In vitro inhibitory activities of selected Australian medicinal plant extracts against protein glycation, angiotensin converting enzyme (ACE) and digestive enzymes linked to type II diabetes

We first examined the extracts to determine their content of phenolics and flavonoids. Phenolic and flavonoid compounds are secondary metabolites ubiquitously found in different parts of plants that commonly exhibit antioxidant activities. The total phenolic content of the tested plant extracts ranged from 72.36 ± 15.84 to 347.87 ± 14.90 μg GAE/mg (Table 2). Among the leaves, fruits and bark extracts, the highest total phenol content was in P. banksii fruits, whereas M. pinnata inner bark extracts had the lowest (Table 2). The extracts contained flavonoids in the range from 3.36 ± 0.87 to 26.30 ± 2.75 μg QE/mg (Table 2). Interestingly, P. pubescens fruits had the lowest flavonoid content, while the leaves of the same plant had the second highest flavonoid content among the selected medicinal plants.

Antioxidant activity of the extracts was then assessed using two different methods, the FRAP and DPPH assays. The effect of selected extracts on FRAP and DPPH measured in this study are shown in Table 2 and Fig. 1, respectively. FRAP, a measure of antioxidant power, determines the reducing ability of an antioxidant reacting with a ferric-tripyridyltriazine (Fe³⁺-TPTZ) complex to form coloured ferrous-tripyridyltriazine (Fe²⁺TPTZ). Test samples that favour reduction of the complex from Fe³⁺-TPTZ to Fe²⁺-TPTZ, with indication of an intense blue colour development confirms the presence of a reductant ie., antioxidant [38]. FRAP values in the selected sample extracts ranged from 26.46 ± 1.73 to 453.30 ± 51.79 μg AAE/mg (Table 2). P. banksii leaf and fruit extracts and the P. pubescens leaf extract were significantly higher (p < 0.05) whereas the M. pinnata inner bark extract had the lowest FRAP values. The DPPH assay is a measure of the reduction of alcoholic DPPH solution in the presence of a hydrogen-donating antioxidant due to the formation of a non-radical form, DPPH-H. In this assay, the purple colour is reduced to a yellow coloured diphenylpicrylhydrazine by the test sample containing antioxidant [39]. For the tested extracts, all except M. pinnata inner bark extract showed very high radical scavenging activity (Fig. 1).

Several reports have shown that plant derived natural products are effective free radical or active oxygen scavengers which are attributed to high levels of phenolics and flavonoids [7, 40]. In this study, total phenolic and flavonoid content were comparable to previous studies reported on Australian food plants [41], but relatively higher than the other Australian medicinal plants [21]. In the present study, the total phenolic content of the medicinal plant extracts significantly correlated with FRAP (r ² = 0.7568, p < 0.001) and DPPH (r ² = 0.5684, p < 0.01), respectively (Table 3). However, there was no correlation observed between the total flavonoid content and FRAP or DPPH (Table 3). Differences in correlations for antioxidant activity and flavonoid and total phenolic content have been reported previously [42]. The result may suggest that components other than flavonoids are responsible for antioxidant effects.

Extracts were screened to examine their inhibitory activity to enzymes relevant to the management of diabetes. A common therapeutic approach used in controlling non-insulin dependent hyperglycaemia is through inhibition of α-amylase and α-glucosidase that control the breakdown and absorption of glucose and its precursors in the small intestine. For α-amylase inhibition, IC₅₀ values for the extracts ranged from 160.20 ± 27.92 to 310.17 ± 12.88 μg/mL (Table 4). The IC₅₀ values for α-amylase inhibition of P. banksii (leaves, fruits and roots), P. pubescens (leaves and fruits) and M. pinnata (inner bark) were significantly lower (p < 0.05) in comparison to other sample extracts. For α-glucosidase inhibition, IC₅₀ values ranged from 167.83 ± 23.82 to 350.23 ± 24.05 μg/mL (Table 4). The IC₅₀ values of P. banksii (leaves, fruits), P. pubescens (leaves) and M. pinnata (inner bark) extracts were significantly lower (p < 0.05) than P. banksii (roots), P. pubescens (fruits), M. pauciflorum (leaves) and Grewia mesomischa (root bark).

