ABSTRACT

Aristolochia plants are notable from an ethnopharmacological viewpoint, but the relevance of these species for medicinal purposes has been debated because of their inherent toxicity. The convergence of these contrasting realities can be readily achieved using bioconversion methods, which have been shown to be useful tools for numerous applications, including the detoxification of biomass. In this context, methanolic extracts of leaves from Aristolochia triangularis and Aristolochia gibertii, as well as the feces of Battus polydamas larvae fed with leaves from these plants, were prepared, and their cytotoxic activities were evaluated on a human fibroblast cell line (GM07492). The leaf extracts were found to be cytotoxic, leading to reductions of 42.1 and 33.8% on cell viability, respectively, while the fecal extracts were considered inactive. In addition to evidencing the cytotoxicity of A. triangularis and A. gibertii, these findings demonstrated a potential bioconversion strategy for obtaining aristolochiaceous extracts with reduced toxicity using the larvae of a specialist phytophagous insect, thus renewing expectations in relation to the pharmacological importance of Aristolochia spp. The results were also ecologically relevant, as B. polydamas larvae were found to be able to detoxify compounds from host plants.

Keywords
Aristolochiaceae; bioconversion; insects; toxicity; detoxification

INTRODUCTION

Despite being time-consuming, the natural product chemistry approaches continue to be the most promising for the discovery of new drugs. This statement remains valid even when the efficiencies of these strategies are compared with those of advanced tools, such as combinatorial chemistry and high-throughput screening of synthesized compounds (CHAGAS-PAULA et al., 2015CHAGAS-PAULA, D.A.; ZHANG, T.; COSTA, F.B.; EDRADA-EBEL, R. A Metabolomic approach to target compounds from the Asteraceae family for dual COX and LOX inhibition. Metabolites, Basel, v.5, n.3, p.404-430, 2015. https://doi.org/10.3390/metabo5030404
https://doi.org/10.3390/metabo5030404... ).

However, the initial selection of a bioactive extract with minimal to no toxicity is a bottleneck to success in drug discovery programs (MCGAWL et al., 2014MCGAWL, L.J.; ELGORASHI, E.E.; ELOFF, J.N. Cytotoxicity of African medicinal plants against normal animal and human cells. In: Kuete, V. (ed). Toxicological Survey of African Medicinal Plants. London: Elsevier, 2014. chap.8, p.181-233. https://doi.org/10.1016/B978-0-12-800018-2.00008-X
https://doi.org/10.1016/B978-0-12-800018... ). Hence, extract libraries are usually initially submitted to toxicity testing, for example cytotoxicity assays, which are also used for other purposes, such as the search for anticancer drugs and the samples found to be toxic are classified as nonpriority (MCGAWL et al., 2014MCGAWL, L.J.; ELGORASHI, E.E.; ELOFF, J.N. Cytotoxicity of African medicinal plants against normal animal and human cells. In: Kuete, V. (ed). Toxicological Survey of African Medicinal Plants. London: Elsevier, 2014. chap.8, p.181-233. https://doi.org/10.1016/B978-0-12-800018-2.00008-X
https://doi.org/10.1016/B978-0-12-800018... ). Although the merit of this approach is widely recognized, caution should be exercised when applying it for three related reasons: i) it is essentially reductionist, ii) extracts are highly complex matrices and their potential should not be underestimated based on toxicological screening results, and iii) even biomasses/samples that are inherently toxic and/or inactive may show promise after being processed or engineered using tools such as bioconversion methods and strategies to generate natural product-like libraries (LÓPEZ et al., 2007LÓPEZ, S.N.; RAMALLO, I.A.; SIERRA, M.G.; ZACCHINO, S.A.; FURLAN, R.L.E. Chemically engineered extracts as an alternative source of bioactive natural product-like compounds. Proceedings of the National Academy of Sciences of the United States of America, Washington, v.104, n.2, p.441-444, 2007. https://doi.org/10.1073/pnas.0608438104
https://doi.org/10.1073/pnas.0608438104... ; LIU; YU, 2010LIU, J.-H.; YU, B.-Y. Biotransformation of bioactive natural products for pharmaceutical lead compounds. Current Organic Chemistry, Budapest, v.14, n.14, p.1400-1406, 2010. https://doi.org/10.2174/138527210791616786
https://doi.org/10.2174/1385272107916167... ).

