Abstract

Introduction

The Annonaceae family comprises about 2500 species distributed in 130 genera. This family consists of trees, shrubs and climbers, with a predominant distribution in lowlands of tropical and subtropical regions, being considered a pantropical family (Richardson et al., 2004Richardson, J.E., Chatrou, L.W., Mols, J.B., Erkens, R.H.J., Pirie, M.D., 2004. Historical biogeography of two cosmopolitan families of flowering plants: Annonaceae and Rhamnaceae. Phil. Trans. R. Soc. Lond. B 359,1495-1508.). This family is chemically characterized by the presence of alkaloids, particularly isoquinoline-derived and terpenoids, where monoterpenes and sesquiterpenes are predominant in the composition of essential oils (Leboeuf et al., 1982Leboeuf, M., Cavé, A., Bhaumik, P.K., Mukherjee, B., Mukherjee, R., 1982. The phytochemistry of the Annonaceae. Phytochemistry 21, 2783-2813.; Fournier et al., 1999Fournier, G., Leboeuf, M., Cavé, A., 1999. Annonaceae essential oils: a review. J. Essent. Oil Res. 11, 131-142.). Another remarkable feature is the presence of annonaceous acetogenins, a class exclusive from this family, that has attracted interest due to the growing list of newly described structures and biological activities (Chang et al., 1999Chang, F.R., Chen, J.L., Lin, C.Y., Chiu, H.F., Wu, M.J., Wu, Y.C., 1999. Bioactive acetogenins from the seeds of Annona atemoya.Phytochemistry 51, 883-889.; Cunha et al., 2009Cunha, M.M., Nascimento, F.C., Santos-Pimenta, L.P., Boaventura, M.A.D., Salas, C.E., Lopes, M.T.P., 2009. Screening of cytotoxic activity in hexanic and ethanolic extracts of Rollinia laurifolia. Lat. Am. J. Pharm. 28, 234-240.). Acetogenins along with the lanostane-type triterpene polycarpol have been suggested as potential chemotaxonomic markers for this family (Leboeuf et al., 1982Leboeuf, M., Cavé, A., Bhaumik, P.K., Mukherjee, B., Mukherjee, R., 1982. The phytochemistry of the Annonaceae. Phytochemistry 21, 2783-2813.; Goulart et al., 1986Goulart, M.O.F., Santana, A.E.G., Oliveira, A.B., Oliveira, G.G., Maia, J.G.S., 1986. Azafluorenones and azaanthraquinone from Guatteria dielsiana. Phytochemistry 25, 1691-1695.; Jung et al., 1990Jung, J.H., Pummangura, S., Chaichantipyuth, P., Patarapanich, C., Mclaughlin, J.L., 1990. Bioactive constituents of Melodorum fruticosum. Phytochemistry 29, 1667-1670.).

