Insect Control: Biological and Synthetic Agents - Index of

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nach Saatgutbeizung. Pflanzenschutz-Nachrichten Bayer 47, 249–303. Tsumura, Y., Nakamura, Y., Tonagai, Y., Kamimoto, Y., Tanaka, Y., et al., 1998. Determination of neonicotinoid pesticide nitenpyram and its metabolites in agricultural products. Shokuhin Eiseigaku Zasshi 39, 127–134. Uneme, H., Iwanaga, K., Higuchi, N., Kando, Y., Okauchi, T., et al., 1999. Syntheses and insecticidal activity of nitroguanidine derivatives. Pestic. Sci. 55,202–205. van den Breukel, I., van Kleef, R.G.D.M., Zwart, R., Oortgiesen, M., 1998. Physiostigmine and acetylcholine differentially activate nicotinic receptor subpopulations in Locusta migratoria neurons. Brain Res. 789, 263–273. Wakita, T., Kinoshita, K., Yamada, E., Yasui, N., Kawahara, N., et al., 2003. The discovery of dinotefuran: a novel neonicotinoid. Pest Mgt Sci. 59, 1016–1022. Weichel, L., Nauen, R., 2003. Monitoring of insecticide resistance in damson hop aphids, Phorodon humuli Schrank (Hemiptera: Aphididae) from German hop gardens. Pest Mgt Sci. 59, 991–998. Werner, G., Hopkins, T., Shmidl, J.A., Watanabe, M., Krieger, K., 1995. Imidacloprid, a novel compound of the chloronicotinyl group with outstanding insecticidal activity in the on-animal treatment of pests. Pharmacol. Res. 31 (Suppl.), 136. Wen, Z.M., Scott, J.G., 1997. Cross-resistance to imidacloprid in strains of German cockroach (Blattella germanica) and housefly (Musca domestica). Pestic. Sci. 49, 367–371. Widmer, H., Steinemann, A., Maienfisch, P., 1999. Chemical and physical properties of thiamethoxam (CGA 293343). In: Abstracts 218th Am. Chem. Sci. Natl Mtg, p. 134. Williams, B., 1993. Reproductive success of cat fleas, Ctenocephalides felis, on calves as unusual host. Med. Vet. Entomol. 7, 94–98. Williamson, M.S., Denholm, I., Bell, C.A., Devonshire, A.L., 1993. Knockdown resistance (kdr) to DDT and pyrethroid insecticides maps to a sodium channel gene locus in the housefly (Musca domestica). Mol. Gen. Genet. 240, 17–22. Williamson, M.S., Martinez-Torres, D., Hick, C.A., Devonshire, A.L., 1996. Identification of mutations in the housefly para-type sodium channel gene associated with knock-down resistance (kdr) to pyrethroid insecticides. Mol. Gen. Genet. 252, 51–60. Wollweber, D., Tietjen, K., 1999. Chloronicotinyl insecticides: a success of the new chemistry. In: Yamamoto, I., Casida, J.E. (Eds.), Neonicotinoid Insecticides and the Nicotinic Acetylcholine Receptor. Springer, New York, pp. 109–125. Yaguchi, Y., Sato, T., 2001. Thiacloprid (Bariard), a novel neonicotinoid insecticide for foliar application. Agrochem. Japan 79, 14–16. Yamada, T., Takahashi, H., Hatano, R., 1999. A novel insecticide, acetamiprid. In: Yamamoto, I., Casida, J.E. (Eds.), Neonicotinoid Insecticides and Nicotinic Acetylcholine Receptor. Springer, New York, pp. 149–175. 3: Neonicotinoid Insecticides 113 Yamamoto, I., 1996. Neonicotinoids: mode of action and selectivity. Agrochem. Japan 68, 14–15. Yamamoto, I., 1998. Nicotine: old and new topics. Rev. Toxicol. 2, 61–69. Yamamoto, I., 1999. Nicotine to neonicotinoids: 162 to 1997. In: Yamamoto, I., Casida, J.E. (Eds.), Neonicotinoid Insecticides and the Nicotinic Acetylcholine Receptor. Springer, New York, pp. 3–27. Yamamoto, I., Tomizawa, M., 1993. New development of nicotinoid insecticides. In: Mitsui, T., Matsumura, F., Yamaguchi, I. (Eds.), Pesticide Development: Molecular Biological Approaches. Pesticide Sci. Soc. Japan, Tokyo, pp. 67–83. Yamamoto, I., Tomizawa, M., Saito, T., Miyamoto, T., Walcott, E.C., et al., 1998. Structural factors contributing to insecticidal and selective actions of neonicotinoids. Arch. Insect. Biochem. Physiol. 37, 24–32. Yamamoto, I., Yabuta, G., Tomizawa, M., Saito, T., Miyamoto, T., et al., 1995. Molecular mechanism for selective toxicity of nicotinoids and neonicotinoids. J. Pestic. Sci. 20, 33–40. Yokota, T., Mikata, K., Nagasaki, H., Ohta, K., 2003. Absorption, tissue distribution, excretion, and metabolism of clothianidin in rats. J. Agric. Food Chem. 51, 7066–7072. Young, D.R., Arther, R.G., Davis, W.L., 2003. Evaluation of K9 Advantix TM vs. Frontline Plus Õ topical treatments to repel brown dog ticks (Rhipicephalus sanguineus) on dogs. Parasitol. Res. 90, 116–118. Young, D.R., Ryan, W.G., 1999. Comparison of Frontline Õ Top Spot TM , Preventic Õ collar alone or combined with Advantage Õ in control of flea and tick infestations in water immersed dogs. In: Proc. 5th Int. Symp. Ectoparas. Pets, Fort Collins, Colorado, April, p. 24. Zewen, L., Zhaojun, H., Yinchang, W., Lingchun, Z., Hongwei, Z., et al., 2003. Selection for imidacloprid resistance in Nilaparvata lugens: cross-resistance patterns and possible mechanisms. Pest Mgt Sci. 59, 1355–1359. Zhang, A., Kayser, H., Maienfisch, P., Casida, J.E., 2000. Insect nicotinic acetylcholine receptor: conserved neonicotinoid specifity of [ 3 H]imidacloprid binding site. J. Neurochem. 75, 1294–1303. Zhao, J.Y., Liu, W., Brown, J.M., Knowles, C.O., 1995. Insecticide resistance in field and laboratory strains of Western flower thrips (Thysanoptera: Thripidae). J. Econ. Entomol. 88, 1164–1170. Zhao, J.Z., Bishop, B.A., Graphius, E.J., 2000. Inheritance and synergism of resistance to imidacloprid in the Colorado potato beetle (Coleoptera: Chrysomelidae). J. Econ. Entomol. 93, 1508–1514. Zhu, K.Y., Clark, J.M., 1997. Validation of a point mutation of acetylcholinesterase in Colorado potato beetle by polymerase chain reaction coupled to enzyme inhibition assay. Pestic. Biochem. Physiol. 57, 28–35. Zwart, R., Oortgiesen, M., Vijverberg, H.P., 1992. The nitromethylene heterocycle 1-(pyridin-3-yl-methyl)- 2-nitromethylene-imidazolidine distinguishes mammalian from insect nicotinic receptor subtypes. Eur. J. Pharmacol. 228, 165–169.