The Aristolochiaceae family is an example of why caution should be observed before drawing an immediate conclusion regarding the pharmacological significance of certain plants. Species of this family of flowering plants, particularly those of the Aristolochia genus, contain a great number of bioactive compounds, making them notable within the global ethnopharmacological context (LOPES et al., 2001LOPES, L.M.X.; NASCIMENTO, I.R.; SILVA, T.D.; DA, L.M. Phytochemistry of the Aristolochiaceae Family. In: MOHAN, R.M.M. (ed). Research Advances in Phytochemistry. Kerala: Global Research Network, 2001, p.19-108.; HEINRICH et al., 2009HEINRICH, M.; CHAN, J.; WANKE, S.; NEINHUIS, C.; SIMMONDS, M.S.J. Local uses of Aristolochia species and content of nephrotoxic aristolochic acid 1 and 2—A global assessment based on bibliographic sources. Journal of Ethnopharmacology, v.125, n.1, p.108-144, 2009. https://doi.org/10.1016/j.jep.2009.05.028
https://doi.org/10.1016/j.jep.2009.05.02... ). However, their medicinal potential conflicts with results of several toxicological studies, which demonstrated the cytotoxicity and mutagenicity of its representative chemical constituents as well as of herbal preparations containing such plants (LOPES et al., 2001LOPES, L.M.X.; NASCIMENTO, I.R.; SILVA, T.D.; DA, L.M. Phytochemistry of the Aristolochiaceae Family. In: MOHAN, R.M.M. (ed). Research Advances in Phytochemistry. Kerala: Global Research Network, 2001, p.19-108.; DECHBUMROONG et al., 2018DECHBUMROONG, P.; AUMNOUYPOL, S.; DENDUANGBORIPANT, J.; SUKRONG, S. DNA barcoding of Aristolochia plants and development of species-specific multiplex PCR to aid HPTLC in ascertainment of Aristolochia herbal materials. PLoS ONE, San Francisco, v.13, n.8, e0202625, p.1-16, 2018. https://doi.org/10.1371/journal.pone.0202625
https://doi.org/10.1371/journal.pone.020... ; HAN et al., 2019HAN, J.; XIAN, Z.; ZHANG, Y.; LIU, J.; LIANG, A. Systematic overview of aristolochic acids: nephrotoxicity, carcinogenicity, and underlying mechanisms. Frontiers in Pharmacology, v.10, p. 1-17, 2019. https://doi.org/10.3389/fphar.2019.00648
https://doi.org/10.3389/fphar.2019.00648... ). These findings have stimulated debate regarding the relevancy of Aristolochia spp. for medicinal purposes and have encouraged the development of approaches to overcome this issue (NOGUEIRA; LOPES, 2013aNOGUEIRA, C.R.; LOPES, L.M. Determination of configuration at C-13 of (–)-ent-8β-hydroxy-labdan-15-oic acid and its biotransformation by Battus polydamas larvae. Planta Medica, New York, v.79, SL35, 2013a. https://doi.org/10.1055/s-0033-1351861
https://doi.org/10.1055/s-0033-1351861... ,b; DECHBUMROONG et al., 2018DECHBUMROONG, P.; AUMNOUYPOL, S.; DENDUANGBORIPANT, J.; SUKRONG, S. DNA barcoding of Aristolochia plants and development of species-specific multiplex PCR to aid HPTLC in ascertainment of Aristolochia herbal materials. PLoS ONE, San Francisco, v.13, n.8, e0202625, p.1-16, 2018. https://doi.org/10.1371/journal.pone.0202625
https://doi.org/10.1371/journal.pone.020... ).

