Expression of the CD117 antigen (C-Kit) on normal and myelomatous plasma cells

Summary. The surface expression of CD117 on plasma cells (PCs) from normal individuals and patients with multiple myeloma (MM) has been analysed using triple-stained cells for flow cytometry. In addition, the clinical significance of CD117 expression in MM patients and its possible value for the evaluation of minimal residual disease was explored. A total of 11 healthy volunteers and 56 untreated MM patients were included in the study. The expression of CD117 was analysed by flow cytometry, using simultaneous staining with the MAbs BB4, CD117 and CD38. Cell acquisition was performed in two consecutive steps using a live gate drawn on SSC/CD38⁺⁺⁺ cells and a total of 300000 events were acquired. For data analysis, the Paint-a-Gate Plus software (Becton Dickinson) was used. PCs were identified according to their strong reactivity for CD38 and their positivity for BB4, as well as by their light scatter distribution. Dilution experiments of CD117⁺ myelomatous PCs with normal bone marrow (BM) cells were performed in order to assess the sensitivity level of the technique for detection of CD117⁺ residual PCs. None of the PCs from normal BM samples showed reactivity for the CD117 antigen. In contrast, CD117 antigen was present in 18/56 MM patients (32%), the proportion of positive cells in these cases being as high as 92·1 ± 9%. Therefore, within PC lineage the c-Kit antigen would be restricted to the myelomatous population and thus could be considered as a “tumour-associated marker” for monitoring minimal residual disease in about one third of MM patients. Dilution experiments indicate that the detection limit with this marker would be 10^?4 (one myelomatous PC/10⁴ normal BM cells). Upon comparing the clinical and haematological disease characteristics of CD117-positive and CD117-negative cases, no significant differences were found.     

Prognostic implications of DNA aneuploidy in 156 untreated multiple myeloma patients

In this study the incidence of DNA aneuploidy in a large series of untreated multiple myeloma (MM) patients was assessed in order to determine its clinical and prognostic significance. A total of 156 MM patients were included in the study. DNA measurements were performed in all cases at diagnosis using two different flow cytometry methods: (1) propidium iodide (PI) staining on isolated nuclei, and (2) CD38/PI double staining on whole cells. The DNA ploidy status was correlated with the most relevant clinical and haematological disease characteristics. From the 156 cases analysed, 91 (58%) were aneuploid (56% hyperdiploid and 2% hypodiploid). The correlation between the two techniques on the detection of DNA aneuploidy was excellent, although CD38/PI double staining would be preferable in cases with <5% of DNA aneuploid plasma cells (PC). Upon comparing the clinical and haematological disease characteristics of hyperdiploid versus diploid cases, the former group was characterized by a lower age, reduced incidence of anaemia, lower 02M levels, higher proliferative activity within the residual normal haemopoietic cells, increased expression of CD 5 6 antigen in PC, and higher proportion of PB CD4⁺ T cells. In contrast, diploid cases had a higher expression of the CD10, CD20 and CD15 antigens and greater numbers of PB CD56⁺CD3 NK cells (P < 0–05). Circulating PC were identified in six cases, all being diploid. Overall survival was significantly longer in hyperdiploid compared to diploid MM (P = 0–02).     

New markers for minimal residual disease detection in acute lymphoblastic leukemia

To identify new markers for minimal residual disease (MRD) detection in acute lymphoblastic leukemia (ALL), we compared genome-wide gene expression of lymphoblasts from 270 patients with newly diagnosed childhood ALL to that of normal CD19?CD10? B-cell progenitors (n = 4). Expression of 30 genes differentially expressed by ≥ 3-fold in at least 25% of cases of ALL (or 40% of ALL subtypes) was tested by flow cytometry in 200 B-lineage ALL and 61 nonleukemic BM samples, including samples containing hematogones. Of the 30 markers, 22 (CD44, BCL2, HSPB1, CD73, CD24, CD123, CD72, CD86, CD200, CD79b, CD164, CD304, CD97, CD102, CD99, CD300a, CD130, PBX1, CTNNA1, ITGB7, CD69, CD49f) were differentially expressed in up to 81.4% of ALL cases; expression of some markers was associated with the presence of genetic abnormalities. Results of MRD detection by flow cytometry with these markers correlated well with those of molecular testing (52 follow-up samples from 18 patients); sequential studies during treatment and diagnosis-relapse comparisons documented their stability. When incorporated in 6-marker combinations, the new markers afforded the detection of 1 leukemic cell among 10(5) BM cells. These new markers should allow MRD studies in all B-lineage ALL patients, and substantially improve their sensitivity.     

