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Antihyperglycaemic activity of Asparagus racemosus roots is partly mediated by inhibition of carbohydrate digestion and absorption, and enhancement of cellular insulin action

Published online by Cambridge University Press:  08 September 2011

J. M. A. Hannan
Affiliation:
Department of Pharmacy, North South University, Dhaka, Bangladesh
Liaquat Ali
Affiliation:
Research Division, BIRDEM, Dhaka, Bangladesh
Junaida Khaleque
Affiliation:
Department of Pharmacy, North South University, Dhaka, Bangladesh
Masfida Akhter
Affiliation:
Research Division, BIRDEM, Dhaka, Bangladesh
Peter R. Flatt
Affiliation:
SAAD Centre for Pharmacy and Diabetes, School of Biomedical Sciences, University of Ulster, Coleraine, Northern IrelandBT52 1SA, UK
Yasser H. A. Abdel-Wahab*
Affiliation:
SAAD Centre for Pharmacy and Diabetes, School of Biomedical Sciences, University of Ulster, Coleraine, Northern IrelandBT52 1SA, UK
*
*Corresponding author: Dr Y. H. Abdel-Wahab, fax +44 28 70 324965, email y.abdel-wahab@ulster.ac.uk
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Abstract

Asparagus racemosus roots have been shown to enhance insulin secretion in perfused pancreas and isolated islets. The present study investigated the effects of ethanol extracts of A. racemosus roots on glucose homeostasis in diabetic rats, together with the effects on insulin action in 3T3 adipocytes. When administered orally together with glucose, A. racemosus extract improved glucose tolerance in normal as well as in two types of diabetic rats. To investigate the possible effects on carbohydrate absorption, the sucrose content of the gastrointestinal tract was examined in 12 h fasted rats after an oral sucrose load (2·5 g/kg body weight). The extract significantly suppressed postprandial hyperglycaemia after sucrose ingestion and reversibly increased unabsorbed sucrose content throughout the gut. The extract also significantly inhibited the absorption of glucose during in situ gut perfusion with glucose. Furthermore, the extract enhanced glucose transport and insulin action in 3T3-L1 adipocytes. Daily administration of A. racemosus to type 2 diabetic rats for 28 d decreased serum glucose, increased pancreatic insulin, plasma insulin, liver glycogen and total oxidant status. These findings indicate that antihyperglycaemic activity of A. racemosus is partly mediated by inhibition of carbohydrate digestion and absorption, together with enhancement of insulin secretion and action in the peripheral tissue. Asparagus racemosus may be useful as a source of novel antidiabetic compounds or a dietary adjunct for the management of diabetes.

Type
Full Papers
Copyright
Copyright © The Authors 2011

Asparagus racemosus (Liliaceae), locally known as Shatavari, is available throughout India, Asia, Australia and Africa. Asparagus is a popular vegetable consumed in many parts of the world. The shoots, the edible part of the plant, are frequently used in salads, vegetable dishes and soups. In India, asparagus is used mainly for its medicinal properties in the treatment of diarrhoea, dysentery, rheumatism and nervous breakdown(Reference Nadkharni1, Reference Chadha2). Studies on crude extracts and isolated components have revealed a wide range of biological activities, such as anti-tumour(Reference Shao, Chin and Ho3), antifungal(Reference Shimoyamada, Suzuki and Sonta4), anti-mutagenic(Reference Edenharder5), immunostimulatory(Reference Thatte and Dahanukar6Reference Dhuley8) and diuretic(Reference Balansard and Rayband9) properties. Asparagus also has been used as a lactogogue in lactational inadequacy(Reference Sharma, Ramji and Kumari10) and appears to help in the prevention and management of post-operative adhesions(Reference Rege, Nazarreth and Isaac7). Extracts exerted potent antioxidant properties on liver mitochondrial membranes in vitro (Reference Kamat, Boloor and Devasagayam11). The chemical constituents of A. racemosus have been studied, revealing flavonoids, oligosaccharides, amino acids, sulphur-containing acids and steroidal saponins(Reference Shao, Chin and Ho3). Various reports have suggested that polysaccharides from A. racemosus exhibit potent antioxidant as well as radioprotective properties(Reference Gang, Li and Xian12, Reference Liu, Yeo and Doniger13Reference Zeng, Meng and Zhang15).

It has been reported that asparagus decreased gastric emptying(Reference Dalvi, Nadkarni and Gupta16), whereas other studies have shown that methanolic root extract decreased intestinal propulsive movement, castor oil-induced diarrhoea and intestinal fluid accumulation in rats. Yohimbine, an α2-adrenoceptor blocker, attenuated the anti-diarrhoeal effect of the extract(Reference Nwafor, Okwuasaba and Binda17). A. racemosus reversed the effects of cisplatin on gastric emptying and normalised cisplatin-induced intestinal hypermotility(Reference Rege, Thatte and Dahanukar18).