Among the various methods, bioconversion, which strictly differs from biotransformation and involves the use of living organisms (COLLINS; KENNEDY, 1999COLLINS, A.M.; KENNEDY, M.J. Biotransformations and bioconversions in New Zealand: Past Endeavours and Future Potential. Australasian Biotechnology, Botafogo, v.9, n.2, p.86-94, 1999. Available from: http://www.bioline.org.br/request?au99006. Access on: 15 Apr. 2019.
http://www.bioline.org.br/request?au9900... ), has attracted great interest, as it has proven to be a very useful tool for numerous applications, including access to new compounds, structural modification and biomass detoxification (PALMQVIST et al., 2000PALMQVIST, E.; HAHN-HÄGERDAL, B. Fermentation of lignocellulosic hydrolysates. I: inhibition and detoxification. Bioresource Technology, Lucknow, v.74, n.1, p.17-24, 2000. https://doi.org/10.1016/S0960-8524(99)00160-1
https://doi.org/10.1016/S0960-8524(99)00... ; LIU; YU, 2010LIU, J.-H.; YU, B.-Y. Biotransformation of bioactive natural products for pharmaceutical lead compounds. Current Organic Chemistry, Budapest, v.14, n.14, p.1400-1406, 2010. https://doi.org/10.2174/138527210791616786
https://doi.org/10.2174/1385272107916167... ; NOGUEIRA; LOPES, 2013aNOGUEIRA, C.R.; LOPES, L.M. Determination of configuration at C-13 of (–)-ent-8β-hydroxy-labdan-15-oic acid and its biotransformation by Battus polydamas larvae. Planta Medica, New York, v.79, SL35, 2013a. https://doi.org/10.1055/s-0033-1351861
https://doi.org/10.1055/s-0033-1351861... ,bNOGUEIRA, C.R.; LOPES, L.M. Sequestration and biotransformation of lignans from Aristolochia giberti by Battus polydamas larvae (Papilonidae: Troidini). Planta Medica, New York, v.79, PI67, 2013b. https://doi.org/10.1055/s-0033-1352156
https://doi.org/10.1055/s-0033-1352156... ). The greatest attention has been given to the utilization of microorganisms for these purposes, but the potential of insects, including the Swallowtail butterfly Battus polydamas, has also been verified (VENISETTY; CIDDI, 2003VENISETTY, R.K.; CIDDI, V. Application of microbial biotransformation for the new drug discovery using natural drugs as substrates. Current Pharmaceutical Biotechnology, Athens, v.4, n.3, p.153-167, 2003. https://doi.org/10.2174/1389201033489847
https://doi.org/10.2174/1389201033489847... ; NOGUEIRA; LOPES, 2013aNOGUEIRA, C.R.; LOPES, L.M. Determination of configuration at C-13 of (–)-ent-8β-hydroxy-labdan-15-oic acid and its biotransformation by Battus polydamas larvae. Planta Medica, New York, v.79, SL35, 2013a. https://doi.org/10.1055/s-0033-1351861
https://doi.org/10.1055/s-0033-1351861... ,bNOGUEIRA, C.R.; LOPES, L.M. Sequestration and biotransformation of lignans from Aristolochia giberti by Battus polydamas larvae (Papilonidae: Troidini). Planta Medica, New York, v.79, PI67, 2013b. https://doi.org/10.1055/s-0033-1352156
https://doi.org/10.1055/s-0033-1352156... ; RAMOS, 2013RAMOS, C.S. Biotransformation of secondary plant metabolites by Lepidoptera. In: GUERRITORE, E.; DESARE, J. (eds). Lepidoptera: classification, behavior, and ecology. New York: Nova Medical, 2013, chap.8, p.203-216.).

Thus, the objective of this work was to evaluate the in vitro cytotoxicity of Aristolochia triangularis and Aristolochia gibertii before and after metabolization of leaf biomasses of these species by larvae of a specialist phytophagous insect, B. polydamas, in order to propose a potential bioconversion approach to obtain aristolochiaceous extracts with reduced toxicity, contributing to overcome challenges that have limited the use of the birthwort family for therapeutic purposes.

