Metformin, a biguanide, is a commonly administered drug for the management of type 2 diabetes mellitus. The drug received tremendous recognition, when retrospective studies proved metformin-associated reduction in cancer risk. Metformin has potential anticancer effects and an ability to suppress tumor growth both in vitro and in vivo. Activation of LKB1/AMPK pathway and cancer stem cell destruction along with cell cycle arrest and apoptosis induction are the proposed mechanisms of anticancer potential of metformin. Nanotechnology approaches have also been adopted for metformin delivery to cancer cells. This review directs on the application of metformin for the therapy of various cancers and also the different pathways responsible for the metformin derived anticancer effect. It also focuses on the pharmacological applications of metformin and the nanotechnology approaches for metformin delivery.
Cancer kinome is now well organized as an important target for a new class of cancer drugs. There are more than 500 members in the kinase family in which some of them are clinically analysed, while the rest are under investigation for potential therapeutic applications. Phosphorylation, major function of kinases is one of the most significant signal transduction mechanism in which intercellular signals regulate intracellular processes like ion transport, hormone responses and cellular proliferation. Any deregulation of kinase function may lead to tumor progression and other disorders such as immunological, neurological , metabolic including also infectious diseases. This led to the necessity in the development of kinase inhibitors as therapeutic agent. Herein we discuss about different types of kinases and their inhibitors in various types of cancers. This review portrays a broad overview of the origin of kinases, discovery, the characterization and mode of action of kinase inhibitors in cancer therapy.
Co-therapy with herbal extracts along with current clinical drugs is being increasingly recognized as a useful complementary treatment for cancer. The anti-cancer property of the phyto-derivative acetyl-11 keto β boswellic acid (AKBA) has been studied in many cancers, including prostate cancer. However, the whole extract of the gum resin Boswellia serrata (BS) and anti-androgen enzalutamide has not been explored in prostate cancer to date. We hypothesized that the BS extract containing 30% (AKBA) with enzalutamide acted synergistically in the early phase of cancer, especially in LNCaP cells, by inhibiting androgen receptor (AR) and by reducing cell proliferation, and further, that the extract would be superior to the action of the active ingredient AKBA when used alone or in combination with enzalutamide. To test our hypothesis, we treated LNCaP cells with BS extract or AKBA and enzalutamide both individually and in combination to analyze cell viability under different levels of dihydrotestosterone (DHT). The inhibition of androgen receptor (AR) followed by the expression of prostate-specific antigen (PSA) and the efflux mechanism of the cells were analyzed to determine the effect of the combination on the cellular mechanism. Cells derived from prostate cancer patients were also tested with the combination. Only 6 µM enzalutamide along with BS in the range of 4.1 µg/ml to 16.4 µg/ml gave the best synergistic results with nearly 50% cell killing even though standard enzalutamide doses were as high as 48 µM. Cell killing was most effective at intermediate DHT concentrations of approximately 1 nM, which corresponds to normal physiological serum levels of DHT. The Pgp expression level and the androgen receptor expression levels were reduced under the combination treatment; the former helping to minimize drug efflux and the latter by reducing the sensitivity to hormonal changes. Furthermore, the combination reduced the PSA level secreted by the cells. In contrast, AKBA could not achieve the needed synergism for adequate cell killing at equivalent concentrations. The combination of enzalutamide and BS extract containing 30% AKBA because of their synergistic interaction is an attractive therapeutic option for treating early stage (hormone-dependent) prostate cancer and is superior to the use of AKBA alone.
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