<b>Differential timing response of Herbivory-Induced Volatiles (HIPVs) in <i>Croton floribundus</i> Spreng. (Euphorbiaceae)</b>

Pinheiro-Oliveira, Débora; Pedrosa, Giselle da Silva; Souza, Silvia Ribeiro de

doi:10.1590/2236-8906-e182022

ABSTRACT

In this study, we demonstrated that Tetranychus urticae Koch (Acari: Tetranychidae), a generalist herbivore, induces volatile organic compounds (VOC) in Croton floribundus Spreng., a pioneer species widely used in Brazilian urban area. We performed experiments to evaluate the quality and quantity of VOC emission at different times (two, six and 24 hours and within four and nine days) of infestation by T. urticae. Results show that C. floribundus emitted 23 volatiles after infestation, including monoterpene, sesquiterpene and green leaf volatiles. Significant differences were only detected between infested and non-infested plants after 24 hours of treatment, in particular methyl salicylate. In contrast, 3-hexen-1ol, linaool, geranyl acetone and caryophyllene seem to be inhibited by hourly infestation. The α-farnesene, methyl salicylate, 3-carene, 3-hexen-1ol benzoate and nerolidol were the main compounds induced after four infestation-days. This study highlights that VOCs blends in C. floribundus is depended on the feeding time-course of T. urticae and suggests that the VOC-mediated ecological interaction may be less efficient in a pioneer species.

Keywords:
Croton floribundus; herbivory; isoprenoids; pioneer tree; volatile organic compound

RESUMO

Neste estudo foi demonstrado que o Tetranychus urticae Koch (Acari: Tetranychidae), um herbívoro generalista, promove a emissão de compostos orgânicos voláteis (COV) em Croton floribundus (L.) Spreng., uma espécie pioneira amplamente utilizada na área urbana brasileira. Avaliou-se a qualidade e quantidade de emissão de COV em diferentes momentos (2, 6 e 24 horas e no intervalo de 4 e 9 dias) de infestação por T. urticae. Os resultados mostram que C. floribundus emitiu 23 voláteis após infestação, incluindo monoterpenos, sesquiterpenos e voláteis de folhas verdes. Diferenças significativas entre plantas infestadas e não infestadas foram detectadas após 24 horas de tratamento, em particular foram observadas alterações nos níveis de metil salicitato. Em contraste, o 3-hexen-1ol, linaool, geranil acetona e cariofileno parecem ter sido inibidos pela infestação horária. O α-farneseno, metil salicilato, 3-careno, benzoato de 3-hexen-1ol e nerolidol foram os principais compostos induzidos após quatro dias de infestação. Este estudo demonstra que o buquet de COVs emitido por C. floribundus depende do tempo de infestação da T. urticae e sugere que a interação ecológica mediada por COVs pode ser menos eficiente em espécie pioneira.

Palavras-chave:
árvores pioneiras; compostos orgânicos voláteis; Croton floribundus; herbivoria; isoprenoides

Introduction

Plants produce mixtures of volatile organic compounds (VOCs), so-called herbivore-induced VOCs (HIPVs) as a natural interaction to herbivory. The amount and chemical variability of VOCs produced are specific for each insect-plant interaction and depends on the nature and the intensity of stress (Pareja and Pinto-Zevallos 2016Pareja, M. & Pinto-Zevallos, D.M. 2016. Impacts of Induction of Plant Volatiles by Individual and Multiple Stresses Across Trophic Levels. In: Deciphering Chemical Language of Plant Communication: 61-93.), natural enemies and neighboring plants (Fürstenberg-Hägg et al. 2013Fürstenberg-Hägg, J., Zagrobelny, M. & Bak, S. 2013. Plant defense against insect herbivores. International Journal of Molecular Sciences 14(5): 10242-10297.). The chemical variability and amounts of VOCs are also dependent on the developmental stage of the plant species and the herbivore. In addition, VOCs can act as repellents for herbivores that infest and cause pests, or as attractants for their natural enemies, as well as alert intact and neighboring plants to future attacks (Maffei 2010Maffei, M.E. 2010. Sites of synthesis, biochemistry and functional role of plant volatiles. South African Journal of Botany 76 (4): 612-631.). Literature data show that the urban environment can alter the physiology and behavior of herbivores and even substantially affect the increase in herbivory rate over time (Baldwin et al 2006Baldwin, I.T., Halitschke, R., Paschold, A., Von Dahl C.C. & Preston C.A. 2006. Volatile signaling in plant-plant interactions:" talking trees" in the genomics era. Science 311 (5762): 812-815., Himanen et al. 2010Himanen, S.J., Blande, J.D., Klemola, T., Pulkkinen, J., Heijari, J. & Holopainen, J.K. 2010. Birch (Betula spp.) leaves adsorb and re‐release volatiles specific to neighboring plants-a mechanism for associational herbivore resistance? New Phytologist 186 (3): 722-732., Holopainen J. K., Blande J. D. 2013Holopainen, J.K. & Blande, J.D. 2013. Where do herbivore-induced plant volatiles go? Frontiers in Plant Science 4: 180-185.). Data on herbivory and the production of VOCs with cultivated plants, in the agricultural sector is well documented, with a significant number of herbivore-plant combinations, however, little is known about herbivory with native species, especially those that occur in urban environments. Croton floribundus (L.) Spreng. is a pioneer species widely distributed in the Brazilian rainforest and used in restoration plans of urban areas for being a pioneer successional species and recently considered as highly tolerant to abiotic stress (Cardoso-Gustavson et al. 2014Cardoso-Gustavson, P., Bolsoni, V.P., de Oliveira, D.P., Guaratini, M.T.G., Aidar, M.P.M., Marabesi, M.A., Segala, E. & Souza, S.R. 2014. Ozone-induced responses in Croton floribundus Spreng. (Euphorbiaceae): metabolic cross-talk between volatile organic compounds and calcium oxalate crystal formation. PloS One 9 (8): e105072., Moura et al. 2018Moura, B.B., Alves, E.S., Marabesi, M.A., Souza, S.R., Schaub, M. & Vollenweider, P. 2018. Ozone affects leaf physiology and causes injury to foliage of native tree species from the tropical Atlantic Forest of southern Brazil. Science of The Total Environment 610: 912-925.). However, the effect of biotic stress in C. floribundus has not yet been reported, especially in the case of VOCs induced by T. urticae.

