Evaluation of fractions and 5,7-dihydroxy-4',6-dimethoxy-flavone from<i>Clerodendrum phlomidis</i> Linn. F. against <i>Helicoverpa armigera</i> Hub.

Duraipandiyan, Veeramuthu; Muthu, Chelliah; Baskar, Kathirvelu; Al-Dhabi, Naif Abdullah; Ignacimuthu, Savarimuthu

doi:10.1590/S1516-8913201400128

Abstract

Twelve fractions from chloroform extract of Clerodendrum phlomidis and 5,7-dihydroxy- 4',6-dimethoxy-flavone (pectolinaringenin) were evaluated against Helicoverpa armigera. Maximum antifeedant (89.41%), larvicidal (83.77%) and ovicidal (69.25%) activities were observed in fraction 5. The least LC₅₀ value for antifeedant (178.09 ppm) and larvicidal (198.23 ppm) were observed in fraction 5. No adult emergence was recorded in fractions 4-6 at 1000 ppm. The oviposition deterrent activity was 100% in fraction 5 at all the concentrations. Pectolinaringenin recorded maximum antifeedant (74.68%) and larvicidal (81.11%) activities at 100 ppm; it completely prevented the adult emergence of H. armigera at 100 ppm. Maximum ovicidal activity at 100 ppm concentration was 67.95%. The oviposition deterrent activity was 100% in 100 and 50 ppm concentrations. C. phlomidis could be effectively used to develop a new formulation to control the economically important pests.

Adult emergence; antifeedant; larvicidal; ovicidal; oviposition deterrent; pectolinaringenin

INTRODUCTION

Continuous use of chemical insecticides cause negative impact on the environment, health and development of resistance by the insects and affect the natural enemies. The negative impact of toxic chemical insecticides leads to increase the strict measures on environmental regulation of insecticides resulted in searching an alternative strategy to develop and use the plant-based pesticides for the management of pests by agrochemical companies (Isman 2000Isman MB. Plant essential oils for pest and disease management. Crop Protect. 2000; 19: 603-608.). Plant-based pesticides are not accumulated in the food chain as by the synthetic chemicals which are the major concern for the environmental pollution (Malau and James 2008Malau MB, James DB. Evaluation of larvicidal properties of some plant extracts on Simulium damnosum complex. The Internet J Toxicol 2008; 4(2): 1-61.). Further, plant based secondary chemicals are non-toxic, targeted for a wide range of pests and could be potent alternatives to synthetic pesticides (Leatemia and Isman 2004Leatemia JA, Isman MB. Insecticidal activity of crude seed extracts of Annona spp. Lanium domesticum and Sandoricum koetjape against lepidopteran larvae. Phytoparasitica. 2004; 32: 30-37.). Azima tetracanthaLam. (syn. Monetia barlerioides L'Her.) derived friedelin did not shows any toxicity against Cyprinus carpio (Baskar et al. 2014Baskar K, Duraipandiyan V and Ignacimuthu S, Bioefficacy of the triterpenoid friedelin against Helicoverpa armigera (Hub.) and Spodoptera litura (Fab.) (Lepidoptera: Noctuidae) . Pest Manage Sci. 2014; DOI: 10.1002/ps.3742.
https://doi.org/10.1002/ps.3742... ). There are different kinds of insect pests which are causing extensive damage to crops and thereby reducing the productivity. David (2008)David BV. Biotechnological approaches in IPM and their impact on environment. J Biopest. 2008; 1: 1-5. reported that some plants in nature possess secondary metabolites which act as antifeedants, oviposition deterrents, larvicides and insect growth regulators.

Many plants extracts, their fractions and isolated compounds present in them possess various pest control properties against many pests such as antifeedants (Raja et al. 2005Raja N, Jeyasankar A, Jeyakumar SV, Ignacimuthu S. Efficacy of Hyptis suaveolens against Lepidopteran pest. Curr Sci. 2005; 88: 220-222.), larvicides (Muthu et al. 2012a,bMuthu C, Reegan AD, Kingsley S, Ignacimuthu S. Larvicidal activity of pectolinaringenin from Clerodendrum phlomidis L. against Culex quinquefasciatus Say. and Aedes aegypti L. (Diptera : Culicidae). Parasitol Res. 2012a; 111: 1059-1065.), ovicidal and oviposition deterrent activities (Muthu et al. 2013Muthu C, Baskar K, Ignacimuthu S, Al-Khaliel AS. Ovicidal and oviposition deterrent activities of the flavonoid pectolinaringenin from Clerodendrum phlomidis against Earias vittella. Phytoparasitica. 2013; 41: 365-372.) and insect growth regulators (Baskar and Ignacimuthu 2012aBaskar K, Ignacimuthu S. Antifeedant, larvicidal and growth inhibitory effect of ononitol monohydrate isolated from Cassia tora L. against Helicoverpa armigera (Hbn.) and Spodoptera litura (Fab.) (Lepidoptera: Noctuidae) . Chemosphere. 2012a; 88: 384-388.; Munoz et al. 2013Munoz E, Escalona D, Salazar JR, Alarcon J, Cespedes CL. Insect growth regulatory effects by diterpenes from Calceolaria talcana Grau & Ehrhart (Calceolariaceae: Scrophulariaceae) against Spodoptera frugiperda and Drosophila melanogaster. Ind Crops Prod. 2013; 45: 283-292.). The different flavonoids in the plants have diverse functions that include providing much of the colour to flowers and fruits, pollinator attraction mechanism, symbiotic relationship with N₂-fixing rhizobia, protection from UV, pathogens and insects, allelopathy and inhibition of auxin transport (Morimoto and Komai 2000Morimoto M, Komai K. Plant secondary metabolites as plant defence systems. Phytochem. 2000; 4: 99-114.; Buer et al. 2010Buer CS, Imin N, Djordjevic MA. Flavonoids: New roles for old molecules. J Integr Plant Biol. 2010; 52: 98-111.). The presence of various groups of flavonoids such as flavones, flavonols, flavanones, anthocyanins and chalcones in the plants play a significant role in insect-plant interactions (Harborne and Grayer 1994Harborne JB, Grayer RJ. Flavonoids and insects. In: Harborne JB, Editor. The flavonoids, advances in research since 1986. Chapman and Hall, London, 1994. pp 589-618.; Simmonds 2003Simmonds MSJ. Flavonoid-insect interactions: recent advances in our knowledge. Phytochem. 2003; 64: 21-30.; Green et al. 2003Green PWC, Stevenson PC, Simmonds MSJ, Sharma HC. Phenolic compounds on the pod-surface of pigeonpea, Cajanus cajan, mediate feeding behaviour of Helicoverpa armigera larvae. J Chem Ecol. 2003; 29: 811-821.). Gahukar (2010)Gahukar RT. Bioefficacy of indigenous plant products against pests and diseases of Indian forest trees. J Forestry Res. 2010; 21: 231-238. reviewed the allelochemicals from some plants for their pesticide activities. Flavonoids from Vitex negundo (Lamiaceae), Melia azedarach (Meliaceae) and Anacardium occidentale had antifeedant, oviposition deterrent and pesticidal properties. 5,7-dihydroxyflavanone (pinocembrine) fromTeloxys graveolens (Amaranthaceae) exhibited fasciolicide, ovicide and larvicidal activities against Ascaridi galli andStomoxys calcitrans (Camacho et al. 1991Camacho MDR, Sanchez B, Quiroz H, Contreras JL, Mata R. Pinocembrine: a bioactive flavanone from Teloxys graveolens. J Ethnopharmacol. 1991; 31: 383-389.).

