Guntram Buesche

Classification and staging of Ph-negative myeloproliferative disorders by histopathology from bone marrow biopsies

The present study illustrates characteristic features of histopathology in the 3 non-leukemic, Ph-negative groups of chronic myeloproliferative diseases (CMPD). Attention is paid to the final outcome of CMPD, especially its transformation into acute leukemias and the occurrence of myelofibrosis from bone marrow biopsies (BMB) in a total of 1,716 CMPD patients. Essential thrombocythemia (ET), polycythemia vera (P. vera), and chronic megakaryocytic granulocytic myelosis (CMGM) can readily be distinguished by histopathology from BMB in the great majority of patients without regarding laboratory data, leaving a compartment of about 12% unclassifiable cases. Histologic patterns of staging are the increase in number and pleomorphism of megakaryocytes (MK), increase in number and density of reticulin fibers and collagen fibrosis, and excess of blasts. These 3 criteria are each graded from 0 to 3 in every biopsy. From these, a staging results by means of the histology of BMB in each of the Ph-negative CMPD. This staging provides a classification by defined criteria which permits comparative studies, the possibility of monitoring the individual patients by follow-up histology, and offers a baseline for reliable evaluation of results from therapy protocols.

Gene Therapy of Mpl Deficiency: Challenging Balance Between Leukemia and Pancytopenia

Signaling of the thrombopoietin (THPO) receptor MPL is critical for the maintenance of hematopoietic stem cells (HSCs) and megakaryocytic differentiation. Inherited loss-of-function mutations of MPL cause severe thrombocytopenia and aplastic anemia, a syndrome called congenital amegakaryocytic thrombocytopenia (CAMT). With the aim to assess the toxicity of retroviral expression of Mpl as a basis for further development of a gene therapy for this disorder, we expressed Mpl in a murine bone marrow transplantation (BMT) model. Treated mice developed a profound yet transient elevation of multilineage hematopoiesis, which showed morphologic features of a chronic myeloproliferative disorder (CMPD) with progressive pancytopenia. Ten percent of mice (3/27) developed erythroleukemia, associated with insertional activation of Sfpi1 and Fli1. The majority of transplanted mice developed a progressive pancytopenia with histopathological features of a myelodysplastic syndrome (MDS)-like disorder. To avoid these adverse reactions, improved retroviral vectors were designed that mediate reduced and more physiological Mpl expression. Self-inactivating gamma-retroviral vectors were constructed that expressed Mpl from the phosphoglycerate kinase (PGK) or the murine Mpl promoter. Mice that received BM cells expressing Mpl from the Mpl promoter were free of any previously observed adverse reactions.

Different involvement of the megakaryocytic lineage by the JAK2 V617F mutation in Polycythemia vera, essential thrombocythemia and chronic idiopathic myelofibrosis.

Atypical megakaryocytes provide the histomorphological hallmark of all Philadelphia-chromosome negative chronic myeloproliferative disorder (Ph− CMPD) subtypes and have not been studied so far for the JAK2V617F mutation. The mutant gene dosage was determined in isolated megakaryocytes from 68 cases of JAK2+/Ph− CMPD by a pyrosequencing assay. Megakaryocytes from essential thrombocythemia (ET) showed significantly lower levels of mutated JAK2 alleles compared to patients with chronic idiopathic myelofibrosis (cIMF) with manifest fibrosis and polycythemia vera (PV) but not to prefibrotic cIMF. Solely, ET JAK2V617F in megakaryocytes is associated with a PV-like phenotype, and at least in one patient, the JAK2 mutation was exclusively acquired within the megakaryocytic lineage. The overt differences between prefibrotic and fibrotic cIMF suggested a causative role of the gene dosage of mutant JAK2 in fibrotic progression. Megakaryocyte analysis of a follow-up of eight individual cases with sequential biopsies, however, showed that progression to homozygosity of V617F mutated JAK2 and onset of manifest fibrosis appeared to be independent events. We conclude that megakaryocytes might be the predominant or even the exclusive lineage that acquires the JAK2V617F mutation in ET and that the JAK2V617F evolution to higher gene dosages represents a dynamic and complex process substantially involving megakaryocytes.

