Cellular fatty acid profile and H(+)-ATPase activity to assess acid tolerance of Bacillus sp. for potential probiotic functional attributes.

The present study has been focused widely on comparative account of probiotic qualities of Bacillus spp. for safer usage. Initially, 170 heat resistant flora were isolated and selected for non-pathogenic cultures devoid of cytK, hblD, and nhe1 virulence genes. Subsequently, through biochemical tests along with 16S rRNA gene sequencing and fatty acid profiling, the cultures were identified as Bacillus megaterium (AR-S4), Bacillus subtilis (HR-S1), Bacillus licheniformis (Csm1-1a and HN-S1), and Bacillus flexus (CDM4-3c and CDM3-1). The selected cultures showed 70-80 % survival under simulated gastrointestinal condition which was also confirmed through H(+)-ATPase production. The amount of H(+)-ATPase increased by more than 2-fold when grown at pH 2 which support for the acid tolerance ability of Bacillus isolates. The study also examined the influence of acidic pH on cellular fatty acid composition of Bacillus spp. A remarkable shift in the fatty acid profile was observed at acidic pH through an increased amount of even numbered fatty acid (C16 and C18) in comparison with odd numbered (C15 and C17). Additionally, the cultures exhibited various probiotic functional properties. Overall, the study increases our understanding of Bacillus spp. and will allow both industries and consumers to choose for well-defined probiotic with possible health benefits.

Potential of marine lactic acid bacteria to ferment Sargassum sp. for enhanced anticoagulant and antioxidant properties.

AIM: To evaluate the suitability of marine lactic acid bacteria (LAB) as starter cultures for Sargassum sp. fermentation to enhance its antioxidant and anticoagulation activity. METHODS AND RESULTS: LAB isolated from marine source were characterized for their ability to utilize seaweed as a sole carbon source and applied to Sargassum fermentation. Fermentation period was optimized by monitoring the fermented sample at regular interval for a period of 18 days. Results revealed that a fermentation period of 12 days was effective with maximum culture viability and other desirable characteristics such as pH, total titratable acidity, total and reducing sugars. Under optimum fermentation period, the sample fermented with P1-2CB-w1 (Enterococcus faecium) exhibited maximum anticoagulation activity and antioxidant activity. CONCLUSIONS: The study reveals a novel well-defined starter culture from marine origin intended for seaweed fermentation for recovery of bioactive molecules. SIGNIFICANCE AND IMPACT OF THE STUDY: The study provides information for the enhancement of bioactive molecules in an eco-friendly manner and also paves a way towards the development of wide range of seaweed functional foods.

Supplementation of adjuvants for increasing the nutritive value and cell viability of probiotic fermented milk beverage.

Probiotic are microorganisms that, upon ingestion in adequate amounts, exert a beneficial effect on the host. In the present work, the potent probiotic Leuconostoc mesenteroides was used as a starter culture in the preparation of fermented milk beverage. The product was analyzed for protein, titrable acidity, fat, total sugar, fatty acids and minerals. The viability of culture and nutrition in the product was further enhanced with supplementation of adjuvants like tryptone, casein hydrolysate, cysteine hydrochloride and ascorbic acid. After 5 days, maximum viability was observed on supplementation of tryptone (100 mg/l). The protein content was enhanced by 1.1-fold in the presence of tryptone (100 mg/l) as compared with control after 5 days of storage. Fermented milk supplemented with tryptone (100 mg/l) showed maximum bioavailability of the minerals like iron (92.05%), zinc (95.02%) and magnesium (92.04%) as compared with control. The increase in the composition of beneficial fatty acids on supplementation of adjuvants supports the therapeutic value of the product.

Probiotic Bacillus spp. in Soy-Curd: Nutritional, Rheological, Sensory, and Antioxidant Properties.

UNLABELLED: The focus of this study was to coculture probiotic Bacillus spp. with dairy starter cultures namely, Streptococcus thermophilus and Lactobacillus bulgaricus for enhanced nutritional properties of soy-curd. Subsequently, rheological, sensory, and antioxidant properties of soy-curd along with mineral as well as fatty acid composition were analyzed. Data revealed an increase in the cell viability of probiotic Bacillus spp. on coculturing rather than as mono-culture. Proximate analysis showed higher nutritional value along with increased trace elements. UFA/SFA ratio, rheology, and sensory properties of probiotic soy-curd were in the acceptable range. Probiotic soy-curd showed higher antioxidant activity as measured by the ability to scavenge free radicals. No significant difference in the overall quality within the probiotic products was observed. However, B. flexus MCC2427 cocultured product displayed slightly better attributes than other samples. In general, the results suggest that soy-curd can be a suitable carrier for probiotic Bacillus spp. and the enhanced nutritional and antioxidant properties could be of additional advantage to combat malnutrition problem. PRACTICAL APPLICATION: In order to supply consumers with intriguing probiotic products for improving health benefits, several criteria including technological and functional properties should be considered as a quality control measures. Further, a meaningful level of probiotics has to be viable to exhibit beneficial effect. Hence, present work has been carried out to improve the quality of soy-curd by supplementation of probiotic Bacillus spp. These Bacillus spp. are well characterized native probiotic cultures with potential functional attributes including antimicrobial, antioxidant, anticholesterol activity (Shobharani and Halami 2014). Hence, the application of these cultures will encourage for development of food product with wider health benefits.

Antioxidant and anticoagulant activity of polyphenol and polysaccharides from fermented Sargassum sp.

The current investigation was carried out with an objective of determining the structural characteristic of polysaccharides extracted from fermented Sargassum sp. to be used as potent natural heparin substitute anticoagulant compound. Sargassum sp. fermented with marine lactic acid bacteria was initially subjected to ethanol precipitation for the recovery of bioactive compounds. Antioxidant activity was maximum in the soluble fraction whereas anticoagulant activity was observed to be high in the precipitate which correlated with the increased polyphenols and total sugars respectively. The precipitate was purified by anion exchange chromatography and the fractions collected were analyzed for total sugars and anticoagulant activity. There was 2.6-3.9-folds increase in anticoagulant activity in the final purified fractions, with a maximum activity in case of sample fermented with Enterococcus faecium (6.7±0.22 IU/mg). Structural elucidation of potential anticoagulant polysaccharide by Fourier Transform Infrared Spectroscopy (FT-IR) and Nuclear Magnetic Resonance (NMR) analysis indicated the presence of alginate rich in mannuronic acid.

A potent probiotic strain from cheddar cheese.

A lactic acid bacteria Leuconostoc paramesenteroides was isolated and characterized from cheddar cheese and was adapted to grow at low pH (2.0) and high bile salt concentration (2%) by sequential sub-culturing so that it can survive the extreme environmental condition of gut. Cell hydrophobicity assay shows the maximum adherence of the culture to toluene (46.11%). Adhesion ability was confirmed by in vitro assay using rat intestinal epithelial layer. The culture has an antimicrobial activity against food borne pathogens and is vancomycin sensitive. The culture shows a ß-galactosidase activity of 3.42 µM/mg protein, which indicates the ability of the culture to hydrolyze lactose for easy absorption. All these properties determine the ability of the culture to be used as a probiotic.