Camino Estivill

Bone marrow WT1 levels at diagnosis, post-induction and post-intensification in adult de novo AML.

We retrospectively assessed whether normalized bone marrow WT1 levels could be used for risk stratification in a consecutive series of 584 acute myeloid leukemia (AML) patients. A cutoff value of 5065 copies at diagnosis identified two prognostic groups (overall survival (OS): 44±3 vs 36±3%, P=0.023; leukemia-free survival (LFS): 47±3 vs 36±4%, P=0.038; and cumulative incidence of relapse (CIR): 37±3 vs 47±4%, P=:0.043). Three groups were identified on the basis of WT1 levels post-induction: Group 0 (WT1 between 0 and 17.5 copies, 134 patients, OS: 59±4%, LFS:59±4% and CIR: 26±4%); Group 1 (WT1 between 17.6 and 170.5 copies, 160 patients, OS: 48±5%, LFS:41±4% and CIR: 45±4%); and Group 2 (WT1 >170.5 copies, 71 patients, OS: 23±6%, LFS: 19±7% and CIR: 68±8%) (P<0.001). Post-intensification samples distinguished three groups: patients with WT1 >100 copies (47 patients, 16%); an intermediate group of patients with WT1 between 10 and 100 copies (148 patients, 52%); and a third group with WT1 <10 copies (92 patients, 32%). Outcomes differed significantly in terms of OS (30±7%, 59±4%, 72±5%), LFS (24±7%, 46±4%, 65±5%) and relapse probability (CIR 72±7%, 45±4%, 25±5%), all P<0.001. WT1 levels in bone marrow assayed using the standardized ELN method provide relevant prognostic information in de novo AML.

Adverse impact of IDH1 and IDH2 mutations in primary AML: Experience of the Spanish CETLAM group

The study of genetic lesions in AML cells is helpful to define the prognosis of patients with this disease. This study analyzed the frequency and clinical impact of recently described gene alterations, isocitrate dehydrogenase 1 (IDH1) and isocitrate dehydrogenase 2 (IDH2) mutations, in a series of homogeneously treated patients with primary (de novo) AML. Two-hundred and seventy-five patients enrolled in the CETLAM 2003 protocol were analyzed. IDH1 and IDH2 mutations were investigated by well-established melting curve-analysis and direct sequencing (R140 IDH2 mutations). To establish the percentage of the mutated allele a pyrosequencing method was used. Patients were also studied for NPM, FLT3, MLL, CEBPA, TET2 and WT1 mutations. IDH1 or IDH2 mutations were identified in 23.3% AML cases and in 22.5% of those with a normal karyotype. In this latter group, mutations were associated with short overall survival. This adverse effect was even more evident in patients with the NPM or CEBPA mutated/FLT3 wt genotype. In all the cases analyzed, the normal allele was detected, suggesting that both mutations act as dominant oncogenes. No adverse clinical impact was observed in cases with TET2 mutations. IDH1 and IDH2 mutations are common genetic alterations in normal karyotype AML. Favourable genotype NPM or CEBPA mutated/FLT3 wt can be further categorized according to the IDH1 and IDH2 mutational status.

Immunophenotype of acute myeloid leukemia with NPM mutations: Prognostic impact of the leukemic compartment size

NPM mutations are the most common genetic abnormalities found in non-promyelocytic AML. NPM-positive patients usually show a normal karyotype, a peculiar morphologic appearance with frequent monocytic traits and good prognosis in the absence of an associated FLT3 mutation. This report describes the immunophenotypic and genetic characteristics of a consecutive series of NPM-mutated de novo AML patients enroled in the CETLAM trial. Eighty-three patients were included in the study. Complete immunophenotype was obtained using multiparametric flow cytometry. Associated genetic lesions (FLT3, MLL, CEBPA and WT1 mutations) were studied by standardized methods. Real-time PCR was employed to assess the minimal residual status. The most common pattern was CD34-CD15+ and HLA-DR+. Small CD34 populations with immunophenotypic aberrations (CD15 and CD19 coexpression, abnormal SSC) were detected even in CD34 negative samples. Nearly all cases expressed CD33 (strong positivity), CD13 and CD117, and all were CD123+. The stem cell marker CD110 was also positive in most cases. Biologic parameters such as a high percentage of intermediate CD45+ (blast gate) (>75% nucleated cells), CD123+ and FLT3-ITD mutations were associated with a poor outcome. Quantitative PCR positivity had no prognostic impact either after induction or at the end of chemotherapy. Only PCR positivity (greater than 10 copies) detected in patients in haematological remission was associated with an increased relapse rate. Further studies are required to determine whether the degree of leukemic stem cell expansion (CD45+CD123+cells) increases the risk of acquisition of FLT3-ITD and/or provides selective advantages.

