Differentiation of leukemic cells induced by short-course high-dose methylprednisolone in children with different subtypes of acute myeloblastic leukemia.

Differentiation of myeloid leukemic cells to mature granulocytes by high-dose methylprednisolone (HDMP, 20-30 mg/kg/day) with a favorable antileukemic effect has previously been demonstrated in children with acute promyelocytic leukemia and acute myeloblastic leukemia (AML) M4. In the present study, three children with other morphological subtypes of AML (two AML M1, one AML M2) were given methylprednisolone (30 mg/kg/day) orally in a single dose. After a short-course (3 or 7 days) of HDMP treatment alone, a striking decrease in blast cells associated with an increase in maturing and abnormally nucleated polymorphonuclear-like cells some containing Auer rods were detected in all patients in peripheral blood or bone marrow smears. During HDMP treatment, in parallel to morphological improvements, marked increases in the percentage of cells expressing granulocytic antigen (CD15) were observed. The increase of CD15 expression on myeloid cells, together with the steady expression of CD34 and CD117 antigens in Casel(AML M1) , is suggestive of aberrant CD34 + CD117 + CD15 + cells, which may indicate the leukemic origin of the maturing myeloid cells. These results suggest that HDMP treatment may induce differentiation of myeloid leukemic cells in some children with different morphological subtypes of AML, and that the differentiation-inducing effect of HDMP should be explored in other malignant diseases.     

Flow cytometric characterization of acute myeloid leukemia: IV. Comparison to the differentiation pathway of normal hematopoietic progenitor cells.

Gradual increase of CD38 on cells expressing CD34 characterizes the early cell differentiation pathway of normal human hematopoietic progenitors. In this study the coordinated expression pattern of CD34 and CD38 was assessed on leukemic blasts from bone marrow aspirates of 95 patients with newly diagnosed acute myeloid leukemia (AML). Expression was divided into six categories analogous to the differentiation pathway of normal bone marrow. The CD38 antigen was expressed on the leukemic cells of all patients and CD34+ leukemic cells were found in 79 patients (83%). In 93 patients, the leukemic cells were found along the differentiation pathway defined by CD34 and CD38. In 33 of the 93 patients, a part of the CD34+ cells did not express the CD38 antigen (categories 1 and 2). In another 33 patients, all CD34+ cells expressed CD38 (categories 3 and 4). In the remaining 27 patients, only cells were found which dimly expressed CD34 or did not express CD34 (categories 5 and 6). Of the 93 patients, 88 were treated with intensive chemotherapy according to the protocol of the German AML Cooperative Group. Of these, 21 died early and were not evaluable for treatment response. Complete remission was achieved in 14 of 22 patients (64%) in categories 1 and 2, in 19 of 26 patients (73%) in categories 3 and 4, and in 18 of 19 patients (95%) in categories 5 and 6. The event-free survival was significantly longer in patients of categories 5 and 6 compared to patients in categories 1 and 2 (p less than 0.01) and categories 3 and 4 (p less than 0.05), respectively. We conclude that in the majority of AML patients the immunophenotype of leukemic cells follows the early cell differentiation pathways defined by coordinated expression of CD34 and CD38 similar to that of normal hematopoietic progenitors. The presence of cells in the late cell differentiation stages (CD34+/-, CD38 /+) identifies patients with a higher complete remission rate and longer complete remission duration.     

Detection of minimal residual disease in acute myeloid leukemia.

The distinction of clonogenic leukemic cells (CFU-L) and normal myeloid progenitors (GM-CFU) is a problem because both types of cells respond to the same growth factors and their clones resemble each other morphologically in culture. We investigated by means of an indirect enzyme-immunoassay the expression of "early" and "late" differentiation markers on bone marrow cell suspensions, as well as on agar clones in 18 cases of newly diagnosed acute myeloid leukemia (AML) as compared with 13 normal controls. Uncultured AML cells carried only low amounts of "late" myeloid differentiation antigen (CD15) but expressed nearly normal levels when cultured in agar with colony-stimulating factor (CSF). In contrast to normal bone marrow, AML cells were strongly reactive with "early" differentiation markers (CD10, CD20, CD34) and remained so during culture. Normal and leukemic agar clones could be specifically distinguished by CD20- and CD34 antibodies. By means of a double marker technique, it could be shown that "late" myeloid differentiation markers (CD15) and "early" markers (CD10, CD20, CD34) were coexpressed on the same cells only in AML but not in normal bone marrow. Leukemic clones were identified by phenotyping of agar clones in 17 of 19 cases investigated during complete clinical remission (CR) of the disease. A formal proof of the leukemic origin of CD20/CD34 positive clones grown in CR was made possible in four cases either by Southern blot analysis or by a cytogenetic marker. These results demonstrate that AML cells can partially differentiate in vitro in the presence of CSF. A distinction of AML from normal clones, however, is possible by their reactivity with "early" differentiation markers, because this is maintained under the differentiating influence of CSF. The technique described here identifies residual leukemic clones in the majority of AML in CR, which persist at a constant rate and increase 6 months before cytological relapse.     

