Hostname: page-component-78c5997874-lj6df Total loading time: 0 Render date: 2024-11-10T07:09:11.612Z Has data issue: false hasContentIssue false

Herbicidal Activity of Monoterpenes Is Associated with Disruption of Microtubule Functionality and Membrane Integrity

Published online by Cambridge University Press:  04 November 2016

David Chaimovitsh
Affiliation:
Unit of Medicinal and Aromatic Plants, ARO, Newe Ya’ar, P.O. Box 1021, Ramat Yishay 30095, Israel R. H. Smith Institute of Plant Sciences in Agriculture, Faculty of Agriculture, Food and Environment, Hebrew University of Jerusalem, Rehovot 76100, Israel
Alona Shachter
Affiliation:
Unit of Medicinal and Aromatic Plants, ARO, Newe Ya’ar, P.O. Box 1021, Ramat Yishay 30095, Israel
Mohamad Abu-Abied
Affiliation:
Institute of Plant Sciences, ARO, Volcani Center, P.O. Box 6, Bet-Dagan 50250, Israel
Baruch Rubin
Affiliation:
R. H. Smith Institute of Plant Sciences in Agriculture, Faculty of Agriculture, Food and Environment, Hebrew University of Jerusalem, Rehovot 76100, Israel
Einat Sadot
Affiliation:
Institute of Plant Sciences, ARO, Volcani Center, P.O. Box 6, Bet-Dagan 50250, Israel
Nativ Dudai*
Affiliation:
Unit of Medicinal and Aromatic Plants, ARO, Newe Ya’ar, P.O. Box 1021, Ramat Yishay 30095, Israel
*
*Corresponding author’s E-mail: nativdud@gmail.com
Rights & Permissions [Opens in a new window]

Abstract

Aromatic plants and their volatile compounds affect seed germination and plant growth, and therefore hold potential for agriculture uses as plant growth regulators and bioherbicides. In the present study 17 major monoterpenes were selected, and their mechanisms of plant toxicity were elucidated using transgenic Arabidopsis thaliana at various growth stages. Microtubulin and the plant cell membrane were identified as the focal targets through which phytotoxicity and herbicidal activity acted. Variability in monoterpene mechanisms was observed. Limonene and (+)-citronellal had strong antimicrotubule efficacy, whereas citral, geraniol, (−)-menthone, (+)-carvone, and (−)-citronellal demonstrated moderate antimicrotubule efficacy. Pulegone, (−)-carvone, carvacrol, nerol, geranic acid, (+)/(−)-citronellol, and citronellic acid lacked antimicrotubule capacity. An enantioselective disruption of microtubule assembly was recorded for (+)/(−)-citronellal and (+)/(−)-carvone. The (+) enatiomers were more potent than their (−) counterparts. Citral, limonene, carvacrol, and pulegone were also tested for phytotoxicity and herbicidal activity. Pulegone had no detectable effect on microtubules or membranes. Citral disrupted microtubules but did not cause membrane damage. Carvacrol lacked a detectable effect on microtubules but incited membrane leakage, and limonene disrupted microtubules and membrane leakage. Therefore, only limonene was herbicidal at the tested concentrations. In planta quantification of residues revealed that citral was biotransformed into nerol and geraniol, and limonene was converted into carvacrol, which could explain its dual capacity with respect to microtubules and membrane functionality. The results obtained are an important added value to commercial efforts in selecting appropriate aromatic plants to be sources of bioherbicidal compounds for sustainable weed management with a limited potential for herbicide resistance evolution in weed populations.

Type
Physiology/Chemistry/Biochemistry
Copyright
© Weed Science Society of America, 2016 

Weeds are among the major causes of crop yield loss together with pests and diseases (Dayan and Duke Reference Dayan and Duke2014; Pimentel et al. Reference Pimentel, Zuniga and Morrison2005). In commercial production, weeds compete with the crop, reducing its growth rate and productivity. Hence, weed control is an essential practice to limit the negative effects on crop production (Berchielli-Robertson et al. Reference Berchielli-Robertson, Gilliam and Fare1990). Various approaches to alternative weed control are available, such as sanitation of plant material and seeds, use of mulch, solarization, hand weeding, heat, use of acids or soaps, etc. (Chappell et al. Reference Chappell, Knox and Stamps2012). However, regardless of the alternatives, commercial production still relies heavily on herbicides with synthetic chemistries. These encompass 91.9% of the new active ingredients registered, whereas 8.1% are synthetic active ingredients derived from natural sources (Cantrell et al. Reference Cantrell, Dayan and Duke2012).

The intensive use of synthetic herbicides poses two major challenges in relation to public health, environmental damage (Narwal Reference Narwal1999), and the development of weeds resistant to the currently used chemistries (Dayan et al. Reference Dayan, Owens and Duke2012). Grana et al. (Reference Grana, Diaz-Tielas, Sanchez- Moreiras and Reigosa2012) pointed out environmental concerns, such as interruption of ecological equilibrium, negative influence on human health, and increased incidence of weeds developing resistance. Research has indicated increased risk of cancer and Parkinson’s disease following exposure to herbicides (Gorrel et al. Reference Gorell, Johnson, Rybicki, Peterson and Richardson1998; Kettles et al. Reference Kettles, Browning, Prince and Horstman1997; Kogevinas et al. Reference Kogevinas, Becher, Benn, Bertazzi, Boffetta, Bueno-de-Mesquita, Coggon, Colin, Flesch-Janys, Fingerhut, Green, Kauppinen, Littorin, Lynge, Mathews, Neuberger, Pearce and Saracci1997); and Dayan et al. (Reference Dayan, Owens and Duke2012) indicated that in the last 20 yr herbicides with mechanisms of action for new target sites have not been commercialized, which consistently increases the risk for resistance developing in weed populations. Therefore, there is a considerable need for new chemistries with innovative mechanisms of action.

The public concern with the possible undesirable effects of synthetic herbicides on human health and the environment calls for the use of ecofriendly chemistries. Currently, only 7% of the commercialized chemistries approved by the U.S. Environmental Protection Agency (EPA) are natural bioherbicides (Cantrell et al. Reference Cantrell, Dayan and Duke2012; Dayan and Duke Reference Dayan and Duke2014), indicating the limited use of natural compounds as herbicides (Seiber et al. Reference Seiber, Coats, Duke and Gross2014). Aromatic plants have been a commercial source of bioactive compounds for many years (Christaki et al. Reference Christaki, Bonos, Giannenas and Florou-Paneri2012; Gerwick and Sparks Reference Gerwick and Sparks2014; Kala Reference Kala2015). Compounds produced by aromatic plants, in particular essential oils and their monoterpene constituents, possess insecticidal (Isman Reference Isman2000), antimicrobial (Abad Reference Abad, Kasrati, Jamili, Zeroual, M’hamed, Spooner-Hart and Leach2014; Bossele and Juliani 2002), and herbicidal properties (Dudai 1999; Grana 2012, 2013a). In this sense, essential oils and their monoterpene constituents are innovative and ecofriendly chemistries that can potentially be used as bioherbicides.

