ABSTRACT

Objective:

The aim of the current research is to evaluate the antiparasite effects of compounds isolated from marine ascidian tunicates on Trichomonas vaginalis.

Methods:

Ascidian tunicates after collection were cut into small pieces, freeze-dried, and powdered. The resulting material was subjected to extraction in double-distilled water, ethanol, n-hexane, and dichloromethane. To fractionate the extracts and identify the most bioactive compound, silica gel column chromatography and GC-M/S analysis were used.

Results:

Fraction 18 of silica gel column chromatography of ethanol extract was the most effective against T. vaginalis. The respective IC₅₀, CC₅₀, and SI values for fraction 18 were 28.62 μg/mL, ˃800 μg/mL, and ˃27.95. GC-M/S analysis of this fraction identified a major phenolic compound (2, 4-bis (1, 1-dimethyl ethyl), whose toxicity against vero cells was only 10.15%.

Conclusion:

The ethanolic fraction containing phenol-2,4-bis (1,1-dimethylethyl), which has a potent lethality effect on T. vaginalis, may be considered as an antiparasite drug candidate.

Keywords: Trichomonas vaginalis, tonicate, ascidians, chromatography, GC-MS, metronidazole

INTRODUCTION

Trichomonas vaginalis (T. vaginalis) as a parasitic protozoan is pathogenic agent of trichomoniasis. It is the most common sexually transmitted non-viral disease with worldwide spread. This infection is asymptomatic in some women and most men, but it can cause various side effects in women, such as unhealthy pregnancy, infertility, pelvic inflammatory disease and cervical malignancy. Men with trichomoniasis are mostly asymptomatic but symptomatic infected women have a wide range of clinical symptoms from mild to severe (1-3). The global incidence of Trichomoniasis is 276 million cases per year and is more common than gonorrhea, syphilis and chlamydia infections (4). Trichomoniasis causes at least a two-fold increase in the risk of HIV transmission as well as a four-fold increase in the spread of the virus (5,6). Studies in Iran have reported the prevalence of trichomoniasis as follows: 9.2% in Tabriz, 3.3% in Zanjan, 3.2% in Tehran, 2% in Yazd and Kashan, and 1.2% in Hamadan city (7-12).

Metronidazole and tinidazole are the only FDA-approved drugs for the treatment of trichomoniasis, but there have been reports of drug resistance and treatment failure against these medications (13-15).

Although research on the effects of the natural substances against T. vaginalis is scarce in scientific databases but some studies have published reports on the effects of marine organisms such as seaweeds, microorganisms and marine fungi against T. vaginalis (16-20). Tunicates are a diverse group of marine invertebrate animals and members of the phylum chordata and subphylum tunicata (21).

To date, 3051 species of tunicates have been identified. These marine organisms were classified into four major classes: Ascidiacea, thaliacea, apendicularins and sorberacea, consisting of 2800 species in ascidiacea, 72 species in thaliacea and 69 species in appendicular (21,22). Ascidians have various chemical defenses to combat predators in the marine ecosystem, most of which are synthesized by symbiotic bacteria. These marine organisms are the deposits of various chemical compounds such as didemnin, appelidin and trabectedin which are effective against many types of cancers. In addition, various studies indicate the presence of antimicrobial compounds in isolated compounds from Ascidians (23,24).

Most of the compounds extracted from Tunicates have antibiotic, antitumor, antiviral and immunosuppressive activities (25). The aim of the current study was to evaluate the effect of the isolated compounds from the ascidian tunicates on T. vaginalis viability.

METHODS

Sample Collection

Ascidian tunicates were collected on ice from the Haleh shure of, Bushehr province, Iran. The samples were washed with tap water and distilled water to remove the contaminants and stored at -70 °C until used.

Extraction

To prepare the aqueous, ethanol, n-hexane and dichloromethane ascidians extracts, the samples were cut into small pieces, chopped and were freeze-dried. The dried samples were powdered by a home grinder. The samples were extracted in double distilled water and in ethanol 70% (V/V) at 40 °C by overnight maceration with interval shaking. Also, the n-hexane and dichloromethane extractions were performed using Soxhlet extractor. All extracts were filtered with filter paper (Watman, no.1, Merk, Germany) and the filtrate was concentrated under vacuum to eliminate the solvent using a rotary evaporator apparatus (Laborota 4000, Heidolph, Germany), dried, powdered and reserved at -20 °C as the crude ascidian extracts.