Our previous research has shown that C. floribundus emits high levels of mono and sesquiterpene constitutive volatile (Bolsoni et al. 2018Bolsoni, V.P., Oliveira, D.P.D., Pedrosa, G.D.S. & Souza, S.R. 2018. Volatile organic compounds (VOC) variation in Croton floribundus (L.) Spreng. related to environmental conditions and ozone concentration in an urban forest of the city of São Paulo, São Paulo State, Brazil. Hoehnea 45 (2): 184-191., Moura et. al 2022Moura, B.B. , Bolsoni, V.P., Paula, M.D., Dias, G.M & Souza, S.R. 2022. Ozone impact on the emission of Biogenic Volatile Organic Compounds (BVOCs) in tropical tree species. Frontiers in Plant Science, V. 13: p. 87039.) and under oxidative ozone stress can induce the signalling volatile, in particular methyl salicylate (MeSa) and monoterpenes that can increase the plant defence against biotic and abiotic stress (Cardoso-Gustavson et al. 2014Cardoso-Gustavson, P., Bolsoni, V.P., de Oliveira, D.P., Guaratini, M.T.G., Aidar, M.P.M., Marabesi, M.A., Segala, E. & Souza, S.R. 2014. Ozone-induced responses in Croton floribundus Spreng. (Euphorbiaceae): metabolic cross-talk between volatile organic compounds and calcium oxalate crystal formation. PloS One 9 (8): e105072.). If abiotic stress, e.g. ozone, can induce signalling VOCs in C. froribundus (Pinto et al. 2010Pinto, D.M., Blande, J., Souza, S.R., Nerg, A. & Holopainen, J.K. 2010. Plant volatile organic compound (VOCs) in ozone polluted atmospheres: The ecological Effects. Journal of Chemical Ecology 36 (1): 22-24., Souza et al. 2013Souza, S.R., Blande, J.D. & Holopainen, J.K. 2013. Pre-exposure to nitric oxide modulates the effect of ozone on oxidative defenses and volatile emissions in lima bean. Environmental Pollution 179: 111-119., Cardoso-Gustavson et al. 2014Cardoso-Gustavson, P., Bolsoni, V.P., de Oliveira, D.P., Guaratini, M.T.G., Aidar, M.P.M., Marabesi, M.A., Segala, E. & Souza, S.R. 2014. Ozone-induced responses in Croton floribundus Spreng. (Euphorbiaceae): metabolic cross-talk between volatile organic compounds and calcium oxalate crystal formation. PloS One 9 (8): e105072.), would also be expected the similar behaviour in biotic stress, e.g. herbivory. However, there are no studies of HIPVs in C. floribundus. Therefore, we aimed to evaluate the effect of time infestation by Tetranychus urticae Koch (Acari: Tetranychidae) on volatile emission in C. floribundus to characterize the profile of HPIV on a pioneer species with high occurrence in an urban area and extensively used in the ecological restoration.

Material and methods

Living Material - One-month old Croton floribundus Spreng. plants purchased from a nursery (Bioflora, Piracicaba, São Paulo) were individually sown in 10-L pots filled with a 3:1 mixture of peat and sand and watered by capillarity. Plants were kept inside the greenhouse with filtered air for four weeks and then transferred to chambers, where they were kept for 4 days before the beginning of the herbivory exposure (acclimation period). Plants were watered as needed until the VOCs collection. Fortnightly the plants received a nutritional solution. Individual of Tetranychus urticae Koch (Acari: Tetranychidae) were started from adults collected from Phaseulus vulgaris and transferred to Croton floribundus for adaptation. Each plant received 200 individuals of T. urticae, which were arranged randomly in the leaf limbs. Each individual was kept in a chamber with continuous airflow, artificial light (422 µmol.cm²sˉ¹), 27.2±2 °C and 65.3± 5.2% humidity.

Plant VOC collection and analysis - VOCs from the headspace of both non-infested (control) and infested C. floribundus plants by T. urticae were collected. Induction of plants was accomplished by infesting two young leaves in two set of experiments, in which one of them was carried out in hours and another in days of infestation by T. urticae. The volatiles were collected from each individual after 0, 2, 6 and 24 hours (hourly experiment) and 4 to 7-9 days (daily experiment). Prior to placing the plants into the chamber, the pots were enclosed in aluminum paper to avoid the presence of volatiles from the pot or soil in the samples. The push-pull sampling system constructed worked as follows. Charcoal-filtered humidified airflow (20 L/min) was generated by a compressor. Airflow was divided into four parts (1.5 L/min) using a manifold line connection with four outlines. In this way, four replicates of treatment and control (individuals infested and non-infested) were collected simultaneously. Each individual was kept in a Teflon bag with two opens; one for inflow air and another connected to a tube for VOC collection. VOCs were collected from the out coming air onto ca. 150 g Tenax TA adsorbent (Mesh 60/80, Supelco, PA, USA) at a rate of 0.200 L/min for 90 minutes, by pulling the air with a vacuum pump (Air lite, Supelco). All the system was constructed with Teflon, and the airflows adjusted with adjustable flow meters (Cole-Parmer Instruments Co). The experiment was repeated six time.

VOCs were analyzed by gas chromatography-mass spectrometry (GC-MS) (MSD 5973; Agilent GC 6890). Trapped compounds were desorbed with a thermal desorption unit (Perkin-Elmer ATD400 Automatic Thermal Desorption system; Perkin Elmer, Waltham, MA, USA) at 250 °C for 10 min, cryofocused at -30 °C and injected into an HP-5 capillary column (50 m x 0.2 mm i.d. x 0.5 µm film thickness; Hewlett-Packard) with helium as a carrier gas. The oven temperature program was held at 40 °C for 1 min, then raised to 210 °C at a rate of 5 °C min^-1 and finally raised further to 250 °C at a rate of 20 °C min^-1. Compounds were identified by comparing their mass spectra with the mass spectra in a reference library (NIST MS 2.0), and in the literature (Adams 2007Adams, R.P. 2007. Identification of essential oil components by gas chromatography/mass spectrometry. 4th ed. Carol Stream, IL: Allured publishing corporation.). Quantification of individual compounds was achieved by comparing the peaks with the peaks of known concentrations of synthetic compounds after the construction of calibration curves. For those compounds that synthetic standards were not available, quantification was achieved by considering their response to be the same as of α-pinene. Emission rates were calculated and expressed in ng per gram of leaf dry weight per hour (leaves dried at 60 °C for 72 hours).

Statistical Analyses - Statistical analyses were performed with Sigma plot 12.0. To detect the main compounds that contributed hourly and daily to the blend of induced volatiles, the comparison between the volatiles of C. floribundus infested by T. urticae and controls was carried out using ANOVA and Tukey post hoc for multiple comparisons. When normality was not achieved, the non-parametric Mann-Whitney U test was performed.

Results

Twenty-three compounds were found in the headspace of Croton floribundus, considering constitutive and induced VOCs. All the identified VOCs were grouped into their respective chemical classes and summarized in tables 1 and 2. No significant differences in the hourly experiment between non-infested (control) and infested plants were found except for methyl salicylate (MeSA) twhich showed higher levels after six and 24 hours and 3-hexen-1-ol after 24 hours of infestation (table 1) Although a significant difference was not detectable in others compounds, it is noteworthy that linalool was the main terpene emitted in the control of the hourly experiment (table 1), while its synthesis was almost completely inhibited in the treatment. There was also an increase in farnesene in the treated plants after 24 hours. In daily experiment, monoterpene 3-carene, -farnesene, 3-hexen-1ol benzoate showed significant differences between the infestation and control (table 2), in which their levels were increased after four infestation-days. In additional, aldehydes such as 3-hexanal and nonanal, and alcohols such as 3-hexen-1-ol reduced their levels upon Tetranychus urticae Koch (Acari: Tetranychidae) infestation (table 2). Comparing the sum of all emissions in the hourly and daily experiments, there were a decrease in plant emissions on hourly treatments while an increase in plant emissions in daily treatments was observed.

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Table 1.
Hourly emissions of Volatile Organic Compounds (VOC) (ng g DW^-1 h^-1) by non-infested (control) Croton floribundus. Spreng. and plants infested (Herbivory) by 200 individuals Tetranychus urticae Koch (Mean ± S.E.M) (N = 24). Statistically significant values are presented with asterisks for comparison of control and treatment.

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Table 2.
Daily emissions of Volatile Organic Compounds (VOC) (ng g DW^-1 h^-1) by non-infested (control) Croton floribundus Spreng. and plants infested (Herbivory) by 200 individuals Tetranychus urticae Koch (Mean ± S.E.M) (N = 24). Statistically significant values are presented with asterisks for comparison of control and treatment.

