Iraqi J Pharm Sci, Vol.22(1) 2013 Arabidopsis thaliana extract and blood glucose level 115 Study the Effect of Arabidopsis thaliana Extract on Reducing Blood Glucose Level in Diabetic White Albino Mice Khaleel I. Rashid *,1 , Abedaljasim M. Aljibouri ** ,AbdulAmeer J. Zayer ** , Luma B. Khalid ** and Ahmed Abdul-Munaem ** * College of Health and Medical, Baghdad, Iraq. ** Biotechnology Center Technologies-Baghdad, Al- Nahrain University, Baghdad ,Iraq. Abstract This study was designed to evaluate the effect of aqueous extract of Arabidopsis thaliana seeds on reducing glucose level for white albino mice. Twenty adults mice were used, divided randomly into four groups (five mice per each group). The first group (normal mice) was administrated with 0.1 ml of distilled water as a control, the second group (normal mice) was administrated with 0.1 ml of the plant extract, whereas the third and fourth groups (diabetic mice) were administrated with single dose of alloxan (150 mg/kg of the body weight) to induce diabetes, and the fourth group was administrated with 0.1 ml of the plant extract for 10 days, then blood glucose level was measured for all of the experimental animals (diabetic and non diabetic). Results showed clear increasing in glucose levels in the diabetic mice, while significant reduction was recorded in glucose levels of the normal mice that was treated with the plant extract as compared with the control group. These results indicate that Arabidopsis thaliana seeds aqueous extract possesses a hypoglycemic effect. Key words: Arabidopsis thaliana, glucose level, albino mice زفٌ خفض هستوى الكلوكو Arabidopsis thalianaًببت اراى الفبر دراسة تأثَر هستخلص فٌ دم الفئراى البَضبء الوصببة ببلسكر خلَل ابراهَن رشَذ *،1 ، عبذالجبسن هحَسي الجبورً ** ، عبذاالهَر جواد زاٍر ** ، لوي برهبى خبلذ ** احوذ عبذ الوٌعن و ** * . ، العشاقبغذاد ، كلُت الخقٌُبث الصحُت والطبُت ** .، بغذاد ، العشاق خبهعت الٌهشَي ،هشكض بحىد الخقٌُبث االحُبئُت الخالصة علً هسخىي السكش فٍ دم Arabidopsis thalianaصووج هزٍ الذساست لخقُُن حأثُش الوسخخلص الوبئٍ لبزوس ًببث اراى الفبس خشعج (. فئشاى لكل هدوىعت 5)قسوج عشىائُآ الً اسبعت هدبهُع , فأسة فٍ هشحلت الٌعىج 20اسخعولج فٍ هزٍ الخدشبت . الفئشاى البُعبء كغن هي /مهلغ 200حشكُض) هللخش هي هسخخلص آراى الفأس 0,1الودوىعت الثبًُت خشعج , هللخش هي الوبء الوقطش 0,1الودوىعت االولً ألسخحذاد هشض السكشٌ (هي وصى الفأس .كغن / هلغن 150) والودوىعت الثبلثت والشابعت حقٌج بدشعت هفشدة هي االلىكسبى, (وصى الفأس بعذهب حن قُبط هسخىي الكلىكىص بذم الحُىاًبث الوخخبشة. اَبم 10هللخش هي هسخخلص الوبئٍ ولوذة 0,1وقذ خشعج الودوىعت الشابعت وًقصبى واظح فٍ هدوىعت , (الوصببت)الوعبهلت ىبٌُج الٌخبئح صَبدة واظحت فٍ هسخىي الكلىكىص فٍ هدوىعت الفئشا(. صبَت والسلُوتالن) وكزلك ًقصبى فٍ هسخىي الكلىكىص للفئشاى السلُوت الودشعت ببلوسخخلص , الفئشاى الوصببت والخٍ خشعج ببلوسخخلص الوبئٍ للٌببث . حشُش هزٍ الٌخبئح الً اى الوسخخلص الوبئٍ لبزوس آراى الفبس حوخلك حبثُش خبفط للسكش(. السُطشة)الطبُعُت ببلوقبسًت هع الودوىعت .أراى الفبر ، هستوى السكر، الفئراى االلبٌَو :الكلوبت الوفتبحَة Introduction Approximately 0.7% of the world's population suffers from insulin-dependent diabetes mellitus (1) . It has been estimated that the incidence of diabetes will double to approximately 300 million in the next 25 years. To date, insulin therapy is the only effective treatment for Type 1 diabetes and is also generally required for the treatment of Type 2 diabetes as the disease progresses. Therapyrequires the regular monitoring of blood glucose levels , combined with frequent injection of insulin , in order to avoid the severe debilitating secondary complications associated with chronic hypoglycemia. Meeting this demand will necessitate the development of more cost-effective, higher capacity production in the near future (2) . Presently, there is growing interest in herbal remedies due to the side effects associated with the oral hypoglycemic agents (therapeutic agent) for the treatment of diabetes mellitus. Corresponding author E-mail: Dr.khaleel2011@yahoo.com Received:12 /11/2012 Accepted: 4/5/2013 Iraqi J Pharm Sci, Vol.22(1) 2013 Arabidopsis thaliana extract and blood glucose level 116 So the traditional herbal medicines are mainly used which are obtained from plants, it plays important role in the management of diabetes mellitus (3) . In recent years, herbal medicines have started to gain importance as a source of hypoglycemic agents. Marles and Farnsworth estimated that more than 1000 plant species are being used as folk medicine for diabetes (4) . Biological actions of the plant products used as alternative medicines to treat diabetes are related to their chemical composition. Herbal products or plant products are rich in phenolic compounds, flavonoids, terpenoids, coumarins, and other constituents which show reduction in blood glucose levels .