TLC and Silica Gel Column Chromatography

Thin-layer chromatography (TLC Silica gel 60 F₂₅₄) was used to choice the appropriate solvent and pre-evaluation of sample solubility for next silica gel G-60 column chromatography. After each column chromatography the TLC were performed for identity and composition analysis of the obtained fractions.

Column Chromatography

The silica gel G-60 column chromatography was performed using (5×70 cm) glass column and ethanol as the mobile phase. Then, the ethanolic crude extract which having more anti parasitic activity was loaded on the column and every 15 minutes the 2.5 mL fractions were recovered. The resulting fractions were concentrated, dried and refrigerated until used.

GC-MS Analysis

The ascidian F18 fraction with the most cytotoxic effect on T. vaginalis was subjected to the Gas chromatography-mass spectroscopy (GC-M/S) analysis equipped with Chemstation software. For this purpose, 1 µL of samples was injected to the GC-MS instrument equipped with HP-5MS and mass detector, placed at 50 °C for 1 min with a heating rate of 1 °C/min. Then, used 300 °C with a heating rate of 15 °C/min, hold time of 20 min, run time of 66/37 min, injector temperature of 120 °C, MS detector temperature of 230 °C, ion source and quadrupole temperature of 230 and 150 °C, respectively. Helium gas with flow of 21.7 mL/min and pressure of 4 psi at a ratio of 30:1 ratio were used as the carrier. In this experiment, a quadrupole mass spectrometer with ionization energy of 70eV was used. The corresponding chemical structure of each peak was identified by comparing the mass spectra obtained from the chromatogram with the National Institute of Standards and Technology (NIST) library and by searching the PubChem database. After detecting the name, molecular formula and chemical structure of each compound, the biological and industrial applications of each compound were determined using the aforementioned database.

Evaluation of Ascidian Effects on T. vaginalis

The T. vaginalis was obtained from Pasteur Institute of Iran. It was cultured in diamond medium (Merk, Germany) at 37 °C. After the parasite reached the logarithmic phase, 125 µL of the culture medium containing 1×10⁶ trophozoites were transferred to the 96 well flat bottom microplate and 125 µL of 20, 40, 80, 100, 200, 400 and 800 µg/mL doses from aqueous and organic extracts, silica gel G-60 column chromatography fractions, (as tests) were added to the wells containing T. vaginalis and incubated at 37 °C (two test sets, 24 and 48 h) The metronidazole as positive control was used.

For cell viability evaluations, the trypan blue dye exclusion and MTT assay tests were used. All experiments were performed in triplicate.

Cytotoxicity Assay

For cytotoxicity evaluations on mammalian cells, the vero cells were affected by the obtained ascidian fractions. Ten thousand of vero cells were cultured (DMEM medium, Gibco, USA) at 37 °C and 5% CO₂for 48 h in pre- trypsinized, PBS washed micoplate in the presence of 20, 40, 80, 100, 200, 400, 800 µg/mL of ascidian fractions. Also, the wells containing only vero cells (as negative control) and cell-free wells (as blank) were considered. The cell viability was performed by the trypan blue exclusion and MTT assay test.

Statistical Analysis

The experiments were replicated three times. Statistical analysis was performed using SPSS Software version: 16.0 (SPSS Inc., Chicago, IL) for data analysis, Kruskal-Wallis test and Mann-Whitney U test were used and p-value <0.05 was considered significant.

RESULTS

The results showed that the ascidian extracted in water, ethanol, n-hexane and dichloromethane solvents have increasing lethal effect on T. vaginalis in dose and time dependent approach. The lowest percentage of lethality was recorded for the water extract at the concentration of 20 µg/mL after 24 h incubation, which almost had no lethal effect. But, the highest lethal effect was for the ethanolic extract, which at dose of 800 µg/mL caused 60% of T. vaginalis trophozoites to be killed after 48 hours (Table 1).