Essential oils affect plant cells, causing membrane breakage and leakage of macromolecules and induction of oxidative stress by lipophilic compounds (Abrahim et al. Reference Abrahim, Francischini, Pergo, Kelmer-Bracht and Ishii-Iwamoto2003; Cox et al. Reference Cox, Gustafson, Mann, Markham, Liew, Hartland, Bell, Warmington and Wyllie1988; Di Pasqua et al. Reference Di Pasqua, Betts, Hoskins, Edwards, Eroolini and Mauriello2007; Einhellig Reference Einhellig1986; Lambert et al. Reference Lambert, Skandamis, Coote and Nychas2001; Maffei et al. Reference Maffei, Camusso and Sacco2001; Sikkema et al. Reference Sikkema, De-Bont and Poolman1995; Singh et al. Reference Singh, Batish, Kaur, Arora and Kohli2009a; Zunino and Zygadlo Reference Zunino and Zygadlo2004). Monoterpenes are one of the largest and most important groups of secondary metabolites found in essential oils, and some of them are phytotoxic, making them potential bioherbicides (Abrahim et al. Reference Abrahim, Braguini, Kelmer-Bracht and Ishii-Iwamoto2000; Dudai et al. Reference Dudai, Larkov, Mayer, Poljakoff-Mayber, Putievsky and Lerner2000a). Monoterpenes are inhibitors of seed germination and plant growth (Abrahim et al. Reference Abrahim, Braguini, Kelmer-Bracht and Ishii-Iwamoto2000; Dudai et al. Reference Dudai, Larkov, Mayer, Poljakoff-Mayber, Putievsky and Lerner2000a; Einhellig and Leather Reference Einhellig and Leather1988; Fischer Reference Fischer1986; Gouda et al. Reference Gouda, Saad and Abdelgaleil2016; Grana et al. Reference Grana, Diaz-Tielas, Sanchez- Moreiras and Reigosa2012; Reynolds Reference Reynolds1987; Weidenhamer et al. Reference Weidenhamer, Menelaou, Macias, Fisher, Richardson and Williamson1994). Anatomical and physiological changes have been recorded in plant seedlings as a result of exposure to monoterpenes in both the vapor and aqueous phases (Dudai et al. Reference Dudai, Larkov, Putievsky, Lerner, Ravid, Lewinson and Mayer2000b; Einhellig and Leather Reference Einhellig and Leather1988; Fischer Reference Fischer1986; Grana et al. Reference Grana, Sotelo, Diaz-Tielas, Araniti, Krasuska, Bogatek, Reigosa and Sanchez-Morieiras2013b; Koitabashi et al. Reference Koitabashi, Suzuki, Kawazu, Sakai, Kuroiwa and Kuroiwa1997).

In 2010, Chaimovitsh et al. demonstrated inhibition of plant growth by citral. The mechanism underlying this inhibition involved microtubule disruption without a detectable effect on the actin cytoskeleton. Furthermore, in vivo and in vitro tests demonstrated a harmful effect of citral on cell microtubules that was dose and time dependent yet reversible. Nevertheless, under the experimental conditions used, damage to the plasma membrane was not recorded.

The study was continued in 2012 (Chaimovitsh et al. Reference Chaimovitsh, Rogovoy-Stelmakh, Altshuler, Belausov, Abu-Abied, Rubin, Sadot and Dudai2012) identifying, in wheat seedlings, that the mitotic microtubules were more sensitive to citral than the cortical microtubules. Citral inhibited the cell cycle and increased the frequency of wheat root cells and BY2 cells with asymmetric walls. The findings explained the observed phytotoxic effect of citral, at micromolar concentrations, in seed germination inhibition.

In a continuing effort to understand the phytotoxic and herbicidal potential of citral derivatives, the present study examined the hypothesis that the mechanism of citral derivatives and other related monoterpenes is via interference with the cortical microtubules, F-actin functioning, and membrane integrity.

Materials and Methods

Plant Material Used

Arabidopsis thaliana ecotype Col-0 was used. Seeds of Arabidopsis plants expressing the green fluorescent protein–tubulin α6 (GFP-TUA6) marker were kindly provided by T. Hashimoto (Ueda et al. Reference Ueda, Matsuyama and Hashimmoto1999), and transgenic plants expressing the GFP-mTalin, were generated in the lab with a plasmid kindly provided by N. Chua (Kost et al. Reference Kost, Spielhofer and Chua1998).

Volatile Compounds Used

The following 17 compounds were used in this study to examine their effect on plant tissue: citral, (+)/(−)-citronellal, geraniol, nerol, (+)/(−)-citronellol, citral dimethyl acetal, geranic acid, (+)/(−)-citronellic acid, limonene, menthone, (+)/(−)-carvone, pulegone, and carvacrol. All compounds were examined for their effect on microtubulin in Arabidopsis seedlings (Table 1). Four compounds—limonene, citral, pulegone, and carvacrol—were also tested for their effect on F-actin and membrane integrity in seedlings and for their effect on membrane leakage and phytotoxicity in mature Arabidopsis plants (Table 1). All compounds were purchased from Sigma-Aldrich, Israel.

Table 1 Effect of 17 monoterpenes and citral derivatives on the activity of microtubulin, membrane, and F-actin in Arabidopsis seedlings and on phytotoxicity and plant biomass in mature Arabidopsis plants.

a Low (0.75 µl per 20 ml) and high (1.5 µl per 20 ml) dosages.

b Effect: +, complete; +/−, partial; −, none; nt, not tested.

c Duration (min) of exposure to vapors.

Analysis of Microtubules, F-actin, and Membrane in Seedlings by Confocal Microscopy

In this test, all 17 compounds were examined for their effect on microtubulin, and citral, limonene, pulegone, and carvacrol were also tested for their effect on F-actin and cell membrane (Table 1).

Arabidopsis seeds were sown onto Murashige and Skoog medium, incubated at 4 C in darkness for 4 d, and then transferred to a growth chamber at 24 C under a photoperiod of 16 h light/8 h dark. Then, five 8-d-old seedlings, each weighing approximately 0.05 g (a total of 0.25 g of plant tissue), were transferred into sterile 20 ml scintillation vials and exposed to 0.75 μl (low dose) or 1.5 μl (high dose) of each compound (Table 1) for 30 min at room temperature in darkness.