A previous study on medicinal plant extracts, reported IC₅₀ values for α-amylase ranging from 2070 to 13,740 μg/mL and α-glucosidase ranging from 2740 to 20,950 μg/mL [20]. These values are relatively high in comparison to the extracts tested in the present study and could be attributed to extraction techniques. The IC₅₀ values of enzyme inhibition presented in our study were slightly higher compared to a previous report on Australian medicinal plant extracts [21], but were comparable to other medicinal plants [43, 44]. It has been reported that polyphenols, flavonoids and the antioxidant constituents of medicinal and food plants inhibit α-amylase and α-glucosidase [7, 43, 44]. In the present study, the IC₅₀ values for both α-amylase and α-glucosidase were poorly correlated with the total phenolic, flavonoid, DPPH and FRAP (Table 5). The lack of correlation between the total phenolics and enzyme inhibitory activities has been previously reported [41, 45]. The various relationships reported in the literature clearly suggest that the total phenolics and their antioxidant capacities do not define hyperglycaemia related enzyme inhibition. This indicates the inhibitory actions of the tested extracts on α-amylase and α-glucosidase may be mediated by the action of constituents other than the phenolic and flavonoid compounds.

Extracts were assessed for inhibition of formation of advanced glycation endproducts (AGEs) in a model of protein glycation. AGEs are classified into two major groups: fluorescent (pentosidine, crosslines, and imidazolones) and non-fluorescent (N^ε-carboxymethyllysine and N^ε-carboxyethyllysine) [11, 12]. The formation of AGEs occurs through multiple processes related in part through ROS [9]. Medicinal plants have demonstrated their ability to inhibit the process of protein glycation, thus preventing alteration of the biological activity of protein, their degradation and conversion to AGEs [22, 23]. To our knowledge there are no reported studies on antiglycation activities of Australian medicinal plants. In the present study, an in vitro screening method was employed to determine the inhibitory effects of extracts on formation of fluorescent AGEs. The model system used a high concentration of reducing sugar to speed up the glycation process as glycation occurs very slowly under physiological conditions. Phosphate buffer (0.2 M, pH 7.4) increases the proportion of the open chain, reactive form of the reducing sugar in solution thus favouring the kinetics of protein glycation including formation of fluorescent AGEs [46]. A temperature-time at 37 ± 1 °C for 3 weeks was chosen to achieve minimally-modified protein under physiological conditions and to prevent any deterioration of the bioactive compounds in the plant extracts. Fluorescence intensity was determined using isolated protein with appropriate dilution to reduce quenching effects of plant extracts and coloured solutions due to glycation.

The antiglycation potential of the selected extracts were compared on the basis of their IC₅₀ values and ranged from 34.49 ± 4.31 to 160.74 ± 3.86 μg/mL (Table 4). Of the selected samples, P. banksii fruits and roots had significantly lower (p < 0.05) levels, whereas P. pubescens leaves showed the highest (p < 0.05) antiglycation IC₅₀ value. In P. pubescens, different plant components indicated different levels of antiglycation potential (Table 4). This suggests that the degree of antiglycation activities could vary from plant to plant and in different tissues from the same plant. It is suggested that the ability to reduce the formation of AGEs is closely related to the antioxidant properties of food and medicinal plants [22, 47]. Our studies showed no correlation between the antiglycation potential and the antioxidant activities (FRAP, DPPH) (Table 5). This indicates the efficiency of antiglycation potential by the tested extracts as an independent pathway rather than their ability in scavenging free radicals formed during protein glycation. Other mechanism of antiglycation such as blocking carbonyl or dicarbonyl groups in reducing sugars, breaking the cross-link structures in the formed AGEs and inhibiting the formation of late-stage Amadori products have been reported through use of natural products [47, 48]. Further comprehensive studies of the extracts tested in this study are required to evaluate the antiglycation mechanisms described above.