To demonstrate the induced, inhibited, and non-affected VOC in infested C. florbundus upon T. urticae the ration between infestation/control VOCs emissions was performed (figure 1 and 2) in logarithmic scale. To standardize the three category of infestation effect, we considered the range of experimental errors (from - 0.05 to 0.05) to non-affected VOC, logarithmic values above 0.05 to induced VOC and below -0.05 to inhibited VOC. The T. urticae was able to induce granyl acetone and a-cubebene at 2h and 3-hexen-1ol benzoate, 3-hexenal at 6h and 24h of exposure. Meanwhile, 3-carene, a -farnesene and b-farnesene were only induced at 24h. The beginning of infestation with T. urticae inhibited the syntheses of gernyl acetone, 3-hexen-1ol benzoate, n-valeric, 3-hexen 1-ol, a -farnesene, caryophelene, b-farnesene, copaene, methyl salicylate, decanal and nonanal (figure 1). In daily experiments, most of the emitted VOCs were induced; -farnesene, 3-carene, Methyl Salicylate (MeSA), 3-hexen-1ol were induced in all days of treatment. Moreover, the sesquiterpenes, α-farnesene, were significantly induced by T. urticae, up to nine infestation-days. Although D-limonene and Methyl Jasmonate (MeJA) were induced in four days, they were inhibited in six and seven days of exposure. Interestingly, MeJA appeared only in the daily experiment; being induced at four days, followed by inhibition at 5 and 6 days and going through induction at 7 days. Furthermore, the induction of MeJA was higher than that of methyl salicylate after seven days of infestation (figure 2).

Figure 1:
Induction and inhibition of Volatile Organic Compound (VOC) in Croton floribundus Spreng. represented as the ration between VOC emission from infested and non-infested plants by Tetranychus urticae Koch in the hourly experiment. The ration is expressed in the log (x). The zero value represents the equal values of control and treatment. Between -0.05 and 0.05 values represents non-affected VOC emission (red dashed line). Above 0.05 value is the ration of induction and below -0.05 is the ration of inhibition of VOCs emissions a: Monoterpene. b: Sesquiterpene. c: Green leaf volatiles. d: Other compounds.

Figure 2:
Induction and inhibition of Volatile Organic Compound (VOC) in Croton floribundus represented as the ration between VOC emission from infested and non-infested plants by Tetranychus urticae Koch in the daily experiment. The ration is expressed in the log (x). The zero value represents the equal values of control and treatment. Between -0.05 and 0.05 values represents non-affected VOC emission (red dashed line). Above 0.05 value is the ration of induction and below -0.05 is the ration of inhibition of VOCs emissions. a: Monoterpene. b: Sesquiterpene. c: Green leaf volatiles. d: Other compounds.

Discussion

Croton floribundus Spreng. is widely used in ecological restoration plans of Brazilian urban areas for being a pioneer successional species and recently considered as highly tolerant to abiotic stress (Cardoso-Gustavson et al. 2014Cardoso-Gustavson, P., Bolsoni, V.P., de Oliveira, D.P., Guaratini, M.T.G., Aidar, M.P.M., Marabesi, M.A., Segala, E. & Souza, S.R. 2014. Ozone-induced responses in Croton floribundus Spreng. (Euphorbiaceae): metabolic cross-talk between volatile organic compounds and calcium oxalate crystal formation. PloS One 9 (8): e105072., Moura et al. 2018Moura, B.B., Alves, E.S., Marabesi, M.A., Souza, S.R., Schaub, M. & Vollenweider, P. 2018. Ozone affects leaf physiology and causes injury to foliage of native tree species from the tropical Atlantic Forest of southern Brazil. Science of The Total Environment 610: 912-925.). However, the effect of biotic stress in C. floribundus has not yet been reported, especially in the case of VOCs induced by Tetranychus urticae Koch (Acari: Tetranychidae). We know that T. urticae is a general herbivore and infests many crop plant species such as beans (Dicke et al. 1990Dicke, M., Sabelis, M.W., Takabayashi, J., Bruin, J. & Posthumus, M.A. 1990. Plant strategies of manipulating predatorprey interactions through allelochemicals: prospects for application in pest control. Journal of Chemical Ecology, 16(11): 3091-3118.), apple (Takabayashi et al. 1991Takabayashi, J., Dicke, M. & Posthumus, M.A. 1991. Variation in composition of predator-attracting allelochemicals emitted by herbivore-infested plants: relative influence of plant and herbivore. Chemoecology 2 (1): 1-6.) and tomato (Dicke et al. 1998Dicke, M., Takabayashi, J., Posthumus, M.A., Schütte, C. & Krips, O.E. 1998. Plant-Phytoseiid interactions mediated by herbivore-induced plant volatiles: variation in production of cues and in responses of predatory mites. Experimental and Applied Acarology 22(6): 311-333.) and induces a variety of volatiles that are attractive to its natural predator Phytoseiulus persimilis (Van Den Boom et al. 2004Van Den Boom, C.E., Van Beek, T.A., Posthumus, M.A., De Groot, A. & Dicke, M. 2004. Qualitative and quantitative variation among volatile profiles induced by Tetranychus urticae feeding on plants from various families. Journal of Chemical Ecology 30(1): 69-89.), such as MeSa and α-farnesene, caryophyllene and linalool. In our study, herbivory-induced volatiles in C. floribundus were similar to those reported by Van Den Boom et al. (2004Van Den Boom, C.E., Van Beek, T.A., Posthumus, M.A., De Groot, A. & Dicke, M. 2004. Qualitative and quantitative variation among volatile profiles induced by Tetranychus urticae feeding on plants from various families. Journal of Chemical Ecology 30(1): 69-89.), being MeSA and α-farnesene promptly induced, indicating that responsiveness of C. floribundus to T. urticae may be similar to that in crop plants.

Previous studies with herbivores have shown that herbivore-induced volatiles are influenced by feeding time-course (Niinemets et al. 2013Niinemets, Ü., Kännaste, A. & Copolovici, L. 2013. Quantitative patterns between plant volatile emissions induced by biotic stresses and the degree of damage. Frontiers in Plant Science 4: 262.), modifying the volatile blends quantitatively (Dicke 1999Dicke, M. 1999. Are herbivore-induced plant volatiles reliable indicators of herbivore identity to foraging carnivorous arthropods? In Proceedings of the 10th International Symposium on Insect-Plant Relationships 91: 131-142., Zhang 2003). However, qualitatively differences in volatile blends have been little reported (Himanen et al. 2010Himanen, S.J., Blande, J.D., Klemola, T., Pulkkinen, J., Heijari, J. & Holopainen, J.K. 2010. Birch (Betula spp.) leaves adsorb and re‐release volatiles specific to neighboring plants-a mechanism for associational herbivore resistance? New Phytologist 186 (3): 722-732.). In this study, the results showed that the herbivore-induced VOCs blends in C. floribundus varied both quantitatively and qualitatively, and that such variations depended on the feeding time-course.