The applied molar dosages (high and low) of the compounds were as follows: citral: 8.79 M and 4.39 M; (+)/(−)-citronellal: 8.31 M and 4.15 M; geraniol: 8.64 M and 4.32 M; nerol: 8.56 M and 4.28 M; (+)/(−)-citronellol: 8.2 M and 4.1 M, citral dimethyl acetal: 6.73 M and 3.36 M, geranic acid: 8.64 M and 4.32 M, (+)/(−)-citronellic acid: 8.13 M and 4.06 M; limonene: 9.26 M and 4.63 M; menthone: 8.7 M and 4.15 M, (+)/(−)-carvone: 9.58 M and 4.79 M; pulegone: 9.2 M and 4.6 M, and carvacrol: 9.75 M and 4.87 M.

The compounds were separately amended onto Whitman filter paper pieces (1 by 1 cm) that were attached to the inner sides of the vials’ caps. Each vial (20 ml) was hermetically sealed, creating a vapor-rich headspace atmosphere. Following exposure, membranes were stained for 5 min with 8 µM of styryl dye FM4-64 (Bolte et al. Reference Bolte, Talbot, Boutte, Catrice, Read and Satiat-Jeune-Maitre2004) to examine membrane integrity. Microtubules and F-actin were determined by live GFP markers. An IX81/FV500 laser-scanning microscope (Olympus) with a Plan Apo 60×1.00 WLSM ∞/0.17 objective was used to observe fluorescently labeled plant cells. The filter sets used for observation were 488 nm excitation and BA505-525 for GFP and 488 or 515 nm excitation and BA660 for FM4-64.

Effect on Membrane Leakage and Phytotoxicity in Mature Plants

In this experiment, limonene, citral, pulegone, and carvacrol were tested for their disruption of membrane integrity and phytotoxicity to mature plants (Table 1). Arabidopsis plantlets, at the two-leaf stage, were transplanted to 200 ml pots with five plantlets per pot. The soil mixture used was composed of 65% peat TS-1 and 35% vermiculite N-2. The plantlets were grown under short-day conditions (10 h of daylight) in the greenhouse until they reached the 14-leaf stage, when they were transferred to the laboratory to be examined for membrane leakage and phytotoxicity.

In the laboratory, each pot was covered with a 500 ml glass beaker. The tested compounds were each applied to a Whitman’s filter paper that was attached to the inner side of the beaker. The plants were exposed to 18.75 μl (low) or 37.5 μl (high) of monoterpene vapor for 0, 15, 30, and 60 min. The dosages were equivalent to 0.75 μl and 1.5 μl previously used in the 20 ml scintillation vials and were (low/high): 4.6/9.2 μmol per 20 ml for limonene, 4.4/9.2 μmol per 20 ml for citral, 4.8/9.7 μmol per 20 ml for carvacrol, and 4.6/9.3 μmol per 20 ml for pulegone. Plants to be examined for phytotoxicity and biomass were retransferred to the greenhouse and were evaluated 2 wk later.

Membrane-leakage quantification was carried out using plants that were exposed to the monoterpene vapors for 30 min following the protocol by Bernstein et al. (Reference Bernstein, Shoresh, Xu and Huang2010). Immediately after the 30 min exposure to the vapors, the treated plants with the roots removed were placed in sealed 50 ml tubes containing 20 ml double-distilled water. The tubes were shaken at 200 rpm for 60 min at room temperature, and electrical conductivity (EC) was measured before and after autoclaving. Membrane leakage was expressed as the ratio between the two values, as follows: % EC=[(ECf–ECi)/ECi]×100, where ECi=EC measured before autoclaving and ECf=EC measured after autoclaving.

In Planta Analysis of Monoterpene Concentrations

Arabidopsis seedlings exposed to the various monoterpenes in vapor phase were weighed and placed in methyl-tert-butyl ether that contained 10 µg ml−1 iso-butylbenzene as an internal standard. The samples were shaken at room temperature for 24 h as previously described (Dudai et al. Reference Dudai, Chaimovitsh, Larkov, Fisher, Blaicer and Mayer2009; Lewinsohn et al. Reference Lewinsohn, Dudai, Tadmor, Katzir, Ravid, Putievsky and Joel1998). The extract was passed through a small column consisting of a Pasteur pipette containing anhydrous Na2SO4 and salicylic acid (Silicagel 60, 230–400 mesh, Merck) to dry it and to remove high-molecular-weight polar substances that could interfere with the gas chromatography (GC) analysis. The samples were analyzed using a GC/mass spectrometer (HP-GCD apparatus) equipped with an HP5 (30 m, 0.25 mm) fused silica capillary column. Helium was used as the carrier in constant-flow mode at 1 ml min−1. The injection temperature was 250 C, and the detector temperature was 280 C. Column conditions were: 70 C for 2 min followed by a 4 C min−1 increase to 200 C. The components were identified by co-injection with authentic samples and by comparison with mass spectra from the computerized libraries Wiley7N and HP1600. Following extraction, the plants were dried in an oven at 80 C for 48 h and weighed.

Statistical Analysis

All trials were carried out in a completely randomized design with five replications per treatment. Data were explored with one-way analysis of variance (ANOVA) followed by mean separation with Tukey’s HSD. Values are presented as mean±standard deviation.

Results and Discussion

Analysis of Microtubules, F-actin, and Membrane by Confocal Microscopy

Eight- day-old Arabidopsis seedlings expressing the microtubule marker GFP-TUA6 or the actin marker GFP-mTalin were exposed to 10 citral derivatives and 6 monoterpenes and then stained with the membrane marker FM4-64 (Bolte et al. Reference Bolte, Talbot, Boutte, Catrice, Read and Satiat-Jeune-Maitre2004). Table 1 summarizes the degree of microtubule-disrupting activity in Arabidopsis seedlings of the 10 citral derivatives: (+)/(−)-citronellal, geraniol, nerol, (+)/(−)-citronellol, geranic acid, (+)/(−)-citronellic acid, citral dimethyl acetal; and the 6 monoterpenes: limonene, (+)/(−)-carvone, (−)-menthone, pulegone, and carvacrol. Dosages and exposure duration were based on our previous work (Chaimovitsh et al. Reference Chaimovitsh, Abu-Abied, Belausov, Rubin, Dudai and Sadot2010) and were 0.75 μl (low dose) and 1.5 μl (high dose) in 20 ml scintillation vials for 30 min. The compounds limonene, (+)-citronellal, and (+)-carvone completely disrupted plant microtubules at high and low dosages. Citral, (−)-menthone, geraniol, and (−)-citronellal disrupted microtubules completely and partially at the high and low dosages, respectively. On the other hand, (−)-carvone, nerol, (+)/(−)-citronellol, citral dimethyl acetal, geranic acid, (+)/(−)-citronellic acid, pulegone, and carvacrol did not. Of note was the enantioselective activity recorded for carvone and citronellal, where (+)-carvone and (+)-citronellal disrupted microtubules completely at the low and/or high dosages, whereas (−)-carvone had no effect on microtubules, and (−)-citronellal had a dose dependant activity (Table 1).

