Serglycin controls megakaryocyte retention of platelet factor 4 and influences megakaryocyte fate in bone marrow.

Megakaryocytes (MKs) produce platelets, and like other hematopoietic progenitors they are involved in homeostatic aspects of their bone marrow niche. MKs release and endocytose various factors, such as platelet factor 4 (PF4/CXCL4). Here we show that the intra-α-granular proteoglycan, serglycin (SRGN) plays a key role in this process by retaining PF4 and perhaps other factors during MK maturation. Immature, SRGN-/- MKs released ~80% of their PF4 and conditioned media from these cells negatively affected wild-type MK differentiation in vitro. This was replicated in wild-type MKs, by treatment with the polycation surfen, a known inhibitor of glycosaminoglycan/protein interactions. In vivo, SRGN-/- mice had an interstitial accumulation of PF4, TGFß-1, IL-1ß, and TNF-α in their bone marrow and increased numbers of immature MKs, consistent with their mild thrombocytopenia. SRGN-/- mice also had reduced numbers of hematopoietic stem cells and multipotent progenitors, reduced laminin, and increased collagen I deposition. These findings demonstrate that MKs depend on SRGN and its charged glycosaminoglycans to balance the distribution of PF4 and perhaps other factors between their α-granules and their adjacent extracellular spaces. Disrupting this balance negatively affects MK development and bone marrow microenvironment homeostasis.

Protocol for optimizing production and quality control of infective EcoHIV virions.

EcoHIV is a model of HIV infection that recapitulates aspects of HIV-1 pathology in mice. However, there are limited published protocols to guide EcoHIV virion production. Here, we present a protocol for producing infective EcoHIV virions and essential quality controls. We describe steps for viral purification, titering, and multiple techniques to analyze infection efficacy. This protocol produces high infectivity in C57BL/6 mice which will aid investigators in generating preclinical data.

Platelet glycogenolysis is important for energy production and function.

Although the presence of glycogen in platelets was established in the 1960s, its importance to specific functions (i.e., activation, secretion, aggregation, and clot contraction) remains unclear. Patients with glycogen storage disease often present with increased bleeding and glycogen phosphorylase (GP) inhibitors, when used as treatments for diabetes, induce bleeding in preclinical studies suggesting some role for this form of glucose in hemostasis. In the present work, we examined how glycogen mobilization affects platelet function using GP inhibitors (CP316819 and CP91149) and a battery of ex vivo assays. Blocking GP activity increased glycogen levels in resting and thrombin-activated platelets and inhibited platelet secretion and clot contraction, with minimal effects on aggregation. Seahorse energy flux analysis and metabolite supplementation experiments suggested that glycogen is an important metabolic fuel whose role is affected by platelet activation and the availability of external glucose and other metabolic fuels. Our data shed light on the bleeding diathesis in glycogen storage disease patients and offer insights into the potential effects of hyperglycemia on platelets.

What did we know? Activated platelets transition from a low-energy-requiring, resting state to a high-energy-demanding state.Platelet glycogen is degraded upon activation.Glycogen storage disorders and glycogen phosphorylase inhibitors are associated with bleeding.What did we discover? Glycogen turnover occurs in resting platelets and its degradation is important for platelet functions.Glycogen phosphorylase inhibitors block secretion and clot contraction of which the latter can be reversed with alternative metabolic fuels.Glucose derived from glycogen may be routed through TCA/OxPhos versus aerobic glycolysis.What is the impact? Glycogen breakdown contributes to the high energy requirements of platelet function.Our work offers insights into potential energy sources in activated platelets.

Ferric Chloride-Induced Arterial Thrombosis and Sample Collection for 3D Electron Microscopy Analysis.

Cardiovascular diseases are a leading cause of mortality and morbidity worldwide. Aberrant thrombosis is a common feature of systemic conditions like diabetes and obesity, and chronic inflammatory diseases like atherosclerosis, cancer, and autoimmune diseases. Upon vascular injury, usually the coagulation system, platelets, and endothelium act in an orchestrated manner to prevent bleeding by forming a clot at the site of the injury. Abnormalities in this process lead to either excessive bleeding or uncontrolled thrombosis/insufficient antithrombotic activity, which translates into vessel occlusion and its sequelae. The FeCl3-induced carotid injury model is a valuable tool in probing how thrombosis initiates and progresses in vivo. This model involves endothelial damage/denudation and subsequent clot formation at the injured site. It provides a highly sensitive, quantitative assay to monitor vascular damage and clot formation in response to different degrees of vascular damage. Once optimized, this standard technique can be used to study the molecular mechanisms underlying thrombosis, as well as the ultrastructural changes in platelets in a growing thrombus. This assay is also useful to study the efficacy of antithrombotic and antiplatelet agents. This article explains how to initiate and monitor FeCl3-induced arterial thrombosis and how to collect samples for analysis by electron microscopy.

Platelet α-granule cargo packaging and release are affected by the luminal proteoglycan, serglycin.

BACKGROUND: Serglycin (SRGN) is an intragranular, sulfated proteoglycan in hematopoietic cells that affects granule composition and function. OBJECTIVE: To understand how SRGN affects platelet granule packaging, cargo release, and extra-platelet microenvironments. METHODS: Platelets and megakaryocytes from SRGN-/- mice were assayed for secretion kinetics, cargo levels, granule morphology upon activation, and receptor shedding. RESULTS: Metabolic, 35 SO4 labeling identified SRGN as a major sulfated macromolecule in megakaryocytes. SRGN colocalized with α-granule markers (platelet factor 4 [PF4], von Willebrand factor [VWF], and P-selectin), but its deletion did not affect α-granule morphology or number. Platelet α-granule composition was altered, with a reduction in basic proteins (pI ≥8; e.g., PF4, SDF-1, angiogenin) and constitutive release of PF4 from SRGN-/- megakaryocytes. P-Selectin, VWF, and fibrinogen were unaffected. Serotonin (5-HT) uptake and ß-hexosaminidase (HEXB) were slightly elevated. Thrombin-induced exocytosis of PF4 from platelets was defective; however, release of RANTES/CCL5 was normal and osteopontin secretion was more rapid. Release of 5-HT and HEXB (from dense granules and lysosomes, respectively) were unaffected. Ultrastructural studies showed distinct morphologies in activated platelets. The α-granule lumen of SRGN-/- platelet had a grainy staining pattern, whereas that of wild-type granules had only fibrous material remaining. α-Granule swelling and decondensation were reduced in SRGN-/- platelets. Upon stimulation of platelets, a SRGN/PF4 complex was released in a time- and agonist-dependent manner. Shedding of GPVI from SRGN-/- platelets was modestly enhanced. Shedding of GP1b was unaffected. CONCLUSION: The polyanionic proteoglycan SRGN influences α-granule packaging, cargo release, and shedding of platelet membrane proteins.