To determine the clonal nature of hematopoiesis and to assess lineage involvement in patients with myelodysplastic syndromes (MDS), we used restriction fragment length polymorphisms of the X-linked genes phosphoglycerate kinase (PGK1) and hypoxanthine phosphoribosyltransferase (HPRT) and the X-linked probe M27 beta. Eleven female MDS patients heterozygous for at least one of these probes were studied: 3 with refractory anemia (RA), 2 with RA with ringed sideroblasts (RARS), 2 with chronic myelomonocytic leukemia (CMML), and 4 with RA with excess of blasts in transformation (RAEB-t). All exhibited clonal hematopoiesis as determined by Southern analysis of DNA prepared from peripheral blood (PB) and/or bone marrow (BM) cells. In three of the six patients heterozygous for the PGK1 gene, purified cell suspensions of polymorphonuclear cells (PMN), monocytes, lymphocytes, and/or T cells prepared from PB were tested. In addition, five of these patients were analyzed by a polymerase chain reaction (PCR)-based procedure as described recently. This method was slightly adapted to facilitate the analysis of cell lysates of fluorescence- activated cell sorted (FACS) monocytes, T and B lymphocytes, and natural killer (NK) cells. The outcome of Southern and PCR analysis was concordant, showing that PMN and monocytes were clonally derived, whereas circulating T and B lymphocytes and NK cells exhibited random X- chromosome inactivation compatible with a polyclonal pattern. To address the question of whether T cells are derived from unaffected progenitor cells or that their origin had antedated the onset of MDS, naive and memory T cells were analyzed separately. Both subsets showed a polyclonal pattern. However, in one patient analysis of constitutive DNA suggested a skewed methylation, and the presence of clonal lymphocytes against a background of polyclonal lymphoid cells cannot be ruled out in this patient. PCR analysis of PB and BM cells showed a nonrandom, unilateral pattern of X-inactivation, compatible with a mixture of clonally (myeloid) and polyclonally (lymphoid) derived cells. In conclusion, in some patients, MDS represents a disorder with clonal hematopoiesis restricted to cells of myeloid origin, whereas a random X-inactivation pattern is found in lymphoid cells.
Clonality of myeloid and lymphoid cell fractions obtained from peripheral blood (PB) or bone marrow (BM) of five patients with a myelodysplastic syndrome (MDS), was studied by combined immunophenotypic analysis and DNA in situ hybridization. This novel technique enables quantitative and direct analysis of cytogenetic alterations in nondividing cells of distinct cell lineages. Four patients with a trisomy 8 and one patient with a translocation (1;7) were studied. For cell lineage determination, antibodies specific for progenitor cells (CD34), myeloid cells (CD15), monocytes (63D3), T cells (CD3), and B cells (CD19,20,22) were used. In one patient with a trisomy 8, BM cells were available and the erythroid lineage could be studied. For detection of cytogenetic aberrations, we used chromosome- specific repetitive DNA probes. In three patients, all nonlymphoid cells carried the cytogenetic abnormality; in two patients, mosaicism within these lineages was suggested by the relative low numbers (35% to 55%) of aberrant cells. None of the T or B cells of the five patients carried the chromosomal aberrations. We conclude that combined immunophenotyping and in situ hybridization is a feasible technique to study lineage involvement. Our data suggest that the chromosomal aberrations studied in MDS are restricted to the myeloid lineages.
Pure interleukin 1 (IL 1) was found to stimulate established human bone marrow stromal layers in long-term culture to produce colony- stimulating activity (CSA). Maximal concentrations in the culture medium were reached 24 hours after a single IL 1 pulse. The effect could be neutralized by a specific rabbit anti-IL 1 antiserum. Stromal layers, once stimulated by IL 1, continued to release CSA into the culture medium in the absence of exogenous IL 1. A second IL 1 pulse induced CSA release in an identical manner, as did the primary stimulation, indicating that the CSA released was actively produced. Using specific immunologic assays, both granulocyte colony-stimulating factor (G-CSF) and macrophage CSF (M-CSF) could be identified in the culture supernatants, and production of both factors was inducible by IL 1. Shortly after initiation of the long-term marrow cultures “spontaneous” G-CSF and M-CSF release occurred. The release of G-CSF diminished following addition of the anti-IL 1 antiserum, indicating that endogenous production of IL 1 by stromal cells had contributed to this effect. These results further support the role of IL 1 as an important modulator of CSF production by cells of the hematopoietic microenvironment.