In the hourly experiment, there was an inhibition of several constitutive volatiles after two and six hours of T. urticae infestation, leading to a qualitative change in the herbivore-induced VOCs blends. In this case, the absence of 3-hexen 1-ol, linalool, β copaene, -farnesene in C. floribundus after infestation by T. urticae was relevant to distinguish the VOCs profiles. In contrast, quantitative changes were observed in the daily experiment, in which 3-hexen-1ol, 3-carene, linalool, MeSA, MeJA α-farnesene and nerolydol were induced and showed significant differences between undamaged and damaged plants. All of these compounds have been associated with a strategy defense of plants against herbivory (Dicke 1999Dicke, M. 1999. Are herbivore-induced plant volatiles reliable indicators of herbivore identity to foraging carnivorous arthropods? In Proceedings of the 10th International Symposium on Insect-Plant Relationships 91: 131-142., Arimura et al. 2000Arimura, G.I., Tashiro, K., Kuhara, S., Nishioka, T., Ozawa, R. & Takabayashi J. 2000. Gene responses in bean leaves induced by herbivory and by herbivore-induced volatiles. Biochemical and Biophysical Research Communications 277 (2): 305-310., Birkett et al. 2000Birkett, M.A., Campbell, C.A., Chamberlain, K., Guerrieri, E., Hick, A. J., Martin, J.L. & Poppy, G.M. 2000. New roles for cis-jasmone as an insect semiochemical and in plant defense. Proceedings of the National Academy of Sciences 97(16): 9329-9334., Baldwin et al. 2006Baldwin, I.T., Halitschke, R., Paschold, A., Von Dahl C.C. & Preston C.A. 2006. Volatile signaling in plant-plant interactions:" talking trees" in the genomics era. Science 311 (5762): 812-815., Kant et al. 2009Kant, M.R., Bleeker, P.M., Van Wijk, M., Schuurink, R.C. & Haring, M.A. 2009. Plant volatiles in defense. Advances in Botanical Research 51: 613-666., Kigathi et al. 2009Kigathi, R.N., Unsicker, S.B., Reichelt, M., Kesselmeier, J., Gershenzon, J. & Weisser, W.W. 2009. Emission of volatile organic compounds after herbivory from Trifolium pratense (L.) under laboratory and field conditions. Journal of chemical ecology 35(11): 1335., Pinto-Zevallos et al. 2013Pinto-Zevallos, D.M., Martins, C.B., Pellegrino, A.C. & Zarbin, P.H. 2013. Compostos orgânicos voláteis na defesa induzida das plantas contra insetos herbívoros. Quim Nova 36 (9): 1395-1405.). Moreover, MeSA and MeJA, which are derived from the oxygenation of polyunsaturated fatty acids via the octadecanoid pathway, play a central role in plant defense against pathogens and herbivory. MeJA has been reported as a vital cellular regulator that mediates diverse developmental process and defenses response against biotic and abiotic stresses (Pinto-Zevallos et al. 2013Pinto-Zevallos, D.M., Martins, C.B., Pellegrino, A.C. & Zarbin, P.H. 2013. Compostos orgânicos voláteis na defesa induzida das plantas contra insetos herbívoros. Quim Nova 36 (9): 1395-1405.). In our study, the syntheses of MeJA triggered only after days of exposure, indicating that that C. floribundus may be more tolerant to T. urticae during the first hours of infestation and before the synthesis of MeJA is activated, when it can diffuse through intercellular migration to induce systemic signaling (Bruinsma et al. 2009Bruinsma, M., Posthumus, M.A., Mumm, R., Mueller, M.J., Van Loon, J.J. & Dicke, M. 2009. Jasmonic acid-induced volatiles of Brassica oleracea attract parasitoids: effects of time and dose, and comparison with induction by herbivores. Journal of Experimental Botany 60 (9): 2575-2587.).

Some compounds detected here, such as 3-hexen-1ol, linalool, α farnesene and caryophyllene have been reported as volatiles induced by T. urticae in crop plants and, unlike those reported in this study, they are induced in shorter time of infestation (Holopainen 2004Holopainen, J.K. 2004. Multiple functions of inducible plant volatiles. Trends in Plant Science 9 (11): 529-533., Holopainen and Blande 2013Holopainen, J.K. & Blande, J.D. 2013. Where do herbivore-induced plant volatiles go? Frontiers in Plant Science 4: 180-185., Zakir 2013Zakir, A., Bengtsson, M., Sadek, M.M., Hansson, B.S., Witzgall, P. & Anderson, P. 2013. Specific response to herbivore-induced de novo synthesized plant volatiles provides reliable information for host plant selection in a moth. Journal of Experimental Biology 216 (17): 3257-3263.). Also, according to Holopainen et al. (2013Holopainen, J.K. & Blande, J.D. 2013. Where do herbivore-induced plant volatiles go? Frontiers in Plant Science 4: 180-185.) the presence of α-farnesene and caryophyllene in the bouquet of volatiles has a relevant impact on the trophic interactions between T. urticae and its predators. Some studies reported that the repellency of α-farnesene and caryophyllene is directly related to the proportion of these compounds in the blend of induced volatiles (Mostafavi et al. 1996Mostafavi, R., Henning, J.A., Gardea-Torresday, J. & Ray, I.M. 1996. Variation in aphid alarm pheromone content among glandular and glandular-haired Medicago accessions. Journal of Chemical Ecology 22 (9): 1629-1638., Holopainen 2004Holopainen, J.K. 2004. Multiple functions of inducible plant volatiles. Trends in Plant Science 9 (11): 529-533.). Many studies have shown that high levels of caryophyllenes can reduce the potential repellency of farnesene (Bernasconi et al. 1998Bernasconi, M.L., Turlings, T. C., Ambrosetti, L., Bassetti, P. & Dorn, S. 1998. Herbivore‐ induced emissions of maize volatiles repel the corn leaf aphid, Rhopalosiphum maidis. Entomologia Experimentalis et Applicata, 87(2), 133-142., Mostafavi et al. 1996Mostafavi, R., Henning, J.A., Gardea-Torresday, J. & Ray, I.M. 1996. Variation in aphid alarm pheromone content among glandular and glandular-haired Medicago accessions. Journal of Chemical Ecology 22 (9): 1629-1638., Kant et al. 2004Kant, M.R., Ament, K., Sabelis, M.W., Haring, M.A. & Schuurink, R. C. 2004. Differential timing of spider mite-induced direct and indirect defenses in tomato plants. Plant Physiology 135 (1): 483-495.). However, the presence of caryophyllene, even in low proportions, is ecologically important because it is key volatile compound involved in the attraction of predators, such as parasitoid wasps (Dawson et al. 1984Dawson, G.W., Griffiths, D.C., Pickett, J.A., Smith, M.C. & Woodcock, C.M. 1984. Natural inhibition of the aphid alarm pheromone. Entomologia experimentalis et Applicata, 36(2), 197-199., Dudareva et al. 2013Dudareva, N., Klempien, A., Muhlemann, J.K. & Kaplan, I. 2013. Biosynthesis, function, and metabolic engineering of plant volatile organic compounds. New Phytologist 198(1): 16-32.). In our study, the inducible volatiles α-farnesene and caryophyllene as well as MeSa and 3-carene were detected after 4 days of infestations, whereas similar concentrations have been found in tomate, beans and maize at 24 hours or less (Bernasconi et al. 1998Bernasconi, M.L., Turlings, T. C., Ambrosetti, L., Bassetti, P. & DornS. 1998. Herbivore‐induced emissions of maize volatiles repel the corn leaf aphid, Rhopalosiphum maidis. Entomologia Experimentalis et Applicata 87 (2): 133-142., Borges et al. 2018Borges, E.D.O., Martins, C.B., da Silva, R.R. & Zarbin, P.H. 2018. Terpenoids dominate the bouquet of volatile organic compounds produced by Passiflora edulis in response to herbivory by Heliconius erato phyllis (Lepidoptera: Nymphalidae). Arthropod-Plant Interactions 12 (1): 123-131.). Our results suggest that ecological interaction in C. floribundus requires more time to occur than in crop plants, in which the VOC induction often happens in the hourly infestation, acting on insect repellency, influencing oviposition and mediating the direct and indirect defenses of plants. So, these observations have important implications for understanding plant responses to herbivory attack in native species present in urban environments; in which abiotic and biotic stress act simultaneously.