Citral, limonene, pulegone, and carvacrol were examined further for their effect on microtubules, F-actin, and membrane uniformity. Similar to citral (Chaimovitsh et al. Reference Chaimovitsh, Abu-Abied, Belausov, Rubin, Dudai and Sadot2010), the three monoterpenes lacked anti−F-actin activity (Table 1; Figure 1). Limonene caused breakage of the plasma membrane, whereas citral, pulegone, and carvacrol, did not (Table 1; Figure 1).

Figure 1 The effect of limonene, pulegone, and carvacrol in relation to citral on microtubules, F-actin, and the plasma membrane in Arabidopsis leaf epidermal cells. GFP-TUA6 or GFP-mTalin lines were exposed to the vapors in 20 ml scintillation bottles for 30 min and then stained with FM4-64. Shown are confocal images of the abaxial leaf epidermis.

Effect on Membrane Leakage and Phytotoxicity to Mature Plants

To compare the influence of the four monoterpenes’ vapors on mature plant growth, we examined two dosages of each compound on Arabidopsis plants. Following treatment, the plants were transferred to the greenhouse, and growth was monitored for 2 wk. Only limonene had herbicidal activity (Table 1; Figure 2), initiating with phytotoxic reaction expressed as necrotic and dried leaves and eventual plant death. At the low limonene vapor concentration, a time-response effect was observed. The plants were not damaged by 15 min exposure and were only partially damaged after 30 min exposure. However, after 60 min exposure to limonene vapor the plants died (Table 1; Figure 2A). Exposure to the high limonene vapor concentration (9.2 μmol per 20 ml) caused severe wilting after only 15 min (Table 1; Figure 2B), indicating a strong herbicidal potential. Exposure of Arabidopsis plants to vapors of citral, carvacrol, and pulegone did not lead to significant wilting (Table 1; Figure 2C), suggesting lack of herbicidal potential at these concentrations.

Figure 2 Phytotoxicity of limonene, pulegone, citral, and carvacrol to Arabidopsis plants. Note: the plants were exposed to monoterpene vapors for 0, 15, 30, and 60 min, and the herbicidal potential was examined 14 d postexposure.

The effect on biomass (Table 1; Figure 3) correlated with time and dose responses described in Figure 2. The biomass decreased from 0.29 g plant−1 for the untreated control to less than 0.05 g plant−1 after 60 min of exposure to either the low or the high concentration of limonene (Figure 3A). Exposure to carvacrol, pulegone, or citral did not cause a significant reduction in plant biomass compared with the untreated plants at any of the time settings (Figure 3C, D).

Figure 3 Effect of time and dose on fresh weight (g plant−1) of Arabidopsis plants exposed to limonene (A), carvacrol (B), pulegone (C), and citral (D) at vapor phase for 15, 30, and 60 min. Lowercase letters represent treatments that were significantly different than the control as determined by ANOVA followed by Tukey’s HSD post hoc test.

To determine the influence of limonene, citral, carvacrol, and pulegone on the cell membrane leakage of the mature plants, we used the experimental setup described in Figure 3. Exposure of the plants to limonene at 4.6 μmol per 20 ml (0.75 μl per 20 ml) led to 18.2 and 29.2% leakage after 30 and 60 min exposure, respectively. Exposure to limonene at 9.2 μmol per 20 ml (1.5 μl per 20 ml) led to 43.3 and 49.8% leakage after 30 and 60 min, respectively. Membrane leakage in control untreated plants was only 11.5% (Figure 4A). Exposure of the plants to citral, carvacrol, and pulegone vapors did not incite a significant membrane leakage (Figure 4A, B), except for exposure to the high dose of carvacrol (1.5 μl per 20 ml) for 60 min, which caused 30% leakage (Figure 4B). Interestingly, the plants tolerated this apparently harmful effect, demonstrating a normal appearance after the treatment (Figure 2C).

Figure 4 Effect of citral, carvacrol, pulegone, and limonene on membrane leakage in Arabidopsis plants exposed to (A) low (0.75 μl per 20 ml) and (B) high (1.5 μl per 20 ml) dosages for 15, 30, and 60 min. Lowercase letters represent treatments that were significantly different than the control as determined by ANOVA followed by Tukey’s HSD post hoc test.

In Planta Analysis of Monoterpene Concentrations

Monoterpene residues were quantified in Arabidopsis plants using the experimental setup described in Figure 2. Treated plants were extracted and analyzed by GC–mass spectrometry to measure the amounts of limonene, carvacrol, pulegone, and citral absorbed by the plants. As reflected in Table 2, a positive correlation was recorded between the residue level in the tissue and the combined compound concentration and exposure duration interaction. In other words, the higher the concentration and the longer the exposure duration were, the higher the residue level detected in the tissue. Of note was the outcome for citral and limonene. Plants that absorbed citral biochemically reduced it to nerol and geraniol; plants that absorbed limonene converted part of it to carvacrol. The levels of carvacrol and pulegone remained stable within the plants (Table 2).

Table 2 Monoterpene residues and their derivatives in Arabidopsis thaliana tissue.

Note: values are mean±standard deviation of five replicated Arabidopsis thaliana plants.

Previous studies conducted by our research team (Chaimovitsh et al. Reference Chaimovitsh, Abu-Abied, Belausov, Rubin, Dudai and Sadot2010, Reference Chaimovitsh, Rogovoy-Stelmakh, Altshuler, Belausov, Abu-Abied, Rubin, Sadot and Dudai2012) shed light on the mode of action of citral. We found that microtubules were the immediate target of citral in plant and animal cells. Microtubules were disrupted in the presence of micromolar concentrations of citral, whereas F-actin and cell membrane remained intact (Chaimovitsh et al. Reference Chaimovitsh, Abu-Abied, Belausov, Rubin, Dudai and Sadot2010). In the present study we provide evidence that only a subset of monoterpenes disrupt microtubules. Furthermore, we confirm our previous observation (Chaimovitsh et al. Reference Chaimovitsh, Abu-Abied, Belausov, Rubin, Dudai and Sadot2010) that citral causes detectable damage to the plasma membrane under the same experimental conditions in which microtubule disruption was observed. Interestingly, plants exposed to citral exhibited cell swelling, inhibition of polar cell growth, zigzagged cell walls, and irregular phragmoplasts, all directly related to microtubule deformation (Grana et al. Reference Grana, Sotelo, Diaz-Tielas, Reigosa and Sanchez-Moreiras2013a).

