Differential distribution of CD4(+)CD25(bright) and CD8(+)CD28(-) T-cells in decidua and maternal blood during human pregnancy.

During pregnancy several maternal and fetal mechanisms are established to prevent a destructive immune response against the allogeneic fetus. Despite these mechanisms, fetus specific T-cells persist throughout gestation but little is known about the regulation of these T-cells. Recently, CD4(+)CD25(+) regulatory T-cells have been identified in human decidua. Human decidua forms the maternal part of the fetal-maternal interface and is subdivided in two distinct regions: the decidua (d.) basalis and the decidua (d.) parietalis. The aim of this study was to determine the distribution of specific T-cell subsets in d. basalis and d. parietalis in early and term pregnancy, with a special emphasis on the presence of CD4(+)CD25(bright) (regulatory) T-cells and CD8(+)CD28(-) (suppressor) T-cells. In addition, we compared phenotypic characteristics of decidua derived T-cell subsets with maternal peripheral blood (mPBL) T-cells and T-cells from non-pregnant controls. We identified significantly higher percentages of CD4(+)CD25(bright) and CD8(+)CD28(-) T-cells in decidua compared to peripheral blood suggesting an important role for these T-cell subsets locally at the fetal-maternal interface. The major differences in T-cell subset distribution and the presence of additional phenotypic differences between T-cells in d. basalis, d. parietalis and mPBL may reflect specific immunomodulatory functions of these T-cell subsets at these different sites during pregnancy.

Bcl-2 protein expression is not related to short survival in multiple myeloma.

The oncoprotein bcl-2 can be expressed in malignant plasma cells and might play a role in the prevention of corticosteroid-mediated apoptosis, thereby prolonging survival of the myeloma cells. We retrospectively investigated whether bcl-2 expression in bone marrow plasma cells measured by two-color fluorescence for immunoglobulin light chains would be related to survival duration in patients suffering from multiple myeloma. In all patients the large majority of plasma cells expressed bcl-2 (median 91%, range 74-100%). Contrary to our expectations, a tendency was observed toward higher percentages bcl-2+ plasma cells in patients with a long survival (more than 5 years, n = 9) vs patients who died from refractory myeloma within a year of diagnosis (n = 7). This tendency was found even when analysis was extended to include four patients in the short diagnosis group (n = 11) who had received chemotherapy prior to bone marrow examination.

Combined immunophenotyping and DNA in situ hybridization to study lineage involvement in patients with myelodysplastic syndromes.

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.

Variable MLC stimulatory capacity of neoplastic B and non-B/non-T lymphocytes expressing HLA-DR antigens.

Neoplastic cells from patients with a variety of B- or non-B/non-T-lymphoid malignancies, including chronic lymphocytic leukemia, various histologic types of non-Hodgkin lymphoma and acute lymphocytic leukemia, showed strong variation with respect to stimulatory capacity in mixed lymphocyte culture (MLC). MLC stimulatory capacity was either normal or strongly decreased in comparison with that of normal lymphocytes despite the expression of HLA-DR antigens and p23,30 ("Ia-like") determinants on the tumor cells of all patients. Strongly decreased stimulatory capacity of HLA-DR-positive tumor cells could not be ascribed to suppressive activity of the tumor cells. Tumor cells from three patients with a T-cell malignancy failed to stimulate in MLC and did not react with anti-p23,30 serum. The decreased stimulatory capacity of many DR-positive neoplastic cells is ascribed either to altered membrane presentation of DR antigens or to the absence of MLC stimulatory determinants specified by genes closely linked to, but different from, those coding for DR.