BIOMED-I concerted action report: flow cytometric immunophenotyping of precursor B-ALL with standardized triple-stainings. BIOMED-1 Concerted Action Investigation of Minimal Residual Disease in Acute Leukemia: International Standardization and Clinical Evaluation.

The flow cytometric detection of minimal residual disease (MRD) in precursor-B-acute lymphoblastic leukemias (precursor-B-ALL) mainly relies on the identification of minor leukemic cell populations that can be discriminated from their normal counterparts on the basis of phenotypic aberrancies observed at diagnosis. This technique is not very complex, but discordancies are frequently observed between laboratories, due to the lack of standardized methodological procedures and technical conditions. To develop standardized flow cytometric techniques for MRD detection, a European BIOMED-1 Concerted Action was initiated with the participation of laboratories from six different countries. The goal of this concerted action was to define aberrant phenotypic profiles in a series of 264 consecutive de novo precursor-B-ALL cases, systematically studied with one to five triple-labelings (TdT/CD10/CD19, CD10/CD20/CD19, CD34/CD38/CD19, CD34/CD22/CD19 and CD19/CD34/CD45) using common flow cytometric protocols in all participating laboratories. The use of four or five triple-stainings allowed the identification of aberrant phenotypes in virtually all cases tested (127 out of 130, 98%). These phenotypic aberrancies could be identified in at least two and often three triple-labelings per case. When the analysis was based on two or three triple-stainings, lower incidences of aberrancies were identified (75% and 81% of cases, respectively) that could be detected in one and sometimes two triple-stainings per case. The most informative triple staining was the TdT/CD10/CD19 combination, which enabled the identification of aberrancies in 78% of cases. The frequencies of phenotypic aberrations detected with the other four triple-stainings were 64% for CD10/CD20/CD19, 56% for CD34/CD38/CD19, 46% for CD34/CD22/CD19, and 22% for CD19/CD34/CD45. In addition, cross-lineage antigen expression was detected in 45% of cases, mainly coexpression of the myeloid antigens CD13 and/or CD33 (40%). Parallel flow cytometric studies in different laboratories finally resulted in highly concordant results (>90%) for all five antibody combinations, indicating the high reproducibility of our approach. In conclusion, the technique presented here with triple-labelings forms an excellent basis for standardized flow cytometric MRD studies in multicenter international treatment protocols for precursor-B-ALL patients.

BIOMED-1 concerted action report: flow cytometric characterization of CD7+ cell subsets in normal bone marrow as a basis for the diagnosis and follow-up of T cell acute lymphoblastic leukemia (T-ALL).

The European BIOMED-1 Concerted Action was initiated in 1994 to improve and standardize the flow cytometric detection of minimal residual disease (MRD) in acute leukemia (AL). Three different protocols were defined to identify the normal subsets of B, T and myeloid cells in bone marrow (BM), and were applied to the different types of AL in order to study aberrant immunophenotypes. Using sensitive acquisition methods ('live gate') T cell subsets in normal BM could be identified with five triple-stains: CD7/CD5/CD3, CD7/CD4/CD8, CD7/CD2/CD3, CD7/CD38/CD34 and TdT/CD7/surface or cytoplasmic (cy)CD3 (antibodies conjugated with FITC/PE/PECy5 or PerCP, respectively). The identification of T cell subsets in BM allowed definition of 'empty spaces' (ie areas of flow cytometric plots where normally no cells are found). All studied T-ALL cases (n = 65) were located in 'empty spaces' and could be discriminated from normal T cells. The most informative triple staining was TdT/CD7/cyCD3, which was aberrant in 91% of T-ALL cases. In most cases, two or more aberrant patterns were found. Apparently the immunophenotypes of T-ALL differ significantly from normal BM T cells. This is mostly caused by their thymocytic origin, but also the neoplastic transformation might have affected antigen expression patterns. Application of the five proposed marker combinations in T-ALL contributes to standardized detection of MRD, since cells persistent or reappearing in the 'empty spaces' can be easily identified in follow-up BM samples during and after treatment.

