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Revista Brasileira de Farmacognosia

Print version ISSN 0102-695XOn-line version ISSN 1981-528X

Rev. bras. farmacogn. vol.18 no.3 João Pessoa July/Sept. 2008

https://doi.org/10.1590/S0102-695X2008000300004 

ARTIGO

 

Antidiabetic and antiradical activities of plants from Venezuelan Amazon

 

Atividades antidiabética e anti-radicalar de plantas da Amazônia venezuelana

 

 

María RodríguezI, *; Masahisa HasegawaI; Freddy González-MújicaII; Norma MottaII; Anibal CastilloIII; Jimmy CastilloIV; Elsa ZeaI; Kiby MoraI; Luis SousaI; Alejandro GonzálezIV; David CamejoIV

ILaboratorio de Productos Naturales, Escuela de Química, Facultad de Ciencias, Universidad Central de Venezuela, Apartado Postal 47102, Caracas 1020A, Venezuela
IISección de Bioquímica Médica, Instituto de Medicina Experimental, Facultad de Medicina, Universidad Central de Venezuela, Apartado Postal 50587, Caracas 1040A, Venezuela
IIICentro de Botánica Tropical, Escuela de Química, Facultad de Ciencias, Universidad Central de Venezuela, Apartado Postal 47102, Caracas 1020A, Venezuela
IVLaboratorio de Espectroscopia Láser, Escuela de Química, Facultad de Ciencias, Universidad Central de Venezuela, Apartado Postal 47102, Caracas 1020A, Venezuela

 

 


ABSTRACT

The aqueous and ethanol extracts derived from twelve plant species collected in the Venezuelan Amazon have been tested for antioxidant activity using a DPPH radical and inhibitory effect on the hydrolysis of glucose-6-phosphate in intact and disrupted microsomes. Without exception, all the extracts inhibited, to a greater or lesser degree, microsomal G-6-Pase enzymatic activity, resulting in greater inhibition on intact microsomes than on disrupted ones. Marked effects were observed for aqueous and ethanol extracts of: Tontelea ovalifolia, Gustavia pulchra, Phthirusa verruculosa, Phthirusa castillana, Psittacanthus acimarius, Tetrapterys styloptyera and Vismia japurensis. Ethanol extracts were more effective DPPH radical scavengers than the corresponding aqueous extracts in all the cases. The ethanol extract of Endlicheria anomala and the aqueous extract of Phthirusa verruculosa, showed the best IC50 with 100 and 250.0 ppm, respectively. The Kobs calculated for the alcoholic extracts were lower than those of the aqueous extracts for the same species, except Psittacanthus acimarius. These results could be related to different concentrations, or more likely different compositions of active principles in both extracts.

Keywords: Amazonian plants, antidiabetic activity, antiradical activity, glucose-6-phosphatase.


RESUMO

Os extratos aquoso e etanólico derivados de doze espécies coletadas na Amazônia venezuelana foram testados quanto à atividade antioxidante utilizando um radical DPPH e o efeito inibitório sobre a hidrólise de glicose-6-fosfato nos microssomas intactos e perturbados. Sem exceção, todos os extratos inibiram, em maior ou menor grau, a atividade enzimática microssomal de G-6-Pase, resultando em maior inibição nos microssomas intactos do que nos perturbados. Efeitos marcantes foram observados para os extratos aquoso e etanólico de: Tontelea ovalifolia, Gustavia pulchra, Phthirusa verruculosa, Phthirusa castillana, Psittacanthus acimarius, Tetrapterys styloptyera e Vismia japurensis. Os extratos etanólicos foram seqüestradores do radical DPPH mais eficazes do que os correspondentes extratos aquosos em todos os casos. O extrato etanólico de Endlicheria anomala e o extrato aquoso de Phthirusa verruculosa exibiram as melhores CI50 com 100 e 250.0 ppm, respectivamente. Os valores de Kobs calculados para os extratos alcoólicos foram mais baixos do que os dos extratos aquosos das mesmas espécies, exceto Psittacanthus acimarius. Estes resultados poderiam estar relacionados a diferentes concentrações, ou mais provavelmente a diferentes composições de princípios ativos em ambos extratos.

Unitermos: Plantas amazônicas, atividade antidiabética, atividade anti-radicalar, glicose-6-fosfatase.