Folate receptor type beta is a neutrophilic lineage marker and is differentially expressed in myeloid leukemia

BACKGROUND: The membrane-associated folate receptor (FR) type beta is elevated in the spleen in patients with chronic myeloid leukemia (CML) and acute myeloid leukemia (AML). In this study, the authors investigated possible cell type and differentiation stage specificity of expression of FR-beta in normal and leukemic hematopoietic cells. METHODS: An affinity-purified rabbit polyclonal antibody specific for FR-beta was employed for immunostaining representative bone marrow smears and peripheral blood smears from normal individuals and from a limited number of patients with various leukemias. Multiple samples of normal bone marrow and peripheral blood were analyzed for the expression of FR-beta and selected CD antigens by two- or three-color flow cytometry. RESULTS: Of the morphologically identifiable cells, only neutrophils were positive for FR-beta. The leukemic blasts in CML patients showed expression of FR-beta with no apparent relation to the occurrence of the Philadelphia chromosome. Among acute nonlymphocytic leukemias, FR-beta was expressed in promyelocytic leukemia, in the myeloblast populations of myelomonocytic and erythroleukemias, and variably in M1/M2 AML. Neither the blasts of acute lymphocytic leukemia nor the more mature cells of chronic lymphocytic and hairy cell leukemias expressed FR-beta. The less differentiated FR-beta positive AML samples also were positive for CD34 and HLA-DR. Flow cytometric analysis of normal bone marrow and peripheral blood revealed low or insignificant coexpression of FR-beta with CD34, CD19, and CD3, whereas significant coexpression was observed with high levels of CD33, CD13, and CD11b; coexpression of FR-beta with CD14 was high in the immature bone marrow cells, comparable to that in myeloid cells, but relatively low in peripheral blood. CONCLUSIONS: The results of this study suggest a narrow expression pattern of FR-beta marking the neutrophilic lineage and the possibility of defining a subtype or subtypes of myeloid leukemia based on FR-beta expression. The identification of FR-beta positive leukemias and the absence of the receptor in normal CD34 positive cells may enable selective receptor-mediated targeting of leukemic cells.     

成人急性髓系白血病的免疫学特点及预后

目的：探讨急性髓细胞白血病（AML）的免疫表型特点。方法：使用淋系和髓系单抗,用间接免疫荧光法对70例原发性AML进行免疫表型分析。结果：所有AML患者的细胞至少被1种髓系单抗标记,各髓系抗原的表达率依次为CD33＞CD13＞CD15。所有M3患者CD9为阳性。16／70例（30％）表达CD34抗原、CD34^ AML组在年龄、外周血象及骨髓原始、幼稚细胞比例等方面与CD34^-组相比较无显著差别,但表达CD34抗原的AML常伴有HLA－DR、CD38、CD7等不成熟细胞表面标记的表达,而较成熟的髓系细胞表面标记CD15则不表达。70例AML中有16例表达淋系抗原,CD4^ 例（13．8％,M2为8．8％,M460％）;CD7^ 9例（16．9％,M1为50％,M218％,M5b16．7％）。CD4^ 的AML患者CD34为低表达,CD33表达。结论：CD9^ 、CD34^-、HLA－DR^-及CD13^ 、CD15^ 是典型M3的免疫表型特点。CD34^ AMLgn AML-M1有着密切的关系,且对化疗反应较差,证明CD34^ 的AML是一组分化程度较差的类型;提示CD7^ 和CD4^ 的AML预后差,CD7^ 的AML的一种独特类型。     

