Figures
Abstract
The biological properties of essential oils have been demonstrated in the treatment of several diseases and to enhance the bioavailability of other drugs. In natural habitats the essential oils compounds may play important roles in the protection of the plants as antibacterials, antivirals, antifungals, insecticides and also against herbivores by reducing their appetite for such plants or by repelling undesirable others. We analyzed by gas-chromatography mass spectrometry the chemical composition of the essential oil of aerial parts of Glandora rosmarinifolia (Ten.) D.C. Thomas obtained by hydrodistillation and verified some biological activities on a panel of hepatocellular carcinoma cell lines (HA22T/VGH, HepG2, Hep3B) and triple negative breast cancer cell lines (SUM 149, MDA-MB-231). In the essential oil we detected 35 compounds. The results of the biological assays indicate that essential oil of G. rosmarinifolia induces cell growth inhibition at concentration-dependent way in all cell line models. This oil does not seem to possess antioxidant activity, while the cytotoxicity of G. rosmarinifolia essential oil appeared to involve, at least in part, a pro-oxidant mechanism. Our results show for the first time the antitumoral and pro-oxidant activities of G. rosmarinifolia essential oil and suggest that it may represent a resource of pharmacologically active compounds.
Citation: Poma P, Labbozzetta M, Notarbartolo M, Bruno M, Maggio A, Rosselli S, et al. (2018) Chemical composition, in vitro antitumor and pro-oxidant activities of Glandora rosmarinifolia (Boraginaceae) essential oil. PLoS ONE 13(5): e0196947. https://doi.org/10.1371/journal.pone.0196947
Editor: Ferenc Gallyas Jr., University of PECS Medical School, HUNGARY
Received: January 30, 2018; Accepted: April 23, 2018; Published: May 3, 2018
Copyright: © 2018 Poma et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper.
Funding: This work was supported by a grant from MIUR-ITALY PRIN2015 "Top-down and Bottom-up approach in the development of new bioactive chemical entities inspired on natural products scaffolds" (Project N. 2015MSCKCE_003). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
The family Boraginaceae includes more than 2700 species commonly found in cosmopolitan habitats especially in Tropic, Turian (Iran) and Mediterranean regions [1]. Several species from this family has been traditionally used as diuretic, anti-inflammatory, diaphoretic and sedative as well as rheumatic pain and burns [2, 3]. From a chemical point of view, the species are characterised by naphthoquinones and its derivatives, pyrrolizidine alkaloids, phenolic compounds and its derivatives [4].
Glandora rosmarinifolia (Ten.) D.C. Thomas (Boraginaceae) [synonyms: Lithodora rosmarinifolia (Ten.) I.M. Johnst.—Lithospermum rosmarinifolium Ten.] is a perennial shrub growing on rocky limestone habitats and cliffs in Algeria, Sicily and in the Sorrento peninsula (Italy) [5, 6, 7]. Glandora rosmarinifolia has been studied from a molecular [5], and morphological point of view [8, 9].
Few papers have been published on the chemical composition of Glandora species (e.g. G. diffusa) [4, 10] but there are no studies on G. rosmarinifolia.
The aim of this study was to identify the chemical composition of the essential oil of aerial parts (branches with leaves) of G. rosmarinifolia obtained by hydrodistillation (HD), analysed by gas chromatography-mass spectrometry (GC-MS), and to verify some biological activities on a panel of hepatocellular carcinoma cell lines (HA22T/VGH, HepG2, Hep3B) and triple negative breast cancer cell lines (SUM 149, MDA-MB-231). Both cancer models are highly aggressive with poor prognosis and are characterized by multi-drug resistance to conventional chemotherapeutic drugs [11, 12]. It is therefore desirable to investigate new therapeutic tools to overcome the adverse biological characteristic and drug resistance of these tumor models.
