Hughes E

Outcome prediction in childhood acute lymphoblastic leukaemia by molecular quantification of residual disease at the end of induction

Methods to detect and quantify minimal residual disease (MRD) after chemotherapy for acute lymphoblastic leukaemia (ALL) could improve treatment by identifying patients who need more or less intensive therapy. We have used a clone-specific polymerase chain reaction to detect rearranged immunoglobulin heavy-chain gene from the leukaemic clone, and quantified the clone by limiting dilution analysis. MRD was successfully quantified, by extracting DNA from marrow slides, from 88 of 181 children with ALL, who had total leucocyte counts below 100 x 10(9)/L at presentation and were enrolled in two clinical trials, in 1980-84 and 1985-89. Leukaemia was detected in the first remission marrow of 38 patients, in amounts between 6.7 x 10(-2) and 9.9 x 10(-7) cells; 26 of these patients relapsed. Of 50 patients with no MRD detected, despite study of 522-496,000 genomes, only 6 relapsed. The association between MRD detection and outcome was significant for patients in each trial. In the first trial, patients relapsed at all levels of detected MRD, whereas in the later trial, in which treatment was more intensive and results were better, the extent of MRD was closely related to the probability of relapse (5 of 5 patients with > 10(-3) MRD, 4 of 10 with 10(-3) to 2 x 10(-5), 0 of 3 with levels below 2 x 10(-5), and 2 of 26 with no MRD detected). Early quantification of leukaemic cells after chemotherapy may be a successful strategy for predicting outcome and hence individualizing treatment in childhood ALL, because the results indicate both in-vivo drug sensitivity of the leukaemia and the number of leukaemic cells that remain to be killed by post-induction therapy.

Monitoring minimal residual disease in peripheral blood in B-lineage acute lymphoblastic leukaemia

The use of peripheral blood rather than marrow has potential advantages for monitoring minimal residual disease during the treatment of leukaemia. To determine the feasibility of using blood, we used a sensitive polymerase chain reaction method to quantify leukaemia in the blood and marrow in 35 paired samples from 15 children during induction treatment. Leukaemic cells in the blood ranged from 1.1 × 10−2 to < 9.4 × 10−7 leukaemic cells/total cells, corresponding to 1.3 × 107 to < 2 × 103 leukaemic cells/l. In 15 paired samples, leukaemia could be quantified in both tissues and in 20 paired samples, leukaemia was not detected in one or both tissues so that only upper level limits could be set. In the former 15 pairs, the level of leukaemia in peripheral blood was directly proportional to that in marrow but was a mean of 11.7‐fold lower. Leukaemia in blood was detected in 10/12 pairs in which the level in marrow was > 10−4, but in only two of 13 pairs in which the level in marrow was < 10−5. Patients studied at multiple time‐points showed parallel declines in the number of leukaemic cells in both tissues. The results showed that leukaemia could be monitored in peripheral blood during induction therapy, and quantitative considerations based on the results suggest that monitoring of blood during post‐induction therapy may be of value in detecting molecular relapse.

Determining the Repertoire of IGH Gene Rearrangements to Develop Molecular Markers for Minimal Residual Disease in B-Lineage Acute Lymphoblastic Leukemia

Molecular markers for minimal residual disease in B-lineage acute lymphoblastic leukemia were identified by determining, at the time of diagnosis, the repertoire of rearrangements of the immunoglobulin heavy chain (IGH) gene using segment-specific variable (V), diversity (D), and junctional (J) primers in two different studies that involved a total study population of 75 children and 18 adults. This strategy, termed repertoire analysis, was compared with the conventional strategy of identifying markers using family-specific V, D, and J primers for a variety of antigen receptor genes. Repertoire analysis detected significantly more markers for the major leukemic clone than did the conventional strategy, and one or more IgH rearrangements that were suitable for monitoring the major clone were detected in 96% of children and 94% of adults. Repertoire analysis also detected significantly more IGH markers for minor clones. Some minor clones were quite large and a proportion of them would not be able to be detected by a minimal residual disease test directed to the marker for the major clone. IGH repertoire analysis at diagnosis has potential advantages for the identification of molecular markers for the quantification of minimal residual disease in acute lymphoblastic leukemia cases. An IGH marker enables very sensitive quantification of the major leukemic clone, and the detection of minor clones may enable early identification of additional patients who are prone to relapse.