Acknowledgements

We thank Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP, 12/11663-8 and 16/25109-3), for financial support. Débora Pinheiro-Oliveira and Giselle da Silva Pedrosa thank Coordenação de Aperfeiçoamento de Pessoal de Nível Superior/ Conselho Nacional de Desenvolvimento Científico e Tecnológico, for Master scholarships and Silvia Ribeiro de Souza thanks Conselho Nacional de Desenvolvimento Científico e Tecnológico, for research grant 305395/2019-0.

Literature cited

Adams, R.P. 2007. Identification of essential oil components by gas chromatography/mass spectrometry. 4th ed. Carol Stream, IL: Allured publishing corporation.
Arimura, G.I., Tashiro, K., Kuhara, S., Nishioka, T., Ozawa, R. & Takabayashi J. 2000. Gene responses in bean leaves induced by herbivory and by herbivore-induced volatiles. Biochemical and Biophysical Research Communications 277 (2): 305-310.
Baldwin, I.T., Halitschke, R., Paschold, A., Von Dahl C.C. & Preston C.A. 2006. Volatile signaling in plant-plant interactions:" talking trees" in the genomics era. Science 311 (5762): 812-815.
Bernasconi, M.L., Turlings, T. C., Ambrosetti, L., Bassetti, P. & DornS. 1998. Herbivore‐induced emissions of maize volatiles repel the corn leaf aphid, Rhopalosiphum maidis Entomologia Experimentalis et Applicata 87 (2): 133-142.
Bernasconi, M.L., Turlings, T. C., Ambrosetti, L., Bassetti, P. & Dorn, S. 1998. Herbivore‐ induced emissions of maize volatiles repel the corn leaf aphid, Rhopalosiphum maidis. Entomologia Experimentalis et Applicata, 87(2), 133-142.
Birkett, M.A., Campbell, C.A., Chamberlain, K., Guerrieri, E., Hick, A. J., Martin, J.L. & Poppy, G.M. 2000. New roles for cis-jasmone as an insect semiochemical and in plant defense. Proceedings of the National Academy of Sciences 97(16): 9329-9334.
Bolsoni, V.P., Oliveira, D.P.D., Pedrosa, G.D.S. & Souza, S.R. 2018. Volatile organic compounds (VOC) variation in Croton floribundus (L.) Spreng. related to environmental conditions and ozone concentration in an urban forest of the city of São Paulo, São Paulo State, Brazil. Hoehnea 45 (2): 184-191.
Borges, E.D.O., Martins, C.B., da Silva, R.R. & Zarbin, P.H. 2018. Terpenoids dominate the bouquet of volatile organic compounds produced by Passiflora edulis in response to herbivory by Heliconius erato phyllis (Lepidoptera: Nymphalidae). Arthropod-Plant Interactions 12 (1): 123-131.
Bruinsma, M., Posthumus, M.A., Mumm, R., Mueller, M.J., Van Loon, J.J. & Dicke, M. 2009. Jasmonic acid-induced volatiles of Brassica oleracea attract parasitoids: effects of time and dose, and comparison with induction by herbivores. Journal of Experimental Botany 60 (9): 2575-2587.
Cardoso-Gustavson, P., Bolsoni, V.P., de Oliveira, D.P., Guaratini, M.T.G., Aidar, M.P.M., Marabesi, M.A., Segala, E. & Souza, S.R. 2014. Ozone-induced responses in Croton floribundus Spreng. (Euphorbiaceae): metabolic cross-talk between volatile organic compounds and calcium oxalate crystal formation. PloS One 9 (8): e105072.
Dawson, G.W., Griffiths, D.C., Pickett, J.A., Smith, M.C. & Woodcock, C.M. 1984. Natural inhibition of the aphid alarm pheromone. Entomologia experimentalis et Applicata, 36(2), 197-199.
Dicke, M. 1999. Are herbivore-induced plant volatiles reliable indicators of herbivore identity to foraging carnivorous arthropods? In Proceedings of the 10th International Symposium on Insect-Plant Relationships 91: 131-142.
Dicke, M., Takabayashi, J., Posthumus, M.A., Schütte, C. & Krips, O.E. 1998. Plant-Phytoseiid interactions mediated by herbivore-induced plant volatiles: variation in production of cues and in responses of predatory mites. Experimental and Applied Acarology 22(6): 311-333.
Dicke, M., Sabelis, M.W., Takabayashi, J., Bruin, J. & Posthumus, M.A. 1990. Plant strategies of manipulating predatorprey interactions through allelochemicals: prospects for application in pest control. Journal of Chemical Ecology, 16(11): 3091-3118.
Dudareva, N., Klempien, A., Muhlemann, J.K. & Kaplan, I. 2013. Biosynthesis, function, and metabolic engineering of plant volatile organic compounds. New Phytologist 198(1): 16-32.
Fäldt, J., Martin, D., Miller, B., Rawat, S. & Bohlmann, J. 2003. Traumatic resin defense in Norway spruce (Picea abies): methyl jasmonate-induced terpene synthase gene expression, and cDNA cloning and functional characterization of (+)-3-carene synthase. Plant Molecular Biology 51(1): 119-133.
Fürstenberg-Hägg, J., Zagrobelny, M. & Bak, S. 2013. Plant defense against insect herbivores. International Journal of Molecular Sciences 14(5): 10242-10297.
Himanen, S.J., Blande, J.D., Klemola, T., Pulkkinen, J., Heijari, J. & Holopainen, J.K. 2010. Birch (Betula spp.) leaves adsorb and re‐release volatiles specific to neighboring plants-a mechanism for associational herbivore resistance? New Phytologist 186 (3): 722-732.
Holopainen, J.K. & Blande, J.D. 2013. Where do herbivore-induced plant volatiles go? Frontiers in Plant Science 4: 180-185.
Holopainen, J.K. 2004. Multiple functions of inducible plant volatiles. Trends in Plant Science 9 (11): 529-533.
Kant, M.R., Ament, K., Sabelis, M.W., Haring, M.A. & Schuurink, R. C. 2004. Differential timing of spider mite-induced direct and indirect defenses in tomato plants. Plant Physiology 135 (1): 483-495.
Kant, M.R., Bleeker, P.M., Van Wijk, M., Schuurink, R.C. & Haring, M.A. 2009. Plant volatiles in defense. Advances in Botanical Research 51: 613-666.
Kigathi, R.N., Unsicker, S.B., Reichelt, M., Kesselmeier, J., Gershenzon, J. & Weisser, W.W. 2009. Emission of volatile organic compounds after herbivory from Trifolium pratense (L.) under laboratory and field conditions. Journal of chemical ecology 35(11): 1335.
Maffei, M.E. 2010. Sites of synthesis, biochemistry and functional role of plant volatiles. South African Journal of Botany 76 (4): 612-631.
Mostafavi, R., Henning, J.A., Gardea-Torresday, J. & Ray, I.M. 1996. Variation in aphid alarm pheromone content among glandular and glandular-haired Medicago accessions. Journal of Chemical Ecology 22 (9): 1629-1638.
Moura, B.B., Alves, E.S., Marabesi, M.A., Souza, S.R., Schaub, M. & Vollenweider, P. 2018. Ozone affects leaf physiology and causes injury to foliage of native tree species from the tropical Atlantic Forest of southern Brazil. Science of The Total Environment 610: 912-925.
Moura, B.B. , Bolsoni, V.P., Paula, M.D., Dias, G.M & Souza, S.R. 2022. Ozone impact on the emission of Biogenic Volatile Organic Compounds (BVOCs) in tropical tree species. Frontiers in Plant Science, V. 13: p. 87039.
Niinemets, Ü., Kännaste, A. & Copolovici, L. 2013. Quantitative patterns between plant volatile emissions induced by biotic stresses and the degree of damage. Frontiers in Plant Science 4: 262.
Pareja, M. & Pinto-Zevallos, D.M. 2016. Impacts of Induction of Plant Volatiles by Individual and Multiple Stresses Across Trophic Levels. In: Deciphering Chemical Language of Plant Communication: 61-93.
Pinto, D.M., Blande, J., Souza, S.R., Nerg, A. & Holopainen, J.K. 2010. Plant volatile organic compound (VOCs) in ozone polluted atmospheres: The ecological Effects. Journal of Chemical Ecology 36 (1): 22-24.
Pinto-Zevallos, D.M., Martins, C.B., Pellegrino, A.C. & Zarbin, P.H. 2013. Compostos orgânicos voláteis na defesa induzida das plantas contra insetos herbívoros. Quim Nova 36 (9): 1395-1405.
Souza, S.R., Blande, J.D. & Holopainen, J.K. 2013. Pre-exposure to nitric oxide modulates the effect of ozone on oxidative defenses and volatile emissions in lima bean. Environmental Pollution 179: 111-119.
Takabayashi, J., Dicke, M. & Posthumus, M.A. 1991. Variation in composition of predator-attracting allelochemicals emitted by herbivore-infested plants: relative influence of plant and herbivore. Chemoecology 2 (1): 1-6.
Van Den Boom, C.E., Van Beek, T.A., Posthumus, M.A., De Groot, A. & Dicke, M. 2004. Qualitative and quantitative variation among volatile profiles induced by Tetranychus urticae feeding on plants from various families. Journal of Chemical Ecology 30(1): 69-89.
Zakir, A., Bengtsson, M., Sadek, M.M., Hansson, B.S., Witzgall, P. & Anderson, P. 2013. Specific response to herbivore-induced de novo synthesized plant volatiles provides reliable information for host plant selection in a moth. Journal of Experimental Biology 216 (17): 3257-3263.