Helicoverpa armigera Hub. is a polyphagous pest causing extensive damage to numerous crops worldwide. It has the potential to migrate long distance, facultative diapause, and high egg laying capacity, developing resistance to many conventional pesticides (Kranthi et al. 2002Kranthi KR, Jadhav DR, Kranthi S, Wanjari RR, Ali SS, Russel DA. Insecticide resistance in five major insect pests of cotton in India. Crop Protect. 2002; 21: 449-460.; Nimbalkar et al. 2009Nimbalkar RK, Shinde SS, Tawar DS, Muley SP. Response of cotton bollworm Helicoverpa armigera (Hübner) (Lepidoptera: Noctuidae) to different insecticides in Maharashtra. India. World J Agric Sci. 2009; 5: 250-255.). It is a cosmopolitan and agronomically important pest affecting more than 300 plants worldwide (Pawar et al. 1986Pawar CS, Bhatnagar VS, Jadhav DR. Heliothis species and their natural enemies with their potential for biological control. Pro National Acad Sci (Animal Sci). 1986; a:697-703.; Rajapakse and Walter 2007Rajapakse CNK, Walter GH. Polyphagy and primary host plants: oviposition preference versus larval performance in the lepidopteran pest Helicoverpa armigera. Arthropod-Plant Interaction. 2007; 1: 17-26.). The damage caused by H. armigera on cotton and pulses alone is estimated to US$ 300-500 million in India (King 1994King ABS. Heliothis/Helicoverpa (Lepidoptera: Noctuidae). In: Matthews GA, Tunstall JP, editors. Insect Pests of Cotton CAB International, UK, 1994. p. 39-106.). Estimation have revealed that annual loss caused by H. armigera alone was estimated at approximately US$ 5 billion on different crops worldwide and India and China spent nearly 50% of the total agricultural pesticides to control H. armigera (Lammers and MacLeod 2007Lammers JW, Macleod A. Report of a pest risk analysis: Helicoverpa armigera (Hübner, 1808). 2007. Available from: http://www.fera.defra.gov.uk/plants/plantHealth/pestsDiseases/documents/helicoverpa.pdf (2007).
http://www.fera.defra.gov.uk/plants/plan... ).

Clerodendrum phlomidis (Lamiaceae) is a medicinal plant used traditionally for various ailments around the world. Juice of leaves is alterative and given in neglected syphilitic complaints (Shafi et al. 2001Shafi MS, Ashraf MY, Sarwar G. Wild medicinal plants of Cholistan area of Pakistan. Pak J Biol Sci. 2001; 4: 112-116.). Bitter tonic from the root is used as antidote, analgesic, anti-asthmatic and to treat inflammatory and rheumatic diseases (Katewa et al. 2004Katewa SS, Chaudhary BL, Jain A. Folk herbal medicines from tribal area of Rajasthan, India. J Ethnopharmacol. 2004; 92: 41-46.). The aim of this work was to evaluate the chloroform extract derived fractions from the leaves of C. phlomidis and a compound isolated from it against H. armigera for their antifeedant, larvicidal, adult emergence, ovicidal and oviposition deterrent activities since the chloroform crude extract had shown maximum antifeedant and larvicidal activities against H. armigera(Vendan et al. 2008Vendan SE, Baskar K, Ramar M, Lingathurai S, Paulraj MG, Ignacimuthu S. Effect of plant extracts on larval development of Helicoverpa armigera. In: Ignacimuthu S, Jayaraj S, editor. Recent trends in Insect Pest Management. Elite Publication, New Delhi, India. 2008. p. 215-219.) andEarias vittella (Muthu et al. 2012bMuthu C, Baskar K, Kingsley S, Ignacimuthu S. Bioefficacy of Clerodendrrum phlomidis Lin. F. and Fleuggea leucoyrus (Koern.) Wild against Earias vittella Fab. J Entomol. 2012b; 9: 332-342. ). To the best of our knowledge, this is the first report on the effect of fractions and an isolated compound, pectolinaringenin isolated from C. phlomidis were studied againstH. armigera for various biological activities.

MATERIAL AND METHODS

Extraction, fractionation and isolation of pectolinaringenin

Extraction, fractionation and isolation of pectolinaringenin from C. phlomidis were similar as reported by Muthu et al. (2012a)Muthu C, Reegan AD, Kingsley S, Ignacimuthu S. Larvicidal activity of pectolinaringenin from Clerodendrum phlomidis L. against Culex quinquefasciatus Say. and Aedes aegypti L. (Diptera : Culicidae). Parasitol Res. 2012a; 111: 1059-1065..

Identification of Compound

Melting points of the compound were determined by an open capillary method on a heating block apparatus. The compound was subjected to UV-Visible Spectrophotometer (Model - Hitachi 2010), IR spectrum (Perkin-Elmer FT- IR instrument on KBr disc), ¹HNMR spectrum (500MHz) and ¹³C NMR (75MHz) spectrum on a JEOL AL-300 instrument in CDCl₃. EI-MS was taken on SHIMADZU instrument at 70ev by the direct inlet method. All the chemicals and solvents used were of analytical grade (Muthu et al. 2012aMuthu C, Baskar K, Ignacimuthu S, Al-Khaliel AS. Ovicidal and oviposition deterrent activities of the flavonoid pectolinaringenin from Clerodendrum phlomidis against Earias vittella. Phytoparasitica. 2013; 41: 365-372.).

Collection and rearing of H. armigera

Larvae of H. armigera Hub. were collected from the field in Melakondayar village in Tiruvallur district of Tamil Nadu and the collected larvae were reared individually in a plastic container (vials) and fed regularly with Abelmoschus esculentus L. (Malvaceae) till the larvae became pupae under the laboratory conditions (27±2ºC and 75±5% relative humidity). Sterilized soil was used for pupation. After pupation, the pupae were collected from the soil and placed inside the cage for the emergence of adults. Cotton soaked with 10% honey solution mixed with a few drops of multivitamins was provided for adult feeding to increase the fecundity. Potted cotton plant was kept inside the adult emergence cage for egg laying. After hatching, the larvae were collected from the cage and fed with standard artificial diet. Laboratory reared insect cultures was used for bioassay.

Antifeedant activity

Antifeedant activity of the chloroform extract fractions of theC. phlomidis and pectolinaringenin from fraction 5 was studied using leaf disc no choice method. Fresh cotton leaves were used. Leaf discs of 4.0 cm diameter were punched using cork borer and were dipped individually in 1000, 500, 250 and 125 ppm for fractions and 100, 50, 25, 12.5 ppm for pectolinaringenin. The leaf discs dipped in acetone + Tween 80 were used as negative control since they were used to dissolve the fractions and pectolinaringenin. In each plastic Petri dish (1.5cm x 9.0 cm) wet filter paper was placed to avoid early drying of the tested leaves. Single larva ofH. armigera was introduced in each treated and control Petri dish. The consumption of leaf disc in the treated and control byH. armigera larvae after 24 h of the experiment was measured using Leaf Area Meter (Delta-T Devices, Serial No. 15736 F 96, U.K). Leaf discs consumed by the larvae in the treatment were corrected from the negative control. Five replicates were maintained for each treatment with 10 larvae per replicate (total, n = 50). The experiment was conducted at laboratory condition (27±2ºC) with 14:10 h light and dark photoperiod and 75 ± 5% relative humidity (Baskar and Ignacimuthu 2012aBaskar K, Ignacimuthu S. Antifeedant, larvicidal and growth inhibitory effect of ononitol monohydrate isolated from Cassia tora L. against Helicoverpa armigera (Hbn.) and Spodoptera litura (Fab.) (Lepidoptera: Noctuidae) . Chemosphere. 2012a; 88: 384-388.). Antifeedant activity was calculated according to the formula of Bentley et al. (1984)Bentley MD, Leonard DE, Stoddard WF, Zalkow LH. Pyrrolizidine alkaloids as larval feeding deterrents for spruce budworm, Choristoneura fumiferana (Lepidoptera: Tortricidae). Ann Entomol Soc Am. 1984; 77: 393-397. .

