Assessment of distribution of CD34 epitope classes in fresh and cryopreserved peripheral blood progenitor cells and acute myeloid leukemic blasts.

So far several reports have described changes in the expression of surface antigens in progenitor cells and blasts following cryopreservation. However, there are no data on the effects of cryopreservation on the expression of the three CD34 epitope classes, and on their relationship with the clonogenic capacity of PBPC collected by leukapheresis. DESIGN AND METHODS: In order to analyze the effects of freezing/thawing procedures (Eth 80C storage for 3 months) and use of dimethylsulfoxide (DMSO) on the immunophenotype profile and colony production of peripheral blood progenitor cells (PBPC) in apheresis products derived from 20 patients with stage 0-III non-Hodgkin's lymphoma (nHL), a flow cytometry study was undertaken using different CD34 monoclonal antibodies (MoAbs) capable of recognizing the 3 epitope classes of CD34 molecule (class III: HPCA-2/FITC, HPCA-2/PE, 581/FITC, 581/PE; class II: Q-Bend 10/PE; class I: ICH3/PE, BI3C5-PE, Immu-133-PE). CD34 epitope expression was also analyzed in thawed CD34+ blasts obtained from 14 patients with acute myeloid leukemia (AML), who were analyzed using a larger number (#17) of CD34 epitope class I, II, and III reactive MoAbs. RESULTS: Under our experimental conditions it was found that class III and class II CD34 epitopes (differentially resistant to enzymatic cleavage with neuraminidase, chymopapain and glycoprotease) are better preserved than class I epitope Eth sensitive to degradation Eth after cell exposure to cryoprotectant DMSO and the freezing- thawing procedures. Results further showed a concomitant decrease in class I CD34+ counts and in BFU-E colony production. A significant increase in CD34 antigen expression levels (i.e. antibody binding capacity, ABC) by cryopreserved cells stained with CD34 epitope class III, and class II reactive MoAbs was also documented, while no changes after cryopreservation were noted using class I-reactive MoAbs. The slight increase in the percentage of CD34+ cells detected after frozen storage was correlated to a concomitant decrease in the number of more mature myeloid cells (CD15+, CD13+, CD33+). Compared to pre-cryopreservation values, a slight reduction in class I CD34 epitope expression was also found in thawed CD34+ AML blasts. INTERPRETATION AND CONCLUSIONS: As far as the reduction of class I CD34 epitope is concerned, it may be hypothesized that the freezing procedure, use of DMSO, and/or lysis methodology may either damage a CD34 subset, or induce distinct alterations of the CD34 glycoprotein, possibly determining a reduction in their immunoreactivity with some CD34 MoAbs. In conclusion, this study has shown that exposure to the cryoprotectant DMSO and the freezing/thawing procedures modifies the distribution of CD34 epitopes as well as the clonogenic capacity of PBPCs from nHL patients, and CD34+ blasts from AML. These findings need to considered when selecting CD34 MoAbs for enumeration and positive selection of stem/progenitor cells for research and clinical purposes

Immunophenotype definition of the stem/ progenitor cell compartment. Implications for the identification of blast cells in acute leukemia

The defining characteristic of a stem cell is its capacity for extensive self-renewal and retention of multilineage differentiation potential (Gordon, 1993). The complex series of events required to guarantee self-renewal, proliferation and differ-entiation leads to the concept that the stem cell compartment has to be very heterogeneous and hierarchical (Ogawa, 1993). The transition from the primitive quiescent stem cell to the active functional hemopoietic cell requires various in-termediate stages characterised by the progres-sive loss of the self-renewal capacity and pro-gressive lineage restriction and commitment (Williams, 1993). This complex system is main-tained through the action of several regulatory molecules and signals originating from the he-mopoietic microenviroment. Up to now, a large number of growth factors, interleukins, and in-hibitory proteins have been identified, and their role in the regulation of the differentiation and proliferation processes have been extensively verified by many authors (Moore, 1991; Metcalf, 1993). Several positive signals for proliferation and differentiation of stem/progenitor cells have been so far recognised, including the family of colony stimulating factors -CSF (GM-CSF, G-CSF, M-CSF, fibroblast-CSF, Meg-CSF, erythropoietin), interleukins (IL-1, IL-3, IL-6, IL-11, IL-12), and related molecules (Kit-ligand etc.) (Pistoia, 1992). However, the non proliferating state may be seen either as a passive process involving ab-sence of positive signals or an active process in-volving suppressive negative regulators that act as blocking, down modulating, or reducing the function of receptors for positive regulators on stem cells. Negative regulators may also inter-fere with signal transduction pathways, transcrip-tional factors, and mRNA production or stabil-ity, through the interaction with genes activated by positive regulators. They also act indirectly by blocking the synthesis of positive regulators. Some of these hemopoietic factors, such as TGF13 (transforming growth factor), TNFa (tumor necrosis factor), IFNs (interferons), and MIP (macrophage inflammatory protein) display pleiotropic activities