Polycarpol displays a growing list of biological activities described in the literature, such as antifilarial (Nyasse et al., 2006Nyasse, B., Ngantchou, I., Nono, J.J., Schneider, B., 2006. Antifilarial activity in vitro of polycarpol and 3-O-acetyl aleuritolic acid from cameroonian medicinal plants against Onchocerca gutturosa. Nat. Prod. Res 20,391-397.), antineoplastic (Matos et al., 2006Matos, M.F.C., Leite, L.I.S.P., Brustolim, D., Siqueira, J.M., Carollo, C.A., Hellmann, A.R., Pereira, N.F.G., Silva, D.B., 2006. Antineoplastic activity of selected constituents of Duguetia glabriuscula. Fitoterapia 77, 227-229.), antitrypanosomal (Ngantchou et al., 2009Ngantchou, I., Nkwengoua, E., Nganso, Y., Nyasse, B., Denier, C., Hannaert, V., Schneider, B., 2009. Antitrypanosomal activity of polycarpol from Piptostigma preussi (Annonaceae). Fitoterapia 80,188-191.) and more recently anti-inflammatory (Saadawi et al., 2012Saadawi, S., Jalil, J., Jasamai, M., Jantan, I., 2012. Inhibitory effects of acetylmelodorinol, chrysin and polycarpol from Mitrella kentii on prostaglandin E2 and thromboxane B2 production and platelet activating factor receptor binding. Molecules 17, 4824-4835.). Although triterpenes possess proven antimicrobial activities (Haraguchi et al., 1999Haraguchi, H., Kataoka, S., Okamoto, S., Hanafi, M., Shibata, K., 1999. Antimicrobial triterpenes from Ilex integra and the mechanism of antifungal action. Phytother. Res. 13,151-156.; Katerere et al., 2003Katerere, D.R., Grev, A.I., Nash, R.J., Waigh, R.D., 2003. Antimicrobial activity of pentacyclic triterpenes isolated from African Combretaceae. Phytochemistry 63, 81-88.; Djoukeng et al., 2005Djoukeng, J.D., Abou-Mansour, E., Tabacchi, R., Tapondjou, A.L., Boudab, H., Lontsi, D., 2005. Antibacterial triterpenes from Syzygium guineense (Myrtaceae). J. Ethnopharmacol. 101 283-286.; Angeh et al., 2007Angeh, J.E., Huang, X., Sattler, I., Swan, G.E., Dahse, H., Hartl, A., Eloff, J.N., 2007. Antimicrobial and anti-inflammatory activity of four known and one new triterpenoid from Combretum imberbe(Combretaceae). J. Ethnopharmacol. 110, 56-60.) a lack of studies describing the antibacterial activities of polycarpol is observed. The continuous search for new antimicrobial drugs is stimulated by the increasing appearance of antibiotic-resistant organisms, such as individuals of the Staphylococcus, Pseudomonas, Enterococcus, and Pneumococcus genera (Pacheco et al., 2012Pacheco, A.G., Alcântara, A.F.C., Abreu, V.G.C., Corrêa, G.M., 2012. Relationships between chemical structure and activity of triterpenes against gram-positive and gram-negative bacteria. In: Bobbarala, V. (Ed.), A Search for Antibacterials Agents. InTech, Rijeka, pp. 1-24.).

Unonopsis, Bocageopsis and Onychopetalum are botanically close genera distributed through neotropical regions. The morphological similarities among these genera were expressed by Fries, when he placed them in the informal “Unonopsis-Gruppe”. Recently this close relationship was supported by phylogenetic researches (Maas et al., 2007Maas, P.J.M., Westra, L.Y.T., Vermeer, M., 2007. Revision of the neotropical genera Bocageopsis, Onychopetalum, and Unonopsis (Annonaceae). BLUMEA 52, 413-554.). Unonopsisis the largest genus among these three, comprising approximately 50 species. On the other hand, Bocageopsis and Onychopetalum comprise few species, four and two, respectively (B. mattogrossensis, B. canescens, B. multiflora and B. pleiosperma, O. amazonicum and O. periquino) (Maas et al., 2007Maas, P.J.M., Westra, L.Y.T., Vermeer, M., 2007. Revision of the neotropical genera Bocageopsis, Onychopetalum, and Unonopsis (Annonaceae). BLUMEA 52, 413-554.). Unonopsis is also the most explored from the chemical and biological points of view (Siqueira et al., 1998; Waechter et al., 1999; Silva et al., 2012b,c, 2014Siqueira, J.M., Bomm, M.D., Pereira, F.G., Garcez, W.S., Boaventura, M.A.D., 1998. Estudo fitoquímico de Unonopsis lindmanii – Annonaceae, biomonitorado pelo ensaio de toxicidade sobre a Artemia salina leach. Quim. Nova 21, 557-559.). The chemical information regarding the Bocageopsis and Onychopetalum genera is still limited, being focused directed to the study of the essential oils and alkaloid compositions (Almeida et al., 1976Almeida, M.E.L., Braz-Filho, R., Bülow, V., Gottlieb, O.R., Maia, J.G.S., 1976. Onychine, an alkaloid from Onychopetalum amazonicum. Phytochemistry 15, 1186-1187.; Oliveira et al., 2014Oliveira, E.S.C., Amaral, A.C.F., Lima, E.S., Silva, J.R.A., 2014. Chemical composition and biological activities of Bocageopsis multiflora essential oil. J. Essent. Oil Res. 26,161-165.; Soares et al., 2015Soares, E.R., Silva, F.M.A., Almeida, R.A., Lima, B.R., Koolen, H.H.F., Lourenco, C.C., Salvador, M.J., Flach, A., Costa, L.A.M.A., Souza, A.Q.L., Pinheiro, M.L.B., Souza, A.D.L., 2015. Chemical composition and antimicrobial evaluation of the essential oils of Bocageopsis pleiosperma Maas. Nat. Prod. Res., http://dx.doi.org/10.1080/14786419.2014.996148 (in press).
http://dx.doi.org/10.1080/14786419.2014.... ). In this work, the presence of the triterpene polycarpol (1) in the aerial parts (trunk barks and twigs) of Amazonian Bocageopsis, Onychopetalum and Unonopsis species was investigated by thin layer chromatography (TLC) and mass spectrometry (MS) approaches. The chemotaxonomic significance of polycarpol was discussed for these three genera and for the Annonaceae family. In addition, polycarpol was submitted to in vitro assays to evaluate its antimicrobial activity against Staphylococcus aureus (ATCC 6538), Staphylococcus epidermidis (ATCC 1228), Pseudomonas aeruginosa (ATCC 27853), Enterobacter faecalis (Ef), Bacillus subtilis (Bs), Escherichia coli (ATCC 10538 and 10799), Candida albicans (ATCC 10231 and 1023), Candida parapsilosis (ATCC 22019), Candida tropicalis (ATCC 157 and ct), Candida glabrata (ATCC 30070) and Candida dubliniensis (ATCC 778157).