A3 Addendum: The Neonicotinoid Insecticides P Jeschke, Bayer CropScience AG, Monheim am Rhein, Germany R Nauen, Bayer CropScience AG, Monheim am Rhein, Germany ß 2010 Elsevier B.V. All Rights Reserved During the last 5 years neonicotinoid insecticides and their biochemical target-site, the insect nicotinic acetylcholine receptor (nAChR), have been described in several excellent reviews, which should serve as additional sources for information (Tomizawa et al., 2005; Thany et al., 2007; Jeschke, 2007a, b; Jeschke and Nauen, 2008; Elbert et al., 2008). These reviews and other numerous articles describe the current knowledge of seven commercially marketed active ingredients such as: (1) the ring systems containing neonicotinoids like imidacloprid (Hopkins et al., 2005; Thielert, 2006), thiacloprid (Jeschke and Nauen, 2008) and thiamethoxam (Maienfisch, 2007), as well as (2) neonicotinoids having non-cyclic structures like acetamiprid, nitenpyram, clothianidin, and dinotefuran (Jeschke and Nauen, 2008; Wakita, 2008). In addition, transformation of neonicotinoids (1) into (2), exemplified by a partial cleavage of thiamethoxam into clothianidin in-vivo in insects and plant tissues, was further discussed (Kayser et al., 2007; Jeschke and Nauen, 2007). There has been rapid progress in research on nAChRs. In 2001, the crystal structures of the first soluble homopentameric acetylcholine binding protein (AChBP) was resolved (Brejc et al., 2001; Smit et al., 2001). This AChBP subtype is secreted by glia cells of a mollusk, the freshwater snail Lymnaea stagnalis (L-AChBP). Some years later a second AChBP subtype (A-AChBP), isolated from the saltwater mollusk Aplysia californica, was characterized. A-AChBP shares only 33% amino acid identity with L-AChBP, but it possesses all the functional residues identified in L-AChBP (Hansen et al., 2004; Celie et al., 2005). Whereas A-AChBP has a similar high sensitivity for both electronegative neonicotinoids and cationic nicotinoids and the L-AChBP demonstrates lower neonicotinoid and higher nicotinoid sensitivities (Tomizawa et al., 2008; Tomizawa and Casida, 2009). Thus, these two AChBPs from mollusks have distinct pharmacology suggestive of the nAChRs from species as divergent as mammals and insects (Tomizawa et al., 2008). Furthermore, a refined 4 A ˚ resolution electron microscopy structure of the heteropentameric vertebrate muscle type (a1)2bgd nAChR showed considerable structural similarity to the L-AChBP ligand binding domain (LBD) (Unwin, 2005). Because of this similarity, L-AChBP is now considered a structural and functional surrogate for the extracellular LBD of insect nAChRs (Talley et al., 2008). Therefore, the ACh binding site of the crystalline structures of AChBPs can be used as an example for the N-terminal domain of an a-subunit of insect nAChRs as a template for docking simulations (CoMFA, 3D QSAR) of ACh ligands such as neonicotinoid insecticides by so-called manual or automated modeling methods. Because of the identical pharmacological profile of AChBPs for neonicotinoids and nicotinoid radioligands (Tomizawa et al., 2007a, b), a deeper insight into molecular determinants of neonicotinoid agonists interacting with their respective binding sites on insect nAChRs is possible (Gao et al., 2006).It was found that the chlorine atom in 6-chloropyrid-3ylmethyl (CPM) of imidacloprid and thiacloprid contacts isoleucine (Ile) 106/methionine (Met) 116 and the pyridine nitrogen is directed to Ile 118/tryptophan (Trp) 147 via a solvent bridge (Casida and Tomizawa, 2008). The guanidine/amidine plane undergoes p-stacking with tyrosine (Tyr) 188 and the pharmacophore group (e.g., [=N–NO2], [=CH–NO 2]or [=N–CN]) interacts with serine (Ser) 189/cysteine (Cys) 190, thereby defining the binding pocket that models AChBPs and possibly insect nAChRs potency and selectivity. Characteristic of several agonists such as imidacloprid and thiacloprid, loop C largely envelops the ligand, positioning aromatic side chains to interact optimally with conjugated and hydrophobic regions of the neonicotinoid insecticides, which is consistent with the results of solution-based photoaffinity labelings (Talley et al., 2008).
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INSECT CONTROL BIOLOGICAL AND SYNTH
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INSECT CONTROL BIOLOGICAL AND SYNTH