The root of asparagus has been claimed to possess antidiabetic properties by traditional healers. It has been reported that A. racemosus reduced blood glucose in rats(Reference Rana, Singh and Rao19) and rabbits(Reference Akhtar and Shah20). Furthermore, recent studies have demonstrated that the extract of A. racemosus roots enhanced insulin secretion from perfused pancreas, isolated islets and clonal pancreatic β-cells(Reference Hannan, Marenah and Ali21). These studies have revealed that the ethanol extract and each of the hexane, chloroform and ethyl acetate partition fractions of A. racemosus concentration-dependently stimulated insulin secretion(Reference Hannan, Marenah and Ali21). Furthermore, the stimulatory effects were potentiated by glucose, 3-isobutyl-1-methyl xanthine, tolbutamide and a depolarising concentration of KCl, indicating that the insulin-releasing machinery of β-cells has been triggered through specific secretory pathways(Reference Hannan, Marenah and Ali21). These findings reveal that constituents of A. racemosus root extracts have wide-ranging stimulatory effects on physiological insulinotropic pathways.

The aim of the present study was to further evaluate the hypoglycaemic effects of A. racemosus in animal models of diabetes and to examine the possible effects on intestinal glucose absorption, gastrointestinal (GI) motility and cellular glucose uptake.

Materials and methods

Plant material and preparation of extract

Roots of A. racemosus were purchased from Ramkrishna Mission (Kolkata, India) and botanically authenticated, and voucher specimens were deposited in the National Herbarium (Bangladesh). The roots were dried at 40°C and ground into a fine powder (200 mesh) by a cyclotec-grinding machine. The powder (2 kg) was extracted with 80 % ethanol (10 litres) in a stainless-steel extraction tank for approximately 4 d at room temperature by changing ethanol daily. The combined extract was filtered and evaporated to dryness using a rotary evaporator. A membrane pump was used to evacuate the extract in order to remove the residual solvent. The extract was then freeze-dried (275 g) using a Varian 801 LY-3-TT freeze-dryer (Varian, Lexington, MA, USA). The dry sample was stored at 4°C.

Experimental animals and induction of diabetes

Long–Evans male rats (180–220 g body weight) bred at the Bangladesh Institute of Research and Rehabilitation in Diabetes, Endocrine and Metabolic Disorders animal house (Dhaka, Bangladesh) were used in the study. Rats were maintained at a constant room temperature of 22 ± 5°C with a humidity of 40–70 % and a 12 h light–12 h dark cycle. A standard pellet diet and water were supplied ad libitum. The overall nutrient composition of the diet was 36·2 % carbohydrate, 20·9 % protein, 4·4 % fat and 38·5 % fibre, with a metabolisable energy content of 11·8 MJ/kg (2820 kcal/kg). Insulin-dependent (type 1-like) diabetes was induced by a single intraperitoneal injection of streptozotocin (65 mg/kg body weight, freshly dissolved in 0·5 m-citrate buffer, pH 4·5) to 12 h fasted rats (180–220 g). Blood glucose level was checked 7 d after streptozotocin administration. Animals having blood glucose levels >20 mmol/l were considered to have diabetes. Diabetes representing type 2 was induced by a single intraperitoneal injection of 48-h-old rats with 90 mg streptozotocin/kg body weight(Reference Bonner-Weir, Trend and Honey22). The experiments were carried out for 3 months after streptozotocin injection. Rats having a blood glucose level of 8–9 mmol/l at fasting and 10 mmol/l and above after the glucose load were taken as type 2 diabetic model rats for the experiments. All experiments involving animals were conducted according to the UK Home Office regulations (UK Animals Scientific Procedures Act 1986) and the ‘Principles of Laboratory Animal Care’ (National Institutes of Health publication no. 86-23, revised 1985).

Acute and chronic effects of plant extract on glucose homeostasis

To study the acute effects of A. racemosus on basal blood glucose, the ethanol extract was administered orally (1·25 g/kg body weight) to 12 h fasted non-diabetic, type 1 and type 2 diabetic rats. Toxicity tests were carried out on ethanol extracts of A. racemosus and did not have any harmful effects in rats including histology of liver, kidney, pancreas, stomach and lungs. The control group received an equal volume of deionised water (10 ml/kg). In another set of experiments, the extract was similarly administered together to the three groups of rats with glucose (2·5 g/kg body weight). Controls received glucose only. To evaluate the long-term effects of A. racemosus on glucose homeostasis, the extract (1·25 g/kg body weight) was administered to type 2 diabetic rats by oral administration twice daily for 28 d. Control rats received an equal dose of water. Blood samples were collected and serum was separated by centrifugation and stored at − 20°C until measurement of different biochemical tests.