Over-expression of angiotensin-converting enzyme (CD 143) on leukemic blasts as a clue for the activated local bone marrow RAS in AML

Local bone marrow renin-angiotensin system (RAS) is an autocrine-paracrine system affecting hematopoiesis. Angiotensin II type 1a (AT1a) receptors are present on the CD34+ hematopoietic stem cells. Angiotensin II stimulates the proliferation of bone marrow and umbilical cord blood hematopoietic progenitors. There are preliminary data that local RAS might also be involved in leukemogenesis. ACE hyper-function may lead to the acceleration of negative hematopoietic regulator peptide, AcSDKP, metabolism, which in turn lowers its level in the bone marrow micro-environment, finally removing the anti-proliferative effect of AcSDKP on the hematopoietic cells and blasts. Renin expression could have a role on the leukemia development and angiotensin may act as an autocrine growth factor for acute myeloid leukemia (AML) cells. The aim of this study is to search ACE (CD 143) surface antigen by flow-cytometric analyses on the leukemic blast cells taken from the bone marrow of the patients with AML. Bone marrow aspiration materials and peripheral blood samples were obtained from 11 patients with AML (eight males, three females; aged 46 (range 26-67) years) and six patients with non-malignant hematological disorders (four males, two females; aged 56 (range 22-71) years). ACE (CD 143) surface antigen was shown to be over-expressed in leukemic myeloid blast cells. ACE is positively correlated with bone marrow blast count. Elucidation of the pathological activity of the local RAS-mediated regulation of the leukemogenesis is both pathobiologically and clinically important, since the angiotensin peptides represent a molecular target in the disease management.     

Acute panmyelosis with myelofibrosis: clinical, immunophenotypic and cytogenetic study of twelve cases

The clinical, cytogenetic, and immunophenotypic features in 12 adult patients with acute panmyelosis with myelofibrosis (APMF; ICD-0-3: 9931/3; C42.1) are reported (median age: 57 years; f/m = 1.4). The white cell count (WBC) was normal in 3 patients; 9 had leucopenia. The median hemoglobin value was 64.5 g/l, and median platelet count 12 x 10(9)/l. Bone marrow biopsy showed a hypercellular marrow in 10/12 patients with a significant infiltration of pathological blasts (range: 30 - 60%). All the cases had marked reticulin fibrosis. Immunophenotyping of bone marrow blast cells showed the expression of early (CD34) and lineage-unspecified antigens (HLA-DR) in 6/7, and 7/7 patients, respectively. "Early" myeloid antigens (CD13, CD33) were seen in 6/7 and 4/6 patients respectively. Monocyte antigen (CD14) was expressed in 3/7 patients. Megakaryocyte antigen (CD61) and erythroid cell antigen (GpA) were each expressed in only 1 patient. Two patients had expression of CD34, HLA-DR and "early" myeloid antigens by their bone marrow blast cells and 1 of these also had a co-expression of the antigens from a differentiated monocytic cell proliferation (lysozyme+, CD68+). Nonspecific chromosomal aberrations were recorded in 8/10 patients. The median survival was 2 months. These findings suggest an immature myeloid phenotype of blast cells in APMF. In 6/9 patients a leukemic cell differentiation into monocytic, megakaryocytic or erythroid lineage was also demonstrated.     

Differentiation and maturation of growth factor expanded human hematopoietic progenitors assessed by multidimensional flow cytometry.

