Insecticidal properties and chemical composition of Piper aduncum L., Lippia sidoides Cham. and Schinus terebinthifolius Raddi essential oils against Plutella xylostella L.

ARAÚJO, MÁRIO J.C. DE; CAMARA, CLÁUDIO A.G. DA; MORAES, MARCILIO M. DE; BORN, FLÁVIA S.

doi:10.1590/0001-3765202020180895

Abstract

In the laboratory, were evaluated the effects (residual contact and feeding deterrence) of the essential oils from the leaves of Piper aduncum, Lippia sidoides and Schinus terebinthifolius, as well as eleven selected constituents and binary blends of oils in different proportions against 3^rd instar larvae of Plutella xylostella (L.). The Piper oil demonstrated the greatest toxicity (LC₅₀ = 0.31 µL/mL) and feeding deterrence (DC₅₀ = 1.08 µL/mL) between oils tested. Dillapiole (LC₅₀ = 1.01 µL/mL; DC₅₀ = 1.10 µL/mL) and carvacrol (LC₅₀ = 6.03 µL/mL; DC₅₀ = 0.075 µL/mL) demonstrated the greatest toxicity and feeding deterrence between constituents tested, respectively. Based on the fractional effects indices for the blends, a synergistic interaction was found for the blend of the Lippia and Schinus oils at a proportion of 75 and 25%, respectively. The present findings indicate that this blend could be used in the control of P. xylostella, as the literature reports populations resistant to the active ingredient in the positive control, Premio®. Further studies are needed for the development of a new botanical insecticide based on the active ingredients in oils from L. sidoides and S. terebinthifolius to improve efficiency, stability and the cost-benefit in the control of P. xylostella.

Key words
Botanical insecticide; diamondback moth; feeding deterrent; synergistic properties

INTRODUCTION

The cultivation of vegetables in Brazil is on the order of 842 thousand hectares. The production of cabbage alone has reached 1.3 million tons in recent years, generating an income of US$ 250 million (ABCSEM 2014ABCSEM - ASSOCIAÇÃO BRASILEIRA DO COMÉRCIO DE SEMENTES E MUDAS. 2014. http://www.abcsem.com.br Acessado em julho de 2015.
http://www.abcsem.com.br... ). This production is currently affected by infestations and damage caused by larvae of the diamondback moth, Plutella xylostella (L.) (Lepidoptera: Plutellidae), which mainly attacks cabbage, kale and lettuce in irrigated systems, especially in the state of Pernambuco in northeastern Brazil. The damage caused by this pest occurs due to its high fecundity and high number of generations per year, causing serious problems for farmers and production losses surpassing 90% (Ulmer et al. 2002ULMER B, GILLOTT C, WOODS D & ERLANDSON M. 2002. Diamondback moth, Plutella xylostella (L.), feeding and oviposition preferences on glossy and waxy Brassica rapa (L.) lines. Crop Prot 21: 327-331.). The annual cost of species of Brassica is estimated to be US$ 1.4 billion, which could reach as high as US$ 2.7 billion if one considers losses in the field (Furlong et al. 2013FURLONG MJ, WRIGHT DJ & DOSDALL LM. 2013. Diamondback moth ecology and management: problems, progress and prospects. Annu Rev Entomol 58: 517-541.).

In an attempt to reduce such losses, synthetic chemical insecticides have been used as the main form of control (Furlong et al. 2013FURLONG MJ, WRIGHT DJ & DOSDALL LM. 2013. Diamondback moth ecology and management: problems, progress and prospects. Annu Rev Entomol 58: 517-541.), the most often employed of which belong to the groups of pyrethroids and organophosphates. The active ingredient (chlorantraniliprole) has been used in formulations of the main insecticides for the control of P. xylostella in Brazil. Despite its selectivity and low degree of toxicity to mammals (Brugger et al. 2010BRUGGER KE, COLE PG, NEWMAN IC, PARKER N, SCHOLZ B, SUVAGIS P, WALKER G & HAMMOND TG. 2010. Selectivity of chlorantraniliprole to parasitoid wasps. Pest Manag Sci 66: 1075-1081.), cases of resistance in populations of P. xylostella have been reported for formulations with chlorantraniliprole as the active ingredient (Gong et al. 2014GONG W, YAN H, GAO L, GUO Y & XUE C. 2014. Chlorantraniliprole resistance in the diamondback moth (Lepidoptera: Plutellidae). J Econ Entomol 107: 806-814., Troczka et al. 2012TROCZKA B, ZIMMER CT, ELIAS J, SCHORN C, BASS C, DAVIES TGE, FIELD LM, WILLIAMSON MS, SLATER R & NAUEN R. 2012. Resistance to diamide insecticides in diamondback moth, Plutella xylostella (Lepidoptera: Plutellidae) is associated with a mutation in the membrane-spanning domain of the ryanodine receptor. Insect Biochem Molec Biol 42: 873-880., Wang & Wu 2012WANG X & WU Y. 2012. High levels of resistance to chlorantraniliprole evolved in field populations of Plutella xylostella. J Econ Entomol 105: 1019-1023.), including populations that occur in the state of Pernambuco, Brazil (Ribeiro et al. 2013RIBEIRO LMS, WANDERLEY-TEIXEIRA V, FERREIRA HN, TEIXEIRA ÁAC & SIQUEIRA HAA. 2013. Fitness costs associated with field-evolved resistance to chlorantraniliprole in Putella xylostella (Lepidoptera: Plutellidae). Bull Entomol Res 104: 88-96.). This shows the indiscriminant use of these products, with an increase in applications in the field.

To establish new control practices with low toxicity to mammals and low persistence in the environment, synthetic insecticides could be replaced with botanical insecticides, especially in the form of complex blends of bioactive compounds, such as essential oils (Akhtar & Isman 2012AKHTAR Y & ISMAN MB. 2012. Plant natural products for pest management: the magic of mixtures. In: Ishaaya I, Palli SR and Horowitz AR (Eds). Advanced Technologies for managing insect pests, London: Springer Science & Business Media, London, p. 231-247.). In recent years, authors have reported the properties of such oils and their chemical constituents on different arthropods through fumigation, contact, residual effects or changes in the behavior of the pest, causing repellence, deterrence to oviposition and feeding deterrence (Jemâa et al. 2013JEMÂA JMB, HAOUEL S & KHOUJA ML. 2013. Efficacy of Eucalyptus essential oils fumigant control against Ectomyelois ceratoniae (Lepidoptera: Pyralidae) under various space occupation conditions. J Stored Prod Res 53: 67-71., Koul et al. 2013KOUL O, SINGH R, KAUR B & KANDA D. 2013. Comparative study on the behavioral response and acute toxicity of some essential oil compounds and their binary mixtures to larvae of Helicoverpa armigera, Spodoptera litura and Chilopartellus. Ind Crop Prod 49: 428-436., Kumrungsee et al. 2014KUMRUNGSEE N, PLUEMPANUPAT W, KOUL O & BULLANGPOTI V. 2014. Toxicity of essential oil compounds against diamondback moth, Plutella xylostella, and their impact on detoxification enzyme activities. J Pest Sci 87: 721-729., Olivero-Verbel et al. 2013OLIVERO-VERBEL J, TIRADO-BALLESTAS I, CABALLERO-GALLARDO K & STASHENKO EE. 2013. Essential oils applied to the food act as repellents toward Tribolium castaneum. J Stored Prod Res 55: 145-147., Setiawati et al. 2011SETIAWATI W, MURTININGSIH R & HASYIM A. 2011. Laboratory and field evaluation of essential oils from Cymbopogon nardus as oviposition deterrent and ovicidal activities against Helicoverpa armigera Hubner on chili pepper. Indones J Agric Sci 12: 9-16., Sousa et al. 2013SOUSA RMOF, ROSA JS, OLIVEIRA L, CUNHA A & FERNANDES-FERREIRA M. 2013. Activities of Apiaceae essential oils against Armyworm, Pseudaletia unipuncta (Lepidoptera: Noctuidae). J Agric Food Chem 61: 7661-7672.). Moreover, there is evidence that small amounts of compounds in essential oils may act as synergists, enhancing the effect of major compounds through different mechanisms (Akhtar & Isman 2012AKHTAR Y & ISMAN MB. 2012. Plant natural products for pest management: the magic of mixtures. In: Ishaaya I, Palli SR and Horowitz AR (Eds). Advanced Technologies for managing insect pests, London: Springer Science & Business Media, London, p. 231-247.). Despite reports in the literature confirming the effectiveness of blending essential oils used as antibiotics or antiseptic agents (Fratini et al. 2014FRATINI F, CASELLA S, LEONARDI M, PISSERI F, EBANI VV & PISTELLI L. 2014. Antibacterial activity of essential oils, their blends and mixtures of their main constituents against some strains supporting livestock mastitis. Fitoterapia 96: 1-7.), studies on the insecticidal action of binary blends of essential oils for the control of agricultural pests are scarce in the literature (Liu et al. 2006LIU CH, MISHRA AK, TAN RX, TANG C, YANG H & SHEN YF. 2006. Repellent and insecticidal activities of essential oils from Artemisia princeps and Cinnamomum camphora and their effect on seed germination of wheat and broad bean. Bioresour Technol 97: 1969-1973.).