 

 

INTRODUCTION

Free radicals (ROS) are atoms or atomic groups containing unpaired electrons that indiscriminately pick up electrons from other species, converting those into secondary free radicals, and thus setting up a chain reaction that can cause substantial biological damage (e.g. lipids, proteins, DNA) leading to many chronic diseases like cancer, Parkinson, Alzheimer, diabetes, and aging (Halliwell, 1994; Finkel and Holbrook, 2000).

Oxygen free radicals can initiate peroxidation of lipids, which in turn stimulates glycation of protein, inactivation of enzymes and alteration in the structure and function of collagen basement and other membranes, and play a role in the long term complication of diabetes (Collier et al., 1990; Boynes, 1991).

Plants may be a source of a wide variety of free radical scavenging molecules, such as phenolic compounds (e.g. flavonoids, coumarins, quinones, etc), nitrogen compounds (alkaloids), terpenoids and some other metabolites (Larson, 1988; Delazar et al., 2006). Finding new natural sources of antioxidant compounds with potential antiradical activity can be useful to future therapy against diabetes mellitus (Mc Cune and Johns, 2002; Sabu and Kuttan, 2002; Tiwari and Rao, 2002; Silva et al., 2005).

The antioxidant activity was assessed using the 1,1-diphenyl-2-picryl-hydrazyl (DPPH) radical which is widely used for quickly determination of polyphenols antioxidant capacity (Mc Cune and Johns, 2002; Silva et al., 2005; Vicentino and Menezes, 2007). Generally, the kinetics of H atom transfer is not evaluated, however could be even more important than the ability of antioxidants to transfer labile H atom to this radical (Koleva et al., 2001). Several studies of free radical scavenging reaction reported kinetic data like Kobs to estimate the "efficiency" or capacity of antioxidants present in plant extracts (Naik et al., 2004; and 2006).

On the other hand, previous results of the biological screening, referred to brine shrimp lethality test, cardiovascular and glucose-6-phosphatase (G-6-Pase) assays of 17 plants belonging to 13 families from the Amazon region was reported (Jiménez et al., 2001). It is known that the G-6-Pase enzyme complex plays a critical role in blood glucose homeostasis and in type II diabetes (Westergaard and Madsen, 2001).

In this paper we present glucose-6-phosphatase and DPPH based antioxidant assay from the ethanol and aqueous extracts of 13 Amazonian species. To our best knowledge, there are few data on mentioned activities of these plants. In the DPPH assay, we report the kinetic data and % inhibition. We also report preliminary phytochemical analyses of these extracts in order to find out possible metabolite and activity relationship.

 

MATERIAL AND METHODS

Plant collection

The specimens were collected around the Cataniapo River, 8 km southeast from Puerto Ayachucho City, capital of the State of Amazonas, cartographically situated between 5° 36'-5° 39'N and 67° 6'-67° 29'W, with an altitude of 80-250 m above sea-level. Voucher specimens are deposited in the National Herbarium of Venezuela (VEN) and the Ambiental Ministry Herbarium at Puerto Ayachucho City (TFAV). Complete plant names, families and authority are indicated in Table 1.

 

 

Extract preparation

The collected fresh leaves and twigs from each plant were kept in cloth bags until the end of every day field work, then chopped into pieces, filled a glass bottle of 500 mL capacity with 95% ethanol, and stored for two months at room temperature to accomplish exhaustive extraction. Then, the ethanol extract was decanted and concentrated in vacuum to dryness. The dry ethanol extract was treated with distilled water and the water soluble part was freeze-dried. The preparation thus obtained, named aqueous extract, was kept in a glass vial at -20 °C until biological assays were performed. The residual water-insoluble part is named ethanol extract in this work. These extract preparation procedures were not controlled quantitatively.

Phytochemical screening

Preliminary phytochemical analysis was carried out using thin layer chromatography. The TLC analysis was performed on silica gel plates developed with a mixture of dichloromethane-methanol (8:2 and 9.75:0.25). Spots were revealed by the following spray-reagents: Dragendorff reagent for alkaloids as orange spots; 5% methanol solution of saturated ceric sulphate in concentrate sulphuric acid for detection of terpenes and flavonoids, the presence of triterpenoids suggested by violet spots and flavonoids by yellow spots (Stahl, 1969; Bilia et al., 1996); Phosphomolybdic acid for lipids, fatty acids, steroids and essential oils (Stahl, 1969) with black or dark green spots and the universal Godin reagent, the observation of violet or blue and red spots is indicative of the presence of monoterpenoids including essential oils. Detection of polyphenols e.g. flavonoids, xanthones, naphthoquinones were suggested by yellow spots and secoiridoids by brown spots with the same Godin reagent (Wagner et al., 1984).

