Fluorescence and circular dichroism studies on the accessibility of tryptophan residues and unfolding of a jacalin-related α-D-galactose-specific lectin from mulberry (Morus indica)

Abstract

MLGL (Mulberry Latex Galactose-specific Lectin) is an α-D-galactose binding lectin isolated from the latex of mulberry (Morus indica) tree and contains two tryptophan residues in each of its subunits. The fluorescence emission maximum of native MLGL seen at 326nm shifts to 350nm upon incubation with 6M guanidinium thiocyanate (Gdn.SCN), suggesting that the tryptophans are located inside the hydrophobic core of the protein and become fully exposed upon denaturation. Fluorescence quenching studies revealed that the neutral acrylamide exhibits the highest quenching, with ~33% of total fluorescence in the native protein being quenched at a quencher concentration of 0.5M, whereas iodide (~24%) and cesium (~4%) ions showed significantly lower quenching. With the denatured protein, acrylamide quenching involves both dynamic and static processes as evident from an upward curving Stern-Volmer plot. Time-resolved fluorescence studies showed two lifetime components of 3.7ns and 1.3ns for the native protein, while three lifetime components were observed for the denatured protein. MLGL showed high resistance to urea (up to 8M) and guanidine hydrochloride (up to 6M), whereas treatment with 6M Gdn.SCN completely denatured the protein, via a broad sigmoidal transition with a transition midpoint at ~3.75M. Circular dichroism studies and hemagglutination assays showed that the secondary and tertiary structures as well as lectin activity of MLGL were unaffected up to 70°C. Additionally, pH dependent studies showed that the secondary structure of MLGL is unaltered in the pH range 6.2 to 8.5, but a decrease in lectin activity is observed (~50%) at pH6.2.