Effect of plant extract on residual gut sucrose content

The effects of A. racemosus on sucrose absorption from the gut were determined by the measurement of unabsorbed sucrose content after an oral sucrose load. Non-diabetic and type 2 diabetic rats, fasted for 12 h, received a 50 % sucrose solution by oral administration (2·5 g/kg body weight) with or without ethanol extract of A. racemosus (1·25 g/kg body weight). Blood samples were obtained from the tail vein before and at 30, 60, 120 and 240 min after the sucrose load for the determination of glucose. Some of the rats were killed at the same timings for the determination of unabsorbed sucrose contents of the GI tract. The GI tract was excised and divided into six segments: the stomach, the upper 20 cm, middle and lower 20 cm of the small intestine, the caecum and the large intestine. Each segment was washed with acidified ice-cold saline and centrifuged at 3000 rpm (1000 g) for 10 min. The resulting supernatant was boiled for 2 h to hydrolyse sucrose followed by the neutralisation of the solution with NaOH. Blood glucose concentrations and the amount of glucose liberated from residual sucrose in the GI tract were measured. GI sucrose content was calculated from the amount of liberated glucose(Reference Goto, Yamada and Ohyama23).

Plant extract effect on intestinal glucose absorption

An in situ intestinal perfusion technique(Reference Swintosky and Pogonowskawala24) was used to evaluate the effect of A. racemosus on intestinal absorption of glucose in normal rats fasted for 36 h and anaesthetised with sodium pentobarbital (50 g/kg body weight). The extract of A. racemosus (25 mg/ml), equivalent to 1·25 g/kg, suspended in Krebs–Ringer buffer, supplemented with glucose (54 g/l), was passed through the pylorus and the perfusate was collected from a catheter inserted at the end of the ileum. The control group was perfused only with Krebs' solution supplemented with glucose. Perfusion was carried out at a constant rate of 0·5 ml/min for 30 min at 37°C. The results are expressed as a percentage of absorbed glucose, calculated from the amount of glucose in solution before and after the perfusion.

Effects of extract on intestinal disaccharidase activity and gastrointestinal motility

The extract (1·25 g/kg body weight) was fed orally to 24 h fasted normal rats. The control group was administered with an equal volume of water. After 60 min, rats were killed and the small intestine was isolated, cut longitudinally, rinsed with ice-cold saline and homogenised in 10 ml saline (0·9 % NaCl). Aliquots of the homogenate were then incubated with 40 mm-sucrose at 37°C for 60 min. The converted glucose in the solution and protein of the homogenate were determined. Disaccharidase activity was calculated from the glucose concentration converted from sucrose as μmol/mg protein per h.

GI motility was evaluated using BaSO4 milk as described previously by Chatterjee(Reference Chatterjee25). BaSO4 milk was prepared by adding BaSO4 as 10 % (w/v) in 0·5 % carboxy methyl cellulose suspension. The ethanol extract was administered orally at the dose of 1·25 g/kg body weight 1 h before the oral administration of BaSO4 milk. Control rats received distilled water (10 ml/kg). Treated and control rats were killed 15 min after BaSO4 administration. The distance traversed by BaSO4 milk was measured and is expressed as a percentage of the total length of the small intestine (from the pylorus to the ileocaecal junction).

Effects of extract on glucose uptake and insulin action

3T3-L1 cells (ATCC, Manassas, VA, USA) were used to evaluate the effect of extract on glucose uptake and insulin action. 3T3-L1 fibroblasts were cultured and differentiated into adipocytes according to the method described by Frost & Lane(Reference Frost and Lane26). Cell monolayers were washed and then incubated for 15 min at 37°C in Krebs–Ringer buffer supplemented with ethanol extract of A. racemosus and insulin, as indicated in Fig. 6. After 15 min, glucose uptake was initiated, according to the established protocol of Frost & Lane(Reference Frost and Lane26), by the addition of 50 ml tritiated 2-deoxyglucose (18·5 MBq/well) plus glucose (50 mmol/l final concentration). The experiment was terminated after 5 min by three rapid washes with ice-cold buffer, after which the cells were detached and lysed with 0·1 % SDS and subsequently lysed. Radioactivity was measured on a Wallac 1409 scintillation counter (Wallac, Turke, Finland) and glucose uptake is expressed as disintegrations per min.