MATERIAL AND METHODS

Plant materials and insects: collection and identification

The plant materials and insects were collected at the Medicinal Plants Garden of the Federal University of Grande Dourados, Dourados (MS), Brazil, during April 2016. A. triangularis Cham. and A. gibertii Hook. were identified by Dr. Joelcio Freitas and voucher specimens (MBML 53232 and MBML 53233, respectively) were deposited at the herbarium of Museu de Biologia Prof. Mello Leitão (MBML) in city of Santa Teresa, Espírito Santo, Brazil. Battus polydamas was identified by MSc. Paulo Ricardo Barbosa de Souza. The authorization IBAMA number was 51842 and the access registers CGEN/MMA numbers were AC96E87 and A1F6637.

Larval rearing and collection of fecal material

Battus polydamas larvae of different instars, which were fed in the laboratory with fresh leaves from A. triangularis or A. gibertii during the first half of April 2016, were reared in cages [30 × 30 × 40 cm (w × h × l)] under semicontrolled conditions: artificial light during the natural photoperiod and ambient humidity and temperature. The fecal materials excreted by the insects were collected every 48 h, air-dried for 15 days and stored at room temperature until extraction.

Extraction steps

The feces of the B. polydamas larvae fed with A. triangularis and A. gibertii leaves (60.0 g and 8.6 g, respectively) and leaves from these two plants (25.6 and 10.0, respectively) were individually and exhaustively extracted by maceration with methanol (HPLC grade, Vetec). After the simple filtration steps, the obtained methanol solutions were concentrated under reduced pressure to give the extracts of the feces [FE-1: 6.82 g (11.4%); FE-2: 0.92 g (10.7%)] and leaves [LE-1: 4.92 g (19.2%); LE-2: 1.28 g (12.8%)].

Cytotoxic activity and data analysis

The cytotoxicity of the methanol extracts of B. polydamas feces and A. triangularis and A. gibertii leaves were evaluated using the liquid extraction method (International Standard ISO 10993-5, 2009). GM07492 cells were seeded in a 96-well plate, maintained in culture medium enriched with fetal bovine serum (FBS) and antibiotics, and incubated for 24 h at 37 °C in a humidified atmosphere containing CO₂ (5%) and atmospheric air (95%). The extract samples were individually prepared at a concentration of 20 mg/ml using Dulbecco’s modified eagle medium (DMEM) as a diluent and allowed to stand for 24 h at 37 °C. After this time, the culture medium of the wells was replaced with 100 μL of culture medium containing either the extracts, the negative control or the positive control, or vehicle, and the cells were maintained under ideal cultivation conditions for 24 h. Subsequently, the wells were washed with 150 μL phosphate buffered saline (PBS) (1×) and 50 μlL of 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) was added to each. The 96-well plate was again incubated for 4 h at 37 °C, after which 100 μL of isopropanol was added to each well to solubilize the formazan crystals. Finally, the quantity of dissolved formazan crystals was determined spectrophotometrically and the optical density values measured at 570 nm were converted into the perceptual of cell viability in relation to a negative control. DMEM + FBS + antibiotics and DMEM + DMSO 25% were used as the negative and positive controls, respectively. The calculations of the reduction in cell viability were performed following the recommendations described in International Standard ISO 10993-5 (2009)[ISO] International Organization for Standardization. 10993–5: 2009 Biological evaluation of medical devices—Part 5: Tests for in vitro cytotoxicity. Geneva: ISO, 2009. Available from: https://www.iso.org/standard/36406.html. Access on: 5 Aug. 2017.
https://www.iso.org/standard/36406.html... .

RESULTS AND DISCUSSION

Monolayers of GM07492 cells were individually treated with 100 μL of culture medium containing 2 mg of one of the extracts to be tested: LE-1, FE-1, LE-2, or FE-2. Relative cell viability values of 57.9, 85.8, 66.2 and 94.2% were obtained for the samples, respectively (Fig. 1), corresponding to 42.1, 14.2, 33.8, and 5.8% reductions in the cell viability as determined using liquid extraction assay.

Figure 1
Relative cell viability values. The graph shows the comparison of cell viability between extracts of leaves and feces in relation to the negative and positive controls. LE-1 and LE-2: extracts of leaves from A. triangularis and A. gibertii, respectively. FE-1 and FE-2: extracts of feces of B. polydamas larvae fed on A. triangularis and A. gibertii leaves, respectively.

