Plants 87McFa
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Natural Products from Plants 89Rodr
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4 Antimicrobials of Plant Originto
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Antimicrobials to Prevent Biodeteri
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5 Some Natural Proteinaceousand Pol
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Proteinaceous and Polyketide Compou
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Page 134 and 135: Proteinaceous and Polyketide Compou
Page 148 and 149: Allelochemicals in Pest Management
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Fungal Endophytes 22111.2 Diversity
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Fungal Endophytes 223tumbling rocks
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Fungal Endophytes 225of a given fun
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Fungal Endophytes 227over 50% of th
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Fungal Endophytes 229isolates in ma
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Fungal Endophytes 231(Kharwar et al
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Fungal Endophytes 233virulent plant
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Fungal Endophytes 235isolated some
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Fungal Endophytes 237Atmosukarto, I
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Fungal Endophytes 239Lee, J.C., Yan
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Fungal Endophytes 241Strobel, G.A.,
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Suppressive Effects of Compost Tea
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13 Biotechnology: a Tool forNatural
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Biotechnology and Natural Product S
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282 Indexantibiotics continuedmodif
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284 Indexcompost tea continuedmicro
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286 Indexessential oils continuedim
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288 Indexmicrobial population, comp
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290 Indexnuts 35controlling aflatox
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292 Indexproteinic inducers of plan
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