Exploring the repurposing potential of telmisartan drug in breast cancer: an in-silico and in-vitro approach.

Anticancer drug resistance is one of the biggest hurdles in the treatment of breast cancer. Drug repurposing is a viable option fordeveloping novel medical treatment strategies since this method is more cost-efficient and rapid. Antihypertensive medicines have recently been found to have pharmacological features that could be used to treat cancer, making them effective candidates for therapeutic repurposing. The goal of our research is to find a potent antihypertensive drug that can be repurposed as adjuvant therapy for breast cancer. In this study, virtual screening was performed using a set of Food and Drug Administration (FDA)-approved antihypertensive drugs as ligands with selected receptor proteins (EGFR, KRAS, P53, AGTR1, AGTR2, and ACE) assuming these proteins are regarded to have a significant role in hypertension as well as breast cancer. Further, our in-silico results were further confirmed by an in-vitro experiment (cytotoxicity assay). All the compounds (enalapril, atenolol, acebutolol, propranolol, amlodipine, verapamil, doxazosin, prazosin, hydralazine, irbesartan, telmisartan, candesartan, and aliskiren) showed remarkable affinity towards the target receptor proteins. However, maximum affinity was displayed by telmisartan. Cell-based cytotoxicity study of telmisartan in MCF7 (breast cancer cell line) confirmed the anticancer effect of telmisartan. IC50 of the drug was calculated to be 7.75 µM and at this concentration, remarkable morphological alterations were observed in the MCF7 cells confirming its cytotoxicity in breast cancer cells. Based on both in-silico and in-vitro studies, we can conclude that telmisartan appears to be a promising drug repurposing candidate for the therapeutic treatment of breast cancer.

Improved pregnancy outcomes in women exposed to malaria with high antibody levels against Plasmodium falciparum.

BACKGROUND: Antibodies against VAR2CSA, the Plasmodium falciparum variant surface antigen that binds placental chondroitin sulfate A, have been suggested to mediate protection against malaria in pregnancy but also to be markers of infection. Here, we aimed to identify clinically relevant antibody responses, taking into consideration variations in parasite exposure and human immunodeficiency virus type 1 (HIV) infection status. METHODS: Levels of immunoglobulin G (IgG) against placental and pediatric isolates, VAR2CSA (DBL2X, DBL3X, DBL5ε, and DBL6ε domains), and other blood-stage antigens (DBLγ, DBLα, MSP119, AMA1, and EBA175) were measured in plasma specimens from 293 pregnant Mozambican women at delivery. Associations between antibody responses, factors influencing malaria exposure, HIV infection status, and pregnancy outcomes were assessed. RESULTS: Maternal antibodies were affected by placental infection, parity, season, and neighborhood of residence. HIV infection modified these associations and attenuated the parity-dependent increase in IgG level. High levels of antibody against AMA1, DBL3X, DBL6ε, placental isolates, and pediatric isolates were associated with increased weight and gestational age of newborns (P ≤ .036) among women with malaria episodes during pregnancy. CONCLUSIONS: Antiparasite IgGs in women at delivery are affected by HIV infection, as well as by variations in the exposure to P. falciparum. Heterogeneity of malaria transmission needs to be considered to identify IgGs against VAR2CSA and other parasite antigens associated with improved pregnancy outcomes.

Drug repurposing-an emerging strategy in cancer therapeutics.

Cancer is a complex disease affecting millions of people around the world. Despite advances in surgical and radiation therapy, chemotherapy continues to be an important therapeutic option for the treatment of cancer. The current treatment is expensive and has several side effects. Also, over time, cancer cells develop resistance to chemotherapy, due to which there is a demand for new drugs. Drug repurposing is a novel approach that focuses on finding new applications for the old clinically approved drugs. Current advances in the high-dimensional multiomics landscape, especially proteomics, genomics, and computational omics-data analysis, have facilitated drug repurposing. The drug repurposing approach provides cheaper, effective, and safe drugs with fewer side effects and fastens the process of drug development. The review further delineates each repurposed drug's original indication and mechanism of action in cancer. Along with this, the article also provides insight upon artificial intelligence and its application in drug repurposing. Clinical trials are vital for determining medication safety and effectiveness, and hence the clinical studies for each repurposed medicine in cancer, including their stages, status, and National Clinical Trial (NCT) identification, are reported in this review article. Various emerging evidences imply that repurposing drugs is critical for the faster and more affordable discovery of anti-cancerous drugs, and the advent of artificial intelligence-based computational tools can accelerate the translational cancer-targeting pipeline.