(5, 6, 7) . Several species of herbal drugs have been described in the scientific and popular literature as having antidiabetic activity (8) . Due to their perceived effectiveness, fewer side effects in clinical experience and relatively low costs, herbal drugs are prescribed (9) . Best reported for the presence of insulin-like substances in plant materials like green tops of onions, lettuce leaves, green bean leaves, barley roots, beet roots and others (10) . The discovery of this hormone in tissues of the higher plants as well as in yeast opened up a new field of research in plant metabolism and afforded another remarkable example of parallelism between certain physiological processes in the plant kingdom with the animal kingdom. Pancreatic insulin’s influence on glycogen formation provoked a theoretical concept on the existence of insulin or insulin like protein hormones in organisms rich in glycogen. Collip’s efforts on extracts of yeast and onion were successful in altering glucose metabolism. The term glucokinin was proposed by him in order to differentiate insulin of plant origin from that of animals. Following Collip’s discovery Charles Best reported on insulin like material in germinating potatoes, rice and even in beetroot (11, 12) .Arabidopsis thaliana, a small, annual flowering, dicotyledonous plant, was discovered by Johannes Thal (hence, thaliana) in the Harz mountains in the sixteenth century. Arabidopsis is a member of the Brassicaceae family, which includes important crops. It has no agronomic significance, but offers important advantages for basic research in genetics and molecular biology (13) . The aims of this research are to determine the active compounds in Arabidopsis plant seeds, for anti-diabetic treatments of patients with high glucose level in their blood, and to achieve commercial and economic source of insulin. Materials and Methods Plant material Seeds of Arabidopsis thaliana were obtained from Dr. Enas Muhgin in Ebn-Albetar Center- Baghdad. The plant was cultivated in north of Iraq and used in genetic engineering experiments in research centers. It was authenticated by Biology Department-College of Science- Baghdad University. Preparation of the extract The powdered material of seeds (50 gram) added to 250 ml of distilled water, left over night on stirrer, the extract then dried under reduced pressure and was subjected to various chemical tests to detect the presence of different active phytoconstituents like alkaloids, tannins, flavonoids, saponins, terpens and steroids (14) . Detection of some active compounds- Colorimetric test This detection was carried out using chemical reagents and depends on appearance of the color to determine the presence of the compound only. Detection of tannins (10 gram) of plant powder was mixed with 50 ml distilled water in a magnetic stirrer. The mixture was boiled in a boiling water bath for few minutes, then filtered and the filtrate was treated with few drops of 1% lead acetate solution. The development of greenish-blue precipitate is an indicator for the presence of tannins (15). Detection of saponins Saponins were detected by two methods: The first method, aqueous extract of A. thaliana seeds powder was shaken vigorously with distilled water in a test tube. The formation of foam standing for a time indicates a positive result. The second method, five milliliters of aqueous extract of the plant was added to 1-3 drops of 3% ferric chloride solution, a white precipitate was developed which indicates a positive result (16) . Detection of terpenes and steroids (1 ml) of ethanolic extract was