Table 1

Separation and identification of ethanolic extract by silica gel G-60 column chromatography resulted in the fractions which subjected to subsequent bioassays. The evaluation of cytotoxic effects of obtained fractions (tests) and the metronidazole (positive control) at 20, 40, 80, 100, 200, 400 and 800 µg/mL doses on the T. vaginalis viability by trypan blue dye exclusion and MTT cytotoxicity assay revealed that fraction 18 was more active against target cells (Table 2).

Table 2

Fraction 18 at a dose of 80 µg/mL showed 100% toxicity (Table 2) which the IC₅₀ was 28.62 µg/mL (Table 3).

Table 3

The GC-M/S analysis was used to identify the chemical composition of the bio-active fractions. The analysis of GC-M/S peaks and searching in the NIST library and PubChem database led to the identification of the phenol-2, 4-bis (1,1-dimethylethyl) compound in Fraction 18 (Table 4).

Table 4

Also, the results showed that the metronidazole (as positive control) at dose of 80 µg/mL caused 100% toxicity after 24-h incubation and at 40 µg/mL after 48 h incubation (Table 2).

The vero cell line was used to evaluate the toxicity of ascidian compounds on mammalian cells. Incubation of vero cells in the presence of fraction 18 at doses of 20-800 µg/mL showed, that this fraction has the most inhibition effect on T. vaginalis growth with very low toxicity against vero cells although at high doses (Table 5).

Table 5

DISCUSSION

Trichomoniasis is the most common non-viral sexually transmitted infection. There have been many reports of a relatively high incidence of this infection especially, in developing countries (4,7-11). On the other hand, there are frequent and reliable reports of the underlying cause of this infection for cervical and prostate malignancies in men, as well as facilitating HIV transmission (1-6).

Given that no approved vaccine has been available to prevent this infection so far, we need to think about a new drug to treat this infection effectively. The current treatments of choice for trichomoniasis are metronidazole and tinidazole. Studies have shown that metronidazole not only has significant side effects, but also there are reports of many cases of treatment failure and drug resistance (13-15). So, finding an effective and low-cost drug to treat this infection is one of the priorities.

In the past few decades, marine organisms have been one of the promising sources for finding medicinal and nutritional compounds. Among the wide range of marine organisms, Tunicates, especially the Ascidians, have received special attention, and promising reports have been published on the efficacy of secondary metabolites extracted from these marine organisms against bacteria, viruses, fungi, and malignancies, but there are few studies to evaluate the effect of these metabolites against T. vaginalis (26-35). Our study showed that among the solvents used to achieve the extracts from ascidians, ethanol as a suitable solvent was able to extract more effective compounds (60% parasite death at 800 µg/mL dose). The silica gel G-60 column chromatography resulted in the separation of 18 different fractions and, the bioassay against T. vaginalis revealed that fraction 18 showed significant dose and time dependent lethal effects. The IC₅₀, CC₅₀ and SI values were 28.62 µg/mL, ˃800 µg/mL and, 27.95 respectively. Cytotoxic analysis of F18 against vero cells showed that this fraction at the concentration of 800 µg/mL had the lethality rate of 10.15% and the maximum concentration of this fraction (800 µg/mL) could not have a 50% inhibitory effect against vero cells, so, it was not possible to calculate the CC₅₀ definitive values for this fraction. Therefore, the CC₅₀ values for all fractions were estimated as ˃800 µg/mL. Due to the very low toxicity of all fractions against vero cells, especially the fraction18 that have shown high toxicity against T. vaginalis, the calculated SI value for this fraction was >27.95.

