Abstract
The aim of this research was to determine the chemical composition and insecticidal activity of the essential oils derived from flowering aerial parts of Artemisia giraldii Pamp. and A. subdigitata Mattf. (Family: Asteraceae) against the maize weevil (Sitophilus zeamais Motsch.). Essential oils of aerial parts of A. giraldii and A. subdigitata were obtained from hydrodistillation and investigated by GC and GC-MS. A total of 48 and 33 components of the essential oils of A. giraldii and A. subdigitata were identified, respectively. The principal compounds in A. giraldii essential oil were β-pinene (13.18%), iso-elemicin (10.08%), germacrene D (5.68%), 4-terpineol (5.43%) and (Z)-β-ocimene (5.06%). 1,8-Cineole (12.26%) and α-curcumene (10.77%) were the two main components of the essential oil of A. subdigitata, followed by β-pinene (7.38%), borneol (6.23%) and eugenol (5.87%). The essential oils of A. giraldii and A. subdigitata possessed fumigant toxicity against the maize weevils with LC50 values of 6.29 and 17.01 mg/L air, respectively. The two essential oils of A. giraldii and A. subdigitata also exhibited contact toxicity against S. zeamais adults with LD50 values of 40.51 and 76.34 µg/adult, respectively. The results indicated that the two essential oils show potential in terms of fumigant and contact toxicity against grain storage insects.
Keywords: Artemisia giraldii, Artemisia subdigitata, Sitophilus zeamais, fumigant, contact toxicity, essential oil composition
1. Introduction
The maize weevil (Sitophilus zeamais Motsch.) is a serious pest of stored grains worldwide. Infestations not only cause significant economic losses due to the consumption of grains; they also result in elevated temperature and moisture conditions that lead to an accelerated growth of molds, including toxigenic species [1]. The maize weevils are small (2.5 mm to 4 mm length) brown black weevils with a long slender snout and four reddish brown spots on the wing covers (two spots on each wing cover). The head and thorax are nearly as long as the wing covers. They are a primary pest of grain as they can infest undamaged grain. In China, they are a major pest of corn. Control of the stored product insects now is based on the application of synthetic insecticides/fumigants. However, repeated use of those fumigants/insecticides for decades has led to resurgence of stored-product insect pests, sometimes resulted in the development of resistance, and had undesirable effects on non-target organisms [2]. These problems have highlighted the need to develop new types of selective insect-control alternatives with fumigant action. Plant essential oils and their components have been shown to possess potential to be developed as new fumigants and they may have the advantage over conventional fumigants in terms of low mammalian toxicity, rapid degradation and local availability [3]. More than 15 essential oils derived from plant species of the genus Artemisia have been evaluated for insecticidal activities against stored product insects [4,5,6,7,8,9,10,11,12,13,14].
The genus Artemisia (commonly wormwood or sagebrush) is one of the largest and most widely distributed genera of the family Asteraceae. It comprises about 380 species of herbs and shrubs well-known for their volatile oil that is extensively used in food and pharmaceutical industry. Artemisia giraldii Pamp. and A. subdigitata Mattf. are two of the 186 species of Artemisia found in China [15]. A. giraldii is an herbaceous plant distributed only in some areas of China (e.g., Henan, Hebei, Gansu, Ningxia, Shannxi, and Sichuan province). In the previous studies, two flavones and several monoterpenoids and sesquiterpenoids were isolated from A. giraldii aerial parts and identified [16,17,18,19]. A. subdigitata is a species of perennial herbaceous rhizome plant distributed in some areas of China (e.g., Gansu, Guizhou, Hebei, inner Mongol, Sichuan, and Yunnan province) and also Nepal, Bhutan, and North India. It is used as traditional medicinal herb in some areas of China (Folium Artemisiae Argyi) [15]. It is used in Chinese traditional medicine to stop bleeding by warming meridians, expel cold and alleviate pain, and prevention of miscarriages [15]. Most of the components isolated from the extracts of A. subdigitata were terpenoids [20,21,22,23,24].
During our mass screening program for new agrochemicals from the wild plants, essential oils of A. giraldii and A. subdigitata were found to possess strong insecticidal activity against maize weevils. A literature survey showed that there are no reports on the volatile constituents and insecticidal activity of A. giraldii. The chemical composition of the essential oil derived from A. subdigitata has been previously reported [25,26]. However, to date, there has been no report on the insecticidal activity of A. subdigitata essential oil. Thus we decided to investigate the chemical constituents and insecticidal activity of the essential oils of A. giraldii and A. subdigitata against grain storage insects for the first time.