Comparative analysis of different permeabilization methods for the flow cytometry measurement of cytoplasmic MPO and lysozyme in normal and leukemic cells

Using a direct one-color (fluorescein isothiocyanate; FITC) staining method with a Facscan flow cytometer, we evaluated the intracellular expression of two granular constituents of myeloid cells [myeloperoxidase (MPO) and lysozyme] on leukemic cells from 21 patients with acute myeloid leukemia (AML), and 6 patients with acute lymphoblastic leukemia (ALL). Three different permeabilization techniques were used [FACS Lysing Solution (FLy), B.Dis; Ortho-PermeaFix (OPF); Fix and Perm (F&P), Caltag] prior to monoclonal antibody (McAb) staining, in order to verify the specificity and the sensitivity of the three labelling methods towards the two model antigens. Peripheral blood cells from 15 healthy subjects and Ortho Absolute Control served as controls. Data were expressed as percentage of positivity, net fluorescence intensity, ratio between mean fluorescence intensity (MFI) of positive cells and that of isotypic controls (P/N ratio; evaluated in both geometric and arithmetic scale), and, in 12 representatives cases (7 AML, 5 normal samples), in the form of both molecules of equivalent soluble fluorochromes (MESF) and antibody binding capacities (ABC). As far as the antigenic expression of MPO and lysozyme in normal samples is concerned, F&P resulted, in our hands, in the most specific and sensitive staining, followed by FLy solution and OPF, which showed positivity for MPO, and, to lesser extent, for lysozyme in a considerable manner of lymphocytes (means 64% and 54%, respectively, for OPF and FLy; range of ABC/cell: 0.9-5.2 x 10(3)) obtained from healthy subjects. With the reference F&P permeabilizing solution, 90% and 80% of FAB M1-M5 cases were found to be positive for MPO and lysozyme, respectively. However, M1, M2, and M3 AML FAB (French-American-British) subvarieties were characterized by a brighter expression for MPO (mean ABC/cell: 89 x 10(3)) than that of lysozyme (mean ABC/cell: 12.5 x 10(3D)), whereas blast cells from patients with M5a FAB subtypes showed higher levels of lysozyme (mean ABC/cell: 65 x 10(3)) than that of MPO (mean ABC/cell: 0.1 x 10(3)). One of five cases of FAB MO AML showed a dull positivity for MPO-7 McAb. Patients with ALL were MPO and lysozyme negative using both F&P and FLy reagents, although a certain degree of positivity was documented in some cases with OPF. Taking these data together, it can be stated that the use of anti-MPO McAbs may be of great value for the diagnosis and monitoring of acute leukemia and, along with lysozyme McAb, can provide useful information in the distinction of myeloid from monocytic leukemias and in the lineage assignment of apparently biphenotypic forms. However, the methodology used for the detection of these myeloid-associated antigens is critical for a correct interpretation of cytofluorimetric data and should be taken into account when evaluating data coming from multicenter trials dealing with leukemias. A standardization of cytofluorimetric analysis of intracellular antigens is needed in order to improve the reproducibility and comparability of results in multicenter studies

