Precise quantification of minimal residual disease at day 29 allows identification of children with acute lymphoblastic leukemia and an excellent outcome

The postinduction level of minimal residual disease (MRD) was quantified with a competitive polymerase chain reaction (PCR) technique in 104 children with acute lymphoblastic leukemia (ALL) diagnosed between June 1993 and January 1998 and followed for a median of 4.2 years. A significant correlation was found between the MRD level on day 15 (D15) and day 29 (D29) after the start of induction therapy (r(s) = 0.70, P <.0001). The 15 patients with T-cell disease had higher D29 MRD than those with B-lineage ALL (P =.01). Age was positively related to D29 MRD (r(s) = 0.32, P =.001). The 16 patients who had a relapse had higher D15 and D29 MRD levels than the patients who stayed in remission (median levels D15, 1% versus 0.1%, P =.03; D29, 0.4% versus 0.01%, P =.0001). No patients with a MRD level less than 0.01% on D29 have so far had a relapse, whereas the 7-year probability of event-free survival for patients with higher MRD levels was 0.52 (P =.0007). The group of patients with a D29 MRD less than 0.01% included patients with T-cell disease, white blood cell count more than 50 x 10(9)/L at diagnosis, or age 10 years or older, and could not be identified by up-front criteria. The best-fit Cox model to predict the risk of relapse included D29 MRD (P =.004) and age (P =.009). These findings indicate that with the present treatment protocol MRD quantification at an early stage of therapy identifies patients with a very low risk of relapse. Further trials are needed to reveal whether such patients with D29 MRD less than 0.01% can be cured with less intensive chemotherapy, which would reduce the risk of serious late effects as well as the costs of therapy.

Minimal residual core binding factor AMLs by real time quantitative PCR—Initial response to chemotherapy predicts event free survival and close monitoring of peripheral blood unravels the kinetics of relapse

Minimal residual disease (MRD) was measured by RQ-PCR in 11 AML1/ETO and 13 CBFbeta/MYH11 patients at diagnosis, after induction chemotherapy, and at all subsequent visits. Median detection limits were 1:50,000 and 1:10,000, respectively. In 64/103 samples MRD was detectable and highly correlated in PB and BM. In 38/103 samples, where MRD was only detectable in BM, median BM MRD was 3.5log lower than at diagnosis. Event free survival was significantly inferior in case of <2log reduction post-induction MRD. Persistent MRD was always followed by hematological relapse. Molecular progression rate in relapsing CBFbeta/MYH11 was surprisingly slow with a time lag to hematological relapse approaching 1 year. This direct comparison between the two subgroups of CBF AMLs delineates clear biological differences and corroborates the value of RQ-PCR.

Post-induction residual leukemia in childhood acute lymphoblastic leukemia quantified by PCR correlates with in vitro prednisolone resistance

