Distinction of eosinophilic leukaemia from idiopathic hypereosinophilic syndrome by analysis of Wilms' tumour gene expression.

In patients presenting with immature eosinophilic precursors it is notoriously difficult to distinguish acute eosinophilic leukaemia (EoL) from the benign idiopathic hypereosinophilic syndrome (HES), based on morphological, cytochemical and immunophenotyping criteria, alone. Cytogenetic analysis or fluorescence in situ hybridization (FISH) can help in discriminating between these rare haematological disorders, but often treatment decisions cannot wait for the results of these time-consuming techniques. Recently, we and others found Wilms' tumour (WT1) gene expression to be increased in virtually all patients with acute leukaemias, whereas normal haemopoietic progenitors express the WT1 gene at much lower levels or not at all. To determine whether detection of WT1 gene expression is useful to distinguish EoL from HES patients, we analysed, by RT-PCR, bone marrow or blood mononuclear cells from EoL (n=3), HES (n=3) and reactive eosinophilia patients (n = 4) for WT1 gene expression. Using our WT1-RT-PCR protocol, we found WT1 gene expression to be restricted to EoL patients. By detecting WT1 mRNA transcripts in the cerebrospinal fluid using RT-PCR, we were also able to diagnose isolated CNS-relapsed leukaemia, initially confused with bacterial meningitis, in an EoL patient. In conclusion, we show that WT1-RT-PCR is a powerful complementary diagnostic tool to distinguish acute eosinophilic leukaemia from the hypereosinophilic syndromes. This observation needs confirmation in a larger series of EoL and HES patients.

Detection by monoclonal antibodies of the Wilms' tumor (WT1) nuclear protein in patients with acute leukemia.

The WT1 gene encodes a transcriptional regulator which during embryogenesis is involved in growth control and differentiation of diverse tissues. It is also expressed in few human malignancies, including acute leukemia. We tested 3 different monoclonal antibodies (MAbs H2, H7, HCl7) and the polyvalent serum WTC-19 for WT1 protein detection in mononuclear cell (MNC) preparations of 104 newly diagnosed acute leukemia patients. Using RT-PCR, these MNC preparations were also analyzed for WT1 gene expression. MAbs H2, H7 and HCl7 and the polyclonal WTC-19 exhibited nuclear immunoreactivity in 63 of 99, 28 of 56, 38 of 60 and 22 of 43 WT1 gene-expressing leukemia samples, respectively. With these antibodies, no WT1 immunoreactivity was found in MNCs from blood of healthy volunteers, from CD34+ progenitor cell-enriched leukapheresis products of patients conditioned for peripheral stem cell harvest or from reactive bone marrow. Contrary to WTC-19, all MAbs reacted highly specifically with the WT1 protein (0.71 vs. 1.0). The WT1 protein was heterogeneously detected in leukemia blast preparations by all antibodies, irrespective of cell morphology. Very few HL60 cells and blasts from newly diagnosed leukemia patients interspersed among normal blood MNCs (50 blasts among 5 x 10(5) MNCs) were easy to identify by indirect immunofluorescence using MAbs H2 and HCl7. Taken together, MAbs H2 and HCl7 were superior to MAb H7 and the polyvalent WTC-19 in detecting the WT1 nuclear protein.

Presence of Wilms' tumor gene (wt1) transcripts and the WT1 nuclear protein in the majority of human acute leukemias.

The wt1 gene is located on chromosome 11p13 and encodes a zinc finger motif-containing transcription factor involved in regulation of growth and differentiation. Its expression was shown during embryonic development in various tissues as well as in a few human malignancies including acute leukemias. Using RT-PCR, we found wt1 gene expression in blast cells of the majority of 150 acute leukemia patients. Particularly, the wt1 transcript was detected in 12 of 14 (86%) pre-pre-B-ALL patients, in 33 of 41 (80%) cALL patients, in 23 of 31 (74%) T-ALL patients, and in 53 of 57 (93%) AML patients. Additionally, mononuclear cells from CML patients expressed the wt1 gene only when diagnosed with blast crisis. In contrast to acute human leukemias, mononuclear cells from reactive bone marrow (n = 4), and peripheral blood of healthy volunteers (n = 20), as well as normal peripheral CD34+ hematopoietic progenitors (n = 6) did not express the wt1 gene at detectable levels. Using the anti-WT1 MoAb 6F-H2 in an immunofluorescence assay on single cell level, we found the translated WT1 protein only in nuclei of leukemia blast cells but not in nuclei of normal CD34+ hematopoietic progenitor cells. Blast cells of 12 of 20 leukemia patients (60%) all tested positive for the wt1 gene expression by RT-PCR displayed a strong nuclear immunofluorescence. Its expression in the majority of human acute leukemias but not in normal mononuclear blood cells and normal CD34+ hematopoietic progenitors qualifies the wt1 gene transcript as a 'pan-acute leukemic' marker probably useful in monitoring minimal residual disease after chemotherapy and in detecting leukemic blast cells in purged or unpurged hematopoietic stem cell preparations intended to be used for autologous bone marrow transplantation.