ALBERT

Description: Conflicting results have been published on whether or not myelodysplastic syndromes (MDS) affect all cell lineages. Involvement of myeloid and erythroid cell lineages has been regularly observed, but it remains controversial whether the different lymphoid cell lineages are involved. In this study of eight patients with MDS associated with monosomy 7, fluorescent in situ hybridization (FISH) was used to enumerate the chromosomes 7 in interphase cells. With the probe D7Z1, the rate of false-positive detection of monosomy 7 was 3% +/- 2% in normal cells. T- and B-cell lines were established from eight patients with MDS and monosomy 7. As determined by FISH in interphase cells, 1.9% (0% to 3%) of the cells in the B-cell lines showed one fluorescent spot and 1.1% (0% to 2.9%) of the cells in the T-cell lines. These values do not differ from normal values. However, the possibility that normal cells were selected when the T- and B-cell lines were established could not be excluded. Therefore, peripheral blood cells were obtained, separated according to surface markers specific for lymphoid and myeloid cell lineage with a cell sorter, and analyzed for the expression of monosomy 7 by FISH. Antibodies recognizing T cells (CD3), B cells (CD20), natural killer (NK) cells (CD57), monocytes and granulocytes (low and high expression of CD11b antigen), and myeloid progenitors (CD33) were used to separate cells. The expression of monosomy 7 in the T cells, NK cells, and B cells did not differ from control values. These results in the lymphoid subpopulations are in stark contrast with the observations in the myeloid populations; the percentage of cells with monosomy 7 ranged from 9% to 78% (controls: 6% +/- 2%) in cells with low CD11b expression, 20% to 89% in cells with a high expression of the CD11b antigen (controls: 7% +/- 3%), and 23% to 91% in the CD33 positive cells (controls: 5% +/- 3%). The results of this study suggest that monosomy 7 does not usually affect lymphoid subpopulations but is restricted to committed progenitor cells with the capacity to differentiate into mature myeloid cells.

Description: Conflicting results have been published on whether or not myelodysplastic syndromes (MDS) affect all cell lineages. Involvement of myeloid and erythroid cell lineages has been regularly observed, but it remains controversial whether the different lymphoid cell lineages are involved. In this study of eight patients with MDS associated with monosomy 7, fluorescent in situ hybridization (FISH) was used to enumerate the chromosomes 7 in interphase cells. With the probe D7Z1, the rate of false-positive detection of monosomy 7 was 3% +/- 2% in normal cells. T- and B-cell lines were established from eight patients with MDS and monosomy 7. As determined by FISH in interphase cells, 1.9% (0% to 3%) of the cells in the B-cell lines showed one fluorescent spot and 1.1% (0% to 2.9%) of the cells in the T-cell lines. These values do not differ from normal values. However, the possibility that normal cells were selected when the T- and B-cell lines were established could not be excluded. Therefore, peripheral blood cells were obtained, separated according to surface markers specific for lymphoid and myeloid cell lineage with a cell sorter, and analyzed for the expression of monosomy 7 by FISH. Antibodies recognizing T cells (CD3), B cells (CD20), natural killer (NK) cells (CD57), monocytes and granulocytes (low and high expression of CD11b antigen), and myeloid progenitors (CD33) were used to separate cells. The expression of monosomy 7 in the T cells, NK cells, and B cells did not differ from control values. These results in the lymphoid subpopulations are in stark contrast with the observations in the myeloid populations; the percentage of cells with monosomy 7 ranged from 9% to 78% (controls: 6% +/- 2%) in cells with low CD11b expression, 20% to 89% in cells with a high expression of the CD11b antigen (controls: 7% +/- 3%), and 23% to 91% in the CD33 positive cells (controls: 5% +/- 3%). The results of this study suggest that monosomy 7 does not usually affect lymphoid subpopulations but is restricted to committed progenitor cells with the capacity to differentiate into mature myeloid cells.