In the search for alternatives to conventional insecticides, the aim of the present study was to determine the chemical composition of essential oils from the leaves of Piper aduncum, Lippia sidoides and Schinus terebinthifolius and evaluate the residual contact effect and feeding deterrence of the oils and selected chemical constituents (six monoterpenes, four sesquiterpenes and one phenylpropanoid) on 3^rd instar larvae of P. xylostella. Possible synergic effects of binary blends between the oils and the role of selected chemical constituents in the toxicity of the oils were also investigated and discussed.

MATERIALS AND METHODS

Collection of plant material

Leaves from Schinus terebinthifolius and Piper aduncum were collected from a fragment of the Atlantic forest in the city of Recife, state of Pernambuco, Brazil. The plants were identified by the botanist Dr. Maria Rita Cabral Sales de Melo by comparison with samples previously and 49.259 (S. terebinthifolius) and HST18177 (P. aduncum) at Herbarium of the Biology Department of the Rural Federal University of Pernambuco.

Essential oils extractions

The essential oils from fresh leaves (100 g) of P. aduncum and S. terebinthifolius were obtained by hydrodistillation using a modified Clevenger-type apparatus for 2 h. The oil layers were separated and dried over anhydrous sodium sulfate, stored in hermetically sealed glass containers and kept at a low temperature (-5 °C) until the insecticide assays and analysis. All experiments were carried out in triplicate. Lippia sidoides oil (genotype LSID104) was donated by Prof. Alves, PB from Chemistry Departament of the Federal University of Sergipe.

Chemicals

All monoterpenes (α-pinene, β-pinene, limonene, thymol, carvacrol and terpinolene), sesquiterpenes (β-caryophyllene, aromadendrene, α-humulene and caryophyllene oxide) and phenylpropanoid (dillapiole) were purchased from Sigma-Aldrich, Brazil. Insecticide Premio®, used as a positive control in the bioassay was acquired from the local market in Recife, Pernambuco, Brazil.

Gas chromatography FID analysis

GC identification was carried out using a Hewlett-Packard 5890 Series II GC apparatus equipped with a flame ionization detector (FID) and a non-polar DB-5 fused silica capillary column (30 m x 0.25 mm x 0.25 μm) (J & W. Scientific). The oven temperature was programmed from 60 to 240 °C at a rate 3 °C/min. Injector and detector temperatures were 260 °C. Hydrogen was used as the carrier gas at a flow rate of 1 mL/min in split mode (1:30). The injection volume was 0.5 µL of diluted solution (1/100) of oil in n-hexane. The percentage of each compound was obtained from GC-FID peak areas in the order of the DB-5 column elution and expressed as the relative percentage of the area of the chromatograms. Analysis was conducted in triplicate.

Gas chromatography-mass spectrometry analysis

The GC-MS analysis of the essential oils was carried out using a Varian 220-MS IT GC system with a mass selective detector, mass spectrometer in EI 70 eV with a scan interval of 0.5 s and fragments from 40 to 550 Da. fitted with the same column and temperature program as that for the GC-FID experiments, with the following parameters: carrier gas = helium; flow rate = 1 mL/min; split mode (1:30); injected volume = 1 µL of diluted solution (1/100) of oil in n-hexane.

Identification of components

Identification of the components was based on GC-MS retention indices with reference to a homologous series of C₈-C₄₀ n-alkanes calculated using the Van Den Dool and Kratz equation (Van Den Dool & Kratz 1963VAN DEN DOOL H & KRATZ PD. 1963. A generalization of the retention index system including linear temperature programmed gas liquid partition chromatography. J Chromatogr A 11: 463-471.) and by computer matching against the mass spectral library of the GC-MS data system (NIST version 11 and WILEY version 11) and co-injection with authentic standards, as well as other published mass spectra (Adams 2007ADAMS RP. 2007. Identification of Essential Oil Components by Gas Chromatography/Quadrupole Mass Espectroscopy, 4th ed., Allured Publishing Corporation: Carol Stream, 804 p.). Area percentages were obtained from the GC-FID response without the use of an internal standard or correction factors.

Rearing of Plutella xylostella

The rearing method for P. xylostella was conducted based on Torres et al. (2006)TORRES AL, BOIÇA JÚNIOR AL, MEDEIROS CAM & BARROS R. 2006. Efeito de extratos aquosos de Azadirachta indica, Melia azedarach e Aspidosperma pyrifolium no desenvolvimento e oviposição de Plutella xylostella. Bragantia 65: 447-457., with modifications. The insects used were from a susceptible population maintained at the Insect Biology Laboratory of the Rural Federal University of Pernambuco. Recently hatched insects were confined in plastic recipients measuring 15 x 10 x 15 cm containing foliar sections of organic cabbage. The leaves were exchanged daily until the insects reached the pupa phase, which were collected daily and placed in glass vials with a flat bottom measuring 1 cm in diameter, closed with transparent PVC wrap with small orifices for the circulation of air. Prior to emergence, the pupas were transferred to circular transparent plastic cages with an opening laterally closed with a “voil” to allow the circulation of air and the emergence of adults.

An orifice containing cotton soaked with a 10% solution of honey was maintained in the upper part of the cage. Cabbage leaves measuring 8.0 cm in diameter were placed inside the cages on moistened filter paper to allow oviposition. The foliar disks were replaced daily and those with eggs were placed in different plastic recipients until the hatching of the larvae.