Non-adherent cord blood and bone marrow mononuclear cells were analyzed by multiparameter flow cytometry before and at day 2, 4, 7, and 11 of culture in recombinant interleukin 3 (IL-3) and granulocyte colony-stimulating factor (G-CSF, cord blood) or stem cell factor (SCF), IL3 and granulocyte-macrophage colony-stimulating factor (GM-CSF, BM) to assess the differentiation and maturational pathway of myeloid cells. Before cell culture cord blood contained progenitor cells (CD34+) in various differentiation stages (CD38(-)----CD38bright), mature lymphocytes, monocytes, and neutrophils, but no immature neutrophils and immature monocytes. During cell culture, all CD34+ cells acquired the CD38 antigen between day 2 and 5 of cell culture, the CD34 antigen was lost between day 5 and 11 of cell culture. Differentiation of cells into the myeloid cell lineage was characterized by the acquisition of both CD33 and CD71. The latter is indicative for the active proliferation of these cells. Maturation of the cells into the neutrophilic pathway was indicated by the acquisition of first the CD15 antigen followed by CD11b and CD16 respectively. Whereas maturation of the cells into the monocytic pathway was indicated by the acquisition of first CD11b followed by CD14 and a dim expression of both CD15 and CD16. In normal bone marrow, cells of various maturational stages are already present before cell culture. During cell culture differentiation of cells into the myeloid lineage and maturation of the cells along the monocyte and neutrophilic lineage followed identical pathways as was observed before cell culture. Differentiation and maturational pathways of cord blood and adult bone marrow were identical. The results confirm the surface-antigen-defined pathways of myeloid cell differentiation described previously for non-cultured normal bone marrow aspirates. The detailed assessment of cell maturation and differentiation of cultured cells by multidimensional flow cytometry permits the determination of the specific effects of various recombinant human growth factors on myeloid cells.     

HLA class I antigen cell surface expression is preserved on acute myeloid leukemia blasts at diagnosis and at relapse.

Human leukocyte antigens (HLA) class I molecules restrict the interaction between cytotoxic T cells and target cells. Abnormalities in HLA class I antigen expression and/or function may provide tumor cells with a mechanism for escaping immune surveillance and resisting T cell-based immunotherapies. The potential for applying T cell-based immunotherapy in the treatment of acute myeloid leukemia (AML) has stimulated interest in analyzing HLA class I antigen expression on leukemic blasts in this disease. Little information is available in the literature. We have analyzed HLA class I antigen expression on bone marrow samples from 25 newly diagnosed AML patients by indirect immunofluorescence staining with monoclonal antibodies. Five of these patients were also studied at relapse. Leukemic blasts were resolved from normal lymphocytes by staining with antiCD45 antibody; CD45 expression is dim on leukemia cells, but bright on lymphocytes. HLA class I antigen expression was higher on leukemic blasts than on autologous lymphocytes in all but one case. Moreover, there was no significant change in HLA class I antigen expression at relapse. These results suggest that abnormalities in HLA class I antigens are infrequent in AML and should not represent a major obstacle to the application of T cell-based immunotherapies in this disease.     

Targeted therapy of acute myeloid leukemia with monoclonal antibodies and immunoconjugates

Traditional chemotherapy for acute leukemia often causes life-threatening toxic effects due to a lack of specificity for hematopoietic cells. Monoclonal antibodies and fusion proteins that target cell surface antigens on leukemic blasts are being evaluated for their cytotoxic effects and as a means of delivering chemotherapeutic agents or radiation directly to malignant cells. It is hoped that this strategy might selectively ablate malignant cells without many of the toxic effects commonly associated with conventional chemotherapy. In acute myeloid leukemia (AML), the cell surface antigens CD33 and CD45 are especially suitable targets. Although CD33 is expressed on AML blast cells from about 90% of patients, normal hematopoietic stem cells lack this antigen, as do essentially all nonhematopoietic tissues. For that reason, anti-CD33 antibodies have been created to target malignant myeloid and immature normal cells selectively while sparing normal stem cells. Anti-CD33 antibodies have also been used to deliver radiation or a cytotoxic agent directly to leukemic cells. Since the vast majority of leukemias and normal stem cells express the cell surface antigen CD45, another targeting approach allows the delivery of myeloablative radiation to bone marrow and spleen, common sites of leukemic involvement. Consequently, ¹³¹I-labeled anti-CD45 antibody has been combined with traditional preparative regimens for patients receiving bone marrow transplantation for acute leukemia. Finally, fusion proteins such as those combining diphtheria toxin with granulocyte-macrophage colony-stimulating factor (GM-CSF) to target the GM-CSF receptor are now being evaluated in clinical trials. Both unconjugated and conjugated antibodies have shown promise in early clinical trials, and may represent appealing therapeutic alternatives for patients with AML.     

Expression of CD44 variant exons in acute myeloid leukemia is more common and more complex than that observed in normal blood, bone marrow or CD34+ cells.