Flow cytometric analysis of normal B cell differentiation: a frame of reference for the detection of minimal residual disease in precursor-B-ALL.

During the last two decades, major progress has been made in the technology of flow cytometry and in the availability of a large series of monoclonal antibodies against surface membrane and intracellular antigens. Flow cytometric immunophenotyping has become a diagnostic tool for the analysis of normal and malignant leukocytes and it has proven to be a reliable approach for the investigation of minimal residual disease (MRD) in leukemia patients during and after treatment. In order to standardize the flow cytometric detection of MRD in acute leukemia, a BIOMED-1 Concerted Action was initiated with the participation of six laboratories in five different European countries. This European co-operative study included the immunophenotypic characterization and enumeration of different precursor and mature B cell subpopulations in normal bone marrow (BM). The phenotypic profiles in normal B cell differentiation may form a frame of reference for the identification of aberrant phenotypes of precursor-B cell acute lymphoblastic leukemias (precursor-B-ALL) and may therefore be helpful in MRD detection. Thirty-eight normal BM samples were analyzed with five different pre-selected monoclonal antibody combinations: CD10/CD20/CD19, CD34/CD38/CD19, CD34/CD22/CD19, CD19/CD34/CD45 and TdT/CD10/CD19. Two CD19- immature subpopulations which coexpressed B cell-associated antigens were identified: CD34+/CD22+/CD19- and TdT+/CD10+/CD19-, which represented 0.11 +/- 0.09% and 0.04 +/- 0.05% of the total BM nucleated cells, respectively. These immunophenotypes may correspond to the earliest stages of B cell differentiation. In addition to these minor subpopulations, three major CD19+ B cell subpopulations were identified, representing three consecutive maturation stages; CD19dim/CD34+/TdT+/CD10bright/CD22dim/CD45dim /CD38bright/CD20- (subpopulation 1), CD19+/CD34-/TdT-/CD10+/CD22dim/CD45+/CD38bright/ CD20dim (subpopulation 2) and CD19+/CD34-/TdT-/CD10-/CD22bright/CD45bright/ CD38dim/CD20bright (subpopulation 3). The relative sizes of subpopulations 1 and 2 were found to be age related: at the age of 15 years, the phenotypic precursor-B cell profile in BM changed from the childhood 'immature' profile (large subpopulations 1 and 2/small subpopulation 3) to the adult 'mature' profile (small subpopulation 1 and 2/large subpopulation 3). When the immunophenotypically defined precursor-B cell subpopulations from normal BM samples are projected in fluorescence dot-plots, templates for the normal B cell differentiation pathways can be defined and so-called 'empty spaces' where no cell populations are located become evident. This allows discrimination between normal and malignant precursor-B cells and can therefore be used for MRD detection.

Immunophenotypic and immunogenotypic characteristics of TCRgammadelta+ T cell acute lymphoblastic leukemia.