Materials and methods
Plant material
Branches with leaves of G. rosmarinifolia were collected in February 2017 from plants located in the following site: “Raffo Rosso, Monte Cuccio, and Vallone Sagana” (38°11’07”N 13°16’05” E—Sicily—Palermo). The matrices were placed in paper bags and kept at 4 ± 1 °C for 24 hours before the hydrodistillation. A voucher specimen (N° MS 120/2017) was deposited at the Herbarium of the University of Palermo. No specific permits were required for the described location and for the collection of plant material. The plant species used in the present study is not endangered or protected.
Essential oil isolation
Branches with leaves (64 g) were hand-cut into small pieces (~ 2 cm) and then hydrodistillated for 3 hours in a Clevenger-type apparatus, using n-pentane as collection solvent. The oil was dried by anhydrous sodium sulphate, filtered and stored at 4 °C until its chemical analysis and pharmacological tests. The essential oil yield was 49.8 mg (0.08%).
Gas chromatography-mass spectrometry
The GC analysis was performed in an Agilent 7000C GC system, fitted with a fused silica Agilent HP-5MS capillary column (30 m x 0.25 mm i.d.; 0.25 μm film thickness), coupled to an Agilent triple quadrupole Mass Selective Detector MSD 5973; ionization voltage 70 eV; electron multiplier energy 2000 V; transfer line temperature, 295 °C. Helium was the carrier gas (1 mL min-1). The other GC analysis was performed in a Shimadzu QP 2010 plus, single quadrupole GC/MS system, fitted with a Supelcowax 10 capillary column (30 m x 0.25 mm i.d.; 0.25 μm film thickness); ionization voltage 70 eV; transfer line temperature, 280 °C. Helium was the carrier gas (1 mL min-1). For both columns, the temperature was initially kept at 40 °C for 5 min, then gradually increased to 250°C at 2°C min-1 rate, held for 15 min and finally raised to 270 °C at 10 °C min-1. One μL of diluted samples (1/100 v/v, in n-hexane) was injected at 250 °C automatically and in the splitless mode; transfer line temperature, 295 °C.
Identification of compounds
Identification of compounds was carried out using NIST 11, Wiley 9, FFNSC 2, and Adams [13] databases. These identifications were confirmed by Linear Retention Indices (LRI) with those available in literature by SciFinder database. Some of the compounds were also confirmed by comparison of mass spectra and retention times with standard compounds available in laboratory. The retention indices were determined in relation to a homologous series of n-alkanes (C8-C30) injected under the same operating conditions. Component relative concentrations were calculated based on GC peak areas without using correction factors.
Cell growth assays
Hepatocellular carcinoma cell lines (HA22T/VGH, HepG2, Hep3B) and triple negative breast cancer cell lines (SUM 149, MDA-MB-231) were used. The human hepatocellular carcinoma cell line HA22T/VGH was kindly provided by Professor Massimo Levrero (Laboratory of Gene Expression, Fondazione Andrea Cesalpino, University of Rome “La Sapienza”, Rome, Italy). HepG2 (ATCC®: HB-8065™) and Hep3B (ATCC®: HB-8064™) cells were obtained from the American Type Culture Collection (ATCC, Rockville, MD, USA). All the above cell lines were authenticated by short tandem repeat profiling (BMR Genomics, Padua, Italy). The human breast cancer cell lines MDA-MB-231 (ATCC®: HTB-26™—Rockville, MD, USA) and SUM149 (SUM149PT—Asterand Bioscience Detroit, MI) were kindly provided by Dr. Elda Tagliabue (Molecular Targeting Unit, Department of Experimental Oncology and Molecular Medicine, Fondazione Institute of Hospitalization and Scientific Care, National Cancer Institute, Milan, Italy) and were authenticated using the short tandem repeat profiling method in their Institute facility.
The cells were seeded at 2 × 104 cells/well onto 96-well plates and incubated overnight at 37 °C. After obtaining the cells, the first passage carried out was assigned passage number 1. Cells with a narrow range of passage number (4–6) were routinely tested for Mycoplasma contamination were used for all experiments.
