Resumo
ß-Glucans (ßG) are polysaccharides widely distributed in nature with chemopreventive properties. The aim of this study was to investigate the effects of ßG and the combined treatment with doxorubicin (Dox) on cell viability and mRNA levels of genes involved in cell cycle, apoptosis and antioxidant response. ßG was not cytotoxic. The mRNA levels of CCNA2of cells exposed to ß-glucan was upregulated and the exposure to Dox decreased the expression, while the combination led to an upregulation. Modulation of mRNA levels of CASP9suggest that ßG could inhibit promotion and progression steps of carcinogenesis, eliminatingneoplastic cells. The upregulation of CCNA2gene in combined treatment could be occurred due to ability of ßG in restoring the cell cycle distribution pattern after treatment with Dox. The upregulation of SOD1suggests that ßG can enhance the intracellular antioxidant defense, reducing the levels of superoxide dismutase induced by Dox. This response could reduce oxidative damage and attenuate tissue damage during chemotherapeutic treatment. Our data suggest that the drug combination may be less effective in killing tumor cells than the treatment with Dox alone. Thus, future studies should carefully consider this effect on indication of ßG during chemotherapy.Keywords:caspase-9; cyclin A2; superoxide dismutase 1; cell cycle; antioxidant.Received on July 2, 2020.Accepted on February 7, 2022.IntroductionGlucans are polysaccharides widely distributed in nature and oftenstudied due to chemopreventive properties. They are constituent of the cell wall of plants (oats and barley), algae, bacteria and fungi. ß-glucans (ßG)have a common structure comprising a main chain of ß-(1,3) and/or ß-(1,4) D-glucopyranosyl unit and they differ in length and branching structures. ßG of Saccharomyces cerevisiaehave 1â6 side branches while those of bacteria have 1â4 side branches (Chan, Chan, & Sze, 2009). ßGcan prevent DNA damage induced by chemical and physical agents (Ghavami,Goliaei, Taghizadeh, & Nikoofar, 2014). Some authors showed its significant efficacy in preventing mutagenic effects caused by doxorubicin, cyclophosphamide and cisplatin (Tohamy, El-Ghor, El-Nahas, & Noshy, 2003), methyl methanesulfonate (Oliveira et al., 2007)and hydrogen peroxide (Slamenová, 2003). Moreover, some studies have related the antioxidant ability of ßGagainst reactive free radicals formed by endogenous metabolic processes or exogenous chemicals (Tsiapali et al., 2001; Slamenová,2003; Sener, Eksioglu-Demiralp, Cetiner, Ercan, & Yegen, 2006; Guerra Dore et al., 2007; Kofuji et al., 2012; Lei et al., 2015). Yeast-derived ßGhave modulating action of humoral and cellular immune responses (Vetvicka et al., 2007).This activity provides protection to the organism against infections and cancer development (Samuelsen, Schrezenmeir, & Knutsen, 2014; Roudbary, Daneshmand, Hajimorad, Roudbarmohammadip, & Hassan, 2015). Despite postulated modes of action by which ß-glucan works are lacking information about the molecular mechanisms involved in the chemopreventive activity of this polysaccharide. In addition, compounds with chemopreventive properties can contribute to reduce side effects and toxicity during the chemotherapeutic treatment. Therefore, the aim of this study was to investigate the effects of ßG and the combined treatment with doxorubicin (Dox) on the expression of genes related with apoptosis (CASP9), cell cycle control (CCNA2)and antioxidant defense (SOD1)in human breast cancer MCF-7 cells. Doxorubicin (Dox) was chosen because it is one of the most used chemotherapeutic agent for cancer treatment. The limitation on the use of Dox in cancer treatment is the lack of selectivity against cancer cells and, consequently, its toxicity to patients.(AU)