2. Results and Discussion
The yellow essential oil yield of A. giraldii flowering aerial parts was 0.36% v/w and the density of the concentrated essential oil was determined to be 0.85 g/mL. The essential oil yield of A. subdigitata was 0.64% v/w and the density of the oil was 0.79 g/mL. A total of 48 components of the essential oil of A. giraldii flowering aerial parts were identified (Table 1). The principal compounds in A. giraldii essential oil were β-pinene (13.18%), iso-elemicin (10.08%), germacrene D (5.68%), 4-terpineol (5.43%) and (Z)-β-ocimene (5.06%). Monoterpenoids represented 24 of the 48 compounds, corresponding to 53.57% of the whole oil, while 21 of the 48 constituents were sesquiterpenoids (41.49% of the crude essential oil). The main constituents in A. giraldii essential oil were quite different from those in the essential oils derived from the other species of the genus Artemisia from China. For example, the main components of essential oil of A. vestita were grandisol (40.3%), 1,8-cineol (14.9%) and camphor (11.4%) [10]. In another report, the major components of A. lavandulaefolia oil were caryophyllene (15.5%), β-thujone (13.8%), 1,8-cineole (13.1%), and β-farnesene (12.3%), and the principal compounds identified in A. sieversiana oil were 1,8-cineole (9.2%), geranyl butyrate (9.2%), borneol (7.9%), and camphor (7.9%) [13]. However, the main components of the essential oil of A. eriopoda were germacrene D (21.6%) and 1,8-cineole (14.2%) [14] while the principal compounds in the essential oil of A. igniaria were 1,8-cineole (14.4%) and camphor (13.4%) [27].
Table 1.
RI * | Compound | Percent Composition |
---|---|---|
939 | α-Pinene | 3.52 |
981 | β-Pinene | 13.18 |
1028 | 3-Isopropenyl-5,5-dimethylcyclopentene | 3.01 |
1038 | (Z)-β-Ocimene | 5.06 |
1044 | β-Terpinene | 0.15 |
1057 | γ-Terpinene | 1.21 |
1067 | cis-Linalool oxide | 1.64 |
1088 | Terpinolene | 0.80 |
1094 | Linalool | 3.36 |
1112 | Rose oxide | 3.72 |
1117 | 2,6-Dimethyleneoct-7-en-3-one | 0.22 |
1140 | trans-p-Menth-2-en-1-ol | 0.35 |
1147 | allo-Ocimene | 0.72 |
1167 | Borneol | 0.28 |
1175 | 4-Terpineol | 3.87 |
1182 | p-Cymen-8-ol | 5.43 |
1191 | α-Terpineol | 0.95 |
1226 | cis-Geraniol | 1.66 |
1275 | Verbenyl acetate | 1.82 |
1281 | Phellandral | 0.13 |
1289 | Bornyl acetate | 0.2 |
1326 | Methyl geranate | 0.18 |
1362 | 3-Allylguaiacol | 0.96 |
1365 | Neryl acetate | 0.67 |
1383 | trans-Geranyl acetate | 1.24 |
1388 | β-Cubebene | 0.36 |
1392 | cis-Jasmone | 0.35 |
1420 | Caryophyllene | 3.38 |
1437 | α-Guaiene | 1.31 |
1440 | epi-Bicyclosesquiphellandrene | 0.81 |
1452 | trans-β-Farnesene | 2.06 |
1454 | 1,4,7,-Cycloundecatriene, 1,5,9,9-tetramethyl-, Z,Z,Z- | 0.77 |
1468 | γ-Himachalene | 1.08 |
1474 | ar-Curcumene | 1.81 |
1480 | Germacrene D | 5.68 |
1498 | α-Muurolene | 0.21 |
1500 | Methyl isoeugenol | 2.19 |
1505 | α-Farnesene | 2.83 |
1513 | γ-Cadinene | 0.55 |
1524 | β-Sesquiphellandrene | 2.63 |
1537 | trans-Cadina-1,4-diene | 0.43 |
1554 | Elemicin | 0.55 |
1563 | Nerodilol | 1.03 |
1578 | Spathulenol | 2.05 |
1596 | iso-Elemicin | 10.08 |
1623 | 3,4,5-trimethoxy-Benzaldehyde | 0.46 |
1653 | α-Cadinol | 2.38 |
1714 | Eudesma-4,11-dien-2-ol | 1.59 |
Total identified | 98.92 | |
Monoterpenoids | 53.57 | |
Sesquiterpenoids | 41.49 | |
Others | 3.61 |
* RI, retention index as determined on a HP-5MS column using the homologous series of n-hydrocarbons.
