[1]Alon F, Alon M, Morin S. 2010. The involvement ofglutathione S-tranferases in the interactions betweenBemisia tabaci (Hemiptera: Aleyrodidae) and itsBrassicaceae hosts. Israel Journal of Plant Sciences,58, 93-102[2]An Z, Chu D, Guo D, Fan Z, Tao Y, Liu G, Zhang Y. 2008.Effects of host plant on activities of some detoxificationenzymes in Bemisia tabaci biotype B. Acta EcologicaSinica, 28, 1536-1543 (in Chinese)[3]Bernays E A, Chapman R F. 1994. Host-Plant Selection byPhytophagous Insects. Chapman and Hall, New York. Bernays E A, Graham M. 1988. On the evolution of hostspecificity in phytophagous arthropods. Ecology, 69,886-892[4]Bradford M M. 1976. A rapid and sensitive method forquantitation of microgram quantities of protein utilizingthe principle of protein-dye-binding. AnalyticalChemistry, 72, 248-254[5]de Barro P J, Liu S S, Boykin L M, Dinsdale A B. 2011.Bemisia tabaci: a statement of species status. AnnualReview of Entomology, 56, 1-19[6]Büyükgüzel E. 2009. Evidence of oxidative and antioxidativeresponses by Galleria mellonella larvae to malathion.Journal of Economic Entomology, 102, 152-159[7]Büyükgüzel E, Kalender Y. 2009. Exposure to streptomycinalters oxidative and antioxidative response in larvalmidgut tissues of Galleria mellonella. PesticideBiochemistry and Physiology, 94, 112-118[8]Büyükgüzel E, Hyršl P, Büyükgüzel K. 2010. Eicosanoidsmediate hemolymph oxidative and antioxidativeresponse in larvae of Galleria mellonella L.Comparative Biochemistry and Physiology (Part A),156, 176-183[9]Castañeda L E, Figueroa C C, Fuentes-Contreras E,Niemeyer H M, Nespolo R F. 2010a. Physiologicalapproach to explain the ecological success of‘superclones’ in aphids: Interplay betweendetoxification enzymes, metabolism and fitness.Journal of Insect Physiology, 56, 1058-1064[10]Castañeda L E, Figueroa C C, Nespolo R F. 2010b. Do insectpests perform better on highly defended plants? Costsand benefits of induced detoxification defences in theaphid Sitobion avenae. Journal of EvolutionaryBiology, 23, 2474-2483[11]Castle S J, Prabhaker N, Henneberry T J, Toscano N C.2009. Host plant influence on susceptibility of Bemisiatabaci (Hemiptera: Aleyrodidae) to insecticides.Bulletin of Entomological Research, 99, 263-273[12]Després L, David J P, Gallet C. 2007. The evolutionaryecology of insect resistance to plant chemicals. Trendsin Ecology and Evolution, 22, 298-307[13]Ding S, Li H, Li X, Zhang Z. 2001. Effects of two kinds oftransgenic poplar on protective enzymes system in themidgut of larvae of American white moth. Journal ofForestry Research, 12, 119-122[14]Fröhlich D R, Torres-Jerez I, Bedford I D, Markham P G,Brown J K. 1999. A phylogeographical analysis of theBemisia tabaci species complex based on mitochondrialDNA markers. Molecular Ecology, 8, 1683-1691[15]Fujimoto Y, Kobayashi A, Kurata S, Natori S. 1999. Twosubunits of the insect 26/29-kDa proteinase areprobably derived from a common precursor protein. TheJournal of Biochemistry, 125, 566-573[16]Gao X W. 1992. Effect of host plant on carboxylesteraseactivity in cotton aphid Aphis gossypii Glov. ActaEntomologica Sinica, 3, 267-272 (in Chinese)[17]Habig W H, Pabst M J, Jakoby W B. 1974. Glutathione Stransferases,the first step in mercapturic acid formation.The Journal of Biological Chemistry, 249, 71-75[18]Iida H, Kitamura T, Honda K. 2009. Comparison of egghatchingrate, survival rate and development time ofthe immature stage between B- and Q-biotypes ofBemisia tabaci (Gennadius) (Homoptera: Aleyrodidae)on various agricultural crops. Applied Entomology andZoology, 44, 267-273[19]Jiang T, Chu D, Jiang D, Tao Y, Liu G, Fan Z. 2009. Activitydynamics of phenylalanine ammonia-lyase andprotective enzymes in transgenic