Immunologic Abnormalities in Myelodysplastic Syndromes: Clinical Features and Characteristics of the Lymphoid Population
It has been recognized that some patients with myelodysplastic syndromes (MDS) develop immunologic abnormalities, but little is known of its correlations to MDS-specific disease features. In a retrospective study of 284 MDS patients, we identified 32 patients (11.3%) with clinical or serologic immunological abnormalities (group A) and compared them to the remaining 252 cases (group B). Group A consisted of 20 patients with clinical signs of autoimmune disease and 12 asymptomatic patients with serologic immunological abnormalities only. Apart from significant female predominance in group A (M/F = 2.5 vs M/F = 0.7, p = 0.001), the other clinical and biological features such as median age, distribution of MDS subtypes, incidence of karyotyopic abnormalities, "abnormal" in vitro growth of GM-progenitors and survival times were similar in the two groups. Autoimmune manifestations partially responded to immunosuppressive therapy, with moderate improvement of peripheral cytopenia. In addition, CD3(+), CD4(+), CD8(+), CD19(+), and CD56(+) cells were quantified in peripheral blood of 38 patients. Matched with similarly aged healthy control group, most MDS patients showed significant lymphocytopenia, mainly due to the reduction of T-helper series (in both absolute numbers and percentage). B-cells were reduced in absolute numbers, but their percentage still overlapped with the control. No major abnormalities of natural killer cells (CD56(+)) were seen. We conclude that autoimmune diseases and asymptomatic immunologic abnormalities are common in patients with MDS, but except for female predominance, no correlation between these abnormalities and MDS-specific disease features were found.
The article is concerned with incidence, clinical features, response to therapy, and prognosis of patients with hypocellular myelodysplastic syndromes. Bone marrow (BM) cellularity <30% (or <20% in patients >70 yr) was found in 24 of 236 (10.2%) trephine biopsies. Median age was 61 yr, with significant male predominance (M/F=3.0) At diagnosis, median hemoglobin was 83 g/L, median platelet and neutrofil counts were 31x109/L and 1.2x109/L, respectively. According to FAB classification, 17 patients had RA, 6 had RAEB, and only 1 had RAEB-t. Beside marrow hypoplasia, the most prominent PH finding was megakaryocyte hypoplasia and dysplasia, found in two-thirds of cases, each. Comparison between hypocellular and normo/hypercellular MDS cases regarding clinicopathological features showed younger age, more severe cytopenia, less blood and BM blast infiltration, MK hypoproliferation, and more pronounced stromal reactions in former cases. Karyotypic abnormalities were present in 12.5% hypocellular cases, in contrast to 44.6% normo/hypercellular cases (p=0.0025). Eleven patients were treated with supportive therapy alone, six with danazol or androgens, six with immunosuppressive therapy, and one with LDARAC. However, complete or partial response was achieved in only four patients treated with danazol or androgens. None of the patients developed leukemia. Eleven patients died, so marrow insufficiency was the main cause of death. Median survival was 33 mo for hypocellular MDS, and 19 mo for normo/hypercellular MDS (p=0.09). The results confirm the existence of hypocellular variant of MDS, which seems to have better prognosis than those patients with normo/hypercellular disease.
Spontaneous colony formation from bone marrow megakaryocyte progenitors (BMsCFU-Mk) was studied in 24 patients with essential thrombocythaemia (ET), 20 patients with reactive thrombocytosis (RT), 20 patients with polycthaemia rubra vera with thrombocytosis (PRVtr), 16 patients with chronic myeloid leukaemia with thrombocytosis (CMLtr) and 18 normal control subjects (C). The culture medium which was used in the methylcellulose assay in vitro contained 30% of plasma from a single patient with hereditary haemochromatosis. Remarkable BMsCFU-Mk growth was recorded in all patients with ET but in none with RT or in C. BMs-CFU-Mk were present in 11/20 patients with PRVtr and 7/16 patients with CMLtr. Spontaneous bone marrow erythroid progenitors (BMsBFU-E) were also determined in these patients. BMsBFU-E were found in 21/24 patients with ET and none in the patients with RT and C. All patients with PRVtr and one patient with CMLtr showed BMsBFU-E. We conclude that our implementation of the in vitro methylcellulose assay allows the BMsCFU-Mk to be used as an unequivocal test for discrimination between ET and RT which has not been shown in previously published studies. In addition, we present evidence that in 10 patients BMsCFU-Mk and/or BMsBFU-E growth in the test persisted after long-lasting haematological remission.
The hypothesis that in immune thrombocytopenia, platelet antibody may not only cause destruction of the circulating platelets but also depress platelet production by injuring the megakaryocytes of the bone marrow, was tested experimentally. Sustained thrombocytopenia was produced in rats by titrated injections of a potent heteroimmune antiplatelet serum and megakaryocytopoiesis was then studied by the use of tritiated thymidine and bone marrow autoradiography. Rats in which the platelet count was maintained at a lower than normal level by repeated thrombocytophereses, and other rats injected with platelet antiserum previously absorbed with rat platelets, served as controls. Profoundly altered patterns of megakaryocytopoiesis were found in the rats in which thrombocytopenia was produced by the antiplatelet serum. The data indicated a severely impaired and depressed megakaryocyte maturation and, possibly, destruction of some of the megakaryocytes during their maturation process. In the rats in which the platelet level was maintained low by repeated thrombocytophereses, the pattern of megakaryocytopoiesis indicated accelerated maturation and there was also an increased megakaryocyte mass. No difference from normal was found in the rats receiving the platelet-adsorbed antiserum. It was concluded that the platelet antibody produced an injurious effect on the megakaryocytes in the bone marrow, thereby depressing platelet production, and that the immune thrombocytopenia was the result of both increased platelet destruction and defective platelet production.