Materials and methods

Plant material

The aerial parts (twigs and trunk barks) of Unonopsis duckeiR.E. Fr., (voucher no. 3289), Onychopetalum amazonicum R.E. Fr. (voucher no. 218341) and Bocageopsis pleiosperma Maas (voucher no. 183125) were collected in the Reserva Florestal Adolpho Ducke, at the municipality of Manaus, Brazil, from individuals previously identified by specialists. The voucher specimens are deposited in the herbarium of the Instituto Nacional de Pesquisas da Amazônia (INPA). The same parts for U. floribunda (voucher no. 6701) and U. rufescens (voucher no. 3767) were collected in the Distrito Agropecuário da SUFRAMA in the same city, from individuals previously identified by specialists. The voucher specimens are deposited in the botany collection of PDBFF/INPA (Projeto Dinâmica Biológica de Fragmentos Florestais). The plant material (twigs and trunk barks) of U. stipitata (voucher no. 8250) was collected in the campus of the Universidade Federal do Amazonas (UFAM). A voucher specimen was deposited in the Herbarium of the institution. The specimen collected on the campus of UFAM was identified by Prof. Antonio Carlos Webber from the Departamento de Biologia of the UFAM. The SISBIO license number for the collection is 34677-1.

Extraction and confirmation of the polycarpol

The extraction of polycarpol from U. duckei, U. floribunda, U. rufescens, U. stipitata, O. amazonicum and B. pleiosperma was made according to the adapted method described for U. guatterioides (Silva et al., 2012aSilva, F.M.A., Koolen, H.H.F., Barisson, A., Souza, A.D.L., Pinheiro, M.L.B., 2012a. Steroids and triterpene from the bark of Unonopsis guatterioides R. E. Fr. (Annonaceae). Int. J. Pharm. Pharm. Sci. 4,522-523.), briefly: 10 g of powdered material (twigs and trunk barks) were macerated for three days with hexane (80 ml). The extract was concentrated at reduced pressure. The precipitate formed was washed with hexane and re-crystallized in ethyl acetate. Approximately 1 mg of the each solid was separated for TLC and MS analysis, being polycarpol (1) identified by comparison with an authentic standard (Silva et al., 2012aSilva, F.M.A., Koolen, H.H.F., Barisson, A., Souza, A.D.L., Pinheiro, M.L.B., 2012a. Steroids and triterpene from the bark of Unonopsis guatterioides R. E. Fr. (Annonaceae). Int. J. Pharm. Pharm. Sci. 4,522-523.).

Biological assay

The pure standard of polycarpol was evaluated for its antimicrobial activity using the broth microdilution method (96-well microtiter plates), as previously described (Salvador et al., 2002; Barros et al., 2009; Costa et al., 2010; Bataglion et al., 2014Salvador, M.J., Ferreira, E.O., Pral, E.M.F., Alfieri, S.C., Albuquerque, S., Ito, I.Y., Dias, D.A., 2002. Bioactivity of crude extracts and some constituents of Blutaparon portulacoides (Amaranthaceae). Phytomedicine 9,566-571.) to give concentrations between 10 and 500 μg ml⁻¹. The minimal inhibitory concentration (MIC) was calculated as the lowest concentration showing complete inhibition of a tested strain. In these tests, chloramphenicol and ketoconazole were used as experimental positive control, while the solution propyleneglycol-sterile distilled water (5:95, v/v) served as the negative control. Each sensitivity test was performed in duplicate for each microorganism and repeated three times. The strains utilized in the assays are shown in Table 1.

