Intramedullary megakaryocytes internalize released platelet factor 4 and store it in alpha granules.

BACKGROUND: Megakaryocytes express and store platelet factor 4 (PF4) in alpha granules. In vivo, PF4 is a clinically relevant, negative regulator of megakaryopoiesis and hematopoietic stem cell replication. These findings would suggest a regulated source of free intramedullary PF4. OBJECTIVES: Define the source of free intramedullary PF4 and its intramedullary life cycle. METHODS: We interrogated both murine and human bone marrow-derived cells during megakaryopoiesis in vitro by using confocal microscopy and enzyme-linked immunosorbent assay. With immunohistochemistry, we examined in vivo free PF4 in murine bone marrow before and after radiation injury and in the setting of megakaryocytopenia and thrombocytopenia. RESULTS: Exogenously added human PF4 is internalized by murine megakaryocytes. Human megakaryocytes similarly take up murine PF4 but not the related chemokine, platelet basic protein. Confocal microscopy shows that internalized PF4 colocalizes with endogenous PF4 in alpha granules and is available for release on thrombin stimulation. Immunohistochemistry shows free PF4 in the marrow, but not another alphagranule protein, von Willebrand factor. Free PF4 increases with radiation injury and decreases with megakaryocytopenia. Consistent with the known role of low-density lipoprotein receptor-related protein 1 in the negative paracrine effect of PF4 on megakaryopoiesis, PF4 internalization is at least partially low-density lipoprotein receptor-related protein 1 dependent. CONCLUSIONS: PF4 has a complex intramedullary life cycle with important implications in megakaryopoiesis and hematopoietic stem cell replication not seen with other tested alpha granule proteins.

Modulation of protein C activation by histones, platelet factor 4, and heparinoids: new insights into activated protein C formation.

OBJECTIVE: Histones are detrimental in late sepsis. Both activated protein C (aPC) and heparin can reverse their effect. Here, we investigated whether histones can modulate aPC generation in a manner similar to another positively charged molecule, platelet factor 4, and how heparinoids (unfractionated heparin or oxygen-desulfated unfractionated heparin with marked decrease anticoagulant activity) may modulate this effect. APPROACH AND RESULTS: We measured in vitro and in vivo effects of histones, platelet factor 4, and heparinoids on aPC formation, activated partial thromboplastin time, and murine survival. In vitro, histones and platelet factor 4 both affect thrombin/thrombomodulin aPC generation following a bell-shaped curve, with a peak of >5-fold enhancement. Heparinoids shift these curves rightward. Murine aPC generation studies after infusions of histones, platelet factor 4, and heparinoids supported the in vitro data. Importantly, although unfractionated heparin and 2-O, 3-O desulfated heparin both reversed the lethality of high-dose histone infusions, only mice treated with 2-O, 3-O desulfated heparin demonstrated corrected activated partial thromboplastin times and had significant levels of aPC. CONCLUSIONS: Our data provide a new contextual model of how histones affect aPC generation, and how heparinoid therapy may be beneficial in sepsis. These studies provide new insights into the complex interactions controlling aPC formation and suggest a novel therapeutic interventional strategy.

Mechanism of platelet factor 4 (PF4) deficiency with RUNX1 haplodeficiency: RUNX1 is a transcriptional regulator of PF4.

BACKGROUND: Platelet factor 4 (PF4) is an abundant protein stored in platelet α-granules. Several patients have been described with platelet PF4 deficiency, including the gray platelet syndrome, characterized by a deficiency of α-granule proteins. Defective granule formation and protein targeting are considered to be the predominant mechanisms. We have reported on a patient with thrombocytopenia and impaired platelet aggregation, secretion, and protein phosphorylation, associated with a mutation in the transcription factor RUNX1. Platelet expression profiling showed decreased transcript expression of PF4 and its non-allelic variant PF4V1. OBJECTIVES: To understand the mechanism leading to PF4 deficiency associated with RUNX1 haplodeficiency, we addressed the hypothesis that PF4 is a transcriptional target of RUNX1. METHODS/RESULTS: Chromatin immunoprecipitation and gel-shift assays with phorbol 12-myristate 13-acetate-treated human erythroleukemia (HEL) cells revealed RUNX1 binding to RUNX1 consensus sites at -1774/-1769 and -157/-152 on the PF4 promoter. In luciferase reporter studies in HEL cells, mutation of each site markedly reduced activity. PF4 promoter activity and PF4 protein level were decreased by small interfering RNA RUNX1 knockdown and increased by RUNX1 overexpression. CONCLUSIONS: Our results provide the first evidence that PF4 is regulated by RUNX1 and that impaired transcriptional regulation leads to the PF4 deficiency associated with RUNX1 haplodeficiency. Because our patient had decreased platelet albumin and IgG (not synthesized by megakaryocytes) levels, we postulate additional defects in RUNX1-regulated genes involved in vesicular trafficking. These studies advance our understanding of the mechanisms in α-granule deficiency.

Elimination of platelet factor 4 (PF4) from platelets reduces atherosclerosis in C57Bl/6 and apoE-/- mice.