Flow cytometry measurement of GM-CSF receptors in acute leukemic blasts, and normal hemopoietic cells

A quantitative analysis of expression levels of GM-CSF receptors was performed by flow cytometry in different disease categories, ie AML (n = 72), ALL (n = 18), and MDS (n = 12), as well as 12 healthy volunteers, using three different unconjugated GM-CSF/R monoclonal antibodies (McAbs) (HGM-CSFR (CD116), M5D12, 4B5F5), and appropriate standards. By using the reference HGM-CSFR McAb, in healthy subjects we found detectable levels of GM-CSF/R on blood monocytes (mean MESF (molecules of equivalent soluble fluorochrome)/cell: 36.1 x 10[3]), neutrophils (mean MESF/cell: 7.4 x 10[3]), bone marrow (BM) myelo-monocytic precursors (MESF range for the myeloid component, ie promyelocytes, myelocytes, metamyelocytes: 11.7-40.5 x 10[3], and for the monocytic lineage: 25.7-69.2 x 10[3]), and in two distinct subsets of BM CD34+ progenitor cells (GM-CSF/R dim: 2.5 x 10[3] MESF/cell, GM-CSF/R bright (10% of the total number of CD34 cells: 22.0 x 10[3] MESF/cell). In these subjects, there was no correlation between the expression levels of GM-CSF/R and CFU (CFU-GM, CFU-GEMM, BFU-E) colony production. Among the AML samples, M5D12 McAb was positive in 33%, 4B5F5 McAb in 90%, and HGM-CSF/R McAb in 78% of the cases examined (range of MESF/cell for the HGM-CSFR McAb: 0.9 x 10[3]-106.7 x 10[3]). The highest MESF values were seen in the M5 FAB subvariety (mean: 39.4 x 10[3]), where all the patients tested (n = 20) showed a strong positivity for the HGM-CSFR McAb. On the contrary, all ALL samples were GM-CSF/R negative except in two patients, who displayed a dim GM-CSF/R positivity (My+ALL: 1.3 x 10[3] MESF/cell; pro-B ALL: 1.0 x 10[3] MESF/cell). In most (>70%) M1 FAB subtypes, GM-CSF/R+ blasts co-expressed CD34low, HLA-DRhigh, CD33, CD38 antigens, and had little or no capacity to form CFU-GM colonies. GM-CSF/R+ blasts from the M5 FAB category were also positive for CD14, CD11c, CD33 and CD87. Furthermore, the number of GM-CSF/R expressed by leukemic cells from five out of 72 (7%) AML patients was above the highest values seen in normal samples (>69.2 x 10[3] MESF/cell), allowing the possibility of using this marker for the monitoring of the minimal residual disease (MRD) in a subset of AML. Cell culture studies aimed at evaluating GM-CSF receptor modulation following AML blast exposure to rhGM-CSF showed two distinct patterns of response; in the first group (6/10 cases) rhGM-CSF down-modulated GM-CSF receptors, whereas in the second group (4/10 cases), rhGM-CSF treatment was associated with either an increase or no change in the number of GM-CSF/R. In conclusion, cellular GM-CSF/R expression was variable and ranged from undetectable (ALL and a minority of AML) to very high intensities in M5 AML, and were also documented in some M0 AML, thus suggesting the concept that GM-CSF/R detection may be of help in lineage assignment of undifferentiated forms. Since the number of GM-CSF/R on AML blasts may be modulated after GM-CSF treatment, it can be postulated that the clinical use of GM-CSF in this disease may be optimized by a dynamic analysis of the number and the affinity status of GM-CSF-R in blasts and normal hemopoietic cells

Flow cytometry measurement of cytokine receptors in acute leukemias. Clinical and biologic implications