CD106 and activated-CD29 are expressed on myelomatous bone marrow plasma cells and their downregulation is associated with tumour progression

Malignant plasma cells (PC) from multiple myeloma (MM) patients characteristically home to the bone marrow (BM). High numbers of tumour cells are found in the peripheral blood (PB) only at end-stage disease (secondary plasma cell leukaemia, PCL) in a minority of patients. Using flow cytometric and fluorescence in situ hybridization (FISH) analysis, a high percentage of tumoral BM PC from untreated patients was found to express CD106. In addition, these cells also expressed an activated form of CD29, as determined using the CD29 activation reporter monoclonal antibody HUTS-21. Adhesion-binding experiments showed that CD106+-activated CD29+ BM PC from these patients adhered to fibronectin (FN) in a CD29/CD49d-dependent manner. In contrast, marrow PC from progressive patients and BM or circulating malignant cells from secondary PCL patients expressed lower levels or were negative for CD106 and activated CD29, respectively, with a decreased or zero ability to adhere to FN. The expression of constitutive CD29 and CD49d, however, was similar during disease progression. We conclude that BM myelomatous cells co-express CD106 and a functionally active form of CD29. Moreover, our results suggest that the loss of expression and/or function of these antigens are associated with the progression of MM and may explain the exit of tumoral cells from the BM.     

Flow cytometry of peripheral blood and bone marrow cells from patients with hairy cell leukemia: phenotype of hairy cells, lymphocyte subsets and detection of minimal residual disease after treatment

By flow cytometry (FC) and an extensive panel of markers we characterized leukemia cells from the peripheral blood (PB) and bone marrow (BM) of 13 symptomatic patients with hairy cell leukemia (HCL). Hairy cells (HCs) identified in the large cell gate always expressed B-cell markers - CD19, CD20, CD22, HLA-DR, and 'HCL-restricted' markers - CD22+CD11c, CD25 and CD103. Other markers, not followed regularly, were occasionally expressed, such as CD34, CD38, CD71, CD15, CD10 and kappa/lambda light chains. Furthermore, in one patient with suspect but not proved HCL in PB or BM, neither morphologically nor immunologically, we confirmed the diagnosis of HCL. Only the immunophenotyping of splenic cells after splenectomy confirmed HCL diagnosis. Flow cytometry was repeated at 3-5 month intervals, after treatment with 2-Chlorodeoxyadenosine (CdA) or less frequently alpha-interferon (IFN). We investigated serially lymphocyte subsets after treatment and we found profound and persistent CD4+ lymphopenia in majority of studied patients after CdA treatment. Simultaneously we investigated the value of FC to detect minimal residual disease (MRD) and to establish, whether MRD+ could predict relapse. Detection of MRD in our series predicted hematological relapse only in one case with persistent MRD+, in majority of cases with occasionally found MRD+ phenotype, did not. Using quantitative immunophenotyping we observed significantly higher values of molecule numbers of hairy cell B-cell markers, comparing to B-cells in nonleukemic gate of the same sample. Our study showed 1) the diagnostic value of FC in management of HCL patients, 2) long-lasting response in the majority of patients after CdA, 3) a profound and persistent CD4+ lymphopenia in CdA treated patients, 4) some correlation between persistent MRD staining and hematological relapse, and 5) further, till now not described activated feature of HCs, given by the increased values of molecular numbers (molecules of equivalent soluble fluoresceine - MESF) in B-cell antigens of HCL.     