Thirty T cell receptor (TCR)gammadelta+ T cell acute lymphoblastic leukemias (T-ALL) were analyzed for their immunophenotype, as well as for the rearrangements and junctional regions of the TCRG and TCRD genes. In 15 cases membrane expression of TCRgammadelta proteins could be studied extensively by flow cytometry with a new Vgamma/Vdelta antibody panel. Virtually all TCRgammadelta+ T-ALLs expressed TdT, CD2, CD3, CD5, CD6, and CD7, but they were heterogeneous in their CD1/CD4/CD8 immunophenotype. The majority expressed either CD4+/CD8- or CD4+/CD8+, whereas only 7/30 TCRgammadelta+ T-ALLs lacked both antigens. Despite heterogeneity in the rearranged TCRG and TCRD genes, we found preferential protein expression of VgammaI (21/30), Jgamma2.3 (19/30) and Cgamma2 (21/30) gene products in the TCRgammadelta+ T-ALL. Expressed TCRD genes were largely limited to Vdelta1-Jdelta1, except for six patients who expressed non-Vdelta1 TCRdelta chains (Vdelta2-Jdelta1, Vdelta2-Jdelta3, Vdelta3-Jdelta1, Vdelta6-Jdelta2, and two Valpha-Jdelta1). In spite of the relatively limited combinatorial repertoire of the TCRG and TCRD genes, the junctional region diversity of the expressed genes was extensive. The Vgamma/Vdelta antibody panel confirmed the predominant, but not exclusive, expression of VgammaI and Vdelta1 proteins. Importantly, not a single T-ALL expressed the common peripheral blood Vgamma9+/Vdelta2+ phenotype. These immunogenotypic and immunophenotypic characteristics represent excellent targets for flow cytometric and PCR-based detection of 'minimal residual disease' in all TCRgammadelta+ T-ALL. Comparison of non-Vdelta1+ TCRgammadelta T-ALLs with the more common Vdelta1+ type showed a trend towards a more mature immunogenotype in the former. Firstly, more complete TCRD rearrangements were identified on the non-expressed allele in the non-Vdelta1+ group (83% vs 43%); secondly, a higher frequency of 'end-stage' Jgamma2.3 gene rearrangements was found in non-Vdelta1 cases on both TCRG alleles (83% vs 66%); thirdly, a higher frequency of complete TCRB rearrangements was found in non-Vdelta1 cases (79% vs 50%).

Comparison of single and dual-platform assay formats for CD34+ haematopoietic progenitor cell enumeration.

Most techniques for CD34+ cell enumeration are dual platform assays. That is, they derive absolute numbers of CD34+ cells from either the flow cytometrically assessed per cent (%) CD34+ cells within the nucleated cells and/or the white blood cell count from a haematology cell analyser. Recently, so-called single-platform assays have been developed, in which the absolute number of CD34+ cells is directly derived from a single flow cytometric measurement. The present study aims to compare the variation between eight laboratories in CD34+ cell counts from paired assays of 15 samples using a common single (ProCOUNT) and the local dual-platform method. Six laboratories used the 'SIHON' and two the 'ISHAGE' protocol for CD34+ cell enumeration. Use of the single-platform method reduced the inter-laboratory variation in per cent and absolute numbers of CD34+ cells, as measured by interquartile ranges, by half but did not lead to an appreciable reduction of the inter-laboratory variation in white blood cell counts. Thus, part of the reduced inter-laboratory variation obtained with ProCOUNT may have been a result of the use of standardized procedures and reagents to detect CD34+ cells. In order to eliminate any variation arising from the use of different local protocols for percentage of CD34+ cell assessments, a comparison was made of the ProCOUNT-derived absolute CD34+ cell numbers (i.e. single platform) with the dual-platform absolute CD34+ cell numbers calculated by multiplying ProCOUNT-derived percentage of CD34+ cells and with the corresponding haematology analyser-derived white blood cell count. Regardless, the interquartile ranges of absolute CD34+ cell numbers remained almost a factor of two smaller with the use of the single platform method. Thus, these results suggest that single-platform methodology can reduce the variation in absolute CD34+ cell numbers between laboratories.

Reduction of interlaboratory variability in flow cytometric immunophenotyping by standardization of instrument set-up and calibration, and standard list mode data analysis.

