Platelet activation and thrombus formation are under the control of signaling systems that integrate cellular homeostasis with cytoskeletal dynamics. Here, we identify a role for the ribosome protein S6 kinase (S6K1) and its upstream regulator mTOR in the control of platelet activation and aggregate formation under shear flow. Platelet engagement of fibrinogen initiated a signaling cascade that triggered the activation of S6K1 and Rac1. Fibrinogen-induced S6K1 activation was abolished by inhibitors of Src kinases, but not Rac1 inhibitors, demonstrating that S6K1 acts upstream of Rac1. S6K1 and Rac1 interacted in a protein complex with the Rac1 GEF TIAM1 and colocalized with actin at the platelet lamellipodial edge, suggesting that S6K1 and Rac1 work together to drive platelet spreading. Pharmacologic inhibitors of mTOR and S6K1 blocked Rac1 activation and prevented platelet spreading on fibrinogen, but had no effect on Src or FAK kinase activation. mTOR inhibitors dramatically reduced collageninduced platelet aggregation and promoted the destabilization of platelet aggregates formed under shear flow conditions. Together, these results reveal novel roles for S6K1 and mTOR in the regulation of Rac1 activity and provide insights into the relationship between the pharmacology of the mTOR system and the molecular mechanisms of platelet activation. (Blood. 2011;118(11):3129-3136) IntroductionPlatelets represent a specialized set of peripheral blood cells that are optimally configured for adhesion, secretion and aggregation at sites of vascular injury. 1,2 The exposure of platelets to extracellular matrix proteins such as collagen or laminin, or endogenous agonists such as ADP or thromboxanes, mediates hemostasis by activating signaling pathways that ultimately result in platelet adhesion and aggregation. 3 On the engagement of the adhesive proteins fibrinogen and fibronectin, platelet tyrosine kinases such as Src, Syk and FAK are recruited to the platelet cytosolic cell surface to initiate signaling pathways to drive platelet cytoskeletal reorganization through the Rho family small GTPase Rac1. [3][4][5] Rac1 regulates actin polymerization at the cell membrane to drive the growth and extension of platelet lamellipodiae that form the basis for platelet spreading. 4 The molecular mechanisms by which tyrosine kinases ultimately activate Rac1 remain ill-defined.The 70 kDa ribosome S6 protein kinase (S6K1) regulates the ribosome S6 protein to integrate processes of protein translation with cell growth and cell proliferation. 6 In cultured cells as well as in vivo, mitogenic signals triggered by nutrients and growth factors initiate a complex sequence of signaling events to activate the mammalian target of rapamycin (mTOR), a serine/threonine kinase which regulates S6K1 phosphorylation and activation. 7 Treatment of cells with rapamycin (Sirolimus) or other inhibitors of mTOR blocks S6K1 Thr389 phosphorylation and inhibits S6K1 activation. 8 The ability of mTOR inhibitors to arrest the growth of transformed tumor cells with...
The study of blood ex vivo can occur in closed or open systems, with or without flow. Microfluidic devices facilitate measurements of platelet function, coagulation biology, cellular biorheology, adhesion dynamics, pharmacology, and clinical diagnostics. An experimental session can accommodate 100s to 1000s of unique clotting events. Using microfluidics, thrombotic events can be studied on defined surfaces of biopolymers, matrix proteins, and tissue factor under constant flow rate or constant pressure drop conditions. Distinct shear rates can be created on a device with a single perfusion pump. Microfluidic devices facilitated the determination of intraluminal thrombus permeability and the discovery that platelet contractility can be activated by a sudden decrease in flow. Microfluidics are ideal for multicolor imaging of platelets, fibrin, and phosphatidylserine and provide a human blood analog to the mouse injury models. Overall, microfluidic advances offer many opportunities for research, drug testing under relevant hemodynamic conditions, and clinical diagnostics.
To investigate the transition from non-cancerous to metastatic from a physical sciences perspective, the Physical Sciences–Oncology Centers (PS-OC) Network performed molecular and biophysical comparative studies of the non-tumorigenic MCF-10A and metastatic MDA-MB-231 breast epithelial cell lines, commonly used as models of cancer metastasis. Experiments were performed in 20 laboratories from 12 PS-OCs. Each laboratory was supplied with identical aliquots and common reagents and culture protocols. Analyses of these measurements revealed dramatic differences in their mechanics, migration, adhesion, oxygen response, and proteomic profiles. Model-based multi-omics approaches identified key differences between these cells' regulatory networks involved in morphology and survival. These results provide a multifaceted description of cellular parameters of two widely used cell lines and demonstrate the value of the PS-OC Network approach for integration of diverse experimental observations to elucidate the phenotypes associated with cancer metastasis.
Immunotherapy is reshaping cancer treatment paradigms; however, response rates to immune therapies are low and depend on the host's pre-existing antitumor immunity. The tumor microenvironment is comprised of malignant cells, stroma, and extracellular molecules and can hinder immune control of tumors. Herein, we review how anti-tumor immune responses are formed and how tumors avoid immune destruction. We also outline potential therapeutic targets in the immunosuppressive tumor microenvironment to promote immune control of tumors.
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