A reduction of more than 30% in cell viability can be interpreted as a cytotoxic effect (International Standard ISO 10993-5, 2009). Therefore, the LE-1 and LE-2 extracts were cytotoxic at the concentration assessed, with the former presenting significantly greater toxic action than the later (p ≤ 0.00). In previous studies, extracts from A. triangularis were shown to cause mortality in Artemia salina larvae, as well as being cytotoxic in an Allium cepa bioassay and towards KB cells (MONGELLI et al., 1996MONGELLI, E.; MARTINO, V.; COUSSIO, J.; CICCIA, G. Screening of Argentine medicinal plants using the brine shrimp microwell cytotoxicity assay. International Journal of Pharmacognosy, Springfield, v.34, n.4, p.249-254, 1996. https://doi.org/10.1076/phbi.34.4.249.13234
https://doi.org/10.1076/phbi.34.4.249.13... ; 2000MONGELLI, E.; PAMPURO, S.; COUSSIO, J.; SALOMON, H.; CICCIA, G.J. Cytotoxic and DNA interaction activities of extracts from medicinal plants used in Argentina. Journal of Ethnopharmacology, Pretoria, v.71, n.1-2, p.145-151, 2000. https://doi.org/10.1016/S0378-8741(99)00195-6
https://doi.org/10.1016/S0378-8741(99)00... ; SILVA et al., 2019SILVA, J.D.A.; NOGUEIRA, C.R.; VIEIRA, M.C.: HEREDIA-VIEIRA, S.C.; BARUFATTI, A.; CRISPIM, B.A.; FRANCISCO, L.F.V.; VIANA, L.F.; CARDOSO, C.A.L. Toxicological properties of an aqueous extract of Aristolochia triangularis leaves, using the brine shrimp lethality and Allium cepa bioassays. Ciência Rural, Santa Maria, v.49, n.8, p.e20190091, 2019. https://doi.org/10.1590/0103-8478cr20190091
https://doi.org/10.1590/0103-8478cr20190... ). Conversely, the toxicological properties of A. gibertii had not been previously described in literature.

The cytotoxicity of LE-1 and LE-2 reflected their chemical compositions, since both plants selected for this work can produce compounds that are known to be cytotoxic. Nearly fifty compounds have been reported to occur in A. triangularis, among which only aristolactam I and aristolochic acids I, II, C and D, all of which are cytotoxic, were detected in leaves of this species (SILVA et al., 2019SILVA, J.D.A.; NOGUEIRA, C.R.; VIEIRA, M.C.: HEREDIA-VIEIRA, S.C.; BARUFATTI, A.; CRISPIM, B.A.; FRANCISCO, L.F.V.; VIANA, L.F.; CARDOSO, C.A.L. Toxicological properties of an aqueous extract of Aristolochia triangularis leaves, using the brine shrimp lethality and Allium cepa bioassays. Ciência Rural, Santa Maria, v.49, n.8, p.e20190091, 2019. https://doi.org/10.1590/0103-8478cr20190091
https://doi.org/10.1590/0103-8478cr20190... ; MICHL et al., 2016MICHL, J.; KITE, G.C.; WANKE, S.; ZIERAU, O.; VOLLMER, G.; NEINHUIS, C.; SIMMONDS, M.S.J.; HEINRICH, M. LC-MS- and 1H NMR-based metabolomic analysis and in vitro toxicological assessment of 43 Aristolochia species. Journal of Natural Products, Washington, v.79, n.1, p.30-37, 2016. https://doi.org/10.1021/acs.jnatprod.5b00556
https://doi.org/10.1021/acs.jnatprod.5b0... ). In contrast, a total of twelve chemical constituents, including the cytotoxic lignans cubebin, (-)-hinokinin, and (-)-kusunokinin, have been isolated from A. gibertii leaves (MARCHESINI et al., 2009MARCHESINI, A.M.; PRADO, G.G.; MESSIANO, G.B.; MACHADO, M.B.; LOPES, L.M.X. Chemical constituents of Aristolochia giberti. Journal of the Brazilian Chemical Society, São Paulo, v.20, n.9, p.1598-1608, 2009. https://doi.org/10.1590/S0103-50532009000900006
https://doi.org/10.1590/S0103-5053200900... ).

