Bacterial infections are major constraints in aquaculture farming. These pathogens often adapt to the biofilm mode of growth and resist antibiotic treatments. We have used a non-toxic glycolipid biosurfactant (BS-SLSZ2) derived from a marine epizootic bacterium Staphylococcus lentus to treat aquaculture associated infections in an eco-friendly manner. We found that BS-SLSZ2 contained threose, a four-carbon sugar as the glycone component, and hexadecanoic and octadecanoic acids as the aglycone components. The critical micelle concentration of the purified glycolipid was 18 mg mL-1. This biosurfactant displayed anti-adhesive activity and inhibited biofilm formation by preventing initial attachment of cells onto surfaces. The biosurfactant (at a concentration of 20 μg) was able to inhibit Vibrio harveyi and Pseudomonas aeruginosa biofilms by 80.33 ± 2.16 and 82 ± 2.03%, respectively. At this concentration, it was also able to disrupt mature biofilms of V. harveyi (78.7 ± 1.93%) and P. aeruginosa (81.7 ± 0.59%). The biosurfactant was non-toxic towards Artemia salina. In vivo challenge experiments showed that the glycolipid was effective in protecting A. salina nauplii against V. harveyi and P. aeruginosa infections. This study highlights the significance of marine natural products in providing alternative biofilm controlling agents and decreasing the usage of antibiotics in aquaculture settings.
Microbial biofilms are important in aquaculture industries as they resist antibiotic treatments. In this study, we have investigated the antibiofilm potential of a tropical marine culture Bacillus licheniformis D1 (containing an antimicrobial protein BLDZ1) against two aquaculture associated pathogens namely, Vibrio harveyi and Pseudomonas aeruginosa. Both the test cultures formed biofilms on polystyrene and glass surfaces. The cell free supernatant (CFS) of B. licheniformis inhibited V. harveyi and P. aeruginosa biofilms on polystyrene surfaces up to around 80% and 78% respectively. In addition, the CFS disrupted pre‐formed biofilms of test cultures by about 73%. Fluorescence and scanning electron microscope analysis confirmed the antibiofilm potential of the CFS. The cell free supernatant displayed antiadhesive activity that inhibited the initial attachment of the bacteria during the process of biofilm formation. In addition, the CFS exhibited antimicrobial activity and mediated cell death via cytoplasmic membrane disruption.
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