Martina Foy

Differential stimulation of monocytic cells results in distinct populations of microparticles

Background: Microparticles (MPs), small vesicles shed from stimulated cells, permit cross‐talk between cells within a particular environment. Their composition is thought to reflect their cell of origin, and differs according to whether they are produced by stimulation or by apoptosis. Whether MP properties vary according to stimulus is not yet known. Methods: We studied the characteristics of MPs produced from monocytic THP‐1 cells upon stimulation with lipopolysaccharide or a soluble P‐selectin chimera, using proteomics, flow cytometry, western blotting, and electron microscopy. Results: Utilizing a novel criterion of calcein‐AM staining to define MPs, we found that MP populations were similar with respect to size, presence and organization of cytoskeleton, and expression of certain antigens. The MPs shared the same level of procoagulant activity. We found that MPs also have distinct characteristics, depending on stimuli. These include differences in phosphatidylserine expression and expression of proteins from specific subcellular locations such as the mitochondria, and of unique antigens such as leukocyte‐associated immunoglobin‐like‐receptor (LAIR)‐1, which was found only upon stimulation with the soluble P‐selectin chimera. Conclusion: We found that the properties of MPs depend on the stimulus that produced them. This supports the concept that monocytic MPs differentially modulate thrombosis, inflammation and immune regulation according to stimulus.

Canonical Wnt signaling negatively regulates platelet function

Wnts regulate important intracellular signaling events, and dysregulation of the Wnt pathway has been linked to human disease. Here, we uncover numerous Wnt canonical effectors in human platelets where Wnts, their receptors, and downstream signaling components have not been previously described. We demonstrate that the Wnt3a ligand inhibits platelet adhesion, activation, dense granule secretion, and aggregation. Wnt3a also altered platelet shape change and inhibited the activation of the small GTPase RhoA. In addition, we found the Wnt-β-catenin signaling pathway to be functional in platelets. Finally, disruption of the Wnt Frizzled 6 receptor in the mouse resulted in a hyperactivatory platelet phenotype and a reduced sensitivity to Wnt3a. Taken together our studies reveal a novel functional role for Wnt signaling in regulating anucleate platelet function and may provide a tractable target for future antiplatelet therapy.

Using proteomics to identify potential therapeutic targets in platelets

Proteomics has provided powerful new insights into the complex events of the anucleate platelet and has revealed many potential protein targets in the search for suitable agents for thrombotic disease. In the present study, we summarize recent proteomic approaches to analyse specific platelet subproteomes, such as the platelet releasate, the platelet phosphotyrosine proteome and characterization of the proteins associated with membrane lipid rafts.

Recent Advances in the Characterisation of the Platelet Membrane System by Proteomics

Platelets are the principle effectors of cellular haemostasis and key mediators in the pathogenesis of thrombosis. A variety of membrane receptors determine platelet reactivity with numerous agonists and adhesive proteins, and therefore represent key targets for the development of antiplatelet drug therapy. Here, we summarise recent advances in the analysis of the complex platelet membrane system achieved through the integration of platelet biology and proteomics.

Analysis of membrane microdomain-associated proteins in the insular cortex of post-mortem human brain.

Membrane microdomains (MM) are membrane rafts within the cell membrane enriched in cholesterol and glycosphingolipids that have been implicated in the trafficking and sorting of membrane proteins, secretory and endocytotic pathways, and signal transduction. To date, MM have not been characterised in the human brain. We reason that by identifying MM in the normal human cortex, we may better understand the molecular mechanisms of human brain dysfunction. To characterize the protein composition of MM in the human brain, we have carried out a comprehensive proteomic analysis of detergent resistant membranes (DRMs) associated proteins derived from human postmortem insular cortex using 1‐DE separation prior to LC coupled to MS/MS or GeLC‐MS/MS. Eighty five proteins were identified including 57 unique to human brain cortex DRMs (by comparison with DRM proteins reported in other cell types). High levels of signal transduction, cell adhesion, cell transport and cell trafficking proteins were identified including synaptic proteins such as synapsin II and synaptic vesicle membrane protein, mitochondrial proteins such as ATPase subunits and metabolic enzymes such as malate dehydrogenase. This data will facilitate our understanding of protein expression changes within membranes in candidate brain regions in human brain diseases such as schizophrenia, bipolar disorder and other psychiatric and neurodegenerative disorders.

Enrichment of phosphotyrosine proteome of human platelets by immunoprecipitation.

Proteomics offers the opportunity to comprehensively investigate the anucleate platelet. Here, we present a detailed procedure for enrichment by immunoprecipitation, using the monoclonal antibody 4G10, of the dynamic phosphotyrosine proteome of human platelets. Such an approach offers the possibility of capturing the dynamic tyrosine phosphorylation events that occur upon platelet activation and aggregation, with an aim to identify novel signaling proteins.

Analysis of the proteins associated with platelet detergent resistant membranes.

Proteomic studies have facilitated the identification of proteins associated with the detergent‐resistant membrane (DRM) fraction in a variety of cell types. Here, we have undertaken label‐free quantitative (LFQ) proteomic profiling of the proteins associated with detergent‐resistant plasma and internal membranes from resting and activated platelets. One hundred forty‐one proteins were identified and raw data is available via ProteomeXchange with identifier PXD002554. The proteins identified include a myriad of important platelet signaling and trafficking proteins including Rap1b, Src, SNAP‐23, syntaxin‐11, and members of the previously unattributed Ragulator complex. Mean LFQ intensities calculated across three technical replicates for the three biological donors revealed that several important platelet signaling proteins altered their detergent solubility upon activation, including GPIbα, GPIbβ, Src, and 14‐3‐3ζ. Altered detergent solubility for GPIbα, following activation using a variety of platelet agonists, was confirmed by immunoblotting and further coimmunoprecipitation experiments revealed that GPIbα forms a complex with 14‐3‐3ζ that shifts into DRMs following activation. Taken together, proteomic profiling of platelet DRMs allowed greater insight in the complex biology of both DRMs and platelets and will be a useful subproteome to study platelet‐related disease. All MS data have been deposited in the ProteomeXchange with identifier PXD002554 (http://proteomecentral.proteomexchange.org/dataset/PXD002554).