Phytochemical profiling and in vitro screening for anticholinesterase, antioxidant, antiglucosidase and neuroprotective effect of three traditional medicinal plants for Alzheimer’s Disease and Diabetes Mellitus dual therapy

Titled plants B.axillaris (BA), H.indicus (HI) and R.mysorensis (RM) are widely distributed throughout tropical Asian countries. The aerial parts of plants were collected in October 2013 from Nallamala hills of Kadapa and its surroundings, a place situated in Andhra Pradesh, India. Dr. A. Madhusudana Reddy, Assistant Professor, Department of Botany, Yogi Vemana University identified the harvested materials employed for the purpose. The herbarium specimens with voucher no. YVU15 AGD, YVU45 AGD and YVU79 AGD were deposited in the herbarium of Yogi Vemana University. The plant materials were air dried at 25–30° C for two weeks, weighed, powdered and stored in darkness at –20 °C until further analysis.

Each ground plant material (100 g) was extracted twice with 500 ml of 90% methanol by soaking for two days. The plant extracts obtained were filtered in vacuo through Whatman No.1 filter paper and the extraction process was repeated twice. The combined filtrates were concentrated using rotavapour (Heidolph, Germany) at 30 °C. The obtained methanolic extracts were fractionated sequentially by different solvents based on polarity viz. chloroform, n-butanol and water for decreasing of complexity of extract and for choosing active fraction. Yield percentage for each extract was calculated. The percentage yield of methanolic extracts per 100g of dry weight for BA, HI and RM are 20.58, 15.69 and 16.97, respectively. The percent yield of CHCl₃, n-BuOH and H₂O fractions are 3.9, 2.56 & 2.98 for BA; 4.98, 5.69 & 6.98 for HI; 11.12, 7.44 & 7.01 for RM, respectively.

The AChE and BuChE inhibition assay was performed spectrophotometrically for methanolic extracts and its derived fractions using acetylthiocholine iodide and butyrylthiocholine iodide (Sigma-Aldrich, USA), respectively as substrate following the method of Ellman et al., with minor changes [20]. In a 96–well plate, 10 μL of enzyme from stock solution (AChE, 2U/mL and BuChE, 2U/mL) was taken and 10 μL of plant extract or fraction (15–150 μg/mL) and 100 μL Phosphate buffer were added to them. To this mixture, 50 μL DTNB solution (3.96 mg DTNB and 1.5 mg sodium bicarbonate dissolved in 10 mL of 200 mM phosphate buffer pH 7.7) was added and incubated for 5 minutes at 25°C. Substrates with the volume of 15 μL (10.85 mg acetylthiocholine iodide or butyrylthiocholine iodide in 5mL phosphate buffer) were added and incubated for further 5 minutes at 25°C. The colour developed due to the formation of 5-thio-2-nitrobenzoate anion was measured at 412 nm. Galantamine, at 0.12, 0.23, 0.46, 0.92, 1.84, 3.68 and 7.37 μg/mL, and the reaction mixture excluding plant sample were taken as positive and negative controls, respectively. The percent of inhibition and IC₅₀ values were determined.

The inhibition of α– and β–Glu activity by methanolic extracts and its derived fractions was assayed with the modified method of Shibano et al. [21]. p-Nitrophenyl α-D-glucopyranoside and p-nitrophenyl β-D-glucopyranoside were used as subtrates for α– and β–Glu, respectively. The assay solution with 10 μL extract or fraction at variuos concentrations (15, 30, 90 and 150 μg/mL), 100 μL phosphate buffer pH 6.8 and 50 μL of enzyme (α–Glu 0.15 unit/mL or β–Glu 0.15 unit/mL) was incubated at 37°C for 15 min. Substrates with a volume of 50 μL (0.5 mM p-nitrophenyl α-D-glucopyranoside or p-nitrophenyl β-D-glucopyranoside) were added and incubated at 37°C for 15 min. To this, added 50 μL of 200 mM Na₂CO₃ to terminate the reaction. Enzyme activity was determined spectrophotometrically at 415 nm through measuring the quantity of p-nitrophenol released. The percent of inhibition and IC₅₀ values were determined.

Kinetic characterization of enzyme inhibitions was performed at different concentrations of the substrate using relevant assay method based on enzyme [22]. Assay mixture (250 μL) contains 145 μL of 200 mM phosphate buffer (pH 7.7), 80 μL of DTNB (in case of AChE and BuChE) and 10 μL of enzyme. Inhibitors with various concentrations 15, 30, 90 and 150 μg/mL were added and incubated for 5 min at 25° C. Then, added 15 μL of substrate at different concentrations (10, 25, 50, 100 μM). Assay without inhibitor was conducted as control.

The double reciprocal plots of 1/V versus 1/[S] were constructed. In order to get inhibition constants (Ki₁ and Ki₂), secondary plots were generated with slopes and intercepts versus inhibitor concentrations.