1.
Part of the first author's Master Dissertation - Vegetal Biodivesity and Environmental Science Program

Author Contributions

Débora Pinheiro-Oliveira: Conceived and designed the experiments; performed the experiments; analysed the data; wrote the paper. Silvia Ribeiro de Souza: Conceived and designed the experiments; analysed the data; wrote the paper. Giselle da Silva Pedrosa: Performed the experiments.
Preprint:

https://doi.org/10.1590/2236-8906-18/2022

Edited by

Editor Associado:

Adriana de Oliveira Fidalgo

Publication Dates

Publication in this collection
13 Nov 2023
Date of issue
2023

History

Received
16 May 2022
Accepted
11 Jan 2023
Preprint posted on
10 Feb 2023

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

[1] Adams, R.P. 2007. Identification of essential oil components by gas chromatography/mass spectrometry. 4th ed. Carol Stream, IL: Allured publishing corporation.

[2] Arimura, G.I., Tashiro, K., Kuhara, S., Nishioka, T., Ozawa, R. & Takabayashi J. 2000. Gene responses in bean leaves induced by herbivory and by herbivore-induced volatiles. Biochemical and Biophysical Research Communications 277 (2): 305-310.

[3] Baldwin, I.T., Halitschke, R., Paschold, A., Von Dahl C.C. & Preston C.A. 2006. Volatile signaling in plant-plant interactions:" talking trees" in the genomics era. Science 311 (5762): 812-815.

[4] Bernasconi, M.L., Turlings, T. C., Ambrosetti, L., Bassetti, P. & DornS. 1998. Herbivore‐induced emissions of maize volatiles repel the corn leaf aphid, Rhopalosiphum maidis Entomologia Experimentalis et Applicata 87 (2): 133-142.

[5] Bernasconi, M.L., Turlings, T. C., Ambrosetti, L., Bassetti, P. & Dorn, S. 1998. Herbivore‐ induced emissions of maize volatiles repel the corn leaf aphid, Rhopalosiphum maidis. Entomologia Experimentalis et Applicata, 87(2), 133-142.

[6] Birkett, M.A., Campbell, C.A., Chamberlain, K., Guerrieri, E., Hick, A. J., Martin, J.L. & Poppy, G.M. 2000. New roles for cis-jasmone as an insect semiochemical and in plant defense. Proceedings of the National Academy of Sciences 97(16): 9329-9334.

[7] Bolsoni, V.P., Oliveira, D.P.D., Pedrosa, G.D.S. & Souza, S.R. 2018. Volatile organic compounds (VOC) variation in Croton floribundus (L.) Spreng. related to environmental conditions and ozone concentration in an urban forest of the city of São Paulo, São Paulo State, Brazil. Hoehnea 45 (2): 184-191.

[8] Borges, E.D.O., Martins, C.B., da Silva, R.R. & Zarbin, P.H. 2018. Terpenoids dominate the bouquet of volatile organic compounds produced by Passiflora edulis in response to herbivory by Heliconius erato phyllis (Lepidoptera: Nymphalidae). Arthropod-Plant Interactions 12 (1): 123-131.

[9] Bruinsma, M., Posthumus, M.A., Mumm, R., Mueller, M.J., Van Loon, J.J. & Dicke, M. 2009. Jasmonic acid-induced volatiles of Brassica oleracea attract parasitoids: effects of time and dose, and comparison with induction by herbivores. Journal of Experimental Botany 60 (9): 2575-2587.

[10] Cardoso-Gustavson, P., Bolsoni, V.P., de Oliveira, D.P., Guaratini, M.T.G., Aidar, M.P.M., Marabesi, M.A., Segala, E. & Souza, S.R. 2014. Ozone-induced responses in Croton floribundus Spreng. (Euphorbiaceae): metabolic cross-talk between volatile organic compounds and calcium oxalate crystal formation. PloS One 9 (8): e105072.

[11] Dawson, G.W., Griffiths, D.C., Pickett, J.A., Smith, M.C. & Woodcock, C.M. 1984. Natural inhibition of the aphid alarm pheromone. Entomologia experimentalis et Applicata, 36(2), 197-199.

[12] Dicke, M. 1999. Are herbivore-induced plant volatiles reliable indicators of herbivore identity to foraging carnivorous arthropods? In Proceedings of the 10th International Symposium on Insect-Plant Relationships 91: 131-142.

[13] Dicke, M., Takabayashi, J., Posthumus, M.A., Schütte, C. & Krips, O.E. 1998. Plant-Phytoseiid interactions mediated by herbivore-induced plant volatiles: variation in production of cues and in responses of predatory mites. Experimental and Applied Acarology 22(6): 311-333.

[14] Dicke, M., Sabelis, M.W., Takabayashi, J., Bruin, J. & Posthumus, M.A. 1990. Plant strategies of manipulating predatorprey interactions through allelochemicals: prospects for application in pest control. Journal of Chemical Ecology, 16(11): 3091-3118.

[15] Dudareva, N., Klempien, A., Muhlemann, J.K. & Kaplan, I. 2013. Biosynthesis, function, and metabolic engineering of plant volatile organic compounds. New Phytologist 198(1): 16-32.

[16] Fäldt, J., Martin, D., Miller, B., Rawat, S. & Bohlmann, J. 2003. Traumatic resin defense in Norway spruce (Picea abies): methyl jasmonate-induced terpene synthase gene expression, and cDNA cloning and functional characterization of (+)-3-carene synthase. Plant Molecular Biology 51(1): 119-133.

[17] Fürstenberg-Hägg, J., Zagrobelny, M. & Bak, S. 2013. Plant defense against insect herbivores. International Journal of Molecular Sciences 14(5): 10242-10297.

[18] Himanen, S.J., Blande, J.D., Klemola, T., Pulkkinen, J., Heijari, J. & Holopainen, J.K. 2010. Birch (Betula spp.) leaves adsorb and re‐release volatiles specific to neighboring plants-a mechanism for associational herbivore resistance? New Phytologist 186 (3): 722-732.

