Characterization of a novel peptide mined from the Red Sea Brine Pools and modified to enhance its anticancer activity

Abstract

AbstractPeptide-based drugs have emerged as highly selective and potent cancer therapy. Cancer is one of the leading causes of death worldwide. Multiple approaches have been developed towards cancer treatment, including chemotherapy, radiation, and hormonal therapy; however, such procedures’ non-specificity, toxicity, and inefficiency present a hurdle. In this study, we developed a support vector machine (SVM) model to detect the potential anticancer properties of novel peptides through scanning the American University in Cairo Red Sea metagenomics library. Further, we performed in silico studies on a novel 37-mer antimicrobial peptide mined from SVM pipeline analysis. This peptide was further modified to enhance its anticancer activity, analyzed for gene oncology, and subsequently synthesized. The anticancer properties of this 37-mer peptide were evaluated via cellular viability and cell morphology of SNU449, HepG2, SKOV3, and HeLa cells, using MTT assay. Furthermore, we assessed the migration capability of SNU449 and SKOV3 via scratch wound healing assay. Moreover, the targeted selectivity of the peptide for cancerous cells was assessed by testing its hemolytic activity on human erythrocytes. The peptide caused a significant reduction in cellular viability and critically affected the morphology of hepatocellular carcinoma (SNU449 and HepG2), ovarian cancer (SKOV3), and to a limited extent, cervical cancer cell lines (HeLa), in addition to decreasing viability of human fibroblast cell line (1Br-hTERT). Peptide treatment significantly affected the proliferation and migration ability of SNU449 and SKOV3 cells. Annexin V assay was used to evaluate induced cell death upon peptide treatment, attributing programmed cell death (Apoptosis) as the main cause of cell death in SNU449 cells. Finally, we established broad-spectrum antimicrobial properties of the peptide on both gram-positive and gram-negative bacterial strains. Thus, these findings infer the novelty of the peptide as a potential anticancer and antimicrobial agent.