Analysis

All samples were stored at − 20°C until analysis. Glucose was measured by the glucose–oxidase method, using kits from Sera Pak (Berkeley, CA, USA). Hepatic glycogen was determined by using the anthrone method(Reference van der Vries27). Protein contents were determined using the detergent-compatible protein kit (Bio-Rad, Hercules, CA, USA). Total antioxidant status was determined using the ABTSw substrate assay kit according to the manufacturer's instructions (Sera Pak). Insulin was measured by ELISA using kits supplied by Crystal Chem, Inc. (Downers Grove, IL, USA) or RIA(Reference Flatt and Bailey28).

Statistical analysis

Statistical analysis was performed using Statistical Package for Social Science software for Windows version 12 (SPSS, Inc., Chicago, IL, USA). Results are presented as means and standard deviations. Groups of data were compared using unpaired Student's t test and the Mann–Whitney U test, where appropriate. Where data were collected over a number of time points, analysis was based on repeated-measures ANOVA, with Bonferroni adjustment to ensure an overall error rate of 5 %. One-way ANOVA was performed and pairwise comparisons were made with the control group using Dunnett's test to preserve an overall error rate of 5 %. A two-tailed P value of < 0·05 was considered statistically significant.

Results

Acute and chronic effects of ethanol extract of Asparagus racemosus on glucose homeostasis

Oral administration of ethanol extract of A. racemosus did not show any hypoglycaemic effect in the fasting state in either normal, type 2 or type 1 diabetic rats (Fig. 1(a)–(c)). The extract improved glucose tolerance at 30 min (P < 0·05 and < 0·01, respectively) when fed simultaneously with glucose in normal and type 2 diabetes rats (Fig. 1(d)–(f)).

Fig. 1 Effects of ethanol extract of Asparagus racemosus () on (a–c) fasting and (d–e) glucose tolerance in (a, d) non-diabetic, (b, e) type 1 and (c, f) type 2 diabetic rats. Values are means and standard deviations represented by vertical bars (n 6). Fasted rats were given ethanol extract by oral administration (1·25 g/kg body weight) with or without glucose (2·5 g/kg body weight). Mean values were significantly different from those of respective control () rats: *P < 0·05, **P < 0·01 (derived from repeated-measures ANOVA and adjusted using Bonferroni correction).

Administration of plant extract twice daily for 28 d to type 2 diabetic rats significantly lowered serum glucose levels (P < 0·01; Table 1). In addition, it increased serum insulin level by 30 % compared with controls (Table 1). Total antioxidant status was significantly increased with the treatment of extract compared with the control group (P < 0·01; Table 1). After chronic feeding of the extract, pancreatic insulin and liver glycogen content was increased significantly (P < 0·05) compared with control rats (Table 1).

Table 1 Effects of ethanol extract of Asparagus racemosus roots on serum levels of glucose and other parameters in type 2 diabetic rats after 28 d of feeding

(Mean values and standard deviations, n 12)

Mean values were significantly different from those of type 2 diabetic control rats: *P < 0·05, **P < 0·01 (unpaired t test).

A. racemosus was administered orally (1·25 g/kg body weight) twice daily for 28 d.

Diabetes was induced by a single intraperitoneal injection of 90 mg streptozotocin/kg to neonatal rats 3 months previously.

Effects of Asparagus racemosus on serum glucose after the sucrose load

A peak serum glucose level for non-diabetic as well as type 2 diabetic rats was achieved 30 min after sucrose ingestion (Fig. 2). The rise in blood glucose after sucrose loading was suppressed by the administration of ethanol extract at 30 min (P < 0·05) and 60 min (P < 0·05) in both normal and type 2 diabetic rats. This may reflect the positive effects of extract on insulin secretion/action but evidence for delayed absorption is provided by direct measurement of sucrose in the gut.

Fig. 2 Effects of ethanol extract of Asparagus racemosus () on serum glucose after the sucrose load in (a) non-diabetic and (b) type 2 diabetic rats. Rats were fasted for 20 h and administered orally with a sucrose solution (2·5 g/kg body weight) with or without ethanol extract (1·25 g/kg body weight). Values are means and standard deviations represented by vertical bars (n 6). Mean values were significantly different from those of respective control () rats: *P < 0·05 (derived from repeated-measures ANOVA and adjusted using Bonferroni correction).