Biological assays

Glucose-6-phosphatase assay

Liver microsomes were purified as described from rats fasted overnight (Marcucci et al., 1983). Protein concentration was estimated using the modification of the Lowry method described by Markwell et al. (1978). The G-6-Pase assay of intact and disrupted microsomes using Histone II A (Sigma Chemical Co. USA) was performed following Burchell et al. (1988). In brief, the assay was carried out with 40 µL, 5 mM of G-6-P as substrate in the absence (control) or in the presence of 40 µL, 520 ppm, of aqueous or alcoholic extracts in 10 % DMSO and finally 20 µL (20 - 30 µg) of microsomal protein to give a 100 µL final volume. The reaction was taken in a water bath at 30 ºC for 10 min. It was stopped by adding 0.9 mL of 0.28% ammonium molybdate, 1.11% sodium dodecyl sulphate and 1.11% ascorbic acid in 0.33 M sulphuric acid. The mixture was incubated at 47 ºC for 20 min and the absorption of colored complex was recorded at 820 nm. Phloridzin (250 ppm) was used as a positive control. The activity is expressed as mmol phosphate released/h/mg of protein and each value represents the average of 5 separate experiments ± standard deviation. The results are also expressed as the percentage of inhibition in comparison with control.

Antiradical activity

Radical scavengers detection on TLC plates was performed using the DPPH method (Cuendet et al., 1997), being positive those compounds which exhibited yellow spots against a purple DPPH background.

Quantitative evaluation of radical scavenging abilities of the aqueous and ethanol extracts was carried out by uv spectrophotometric measurement using quercetin as reference compound. DPPH has a purple colour (λmax 515-517 nm) and becomes colorless in the presence of a substance capable of donating an electron. Absorbance decrease of freshly prepared 60 µM solution of DPPH in methanol in presence and absence of different concentrations of plant extracts was continuously recorded at 515 nm at 25 ºC every 0.5 s. All the experiments were carried out in triplicate. The rate constants data were obtained to 1-5 min using an extract concentration corresponding to a total consumption of DPPH (Naik et al., 2004 and 2006; Andrade et al., 2007; Rocha et al., 2007).

 

RESULTS

Tables 1, 2, and 3 present the results of a preliminary phytochemical analysis, effects on the enzymatic activity of G-6-Pase and evaluation of the antiradical activity of 23 extracts derived from 12 plant species collected in the Venezuelan Amazon.

 

 

 

 

Phytochemical screening

Table 1 presents the preliminary phytochemical analysis of the extracts using thin layer chromatography. Almost all the ethanol extracts showed possible presence of triterpenoids and essential oils as blue-violet and red spots by ceric sulphate and Godin reagents. The majority of the aqueous and ethanol extracts showed the presence of alkaloids using the Dragendorff reagent. Secoiridoids were detected in the aqueous extracts of half of the plants examined, but less in the alcoholic extracts. Polyphenolic compounds other than flavonoids were observed only in C. panamensis alcoholic extract using the Godin reagent.

On the other hand, marginal presence of terpenes was observed in the aqueous extracts. Saponins were observed in the majority of the extracts. Whilst, yellow spots indicative of flavonoids using ceric sulphate reagent, were observed only in G. pulchra and P. acimarius ethanol extracts.

Glucose-6-phosphatase activity

The data are expressed in % inhibition in order to compare them with the results shown in previous reports (Jiménez et al., 2001). Without exception, all the extracts inhibited, to a greater or lesser degree, microsomal G-6-Pase enzymatic activity, resulting in greater inhibition on intact microsomes than on disrupted ones. Marked effects (>70 %) were observed for both aqueous and alcoholic extracts of T. ovalifolia, G. pulchra, P. verruculosa and P. castillana, P. acimarius, T. styloptyera and V. japurensis (Table 2). These plants showed presence of alkaloids, secoridoids and saponins (Table 1). It is worth to note that all the extracts mentioned above showed more inhibition than the positive control phloridzin (Table 2).

