Production, Purification and Efficacy of Bacteriocin Isolated from Natural Lactic Acid Fermentation of Wild Himalayan Fig Fruit

The biopreservative effect of purified bacteriocin produced during lactic acid fermentation of wild Himalayan fig pickle was investigated in RTS-drink. A total number of seven isolates (SS1, SS2, SS3, SS4, SS5, SS6 and SS7) were isolated from fermented wild Himalayan fig pickle. SS7 isolate was identified as Lactobacillus genus according to Bergeys Manual of Systemic Bacteriology. SS7 isolate of Lactobacillus genus produced bacteriocin with maximum antagonistic activity against Escherichia coli, listeria monocytogenes and Bacillus cereus, though it was more effective against Bacillus cereus than others. Completely purified bacteriocin showed increased in zone of inhibition against food borne pathogens then partially purified bacteriocin. Bacteriocin was thermo stable as it retains its stability up to 121 °C. The maximum antimicrobial activity was retained within the pH range of 6–7, but it was adversely affected by the addition of proteolytic enzyme papain. The biopreservative efficacy of bacteriocin of SS7 isolate was found in RTS-drink. In RTS-drink, Minimal Inhibitory Concentration of bacteriocin was found to be 4.0 mL for Bacillus cereus, E. coli and 4.5 mL for L. monocytogenes

Identification of Key Regulatory Pathways of Basidiocarp Formation in Pleurotus spp. Using Modeling, Simulation and System Biology Studies

Pleurotus (Oyster mushroom) is an important cultivated edible mushroom across the world. It has several therapeutic effects as it contains various useful bio-molecules. The cultivation and crop management of these basidiomycete fungi depends on many extrinsic and intrinsic factors such as substrate composition, growing environment, enzymatic properties, and the genetic makeup, etc. Moreover, for efficient crop production, a comprehensive understanding of the fundamental properties viz. intrinsic–extrinsic factors and genotype-environment interaction analysis is required. The present study explores the basidiocarp formation biology in Pleurotus mushroom using an in silico response to the environmental factors and involvement of the major regulatory genes. The predictive model developed in this study indicates involvement of the key regulatory pathways in the pinhead to fruit body development process. Notably, the major regulatory pathways involved in the conversion of mycelium aggregation to pinhead formation and White Collar protein (PoWC1) binding flavin-chromophore (FAD) to activate respiratory enzymes. Overall, cell differentiation and higher expression of respiratory enzymes are the two important steps for basidiocarp formation. PoWC1 and pofst genes were participate in the structural changes process. Besides this, the PoWC1 gene is also involved in the respiratory requirement, while the OLYA6 gene is the triggering point of fruiting. The findings of the present study could be utilized to understand the detailed mechanism associated with the basidiocarp formation and to cultivate mushrooms at a sustainable level