Independent and synergistic activity of the flavonoids of <i>Gracilaria corticata</i> as promising antidiabetic agents

Sangeetha, Ragupathy

doi:10.1590/s2175-97902019000418766

Abstract

The therapeutic approaches for Type 2 Diabetes Mellitus rely most on the usage of oral hypoglycaemic drugs. These drugs have adverse side effects and hence alternative medicines are continuously explored. The present study intends to investigate the antidiabetic potential of the flavonoids present in Gracilaria corticata. The flavonoids were isolated (FEGC) and their inhibitory activity on the carbohydrate hydrolysing enzymes such as α-amylase and α-glucosidase was analysed. The flavonoids were found to inhibit α-amylase and α-glucosidase with an IC₅₀ value of 302 µg and 75 µg respectively. The synergistic effect of FEGC and luteolin was also investigated and the results show that both FEGC and luteolin inhibited synergistically at half their IC₅₀ values. The observations of this study reveal that the flavonoids of G. corticata have potential antidiabetic activity and can act independently or synergistically in the management of Type 2 Diabetes Mellitus

Keywords:
α-amylase; α-glucosidase; Antidiabetic; Gracilaria corticata; Luteolin; Synergistic

INTRODUCTION

Diabetes Mellitus (DM) is a metabolic disorder which manifests itself as hyerglycemia. The prevalence of DM is increasing at an alarming rate and it is estimated that more than 550 million people would be afflicted by it by the year 2030. Type 2 DM is the most common form of DM and its incidence is triggered by genetic, environmental and lifestyle factors (Olokoba, Obateru, Olokoba, 2012Olokoba AB, Obateru OA, Olokoba LB. Type 2 Diabetes Mellitus: A review of current trends. Oman Med J. 2012;27(4): 269-273.). Insulin resistance coupled by insufficient insulin secretion by the β-islet cells of the pancreas cause Type 2 DM (Kahn, 2008Kahn SE. The relative contributions of insulin resistance and beta-cell dysfunction in the pathophysiology of type 2 diabetes. Diabetologia. 2008;46(1):3-19.). The short and long term complications of diabetes and its relatively late diagnosis account for the morbidity and mortality seen in diabetes (Malviya et al., 2010Malviya N, Jain S, Malviya S. Antidiabetic Potential of Medicinal Plants. Acta Pol Pharm. 2010;67(2):113-118.). DM is prevalent more in certain ethnic groups and in low and middle income countries (Azevedo, Alla, 2008Azevedo M, Alla S. Diabetes in sub-saharan Africa: kenya, mali,mozambique, Nigeria, South Africa and Zambia. Int J Diabetes Dev Ctries. 2008;28(4):101-108., Global Burden of Diabetes, 2011Global Burden of Diabetes. International Diabetes Federation . Diabetic Atlas fifth edition 2011, Brussels. (cited on 2018, September 14). Available at http://www.idf.org/diabetesatlas.
http://www.idf.org/diabetesatlas... ).

The treatment for DM involves hypoglycaemic drugs, diet changes and lifestyle modifications. The spectrum of hypoglycaemic drugs includes insulin, insulin secretagogues, insulin sensitizers and enzyme inhibitors. Chronic consumption of these drugs results in undesirable side effects and economic burden (Ahmad, Crandall, 2010Ahmad LA, Crandall JP. Type 2 Diabetes prevention: a review. Clin Diab. 2010;28(2):53-54., Siddiqui et al., 2013Siddiqui AA, Siddiqui SA, Ahmad S, Siddiqui S, Ahsan I, Sahu K. Diabetes: mechanism, pathophysiology and management-a review. Int J Drug Dev Res. 2013;5(2):1-23.). Hence complementary and alternative medicine is sought after in many countries around the world. Medicinal plants, plant phytoconstituents and sea weeds are the most common forms of alternative medicine used and researched worldwide (Malviya, Jain, Malviya, 2010Malviya N, Jain S, Malviya S. Antidiabetic Potential of Medicinal Plants. Acta Pol Pharm. 2010;67(2):113-118.).