Two workshops addressed the question to which degree standardization of instrument set-up and calibration, and standard list mode data analysis would reduce interlaboratory variability of flow cytometric results on prestained peripheral blood mononuclear cells (PBMC). Standard instrument set-up included uniform positioning of the "windows of analysis" for the forward and sideward light scatter and fluorescence (FL) 1 (i.e., fluorescein isothiocyanate [FITC]) and 2 (i.e., phycoerythrin [PE]) parameters. Reference standards and PBMC, double-stained with FITC- and PE-conjugated monoclonal antibodies covering a wide range of FL intensities and coexpression patterns, were sent out to 25 laboratories in Workshop 1 and to 35 laboratories in Workshop 2 with the following requests: a) to set up instruments according to local and standard protocols, b) to acquire list mode data on the PBMC with both instrument settings, and c) to analyze both datasets according to local protocols. Standard analysis of the list mode data acquired with uniform instrument settings was performed centrally using so-called "latent class model" software (Van Putten et al., Cytometry 14:86-96, 1993). This software provides an automated, "no-gating" analytical method of lymphocyte immunophenotypes and employs fixed FL marker settings as defined prior to each analytical run. In Workshop 1, these markers were set in identical histogram channels for all instruments based on results obtained with a reference instrument. Standard analysis of list mode data acquired after uniform instrument set-up led only to a 13% reduction of interlaboratory variability of results as compared to data analysis using local protocols. The standard protocol for instrument set-up led to uniform positioning of relatively strong FL signals but variable positioning of unstained cells on the FL histogram scales. Hence, standard FL marker settings were inappropriate for some instruments. Therefore, instrument responses to FITC and PE signals in Workshop 2 were calibrated using microbeads labeled with FITC or PE in a range of predefined FL intensities expressed in MESF units (molecules of equivalent soluble fluorochrome). That approach allowed the positioning of the FL markers for the standard analysis on the basis of identical FL1 and FL2 intensities, expressed in MESF units, for all instruments. Standard analysis of list mode data acquired after uniform instrument set-up and calibrated FL marker settings led to a 43% reduction of interlaboratory variability as compared to data analysis to local protocols. We conclude that standard list mode data analysis using fixed FL marker settings reduces the interlaboratory variability of flow cytometric results on prestained PBMC, provided that the instruments have been set up in a uniform way and that FL markers have been standardized on the basis of calibration of each instrument's response to the corresponding FL signals.

Flow cytometric detection of intracellular antigens for immunophenotyping of normal and malignant leukocytes.

Intracellular antigens are of major importance for immunophenotyping of normal leukocytes as well as leukemias and malignant lymphomas. Immunofluorescence microscopic evaluation of cytocentrifuge preparations has remained the preferred technique for detection of intracellular antigens for a long time. Recently, flow cytometric detection of intracellular antigens has been improved by the development of new permeabilization/fixation solutions. We compared four commercially available solutions: FACS Brand Lysing Solution (FACS Brand; Becton Dickinson, San Jose, CA, USA), Fix & Perm cell permeabilization kit (Fix & Perm; An der Grub, Vienna, Austria), OptiLyse B lysing solution (OptiLyse B; Immunotech, Marseille, France), and ORTHO PermeaFix(PermeaFix; Ortho Diagnostic Systems, Raritan, NJ, USA). These solutions were evaluated for the complexity and duration of the intracellular staining procedure, the effects on light scatter patterns, and the staining results for the intracellular antigens terminal deoxynucleotidyl transferase (TdT), cytoplasmic CD3 (CyCD3), myeloperoxidase (MPO), and cytoplasmic immunoglobulin light chains (CylgL). The four methods could easily be introduced in our laboratory and had only minor effect on the light scatter patterns of the tested cell samples. Each of the four tested antigens was detectable with at least one of the four methods. Only the Fix & Perm cell permeabilization kit could be used for reliable detection of all four intracellular antigens. In a large series of 450 BM and PB samples containing various percentages of TdT+ cells, the results of flow cytometric TdT staining with FACS Brand Lysing Solution were highly comparable to the results obtained by immunofluorescence microscopy (P = <0.00001). Our comparative study shows that flow cytometric detection of the intracellular antigens TdT, CyCD3, MPO, and CylgL can now reliably be performed on a routine basis.

