Calcium ionophore-activated platelets induce eosinophil extracellular trap formation.

BACKGROUND: Platelets play a modulatory role in inflammatory response by secreting a vast array of granules and disintegrating into membrane-bound microparticles upon activation. The interplay between eosinophils and platelets is postulated to be implicated in the pathology of allergic airway inflammation. In this study, we investigated whether activated platelets can induce eosinophil extracellular trap (EET) formation, a cellular process by which activated eosinophils release net-like DNA fibers. METHODS: Platelets were stimulated with the calcium ionophore, A23187, and the platelet agonists, thrombin and adenosine diphosphate (ADP). Platelet cultures were fractionated into conditioned medium (CM) and pellet, which were then overlaid on eosinophils to examine EET formation. RESULTS: The CM and pellet from A23187-activated platelets stimulated eosinophils to generate EET, whereas those from thrombin- or ADP-activated platelets failed to induce such generation. The EET-inducing activity of the A23187-activated platelet culture was linearly proportional to the number of activated platelets. Interestingly, while EET formation induced by the direct stimulation of eosinophils with A23187 was NADPH oxidase (NOX)-dependent, EET formation induced by A23187-activated platelets was NOX-independent and significantly inhibited by necroptosis pathway inhibitors. CONCLUSIONS: Activated platelets and their products may induce EET formation, thereby potentiating their role in eosinophilic airway inflammation.

Lysophosphatidylserine Induces MUC5AC Production via the Feedforward Regulation of the TACE-EGFR-ERK Pathway in Airway Epithelial Cells in a Receptor-Independent Manner.

Lysophosphatidylserine (LysoPS) is an amphipathic lysophospholipid that mediates a broad spectrum of inflammatory responses through a poorly characterized mechanism. Because LysoPS levels can rise in a variety of pathological conditions, we sought to investigate LysoPS's potential role in airway epithelial cells that actively participate in lung homeostasis. Here, we report a previously unappreciated function of LysoPS in production of a mucin component, MUC5AC, in the airway epithelial cells. LysoPS stimulated lung epithelial cells to produce MUC5AC via signaling pathways involving TACE, EGFR, and ERK. Specifically, LysoPS- dependent biphasic activation of ERK resulted in TGF-α secretion and strong EGFR phosphorylation leading to MUC5AC production. Collectively, LysoPS induces the expression of MUC5AC via a feedback loop composed of proligand synthesis and its proteolysis by TACE and following autocrine EGFR activation. To our surprise, we were not able to find a role of GPCRs and TLR2, known LyoPS receptors in LysoPS-induced MUC5AC production in airway epithelial cells, suggesting a potential receptor-independent action of LysoPS during inflammation. This study provides new insight into the potential function and mechanism of LysoPS as an emerging lipid mediator in airway inflammation.

Lysophosphatidylserine induces eosinophil extracellular trap formation and degranulation: Implications in severe asthma.

BACKGROUND: Recent evidence demonstrates that activated eosinophils undergo a distinct form of lytic cell death, accompanied by formation of DNA-based eosinophil extracellular trap (EET) and degranulation, enhancing inflammatory immune responses in asthmatic airways. We previously showed that human blood eosinophils undergo degranulation in response to lysophosphatidylserine (LysoPS), an inflammatory lipid mediator, and strongly express P2Y10, a LysoPS receptor. METHODS: We evaluated EET, degranulation, and cell death of eosinophils in response to various concentrations of LysoPS. We also compared responsiveness to LysoPS between eosinophils from severe and nonsevere asthmatics. RESULTS: Extensive EET formation was elicited from a substantial fraction of stimulated eosinophils in response to 50 µmol/L LysoPS. Analyses for LDH and eosinophil-derived neurotoxin release showed that both lytic cell death and degranulation accompanied EET formation in response to LysoPS. Cytological analyses demonstrated that citrullinated histone 3 was present in the extracellular, filamentous DNA structure embedded with eosinophil granules. The LysoPS-induced EET was independent of ROS production and irrelevant to several signaling pathways examined, but dependent on protein arginine deiminase 4. A low concentration of LysoPS (5 µmol/L) did not induce EET or degranulation, but significantly increased platelet-activating factor-induced degranulation. Eosinophils from severe asthmatics exhibited greater degranulation, but not EET formation, in response to LysoPS (50 µmol/L), than those from nonsevere asthmatics, along with great expression of surface P2Y10. CONCLUSIONS: We identified a novel function of LysoPS, namely induction of EET in association with cytolysis and degranulation. LysoPS-dependent EET or degranulation plays a potential role in eosinophilic inflammation of severe asthma.

SERS biosensors for ultrasensitive detection of multiple biomarkers expressed in cancer cells.

The design and fabrication of multifunctional surface-enhanced Raman scattering (SERS) nanotags are key issues in their application to biological imaging of cells and tissues. In this study, highly sensitive, reproducible and long-term stable SERS nanotags were developed for the identification of localized distribution of multiple protein biomarkers expressed on breast cancer cells. To enhance the surface electromagnetic fields of Raman reporter molecules, Ag-encapsulated Au (Ag-Au) hollow nanospheres were synthesized. Strong Raman signal enhancement effects could be achieved by positioning Raman reporter molecules in nanogaps between the Au hollow nanospheres and silver shell. In addition, the signal was also enhanced due to the localization of surface electromagnetic fields through the pinholes on the surface of Au hollow nanospheres. To maintain the long-term stability of the Au hollow-Ag core/shell nanospheres, their surface was coated with a polyethylene glycol (PEG) layer. The biocompatibility of PEGylated Ag-Au hollow nanospheres was investigated using the premix water soluble tetrazolium salt (WST-1) cell viability test. These SERS nanotags also enabled a high-resolution multiplexed live cell imaging. Our proposed SERS imaging technique using the new SERS nanotags provides a new platform for fast and accurate classification of different phenotypes of breast cancer cells.