Marine organisms are promising resources of several compounds with medicinal values. Algae, also referred to as sea weeds, are large group of marine organisms, unicellular or multicellular, capable of carrying out photosynthesis (Pulz, Gross, 2004Pulz O, Gross W. Valuable products from biotechnology of microalgae. Appl Microbiol Biotechnol. 2004;65(6):635-648.). Algae form a component of traditional medicine, Chinese medicine in particular (Yamamoto et al., 1984Yamamoto I, Takahashi M, Tamura E, Maruyama H, Mori H. Antitumor activity of edible marine algae: Effect of crude fucoidan fractions prepared from edible brown seaweeds against L-1210 leukemia. Hydrobiologia. 1984;116-117.). Sea weeds are rich sources of bioactive molecules like flavonoids, terpenoids, vitamins etc and hence serve as excellent food and medicine. Algae belonging to all three categories namely, Red, Brown and Green algae are consumed as food and found to possess pharmacological activities (Kaliaperumal, Kalimuthu, 1997Kaliaperumal N, Kalimuthu S. Seaweed potential and its exploitation in India. Seaweed Res Utiln. 1997;19(1-2):33-40.).

Gracilaria corticata is a red seaweed with immense industrial and biotechnological potential, owing to the presence of phycocolloids (de Almeida et al., 2011de Almeida CLF, de S. Falcão H, de M. Lima GR, de A. Montenegro C, Lira NS, de Athayde-Filho PF, Rodrigues LC, Souza MFV, Barbosa-Filho JM, Batista LM. Bioactivities from Marine Algae of the Genus Gracilaria. Int J Mol Sci. 2011;12(7):4550-4573.). G. corticata exhibits antioxidant, antidiabetic, antimicrobial, cardioprotective, gastroprotective and hepatoprotective activities. The pharmacological activities of G. corticata are manifested by its phytoconstituents such as flavonoids, quinines, phenolics, glycosides etc (Balakrishnan, Jenifer, Esakkilingam, 2013Balakrishnan CP, Jenifer P, Esakkilingam M. Algal documentation and phytochemical studies of red algae Gracilaria corticata of Manapad Coast, Tamil Nadu. J Pharmacog Phytochem. 2013;2(4):193-197.). G.corticata are rich in flavonoids and the present study aims at comparing the antidiabetic potential of the flavonoids present in G.corticata and luteolin. The inhibition of α-amylase and α-glucosidase by luteolin and G. corticata extract was studied to evaluate their hypoglycaemic activity.

METHODS

Chemicals

Acarbose, α-glucosidase and p-nitrophenyl-α-D-glucopyranoside were purchased from Sigma-Aldrich, St. Louis, USA and α-amylase was purchased from Himedia. All the other chemicals used were of analytical grade.

Collection of Gracilaria corticata seaweed

Seaweeds of Gracilaria corticata were collected in the month of June from south sea coast of Mandapam, Rameshwaram, Tamil Nadu, India.

Preparation of extracts

G. corticata seaweeds were cleaned and the necrotic parts were removed. The seaweeds were washed with tap water to remove any associated debris and shade dried at room temperature (28 ± 2 ºC) for 5-8 days or until they are brittle easily by hand. After complete drying, the seaweed material (1.0 kg) was ground to a fine powder using an electrical blender. Forty gram of powdered seaweeds was extracted with 200 mL of water by cold maceration until the extract was clear. The extract was evaporated to dryness under reduced pressure using a rotary vacuum evaporator and the resulting extract was stored at 4 °C for future use. The prepared extract of Gracilaria corticata seaweed was named as Aqueous Extract of Gracilaria corticata (AEGC).

Extraction of total flavonoids

The total flavonoids present in G. corticata were extracted with the assistance of microwaves. The extraction was carried out in a domestic microwave oven. The AEGC irradiated for 20 min in the oven at regular intervals to maintain the temperature below 80 ˚C (1 min on and 2 min off). The extract (FEGC) obtained was cooled, filtered, evaporated using a rotary evaporator and stored at 4 ˚C for further study.