The GC-M/S analysis of fraction 18 showed that, phenol-2,4-bis (1,1-dimethylethyl) with the chemical formula of C14H22O; is a phenolic compound. Some studies confirmed the antioxidant (36) and antifungal activity of phenol-2,4-bis (1,1-dimethylethyl) against Aspergillus niger, Fusarium oxysporum and Penicillium chrysogenum (37). Also, in a study which investigated the phenol-rich extracts from plants against Giardia lamblia, different concentrations of these extracts inhibited the growth of the protozoa in the culture medium. In that study, the most inhibitory effect was 275 µg/mL (38). In another study, the effects of extracts containing phenolic compounds at the concentrations of 125 and 250 mg/mL were investigated on L. infantum, Leishmania braziliensis and Trypanosoma cruzi in the culture medium and the results as lethality percentages were 54.27%, 80.39% for Leishmania infantum, and 68.61%. 80.159% for Leishmania braziliensis and 54.45%, 22.26% for Trypanosoma cruzi respectively (39). Another study evaluated the ethanol extract of three plant species containing phenolic compounds against Leishmania spp. and Trypanosoma spp., and found that the lethality percentages were 63.8% for Leishmania braziliensis, 95% for Leishmania infantum and 63% for Trypanosoma cruzi (40). As in our results, Ezz Eldin and Badawy (41) investigated the effects of two plant extracts containing phenolic compounds on T. vaginalis and showed that these compounds have an increasing lethality in time and dose dependent manner.

CONCLUSION

The biological assay of F18, containing the phenol-2,4-bis (1,1-dimethylethyl, showed that this fraction at the concentration of 80 µg/mL caused 100% parasite death and its IC₅₀, CC₅₀, and SI values were 28.62 µg/mL, ˃800 µg/mL and ˃27.95 respectively. Then, based on the bioassay results from the evaluation of fraction F18 effect on the T. vaginalis, it showed potent anti-parasite effects. Other studies on the phenolic potential compounds such as phenol-2,4-bis (1,1-dimethylethyl) and other alkaloid derivatives indicated a wide range of biological effects and caused death or inhibition of cancer cells, bacteria, viruses, fungi and the parasites. Therefore, our study indicates that ascidians, which are a source of biologically active compounds especially the phenolic, with anti T. vaginalis activity, can be considered as a therapeutic drugs after further more details investigations.

Acknowledgments

This work was supported by Research Deputy of Bushehr University of Medical Sciences, we would like to thank the Vice-chancellor of Research of Bushehr University of Medical Sciences for financial support.

Ethics

Ethics Committee Approval: This study was approved in Research Committee of Bushehr University of Medical Sciences with ethics code IR.BPUMS.REC.1396.160.

Informed Consent: This study was conducted in vitro, so, it doesn’t involve any patients or human samples.

*Authorship Contributions

Design: M.F., Data Collection or Processing: H.M., A.B., S.K., M.K., M.F., Analysis or Interpretation: H.M., A.B., S.K., M.K., M.F., Writing: H.M., A.B., S.K., M.K., M.F.

Conflict of Interest: No conflict of interest was declared by the authors.

Financial Disclosure: This study was financially supported by the Vice-chancellor for Research of Bushehr University of Medical Sciences with grant no: 787.

References

Secor WE, Meites E, Starr MC, Workowski KA. Neglected parasitic infections in the United States: trichomoniasis. Am J Trop Med Hyg 2014; 90: 800-4.

Edwards T, Burke P, Smalley H, Hobbs G. Trichomonas vaginalis: Clinical relevance, pathogenicity and diagnosis. Crit Rev Microbiol 2016; 42: 406-17.

Kissinger P. Trichomonas vaginalis: a review of epidemiologic, clinical and treatment issues. BMC Infect Dis 2015; 15: 307.

World Health Organization. 2012. Global incidence and prevalence of selected curable sexually transmitted infections. World Health Organization, Dept. of Reproductive Health and Research, available from: http://www.who.int/reproductivehealth/publications/rtis/stisestimates/en/index.html

Vais RD, Heli H, Sattarahmady N, Barazesh A. A novel and ultrasensitive label-free electrochemical DNA biosensor for Trichomonas vaginalis detection based on a nanostructured film of poly (ortho-aminophenol). Synthetic Metals 2022; 287: 117082.

Kusdian G, Gould SB. The biology of Trichomonas vaginalis in the light of urogenital tract infection. Mol Biochem Parasitol 2014; 198: 92-9.

Nazari N, Zangeneh M, Moradi F, Bozorgomid A. Prevalence of trichomoniasis among women in kermanshah, iran. Iran Red Crescent Med J 2015; 17: e23617.

