RT-PCR method with increased sensitivity shows persistence of PML-RARA fusion transcripts in patients in long-term remission of APL

The clinically relevant CHK1 inhibitor MK-8776 induces the degradation of the oncogenic protein PML-RARα and overcomes ATRA resistance in acute promyelocytic leukemia cells

Acute promyelocytic leukemia (APL) is a hematological disease characterized by the expression of the oncogenic fusion protein PML-RARα. The current treatment approach for APL involves differentiation therapy using all-trans retinoic acid (ATRA) and arsenic trioxide (ATO). However, the development of resistance to therapy, occurrence of differentiation syndrome, and relapses necessitate the exploration of new treatment options that induce differentiation of leukemic blasts with low toxicity. In this study, we investigated the cellular and molecular effects of MK-8776, a specific inhibitor of CHK1, in ATRA-resistant APL cells. Treatment of APL cells with MK-8776 resulted in a decrease in PML-RARα levels, increased expression of CD11b, and increased granulocytic activity consistent with differentiation. Interestingly, we showed that the MK-8776-induced differentiating effect resulted synergic with ATO. We found that the reduction of PML-RARα by MK-8776 was dependent on both proteasome and caspases. Specifically, both caspase-1 and caspase-3 were activated by CHK1 inhibition, with caspase-3 acting upstream of caspase-1. Activation of caspase-3 was necessary to activate caspase-1 and promote PML-RARα degradation. Transcriptomic analysis revealed significant modulation of pathways and upstream regulators involved in the inflammatory response and cell cycle control upon MK-8776 treatment. Overall, the ability of MK-8776 to induce PML-RARα degradation and stimulate differentiation of immature APL cancer cells into more mature forms recapitulates the concept of differentiation therapy. Considering the in vivo tolerability of MK-8776, it will be relevant to evaluate its potential clinical benefit in APL patients resistant to standard ATRA/ATO therapy, as well as in patients with other forms of acute leukemias.

Measurable residual disease testing in acute myeloid leukaemia

There is considerable interest in developing techniques to detect and/or quantify remaining leukaemia cells termed measurable or, less precisely, minimal residual disease (MRD) in persons with acute myeloid leukaemia (AML) in complete remission defined by cytomorphological criteria. An important reason for AML MRD-testing is the possibility of estimating the likelihood (and timing) of leukaemia relapse. A perfect MRD-test would precisely quantify leukaemia cells biologically able and likely to cause leukaemia relapse within a defined interval. AML is genetically diverse and there is currently no uniform approach to detecting such cells. Several technologies focused on immune phenotype or cytogenetic and/or molecular abnormalities have been developed, each with advantages and disadvantages. Many studies report a positive MRD-test at diverse time points during AML therapy identifies persons with a higher risk of leukaemia relapse compared with those with a negative MRD-test even after adjusting for other prognostic and predictive variables. No MRD-test in AML has perfect sensitivity and specificity for relapse prediction at the cohort- or subject levels and there are substantial rates of false-positive and -negative tests. Despite these limitations, correlations between MRD-test results and relapse risk have generated interest in MRD-test result-directed therapy interventions. However, convincing proof that a specific intervention will reduce relapse risk in persons with a positive MRD-test is lacking and needs testing in randomized trials. Routine clinical use of MRD-testing requires further refinements and standardization/harmonization of assay platforms and results reporting. Such data are needed to determine whether results of MRD-testing can be used as a surrogate end point in AML therapy trials. This could make drug-testing more efficient and accelerate regulatory approvals. Although MRD-testing in AML has advanced substantially, much remains to be done.

Molecular Monitoring as a Path to Cure Acute Promyelocytic Leukemia

Acute promyelocytic leukemia (APL) is a molecularly well-defined disease, characterized by a specific chromosomal translocation; the improvement in biologic and clinical knowledge and subsequent introduction of molecularly targeted therapies have transformed the management of APL, with survival rates now exceeding 80%. Minimal residual disease (MRD) assessment in APL is the most important tool for its treatment; the prognostic role of the molecular detection of promyelocytic leukemia retinoic acid receptor α (PML-RARα) transcript after consolidation therapy in the early identification of the following hematologic relapse is now well established and guides preemptive therapy. First experiences performed with a qualitative polymerase chain reaction (PCR) approach were replaced with more accurate real-time quantitative PCR (RQ-PCR), which guarantees a numeric quantification of MRD. The identification of arsenic trioxide (ATO) as a valid therapy not only in relapsed patients but also as an alternative to standard therapy alone or in association with all-trans-retinoic acid enlarges the setting of validation of MRD evaluation in APL patients, considering a possible different clearance of PML-RARα with innovative therapy different from the standard ones. MRD monitoring demonstrated its validity also in the setting of relapsed patients with interesting results in the autologous and allogeneic stem cell transplantation setting or with the use of other biological agents. The aim of this review is to report and discuss the actual state of the art of MRD in APL.

