The purification of the antimicrobial compound was carried by using silica gel column (2.5 × 25) chromatography. Silica gel of 100–200 μm Rapamycin particle size was used for packing the column. Chloroform and methanol (7:3, v/v) were used as an
eluting solvent. 5 g of crude extract to be fractioned was dissolved in 50 ml of methanol and passed through the silica gel column keeping the flow rate at 0.2 ml/min; thirty fractions were collected (5 ml each) and tested for their antimicrobial activities. The purity of the active fraction was determined by Waters Reverse Phase HPLC, Spherisorb 5 μm ODS 2 (C18) column with solvent system methanol and water 70:30 (v/v) at 2500 psi in isocratic mode. The operating flow rate was 1.0 ml/min. The solubility pattern of the compound was determined in various polar and non-polar solvents. The melting point of the compound was determined by Fisher–Johns melting point apparatus. The UV absorption spectrum of the compound was determined by Shimadzu AUY-922 clinical trial UV 1800 spectrophotometer. The Infra-red (IR) spectrum of the purified antimicrobial compound was recorded using Bruker Alpha FT-IR spectroscopy. The resulting data
generated was viewed with the help of OPUS v6.5 software. NMR spectrum of the compound was determined by using an AMX-400 spectrometer (Bruker, Germany) 1H data was obtained at 399.7 MHz and 13C was at 100.5 MHz using chloroform-d as solvent and trimethylsilane as internal reference. The minimum inhibitory concentration has been determined by broth dilution method.12
The media used were nutrient broth for bacteria and Czapek Dox broth for fungi. The optimization of the metabolite production was carried out in batch cultures. The isolate BTSS-301 was cultivated in basal medium supplemented with different carbon sources, and their effect on growth and antimicrobial activity was studied (Table 1). The isolate grow in all the test carbon sources. Maximum metabolite production was obtained with glucose (160 μg/ml) followed by glycerol (120 μg/ml) and starch (112 μg/ml) and the biomass obtained was also highest with glucose (3 mg/ml) than that of glycerol and starch. The effect of different concentrations Metalloexopeptidase of glucose (Fig. 1) on growth and production showed that the antibiotic titer was highest with 10 g/l glucose concentration with biomass of 3.6 mg/ml. Among the various inorganic nitrogen sources, the maximum metabolite production was achieved with NH4NO3 (192 μg/ml) with biomass of 3.8 mg/ml. Among the organic nitrogen sources, the high level of metabolite yield was obtained with soyabean meal (Table 2). Further, the concentration of 2.5 g/l of NH4NO3 (Fig. 1) greatly influenced the antimicrobial compound production with maximum yield and biomass accretion of 3.3 mg/ml. Moreover the yield was reduced with increase and decrease of NH4NO3 concentration.