participated in a few drops of chloroform, then a drop of acetate anhydride and drop of concentrated sulfuric acid were added, brown precipitate appeared which representing the presence of terpene, and the appearance of dark blue color after few minutes would represent the present of steroids. The color is due to the hydroxyl group (-OH) of the steroids reacting with the reagents and increasing the conjugation of the un- saturation in the adjacent fused ring. Since this Iraqi J Pharm Sci, Vol.22(1) 2013 Arabidopsis thaliana extract and blood glucose level 117 test uses acetic anhydride and sulfuric acid as reagents, caution must be exercised so as not to receive severe burns (17). Detection of flavonoids Flavonoids were extracted by well established method of Harborne 1984, and the procedure has also been followed by several others authors. The extraction protocol which has been carried out in this investigation is only for detection of flavonoids in seed extract of A. thaliana. Ethanolic extract was partitioned with petroleum ether (1:1v/v), the aqueous layer was mixed with the aluminum solution. The appearance of dark color is an evidence for the presence of flavonoids. Flavonoids react with the reagent and give colour reactions. Spraying reagents 5% fehling solution and 1% AlCl3 solution are exclusively used to detect flavonoids (17) . Detection of alkaloids (10 gram) of the extract was boiled with 50 ml of distilled water and 4% of hydrochloric acid was added, then the solution was filtered and cooled. 0.5 ml of the supernatant was tested with Mayer solution, appearance of white precipitate indicates the presence of alkaloids (17) . Experimental animals Healthy 20 adult albino male mice of Swiss albino strain were obtained from the animal house of Biotechnology Research Center, Al- Nahrain University. The age of the mice was 8 weeks, and the weight was 25 gram. The animals were housed in plastic cages, which were cleaned and sterilized weekly with 70% ethanol. Five mice kept in each cage with natural 14 hours light , 10 hours dark , and a controlled temperature at (24-28) C ͦ . The animals were fed chow and water ( The protocol was proved by Institutional Animal Ethical Committee JKKMMRF/CP/PhD/ 2008) . Induction of diabetes The animals were fasted for 24 hours, then diabetes was induced by a single intraperitoneal (IP) injection of alloxan monohydrated dissolved in distilled water at a dose of 150 mg/kg of mice body weight in volume of 0.1 ml. The diabetic state was confirmed 48 hours after alloxan injection. Blood glucose value was reached 260 mg/dl which indicate hyperglycemia (140 mg/dl as standard before treatment), and there was 5% mortality in animals treated with alloxan. Surviving mice with fasting blood glucose level 250 mg/dl or higher were included in this study (18). Experimental groups The animals were divided into four groups (five mice per each group), and the groups were treated as following: First group, control, normal mice administrated with 0.1 ml distilled water. Second group, normal mice administrated with 0.1 ml of Arabidopsis seed extract. Third group, diabetic mice administrated with 0.1 ml of distilled water. Fourth group, diabetic mice administrated with 0.1 ml of Arabidopsis seed extract. Blood sample collection For 10 days after the experiment, blood samples were collected every two days (2, 4, 6, 8, 10) days, from the tail vein of the mice under the experiment, and glucose was assayed immediately using glucometer apparatus. Results Results Chemical detection The chemical test of the active compounds in Arabidopsis thaliana seed extract showed in table (1) indicated that the aqueous extract of this medicinal plant contains tannins, favonoids, alkaloids, saponins, terpenes and steroids. Table (1): Chemical detection of some active compounds in Arabidopsis thaliana seed extract Anti-hyperglycemic activity The effect of treatment with aqueous extract of Arabidopsis thaliana on blood glucose levels in normal and diabetic mice are reported in table 2. Blood glucose levels of the treated mice were significantly higher than normal mice (control). Injection of 0.1 ml alloxan induced diabetes