In the present study 10 derivatives of citral were screened. Some are known allelochemicals, such as geraniol (Martino et al. Reference Martino, Mancini, Rolim de Almeida and De-Feo2010; Zunino and Zygadlo Reference Zunino and Zygadlo2004), citronellol (Martino et al. Reference Martino, Mancini, Rolim de Almeida and De-Feo2010; Singh et al. Reference Singh, Batish, Kaur, Ramezani and Kohli2002), citronellal (Singh et al. Reference Singh, Batish, Kaur, Ramezani and Kohli2002), and citral itself (Dudai et al. Reference Dudai, Poljakoff-Mayber, Mayer, Putievsky and Lerner1999; Martino et al. Reference Martino, Mancini, Rolim de Almeida and De-Feo2010; Sousa et al. Reference Sousa, Silva and Viccini2010). The list also included two different enantiomers of three compounds: (+)/(−)-citronellal, (+)/(−)-citronellol, which are abundant in Java citronella (Cymbopogon winterianus Jowitt) and cymbopogon [Cymbopogon nardus (L.) W. Watson] (Kreis and Mosandl Reference Kreis and Mosandl1994b); and (+)/(−)-citronellic acid, which are abundant in common balm (Melissa officinalis L.) (Kreis and Mosandl Reference Kreis and Mosandl1994a). Other derivatives, such as geraniol and geranic acid, are present in sweet scented geranium (Pelargonium graveolens L’Hér. ex Aiton); nerol is abundant in cymbopogon (Kreis and Mosandl Reference Kreis and Mosandl1994b); and finally, citral dimethyl acetal is an artificial derivative of citral (Sigma-Aldrich catalog no. 7549-37-3).

Six highly active allelochemical monoterpenes were also screened. These included two enantiomers (+)/(−) of carvone (Martino et al. Reference Martino, Mancini, Rolim de Almeida and De-Feo2010; Zunino and Zygadlo Reference Zunino and Zygadlo2004), limonene (Abrahim et al. Reference Abrahim, Braguini, Kelmer-Bracht and Ishii-Iwamoto2000; Martino et al. Reference Martino, Mancini, Rolim de Almeida and De-Feo2010; Singh et al. Reference Singh, Kaur, Mittal, Batish and Kohli2009b), menthone (Maffei et al. Reference Maffei, Camusso and Sacco2001; Martino et al. Reference Martino, Mancini, Rolim de Almeida and De-Feo2010; Mucciarelli et al. Reference Mucciarelli, Camusso, Bertea, Bossi and Maffei2001), pulegone (Dudai et al. Reference Dudai, Poljakoff-Mayber, Mayer, Putievsky and Lerner1999, Reference Dudai, Chaimovitsh, Larkov, Fisher, Blaicer and Mayer2009; Maffei et al. Reference Maffei, Camusso and Sacco2001; Mucciarelli et al. Reference Mucciarelli, Camusso, Bertea, Bossi and Maffei2001), and carvacrol (Dragoeva et al. Reference Dragoeva, Nanova and Kalcheva2008; Dudai et al. Reference Dudai, Poljakoff-Mayber, Mayer, Putievsky and Lerner1999). It was found that in addition to citral, limonene, (+)-citronellal, menthone, geraniol, and (+)-carvone have the ability to disrupt plant microtubules. Based on our results, the monoterpenes examined in this work can be classified into three main groups: (1) monoterpenes with strong antimicrotubule activity, i.e., limonene and (+)-citronellal; (2) monoterpenes with moderate anti-microtubule activity, i.e., citral, geraniol, (−)-menthone, (−)-citronellal, and (+)-carvone; and (3) monoterpenes lacking antimicrotubule activity, i.e., (−)-carvone, nerol, (+)/(−)-citronellol, geranic acid, (+)/(−)-citronellic acid, citral dimethyl acetal, pulegone, and carvacrol.

An enantioselective activity was also recorded for isomers. The (+)-carvone and (+)-citronellal isomers were more potent than their (−)-carvone and (−)-citronellal counterparts in disrupting plant microtubules (Table 1), a finding which is in agreement with Altshuler et al. (Reference Altshuler, Abu-Abied, Chaimovitsh, Shechter, Frucht, Dudai and Sadot2013), who showed enantioselective effects of (+)- and (−)-citronellal in animal and plant microtubules. In that work (Altshuler et al. Reference Altshuler, Abu-Abied, Chaimovitsh, Shechter, Frucht, Dudai and Sadot2013), (+)-citronellal disrupted microtubules, whereas (−)-citronellal at the same concentration did not. Interestingly, positive enantiomers of (+)-α pinene and (+)-β pinene were found to have stronger antimicrobial activity than their (−) counterparts (Rivas da Silva et al. Reference Rivas da Silva, Monteiro Lopes, Barros de Azevedo, Machado Costa, Sales Alviano and Sales Alviano2012). In addition, (+)-limonene and (+)-carvone had stronger activity to different bacteria and dermatophytic fungi than (−)-limonene and (−)-carvone (Aggarwal et al. Reference Aggarwal, Khanuja Ateeque Ahmad, Santha Kumar, Gupta and Kumar2002).

In the present study we focused on four allelochemicals—citral, limonene, carvacrol, and pulegone—which are known as seed-germination inhibitors (Dudai et al. Reference Dudai, Poljakoff-Mayber, Mayer, Putievsky and Lerner1999, Reference Dudai, Chaimovitsh, Larkov, Fisher, Blaicer and Mayer2009). These four monoterpenes had differential modes of action in Arabidopsis plants. Limonene was highly active, with strong microtubule- and membrane-disrupting activity. In contrast, carvacrol exhibited only membrane-disrupting activity that was dependent on long exposure at high concentration. Citral exhibited microtubule- but not membrane-disrupting activity; and pulegone lacked an effect on either microtubules or cell membrane.

Limonene inflicted visible damage on the plants and demonstrated herbicidal activity. Its effect was significantly more visible than that of the three other monoterpenes. Its damage was characterized by a range of symptoms, from phytotoxicity in individual leaves to toxicity in all leaves leading to plant death. At the low dose, limonene’s herbicidal activity was time dependent, while at the high dosage it was herbicidal at all exposure durations. In contrast, citral, carvacrol, and pulegone were nonherbicidal to the plants even at extended exposures to high dosages.

The effect of monoterpenes on biomass and phytotoxicity was examined using mature, 14-d-old Arabidopsis plants. A relationship between phytotoxicity and biomass reduction was observed in the case of limonene. Yet exposure of plants to the high dose of carvacrol did not show any significant biomass differences between exposed and untreated plants, and there were no clear phytotoxicity symptoms. Interestingly, citral, which is a known microtubule-disrupting agent did not incite phytotoxicity or biomass reduction, which was in contrast to its previously described effect on young seedlings (Chaimovitsh et al. Reference Chaimovitsh, Abu-Abied, Belausov, Rubin, Dudai and Sadot2010). This could be due to the ability of Arabidopsis to recover within hours of exposure to citral (Chaimovitsh et al. Reference Chaimovitsh, Abu-Abied, Belausov, Rubin, Dudai and Sadot2010). Furthermore, pulegone had no phytotoxic effect on mature Arabidopsis plants in this work. This outcome prevents clarification of its mode of action, indicating further study is needed.