As expected, the fecal extracts were not considered cytotoxic, which supported the hypothesis of this study that bioconversion by B. polydamas larvae would be an efficient way to obtain Aristolochiaceous extracts with minimal to no toxicity. Consequently, the method developed in this research could renew expectations regarding the potential of the controversial Aristolochia spp.

These results also had chemical-ecological relevancy, since they suggest that B. polydamas larvae detoxify the chemical constituents of their host plants. Phytophagous insects have developed a variety of strategies to overcome the chemical barriers imposed by plants (EDWARDS; WRATTEN, 1981EDWARDS, P.J.; WRATTEN, S.D. Ecologia das interações entre insetos e plantas. São Paulo: Pedagógica e Universitária, 1981, 71p.; OPTIZ; MÜLLER, 2009OPTIZ, S.E.W.; MÜLLER, C. Plant chemistry and insect sequestration. Chemoecology, Graz, v.19, n.3, p.117-154, 2009. https://doi.org/10.1007/s00049-009-0018-6
https://doi.org/10.1007/s00049-009-0018-... ; RAMOS, 2013RAMOS, C.S. Biotransformation of secondary plant metabolites by Lepidoptera. In: GUERRITORE, E.; DESARE, J. (eds). Lepidoptera: classification, behavior, and ecology. New York: Nova Medical, 2013, chap.8, p.203-216.). A particularly effective way of dealing with this issue is to metabolize the chemical constituents via a variety of metabolic pathways or with the help of endosymbiotic microorganisms (EDWARDS; WRATTEN, 1981EDWARDS, P.J.; WRATTEN, S.D. Ecologia das interações entre insetos e plantas. São Paulo: Pedagógica e Universitária, 1981, 71p.; OPTIZ; MÜLLER, 2009OPTIZ, S.E.W.; MÜLLER, C. Plant chemistry and insect sequestration. Chemoecology, Graz, v.19, n.3, p.117-154, 2009. https://doi.org/10.1007/s00049-009-0018-6
https://doi.org/10.1007/s00049-009-0018-... ; RAMOS, 2013RAMOS, C.S. Biotransformation of secondary plant metabolites by Lepidoptera. In: GUERRITORE, E.; DESARE, J. (eds). Lepidoptera: classification, behavior, and ecology. New York: Nova Medical, 2013, chap.8, p.203-216.). Similar detoxification pathways have been observed in Lepidoptera, whose larvae feed on plants belonging to several botanical families (RAMOS, 2013RAMOS, C.S. Biotransformation of secondary plant metabolites by Lepidoptera. In: GUERRITORE, E.; DESARE, J. (eds). Lepidoptera: classification, behavior, and ecology. New York: Nova Medical, 2013, chap.8, p.203-216.). The toxic compounds in the plants are generally transformed into more polar and less toxic derivatives, mainly by demethylation, hydroxylation and glycosylation reactions (RAMOS, 2013RAMOS, C.S. Biotransformation of secondary plant metabolites by Lepidoptera. In: GUERRITORE, E.; DESARE, J. (eds). Lepidoptera: classification, behavior, and ecology. New York: Nova Medical, 2013, chap.8, p.203-216.).

