Resistencia en Insectos, Plantas y Microorganismos
Abstract
Resumen
Se describe la noción de la resistencia y se mencionan diferentes clases de este fenómeno, es decir, los tipos de morfológico, comportamental, y fisiológico o metabólico. Se destaca la historia y evolución de la resistencia en los artrópodos. Se marcan los casos de resistencia en artrópodos y también la resistencia de éstos organismos a diferentes clases de plaguicidas. Se explica el proceso del metabolismo de los pesticidas en las plantas y los microorganismos y finalmente, los mecanismos de resistencia de las plantas hacia los estímulos.
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Bisset J. A. Rodríguez M. M. Díaz C., Ortiz E., Marquetti M. C., Hemingway J.1990. The mechanisms of organophosphate and carbamate resistance in Culex quinquefasciatus (Diptera: Culicidae) from Cuba. Bull Entomol Res, 80:245-250.
Bourguet D., Prou, Raymond, M. D. Raymond, M. 1996a.. Dominance of insecticide resistance presents a plastic response. Genetics. 143:407-16.
Bourget D., Pasteur N., Bisset J., Raymond M. 1996b. Determination of Ace. 1 genotypes in single mosquitoes : toward an ecumenical and biochemical test. Pestic Biochem Phisiol; 55-7.
Bourget D., Raymond M., Fournier D., Malcom CA. Toutan JP., Arpagaus M. 1996c; Existence of two acetylcholinesterases in the mosquito Culex pipiens (Diptera: Culicidae). J. Neurochem; 67:2115-23.
Bourget D., Capela R., Raymond M. 1996d. An insensitive acetylcholinesterase in Culex pipiens (Diptera Culicidae) from Portugal. J. Econ Entomol; 89:4060-6.
Brattsten, L. B. 1990. Resistente mechanisms to carbamate and organophosphate insecticide. In: Managing resistance to agrochemicals. Green, M. B.; H. M. y W. K. Moberg (eds.), American Chemical Society. Washintong, D.C. p. 24-60.
Brogdon W. 1988-90c. Microassay of acetylcholinesterase activitin small portions of single mosquito homogenates. Comp. Biochem Physiol. 145-50.
Brown, A. W.A. y K. Pal. 1971. Insecticide resistance in arthropods. In World Health Organization Monograph Series Nº. 38. Geneva, World Health Organization. P. 491.
Brown A. W. A. 1971. Pest resistance to pesticides, in “Pesticides in the Environment” (R. White-Stevens, Ed), Vol. 1, Part II, p. 457-552, Dekker, New York.
Card, F. W. 1897. Notes on the codling moth, Garden Forest X (Nº. 493), 302.
Carino, F., Koener, J. F. Plapp, F. W., feyereisen, R. 1994. Constitutive overesxpresion of the cytochrome P450 gene CYP6A1 in a house fly strain with metabolic resistance to insecticides. Insect Biochemistry ans Moleular Biology 24(4), 411-418.
Carrillo, R. H. 1984. Análisis De Acción Conjunta de Insecticidas en Larvas del Gusano Cogollero del Maíz (J.E: Smith) (Lepidoptera: Noctuidae). Tesis de Maestría en Ciencias. Centro de Entomología y Acarología. Colegio de Postgraduados. Chaíngo, México, p. 82.
Casida J. E. 1970. Mixed-Function oxidase involvement in the biochemistry of insecticide sinergists. J Agric Food Chem; 18:753.
Crow, J. F. 1960. Genetics of insecticide resistance: general considerations. Miscelaneous Publication of the Entomological Society of America 2. 69-74.
Curtis C.F. Pasteur. 1981. Organophosphate resistance in vector populations of the complex pipiens L. (Diptera, Culicidae): Bull Entomol Res. 71:153-161.
Dauterman, W. C. 1983. Role of Hydrolases and Gluthathione S-transferases in Insecticide Resistance. En Georghiou, G. P. and T. Saito (eds.). Pest Resistance to Pesticides. Plenum Press. New York. Pp.229-247.
Doyle K. E. Knipple D. C. 1991. PCR based phylogenetic walking: isolation of parahomologous sodium chanel gene sequences from seven insect species and arachnid. Insect Biochem. 21:689-96.
FAO (1979). Recommended methods for the detection and measurement of the resistance of agricultural pests to pesticides. FAO Plant Protection Bull. 27:29-32.
Georghiou, G. P. 1965. Genetic studies on Insecticide Resistance. Adv. Pest Control Res. 6:171.
Georghiou, G. P. 1981. “The occurrence of resistance to pesticide in arthropods: An index of cases reported through 1980”, FAO Plant Production and ProtectionSeries, FAO, Rome.
Georghiou, G. P. y C. E. Taylor. 1977. Pesticide resistance as an evolutionary phenomenon, in “Proceedingd XV International Congress of Entomology, Washintong, D. C. August 19-27, 1976”.
Georgiou, G. P. y A. Lagunas-Tejada. 1991. The ocurrence of resistance to pesticidas in arthropods. Food and Agriculture Organization of the United Nations. Rome p. 318.
Hama, H, 1983. resistance to Insecticides Due to Reduced Sensitivity of Acetylcholinesterasa. En Georghiou, G. P. and T. Saito (eds.) Pest resistance to Pesticides. Plenum Press. New York. Pp. 299-331.