Larvicidal bioassay

Larvicidal activity was studied using leaf disc no choice method.Cotton leaf discs (Gossypium sp.) were used; they were dipped in different concentrations of fractions and compound as used for the antifeedant bioassay. After 24 h treatment, the larvae were continuously maintained on untreated fresh cotton leaves. Diet was changed every 24 h. Larval mortality was recorded up to 96 h of treatment. The number of larvae, replicates used and laboratory conditions were same as antifeedant experiment. Per cent mortality was calculated using Abbott's formula.

Growth inhibitory activity

The treated larvae that attained pupae at different concentrations were kept in the adult emergence cage. Growth inhibitory activities like larval-pupal intermediates, malformation in adults and pupicidal were observed. The adults emerged with normal condition was recorded and was calculated using the following formula:

Adult emergence = No. of Emerged adults/Number of pupae X 100.

Oviposition deterrent activity

Oviposition deterrent activity was studied according to Raja et al. (2004)Raja N, Jayakumar M, Elumalai K, Jeyasankar A, Muthu C, Ignacimuthu S. Oviposition deterrent and ovicidal activity of solvent extracts of 50 plants against the Armyworm, Spodoptera litura Fab. (Lepidoptera:Noctuidae) . Malays Appl Biol. 2004; 33: 73-81. . The oviposition deterrent activity was studied at the concentrations of 1000, 500, 250, 125, 100, 50, 25 and 12.5 ppm for fractions and compound, respectively. The treated materials were sprayed on fresh cotton plants (cultured in the pots) along with selected controls and placed inside the cage (60 cm X45 cm X 45cm) and covered with mosquito net. Ten pairs of adult H. armigera moths were introduced into a cage and were fed with 10% (w/v) sucrose solution with multivitamin drops. After 48 h, the number of eggs laid on the treated and control leaves were recorded and the percentage of oviposition deterrent was calculated. Five replicates were maintained for all the experiments.

The oviposition deterrent activity was calculated using the formula of Williams et al. (1986)Williams AL, Mitchell ER, Heath RR, Barfield CS. Oviposition deterrents for fall armyworm (Lepidoptera: Noctuidae) from larval frass, corn leaves and artificial diet. Environ Entomol. 1986; 15: 327-330.:

Ovicidal activity

Twenty individual eggs of H. armigera were separated and dipped in 125, 250, 500 and 1000 ppm concentrations of fractions and 100, 50, 25 and 12.5 ppm of pectolinaringenin. Five replicates were maintained (n=100). Number of eggs hatched in the control and treatments were recorded. The laboratory conditions were the same as in the antifeedant experiment. Per cent ovicidal activity was calculated according to Abbott (1925)Abbott WS. A method of computing the effectiveness of an insecticide. J Econ Entomol. 1925; 18: 265-266..

Statistical Analysis

All the biological data were subjected to analysis of variance (ANOVA). Significant differences between treatments were determined by Tukey's multiple range tests (p ≤ 0.05). LC₅₀ value was calculated using Probit Analysis (Finney 1971Finney DJ. Probit Analysis, 3rd edition. Cambridge University Press, London, UK. 1971; pp. 383.). All the data were analysed using SPSS package version 11.5.

RESULTS

Fractions

Antifeedant activity

Antifeedant activity of 12 fractions isolated from the chloroform extract ofC. phlomidis against H. armigera is presented in Table 1. Fraction 5 recorded maximum antifeedant activity of 89.41% followed by fractions 6 and 4 which recorded 86.15 and 85.22%, respectively, at 1000 ppm concentration. Fractions 5, 6 and 4 exhibited statistically similar antifeedant activity in 500 and 1000 ppm concentrations. More than 60% antifeedant activity was observed in fractions 4, 5, 6 and 7 at 1000ppm concentration. Less than 20% antifeedant activity was observed in fraction 2 and 12 at 1000 ppm concentration. Fraction 5 showed the least LC₅₀ and LC₉₀values of 178.09 and 946.13 ppm followed by fractions 6 and 4 which showed LC₅₀ and LC₉₀ values of 236.39 and 273.48 ppm and 1049.46 and 1083.07 ppm, respectively. The highest LC₅₀ value was recorded in fraction 12. All the fractions recorded statistically significant Chi-square values except fractions 1, 11 and 12.

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Table 1
Antifeedant activity (%) with LC50 and LC90 of different fractions isolated from chloroform extract of Clerodendrum phlomidis against Helicoverpa armigera.

Larvicidal activity

Results of the larvicidal activity of different fractions against H. armigera and are presented in Table 2. Statistically significant larvicidal activity of 83.77% was recorded in fraction 5 followed by fractions 4 and 6 which recorded 75.55 and 73.55%, respectively at 1000 ppm concentration. Fraction 5 exhibited more than 55% larvicidal activity in all the concentrations except 125 ppm which recorded 38.66%. All the other fractions recorded less than 50% larvicidal activity. Fractions 1, 2, 9, 10 and 11 showed very low larvicidal activity.

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Table 2
Larvicidal activity (%) with LC50 and LC90 of different fractions isolated from chloroform extract of Clerodendrum phlomidis against Helicoverpa armigera.

Effective concentrations (LC₅₀ and LC₉₀) of fractions were evaluated against H. armigera showed that fraction 5 had least LC₅₀ and LC₉₀ values of 198.23 and 1094.23 ppm, respectively followed by fractions 6 and 4, which recorded the LC₅₀values of 417.83 and 480.49 ppm, respectively and the LC₉₀values of 1445 and 1343 ppm, respectively. Chi-square values were statistically significant for all the fractions except fraction 7.

Growth inhibitory activity

Fractions 4, 5 and 6 completely prevented the adult emergence of H. armigera at 1000 ppm concentration. Also 500 ppm concentration of fraction 5 showed no adult emergence. Fraction 6 at a concentration of 500 ppm recorded 26.66% adult emergence while concentrations 250 and 125 ppm of fraction 5 showed 31.0 and 36.66% adult emergence, respectively. Less than 50% adult emergence was observed in fractions 7, 8, 9 and 10 at 1000 ppm concentrations and fractions 7, 9 and 10 at 500 ppm concentrations. Irrespective of the concentrations tested, fractions 1, 2, 11 and 12 showed maximum adult emergence (Table 3).

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Table 3
Percentage of adult emergence of Helicoverpa armigera treated with different fractions isolated from chloroform extract of Clerodendrum phlomidis.

Ovicidal activity

Maximum ovicidal activity was noticed in fraction 5 at 1000 and 500 ppm concentrations which recorded 69.25 and 61.76%, respectively followed by fractions 4 and 6 against H. armigera. All the fractions had notable amount of ovicidal activity in a dose dependent manner. Among the fractions, fraction 9 showed poor ovicidal activity (Table 4).

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Table 4
Ovicidal activity (%) of different fractions isolated from chloroform extract of Clerodendrum phlomidis against Helicoverpa armigera.

Oviposition deterrent activity

Oviposition deterrent activity of different fractions against H. armigera is presented in Table 5. Fraction 5 at all the tested concentrations exhibited 100% oviposition deterrent activity followed by fraction 4 at 1000 and 500 ppm concentrations and fraction 6 at 1000 ppm. Fractions 1 to 8 at all the concentrations revealed notable amount of oviposition deterrent activity in a dose dependent manner. Fractions 9-12 showed poor oviposition deterrent activity compared to other fractions. In control, oviposition deterrent activity was observed as 11.23%.

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Table 5
Oviposition deterrent activity of chloroform fractions of Clerodendrum phlomoides against Helicoverpa armigera.