Residual effect bioassays

The residual effect bioassays were based on the method described by Torres et al. (2006)TORRES AL, BOIÇA JÚNIOR AL, MEDEIROS CAM & BARROS R. 2006. Efeito de extratos aquosos de Azadirachta indica, Melia azedarach e Aspidosperma pyrifolium no desenvolvimento e oviposição de Plutella xylostella. Bragantia 65: 447-457., with modifications. Cabbage leaf disks measuring 5.0 cm in diameter were immersed for 30 seconds in the solutions prepared with essential oil or blends of oils or individual chemical constituents, diluted in methanol and allowed to dry on a paper towel at room temperature. The concentrations of essential oils used in the bioassays ranged from 0.05 to 200.00 µL/mL, their blends from 1.00 to 55.00 µL/mL and chemical constituents from 0.10 to 175.00 µL/mL. Control disks were only immersed in methanol. After drying, the disks were transferred to Petri dishes containing filter paper slightly moistened with distilled water. Five third instar P. xylostella larvae were placed in each dish. Mortality was recorded after 48 hours of exposure. The experimental design was entirely randomized, with 12 repetitions, totaling 60 larvae per treatment.

Mortality data were analyzed using the Probit model with the aid of the POLO-PC program for the determination of LC₅₀ with 95% confidence intervals (LeOra 1987LEORA S. 1987. POLO-PC: A User’s Guide to Probit Logit Analysis; Berkely.). The method described by Robertson et al. (2007)ROBERTSON JL, SAVIN NE, PREISLER HK & RUSSEL RM. 2007. Bioassays with arthropods. CRC Press, 224 p. was used to calculate the toxicity ratios with 95% confidence intervals. The results were compared to the positive control, which was the synthetic chemical insecticide Premio®, the active ingredient of which is chlorantraniliprole. The concentrations used for the positive control ranged from 1.4 x 10^-4 to 9.4 x 10^-3 µL/mL.

Feeding deterrence bioassays

The feeding deterrence method was adapted from Akhtar et al. (2012)AKHTAR Y, PAGES E, STEVENS A, BRADBURY R, DA CAMARA CAG & ISMAN MB. 2012. Effect of chemical complexity of essential oils on feeding deterrence in larvae of the cabbage looper. Physiol Entomol 37: 81-91.. Third instar P. xylostella larvae were transferred to Petri dishes and deprived of food for three to four hours prior to the experiments. Cabbage leaf disks measuring 2.0 cm in diameter were immersed for 30 seconds in the solutions prepared with essential oil or blends of oils or individual chemical constituents, diluted in methanol and allowed to dry on a paper towel at room temperature. The concentrations of the oils used in the bioassays ranged from 0.25 to 45.0 µL/mL, their blends from 0.20 to 20.0 µL/mL and chemical constituents from 0.05 to 425.0 µL/mL. The control disks were only immersed in methanol. After drying, a treated disk and control disk were placed at a distance of 0.7 cm in each Petri dish. A larva was placed in the center of the Petri dish between the two leaf disks and allowed to feed for 24 h. Twenty-four repetitions were used for each treatment, with each repetition consisting of one Petri dish containing one larva.

After 24 h of exposure, the larvae were removed and the foliar areas of the leaves consumed in the control and treatment disks were evaluated. This evaluation was performed with the aid of the Scion Image Software program. The feeding deterrence index (FDI) was calculated using the following formula: FDI = 100{(C – T) / (C + T)}, in which C and T are the areas consumed on the control and treated disks, respectively.

Preliminary tests were performed for all essential oils and binary blends at a concentration of 50 µL/mL and the FDI was submitted to analysis of variance with the means compared using Tukey’s test (P <0.05) with the aid of the SAS statistical program (SAS 2002SAS. 2002. SAS/User’s Guide: Statistics, version 9.0, 7th ed., SAS Institute Inc.: Cary.). After the preliminary tests, the FDI was calculated for each treatment and the concentrations causing 50% feeding deterrence (DC₅₀) were calculated through regression analysis with the aid of the SAS program (SAS 2002SAS. 2002. SAS/User’s Guide: Statistics, version 9.0, 7th ed., SAS Institute Inc.: Cary.). The results were compared with the positive control Premio®. The concentrations used in the bioassays of the positive control ranged from 3.6 x 10^-5 to 1.9 x 10^-2 µL/mL.

Fractional effect indices of binary essential oil blends

To investigate the possible synergistic action between the essential oils previously tested on P. xylostella, blends were prepared with the essential oils from L. sidoides (LS) + S. terebinthifolius (ST) and P. aduncum (PA) + L. sidoides (LS) in different proportions (50/50%, 25/75% and 75/25%). The LC₅₀ and DC₅₀ of the binary blends were estimated based on the methods used to evaluate the essential oils. The fractional effect indices (FEI) were calculated as follows: FEI = fractional effect_a + fractional effect_b, in which fractional effects_a = LC₅₀ _blend / LC₅₀ _a and fractional effect_b = LC₅₀ _blend / LC₅₀ _b (Houghton 2009HOUGHTON P. 2009. Synergy and polyvalence: paradigms to explain the activity of herbal products. In: Mukherjee PK and Houghton P (Eds). Evaluation of herbal medicinal products: Perspectives on quality, safety and efficacy, London: Pharmaceutical Press, London, p. 85-94.). The FEIs for the binary blends were interpreted based on the classification described by Bassolé et al. (2010)BASSOLÉ IHN, LAMIEN-MEDA A, BAYALA B, TIROGO S, FRANZ C, NOVAK J, NEBIÉ RC & DICKO MH. 2010. Composition and antimicrobial activities of Lippia multiflora Moldenke, Mentha x piperita L. and Ocimum basilicum L. essential oils and their major monoterpene alcohols alone and in combination. Molecules 15: 7825-7839. as being synergistic if FEI < 0.5, additive if FEI ≥ 0.5 and ≤ 1.0, indifferent if FEI > 1.0 and ≤ 4.0 or antagonistic if FEI > 4.0.

RESULTS

The yields and chemical composition of the essential oils from P. aduncum, L. sidoides and S. terebinthifolius and the chemical constituents are listed in increasing order based on the retention index (Table I).

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Table I
Percentage composition, yield of essential oils from Piper aduncum, Lippia sidoides and Schinus terebinthifolius.

The chemical analysis allowed identifying 16, 18 and 38 constituents, representing 98.8 ± 0.69%, 96.7 ± 1.08% and 96.0 ± 0.80% of the oils from P. aduncum, L. sidoides and S. terebinthifolius, respectively. The GC-MS analysis enabled the identification of dillapiole (73.4 ± 0.61%), carvacrol (49.2 ± 1.01%) and β-caryophyllene (17.2 ± 0.76%) as the main constituents of the Piper, Lippia and Schinus oils, respectively.

Essential oils from the leaves of P. aduncum (LC₅₀ = 0.31 µL/mL), L. sidoides (LC₅₀ = 27.94 µL/mL) and S. terebinthifolius (LC₅₀ = 83.42 µL/mL) were toxic to 3^rd instar P. xylostella larvae. Table II displays the estimated LC₅₀ values for the residual effect of the essential oils on P. xylostella. The susceptibility of the pest varied among the different oils. The Piper oil (LC₅₀ = 0.31 µL/mL) was 90-fold more toxic than the Lippia oil (LC₅₀ = 27.94 µL/mL) and 269-fold more toxic than the Schinus oil (LC₅₀ = 83.42 µL/mL).