Most prognostic factors in childhood acute lymphoblastic leukemia (ALL) are informative for groups of patients, whereas new approaches are needed to predict the efficacy of chemotherapy for the individual patient. The residual leukemia following 4 weeks of induction therapy with prednisolone, vincristine, doxorubicin and i.t. methotrexate and the in vitro resistance to prednisolone, vincristine, and doxorubicin were measured in 30 boys and 12 girls with B (n = 34) or T lineage (n = 8) ALL. The residual leukemia was quantified after 2 (MRD-D15, n = 29) and 4 weeks (MRD-PI, n = 42) of induction therapy with a precise and reproducible clone-specific PCR technique. The median MRD-D15 and MRD-PI were 0.50% (75% range 0.0088.1%) and 0.014% (75% range 0.001-2.0%), respectively, and these levels correlated significantly (n = 29, rs = 0.75, P < 0.001). Both the MRD-D15 and the MRD-PI were related to the age of the patient (MRD-D15: rs= 0.48, P= 0.009; MRD-PI: rs = 0.45, P = 0.003). Patients with T lineage ALL had higher MRD-PI than those with B lineage ALL (median MRD-PI: 0.5% vs 0.01%, P = 0.05). The median LC50 (concentration lethal to 50% of cells) for prednisolone was 2.3 microg/ml (75% range 0.05-668). Both MRD-D15 and MRD-PI correlated significantly with the in vitro resistance to prednisolone (MRD-D15: rs = 0.41, P = 0.03; MRD-PI: rs = 0.39, P = 0.01); but not to in vitro vincristine or doxorubicin resistance. The correlations between MRD and in vitro prednisolone resistance were even more pronounced when B cell precursor and T cell leukemia were analyzed separately (B cell precursor ALL: MRD-PI vs prednisolone LC50: n = 33, rs = 0.47, P = 0.006; T cell ALL: MRD-PI vs prednisolone resistance: n = 8, rs = 0.84, P = 0.009). After a median follow-up of 5.0 years (75% range 3.2-6.9) eight patients have relapsed. All of the 21 patients with a MRD-PI < or =0.5% and a prednisolone LC50 < or =10 microg/ml have remained in remission whereas the 7 year event-free survival for the remaining 20 patients was 0.45 +/- 0.16 (P= 0.002) Prospective studies in childhood ALL are needed to clarify whether combined monitoring of in vitro drug resistance and residual leukemia early during chemotherapy could offer new ways to classify patients and stratify the intensity of therapy.

Molecular typing of adult acute myeloid leukaemia: significance of translocations, tandem duplications, methylation, and selective gene expression profiling

Although a number of molecular aberrations have been described in acute myeloid leukaemia (AML), no study has yet determined their relative prognostic importance. We have analysed blast cells from 250 adult patients treated at the same institution during a 15-year period. Balanced translocations were detected by multiplex polymerase chain reaction in 13% of the cases. Internal tandem duplication (ITD) of the FLT3 gene and partial tandem duplication of the MLL gene were found in 24% and 4%, respectively. Promoter hypermethylation of the P15, CDH1, ER and MDR1 genes was observed in 71%, 64%, 40% and 4%, respectively. Compared with normal bone marrow, the chemotherapy resistance protein MRP1 and apoptosis related genes BAX and CASPASE3 were found to be overexpressed in AML blasts. Univariate analysis revealed that the most important determinants of prognosis were presence of balanced translocations, age, white blood cell count and extramedullary disease, in order of statistical significance. In a multivariate analysis, balanced translocations retained their prognostic significance and FLT3 ITD as well as high gene expression of MDR1 were negative prognostic factors. From these data, which are the first to compare these molecular aberrations directly, we conclude that, when a battery of molecular changes is evaluated for upfront significance in AML, recurrent translocations are of prime importance for treatment outcome.

A highly sensitive and specific qPCR assay for quantification of the biomarker SOX11 in mantle cell lymphoma

OBJECTIVES

Mantle cell lymphoma (MCL) is one of the most heterogeneous lymphoid neoplasms with a variable course of disease. Although t(11;14)(q13;q32) is the hallmark of MCL resulting in cyclin D1 (CCND1) overexpression in 90% of patients, this is difficult to validate by immunohistochemistry. We hypothesised that SOX11 could be a robust molecular biomarker for MCL.

METHODS

We have developed very sensitive and specific RT-qPCR assay employing a poly-A specific RT primer to circumvent contamination from gDNA caused by the intron-less nature of SOX11.

RESULTS

We found a significant difference between the expression levels of SOX11 in patients with MCL at diagnosis (n = 21) and in healthy donors (n = 18) (blood: P < 0.0001; marrow: P = 0.0001). SOX11 expression of very low levels close to the assay sensitivity was detected in only 2 of 18 healthy donors, while low levels of CCND1 expression was observed in all blood and 12 of 13 marrow samples within the defined detection limit of Cq = 40. In spiking experiments of the GRANTA-519 MCL cell line into mononuclear cells from normal donor, the sensitivity of the SOX11 assay was found to be 2 × 10(-4) , while the sensitivity of the CCND1 assay was estimated to 2 × 10(-3) because of the normal background expression. In longitudinal sampling from patients with MCL the minimal residual disease (MRD) values based on the SOX11 expression mirrored the clinical disease development.