in the experimental animals as data showed, higher glucose level reached 249.2 mg/dl (as the average of five investigation) for the diabetic mice, and while it was recorded 166 mg/dl when it was injected with 0.1 ml of Arabidopsis extract No. Compound Result 1 Tannins + 2 Flavonoids + 3 Alkaloids + 4 Saponins + 5 Terpenes and Steroids + 6 Glycoside - (+) means positive detection , (-) means negative detection Iraqi J Pharm Sci, Vol.22(1) 2013 Arabidopsis thaliana extract and blood glucose level 118 (200 mg/kg of B. Wt). It was reached 163 mg/dl with diabetic mice which were treated with swine insulin. From these results, significant decrease in blood glucose levels was obtained as compared with normal mice (control treatment) which recorded 164.4 mg/dl. Table 2: Anti-hyperglycemic effects of Arabidopsis thaliana seed extract (200 mg/kg of body weight) on induced diabetic mice Group/Treatment Dose (0.1 ml) After 2 days (mg/dl) After 4 days (mg/dl) After 6 days (mg/dl) After 8 days (mg/dl) After 10 days (mg/dl) AVG (mg/dl) Normal mice (control) 142 168 162 169 181 164.4 Diabetic mice treated with alloxan only 260 250 242 248 248 249.2 Diabetic mice treatment with insulin 168 164 162 163 164 163 Diabetic mice treated with extract 173 171 161 166 159 166 Discussion The plant extract studied could be an answer to the people seeking for therapeutic agents from natural sources which is believed to be more efficient with a little or no side effects when compared to the synthetic chemotherapeutic agents. The present experiment indicated that aqueous extract of Arabidopsis seeds exhibited a potent blood glucose lowering properties in diabetic white albino mice. Recombinant human insulin in the model plant species of A. thaliana seeds was produced by Cory et al. (2) . Weili et al., reported that an important therapeutic protein human insulin-like growth factor 1(hIGF-1) called somatomedin C, was expressed in Arabidopsis thaliana seeds via oleosin fusion technology. The biological activity of the hIGF-1 as an oleosin-hIGF-1 fusion protein in vitro was demonstrated by using human neuroblastoma cells (19) . The hypoglycemic activity shown in this study may be related to the presence of flavonoids compounds which had very pronounces effect in the seed extract of this plant. Flavonoids may preserve β-cell function by reducing oxidative stress-induced tissue damage and therefore protect against the progression of insulin resistance to type 2 diabetes. A prospective study in Finland showed that the intakes of some specific types of flavonoids including quercetin and myricetin were inversely associated with risk of incident type 2 diabetes. In addition, emerging evidence shows that oxidative stress may be involved in the pathogenesis of chronic inflammation underlying insulin resistance, diabetes and cardiovascular disease (20, 21) . Many literature reports suggest the existence of proteins with functions similar to proteins that are members of insulin pathways characteristic of vertebrates. Localization of insulin-like protein in plant tissues and it has functions in connection with carbohydrate metabolism (22) . Results of this study are in harmony with the results demonstrated by Sheng et al. who found a hypoglycemic activity in Momordica charantia and Canavalia ensiflormis seed extracts. The results are also in agreement with Panahi et al who found that transgenic plants such as, Arabidopsis thaliana producing recombinant human insulin-like growth factor-1 (hIGF-1), the plant-derived hIGF-1 caused differentiation of human neuroblastoma cell line SH-SY5Y, indicating its biological activity (23, 24, 25) . It was concluded that it was plant insulin, The presence of insulin-like molecule was recently demonstrated in the seed extract of Arabidopsis thaliana , this protein may be responsible for the lowering of blood glucose concentrations when it was injected in diabetic mice. The hypoglycemic activity of the insulin-like protein from seed extract of this plant was similar to that of commercial swine insulin used as control. References 1. Winter, J., Neubauer, P., Glockshuber, R. and Rudolph, R. “Increased production of human proinsulin in the periplasmic space of Escherichia coli by fusion to DsbA”. J. Biotechnol. 