Macrophages are vital components of the inflammatory response and exhibit phenotypical plasticity through active conversion between pro- and anti-inflammatory cell subtypes, a feature which can be reproduced in ex vivo culture. We employed a multifaceted approach utilizing proteomics, flow cytometry, activity assays and live-cell microscopy imaging to characterize four cultured macrophage subtypes: unstimulated M, classically activated M1, alternatively activated M2a, and deactivated M2c macrophages. Whole cell proteomics identified a total of 5435 proteins, with >50% of these proteins exhibiting significant alterations in abundance between the different subtypes. This confirms that four distinct macrophage subtypes are induced from the same originating donor material through stimulation with specific cytokines. Additional surfaceome analysis revealed that M2c macrophages significantly upregulate pro-inflammatory markers compared to the M baseline and thus appear to be activated or primed to activate, similar to M1. Surface protein expression provided further subtype characterization, in particular distinguishing between the M2a and M2c macrophages. We next explored the re-polarization capabilities of macrophages using dexamethasone, an anti-inflammatory glucocorticoid known to induce macrophage polarization towards the M2c de-activated phenotype. We show that activated M1 macrophages treated with dexamethasone for 48-hours upregulate the levels of CD163 and CD206, markers synonymous with a phenotypical shift from M1 to M2c yet retain key surface markers and display the functional phenotype of M1 macrophages. The observed repolarization of M1 pro-inflammatory macrophages provides a potential mechanism through which dexamethasone treatment improves COVID-19 prognosis and constitutes evidence of partial repolarization along the macrophage continuum. These proteomic and functional ex vivo macrophage datasets provide a valuable resource for studying macrophage polarity and the impact of dexamethasone on macrophage phenotype and function.
Several immune cell‐expressed miRNAs (miRs) are associated with altered prognostic outcome in cancer patients, suggesting that they may be potential targets for development of cancer therapies. Here, translucent zebrafish (Danio rerio) is utilized to demonstrate that genetic knockout or knockdown of one such miR, microRNA‐223 (miR223), globally or specifically in leukocytes, does indeed lead to reduced cancer progression. As a first step toward potential translation to a clinical therapy, a novel strategy is described for reprogramming neutrophils and macrophages utilizing miniature artificial protocells (PCs) to deliver anti‐miRs against the anti‐inflammatory miR223. Using genetic and live imaging approaches, it is shown that phagocytic uptake of anti‐miR223‐loaded PCs by leukocytes in zebrafish (and by human macrophages in vitro) effectively prolongs their pro‐inflammatory state by blocking the suppression of pro‐inflammatory cytokines, which, in turn, drives altered immune cell‐cancer cell interactions and ultimately leads to a reduced cancer burden by driving reduced proliferation and increased cell death of tumor cells. This PC cargo delivery strategy for reprogramming leukocytes toward beneficial phenotypes has implications also for treating other systemic or local immune‐mediated pathologies.
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