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Anti-Cancer Agents in Medicinal Chemistry

Editor-in-Chief

ISSN (Print): 1871-5206
ISSN (Online): 1875-5992

Research Article

Zidovudine Glycosylation by Filamentous Fungi Leads to a Better Redox Stability and Improved Cytotoxicity in B16F10 Murine Melanoma Cells

Author(s): Evilanna L. Arruda*, Kamila B. Japiassu, Paula L. de Melo Souza, Kelly C.F. Araújo, Douglas V. Thomaz, Alane P. Cortez, Luane F. Garcia, Marize C. Valadares, Eric de Souza Gil and Valéria de Oliveira

Volume 20, Issue 14, 2020

Page: [1688 - 1694] Pages: 7

DOI: 10.2174/1871520620666200424112504

Price: $65

Abstract

Background: The strategic development of therapeutic agents, capable of being targeted at their active sites, has been a major goal in treatment of cancer. The delivery of drugs for tumors has as its main challenge the development of safe and effective drugs, since the goal of chemotherapy is to eliminate the tumor completely without affecting healthy cells. The aim of present study was to investigate the antioxidant, anticancer activities of zidovudine and its α-O-glycosylated derivative obtained by biosynthesis of a filamentous fungi, Cunninghamela echinulata.

Methods: An evaluation of the cytotoxic potential of zidovudine and its α-O-glycosylated was performed in fibroblasts and melanoma cells by the tetrazolium reduction method (MTT) and the antioxidant activity of this derivative was observed.

Results: The antioxidant activity of zidovudine demonstrated an electrochemical oxidation potential of 0.91V, while the α-O-glycosylated derivative did not exhibit any antioxidant activity. The zidovudine exhibited low cytotoxicity for melanoma and fibroblast cells, while the α-O-glycosylated derivative presented better cytotoxicity on melanoma cells at a concentration of 10mg. mL-1.

Conclusion: This study demonstrates the specific cytotoxicity of the glycoconjugate and suggests that glycosylation by biosynthesis can be a useful strategy for obtaining new anticancer compounds.

Keywords: Glycoconjugate, zidovudine, antioxidant, anticancer, biotransformation, Cunninghamella echinulata.

Graphical Abstract
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