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Table II
Residual activity of essential oils from the leaves of Piper aduncum L. (PA) (Piperaceae), Schinus terebinthifolius Raddi (Anacardiaceae) (ST) and Lippia sidoides Cham. (Verbenaceae) (LS), their binary mixtures, and Premio® as a positive control and selected oils constituents against lavae of 3^rd instar on Plutella xylostella (L.) (Lepidoptera: Plutellidae) in laboratory. Temp.: 25 ± 1°C, RH: 65 ± 5% and photophase: 12h.

The susceptibility of the pest varied in accordance with different proportions of the binary blends of the Piper, Lippia and Schinus oils (Table II). Independently of the proportion, the blend of the Lippia and Schinus oils had a significantly greater residual effect than the respective pure oils.

Based on the fractional effect index (FEI) of the blends, a synergistic interaction (FEI = 0.45) was found with the combination of the Lippia oil at 75% and the Schinus oil at 25% (Table II). An additive interaction was found for the combinations of 50% Lippia oil and 50% Schinus oil, as well as 25% Lippia oil and 75% Schinus oil. In contrast, all blends tested with the Piper and Lippia resulted in an antagonistic effect. However, none of the oils or blends was more toxic than the positive control (Premio®).

The results indicate the residual toxicity varied in accordance with the chemical class of each individual chemical constituent tested (Table II). Dillapiole, which belongs to the class of phenylpropanoids, was the most toxic (LC₅₀ = 1.01 µL/mL), followed by the monoterpenes carvacrol > terpinolene = thymol > β-pinene > α-pinene > limonene and, finally, the sesquiterpenes β-caryophyllene, aromadendrene, α-humulene and caryophyllene oxide, all which had the same level of toxicity. On the other hand, the phenylpropanoid dillapiole, which was identified as the major chemical constituent in the Piper oil, was 3.26-fold less toxic in comparison to the essential oil. Carvacrol and terpinolene were the most toxic among the monoterpenes (LC₅₀ = 6.03 and 9.03 µL/mL, respectively). Sesquiterpenes had the lowest toxicity: P. xylostella was more susceptible to β-caryophyllene, aromadendrene and α-humulene (LC₅₀ = 40.46, 49.34 and 55.61 µL/mL, respectively).

The residual effect LC₅₀ values of the constituents β-pinene, α-pinene and limonene were not estimated due to the low sensitivity of the 3^rd instar P. xylostella larvae, with mortality rates of 13.3, 32.0 and 53.0% at concentrations of 500, 600 and 1000 µL/mL, respectively.

Table III displays the feeding deterrence index (FDI) for the P. aduncum, L. sidoides and S. terebinthifolius essential oils, selected compounds and binary blends. The FDI was high (100%) for the oils and all blends.

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Table III
Activity feeding deterrent of essential oils from the leaves of Piper aduncum (PA) Schinus terebinthifolius (ST) and Lippia sidoides (LS), their binary mixtures, Premio® as a positive control and selected oils constituents against lavae of 3^rd instar on Plutella xylostella (L.) (Lepidoptera: Plutellidae) in laboratory. Temp.: 25 ± 1°C, RH: 65 ± 5% and photophase: 12h.

Considering the estimated DC₅₀ values, the best result was achieved with the Piper oil (DC₅₀ = 1.08 µL/mL), which was 1.58-fold more deterrent than the Lippia oil (DC₅₀ = 1.71 µL/mL) and 10.66-fold more deterrent than the Schinus oil (DC₅₀ = 11.51 µL/mL). Comparing the results with the positive control (Premio®) (DC₅₀ = 2.6 x 10^-3 µL/mL), the synthetic insecticide was 415.38-fold more deterrent than the Piper oil.

The deterrent effect varied with the different proportions of binary blends (Table III). The Piper and Lippia blend at a proportion of 25/75% was the most deterrent (DC₅₀ = 3.23 µL/mL), followed by 75/25% and 50/50% (DC₅₀ = 3.44 and 3.55 µL/mL, respectively). The blends prepared with 75/25% and 25/75% of the Lippia and Schinus oils had the same deterrent effect on P. xylostella and differed significantly from the blend at a proportion of 50/50%.

Based on the FEI values calculated for the blends, the results of the feeding deterrent effect suggest that the blends of Lippia and Schinus oils at proportions of 25/75% and 75/25% were indifferent and all other blends were antagonistic (Table III). Regarding the deterrent action of the selected chemical constituents against P. xylostella, the results displayed in Table III reveal that the monoterpene carvacrol (DC₅₀ = 0.075 µL/mL) was 14.0-fold more deterrent than the Piper oil and dillapiole (DC₅₀ = 1.08 and 1.10 µL/mL, respectively), which did not differ significantly from each other. Comparing the action of the sesquiterpenes, caryophyllene oxide (DC₅₀ = 23.69 µL/mL) was the most deterrent, followed by aromadendrene (DC₅₀ = 31.65 µL/mL). The constituents with the least deterrent action against the pest were the monoterpenes β-pinene and limonene (DC₅₀ = 52.19 and 73.11 µL/mL, respectively). Despite the significant deterrent action of the chemical constituents, none was more deterrent than the positive control (Premio®), which was 28.85-fold more deterrent than carvacrol.

DISCUSSION

The chemotypes determined for the Piper (dillapiole, 73.4 ± 0.61%). Lippia (carvacrol, 49.2 ± 1.01%) and Schinus (β-caryophyllene, 17.2 ± 0.76%) oils have been reported for P. aduncum (Souto et al. 2012SOUTO RNP, HARADA AY, ANDRADE EHA & MAIA JGS. 2012. Insecticidal Activity of Piper Essential Oils from the Amazon Against the Fire Ant Solenopsis saevissima (Smith) (Hymenoptera: Formicidae). Neotrop Entomol 41: 510-517.), L. sidoides (Silva et al. 2014SILVA DT ET AL. 2014. Larvicidal activity of Brazilian plant essential oils against Coenagrionidae larvae. J Econ Entomol 107: 1713-1720.) and S. terebinthifolius (Cavalcanti et al. 2015CAVALCANTI AS, ALVES MS, SILVA LCP, PATROCÍNIO DS, SANCHES MN, CHAVES DAS & SOUZA MAA. 2015. Volatiles composition and extraction kinetics from Schinus terebinthifolius and Schinus molle leaves and fruit. Rev Bras Farmacogn 25: 356-362.) from other collection sites. Despite the similarity between the major compounds identified in the present study and those reported in the literature, the GC-MS analysis enabled the identification of qualitative and quantitative differences, independently of the sampling site. The difference in the chemical profile of the essential oils of plants of the same species is generally attributed to genetic variability or biotic and abiotic factors, such as soil, altitude, collection season, etc. (Figueiredo et al. 2008FIGUEIREDO AC, BARROSO JG, PEDRO LG & SCHEFFER JJC. 2008. Factors affecting secondary metabolite production in plants: volatile components and essential oils. Flavour Fragr J 23: 213-226.).

The greater susceptibility of P. xylostella to the Piper oil in the residual effect and feeding deterrent tests may be attributed to differences in the chemical profile of the oils. Reports in the literature demonstrate that the relative toxicity and feeding deterrent action of essential oils are associated with their qualitative and quantitative composition, as well as the types of interactions among the chemical constituents (i.e., synergistic, antagonistic, additive or indifferent) (Moraes et al. 2017MORAES MM, DA CAMARA CAG & SILVA MMC. 2017. Comparative toxicity of essential oil and blends of selected terpenes of Ocotea species from Pernambuco, Brazil, against Tetranychus urticae Koch. An Acad Bras Cienc 89: 1417-1429., 2012, Neves & da Camara 2016NEVES RCS & DA CAMARA CAG. 2016. Chemical composition and acaricidal activity of the essential oils from Vitex agnus-castus L. (Verbenaceae) and selected monoterpenes. An Acad Bras Cienc 88: 1221-1233.).