Instruments and materials

TLC analysis were run on a 0.25 mm tick aluminum-backed silica-gel 60 plates type F-UV_{254 and 366} from Merck (Darmstadt, Germany). The spots were exposure to ultra-violet (UV) light at 254 and 366 nm, as well as revelation with vanillin–sulphuric acid reagent. The MS analyses were performed using a LCQ Fleet ion-trap mass spectrometer (Thermo LCQ Fleet – San Jose, CA, USA) equipped with an atmospheric pressure chemical ionization (APCI) source operating in positive ion mode. All mass spectra were acquired in a continuous monitoring mode (Thermo LCQ Fleet Tune application). The TLC and MS experiments were conducted in comparison with an authentic polycarpol standard previously isolated from U. guatterioides and characterized by nuclear magnetic resonance experiments (NMR) (Silva et al., 2012aSilva, F.M.A., Koolen, H.H.F., Barisson, A., Souza, A.D.L., Pinheiro, M.L.B., 2012a. Steroids and triterpene from the bark of Unonopsis guatterioides R. E. Fr. (Annonaceae). Int. J. Pharm. Pharm. Sci. 4,522-523.). All solvents used for chromatographic and MS experiments were high performance liquid chromatography (HPLC) grade purchased from Tedia (Fairfield, OH, USA), and the water purified by using a Milli-Q system (Millipore, Bedford, MA, USA).

Results and discussion

Confirmation of polycarpol by TLC and MS analyses

From the aerial parts of U. duckei, U. floribunda, U. rufescens, U. stipitata, O. amazonicum and B. pleiosperma white solids were obtained after extraction and re-crystallization procedures. All the samples were dissolved in ethyl acetate and analyzed by TLC in comparison with an authentic polycarpol standard (Silva et al., 2012aSilva, F.M.A., Koolen, H.H.F., Barisson, A., Souza, A.D.L., Pinheiro, M.L.B., 2012a. Steroids and triterpene from the bark of Unonopsis guatterioides R. E. Fr. (Annonaceae). Int. J. Pharm. Pharm. Sci. 4,522-523.). The samples and the standard presented the same retention factor (R_f 0.6) when eluted with a hexane–ethyl acetate (7:3) mixture and revealed with vanillin–sulphuric acid reagent (blue spot) and under UV light (254 nm). The observation of an intense blue spot in all samples is in agreement with results expected for triterpene compounds (Oleszek et al., 2008Oleszek, W., Kapusta, I., Stochmal, A., 2008. TLC of triterpenes (including saponins). In: Waksmundzka-Hajnos, M. (Ed.), Thin Layer Chromatography in Phytochemistry. CRC Press, Taylor & Francis Group, LLC, New York, pp. 519-537.). The samples when subjected to MS analysis in full scan mode, presented three major ions at m/z 441 [M+H]⁺, 423 (−18 Da) and 405 (−18 Da) (Fig. 1). The ion at m/z 441 corresponds to the protonated molecule expected for polycarpol, while the m/z 423 and 405 are consistent with sequential neutral losses (−H₂O). Hydroxilated triterpenes present this dissociative behavior due to the application of high desolvation temperatures in APCI experiments (Koolen et al., 2013Koolen, H.H.F., Soares, E.R., Silva, F.M.A., Oliveira, A.A., Souza, A.Q.L., Medeiros, L.S., Rodrigues-Filho, E., Cavalcanti, B.C., Pessoa, C.O., Morais, M.O., Salvador, M.J., Souza, A.D.L., 2013. Mauritic acid: a new dammarane triterpene from the roots of Mauritia flexuosa L.f. (Arecaceae). Nat. Prod. Res. 27, 2118-2125.). All samples presented the same three major ions when subjected to MS analysis. These evidence along with TLC observations assisted the confirmation of polycarpol (1) in aerial parts (twigs and trunk barks) of U. duckei, U. floribunda, U. rufescens, U. stipitata, O. amazonicum and B. pleiosperma, being this substance reported for the first time in this Unonopsis species as well in Onychopetalum and Bocageopsisgenus.