Detection of minimal residual disease in acute leukemia patients.

Diagnostic techniques, routinely used in clinical practice for monitoring acute leukemia patients, are able to detect only 1-5% of malignant cells. At present, two main techniques are being introduced for detection of minimal residual disease (MRD) in leukemia, namely immunological marker analysis and the polymerase chain reaction (PCR) technique with general sensitivity of 10(-4)-10(-5). Immunological marker analysis allows detection of unusual and aberrant immunophenotypes, and is usually performed by flow cytometry. PCR analysis allows detection of leukemia-specific DNA sequences, such as fusion regions of chromosome aberrations and junctional regions of rearranged immunoglogulin (Ig) genes and T-cell receptor (TcR) genes. The applicability of the immunophenotyping and PCR-mediated MRD techniques is dependent on the type of leukemia. In virtually all acute lymphoblastic leukemias, PCR analysis of Ig and TcR genes can be used, and immunophenotypic MRD detection is also possible in 70-80% of cases. In AML, immunophenotypic MRD detection can be applied in approximately 80% of cases and PCR analysis of chromosome aberrations in 25-40%. Each MRD technique has its advantages and limitations, which have to be weighed carefully to make an appropriate choice. Furthermore, standardization of the MRD techniques is needed before they are used for stratification or adaptation of treatment protocols. Finally, the clinical impact of MRD detection for the various subtypes of acute leukemias has to be established.

Early diagnosis of smoldering acute lymphoblastic leukemia using immunological marker analysis.

During a period of 9 years, we performed immunological marker analysis in 164 children with acute lymphoblastic leukemia. In four children the diagnosis acute leukemia could not be established by cytomorphological analysis of bone marrow and peripheral blood samples at initial presentation. In two of these four children a hypoplastic bone marrow was found, whereas the bone marrow of the other two children was normocellular. Using double immunological marker analysis, we detected high frequencies of CD10+, TdT+ cells in bone marrow (range: 18-53%) as well as peripheral blood (range: 0.04-19.5%). In control bone marrow and peripheral blood samples from healthy children, the frequency of CD10+, TdT+ cells does not exceed 10% and 0.03%, respectively. Based on the immunological data, a common acute lymphoblastic leukemia (ALL) was suspected. In addition, chromosome analysis revealed a high hyperdiploid (> 50 chromosomes) karyotype in three patients and t(9;22) in one patient. At 18 to 68 days after initial presentation, an ALL was diagnosed according to cytomorphological criteria in all four patients. At that time the percentage of CD10+, TdT+ cells in bone marrow and peripheral blood had increased significantly. One patient could be monitored frequently from initial presentation onwards. First a decline in the percentage of CD10+, TdT+ cells was found, although treatment consisted only of red blood cell transfusion and antibiotics. Subsequently the percentage of CD10+, TdT+ cells gradually increased until the morphological ALL diagnosis. These results illustrate that CD10, TdT double immunological marker analysis is a useful tool for early diagnosis of smoldering ALL in patients with a suspicious bone marrow, even when the bone marrow is hypoplastic.

CD5+ B lymphocytes and other lymphocyte subsets in primary Sjögren's syndrome.

CD5+ B cells and other lymphocyte subsets were analyzed by flow cytometry in patients with primary Sjögren's syndrome (pSS), in healthy subjects (HS) and in patients with various control diseases. When compared with HS, patients with pSS were found to have similar levels of CD5+ B cells and decreased levels of CD8+ T cells (P = 0.0003). When compared with patients with various other diseases, however, the number of CD5+ B cells in pSS was more than twice as high (P = 0.0002), whereas no difference was found between numbers of CD8+ T cells. When the number of CD5+ B cells was expressed as a percentage of total B cells, the results obtained were similar to those with absolute numbers. Determination of lymphocyte subsets may be used as a diagnostic aid for Sjögren's syndrome in selected patients with suspected immunological diseases of unknown type.