We described here the influence of limonene, citral, pulegone, and carvacrol on membrane leakage in Arabidopsis plants and on the accumulation of these four monoterpenes in the plant tissue. Accumulation of limonene in the plant tissue increased dramatically with increasing dose and exposure time. The amount of limonene that was absorbed by the plants was 10-fold higher than that of citral, 8-fold higher than that of carvacrol, and 3-fold higher than that of pulegone. This might be due to limonene’s higher physical volatility. The higher concentrations that accumulated in the plants could explain the stronger antimicrotubule and antimembrane activities, hence its herbicidal potential. The observed conversion of limonene to carvacrol by Arabidopsis plants is a novel finding. Carvacrol accumulated following exposure to the high dose of limonene and showed a slight membrane leakage effect. The metabolic pathway that underlies this conversion is currently unclear. Yet the observations in this study suggest that the mode of action of carvacrol as an allelochemical is via membrane leakage at high dosages and extensive exposure duration.

Accumulated data show that growth-inhibiting effects of different monoterpenes depend on their chemical structure. Monoterpenes that contain oxygen show higher inhibitory activity toward seed germination and plant growth than hydrocarbon monoterpenes (Elakovich Reference Elakovich1988; Reynolds Reference Reynolds1987; Vaughn and Spencer Reference Vaughn and Spencer1993). Weidenhamer et al. (Reference Weidenhamer, Macias, Fischer and Williamson1993) showed a connection between inhibitory activity and water solubility of monoterpenes. Ketones were more soluble and more active than alcohols, which were more active and soluble than hydrocarbons. In addition, the bioactivity of monoterpenes seems to be inversely correlated to lipophilicity (Abrahim et al. Reference Abrahim, Braguini, Kelmer-Bracht and Ishii-Iwamoto2000). Zunino and Zygadlo (Reference Zunino and Zygadlo2004) concluded that most phytotoxic monoterpenes are from the group of alcohols and phenols. The work presented here examined 17 monoterpenes for microtubule-disrupting activity, and no direct correlation was found between monoterpene structure and microtubule-disrupting activity. The most active monoterpene was limonene, a hydrocarbon that belongs to the less active group described by Weidenhamer et al. (Reference Weidenhamer, Macias, Fischer and Williamson1993). Monoterpenes from the ketone group showed differential activities toward microtubules; (+)-carvone and menthone exhibited microtubule-disrupting activity, and pulegone did not. Monoterpenes from the alcohol group also exhibited differential microtubule-disrupting activity; geraniol exhibited antimicrotubule activity, whereas citronellol and nerol did not. The monoterpenes citral and citronellal from the aldehyde group were found to exhibit microtubule-disrupting activity, but it was weaker than that of the hydrocarbon limonene.

We observed a bioconversion of citral into its derivatives nerol and geraniol in Arabidopsis plants. A similar conversion was previously described in wheat seeds and was explained as a mechanism for detoxification of citral by the seeds through reduction to less bioactive derivatives (Dudai et al. Reference Dudai, Larkov, Putievsky, Lerner, Ravid, Lewinson and Mayer2000b). Interestingly, while geraniol was found to have antimicrotubule activity similar to that of citral, nerol did not.

In this study, no specific effects of pulegone on microtubulin and membrane leakage in the plants were observed. Therefore, the experimental setup used here did not provide evidence for its mode of action. It is probable that higher doses of this compound are required to affect mature Arabidopsis plants.

In conclusion, the present study sheds new light on the modes of action of various monoterpenes known as allelochemicals, demonstrating that some of the monoterpenes have isomeric-specific activity and pointing out limonene as possessing high herbicidal potency. These findings could assist in designing new, natural, and ecofriendly herbicides.

Acknowledgment

The authors thank Nadav T. Nitzan for his assistance in editing and critically reviewing this article.

Footnotes

Associate Editor for this paper: Franck E. Dayan, Colorado State University.