CD44 is an adhesion molecule that is expressed on hematopoietic cells and has been implicated in the interactions between bone marrow stromal layers and hematopoietic progenitors. The expression of variant forms of CD44, particularly forms containing exon v6, have been associated with poor prognosis in a number of hematological malignancies. The expression of CD44 variants on normal bone marrow (BM), peripheral blood (PBMC) and CD34+ hematopoietic progenitors was compared with those expressed on blasts from 30 patients with acute myeloid leukemia (AML). Normal BM, PBMC and CD34+ progenitor cells were negative for all variants tested by flow cytometry. In contrast exon v3 was expressed on 13%, v4 on 67%, v5 on 19%, v6 on 7% and v7 on 65% of AML cases. RT-PCR and Southern blotting revealed the expression of exons v3, v6, v8, v9 and v10 in normal bone marrow and peripheral blood mononuclear cells and the expression of exons v3, v6, v8 and v10 in CD34+ progenitors. A more complex pattern of variant exon expression was observed in leukemic samples in comparison to normal hematopoietic cells. Sixty-two percent of AML cases expressed exon v3 and 70% exon v6. Exons v4 and v5 were not detected while exons v7, v8, v9 and v10 were detected in 21, 83, 71 and 92% of cases, respectively. In summary, our data demonstrate a striking increase in the complexity of CD44 variant expression in cells from patients with AML, along with surface expression of some variant CD44 proteins. Further analysis will be directed at how these alter the interaction of leukemic blasts with the bone marrow microenvironment and their diagnostic, prognostic and therapeutic potential.     

The role of platelet/endothelial cell adhesion molecule 1 (CD31) and CD38 antigens in marrow microenvironmental retention of acute myelogenous leukemia cells

In acute myelogenous leukemia (AML), leukemic cell-microenvironment interactions within various niches (stromal/osteoblastic or sinusoidal endothelial cell niches) have a role in leukemia cell survival and drug resistance. The AML leukemic cells express platelet/endothelial cell adhesion molecule-1 (CD31) and CD38, two adhesion molecules that could interact with microenvironmental elements, i.e., CD31 on the surface of marrow endothelial cells (CD31/CD31 and CD38/CD31 interactions) and hyaluronate (CD38/hyaluronate interactions). We report a physical association of these two antigens on the plasma membrane of myeloid leukemic cells. In this context, in vitro experiments done using interaction-blocking anti-CD31 and anti-CD38 monoclonal antibodies (CLB-HEC75 and OKT10, respectively) indicate that an excess of CD31 on the cell membrane of leukemic cells (CD31/CD38 MFI ratio >1) promotes a homotypic interaction with marrow endothelial cells, resulting in higher transendothelial migration. Conversely, an excess of CD38 (CD31/CD38 MFI ratio <1) allows leukemic cells to be entrapped within the bone marrow microenvironment through hyaluronate adhesion. The results obtained in vitro using fluorescence resonance energy transfer, co-capping, and co-immunoprecipitation experiments, and hyaluronate adhesion and transendothelial migration assays, are supported by immunophenotypic characterization of marrow leukemic cells from 78 AML patients on which CD38 expression levels were found to be positively correlated with those of CD31. Importantly, the excess of CD31 in those samples was associated with a higher peripheral WBC count. These findings indicate that bone marrow retention of AML cells depends on CD31 and CD38 coexpression levels.     

Migratory behavior of leukemic cells from acute myeloid leukemia patients.

The chemokine stromal cell-derived factor-1 (SDF-1) and its receptor CXCR-4 contribute to stem cell homing and may play a role in the trafficking of leukemic cells. Therefore, we analyzed migration across Transwell filters of cells derived from bone marrow (BM) or peripheral blood (PB) from 26 acute myeloid leukemia (AML) patients. The presence of the extracellular matrix protein fibronectin (FN) strongly enhanced the spontaneous and SDF-1-induced migration of leukemic PB and BM cells. No differences in spontaneous, SDF-1-induced migration or CXCR-4 expression were observed between the different AML subtypes. Subsequently, it was determined whether SDF-1 preferentially promoted migration of subsets of leukemic cells. Leukemic cells expressing CD34, CD38 and HLA-DR were preferentially migrating, whereas cells expressing CD14 and CD36 showed diminished migration. Analysis of paired PB and BM samples indicated that significantly higher SDF-1-induced migration was observed in AML for CD34(+) BM-derived cells compared to CD34(+) PB-derived cells, suggesting a role for SDF-1 in the anchoring of leukemic cells in the BM or other organs. The lower percentage of circulating leukemic blasts in patients with a relatively high level of SDF-1-induced migration also supports this hypothesis. In conclusion, we have shown that primary AML cells are migrating towards SDF-1 independent of the AML subtypes.     