Estimation of flavonoid content

The total flavonoid content of FEGC was estimated by aluminium chloride method. Briefly, 1 mL of the extract (100 mg/mL) was diluted to 5 mL and 300 µL of sodium nitrite (5% w/v) was added and incubated for 5 minutes. This was followed by the addition of aluminium chloride (10% w/v). After 6 minutes, 2 mL of sodium hydroxide (1 M) was added and the resulting mixture was diluted to 10 mL with d.water. After an incubation period of 15 minutes, the color developed was read at 510 nm. The amount of flavonoid present in the extract was calibrated from a quercetin standard curve. The experiment was done in triplicate.

Assay of alpha amylase inhibition

In vitro amylase inhibition was studied by the method of Bernfeld (1955Bernfeld P. Amylases α and β. Methods Enzymol. 1955;1:149-158.). In brief, 100 µL of the extract was allowed to react with 200 µL of α-amylase enzyme and 100 µL of phosphate buﬀer (2 mM, pH 6.9). Hundred microlitres of 1% starch solution was added after 20 min incubation. 200 µL of the buffer served as the control. About 500 µL of dinitrosalicylic acid reagent was added to both control and test and incubated at 60 ˚C for 5 min. Acarbose was used as the standard inhibitor. The absorbance was recorded at 540 nm and the experiment was done in triplicate.

Assay of alpha glucosidase inhibition

In vitro α-glucosidase inhibition was performed by pre-incubation of equal volumes of extract, sodium phosphate buffer (1 mM, pH 6.9) and α-glucosidase enzyme for 5 min and then addition of 0.1 mL of p-nitrophenyl-α-D-glucopyranoside, followed by incubation at 25 ˚C for 10 min. Acarbose was used as the standard inhibitor. The absorbance was recorded at 405 nm and the percentage of inhibition was calculated.

Calculation of percentage of inhibition

The percentage inhibition of the enzymes was calculated using the formula

inhibition (%) \frac{100 \times (Absorbance of Control - Absorbance of Test)}{Absorbance of Control}

Determination of Combination Index (CI)

CI = \frac{C_{a, x}}{{IC}_{a, x}} + \frac{C_{b, x}}{{IC}_{b, x}}

C_a,x is IC₅₀of luteolin

C_b,x is IC₅₀of FEGC

IC_a,xis the concentration of luteolin in combination required to achieve 50% inhibition

IC_b,xis the concentration of FEGC in combination required to achieve 50% inhibition

Statistical analysis

All the observed values are expressed as mean of six experiments ± standard deviation. The IC50 values were calculated by regression analysis.

RESULTS AND DISCUSSION

One common therapeutic approach for treating DM is preventing the post-prandial increase of glucose in blood. This can be achieved by interfering with glucose absorption and thus with carbohydrate hydrolysing enzymes. α-amylase and α-glucosidase convert oligo- and di-saccharides into monosaccharides for absorption. Inhibition of these hydrolysing enzymes delays the absorption process and thus indirectly prevents the increase in the postprandial levels of glucose. This study was conducted primarily to analyse the antidiabetic potentials of flavonoids present in AEGC (FEGC) and luteolin. The additive effect of FEGC and luteolin was also investigated.

The flavonoid extraction was performed using microwaves. Microwave assisted extraction of flavonoids has been reported for several plants. Alghazeer et al. (2017)Alghazeer R, Elmansori A, Sidati M, Gammoudi F, Azwai S, Naas H, Garbaj A, Eldaghayes I. In vitro antibacterial activity of flavonoid extracts of two selected libyan algae against multi-drug resistant bacteria isolated from food products. J Biosci Med. 2017;5(1):26-48. has reported such extraction for brown algae. The flavonoid content in FEGC was found to be 18 mg/g of extract.

The α-amylase inhibitory potential of luteolin and FEGC were studied and the concentration range under study was 12.5 to 400 µg. The results indicate that inhibition of the enzyme was better with luteolin and FEGC also showed significant inhibition. Around 50% inhibition of enzyme was shown by luteolin, FEGC and acarbose at 25 µg concentration. Maximum inhibition of the enzyme was found at 200 µg. The IC50 of luteolin was 34.5 µM and that of FEGC was 302 µg.

Similarly, the α-glucosidase inhibition study revealed that the inhibitory potential was dose dependent and maximum inhibition was observed at 200 µg concentration for all the three components studied. The IC50 of luteolin was 2.4 µM and that of FEGC was 75 µg.

