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Molecular Techniques for Developing New Insecticide Molecules 497 Selective Sweeps and Genomic Consequences One feature of the evolution of insecticide resistance in the fi eld is the rapid spread of resistance alleles after the initial outbreak. Since it happens so quickly, there is little time for recombination to separate the favored resistance gene from the particular combination (haplo-type) of closely linked genes where it appeared fi rst. It is likely that the sweep of mutant esterase/organophosphate hydrolase genes in organophosphate-resistant blowfl ies (Newcomb et al., 1997; Campbell et al., 1998; Smyth et al., 2000) replaced most of the variation throughout the cluster of ten esterase genes in which it lies with a couple of wholecluster haplotypes. This cluster makes up a large proportion of the detoxifying esterase genes in the blowfl y’s genome (Claudianos et al., 2002). Probably, similar sweeps have occurred in clusters containing resistant mutants of P450s and GSTs (Russell et al., 1990). A major reduction may have occurred in the genetic variation in this species’ chemical defense system in a short span of time. There may also be additional detoxifi cation systems beyond the three major gene families so far studied. In addition to direct fi tness costs in the absence of insecticide that may occur for some resistance mutants, there may also be a substantial “opportunity cost” in terms of lost variation with which the species can respond (Batterham et al., 1996). Conclusions There is a continued need for identifying new insecticides either to be used alone or in combination with insect-resistant transgenic crops for integrated pest management. It is in this context that molecular techniques can be employed to detect different receptor sites, and screening of the molecules for receptor specifi city, and mode of action. Functional genomics offers the opportunity to acquire in-depth knowledge of the genetic makeup and gene function of insect pests that may lead to the discovery of new processes that could be the targets for novel chemistry. Advances in pest control are now being aided through rapid synthesis of novel compounds using combinational chemistry, genomics, proteomics, and molecular modeling. Combining genomics with high-throughput biochemical screening and combinatorial chemical approaches to generate extensive arrays of compounds for screening will lead to a range of new chemicals for pest control. Another application of molecular biology is the development of novel strains of entomopathogenic bacteria, fungi, nuclear polyhedrosis viruses, and nematodes. Genomic technologies will allow investigation of some previously intractable resistance mechanisms to both synthetic insecticides and biopesticides. The molecular techniques will be useful to understand the nature of mutations and genetic processes such as gene amplifi cation, altered gene transcription, and amino acid substitution. This in turn will lead to high-resolution diagnostics for resistance alleles, in both homozygous and heterozygous forms, especially for insect pests with multiple resistance mechanisms, or for resistance mechanisms not amenable to biochemical assays. The evolution of insecticide-resistant insects also provides evolutionary biologists an ideal model system for studying how new adaptations can be rapidly acquired. There is, therefore, a great interest in the use of the tools of molecular biology to develop new insecticide molecules and elucidate the mechanisms of resistance to insecticides.
498 Biotechnological Approaches for Pest Management and Ecological Sustainability References Batterham, P., Davies, A.G., Game A.Y. and Mckenzie J.A. (1996). Asymmetry: Where evolutionary and developmental genetics meet. Bioassays 18: 841–845. Campbell, P.M., Newcomb, R.D., Russell, R.J. and Oakeshott, J.G. (1998). Two different amino acid substitutions in the ali-esterase, E3, confer alternative types of organophosphorus insecticide resistance in the sheep blowfl y, Lucilia cuprina. Insect Biochemistry and Molecular Biology 28: 139–150. Claudianos, C., Russell, R.J. and Oakeshott, J.G. (1999). The same amino acid substitution in orthologous esterases confers organophosphate resistance on the housefl y and a blowfl y. Insect Biochemistry and Molecular Biology 29: 675–686. Claudianos, C., Crone, E., Coppin, C., Russell, R. and Oakeshott, J. (2002). A genomic perspective on mutant aliesterases and metabolic resistance to organophosphates. In