The use of monoclonal gene rearrangement for detection of minimal residual disease in acute lymphoblastic leukemia of childhood

Sensitive quantification of minimal residual disease (MRD) using the polymerase chain reaction (PCR) is strongly predictive of outcome in childhood acute lymphoblastic leukemia (ALL), with MRD levels at the end of induction therapy of >10−3 predicting a poor outcome. Methods for sensitive quantification are, however, complicated and time-consuming. Detection by PCR of monoclonal immunoglobulin heavy chain (IgH) and T cell receptor (TCR) gene rearrangements is simple and can be used in routine laboratories but is non-quantitative and of lower but uncertain sensitivity. The aim of this study was to determine the value of detection of monoclonality in identification of different levels of MRD. We looked for monoclonality in 64 bone marrow aspirates which had been obtained from 31 patients with B lineage ALL at various times during induction therapy and for which levels of MRD had been determined by limiting dilution analysis using patient-specific PCR primers. Detection of monoclonality identified levels of MRD of ⩾10−3 during induction with a sensitivity of 78% and a specificity of 93%. The positive and negative predictive values were 0.86 and 0.88, respectively. The sensitivity of detection of a monoclonal IgH rearrangement was greater than that for the TCRγ locus during induction as an IgH rearrangement was detected more often than a TCRγ rearrangement in patients who had both IgH and TCRγ rearrangement at diagnosis. Detection of monoclonality is therefore a simple and quick test applicable to the majority of patients with ALL and it may be useful in identifying high-risk patients at the end of induction and in identifying relapsing patients later during therapy.

Effect of the Philadelphia chromosome on minimal residual disease in acute lymphoblastic leukemia.

The Philadelphia translocation is associated with a poor prognosis in adults and children with acute lymphoblastic leukemia, even though the majority of patients achieve remission. To test the hypothesis that the translocation leads to drug resistance in vivo, we studied 61 children and 20 adults with acute lymphoblastic leukemia and used the level of minimal residual disease at the end of induction as the measure of drug resistance in vivo. In children the presence of the translocation was associated with a significant increase in residual disease, indicating higher drug resistance in vivo; five of seven Philadelphia-positive children but only five of 54 Philadelphia-negative children had a minimal residual disease level >10−3, a level which is associated with a high risk of relapse in childhood acute lymphoblastic leukemia of standard risk. By contrast, in adults, residual disease and hence drug resistance was already higher than in children, and the presence of the Philadelphia translocation in seven patients had no obvious additional effect. We conclude that the Philadelphia chromosome may increase resistance to drugs in vivo in children, but not detectably in adults.

Comparison of methods for assessment of minimal residual disease in childhood B-lineage acute lymphoblastic leukemia

The level of minimal residual disease (MRD) early in treatment of acute lymphoblastic leukemia (ALL) strongly predicts the risk of marrow relapse. As a variety of methods of varying complexity have been separately used for detecting and quantifying MRD, we compared the prognostic utility of three methods – measurement of blast percentage on day 14 of treatment, detection of monoclonality on day 14 or day 35, and measurement of MRD by PCR-based limiting dilution analysis on day 14 or day 35. The study group comprised 38 children aged 1–15 with Philadelphia-negative B-lineage ALL who were uniformly treated and followed until relapse or for a minimum of 5 years. We also studied some of the technical factors which influence the ability to detect MRD. Measurement of blast percentage on day 14 by an expert morphologist, detection of monoclonality on day 35, and PCR-based measurement of MRD levels on days 14 and 35 all showed significant ability to divide patients into prognostic groups. Measurement of blast percentage on day 14 by routine morphology or detection of monoclonality on day 14 were not useful. The quality of DNA samples varied greatly, as determined by amplifiability in the PCR. However, virtually all amplifiable leukemic targets in a sample were detectable which suggests that the level of detection achieved by limiting dilution analysis is essentially determined by the amount of DNA which it is practicable to study. We conclude that quantification of MRD at the end of induction provides the full range of prognostic information for marrow relapse but is complex; detection of monoclonality on day 35 is simple and has good positive predictive value; and quantification of MRD on day 14 merits further study. PCR-based methods for measurement of MRD levels should incorporate a correction for variation in DNA amplifiability.