The percentage inhibition of enzymes at the IC50 concentrations was also studied. It was observed that luteolin exhibited 60% and 45% inhibitory activity for amylase and glucosidase respectively and FEGC exhibited 58% and 52% inhibitory activity for amylase and glucosidase respectively (Table I). These results were almost compatible with those reported by Kim, Kwon and Son (2000)Kim JS, Kwon CS, Son JH. Inhibition of alpha-glucosidase and amylase by luteolin, a flavonoid. Biosci Biotechnol Biochem. 2000;64(11):2458-2461. and Tadera et al. (2006)Tadera K, Minami Y, Takamatsu K, Matsuoka K. Inhibition of α-glucosidase and α-amylase by flavonoids. J Nutr Sci Vitaminol. 2006;52(2):149-153..

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TABLE I
Inhibitory activity of FEGC and luteolin against α-amylase and α-glucosidase

The flavonoids inhibit amylase activity by forming complexes with starch, thereby suppressing the digestion of starch molecules (Takahama, Hirota, 2018Takahama U, Hirota S. Interactions of flavonoids with α-amylase and starch slowing down its digestion. Food Funct. 2018:9(2):677-687. ). Few studies suggest that the inhibitory activity of flavonoids is related to the structure of flavonoids. The hydroxyl groups, the substitution on B ring, the double bonds and the linkage of B ring were reported to enhance the inhibitory potential (Tadera et al., 2006Tadera K, Minami Y, Takamatsu K, Matsuoka K. Inhibition of α-glucosidase and α-amylase by flavonoids. J Nutr Sci Vitaminol. 2006;52(2):149-153.; Proenca et al., 2017Proenca C, Freitasa M, Ribeiro D, Oliveira EFT, Sousa JLC, Tome SM, Ramos MJ, Silva AMS, Fernandes PA, Fernandes E. a-Glucosidase inhibition by flavonoids: an in vitro and in silico structure-activity relationship study. J Enzyme Inhib Med Chem. 2017;32(1):1216-1228.).

The synergistic effect of FEGC and luteolin at four different doses were studied, i.e., 0.5, 1, 2 and 4 times their IC50 concentrations. The combination index was calculated and it was found that luteolin and FEGC functioned synergistically in inhibiting α-amylase at concentrations half their IC50 values. However, such a synergistic effect was not observed with α-glucosidase and luteolin and FEGC exhibited additive effect at 0.5 x IC50 concentrations (Table II).

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TABLE II
Activity of FEGC and luteolin as a combination against α-amylase and α-glucosidase

The observations however imply that the combination of luteolin and FEGC can be investigated in vivo for their antidiabetic potential. Omojokun et al. (2014)Omojokun OS, Oboh G, Ademosun A, Ayeni P, Bello FO. Comparative effect of quercetin and rutin on amylase, glucosidase and some pro-oxidant induced lipid peroxidation in rat pancreas. Comp Clin Path. 2014;24(5):1103-10. have reported on the combination of quercetin and rutin in experimental diabetic rats.

This study shows that the flavonoids of G. corticata are potent antidiabetic agents and can be used to treat or manage type 2 DM. G. corticata has been reported to possess a wide spectrum of pharmacological properties (de Almeida et al., 2011de Almeida CLF, de S. Falcão H, de M. Lima GR, de A. Montenegro C, Lira NS, de Athayde-Filho PF, Rodrigues LC, Souza MFV, Barbosa-Filho JM, Batista LM. Bioactivities from Marine Algae of the Genus Gracilaria. Int J Mol Sci. 2011;12(7):4550-4573.). Nevertheless, the potential of the flavonoids of G.corticata are yet to be explored.

CONCLUSION

The management of Type 2 diabetes using the antidiabetic potential of the flavonoids present in G. corticata was investigated. The flavonoids were observed to possess potent antidiabetic activity and were found to act synergistically with luteolin, a flavonoid that has manifested itself as an important antidiabetic agent. The in vivo antidiabetic effect of the flavonoids of G. corticata must be evaluated.