Comprehensive characterization of circulating and bone marrow-derived multiple myeloma cells at minimal residual disease

The presence or absence of minimal residual disease (MRD) in patients with multiple myeloma (MM) has emerged as a useful marker to determine the depth of remission. MRD negativity as an endpoint has been shown to be associated with improved progression-free survival in many studies. MRD detection is therefore part of numerous clinical trial protocols for MM. At the present time, two methodologies are most widely accepted for MRD detection: (1) multicolor flow cytometry and (2) next-generation sequencing-based clonotype detection. While both of those methodologies enable accurate quantification of MRD in the bone marrow (BM), with sensitivity as low as 10⁻⁵ to 10⁻⁶, there are several limitations to these methods. First, these approaches reveal the presence or absence of MRD but provide limited molecular information about MM. More comprehensive characterization of MM cells at the MRD stage may identify molecular mechanisms of drug resistance. Second, MRD detection in the BM is typically performed at one time point only, but more frequent detection may define the duration of the MRD status and thus refine its prognostic value. Third, less-invasive approaches that avoid the discomfort and risk associated with BM biopsy would be highly desirable, especially in elderly or frail patients. “Liquid biopsy” for the detection and characterization of circulating MM cells may address these issues. Although MRD detection in the peripheral blood at the same sensitivity as in the BM may be challenging, the identification of patients who do not achieve MRD negativity might reduce the need for BM biopsies. Here, we give an overview of approaches that have been described to detect and characterize MM cells when they occur at very low frequencies in the peripheral blood or in the BM, emphasizing recently described next-generation sequencing approaches for more comprehensive characterization of circulating MM cells.     

Detection of 13q abnormalities in multiple myeloma using immunomagnetically selected plasma cells

Accurate prognostic evaluation of patients with multiple myeloma (MM) is required for their stratification for more adequate therapy. Chromosomal G-banding and interphase fluorescence in situ hybridization (FISH) on cell-nonspecific samples and on myeloma cells selected by magnetic-activated cell separation (MACS) were used to study 13 samples from 12 multiple myeloma (MM) patients. Bone marrow (BM) samples were analysed using three approaches. Standard mitotic samples were prepared and analysed after G-banding. Interphase FISH was performed to detect the 13q14 deletion in unselected BM cells. In parallel, myeloma cells were selected from the BM using the CD138-specific antibody. The high-purity myeloma cell suspension was then analysed by interphase FISH for the 13q14 deletion. Magnetic separation yielded enriched myeloma cell suspensions with the mean viability of 98.0% (range: 97.0%-99.0%), and the purity of 97.6% (range: 87.2%-99.2%) as detected morphologically, and 85.2% (range: 44.8%-98.4%) as detected by immunophenotyping for CD138+ cells. Interphase FISH revealed the 13q14.3 deletion in 5 of 13 (38.5%) of cell-nonspecific samples and in 9 of 13 (69.2%) of enriched myeloma cell suspensions. In conclusion, interphase FISH on immunomagnetically selected MM cells increases the detection of the 13q14 deletion in BM samples from the patients with MM.     

Hairy cell leukemia: early immunophenotypical detection and quantitative analysis by flow cytometry

The abnormal coexpression of the so-called 'HCL-restricted' markers (CD22+CD11c, CD25 and CD103) identified on monotypic, slightly large B-lymphocytes in the large cell-gate of dot-plots has previously been shown to be highly characteristic of hairy cell leukemia (HCL). The main aim of our present study was to determine if patterns with low levels of neoplastic cells in bone marrow (BM) or peripheral blood (PB) are of a value the early diagnosis and/or detection of minimal residual disease (MRD) in HCL. Next we wished to determine if quantitative immunophenotyping given by molecules of equivalent soluble fluoresceine (MESF) could help to distinguish pathologic B-lymphocytic pool from that of normal residual B-cells also in patients with low numbers of HCL cells. The abnormal immunophenotypes were studied in 174 specimens from 19 patients with suspect HCL or during follow-up of already treated patients. For evaluation of marker density fluorescent calibration microbeads were used. In 12 HCL patients (67%) permanent complete remission was observed after treatment. In 6 patients (33%) transient MRD+ phenotype was identified but the clinical manifestation of relapse was followed till now in only three patients. One patient was phenotyped just only at diagnosis. The pathological cells in low levels were found in 5 patients at diagnosis (in the range from 2 to 12%) and in patients with MRD+ phenotype they were recognized repeatedly in the range from 2 to 8%. Furthermore, we observed in hairy cells significantly higher values of molecule numbers of some B-cell markers, comparing to that of residual B-cells in nonleukemic lymphocyte gate of the same sample. We found profound and persistent CD4+ lymphopenia in all but one studied patients after CdA treatment. Conclusions: Flow cytometric immunophenotyping of PB and BM is highly sensitive and specific method and is capable to detect low levels of malignant cells in HCL. Quantitative analysis of MESF values of pathological B-cells comparing to normal residual B-cells seems to be another new marker of HCL in common, which is reliable detecting also small cell numbers in examined sample. A long-term decline of CD4+ T-cells correlated with the relatively low incidence of clinical progression of HCL.     