Isolation and characterization of the compound

The fraction eluted with the solvent hexane: ethyl acetate (1:1) gave a compound as pale yellow crystal crystallized from methanol (melting point 210°C, Lit. mp 210 - 212°C). The yield was 850 mg. It gave positive ferric reaction by giving green colour with alcoholic ferric chloride for phenol. It also answered Shinoda test for flavonoid by giving reddish pink colour with mg/HCl. TLC over silica gel G with Chloroform: Ethyl acetate (9:1) as the developing system gave a single spot, pale yellow turning dark yellow, on exposure to ammonia (Rf = 0.35). The purity of the compound was (98.2%) checked using HPLC. Spectral analyses were performed using UV, IR, ¹HNMR, ¹³CNMR and EI-MS.

The¹HNMR spectrum showed the absence of substituent at C-3, H-3 appearing as singlet at δ = 6.56. The lone aromatic proton H-8 appeared as singlet at δ = 6.54. The A₂B₂ system in ring B was shown by two sets of ortho coupled protons at δ 7.85 and 7.03 (J=9.0 Hz) corresponding to H-2' , H-6' and H-3' and H-5'. 4'-OMe appeared as three proton singlet at δ - 3.94 and 6-OMe appeared at 3.90. 7-OH appeared as a broad at singlet δ 9.39 and the chelated 5-OH appeared downfield at δ 12.96.

The ¹³CNMR also confirmed the structure of the compound as pectolinaringenin in the present investigation. The flavonoid carbonyl appeared slightly downfield at δ = 182.33. This suggested the unsubstituted C-3 with 5-OH. The single peak at δ 93.09 was assigned to C-8 and the absence of slightly downfield peak around δ 97.0 found for C-6 in 5,7-oxygenated flavones showed that C-6 was substituted. C-6 OMe appeared at δ 131.08. C-5 attached to chelated OH appeared at δ 152.72. The δ_c values in the ring B corresponded to pectolinaringenin.

The EI-MS gave M⁺, the molecular ion at m/z 314 corresponded to the molecular formula C₁₇H₁₄O_6.The peak at m/z 296 corresponded to [M-H₂O]⁺. The above data confirmed the structure as pectolinaringenin (Fig 1). The molecular formula is C₁₇H₁₄O_6.

Figure 1
Pectolinaringenin (5,7-dihydroxy- 4¢,6- dimethoxy-flavone).

Bioeffficacy of pectolinaringenin

Antifeedant activity

Pectolinaringenin exhibited 74.68% antifeedant activity against H. armigera at 100 ppm concentration followed by 50 ppm, which was 66.89%. The LC₅₀and LC₉₀ values were 33.95 and 140.44 ppm, respectively. Significant chi-square value was shown in Table 6.

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Table 6
Percent antifeedant, larvicidal, adult emergence, ovicidal and oviposition deterrent activities of pectolinaringenin against H. armigera.

Larvicidal activity

Maximum larvicidal activity of 81.11% was observed in pectolinaringenin againstH. armigera at 100 ppm concentration followed by 50 ppm concentration, which was 68.22%. The LC₅₀and LC₉₀values were 27.31 and 122.72 ppm, respectively. The Chi-square value was significant (Table 6).

Growth inhibitory activity

Pectolinaringenin at 100 ppm concentration completely prevented the adult emergence of H. armigera; 50 ppm resulted 35% adult emergence. In the case of control, the adult emergence was observed as 95.55% (Table 6).

Ovicidal activity

Pectolinaringenin at 100 ppm exhibited 67.95% ovicidal activity againstH. armigera followed by 50 ppm concentration, which was 56.67% (Table 6).

Oviposition deterrent activity

The oviposition deterrent activity was 100% at 100 and 50 ppm concentrations against H. armigera. More than 84.8% oviposition deterrent activity was observed at 25 and 12.5% concentrations (Table 6).

DISCUSSION

Antifeedant activity

Fractions eluted with hexane: ethyl acetate (1:1) of chloroform extract ofC. phlomidis recorded maximum feeding protection againstH. armigera at 1000 ppm concentration. The result was in agreement with Baskar et al. (2010)Baskar K, Duraipandiyan V and Ignacimuthu S, Bioefficacy of the triterpenoid friedelin against Helicoverpa armigera (Hub.) and Spodoptera litura (Fab.) (Lepidoptera: Noctuidae) . Pest Manage Sci. 2014; DOI: 10.1002/ps.3742.
https://doi.org/10.1002/ps.3742... who reported that hexane extract and effective fraction 8 from Couroupita guianensis exhibited more than 80% antifeedant activity againstH. armigera.

Pectolinaringenin at 100 ppm concentration showed maximum antifeedant activity of 74.68% followed by 50 ppm with the LC₅₀and LC₉₀ values of 33.95 and 140.44 ppm, respectively. This findings agreed with the report ofThoison et al.(2004)Thoison O, Sevenet T, Niemeyer HM, Russell GB. Insect antifeedant compounds from Nothofagus dombeyi and N. pumilio. Phytochem. 2004; 65: 2173-2176. who isolated several triterpenes and flavonoids fromNothofagus dombeyi and N. pumilio using bioassay-guided fractionation and observed that pectolinarigenin and 12-hydroxyoleanolic lactone from N. dombeyi and dihydrooroxylin A from N. pumilio exhibited feeding deterrent toCtenopsteustis obliquana larvae. Kumari et al. (2003)Kumari GNK, Balachandran J, Aravind S, Ganesh MR, Govindachari TR. Antifeedant and growth inhibitory effects of some neo-clerodane diterpenoids isolated from Clerodendron species (Verbenaceae) on Earias vittella and Spodoptera litura. J Agric Food Chem. 2003; 51: 1555-1559. studied the antifeedant activity of six neo-clerodane diterpenoides isolated fromClerodendrum species against E. vittellaand S. litura; they observed that all the compounds were exhibited more than 65% antifeedant activity at 10 µg/cm². Akhtar and Isman (2004)Akhtar Y, Isman MB. Comparative growth inhibitory and antifeedant effects of plant extracts and pure allelochemicals on four phytophagous insect species. J Appl Entomol. 2004; 128: 32-38. evaluated antifeedant effects of digitoxin, cymarin, xanthotoxin, toosendanin, thymol and trans-anethole against Trichoplusia ni, Pseudaletia unipuncta, Plutella xylostella andEpilachna varivestis and they found that xanthotoxin was most effective deterrent for T. ni, whereas thymol acted as good antifeedant against P. unipuncta, P. xylostella andE. varivestis.

Pectilonaringenin isolated from C. phlomidis exhibited strong antifeedant activity against H. armigera at 100 ppm concentration with least LC₅₀ and LC₉₀ values. The present findings agreed with the reports of Singh et al. (2011)Singh R, Koul O, Rup PJ, Jindal J. Oviposition and feeding behaviour of the maize borer, Chilo partellus, in response to eight essential oil allelochemicals. Entomol Exp Appl. 2011; 138: 55-64., who evaluated eight essential oils and some compounds againstChilo partellus for their antifeedancy. They observed that thymol and 1,8-Cineole exhibited least LC₅₀ values of 141.8 and 148.2 ppm, respectively. Similarly, Morimoto et al. (2000; 2003)Morimoto M, Komai K. Insect antifeedant activity of natural products and the structure-activity relationship of their derivatives. In: Natural Products for Pest Management. Am Chem Soc Sym Se. 2006; 927: 182-193. reported the antifeedant activity of rotenone, flavone, and 5-hydroxy-3,6,7,8,40-pentamethoxyflavone and recorded the LC₅₀values of 59.1 and 24.6 l and 42.8 mg/cm², respectively againstS. litura.

Proportionately little quantity of pectolinaringenin detected by HPLC was isolated from chloroform extract of C. phlomidis showed high antifeedant activity against H. armigera in the present study. This finding corroborated the earlier findings of Morimoto and Komai (2006)Morimoto M, Komai K. Insect antifeedant activity of natural products and the structure-activity relationship of their derivatives. In: Natural Products for Pest Management. Am Chem Soc Sym Se. 2006; 927: 182-193. who isolated four flavonoids namely, 5-hydroxy-3,6,7,8,4'-pentamethoxyflavone, 5-hydroxy-3,6,7,8-tetramethoxyflavone, 5,6-dihydroxy-3,7-dimethoxy flavone, and 4,4',6'-trihydroxy-2'-methoxychalcone from cudweed Gnaphalium affine and were screened against S. litura for feeding deterrent activity. Except 4,4',6'-trihydroxy-2'-methoxychalcone, all the other flavonoids showed strong antifeedant activity and were detected in small quantity by HPLC.

