Insect Control: Biological and Synthetic Agents - Index of

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B A IIS4-S5 linker, IIS5 helix and IIIS6 helix that cause reduced sensitivity to pyrethroids and DDT in resistant insect and mite strains, and (5) the binding site will also accommodate DDT, albeit with a reduced number of contacts, which in turn is consistent with the lower potency of this compound compared with pyrethroids. The publication of this model, and further dockings of a range of pyrethroid and DDT structures, identifies a number of additional residues, above and beyond those already highlighted from resistance studies, that are also predicted to form important ligand–target interactions within the binding site. These predictions can be investigated experimentally and two recent mutagenesis/expression studies have confirmed an important role for several new residues in the IIS4-S5 linker/IIS5 helix (Usherwood et al., 2007) and IIIS6 helix (Du et al., 2009), thereby reinforcing the validity of the original model. This research provides an opportunity to re-examine species-specific differences in sodium channel sequences between insects and mammals that are responsible for the exquisite insect (and C A1: Addendum 33 Figure A1 Structural model of the housefly sodium channel showing the putative binding site for pyrethroids and DDT (Reproduced with permission, from O’Reilly, A.O., Khambay, B.P.S., Williamson, M.S., Field, L.M., Wallace, B.A., Davies, T.G.E., 2006. Modelling insecticide-binding sites in the voltage-gated sodium channel. Biochem. J. 396, 255–263. ª The Biochemical Society). (a) Homology model with the voltage sensor domains coloured red and central pore helices in blue, cyan and yellow. The pyrethroid fenvalerate (grey space fill) is shown docked at the binding site. (b, c) Close-up docking predictions for fenvalerate (b) and DDT (c) within the binding site, highlighting the residues involved in ligand–target interactions. mite) selectivity of these compounds. By combining increased processing power of modern computers with improved programs for in silico ligand/protein predictions, it may now be possible to re-model structural features that contribute to insect selectivity at the species level (e.g., in comparing crop pests with beneficial insects), and to design novel ‘‘resistance-defeating’’ pyrethroid derivatives that bind with higher affinity within the binding site of strains that carry preexisting resistance mutations. A1.6. Conclusions and Future Prospects Although research activity in pyrethroid chemistry has largely ceased, with the industry focus shifting more towards less neurotoxic modes of action, the pyrethroids, nevertheless, remain major player in the world insecticide market and are particularly important for the more restricted public health market. Significant progress has been achieved in our understanding of pyrethroid sodium channel pharmacology and molecular characterization of pyrethroid resistance mechanisms. Translation of
34 A1: Addendum this research into practical applications, such as rapid and sensitive molecular diagnostics for resistance monitoring and the development of synergistic inhibitors for existing insecticide formulations will hopefully improve the sustainability of pyrethroid applications by supporting the implementation of effective resistance management strategies that combat the onset and spread of resistance. Acknowledgments Rothamsted Research receives grant-aided support from the Biotechnology and Biological Research Council of the United Kingdom. References Anadon, A., Martinez-Larranaga, M.R., Martinez, M.A., 2009. Use and abuse of pyrethrins and synthetic pyrethroids in veterinary medicine. Vet. J. 182, 7–20. Bautista, M.A.M., Miyata, T., Miura, K., Tanaka, T., 2009. RNA interference-mediated knockdown of a cytochrome P450, CYP6BG1, from the diamondback moth, Plutella xylostella, reduces larval resistance to permethrin. Insect. Biochem. Mol. Biol. 39, 38–46. Bingham, G., Gunning, R.V., Gorman, K., Field, L.M., Moores, G.D., 2007. Temporal synergism by microencapsulation of piperonyl butoxide and alphacypermethrin overcomes insecticide resistance in crop pests. Pest. Manag. Sci. 63, 276–281. Boonsuepsakul, S., Luepromchai, E., Rongnoparut, P., 2008. Characterization of Anopheles minimus CYP6AA3 expressed in a recombinant baculovirus system. Arch. Insect Biochem. Physiol. 