The expression levels of telomerase catalytic subunit hTERT and oncogenic MYC in essential thrombocythemia are affected by the molecular subtype

The role of telomerase catalytic subunit hTERT in clonal malignancies including human leukemia is fundamental in overcoming cell senescence and enabling prolonged proliferation. One direct transcriptional activator of hTERT is the oncogene MYC which is known to be, in turn, activated by JAK2. To explore the relationship of telomerase, MYC and JAK2 in chronic myeloproliferative diseases, we investigated hTERT and MYC expression in bone marrow cells of essential thrombocythemia (ET) and polycythemia vera (PV). We could determine an up-regulation of MYC expression exclusively in JAK2wt ET, whereas hTERT expression was rather inconsistent across the groups. Interestingly, a significant correlation between MYC and hTERT expression could only be established in homozygous JAK2V617F PV and control cases. Thus, the functional link between MYC and hTERT seems to be impaired depending on the molecular ET subtype, which in turn may have implications on the phenotype and course of the disease.

Impaired formation of erythroblastic islands is associated with erythroid failure and poor prognosis in a significant proportion of patients with myelodysplastic syndromes

Erythropoiesis is arranged in erythroblastic islands (Ery-Is),[1][1] the specialized niche known for more than 50 years[2][2] in which erythroid precursors proliferate and differentiate. However, the significance of erythropoiesis in anemia, the leading symptom of myelodysplastic syndromes (MDS),

Routes of Clonal Evolution into Complex Karyotypes in Myelodysplastic Syndrome Patients with 5q Deletion

Myelodysplastic syndrome (MDS) can easily transform into acute myeloid leukemia (AML), a process which is often associated with clonal evolution and development of complex karyotypes. Deletion of 5q (del(5q)) is the most frequent aberration in complex karyotypes. This prompted us to analyze clonal evolution in MDS patients with del(5q). There were 1684 patients with low and intermediate-risk MDS and del(5q) with or without one additional cytogenetic abnormality, who were investigated cytogenetically in our department, involving standard karyotyping, fluorescence in situ hybridization (FISH) and multicolor FISH. We identified 134 patients (8%) with aspects of clonal evolution. There are two main routes of cytogenetic clonal evolution: a stepwise accumulation of cytogenetic events over time and a catastrophic event, which we defined as the occurrence of two or more aberrations present at the same time, leading to a sudden development of highly complex clones. Of the 134 patients, 61% underwent a stepwise accumulation of events whereas 39% displayed a catastrophic event. Patients with isolated del(5q) showed significantly more often a stepwise accumulation of events rather than a catastrophic event. The most frequent aberrations in the group of stepwise accumulation were trisomy 8 and trisomy 21 which were significantly more frequent in this group compared to the catastrophic event group. In the group with catastrophic events, del(7q)/-7 and del(17p)/-17 were the most common aberrations. A loss of 17p, containing the tumor suppressor gene TP53, was found significantly more frequent in this group compared to the group of stepwise accumulation. This leads to the assumption that the loss of TP53 is the driving force in patients with del(5q) who undergo a sudden catastrophic event and evolve into complex karyotypes.

P-198 SPARC and TNF-α contribute significantly to erythroid failure in MDS with 5q deletion and influence considerably the efficacy of lenalidomide

G. Buesche1, A. Giagounidis2, O. Bock3, H. Teoman3, G. Gohring4, B. Schlegelberger4, S. Dieck3, A. Ganser5, A. List6, J.M. Bennett7, C. Aul8, H.H. Kreipe3. 1Department of Pathology, Hannover Medical School, Hannover, Germany; 2Department of Oncology Hematology and Palliative Treatment, Marienhospital, Dusseldorf, Germany; 3Department of Pathology, Hannover Medical School, Hannover, Germany; 4Institute of Cell and Molecular Pathology, Hannover Medical School, Hannover, Germany; 5Department of Hematology Hemostasis Oncology and Stem Cell Transplantation, Hannover Medical School, Hannover, Germany; 6Department of Interdisciplinary Oncology, University of South Florida, Tampa FL, USA; 7Cancer Center, University of Rochester, Rochester NY, USA; 8Department 2 Oncology and Hematology, St. Johannes Clinic, Duisburg, Germany