Positions of different groups in the structure decide the activity of the compound. In this study the presence of hydroxyl group at 5^th and 7^th position in A-ring and 4-pyran ring (a carbonyl in C-ring) contributed towards strong antifeedant activity. Methyoxyl group at C-4' in the B-ring contributed moderate antifeedant activity (Fig. 1). Feeding deterrency of pectolinaringenin in the present study agreed with the findings of Ohmura et al. (2000)Ohmura W, Doi S, Aoyama M, Ohara S. Antifeedant activity of flavonoids and related compounds against the subterranean termite Coptotermes formosanus Shiraki. J Wood Sci. 2000; 46: 149-153. who reported that the presence of hydroxyl group at 7^th position in the A-ring and carbonyl group at C-4 in the pyran ring in naringenin contributed strong antifeedant activity ofCoptotermes formosanus than the C-4' in the B-ring. Similarly, pinocembrin isolated from Flourensia oolepis having hydroxyl groups at 7^th position in A-ring and carbonyl at 4^th position in pyran ring C were responsible for the highest antifeedant activity against Epilachna paenulata (Georgina et al. 2009Georgina N, Napal D, Carpinella MC, Palacios SM. Antifeedant activity of ethanolic extract from Flourensia oolepis and isolation of pinocembrin as its active principle compound. Bioresource Technol. 2009; 100: 3669-3673.). Pectolinaringenin isolated from Clerodendron siphonenthus byPal et al. (1989)Pal S, Chowdhury A, Adityachaudhury N. Isolation of rice weevil feeding inhibitors uncinatone and pectolinarigenin from Clerodendron siphonenthus. J Agric Food Chem. 1989; 37: 234-236. showed feeding inhibition against the rice weevil, Sitophilus oryzae and fromC. phlomidis by Muthu et al. (2013)Muthu C, Baskar K, Ignacimuthu S, Al-Khaliel AS. Ovicidal and oviposition deterrent activities of the flavonoid pectolinaringenin from Clerodendrum phlomidis against Earias vittella. Phytoparasitica. 2013; 41: 365-372. showed ovicidal and oviposition deterrent activities against E. vittella, which also confirmed the present findings.

Larvicidal activity

Fraction 5 isolated from hexane: ethyl acetate system from chloroform extract ofC. phlomidis exhibited the least LC₅₀ value of 198.23 ppm against H. armigera larvae in the present study. This result coincided with the findings of Adeloma and Eloff (2011)Adeloma IO, Eloff JN. Ovicidal and larvicidal activity of Cassia alata leaf acetone extract and fractions on Haemonchus contortus: In vitro studies. Pharm Biol. 2011; 49: 539-44. who reported that acetone: chloroform fractions of Cassia alata exhibited the LC₅₀values of 0.505 mg/mL against the larvae of Haemonchus controtus.Recently, Anshul et al (2013)Anshul N, Bhakuni RS, Gaur R, Singh D. Isomeric flavonoids of Artemisia annua (Asterales: Asteraceae) as insect growth inhibitors against Helicoverpa armigera (Lepidoptera: Noctuidae). Florida Entomologist 2013; 96:897-903. reported that methanol extract containing isomeric flavonoids had potent larval mortality against H. armigera.

Chloroform extract fractions 5, 6 and 4 from C. phlomidis showed potent larvicidal activity against H. armigera in the present investigation. This result correlated with the earlier findings of Calle et al. (1990)Calle J, Rivera A, Luis JG, Aguiar ZE, Niemeyer HN, Natha PD. Insecticidal activity of the petroleum ether extract of Ageratum conyzoides L. Rev Colomb Quim. 1990; 19: 91-96., who studied the insecticidal activity of four fractions of Ageratum conyzoides petroleum extract, eluted with petroleum and increasing amount of chloroform. They reported that fraction 4 showed potent insecticidal activity of 80% against 3^rdand 4^th instar Lepidopteran larvae, Cynthia carye. They hypothesised that the activity might be due to the presence of flavonoidal compounds. Also, some flavonoids and flavonoid-containing extracts possessed anthelmintic and nematicidal activities which induced embryonic and larval lethality (Ayers et al. 2008Ayers S, Zink DL, Mohan K, Powell JS, Brown CM, Murphy T, et al. Flavones from Struthiola argentea with anthelmintic activity in vitro. Phytochem. 2008; 69: 541-545.; Kim et al. 2009Kim KS, Kawasaki I, Chong Y, Shim YH. Inhibition of over expressed CDC-25.1 phosphatase activity by flavone in Caenorhabditis elegans. Mol Cell. 2009; 27: 345-350.).

Fraction 5 at 1000 ppm and pectolinaringenin at 100 ppm exhibited potent larvicidal activity with least LC₅₀ values of 198.23 and 27.31ppm, respectively against H. armigera in this investigation. Similarly, Muthu et al. (2012a)Muthu C, Reegan AD, Kingsley S, Ignacimuthu S. Larvicidal activity of pectolinaringenin from Clerodendrum phlomidis L. against Culex quinquefasciatus Say. and Aedes aegypti L. (Diptera : Culicidae). Parasitol Res. 2012a; 111: 1059-1065. reported that fraction 5 exhibited LC₅₀ 5.02 and 61.63 ppm and pectolinaringenin LC₅₀ 0.62 and 2.87 ppm against C. quinquefasciatus and A. aegypti, respectively. At lower concentration (12.5 ppm), the compound exhibited more than 38% larval mortality against H. armigera. It was in accordance with the earlier findings of Kumari et al. (2003)Kumari GNK, Balachandran J, Aravind S, Ganesh MR, Govindachari TR. Antifeedant and growth inhibitory effects of some neo-clerodane diterpenoids isolated from Clerodendron species (Verbenaceae) on Earias vittella and Spodoptera litura. J Agric Food Chem. 2003; 51: 1555-1559.who reported that six neo-clerodane diterpenoides isolated fromClerodendrum species at 10 µg/cm² exhibited 20 and 44% larval mortality against E. vittella and S. litura, respectively. There are many reports on various flavonoids isolated from plants which also supported the present findings: quercetin and kaempferol isolated from Ricinus communis showed insecticidal activity against C. chinensis (Upasani et al. 2003Upasani SM, Kotkar HM, Mendki PS, Maheshwari VL. Partial characterization and insecticidal properties of Ricinus communis L foliage flavonoids. Pest Manage Sci. 2003; 59: 1349-1354.), bioassay with quercetin and rutin againstH. armigera drastically reduced the larval survival were reported by Jadhav et al. (2012)Jadhav DR, Nalini Mallikarjuna Rathore A, Dilip Pokle. Effect of Some Flavonoids on Survival and Development of Helicoverpa armigera(Hübner) and Spodoptera litura (Fab) (Lepidoptera: Noctuidae). Asian J Agric Sci 2012; 4: 298-307. which evidenced the larvicidal activity of flavonoids.