Enhanced myeloid specificity of CD 117 compared with CD13 and CD33

The c-kit proto-oncogene encodes a 145 kd tyrosine kinase transmembrane receptor, which plays a key role in haemopoiesis. The c-kit has been classified as CD117 and is especially useful in the differential diagnosis of acute myelogenous leukemia (AML) and acute lymphoblastic leukemia (ALL). We analysed 104 consecutive cases (55 AML, 23 B-cell lineage ALL, three T-cell ALL, 11 blast crisis of chronic myeloproliferative disorders and 12 cases of myelodysplastic syndromes with more than 10% of blasts) referred to our Hospital for immunophenotypic diagnosis and compared the expression pattern of CD13, CD33 and CD117 using the same fluorochrome (phycoerythrin-PE). The recommendations of the EGIL group were followed in order to establish lineage involvement of the blastic population. The threshold used to assign positivity for CD117 was 10%. Bcr/abl, TEL/AML-1 and MLL rearrangements were assessed by molecular methods. CD117 expression was detected in 91% of AML and MDS. All the negative cases corresponded to acute monocytic leukemias. The calculated specificity for myeloid involvement was 0.86 for CD117, 0.36 for CD13 and 0.44 for CD33 (P < 0.005). CD117 was also positive in four cases of ALL. None of these cases showed bcr/abl or MLL rearrangements. In the light of these findings, CD117 expression should yield a higher score, at least one point, in the system currently applied for the diagnosis of biphenotypic acute leukemias (BAL) as its myeloid specificity is greater than that of CD13 and CD33. Moreover, its absence in AML could identify two subgroups of M5b cases. The coexpression of CD117 with cytoplasmic CD79a is often associated with CD7 reactivity, suggesting a stem cell disorder. CD117 should be included on a routine basis for the immunophenotypic diagnosis of acute leukemias.

Uniparental disomy may be associated with microsatellite instability in acute myeloid leukemia (AML) with a normal karyotype

The discovery of underlying genetic lesions helps to better understand the mechanisms of leukemogenesis and identify prognostic subgroups. Recent insights have allowed normal karyotype acute myeloid leukemia (AML) to be split into many molecular entities according to the genetic status of FLT3, NPM, CEBPA and MLL. Genome-wide single nucleotide polymorphism analysis was performed on 22 well-characterised AML patients with a normal karyotype. At the same time, microsatellite instability was investigated using a commonly used panel of polymorphic markers. Loss of heterozygosity (LOH) was found in 22.7% of cases without an associated copy number variation, suggesting that LOH represented an acquired partial uniparental disomy (aUPD) event. Three UPD+ cases harboured NPM mutations, associated with FLT3-ITD in two of them. An additional UPD patient had mutations both in CEBPA and in WT1. MSI was present at three loci in the three UPD+ cases (60%), whereas single locus MSI was present in three UPD- patients (17%). MSI involved the polymorphic PIG3 promoter in two UPD+ cases. It remains to be tested whether UPD and MSI association marks a common pathway of leukemogenesis.

FLT3 mutations are associated with other molecular lesions in AML.

The basic molecular defects underlying acute myeloid leukemias (AML) seem to be caused by inactivating mutations in transcription factors which control normal myeloid differentiation (Class II mutations) and genetic lesions in tyrosine kinases resulting in constitutive activation (Class I mutations). We sought to determine the frequency of associated mutations (Class I + Class II) in a consecutive series of adult de novo AML (353 patients) in order to stress the validity of this model. Mutations and rearrangements at the FLT3, AML1/ETO, CBFbeta/MYH11, AML1, CEBPalpha and MLL genes were investigated using standard molecular methods. Despite the limitations of the study (DNA availability hampered c-kit and ras mutational analysis), 3.4% of patients showed Class I + Class II mutations. Our findings could be consistent with the cooperative model. The search for new tyrosine kinases which can be the target of molecular lesions in AML warrants further investigation.

WT1 monitoring in core binding factor AML: Comparison with specific chimeric products

Minimal residual disease may help to establish clinical decisions in patients with AML. WT1 offers the possibility to analyze those cases without currently known underlying genetic abnormalities. To compare the value of chimeric specific quantitative PCR with WT1 PCR in CBF acute leukemia, 445 samples from 96 AML (49 AML1-ETO+ and 47 CBFB-MYH11+) cases were included in the study. For each sample AML1-ETO or CBFB-MYH11 levels obtained using the conditions of the BIOMED group were compared with the results of WT1 levels using sensitive primers and conditions. Simultaneously, normal range expression of WT1 was established using RNA obtained from eight healthy donors. WT1 mutations were also investigated both at RNA and at the genomic level. The majority of CBF samples showed rises in WT1 levels (88.7%) at diagnosis. However, 18% of AML1-ETO showed WT1 levels below 250 copies in contrast with 5% CBFB-MYH11 cases. WT1 mutation was not detected in any case (70 diagnostic samples). We found correlation between WT1 levels at diagnosis and the CD34 blast population estimated by flow cytometry in CBFB-MYH11+ cases. We found no association between WT1 levels and clinical outcome. There was a high concordance between chimeric transcript analysis and WT1 levels in CR patients. Concordance was also high in relapsed patients (78% in AML1-ETO and 98% in CBFB-MYH11+ cases). Both WT1 and specific chimeric transcript identified and rescued false negative results of the other test. Additional studies are needed to determine whether the rare discrepancies are a reflection of the cooperative nature of WT1 overexpression or a consequence of the uneven distribution in the leukemic population. WT1 is a powerful MRD tool even in cases with currently available molecular targets.