Advancing the Minimal Residual Disease Concept in Acute Myeloid Leukemia

The criteria to evaluate response to treatment in acute myeloid leukemia (AML) have changed little in the past 60 years. It is now possible to use higher sensitivity tools to measure residual disease burden in AML. Such minimal or measurable residual disease (MRD) measurements provide a deeper understanding of current patient status and allow stratification for risk of subsequent clinical relapse. Despite these obvious advantages, and after over a decade of laboratory investigation and preclinical validation, MRD measurements are not currently routinely used for clinical decision-making or drug development in non-acute promyelocytic leukemia (non-APL) AML. We review here some potential constraints that may have delayed adoption, including a natural hesitancy of end users, economic impact concerns, misperceptions regarding the meaning of and need for assay sensitivity, the lack of one single MRD solution for all AML patients, and finally the need to involve patients in decision-making based on such correlates. It is our opinion that none of these issues represent insurmountable barriers and our hope is that by providing potential solutions we can help map a path forward to a future where our patients will be offered personalized treatment plans based on the amount of AML they have left remaining to treat.

Real-time PCR analysis of PML-RARα in newly diagnosed acute promyelocytic leukaemia patients treated with arsenic trioxide as a front-line therapy

BACKGROUND

Recently, patients with acute promyelocytic leukaemia (APL) have experienced significant clinical gains after treatment with arsenic trioxide. However, the use of this agent as a front-line therapy for newly diagnosed patients is unclear.

PATIENTS AND METHODS

Of 95 newly diagnosed APL patients, 85 patients who achieved complete remission (CR) were sequentially evaluated during a 4-60 month period by conventional RT-PCR. A total of 30 patients (six relapsed and 24 in continued CR) were selected and monitored by quantitative real-time PCR (RQ-PCR) assay. The PML-RARalpha fusion transcripts values were normalised to every 10(6) copies of G6PDH transcripts (NQ).

RESULTS

RQ-PCR analyses showed a rapid rate of clearance of NQ levels during the courses of arsenic therapy. In the majority of patients in CR, the NQ levels were below 5 x 10(2) in peripheral blood (PB) samples. In all the relapsed cases with follow-up intervals of 1-6 months (median 3 months) clinical relapse was predictable by increasing NQ level above this threshold.

CONCLUSIONS

Our study highlights the usefulness of PB and the definition of threshold level for early prediction of relapse. The threshold level correlates well with risk of relapse; therefore, transcript ratio below the level should be regarded as a goal in the clinical management of this disease.

Pathogenesis, diagnosis and monitoring of residual disease in acute promyelocytic leukaemia

The clinical course of acute promyelocytic leukaemia (APL) has changed over the last 25 years from one that was fatal for the majority of patients to representing one of the most curable subtypes of acute myeloid leukaemia. Besides improved supportive care this has mainly been achieved through the introduction of novel targeted therapies in the form of all-trans retinoic acid (ATRA) and arsenic trioxide that specifically address the underlying molecular lesion. APL is characterized by chromosomal rearrangements of 17q21 leading to the formation of fusion proteins involving retinoic acid receptor alpha (RARA). To date five different fusion partners of RARA have been identified, but the vast majority of cases are characterized by the presence of the t(15;17)(q22;q12-21), which involves the promyelocytic leukaemia (PML) gene. The identification of different breakpoint microclusters within RARA intron 2 suggests that sequence-associated or structural factors play a role in the formation of the t(15;17). In addition, the comparison of forward and reverse genomic junctions has revealed microhomologies, deletions and/or duplications of either gene consistent with the hypothesis that the t(15;17) occurs by non-homologous recombination of DNA after processing of the double strand breaks by a dysfunctional DNA damage repair mechanism. The detection of the PML-RARA fusion gene by reverse-transcription polymerase chain reaction (RT-PCR) is routinely used for diagnosis and monitoring of minimal residual disease (MRD). In PML-RARA-positive APL about 70% of patients are expected to be cured with a combination of ATRA and anthracycline-based chemotherapy. However, relapse remains a major problem. The identification of patients at high risk of relapse and the development of risk-adapted treatment schedules are therefore clearly the most challenging tasks in the treatment of APL. Recent studies have shown that pre-emptive chemotherapy at the time of molecular relapse improves survival compared to treatment at the point of haematological relapse. Quantitative RT-PCR technology is expected to further improve the predictive value of MRD monitoring and therefore to guide therapy in order to reduce the rate of relapses and to increase rates of cure in high-risk patients.

The importance of molecular monitoring in acute promyelocytic leukaemia

Acute promyelocytic leukaemia (APL) is characterized by a unique genetic marker in virtually 100% of cases, i.e. the PML/RARalpha fusion gene which is readily amplified by the reverse transcriptase-polymerase chain reaction (RT-PCR) method. Several international groups reported the prognostic significance of minimal residual disease (MRD) assessment in APL, indicating that sequential PCR analysis should be used as a guide to therapy. In fact, such evaluation offers the possibility of identifying, after front-line treatment, either patients requiring additional therapy or patients at low risk who are presumably cured and who may be spared unnecessary toxicity. In this view, the terms molecular remission and molecular relapse are now widely employed to define a more advanced therapeutic objective and a condition necessitating anticipated salvage, respectively. The introduction of quantitative PCR through automated technologies is likely to further improve standardization of the method and comparison of results obtained in the context of large clinical trials.