Effects of Asparagus racemosus on unabsorbed sucrose content in the gut

In non-diabetic rats, little carbohydrate was detected as liberated glucose in the GI tract after the 20 h fast (data not shown). After sucrose loading (average 425 mg/rat), sucrose was detected in the stomach and the upper, middle and lower small intestine at 1 h as well as in the stomach, upper and middle intestine at 2 h. However, at 4 h, sucrose content was almost nil throughout the GI tract, indicating that sucrose was rapidly hydrolysed and absorbed in the upper part of the intestine (Fig. 3). The unabsorbed sucrose content after the administration of sucrose (2·5 g/kg body weight) with ethanol extract (1·25 g/kg) was increased significantly (P < 0·01) in the stomach, upper and middle intestine after 30 min, in the upper and middle intestine after 1 h and in the middle and lower intestine after 2 h. After 4 h, sucrose was not detected in the gut of either group (Fig. 3).

Fig. 3 Effects of ethanol extract of Asparagus racemosus () on gastrointestinal sucrose content after oral sucrose loading in (a) non-diabetic and (b) type 2 diabetic rats. Rats were fasted for 20 h before the oral administration of a sucrose solution (2·5 g/kg body weight) with or without ethanol extract (1·25 g/kg body weight). Values are means and standard deviations represented by vertical bars (n 6). * Mean values were significantly different from those of control (■) rats (P < 0·05).

After the administration of sucrose in type 2 diabetic rats, it remained in the stomach, upper, middle and lower small intestine at 1 h as well as in the stomach at 2 h. This indicates that sucrose was more slowly absorbed in type 2 diabetic rats given the plant extract (Fig. 3).

When extract was administered to type 2 diabetic rats with the sucrose load, the residual sucrose content was increased significantly (P < 0·001) in the upper intestine after 30 min, in the whole small intestine after 1 h and in the entire small intestine as well as in the caecum after 2 h. After 4 h, sucrose content were almost nil in the control group. However, at this time, sucrose was detected in the lower intestine as well as in the caecum (Fig. 3).

Effects of Asparagus racemosus on intestinal glucose absorption

Intestinal glucose absorption was almost constant during 30 min of perfusion with glucose. The glucose solution when supplemented with the extract, intestinal glucose absorption was decreased significantly (P < 0·05 to P < 0·01) during most of the perfusion period (Fig. 4).

Fig. 4 Effects of ethanol extract of Asparagus racemosus () on intestinal glucose absorption in non-diabetic rats. Rats were fasted for 36 h and the intestine was perfused with glucose (54 g/l) with or without ethanol extract of A. racemosus (25 mg/ml). Values are means and standard deviations represented by vertical bars (n 6). Mean values were significantly different from those of respective control () rats: *P < 0·05, **P < 0·01 (derived from repeated-measures ANOVA and adjusted using Bonferroni correction).

Effects of Asparagus racemosus on intestinal disaccharidase activity and gastrointestinal motility

The ethanol extract of A. racemosus inhibited disaccharidase (sucrose) activity significantly (P < 0·05) in normal rats. In contrast, the extract did not show any effect on GI motility (Fig. 5).

Fig. 5 Effects of ethanol extract of Asparagus racemosus on (a) intestinal disaccharidase activity and (b) gastrointestinal motility (by BaSO4 traversed) in non-diabetic rats. Rats were fasted for 20 h before the oral administration of ethanol extract of A. racemosus (1·25 g/kg body weight). Enzyme activity was determined and BaSO4 administered at 60 min. Motility was measured over the following 15 min. Values are means and standard deviations represented by vertical bars (n 12). * Mean values were significantly different from those of non-diabetic control rats (P < 0·001).

Effects of ethanol extract of Asparagus racemosus on glucose uptake in 3T3-L1 cells

Ethanol extract of A. racemosus significantly enhanced glucose uptake compared with the control (no insulin, P < 0·05). This effect was further increased by the presence of 10− 9 m-insulin (P < 0·001; Fig. 6).

Fig. 6 Effects of ethanol extract of Asparagus racemosus (200 μg/ml) on glucose uptake by 3T3-L1 adipocytes. Values are means and standard deviations represented by vertical bars (n 6). One-way ANOVA was performed and pairwise comparisons were made using Dunnett's test to preserve an overall error rate of 5 %. Mean values were significantly different from those of no insulin incubation: *P < 0·05, ***P < 0·001. † Mean values were significantly different from those of plant ethanol extract incubation without insulin (■, P < 0·001). ‡ Mean values were significantly different from those of 10− 9 m-insulin () alone (P < 0·0001). , 10− 6 m-insulin. DPM, disintegrations per min.