A total of 33 components of the essential oil of A. subdigitata were identified, accounting for 98.31% of the total oil (Table 2). 1,8-Cineole (12.26%) and α-curcumene (10.77%) were the two main constituents of A. subdigitata essential oil, followed by β-pinene (7.38%), borneol (6.23%) and eugenol (5.87%). The chemical composition of the essential oil of A. subdigitata was quite different from that reported in other studies. For example, β-pinene (35.7%) and limonene (11.0%) was the two main components of the essential oils of young leaves of A. subdigitata harvested in Northwest China [20]. However, the leaf oil of A. subdigitata collected from Mongolia was dominated by eugenol (11.2%), methyl eugenol (9.4%) and camphor (9.0%) [21]. The above findings suggested that there were great geographic variations in chemical composition of A. subdigitata essential oil.
Table 2.
RI * | Compound | Percent Composition |
---|---|---|
927 | α-Thujene | 1.43 |
939 | α-Pinene | 0.49 |
952 | Camphene | 2.28 |
977 | Sabinene | 0.64 |
981 | β-Pinene | 7.38 |
991 | β-Myrcene | 4.54 |
1010 | δ-3-Carene | 0.23 |
1032 | 1,8-Cineole | 12.26 |
1038 | (Z)-β-Ocimene | 1.75 |
1049 | 2,6-Dimethyl-2,6-octadiene | 0.27 |
1057 | γ-Terpinene | 2.26 |
1167 | Borneol | 6.23 |
1175 | Terpinen-4-ol | 3.39 |
1191 | α-Terpineol | 1.14 |
1195 | Estragole | 4.25 |
1235 | Geraniol | 2.82 |
1297 | Acetophenone | 1.56 |
1356 | Eugenol | 5.87 |
1374 | Copaene | 0.29 |
1420 | Caryophyllene | 2.84 |
1436 | β-Bergamotene | 0.88 |
1454 | α-Caryophyllene | 1.15 |
1457 | (E)-β-farnesene | 1.64 |
1483 | α-Curcumene | 10.77 |
1488 | Acenaphthene | 3.83 |
1492 | α-Zingiberene | 4.62 |
1505 | α-Farnesene | 1.64 |
1512 | δ-Amorphene | 0.55 |
1521 | δ-Cadinene | 1.78 |
1524 | β-Sesquiphellandrene | 0.22 |
1578 | Spathulenol | 4.09 |
1584 | Caryophyllene oxide | 3.14 |
1608 | Humulene oxide II | 2.08 |
Total | 98.31 | |
Monoterpenoids | 51.36 | |
Sesquiterpenoids | 39.52 | |
Others | 7.43 |
* RI, retention index as determined on a HP-5MS column using the homologous series of n-hydrocarbons
The essential oils of A. giraldii and A. subdigitata flowering aerial parts exhibited contact toxicity against S. zeamais adults, with LD50 values of 40.51 and 76.34 μg/adult, respectively (Table 3). The essential oil of A. giraldii shows stronger toxicity than A. subdigitata essential oil against S. zeamais adults (no overlaps in 95% fiducial limit, Table 3). Compared with the famous botanical insecticide, pyrethrum extract (25% pyrethrine I and pyrethrine II), the two essential oils were 9 and 18 times less toxic against the maize weevils because pyrethrum extract displayed a LD50 value of 4.29 μg/adult [12].
Table 3.
