Effects of ultraviolet-C on the spores of Bacillus subtilis and Bacillus velezensis suspension in phosphate buffered saline with their structural and molecular analysis using Raman-AFM imaging

Abstract

Bacterial spores are of concern in food processing due to their ubiquity and resistance. This study seeks to determine the effect of ultraviolet C (UV-C) in the inactivation of spores of Bacillus subtilis and Bacillus velezensis that can result in enzymatic spoilage in foods using PBS as the suspension medium. Purified spore samples were treated under 1 pass in a UV-C reactor using 10 mL of spore inoculum with one dose of the radiation (410 mJ/cm2) for 10secs at room temperature. Aliquots of the treated samples were plated on tryptone soy agar supplemented with 0.6% glucose and the colonies counted. Flow cytometry analysis was done using 500 μL of both treated and control samples with a cell concentration of a ≥106 CFU/ml with propidium iodide (15 μM) and SYTO 9 (500 nM) used as live/dead stains. Samples were processed for microscopy (SEM and Raman-AFM Imaging). The maximum lethality is 2.5 for B. velezensis and the minimum is 0.1 for B. subtilis. Microscopic imaging of treated spores shows significant morphological disruption of the spore structure. The Raman spectroscopy analysis reveals the B. subtilis isolates to have the highest concentrations of dipicolnic acid (Ca+2DPA) as well as other compounds belonging to other functional groups. Flow cytometric analysis of treated spores reveals sub-populations unaccounted for by plate count. UV-C shows a promising application in the inactivation of resistant spores during processing of liquid foods such as milk.