Growth inhibitory activities

Fractions and the compound either completely reduced the adult mergence or larval-pupal intermediate or pupicidal activities were observed in this study. This agreed with the earlier observation of Muthu et al. (2010)Muthu C, Baskar K, Kingsley S, Ignacimuthu S. Bioefficacy of Atalantia monophylla (L.) Correa. against Earias vittella Fab. J Cent Eur Agric. 2010; 11: 23-26. who reported very low adult emergence was observed in hexane and ethyl acetate extracts of Atalantia monophylla against E. vittella; Baskar et al. (2009)Baskar K, Kingsley S, Vendan SE, Paulraj MG, DuraipandiyanV, Ignacimuthu S. Antifeedant, larvicidal and pupicidal activities of Atalantia monophylla (L.) Correa against Helicoverpa armigera (Hubner) (Lepidoptera: Noctuidae). Chemosphere. 2009; 75: 355-359. observed complete prevention of adult emergence of H. armigera at higher concentration. Further, the fractions from the chloroform extract ofCaesalpinia bonduc reduced the emergence of S. litura (Baskar et al. 2012aBaskar K, Ignacimuthu S. Antifeedant, larvicidal and growth inhibitory effect of ononitol monohydrate isolated from Cassia tora L. against Helicoverpa armigera (Hbn.) and Spodoptera litura (Fab.) (Lepidoptera: Noctuidae) . Chemosphere. 2012a; 88: 384-388.).

In the present finding, pectolinaringenin completely prevented the adult emergence at 100 ppm concentration and low amount of adult emergence was observed in the lower concentrations against H. armigera. This was in agreement with the earlier findings of Muthu et al. (2012b)Muthu C, Baskar K, Kingsley S, Ignacimuthu S. Bioefficacy of Clerodendrrum phlomidis Lin. F. and Fleuggea leucoyrus (Koern.) Wild against Earias vittella Fab. J Entomol. 2012b; 9: 332-342. who found that chloroform extract of C. phlomidis completely prevented the adult emergence of E. vittella. Further, Isomeric flavonoid from methanol extract ofA. annua exhibited promising growth inhibitory activities against H. armigera (Anshul et al. 2013Anshul N, Bhakuni RS, Gaur R, Singh D. Isomeric flavonoids of Artemisia annua (Asterales: Asteraceae) as insect growth inhibitors against Helicoverpa armigera (Lepidoptera: Noctuidae). Florida Entomologist 2013; 96:897-903.).

Ovicidal activity

Maximum ovicidal activity of 69.25% was recorded in fraction 5 from chloroform extract of C. phlomidis at 1000 ppm concentration againstH. armigera. This agreed with the findings of Raja et al. (2005)Raja N, Jeyasankar A, Jeyakumar SV, Ignacimuthu S. Efficacy of Hyptis suaveolens against Lepidopteran pest. Curr Sci. 2005; 88: 220-222. who studied the ethyl acetate derived fractions and their compounds from Hyptis suaveolensshowed more than 60% ovicidal activity against S. litura and H. armigera. Ovicidal activity of different fractions from the hexane extract of Atalantia monophyllaagainst S. litura and H. armigera was studied by Baskar et al. (2012b)Baskar K, Ignacimuthu S. Ovicidal activity of Atalantia monophylla (L) Correa against Helicoverpa armigera Hubner (Lepidoptera: Noctuidae). J Agric Technol. 2012b; 8: 861-868. andBaskar and Ignacimuthu (2012b)Baskar K, Ignacimuthu S. Ovicidal activity of Atalantia monophylla (L) Correa against Helicoverpa armigera Hubner (Lepidoptera: Noctuidae). J Agric Technol. 2012b; 8: 861-868.; they reported that fraction 9 at 1000 ppm exhibited 75.61 and 72.21%, respectively.Jeyasankar et al. (2013)Jeyasankar A, Elumalai K, Raja N, Ignacimuthu S. Effect of plant chemicals on oviposition deterrent and ovicidal activities against female moth, Spodoptera litura (Fab.) (Lepidoptera: Noctuidae) . Int J Agric Sci Res. 2013; 2: 206-213. reported that Syzygium lineare derived fraction 3 and compound 3-(3-Hydroxy-hexyl)-detrahydro-pyron-4-one 3 showed ovicidal activity of 66.74 and 69.50% against S. litura.

Higher concentration of fraction 5 and 100 ppm of the compound reduced the egg hatchability in this study and the ovicidal activity was in dose dependent. Results of this investigation narrowly correlated with the results of Muthu et al. (2013)Muthu C, Baskar K, Ignacimuthu S, Al-Khaliel AS. Ovicidal and oviposition deterrent activities of the flavonoid pectolinaringenin from Clerodendrum phlomidis against Earias vittella. Phytoparasitica. 2013; 41: 365-372. who observed maximum ovicidal activity of 69.25% at 1000 ppm of fraction 5 and 67.95% activity in pectolinaringenin at 100 ppm against E. vittella. Earlier,Malarvannan et al. (2009)Malarvannan S, Giridharan R, Sekar S, Prabavathy VR, Nair S. Ovicidal activity of crude extracts of few traditional plants against Helicoverpa armigera (Hub.) (Noctuidae: Lepidoptera). J Biopest. 2009; 2: 64-71. observed higher concentration of plant derived extracts either completely or maximum percentage prevention of egg hatchability of H. armigera. Ovicidal activity may due to interference of the plant derived substances with the normal embryonic development of the eggs by suppressing hormonal and biochemical process, incomplete blastokinensis and abnormal breakage of extra embryonic membrane in the embryo (Enslee and Riddifold 1977Enslee EC, Riddiford LM. Morphological effects of JKM on embryonic development in the bug Pyrrhocoris apteru Wilhelm Roux's arch. Dev Biol. 1977; 181: 163-181.; Fagoonee and Lauge 1981Fagoonee I, Lange G. Noxious effects of neem extract of Crocidolomia binotalis. Phytoparasitica. 1981; 92: 111-118.). Garlic volatile was studied against the eggs of S. litura, Dysdercus koenigii, E. vittellaand H. armigera by Gurusubramanian and Krishna (1996)Gurusubramanian G and Krishna SS. The effects of exposing eggs of four cotton insect pests to volatiles of Allium sativum (Liliaceae). Bull Entomol Res. 1996; 86: 29-31. who observed that the chemicals present in the volatiles of garlic could diffuse into the eggs, thereby affecting the important physiological and biochemical processes associated with embryonic development.

Oviposition deterrent activity

Oviposition deterrency may be caused due to the adverse effects of secondary plant chemicals on ovarian development, fecundity and fertility of adults. In the present investigation, the fractions 4-6 and pectolinaringenin exhibited 100% oviposition deterrent activity against H. armigera. The observations of Muthu et al. (2013)Muthu C, Baskar K, Ignacimuthu S, Al-Khaliel AS. Ovicidal and oviposition deterrent activities of the flavonoid pectolinaringenin from Clerodendrum phlomidis against Earias vittella. Phytoparasitica. 2013; 41: 365-372.confirmed the present findings. They reported that fractions 3-6 from chloroform extract of C. phlomidis completely prevented the oviposition ofE. vittella at 1000 and 500 ppm concentrations and pectolinaringenin also showed 100% oviposition deterrent activity at 100 ppm concentration. Similarly, Singh et al. (2011)Singh R, Koul O, Rup PJ, Jindal J. Oviposition and feeding behaviour of the maize borer, Chilo partellus, in response to eight essential oil allelochemicals. Entomol Exp Appl. 2011; 138: 55-64. observed maximum oviposition deterrent activity in thymol against Chilo partellus both in choice and no-choice methods.

The presence of flavonoids in active fraction 5 and pectolinaringenin exhibited maximum oviposition deterrent activity against H. armigera. The present finding agreed with the findings of Hashem et al. (2013)Hashem MY, Ahmed AAI, Mohamed SM, Sewify GH, Khalil SH. Oviposition deterrent effect of Spodoptera littoralis (Boisd.) larval frass to adult females of two major noctuid insect pests. Arch Phytopathology Plant Protect. 2013; 46: 911-916. who studied the frass extract of S. littoralis fed with castor leaf against female adults of S. littoralis and A. ipsilon for oviposition deterrent activity; they observed that the presence of low amount of phenolics/ flavonoids effectively prevented the egg laying.

