Whitefly and whitefly-borne viruses in the tropics : Building a ... - cgiar

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Conclusions developing countries, at lower prices. These problems have forced many farmers to abandon the cultivation of susceptible crops in prime agricultural regions. The TWF-IPM Project has gathered enough evidence to suggest that the whitefly problem can be managed with the collaboration of farmers, by providing proper and timely technical assistance. The challenge for the project is to find the most appropriate communication means to disseminate the IPM technology that has been found to be effective and economically viable for small-scale farmers. To this end, the TWF-IPM Project is about to initiate its third and final phase to disseminate and scale out suitable IPM technology using farmer participatory research and different communication channels to reach affected farmers throughout the tropics, wherever whiteflies are a food production constraint. We are confident that well-informed farmers will be able to reduce the number of application of insecticides, lower production costs, increase profits, and reduce environmental contamination and human health hazards. Ultimately, farmers will be able to recover the biological equilibrium of their agricultural ecosystems, and thus prevent future whitefly outbreaks. The information presented in this book represents a major achievement in terms of compiling the international and national (grey) literature and knowledge available on the extent and socioeconomic importance of whiteflies as pests and vectors of plant viruses. This information has been essential in selecting the most promising and viable IPM strategies to be tested in Phase II of the TWF-IPM Project. The information contained in this book also reflects the interest and hard work of many colleagues who now form one of the most extensive research networks in the tropics. This joint effort has already yielded visible results in terms of raising awareness about the nature of the whitefly problem, particularly in relation to the key issue of pesticide abuse, and the use of appropriate methods to characterize whitefly pests and diagnose whitefly-borne viruses. The design, validation, implementation and success of IPM methods recommended to control whiteflies and whitefly-transmitted viruses largely depends upon a solid knowledge base. References Boiteau, G.; Singh, P. 1988. Resistance to the greenhouse whitefly, Trialeurodes vaporariorum (Westwood) (Homoptera: Aleyrodidae), in a clone of the wild potato Solanum berthaultii Hawkes. Ann. Entomol. Soc. Am. 81:428-431. Brown, J. K.; Bird, J. 1995. Variability within the Bemisia tabaci species complex and its relation to new epidemics caused by geminiviruses. CEIBA 36:73-80. Cardona, C. 1995. Manejo de Trialeurodes vaporariorum (Westwood) en frijol en la zona Andina: Aspectos técnicos, actitudes del agricultor y transferencia de tecnología. Memoria IV Taller Latinoamericano sobre moscas blancas y geminivirus, 16-18 octubre 1995, Zamorano, HN. CEIBA 36(1):53-64. Chao, S. L.; Dennehy, T. J.; Casida, J. E. 1997. Whitefly (Homoptera: Aleyrodidae) binding site for imidacloprid and related insecticides: a putative nicotinic acetylcholine receptor. J. Econ. Entomol. 90:879-882. Chu, C. C.; Henneberry, T.; Akey, D. H.; Naranjo, S. E.; Perkins, H. H.; Prabhaker, N.; Mackey, B. E. 1995. Silverleaf whitefly: development of an action threshold for chemical control on cotton. In: Procs. Beltwide Cotton Conferences, 4-7 January 1995, San Antonio, TX, USA. Volume 2, p. 873-874. 343
Dennehy, T. J.; Antilla, L. 1996. Whitefly resistance to insecticides in Arizona. In: Procs. Beltwide Cotton Conferences, 9-12 January 1996 Nashville, TN, USA. Volume 1, p. 144-145. Ernst, G. H. 1994. Whiteflies (Bemisia tabaci) in cotton: Possible origin of the problem and today’s chemical control opportunities. Pestic. Sci. 42:139-141. Fargette, D.; Fauquet, C.; Grenier, E.; Thresh, J. M. 1990. The spread of African cassava mosaic virus into and within cassava fields. J. Phytopathol. 130: 289-302. Fauquet, C.; Fargette, D. 1990. African cassava mosaic virus: Etiology epidemiology, and control. Plant Dis. 74:404-411. Gibson, R. W.; Legg, J. P.; Otim-Nape, G.W. 1996. Unusually severe symptoms are a characteristic of the current epidemic of mosaic virus disease of cassava in Uganda. Ann. Appl. Biol. 128:479-490. Godfrey, L. D.; Goodell, P. B.; Summers, C. G.; Bentley, W. J.; Perring, T. M. 1995. Seasonal development of silverleaf whitefly populations in cotton and other crops in the San Joaquin valley. In: Procs. Beltwide Cotton Conferences, 4-7 January 1995, San Antonio, TX, USA. Volume 2, p. 831-834. Gruenhagen, N. M.; Perring, T. M.; Bezark, L. G.; Daoud, D. M.; Leigh, T. F. 1993. Silverleaf whitefly present in the San Joaquin Valley. Calif. Agric. 47:4-6. Henneberry, T. J.; Hendrix, D. L.; Perkins, H. H.; Jech, L. F.; Burke, R. A. 1996. Bemisia argentifolii (Homoptera: Aleyrodidae) honeydew sugars and relationships to sticky cotton. Environ. Entomol. 25:551-558. 344 Whiteflies and Whitefly-borne Viruses in the Tropics Jones, D. R. 2003. Plant viruses transmitted by whiteflies. Eur. J. Plant Pathol. 109:195-219. Markham, P. G.; Bedford, I. D.; Liu, S. J.; Pinner, M. S. 1994. The transmission of geminiviruses by Bemisia tabaci. Pestic. Sci. 42:123-128. Morales, F. J. 2001. Conventional breeding for resistance to Bemisia tabacitransmitted geminiviruses. Crop Prot. 20:825-834. Morales, F. J.; Anderson, P. K. 2001. The emergence and dissemination of whitefly-transmitted geminiviruses in Latin America. Arch. Virol. 146(3): 415-441. Omer, A. D.; Johnson, M. W.; Tabashnik, B. E.; Ullman, D.E . 1993. Association between insecticide use and greenhouse whitefly (Trialeurodes vaporariorum Westwood) resistance to insecticides in Hawaii. Pestic. Sci. 37:253-259. Pita, J. S.; Fondong, V. N.; Sangaré, A.; Otim-Nape, G. W.; Ogwal, S.; Fauquet, C. M. 2001. Recombination, pseudorecombination and synergism of geminiviruses are determinant keys to the epidemic of severe cassava mosaic disease in Uganda. J. Gen. Virol. 82:655-665. Polston, J. E.; Anderson, P. K. 1997. The emergence of whitefly-transmitted geminiviruses in tomato in the western hemisphere. Plant Dis. 81:1358-1369. Riley, D. G.; Palumbo, P. J. 1995. Abundance of two whitefly species (Homoptera: Aleyrodidae) on Georgia soybean. J. Entomol. Sci. 30:527-533. Tsai, J. H.; Kaihong, W.; Wang, K. H. 1996. Development and reproduction of Bemisia argentifolii (Homoptera: Aleyrodidae) on five host plants. Environ. Entomol. 25:810-816.