In a retrospective study of 236 patients with primary myelodysplastic syndromes (MDS), 130 cases (55.1%) revealed myelofibrosis in bone marrow biopsies. It was observed that fibrosis mostly occurs focally or patchy, and collagen deposits were found very rarely (only four patients). The histopathology of bone marrow biopsies revealed several differences between fibrotic and non-fibrotic MDS: cellularity is significantly higher, dysmegakaryopoiesis is more pronounced, plasmocytes and mast cells are more often increased, and disturbance of marrow topography (particularly of the MK- and G-line) can be found more frequently in MDS with myelofibrosis. Reticulin fibrosis occurred in all subtypes of MDS; however, there was a higher incidence in chronic myelomonocytic leukemia. The frequency of abnormal growth of GM-progenitors was significantly higher in the MDS cases with myelofibrosis, compared to the cases without fibrosis. Clinical data showed significantly higher WBC, more frequent presence of immature granulocytes, and higher percentage of myeloblasts in peripheral blood and bone marrow in MDS with myelofibrosis compared to cases without myelofibrosis. Life expectancy was reduced to 13 mo, compared with 35 mo in MDS without fibrosis (p=0.00055). Time to leukemic transformation was 32 mo in MDS with fibrosis, compared with >56 mo in MDS without fibrosis (p=0.015). Myelofibrosis therefore seems to herald a poor prognosis.
Abnormalities of chromosome 17 in myelodysplastic syndromes: Incidence and biological significance
Cytogenetic analysis has proven to be a mandatory part of the diagnosis of myelodysplastic syndromes (MDS) as well as a major indicator for predicting clinical course and outcome. Aside from the 5q-syndrome, no specific clinico-cytogenetic entity has been reported. To determine the incidence and clinical significance of acquired abnormalities of chromosome 17 in adult primary MDS, we reviewed the cytogenetic features of 271 patients detected at our institution during a 10-year period. Clonal cytogenetic abnormalities were identified in 109 cases. Among them, abnormalities of chromosome 17 were identified in 13 patients (11.9%). Five patients had "single" defects, while in eight patients abnormalities of chromosome 17 were associated with other chromosomal rearrangements ("complex" defects). After chromosomes 5, 7, 8 and 1, abnormalities of chromosome 17 were the most frequent chromosomal rearrangements in our patients with MDS. Following "single" defects of chromosome 17 were identified: del(17)(p12) in two cases, and i(17)(q10), del(17)(q21;q23) and del(17)(q12;q22) in one case each. Two patients with del(17p), one with RAEB-t and the other one with CMML, had an aggressive course of the disease with accelerated leukemic transformation and short survival. Patient with i(17q) had RARS subtype and died soon after diagnosis, while other two cases with interstitial deletions of the long arm of chromosome 17 had RAEB subtype and stable, no progressive course of the disease. Among "complex" karyotypes with abnormalities of chromosome 17 we identified der(17) in four, monosomy 17 in two, and del(17p) and l(17q) in one case each. Most of these patients transformed to acute leukemia and had very short survival. The results of this study suggest that abnormalities of chromosome 17 are frequent finding in MDS. Loss of genetic material in 17p, both in "single" and "complex" defects, seems to be closely related to poor prognosis of MDS patients.
Biological and Clinical Significance of Clonogenic Assays in Patients with Myelodysplastic Syndromes
Biological and clinical significance of growth pattern of hematopoietic progenitors were investigated in 117 patients with primary myelodysplastic syndromes (MDSs) at referral. Abnormal (i.e., "leukemic" or absent) growth of GM colonies (CFU-GM) and GM clusters was found in 47% of patients with "advanced" MDS (RAEB, RAEB-t, and CMML) and in 15% of "low-risk" (RA/RARS) patients. In vitro erythropoiesis was decreased in most of the patients, with significantly lower number of BFU-E in "advanced" MDS than in RA/RARS patients. Megakaryocyte progenitors (CFU-MK) were very low or absent in almost all the patients, regardless of the FAB type. Significant correlation was demonstrated between the number of BFU-E and hemoglobin concentration and between number of CFU-MK and platelet count. Growth capacity of GM progenitors appears to be in proportion to "myeloproliferative" capacity of the malignant clone. T-cell depletion had no influence on growth capacity of hematopoietic progenitors, nor did colony growth respond in a dose-dependent manner to different concentrations of LCM. Growth capacity of MDS hematopoietic progenitors was independent of Bournemouth score, of the presence and type of cytogenetic abnormality, and of the expression of CD95 and caspase-3 antigens on bone marrow cells. However, in patients with "abnormal" growth of GM progenitors, CD34 antigen expression was significantly higher than in patients with "normal" growth. "Abnormal" GM growth was found to be independently predictive regarding the survival and the risk for AML development. In contrast, the prognostic value of erythroid and megakaryocyte cultures was found to be limited.
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