The purified mung bean LOX has resolved into two peaks by chromatofocusing, one has highest LOX activity with an isoelectric point of 5.84 and the other has least expensive LOX activity with an isoelectric point of 5.52. chemical properties of the mung bean LOX are similar to the other legume LOXs and may be considered as type-1 LOX. for 30?min. The fine supernatant was dialyzed against 25?mM sodium phosphate buffer (pH 6.8) for 24?h with three buffer changes and centrifuged at 25,000for 20?min. The supernatant was dialyzed against 40?% poly ethylene glycol 20,000 for 16?h and then centrifuged at 25,000for 20?min. The dialyzed sample was applied to Sephadex G-150, gel filtration column (100??2.5?cm) and fractions were collected with a portion size of 2.5?ml per tube at a circulation rate of 20?ml/h. The active fractions were pooled and further purified by ion exchange chromatography (DEAE 52, column 3??30?cm). Bound protein was eluted using a linear salt gradient [0?mM (150?ml) to 300?mM (150?ml)] sodium phosphate buffer [pH 6.8] and fractions were assayed for protein and LOX activity. At the end of this purification step, two protein fractions were obtained, one with high and the other without LOX activities. To determine the isoelectric points of mung bean seedling LOX, the peak with high LOX activity fractions was pooled, concentrated and dialyzed to remove salt, centrifuged at 25,000for 20?min at 4?C and the sn-Glycero-3-phosphocholine supernatant was applied on the PBE-94 chromatofocusing column (3??12?cm) which was saturated with 5?ml of gradient buffer (Poly buffer 94, 1: 8, pH 4.0) to create a pH gradient in column. The flow rate was adjusted to 8?ml/h and elute was collected in 1?ml per fraction. The protein in each fraction was read at 280?nm and assayed for LOX activity. The pH of each fraction was determined by using a KL-009 (1B) pocket size pH meter. All purification steps were performed at 4?C until otherwise mentioned. SDS-PAGE SDS-PAGE was performed according to the method of Laemmli (1970) using 12?% gels. The proteins were stained with Coomassie brilliant blue R-250 in methanol:water:acetic acid (60:30:10) for few hours and then washed in destaining buffer until protein bands appear. Activity staining Sample containing 50C100?g LOX protein of germinated seedlings extract was separated on 8?% polyacrylamide gel electrophoresis without adding SDS to the gel and running buffer (0.025?M TrisCHCl and 0.192?M glycine, pH 8.8) at 4?C as suggested by Heydeck and Schewe (1984). In brief, following the isozymes separation, gels were washed briefly with phosphate buffer (pH 6.8), and incubated in substrate solution for 5?min at room temperature. After incubation the gels were washed quickly with 100?mM phosphate buffer (pH 6.8), and incubated in staining solution with values of mung bean LOX are closely related to English pea sn-Glycero-3-phosphocholine and soybean LOX isoenzymes (Eriksson and Svensson 1970). The SDS-PAGE purified mung bean LOX (first isozyme fraction) showed a single band with an approximate molecular mass of 97??5?kDa and greater than 90?% purity (Fig.?3a). The molecular mass of mung bean LOX is similar to broad bean, faba beans, soybean, durum wheat and pea LOXs as reported (Barone et al. 1999; Clemente et al. 2000). Activity staining on native PAGE of mung bean seedlings extract showed two brown enzymatically active bands which indicate the presence of two LOX isoenzymes during seedling growth (Fig.?3b). Based on the activity staining, presence of multiple bands suggest that perhaps two or more isoenzymes will be expressed in later stages of plant development and each will play important roles in plant growth and defense (Haydar and Hadziyev 1973). Table?1 Summary of purification methods employed for lipoxygenase purification from mung bean germinating seedlings molecular weight standards (in kDa). Lane Anion exchange (DE-52) Purified mung bean LOX (peak1). b Native PAGE analysis- Mung bean LOX isoenzymes (Mb LOX1 and Mb LOX2) stained with ETYA and NDGA Circular dichroism (CD) studies Far sn-Glycero-3-phosphocholine UV-circular dichroism spectra of mung bean LOX showed a negative dip at 208 and 222?nm, indicating the existence of predominant secondary structure with significant -helix and -strands (Fig.?7a). Further, temperature effect on mung bean LOX as function of its secondary structure at optimal pH showed that the secondary structures were stable up to 60?C and the secondary structures were destabilized upon further increase of temperature (Fig.?7b). Thermal stability of mung bean LOX was also depicted by measuring the dichroic activity at 222?nm as a function of temperature. A Sigmoid decrease in ellipticity at 222?nm was observed with increase in temperature and the inflection point of 60?C at optimal pH. The CD data of mung bean LOX is consistent with LOX activities measured at different temperatures whereas loss in enzymatic activities was observed over 60?C at optimal pH. These data suggest that, the mung bean.In brief, following the isozymes separation, gels were washed briefly with phosphate buffer (pH 6.8), and incubated in substrate solution for 5?min at room temperature. type-1 LOX. for 30?min. The fine supernatant was dialyzed against 25?mM sodium phosphate buffer (pH 6.8) for 24?h with three buffer changes and centrifuged at 25,000for 20?min. The supernatant was dialyzed against 40?