Biochemical Analyses of Action of Chlorfluazuron as Reproductive Inhibitor in Spodoptera litura

Perveen, Farzana

doi:10.5772/33908

Cited by 10 publications

(12 citation statements)

References 59 publications

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“…Also, larval duration was generally prolonged and the developmental rate of these larvae was regressed, in almost dose-dependent manner. This inhibited growth of P. unionalis by methoxyfenozide was in accordance with those reported results of inhibited growth of some insects by various IGRs, such as S. littoralis by flufenoxuron (Bakr et al, 2010), lufenuron (Adel, 2012), and novaluron (Ghoneim et al, 2015); P. demoleus by Diofenolan (Singh and Kumar, 2011), S. litura by chlorfluazuron (Perveen, 2012), Aedes aegypti (Farnesi et al, 2012), Culex pipiens by novaluron (Djeghader et al, 2014) and kinoprene (Hamaidia and Soltani, 2014). Likewise, some IGRs failed to affect the growth of different insects, such as M. domestica (Ghoneim et al, 1991), Periplaneta americana and Oncopeltus fasciatus (Darvas et al, 1992), Spodoptera exempta, Spodoptera exigua, and Leptinotarsa decemlineata (Smagghe and Degheele, 1994).…”

Section: Inhibited Growth and Retarded Development Of P Unionalis Bysupporting

confidence: 90%

“…2). (Bakr et al, 2013), buprofezin (Nasr et al, 2010), methoxyfenozide (Pineda et al, 2004) and cyromazine (Tanani et al, 2015) against Spodoptera littoralis; pyriproxyfen against Eurygaster integriceps (Mojaver and Bandani, 2010); diofenolan against Papilio demoleus (Singh and Kumar, 2011); diflubenzuron against Halyomorpha halys (Kamminga et al, 2012); chlorfluazuron against Spodoptera litura (Perveen, 2012); flufenoxuron and pyriproxyfen against Locusta migratoria (Hu et al, 2012); kinoprene against Culex pipiens (Hamaidia and Soltani, 2014); flufenoxuron and methoprene against Agrotis ipsilon (Khatter, 2014) and lufenuron against Tribolium castaneum (Gado et al, 2015). Recently, IGRs exhibited various toxicities against some insects, such as pyriproxyfen against Spodoptera mauritia (Resmitha and Meethal, 2016); lufenuron and methoxyfenozide against T. castaneum (Ali et al, 2016); methoxyfenozide against C. pipiens (Hamaidia and Soltani, 2016); tebufenozide against Ephestia kuehniella (Tazir et al, 2016); lufenuron against Glyphodes pyloalis (Aliabadi et al, 2016) and Helicoverpa armigera (Vivan et al, 2016); fenoxycarb against Corcyra cephalonica (Begum and Qamar, 2016); methoprene and pyriproxyfen against Culex quinquefasciatus and Aedes albopictus (Khan et al, 2016); cyromazine against Musca domestica, Stomoxys calcitrans and Fannia canicularis (Donahue et al, 2017); novaluron against Pectinophora gossypiella (Ghoneim et al, 2017a) and P. unionalis (Ghoneim et al, 2017b).…”

Section: Effects Of Methoxyfenozide On Growth Development and Metamomentioning

confidence: 99%

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Deteriorating Effects of Methoxyfenozide on Survival, Development and Metamorphosis of the Olive Leaf Moth, Palpita unionalis (Hübner) (Lepidoptera: Pyralidae).

Hamadah

2018

Egyptian Academic Journal of Biological Sciences. A, Entomology

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The olive leaf moth Palpita unionalis is one of the serious olive pests in Egypt and several countries. The objective of the current study was to evaluate the effects of methoxyfenozide, an ecdysteroid agonist, on survival, growth, development and metamorphosis of this pest. The newly moulted last instar (6 th) larvae were treated with six concentrations (100, 10.0, 1.00, 0.10, 0.01 and 0.001 ppm) via the fresh olive leaves, as food. The strongest acute toxicity (100% mortality) was exhibited against larvae at the highest concentration, but no mortality was observed at the lowest one. The developed pupae had been subjected to the toxic effect only at the higher three concentrations. Increasing adult mortality% was recorded at concentrations other than the highest or lowest one. LC 50 was calculated in 0.176 ppm. The somatic weight gain of larvae, growth rate, larval duration and developmental rate of larvae had been pronouncedly reduced. The pupal duration was non-significantly prolonged and the pupal developmental rate was slightly regressed. The successfully developed pupae suffered a desiccation action of methoxyfenozide. The metamorphosis program was impaired, since some larval-pupal intermediates had been produced. In addition, the pupal morphogenesis was deteriorated, since some pupal deformations had been produced after larval treatment only with 0.10 ppm.

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Section: Inhibited Growth and Retarded Development Of P Unionalis Bysupporting

confidence: 90%

Section: Effects Of Methoxyfenozide On Growth Development and Metamomentioning

confidence: 99%

Deteriorating Effects of Methoxyfenozide on Survival, Development and Metamorphosis of the Olive Leaf Moth, Palpita unionalis (Hübner) (Lepidoptera: Pyralidae).

