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Friday 19 January 2018

Structural and antitrypanosomal data of different carbasones of piperitone

Data in Brief Volume 9, December 2016, Pages 1039-1043 open access Data Article Author links open overlay panelAmoussatouSakiriguiaFernandGbaguidiabUrbain C.KasséhincJacquesPoupaertdGeorges C.AccrombessiaSimeon O.Kotchonief a University of Abomey-Calavi (UAC), Faculty of Sciences and Technics (FAST), Department of Chemistry, Laboratory of Physic and Synthesis Organic Chemistry (LaCOPS), 01 PB: 4521, Cotonou, Benin b Laboratoire de Pharmacognosie, Centre Béninois de Recherche Scientifique et Technique, 01 PB 06 Oganla, Porto-Novo, Benin c Laboratoire de Chimie Pharmaceutique Organique, Faculté des Sciences de la Santé, Université d׳Abomey-Calavi, Campus du Champ de Foire, 01 BP 188, Cotonou, Bénin d Université catholique de Louvain (UCL), Louvain Drug Research Institute (LDRI), B1 7203 Av. E. Mounier 72, B-1200 Bruxelles, Belgium e Department of Biology, Rutgers University, 315 Penn St., Camden, NJ 08102, USA f Center for Computational and Integrative Biology, 315 Penn St., Camden, NJ 08102, USA Received 23 August 2016, Revised 2 November 2016, Accepted 14 November 2016, Available online 18 November 2016. crossmark-logo Show less https://doi.org/10.1016/j.dib.2016.11.044Get rights and content Under a Creative Commons license Abstract This article reports data on four carbazones of piperitone: semicarbazone 1, thiosemicarbazone 2, 4-phenyl semicarbazone 3 and 4-phenyl thiosemicarbazone 4 prepared directly in situ from essential oil of Cymbopogon schoenantus, whose GC-FID and GC–MS analysis revealed piperitone as major component (68.20%). The structures of hemi-synthesized compounds were confirmed by high throughput IR, MS, 1H and 13C NMR based spectrometric analysis. Their antiparasitic activities were evaluated in vitro on Trypanosoma brucei brucei (Tbb). The compound 3 (IC50=8.63±0.81 µM) and 4 (IC50=10.90±2.52 µM) exhibited antitrypanosomal activity, 2 had a moderate activity (IC50=74.58±4.44 µM) but 1 was void of significant activity (IC50=478.47 µM). The in vitro tests showed that all compounds were less cytotoxic against the human non cancer fibroblast cell line (WI38) (IC50>80 µM) while only 2 (IC50=21.16±1.37 μM) and 4 (IC50=32.22±1.66 µM) were cytotoxic against the Chinese Hamster Ovary (CHO) cells and toxic on Artemia salina (Leach) larvae. Piperitone 4-phenyl semicarbazone 3, the best antitrypanosomal compound, showed also a selectivity index (SI) higher than 7 on the larvae and the tested cells and therefore might be further studied as antitrypanosomal agent. Also, all compounds except 3 showed selectivity between the two tested cell lines (SI>2). This data reveals for the first time the antitrypinosomal properties of thiosemicarbazones, their cytotoxicity on mammalian cells as well as their activities against Tbb and A. salina Leach. Previous article in issueNext article in issue Keywords Hemi-synthesizedPiperitone carbazonesEssential oilCymbopogon shoenantusTrypanosoma brucei bruceiArtemia salina Specifications Table Subject area Chemistry, Biology, Phytochemistry, Analytical Chemistry, Medicinal Biology More specific subject area Pharmacognosy Type of data Tables, text file, figures How data was acquired FT-IR (Perkin-Elmer Frontier 286™), GC–MS (Thermo-Quest), NMR (Bruker), in vitro bioassays Data format Analyzed Experimental factors Structural elucidation and antitrypanosomal activities of novel compounds derived from medicinal plants Experimental features Thiosemicarbazones were sysnthesized from Cymbopogon schoenatus essential oil and fully characterized using GC–MS, FT-IR, and NMR and their antiparasitic activities evaluated in vitro on Trypanosoma brucei brucei (Tbb) Data source location Cotonou, Benin Data accessibility The data is available with this article Value of the data • 4-phenyl semicarbazone (3) and 4-phenyl thiosemicarbazone (4) can be used as asantitrypanosomal drugs against sleeping sickness. • 4-phenyl semicarbazone (3) can be used with no cytotoxicity effect. • Data shows that Cymbopogon schoenatus essential Oil can be used as an antiparasitic agent. 