Detection of minimal residual disease in B-lineage acute lymphoblastic leukaemia by quantitative flow cytometry

The clinical significance of detecting minimal residual disease (MRD) in B-lineage acute lymphoblastic leukaemia (ALL) was evaluated by quantitative flow cytometry using a combination of TdT with CD10 and CD19. 53 patients with B-cell precursor ALL were followed during and after completion of treatment (median follow-up 23 months). Nine patients relapsed and MRD had been detected in six of them, 5–15 weeks before relapse despite morphological complete remission. 43 patients remain in clinical remission and in none of these was MRD detected. Disease-free survival based on the detection of MRD by flow cytometry showed a statistically significant difference between both groups ( P  < 0.0001). The absence of MRD correlates with a low relapse rate, whereas the presence of MRD predicted early relapse. This study has shown that flow cytometry can improve the morphologic assessment of bone marrow (BM) remission status in B-lineage ALL. The finding of < 5% blasts in BM aspirates did not correlate with 'true' remission in a proportion of cases as residual leukaemic blasts were detected by flow cytometry in nine samples from six patients. On the other hand, the presence of > 5% blasts assessed by morphology was not necessarily a feature of relapse in five patients as these cells were shown to have a phenotype identical to normal TdT-negative B-cell precursors. Quantitative flow cytometry was more informative than conventional morphology to assess remission status and showed a strong correlation with clinical outcome. This methodology is useful to define MRD in the majority of patients with B-lineage ALL and should be tested in prospective clinical trials.     

CD34+ cell subpopulations detected by 8-color flow cytometry in bone marrow and in peripheral blood stem cell collections: application for MRD detection in leukemia patients

Fast development in polychromatic flow cytometry (PFC) makes it possible to study CD34+ cells with two scatter and eight fluorescence parameters. Minimal residual disease (MRD) is determined as persistence of leukemic cells at submicroscopic levels in bone marrow (BM) of patients in complete remission. MRD can be present in collections of hematopoietic stem cell from blood (HSC-B). Using PFC, we have defined patterns of antigen expression in CD34+ cell subpopulations in BM and applied them as templates in MRD analysis. Twelve BM samples from hospital control (HC) patients with no signs of hematological malignancy were studied using five 8-color monoclonal antibody combinations detecting subsets of CD34+ cells. These patterns have been used as templates to determine levels of MRD in HSC-B collections from six AML patients. Several subsets of CD34+ precursor cells were found to be present at very low frequencies (<10⁻⁴) in BM and/or HSC-B collections. All six HSC-B collections from AML patients showed MRD by 8-color technique and only three by previously applied 3-color method. The 8-color technique showed promising results in efficient detection of different CD34+ subpopulations of HSC-B and in MRD quantification. Monitoring of MRD should become a part of quality control of HSC-B collections.     

Minimal residual disease detection defined as the malignant fraction of the total primitive stem cell compartment offers additional prognostic information in acute myeloid leukaemia

Introduction: Immunophenotypic detection of minimal residual disease (MRD) in bone marrow (BM) of acute myeloid leukaemia (AML) patients is of high prognostic relevance. Standard MRD percentage is assessed as a percentage of total white blood cells (WBCs) and is therefore highly dependent on WBC count. Peripheral blood (PB) contains more than five times lower MRD percentages. Therefore, PB in BM aspirates cause dilution of the MRD cells, possibly leading to false‐negative results for BM MRD. The latter is avoided when relating the fraction of malignant primitive cells, identified by aberrant marker expression [aberrant primitive cells (aPC)], to the total population of primitive cells. Such a fraction may in addition reflect an important biological parameter. Methods: As this approach is thus independent of WBC count and the total size of the primitive compartment, we investigated the role of aPC fractions on overall and relapse‐free survival (RFS) in 98 patients with AML under the age of 60. Results: We show that this approach identifies MRD‐negative (as defined by % of WBC) but aPC‐positive (as defined by % of primitive cells) patients with poor outcome after both first and second induction cycle of chemotherapy. Conclusion: As a result, in cases with a primitive marker present, RFS is best predicted when combining standard MRD percentage with aPC fractions.     