% poly ethylene glycol 20,000 for 16?h and then centrifuged at 25,000for 20?min. The dialyzed sample was applied to Sephadex G-150, gel filtration column (100??2.5?cm) and fractions were collected with a fraction size of 2.5?ml per tube at a flow rate of 20?ml/h. PKN1 The active fractions were pooled and further purified by ion exchange chromatography (DEAE 52, column 3??30?cm). Bound protein was eluted using a linear salt gradient [0?mM (150?ml) to 300?mM (150?ml)] sodium phosphate buffer [pH 6.8] and fractions were assayed for protein and LOX activity. At the end of this purification step, two protein fractions were obtained, one with high and the other without LOX activities. To determine the isoelectric points of mung bean seedling LOX, the peak with high LOX activity fractions was pooled, concentrated and dialyzed to remove salt, centrifuged at 25,000for 20?min at 4?C and the supernatant was applied on the PBE-94 chromatofocusing column (3??12?cm) which was saturated with 5?ml of gradient buffer (Poly buffer 94, 1: 8, pH 4.0) to create a pH gradient in column. The flow rate was adjusted to 8?ml/h and elute was collected in 1?ml per fraction. The protein in each fraction was read at 280?nm and assayed for LOX activity. The pH of each fraction was determined by using a KL-009 (1B) pocket size pH meter. All purification steps were performed at 4?C until otherwise mentioned. SDS-PAGE SDS-PAGE was performed according to the method of Laemmli (1970) using 12?% gels. The proteins were stained with Coomassie brilliant blue R-250 in methanol:water:acetic acid (60:30:10) for few hours and then washed in destaining buffer until protein bands appear. Activity staining Sample containing 50C100?g LOX protein of germinated seedlings extract was separated on 8?% polyacrylamide gel electrophoresis without adding SDS to the gel and running buffer (0.025?M TrisCHCl and 0.192?M glycine, pH 8.8) at 4?C as suggested by Heydeck and Schewe (1984). In brief, following the isozymes separation, gels were washed briefly with phosphate buffer (pH 6.8), sn-Glycero-3-phosphocholine and incubated in substrate solution for 5?min at room temperature. After incubation the gels were washed quickly with 100?mM phosphate buffer (pH 6.8), and incubated in staining solution with values of mung bean LOX are closely related to English pea and soybean LOX isoenzymes (Eriksson and Svensson 1970). The SDS-PAGE purified mung bean LOX (first isozyme fraction) showed a single band with an approximate molecular mass of 97??5?kDa and greater than 90?% purity (Fig.?3a). The molecular mass of mung bean LOX is similar to broad bean, faba beans, soybean, durum wheat and pea LOXs as reported (Barone et al. 1999; Clemente et al. 2000). Activity staining on native PAGE of mung bean seedlings extract showed two brown enzymatically active bands which indicate the presence of two LOX isoenzymes during seedling growth (Fig.?3b). Based on the activity staining, presence of multiple bands suggest that perhaps two or more isoenzymes will be expressed in later stages of plant development and each will play important roles in plant growth and defense (Haydar and Hadziyev 1973). Table?1 Summary of purification methods employed for lipoxygenase purification from mung bean germinating seedlings molecular weight standards (in kDa). Lane Anion exchange (DE-52) Purified mung bean LOX (peak1). b Native PAGE analysis- Mung bean LOX isoenzymes (Mb LOX1 and Mb LOX2) stained with ETYA and NDGA Circular dichroism (CD) studies Far UV-circular dichroism spectra of mung bean LOX showed a negative dip at 208 and 222?nm, indicating the existence of predominant secondary structure with significant -helix and -strands (Fig.?7a). Further, temperature effect on mung bean LOX as function of its secondary structure at optimal pH showed that the secondary structures were stable up to 60?C and the secondary structures were destabilized upon further increase of temperature (Fig.?7b). Thermal stability of mung bean LOX was also depicted by measuring the dichroic activity at 222?nm as a function of temperature. A Sigmoid decrease in ellipticity at 222?nm was observed with increase in temperature and the inflection point of 60?C at optimal pH. The CD data of mung bean LOX is consistent with LOX activities measured at different temperatures whereas loss in enzymatic activities was observed over 60?C at optimal pH. These data suggest that, the mung bean LOX secondary structure is pH and temperature dependent.