The plant extracts were also tested for ACE inhibitory activities. ACE is another enzyme that has an impact on metabolic syndrome - the stimulation of ACE causing high blood pressure. Inhibition of ACE by medicinal plant extracts to reduce hypertension has been previously reported [43, 44]. Recently effects of polyphenolic-rich fractions of the native Australian herbs and foods on ACE inhibition have been reported [41, 49], however, to our knowledge the present study is the first to report on the role of Australian medicinal plants on ACE inhibitory activities. For ACE inhibition, IC₅₀ values ranged between 266.27 ± 6.91 to 695.17 ± 15.38 μg/mL (Table 3), with P. banskii leaves and P. pubescens leaves showing comparable and higher ACE inhibitory activities. M. pinnata inner bark extracts showed significantly (p < 0.05) lower ACE inhibitory activities. Results from our studies were comparable to ACE inhibitory activities of Lebanese traditional medicinal extracts reported previously [44]. Further, another study with different extracts of Gynura divaricata extracts has shown IC₅₀ values for ACE inhibition ranging from 370–1540 μg/mL [43]. In the present study, a negative correlation between IC₅₀ values of ACE inhibitory activities and total phenolics (r² = −0.775, p < 0.001), FRAP (r² = −0.845, p < 0.001) (Table 5) were seen in the tested extracts. In addition, moderate negative correlation between IC₅₀ values of ACE inhibition and DPPH (r² = −0.510, p < 0.05), but not the flavonoid content were found (Table 5). P. banksii leaves and P. pubescens leaves have shown lower IC₅₀ values for ACE inhibition than the previous studies [43, 44], suggesting that a lower concentration of these extracts can be used to obtain 50 % inhibition of ACE. These results suggest that the Australian medicinal plants could be further investigated for treating hypertension through ACE inhibition.

There have been limited previous studies of the medicinal activities of Australian species tested in this study. Extracts of different parts of P. pubescens and P. banksii were found to have promising antiglycation and enzyme inhibitory activities which have not been previously reported. Extracts of Petalostigma species including P. pubescens, P. augustifolium and P. triloculare have previously been found to exhibit antimicrobial activity [50, 51], however very little is known of the chemistry of the genus. A GC-MS analysis of a fruit extract of P. triloculare showed the presence of low molecular weight compounds including acetic acid, 2,2-dimethoxybutane, decane, undecane, 1,2-benzenediol, 1,2,3-benzenetriol and benzoic acid [51]. The heartwood of P. pubescens has also been shown to contain diterpenoids including a cytotoxic diterpene (−)-sonderianol [52]. Another species, P. sericea, has been found to contain oleanolic acid [53]. No previous studies of this genus have examined effects on carbohydrate metabolism, antiglycation activities or ACE inhibition, and the possible active constituents are unknown.

Various species in the genus Grewia have uses in traditional medicine systems from a number of countries [54] and some species have been studied for their antioxidant effects. However there are no previous reports examining the antioxidant and enzyme inhibitory of effects of the Australian species G. mesomischa examined in this study.

The species Memecylon pauciflorum occurs naturally in Northern Australia and also occurs in SE Asia, southern Malesia and New Guinea [55]. Other Memecylon species used in traditional medicine in India including those reported as Memecylon umbellatum, M. talbotianum, M. edule and M. malabaricum have been studied for their medicinal effects including antioxidant [56, 57], anti-inflammatory [58, 59] and in vivo antidiabetic effects [60].

Millettia pinnata (synonym Pongamia pinnata) has a broad distribution from India, through central and south-eastern Asia, Indonesia and into northern Australia. M. pinnata grown in India has been studied for a number of activities. An extract of the leaves of the plant collected in Tamil Nadu, India was recently found to have moderate antioxidant activity and significant nitric oxide scavenging activity [61]. The total phenolic content of the leaf extract of M. pinnata was reported in that study as 4.1 ± 1.5 mg/g (μg/mg), lower than the total phenolic content of inner bark extract reported in our study (Table 2). Extracts of the stem bark have been shown to have antihyperglycaemic activity in diabetic mice and recently have been shown to decrease blood glucose levels, and improve electrocardiographic and hemodynamic parameters and improve oxidative stress in a model of cardiomyopathy in diabetic rats [62]. The stem bark extract has been shown to contain alkaloids, terpenoids (including triterpenes), steroids, flavonoids and volatile oils, with the isolated triterpenoid cycloart-23-ene-3β, 25-diol (B2) possessing antidiabetic activity and antioxidant activity in diabetic animals [63]. The bark has also been shown to have in vitro wound healing activity [64]. As M. pinnata has been noted to be a variable species and a number of varieties [65] it would of interest to further compare the medicinal activities and chemistry of M. pinnata native to northern Australia with that in other countries.