69, 13–21. Davies, T.G.E., Field, L.M., Usherwood, P.N.R., Williamson, M.S., 2007. DDT, pyrethrins, pyrethroids and insect sodium channels. IUBMB Life 59, 151–162. Du, Y., Nomura, Y., Luo, N., Liu, Z., Lee, J.-E., Khambay, B., Dong, K., 2009. Molecular determinants on the insect sodium channel for the specific action of type II pyrethroid insecticides. Toxicol. Appl. Pharmacol. 234, 266–272. Grubor, V.D., Heckel, D.G., 2007. Evaluation of the role of CYP6B cytochrome P450s in pyrethroid resistant Australian Helicoverpa armigera. Insect. Mol. Biol. 16, 15–23. Hardstone, M.C., Leichter, C.A., Scott, J.G., 2009. Multiplicative interaction between the two major mechanisms of permethrin resistance, kdr and cytochrome P450-monooxygenase detoxification, in mosquitoes. J. Evol. Biol. 22, 416–423. Kawada, H., Yen, N.T., Hoa, N.T., Sang, T.M., Dan, N.V., Takagi, M., 2005. Field evaluation of spatial repellency of metofluthrin impregnated plastic strips against mosquitoes in Hai Phong city, Vietnam. Am J. Trop. Med. Hyg. 73, 350–353. Khambay, B., Jewess, P., 2005. Pyrethroids. In: Gilbert, L.I., Iatrou, K., Gill, S.S. (Eds.), Comprehensive Molecular Insect Science, Vol. 6. Elsevier, Oxford, UK, pp. 1–29. Long, S.B., Campbell, E.B., Mackinnon, R., 2005. Crystal structure of a mammalian voltage-dependent Shaker family K+ channel. Science 309, 897–903. Muller, P., Warr, E., Stevenson, B.J., Pignatelli, P.M., Morgan, J.C., Steven, A., Yawson, A.E., Mitchell, S.N., Ranson, H., Hemingway, J., Paine, M.J.I., Donnelly, M.J., 2008. Field-caught permethrin-resistant Anopheles gambiae overexpress CYP6P3, a P450 that metabolises pyrethroids. Plos Genetics 4, Genet 4(11): e1000286. doi:10.1371/journal.pgen.1000286. O’Reilly, A.O., Khambay, B.P.S., Williamson, M.S., Field, L.M., Wallace, B.A., Davies, T.G.E., 2006. Modelling insecticide-binding sites in the voltagegated sodium channel. Biochem. J. 396, 255–263. Pasay, C., Arlian, L., Morgan, M., Vyszenski-Moher, D., Rose, A., Holt, D., Walton, S., McCarthy, J., 2008. High-resolution melt analysis for the detection of a mutation associated with permethrin resistance in a population of scabies mites. Med. Vet. Entomol. 22, 82–88. Saavedra-Rodriguez, K., Urdaneta-Marquez, L., Rajatileka, S., Moulton, M., Flores, A.E., Fernandez- Salas, I., Bisset, J., Rodriguez, M., McCall, P.J., Donnelly, M.J., Ranson, H., Hemingway, J., Black, W.C., 2007. A mutation in the voltage-gated sodium channel gene associated with pyrethroid resistance in Latin American Aedes aegypti. Insect. Mol. Biol. 16, 785–798. Silverio, F.O., Alvarenga, E.S.D., Moreno, S.C., Picanco, M.C., 2009. Synthesis and insecticidal activity of new pyrethroids. Pest. Manag. Sci. 65, 900–905. Soderlund, D.M., 2008. Pyrethroids, knockdown resistance and sodium channels. Pest. Manag. Sci. 64, 610–616. Sonoda, S., Igaki, C., Tsumuki, H., 2008. Alternatively spliced sodium channel transcripts expressed in field strains of the diamondback moth. Insect. Biochem. Mol. Biol. 38, 883–890. Tsagkarakou, A., Van Leeuwen, T., Khajehali, J., Ilias, A., Grispou, M., Williamson, M.S., Tirry, L., Vontas, J., 2009. Identification of pyrethroid resistance associated mutations in the para sodium channel of the twospotted spider mite Tetranychus urticae (Acari: Tetranychidae). Insect. Mol. Biol. 18, 583–593. Wondji, C.S., Irving, H., Morgan, J., Lobo, N.F., Collins, F.H., Hunt, R.H., Coetzee, M., Hemingway, J., Ranson, H., 2009. Two duplicated P450 genes are associated with pyrethroid resistance in Anopheles funestus, a major malaria vector. Genome Res. 19, 452–459. Usherwood, P.N.R., Davies, T.G.E., Mellor, I.R., O’Reilly, A.O., Peng, F., Vais, H., Khambay, B.P.S., Field, L.M., Williamson, M.S., 2007. Mutations in DIIS5 and the DIIS4-S5 linker of Drosophila melanogaster sodium channel define binding domains for pyrethroids and DDT. FEBS Lett. 581, 5485–5492. Yoon, K.S., Kwon, D.H., Strycharz, J.P., Hollingsworth, C.S., Lee, S.H., Clark, A.J.M., 2008. Biochemical and molecular analysis of deltamethrin resistance in the common bed bug (Hemiptera: Cimicidae). J. Med. Entomol. 45, 1092–1101. Yang, Y., Yue, L., Chen, S., Wu, Y., 2008. Functional expression of Helicoverpa armigera CYP9A12 and CYP9A14 in Saccharomyces cerevisiae. Pest. Biochem. Physiol. 92, 101–105.