Bt+CpTI cottoninduced by Bemisia tabaci feeding. ShandongAgricultural Sciences, 10, 48-53 (in Chinese[20])Kong G C, Daud M K, Zhu S J. 2010. Effects of pigmentglands and gossypol on growth, development andinsecticide-resistance of cotton bollworm (Heliothisarmigera (Hübner)). Crop Protection, 29, 813-819[21]Kopp A, Barmina O, Hamilton A M, Higgins L, McIntyre LM, Jones C D. 2008. Evolution of gene expression inthe Drosophila olfactory system. Molecular Biologyand Evolution, 25, 1081-1092[22]Kotkar H M, Sarate P J, Tamhane V A, Gupta V S, Giri V P.2009. Responses of midgut amylases of Helicoverpaarmigera to feeding on various host plants. Journal ofInsect Physiology, 55, 663-670[23]Li J, Ruan Y, Li F, Liu S, Wang X. 2011. Gene expressionprofiling of the whitefly (Bemisia tabaci) Middle East-Asia Minor 1 feeding on healthy and Tomato yellowleaf curl China virus-infected tobacco. Insect Science,18, 11-22[24]Li S, Xue X, Ahmed M Z, Ren S, Du Y, Wu J, CuthbertsonA G S, Qiu B. 2011. Host plants and natural enemies ofBemisia tabaci (Hemiptera: Aleyrodidae) in China.Insect Science, 18, 101-120[25]Li X C, Berenbaum M R Schuler M A. 2002a. Plantallelochemicals differentially regulate Helicoverpa zeacytochrome P450 genes. Insect Molecular Biology, 11,343-351[26]Li X C, Schuler M, Berenbaum M R. 2002b. Jasmonate andsalicylate induce expression of herbivore cytochromeP450 genes. Nature, 419, 712-715[27]Li X C, Schuler M, Berenbaum M R. 2007. Molecularmechanisms of metabolic resistance to synthetic andnatural xenobiotics. Annual Review of Entomology, 52,231-253[28]Li Z, Shen H, Jiang Q, Ji B. 1994. A study on the activities ofendogenous enzymes of protective system in someinsects. Acta Entomologica Sinica, 37, 399-403 (in Chinese)[29]Liang P, Cui J Z, Yang X Q, Gao X W. 2007. Effects of hostp l a n t s o n i n s e c t i c i d e s u s c e p t i b i l i t y a n dcarboxylesterase activity in Bemisia tabaci biotype Band greenhouse whitefly. Trialeurodes vaporariorum.Pest Management Science, 63, 365-371[30]Lindroth R L, Weisbrod A V. 1991. Genetic variation inresponse of the gypsy moth to aspen phenolicglycosides. Biochemical Systematics and Ecology, 19,197-203[31]Liu B, Shu C, Xue K, Zhou K, Li X, Liu D. 2009. The oraltoxicity of the transgenic Bt+CpTI cotton pollen tohoneybees (Apis mellifera). Ecotoxicology andEnvironmental Safety, 72, 1163-1169[32]Liu S, Colvin J, de Barro P J. 2012. Species concepts asapplied to the whitefly Bemisia tabaci systematics: howmany species are there? Journal of IntegrativeAgriculture, 11, 176-186[33]Lowry O H, Rosebrough N J, Farr A L. 1951. Proteinmeasurement with the Folin-phenol reagent. TheJournal of Biological Chemistry, 193, 265-275[34]Luan J, Xu J, Lin K, Myron P Z, Liu S. 2012. Species exclusionbetween an invasive and an indigenous whitefly onhost plants with differential levels of suitability. Journalof Integrative Agriculture, 11, 215-224[35]Ma Z, Han X, Feng J, Li G, Zhang X. 2008. Effects ofTerpinen-4-ol on four metabolic enzymes andpolyphenol oxidase (PPO) in Mythimna separta walkerAgricultural Sciences in China, 7, 726-730[36]Mansaray A, Sundufu A J. 2009. Oviposition, developmentand survivorship of the sweetpotato whitefly Bemisiatabaci on soybean, Glycine max, and the garden bean,Phaseolus vulgaris. Journal of Insect Science, 9, 1-6[37]Mendiola-Olaya E, Valencia-Jimenez A, Valdes-RodriguezS, Delano-Frier J, Blanco-Labra A. 2000. Digestiveamylase from the larger grain borer, Prostephanustruncatus Horn. Comparative Biochemistry andPhysiology (Part B), 126, 425-433[38]Miller G L. 1959. Use of dinitrosalicylic acid reagent fordetermination of reducing sugar. Analytical Chemistry,31, 426-428[39]Mou S. 2005. Eeffet of Quercetin and 2-tridecanone onspecific activities of carboxylesterase, glutathionestransefraseand acetyleholinesterase in Bemisia tabaci.Ph D thesis, China Agricultural University, Beijing. (inChinese)Mukherjee S. 2003. Influence of plant allelochemicals ongrowth rate, nutritional physiology and midgut esteraseactivity in fifth instar larvae of Spodoptera litura (F.)