Cancer therapy through anticancer drugs and radiotherapy is associated with several side effects as well as tumor resistance to therapy. The genotoxic effects of chemotherapy and radiotherapy may lead to genomic instability and increased risk of second cancers. Furthermore, some responses in the tumor may induce the exhaustion of antitumor immunity and increase the resistance of cancer cells to therapy. Administration of low-toxicity adjuvants to protect normal tissues and improve therapy efficacy is an intriguing strategy. Several studies have focused on natural-derived agents for improving the antitumor efficiency of radiotherapy, chemotherapy, and novel anticancer drugs such as immunotherapy and targeted cancer therapy. Resveratrol is a naturally occurring substance with intriguing antioxidant, cardioprotective, anti-diabetes, and antitumor properties. Resveratrol has been demonstrated to modulate tumor resistance and mitigate normal tissue toxicity following exposure to various drugs and ionizing radiation. Compelling data suggest that resveratrol may be an appealing adjuvant in combination with various anticancer modalities. Although the natural form of resveratrol has some limitations, such as low absorption in the intestine and low bioavailability, several experiments have demonstrated that using certain carriers, such as nanoparticles, can increase the therapeutic efficacy of resveratrol in preclinical studies. This review highlights various effects of resveratrol that may be useful for cancer therapy. Consequently, we describe how resveratrol can protect normal tissue from genomic instability. In addition, the various mechanisms by which resveratrol exerts its antitumor effects are addressed. Moreover, the outcomes of combination therapy with resveratrol and other anticancer agents are reviewed.
Induction of cell death and inhibition of cell proliferation in cancer have been set as some of the main goals in anti-tumor therapy. Cancer cell resistance leads to less efficient cancer therapy, and consequently, to higher doses of anticancer drugs, which may eventually increase the risk of serious side effects in normal tissues. Apigenin, a nature-derived and herbal agent, which has shown anticancer properties in several types of cancer, can induce cell death directly and/or amplify the induction of cell death through other anti-tumor modalities. Although the main mechanism of apigenin in order to induce cell death is apoptosis, other cell death pathways, such as autophagic cell death, senescence, anoikis, necroptosis, and ferroptosis, have been reported to be induced by apigenin. It seems that apigenin enhances apoptosis by inducing anticancer immunity and tumor suppressor genes, like p53 and PTEN, and also by inhibiting STAT3 and NF-κB signaling pathways. Furthermore, it may induce autophagic cell death and ferroptosis by inducing endogenous ROS generation. Stimulation of ROS production and tumor suppressor genes, as well as downregulation of drug-resistance mediators, may induce other mechanisms of cell death, such as senescence, anoikis, and necroptosis. It seems that the induction of each type of cell death is highly dependent on the type of cancer. These modulatory actions of apigenin have been shown to enhance anticancer effects by other agents, such as ionizing radiation and chemotherapy drugs. This review explains how cancer cell death may be induced by apigenin at the cellular and molecular levels.
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