Antibacterial activity

The polycarpol was evaluated in vitro for antimicrobial activity against eleven strains of microorganism (Table 1). This substance presented significant antimicrobial activity against S. aureus (ATCC 6538), S. epidermidis(ATCC 1228) and E. coli (ATCC 10538 and ATCC 10799) with MIC values between 25 and 50 μg ml⁻¹. For the strains of B. subtilis, E. faecalis and P. aeruginosa were not observed inhibition of the development. These observations are in agreement with literature data, since lannostane triterpenes isolated from the vegetal species and fungi when assayed against gram-negative and gram-positive bacteria, present several active structures (Liu et al., 2010aLiu, X.T., Winkler, A.L., Schwan, W.R., Volk, T.J., Rott, M.A., Monte, A., 2010a. Antibacterial compounds from mushrooms I: A Lanostane-type triterpene and prenylphenol derivatives from Jahnoporus hirtusand Albatrellus flettii and their activities against Bacillus cereus and Enterococcus faecalis. Planta Med. 76, 182-185.,bLiu, X.T., Winkler, A.L., Schwan, W.R., Volk, T.J., Rott, M.A., Monte, A., 2010b. Antibacterial compounds from mushrooms. II: Lanostane triterpenoids and an ergostane steroid with activity against Bacillus cereus isolated from fomitopsis pinicola. Planta Med. 76, 464-466.; Mosa et al., 2014Mosa, R.A., Nhleko, M.L., Dladla, T.V., Opoku, A.R., 2014. Antibacterial activity of two triterpenes from stem bark of Protorhus longifolia. J. Med. Plants Res. 8,686-702.). Oleanane, ursane, lupane, friedelane, fernane and others miscellaneous-type triterpenes also present several active compounds against gram-negative bacteria, mainly P. aeruginosa, E. coli, Klebsiella pneumoniae, and Salmonella typhi, and gram-positive, comprising S. aureus, B. subtilis, Bacillus cereus, and S. faecalis. The tentative understanding of the relationships between the chemical structures of triterpenes and the antibacterial activities indicates that the activity may be related to the presence of an oxygenated group at C-3 (Pacheco et al., 2012Pacheco, A.G., Alcântara, A.F.C., Abreu, V.G.C., Corrêa, G.M., 2012. Relationships between chemical structure and activity of triterpenes against gram-positive and gram-negative bacteria. In: Bobbarala, V. (Ed.), A Search for Antibacterials Agents. InTech, Rijeka, pp. 1-24.). In polycarpol this position is occupied by a hydroxyl group, however another substituents, like carbonyls, O-glycosides, esters (mainly acetyl moieties), or hydroxylamines can be present in this position (Pacheco et al., 2012Pacheco, A.G., Alcântara, A.F.C., Abreu, V.G.C., Corrêa, G.M., 2012. Relationships between chemical structure and activity of triterpenes against gram-positive and gram-negative bacteria. In: Bobbarala, V. (Ed.), A Search for Antibacterials Agents. InTech, Rijeka, pp. 1-24.).

The significant antibacterial activities observed for polycarpol and described in this work for the first time needs further investigations, which could help in the search for new antimicrobial drugs.

