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Hemalatha C, Dhamotharan R, Murugesan S, Studies on Lectin From Glycine Max (L.) Merrill. Biosci Biotech Res Asia 2010;7(1)
Manuscript received on : March 10, 2010
Manuscript accepted on : April 16, 2010
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Studies on Lectin From Glycine Max (L.) Merrill

C. Hemalatha, R. Dhamotharan1 and S. Murugesan2

1PG and Research Department of Plant Biology and Plant Biotechnology, Presidency College, Chennai - 600 005 (India). 2Unit of Algal Biotechnology and BionanoTechnology, PG and Research Department of Plant Biology and Plant Biotechnology, Pachaiyappa’s College, Chennai - 600 030 (India).

ABSTRACT: A plant lectin isolated in its pure state from the Indian of soya bean seeds produced single band in SDS–PAGE (30kDa) and one peak by gel filtration chromatography on Sephadex G-100, corresponding to 120 kDa. SBL is a glycoprotein bound with glucose and mannose (2 mol/mol of protein) and stabilized by 4 atoms of each of Ca2+ and Mn2+ per subunit. The soya bean lectin exhibited haemagglutinating activities in various degrees against human ABO type, rabbit and rat erythrocytes. Maximum activity was observed against rabbit and human AB blood groups. Among the various tested sugars, SBL agglutination was most inhibited by N-acetylgalactose. Hemagglutination was markedly affected by acidic pH, but was heat stable below 60°C for 30 min. The haemagglutinating activity of the soya bean lectin was inhibited by addition of Ca2+, Mg2+, Mn2+ and EDTA. SBL is rich in hydroxyl amino acids while totally lacking sulfur amino acids.

KEYWORDS: Soya bean lectin; Hemagglutination activity

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Introduction

Lectins are naturally occurring glycoproteins that bind carbohydrate residues selectively and non-covalently (Van Damme et al., 1998). Lectins can be found in all kingdoms of life ranging from viruses, bacteria and plants to animals (Loris, 2002). Lectins are protein that interact with cell surfaces and cause cells to agglutinate. Some lectins have been shown to have a greater capacity to agglutinate transformed cells than normal cells, and are being used to investigate the differences between the surfaces of these cells. Legume lectins are the largest and most thoroughly studied, family of the simple lectins (Sharon and Lis, 1972; Bog-Hansen, 1981. The genus Glycine max (family leguminosae, subfamily Paplionaceae) are grown fairly throughout in India, In this aspect, soya bean is an important legume as it has high protein content and nutritionally balanced amino acid profile. The reasonable price and steady supply are also favourable factors in soya beans emerging as an important source of protein in animal nutrition (Olguin et al., 2003) However, the nutritional value of soya bean meal is much lower than expected, in spite of its protein content and amino acid profile was largely attributed to antinutritional factors (Pusztai, 1991). Soya bean flour also contains several haemagglutinatingisolectins. Their presence in the diet is known to reduce the growth rate of young monogastric animals (Van Damme et al., 1998). As parts of general programme on the study of biologically important proteins from legumes are used in the Indian dietary, the work on soya lectins has been initiated. In the present study, successful efforts have been made to remove the lectins from soya bean flour and recover these value-added products.

Material and methods

Soya bean seeds were collected from various regions of Tamil Nadu and the collected specimens were authenticated by the Department of pulses, Tamil Nadu Agricultural University, Coimbatore, Tamil Nadu, India. Human blood cells (A, AB, B and O) of healthy donors and Rabbit, rat, and sheep blood cells were obtained from the animal house of Veterinary College, Chennai.

The lectin was purified from plant materials according to Rudiger protocol (1993). The precipitate (the prepurified extract) was dissolved in a minimum amount of the buffer and extensively dialyzed against the same buffer. The prepurified extract was applied to the Sephadex G-100 column (100 h x 2.5 dia cm) at flow rate of 60 ml/h. The column was washed with the buffer at the same speed until the A280 fell down to <0.05. The buffer was exchanged by the eluting buffer (0.25 M Galactose, and 0.02% NaN3) to desorb the lectin from the column. The fractions containing lectin were combined on the basis of A280, dialyzed against water, frozen and lyophilized.

The measurement of protein content in different fractions was described by Bradford (1976), using bovine serum albumin (BSA) as standard. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS–PAGE) was performed in discontinues system with 12.5% separating and 5% stacking gels according to the method of Laemmli and Favre (1973).