Toxicity | Essential oil | LD50/LC50 * | 95% FL | Slope ± SE | Chi square (χ2 ) |
---|---|---|---|---|---|
Contact | A. giraldii | 40.51 | 37.83–44.89 | 3.26 ± 0.39 | 7.13 |
A. subdigitata | 76.34 | 70.77–82.14 | 2.37 ± 0.21 | 9.48 | |
Pyrethrum extract | 4.29 a | 3.86–4.72 | 0.72 ± 0.01 | 13.51 | |
Fumigant | A. giraldii | 6.29 | 5.48–7.38 | 2.59 ± 0.30 | 8.12 |
A. subdigitata | 17.01 | 15.57–18.78 | 1.67 ± 0.14 | 15.90 | |
MeBr | 0.67 b | - | - | - |
The essential oils of A. giraldii and A. subdigitata flowering aerial parts also possessed strong fumigant activity against S. zeamais adults, with LC50 values of 6.29 and 17.01 mg/L air, respectively (Table 3). On the basis of LC50 values, S. zeamais adults were significantly more susceptible (no overlaps in 95% fiducial limit) to the essential oil of A. giraldii than to A. subdigitata essential oil. However, the currently used grain fumigant, methyl bromide (MeBr) was reported to have fumigant activity against S. zeamais adults with a LC50 value of 0.67 mg/L air [28]. Thus, the two essential oils of A. giraldii and A. subdigitata flowering aerial parts were only 9 and 25 times less toxic to the maize weevil compared with the commercial fumigant MeBr. However, compared with the other essential oils in the previous studies, the two essential oils of A. giraldii and A. subdigitata exhibited stronger or the same level of fumigant toxicity against the maize weevils, e.g., essential oils of Murraya exotica (LC50 = 8.29 mg/L) [29], A. lavandulaefolia LC50 = 11.2 mg/L) and A. sieversiana (LC50 = 15.0 mg/L) [13], A. vestita (LC50 = 13.42 mg/L) [10], A. capillaris (LC50 = 5.31 mg/L) and A. mongolica (LC50 = 7.35 mg/L) [12], Illicium simonsii (LC50 = 14.95 mg/L) [11], I. fragesii (LC50 = 11.36 mg/L) [30], Rhododendron anthopogonoides (LC50 = 9.66 mg/L) [31], Kadsura heteroclite (LC50 = 14.04 mg/L) [32], and Lonicera japonica (LC50 = 13.36 mg/L) [33]. The above findings suggest that fumigant activity of the two essential oils is quite promising, considering the currently used fumigants are synthetic insecticides and they show potential to be developed as possible natural fumigants for the control of stored product insects. Moreover, for the practical application of the essential oils as novel fumigant/insecticide, further studies on the safety of the essential oils to humans and on development of formulations are necessary to improve the efficacy and stability and to reduce cost. The isolation and identification of the bioactive compounds in the essential oils of A. giraldii and A. subdigitata flowering aerial parts are of utmost importance so that their potential application in controlling stored-product pests can be fully exploited.
In previous studies [6,34,35,36,37,38,39,40], the insecticidal activity of 1,8-cineole, β-pinene, borneol, terpinen-4-ol, and (Z)-β-ocimene (main constituents of the studied essential oils) against the grain storage insects had been reported. For example, 1,8-cineole and β-pinene exhibited fumigant toxicity against S. zeamais adults, with 24 h LC50 values of 1.82 mg/cm2 and 3.82 mg/cm2, respectively [34] and also possessed contact toxicity against S. zeamais adults with 7 d LD50 values of 48 μg/mg and 113 μg/mg, respectively, while terpinen-4-ol has a 7 d LD50 value of 10 μg/mg [35]. Moreover, (Z)-β-ocimene exhibited fumigant toxicity against S. zeamais adults with a 24 h LC50 value of 28.66 mg/L air [36]. However, no reports on insecticidal activity of α-curcumene, iso-elemicin and germacrene D against grain storage insects were available so far.
3. Experimental
3.1. Plant Material and Essential Oil Extraction
Fresh flowering aerial parts (10 kg of leaves, stems and flowers) of A. giraldii and A. subdigitata were harvested in August 2010 from Xiaolongmeng National Forest Park (Mentougou District, Beijing 102300). The samples were air-dried for one week and ground to a powder using a grinding mill (Retsch Muhle, Haan, Germany). The species were identified by Dr Liu, QR (College of Life Sciences, Beijing Normal University) and the voucher specimens (BNU-zhilongliu-2010-08-23-035 and BNU-zhilongliu-2010-08-23-036) were deposited at the Herbarium (BNU) of College of Life Sciences, Beijing Normal University. The ground powder of the two plants was subjected to hydrodistillation using a modified Clevenger-type apparatus for 4 h and extracted with n-hexane. Anhydrous sodium sulphate was used to remove water after extraction. Essential oils were stored in airtight containers in a refrigerator at 4 °C.
3.2. Insects
The maize weevils (S. zeamais) were obtained from laboratory cultures maintained for the last 15 years in the dark in incubators at 29–30 °C and 70–80% relative humidity. The maize weevils were reared on whole wheat at 12–13% moisture content in glass jars (diameter 85 mm, height 130 mm) at 29–30 °C and 70–80% relative humidity. Unsexed adult weevils used in all the experiments were about 2 weeks old.