Against the tested fungi, polycarpol showed inhibition on the growth of C. albicans (ATCC 10231 and ATCC 1023) and C. dubliniensis (ATCC 778157) with MIC values of 250 μg ml⁻¹, being this inhibitions considerate weak when compared to the positive control (ketoconazole, MIC 12.5 μg ml⁻¹). In general the antifungal activity of lanostane triterpenes is not well explored, being found only few works reporting this type of study (Kitagawa et al., 1981Kitagawa, I., Kobayashi, M., Inamoto, T., Yasuzawa, T., Kyogoku, Y., 1981. The structures of six antifungal oligoglycosides, stichlorosides A1, A2, B1, B2, C1, and C2, from the sea cucumber Stichopus chloronotus(Brandt). Chem. Pharm. Bull. 29, 2387-2391., 1985Kitagawa, I., Kobayashi, M., Inamoto, T., Fuchida, M., Kyogoku, Y., 1985. Marine natural products. XIV. Structures of echinosides A and B, antifungal lanostane-oligosides from the sea cucumber Actinopyga echinites (Jaeger). Chem. Pharm. Bull. 33, 5214-5224., 1989Kitagawa, I., Kobayashi, M., Son, B.W., Suzuki, S., Kyogoku, Y., 1989. Marine natural products. XIX. Pervicosides A, B, and C, lanostane-type triterpene-oligoglycoside sulfates from the sea cucumber Holothuria pervicax. Chem. Pharm. Bull. 37, 1230-1234.; Krohn et al., 1992Krohn, K., Ludewig, K., Jones, P.G., Doering, D., Aust, H.J., Draeger, S., Schulz, B., 1992. Biologically active metabolites from fungi, 21 An antifungal and herbicidal lanostane lactone from Sporormiella australis. Nat. Prod. Lett. 1, 29-32.; Hosoe et al., 2000Hosoe, T., Okada, H., Itabashi, T., Nozawa, K., Okada, K., Takaki, G.M., Fukushima, K., Miyaji, M., Kawai, K.I., 2000. A new pentanorlanostane derivative, cladosporide A, as a characteristic antifungal agent against Aspergillus fumigatus, isolated from Cladosporium sp. Chem. Pharm. Bull. 48,1422-1426.). In most cases satisfactory activities are related to unusual lanostane-triterpenes (e.g. oligosides-lanostane, oligoglycosides-lanostane and lactone-lanostane triterpenes) (Kitagawa et al., 1981Kitagawa, I., Kobayashi, M., Inamoto, T., Yasuzawa, T., Kyogoku, Y., 1981. The structures of six antifungal oligoglycosides, stichlorosides A1, A2, B1, B2, C1, and C2, from the sea cucumber Stichopus chloronotus(Brandt). Chem. Pharm. Bull. 29, 2387-2391., 1985Kitagawa, I., Kobayashi, M., Inamoto, T., Fuchida, M., Kyogoku, Y., 1985. Marine natural products. XIV. Structures of echinosides A and B, antifungal lanostane-oligosides from the sea cucumber Actinopyga echinites (Jaeger). Chem. Pharm. Bull. 33, 5214-5224., 1989Kitagawa, I., Kobayashi, M., Son, B.W., Suzuki, S., Kyogoku, Y., 1989. Marine natural products. XIX. Pervicosides A, B, and C, lanostane-type triterpene-oligoglycoside sulfates from the sea cucumber Holothuria pervicax. Chem. Pharm. Bull. 37, 1230-1234.; Krohn et al., 1992Krohn, K., Ludewig, K., Jones, P.G., Doering, D., Aust, H.J., Draeger, S., Schulz, B., 1992. Biologically active metabolites from fungi, 21 An antifungal and herbicidal lanostane lactone from Sporormiella australis. Nat. Prod. Lett. 1, 29-32.).

Chemotaxonomic significance of polycarpol

The chemotaxonomic importance of the polycarpol for the Annonaceae family was firstly recognized by Leboeuf et al. (1982)Leboeuf, M., Cavé, A., Bhaumik, P.K., Mukherjee, B., Mukherjee, R., 1982. The phytochemistry of the Annonaceae. Phytochemistry 21, 2783-2813. during a systematic research with several species belonging to neighboring families, such as Lauraceae, Monimiaceae and Menispermaceae. At this time, polycarpol was not found, being suggested for the first time in literature as chemotaxonomic marker for Annonaceae. This idea was supported over the years (Goulart et al., 1986Goulart, M.O.F., Santana, A.E.G., Oliveira, A.B., Oliveira, G.G., Maia, J.G.S., 1986. Azafluorenones and azaanthraquinone from Guatteria dielsiana. Phytochemistry 25, 1691-1695.; Jung et al., 1990Jung, J.H., Pummangura, S., Chaichantipyuth, P., Patarapanich, C., Mclaughlin, J.L., 1990. Bioactive constituents of Melodorum fruticosum. Phytochemistry 29, 1667-1670.). Polycarpol was recently isolated from Duguetia glabriuscula (Pereira et al., 2003Pereira, N.F.G., Carollo, C.A., Garcez, W.S., Siqueira, J.M., 2003. Novel santalane sesquiterpenoids from the stem bark of Duguetia glabriuscula - Annonaceae. Quim. Nova 26, 512-516.), Duguetia furfuraceae (Silva et al., 2007Silva, D.B., Tulli, E.C.O., Garcez, W.S., Nascimento, E.A., Siqueira, J.M., 2007. Chemical constituents of the underground stem bark of Duguetia furfuracea (Annonaceae). J. Braz. Chem. Soc. 18,1560-1565.), Artabotrys madagascariensis (Murphy et al., 2008Murphy, B.T., Cao, S., Brodie, P.J., Miller, J.S., Ratovoson, F., Birkinshaw, C., Rakotobe, E., Rasamison, V.E., Tendyke, K., Suh, E.M., Kingston, D.G.I., 2008. Antiproliferative compounds of Artabotrys madagascariensis from the Madagascar rainforest. Nat. Prod. Res. 22, 1169-1175.), Piptostigma preussi (Ngantchou et al., 2009Ngantchou, I., Nkwengoua, E., Nganso, Y., Nyasse, B., Denier, C., Hannaert, V., Schneider, B., 2009. Antitrypanosomal activity of polycarpol from Piptostigma preussi (Annonaceae). Fitoterapia 80,188-191.) and Artabotrys spinosus (Sichaem et al., 2011Sichaem, J., Ruksilp, T., Worawalai, W., Siripong, P., Khumkratok, S., Tip-pyang, S., 2011. A new dimeric aporphine from the roots of Artabotrys spinosus. Fitoterapia 82, 422-425.), all species from Annonaceae family, which enhances the initial proposition of this compound as a chemotaxonomic marker for this family. Considering its broad occurrence at genera level, is appropriate to restrict the term “chemotaxonomic marker” at a family level, being suggested the use of the term “chemical marker” to genera level.