CONCLUSION

This SOX11 RT-qPCR assay could be a useful tool for MRD monitoring in patients with MCL.

The Mycoplasma hominis P120 membrane protein contains a 216 amino acid hypervariable domain that is recognized by the human humoral immune response

In the antigenically heterogeneous species Mycoplasma hominis a monoclonal antibody, mAb 26.7D, was previously found to recognize a 120 kDa polypeptide from M. hominis 7488. This antibody did not react with the type strain PG21. The homologous gene from M. hominis PG21 was cloned and sequenced and found to have a sequence identity of 91% with the gene of strain 7488. One hypervariable and two semivariable regions were detected. The epitope for mAb 26.7D was mapped to the hypervariable domain by expression of various parts of this domain in Escherichia coli using expression vector systems. A polyclonal antiserum (pAb 121) generated against the hypervariable region of P120 from PG21 identified the P120 homologue in M. hominis PG21. Fusion proteins of the hypervariable and constant parts of the proteins were constructed and tested for reactivity with 21 human sera. Twelve sera reacted with the 7488 hypervariable fusion protein, but only four reacted with PG21 hypervariable fusion protein. No reactivity was seen with a fusion protein containing part of the constant region of P120. Gene fragments amplified from 18 M. hominis isolates by PCR confirmed the heterogeneity of the hypervariable domain. Based on restriction endonuclease cleavage patterns of the hypervariable domain the 18 isolates could be divided into four cases. Reactivity with both mAb 26.7D and pAb 121 confirmed these classes. The hypervariable, but not the constant, part of P120 was recognized by the human humoral immune response. Such a variable domain may be important in evasion of the host's immune response, and thus aid survival of the micro-organism.

Analysis of a Mycoplasma hominis membrane protein, P120

The monoclonal antibody mAb 26.7D generated against a clinical isolate of Mycoplasma hominis 7488 was shown to react with a surface-exposed epitope on a 120-kDa protein (P120). The gene encoding the protein was cloned and sequenced, and the transcriptional start point was determined by primer extension analysis. The gene contained an open reading frame of 3237 bp encoding a peptide of 1079 amino acids with a deduced molecular mass of 123 kDa. A putative amino-terminal signal peptide and cleavage site for signal peptidase II were found. This suggests that the protein was synthesized as a precursor with subsequent processing to a mature lipoprotein. Surface exposure was confirmed by immunoelectron microscopy. mAb 26.7D reacted with 11 of 19 M. hominis strains. The gene was, however, present in all strains.

Immunoelectron microscopy and mass spectrometry for classification of amyloid deposits

Amyloidosis is a shared name for several rare, complex and serious diseases caused by extra-cellular deposits of different misfolded proteins. Accurate characterization of the amyloid protein is essential for patient care. Immunoelectron microscopy (IEM) and laser microdissection followed by tandem mass spectrometry (LMD-MS) are new gold standards for molecular subtyping. Both methods perform superiorly to immunohistochemistry, but their complementarities, strengths and weaknesses across amyloid subtypes and organ biopsy origin remain undefined. Therefore, we performed a retrospective study of 106 Congo Red positive biopsies from different involved organs; heart, kidney, lung, gut mucosa, skin and bone marrow. IEM, performed with gold-labelled antibodies against kappa light chains, lambda light chains, transthyretin and amyloid A, identified specific staining of amyloid fibrils in 91.6%; in six biopsies amyloid fibrils were not identified, and in two, the fibril subtype could not be established. LMD-MS identified amyloid protein signature in 98.1%, but in nine the amyloid protein could not be clearly identified. MS identified protein subtype in 89.6%. Corresponding specificities ranged at organ level from 94-100%. Concordance was 89.6-100% for different amyloid subtypes. Importantly, combined use of both methods increased the diagnostic classification to 100%. Some variety in performances at organ level was observed.