References

Literature Cited

Abad, A, Kasrati, A, Jamili, CA, Zeroual, S, M’hamed, TB, Spooner-Hart, R, Leach, D (2014) Insecticidal properties and chemical composition of essential oils of some aromatic herbs from Morocco. Nat Prod Res 28:23382341 Google Scholar
Abrahim, D, Braguini, WL, Kelmer-Bracht, AM, Ishii-Iwamoto, EL (2000) Effects of four monoterpenes on germination, primary root growth, and mitochondrial respiration of maize. J Chem Ecol 26:611624 Google Scholar
Abrahim, D, Francischini, AC, Pergo, EM, Kelmer-Bracht, AM, Ishii-Iwamoto, EL (2003) Effects of α-pinene on the mitochondrial respiration of maize seedlings. Plant Phys Biochem 41:985991 Google Scholar
Aggarwal, KK, Khanuja Ateeque Ahmad, SPS, Santha Kumar, TR, Gupta, VK, Kumar, S (2002). Antimicrobial activity profiles of the two enantiomers of limonene and carvone isolated from the oils of Mentha spicata and Anethum sowa. Flavour Fragr J 17:5963 Google Scholar
Altshuler, O, Abu-Abied, M, Chaimovitsh, D, Shechter, A, Frucht, H, Dudai, N, Sadot, E (2013) Enantioselective effects of (+)- and (−)-citronellal on animal and plant microtubules. J Nat Prod 76:15981604 CrossRefGoogle ScholarPubMed
Bassolé, IHN, Juliani, HR (2002) Essential oils in combination and their antimicrobial properties. Molecules 17:39894006 Google Scholar
Berchielli-Robertson, DL, Gilliam, CH, Fare, DC (1990) Competitive effects of weeds on the growth of container-grown plants. Hort Sci 25:7779 Google Scholar
Bernstein, N, Shoresh, M, Xu, Y, Huang, B (2010) Involvement of the plant antioxidative response in the differential growth sensitivity to salinity of leaves vs. roots during cell development. Free Radicals Biol Med 49:11611171 Google Scholar
Bolte, S, Talbot, C, Boutte, Y, Catrice, O, Read, ND, Satiat-Jeune-Maitre, B (2004) FM-dyes as experimental probes for dissecting vesicle trafficking in living plant cells. J Microscopy 214:159173 Google Scholar
Cantrell, CL, Dayan, FE, Duke, SO (2012) Natural products as sources of new pesticides. J Nat Prod 75:12311242 Google Scholar
Chaimovitsh, D, Abu-Abied, M, Belausov, E, Rubin, B, Dudai, N, Sadot, E (2010) Microtubules are an intracellular target of the plant terpene citral. Plant J 61:399408 Google Scholar
Chaimovitsh, D, Rogovoy-Stelmakh, O, Altshuler, O, Belausov, E, Abu-Abied, M, Rubin, B, Sadot, E, Dudai, N (2012) The relative effect of citral on mitotic microtubules in wheat roots and BY2 cells. Plant Biol 14:354364 Google Scholar
Chappell, L, Knox, G, Stamps, RH (2012) Alternatives to synthetic herbicides for weed management in container nurseries. UGA Cooperative Extension Bulletin 1410. Athens, GA: University of Georgia Cooperative Extension Google Scholar
Christaki, E, Bonos, E, Giannenas, I, Florou-Paneri, P (2012) Aromatic plants as a source of bioactive compounds. Agriculture 2:228243 Google Scholar
Cox, SD, Gustafson, JE, Mann, CM, Markham, JL, Liew, YC, Hartland, RP, Bell, HC, Warmington, JR, Wyllie, SG (1988) Tea tree oil causes K+ leakage and inhibits respiration in Escherichia coli . Lett Appl Microbiol 26:355358 Google Scholar
Dayan, FE, Duke, SO (2014) Natural compounds as next-generation herbicides. Plant Physiol 166:10901105 Google Scholar
Dayan, FE, Owens, DK, Duke, SO (2012) Rationale for a natural products approach to herbicide discovery. Pest Manag Sci 68:519528 Google Scholar
Di Pasqua, R, Betts, G, Hoskins, N, Edwards, M, Eroolini, D, Mauriello, G (2007) Membrane toxicity of antimicrobial compounds from essential oils. J Agric Food Chem 55:48634870 Google Scholar
Dragoeva, AP, Nanova, ZD, Kalcheva, VK (2008) Allelopathic activity of micropropagated Origanum vulgare ssp. hirtum and its effect on mitotic activity. Allelopathy 22:131142 Google Scholar
Dudai, N, Chaimovitsh, D, Larkov, O, Fisher, R, Blaicer, Y, Mayer, AM (2009) Allelochemicals released by leaf residues of Micromeria fruticosa in soils, their uptake and metabolism by inhibited wheat seed. Plant Soil 314:311317 Google Scholar
Dudai, N, Larkov, O, Mayer, AM, Poljakoff-Mayber, A, Putievsky, E, Lerner, HR (2000a) Metabolism of essential oils during inhibition of wheat seed germination. Pages 315321 in Black M, Bradford KJ, Vázquez-Ramos J, eds. Seed Biology: Advances and Applications. Wallingford, UK: CABI Publishing Google Scholar
Dudai, N, Larkov, O, Putievsky, E, Lerner, HR, Ravid, U, Lewinson, E, Mayer, AM (2000b) Biotransformation of constituents of essential oils by germinating wheat seed. Phytochemistry 55:375382 Google Scholar
Dudai, N, Poljakoff-Mayber, A, Mayer, AM, Putievsky, E, Lerner, HR (1999) Essential oils as allelochemicals and their potential use as bioherbicides. J Chem Ecol 25:10791089 Google Scholar
Einhellig, FA (1986) Mechanisms and modes of action of allelochemicals. Pages 171188 in Putnam AR, Tang CS, eds. The Science of Allelopathy. New York: Wiley-Interscience Google Scholar
Einhellig, FA, Leather, GR (1988) Potentials for exploiting allelopathy to enhance crop production. J Chem Ecol 14:18291844 Google Scholar
Elakovich, SD (1988) Terpenoids as models for new agrochemicals. Pages 250261 in Cutler HG, ed. Biologically Active Natural Products—Potential Use in Agriculture. Washington, DC: American Chemical Society Google Scholar
Fischer, NH (1986) The function of mono and sesquiterpenes as plant germination and growth regulators. Pages 203218 in Putnam A, Chung-Shih T, eds. The Science of Allelopathy. New York: Wiley-Interscience Google Scholar
Gerwick, BC and Sparks, TC (2014) Natural products for pest control: an analysis of their role, value and future. Pest Manag Sci 70:11691185 Google Scholar
Gorell, JM, Johnson, CC, Rybicki, BA, Peterson, EL, Richardson, RJ (1998) The risk of Parkinson’s disease with exposure to pesticides, farming, well water, and rural living. Neurology 50:13461350 Google Scholar
Gouda, NAA, Saad, MMG, Abdelgaleil, SAM (2016) Pre and post herbicidal activity of monoterpenes against barnyard grass (Echinochloa crus-galli). Weed Sci 64:191200 Google Scholar
Grana, E, Diaz-Tielas, C, Sanchez- Moreiras, AM, Reigosa, MJ (2012) Mode of action of monoterpenes in plant-plant interactions. Curr Bioactive Compounds 8:8089 Google Scholar
Grana, E, Sotelo, T, Diaz-Tielas, C, Araniti, F, Krasuska, U, Bogatek, R, Reigosa, MJ, Sanchez-Morieiras, AM (2013b) Citral induces auxin and ethylene-mediated malformations and arrests cell division in Arabidopsis thaliana roots. J Chem Ecol 39:271282 Google Scholar
Grana, E, Sotelo, T, Diaz-Tielas, C, Reigosa, MJ, Sanchez-Moreiras, AM (2013a) The phytotoxic potential of the terpenid citral on seedlings and adult plants. Weed Sci 61:469481 Google Scholar
Isman, BB (2000) Plant essential oils for pest and disease management. Crop Protect 19:603608 Google Scholar
Kala, PC (2015) Medicinal and aromatic plants: boon for enterprise development. J Appl Res Med Aromatic Plants 2(4): 134139 Google Scholar
Kettles, MK, Browning, SR, Prince, TS, Horstman, SW (1997) Triazine herbicide exposure and breast cancer incidence: an ecologic study of Kentucky counties. Environ Health Perspect 105:12221227 Google Scholar
Kogevinas, M, Becher, H, Benn, T, Bertazzi, PA, Boffetta, P, Bueno-de-Mesquita, HB, Coggon, D, Colin, D, Flesch-Janys, D, Fingerhut, M, Green, L, Kauppinen, T, Littorin, M, Lynge, E, Mathews, JD, Neuberger, M, Pearce, N, Saracci, R (1997) Cancer mortality in workers exposed to phenoxy herbicides, chlorophenols, and dioxins. An expanded and updated international cohort study. Am J Epidemiol 145:10611075 Google Scholar
Koitabashi, R, Suzuki, T, Kawazu, T, Sakai, A, Kuroiwa, H, Kuroiwa, T (1997) 1,8-Cineole inhibits root growth and DNA synthesis in the root apical meristem of Brassica campestris L. J Plant Res 110:16 Google Scholar
Kost, B, Spielhofer, P, Chua, NH (1998) A GFP-mouse talin fusion protein labels plant actin filaments in vivo and visualizes the actin cytoskeleton in growing pollen tubes. Plant J 16:393401 Google Scholar
Kreis, P, Mosandl, A (1994a) Chiral compounds of essential oils. Part XVI. Simultaneous stereoanalysis of cymbopogon oil constituents. Flav Frag J 9:249256 Google Scholar
Kreis, P, Mosandl, A (1994b) Chiral compounds of essential oils. Part XVII. Simultaneous stereoanalysis of cymbopogon oil constituents. Flav Frag J 9:257260 Google Scholar
Lambert, RJW, Skandamis, PN, Coote, PJ, Nychas, G-JE (2001) A study of the minimum inhibitory concentration and mode of action of oregano essential oil, thymol and carvacrol. J Appl Microbiol 91:453462 Google Scholar
Lewinsohn, E, Dudai, N, Tadmor, Y, Katzir, I, Ravid, U, Putievsky, E, Joel, DM (1998) Histochemical localization of citral accumulation in lemongrass leaves (Cymbopogon citratus (DC.) Stapf., Poaceae). Ann Bot 81:3539 Google Scholar
Maffei, M, Camusso, W, Sacco, S (2001) Effect of Mentha × piperita essential oil and monoterpenes on cucumber root membrane potential. Phytochemistry 58:703707 Google Scholar
Martino, LD, Mancini, E, Rolim de Almeida, LF, De-Feo, V (2010) The antigerminative activity of twenty-seven monoterpenes. Molecules 15:66306637 Google Scholar
Mucciarelli, M, Camusso, W, Bertea, CM, Bossi, S, Maffei, M (2001) Effect of (+) pulegone and other oil components of Mentha×Piperita on cucumber respiration. Phytochemistry 57:9198 Google Scholar
Narwal, SS (1999) Allelopathy in weed management. Pages 203254 in Narwal SS, ed. Allelopathy Update: Basic and Applied Aspects. Volume 2. Enfield, NH: Science Publisher Google Scholar
Pimentel, D, Zuniga, R, Morrison, D (2005) Update on the environmental and economic costs associated with alien-invasive species in the United States. Ecol Econ 52:273288 Google Scholar
Reynolds, T (1987) Comparative effect of alicyclic compounds and quinones on inhibition of lettuce fruit germination. Ann Bot 60:215223 Google Scholar
Rivas da Silva, AC, Monteiro Lopes, P, Barros de Azevedo, MM, Machado Costa, DC, Sales Alviano, C, Sales Alviano, D (2012) Biological activities of α-pinene and β-pinene enantiomers. Molecules 17:63056316 Google Scholar
Seiber, JN, Coats, J, Duke, SO and Gross, AD (2014) Biopesticides: state of the art and future opportunities. J Agri Food Chem 62:1161311619 Google Scholar
Sikkema, J, De-Bont, JAM, Poolman, B (1995) Mechanisms of membrane toxicity of hydrocarbons. Microbiol Rev 59:201222 Google Scholar
Singh, HP, Batish, DR, Kaur, S, Arora, K, Kohli, RK (2009a) α-Pinene inhibits growth and induces oxidative stress in roots. Ann Bot 98:12611269 Google Scholar
Singh, HP, Batish, DR, Kaur, S, Ramezani, H, Kohli, RK (2002) Comparative phytotoxicity of four monoterpenes against Cassia occidentalis . Ann Appl Biol 141:111116 Google Scholar
Singh, HP, Kaur, S, Mittal, S, Batish, DR, Kohli, RK (2009b) Essential oil of Artemisia scoparia inhibits plant growth by generating reactive oxygen species and causing oxidative damage. J Chem Ecol 35:154162 Google Scholar
Sousa, SM, Silva, PS, Viccini, LF (2010) Cytogenotoxicity of Cymbopogon citratus (DC) Stapf (lemon grass) aqueous extracts in vegetal test systems. Ann Acad Bras Cienc 82:305311 Google Scholar
Ueda, K, Matsuyama, T, Hashimmoto, T (1999) Visualization of microtubules in living cells of transgenic Arabidopsis thaliana . Protoplasma 206:201206 Google Scholar
Vaughn, SF and Spencer, GF (1993) Volatile monoterpenes as potential parent structures for new herbicides. Weed Sci 41:114119 Google Scholar
Weidenhamer, JD, Macias, FA, Fischer, NH, Williamson, GB (1993) Just how insoluble are monoterpenes? J Chem Ecol 19:17991803 Google Scholar
Weidenhamer, JD, Menelaou, M, Macias, FA, Fisher, NH, Richardson, DR, Williamson, B (1994) Allelopathic potential of menthofuran monoterpenes from Calamintha ashei . J Chem Ecol 20:33453359 Google Scholar
Zunino, MP, Zygadlo, JA (2004) Effect of monoterpenes on lipid oxidation in maize. Planta 219:303309 Google Scholar
Figure 0