In the last few years, the molecular cloning and purification of several hemopoietic growth factors (GF) and cytokines has made it possible to use them (at least some of these GF) in the clinical setting of many haematological disorders. The main clinical use of G- CSF and GM-CSF is to stimulate recovery of’ neutropenia and/or monocytopenia following myeloablative chemotherapy, radiotherapy, and/or bone marrow transplantation. Although the administration of these CF in patients affected by neoplastic proliferaiion of 1 lymphoid origin (ALL, MM, and MI.) is widely accepted, their clinical usefulness and safety in lhe management of acute myeloid leukemia (AML) and myelodysplastic syndrome (MDS) is still controversial. However, a number of reports have shown that CM-CSF anti G-NSF could be given to AML patients, without increasing the remission and the relapse rates or shortening the life expectancy of the disease. In othter words, the risk of stimulating the leukcrnic clone using GF seems to be very low even in patients with myeloid maligriancies

Human bone marrow endothelial-colony growth before and after stem cell transplantation in non-hodgkin’s lymphoma patients.

Human bone marrow endothelial-colony growth before and after stem cell transplantation in non-hodgkin’s lymphoma patients

CD34+ leukemic cells assessed by different CD34 monoclonal antibodies

CD34 monoclonal antibodies (McAbs) are widely used to identify and isolate hemopoietic progenitors and to classify acute and chronic leukemias. We assessed the reactivity of 17 CD34 McAbs from the 5th International Workshop on Leukocyte Differentiation Antigens with a variety of cells types: normal bone marrow hemopoietic progenitors, 10 AML, 6 ALL, 11 CML. The reactivity for these McAbs was compared with that of reference CD34 McAbs (Q-Bend 10 and 8G12). For each cell population the % of McAb binding cells, the peak channel and the mean fluorescence intensity (MFI) of the positive cells was evaluated. The peak channel, the MFI and the number of positive cells varied significantly from case to case, depending on the McAb and the type of leukemia. According to the spectrum of reactivity three groups of McAbs were defined; however, 7 McAbs do not belong to any of these subgroups. These groups were not entirely in accordance with McAb classification based on enzyme cleavage that identified three epitopes of the CD34 molecule. Some reagents were found to be more specific for AML, other for ALL, CML or normal CD34+ cells. Normal bone marrow light density cells showed a significantly higher percentage of positive cells for 43A1 and MD34.2 McAbs compared to that documented for the remaining McAbs. AML cells showed the most variable pattern of expression for the CD34 McAbs. In leukemic samples, MESF (molecular equivalents of soluble fluorochrome) values ranged from 18,200 to 322,000 and the number of binding sites per cells was 5,000-81,000.(ABSTRACT TRUNCATED AT 250 WORDS

Flow cytometry evaluation of urokinase-type plasminogen activator receptor (UPA-R) in acute myeloid leukemia cells.

The aim of this study was to investigate by flow cytometry the expression of the UPA-R (Urokinase type plasminogen activator receptor-CD87) on the blastic population of AML and ALL patients in order to evaluate whether the presence of this molecule could be associated with peculiar clinical and biologic features of leukemic cells. Five different monoclonal antibodies (MoAbs) (clones: 3B10#; VIM5*; 109#; 68#; 100#) were used in order to detect the distinct forms of this cellular receptor. Cell reactivity varied significantly from case to case, also depending on the MoAb used for the flow cytometry analysis. In brief, 3B10# and VIM5* MoAbs were found to be positive in more than 90% of monocytes and neutrophils from healthy subjects, while the number of positive cells was decreased (60%) using the 109# MoAb. However, either 68# and 100# MoAbs recognised only a low number of blood monocytes and neutrophils (8-20%), while lymphocytes were unreactive with all the five UPA-R MoAbs. ALL cells were found to be CD87 negative in all cases. Blasts from AML showed a heterogeneous pattern of expression for the UPA-R MoAbs, being the reactivity strictly dependent on the MoAb used, and, to a higher extent, on the degree and type of maturation of the blastic cells. The number of blasts recognising 3B10# and VIM5* MoAbs was significantly higher than that reacting with the remaining MoAbs irrespective of the FAB subtype. Since proteolytic enzymes, like UPA, play a key role in the dissolution of the extracellular matrix, and in facilitating the cell egress from the bone marrow, it is conceivable that the expression of the UPA-R could contribute to the invasive properties and, possibly, metastatic potential of leukemic cells