Discussion

The present study was undertaken to assess antihyperglycaemic properties and the mechanism of action of A. racemosus. The findings show that the ethanol extract of A. racemosus roots elicited glucose-lowering effects in normal and type 2 diabetic rats when administered simultaneously with glucose. However, no significant effects were observed in type 1 diabetic rats. This indicates that the antihyperglycaemic effects of the active plant constituent(s) are partly mediated by improving the insulin secretory capacity of the β-cells(Reference Hannan, Marenah and Ali21) or enhancing insulin action(Reference Nahar, Rokeya and Ali29). The former is consistent with increased serum and pancreatic insulin in 28 d chronic studies, whereas the latter accords with observations made with 3T3 adipocytes.

In acute experiments, when A. racemosus was administered simultaneously with glucose, significant glucose lowering was observed in non-diabetic as well as type 2 diabetic rats. In the postprandial state, this effect may partly result from interference with intestinal absorption of glucose(Reference Nahar, Rokeya and Ali29). Indeed, A. racemosus extract significantly inhibited glucose absorption during gut perfusion. In addition, postprandial hyperglycaemia was suppressed after sucrose ingestion and the amounts of unabsorbed sucrose were measured throughout the gut when administered with A. racemosus. The extract also inhibited intestinal disaccharidase enzyme activity, which suggests that retardation of carbohydrate absorption was at least partially due to the inhibition of gut enzyme activity. However, further studies may be required to evaluate further such effect on animal models of diabetes. When GI motility was evaluated in non-diabetic rats under physiological conditions using BaSO4 milk as described previously by Chatterjee(Reference Chatterjee25) and expressed as a percentage of BaSO4 milk passed through from the total length of the small intestine (from the pylorus to the ileocaecal junction), the extract did not show any significant effect on the motility of the GI tract compared with the control. However, further studies may be required to evaluate the effects of A. racemosus on GI motility in diabetic models.

To further elucidate the possible mechanisms underlying the antihyperglycaemic effects of A. racemosus, studies of glucose uptake by 3T3-L1 cells were performed. These revealed that ethanol extract significantly enhanced glucose transport with further stimulation in the presence of 10− 9 m-insulin. These results suggest that actions of the plant extract on glucose transport may be achieved, to some extent, without accompanying elevation of insulin. Further work is required to elucidate the in vivo effects of A. rascemosus on glucose uptake, related transporter/enzyme activities or their gene expression in tissues such as liver, fat and muscle. However, the significance of such effect seems less likely, given the absence of the effect of plant extract in type 1 diabetic rats.

In the chronic study, A. racemosus extract significantly increased total antioxidant status, which confirms the idea that the extract has potent antioxidant activities(Reference Kamat, Boloor and Devasagayam11). Interestingly, liver glycogen content was increased in type 2 diabetic rats compared with the controls after administration for 28 d. This novel finding is possibly due to the stimulation of insulin release from β-cells plus enhancement of insulin action, thereby improving hepatic glucose uptake.

In conclusion, the present study has shown that in addition to the effects of A. racemosus root extract on pancreatic β-cells(Reference Hannan, Marenah and Ali21), antihyperglycaemic activities in normoglycaemic and diabetic animals are associated with decreased intestinal glucose absorption and enhanced tissue glucose utilisation. The identification of active principle(s) from this antidiabetic plant may provide an opportunity to develop new agents for the treatment of type 2 diabetes. Meanwhile, a sound scientific basis appears to exist for the use of A. racemosus as a dietary adjuvant for type 2 diabetes.

Acknowledgements

The present study was supported by the SAAD Trading and Contracting Company and University of Ulster Strategic Research Funding. All authors contributed to the conception and design of the experiments. J. M. A. H., L. A., J. K., M. A. and Y. H. A. A.-W. contributed to the experimental study. P. R. F. and Y. H. A. A.-W. contributed equally to the supervision of the study, analysis and preparation of the manuscript. There is no conflict of interest to declare.