Table 1 Effect of 17 monoterpenes and citral derivatives on the activity of microtubulin, membrane, and F-actin in Arabidopsis seedlings and on phytotoxicity and plant biomass in mature Arabidopsis plants.

Figure 1

Figure 1 The effect of limonene, pulegone, and carvacrol in relation to citral on microtubules, F-actin, and the plasma membrane in Arabidopsis leaf epidermal cells. GFP-TUA6 or GFP-mTalin lines were exposed to the vapors in 20 ml scintillation bottles for 30 min and then stained with FM4-64. Shown are confocal images of the abaxial leaf epidermis.

Figure 2

Figure 2 Phytotoxicity of limonene, pulegone, citral, and carvacrol to Arabidopsis plants. Note: the plants were exposed to monoterpene vapors for 0, 15, 30, and 60 min, and the herbicidal potential was examined 14 d postexposure.

Figure 3

Figure 3 Effect of time and dose on fresh weight (g plant−1) of Arabidopsis plants exposed to limonene (A), carvacrol (B), pulegone (C), and citral (D) at vapor phase for 15, 30, and 60 min. Lowercase letters represent treatments that were significantly different than the control as determined by ANOVA followed by Tukey’s HSD post hoc test.

Figure 4

Figure 4 Effect of citral, carvacrol, pulegone, and limonene on membrane leakage in Arabidopsis plants exposed to (A) low (0.75 μl per 20 ml) and (B) high (1.5 μl per 20 ml) dosages for 15, 30, and 60 min. Lowercase letters represent treatments that were significantly different than the control as determined by ANOVA followed by Tukey’s HSD post hoc test.

Figure 5

Table 2 Monoterpene residues and their derivatives in Arabidopsis thaliana tissue.