Abstracts
The relationship between man and insect pests exists since the beginning of agriculture. Historically, the pest control most widely used is the chemical, however, despite its importance in controlling pests in various crops, its intensive use has been environmentally harmful, causing problems such as selection of populations of insect pests resistant to the products used outbreaks of secondary pests, reduction of natural enemies, undesirable residues in food poisoning in humans, animals, and environmental contamination. The alternative would be the development of resistant cultivars, it has significant advantages in the use of insecticides, and is considered an alternative strategy, at leorast complement, the use of insecticides. Furthermore, does not represent additional burden brings farmers and does not require transfer of a new technology. The methods used in breeding programs for resistance to insects are similar to those used for other traits of agronomic interest. In the literature, the methods used to incorporate resistance genes in plants are arthropods: mass selection, pedigree method, bulk, single seed descent, backcross, and recurrent selection. The procedures used in plant breeding have made significant progress with the development of techniques of molecular biology and genetic engineering. The transfer of exogenous genes for agronomic species can be considered the most significant advances in the biological sciences in recent years. Unlike what happens in the classic improvement where a large part of the genome is transferred by hybridization, genetic engineering techniques allow isolated genes are engineered and introduced in cultivars. Biotechnology is not intended to replace the conventional breeding, but the progress is undeniable and the contributions they have given to basic research and advanced genetics, as well as the development of cultivars with recognized contribution to agriculture.
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References
Barnes WC, Cuthbert FP (1975) Breeding turnips for resistance to the turnip aphid. Hort Sci 10:59–60
Beland GL, Hatchett JH (1976) Expression of antibiosis to the bollworm in two soybean genotypes. J Econ Entomol 69:557–560
Bento JMS (1999) Perda por insetos na agricultura. Ação Ambiental 2:19–21
Bing JW, Guthrie WD (1991) Generation mean analysis for resistance in maize to the corn leaf aphid Homoptera: Aphididae. J Econ Entomol 84:1080–1082
Bird LS (1982) Multi-adversity diseases, insects and stresses resistance MAR in cotton. Plant Dis 66:172–176
Borém A, Caixeta ET (2009) Marcadores Moleculares. UFV, Viçosa
Borém A, Miranda GV (2009) Melhoramento de Plantas. UFV, Viçosa
Butron A, Widstrom NW, Snook ME, Wiseman BR (2002) Recurrent selection for corn earworm Lepidoptera: Noctuidae resistance in three closely related corn southern synthetics. J Econ Entomol 95:458–462
Cartea ME, Malvar RA, Butrón A, Vales MI, Ordás A (1999) Inheritance of antibiosis to Sesamianonagrioides Lepidoptera: Noctuidae in maize. J Econ Entomol 92:994–998
Cartea ME, Malvar RA, Vales MI, Butrón A, Ordás A (2001) Inheritance of resistance to ear damage caused by Sesamianonagrioides Lepidoptera: Noctuidae in maize. J Econ Entomol 94:277–283
Clay K, Cheplick GP (1989) Effect of ergot alkaloids from fungal endophyte-infected grasses on fall armyworm Spodoptera frugiperda. J Chem Ecol 15:169–182
Diarisso NY, Pendleton BB, Teetes GL, Peterson GC, Anderson RM (1998) Spikelet flowering time: Cause of sorghum resistance to sorghum midge Diptera: Cecidomyiidae. J Econ Entomol 87:514–522
Fagundes AC, Arnt TA (1975) Efeito de diferentes temperaturas sobre o pulgão da espiga Macrosiphumavenae (F.). Anais da sociedade entomológica do Brasil 4:28–32
Funk CR, Halisky PM, Johnson MC, Siegel MR, Stewart AV, Amhad S, Hurley RH, Harvey IC (1983) An endophytic fungus and resistance to sod webworms: association in Loliumperenne L. Bio/Technology 1:189–191
Gallo D, Nakano O, Neto SS, Carvalho RPL, Batista GC, Filho EB, Parra JRP, Lopes JRS, Omoto C (2002) Entomologia Agrícola. FEALQ, Piracicaba
Gatehouse AM, Boulter D, Hilder VA (1994) Potential of plant-derived genes in the genetic manipulation of crops for insect resistance. Plant Genet Manip Crop Prot 7:155–181