Impact of two independent bone marrow samples on minimal residual disease monitoring in childhood acute lymphoblastic leukaemia

Minimal residual disease (MRD) diagnostics are used for risk group stratification in several acute lymphoblastic leukaemia (ALL) treatment protocols. It is, however, unclear whether MRD is homogeneously distributed within the bone marrow (BM) and whether this affects MRD diagnostics. We, therefore, analysed MRD levels in 141 paired BM samples (two independent punctures at different locations) from 26 ALL patients by real-time quantitative polymerase chain reaction (PCR) analysis of immunoglobulin and T-cell receptor gene rearrangements. MRD levels were comparable in 112 paired samples (79%), whereas two samples (both taken at day 15) had MRD levels that differed more than threefold. In the remaining 27 paired samples, MRD could be quantified or detected in one sample only. In four patients, MRD-based risk group classification was dependent on the site of BM puncture. Repetition of MRD analyses using 10-fold replicates instead of triplicates resolved most differences. In conclusion, MRD levels in paired BM samples were highly comparable, indicating that it is sufficient to analyse MRD in a single sample only. Nevertheless, MRD-based risk group classification can differ between paired BM samples, mainly because of variation below the quantitative range of the PCR assay rather than to a different distribution of leukaemic cells within the BM.     

Fibroblast activation protein (FAP) is upregulated in myelomatous bone and supports myeloma cell survival

The microenvironment plays a critical role in facilitating cancer progression and metastasis. We previously demonstrated the ability of osteoclasts to support primary myeloma plasma cell (MM PC) growth. Our study on the role of the bone marrow (BM) microenvironment in myeloma, using global gene expression profiling, has identified fibroblast activation protein (FAP) as one of 28 genes significantly overexpressed in cocultured osteoclasts. Because FAP has been previously implicated in tumorigenesis and shown to be selectively expressed by the reactive stroma of epithelial tumours, we focused our study on the role of this serine protease in myeloma. Using quantitative polymerase chain reaction amplification, we demonstrated upregulation of FAP by cocultured osteoclasts and mesenchymal stem cells, and in whole myelomatous human bone in SCID-hu mice. Immunohistochemical analysis of myelomatous bone sections revealed FAP expression by osteoclasts, osteogenic cells, fibrotic stroma and certain adipocytes and vascular endothelial cells. FAP was not expressed in PCs by all these methods. Inhibition of FAP expression with the use of small-interference RNA reduced MM PC survival in cocultures. Our results indicate that FAP is critical for the interaction of MM cells with the BM microenvironment--a potential therapeutic target in myeloma.     

The significance of minimal residual disease in hairy cell leukaemia treated with deoxycoformycin: a long-term follow-up study

We investigated the clinical significance and long-term follow-up of detecting minimal residual disease (MRD) in hairy cell leukaemia (HCL) in complete remission (CR) after treatment with deoxycoformycin (DCF). MRD was assessed in 23 patients by immunophenotyping peripheral blood and bone marrow frozen sections using a panel of antibodies, CD11c, CD25, CD103 and HC2, which detect hairy cells. 31 cases with active HCL were used as controls. 10/23 patients (43%) had MRD in bone marrow (seven), blood (one) or both sites (two) which was not detected on haematoxylin–eosin bone marrow sections nor by immunohistochemistry on paraffin sections in six cases tested. Sequential studies in four cases did not show changes in the amount of MRD. At a median follow-up of 72 months (range 15–108), 5/23 (22%) patients have relapsed with a median time of 59 months (range 15–105). MRD was detected in three of the five patients who relapsed. In the two patients with negative MRD, one relapsed with an abdominal mass and the other was a late relapse at 84 months. MRD was also documented in 7/18 patients who continued in clinical CR for a median of 80 months (range 63–98). There were no statistical differences in disease-free survival between MRD⁺ and MRD⁻ patients ( P   =  0.8). Our findings indicate that relapse after long-term remission achieved with DCF cannot be predicted when MRD is detected by sensitive methods. A search for other parameters such as proliferative rate of the residual cells or chest and abdominal CT scan might identify patients with a higher probability of disease recurrence.     