Promoter hypermethylation of the retinoic acid receptor beta2 gene is frequent in acute myeloid leukaemia and associated with the presence of CBFbeta-MYH11 fusion transcripts

Silencing of the putative tumour suppressor gene retinoic acid receptor beta2 (RARbeta2) caused by aberrant promoter hypermethylation has been identified in several solid tumours. In order to evaluate the extent of RARbeta2 hypermethylation and transcription in acute myeloid leukaemia (AML) at diagnosis, 320 patients were investigated by bisulphite-denaturing gradient gel electrophoresis and mRNA transcription levels were analysed in 61 of these by quantitative real-time polymerase chain reaction. The results were compared with demographic- and molecular data from the patients. While RARbeta2 was unmethylated in 10/10 bone marrow and 7/7 blood samples from healthy individuals, the gene was hypermethylated in 43% of the AML patients. The RARbeta2 degree of promoter methylation differed between and within individuals, and the mRNA transcription levels of the gene varied inter-individually by a factor of 4000. A significant inverse correlation between promoter hypermethylation and gene expression could be established (t-test, P = 0.019). Comparison of methylation data with a series of other molecular alterations in the same patient materials revealed a correlation between hypermethylation of the RARbeta2 promoter and the presence of CBF-MYH11 fusion transcripts (P < 0.01). Our data suggest that RARbeta2 promoter methylation is frequent in AML and may co-operate with the expression of CBF-MYH11 fusion transcripts in leukaemogenesis.

Delineation of known and new transcript variants of the SETMAR (Metnase) gene and the expression profile in hematologic neoplasms

SET domain and mariner transposase fusion gene (SETMAR), also known as Metnase, has previously been shown to suppress the formation of chromosomal translocation in mouse fibroblasts. Despite the fact that hematologic malignancies are often characterized by chromosomal rearrangements, no studies have hitherto investigated the expression pattern of the gene in these disorders. We hypothesized that a high expression of SETMAR protected the cells from chromosomal rearrangements; thus, we examined the mRNA expression of SETMAR transcript variants in hematologic patients. We identified six transcript variants (var1, var2, var5, varA, varB, varC), of which three had not been reported previously. Expression levels were quantified by transcript-specific quantitative polymerase chain reaction in 15 healthy individuals, 70 acute myeloid leukemia (AML) patients (translocation positive, n= 30 [AML(TPos)], translocation negative, n = 40 [AML(TNeg)]), seven patients with mantle cell lymphoma (t [11,14] positive), and 13 patients with chronic myeloid leukemia (t [9,22] positive). All variants were significantly overexpressed in both subgroups of AML compared with healthy individuals (var1 and var2: p < 0.00001 for both AML subgroups, varA and varB: p = 0.0002, var5: p = 0.0008, and varC: p = 0.0001 for AML(TNeg); varA: p = 0.0048, varB and var5: p = 0.0001, varC: p = 0.0017). When comparing the expression in AML(TNeg) and AML(TPos), we found a significantly increased expression of the full length SETMAR in AML(TNeg) (var1: p = 0.047), suggesting a protective effect of high SETMAR expression on formation of chromosomal translocations. In conclusion, we have found known and novel SETMAR splice variants to be significantly increased in AML. To our knowledge, this is the first study that describes an expression profile of SETMAR in subgroups of hematologic malignancies, which can be linked to the incidence of chromosomal rearrangements.

