Green Synthesis of a Novel Phytoalexin Derivative: In Silico Profiling, Apoptotic Induction, and Antiproliferative Activity against MCF-7 cells - From Vineyards to Potent Anticancer Drug Molecule.

Abstract

Resveratrol's structural similarity to commercialized anti-breast cancer medications such as Tamoxifen underlines its potential as a promising option for developing successful anti-breast cancer drugs. However, the pharmacokinetic issues associated with resveratrol, such as its low bioavailability, have piqued the attention of researchers in developing novel derivatives. A novel phytoalexin derivative, RsvD1, was successfully synthesized using resveratrol extracted from green grape peels as a precursor to investigate its anti-breast cancer efficacy on Estrogen receptor (ER) positive and negative breast cancer cells. The comparative analysis revealed that RsvD1 exhibited remarkable radical scavenging ability (IC50 = 2.21 μg/mL), surpassing the control, Trolox (IC50 = 6.3 μg/mL). Furthermore, RsvD1 demonstrated enhanced and selective antiproliferative activity against ER-positive MCF-7 cells (IC50 = 20.09 μg/mL) compared to resveratrol, the parent molecule (IC50 = 30.90 μg/mL). Further investigations unveiled that RsvD1 induced apoptosis and DNA damage in MCF-7 cells, leading to cell cycle arrest at the G0/G1 phase after 24 hours of incubation. RTqPCR gene expression analysis indicated that RsvD1 down-regulated the CAXII (ER-dependent) genes. In silico predictions demonstrated that RsvD1 possesses promising potential as a drug candidate due to its drug-like characteristics and favourable ADMET profile. Moreover, molecular docking studies provided insights into the theoretical binding mode between RsvD1 and ERα protein. The study highlights the therapeutic potential of the synthesized resveratrol derivative, RsvD1, positioning it as a promising scaffold for developing novel analogues with improved therapeutic properties and selectivity, specifically targeting ER+ breast cancer cells. Moreover, the compound's non-cytotoxic yet antiproliferative properties, coupled with its capability to induce programmed cell death and cell cycle arrest, enhance its potential as a highly effective drug candidate. As a result, this paves a promising path for the development of innovative and selective inhibitors targeting ER+ breast cancer with enhanced efficacy.