Antiradical activity

Each extract was chromatographed on TLC plate in order to evaluate qualitatively radical scavenging ability of the components present in the extracts. The plates were sprayed with DPPH methanol solution and heated. A pale yellow spot against a DPPH purple background is indicative of trapping DPPH radical. The results are presented in Table 1. Spots corresponding to saponin, alkaloid and secoiridoid in the aqueous extracts from T. ovalifolia, P. acimarius, P. verruculosa, T. styloptera and V. japurensis showed positive yellowish color.

The IC50 (ppm) and Kobs (s-1) values of the extracts are shown in Table 3. The aqueous extracts of P. verruculosa, and P. acimarius, in which alkaloids, saponins and secoiridoids were detected, showed the best IC50 with 250.0 and 337.97, respectively (Table 3). The aqueous extracts of T. ovalifolia, E. anomala, T. mucronata, C. panamensis, P. castillana and V. japurensis, showed IC50 values between 600-900 ppm (Table 3). I. alata and G. pulchra, showed weak effects with IC50 values higher than 1000 ppm (Table 3), although in these extracts we detected alkaloids for I. alata, and saponins and alkaloids for G. pulchra (Table 1).

All the ethanol extracts tested had an IC50 lower than 700 ppm and were more effective DPPH radical scavengers than corresponding aqueous extracts in all the cases. The best results were obtained with E. anomala, P. castillana and P. acimarius which showed IC50 of 100, 147.34 and 142.80 ppm, respectively, followed by P. verruculosa (164.28 ppm) and T. styloptera (153.85 ppm). The other six extracts tested had lower activities with IC50 close to 600 ppm.

The phytochemical studies showed the presence of alkaloids and with a minor proportion, secoiridoids in almost all the extracts. Flavonoids were detected only in the ethanol extracts of G. pulchra and P. acimarius. Only mono and triterpenoids were detected in the ethanol extract of E. anomala. For this reason, no assumption can be made about the DPPH scavenger activity with respect to classes of compounds in these extracts. Nerveless, some triterpenoids with the aromatic phenol moiety like cognatin, isolated from Cheiloclinium cognatum, and some phenolic components of essential oils like carvacrol detected in the Thymus genus had showed DPPH scavenger activity (Jeller et al., 2004; Tepe et al., 2005). Only in the ethanol extract of C. panamensis non-flavonoid polyphenols were detected.

All the aqueous extracts were found to bleach the DPPH purple color. For I. alata, T. ovalifolia and C. panamensis, this bleach was reached in a few seconds, while, for the other species, the bleach was observed in the first five minutes. This scavenging of the DPPH radical could be considered mainly due to the presence of metabolites like essential oils, alkaloids, and polyphenols (Table 1 and 3).

The reaction rates observed for E. anomala and P. castillana, were slower than the other extracts. This probably means that the compounds containing labile hydrogen in these extracts are in minor proportion. The Kobs, calculated for the alcoholic extracts, are lower than those of the aqueous extracts for the same species, except P. acimarius. These results can be related to different concentrations, or more likely different compositions of active principles in both extracts.

 

DISCUSSION

Alkaloids and essential oils were detected in almost all the aqueous and alcoholic extracts. Secoiridoids were observed in the Loranthaceae family (Table 1). Saponins were common to eight of the aqueous extracts and triterpenoids were detected in almost all the alcoholic extracts.

Psittacanthus calyculatus has been used in the traditional Mexican medicine as antidiabetic (Andrade-Cetto and Heinrich, 2005; Barbosa-Filho et al., 2005). Irlbachia alata, has been traditionally used as antimalarial in the French Guiana (Bertani et al., 2005) and one novel phosphatidylcholine, irlbacholine isolated from this specie, has been used as precursor for synthetic analogs with antifungal activity (Lu et al., 1999). Calathea warscewiczii is used by the Panama traditional medicine for several diseases (Gupta et al., 2005). The plant (aerial) infusions of Phoradendron bolleanum and Phoradendron tomentosum have been used in Mexico by its hypoglycaemic effect. A phytochemical study of these species showed the presence of tannins, saponins, flavonoids, coumarins from P. bolleanum and phoratoxins from Phoradendron tomentosum (Andrade-Cetto and Heinrich, 2005). Tetrapterys styloptera and Phthirusa retroflexa have been investigated for its anti-Mycobacterium tuberculosis activity (Rojas et al., 2003).

