Abstract
More attention has been recently directed toward glutathione peroxidase and s-transferase enzymes because of the great importance they hold with respect to their applications in the pharmaceutical field. This work was conducted to optimize the production and characterize glutathione peroxidase and glutathione s-transferase produced by Lactobacillus plantarum KU720558 using Plackett-Burman and Box-Behnken statistical designs. To assess the impact of the culture conditions on the microbial production of the enzymes, colorimetric methods were used. Following data analysis, the optimum conditions that enhanced the s-transferase yield were the De Man-Rogosa-Sharp (MRS) broth as a basal medium supplemented with 0.1% urea, 0.075% H2O2, 0.5% 1-butanol, 0.0125% amino acids, and 0.05% SDS at pH 6.0 and anaerobically incubated for 24 h at 40°C. The optimum s-transferase specific activity was 1789.5 U/mg of protein, which was ~12 times the activity of the basal medium. For peroxidase, the best medium composition was 0.17% urea, 0.025% bile salt, 7.5% Na Cl, 0.05% H2O2, 0.05% SDS, and 2% ethanol added to the MRS broth at pH 6.0 and anaerobically incubated for 24 h at 40°C. Furthermore, the optimum peroxidase specific activity was 612.5 U/mg of protein, indicating that its activity was 22 times higher than the activity recorded in the basal medium. After SDS-PAGE analysis, GST and GPx showed a single protein band of 25 and 18 kDa, respectively. They were able to retain their activities at an optimal temperature of 40°C for an hour and pH range 4–7. The 3D model of both enzymes was constructed showing helical structures, sheet and loops. Protein cavities were also detected to define druggable sites. GST model had two large pockets; 185Å3 and 71 Å3 with druggability score 0.5–0.8. For GPx, the pockets were relatively smaller, 71 Å3 and 32 Å3 with druggability score (0.65–0.66). Therefore, the present study showed that the consortium components as well as the stress-based conditions used could express both enzymes with enhanced productivity, recommending their application based on the obtained results.
Highlights
The use of enzyme technologies in the pharmaceutical research and industrial production fields is growing day by day
It was found that 0.05% H2O2, FIGURE 1 | Time-course of glutathione peroxidase and s-transferase production by L. plantarum along with the biomass
Placket-Burman and Box- Behnken statistical designs were used for evaluating the effective parameters and their optimal concentrations to enhance Glutathione s-transferases (GSTs) and GPx enzyme productivity by L. plantarum KU720558
Summary
The use of enzyme technologies in the pharmaceutical research and industrial production fields is growing day by day. Enzymes act as catalyst, which convert the target molecules into the required products. These two advantages make enzymes more potent and specific medicaments that can exert superior therapeutic effect within the body than smaller molecules. Based on these properties, many enzyme drugs have been developed for treatment of a wide range of diseases in which oxidative stress is involved such as several age-related conditions Zhang et al (2000) reported that oral administration of glutathione peroxidase-mimetic (bxt-51072) showed a potent anti-oxidant effect protecting the inflamed colonic mucosa from nitration and oxidation in patients with ulcerative colitis
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