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About the Partners CIAT The Interna
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Centro Internacional de Agricultura
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Chapter 4 Whiteflies and Whitefly-b
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Chapter 6 Whiteflies and Whitefly-b
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Contents Page Foreword vii Introduc
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Contents Chapter SECTION THREE Whit
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Foreword This book is the product o
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Introduction Introduction The Probl
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Introduction In addition to the yie
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Introduction in pesticide use in La
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Introduction annual crops, especial
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Introduction Plant Resistance contr
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Introduction Otim-Nape, G. W.; Bua,
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SECTION ONE Whiteflies as Vectors o
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Introduction CHAPTER 1.1 Introducti
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Introduction diseases than is cassa
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Introduction Sub-project on Whitefl
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Introduction References Aritua, V.;
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Introduction Thresh, J. M.; Otim-Na
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Ghana 1997, on 80 farms. These incl
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Ghana (6.2%), Bakentenma (5%) and K
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Ghana Legg, J. P.; James, B. D. 199
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Benin Northern guinea savannah Sout
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Benin or disease problem, the main
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Nigeria CHAPTER 1.4 Nigeria Introdu
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Nigeria TMS 30572 (18.8%) and TMS 3
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Nigeria FAO (Food and Agriculture O
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Cameroon protocol, to enable valid
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Cameroon Farmers undertook various
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Cameroon Robertson, I. A. D. 1987.
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Uganda between November 1997 and Ja
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Uganda environment, host plant heal
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Uganda local varieties. Assessments
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Uganda Harrison, B. D. 1987. Proper
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Kenya Recent epidemiological studie
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Kenya respective diseases were reco
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Kenya Bock, K. R. 1983. Epidemiolog
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Tanzania CHAPTER 1.8 Tanzania Intro
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Tanzania Adult whiteflies were more
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Tanzania loss) to assess yield loss
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Tanzania Legg, J. P.; Raya, M. 1998
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Malawi Increased Biological Underst
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Malawi Physiology and Ecology in th
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Madagascar Tanzania Madagascar Moza
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Madagascar surprising, particularly
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Diversity of African Cassava Mosaic
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Sweetpotato Virus Disease in East A
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Factors Associated with Damage CHAP
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Factors Associated with Damage Mean
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Factors Associated with Damage % SP
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Factors Associated with Damage thro
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Factors Associated with Damage Gedd
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Conclusions and Recommendations col
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Conclusions and Recommendations Mal
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Conclusions and Recommendations Mpi
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Conclusions and Recommendations com
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Conclusions and Recommendations con
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Conclusions and Recommendations (2)
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Conclusions and Recommendations Ger
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SECTION TWO Whiteflies as Pests and
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Introduction Czosnek, H.; Navot, N.