New insights into the biology of multiple myeloma using a combination of May-Grünwald-Giemsa staining and fluorescence in situ hybridization techniques at the single cell level

Up to now only limited information is available about the significance of chromosomal aberrations in multiple myeloma (MM) and about the time point of the neoplastic transformation. Fluorescence in situ hybridization (FISH) combined with standard May-Grünwald-Giemsa (MGG) staining or immunophenotyping on a single cell level were applied. Bone marrow (BM) samples were obtained from 11 patients with morphologically proven multiple myeloma. For detection of the chromosomal aberrations, we used FISH on interphase nuclei with commercially available centromere-specific probes for chromosomes 1, 7, 9, 11, 15, and 17 and further DNA probes for 5p13, 5q31, Rb-gene (13q14), cyclin D1 gene (11q13), and p53 gene (17p13). The aberration rate differed between 14% and 71% on bone marrow smears. Using the combination of MGG and FISH we analyzed eight patients. A total of 2622 bone marrow cells were morphologically identified and investigated for their specific chromosomal aberrations. For all probes applied, 57 cells of the erythropoietic lineage, 698 cells of the granulopoietic lineage, and 168 lymphocytes showed two normal FISH signals. Of 1723 nuclei of plasma cells, 464 (26.9%) were also not aberrant, whereas all other nuclei of plasma cells (n=1259, 73%) showed a specific aberration. Combination of fluorescence immunophenotyping and in situ hybridization (FICTION) was applied in 10 of 11 patients. Seventy-eight investigated CD34-positive precursor cells did not show any specific aberration detected before in the plasma cell compartment. In conclusion, the combination of MGG and FISH on a single cell level demonstrated that only plasma cells bore the chromosomal aberration and MM did not evolve at an early cell level.     

Contribution of flow cytometric immunophenotyping and bone marrow trephine biopsy in the detection of lymphoid bone marrow infiltration in non-Hodgkin's lymphomas

The bone marrow (BM) is a frequent site of involvement in non-Hodgkińs lymphomas (NHL) and evidence of an infiltrated BM may implicate different therapeutical regimens. Flow cytometric immunophenotyping of bone marrow aspirates now is included in the assessment of patients with NHL and used as an adjunct to morphologic evaluation in the staging of lymphoma. The aim of the study was to compare flow cytometric immunophenotyping of BM and paraffin section staining of BM biopsies in the marrow involvement of NHL. Cytometric immunophenotyping of bone marrow and immunohistochemical paraffin section staining of bone marrow biopsies in 53 B- and T-cell lymphoma patients were performed. We used the following fluorochrom conjugated monoclonal antibodies specific for: CD3, CD4, CD5, CD7, CD8, CD10, CD19, CD20, CD22, CD23, CD79B, FMC7 and Ig kappagamma light chain. Unilateral BM trephine biopsies were obtained in all cases, fixed, decalcified and paraffin-embedded. Morphologic marrow involvement by lymphoma was found in 24 cases; flow immunophenotyping identified 26 cases with NHL: morphology-positive/flow-positive (n=21), morphology positive/flow-negative (n=3), morphology-negative/flow-positive (n=4), and morphology-negative/flow-negative (n=23). The concurrence rate of BM trephine biopsy and flow cytometric immunophenotyping in evaluation of NHL bone marrow infiltration was 88.7%. Immunophenotyping of the bone marrow of NHL patients by flow cytometry is helpful for assessment of bone marrow infiltration, especially in B-cell disorders. Both trephine biopsies and flow cytometry are better than single investigation for detection of infiltration in NHL.     

Early immunophenotypical evaluation of minimal residual disease in acute myeloid leukemia identifies different patient risk groups and may contribute to postinduction treatment stratification