Delineation and molecular characterization of acute myeloid leukemia patients with coduplication of FLT3 and MLL

Partial tandem (PTD) and internal tandem duplications (ITD) of the MLL or FLT3 genes respectively, have been demonstrated in acute myeloid leukemia (AML). While occurrence of each of these PTD/ITD seem to confer an unfavorable prognosis, the literature contains only sparse information of the occurrence and the prognosis of simultaneous PTD/ITD of these genes. We have therefore attempted to determine the presence and its consequence in AML and with the further aim of characterizing such patients with respect to other genetic aberrations and to prototype variables in this disease. We analyzed blast cells from 250 adult patients treated at the same institution during a 15-year period for FLT3 ITD and MLL PTD and the duplications were found in 24% and 4%, respectively. The four co-duplicated cases (2%) did not differ with respect to sex, age, FAB-type, or immunophenotype, promoter methylation of p15, E-cadherin (CDH1), Estrogen receptor, MDR1, expression of apoptosis-related or multidrug resistance-related genes, though a trend toward decreased gene expression of MDR1 was observed. Two of the patients had a normal karyotypic analysis, while the remaining two showed aberrations in chromosome 11, one with trisomy 11 and the other with a der (11). The extensive molecular characterization of FLT3/MLL coduplicated patients presented here indicates that, even though they do not differ molecularly from the groups of patients with single ITDs, their prognosis and overall survival is universally poor. More patients are needed to determine whether coduplication has independent clinical implications compared to patients with single ITD/PTD.

Competitive PCR for quantification of minimal residual disease in acute lymphoblastic leukaemia

A very precise and reproducible polymerase chain reaction (PCR) method was developed in order to quantify minimal residual disease (MRD) in children with acute lymphoblastic leukaemia (ALL). A clone-specific competitor was constructed by introducing a restriction site in a PCR product identical to parts of the highly specific rearranged T-cell receptor delta (TCR-delta), T-cell receptor gamma (TCR-gamma), or immunoglobulin heavy chain (IgH) genes of the malignant clone. Using primers located externally to the restriction site the competitor and the DNA from the malignant clone will be amplified under identical conditions. After restriction enzyme cleavage, the PCR products originating from the competitor and the malignant clone can be distinguished by size in a gel electrophoresis step and the amount of residual disease can be determined. The method is very sensitive with a detection limit of at least one malignant cell in 10(5) normal cells. This method may be used for treatment stratification based on the early response to antileukaemic therapy.

Harnessing the Immune System to Fight Multiple Myeloma

Multiple myeloma (MM) is a heterogeneous plasma cell malignancy differing substantially in clinical behavior, prognosis, and response to treatment. With the advent of novel therapies, many patients achieve long-lasting remissions, but some experience aggressive and treatment refractory relapses. So far, MM is considered incurable. Myeloma pathogenesis can broadly be explained by two interacting mechanisms, intraclonal evolution of cancer cells and development of an immunosuppressive tumor microenvironment. Failures in isotype class switching and somatic hypermutations result in the neoplastic transformation typical of MM and other B cell malignancies. Interestingly, although genetic alterations occur and evolve over time, they are also present in premalignant stages, which never progress to MM, suggesting that genetic mutations are necessary but not sufficient for myeloma transformation. Changes in composition and function of the immune cells are associated with loss of effective immune surveillance, which might represent another mechanism driving malignant transformation. During the last decade, the traditional view on myeloma treatment has changed dramatically. It is increasingly evident that treatment strategies solely based on targeting intrinsic properties of myeloma cells are insufficient. Lately, approaches that redirect the cells of the otherwise suppressed immune system to take control over myeloma have emerged. Evidence of utility of this principle was initially established by the observation of the graft-versus-myeloma effect in allogeneic stem cell-transplanted patients. A variety of new strategies to harness both innate and antigen-specific immunity against MM have recently been developed and intensively tested in clinical trials. This review aims to give readers a basic understanding of how the immune system can be engaged to treat MM, to summarize the main immunotherapeutic modalities, their current role in clinical care, and future prospects.

Measurable residual disease monitoring using Wilms tumor gene 1 expression in childhood acute myeloid leukemia based on child-specific reference values

BACKGROUND

Measurable/minimal residual disease (MRD) monitoring can predict imminent hematological relapse in acute myeloid leukemia (AML). The majority of childhood AML patients do not harbor fusion genes or mutations applicable as MRD markers and overexpression of Wilms tumor gene 1 (WT1) may constitute a useful monitoring target. However, age-specific reference values in healthy hematopoiesis and standardization of WT1 assessment are prerequisites for clinical utility.