Although virtually nothing is known about the toxicity of most bioconversion products, B. polydamas larvae are known to be able to metabolize aristolochic acids (AAs), aristolactams (ALs), lignans and diterpenes (NOGUEIRA; LOPES, 2013aNOGUEIRA, C.R.; LOPES, L.M. Determination of configuration at C-13 of (–)-ent-8β-hydroxy-labdan-15-oic acid and its biotransformation by Battus polydamas larvae. Planta Medica, New York, v.79, SL35, 2013a. https://doi.org/10.1055/s-0033-1351861
https://doi.org/10.1055/s-0033-1351861... ,b; NOGUEIRA, 2014NOGUEIRA, C.R. Biotransformação e sequestro de micromoléculas de Aristolochia gibertii por Battus polydamas. 288f. Thesis (Doctorate in Chemistry) – Universidade Estadual Paulista, Araraquara, 2014. Available from: https://repositorio.unesp.br/handle/11449/115794. Access on: 15 Apr. 2019.
https://repositorio.unesp.br/handle/1144... ). For the metabolism of AAs, all chemical transformations mentioned above have already been observed, although the glycosylated derivatives still lack an unambiguous structural determination (PRIESTAP et al., 2012PRIESTAP, H.A.; VELANDIA, A.E.; JOHNSON, J.V.; BARBIERI, M.A. Secondary metabolite uptake by the Aristolochia-feeding papilionoid butterfly Battus polydamas. Biochemical Systematics and Ecology, Richmond, v.40, p.126-137, 2012. https://doi.org/10.1016/j.bse.2011.10.006
https://doi.org/10.1016/j.bse.2011.10.00... ). A single study on the metabolism of ALs has been published in the literature, which verified that the ALs I and II were oxidized into AAs I and II, respectively (URZÚA et al., 2013URZÚA, A.; OLGUÍN, A.; SANTANDER, R. Fate of ingested aristolactams from Aristolochia chilensis in Battus polydamas archidamas (Lepidoptera: Papilionidae). Insects, Basel, v.4, n.4, p.533-541, 2013. https://doi.org/10.3390/insects4040533
https://doi.org/10.3390/insects4040533... ). The metabolism of dibenzylbutyrolactone lignans by B. polydamas larvae produced (-)-(8S,8R’)-(3,4-methylenedioxy)-(3’,4’)-(dimethoxy)-9’-O-β-glucopyranosyl-lignan-9-oic acid and (-)-(8S,8R’)-[3,4:3’,4’-bis(methylenedioxy)]-9’-O-β-glucopyranosyl-lignan-9-oic acid, whereas the labdane diterpene (-)-(5R,8R,9S,10R,13R)-8-hydroxy-labdan-15-oic acid was bioconverted into (4S,5S,8R,9S,10R,13R)-8,18-dihydroxy-labdan-15-oic acid, (4S,5S,7R,8S,9S,10R,13R)-7,8,18-trihydroxy-labdan-15-oic acid and (-)-(4S,5S,8R,9S,10R,13R)-8-hydroxy-labdan-15,18-dioic acid (NOGUEIRA; LOPES, 2013aNOGUEIRA, C.R.; LOPES, L.M. Determination of configuration at C-13 of (–)-ent-8β-hydroxy-labdan-15-oic acid and its biotransformation by Battus polydamas larvae. Planta Medica, New York, v.79, SL35, 2013a. https://doi.org/10.1055/s-0033-1351861
https://doi.org/10.1055/s-0033-1351861... ,b; NOGUEIRA, 2014NOGUEIRA, C.R. Biotransformação e sequestro de micromoléculas de Aristolochia gibertii por Battus polydamas. 288f. Thesis (Doctorate in Chemistry) – Universidade Estadual Paulista, Araraquara, 2014. Available from: https://repositorio.unesp.br/handle/11449/115794. Access on: 15 Apr. 2019.
https://repositorio.unesp.br/handle/1144... ).

CONCLUSIONS

Extracts of A. triangularis and A. gibertii leaves were found to be cytotoxic to GM07492 cells, whereas the extracts of the feces of B. polydamas larvae fed on leaves of these plants were inactive. Thus, the bioconversion strategy utilized in this work was shown to be effective for the detoxification of aristolochiaceous foliar biomasses, renewing expectations of the pharmacological relevance of Aristolochia spp. The reduction in toxicity observed after the digestion of leaves from these two plants by B. polydamas larvae also had chemical-ecological implications, as it demonstrated that these insects may have their own strategies to overcome the chemical barriers imposed by their host plants.

ACKNOWLEDGEMENTS

The authors would like to thank Dr. Joelcio Freitas and MSc. Paulo Ricardo Barbosa de Souza for botanical and entomological identifications.

REFERENCES

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