None of the oils or binary blends tested on P. xylostella achieved better residual effect or feeding deterrent results than the insecticide Premio® used as the positive control. Chlorantraniliprole, which is the active ingredient in Premio®, was approved by the Brazilian Ministry of Agriculture in 2009 for the control of P. xylostella (Silva et al. 2012SILVA JE, SIQUEIRA HAA, SILVA TBM, CAMPOS MR & BARROS R. 2012. Baseline susceptibility to chlorantraniliprole of Brazilian populations of Plutella xylostella. Crop Prot 35: 97-101.), but cases of resistant populations of this pest to this main ingredient have been reported in different regions of the world since 2012 (Gong et al. 2014GONG W, YAN H, GAO L, GUO Y & XUE C. 2014. Chlorantraniliprole resistance in the diamondback moth (Lepidoptera: Plutellidae). J Econ Entomol 107: 806-814.), including the state of Pernambuco in Brazil (Ribeiro et al. 2013RIBEIRO LMS, WANDERLEY-TEIXEIRA V, FERREIRA HN, TEIXEIRA ÁAC & SIQUEIRA HAA. 2013. Fitness costs associated with field-evolved resistance to chlorantraniliprole in Putella xylostella (Lepidoptera: Plutellidae). Bull Entomol Res 104: 88-96.). While Premio® has a single active ingredient (chlorantraniliprole), which basically acts on calcium channels (Lahm et al. 2005LAHM GP, SELBY TP, FREUDENBERGER JH, STEVENSON TM, MYERS BJ, SEBURYAMO G, SMITH BK, FLEXNER L, CLARK CE & CORDOVA D. 2005. Insecticidal anthranilic diamides: a new class of potent ryanodine receptor activators. Bioorg Med Chem Lett 15: 4898-4906.), the different chemical constituents of essential oils may have different mechanisms of action, such as the inhibition of acetylcholinesterase, the blocking of octopamine receptors and GABA receptors and the inhibition of P450 cytochromes (Pavela & Benelli 2016PAVELA R & BENELLI G. 2016. Ethnobotanical knowledge on botanical repellents employed in the African region against mosquito vectors – a review. Exp Parasitol 167: 103-108.), thereby reducing the occurrence of the selection of resistant pest populations.

This is the first report on the insecticidal action and feeding deterrence of essential oils from Piper, Lippia and Schinus on P. xylostella larvae. However, other oils obtained from different plant species have been the object of study. For instance, oil from the stem of Cedrus deodara evaluated on 2^nd instar P. xylostella (LC₅₀ = 424.82 mg/mL) was 1300-fold less toxic than the Piper oil (Chaudhary et al. 2011CHAUDHARY A, SHARMA P, NADDA G, TEWARY DK & SINGH B. 2011. Chemical composition and larvicidal activities of the Himalayan cedar, Cedrus deodara essential oil and its fractions against the diamondback moth, Plutella xylostella. J Insect Sci 11: 1-10.). Purwatiningsih & Hassan (2012)PURWATININGSIH NH & HASSAN E. 2012. Efficacy of Leptospermum petersonii oil, on Plutella xylostella, and its parasitoid, Trichogramma pretiosum. J Econ Entomol 105: 1379-1384. evaluated the insecticidal action and feeding deterrence of the leaf oil from Leptospermum petersonii on 3^rd instar P. xylostella after seven days of treatment. Comparing the results of the study to those of the present investigation involving oils from Piper, Lippia and Schinus, the Piper oil was 94.6-fold more toxic than the L. petersonii oil (LC₅₀ = 2.93%), while the Lippia oil had the same degree of toxicity as the L. petersonii oil, but the latter oil was threefold more toxic than the oil from Schinus. However, the Piper, Lippia and Schinus oils at a concentration of 50 µL/mL (5%) had a greater feeding deterrent effect (FDI = 100%) in comparison to the L. petersonii (FDI = 63.2%) at a concentration of 6%.

The different responses found for the Piper, Lippia and Schinus oils in comparison to those reported in the literature on feeding deterrence may be explained by chemical interactions among the constituents of an essential oil and how a blend is detected by taste receptor sensilla (Akhtar et al. 2012AKHTAR Y, PAGES E, STEVENS A, BRADBURY R, DA CAMARA CAG & ISMAN MB. 2012. Effect of chemical complexity of essential oils on feeding deterrence in larvae of the cabbage looper. Physiol Entomol 37: 81-91.). Moreover, the activity of a blend depends on the susceptibility of the target organism (Cox et al. 2001COX SD, MANN CM & MARKHAM JL. 2001. Interactions between components of the essential oil of Melaleuca alternifolia. J Appl Microbiol 91: 492-497.). The different degrees of susceptibility and behavioral changes of the pest in response to the Piper, Lippia and Schinus oils and those reported in the literature for oils from C. deodara (Chaudhary et al. 2011CHAUDHARY A, SHARMA P, NADDA G, TEWARY DK & SINGH B. 2011. Chemical composition and larvicidal activities of the Himalayan cedar, Cedrus deodara essential oil and its fractions against the diamondback moth, Plutella xylostella. J Insect Sci 11: 1-10.) and L. petersonii (Purwatiningsih & Hassan 2012PURWATININGSIH NH & HASSAN E. 2012. Efficacy of Leptospermum petersonii oil, on Plutella xylostella, and its parasitoid, Trichogramma pretiosum. J Econ Entomol 105: 1379-1384.) may also be explained by differences in the chemical profile of the oils investigated, the use of different populations of the pest, as well as differences in the evaluation period and development stage of the insect.

The results for the binary blends of the oils in different proportions suggest that plant-based insecticides formulated with a combination of essential oils may have increased effectiveness. Pavela (2012)PAVELA R. 2012. Efficacy of three newly developed botanical insecticides based on pongan oil against Plutella xylostella L. larvae. J Biopest 5: 62-70. found similar results investigating the insecticidal action against P. xylostella in a greenhouse setting using oil from Pongamia pinnata blended with oils from Thymus vulgaris and Foeniculum vulgare.

Although no synergistic or additive effects were found with regard to feeding deterrence, the results suggest that the combination of different essential oils could potentiate their activity, as in the case of blends of L. sidoides and S. terebinthifolius, in which the deterrent activity at proportions of 25/75% and 75/25% was twofold greater than the pure Schinus oil. However, none of the blends was more deterrent than the positive control (Premio®).

Essential oils are complex mixtures comprised mainly of secondary metabolites that generally belong to the monoterpene, sesquiterpene and phenylpropanoid chemical classes. The relative toxicity and feeding deterrence effects found for selected chemical constituents from the Piper, Lippia and Schinus oils suggest that the biological properties of these oils depend not only on the properties of the individual constituents and their proportions in the oil, but also on possible synergistic or antagonistic interactions between these compounds (Moraes et al. 2012MORAES MM, DA CAMARA CAG, SANTOS ML & FAGG CW. 2012. Essential oil composition of Eugenia langsdorffii O. Berg.: relationships between some terpenoids and toxicity against Tetranychus urticae. J Braz Chem Soc 23: 1647-1656.). In the present study, the residual action of the compounds tested varied in accordance with the chemical class of the compounds and biological activity evaluated.