Phenotyping of acute myelocytic leukemia (AML) progenitors: an approach for tracing minimal numbers of AML cells among normal bone marrow

Previous studies have shown that the phenotypes of progenitors of human AML (AML-CFU) are variable, reflecting arrests at different stages of maturation. We were interested to seek discrepancies between the surface properties of AML precursors and normal bone marrow colony formers in order to detect minimal numbers of AML cells among normal bone marrow cells in remission bone marrow. Therefore, we selected two surface markers, the MoAb CD34, reactive with blast cells, and Vim-2, a surface marker reactive with mature myeloid cells, and determined the antigen density of these markers (relative fluorescence intensity using fluorescence-activated cell sorting) for normal marrow and AML progenitors. While these markers defined an identical phenotype (CD34++/Vim-2-/+) for a broad spectrum of normal progenitors, i.e., CFU-GEMM, BFU-e, day 15 CFU-GM, and day 7 CFU-GM, referred to as the "normal" progenitor phenotype, AML progenitors frequently exhibited different phenotypes. In 12 of 20 cases the phenotypes of the majority of AML progenitors were discrepant from the normal surface profile, i.e., according to one marker in 8 cases (CD34-/+/Vim-2-/+ or CD34++/Vim-2++) and two markers in 4 cases (CD34-/+/Vim-2++). Since these data indicate that AML and normal progenitors were frequently distinguishable, we then determined the potential utility of these phenotypic dissimilarities for detection of minimal disease. Artificial mixtures of normal bone marrow and minimal numbers (0.1-1%) of AML cells were prepared. Based upon the phenotypic discrepancies, AML metaphases were successfully demonstrated in these mixtures following cell sorting and culture. Thus, it appears that minimal numbers of AML mitoses can be identified with an approximate 10(-2) to 10(-3) sensitivity by taking advantage of differential coexpression of surface antigens.     

Retinoic acid induction of CD38 antigen expression on normal and leukemic human myeloid cells: relationship with cell differentiation

Differentiation in the hematopoietic system involves, among other changes, altered expression of antigens, including the CD34 and CD38 surface antigens. In normal hematopoiesis, the most immature stem cells have the CD34+CD34 -phenotype. In acute myeloid leukemia (AML), although blasts from most patients are CD38+, some are CD38 -. AML blasts are blocked at early stages of differentiation; in some leukemic cells this block can be overcome by a variety of agents, including retinoids, that induce maturation into macrophages and granulocytes both in vitro and in vivo . Retinoids can also induce CD38 expression. In the present study, we investigated the relationship between induction of CD38 expression and induction of myeloid differentiation by retinoic acid (RA) in normal and leukemic human hematopoietic cells. In the promyelocytic (PML) CD34 -cell lines, HL60 and CB-1, as well as in normal CD34+CD34 -hematopietic progenitor cells RA induced both CD38 expression as well as morphological and functional myeloid differentiation that resulted in loss of self-renewal. In contrast, in the myeloblastic CD34+ leukemic cell lines, ML-1 and KG-1a, as well as in primary cultures of cells derived from CD34+-AML (M 0 and M 1 ) patients, RA caused an increase in CD38+ that was not associated with significant differentiation. Yet, long exposure of ML-1, but not KG-1, cells to RA resulted in loss of self-renewal. The results suggest that while in normal hematopoietic cells and in PML CD34 -cells induction of CD38 antigen expression by RA results in terminal differentiation along the myeloid lineage, in early myeloblastic leukemic CD34+ cells, induction of CD38 and differentiation are not functionally related. Since, several lines of evidence suggest that the CD38 -cells are the targets of leukemic transformation, transition of these cells into CD38+ phenotype by RA or other drugs may have therapeutic effect, either alone or in conjunction with cytotoxic drugs, regardless the ability of the cells to undergo differentiation.     