Activated platelets, which release platelet factor 4 (PF4) are present in patients with atherosclerosis. To date, no direct in-vivo evidence exists for the involvement of PF4 in atherogenesis. In the current study, we tested the hypothesis that PF4 is atherogenic, and that genetic elimination of PF4 would protect mice from atherosclerosis. We have bred PF4(-/-) mice onto two athero-susceptible backgrounds, WT-C57Bl/6(WT) and apoE(-/-) to examine the importance of PF4 in atherogenesis. In order to induce atherosclerosis, WT and PF4(-/-) mice were fed an atherogenic diet for 30 weeks, while apoE(-/-) and apoE(-/-) PF4(-/-) mice were fed a high-fat Western-style diet for 10 weeks. Examination of lesions in the aortic roots of atherogenic diet fed mice demonstrated reduced atherosclerosis in PF4(-/-) (20% compared to WT). Examination of apoE(-/-) mice demonstrated similar changes, with apoE(-/-) PF4(-/-) mice demonstrating 37% of the aortic atherosclerotic burden compared to apoE(-/-) mice. Although we found similar levels of total and non-HDL cholesterol in WT and PF4(-/-) mice, HDL-cholesterol levels were increased in PF4(-/-) on both backgrounds. These data demonstrate, for the first time, that the platelet specific chemokine PF4 promotes atherosclerotic lesion development in vivo.

Platelets of the Wistar Furth rat have reduced levels of alpha-granule proteins. An animal model resembling gray platelet syndrome.

Rats of the Wistar Furth (WF) strain have hereditary macrothrombocytopenia (large mean platelet volume [MPV] with increased platelet size heterogeneity and reduced platelet count). Ultrastructural studies suggest that this anomaly results from erratic subdivision of megakaryocyte cytoplasm into platelets. In this study, we have examined protein profiles of platelets of WF rats for biochemical abnormalities associated with this anomaly. Marked decreases in protein bands with an Mr of 185, 57, 53, 16, 13, and 8 kd were observed in one-dimensional reduced SDS-PAGE gels in WF platelets compared with platelets of Wistar, Long Evans, and Sprague-Dawley rats. These proteins were released into the supernatant when washed platelets were treated with thrombin suggesting that they were alpha-granule proteins. These abnormalities were not present in offspring of crosses between Wistar Furth and Wistar rats; however, they were present in platelets of offspring with large MPV derived from backcrosses of (WF X Wistar) F1 males to WF females, but not in backcross offspring with normal platelet size. Immunoblotting confirmed decreased levels of thrombospondin, fibrinogen, and platelet factor 4 in WF platelets. Electron microscopic examination revealed that platelet alpha granules were usually smaller in Wistar Furth than in Wistar rats. In addition, immunogold electron microscopy demonstrated that the surface connected canalicular system of the large Wistar Furth platelets, contained dense material composed of alpha-granule proteins, not present in Wistar platelets. From these results, we conclude that the Wistar Furth rat platelet phenotype of large mean platelet volume and decreased levels of alpha-granule proteins represents an animal model resembling gray platelet syndrome. The autosomal recessive pattern of inheritance of the large MPV phenotype and platelet alpha-granule protein deficiencies suggests that a component common to both formation of platelet alpha granules, and subdivision of megakaryocyte cytoplasm into platelets, is quantitatively or qualitatively abnormal in Wistar Furth rat megakaryocytes and platelets.

Grey platelet syndrome: evidence for alpha-granule localization of the platelet plasminogen activator inhibitor-1 pool.

The case of an 11-year-old boy with grey platelet syndrome is described. Platelets had the typical grey and ghostly appearance on May-Grünwald/Giemsa staining, caused by the absence of alpha granules confirmed by electron microscopy. Alpha granule protein content, i.e., beta-thromboglobulin and platelet factor 4, was less than 3% of normal and alpha granule secretion in response to thrombin was not detectable photometrically. The plasminogen activator inhibitor-1 pool in the patient's platelets was 5% of normal, confirming previous indirect evidence for the storage of this protein within the alpha-granule. Dense body secretion of adenosine triphosphate and 5-hydroxytryptamine was normal. Aggregation occurred normally in response to adenosine diphosphate and there was a slight delay in response to collagen.

Gray platelet syndrome: selective alpha-granule deficiency and thrombocytopenia due to increased platelet turnover.

Clinical and laboratory studies of two siblings, both suffering from gray platelet syndrome (GPS) are described. The patients had a mild bleeding disorder, their platelets were blue-gray in panoptic stains, and alpha-granules were markedly reduced, as shown by electron microscopy. The platelet content of platelet factor 4 and that of beta-thromboglobulin were significantly reduced (3%-7% of normal). Platelet count was decreased (33-150 X 10(9)/1) and small platelets were increased in platelet volume distribution. Bleeding time was prolonged on most occasions. Bone marrow aspiration was performed in one patient and revealed increased reticulin fibers, however, megakaryocyte count was normal. The mean platelet survival was 4.8 days using 111indium-labelled platelets. In this patient, platelet-associated IgG was within the normal range. Prednisone therapy failed to increase platelet count. Dental surgery was performed under cover of desmopressin and no bleeding complication occurred; however, no improvement of bleeding time was observed. The patient delivered a healthy male infant without hemorrhaging while under concurrent platelet transfusion therapy.