Marshall Clark, J. and Yamaguchi, I. (Eds.), Agrochemical Resistance: Extent, Mechanism and Detection. Washington, D.C., USA: American Chemical Society, 90–101. Daborn, P.J., Yen, J.L., Bogwitz, M.R., Le Goff, G., Feil, E., Jeffers, S., Tijet, N., Perry, T., Heckel, D., Batterham, P., Feyereisen, R., Wilson, T.G. and Ffrench-Constant, R.H. (2002). A single P450 allele associated with insecticide resistance in Drosophila. Science 297: 2253–2256. Ferre, J. and Van Rie, J. (2002). Biochemistry and genetics of insect resistance to Bacillus thuringiensis. Annual Review of Entomology 47: 501–533. Feyereisen, R. (1999). Insect P450 enzymes. Annual Review of Entomology 44: 507–533. Ffrench-Constant, R.H., Anthony, N., Aronstein, K., Rocheleau, T. and Stilwell, G. (2000). Cyclodiene insecticide resistance: From molecular to population genetics. Annual Review of Entomology 45: 449–466. Field, L.M., Devonshire, A.L. and Forde, B.G. (1988). Molecular evidence that insecticide resistance in peach-potato aphids (Myzus persicae Sulz.) results from amplifi cation of an esterase gene. Biochemistry Journal 251: 309–312. Gahan, L.J., Gould, F. and Heckel, D.G. (2001). Identifi cation of a gene associated with Bt resistance in Heliothis virescens. Science 293: 857–860. Heckel, D.G., Gahan, L.J., Liu, Y.B. and Tabashnik, B.E. (1999). Genetic mapping of resistance to Bacillus thuringiensis toxins in diamondback moth using biphasic linkage analysis. Proceedings National Academy of Sciences USA 96: 8373–8377. Hemingway, J. (2000). The molecular basis of two contrasting metabolic mechanisms of insecticide resistance. Insect Biochemistry and Molecular Biology 30: 1009–1015. Hess, F.D., Anderson, R.J. and Reagan, J.D. (2001). High throughput synthesis and screening: The partner of genomics for discovering of new chemicals for agriculture. Weed Science 49: 249–256. Kaur, S. (2004). Molecular approaches towards development of novel Bacillus thuringiensis biopesticides. World Journal of Microbiology and Biotechnology 16: 781–793. Knipple, D.C., Doyle, K.E., Marsella-Henrick, P.A. and Soderland, D.M. (1994). Tight genetic linkage between the Kdr insecticide resistance trait and a voltage sensitive sodium channel gene in the house fl y. Proceedings National Academy of Sciences USA 91: 2483–2487. Marroquin, L.D., Elyassnia, D., Griffi tts, J.S., Feitelson, J.S. and Aroian, R.V. (2000). Bacillus thuringiensis (Bt) toxin susceptibility and isolation of resistance mutants in the nematode Caenorhabditis elegans. Genetics 155: 1693–1699. Martin, R.L., Pittendrigh, B., Liu, J., Reenan, R., Ffrench-Constant, R. and Hanck, D.A. (2000). Point mutations in domain III of a Drosophila neuronal Na channel confer resistance to allethrin. Insect Biochemistry and Molecular Biology 30: 1051–1059. Mutero, A., Pralavorio, M., Bride, J.M. and Fournier, D. (1994). Resistance-associated point mutations in insecticide-insensitive acetyl-cholinesterase. Proceedings National Academy of Sciences USA 91: 5922–5926.
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BIOTECHNOLOGICAL APPROACHES FOR PES
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CRC Press Taylor & Francis Group 60
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vi Contents Population Prediction M
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viii Contents Multilines/Synthetics
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x Contents 7. Genetic Transformatio
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xii Contents Horizontal Gene Flow .
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xiv Contents Cereals ..............
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xvi Contents Expressed Sequence Tag
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xviii Foreword Large-scale deployme
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xx Preface of newer insecticide mol
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2 Biotechnological Approaches for P
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Page 522 and 523: 19 Biotechnology, Pest Management,
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Page 535 and 536: 514 Species Index Arabidopsis thali
Page 537 and 538: 516 Species Index Empoasca fabae HP
Page 539 and 540: 518 Species Index N Nasonovia ribis
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Page 543 and 544: 522 Subject Index Brown planthopper
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Page 547: 526 Subject Index Toxin genes for i
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