At time 0, the medium was replaced with fresh complete medium supplemented of essential at the indicated concentrations. Following 72 h of treatment, 16 μL of a commercial solution obtained from Promega Corporation (Madison, WI, USA) containing 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxy methoxyphenyl)-2-(4-sulphophenyl)-2H-tetrazolium (MTS) and phenazine ethosulfate were added. The plates were incubated in a humidified atmosphere at 37 °C in 5% CO2 for 2 h, and the bioreduction of MTS dye was evaluated by measuring the absorbance of each well at 490 nm using a microplate absorbance reader (iMark Microplate Reader; Bio-Rad Laboratories, Inc., Hercules, CA, USA). Cell growth inhibition was expressed as a percentage (mean ± SD) of the absorbance of the control cells.
Anti- and pro-oxidant activity
To evaluate antioxidant activity, we have used DPPH Assay. The antiradical efficiency of the sample was evaluated by the DPPH stable radical method [14, 15]. 100 μL of sample, the essential oil of G. rosmarinifolia at different concentrations, was added to aliquots (3.9 mL) of a solution made up with DPPH (4.8 mg) in MeOH (200 mL), and the mixture was incubated for 1 h at room temperature in the dark. Then the absorbance was measured at 517 nm using a UV-VIS spectrophotometer. The initial concentration of DPPH was approximately 60 μM. Lower absorbance values of reaction mixture indicate higher free radical scavenging activity. The results were plotted as the percentage of absorbance disappearance at 517 nm [(1—A/A0) × 100] against the amount of sample divided by the initial concentration of DPPH. Each point was acquired in triplicate. ED50 corresponds to micrograms of fraction able to consume half the amount of free radical divided by micromoles of initial DPPH. The results were expressed as antiradical capacity (ARC), which is the inverse of ED50.
Trolox (6-hydroxy-2,5,7,8-tetramethyl-chroman-2-carboxylic acid) curve was used as the positive control.
Pro-oxidant activity was examined by cell counting, adding N-acetyl-L-cysteine (NAC), an antioxidant molecule, 1 h before essential oil. Data were expressed as mean ± standard deviation (SD) of at least three different experiments performed in duplicate. All the chemicals were supplied by Sigma Aldrich srl, Milan, Italy.
Results
Chemical composition
In the essential oil of G. rosmarinifolia, we detected 35 compounds: 10 aliphatic alkanes (33.5%), 5 monoterpene hydrocarbons (3.6%), 4 diterpene hydrocarbons (25.9%), 3 aliphatic alcohols (2.3%), 3 aliphatic aldehydes (4.5%), 2 aromatic compounds (5.8%), 2 sesquiterpene hydrocarbons (1.5%), 1 aliphatic ester (0.5%), 1 aromatic ether (0.8%), 1 diterpene alcohol (4.1%), 1 irregular terpene ketone (0.5%), 1 monoterpene alcohol (0.5%) and 1 phenolic compound (1.7%) (Table 1). The most abundant compounds (≥ 4.0%) were m-camphorene (13.3%), heptacosane (10.7%), nonacosane (6.6%), hydroxy-methyl-naphthoquinone (5.3%; isomer not identified), 2,6-dimethyl-10-(p-tolyl)-2,6-(E)-undecadiene (4.9%), cembrene C (4.8%) and phytol (4.1%) contributing together 49.7% of the total composition accounting to 85.2%. Eleven compounds were found in amounts between 1.3 and 3.6% and another 17 compounds were detected in amounts < 1% (Table 1).
Compounds belonging to the same chemical class are arranged according to Linear Retention Indices (LRI) of the HP-5MS column.
In vitro anticancer and pro-oxidant activity
We investigated the cytotoxic activity of G. rosmarinifolia essential oil by 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxy methoxyphenyl)-2-(4-sulphophenyl)-2H-tetrazolium (MTS) assay on a panel of hepatocellular carcinoma cell lines (HA22T/VGH, HepG2, Hep3B) and triple negative breast cancer cell lines (SUM 149, MDA-MB-231). As shown in Fig 1, the essential oil induces cell growth inhibition at concentration dependent way in all cell line models. The relative IC50 are reported in Table 2.
Cell viability was assessed by MTS. Data are expressed as mean ± standard deviation (SD) of at least three different experiments performed in triplicate. Different letters represent significant differences (p < 0.01) in cytotoxic activity among the concentrations of each cell line.