PROCEDURE

We investigated WT1 expression across age in hematologically healthy controls (n = 109), during suspected infection (n = 90) and bone marrow (BM) regeneration (n = 13). WT1 expression in AML at diagnosis (n = 91) and during follow-up (n = 30) was compared with age-specific reference values.

RESULTS

WT1 expression correlated with age and showed higher levels in both BM and peripheral blood (PB) in children compared with adults (P < 0.001 and P = 0.01). WT1 expression from healthy hematopoiesis was lower in PB compared with BM (WT1_BM /WT1_PB  = 8.6, 95% CI: 5.3-13.7) and not influenced by infection nor BM regeneration. At AML diagnosis, 66% had more than 20-fold WT1 overexpression in PB or BM (PB 74%; BM 45%). WT1 was quantified in 279 PB samples during follow-up. All 11 patients with PB sampling within 4 months of disease recurrence displayed WT1 overexpression by a median of 1.9 months (range, 0.7-9.7) before hematological relapse.

CONCLUSIONS

This study defines child-specific reference values for WT1 expression in healthy hematopoiesis and demonstrates that WT1 expression in PB is a useful post-treatment monitoring tool in childhood AML. Based on these observations, we propose definitions for childhood AML molecular relapse using WT1 overexpression.

Infectious complications after chemotherapy and stem cell transplantation in multiple myeloma: implications of Fc gamma receptor and myeloperoxidase promoter polymorphisms

Multiple myeloma is associated with a high risk of infections. We hypothesized that Fc gamma receptor (FCGR) and myeloperoxidase (MPO) promoter gene polymorphisms influence the risk of infections after induction chemotherapy (IC) and autologous stem cell transplantation (ASCT). Retrospectively, we analysed 136 patient courses of IC and 113 procedures of ASCT. Genetic analyses were made with PCR techniques on genomic DNA. The incidence rate ratio of sepsis during ASCT in patients homozygous for the G-129MPO promoter type was 0.30 (95% CI: 0.09-0.96). The G-463AMPO promoter polymorphism was not associated with the risk of infections. The polymorphisms of FCGR2A, FCGR3A and FCGR3B were not convincingly associated with infections. The NA1 variant of FCGR3B was strongly skewed with other risk factors, and the results in IC and ASCT were conflicting. Further studies of the G-129AMPO promoter as a potential risk modifier for infections are relevant.

A novel RT-qPCR assay for quantification of the MLL-MLLT3 fusion transcript in acute myeloid leukaemia

OBJECTIVES

Patients with acute myeloid leukaemia (AML) of the monocytic lineage often lack molecular markers for minimal residual disease (MRD) monitoring. The MLL-MLLT3 fusion transcript found in patients with AML harbouring t(9;11) is amenable to RT-qPCR quantification but because of the heterogeneity of translocation break points, the MLL-MLLT3 fusion gene is a challenging target. We hypothesised that MRD monitoring using MLL-MLLT3 as a RT-qPCR marker is feasible in the majority of patients with t(9;11)-positive AML.

METHODS

Using a locked nucleic acid probe, we developed a sensitive RT-qPCR assay for quantification of the most common break point region of the MLL-MLLT3 fusion gene. Five paediatric patients with t(9;11)-positive AML were monitored using the MLL-MLLT3 assay.

RESULTS

A total of 43 bone marrow (BM) and 52 Peripheral blood (PB) samples were collected from diagnosis until follow-up. Two patients relapsed, and both were MRD positive in BM after first induction course. A total of three relapses occurred, and they were detected by RT-qPCR 3 wks before haematological relapse was diagnosed.

CONCLUSION

This MLL-MLLT3 RT-qPCR assay could be useful in MRD monitoring of a group of patients with AML who often lack reliable MRD markers.