Description: To help elucidate the mechanism responsible for graft failure (GF) following a T-cell depleted bone marrow transplant (BMT) from an unrelated donor, five patients (2 chronic myelogenous leukemia, 1 acute undifferentiated leukemia, 2 myelodysplastic syndrome) who experienced this complication were studied. All patients were HLA class I identical with their donors as determined by serology and one-dimensional isoelectric focusing (IEF); two were serologically matched with their donors for HLA class II antigens, whereas three donor-recipient pairs were serologically mismatched for one HLA-DR antigen. All patients received total body irradiation (fractionated, 1,500 rads), VP-16 (750 mg/m2), and cyclophosphamide (120 mg/kg) pre-BMT and antithymocyte globulin (15 mg/kg every other day) and methylprednisolone (2 mg/kg) post-BMT. Three patients experienced primary nonengraftment and two experienced secondary GF. Peripheral blood mononuclear cells obtained from the patients at the time of GF were studied to examine their functional and phenotypic characteristics. Emerging cells were of host origin and were found to be specifically cytotoxic to donor target cells and suppressive to the in vitro growth of donor BM, especially in the cases of primary nonengraftment. Peripheral blood mononuclear cells from these patients were expanded to form T-cell lines (TcLs). The cytotoxic activities of TcLs were tested in the presence of blocking MoAbs directed against various HLA determinants in an attempt to determine if HLA antigens expressed on donor cells were the target for cytotoxicity. The observed cytotoxic activity was blocked by antibodies to HLA-B, -C (1 patient), HLA-DR (1 patient), and HLA-DQ (1 patient). In two cases, antidonor cytotoxicity could not be blocked by MoAb directed against HLA-A, -B, -C, or -DR. Phenotypic characterization of four successfully maintained TcLs showed 100% CD3+ cells with 100% CD4+ (3 patients) or 50% CD4+/50% CD8+ (1 patient). In two of the three patients with 100% CD4+ cells, antidonor cytotoxicity was blocked by an anti-HLA class II MoAb. In contrast to our previous findings in cases of GF following T-cell-depleted HLA nonidentical family member BMT in which host T cells were CD8+ and cytotoxicity was directed against HLA class I antigens, our present study indicates host T cells emerging at the time of GF following BMT from an HLA class I IEF-identical unrelated donor can be of the CD4+ subset and seem to be capable of recognizing antigenic disparities in the HLA class II region.

Description: To help elucidate the mechanism responsible for graft failure (GF) following a T-cell depleted bone marrow transplant (BMT) from an unrelated donor, five patients (2 chronic myelogenous leukemia, 1 acute undifferentiated leukemia, 2 myelodysplastic syndrome) who experienced this complication were studied. All patients were HLA class I identical with their donors as determined by serology and one-dimensional isoelectric focusing (IEF); two were serologically matched with their donors for HLA class II antigens, whereas three donor-recipient pairs were serologically mismatched for one HLA-DR antigen. All patients received total body irradiation (fractionated, 1,500 rads), VP-16 (750 mg/m2), and cyclophosphamide (120 mg/kg) pre-BMT and antithymocyte globulin (15 mg/kg every other day) and methylprednisolone (2 mg/kg) post-BMT. Three patients experienced primary nonengraftment and two experienced secondary GF. Peripheral blood mononuclear cells obtained from the patients at the time of GF were studied to examine their functional and phenotypic characteristics. Emerging cells were of host origin and were found to be specifically cytotoxic to donor target cells and suppressive to the in vitro growth of donor BM, especially in the cases of primary nonengraftment. Peripheral blood mononuclear cells from these patients were expanded to form T-cell lines (TcLs). The cytotoxic activities of TcLs were tested in the presence of blocking MoAbs directed against various HLA determinants in an attempt to determine if HLA antigens expressed on donor cells were the target for cytotoxicity. The observed cytotoxic activity was blocked by antibodies to HLA-B, -C (1 patient), HLA-DR (1 patient), and HLA-DQ (1 patient). In two cases, antidonor cytotoxicity could not be blocked by MoAb directed against HLA-A, -B, -C, or -DR. Phenotypic characterization of four successfully maintained TcLs showed 100% CD3+ cells with 100% CD4+ (3 patients) or 50% CD4+/50% CD8+ (1 patient). In two of the three patients with 100% CD4+ cells, antidonor cytotoxicity was blocked by an anti-HLA class II MoAb. In contrast to our previous findings in cases of GF following T-cell-depleted HLA nonidentical family member BMT in which host T cells were CD8+ and cytotoxicity was directed against HLA class I antigens, our present study indicates host T cells emerging at the time of GF following BMT from an HLA class I IEF-identical unrelated donor can be of the CD4+ subset and seem to be capable of recognizing antigenic disparities in the HLA class II region.