Nourian A, Shabani N, Fazaeli A, Mousavinasab SN. Prevalence of Trichomonas vaginalis in pregnant women in Zanjan, Northwest of Iran. Jundishapur Journal of Microbiology 2013; 6: e7258.

Rezaeian M, Vatanshenassan M, Rezaie S, Mohebali M, Niromand N, Niyyati M, et al. Prevalence of Trichomonas vaginalis using parasitological methods in Tehran. Iranian Journal of Parasitology 2009; 4: 43-7.

Bafghi AF, Aflatoonian A, Barzegar K, Ghafourzadeh M, Nabipour S. Frequency distribution of trichomoniasis in pregnant women referred to health centers of Ardakan, Meibod and Yazd, Iran. Jundishapur Journal of Microbiology 2009; 2: 132-9.

Arbabi M, Fakhrieh Z, Delavari M, Abdoli A. Prevalence of Trichomonas vaginalis infection in Kashan city, Iran (2012-2013). Iran J Reprod Med 2014; 12: 507-12.

Matini M, Rezaie S, Mohebali M, Maghsood A, Rabiee S, Fallah M, et al. Prevalence of Trichomonas vaginalis Infection in Hamadan City, Western Iran. Iran J Parasitol 2012; 7: 67-72.

Blaha C, Duchêne M, Aspöck H, Walochnik J. In vitro activity of hexadecylphosphocholine (miltefosine) against metronidazole-resistant and -susceptible strains of Trichomonas vaginalis. J Antimicrob Chemother 2006; 57: 273-8.

Upcroft JA, Dunn LA, Wal T, Tabrizi S, Delgadillo-Correa MG, Johnson PJ, et al. Metronidazole resistance in Trichomonas vaginalis from highland women in Papua New Guinea. Sex Health 2009; 6: 334-8.

Krashin JW, Koumans EH, Bradshaw-Sydnor AC, Braxton JR, Evan Secor W, Sawyer MK, et al. Trichomonas vaginalis prevalence, incidence, risk factors and antibiotic-resistance in an adolescent population. Sex Transm Dis 2010; 37: 440-4.

Gehrig S, Efferth T. Development of drug resistance in Trichomonas vaginalis and its overcoming with natural products. The Open Bioactive Compounds Journal 2009; 2: 21-8.

Watts KR, Tenney K, Crews P. The structural diversity and promise of antiparasitic marine invertebrate-derived small molecules. Curr Opin Biotechnol 2010; 21: 808-18.

Moo-Puc R, Robledo D, Freile-Pelegrin Y. Evaluation of selected tropical seaweeds for in vitro anti-trichomonal activity. J Ethnopharmacol 2008; 120: 92-7.

Cantillo-Ciau Z, Moo-Puc R, Quijano L, Freile-Pelegrín Y. The tropical brown alga Lobophora variegata: a source of antiprotozoal compounds. Mar Drugs 2010; 8: 1292-304.

Washida K, Koyama T, Yamada K, Kita M, Uemura D. Karatungiols A and B, two novel antimicrobial polyol compounds, from the symbiotic marine dinoflagellate Amphidinium sp. Tetrahedron Lett 2006; 47: 2521-5.

Satoh N, Rokhsar D, Nishikawa T. Chordate evolution and the three-phylum system. Proc Biol Sci 2014; 281: 20141729.

Palanisamy SK, Rajendran NM, Marino A. Natural Products Diversity of Marine Ascidians (Tunicates; Ascidiacea) and Successful Drugs in Clinical Development. Nat Prod Bioprospect 2017; 7: 1-111.

Casertano M, Menna M, Imperatore C. The Ascidian-Derived Metabolites with Antimicrobial Properties. Antibiotics (Basel) 2020; 9: 510.

George J, Sabapathi SN. Cellulose nanocrystals: synthesis, functional properties, and applications. Nanotechnol Sci Appl 2015; 8: 45-54.

Gerwick WH, Fenner AM. Drug discovery from marine microbes. Microb Ecol 2013; 65: 800-6.