(Lepidoptera: Noctuidae). Invertebrate Reproductionand Development, 43, 125-132[40]Naseri B, Fathipour Y, Moharramipour S, HosseininavehV, Gatehouse A M R. 2010. Digestive proteolytic andamylolytic activities of Helicoverpa armigera inresponse to feeding on different soybean cultivars. PestManagement Science, 66, 1316-1323[41]Nasr H M, Badawy M E I, Rabea E I. 2010. Toxicity andbiochemical study of two insect growth regulators,buprofezin and pyriproxyfen, on cotton leafwormSpodoptera littoralis. Pesticide Biochemistry andPhysiology, 98, 198-205[42]Oliveira M R V, Henneberry T J, Anderson P. 2001. History,current status and collaborative research projects forBemisia tabaci. Crop Protection, 20, 709-723[43]Rose R, Barbhaiya L, Roe R, Rock G, Hodgson E. 1995.Cytochrome P-450-associated insecticide resistance andthe development of biochemical diagnostic assays inHeliothis virescens[44]Pesticide Biochemistry andPhysiology, 51, 178-191[45]Saito H, Kurata S, Natori S. 1992. Purification andcharacterization of a hemocyte proteinase ofSarcophaga, possibly participating in elimination off o r e i g n s u b s t a n c e s . European Journal ofBiochemistry, 209, 939-944[46]Schoonhoven L M, van Loon J J A, Dicke M. 2005. Insect-Plant Biology, 2nd ed. Oxford University Press, NewYork.Schuler M A. 2011. P450s in plant-insect interactions.Biochimica et Biophysica Acta, 1814, 36-45[47]Smadja C, Butlin R K. 2009. On the scent of speciation: thechemosensory system and its role in prematingisolation. Heredity, 102, 77-97[48]Stumpf N, Nauen R. 2002. Biochemical markers linked toabamectin resistance in Tetranychus urticae (Acari:Tetranychidae). Pesticide Biochemistry andPhysiology, 72, 111-121[49]Vanhaelen N, Haubruge E, Lognay G, Francis F. 2001.Hoverfly glutathione S-transferases and effect ofBrassicaceae secondary metabolites. PesticideBiochemistry and Physiology, 71, 170-177[50]Wang H, Li X, Zhang N. 2007. Effects of host shifts on thecarboxylesterase and acetyleholinesterase activities inBemisia tabaci. In: Annual Meeting of China Societyof Plant Protection. Beijing, China. pp. 25-30[51](inChinese)Wu K M, Lu Y H, Feng H Q, Jiang Y Y, Zhao J Z. 2008.Suppression of cotton bollworm in multiple crops inChina in areas with Bt toxin-containing cotton. Science,321, 1676-1678[52]Xie W, Wang S L, Wu Q J, Feng Y T, Pan H P, Jiao X G,Zhou L, Yang Y, Fu W, Teng H Y, et al. 2011. Inductioneffects of host plants on insecticide susceptibility anddetoxification enzymes of Bemisia tabaci (Hemiptera:Aleyrodidae). Pest Management Science, 67, 87-93[53]Yan Y, Peng L, Liu W, Wan F, Harris M K. 2011. Host planteffects on alkaline phosphatase activity in thewhiteflies, Bemisia tabaci biotype B and Trialeurodesvaporariorum. Journal of Insect Science, 11, 9.[54]Zang L S, Chen W Q, Liu S S. 2006. Comparison ofperformance on different host plants between the Bbiotype and a non-B biotype of Bemisia tabaci fromZhejiang, China. Entomologia Experimentalis etApplicata, 121, 221-227[55]Zhang G, Lei F, Wan F, Ma J, Yang Y. 2008. Effects of plantspecies switching on dynamics of amylase andproteinase activity of Bemisia tabaci biotype B andTrialeurodes vaporariorum. Biodiversity Science, 16,313-320.[56]Zhou F, Li C, Zhou G, Gu A, Wang P. 2010. Responses ofdetoxification enzymes in Bemisia tabaci (Gennadius)to host shift. Acta Ecologica Sinica, 30, 1806-1811. (in Chinese) |