REFERENCES

Ahmad LA, Crandall JP. Type 2 Diabetes prevention: a review. Clin Diab. 2010;28(2):53-54.
Alghazeer R, Elmansori A, Sidati M, Gammoudi F, Azwai S, Naas H, Garbaj A, Eldaghayes I. In vitro antibacterial activity of flavonoid extracts of two selected libyan algae against multi-drug resistant bacteria isolated from food products. J Biosci Med. 2017;5(1):26-48.
Azevedo M, Alla S. Diabetes in sub-saharan Africa: kenya, mali,mozambique, Nigeria, South Africa and Zambia. Int J Diabetes Dev Ctries. 2008;28(4):101-108.
Balakrishnan CP, Jenifer P, Esakkilingam M. Algal documentation and phytochemical studies of red algae Gracilaria corticata of Manapad Coast, Tamil Nadu. J Pharmacog Phytochem. 2013;2(4):193-197.
Bernfeld P. Amylases α and β. Methods Enzymol. 1955;1:149-158.
de Almeida CLF, de S. Falcão H, de M. Lima GR, de A. Montenegro C, Lira NS, de Athayde-Filho PF, Rodrigues LC, Souza MFV, Barbosa-Filho JM, Batista LM. Bioactivities from Marine Algae of the Genus Gracilaria Int J Mol Sci. 2011;12(7):4550-4573.
Global Burden of Diabetes. International Diabetes Federation . Diabetic Atlas fifth edition 2011, Brussels. (cited on 2018, September 14). Available at http://www.idf.org/diabetesatlas
» http://www.idf.org/diabetesatlas
Kahn SE. The relative contributions of insulin resistance and beta-cell dysfunction in the pathophysiology of type 2 diabetes. Diabetologia. 2008;46(1):3-19.
Kaliaperumal N, Kalimuthu S. Seaweed potential and its exploitation in India. Seaweed Res Utiln. 1997;19(1-2):33-40.
Kim JS, Kwon CS, Son JH. Inhibition of alpha-glucosidase and amylase by luteolin, a flavonoid. Biosci Biotechnol Biochem. 2000;64(11):2458-2461.
Malviya N, Jain S, Malviya S. Antidiabetic Potential of Medicinal Plants. Acta Pol Pharm. 2010;67(2):113-118.
Olokoba AB, Obateru OA, Olokoba LB. Type 2 Diabetes Mellitus: A review of current trends. Oman Med J. 2012;27(4): 269-273.
Omojokun OS, Oboh G, Ademosun A, Ayeni P, Bello FO. Comparative effect of quercetin and rutin on amylase, glucosidase and some pro-oxidant induced lipid peroxidation in rat pancreas. Comp Clin Path. 2014;24(5):1103-10.
Proenca C, Freitasa M, Ribeiro D, Oliveira EFT, Sousa JLC, Tome SM, Ramos MJ, Silva AMS, Fernandes PA, Fernandes E. a-Glucosidase inhibition by flavonoids: an in vitro and in silico structure-activity relationship study. J Enzyme Inhib Med Chem. 2017;32(1):1216-1228.
Pulz O, Gross W. Valuable products from biotechnology of microalgae. Appl Microbiol Biotechnol. 2004;65(6):635-648.
Siddiqui AA, Siddiqui SA, Ahmad S, Siddiqui S, Ahsan I, Sahu K. Diabetes: mechanism, pathophysiology and management-a review. Int J Drug Dev Res. 2013;5(2):1-23.
Tadera K, Minami Y, Takamatsu K, Matsuoka K. Inhibition of α-glucosidase and α-amylase by flavonoids. J Nutr Sci Vitaminol. 2006;52(2):149-153.
Takahama U, Hirota S. Interactions of flavonoids with α-amylase and starch slowing down its digestion. Food Funct. 2018:9(2):677-687.
Yamamoto I, Takahashi M, Tamura E, Maruyama H, Mori H. Antitumor activity of edible marine algae: Effect of crude fucoidan fractions prepared from edible brown seaweeds against L-1210 leukemia. Hydrobiologia. 1984;116-117.

Publication Dates

Publication in this collection
26 Apr 2021
Date of issue
2020

History

Received
18 Sept 2018
Accepted
13 Nov 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Ahmad LA, Crandall JP. Type 2 Diabetes prevention: a review. Clin Diab. 2010;28(2):53-54.