No phytochemical and biological reports from Vismia japurensis have been made. Nevertheless, 5-dihydroxy-8-methoxyxanthone has been isolated from Vismia amazonica and the plant has been tested for antimutagenic activity (Sangwan et al., 1998).

Alkaloids were detected in almost all the extracts studied (Table 1). Those compounds are known to exhibit a variety of biological activities including inhibition of malignant cell growth and proliferation, leishmanicidal, anti-HIV, anti-inflammatory and antioxidant activities (Bacher et al., 2001; Chan-Bacab and Peña-Rodríguez, 2001; Račková et al., 2004; Singh et al., 2005; Barbosa-Filho et al., 2006; Castilhos et al., 2007). On the other hand, secoiridoids are reported to show leishmanicidal and antioxidant activity (Chan-Bacab and Peña-Rodríguez, 2001; Carrasco-Pancorbo et al., 2005). Triterpenoids and their glycosides (saponins) display a variety of biological activities such as immunomodulatory and antitumoral activity (Plohmann et al., 1997; Fulda et al., 1999). Polyphenols like flavonoids and catechins have been shown to exert a broad spectrum of anti-HIV, leishmanicidal and antioxidant activity (Plumb et al., 1998; Yokozawa et al., 1998; Chan-Bacab and Peña-Rodríguez, 2001; Singh et al., 2005).

We have studied several plants belonging to the Amazonian region trying to seek a relationship between the inhibition of the G-6-Pase activity and the antiradical activity. These plants cited in Table 1, have not been reported previously concerning G-6-Pase enzymatic activity and DPPH antiradical activity.

G-6-Pase is the enzyme that catalyses the last step of neoglucogenesis and glycogenolysis, and its structure has been elucidated as five polypeptide subunits (Burchell and Waddell, 1991). Its inhibition might be of some help in the control of the hyperglycaemia present in the diabetes. A relationship between inhibitory effects of the G-6-Pase activity and the presence of some metabolites like alkaloids, saponins, secoiridoids and polyphenols was observed for the evaluated extracts (Tables 1 and 2). In general, the extracts were much more effective on intact microsomes than on disrupted ones. This fact means that the extract causes an inhibitory action mainly on the G-6-P transporter (T1 transporter) but also on the G-6-Pase catalytic subunit. It is also possible that the extracts affect the flow-out of phosphate ion and/or glucose and the products of G-6-P hydrolysis in microsomes (T2 and/ or T3 transporter), (Van Schaftingen and Gerin, 2002). Three species belonging to the Loranthaceae family were notably effective as well as V. japurensis, T. ovalifolia and T. styloptera. The ethanol extracts result more effective than the aqueous ones with inhibition percentages between 60 - 95 % for nine of the evaluated extracts.

Based on the mechanism of the DPPH reduction, and on previous studies of the antioxidant plants (unpublished results), it is possible to propose that the antioxidant activity could be due, at least in part, to the presence of metabolites with a labile hydrogen like phenolic compounds (e.g. flavonoids, coumarins, naphthoquinones, tannins, etc.) and nitrogen-containing compounds (alkaloids).

The results about the antiradical activity displayed by the ethanol extract of E. anomala are very singular. Its alcoholic extract is rich in compounds like terpenoids (essential oils and triterpenoids); Nerveless, the best antiradical activity was observed. Monoterpenoids like carvone possess high antioxidant activity (Elmastas et al., 2006; Souza et al., 2007) and some components of essential oils from Artemisia species have been showed antioxidant activity (Kordali et al., 2005).

The results from the Loranthaceae family are interesting; a relationship between the phytochemical constitution, the G-6-Pase inhibition activity and the antiradical activity (IC50 and Kobs) was observed for this family in both extracts. In fact, this family conformed by P. verruculosa, P. castillana and P. acimarius, rich in alkaloids, secoiridoids and flavonoids (P. acimarius), showed high G-6-Pase inhibition and significant antiradical activity. Another interesting alkaloid-containing plant with presence of high antidiabetic and antioxidant activities was T. styloptera of Malpighiaceae family. These results suggest that the species of the Loranthaceae family are possible targets for further test as antidiabetic and antioxidant plants.

 

ACKNOWLEDGMENTS

This work was supported by grants 03-12-5326-2003; 09-4788-05; 09-4706-05 from the Consejo de Desarrollo Científico y Humanístico, Universidad Central de Venezuela and S195001697; S12002000284 from FONACIT.

 

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