High-resolution single-nucleotide polymorphism array-profiling in myeloproliferative neoplasms identifies novel genomic aberrations.

Single-nucleotide polymorphism arrays allow for genome-wide profiling of copy-number alterations and copy-neutral runs of homozygosity at high resolution. To identify novel genetic lesions in myeloproliferative neoplasms, a large series of 151 clinically well characterized patients was analyzed in our study. Copy-number alterations were rare in essential thrombocythemia and polycythemia vera. In contrast, approximately one third of myelofibrosis patients exhibited small genomic losses (less than 5 Mb). In 2 secondary myelofibrosis cases the tumor suppressor gene NF1 in 17q11.2 was affected. Sequencing analyses revealed a mutation in the remaining NF1 allele of one patient. In terms of copy-neutral aberrations, no chromosomes other than 9p were recurrently affected. In conclusion, novel genomic aberrations were identified in our study, in particular in patients with myelofibrosis. Further analyses on single-gene level are necessary to uncover the mechanisms that are involved in the pathogenesis of myeloproliferative neoplasms.

Pegylated interferon for the treatment of high risk essential thrombocythemia: results of a phase II study.

BACKGROUND AND OBJECTIVES: Patients with high-risk essential thrombocythemia require cytoreductive therapy in order to normalize the elevated platelet counts. We evaluated the efficacy and toxicity of pegylated interferon in high-risk essential thrombocythemia in a phase II trial. DESIGN AND METHODS: Thirty-six patients with high-risk essential thrombocythemia (median age 54 years; range, 24-72 years) were studied. The dose of pegylated interferon was initially 50 mg per week and could be escalated up to 150 mg per week. RESULTS: During the first three months platelet counts decreased significantly from a median baseline count of 895x10(9)/L (range: 383-1779) to a median count of 485x10(9)/L (range: 211-1283; p<=0.001). A complete response was defined as platelet counts < 450x10(9)/L. The complete response rate was 39%, 47%, 58% and 67% at 3, 6, 9 and 12 months of treatment, respectively. There were 25%, 11%, 8% and 0% poor responders, defined as patients with platelet counts > 600x10(9)/L, at 3, 6, 9 and 12 months of treatment, respectively. After a median time of 23 months (range 3-39 months) 23 of 36 patients (64%) are still receiving pegylated interferon. In ten patients (28%) treatment was stopped due to grade 1 to 2 toxicity, classified according to the WHO standard toxicity scale. One patient, who responded partially to pegylated interferon (platelet count 542x10(9)/L), had a cerebral stroke after 23 months of treatment. INTERPRETATION AND CONCLUSIONS: In high-risk essential thrombocythemia sustained treatment with pegylated interferon is effective and safe in reducing platelet counts with a toxicity comparable to that of conventional interferon.

The platelet function defect of paroxysmal nocturnal haemoglobinuria.

Paroxysmal nocturnal haemoglobinuria (PNH) is a rare, acquired stem cell disorder, characterised by an abnormal susceptibility of red blood cells to complement induced lysis, resulting in repeated episodes of intravascular haemolysis and haemoglobinuria, thromboembolic events at atypical locations and, to a much lesser extent, bleeding complications. Platelet function is assumed to be abnormal, however, a defect has not yet been characterised and underlying mechanisms remain elusive. To explore these issues, we investigated platelet function in PNH patients using assays for clot formation under low and high shear force (thrombelastography and PFA100 device), adhesion to glass beads in native whole blood (Hellem method), aggregometry using various agonists (Born method), and flow cytometric assays for baseline and agonist-induced surface expression density of alpha-granule (CD62P) and lysosomal granule proteins (CD63), ligand binding to surface receptors (thrombospondin), and expression density of activation-induced neoepitopes of the fibrinogen receptor complex (PAC-1). Platelet PNH clone size determined by CD55 and CD59 labelling was compared to the clone sizes of granulocytes, monocytes, erythrocytes, and reticulocytes. A profound reduction of platelet reactivity was observed in PNH patients for all "global function" assays (clot formation, adhesion, aggregation). Platelet hyporeactivity was confirmed using flow cytometric assays. Whereas baseline levels of flow cytometrically determined platelet activation markers did not differ significantly between controls and PNH patients, agonist-induced values of all markers were distinctly reduced in the PNH group. Moreover, significantly reduced white blood cell counts (3.1/nl vs. 5.9/nl), haemoglobin values (9.5 vs. 14.3/g per dl), and platelet counts (136 vs. 219/nl) delineate profound tricytopenia in PNH patients. The fraction of particular cell types lacking the surface expression of GPI-anchored glycoproteins is referred to as the respective PNH clone; median PNH clone sizes of cells with short life spans (reticulocytes, platelets, granulocytes) was 50-80% of total cell populations compared to 20% of red blood cells. The results of our laboratory investigations show, that in PNH, reduced platelet counts coincide with reduced platelet reactivity. The foremost clinical complication in PNH, however, is venous thromboembolism, very probably induced by an activated and dysregulated plasmatic coagulation system. From these seemingly contradictory findings we infer, that part of the platelet hyporeactivity is probably due to reactive downregulation of platelet function in response to chronic hyperstimulation. The overall result is thought to be an unsteady balance, associated with thromboembolism in a larger proportion of patients, and with bleeding in a smaller proportion.

Plasmatic coagulation and fibrinolytic system alterations in PNH: relation to clone size.

Paroxysmal nocturnal haemoglobinuria (PNH) is characterized pathophysiologically by intravascular lysis of blood cells and clinically by thromboembolic events, often atypical in localization. In this study, we examined the plasmatic coagulation system of PNH patients to investigate a potential relation between coagulation alterations and disease intensity (PNH clone size). We found evidence for both an increase in procoagulant and in fibrinolytic activity, resulting in increased fibrin generation and turnover. Whereas a positive association of the procoagulant potential with PNH clone size was notable, fibrinolytic activity showed an inverse association with clone size. As a possible cause, a growing impairment of fibrinolytic activation and/or an increasing displacement of fibrinolytic activity is assumed. These mechanisms are most likely caused by the detachment of the glycosyl-phosphatidyl-inositol-anchored urokinase plasminogen activator receptor from cell surfaces, causing a progressive resistance to fibrinolytic stimuli, together with a probable shift of the fibrinolytic potential from cell surfaces to soluble, circulating complexes, resulting in a cellular fibrinolysis-steal phenomenon. Together, these processes are accused of mediating an increased thrombophilic risk in PNH. As hereditary prothrombogenic defects were found more frequently in patients suffering ischaemic complications, genetic thrombophilia seems to confer an additional thromboembolic risk in PNH, and should therefore be screened for.