Azimi S, Rahmani Sh & Ashoori A, 2016. Effects of Bt cotton on biological characteristics of Macrolophus pygmeus Rambur (Hem.: Miridae). Plant Pest Research 6(2): 75–86.
Bonsignore C P, 2015. Effect of environmental factors on the flight activity of Trialeurodes vaporariorum (Westwood) under greenhouse conditions. Entomological Science 18: 207–216.
Blancard D, 2012. Tomato Diseases. Boca Raton: Academic Press.
Bruinsma, M, Posthumus M A., Mumm R, Mueller M J, van Loon J J A, & Dicke M, 2009. Jasmonic acid-induced volatiles of Brassica oleracea attract parasitoids: effects of time and dose, and comparison with induction by herbivores. Journal of Experimental Botany 60: 2575–2589.
Campos O R, Crocomo W B, & Labinas A M, 2003. Comparative biology of the whitefly Trialeurodes vaporariorum (West.) (Hemiptera - Homoptera: Aleyrodidae) on soybean and bean cultivars. Neotropical Entomology 32(1): 133–138.
Chiozza m V, O'Neal M E, & Macintosh G C, 2010. Constitutive and induced differential accumulation of amino acid in leaves of susceptible and resistant soybean plants in response to the soybean aphid (Hemiptera: Aphididae). Environmental Entomology 39(3): 856–864.
Cui H, Guo L, Wang S, Xie W, Jiao X, Wu Q, & Zhang Q, 2017. The ability to manipulate plant glucosinolates and nutrients explains the better performance of Bemisia tabaci Middle East-Asia Minor 1 than Mediterranean on cabbage plants. Ecology & Evolution, 7(16): 6141–6150.
Cui H, Sun Y, Su J, Li C, & Ge F, 2012. Reduction in the fitness of Bemisia tabaci fed on three previously infested tomato genotypes differing in the jasmonic acid pathway. Environmental Entomology, 41(6): 1443–1453.
Delphia C M, Mescher M C, & De Moraes C M, 2007. Induction of plant volatiles by herbivores with different feeding habits and the effects of induced defenses on host-plant selection by thrips. Journal of Chemical Ecology 33: 997–1012.
Deneve T, 2015. Neveneffecten van entomopathogene nematoden op de roofwants Macrolophus pygmaeus. PhD Thesis, Plant Pathology, Gent University.
Dicke M, van Loon J J A, & Solar R, 2009. Chemical complexity of volatiles from plants induced by multiple attack. Nature Chemical Biology 5: 317–324.
Drobnjakovic T, Marčić D, Prijović M, Perić P, Milenković S, & Bošković J, 2016. Life history traits and population growth of Encarsia formosa Gahan (Hymenoptera: Aphelinidae) local population from Serbia. Entomologia Generalis 35(4): 281–295.
Erb M, Meldau S, & Howe G A, 2012. Role of phytohormones in insectspecifc plant reactions. Trends in Plant Science 17: 250–259.
Escobar-Bravo R, Alba J M, Pons C, Granell A, Kant M , Moriones E, &
Fernández-Muñoz R. 2016. A jasmonate-inducible defense trait transferred from wild into cultivated tomato establishes increased whitefly resistance and reduced viral disease incidence.
Frontiers in Plant Science 7:1–16.
Foruzan M, Nouri H. 2023. Lethal effects of azadirachtin, spiromesifen and thiamethoxam insecticides on the greenhouse whitefly, Trialeurodes vaporariorum and it’s parasitoid Encarsia formosa. Journal of Applied Research in Plant Protection 12(1):97-109.
Ghahhari H & Hatami B, 2001. Taxonomic studies of white flies (Homoptera: Aleyrodidae) in Esfahan Province. Journal of pests & plant diseases 96(1): 141–170.
Ghasemzadeh M & Gharekhani G H, 2018. Feasibilty of rearing of predatory bug Macrolophus pygmaeus Rambur (Hemiptera: Miridae) using Urmia Lake artemia (Artemia urmiana Gunther). Journal of Applied Research in Plant Protection7(4):1–17.
Girousse C, Moulia B, Silk W & Bonnemain J L, 2005. Aphid infestation causes different changes in carbon and nitrogen allocation in alfalfa stems as well as different inhibitions of longitudinal and radial expansion. Plant Physiology 137: 1474–1484.
Glas J J, Alba J M, Simoni S, Villarroel C A, Stoops M, Schimmel B C, Schuurink R C, Sabelis M W & Kant M R. 2014. Defense suppression benefits herbivores that have a monopoly on their feeding site but can backfire within natural communities. BMC biology 12(1): 1–14.
