High-grade serous ovarian tumor cells modulate NK cell function to create an immune-tolerant microenvironment Graphical abstract Highlights d Decidual-like NK cells correlate with tumor cell abundance in tubo-ovarian HGSC d Combinatorial NK receptor ligand expression levels differ across tumor compartments d NK cells acquire CD9 from HGSC tumor cells via trogocytosis d CD9 suppresses anti-tumor cytokine production and cytotoxicity in NK-92 cells
Herein, we describe
the synthesis and application of cross-linked
polystyrene-based dual-function nano- and microparticles containing
both fluorescent tags and metals. Despite containing a single dye,
these particles exhibit a characteristic dual-band fluorescence emission.
Moreover, these particles can be combined with different metal ions
to obtain hybrid metallofluorescent particles. We demonstrate that
these particles are easily nanofected into living cells, allowing
them to be used for effective fingerprinting in multimodal fluorescence-based
and mass spectrometry-based flow cytometry experiments. Likewise,
the in situ reductions of the metal ions enable other potential uses
of the particles as heterogeneous catalysts.
Chemical proteomics approaches are widely used to identify molecular targets of existing or novel drugs. This manuscript describes the development of a straightforward approach to conjugate azide-labeled drugs via click chemistry to alkyne-tagged cell-penetrating fluorescent nanoparticles as a novel tool to study target engagement and/or identification inside living cells. A modification of the Baeyer test for alkynes allows monitoring the Cu(I)-catalyzed azide-alkyne cycloaddition (CuAAC) reaction, guaranteeing the presence of the drug on the solid support. As a proof of concept, the conjugation of the promiscuous kinase inhibitor dasatinib to Cy5-labeled nanoparticles is presented. Dasatinib-decorated fluorescent nanoparticles efficiently inhibited its protein target SRC in vitro, entered cancer cells, and colocalized with SRC in cellulo.
Mass cytometry is a highly multiparametric proteomic technology that allows the measurement and quantification of nearly 50 markers with single-cell resolution. Mass cytometry reagents are probes tagged with metal isotopes of defined mass and act as reporters. Metals are detected using inductively coupled plasma time-offlight mass spectrometry (ICP-TOF-MS). Many different types of mass-tag reagents have been developed to afford myriad applications. We have classified these compounds into polymer-based mass-tag reagents, nonpolymer-based mass-tag reagents, and inorganic nanoparticles. Metal-chelating polymers (MCPs) are widely used to profile and quantify cellular biomarkers; however, both the range of metals that can be detected and the metal signals have to be improved. Several strategies such as the inclusion of chelating agents or highly branched polymers may overcome these issues. Biocompatible materials such as polystyrene and inorganic nanoparticles are also of profound interest in mass cytometry. While polystyrene allows the inclusion of a wide variety of metals, the high metal content of inorganic nanoparticles offers an excellent opportunity to increase the signal from the metals to detect lowabundance biomarkers. Nonpolymer-based mass-tag reagents offer multiple applications: cell detection, cell cycle property determination, biomarker detection, and mass-tag cellular barcoding (MCB). Recent developments have been achieved in live cell barcoding by targeting proteins (CD45, b2m, and CD298), by using small and nonpolar probes or by ratiometric barcoding. From this perspective, the principal applications, strengths, and shortcomings of mass-tag reagents are highlighted, summarized, and discussed, with special emphasis on mass-tag reagents for MCB. Thereafter, the future perspectives of mass-tag reagents are discussed considering the current state-of-the-art technologies.
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