The shade dried, powdered plant material was extracted with 90% methanol in water. The obtained crude methanolic extract was suspended into water and fractionated by successive solvent-solvent extraction with chloroform and n-butanol. Dried yield percent of 90% methanol extract of BA, HI and RM from solvent extraction by soaking was found to be 20.58, 15.69 and 16.97, respectively. The fractionation of methanolic extract produced the chloroform, n-butanol and residual aqueous fractions. Initially, methanol showed the highest extractive capacity. As indicated by data, different extractive capacities of solvents used for fractionation were in descending order of residual aqueous > n-butanol > chloroform fraction of each solvent.

The methanolic extracts of three plants (BAM, HIM and RMM) and its derived fractions (BAC, BAB, and BAW; HIC, HIB, and HIW; RMC, RMB, and RMW) were screened for their inhibitory activity against AChE and BuChE enzymes using Ellman’s colorimetric method [20]. The standard drug Galantamine was used as positive control. All the plant extracts and fractions evaluated at different concentrations (15, 30, 90 and 150 μg/mL) displayed dose-dependent inhibitory activities against enzymes AChE and BuChE (Fig. 1). As tabulated in Table 2, the BAM, HIM and RMM extracts were potent in inhibiting AChE and BuChE with an IC₅₀ ranges from 3.8±0.2 to 48.64±11.72 μg/mL (See Additional file 1 for IC₅₀ graphs). Among the fractions, BAC, HIC and RMC showed a higher activity than other fractions against AChE and BuChE enzymes with an IC₅₀ ranges 5.16±0.22 to 41.35±1.6 μg/mL and were observed as most potent. Thus, all these three plants can be considered as dual inhibitors of AChE and BuChE enzymes. The IC₅₀ values of galantamine were 0.77 ± 0.09 and 8.1± 0.02 against AChE and BuChE, respectively. All titled plants showed lesser activity against AChE when compared to galantamine. However, BAM, HIM, HIC and RMM exhibited stronger potency against BuChE than galantamine. Overall, the most prominent AChE inhibition was recorded with BA while HI was most active against BuChE. Comparatively HI and RM showed better activities against BuChE whereas BA was active against AChE. Regarding n-butanol fractions, BAB and RMB showed moderate activity against both the enzymes. In case of water fractions, only HIW displayed moderate activity compared to BAW and RMW against AChE and BuChE.

To assess the antidiabetic potency of titled plants, the extracts and derived fractions were tested for their α– and β–Glu inhibitory activity by in vitro enzyme assay as per earlier reported methods [21]. The IC₅₀ values of tested extracts and fractions on α– and β–Glu are showed in Table 2 (See Additional file 1 for IC₅₀ graphs). Acarbose and D-Glucono-δ-lactone were used as reference drugs and showed IC₅₀ values ranging between 117.20±0.017 and 10.68±0.005 against α– and β–Glu, respectively. The tested methanolic extracts (BAM, HIM and RMM) have shown varying degree of α– and β–Glu inhibition with IC₅₀ values ranging from 9.33±0.2 μg/mL to 70.11±1.9 μg/mL. Among fractions, the most active was found to be BAC, HIC and RMC with IC₅₀ values of 16.65 ± 1.99, 11.03±0.5 and 26.04±0.37 against α–Glu and 27.38±1.24, 87.64±15.41 and 25.33±0.3 on β–Glu. All the titled plants were displayed better potency than the standard acarbose against α–Glu. From these data, it is found that the fractions BAC, HIC and RMC were the most potent in inhibition of α– and β–Glu activity. HIW displayed moderate inhibition on α– and β–Glu activity; but BAB, BAW, HIB, RMB and RMW fractions were less active against both enzymes

In order to explore the mode of inhibition of most active fractions BAC, HIC and RMC, enzyme kinetic studies were conducted. The initial velocity was measured at different concentrations of the substrates (S) using three different concentrations of fractions. The reciprocal of the initial velocity (1/v) was plotted against the reciprocal of concentrations of substrates (Lineweaver-Burke plot) to calculate the rate of the enzyme activity in turn the mode of inhibition (Fig. 2) (See Additional file 1 for kinetic plots of HIC and RMC). At increasing concentration of the inhibitor, increased slopes and intercepts were noticed in Lineweaver-Burke plots. The data points were intersected in the second quadrant (upper left quadrant) of double reciprocal plots. The observations inferred a mixed type of inhibition for most active fractions [29]. For mixed inhibitors BAC, HIC and RMC, two inhibition constants Ki₁ and Ki₂ (Table 3) were computed from the secondary plots of slope versus inhibitor concentration and Y-intercept versus inhibitor concentration, respectively. The values of inhibition constants revealed that all active fractions have strong affinity to bind to the free enzyme.