[19] Holopainen, J.K. & Blande, J.D. 2013. Where do herbivore-induced plant volatiles go? Frontiers in Plant Science 4: 180-185.

[20] Holopainen, J.K. 2004. Multiple functions of inducible plant volatiles. Trends in Plant Science 9 (11): 529-533.

[21] Kant, M.R., Ament, K., Sabelis, M.W., Haring, M.A. & Schuurink, R. C. 2004. Differential timing of spider mite-induced direct and indirect defenses in tomato plants. Plant Physiology 135 (1): 483-495.

[22] Kant, M.R., Bleeker, P.M., Van Wijk, M., Schuurink, R.C. & Haring, M.A. 2009. Plant volatiles in defense. Advances in Botanical Research 51: 613-666.

[23] Kigathi, R.N., Unsicker, S.B., Reichelt, M., Kesselmeier, J., Gershenzon, J. & Weisser, W.W. 2009. Emission of volatile organic compounds after herbivory from Trifolium pratense (L.) under laboratory and field conditions. Journal of chemical ecology 35(11): 1335.

[24] Maffei, M.E. 2010. Sites of synthesis, biochemistry and functional role of plant volatiles. South African Journal of Botany 76 (4): 612-631.

[25] Mostafavi, R., Henning, J.A., Gardea-Torresday, J. & Ray, I.M. 1996. Variation in aphid alarm pheromone content among glandular and glandular-haired Medicago accessions. Journal of Chemical Ecology 22 (9): 1629-1638.

[26] Moura, B.B., Alves, E.S., Marabesi, M.A., Souza, S.R., Schaub, M. & Vollenweider, P. 2018. Ozone affects leaf physiology and causes injury to foliage of native tree species from the tropical Atlantic Forest of southern Brazil. Science of The Total Environment 610: 912-925.

[27] Moura, B.B. , Bolsoni, V.P., Paula, M.D., Dias, G.M & Souza, S.R. 2022. Ozone impact on the emission of Biogenic Volatile Organic Compounds (BVOCs) in tropical tree species. Frontiers in Plant Science, V. 13: p. 87039.

[28] Niinemets, Ü., Kännaste, A. & Copolovici, L. 2013. Quantitative patterns between plant volatile emissions induced by biotic stresses and the degree of damage. Frontiers in Plant Science 4: 262.

[29] Pareja, M. & Pinto-Zevallos, D.M. 2016. Impacts of Induction of Plant Volatiles by Individual and Multiple Stresses Across Trophic Levels. In: Deciphering Chemical Language of Plant Communication: 61-93.

[30] Pinto, D.M., Blande, J., Souza, S.R., Nerg, A. & Holopainen, J.K. 2010. Plant volatile organic compound (VOCs) in ozone polluted atmospheres: The ecological Effects. Journal of Chemical Ecology 36 (1): 22-24.

[31] Pinto-Zevallos, D.M., Martins, C.B., Pellegrino, A.C. & Zarbin, P.H. 2013. Compostos orgânicos voláteis na defesa induzida das plantas contra insetos herbívoros. Quim Nova 36 (9): 1395-1405.

[32] Souza, S.R., Blande, J.D. & Holopainen, J.K. 2013. Pre-exposure to nitric oxide modulates the effect of ozone on oxidative defenses and volatile emissions in lima bean. Environmental Pollution 179: 111-119.

[33] Takabayashi, J., Dicke, M. & Posthumus, M.A. 1991. Variation in composition of predator-attracting allelochemicals emitted by herbivore-infested plants: relative influence of plant and herbivore. Chemoecology 2 (1): 1-6.

[34] Van Den Boom, C.E., Van Beek, T.A., Posthumus, M.A., De Groot, A. & Dicke, M. 2004. Qualitative and quantitative variation among volatile profiles induced by Tetranychus urticae feeding on plants from various families. Journal of Chemical Ecology 30(1): 69-89.

[35] Zakir, A., Bengtsson, M., Sadek, M.M., Hansson, B.S., Witzgall, P. & Anderson, P. 2013. Specific response to herbivore-induced de novo synthesized plant volatiles provides reliable information for host plant selection in a moth. Journal of Experimental Biology 216 (17): 3257-3263.

Identified compounds	Treatment
	Control				Herbivory
	0 hour	2 hours	6 hours	24 hours	0 hour	2 hours	6 hours	24 hours
Monoterpenes (C10)
α-Pinene	-	0.7±1.2	-	0.4±0.5	-	-	-	-
β-Phellandrene	3.7±3.7	-	3.2±5.5	-	-	-	-	-
D-Limonene	-	-	-	2.5±2.9	-	-	-	-
3-Carene	-	-	-	-	-	-	-	0.3±0.5
Linalool	-	24.1±20.9	8.1±11.6	20.1±10.8	-	-	2.9±3.1	0.4±0.7
Geranyl acetone	5.1±8.9	-	1.4±2.4	-	0.2±0.3	0.2±0.3	-	-
Sesquiterpenes (C15)
α-Cubebene	-	0.2±0.4	0.2±0.4	-	-	0.2±0.5	-	0.2±0.4
α -Copaene	1.7±2.9	1.9±2.8	-	1.8±1.8	0.3±0.5	-	-	6.0±10.4
β-copaene	11.3±10.1	1.1±1.9	0.5±0.9	2.2±2.2	-	-	-	0.8±1.3
(E)-β-Famesene	2.4±4.1	12.8±12.6	-	-	-	-	-	21.7±33.6
(-)-β-Bourbonene	7.9±7.2	13.5±10.7	1.2±2.2	5.8±4.0	3.6±6.3	0.5±0.4	1.1±2.0	0.3±0.6
Caryophyllene	6.5±6.4	13.1±19.2	0.9±1.6	6.1±6.3	1.4±2.5	-	0.2±0.4	1.5±1.5
γ-Elemene	-	1.9±3.3	-	-	-	-	-	-
α-Farnesene	6.2±9.9	15.6±20.4	2.0±2.2	2.0±2.4	-	-	0.1±0.3	3.4±3.5
Green Leaf Volatiles
2-Hexenal	-	-	-	-	-	-	-	-
3-Hexenal	-	0.1±0.3	-	-	-	-	-	-
3-Hexen-1-ol	4.2±5.3	7.8±9.0	8.9±13.9	10.0±7.9*	0.5±0.4	-	7.0±6.5	0.6±0.9*
n valeric acid	3.0±5.2	4.6±8.0	-	3.4±3.9	0.1±0.2	-	1.7±2.1	0.2±0.5
3-Hexen-1-ol benzoate	6.0±5.2	13.5±17.0	-	-	-	-	-	2.2±2.0
Other Compounds
Nonanal	10.5±10.6	7.4±1.3	10.9±4.3	17.9±12.2	-	0.1±0.1	9.2±9.9	6.8±6.1
Decanal	19.2±12.3	9.8±8.7	23.6±7.0	26.±19.7	0.4±0.3	0.2±0.2	26.0±27.2	9.2±11.7
Methyl salicylate	44.9±66.7	34.3±36.5	22.8±23.4*	40.9±43.1*	0.3±0.5*	-	65.1±99.9*	141.0±90.2*
Nerolidyl acetate	-	3.2±5.6	-	-	-	-	-	-
Sum	133.0±159.1	479.4±504.7	84.2±75.8	140.1±124.5	7.0±11.3	1.5±1.8	113.7±151.7	68.2±84.4