Hamadah

2018

Egyptian Academic Journal of Biological Sciences. A, Entomology

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“…Some malformed pupae had been observed in non-tanned segmented body or segmented body with tanned part and incompletely tanned part, depending on the concentration level of Novaluron (see Plate 3). The currently available literature contains many reported results of toxic effects of several insect growth regulators (IGRs)(Juvenoids, ecdysteroids and chitin synthesis inhibitors, CSIs) on various insect species, such as Spodoptera littoralis by Diflubenzuron [70], Triflumuron [71], Flufenoxuron [72], Lufenuron [73,74], Buprofezin [75,76], Tebufenozide and Methoxyfenozide [77], Cyromazine [78]; Papilio demoleus by Diofenolan [79]; Eurygaster integriceps by Pyriproxyfen [80]; Dysdercus koenigii by Flufenoxuron [81]; Halyomorpha halys by Diflubenzuron [46]; Spodoptera litura by Chlorfluazuron [82]; Locusta migratoria var. manilensis by Flufenoxuron, RH-5849 and Pyriproxyfen [83]; Culex pipiens by Kinoprene [84]; Agrotis ipsilon by Flufenoxuron and Methoprene [85] or Pyriproxyfen [86] and Tribolium castaneum by Lufenuron [87].…”

Section: Toxicity and Lethal Effectsmentioning

confidence: 99%

Toxicity and Disruptive Impacts of Novaluron, A Chitin Synthesis Inhibitor, on Development and Metamorphosis of The Olive Leaf Moth Palpita unionalis

Ghoneim¹,

Hamadah²,

Elsoud³

2017

IJTSRD

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The olive leaf moth Palpita unionalis (Lepidoptera: Pyralidae) is an economic pest of the commercial olive groves in Egypt and different Mediterranean countries. The present study was conducted aiming to assess the effects of Novaluron, a chitin synthesis inhibitor, on survival, growth, development and metamorphosis of this pest. The newly moulted last instar (6th) larvae had been treated with six concentrations (100.0, 10.0, 1.00, 0.10, 0.01 and 0.001 ppm), via the fresh olive leaves, as food. Different degrees of toxicity were recorded on all developmental stages. LC 50 was calculated in 0.97 ppm. The somatic weight gain of larvae was drastically reduced and the larval growth rate was severely regressed, regardless the concentration. The larval duration was generally shortened but the pupal duration was remarkably prolonged, in a dosedependent manner. The pupation rate was regressed, especially at the higher four concentrations. The metamorphosis program was impaired, since larvalpupal intermediates had been produced at some concentrations. In addition, the pupal morphogenesis was disrupted, since some pupal deformities had been observed at some concentrations.

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“…Also, cycloheximide remarkably enhanced the treated larvae to grow higher rate than control larvae. These results were found contradictory to many reported results of the inhibited larval growth in different insect species by various IGRs, such as S. littoralis by flufenoxuron (Bakr et al, 2010), lufenuron (Adel, 2012) and novaluron (Ghoneim et al, 2015); the common lime butterfly Papilio demoleus by diofenolan (Singh and Kumar, 2011), S. litura by chlorfluazuron (Perveen, 2012), the yellow fever mosquito Aedes aegypti (Farnesi et al, 2012), C. pipiens by novaluron (Djeghader et al, 2014) and kinoprene (Hamaidia and Soltani, 2014). Also, our results of increasing body weights and enhanced growth of S. littoralis larvae disagreed with those reported results of growth inhibition in some insects by some anti-JH compounds, such as the mealworm beetle Tenebrio molitor by several chromene derivatives (Roberto et al, 1998); A. aegypti, Anopheles sacharovi and An.…”

Section: Influenced Growth and Development Of S Littoralis By Cyclohmentioning

confidence: 64%

Impairment of Development and Reproductivity of the Egyptian cotton leafworm Spodoptera littoralis Boisduval (Noctuidae: Lepidoptera) by Cycloheximide.

Basiouny

Ghoneim

2018

Egyptian Academic Journal of Biological Sciences. A, Entomology

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The Egyptian cotton leafworm, Spodoptera littoralis, is destructive pest of cotton and various crops in Egypt and some parts of the world. The present study was carried out aiming to assess the disruptive effects of cycloheximide on survival, growth, development, metamorphosis and reproductive potential of this pest. Four doses: 180, 120, 60 and 30 µg/larva had been topically applied (once) onto the newly moulted last instar larvae. cycloheximide exhibited toxic effect on larvae, pupae and adults. Unexpectedly, no mortality was observed at the highest dose. LD 50 was estimated at 0.013 µg/larva. The maximal weights of the treated larvae increased and the larval growth was remarkably enhanced. The larval and pupal durations were shortened. Some larvae appeared as 'giant larvae', only at the lower two doses. They enlarged in size and appeared heavier than other treated and control larvae. They survived 2-times longer period than of the control larvae and perished without pupation. Topical treatment of larvae only with the lower two doses induced a state of suspended development, 'permanent prepupae' which failed to pupate. Cycloheximide exerted an inhibitory action on the pupation rate after treatment only with the lower three doses. Some deformed pupae were produced. The adult emergence was considerably blocked at lower three doses. The oviposition was completely prevented, at the higher two doses, but partially inhibited at the lower two doses. No fecundity could be determined at the higher two doses because no oviposition was carried out. At the lower two doses, fecundity was dramatically reduced. All eggs failed to hatch indicating complete sterility of S. littoralis.

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Biochemical Analyses of Action of Chlorfluazuron as Reproductive Inhibitor in Spodoptera litura

Cited by 10 publications

References 59 publications

Deteriorating Effects of Methoxyfenozide on Survival, Development and Metamorphosis of the Olive Leaf Moth, Palpita unionalis (Hübner) (Lepidoptera: Pyralidae).

Deteriorating Effects of Methoxyfenozide on Survival, Development and Metamorphosis of the Olive Leaf Moth, Palpita unionalis (Hübner) (Lepidoptera: Pyralidae).

Toxicity and Disruptive Impacts of Novaluron, A Chitin Synthesis Inhibitor, on Development and Metamorphosis of The Olive Leaf Moth Palpita unionalis

Impairment of Development and Reproductivity of the Egyptian cotton leafworm Spodoptera littoralis Boisduval (Noctuidae: Lepidoptera) by Cycloheximide.

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