Grille G, Lorenzo M E, Burla J P, Franco J, & Basso C, 2012. Parasitoid niches of Encarsia formosa and Encarsia lycopersici (Hymenoptera: Aphelinidae) exploiting Trialeurodes vaporariorum (Hemiptera: Aleyrodidae). Florida Entomologist 95: 1024–1030.
Gruszecki R, & Stawiarz A, 2021. Biostimulants containing amino acids in vegetable crop production. Acta Scientiarum Polonorum Hortorum Cultus 20(6):45–57.
Heil M, 2008. Indirect defence via tritrophic interactions. New Phytologist 178: 41–61.
Hu J S, Gelman D B, & Blackburn M B, 2002. Growth and development of Encarsia formosa (Hymenoptera: Aphelinidae) in the greenhouse whitefly, Trialeurodes vaporariorum (Homoptera: Aleyrodidae): Effect of host age. Archives of Insect Biochemistry & Physiology 49(3): 125–136.
Kant M R, Jonckheere, W Knegt B, Lemos F, Liu J, et al., 2015. Mechanisms and ecological consequences of plant defence induction and suppression in herbivore communities. Annals of Botany 115: 1015–1051.
Karley A J, Douglas A E, & Parker W E, 2002. Amino acid composition and nutritional quality of potato leaf phloem sap for aphids. The Journal of Experimental Biology 205: 3009–3018.
Karban R, & I T Baldwin, 1997. Induced responses to herbivory. University of Chicago Press, Chicago.
Kessler A, & Baldwin I T, 2001. Defensive function of herbivore-induced plant volatile emissions in nature. Science 291: 2141–2144.
Lin D, Xu Y, Liu X, Zhang L, Wang J, Wu H & Rao Q, 2019. Plants defence responses induced by two herbivores and consequences for whitefly Bemisia tabaci. Frontiers in Physiology 10(346): 1–24.
Luan J B, Yao D M, Zhang, T, Walling L L, Yang M, Wang Y J, et al, 2013. Suppression of terpenoid synthesis in plants by a virus promotes it mutualism with vectors. Ecology Letters 16: 390–398.
Lykouressis D, & Perdikis D, 2014. Plant food effects on prey consumption by the omnivorous predator Macrolophus pygmaeus. Phytoparasitica 42: 303–309.
Mirzamohammadzadeh S, Iranipour Sh, Lotfalizadeh H & Jafarlou M, 2014. Biological parameters of Trialeurodes vaporariorum (Hem.: Aleyrodidae) in four greenhouse cucumber cultivars. Journal of Entomological Society of Iran 34(4):53–67.
Naselli M, Urbaneja A, Siscaro G, Jaques J A, Zappalà L, Flors V, & Pérez-Hedo M, 2017. Stage-Related Defense Response Induction in Tomato Plants by Nesidiocoris tenuis. International Journal of Molecular Science 17(8):1210.
Omer A D, Granett J, Karban R & Villa E M, 2001. Chemically-induced resistance against multiple pests in cotton. International Journal of Pest Management 47: 49–54.
Ortega-Arenas L D, Miranda-Aragón D A & Sandoval-Villa Y M, 2006. Whitefly Trialeurodes vaporariorum (West.) eggs and nymphs density on Gerbera jamesonii H. Bolus under different nitrogenous fertilizer regimes. Publicado como ARTÍCULO en Agrociencia 40: 363–371.
Pappas M L, Steppuhn A, Geuss D, Topalidou N, Zografou A, Sabelis M W, & Broufas G D, 2015. Beyond predation: the zoophytophagous predator Macrolophus pygmaeus induces tomato resistance against spider mites. PLoS One 10(5): 1–18.
Pérez-Hedo M, Arias-Sanguino ÁM, & Urbaneja A, 2018. Induced Tomato Plant Resistance Against Tetranychus urticae Triggered by the Phytophagy of Nesidiocoris tenuis. Frontiers in Plant Science 9(1419): 1–8.
Perez-Hedo M, Bouagga S, Jaques J A, Flors V, & Urbaneja A, 2015. Tomato plant responses to feeding behavior of three zoophytophagous predators (Hemiptera: Miridae). Biological Control 86: 46–51.
Perez-Hedo M, & Urbaneja A, 2015. Prospects for predatory mirid bugs as biocontrol agents of aphids in sweet peppers. Journal of Pest Science 88: 65–73.
Pieterse C M, Van der Does D, Zamioudis C, Leon-Reyes A, & Van Wees S C, 2012. Hormonal modulation of plant immunity. Annual Review of Cell & Developmental Biology 28: 489–521.
Portillo N, Alomar O, & Wäckers F, 2012. Nectarivory by the plant-tissue feeding predator Macrolophus pygmaeus Rambur (Heteroptera: Miridae): Nutritional redundancy or nutritional benefit? Journal of Insect Physiology 58: 397–401.