CONCLUSION

To the best of our knowledge, this is the first report on the fractions and pectolinaringenin against H. armigera for antifeedant, larvicidal, growth regulation, ovicidal and oviposition deterrent activities. The semi-purified extracts and an isolated compound from C. phlomidis exhibited various biological activities and could be effectively used to develop a new pesticidal formulation to control economically important agricultural pests and disease causing vector mosquitoes.

ACKNOWLEDGEMENT

This project was supported by King Saud University, Deanship Scientific Research, College of Science, Research Center

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Muthu C, Reegan AD, Kingsley S, Ignacimuthu S. Larvicidal activity of pectolinaringenin from Clerodendrum phlomidis L. against Culex quinquefasciatus Say. and Aedes aegypti L. (Diptera : Culicidae). Parasitol Res. 2012a; 111: 1059-1065.
Nimbalkar RK, Shinde SS, Tawar DS, Muley SP. Response of cotton bollworm Helicoverpa armigera (Hübner) (Lepidoptera: Noctuidae) to different insecticides in Maharashtra. India. World J Agric Sci. 2009; 5: 250-255.
Ohmura W, Doi S, Aoyama M, Ohara S. Antifeedant activity of flavonoids and related compounds against the subterranean termite Coptotermes formosanus Shiraki. J Wood Sci. 2000; 46: 149-153.
Pal S, Chowdhury A, Adityachaudhury N. Isolation of rice weevil feeding inhibitors uncinatone and pectolinarigenin from Clerodendron siphonenthus. J Agric Food Chem. 1989; 37: 234-236.
Pawar CS, Bhatnagar VS, Jadhav DR. Heliothis species and their natural enemies with their potential for biological control. Pro National Acad Sci (Animal Sci). 1986; a:697-703.
Raja N, Jayakumar M, Elumalai K, Jeyasankar A, Muthu C, Ignacimuthu S. Oviposition deterrent and ovicidal activity of solvent extracts of 50 plants against the Armyworm, Spodoptera litura Fab. (Lepidoptera:Noctuidae) . Malays Appl Biol. 2004; 33: 73-81.
Raja N, Jeyasankar A, Jeyakumar SV, Ignacimuthu S. Efficacy of Hyptis suaveolens against Lepidopteran pest. Curr Sci. 2005; 88: 220-222.
Rajapakse CNK, Walter GH. Polyphagy and primary host plants: oviposition preference versus larval performance in the lepidopteran pest Helicoverpa armigera. Arthropod-Plant Interaction. 2007; 1: 17-26.
Shafi MS, Ashraf MY, Sarwar G. Wild medicinal plants of Cholistan area of Pakistan. Pak J Biol Sci. 2001; 4: 112-116.
Simmonds MSJ. Flavonoid-insect interactions: recent advances in our knowledge. Phytochem. 2003; 64: 21-30.
Singh R, Koul O, Rup PJ, Jindal J. Oviposition and feeding behaviour of the maize borer, Chilo partellus, in response to eight essential oil allelochemicals. Entomol Exp Appl. 2011; 138: 55-64.
Thoison O, Sevenet T, Niemeyer HM, Russell GB. Insect antifeedant compounds from Nothofagus dombeyi and N. pumilio. Phytochem. 2004; 65: 2173-2176.
Upasani SM, Kotkar HM, Mendki PS, Maheshwari VL. Partial characterization and insecticidal properties of Ricinus communis L foliage flavonoids. Pest Manage Sci. 2003; 59: 1349-1354.
Vendan SE, Baskar K, Ramar M, Lingathurai S, Paulraj MG, Ignacimuthu S. Effect of plant extracts on larval development of Helicoverpa armigera. In: Ignacimuthu S, Jayaraj S, editor. Recent trends in Insect Pest Management. Elite Publication, New Delhi, India. 2008. p. 215-219.
Williams AL, Mitchell ER, Heath RR, Barfield CS. Oviposition deterrents for fall armyworm (Lepidoptera: Noctuidae) from larval frass, corn leaves and artificial diet. Environ Entomol. 1986; 15: 327-330.

Publication Dates

Publication in this collection
14 Oct 2014
Date of issue
Mar-Apr 2015

History

Received
03 May 2014
Accepted
04 Aug 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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[49] Ohmura W, Doi S, Aoyama M, Ohara S. Antifeedant activity of flavonoids and related compounds against the subterranean termite Coptotermes formosanus Shiraki. J Wood Sci. 2000; 46: 149-153.

[50] Pal S, Chowdhury A, Adityachaudhury N. Isolation of rice weevil feeding inhibitors uncinatone and pectolinarigenin from Clerodendron siphonenthus. J Agric Food Chem. 1989; 37: 234-236.

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[52] Raja N, Jayakumar M, Elumalai K, Jeyasankar A, Muthu C, Ignacimuthu S. Oviposition deterrent and ovicidal activity of solvent extracts of 50 plants against the Armyworm, Spodoptera litura Fab. (Lepidoptera:Noctuidae) . Malays Appl Biol. 2004; 33: 73-81.

[53] Raja N, Jeyasankar A, Jeyakumar SV, Ignacimuthu S. Efficacy of Hyptis suaveolens against Lepidopteran pest. Curr Sci. 2005; 88: 220-222.

[54] Rajapakse CNK, Walter GH. Polyphagy and primary host plants: oviposition preference versus larval performance in the lepidopteran pest Helicoverpa armigera. Arthropod-Plant Interaction. 2007; 1: 17-26.

[55] Shafi MS, Ashraf MY, Sarwar G. Wild medicinal plants of Cholistan area of Pakistan. Pak J Biol Sci. 2001; 4: 112-116.

[56] Simmonds MSJ. Flavonoid-insect interactions: recent advances in our knowledge. Phytochem. 2003; 64: 21-30.

[57] Singh R, Koul O, Rup PJ, Jindal J. Oviposition and feeding behaviour of the maize borer, Chilo partellus, in response to eight essential oil allelochemicals. Entomol Exp Appl. 2011; 138: 55-64.

[58] Thoison O, Sevenet T, Niemeyer HM, Russell GB. Insect antifeedant compounds from Nothofagus dombeyi and N. pumilio. Phytochem. 2004; 65: 2173-2176.

[59] Upasani SM, Kotkar HM, Mendki PS, Maheshwari VL. Partial characterization and insecticidal properties of Ricinus communis L foliage flavonoids. Pest Manage Sci. 2003; 59: 1349-1354.

[60] Vendan SE, Baskar K, Ramar M, Lingathurai S, Paulraj MG, Ignacimuthu S. Effect of plant extracts on larval development of Helicoverpa armigera. In: Ignacimuthu S, Jayaraj S, editor. Recent trends in Insect Pest Management. Elite Publication, New Delhi, India. 2008. p. 215-219.

