Anti-inflammatory Activity of PLA2 Inhibitory Saccharumoside-B.

BACKGROUND: Saccharumoside-B and its analogs were found to have anticancer potential in vitro. The present study reports acute toxicity, molecular docking, ADMET profile analysis, and in vitro and in vivo anti-inflammatory activity of saccharumoside-B for the first time. METHODS: The in vitro enzyme inhibitory activity of saccharumoside-B on PLA2, COX-1, COX-2, and 5-LOX enzymes was evaluated by the cell-free method, and its effect on TNF-α, IL1ß, and IL- 6 secretion levels in LPS stimulated THP-1 human monocytes was determined by ELISA-based methods. The anti-inflammatory activity was evaluated in vivo by carrageenan-induced rat paw edema model. To test its binding affinity at the active site pockets of PLA2 enzymes and assess drug-like properties, docking experiments and ADMET studies were performed. RESULTS: Saccharumoside-B showed selective inhibition of the sPLA2 enzyme (IC50 = 7.53 ± 0.232 µM), and thioetheramide-PC was used as a positive control. It showed significant inhibition (P ≤ 0.05) of TNF-α, IL-1ß, and IL-6 cytokines compared to the positive control dexamethasone. Saccharumoside-B showed a dose-dependent inhibition of carrageenan-induced rat paw edema, with a maximum inhibition (76.09 ± 0.75) observed at 3 hours after the phlogistic agent injection. Saccharumoside-B potentially binds to the active site pocket of sPLA2 crystal protein (binding energy -7.6 Kcal/Mol). It complies with Lipinski's Rule of Five, showing a promising safety profile. The bioactivity scores suggested it to be a better enzyme inhibitor. CONCLUSION: Saccharumoside-B showed significant PLA2 inhibition. It can become a potential lead molecule in synthesizing a new class of selective PLA2 inhibitors with a high safety profile in the future.

The Role of Tumor Associated Macrophages (TAMs) in Cancer Progression, Chemoresistance, Angiogenesis and Metastasis - Current Status.

Tumor associated macrophages (TAMs), located in the tumor microenvironment (TME), play a significant role in cancer cell survival and progression. TAMs have been involved in producing immuno-suppressive TME in the tumor by generating inflammatory mediators, growth factors, cytokines, chemokines, etc. TAMs can influence the angiogenesis, metastatic behavior of tumor cells (TCs) and cause multidrug resistance. TAMs within the TME can enhance cancer cell metastasis and are stromal and perivascular. The angiogenesis is promoted at the hypoxia, and the avascular zones of TME. Differentiation states of TAMs are considered 'plastic' as they exhibit temporal expression of one or several phenotypes depending on local cues. Emerging cancer research depicted the epigenetic regulation of macrophage polarization (both M1s, M2s) and their potential implications to develop pharmacologic modulators and microRNAs to act as molecular switches and even to serve as targeted therapies to inhibit tumor growth. In the present article, the role of TAMs in tumor progression, angiogenesis and metastasis was discussed. In addition, key signaling cascades regulated by TAMs, which have a role in chemoresistance, were also discussed. Currently, novel pleiotropic properties of various anticancer phytomedicines are gaining importance as they assist in overcoming TAMs-induced chemoresistance. Moreover, these phytomedicines are being tested as 'adjunct therapeutics' along with chemotherapeutic agents, anti-angiogenic molecules, anti-metastatic compounds, and other immune-checkpoint blockers against tumor metastasis/angiogenesis. Hence, a brief note on natural products targeting TAMs was provided. In summary, this review would benefit pharmacologists and medical professionals to develop therapies to target TAMs using multi-OMICs approaches, including genomics, epigenomics, transcriptomics, and proteomics.