References

1Nadkharni, AK (1976) India Materia Medica. Bombay: Popular Prakashan, pp. 151155.Google Scholar
2Chadha, YR (1985) The Wealth of India. vol. 1, New Delhi: Publications and Information Directorate, pp. 468472.Google Scholar
3Shao, Y, Chin, C-K, Ho, C-T, et al. (1996) Anti-tumour activity of the crude saponins obtained from asparagus. Cancer Lett 104, 3136.CrossRefGoogle ScholarPubMed
4Shimoyamada, M, Suzuki, M, Sonta, H, et al. (1990) Antifungal activity of the saponin fraction obtained from asparagus and its active principle. Agric Biol Chem 54, 25532557.Google Scholar
5Edenharder, R (1990) Antimutagenic activity of vegetable and fruit extracts against in-vitro benzo(a)pyrene. Z Gesamte Hyg 36, 144148.Google ScholarPubMed
6Thatte, UM & Dahanukar, SA (1988) Comparative study of immunomodulating activity of Indian medicinal plants, lithium carbonate and glucan. Methods Find Exp Clin Pharmacol 10, 639644.Google ScholarPubMed
7Rege, NN, Nazarreth, HM, Isaac, A, et al. (1989) Immunotherapeutic modulation of intraperitoneal adhesions by A. racemosus. J Postgrad Med 35, 199203.Google Scholar
8Dhuley, JN (1997) Effect of some Indian herbs on macrophage functions in ochratoxin A treated mice. J Ethnopharmacol 58, 1520.CrossRefGoogle ScholarPubMed
9Balansard, S & Rayband, M (1987) Diuretic action of A. racemosus. Crit Rev Soc Biol 126, 954956.Google Scholar
10Sharma, S, Ramji, S, Kumari, S, et al. (1996) Randomized controlled trial of A. racemosus (Shatavari) as a lactogogue in lactational inadequacy. Indian Padiatr 32, 675677.Google Scholar
11Kamat, JP, Boloor, KK, Devasagayam, TPA, et al. (2000) Antioxidant properties of Asparagus racemosus against damage induced by gamma-radiation in rat liver mitochondria. J Ethnopharmacol 71, 425435.CrossRefGoogle ScholarPubMed
12Gang, ZZ, Li, LZ & Xian, LX (1997) Study on the isolation, purification and antioxidation properties of polysaccharides from Spirulina maxima. Acta Bot Sin 39, 7781.Google Scholar
13Liu, J, Yeo, HC, Doniger, SJ, et al. (1997) Assay of aldehydes from lipid peroxidation: gas chromatography–mass spectrometry compared to thioabarbituric acid. Anal Biochem 245, 161166.CrossRefGoogle ScholarPubMed
14Liu, SX, Chen, Y, Zhou, M, et al. (1997) Protective effect of the polysaccharide kreskin on inhibition of lipo-polysaccharide-induced nitric oxide production in macrophages caused by oxidized low-density lipoprotein. Med Sci Res 25, 507509.Google Scholar
15Zeng, N, Meng, X & Zhang, Y (1997) Studies on the antioxidative effect of constituents of Herba epimedii (ESPS). Zhongguo Zhongyao Zazhi 22, 4648.Google Scholar
16Dalvi, SS, Nadkarni, PM & Gupta, KC (1990) Effect of A. racemosus (Shatavari) on gastric emptying time in normal healthy volunteers. J Postgrad Med 36, 9194.Google ScholarPubMed
17Nwafor, PA, Okwuasaba, FK & Binda, LG (2000) Antidiarrhoeal and antiulcerogenic effects of methanolic extract of Asparagus pubescens root in rats. J Ethnopharmacol 72, 421427.CrossRefGoogle ScholarPubMed
18Rege, NN, Thatte, UM & Dahanukar, SA (1999) Adaptogenic properties of six rasayana herbs used in Ayurvedic medicine. Phytother Res 3, 275291.3.0.CO;2-S>CrossRefGoogle Scholar
19Rana, TS, Singh, KK & Rao, RR (1994) Some interesting reports on indigenous herbal remedies for diabetes mellitus from India. In Fourth International Congress Ethnobiology, pp. 1721. Lukhnow: NBRI.Google Scholar
20Akhtar, MS & Shah, MV (1993) Elemental constituents of antidiabetic screening of a folklore medicinal plant prescription. Ind J Toxicology, Occup Envt Health 2, 46.Google Scholar
21Hannan, JMA, Marenah, L, Ali, L, et al. (2007) Insulin secretory actions of extracts of Asparagus racemosus root in perfused pancreas, isolated islets and clonal pancreatic β-cells. J. Endocrinol 192, 159168.CrossRefGoogle ScholarPubMed
22Bonner-Weir, S, Trend, DF, Honey, RN, et al. (1981) Responses of neonatal rat islets to streptozotocin: limited β-cell regeneration and hyperglycemia. Diabetes 30, 6469.CrossRefGoogle Scholar
23Goto, Y, Yamada, K, Ohyama, T, et al. (1995) An alpha-glucosidase inhibitor, AO-128, retards carbohydrate absorption in rats and humans. Diabetes Res Clin Pract 28, 8187.CrossRefGoogle ScholarPubMed
24Swintosky, JV & Pogonowskawala, E (1982) The in-situ rat gut technique. Pharm Int 3, 163167.Google Scholar
25Chatterjee, TK (1993) Handbook on Laboratory Mice and Rats, pp. 157. Kolkata, India: Department of Pharmaceutical Technology, Jadavpur University.Google Scholar
26Frost, SC & Lane, MD (1985) Evidence for the involvement of vicinal sulfhydryl groups in insulin-activated hexose transport by 3T3-L1 adipocytes. J Biol Chem 260, 26462652.CrossRefGoogle ScholarPubMed
27van der Vries, J (1954) Two methods for the determination of glycogen in liver. Biochem J 57, 410416.CrossRefGoogle Scholar
28Flatt, PR & Bailey, CJ (1981) Abnormal plasma glucose and insulin response in heterozygous lean (ob/+) mice. Diabetologia 20, 573577.CrossRefGoogle ScholarPubMed
29Nahar, N, Rokeya, B, Ali, L, et al. (2000) Effects of three medicinal plants on blood glucose levels of non-diabetic and diabetic model rats. Diabetes Res 35, 4149.Google Scholar
Figure 0