In order to explain if antitumor activity of this oil could depend on pro-oxidant activity, as in the case of other natural compounds, we performed a separate experiment in which cell lines were treated with the antioxidant N-acetyl-L-cysteine (NAC) at two concentrations, 1 mM and 2 mM before exposure to the essential oil at the corresponding IC50 values as reported in Tables 2 and 3. In all tested cell lines a reduction between 27.3% and 38.0% of the cytotoxicity activity of the essential oil was observed, suggesting that the mechanism involves an at least partially pro-oxidant effect (Table 3).
Data are expressed as mean ± standard deviation (SD).
DPPH (2,2-diphenyl-1-picrylhydrazyl) reduction assay confirmed that essential oil does not possess antioxidant activity, in fact on the contrary to known antioxidants as Trolox (ED50 117.5 μg/ml, ACR 0.0085), it was not identified the efficient dose (ED50) of the essential oil of G. rosmarinifolia (Table 4).
Discussion
Essential oils have been used for centuries in folk medicine and in the last few years the biological properties of different essential oils have been demonstrated. Their use in the treatment of pain, inflammation, viral diseases and cancer, enhancement of the bioavailability of other drugs, as well as repellent/insecticidal properties against stored product and crop insects were confirmed [16]. According to Bakkali et al. [17] in natural habitats the essential oils compounds may play important roles in the protection of the plants as antibacterials, antivirals, antifungals, insecticides and also against herbivores by reducing their appetite for such plants or by repelling undesirable others.
Our chemical composition indicates that the compounds found in G. rosmarinifolia essential oil potentially have several biological roles. Among others, diterpenes contributing to 30% of G. rosmarinifolia composition could have beneficial effects as bactericides, as protection against free radical cell damages, as anti-inflammatory and in the treatment of cancer, among others [18]. As reported by Islam [19] diterpenes may act as anticancer alone or in combination with other diterpenes or anticancer drugs with synergic effects. In particular, phytol, occurring in G. rosmarinifolia essential oil to 4.1%, can induce apoptosis in human gastric adenocarcinoma cells and its cytotoxic activity has been demonstrated in vitro for several tumor cell lines [20]. Moreover, the diterpenes have also evident actions against toxic substances that cause cytogenotoxic damages in biological systems [19]. In an ecological context, they may confer to plants resistance against pests or pathogens [21].
A hydroxy-methyl-naphthoquinone is also among of the main compounds (5.3%) found in the essential oil of G. rosmarinifolia. It was recognized as a naphotoquinones belonging to hydroxy-methyl-naphthoquinone since its mass spectrum and its linear retention indices are very similar to those of other known isomers of hydroxyl-methyl-naphthoquinones (e.g. plumbagin, 7-methyl-juglone). It is interesting to note that naphthoquinones are biosynthesized in several plant families (e.g. Plumbaginaceae, Juglandaceae, Boraginaceae, Iridaceae, Verbenaceae, Scrophulariaceae, Gentianaceae, Droseraceae, and Euphorbiaceae, among others) as well as in algae, fungi, some animals and also as products of the metabolism in some bacteria [22]. From an ecological point of view, naphthoquinones act as chemical defense for many plants and several naphthoquinones are essentials in the biosynthesis of many molluscicidal and insecticidal compounds (e.g. 2-hydroxy-1,4-naphthoquinone derivatives) [22]. Furthermore, naphthoquinones and their derivatives are compounds with important pharmacological activities such as anticancer, antibacterial, antifungal, antiviral and anti-parasitic (e.g. antimalarial and antileishmania) [23, 24]. Pharmacological activities showed by naphthoquinones and derivatives can be explicated through two mechanisms: (1) as pro-oxidants, reducing oxygen to reactive oxygen species (ROS); and (2) as electrophiles, forming covalent bonds with tissue nucleophiles [25, 26]. According to López et al. [22], hydroxy-naphthoquinones and their derivatives are promising compounds for treating disease and for pest control. Several natural compounds exert its antitumor activity through anti or pro-oxidant mechanisms. In the present study, G. rosmarinifolia essential oil induces a strong suppressive growth effects in all tested cancer cell lines, probably through an increase in free radical generation due to diterpenes and hydroxy-methyl-naphthoquinone (Table 1) which are the main compounds found in this oil [19, 25, 26].