1. Data The data of this study provides the chemical composition characteristics (Supplementary data), the antitrypanosomal activities and the cytotoxicity levels of novel in situ hemisynthesis of thiosemicarbazone derivatives from Cymbopogon schoenatus essential oil (Tables 1 and 2). Table 1. Chemical composition of Cymbopogon schoenantus essential oil. aCompounds bRI %Area myrcene 991 0.18 δ-2-carene 1000 19.38 p-cymene 1025 0.13 limonene 1030 3.16 Cis-β-ocimene 1036 0.19 trans-β-ocimene 1047 0.13 Cis-menth-2-en-1-ol 1126 1.02 trans-menth-2-en-1-ol 1144 0.68 citronellal 1153 0.12 α-terpineol 1196 1.29 trans-piperitol 1210 0.37 eucarvone 1249 0.22 piperitone 1262 68.20 β-elemene 1390 0.21 β-caryophyllene 1421 0.40 elemol 1548 1.20 eranyle butyrate 1553 0.30 carayophyllene oxide 1584 0.20 γ-eudesmol 1632 0.20 α-cadinol 1656 0.53 Total 98.11 a Compounds listed in order of elution from HP-5-MS column. b Retention indice (RI) on HP5-MS. Table 2. in vitro antitrypanosomal, cytotoxicity and toxicity against A. salina Leach, and selectivity indices of hemi-synthesized compounds. Composés 1 2 3 4 Antitrypanosomal activity (IC50μM) Tbb 478.47±7.19c 74.58±4.44b 8.63±0.81a 10.90±2.52a activity low moderate trypanocidal trypanocidal Toxicity againstA. salinaLeach LC50 (μM) 373.20±6.60c 86.66±2.33b 85.52±2.28b 32.22±1.66a Activity Not toxic Not toxic Not toxic Toxic Cytotoxicity (IC50μM) WI38 (μM) 481.48±6.69c 143.38±4.89b 80.95±9.15a 134.09±5.45b Activity Not cytotoxic Not cytotoxic Not cytotoxic Not cytotoxic CHO (μM) 213.54±7.56c 21.16±1.37a 65.87±4.8b 65.35±4.02b Activity Not toxic Cytotoxic Moderate Moderate αSelectivity indices LC50/tbb 0.78 1.16 9.91 2.96 WI38/ tbb 1.01 1.92 9.38 12.30 CHO/tbb 0.45 0.28 7.63 6.00 WI38/CHO 2.25 6.78 1.23 2.05 1: piperitone semicarbazone, 2: piperitone thiosemicarbazone, 3: piperitone 4-phenyl semicarbazone, 4: piperitone 4-phenyl thiosemicarbazone. Tbb: Trypanosoma brucei brucei, αSelectivity index (SI): IC50 (WI38)/IC50 (Tbb), IC50: sample concentration providing 50% death of cells or parasites, LC50: sample concentration providing 50% death of larvae, WI38: human normal fibroblast cells, CHO: Chinese Hamster Ovary cells; Data in the same line followed by different letters are statistically different by Student׳s t-test (P<0.05). Values are means±standard deviation of three separate experiments. 2. Experimental design, materials and methods 2.1. Analysis of the essential oil by GC-FID and GC–MS The GC-FID analysis was carried out on a FOCUS GC (Thermo Finigan; Milan, Italy) using the following operating conditions: HP 5MS column (30 m×0.25 mm, film thickness: 0.25 μm) (J&W Scientific Column of Agilent Technologies, USA); injection mode: splitless; injection volume: 1 µL (TBME solution); flow of split: 10 ml/min; splitless time: 0.80 min; injector temperature: 260 °C; oven temperature was programmed as following: 50 °C–250 °C at 6 °C/min and held at 250 °C for 5 min; the carrier gas was helium with a constant flow of 1.2 mL/min; FID detector temperature was 260 °C. The data were recorded and treated with the ChromCard software. The quantification was completed by the calculation of the areas under curve of the peaks (GC-FID, normalization process) and the identification of compounds by comparison of the retention indices (RI) with the references. The GC–MS analysis were carried out using a TRACE GC 2000 series (Thermo-Quest, Rodano, Italy), equipped with an autosampler AS2000 Thermo-Quest operating in the electronic impact mode at 70 eV. HP 5MS column (30 m×0.25 mm, film thickness: 0.25 μm). The coupling temperature of the GC was 260 °C and the temperature of the source of the electrons was 260 °C. The data were analyzed with the Xcalibur 1.1 software (ThermoQuest). The mass spectra of the peaks were analyzed and compared with references, literature and the NIST/EPA/NIH database. The individual components of the volatile oils were identified by comparison of their relative retention times with those of authentic standard references, computer