Identified compounds	Treatment
	Control					Herbivory
	4 days	5 days	6 days	7 days	9 days	4 days	5 days	6 days	7 days	9 days
Monoterpenes (C10)
α-Pinene	-	-	5.6 ± 4.78	-	-	6.88 ± 10.36	8.28 ± 8.28	0.26 ± 0.55	0.37 ± 0.92	0.49 ± 1.05
α-Phellandrene	0.45 ± 0.64	3.86 ± 5.47	6.7 ± 9.47	0.26 ± 0.36	-	-	-	0.32 ± 1.02	0.17 ± 0.28	0.16 ± 0.52
D-Limonene	-	-	14.1 ± 3.21	-	-	0.55 ± 1.11	-	0.86 ± 1.93	-	-
3-Carene	32.69 ± 4.5	37.84 ± 41.2	9.33 ± 0.76	8.17 ± 1.21	6.3 ± 3.36	197.68 ± 80.09*	240.48 ± 106.9*	66.09 ± 57.2*	52.32 ± 51.9*	62.04 ± 53.4*
Linalool	13.53 ± 19.14	5.76 ± 4.21	8.07 ± 4.78	2.52 ± 3.56	4.68 ± 6.62	9.04 ± 8.25	16.77 ± 11.49	3.8 ± 3.02	3.76 ± 4.19	3.54 ± 2.44
Geranylacetone	2.48 ± 3.51	4.29 ± 1.67	10.1 ± 2.47	3.32 ± 0.17	9.1 ± 7.73	2.99 ± 2.02	4.39 ± 1.43	2.77 ± 1.87	2.8 ± 2.23	2.52 ± 1.86
Sesquiterpenes (C15)
α-Cubebene	-	-	1.12 ± 1.59	-	-	-	-	1.4 ± 4.43	1.1 ± 2.71	0.45 ± 1.44
α-Copaene	5.37 ± 3.78	5.12 ± 0.53	7.84 ± 2.26	3.31 ± 0.96	4.85 ± 6.86	5.72 ± 1.33	7.41 ± 2.94	19.51 ± 50.19	14.7 ± 32.74	9.07 ± 21.28
(-)-β-Bourbonene	1.24 ± 1.76	3.38 ± 0.14	-	-	-	0.47 ± 0.94	0.88 ± 1.76	0.3 ± 0.96	-	-
Caryophyllene	12.47 ± 8.22	9.45 ± 0.55	10.37 ± 0.82	6.05 ± 3.43	9.38 ± 6.26	24.18 ± 3.52	28.16 ± 5.02	13.46 ± 6.33	8.82 ± 6.1	10.16 ± 4.76
γ-Elemene	5.87 ± 8.31	-	3.9 ± 5.52	1.09 ± 1.54	5.98 ± 6.19	5.55 ± 11.11	7.45 ± 10.5	6.36 ± 4.81	7.02 ± 4.8	6.59 ± 3.74
α-Farnesene	1.99 ± 2.81	2.07 ± 2.92	-	-	-	124.79 ± 52.9*	81.49 ± 47.2*	9.56 ± 17.45	1.35 ± 3.32	5.2 ± 6.95
Green Leaf Volatiles
3-Hexenal	5.89 ± 8.33	1.77 ± 2.51	9.86 ± 1.26	-	10.81 ± 11.1	1.68 ± 2.28*	0.66 ± 1.32*	3.1 ± 5.82*	0.53 ± 1.31*	2.92 ± 4.2*
2-Hexenal	-	-	-	-	1.94 ± 2.74	-	-	-	-	0.45 ± 0.99
3-Hexen-1-ol	35.73 ± 57.92	22.6 ± 21.5	46.38 ± 45.3	4.25 ± 0.33	39.75 ± 34.77	8.71 ± 6.55*	22.98 ± 19.71	19.65 ± 38.86	2.89 ± 4.85	30.16 ± 33.5
Valeric acid	4.63 ± 6.56	-	2.21 ± 3.12	-	1.2 ± 1.69	5.56 ± 7.92	9.42 ± 9.63	3.83 ± 6.46	0.29 ± 0.72	15.45 ± 27.13
3-Hexen-1-ol. benzoate	2.84 ± 4.02	3.16 ± 4.47	1.7 ± 2.4	-	1.69 ± 2.39	13.42 ± 4.31*	18.27 ± 22.45	7.25 ± 10.08	0.81 ± 1.99	5.7 ± 6.78
Other compounds
Nerolidyl acetate	4.59 ± 6.49	2.16 ± 3.06	2.36 ± 3.34	-	3.78 ± 2.20	6.25 ± 1.27	4.58 ± 3.17	4.78 ± 3.74	3.44 ± 3.04	3.24 ± 2.59
Nerolydol	9.52 ± 13.46	5.02 ± 4.01	2.35 ± 3.33	1.13 ± 1.6	1.58 ± 2.24	17.56 ± 5.13	25.77 ± 24. 85	4.48 ± 5.24	2.21 ± 4.56	3.01 ± 3.65
Methyl salicylate	32.57 ± 27.04	23.46 ± 3.89	36.64 ± 10.53	10.9 ± 0.49	6.87 ± 1.71	123.41 ± 75.5*	111.78 ± 59.1*	78.87 ± 81.9*	37.99 ± 47.6*	41.09 ± 27.2*
Methyl jasmonate	-	3.98 ± 2.03	2.36 ± 3.34	-	-	3.46 ± 4.49	-	-	26.85 ± 65.77	-
Nonanal	6.17 ± 2.92	9.52 ± 2.62	15.15 ± 6.06	4.39 ± 0.91	9.1 ± 6.34	4.4 ± 1.2*	4.1 ± 1.64*	4,05 ± 1.81*	2.77 ± 1.17*	2.92 ± 0.83*
Decanal	6.43 ± 1.23	10.87 ± 2.35	14.62 ± 5.87	5.48 ± 0.06	12.12 ± 8.38	6.11 ± 1.43	5.75 ± 1.47	5.14 ± 2.17	4.05 ± 2.04	4.06 ± 1.15
Sum of compounds	264.46± 288.78	154.31± 140.18	210.76± 161.22	50.87± 33.46	129.13± 123.21	568.41± 363.92	598.62± 400.67	255.84± 308.22	174.24± 195.37	209.22± 205.7

Brasil

Brasil

**Differential timing response of Herbivory-Induced Volatiles (HIPVs) in Croton floribundus Spreng. (Euphorbiaceae)** ¹ 1. Part of the first author's Master Dissertation - Vegetal Biodivesity and Environmental Science Program

Resposta temporal diferencial de voláteis induzidos por herbivoria (HIPVs) em Croton floribundus Spreng. (Euphorbiaceae)

ABSTRACT

RESUMO

Introduction

Material and methods

Results

Discussion

Acknowledgements

Literature cited

Author Contributions

Preprint:

Edited by

Editor Associado:

Publication Dates

History

Brasil

Brasil

Differential timing response of Herbivory-Induced Volatiles (HIPVs) in Croton floribundus Spreng. (Euphorbiaceae) 1 1. Part of the first author's Master Dissertation - Vegetal Biodivesity and Environmental Science Program

Resposta temporal diferencial de voláteis induzidos por herbivoria (HIPVs) em Croton floribundus Spreng. (Euphorbiaceae)

ABSTRACT

RESUMO

Introduction

Material and methods

Results

Discussion

Acknowledgements

Literature cited

Author Contributions

Preprint:

Edited by

Editor Associado:

Publication Dates

History

**Differential timing response of Herbivory-Induced Volatiles (HIPVs) in Croton floribundus Spreng. (Euphorbiaceae)** ¹ 1. Part of the first author's Master Dissertation - Vegetal Biodivesity and Environmental Science Program