Serial two fold dilutions of purified soya bean lectin (10 mg/ mL) in phosphate buffer saline (PBS) (50 µl) were incubated with 50 µl of 4% erythrocyte suspension in V-shaped micro titer plates and after incubating the plate for 1h at 4oC the haemagglutination titer was scored visually. Haemagglutination-inhibition assays with the purified soya bean lectin were done using the same procedure with different concentrations of sugar solution. The haemagglutination unit (HU) was expressed as the reciprocal of the highest lectin dilution showing detectable visible erythrocyte agglutination and the specific activity was calculated as HU/mg protein.

The effect of pH, temperature and EDTA, Ca2+ and Mn2+ on lectinhemagglutinating activity of the purified soya bean lectin was determined. The lectins were hydrolysed with 1 Í HCl in vacuo for 2 h at 110°C and analysed for amino acid and carbohydrate analysis followed by HPLC analysis.

Results and Discussion

The lectin could be successfully purified in a single step by affinity chromatography on Sephadex G-100. Loading of prepurified extract on an affinity column followed by washing out the unbound proteins then eluting the bound lectin with 250 mM glucose led to increments in the specific activity up to 302 titer/mg corresponding to 72 % yield. The final lectin yield was ca. 135 mg per 100 g dry seed weight. This value is exactly the same as obtained by Lotan et al. (1974) and Vretblad (1993). A purified soya bean lectin (SBL) moved as a single band in SDS-page and the approximate molecular weight was found to be 30 kDa (Lis et al., 1966; Franco-Fraguas et al., 2003).

SBL showed specificity in its ability to hemagglutinate human (A, B, AB and O) erythrocytes and indiscriminately agglutinate rabbit, rat and chicken. However, hemagglutinating activity against chicken erythrocyte was comparatively the lowest one. This difference in the agglutination activity may be due to the nature of the glycoproteins protruding on the cell surface, which are weakly or not totally recognized by the lectin (Oliveria et al., 2002).

Mono and disaccharides inhibited the agglutinating activity of SBL and the maximum inhibition was observed with N-acetyl- D- galactose and raffinose showed the least degree of inhibition of the agglutinating activity of SBL. The IC50 value of N-acetyl- D-galactose was very low as compared with other sugars. It is known that soya bean lectin i.e. SBL is specific for N-acetyl- D- galactosamine, which provide an axial 4-OH group for binding (Goldstein and Portez,1986).

The amino acid composition of the purified lectin, generally characterized by high levels of hydroxyl amino acids and low/absence of sulphur containing amino acids and high levels of hydroxyl amino acids, is in accordance with the results of Wayne Gade et al., (1981). SBL from soya bean is a glycoprotein consisting mostly glucose, mannose and glucosamine are present at the following content, 5-8 moles of mannose, 1-2 mole of glucose per mole of lectin. A similar observation was also made by Lis and Nathan Sharon (1977).

Soya bean lectin showed tolerance to a wide range of pH between 5.0 and 8.0. In acidic pH, there is a loss of activity. Similar observations have been made by Damico et al. (2003) for the seed lectins of Annonamuricata and by Mahmoud Sitohy et al., (2007) for soya bean lectins. Maximum activity for SBL was found to be at neutral pH 7. At this pH, the lectins are reported to exist as tetramer (Loris et al., 1998; Srinivas et al., 2001). The relatively lower reduction of activity, at the basic pH values may be due to some degree of base induced denaturation. Thermal denaturation studies with SBL showed its stability against high temperature for prolonged periods. The SBL remained intact without losing its hemagglutinating activity to a significant extent at 60-70°C for nearly 90 minutes. However, the lectin was significantly stable at temperatures below 60°C. Temperatures above 60°C marginally reduced the activity but not to the level of inactivation. The loss of hemagglutinating activity with   increasing temperature is evidently due to heat-induced denaturation of the lectin. This denaturation may expectedly weaken the interaction between lectin and the carbohydrate ligand (Schwarz et al., 1993) leading consequently to attenuated agglutination activity. The (SBL) hemagglutinating activity remarkably decreased after metal removal by prolonged dialysis against 50 mM EDTA, followed by dialysis against 0.15M NaCl; however, when Ca2+ and Mn2+ (50 mM) were readded to the assay medium, the SBL activity was fully restored.

Conclusion

Soya bean lectin is a glycoprotein with glucose and mannose and stabilized by 4 atoms of each of Ca2+ and Mn2+ per subunit. Hence, SBL is a tetramer.  SBL is rich in hydroxyl amino acids while totally lacking in sulphur amino acids. The purified soya bean lectin fractions showed antifungal activity against Fusariumoxysporum and Pyriculariaoryzae. Maximum activity was observed against Pyriculariaoryzae.

