In Silico Analysis of Anti-Cancer Activity of Exopolysaccharide Isolated from Novel Pseudolagarobasidium acaciicola through Mass Production, Gel Permeation Separation, and Compositional Analysis.

Bacteria, fungi, and algae are examples of microorganisms that synthesize polysaccharides, which are macromolecules that belong to the carbohydrate class. Production of polysaccharides represents an alternative to chemical and plant-derived compounds that could be used for human well-being which requires implementation of different methods standardized during the extraction and purification process. In the current investigation, Pseudolagarobasidium acaciicola, a novel fungal source of exopolysaccharide (EPS) was used which produced 2773.23 ± 100.39 mg/L when cultured under pre-optimized composed medium for 7 days under submerged culture conditions. Biochemical estimation of crude polysaccharides revealed the presence of carbohydrates, protein, reducing sugar, least phenolics and no flavonoids. Partially purified EPS (ppEPS) was subjected to monosaccharide analysis, molecular weight determination and structural confirmation using FTIR and LCMS analysis. The presence of maltose, fructose, xylose, galactose, glucose, raffinose and sorbose was evident in the ppEPS using HPTLC at 285 nm, with molecular weight of dextran 70 (tentative). Characterization revealed the presence of functional groups including -OH, -COO, C-O-C and C-O with compounds like cellulose, phosphate and 3'-Sialyl-N-acetyllactosamine with glycan as the main structural form. Hence, our hypothesis is: the fungal strain may be used as a novel source of glycan and explore more possibilities for enhanced recovery of EPS important for further drug discovery and formulation programs. Based on existing research on the anti-cancerous characteristics of β-Glycans, an in silico study was carried out, which suggested that β-Glycans may operate more potent against its receptor CLEC7A than the oral chemotherapy drug imatinib.