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CONTENTS Preface vii Contributors i
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PREFACE When Elsevier published the
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J T Andaloro E. I. Du Pont de Nemou
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1 Pyrethroids B P S Khambay and P J
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activity. In contrast to most other
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Figure 1 Commercial and novel pyret
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Figure 2 Pyrethroids referred to in
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4-position result in almost complet
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and their primary site of action is
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Figure 4 Folded and extended confor
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aromatic rings or methyl groups by
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pyrethroids) and consequently a sec
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1998), although the precise mechani
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polymorphisms in the protein. Of th
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observed resistance to pyrethroids,
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propoxur against Culex quinquefasci
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esistance in house fly. Insect Bioc
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Shan, G.M., Hammock, B.D., 2001. De
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A1.4. Resistance The increasing num
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B A IIS4-S5 linker, IIS5 helix and
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2 Indoxacarb and the Sodium Channel
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Figure 2 Structures of pyrazoline-l
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observed that both indoxacarb and i
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deflections resulting from stresses
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Figure 8 Dihydropyrazole block appe
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potential conduction in the CNS of
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known to affect blocker affinity, w
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Figure 13 Diagrammatic representati
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that the probable mechanism of ovil
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conventional chemistries and spinos
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Clare, J.J., Tate, S.N., Nobbs, M.,
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Tsurubuchi, Y., Karasawa, A., Nagat
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R1 N N O N H indoxacarb. Thus, whil
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3 Neonicotinoid Insecticides P Jesc
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Page 82 and 83: sampling using forcefield methods (
Page 84 and 85: Figure 9 Stable conformations and p
Page 86 and 87: Figure 13 Binding to putative catio
Page 88 and 89: Figure 14 Systemicity of neonicotin
Page 90 and 91: site (Kayser et al., 2002). Clothia
Page 92 and 93: Figure 20 Important pest insects ta
Page 94 and 95: Barley yellow dwarf virus vectors s
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Page 112 and 113: Figure 25 Flea control achieved wit
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Page 116 and 117: Brown, J.K., Perring, T.M., Cooper,
Page 118 and 119: In: Ishaaya, I. (Ed.), Biochemical
Page 120 and 121: Léna, C., Changeux, J.-P., 1993. A
Page 122 and 123: patterns in Colorado potato beetle
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Page 130 and 131: Biochem. Physiol., doi: 10.1016/j.p
Page 132 and 133: 4 Insect Growth- and Development-Di
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Page 136 and 137: Table 1 Bisacylhydrazine insecticid
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Page 140 and 141: to the three EcRs with either muris
Page 142 and 143: of action of ecdysone agonists was
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Page 148 and 149: dipteran insects, like the midge, C
Page 150 and 151: eetle (Exomala orientalis) when app
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Page 154 and 155: y specific proteins in signaling pa
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Page 158 and 159: can be reversed by applying JH. JH
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Page 162 and 163: apparent that it was a bHLH-PAS and
Page 164 and 165: Table 9 Continued Bemisia tabaci (s
Page 166 and 167: Table 11 Insect control with some a
Page 168 and 169: Table 13 Ecotoxicological profile o
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Table 15 Environmental effects of s
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ecessive (R male S female) manner,