[2] Alghazeer R, Elmansori A, Sidati M, Gammoudi F, Azwai S, Naas H, Garbaj A, Eldaghayes I. In vitro antibacterial activity of flavonoid extracts of two selected libyan algae against multi-drug resistant bacteria isolated from food products. J Biosci Med. 2017;5(1):26-48.

[3] Azevedo M, Alla S. Diabetes in sub-saharan Africa: kenya, mali,mozambique, Nigeria, South Africa and Zambia. Int J Diabetes Dev Ctries. 2008;28(4):101-108.

[4] Balakrishnan CP, Jenifer P, Esakkilingam M. Algal documentation and phytochemical studies of red algae Gracilaria corticata of Manapad Coast, Tamil Nadu. J Pharmacog Phytochem. 2013;2(4):193-197.

[5] Bernfeld P. Amylases α and β. Methods Enzymol. 1955;1:149-158.

[6] de Almeida CLF, de S. Falcão H, de M. Lima GR, de A. Montenegro C, Lira NS, de Athayde-Filho PF, Rodrigues LC, Souza MFV, Barbosa-Filho JM, Batista LM. Bioactivities from Marine Algae of the Genus Gracilaria Int J Mol Sci. 2011;12(7):4550-4573.

[7] Global Burden of Diabetes. International Diabetes Federation . Diabetic Atlas fifth edition 2011, Brussels. (cited on 2018, September 14). Available at http://www.idf.org/diabetesatlas
» http://www.idf.org/diabetesatlas

[8] Kahn SE. The relative contributions of insulin resistance and beta-cell dysfunction in the pathophysiology of type 2 diabetes. Diabetologia. 2008;46(1):3-19.

[9] Kaliaperumal N, Kalimuthu S. Seaweed potential and its exploitation in India. Seaweed Res Utiln. 1997;19(1-2):33-40.

[10] Kim JS, Kwon CS, Son JH. Inhibition of alpha-glucosidase and amylase by luteolin, a flavonoid. Biosci Biotechnol Biochem. 2000;64(11):2458-2461.

[11] Malviya N, Jain S, Malviya S. Antidiabetic Potential of Medicinal Plants. Acta Pol Pharm. 2010;67(2):113-118.

[12] Olokoba AB, Obateru OA, Olokoba LB. Type 2 Diabetes Mellitus: A review of current trends. Oman Med J. 2012;27(4): 269-273.

[13] Omojokun OS, Oboh G, Ademosun A, Ayeni P, Bello FO. Comparative effect of quercetin and rutin on amylase, glucosidase and some pro-oxidant induced lipid peroxidation in rat pancreas. Comp Clin Path. 2014;24(5):1103-10.

[14] Proenca C, Freitasa M, Ribeiro D, Oliveira EFT, Sousa JLC, Tome SM, Ramos MJ, Silva AMS, Fernandes PA, Fernandes E. a-Glucosidase inhibition by flavonoids: an in vitro and in silico structure-activity relationship study. J Enzyme Inhib Med Chem. 2017;32(1):1216-1228.

[15] Pulz O, Gross W. Valuable products from biotechnology of microalgae. Appl Microbiol Biotechnol. 2004;65(6):635-648.

[16] Siddiqui AA, Siddiqui SA, Ahmad S, Siddiqui S, Ahsan I, Sahu K. Diabetes: mechanism, pathophysiology and management-a review. Int J Drug Dev Res. 2013;5(2):1-23.

[17] Tadera K, Minami Y, Takamatsu K, Matsuoka K. Inhibition of α-glucosidase and α-amylase by flavonoids. J Nutr Sci Vitaminol. 2006;52(2):149-153.

[18] Takahama U, Hirota S. Interactions of flavonoids with α-amylase and starch slowing down its digestion. Food Funct. 2018:9(2):677-687.

[19] Yamamoto I, Takahashi M, Tamura E, Maruyama H, Mori H. Antitumor activity of edible marine algae: Effect of crude fucoidan fractions prepared from edible brown seaweeds against L-1210 leukemia. Hydrobiologia. 1984;116-117.

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