The antioxidant activity of active fractions was determined using the free radicals DPPH and ABTS by the addition of various concentrations of BAC, HIC and RMC. The total data is tabulated in Table 4.

With respect to ABTS assay, the reduction of ABTS radical cation with hydrogen-donating capacity of fractions was measured spectrophotometrically. All the tested fractions had remarkable radical scavenging activity (RSA) with Trolox Equivalents of 50.37±1.68, 43.9±0.96 and 38.98±4.15 μg/mL.

Concerning DPPH assay, the degree of colour change of purple-coloured DPPH radical solution by electron donation ability of fractions was recorded [30]. In DPPH assay, all the three active fractions BAC, HIC and RMC showed strong RSA with Ascorbic acid Equivalents of 5.97 ± 0.05, 5.5 ± 0.2 and 16.4 ± 0.07 μg/mL, respectively. Ultimately, no marked difference was observed between BAC and HIC in DPPH RSA assay. However, comparatively all the fractions exerted higher activity against ABTS than DPPH indicating that the phytoconstituents of tested fractions have capacity to donate hydrogen to a free radical.

The safety of the extract is absolutely crucial for a successful drug. To grab this, the possible toxicity effects of active fractions BAC, HIC and RMC in the SK N SH cells (human neuroblastoma cell line) was measured using MTT assay. The evaluation results were summarized in Fig. 3. After 24 h incubation, fractions BAC, HIC and RMC at various concentrations (50, 100, 200 and 400 μg) displayed concentration dependent cell viability.

In all, and based on the results obtained, under the above conditions fractions BAC, HIC and RMC showed the cell viability in the range of 25 to 63%. All tested fractions attenuated the cell toxicity significantly in a concentration dependent manner.

The neuroprotective effects of active fractions against H₂O₂ induced oxidative stress in SK N SH cells were evaluated using MTT assay. When SK N SH cells were exposed to H₂O₂, the cell viability was greatly reduced in concentration and time-dependent way. The survival rate of SK N SH cells was about 44.65 % when the cells were treated with 1.0 mM of H₂O₂ for 8 h. On pretreatment with BAC, HIC and RMC at 50, 100, 200 and 400 μg, 24 h before exposure to H₂O₂, the viability of SK N SH cells was significantly increased in a dose dependent manner (Fig. 4). When the neuroprotective effect induced by fractions was compared with control, very interestingly, the fraction HIC showed higher neuroprotectivity than control at all concentrations. Fractions BAC and RMC provided almost similar neuroprotective profile to that of control at higher concentrations.

Phytochemicals such as polyphenols, flavonoids, alkaloids, terpenoids, tannins etc. that are obtained from plant sources have excellent potential to combat chronic diseases besides promising health promoting properties while acting in combination. Thus, phytochemical analysis reveals significant information about medicinal value of plants.

Phytochemical studies on the most active fractions of titled plants revealed the presence of phenolics, flavonoids, tannins, terpenoids, and alkaloids. Among quantified constituents, the total flavonoid and total phenolic content was significantly higher in all three active fractions BAC, HIC and RMC. Total phenolic contents (TPC) in the active fractions were determined using Folin-Ciocalteu method and expressed as gallic acid equivalents (GAE/g extract). Aluminium-flavonoids complex formation assay was used for the quantification of total flavonoids (TFC). The TFC was expressed as mg RE/100 g dw of extract.

Based on the data expressed in Table 5 the highest amount of flavonoids (691.6±63.26 mg RE/g dry matter) was observed in BAC while the lowest amount (156.32±13.5 mg RE/g dry matter) was detected in HIC. The phenolic content in all the plant species ranged from 182.93±29.3 to 47.12±0.07 mg GAE/g dry matter. The highest amount of phenolics was observed in BAC with 182.93±29.3 GAE/g dry matter. However, almost equal quantities of terpenoids (162.1±1.06 mg LE/g) and flavonoids (156.32±13.5 mg RE/g dry matter) were noticed in HIC. Least amount of tannins and alkaloids were detected in all three fractions. Among tested highest amount of alkaloids (76.51±5.8 mg AE/g) were found in HIC.

The correlation coefficients (R²) of the total phenol and biological activities (AChE inhibitory, β–Glu inhibitory and ABTS radical scavenging activities), and total flavonoid and biological activities of the BAC, HIC and RMC were shown in Fig. 5. The R² value of total phenol and AChE inhibitory, β–Glu inhibitory and ABTS radical scavenging activities of BAC, HIC and RMC was 0.94. 0.95 and 0.99, respectively (Fig. 5a). Similarly, R² value of total flavonoid and AChE inhibitory, β–Glu inhibitory and ABTS radical scavenging activities of BAC, HIC and RMC was 0.72, 0.74 and 0.92, respectively. From these data, it is evident that there are high correlations between AChE inhibitory, β–Glu inhibitory and ABTS radical scavenging activities and the total phenol and also the total flavonoid content.