For instance, apparently none of the compounds of the Piper oil tested contributed substantially to the residual contact toxicity, as none demonstrated toxicity greater than or equal to that of the whole oil. This finding suggests that other constituents in the oil contribute more effectively to the toxicity of the oil. However, it is possible that interactions among the chemical constituents may have enhanced this residual contact effect. In contrast, dillapiole, which was the main component of the oil, demonstrated the same degree of feeding deterrence as that found for the whole oil. In this case, the activity of the oil can be partially attributed to this phenylpropanoid. Using the same reasoning, the residual contact activity found for the other oils can be partially attributed to the compounds carvacrol, terpinolene and thymol in the Lippia oil, whereas β-caryophyllene, aromadendrene, α-humulene and caryophyllene oxide contributed significantly to the toxicity found for the Schinus oil.

The results found for the Schinus oil suggest that the selected compounds do not directly contribute to the deterrent effect of the oil. In contrast, the feeding deterrent effect of the Lippia oil can be attributed to carvacrol, which was approximately 24.4-fold more deterrent than the whole oil.

Among the selected constituents of the Piper oils evaluated for activity against P. xylostella, the main component of the oil (dillapiole) was the most effective in terms of residual contact (LC₅₀) and feeding deterrence (DC₅₀), but its toxicity was lower than that found for the whole oil. Thus, the active ingredient in an essential oil is not always related to the major component and the insecticidal property found in the Piper oil may stem from synergistic interactions among the constituents. On the other hand, as dillapiole demonstrated the same degree of feeding deterrence as the whole oil, this phenylpropanoide contributes strongly to the deterrent action of the Piper oil.

This is the first report of the feeding deterrent action and toxicity of dillapiole, β-caryophyllene, terpinolene, carvacrol, aromadendrene, α-humulene, caryophyllene oxide, β-pinene and α-pinene against P. xylostella. However, there are reports in the literature on the biological properties of the other chemical constituents investigated in this study against the same pest. Ibrahim et al. (2005)IBRAHIM MA, NISSINEN A & HOLOPAINEN JK. 2005. Response of Plutella xylostella and its parasitoid Cotesia plutellae to volatile compounds. J Chem Ecol 31: 1969-1984. found that the monoterpene limonene did not demonstrate significant deterrent action against P. xylostella, but was attractive to its natural enemy, Cotesia plutellae. Likewise, limonene demonstrated low residual contact and feeding deterrent activity against P. xylostella larvae in the present study. Thymol is another chemical constituent investigated by our research group with previously reported results in the literature. Somjit et al. (2015)SOMJIT C, KUMRUNGSEE N, PLUEMPANUPAT W & BULLANPOTIL V. 2015. Insecticidal activities of thymol on egg production and development in the diamondback moth, Plutella xylostella (Lepidoptera). Commun Agric Appli Biol Sci 80: 187-192. used sublethal doses of thymol against P. xylostella through topical application and recorded a 54.3% reduction in the number of eggs, as well as a 30.0% pupation inhibition rate and 33.3% inhibition rate regarding the emergence of adults. Akhtar & Isman (2004)AKHTAR Y & ISMAN MB. 2004. Comparative growth inhibitory and antifeedant effects of plant extracts and pure allelochemicals on four phytophagous insect species. J Appl Ent 128: 32-38. estimated a DC₅₀ of 22.8 µg/cm² for thymol against third instar P. xylostella larvae, whereas the DC₅₀ in the present study was 70-fold lower. This divergence may be explained by differences between P. xylostella populations used in the experiments and their levels of susceptibility. The findings indicate that the activity of individual chemical constituents with regard to the feeding deterrence of pests depends on both the chemical nature of the compounds, as well as the susceptibility of the target organism.

The essential oils from the leaves of P. aduncum, L. sidoides and S. terebinthifolius had the same chemotypes as those reported for these species collected in different locations, revealing standardization in the chemical profile independently of the collection site. This is the first report of the residual contact and feeding deterrent action of these oils and selected constituents (dillapiole, carvacrol, terpinolene, β-caryophyllene, aromadendrene, α-humulene, caryophyllene oxide, α-pinene and β-pinene) against third instar larvae of P. xylostella. Based on the findings, it was possible to infer the relative contribution of the selected chemical constituents to the toxicity and feeding deterrence of the oils.

The toxicity of the oils and their binary blends, especially the Piper oil, indicate that these oils are excellent candidates for the formulation of botanical insecticides using essential oil as the active ingredient. However, further investigations should be conducted for the development of a new plant-based insecticide with the aim of improving the effectiveness, stability and cost-benefit relationship for the control of P. xylostella.

ACKNOWLEGMENTS

The authors are grateful to the Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco (FACEPE), Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior for awarding a grant (CAPES – Proc. # IBPG-0984-5.01/10; APQ-08601.06/16; a productivity scholarship (CNPq, # PQ-2-302860/2016-9) and research funding for this study (CNPq # 403162/203-0; FACEPE # APQ-1008-1.06/15; BCT-0185-1.06/17).

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» http://www.abcsem.com.br
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Publication Dates

Publication in this collection
26 June 2020
Date of issue
2020

History

Received
30 Aug 2018
Accepted
26 Oct 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ABCSEM - ASSOCIAÇÃO BRASILEIRA DO COMÉRCIO DE SEMENTES E MUDAS. 2014. http://www.abcsem.com.br Acessado em julho de 2015.
» http://www.abcsem.com.br

[2] ADAMS RP. 2007. Identification of Essential Oil Components by Gas Chromatography/Quadrupole Mass Espectroscopy, 4th ed., Allured Publishing Corporation: Carol Stream, 804 p.

[3] AKHTAR Y & ISMAN MB. 2004. Comparative growth inhibitory and antifeedant effects of plant extracts and pure allelochemicals on four phytophagous insect species. J Appl Ent 128: 32-38.

[4] AKHTAR Y & ISMAN MB. 2012. Plant natural products for pest management: the magic of mixtures. In: Ishaaya I, Palli SR and Horowitz AR (Eds). Advanced Technologies for managing insect pests, London: Springer Science & Business Media, London, p. 231-247.

[5] AKHTAR Y, PAGES E, STEVENS A, BRADBURY R, DA CAMARA CAG & ISMAN MB. 2012. Effect of chemical complexity of essential oils on feeding deterrence in larvae of the cabbage looper. Physiol Entomol 37: 81-91.

[6] BASSOLÉ IHN, LAMIEN-MEDA A, BAYALA B, TIROGO S, FRANZ C, NOVAK J, NEBIÉ RC & DICKO MH. 2010. Composition and antimicrobial activities of Lippia multiflora Moldenke, Mentha x piperita L. and Ocimum basilicum L. essential oils and their major monoterpene alcohols alone and in combination. Molecules 15: 7825-7839.

[7] BRUGGER KE, COLE PG, NEWMAN IC, PARKER N, SCHOLZ B, SUVAGIS P, WALKER G & HAMMOND TG. 2010. Selectivity of chlorantraniliprole to parasitoid wasps. Pest Manag Sci 66: 1075-1081.

[8] CAVALCANTI AS, ALVES MS, SILVA LCP, PATROCÍNIO DS, SANCHES MN, CHAVES DAS & SOUZA MAA. 2015. Volatiles composition and extraction kinetics from Schinus terebinthifolius and Schinus molle leaves and fruit. Rev Bras Farmacogn 25: 356-362.