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Fractions	Concentrations (ppm)				Effective concentration (ppm)		Χ²
Fractions	125	250	500	1000	LC₅₀	LC₅₀
1	12.26±3.12^bcd	20.31±2.92^bc	21.38±2.94^b	27.40±3.69^bc	2136.57	4677.23	18.44
2	7.41±1.34^ab	15.18±2.89^b	18.66±2.05^b	19.32±5.35^b	2755.51	5562.21	29.07*
3	15.63±3.28^cd	25.62±3.87^cd	43.62±5.66^d	59.18±1.60^e	761.73	1731.19	31.14*
4	34.24±3.45^ef	52.93±5.00^f	68.68±3.46^f	85.22±2.77^f	273.48	1083.07	30.53*
5	42.10±4.40^g	56.12±4.36^f	75.85±2.70^f	89.41±5.13^f	178.09	946.13	35.17*
6	37.38±2.65^fg	53.60±5.36^f	71.45±3.26^f	86.15±3.15^f	236.39	1049.46	29.59*
7	27.78±4.45^e	37.54±4.41^e	59.78±2.04^e	63.29±4.58^e	541.92	1799.57	50.43*
8	18.78±4.65^d	31.23±3.57^de	36.40±3.74^cd	43.80±4.37^d	1148.72	3029.64	29.32*
9	17.38±2.05^d	25.67±3.88^cd	33.52±4.87^c	36.18±5.92^cd	1507.45	3773.80	29.10*
10	13.95±2.83^bcd	22.51±5.74^bcd	33.02±1.24^c	39.28±5.45^d	1243.81	2834.54	33.32*
11	15.23±1.07^cd	18.43±3.04^bc	23.99±4.11^b	27.20±4.08^bc	2280.88	5155.99	13.39
12	9.89±1.93^bc	14.00±3.84^b	16.64±3.36^b	18.43±3.68^b	3372.13	6898.15	17.94
Control	2.72±0.64^a

Fractions	Concentrations (ppm)				Lethal concentration (ppm)		χ²
Fractions	125	250	500	1000	LC₅₀	LC₉₀	χ²
1	6.22±5.69^ab	10.22±0.49^b	14.22±5.29^bc	18.44±4.81^bc	2387.93	4460.89	39.20*
2	00±00^a	00±00^a	6.22±5.69^ab	10.22±0.49^b	1817.01	2700.91	79.58*
3	14.22±5.29^cd	20.44±0.99^cd	40.88±1.98^d	49.11±5.63^e	930.73	2060.39	44.11*
4	22.44±4.33^e	42.88±4.41^e	55.11±5.01^e	75.55±5.15^fg	480.49	1343.93	43.66*
5	38.66±2.98^g	55.11±5.15^f	75.77±8.51^f	83.77±5.18^g	198.23	1094.23	64.17*
6	30.66±1.49^f	42.88±4.41^e	61.33±2.98^e	73.55±4.93^f	417.83	1445.05	29.55*
7	18.22±3.97^de	26.44±4.93^d	38.66±2.98^d	46.88±4.54^e	1012.38	2495.13	27.41
8	8.22±4.62^bc	14.22±5.29^bc	20.44±0.99^c	28.44±3.47^d	1648.17	3229.83	29.14*
9	00±00^a	10.22±0.49^b	14.22±5.29^bc	22.44±4.33^cd	1609.25	2755.03	61.03*
10	00±00^a	00±00^a	6.22±5.69^ab	14.22±5.29^bc	1583.93	2327.70	77.49*
11	00±00^a	8.22±4.62^b	14.22±5.29^bc	20.44±0.99^cd	1656.66	2799.79	70.32*
12	00±00^a	00±00^a	00±00^a	00±00^a	-	-	-

Fractions	Concentrations (ppm)
Fractions	125	250	500	1000
1	91.55±4.75^de	88.61±0.62^f	83.33±6.44^f	75.47±6.76^c
2	100±00^e	100±00^g	89.05±1.03^f	84.16±5.85^c
3	83.61±5.32^d	74.28±1.59^e	69.33±5.96^e	44.00±5.47^b
4	58.21±9.07^bc	50.66±10.90^bcd	46.00±5.47^cd	00±00^a
5	36.66±7.45^a	31.00±8.21^a	00±00^a	00±00^a
6	52.85±6.38^b	46.00±5.47^b	26.66±3.72^b	00±00^a
7	52.50±5.59^b	47.14±6.38^bc	40.00±9.12^c	38.66±2.98^b
8	64.50±3.09^c	59.72±3.80^d	51.42±3.19^d	45.71±6.38^b
9	59.11±1.98^bc	56.94±3.10^cd	47.77±3.04^cd	42.5±8.50^b
10	57.11±4.41^bc	51.11±2.48^bcd	43.77±4.12^cd	38.33±6.84^b
11	89.77±0.49^de	88.83±0.88^f	85.83±4.54^f	82.14±6.56^c
12	100±00^e	97.77±4.96^fg	89.77±0.49^f	83.77±5.18^c
Control	100±00^e	100±00^g	100±00^g	100±00^d

Fractions	Concentrations (ppm)
Fractions	125	250	500	1000
1	15.87±3.17^bcd	24.41±2.07^def	36.12±3.59^efg	43.56±3.21^cde
2	12.64±4.41^abc	21.19±3.00^bcde	30.68±5.86^bcde	36.01±5.67^bc
3	19.02±5.62^cde	28.80±3.53^ef	32.95±5.50^def	42.56±3.42^cd
4	25.41±4.96^ef	31.90±3.43^f	42.45±5.12^g	52.05±5.80^e
5	31.90±3.43^f	41.45±3.55^g	61.76±3.33^h	69.25±3.04^f
6	22.25±3.76^de	28.63±3.90^ef	40.40±4.03^fg	49.05±4.03^de
7	19.14±2.79^cde	23.47±6.51^cde	34.01±4.40^defg	45.61±5.64^de
8	8.43±4.43^ab	13.81±2.80^ab	21.19±4.78^ab	30.85±2.08^ab
9	7.38±2.64^a	11.76±4.63^a	18.14±3.26^a	24.47±2.80^a
10	13.87±4.82^abc	18.09±2.88^abcd	23.42±2.92^abc	35.07±1.75^bc
11	15.98±0.70^bcd	20.19±2.12^bcd	31.90±3.43^cdef	43.56±3.21^cde
12	9.54±2.26^ab	15.87±4.89^abc	25.41±4.96^abcd	36.12±3.59^bc

Fractions	Concentrations (ppm)
Fractions	125	250	500	1000
1	55.26±4.13^fg	67.25±3.60^d	74.11±4.38^cd	88.24±1.40^ef
2	51.43±4.61^ef	69.57±5.95^de	85.21±3.29^e	89.33±1.57^ef
3	64.09±3.35^hi	79.67±3.56^f	93.40±1.20^f	96.18±1.64^gh
4	85.22±1.78^j	92.58±1.13^g	100.0±00^f	100.0±00^h
5	100.0±00^k	100.0±00^g	100.0±00^f	100.0±00^h
6	71.40±3.38ⁱ	78.04±2.39^ef	96.44±1.26^f	100.0±00^h
7	67.42±3.51^hi	71.65±3.68^def	78.57±4.84^de	91.80±2.03^fg
8	62.62±5.11^gh	72.77±3.42^def	79.48±3.74^de	85.21±0.50^e
9	38.81±1.59^cd	43.16±6.38^b	54.15±4.03^b	63.04±6.33^bc
10	33.37±4.74^bc	38.34±4.32^b	47.23±5.38^b	56.88±4.75^b
11	44.24±5.30^de	51.78±4.48^c	69.15±4.09^c	74.48±1.77^d
12	29.21±3.84^b	37.48±2.44^b	51.28±2.20^b	65.88±3.60^c
Control	11.23±3.95^a

Brasil

Brasil

Evaluation of fractions and 5,7-dihydroxy-4',6-dimethoxy-flavone fromClerodendrum phlomidis Linn. F. against Helicoverpa armigera Hub.

Abstract

INTRODUCTION

MATERIAL AND METHODS

Extraction, fractionation and isolation of pectolinaringenin

Identification of Compound

Collection and rearing of H. armigera

Antifeedant activity

Larvicidal bioassay

Growth inhibitory activity

Oviposition deterrent activity

Ovicidal activity

Statistical Analysis

RESULTS

Fractions

Antifeedant activity

Larvicidal activity

Growth inhibitory activity

Ovicidal activity

Oviposition deterrent activity

Isolation and characterization of the compound

Bioeffficacy of pectolinaringenin

Antifeedant activity

Larvicidal activity

Growth inhibitory activity

Ovicidal activity

Oviposition deterrent activity

DISCUSSION

Antifeedant activity

Larvicidal activity

Growth inhibitory activities

Ovicidal activity

Oviposition deterrent activity

CONCLUSION

ACKNOWLEDGEMENT

REFERENCES

Publication Dates

History