Page 2 and 3: INSECT CONTROL BIOLOGICAL AND SYNTH
Page 4 and 5: INSECT CONTROL BIOLOGICAL AND SYNTH
Page 6 and 7: CONTENTS Preface vii Contributors i
Page 8 and 9: PREFACE When Elsevier published the
Page 10 and 11: J T Andaloro E. I. Du Pont de Nemou
Page 12 and 13: 1 Pyrethroids B P S Khambay and P J
Page 14 and 15: activity. In contrast to most other
Page 16 and 17: Figure 1 Commercial and novel pyret
Page 18 and 19: Figure 2 Pyrethroids referred to in
Page 20 and 21: 4-position result in almost complet
Page 22 and 23: and their primary site of action is
Page 24 and 25: Figure 4 Folded and extended confor
Page 26 and 27: aromatic rings or methyl groups by
Page 28 and 29: pyrethroids) and consequently a sec
Page 30 and 31: 1998), although the precise mechani
Page 32 and 33: polymorphisms in the protein. Of th
Page 34 and 35: observed resistance to pyrethroids,
Page 36 and 37: propoxur against Culex quinquefasci
Page 38 and 39: esistance in house fly. Insect Bioc
Page 40 and 41: Shan, G.M., Hammock, B.D., 2001. De
Page 42 and 43: A1.4. Resistance The increasing num
Page 46 and 47: 2 Indoxacarb and the Sodium Channel
Page 48 and 49: Figure 2 Structures of pyrazoline-l
Page 50 and 51: observed that both indoxacarb and i
Page 52 and 53: deflections resulting from stresses
Page 54 and 55: Figure 8 Dihydropyrazole block appe
Page 56 and 57: potential conduction in the CNS of
Page 58 and 59: known to affect blocker affinity, w
Page 60 and 61: Figure 13 Diagrammatic representati
Page 62 and 63: that the probable mechanism of ovil
Page 64 and 65: conventional chemistries and spinos
Page 66 and 67: Clare, J.J., Tate, S.N., Nobbs, M.,
Page 68 and 69: Tsurubuchi, Y., Karasawa, A., Nagat
Page 70 and 71: R1 N N O N H indoxacarb. Thus, whil
Page 72 and 73: 3 Neonicotinoid Insecticides P Jesc
Page 74 and 75: esidues, like the pyrid-3-ylmethyl
Page 76 and 77: containing neonicotinoids, and neon
Page 78 and 79: Studies were also done using compar
Page 80 and 81: Becke, 1988; Klamt, 1995) level of
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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investigate the mode of action of n
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within the desensitized state over
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the accumulation of this acid in th
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3.8.1. Safety Profile The introduct
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Table 7 Environmental profile of co
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substance is bound irreversibly to
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imidacloprid conferring a high leve
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nAChR are comparable to the efficac
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Figure 25 Flea control achieved wit
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and the resolution of FAD was teste
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Brown, J.K., Perring, T.M., Cooper,
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In: Ishaaya, I. (Ed.), Biochemical
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Léna, C., Changeux, J.-P., 1993. A
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patterns in Colorado potato beetle
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nach Saatgutbeizung. Pflanzenschutz
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Today, photoaffinity labeling (e.g.
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for control of stinkbugs in soybean
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Biochem. Physiol., doi: 10.1016/j.p
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4 Insect Growth- and Development-Di
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The molting process is initiated by
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Table 1 Bisacylhydrazine insecticid
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4.2.2. Bisacylhydrazines as Tools o
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to the three EcRs with either muris
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of action of ecdysone agonists was
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thus inducing effects and symptomol
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and microsomes. Subsequently, Willi
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dipteran insects, like the midge, C
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eetle (Exomala orientalis) when app
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metabolic fate studies showed the i
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y specific proteins in signaling pa
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their reduced risk for the environm
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can be reversed by applying JH. JH
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door for a more rational approach t
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apparent that it was a bHLH-PAS and
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Table 9 Continued Bemisia tabaci (s
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Table 11 Insect control with some a
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Table 13 Ecotoxicological profile o
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Flucycloxuron Nonsystemic acaricide
Page 172 and 173:
The discovery of diflubenzuron spaw
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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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