An Insight on Synergistic Anti-cancer Efficacy of Biochanin A and Sulforaphane Combination Against Breast Cancer.

Breast cancer is a serious malignancy that has higher rate of morbidity and mortality. It has been known to affect the women indifferently. The lack and side effects in the current therapeutic modules result in the search of the wide treatment options including combinatorial treatment. The goal of this study was to investigate combinatorial anti-proliferative efficacy of biochanin A (BCA) and sulforaphane (SFN) against MCF-7 breast cancer cells. The study involves the utilisation of various qualitative techniques including cytotoxicity analysis (MTT), morphogenic analysis, AO/EtBr, DAPI, ROS, cell cycle, and cell migration analysis in order to examine the combinatorial efficacy of BCA and SFN in inducing the cell death. The results had shown that the cytotoxicity of BCA and SFN was found to be around 24.5 µM and 27.2 µM respectively, while the combination of BCA and SFN had shown an inhibitory activity at about 20.1 µM. And furthermore, AO/EtBr and DAPI had shown a profound increase in apoptogenic activity of compounds when treated in combination at lower dose. This apoptogenic activity may be attributed to the increased ROS production. Moreover, it has been shown that the BCA and SFN have been involved in the down-regulation of ERK-1/2 signalling pathway resulting in induction of apoptosis of cancer cells. Thus, our results had concluded that BCA and SFN co-treatment could be used as an efficient therapeutic target against breast cancer. Furthermore, in vivo efficiency by which the co-treatment induces apoptosis has to be deliberated further in near future to make their use commercially.

Allosteric Nucleic Acid Enzyme: A Versatile Stimuli-Responsive Tool for Molecular Computing and Biosensing Nanodevices.

Allostery is a naturally occurring mechanism in which effector binding induces the modulation and fine control of a related biomolecule function. Deoxyribozyme (DNAzyme) with catalytic activity and substrate recognition ability is ideal to be regulated by allosteric strategies. However, the current regulations frequently confront various obstacles, such as severe activity decay, signal leakage, and limited effectors. In this work, a rational regulation strategy for developing versatile effectors-responsive allosteric nucleic acid enzyme (ANAzyme) by introducing an allosteric domain in response to diverse effectors is established. The enzyme-like activity of this re-engineered ANAzyme can be modulated in a more predictable and fine way compared with the previous DNAzyme regulation strategies. Based on the allosteric strategy, the construction of allosterically coregulatory nanodevices and a series of basic logic gates and logic circuits are achieved, demonstrating that the proposed ANAzyme-regulated strategy showed great potential in molecular computing. Given these facts, the rational design of ANAzyme with the allosteric domain presented here can expand the available toolbox to develop a variety of stimuli-responsive allosteric DNA materials, including molecular machines, computing systems, biosensing platforms, and gene-silencing tools.