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esistance management programs due t
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IPS Paraconfusus lanier (Coleoptera
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larvae parasitized by Microplitis r
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Kostyukovsky, M., Chen, B., Atsmi,
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Three-dimensional quantitative stru
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Riddiford, L.M., 1994. Cellular and
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characterization of resistant clone
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Biological Approaches to Pest Contr
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M389 L308 M272 T304 T393 V404 L420
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5 Azadirachtin, a Natural Product i
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and Hemiptera and was related to ef
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eported, but this is rather nonspec
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important source of pest control at
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effects with physiological effects
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eing associated with an accumulatio
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et al., 1992). Salehzadeh et al. (2
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ehavior of Spodoptera littoralis (p
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indica A. Juss. IBH Publishing Comp
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Smith, S.L., Mitchell, M.J., 1988.
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which interact directly with azadir
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6 The Spinosyns: Chemistry, Biochem
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Table 1 Structures of the spinosyns
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Table 2 Biological activity of spin
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A large synthetic effort has gone i
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216 6: The Spinosyns: Chemistry, Bi
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Figure 4 Spinosad metabolism in avi
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A6 Addendum: The Spinosyns T C Spar
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246 A6: Addendum Scott, 2008) and i
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248 7: Bacillus thuringiensis: Mech
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A7 Addendum: Bacillus thuringiensis
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280 A7: Addendum toxins is magnitud
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Table 1 Comparative properties of s
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286 8: Mosquitocidal B. sphaericus:
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Table 4 Characteristics of various
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A8 Addendum: Bacillus sphaericus Ta
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310 A8: Addendum essential to devel
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314 9: Insecticidal Toxins from Pho
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A9 Addendum: Recent Advances in Pho
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330 A9: Addendum Lee, S.C., Stoilov
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332 10: Genetically Modified Baculo
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384 A10: Addendum cysteine protease
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388 11: Entomopathogenic Fungi and
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Zare, R., Gams, W., Culham, A., 200
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434 A11: Addendum although a number
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436 A11: Addendum Examination of ge
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440 12: Insect Transformation for U
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448 A12: Addendum genetic transform
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452 Subject Index Aphis gossypii (c
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454 Subject Index Bisacylhydrazine
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456 Subject Index Cry toxins (conti
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458 Subject Index Entomopathogenic
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460 Subject Index Homoptera molting
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462 Subject Index Kinoprene (ENSTAR
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464 Subject Index Muscle(s) sodium
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466 Subject Index Photorhabdus (con
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468 Subject Index Sodium channel bl
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470 Subject Index Toxocara cati, im
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