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Sudan cotton, leading to the introd
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Sudan Table 1. Reproductive host pl
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Sudan Historically, Sudan has been
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Sudan Only 10% of producers reporte
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Sudan Conclusions The work conducte
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Kenya CHAPTER 2.3 Kenya Introductio
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Kenya Increased Biological Understa
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Kenya Samples of 10 plants per fiel
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Kenya Table 4. Maximum incidence (%
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Kenya Seventy-nine percent of tomat
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Kenya under Phase 2 of the TWF-IPM
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Tanzania CHAPTER 2.4 Tanzania Intro
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Tanzania The reproductive host plan
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Tanzania Geographical range of whit
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Tanzania Local names given to white
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Tanzania Nono-Womdim, R.; Swai, I.
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Malawi levels of infestation by the
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Malawi Table 3. Maximum incidence (
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Malawi (40%) believe that the white
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Tomato Yellow Leaf Curl Virus in E.
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Conclusions and Recommendations CHA
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Conclusions and Recommendations (Fi
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Conclusions and Recommendations Cen
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Conclusions and Recommendations the
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SECTION THREE Whiteflies as Vectors
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Introduction especially for export.
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Mexico CHAPTER 3.2 Mexico Introduct
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Mexico Culiacán, Sinaloa, in north
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Mexico Table 2. Virus survey of tom
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Mexico results of the molecular bio
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Mexico Strengthened Research Capaci
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Mexico López, R. 1996. Experiencia
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Guatemala 1960s, and at this time t
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Guatemala Table 2. Results of white
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Guatemala Table 5. Cropping systems
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Guatemala contemplated in this prel
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El Salvador CHAPTER 3.4 El Salvador
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El Salvador During the course of th
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El Salvador markets: common bean, m
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El Salvador Current Status of White
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Honduras Copan Ocotepeque Santa Bá
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Honduras Table 3. Biotyping of whit
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Honduras References Caballero, R. 1
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Nicaragua Nueva Segovia Madriz Este
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Nicaragua Lowlands of Nicaragua. Th
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Nicaragua Region VI is a main horti
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Costa Rica CHAPTER 3.7 Costa Rica I
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Costa Rica Table 1. Characterizatio
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Costa Rica Castillo, J. 1997. Movim
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Panama Bocas del Toro Chiriquí Ver
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Panama Gámez, R. 1970. Los virus d
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Haiti Grande-Anse Sud Grande-Anse S
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Haiti collaborators in this project
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Cuba Ciudad de la Habana Pinar del
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Cuba Table 3. Comparative homologie
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Cuba project provided three keynote
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Dominican Republic CHAPTER 3.11 Dom
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Dominican Republic monoclonal antib
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Dominican Republic Strengthened Res
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Reproductive Crop Hosts of Bemisia
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Biotypes of Bemisia tabaci CHAPTER
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Biotypes of Bemisia tabaci For this
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Biotypes of Bemisia tabaci 100 99 B
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Biotypes of Bemisia tabaci biotype
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Biotypes of Bemisia tabaci Table 2.
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Biotypes of Bemisia tabaci Already
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Conclusions and Recommendations CHA
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Conclusions and Recommendations gre
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SECTION FOUR Whiteflies as Pests of
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Introduction control, due to resist
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Introduction Posada, L. 1976. Lista
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Colombia and Ecuador B biotype B. t
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Colombia and Ecuador assistants and
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Colombia and Ecuador and squash. On
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Colombia and Ecuador Table 2. Main
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Colombia and Ecuador Table 6. Patte
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Insecticide Resistance in Colombia
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Page 308 and 309: Insecticide Resistance in Colombia
Page 310 and 311: Conclusions and Recommendations CHA
Page 312 and 313: Conclusions and Recommendations res
Page 314 and 315: Conclusions and Recommendations rot
Page 316 and 317: SECTION FIVE Special Topics on Pest
Page 318 and 319: Sustainable IPM through Host Plant
Page 328 and 329: Biological Control of Whiteflies by
Page 340 and 341: Progress of Cassava Mosaic Disease
Page 348 and 349: Management of the Cassava Mosaic Di
Page 354 and 355: Conclusions Conclusions The Tropica
Page 356 and 357: Conclusions whitefly pests and thus
Page 360 and 361: Acronyms and Abbreviations Acronyms
Page 362 and 363: Acronyms and Abbreviations FIRA Fid
Page 364 and 365: Acronyms and Abbreviations PROFRIJO
Page 366: Acronyms and Abbreviations PYR pyre
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