Fig. 1 Effects of ethanol extract of Asparagus racemosus () on (a–c) fasting and (d–e) glucose tolerance in (a, d) non-diabetic, (b, e) type 1 and (c, f) type 2 diabetic rats. Values are means and standard deviations represented by vertical bars (n 6). Fasted rats were given ethanol extract by oral administration (1·25 g/kg body weight) with or without glucose (2·5 g/kg body weight). Mean values were significantly different from those of respective control () rats: *P < 0·05, **P < 0·01 (derived from repeated-measures ANOVA and adjusted using Bonferroni correction).

Figure 1

Table 1 Effects of ethanol extract of Asparagus racemosus† roots on serum levels of glucose and other parameters in type 2 diabetic rats after 28 d of feeding‡(Mean values and standard deviations, n 12)

Figure 2

Fig. 2 Effects of ethanol extract of Asparagus racemosus () on serum glucose after the sucrose load in (a) non-diabetic and (b) type 2 diabetic rats. Rats were fasted for 20 h and administered orally with a sucrose solution (2·5 g/kg body weight) with or without ethanol extract (1·25 g/kg body weight). Values are means and standard deviations represented by vertical bars (n 6). Mean values were significantly different from those of respective control () rats: *P < 0·05 (derived from repeated-measures ANOVA and adjusted using Bonferroni correction).

Figure 3

Fig. 3 Effects of ethanol extract of Asparagus racemosus () on gastrointestinal sucrose content after oral sucrose loading in (a) non-diabetic and (b) type 2 diabetic rats. Rats were fasted for 20 h before the oral administration of a sucrose solution (2·5 g/kg body weight) with or without ethanol extract (1·25 g/kg body weight). Values are means and standard deviations represented by vertical bars (n 6). * Mean values were significantly different from those of control (■) rats (P < 0·05).

Figure 4

Fig. 4 Effects of ethanol extract of Asparagus racemosus () on intestinal glucose absorption in non-diabetic rats. Rats were fasted for 36 h and the intestine was perfused with glucose (54 g/l) with or without ethanol extract of A. racemosus (25 mg/ml). Values are means and standard deviations represented by vertical bars (n 6). Mean values were significantly different from those of respective control () rats: *P < 0·05, **P < 0·01 (derived from repeated-measures ANOVA and adjusted using Bonferroni correction).

Figure 5

Fig. 5 Effects of ethanol extract of Asparagus racemosus on (a) intestinal disaccharidase activity and (b) gastrointestinal motility (by BaSO4 traversed) in non-diabetic rats. Rats were fasted for 20 h before the oral administration of ethanol extract of A. racemosus (1·25 g/kg body weight). Enzyme activity was determined and BaSO4 administered at 60 min. Motility was measured over the following 15 min. Values are means and standard deviations represented by vertical bars (n 12). * Mean values were significantly different from those of non-diabetic control rats (P < 0·001).

Figure 6

Fig. 6 Effects of ethanol extract of Asparagus racemosus (200 μg/ml) on glucose uptake by 3T3-L1 adipocytes. Values are means and standard deviations represented by vertical bars (n 6). One-way ANOVA was performed and pairwise comparisons were made using Dunnett's test to preserve an overall error rate of 5 %. Mean values were significantly different from those of no insulin incubation: *P < 0·05, ***P < 0·001. † Mean values were significantly different from those of plant ethanol extract incubation without insulin (■, P < 0·001). ‡ Mean values were significantly different from those of 10− 9 m-insulin () alone (P < 0·0001). , 10− 6 m-insulin. DPM, disintegrations per min.