Sensitive and specific measurement of minimal residual disease in acute lymphoblastic leukemia

A sensitive and specific quantitative real-time polymerase chain reaction method, involving three rounds of amplification with two allele-specific oligonucleotide primers directed against an rearrangement, was developed to quantify minimal residual disease (MRD) in B-lineage acute lymphoblastic leukemia (ALL). For a single sample containing 10 microg of good quality DNA, MRD was quantifiable down to approximately 10(-6), which is at least 1 log more sensitive than current methods. Nonspecific amplification was rarely observed. The standard deviation of laboratory estimations was 0.32 log units at moderate or high levels of MRD, but increased markedly as the level of MRD and the number of intact marker gene rearrangements in the sample fell. In 23 children with ALL studied after induction therapy, the mean MRD level was 1.6 x 10(-5) and levels ranged from 1.5 x 10(-2) to less than 10(-7). Comparisons with the conventional one-round quantitative polymerase chain reaction method on 29 samples from another 24 children who received treatment resulted in concordant results for 22 samples and discordant results for seven samples. The sensitivity and specificity of the method are due to the use of nested polymerase chain reaction, one segment-specific and two allele-specific oligonucleotide primers, and the use of a large amount of good quality DNA. This method may improve MRD-based decisions on treatment for ALL patients, and the principles should be applicable to DNA-based MRD measurements in other disorders.

A DNA Real-Time Quantitative PCR Method Suitable for Routine Monitoring of Low Levels of Minimal Residual Disease in Chronic Myeloid Leukemia

The BCR-ABL1 sequence has advantages over the BCR-ABL1 transcript as a molecular marker in chronic myeloid leukemia and has been used in research studies. We developed a DNA real-time quantitative PCR (qPCR) method for quantification of BCR-ABL1 sequences, which is also potentially suitable for routine use. The BCR-ABL1 breakpoint was sequenced after isolation by nested short-range PCR of DNA from blood, marrow, and cells on slides, obtained either at diagnosis or during treatment, or from artificial mixtures. PCR primers were chosen from a library of presynthesized and pretested BCR (n = 19) and ABL1 (n = 568) primers. BCR-ABL1 sequences were quantified relative to BCR sequences in 521 assays on 266 samples from 92 patients. For minimal residual disease detectable by DNA qPCR and RT-qPCR, DNA qPCR gave similar minimal residual disease results as RT-qPCR but had better precision at low minimal residual disease levels. The limit of detection of DNA qPCR depended on the amount of DNA assayed, being 10(-5.8) when 5 μg was assayed and 10(-7.0) when 80 μg was assayed. DNA qPCR may be useful and practical for monitoring the increasing number of patients with minimal residual disease around or below the limit of detection of RT-qPCR as the assay itself is simple and the up-front costs will be amortized if sequential assays are performed.

Molecular relapse can be detected in blood in a sensitive and timely fashion in B-lineage acute lymphoblastic leukemia.

Molecular relapse can be detected in blood in a sensitive and timely fashion in B-lineage acute lymphoblastic leukemia

Leukaemia presenting as marrow hypoplasia: molecular detection of the leukaemic clone at the time of initial presentation

Occasional cases of transient marrow hypoplasia in childhood evolve into acute leukaemia. We studied two children who presented with marrow hypoplasia following infection and who developed acute lymphoblastic leukaemia 2–3 months later. A simple polymerase‐chain‐reaction (PCR) test for monoclonality showed that immunoglobulin heavy‐chain gene rearrangements of the same size were present at the times of both hypoplasia and leukaemia, and DNA sequencing confirmed identity of these rearrangements. PCR‐based quantification, using patient‐specific primers, showed in both patients that the leukaemic clone made up 20–25% of the marrow cells during hypoplasia. In contrast, four patients with typical aplastic anaemia showed only polyclonal B‐cell populations in the marrow. We conclude that the leukaemic clone was already present at the time of hypoplasia in the two index patients and that in future a simple PCR test for monoclonality could be used to screen patients with marrow aplasia or hypoplasia for the presence of a monoclonal B‐cell population. Patients with monoclonal populations could then be monitored carefully for subsequent development of leukaemia.