Microsatellite instability is not an uncommon finding in adult de novo acute myeloid leukemia

To investigate the biologic relevance of microsatellite instability (MSI) in de novo acute myeloid leukemia (AML), 102 consecutive adult patients were analyzed by using a panel of seven microsatellites (BAT25, BAT26, D13S1267, D13S174, D2S123, D5S346 and Mdf15). Frame-shift mutations in the repetitive sequences in the coding region of MSH3, MSH6, BAX, TGFBRII and IGFRII were also investigated by using a fluorescent PCR-based assay. Methylation-specific PCR was used to determine the methylation status of hMLH1 in MSI+ cases. MSH3, MSH6 and MLH1 expression was also analyzed in 68 cases by means of real-time quantitative PCR. MSI was detected in 20 cases: 14 cases had MSI-high (instability of at least two microsatellite markers) and 6 cases corresponded to MSI-low (a single polymorphic marker with instability). Six MSI+ cases showed an associated MLL rearrangement (p=0.002). No single case showed a mutation in the repetitive sequences of the MSH3, MSH6, BAX, TGFBRII and IGFRII genes. Most samples displayed low mRNA levels of the repair genes. hMLH1 promoter was hypermethylated in five MSI+ cases. Overall survival analysis revealed no adverse effect of MSI positivity. These results suggest that MSI may be a common biologic finding in de novo AML.

Bone Marrow WT1 Levels in Allogeneic Hematopoietic Stem Cell Transplantation for Acute Myelogenous Leukemia and Myelodysplasia: Clinically Relevant Time Points and 100 Copies Threshold Value

The outcome of allogeneic hematopoietic stem cell transplantation (HCT) in patients with myeloid malignancies is better in those without minimal residual disease (MRD) than in those with MRD+, as assessed by multiparametric flow cytometry (MPFC). WT1 quantitation also has been used to assess the probability of relapse in acute myelogenous leukemia (AML) treated with chemotherapy. We analyzed the clinical value of normalized bone marrow WT1 levels as a measure of the expanded myeloid progenitor compartment in a consecutive series of 193 adult patients with myeloid malignancies who underwent HCT. Bone marrow WT1 levels before the HCT, at the first bone marrow aspirate after infusion, and in the follow-up samples after HCT were determined by means of real-time PCR using the European LeukemiaNet normalized method. We sought to clarify the prognostic relevance in terms of overall survival (OS), progression-free survival (PFS), and cumulative incidence of relapse (CIR). Based on earlier experience in AML, we selected a threshold of 100 copies, defining 2 groups: patients with <100 WT1 copies and those with ≥100 copies. Patients with <100 WT1 copies before HCT (median time, 36 days; range, 4 to 268 days) had a better OS, PFS, and CIR than those with ≥100 copies (40 ± 1 versus 29 ± 6 days, P = .004; 35 ± 9 versus 26 ± 6 days, P = .002; and 29 ± 7 versus 37 ± 6 days, P = .051). In the first bone marrow study after the HCT (median time, 42 days; range 14 to 157 days, respectively), patients with <100 WT1 copies also had better outcomes in terms of OS, PFS, and CIR (40 ± 7 versus 31 ± 9 days, P = .025; 36 ± 7 versus 30 ± 8 days, P = .004; and 29 ± 6 days versus 54 ± 9, P < .001, respectively). At this time point, bone marrrow samples with >100 copies also included patients who were negative for MRD as assessed by MPFC (19 of 32). During the HCT follow-up, patients with sustained WT1 levels <100 copies showed a marked benefit in terms of OS, PFS, and CIR even compared with those with only a single measurement >100 copies (mean, 68 ± 11 versus 26 ± 7 days, P < .001; 63 ± 11 versus 20 ± 8 days, P < .001; and 20 ± 8 vs. 71 ± 8 days, P < .001, respectively). Standardized bone marrow WT1 levels using a 100-copy threshold in samples obtained before HCT, at leukocyte recovery, and during follow-up provided relevant prognostic information in patients with myeloid malignacies submitted to HCT.

Clonal Heterogeneity Assessed by Flow Cytometry in B-Cell Lymphomas Arising From Germinal Centers

Patients with mature follicular B-cell lymphomas develop aggressive non-Hodgkin lymphomas (NHLs) during disease progression. It is controversial whether most diffuse large B-cell lymphomas (DLBCLs) and Burkitt lymphomas (BLs) emerge as de novo lymphomas or from an original follicular lymphoma. To distinguish clonally related populations in aggressive NHL, we studied the immunophenotypic features of 18 consecutive samples from 16 patients. Three flow cytometric patterns were distinguished: (1) a homogeneous neoplastic population of large B cells with phenotypic features of follicular center cells; (2) 2 atypical populations of B cells, small monoclonal B cells, and large B cells with loss of some surface antigens; and (3) 2 clonal populations of small and large B cells sharing the same light-chain isotype. The 3 flow cytometric patterns were observed, respectively, in de novo DLBCL and BL, transformation into BL, and transformation into DLBCL. Flow cytometric data can provide valuable information about the natural history of NHL.