Wu Wu C, Wang Y, Yang Y. Pestalotiopsis Diversity: Species, Dispositions, Secondary Metabolites, and Bioactivities. Molecules 2022; 27: 8088.

Ruprich J, Prout A, Dickson J, Younglove B, Nolan L, Baxi K, et al. Design, synthesis and biological testing of cyclohexenone derivatives of combretastatin-A4. Letters in Drug Design & Discovery 2007; 4: 144-8.

AbdElal SN. Synthesis of some new cyclohexene carboxylic acid derivatives as potent anti-tumor agents. J Chem Pharm Res 2013; 5: 168-77.

Roumy V, Fabre N, Portet B, Bourdy G, Acebey L, Vigor C, et al. Four anti-protozoal and anti-bacterial compounds from Tapirira guianensis. Phytochemistry 2009; 70: 305-11.

Bhardwaj V, Gumber D, Abbot V, Dhiman S, Sharma P. Pyrrole: a resourceful small molecule in key medicinal hetero-aromatics. Rsc Advances 2015; 5: 15233-66.

Qian X, Liang GB, Feng D, Fisher M, Crumley T, Rattray S, et al. Synthesis and SAR studies of diarylpyrrole anticoccidial agents. Bioorg Med Chem Lett 2006; 16: 2817-21.

Zhao S, Zhang X, Wei P, Su X, Zhao L, Wu M, et al. Design, synthesis and evaluation of aromatic heterocyclic derivatives as potent antifungal agents. Eur J Med Chem 2017; 137: 96-107.

Gilleran JA, Yu X, Blayney AJ, Bencivenga AF, Na B, Augeri DJ, et al. Benzothiazolyl and Benzoxazolyl Hydrazones Function as Zinc Metallochaperones to Reactivate Mutant p53. J Med Chem 2021; 64: 2024-45.

Moorkoth S, Joseph A, Srinivasan KK, Kutty G. Synthesis and evaluation of biological activity of imidazolidinone analysis of 2-aminochromone. Int J Pharm Biosci Technol 2013; 1: 130-41.

Demir B, Cerkez I, Worley SD, Broughton RM, Huang TS. N-Halamine-modified antimicrobial polypropylene nonwoven fabrics for use against airborne bacteria. ACS Appl Mater Interfaces 2015;7: 1752-7.

Shang XF, Morris-Natschke SL, Yang GZ, Liu YQ, Guo X, Xu XS, et al. Biologically active quinoline and quinazoline alkaloids part II. Med Res Rev 2018; 38: 1614-60.

Varsha KK, Devendra L, Shilpa G, Priya S, Pandey A, Nampoothiri KM. 2,4-Di-tert-butyl phenol as the antifungal, antioxidant bioactive purified from a newly isolated Lactococcus sp. Int J Food Microbiol 2015; 211: 44-50.

Machado M, Dinis AM, Salgueiro L, Cavaleiro C, Custódio JB, Sousa Mdo C. Anti-Giardia activity of phenolic-rich essential oils: effects of Thymbra capitata, Origanum virens, Thymus zygis subsp. sylvestris, and Lippia graveolens on trophozoites growth, viability, adherence, and ultrastructure. Parasitol Res 2010; 106: 1205-15.

Cunha F, Tintino SR, Figueredo F, Barros L, Duarte AE, Vega Gomez MC, et al. HPLC-DAD phenolic profile, cytotoxic and anti-kinetoplastidae activity of Melissa officinalis. Pharm Biol 2016; 54: 1664-70.

Calixto Júnior JT, de Morais SM, Gomez CV, Molas CC, Rolon M, Boligon AA, et al. Phenolic composition and antiparasitic activity of plants from the Brazilian Northeast “Cerrado”. Saudi J Biol Sci 2016; 23: 434-40.

Ezz Eldin HM, Badawy AF. In vitro anti-Trichomonas vaginalis activity of Pistacia lentiscus mastic and Ocimum basilicum essential oil. J Parasit Dis 2015; 39: 465-73.

Anti-Trichomonas vaginalis Activity of Marine Ascidians (Tunicates; Ascidiacea) from the Bushehr Province, Iran