Perdikis D, & Lykouressis D, 2000. Effects of various items, host plants, and temperatures on the development and survival of Macrolophus pygmaeus Rambur (Hemiptera: Miridae). Biological Control 17(1): 55–60.
Puthoff D P, Holzer F M, Perring T M & Walling L L, 2010. Tomato pathogenesis-related protein genes are expressed in response to Trialeurodes vaporariorum and Bemisia tabaci biotype B feeding. Journal of Chemical Ecology 36: 1271– 1285.
Risal J, Meyhoefer R, Wydra K, & Poehling H M, 2008. Induction of resistance to the whitefly Trialeurodes vaporariorum in tomato by external application of Jasmonic Acid (JA) and Benzothiadiazole (BTH). Conference on international research on food security, natural resource management and rural development, University of Hohenheim.
Gao R-R, Zhang W P, Wu H T, Zhang R-M, Zhou H-X, Pan H-P, Zhang Y J, Brown J K, & Chu D, 2014. Population structure of the greenhouse whitefly, Trialeurodes vaporariorum (Westwood), an invasive species from the Americas, 60 years after invading China. International Journal of Molecular Sciences 15(8): 13514–13528.
Samadipour M, Farazmand H, Nazari A, Baniameri V 2023. Evaluation of colored sticky traps to attract greenhouse whitefly, Trialeurodes vaporariorum. Journal of Applied Research in Plant Protection 12(1): 77–85.
Sarmento R A, Lemos F, Bleeker P M, Schuurink R C, Pallini A, Oliveira A M G, & Janssen A, 2011. An herbivore that manipulates plant defence. Ecology Letters 14: 229–236.
Sarraf Moaiery H R, Ashoori A, Kharrazi Pakdel A, & Farrokhi Sh, 2004. Effects of four different host plants on Encarsia formosa Gahan, the important agent in biological contorol of greenhouse whitefly. Iranian Journal of Agriculture Science 35(2): 437–443.
Schoonhoven L M, Van Loon J J A & Dicke M, 2006. Insect-Plant Biology. New York: Oxford University Press.
Shishehbor P, 2002. Whiteflies - Bioecology, pest status and their management, University of Shahid Chamran. 644.
Thaler J S, Humphrey P T, & Whiteman N K, 2012. Evolution of jasmonate and salicylate signal crosstalk. Trends in Plant Science 17(5): 260–270.
Stam J M, Kroes A, Li Y, Gols R, van Loon J J, Poelman E H, & Dicke M, 2014. Plant interactions with multiple insect herbivores: from community to genes. Annual Review of Plant Biology 65: 689–713.
Walling L L, 2008. Avoiding effective defenses: strategies employed by phloem-feeding insects. Plant Physiol 146: 859–866.
Walling L L, 2000. The myriad plant responses to herbivores. Journal of Plant Growth Regulation 19(2): 195–216.
Wang X S, Chen Q Z, Zhang S Z, & Liu T X, 2015. Parasitism, host feeding and immature development of Encarsia formosa reared from Trialeurodes vaporariorum and Bemisia tabaci on Trialeurodes ricini. Journal of Applied Entomology 39: 647–726.
Wei J N, Yan L, Ren Q, Li C Y, Ge F, & Kang L 2013. Antagonism between herbivore-induced plant volatiles and trichomes affects tritrophic interactions. Plant, Cell & Environment 36: 315–327.
Wei J N, Wang L Z, Zhao J H, Li C Y, Ge F, & Kang L, 2011. Ecological trade-offs between jasmonic acid-dependent direct and indirect plant defenses in tritrophic interactions. New Phytologist 189: 557–567.
Zarate S I, Kempema L A, & Walling L L, 2007. Silverleaf whitefly induces salicylic acid defenses and suppresses effectual jasmonic acid defenses. Plant Physiology 143: 866–875
Zhang N X, Messelink G J, Alba J M, Schuurink R C, Kant M R, & Janssen A, 2017. Phytophagy of omnivorous predator Macrolophus pygmaeus afects performance of herbivores through induced plant defences. Oecologia 186(1):101–113.
Zhang P J, He Y Ch, Zhao Ch, Ye Z H, & Yu X P, 2018. Jasmonic Acid-Dependent defenses play a key role indefending tomato against Bemisia tabaci nymphs, but not adults. Frontiers in Plant Science 9: 1–10.
Zhang P J, Xu C X, Zhang J M, Lu Y B, Wei J N, Liu Y Q, David A, Boland W, & Turlings T C J, 2013. Phloem-feeding whiteflies can fool their host plants, but not their parasitoids. Functional Ecology 27: 1304–1312.