Hodgson, E., Rose, R. L. Goh, D. K. S., Rock, G. C. Roe, R. M. 1993. Insect Cytochrome P-450 metabolism and resistance to insecticides. Biochemical Society Transactions 21, 1060-1065.
Knipple D. C. Payne L. Soderlund D. M. 1991. PCR- generated conspecific sodium chanel gene probe for he house fly. Arch. Insect Biochem. Physiol. 16: 45-53.
Knipple D. C., Doyle K. E., Marsella-Herrick P. A., Soderlug D. M. 1994. Tight genetic linkage between the kdr insecticide resistance trait and a voltage-sensitivy sodium channel gene in the house fly. Proc Natl Acad Sci, 91:2483-7.
Lagunes, T. A. 1991. Notas del Curso de Toxicología y Manejo de Insecticidas (Documentos de Trabajo). Centro de Entomología y Acarología. Colegio de Postgraduados. Montecillo- Chapingo, Méx. p.195.
Melander, A. L. 1914. Can insect become resistant to spray? J. Econ. Entomol. 7,167.
Metcalf, R. L. 1989. Insect Resistance to Insecticides. Pestic. Sci. 26:333-358.
Miller T. A. 1988. Mechanisms of resistance to pyrethroid insecticides. Parasitology Today. 4:13-5.
Moberg, W.K. 1990. Understanding and combating agrochemical resistance. In: Managing resistance to agrochemicals; Green, M. N., LeBaron, H. M. y W. K.
Moberg (eds.), American Chemical Society, Washintong, D. C. 1990. p. 1-15.
Monge, L. A. 1986. Manejo Racional de Insecticidas. Resistencia y rotación. Editorial tecnológica de Costa Rica. Cartago, Costa Rica. p. 74.
Mouches, C., Pauplin, Y. Agarwal, M., Lemieux, L. Herzog, M., Abadon, M., Beyssat-Arnaouty, V., Hyrien, O., Robert-de-Saint-Vicent, B. R.
Georghiou, G. P. , Pasteur N. 1990. Characterisation of amplification core and esterae B1 gene responsible for insecticide resistance in Culex. Proceedings of the National Academy of Sciences (USA) 87, 2574-2578.
Narashi, T. 1983. Resistance to Insecticides Due to Reduced Sensitivity of the Nervous System. En: Georghiou, G. P. and T. Saito (eds.). Pest Resistance to Pesticides. Plenum Press. New York. Pp. 333-366.
Pasteur N. 1977. Reserche de genetique chez in Culex pipiens L. Polimorphisme enzimatique,m autogénese et resistance aux insecticides otganophosphores. Thése doctorat dEtat. Université de Montpellier II, Montpellier, Frane, pp. 170.
Plapp, F. W. Jr. 1976. Biochemical genetics of Insecticide Resistance. Ann Rev. Entomol. 31:179-197.
Sawicki R. M. Farnham A. W. 1968. Genetics of resistance to insecticides in the Ska strain of Musca domestica. Location and isolation of the factors of resistance to dieldrin. Entomologica Experientia Applica. 11:133-42.
Sawicki, R. M. 1987. Definition, detection and documentation of insecticide resistance. In: Combating resistance to xenobiotics: Biological and chemical approaches. Ford, M. G., Holloman. D. W., Khambay, B. P. S. y R. M. Sawicki (eds.), Ellis Horwood, Chichester, p. 105-11.
Smissaert H. R. Voerman S., Oostenbrugge L. Renooy N. 1970. Achetylcolinesterases of organophosphate susceptible and resistant spider mites. J. Agric Food Chem; 18.66.
Smith, J. B. 1897. The influences of the environment on the life history of insect, Garden Forest X (Nº496). P.334.
Sotolongo M. G. Vidal A. N. 1988. Metabolismo y excreción de los compuestos extraños en : Elementos de Toxicología. La Habana: Editorial Pueblo y Educación; p. 11,12.
Terriere C. L. 1984. Induction of detoxication enzymes in insects. Ann Rev Entomol, 29:71-8.
Villany F. Hemingway J. 1987. The detection and interaction of multiple organophosphorus and carbamate insecticide resistance genes in field populations of Culex pipiens from Italy. Pestic Biochem Phisiol, 27:218-28.
Villany F. White G. B. Curtis C. F. Miles S. J. 1983. Inheritance and activity of some esterases associated with organophosphate resistance in mosquitoes of the complex Culex pipiens L. (Diptera. Culicidae): Bull Entomol Res; 73: 153-70.
Voss G. Matsumura F. 1965. Biochemical studies on modifies and normal cholinesterase found in thte Levercusen strains of two spotle spidermite Tetranycus urticae Con J Bio, 46:63-72.
Wilkinson, C. F. 1983. Role of Mixed-Function Oxidases in Insecticides Resistance. En: Georghiou , G.P. and T. Saito (eds.). Pest Resistance to Pesticides. Plenum Press. New York. Pp. 175-205.
WHO. 1992. Vector resistance to pesticide. Fifteenth report of the expert committee on vector biology and control. In WHO Tech. Rep. Ser. 818: 1-55.
Yasutomi, K. 1983. Role of Detoxication Esterases in Insecticide Resistance. En Georghiou, G. P. and T. Saito (eds.). Pest Resistance to Pesticides. Plenum Press. New YorK. Pp. 249-263.
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