Our previous data on the same tumor cellular models, demonstrated that the redox perturbation due to natural compounds led to inhibition of NF-κB, a transcriptional factor often constitutively activated in many type of cancers and an important target for antitumor therapy [11, 27]. It would be interesting to assess the chemical structure of the tentatively identified hydroxy-methyl-naphthoquinone. Further studies should be also necessary to confirm if the diterpenes and this hydroxy-methyl-naphthoquinone are NF-κB inhibitors in these cancer models and to evaluate their possible use as anticancer drugs.
Conclusions
Our results show for the first time the antitumoral and pro-oxidant activities of G. rosmarinifolia essential oil. G. rosmarinifolia thus represents a resource of pharmacologically valuable compounds and we speculate that its anticancer property could be linked to the high content in diterpenes and naphthoquinone. However, further experiments must be conducted to identify molecular pathway in which the oil compounds are involved.
Acknowledgments
This work was supported by grant from MIUR-ITALY PRIN2015 “Top-down and Bottom-up approach in the development of new bioactive chemical entities inspired on natural products scaffolds” (Project N. 2015MSCKCE_003).
We thank Francesca Tavella and Giovanni Macaluso for their support during the collection of the plants.
References
- 1.
Castovejo S. Flora Ibérica. Plantas vasculares de la Peninsula Iberica e Islas Baleares. Real Jardín Botánico, CSIC: Boraginaceae, Madrid. 2012, Volume 11. ISBN 9788400094157.
- 2.
Crellin JK, Philpott J, Bass ALT. Herbal medicine past and present: A reference guide to medicinal plants. Durham, USA, Duke University Press; 1990.
- 3.
Khan IA, Abourashed EA. Leung’s encyclopedia of common natural ingredients: Used in food, drugs and cosmetics. John Wiley & Sons, Hoboken, New Jersey, USA; 2009.
- 4. Ferreres F, Vinholes J, Gil-Izquierdo A, Valentão P, Gonçalves RF, Andrade PB. In vitro studies of α-glucosidase inhibitors and antiradical constituents of Glandora diffusa (Lag.) DC Thomas infusion. Food Chem. 2013; 136: 1390–1398. pmid:23194539
- 5. Thomas DC, Weigend M, Hilger HH. Phylogeny and systematics of Lithodora (Boraginaceae-Lithospermeae) and its affinities to the monotypic genera Mairetis, Halacsya and Paramoltkia based on ITS1 and trnLUAA-sequence data and morphology. Taxon. 2008; 57: 79–97.
- 6. Ferrero V, Chapela I, Arroyo J, Navarro L. Reciprocal style polymorphisms are not easily categorised: the case of heterostyly in Lithodora and Glandora (Boraginaceae). Plant Biol. 2011; 13: 7–18.
- 7.
Hassler M. World Plants: Synonymic Checklists of the Vascular Plants of the World (version Feb 2017). In: Species 2000 & ITIS Catalogue of Life, 2017 Annual Checklist (Roskov Y., Abucay L., Orrell T., Nicolson D., Bailly N., Kirk P.M., et al. eds.) 2018. www.catalogueoflife.org/annual-checklist/2017.
- 8. Ferrero V, Arroyo J, Vargas P, Thompson JD, Navarro L. Evolutionary transitions of style polymorphisms in Lithodora (Boraginaceae). PPEES. 2009; 11: 111–125.
- 9. Ferrero V, Arroyo J, Castro S, Navarro L. Unusual heterostyly: style dimorphism and self-incompatibility are not tightly associated in Lithodora and Glandora (Boraginaceae). Ann Bot. 2012; 109: 655–665. pmid:21985797
- 10. Fernandes F, Andrade PB, Ferreres F, Gil-Izquierdo A, Sousa-Pinto I, Valentão P. The chemical composition on fingerprint of Glandora diffusa and its biological properties. Arabian J Chem. 2017; 10: 583–595.