84: pp175–185, 2001. Iraqi J Pharm Sci, Vol.22(1) 2013 Arabidopsis thaliana extract and blood glucose level 119 2. Cory, L. N.; Joseph, G. B.; Elizabeth, W. M.; Richard, G. K.; Joseph, G.; Nancy, A. M. and Maurice, M. M. ” Transgenic expression and recovery of biologically active recombinant human insulin from Arabidopsis thaliana seeds “ Plant Biotechnology Journal, Vol.4 Issue 1, pp:77–85, 2006. 3. Patel, K. and Srinivasan, K. “ Plant foods in the management of diabetes mellitus: vegetables as potential hypoglycemic agents “. Nahrung 41: pp 68–74, 1997. 4. Marles, R. J. and Farnsworth, N. R.“Antidiabetic plants and their active constituents”. Phytomedicine 2: pp137–189, 1995. 5. He, C. N.; Wang, C. L. and Guo, S. x. “ Study on chemical constituents in herbs of anoectochilus roxburghii II, Chin. J. Chin. Materia. Medica 30: pp761–776, 2005. 6. Jung, M.; Park, M.; Lee HC.; Kang, Y.; Kang, E. S. and Kim, S. K.“Antidiabetic agents from medicinal plants, Curr. Med. Chem. 13: pp1203–1218, 2006. 7. Ji, H. F.; Li, X. J. and Zhang, H. y.” Natural products and drug discovery”EMBO Rep. 10 (3):pp194–200, 2009. 8. Valiathan, M.S., Healing plants. Curr. Sci. 75, pp:122–1126, 1989. 9. Verspohl, E. J.” Recommended testing in diabetes research”. Planta Med. 68, pp: 581–585, 2002. 10. Grover, JK.; Yadav, S. and Vats, V.” Medicinal plants of India with anti-diabetic Potential”. J. Ethnopharmacol, 81(1): pp81- 100, 2002. 11. Wild, S. and Bchir, R. G.” Green A, Sicree S, King H. Global prevalence of diabetes estimates for the year 2000 and projections for 2030”. Diabetes Care, 27:1047–1053, 2004. 12. Lucy, D.; Anoja, S.; Attele, Ch. and Yuan, Su.“ Alternative therapies for type 2 diabetes - Review: type 2 diabetes”. Alternative Medicine Review,Feb, 2002. 13. Sommerville, C. and Koornneef, M.“ A fortunate choice: the history of Arabidopsis as a model plant. Nature Reviews Genetics 3: pp 883-889, 2002. 14. Kokate, R. N. Practical pharmacognosy 3 rd (Eds) Vallabh Prakashan New Delhi, pp:107-109, 1994. 15. Evans, W. C. Pharmacognosy 13 th (Eds) Balliere Tindal, London, pp:419-420, 1989. 16. Alsereita, M. and Abu-Amer, K. “Therapeutic potential and pharmacology of medicinal plants. In 40 th Annul of the Egy. Soc. of Pharmacol. Ant Therap., Cairo,44, 1996. 17. Harborne, J. B.” Phytochemical Methods. A guide to Modern Technique of Plant Analysis, Chapman Hall, London, 1984. 18. Diasy, P.; Santosh, K. and Rajath, M. “ Antihyperglycemic and antihyperlip demic effect of Clitoria ternate L. in alloxan- induced diabetic rats. African Journal of Microbiology Research, 3(5): pp 287-291, 2009. 19. Weili, L.; Linguo, Li.; Kunlon, Li.; Juan, Lin.; Xiaofen, Sun. And Kexuan, T.“ Expression of biologically active human insulin-like growth factor-1 in Arabidopsis thaliana seeds via oleosin fusion technology. Int. Union of Biochemistry and Molecular Biology. Inc. Vol. 58: 139- 146,2011. 20. Knekt, P.; Kumpulainen, J.; Jarvinen, R.; Rissanen.,H.; Heliovaara, M.; Reunanen, A.; Hakulinen, T. and Aromaa, A.” Flavonoid intake and risk of chronic diseases”. Am J Clin Nutr76 :560– 568,2002. 21. Esposito K, Nappo F, Marfella R, Giugliano G, Giugliano F, Ciotola M, Quagliaro L, Ceriello A, Giugliano D: Inflammatory cytokine concentrations are acutely increased by hyperglycemia in humans: role of oxidative stress. Circulation106 :2067– 2072,2002. 22. Xavier-Filho, J.; Oliveira, AEA.; Silva, L. B.; Azevedo, CR. and Venancio, TM.” Plant insulin or glycokinin: a conflicting issue. Bras. J. Plant Physiol., 15: 67-78, 2003. 23. Sheng, Q.; Yao, H.; Xu, H.; Ling, X. and He, T.” Isolation of plant protein from Momordica charantia seeds by gel filtration and RP-HPLC.Zhang. Yao Cal, 27: 414- 416, 2004. 24. Panahi, M., Alli, Z., Cheng, X., Belbaraka, L., Belgoudi, J., Sardana, R., Phipps, J., and Altosaar, I. Insulin like growth factor (In Weili, et al. , 2011) Trans . genic Res. 13 , 245–259, 2004. 25. Menand, B., Desnos, T., Nussaume, L., Berger, F., Bouchez, D. and Meyer, C. Expression and disruption of the Arabidopsis TOR (target of rapamycin) gene. Proc Natl. Acad. Sci. ; 99:6422-6427, 2002.