AC133 expression on acute myeloid leukemia blasts: correlation to FAB and to CD34 expression and possible implications for peripheral blood progenitor cell purging in AML

AC133 is an antigen expressed on CD34+ hematopoietic progenitor cells. In acute myeloid leukemia (AML) it is expressed on leukemic blasts of most FAB subtypes. However, few data are available regarding coexpression of other surface antigens. We measured AC133 expression on AML blasts from 28 consecutive patients at initial diagnosis (n=26) or at diagnosis of first relapse (n=2) and on 26 leukapheresis products from 14 patients. In AML AC133 correlated with CD34 expression (Spearman r=0.4711, P=0.0114) and even stronger with combined CD34/CD33 expression (Spearman r=0.5083, P=0.0068). In leukapheresis products AC133 expression correlated with CD34 expression (Spearman r=0.7495, P=0.002) and the yield of the obtained amount of CD34+ cells (Spearman r=0.6484, P=0.0121). In conclusion AC133 expression is closely related to CD34 expression in AML. In leukapheresis products AC133 provides an additional marker for selection of PBPC autografts in AC133- AML.     

Terminal deoxynucleotidyl transferase positive subpopulations occur in the majority of ANLL: implications for the detection of minimal disease

A series of 60 acute nonlymphocytic leukemias (ANLL) was analyzed for the expression of terminal deoxynucleotidyl transferase (TdT). The detected TdT+ cells were studied in detail by use of double marker analyses for TdT and differentiation markers, such as myeloid markers (CD13 and CD33), B cell markers, T cell markers, and the precursor antigen CD34. In 15 (25%) of these leukemic cell samples, we found no TdT+ cells or low percentages of CD10+TdT+ cells; the latter probably represent precursor B cells. In the other 45 (75%) ANLL myeloid marker+TdT+ CD10- cells were detected, ranging from 0.1-10% (n = 24) or over 10% (n = 21) of mononuclear cells. Interestingly, a higher frequency of CD34 positivity was found on the TdT+ cells as compared to the TdT- cells, suggesting that the TdT+ cells represent an immature leukemic subpopulation. Therefore, it may be speculated that the TdT+ subpopulation contains the clonogenic ANLL cells. In two patients, in whom immunologic marker analysis was performed at initial diagnosis as well as at relapse, an expansion of the TdT+ subpopulation was documented at relapse, which may reflect a reduced differentiation capacity of the leukemic cells. Previous studies on a series of nonleukemic bone marrow and blood samples revealed that normal counterparts of myeloid marker+TdT+ cells are rare in bone marrow (less than 0.03%, if they occur at all) and that such cells are not detectable in blood. Therefore myeloid marker TdT double stainings may be useful to monitor the TdT+ leukemic subpopulation in patients with a TdT+ ANLL during and after chemotherapy. Our preliminary results on the follow-up of two such patients support this hypothesis.     

Proliferation and apoptosis in acute and chronic leukemias and myelodysplastic syndrome

Clonal expansion of leukemic cells is thought to be due to proliferation in excess of apoptosis. To define and compare proliferation and apoptosis between various leukemias and myelodysplastic syndrome (MDS), we measured proliferating cell nuclear antigen (PCNA) and bromodeoxyuridine (BrdU) incorporation as surrogate markers for proliferation and caspase 3 activity and annexin V surface binding as surrogate markers for activation of the apoptotic cascade in patients with MDS, chronic myelomonocytic leukemia (CMML), acute myeloid leukemia (AML), acute lymphoblastic leukemia (ALL), chronic lymphocytic leukemia (CLL), and chronic myeloid leukemia (CML). We found high proliferation in bone marrow cells from MDS and CMML as measured by PCNA and BrdU incorporation. The lowest level of proliferation was found in CLL. Apoptosis was also highest in MDS and CMML as measured by annexin V and caspase 3 activity. Unexpectedly, we found no significant difference in proliferation in bone marrow CD34+ cells from various leukemias or MDS. Apoptosis was significantly higher in bone marrow CD34+ cells from MDS and CML in chronic phase as compared to CD34+ cells from AML patients. Our results illustrate differences in proliferation and apoptosis between acute and chronic leukemias and MDS. These differences may have diagnostic and therapeutic implications.