- 11. Notarbartolo M, Poma P, Perri D, Dusonchet L, Cervello M, D'Alessandro N. Antitumor effects of curcumin, alone or in combination with cisplatin or doxorubicin, on human hepatic cancer cells. Analysis of their possible relationship to changes in NF- κB activation levels and in IAP gene expression. Cancer Lett. 2005; 224: 53–65. pmid:15911101
- 12. Labbozzetta M, Notarbartolo M, Poma P, Maurici A, Inguglia L, Marchetti P, et al. Curcumin as a possible lead compound against hormone-independent, multidrug-resistant breast cancer. Ann NY Acad Sci. 2009; 1155: 278–283. pmid:19250217
- 13.
Adams RP. Identification of essential oil components by gas chromatography/mass spectrometry. Allured Publishing Corporation, Carol Stream, Illinois. 2007.
- 14. Blois MS. Antioxidant determinations by the use of a stable free radical. Nature. 1958; 181: 1199–1200.
- 15. Brand-Williams W, Cuvelier ME, Berset C. Use of a free radical method to evaluate antioxidant activity. Food Sci Technol. 1995; 28: 25–30.
- 16. Adorjan B, Buchbauer G. Biological properties of essential oils: an updated review. Flavour Fragr J. 2010; 25: 407–426.
- 17. Bakkali F, Averbeck S, Averbeck D, Idaomar M. Biological effects of essential oils–a review. Food Chem Toxicol. 2008; 4: 446–475.
- 18. Scotti L, Ishiki H, Junior FJ, Santos PF, Tavares JF, Silva MS, et al. Theoretical research into anticancer activity of diterpenes isolated from the paraiban flora. Nat Prod Com. 2014; 9: 911–914.
- 19. Islam MT. Diterpenes and Their Derivates as Potential Anticancer Agents. Phytother Res. 2017; 31: 691–712. pmid:28370843
- 20. Song Y, Cho SK. Phytol Induces Apoptosis and ROS-Mediated Protective Autophagy in Human Gastric Adenocarcinoma AGS Cells. Biochem. Anal Biochem. 2015; 4: 211.
- 21. Zerbe P, Bohlmann J. Plant diterpene synthases: exploring modularity and metabolic diversity for bioengineering. Trends Biotechnol. 2015; 33: 419–428. pmid:26003209
- 22. López LLI, Flores N, Daniel S, Silva Belmares SY, Sáenz Galindo A. Naphthoquinones: biological properties and synthesis of lawsone and derivatives-a structured review. Vitae. 2014; 21: 248–258.
- 23. Kumar BS, Ravi K, Verma AK, Fatima K, Hasanain M, Singh A, et al. Synthesis of pharmacologically important naphthoquinones and anticancer activity of 2-benzyllawsone through DNA topoisomerase-II inhibition. Bioorg Med Chem. 2017; 25: 1364–1373. pmid:28094224
- 24.
Ramos-Peralta L, López-López LI, Silva-Belmares SY, Zugasti-Cruz A, Rodríguez-Herrera R, Aguilar-González CN. Naphthoquinone: Bioactivity and Green Synthesis: Badajoz, Spain. 2015.
- 25. Murakami K, Haneda M, Iwata S, Yoshino M. Effect of hydroxy substituent on the pro-oxidant action of naphthoquinone compounds. Toxicol In Vitro. 2010; 24: 905–909. pmid:19961919
- 26. Kumagai Y.; Shinkai Y.; Miura T.; Cho A. K. The chemical biology of naphthoquinones and its environmental implications. Annu. Rev. Pharmacol. Toxicol. 2012; 52: 221–247. pmid:21942631
- 27. Poma P, Labbozzetta M, D'Alessandro N, Notarbartolo M. NF-κB Is a Potential Molecular Drug Target in Triple-Negative Breast Cancers. OMICS. 2017; 21: 225–231. pmid:28388298