[9] CHAUDHARY A, SHARMA P, NADDA G, TEWARY DK & SINGH B. 2011. Chemical composition and larvicidal activities of the Himalayan cedar, Cedrus deodara essential oil and its fractions against the diamondback moth, Plutella xylostella. J Insect Sci 11: 1-10.

[10] COX SD, MANN CM & MARKHAM JL. 2001. Interactions between components of the essential oil of Melaleuca alternifolia. J Appl Microbiol 91: 492-497.

[11] FIGUEIREDO AC, BARROSO JG, PEDRO LG & SCHEFFER JJC. 2008. Factors affecting secondary metabolite production in plants: volatile components and essential oils. Flavour Fragr J 23: 213-226.

[12] FRATINI F, CASELLA S, LEONARDI M, PISSERI F, EBANI VV & PISTELLI L. 2014. Antibacterial activity of essential oils, their blends and mixtures of their main constituents against some strains supporting livestock mastitis. Fitoterapia 96: 1-7.

[13] FURLONG MJ, WRIGHT DJ & DOSDALL LM. 2013. Diamondback moth ecology and management: problems, progress and prospects. Annu Rev Entomol 58: 517-541.

[14] GONG W, YAN H, GAO L, GUO Y & XUE C. 2014. Chlorantraniliprole resistance in the diamondback moth (Lepidoptera: Plutellidae). J Econ Entomol 107: 806-814.

[15] HOUGHTON P. 2009. Synergy and polyvalence: paradigms to explain the activity of herbal products. In: Mukherjee PK and Houghton P (Eds). Evaluation of herbal medicinal products: Perspectives on quality, safety and efficacy, London: Pharmaceutical Press, London, p. 85-94.

[16] IBRAHIM MA, NISSINEN A & HOLOPAINEN JK. 2005. Response of Plutella xylostella and its parasitoid Cotesia plutellae to volatile compounds. J Chem Ecol 31: 1969-1984.

[17] JEMÂA JMB, HAOUEL S & KHOUJA ML. 2013. Efficacy of Eucalyptus essential oils fumigant control against Ectomyelois ceratoniae (Lepidoptera: Pyralidae) under various space occupation conditions. J Stored Prod Res 53: 67-71.

[18] KOUL O, SINGH R, KAUR B & KANDA D. 2013. Comparative study on the behavioral response and acute toxicity of some essential oil compounds and their binary mixtures to larvae of Helicoverpa armigera, Spodoptera litura and Chilopartellus. Ind Crop Prod 49: 428-436.

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Compounds	RIC	RIL	Piper	Lippia	Schinus	Method of identification
α-Pinene	928	932	-	0.42 ± 0.00	0.37 ± 0.00	RI, MS, CI
β-Pinene	973	974	0.20 ± 0.01	1.88 ± 0.09	0.19 ± 0.00	RI, MS, CI
iso-Sylvestrene	1004	1007	0.43 ± 0.00	-	7.38 ± 0.58	RI, MS, CI
o-Cymene	1018	1022	1.80 ± 0.01	-	1.7 ± 0.02	RI, MS
Limonene	1021	1024	-	13.45 ± 0.68	1.02 ± 0.02	RI, MS, CI
Sylvestrene	1023	1025	-	0.43 ± 0.01	-	RI, MS
(E)-β-Ocimene	1025	1044	1.04 ± 0.02	0.41 ± 0.00	2.84 ± 0.17	RI, MS
γ-Terpinene	1050	1054	0.20 ± 0.01	6.07 ± 0.24	-	RI, MS
Terpinolene	1083	1086		0.40 ± 0.00	0.66 ± 0.10	RI, MS, CI
Terpinen-4-ol	1171	1174	0.55 ± 0.00	1.63 ± 0.09	1.5 ± 0.02	RI, MS
(E)-Isocitral	1176	1177	-	-	1.29 ± 0.17	RI, MS
α-Terpineol	1185	1186	1.92 ± 0.11	2.91 ± 0.08	-	RI, MS
Dihydro carveol	1191	1192	-	0.21 ± 0.01	-	RI, MS
Neral	1223	1227	-	-	0.22 ± 0.00	RI, MS
Methyl-ether-thymol	1229	1232	-	11.69 ± 0.41	-	RI, MS
Thymol	1286	1289	-	2.25 ± 0.09	-	RI, MS, CI
Carvacrol	1295	1298	-	49.23 ± 1.01	-	RI, MS, CI
δ-Elemene	1332	1335	0.68 ± 0.02	-	1.50 ± 0.05	RI, MS
α-Ylangene	1371	1373	-	-	0.86 ± 0.08	RI, MS
α-Copaene	1373	1374	-	-	1.66 ± 0.09	RI, MS
iso-longipinene	1390	1389	-	-	3.22 ± 0.13	RI, MS
Longipinene	1400	1400	-	-	3.24 ± 0.24	RI, MS
β-Funebrene	1410	1413	-	-	1.00 ± 0.11	RI, MS
β-Caryophyllene	1413	1417	3.13 ± 0.20	1.97 ± 0.11	17.18 ± 0.76	RI, MS, CI
β-Ylangene	1416	1419	-	-	1.41 ± 0.05	RI, MS
β-Duprezianene	1419	1421	-	-	0.40 ± 0.01	RI, MS
β-Copaene	1430	1430	-	-	2.16 ± 0.07	RI, MS
β-Gurjunene	1432	1431	-	-	1.91 ± 0.02	RI, MS
α-trans-Bergamotene	1433	1432	-	0.37 ± 0.01	-	RI, MS
γ-Elemene	1435	1434	1.20 ± 0.01	-	2.23 ± 0.10	RI, MS
Aromadendrene	1438	1439	-	-	15.49 ± 0.44	RI, MS, CI
cis-Prenyl-limonene	1440	1443	-	0.29 ± 0.00	-	RI, MS
α-Humulene	1450	1452	7.32 ± 0.34	-	-	RI, MS
9-epi-(E)-Caryophyllene	1461	1464	-	-	1.97 ± 0.10	RI, MS
γ-Gurjunene	1476	1475	1.50 ± 0.01	-	1.5 ± 0.10	RI, MS
γ-Muurolene	1477	1478	0.51 ± 0.00	-	-	RI, MS
γ-Himachalene	1479	1481	1.88 ± 0.0	-	-	RI, MS
α-Amorphene	1482	1483	1.00 ± 0.02	-	2.45 ± 0.15	RI, MS
Germacrene D	1485	1485	-	-	0.52 ± 0.01	RI, MS, CI
β-Selinene	1490	1489	-	1.12 ± 0.02	-	RI, MS
δ-Selinene	1491	1492	-	2.02 ± 0.09	-	RI, MS
Yalencene	1495	1496	-	-	1.14 ± 0.07	RI, MS
Bicyclogermacrene	1499	1500	-	-	8.64 ± 0.11	RI, MS, CI
β-Himachalene	1500	1500	-	-	1.71 ± 0.09	RI, MS
Germacrene A	1505	1508	-	-	1.84 ± 0.08	RI, MS
δ-Cadinene	1523	1522	-	-	0.52 ± 0.00	RI, MS
γ-(E)-Bisabolene	1530	1529	-	-	0.47 ± 0.02	RI, MS
γ-Cuprenene	1533	1532	-	-	0.21 ± 0.00	RI, MS
α-Cadinene	1539	1537	-	-	0.84 ± 0.02	RI, MS
Elemol	1544	1548	-	-	0.86 ± 0.03	RI, MS
Germacrene B	1558	1559	1.15 ± 0.04	-	1.75 ± 0.04	RI, MS
Longipinanol	1569	1567	-	-	0.74 ± 0.01	RI, MS
Caryophyllene oxide	1592	1590	-	-	0.68 ± 0.02	RI, MS
Carotol	1594	1594	-	-	0.23 ± 0.00	RI, MS
Dillapiole	1624	1620	73.40 ± 0.61	-	-	RI, MS, CI
Total			98.81 ± 0.69	96.66 ± 1.08	96.00 ± 0.80
Monoterpenes			3.94 ± 0.10	90.52 ± 1.01	9.67 ± 0.61
Sequiterpenes			21.47 ± 0.31	6.14 ± 0.11	85.23 ± 0.55
Phenylpropanoids			73.40 ± 0.61	-	-