3.3. Gas Chromatography-Mass Spectrometry
The two essential oils were subjected to GC-MS analysis on an Agilent system consisting of a model 6890N gas chromatograph, a model 5973N mass selective detector (EIMS, electron energy, 70 eV), and an Agilent ChemStation data system. The GC column was an HP-5ms fused silica capillary with a 5% phenyl-methylpolysiloxane stationary phase, film thickness of 0.25 µm, a length of 30 m, and an internal diameter of 0.25 mm. The GC settings were as follows: The initial oven temperature was held at 60 °C for 1 min and ramped at 10 °C·min−1 to 180 °C held for 1 min, and then ramped at 20 °C·min−1 to 280 °C and held for 15 min. The injector temperature was maintained at 270 °C. The sample (1 μL) was injected neat, with a split ratio of 1:10. The carrier gas was helium at flow rate of 1.0 mL·min−1. Spectra were scanned from 20 to 550 m/z at 2 scans·s−1. Most constituents were identified by gas chromatography by comparison of their retention indices with those of the literature or with those of authentic compounds available in our laboratories. The retention indices were determined in relation to a homologous series of n-alkanes (C8–C24) under the same operating conditions. Further identification was made by comparison of their mass spectra with those stored in NIST 05 and Wiley 275 libraries or with mass spectra from literature [41]. Component relative percentages were calculated based on normalization method without using correction factors.
3.4. Contact Toxicity
The contact toxicity of the two essential oils against S. zeamais adults was measured as described by Liu and Ho [28]. Range-finding studies were run to determine the appropriate testing concentrations. A serial dilution of the essential oil (six concentrations, 2.6–13.3%, v/w) was prepared in n-hexane. Aliquots of 0.5 μL of the dilutions were applied topically to the dorsal thorax of the insects, using a Burkard Arnold microapplicator. Controls were determined using 0.5 µL of n-hexane per insect. Ten insects were used for each concentration and control, and the experiment was replicated six times. Both treated and control insects were then transferred to glass vials (10 insects/vial) with culture media and kept in incubators at 29–30 °C and 70–80% relative humidity. Mortality was observed after 24 h. The observed mortality data were corrected for control mortality using Abbott’s formula. Results from all replicates were subjected to probit analysis using the PriProbit Program V1.6.3 to determine LD50 values [42].
3.5. Fumigant Toxicity
Range-finding studies were run to determine the appropriate testing concentrations. A serial dilution of the essential oil (2.0–40.0%, six concentrations) was prepared in n-hexane. A Whatman filter paper (diameter 2.0 cm) was placed on the underside of the screw cap of a glass vial (diameter 2.5 cm, height 5.5 cm, volume 24 mL). Ten microliters of an appropriate concentration of the essential oil was added to the filter paper. The solvent was allowed to evaporate for 15 s before the cap was placed tightly on the glass vial (with 10 insects) to form a sealed chamber. Fluon (ICI America Inc., Wilmington, DE, USA) was used inside each glass vial to prevent insects from the treated filter paper. Preliminary experiments demonstrated that 15 s were sufficient for the evaporation of solvents. n-Hexane was used as controls. Six replicates were used in all treatments and controls and they were incubated at 29–30 °C and 70–80% relative humidity for 24 h. The mortality was recorded. The observed mortality data were corrected for control mortality using Abbott’s formula. Results from all replicates were subjected to probit analysis using the PriProbit Program V1.6.3 to determine LC50 values [42].
4. Conclusions
The composition of the essential oils obtained from A. giraldii and A. subdigitata flowering aerial parts was determined by GC-FID and GC-MS. The two essential oils exhibited strong fumigant activity against S. zeamais adults. The two essential oils of A. giraldii and A. subdigitata were only 9 and 25 times less toxic to the maize weevil compared with the commercial fumigant MeBr. Moreover, the essential oils exhibited stronger toxicity than most of the reported essential oils in the literature. The two essential oils also possessed strong contact toxicity against the maize weevils. These findings suggest that the essential oils of A. giraldii and A. subdigitata flowering aerial parts have potential for development as novel natural insecticides/fumigants for grain storage insects. Further studies are required to isolate and identify the active components from the essential oils.
Acknowledgments
This project was supported by the Hi-Tech Research and Development of China 2011AA10A202. We thank Liu Q.R. from the College of Life Sciences, Beijing Normal University, Beijing 100875, for the identification of the investigated medicinal herbs. The authors thank Yang, Kai from Department of Entomology, China Agricultural University, for the bioassay.
Footnotes
Sample Availability: Samples of the crude extracts and pure compounds are available from the authors.
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