Breast cancer is a common form of cancer that affects both men and women. One of the most common types of genomic flaws in cancer is the aberrations in the PI3K/AKT/mTOR pathway. The benefit of dual targeting PI3K as well as mTOR is that the kinase-positive feedback loops are more effectively inhibited. Therefore, in the current study, structure-based models like molecular docking, MM-GBSA, Qikprop, induced fit docking, simulated molecular dynamics (MD), and thermal MM-GBSA were used to identify the phytochemicals from the zinc 15 database, which may inhibit PI3K and mTOR. After docking the phytochemicals with PI3K (PDB 4FA6), ten ligands based on the docking score were selected, among which salvianolic acid C had the highest docking score. Hence, salvianolic acid A was also docked. All the ligands taken showed a binding energy of greater than − 30 kcal/mol. The predicted ADME showed that the ligands have druggable properties. By performing MD of the top five ligands and salvianolic acid A, it was found that ZINC000059728582, ZINC000257545754, ZINC000253532301, and salvianolic acid A form a stable complex with PI3K protein, among which ZINC000014690026 showed interaction with Val 882 for more than 89% of the time. Salvianolic acid A is already proven to suppress tumor growth in acute myeloid leukemia by inhibiting PI3K/AKT pathway, but the exact protein target is unknown. Therefore, the present study identifies new molecules and provides evidence for salvianolic acid A for dual inhibition. Further experiments must be performed both in vitro and in vivo to support the predictions of these computational tools.
Graphical abstract
Coronavirus disease (COVID-19), caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) emerged in late 2019 with severe respiratory failure and organ damage that later appeared as a pandemic disease. Worldwide, people’s mental and physical health and socioeconomic have been affected. Currently, with no promising treatment for COVID-19, the existing anti-viral drugs and vaccines are the only hope to boost the host immune system to reduce morbidity and mortality rate. Unfortunately, several reports show that people who are partially or fully vaccinated are still susceptible to COVID-19 infection. Evidence suggests that COVID-19 immunopathology may include dysregulation of macrophages and monocytes, reduced type 1 interferons (IFN-1), and enhanced cytokine storm that results in hypersecretion of proinflammatory cytokines, capillary leak syndrome, intravascular coagulation, and acute respiratory distress syndrome (ARDS) ultimately leading to the worsening of patient’s condition and death in most cases. The recent use of cell-based therapies such as mesenchymal stem cells (MSCs) for critically ill COVID-19 patients has been authorized by the Food and Drug Administration (FDA) to alleviate cytokine release syndrome. It protects the alveolar epithelial cells by promoting immunomodulatory action and secreting therapeutic exosomes to improve lung function and attenuate respiratory failure. As a result, multiple clinical trials have been registered using MSCs that aim to use various cell sources, and dosages to promote safety and efficacy against COVID-19 infection. In this review, the possibility of using MSCs in COVID-19 treatment and its associated challenges in their use have been briefly discussed.
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