Gibson RW (1979) The geographical distribution, inheritance and pest-resisting properties of stickytipped foliar hairs on potato species. Potato Res 22:223–237
Godoi CRC, Pinheiro JB (2009) Genetic parameters and selection strategies of soybean genotypes resistant to stink bug-complex. Genet Mol Biol 32:328–336
Graham JH, Hill RR, Barnes, D K, Hanson CH (1965) Effect of three cycles of selection for resistance to common leaf spot in alfalfa. Crop Sci 5:171–173
Hanson CH, Busbice JH, Hill RR, Hunt OJ, Oakes AJ (1972) Directed mass selection for developing multiple pest resistance and conserving germplasm in alfalfa. J Environ Qual 1:106–111
Harlan SC (1916) The inheritance of immunity to leaf blister mite Eriophyesgossypii Banks in cotton. West Ind Bull 17:162–166
Havens JN (1792) Observations on the Hessian fly. Trans New York Soc Agron Pt 1:89–107
Jenkins JN (1981) Breeding for insect resistance. In: Frey KJ (ed) Plant breeding II. Iowa University Press, Ames
Jones A, Duke PD Cuthbert FP Jr (1976) Mass selection in sweet potato: breeding for resistance to insects and diseases and for horticultural characteristics. J Am Soc Hort Sci 101:701–704
Jones A, Cuthbert PF (1973) Associated effects of mass selection for soil-insect resistance in sweet potato. J Am Soc Hort Sci 98:480–482
Kaloshian I, Lange WH, Williamson VM (1995) An aphid-resistance locus is tightly linked to the nematode-resistance gene Mi, in tomato. PNAS 92:622–625
Khush GS (1980) Breeding rice for multiple disease and insect resistance. In: Rice Improvement in China and Other Asian Countries. International Rice Research Institute, Los Banos, pp 219–238
Khush GS (1978) Biology techniques and procedures employed at IRRI for developing rice germplasm with multiple resistance to diseases and insects. Jap Trop Agric Res Ctr Res Ser 11:8
Kilen TC, Hatchett JH, Hartwig EE (1977) Evaluation of early generation soybeans for resistance to soybean looper. Crop Sci 17:397–398
Klenke JR, Russell WA, Guthrie WD (1986) Distributions for European corn borer Lepidoptera: Pyralidae ratings of S1 lines from ‘BS9’ corn. J Econ Entomol 79:1076–1081
Kogan M, Ortman EF (1978) Antixenosis - A new term proposed to define Painter’s “nonpreference” modality of resistance. Bull Entomol Soci Am 24:175–176
Kornegay JL, Temple SR (1986) Inheritance and combining ability of leafroller defense mechanisms in common bean. Crop Sci 26:1153–1158
Lara FM (1978) Princípios de resistência de plantas à Insetos. Ceres, Piracicaba, p 318
Lindley G (1831) A guide to the orchard and kitchen garden
Luedders VD, Dickerson WA (1977) Resistance of selected soybean genotypes and segregating populations to cabbage looper feeding. Crop Sci 17:395–396
Lyman JM, Cardona C (1982) Resistance in lima beans to a leafhopper, Empoascakrameri. J Econ Entomol 75:281–286
McWilliams JM, Beland GL (1977) Bollworm: effect of soybean leaf age and pod maturity on development in the laboratory. Ann Entomol Soc Am 70:214–216
Mehlenbacher SA, Plaisted RL, Tingey WM (1984) Heritability of trichome density and droplet size in interspecific potato hybrids and relationship to aphid resistance. Crop Sci 24:320–322
Ohm HW, Ratcliffe RH, Patterson FL, Cambron SE (1997) Resistance to Hessian fly conditioned by genes H19 and proposed gene H27 of durum wheat line PI422297. Crop Sci 37:113–115
Ortiz R, Iwanaga M, Raman KV, Palacios M (1990) Breeding for resistance to potato tuber moth, Phthorimaeaoperculella Zeller, in diploid potatoes. Euphytica 50:119–125
Painter RH (1951) Insect resistance in crop plants. McMillian, New York
Panda N, Khush GS (1995) Host plant resistance to insects. Guildford, Biddles
Pathak RS (1991) Genetics of sorhgum, maize, rice and sugarcane resistance to the cereal stem borer Chilo spp. Insect Sci Applic 11:689–699
Rasmusson DC, Phillip RL (1997) Review and interpretation: plant breeding progress and genetic diversity from the new variation and elevated epistasis. Crop Sci 37:303–310
Robinson RA (1996) Return to resistance: breeding crops to reduce pesticide dependence. AgAccess, Davis
Rodriguez JG, Reicosky DA, Patterson CG (1983) Soybean and mite interactions: Effects of cultivar and plant growth stage. J Kans Entomol Soc 56:320–326
Rossetto CJ (1973) Resistência de Plantas a Insetos. ESALQ, Piracicaba
Rossi M, Goggin FL, Milligan SB, Kaloshian I, Ullman DE, Williamson VM (1998) The nematode resistance gene Mi of tomato confers resistance against the potato aphid. PNAS 95:9750–9754