Oils/Mixtures/Constituents	n	df	Slope ± SE	χ²	LC₅₀ (µL/mL)(IC 95%)	TR₅₀ *(IC 95%)	FEI	Interactiontype
Premio®	480	5	1.68 ± 0.14	2.24	1 x 10^-3 (1 x 10^-3 -2 x 10^-3)	-	-	-
PA	420	4	2.44 ± 0.22	3.86	0.31 (0.26-0.35)	2.07 x10² (4.54 x10^-9.40 x10²)	-	-
LS	416	4	2.27 ± 0.20	3.81	27.94 (23.62-32.74)	18.91 x10³ (15.46 x10³-23.14 x10³)	-	-
ST	360	3	3.46 ± 0.33	2.50	83.42 (73.83-93.68)	5.58 x10⁴ (4.48 x10⁴-6.95 x10⁴)	-	-
PA + LS (50-50%)	420	4	3.14 ± 0.28	3.68	3.93 (3.48-4.41)	2.65 x10³ (4.70 x10²-1.49 x10⁴)	12.82	Antagonist
PA + LS (25-75%)	420	4	2.89 ± 0.27	3.90	4.48 (3.91-5.01)	3.01 x10³ (6.85 x10²-1.32 x10⁴)	14.61	Antagonist
PA + LS (75-25%)	420	4	6.89 ± 0.62	3.96	4.73 (4.48-4.99)	3.18 x10³ (7.30 x10²-1.38 x10⁴)	15.43	Antagonist
LS + ST (75/25%)	420	4	2.92 ± 0.27	3.73	9.36 (8.22-10.56)	6.25 x10³ (5.23 x10³-7.49 x10³)	0.45	Synergistic
LS + ST (50/50%)	480	5	2.75 ± 0.24	4.53	11.55 (10.18-12.99)	7.75x10³ (6.53 x10³-9.20 x10³)	0.55	Additive
LS + ST (25/75%)	480	5	3.27 ± 0.28	3.67	18.27 (16.48-20.18)	1.22 x10⁴ (1.06 x10⁴-1.40x10⁴)	0.87	Additive
Dillapiole	360	3	1.92 ± 0.19	3.13	1.01 (0.70-1.44)	6.80 x10² (1.47x10²-3.14x10³)	-	-
Carvacrol	420	4	2.27 ± 0.21	4.32	6.03 (4.71-7.60)	4.05 x10³ (9.41 x10²-1.74 x10⁴)	-	-
Terpinolene	420	4	1.23 ± 0.11	4.05	9,03 (5.78-13.71)	6.01 x10³ (1.41 x10³-2.55 x10⁴)	-	-
Thymol	360	3	2.92 ± 0.28	3.39	13.60 (10.73-17.63)	9.14 x10³ (2.41 x10³-3.47 x10⁴)	-	-
β-Caryophyllene	480	5	1.83 ± 0.15	4.23	40.46 (33.64-48.36)	2.75 x10⁴ (8.67 x10³-8.72 x10⁴)	-	-
Aromadendrene	360	3	2.75 ± 0.26	2.59	49.34 (42.60-57.05)	3.33 x10⁴ (1.38 x10⁴-8.04 x10⁴)	-	-
α-Humulene	420	4	2.60 ± 0.23	4.24	55.61 (44.89-67.92)	3.71 x10⁴ (1.43 x10⁴-9.62 x10⁴)	-	-
Caryophyllene oxide	480	5	2.64 ± 0.23	4.90	60.99 (53.61-68.96)	4.05 x10⁴ (1.60 x10⁴-1.02 x10⁵)	-	-

Oils/Mixtures/Constituents	% FDI ± SE(50 µL mL^-1)	DC₅₀ (µL/mL)(IC 95%)	R ²	FEI	Interaction type
Premio®	100.00 ± 0.00	2.6 x 10^-3 (2.4 x 10^-3-2.8 x 10^-3)	0.59	-	-
PA	100.00 ± 0.00	1.08 (0.99-1.18)	0.54	-	-
LS	100.00 ± 0.00	1.71 (1.58-1.87)	0.56	-	-
ST	100.00 ± 0.00	11.51 (10.66-12.52)	0.51	-	-
PA + LS (25-75%)	100.00 ± 0.00	3.23 (3.15-3.32)	0.93	4.88	Antagonist
PA + LS (75-25%)	100.00 ± 0.00	3.44 (3.35-3.55)	0.92	5.20	Antagonist
PA + LS (50-50%)	100.00 ± 0.00	3.55 (3.45-3.65)	0.93	5.36	Antagonist
LS + ST (75-25%)	100.00 ± 0.00	5.38 (5.23-5.53)	0.96	3.61	Indiferent
LS + ST (25-75%)	100.00 ± 0.00	5.49 (5.30-5.69)	0.86	3.69	Indiferent
LS + ST (50-50%)	100.00 ± 0.00	10.21 (10.04-10.39)	0.97	6.86	Antagonist
Carvacrol	100.00 ± 0.00	0.075 (0.071-0.080)	0.76	-	-
Dillapiole	100.00 ± 0.00	1.10 (1.06-1.15)	0.87	-	-
Thymol	100.00 ± 0.00	5.38 (5.29-5.57)	0.89	-	-
Caryophyllene oxide	82.39 ± 2.63	23.69 (22.62-24.87)	0.80	-	-
Aromadendrene	78.87 ± 1.56	31.65 (30.28-33.15)	0.82	-	-
Terpinolene	74.50 ± 1.19	35.18 (33.78-36.70)	0.72	-	-
β-Caryophyllene	68.08 ± 1.20	35.85 (34.99-36.76)	0.88	-	-
α-Humulene	75.14 ± 1.28	37.27 (35.72-38.96)	0.84	-	-
α-Pinene	72.16 ± 1.12	37.43 (34.34-39.78)	0.64	-	-
β-Pinene	63.38 ± 2.16	52.19 (49.47-55.22)	0.77	-	-
Limonene	67.31 ± 4.09	73.11 (68.69-78.15)	0.54	-	-

Brasil

Brasil

Insecticidal properties and chemical composition of Piper aduncum L., Lippia sidoides Cham. and Schinus terebinthifolius Raddi essential oils against Plutella xylostella L.

Abstract

INTRODUCTION

MATERIALS AND METHODS

Collection of plant material

Essential oils extractions

Chemicals

Gas chromatography FID analysis

Gas chromatography-mass spectrometry analysis

Identification of components

Rearing of Plutella xylostella

Residual effect bioassays

Feeding deterrence bioassays

Fractional effect indices of binary essential oil blends

RESULTS

DISCUSSION

ACKNOWLEGMENTS

REFERENCES

Publication Dates

History