Early response to therapy is one of the most important prognostic factors in acute leukemia. It is hypothesized that early immunophenotypical evaluation may help identify patients at high risk for relapse from those who may remain in complete remission (CR). Using multiparametric flow cytometry, the level of minimal residual disease (MRD) was evaluated in the first bone marrow (BM) in morphologic CR obtained after induction treatment from 126 patients with acute myeloid leukemia (AML) who displayed aberrant phenotypes at diagnosis. Based on MRD level, 4 different risk categories were identified: 8 patients were at very low risk (fewer than 10(-4) cells), and none have relapsed thus far; 37 were at low risk (10(-4) to 10(-3) cells); and 64 were at intermediate risk (fewer than 10(-3) to 10(-2) cells), with 3-year cumulative relapse rates of 14% and 50%, respectively. The remaining 17 patients were in the high-risk group (more than 10(-2) residual aberrant cells) and had a 3-year relapse rate of 84% (P =.0001). MRD level not only influences relapse-free survival but also overall survival (P =.003). The adverse prognostic impact was also observed when M3 and non-M3 patients with AML were separately analyzed, and was associated with adverse cytogenetic subtypes, 2 or more cycles to achieve CR, and high white blood cell counts. Multivariate analysis showed that MRD level was the most powerful independent prognostic factor, followed by cytogenetics and number of cycles to achieve CR. In conclusion, immunophenotypical investigation of MRD in the first BM in mCR obtained after AML induction therapy provides important information for risk assessment in patients with AML.     

Regenerating normal B-cell precursors during and after treatment of acute lymphoblastic leukaemia: implications for monitoring of minimal residual disease

We studied 57 childhood acute lymphoblastic leukaemia (ALL) patients who remained in continuous complete remission after treatment according to the Dutch Childhood Leukaemia Study Group ALL-8 protocols. The patients were monitored at 18 time points during and after treatment [640 bone marrow (BM) and 600 blood samples] by use of cytomorphology and immunophenotyping for the expression of TdT, CD34, CD10 and CD19. Additionally, 60 BM follow-up samples from six patients were subjected to clonality assessment via heteroduplex polymerase chain reaction (PCR) analysis of immunoglobulin VH-JH gene rearrangements. We observed substantial expansions of normal precursor B cells in regenerating BM not only after maintenance therapy but also during treatment. At the end of the 2-week intervals after consolidation and reinduction treatment, B-cell-lineage regeneration was observed in BM with a large fraction of immature CD34+/TdT+ B cells. In contrast, in regenerating BM after cessation of maintenance treatment, the more mature CD19+/CD10+ B cells were significantly increased, but the fraction of immature CD34+/TdT+ B cells was essentially smaller. Blood samples showed a profound B-cell lymphopenia during treatment followed by a rapid normalization of blood B cells after treatment, with a substantial CD10+ fraction (10-30%). Heteroduplex PCR analysis confirmed the polyclonal origin of the expanded precursor B cells in regenerating BM. This information regarding the regeneration of BM is essential for the correct interpretation of minimal residual disease studies.     

The use of CD138 positively selected marrow samples increases the applicability of minimal residual disease assessment by PCR in patients with multiple myeloma

We have evaluated the use of CD138+ positively selected bone marrow samples to identify a molecular target for minimal residual disease assessment by polymerase chain reaction (PCR) in 25 untreated patients with multiple myeloma. A fraction of each sample was used for CD138+ selection, and the rest served as a reference control. VDJH, DJH, and Kde gene rearrangements were tested for amplification according to the BIOMED-2 Concerted Action. PCR products were directly sequenced in an automated ABI 3130 DNA sequencer using Big-Dye terminators. Within the CD138+ selected group, VDJH rearrangements were detected in all cases (100 %), DJH in 16 (64 %), and Kde in 18 (72 %) cases; whereas in the control samples, VDJH, DJH, and Kde rearrangements were detected in 19 (76 %), 11 (44 %), and 12 (48 %) cases, respectively. After sequencing, 24 (96 %) cases within the CD138+ group had a PCR target for MRD detection compared with 15 (60 %) cases in the control group. We conclude that the use of CD138+ positively selected bone marrow samples increases the applicability of minimal residual disease studies by PCR in patients with multiple myeloma.     

The absence of CD56 on malignant plasma cells in the cerebrospinal fluid is the hallmark of multiple myeloma involving central nervous system

By immunohistochemistry, the CD56-positive myeloma cells were detected in three (38%) bone marrow (BM) and one (13%) cerebrospinal fluid (CSF) samples from eight patients with multiple myeloma involving the central nervous system (CNS MM). Of the three patients with CD56-positive BM myeloma cells, two had CSF myeloma cells negative for CD56. In a control cohort of 84 MM patients without CNS involvement, the BM myeloma cells were CD56-positive in 68 (80%) cases (P < 0.0001). The prevalence of CD56-negative myeloma cells in the BM and CSF of our patients suggests that CD56 downregulation may play a role in the pathogenesis of CNS MM.