References

  1. Bog-Hansen, T.C., Lectins, Biology, Biochemistry, Clinical Biochemistry (Berlin, New York: Walter de Gruyter) 1: 3 (1981).
  2. Bradford, M.M., A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein dye binding. Analytical Biochemistry, 72: 248-254 (1976).
  3. Damico, D. C., Freire, M. G., Gomes, V. M., Toyama, M. H., Marangoni, S., Novello, J. C. Isolation and characterization of a lectin from Annonamuricata seeds. Journal of Protein Chemistry, 22: 655–661.
  4. Franco-Fraguas, L., Pla, A., Ferreira, F., Massaldi, H., Suarez, N., and Batista-Viera, F., Preparative purification of soya bean agglutinin by affinity chromatography and its immobilization for polysaccharide isolation. Journal of Chromatography B.90: 365-372 (2003).
  5. Goldstein, I. J., and Hayes, C. E., The lectins: carbohydrate- binding proteins of plant and animals. Advanced Carbohydrate Chemistry and Biochemistry 35: 127-340 (1978).
  6. Laemmli, U. K., and Favre, M., Gel electrophoresis of proteins. Journal of Molecular Biology, 80: 575-599 (1973).
  7. Lis, H. and Sharon, N., The biochemistry of plant lectins (phytohaemagglutinins). In: E. E. et al. (eds) Ann. Rev. Biochem. 42: 541-574 (1973).
  8. Loris, R., Hamelryck, T., Bouckaert, J., and Wyns, L., Legume lectin structure. BiochimicaEtBiophysicaActa. 1383: 9-36 (1998).
  9. Lotan, R., Siegelman, H. W., Lis, H., and Sharon, N., Subunit structure of soya bean agglutinin J.Biol. Chem. 249: 1219-1223 (1974).
  10. Mahmoud Sitohy, Mahmoud Doheim, Haitham., Isolation and characterization of a lectin with antifungal activity from Egyptian Pisumsativum seeds. Food Chemistry 104: 971-979 (2007).
  11. Olguin, M. C., Hisano, N., D’Ottavio, A. E., Zingale, M. I., Revelant, G. C., and Calderari, S.A., Nutritional and antinutritional aspects of Argentinan soy flour assessed on weanling rats. Journal of Food Composition and Analysis. 16: 141-149 (2003).
  12. Oliveria, J. T., Purification and physicochemical characterization of a cotyledonarylectin from Luetzelburgiaauriculata. Phytochemistry 61: 301-310 (2002).
  13. Pusztai, A., Plant lectins. Cambridge University Press, Cambridge (1991).
  14. Rudiger, H., Isolation of plant lectins. In H. J. Gabius and S. Gabius (Eds.), Lectins and glycobiology (pp. 32–46). Berlin: Springer Verlag (1993).
  15. Schwarz, F. P., Puri, K. D., Bhat, R. G., and Surolia, A., Thermodynamics of monosaccharide binding to concanavalin A, pea (Pisumsativum) lectin, and lentil (Lens culinaris) lectin. Journal of Biological Chemistry, 268: 7668-7677 (1993).
  16. Sharon N and Lis H., Lectins: cell agglutinating and sugar-specific proteins. Science. 177: 949-959 (1972).
  17. Srinivas, V. R., Legumelectin family the natural mutants of the quaternary state provide insights into the relationship between protein stability and oligimerization. BiochimicaEtBiophysicaActa. 1527: 102-111 (2001).
  18. Van Damme E.J.M, Peumans, W.J., Developmental changes in the tissue distribution of lectin in Galantkusnivalis L. and Narcissus cv. Calton. Planta 182: 605-609 (1990).
  19. Van Damme, E. J. M., Plant lectins: a composite of several distinct families of structurally devolutionary related proteins with diverse biological roles. Critical Reviews in Plant Sciences 17: 575–692 (1998).
  20. Vretblad P., Bioabsorbents for biospecific affinity chromatography. In: M.N. Gupta, Editor, H. Lis and N. Sharon, Soy bean (Glycine max) agglutinin Purification of lectins by biospecific affinity chromatography (1993).
  21. Wayne Gade., The Isolation and Characterization of a Root Lectin from Soya bean (Glycine max (L), Cultivar Chippewa). J. Biological chemistryl. 256: 12905-12910 (1981).
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