An alphoid repetitive DNA (D8Z2) probe specific for the pericentromeric region of chromosome 8 was used to detect extra copies of chromosome 8 in bone marrow cells obtained from 10 patients with hematological disorders and five controls. Numerical aberrations of chromosome 8 were established by conventional banding techniques. Trisomy 8 was found in four patients with myelodysplastic syndrome (MDS) and three with acute myeloid leukemia (AML). Three additional patients with MDS exhibited an extra chromosome 8 in only one metaphase. In five of the seven trisomy cases, the presence of the trisomy 8 clone was confirmed by in situ hybridization (ISH). In one case of AML with trisomy 8, detected by GTG-banding, no significant numbers of cells containing three spots were found using the alphoid repetitive probe; however, hybridization with a chromosome 8-specific library revealed that the alleged extra chromosome 8 was a translocation chromosome containing only the long arm of chromosome 8. Due to a lack of material, it was not possible to achieve optimal ISH results on the trisomy 8 bone marrow cells of patient 7. In the three MDS patients with a single trisomy 8 metaphase, a slight, albeit significant, increase of trisomy 8 interphase cells was found with ISH. We conclude that this probe is useful for cytogenetic studies. Moreover, ISH, in general, is a powerful tool for precise classification of chromosomal aberrations and can also contribute significantly to the clinical evaluation of patients with hematological disorders.
Summary. Acquired aplastic anaemia (AA) represents a state of bone marrow (BM) failure which is characterized by BM hypocellularity and pancytopenia. It has been hypothesized that in some AA patients, bone marrow failure is secondary to the targeted destruction of haemopoietic stem cells by autoreactive T cells. The response of T cells to antigenic stimulation has been shown, in a number of animal models and in autoimmune diseases, to result in the (oligo)clonal expansion of positively reacting T cells. For this reason, we studied the utilization of 24 T-cell receptor-variable gene segments (TCRBV) and the clonality in BM aspirates and peripheral blood (PB) of seven AA patients. BM from transplant donors served as controls. Determination of TCRBV gene segment usage revealed no significant differences between patients and controls.Clonality within each family was analysed by singlestrand conformation polymorphism (SSCP) analysis. Clonal and clonally predominant bands were seen in BM of three AA patients in five to eight TCRBV families. Clonal rearrangements were encountered less often in BM of control subjects. In conclusion, our results suggest an antigen-driven T-cell response in the BM of predominantly AA patients resulting in oligoclonal T-cell outgrowth.Keywords: aplastic anaemia, clonality, T-cell receptor-, SSCP, V usage.Aplastic anaemia (AA) is an acquired disorder affecting haemopoietic stem cells and is characterized by a reduced bone marrow (BM) cellularity and pancytopenia. Previously, we have studied the clonality of haemopoiesis in peripheral blood (PB) cells of female patients, who entered remission after anti-thymocyte globulin (ATG) therapy. Employing a PCR-based X-chromosome inactivation analysis, it was shown that about half of the patients exhibited clonal haemopoiesis (Van Kamp et al, 1991;Melenhorst et al, 1996). Analysis of the rearrangement patterns at the T-cell receptor-and immunoglobulin heavy chain loci by PCR revealed a polyclonal character of gene rearrangements, irrespective of the X-chromosome inactivation status of the lymphocyte populations.Clonal haemopoiesis in AA may result from a reduced stem cell pool to a clonal composition. It has been hypothesized that in a subgroup of AA patients this reduction is caused by autoreactive T lymphocytes (Young, 1992), recognizing an autoantigen expressed on haemopoietic progenitor cells. Evidence for the T-cellmediated pathogenesis of AA is found in the response of 70% of the patients treated with immunosuppressives, i.e. anti-lymphocyte globulin (ALG)/anti-thymocyte globulin (ATG) and cyclosporin A (Young & Barrett, 1995;Frickhofen et al, 1991). An increased percentage of CD8 HLA-DR T cells in PB and BM has been found (Zoumbos et al, 1985;Maciejewski et al, 1994) as well as a significant association of AA with the HLA-DR2 allele (Nimer et al, 1994;Nakao et al, 1994). The association of an HLA-allele with autoimmune disease predisposition is one of the most clearly established factors, and is related to the MHC-restricted T-cell response (T...
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