In Unonopsis genus, polycarpol has been reported in Unonopsis glaucopetala (Jayasuriya et al., 2005Jayasuriya, H., Herath, K.B., Ondeyka, J.G., Guan, Z., Borris, R.P., Tiwari, S., Jong, W., Chavez, F., Moss, J., Stevenson, D.W., Beck, H.T., Slattery, M., Zamora, N., Schulman, M., Ali, A., Sharma, N., Macnaul, K., Hayes, N., Menke, J.G., Singh, S.B., 2005. Diterpenoid, steroid, and triterpenoid agonists of liver x receptors from diversified terrestrial plants and marine sources. J. Nat. Prod. 68,1247-1258.), Unonopsis guatterioides(Touché et al., 1981Touché, A., Desconclois, J.F., Jacquemin, H., Lelièvre, Y., Forgacs, P., 1981. Constituants de quelques annonacées guyanaises analyse qualitative et quantitative des acides aminés basiques libres. Présence d'un triterpène, Le polycarpol. Plant. Med. Phytother. 15,4-9.; Silva et al., 2012aSilva, F.M.A., Koolen, H.H.F., Barisson, A., Souza, A.D.L., Pinheiro, M.L.B., 2012a. Steroids and triterpene from the bark of Unonopsis guatterioides R. E. Fr. (Annonaceae). Int. J. Pharm. Pharm. Sci. 4,522-523.), Unonopsis spectabilis (Laprévote et al., 1987Laprévote, O., Roblot, F., Hocquemiller, R., Cavé, A., 1987. Alcaloïdes des annonacées, 84. bisaporphinoïdes de l'Unonopsis spectabilis. J. Nat. Prod. 50,984-988.) and Unonopsis pacifica (Arango et al., 1988Arango, G.J., Cortes, D., Cavé, A., D'Ocon, P.M., 1988. 7-7'-Bisdeshidroaporfns de Unonopsis pacifica. An. Quim. C-Org. Bioq. 84,124-127.). The re-current observation of polycarpol in all these species subjected to phytochemical approaches, as well as in O. amazonicum and B. pleiosperma is an important chemical evidence not only to confirm the botanical proximity of these genera (Maas et al., 2007Maas, P.J.M., Westra, L.Y.T., Vermeer, M., 2007. Revision of the neotropical genera Bocageopsis, Onychopetalum, and Unonopsis (Annonaceae). BLUMEA 52, 413-554.), but also to reinforce polycarpol as a chemical marker for these genera. The insufficient phytochemical knowledge regarding Onychopetalum and Bocageopsis genera still not does allows a profound evaluation of the chemical similarities between them and Unonopsis. In this sense, phytochemical investigations directed at better understanding of the chemical relationships among these three close-related genera are indispensable in the future.

Acknowledgment

The authors are grateful to CAPES, CNPq, FINEP, FAPEAM and FAPESP for financial support. We thank PDBFF for providing logistical and field support. This is publication number 663 in the PDBFF Technical Series.

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