matching against commercial library and custom proprietary library mass spectra made from pure substances and components of known oils. Mass spectrometry literature data were also used for the identification. Quantification (expressed as percentages) was carried after normalization using peak areas obtained by FID. 2.2. Hemi-synthesized compounds identification The melting points were taken on a fusionometer type electrothermal 1A 9000. The IR spectra were recorded on a Perkin-Elmer FTIR 286. The frequencies of absorption bands were expressed in cm−1. The NMR spectra were registered on a Bruker 500 in chloroform-d6 (CDCl3) or dimethylsulfoxide-d6 (DMSO-d6) which frequencies for 1H and 13C were 400 MHz and 100 MHz respectively. Chemical shifts were given in parts per million (ppm) relative to tetra-methyl silane (TMS) as an internal reference. Multiplicity was designated as singlet (s), triplet (t), doublet (d) and multiplet (m). MS spectrometric data of compounds were reported in APCI mode. The semicarbazones and thiosemicarbazones were synthesized by the following methods: Piperitone semicarbazone (1): to a stirred mixture of 304 mg of C. schoenantus essential oil dissolved in 3 ml of ethanol at 95° was added 1 mmol (111.5 mg) of semicarbazide hydrochloride dissolved in 2 ml of distilled water. 5 drops of triethylamine were added to a mixture after a minute of stirring. Then crystals appeared after 5 min of agitation but the stirring was maintained for another hour. The resulting crystals were filtered, washed until neutral, dried, weighed and then recrystallized in ethanol (Fig. 1). Piperitone substituted semicarbazone and thiosemicarbazones (2, 3, 4): To a stirring of the mixture of 304 mg of C. schoenantus essential oil dissolved in 3 ml of ethanol was added 1 mmol of semicarbazide or substituted (thio) semicarbazides dissolved in 3 ml of hydrochloric acid (1 N). After the appearance of crystals between one to three minutes, stirring was continued for one hour. The resulting crystals were filtered, washed until neutral, dried, weighed and recrystallized from ethanol (Fig. 2). Fig. 1 Download high-res image (86KB)Download full-size image Fig. 1. Hemi-synthetic routes of semicarbazones. Fig. 2 Download high-res image (84KB)Download full-size image Fig. 2. Hemi-synthetic routes of thiosemicarbazones. 2.3. Bioassay tests The Antitrypanosomal activity, toxicity test, and cytotoxicity assay were done according to Räz et al. [6], Sleet and Brendel [7] and Stevigny et al. [8], respectively. Acknowledgements We gratefully acknowledge the financial support of Brurroughs Wellcome Fund (BWF) collaborative Research Travel Grant (CRTG) ID #1015189 to SOK. Transparency document. Supplementary material Download Acrobat PDF file (1MB)Help with pdf files Supplementary material . Appendix A. Supplementary material Download Word document (14KB)Help with docx files Supplementary material . References [6] B. Räz, M. Iten, Y. Grether-Bühler, R. Kaminsky, R. Brun The Alamar Blue assay to determine drug sensitivity of African trypanosomes (T.b. rhodesiense and T.b. gambiense) in vitro Acta Trop., 68 (2) (1997), pp. 139-147 ArticlePDF (103KB)View Record in Scopus [7] R.B. Sleet, K. K Brende Improved methods for harvesting and counting synchronous populations of Artemia nauplii for use in developmental toxicology Ecotoxicol. Environ. Saf., 7 (5) (1983), pp. 435-446 ArticlePDF (3MB)View Record in Scopus [8] C. Stevigny, S. Block, M.C. Pauw-Gillet, E. de Hoffmann, G. Llabres, V. Adjakidje, J. Quetin-Leclercq Cytotoxic aporphine alkaloids from Cassytha filiformis Planta Med., 68 (11) (2002), pp. 1042-1044 CrossRefView Record in Scopus Other Important Links and Databases [1] G. Nonviho, V.D. Wotto, J.P. Noudogbessi, F. Avlessi, M.A kogbeto, D.C.K. Sohounhloué, Insecticidal activities of essential oils extracted from three species of Poaceae on Anopheles gambiae spp., major vector of malaria, CICBIA 11 (4) (2010) 411–420. [2] X. Du, C. Guoi, E. 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Agents Chemother. 49 (1), 2005, 176–182 © 2016 The Author(s). Published by Elsevier Inc.