Sams DW, Lauer FI, Radcliffe EB (1976) Breeding behavior of resistance to green peach aphid in tuber-bearing Solanum germplasm. Am Potato J 53:23–29
Sanford LL, Ladd LT (1987) Genetic transmission of potato leafhopper resistance from recurrent selection populations in potato Solanum tuberosum L. Gp. tuberosum. Am Pot J 64:655–662
Sisson VA, Miller PA, Campbell WV, Van Duyn JW (1976) Evidence of inheritance of resistance to the Mexican bean beetle in soybeans. Crop Sci 16:835–837
Smith CM (2005) Plant resistance to arthropods–molecular and conventional approaches. Springer, New York
Smith CM, Brim CA (1979) Field and laboratory evaluations of soybean lines for resistance to corn earworm leaf feeding. J Econ Entomol 72:78–80
Smith CM, Robinson JF (1983) Effect of rice cultivar height on infestation by the least skipper, Ancyloxypha numitor F. Lepidoptera: Hesperiidae. Environ Entomol 12:967–969
Smith RF (1970) Pesticides: their use and limitations in pest management. In: Rabb RL, Guthrie FE (ed) Concepts of pest management. North Caroline State University, Raleigh
Vendramim JD, Nishikawa MA (2001) Melhoramento para resistência a insetos In: Nass LL, Valois AC, Melo IS, Valadares-Inglis MC (ed) Recursos genéticos e melhoramento de plantas. Fundação MT, Rondonópolis
Ventura MU, Pinheiro JB (1999) Resistência de plantas a insetos. In: Destro D, Montalvan R (eds) Melhoramento Genético de Plantas. Universidade Estadual de Londrina, Londrina
Webster JA, Smith Jr DH, Gage SH (1978) Cereal leaf beetle Coleoptera: Chrysomelidae: influence of seeding rate of oats on populations. Great Lakes Entomol, 11:117–120
Widstrom NW (1989) Breeding methodology to increase resistance in maize to corn earworm, fall armyworm and maize weevil. In: Mihm, JA (ed) Toward insect resistant corn for the third world: proceedings of the international symposium on methodologies for developing host plant resistance to corn insects. CIMMYT, Mexico
Widstrom NW, Bondari K, McMillian WW (1992) Hybrid performance among maize populations selected for resistance to insects. Crop Sci 32:85–89
Widstrom NW, Wiseman BR, McMillian WW (1972) Resistance among some maize inbreds and single crosses to fall armyworm injury. Crop Sci 12:290–292.
Widstrom NW, Wiseman BR, McMillian WW (1982) Responses to index selection in maize for resistance to ear damage by the corn earworm. Crop Sci 22:843–846
Widstrom NW, Hamm JJ (1969) Combining abilities and relative dominance among maize inbreds for resistance to earworm injury. Crop Sci 9:216–219
Widstrom NW, McMillian WW (1973) Genetic factors conditioning resistance to earworm in maize. Crop Sci 13:459–461
Williams WP, Davis FM, Buckley PF (1998) Resistance to southwestern corn borer in corn after anthesis. Crop Sci 38:1514–1517
Wilson FD, George BW (1979) Combining ability in cotton for resistance to pink bollworm. Crop Sci 19:834–836
Wilson FD, George BW (1983) A genetic and breeding study of pink bollworm resistance and agronomic properties in cotton. Crop Sci 23:1–4
Wilson FD, Lee JA (1971) Genetic relationships between tobacco budworm feeding response and gland number in cotton seedlings. Crop Sci 11:419–421
Wilson FD, Smith JN (1977) Variable expressivity and gene action of gland-determining alleles in Gossypiumhirsutum L. Crop Sci 17:539–543
Wiseman BF, Bondari K (1995) Inheritance of resistance in maize silks to the corn earworm. Entomol Exp Appl 77:315–321
Wiseman BR (1987) Technological Advances for determining resistance in maize to Heliothiszea. In: Mihm JA (ed) International symposium on methodologies for developing host plant resistance to corn insects: proceedings of the international symposium on methodologies for developing host plant resistance to maize insects 7. CIMMYT, Mexico
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The authors would like to acknowledge the graduate program in genetics and plant breeding of ESALQ/USP for their support in the publication of the current chapter.
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de Morais, A.A., Pinheiro, J.B. (2012). Breeding for Resistance to Insect Pests. In: Fritsche-Neto, R., Borém, A. (eds) Plant Breeding for Biotic Stress Resistance. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-33087-2_6
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