Monitoring PML-RARalpha in acute promyelocytic leukemia

Acute promyelocytic leukemia (APL) is characterized by a translocation between the promyelocytic leukemia gene (PML) on chromosome 15 and the retinoic acid receptor-alpha (RARalpha) gene on chromosome 17. Reverse-transcription polymerase chain reaction (RT-PCR) amplification of PML-RARalpha messenger RNA can establish the diagnosis of APL, predict response to all-trans retinoic acid and arsenic trioxide, detect minimal residual disease, and predict relapse. Quantitative "real-time" RT-PCR techniques may improve residual disease assessment by facilitating more rapid and standardized results. APL provides a useful model in which therapy is targeted to an underlying genetic aberration and treatment is adapted based on monitoring of residual disease.

Acute promyelocytic leukemia: a model for the role of molecular diagnosis and residual disease monitoring in directing treatment approach in acute myeloid leukemia

Acute promyelocytic leukemia (APL) is characterized by a number of features that underpin the need for rapid and accurate diagnosis and demand a highly specific treatment approach. These include the potentially devastating coagulopathy, sensitivity to anthracycline-based chemotherapy regimens, as well as unique responses to all-trans retinoic acid and arsenic trioxide that have revolutionized therapy over the last decade. The chromosomal translocation t(15;17) which generates the PML-RARalpha fusion gene has long been considered the diagnostic hallmark of APL; however, this abnormality is not detected in approximately 10% cases with successful karyotype analysis. In the majority of these cases, the PML-RARalpha fusion gene is still formed, resulting from insertion events or more complex rearrangements. These cases share the beneficial response to retinoids and favorable prognosis of those with documented t(15;17), underscoring the clinical relevance of molecular analyses in diagnostic refinement. In other cases of t(15;17) negative APL, various chromosomal rearrangements involving 17q21 have been documented leading to fusion of RARalpha to alternative partners, namely PLZF, NPM, NuMA and STAT5b. The nature of the fusion partner has a significant bearing upon disease characteristics, including sensitivity to retinoids and arsenic trioxide. APL has provided an exciting treatment model for other forms of AML whereby therapeutic approach is directed towards cytogenetically and molecularly defined subgroups and further modified according to response as determined by minimal residual disease (MRD) monitoring. Recent studies suggest that rigorous MRD monitoring, coupled with pre-emptive therapy at the point of molecular relapse improves survival in the relatively small subgroup of PML-RARalpha positive patients with 'poor risk' disease. Advent of 'real-time' quantitative RT-PCR technology seems set to yield further improvements in the predictive value of MRD assessment, achieve more rapid sample throughput and facilitate inter- and intra-laboratory standardization, thereby enabling more reliable comparison of data between international trial groups.

The significance of minimal residual disease in patients with t(15;17)

Acute promyelocytic leukaemia (APL) is characterized by the t(15;17)(q22;q21) leading to the formation of PML-RARalpha and RARalpha-PML fusion genes which provide suitable targets for the assessment of minimal residual disease (MRD). Studies have focused upon detection of PML-RARalpha because, although assays for RARalpha-PML transcripts are more sensitive, they are not applicable to 25% of cases. Among patients receiving standard therapy (ATRA and anthracycline-based chemotherapy), qualitative assays using a nested reverse transcriptase-polymerase chain reaction (RT-PCR), which typically achieve sensitivities of 1 in 10(4), have been found to provide independent prognostic information suitable for directing an approach to treatment. Detection of PML-RARalpha at the end of consolidation, or subsequent recurrence of PCR positivity, heralds relapse, which may, however, be averted by additional therapy leading to improvements in survival for this "high-risk" subgroup of patients. MRD analysis has also proved of value in predicting response to autologous transplant procedures undertaken in second complete remission and in directing the need for additional therapy in the post-transplantation setting. Overall, these studies undertaken within the context of a relatively homogeneous disease entity confirm that MRD monitoring provides independent prognostic information, serving as a valuable model for improving treatment strategy in other molecularly defined subsets of acute myeloid leukaemia (AML). Nevertheless, conventional nested RT-PCR assays fail to detect residual disease in a significant proportion of patients who ultimately relapse, which may be a reflection of RNA quality and/or assay sensitivity. Therefore, it is hoped that "real-time" quantitative RT-PCR technology (RQ-PCR) which permits quantification of fusion gene transcripts in relation to endogenous control genes will be even more predictive of outcome and achieve greater standardization of MRD detection in the context of large-scale clinical trials.

Detection of minimal residual disease

A high percentage of patients with leukemia, lymphoma, and solid tumors achieve a complete clinical remission after initial treatment, but the majority of these patients will finally relapse from residual tumor cells detectable in clinical remission only by the most sensitive methods. The in vitro amplification of tumor-specific DNA or RNA sequences by polymerase chain reaction (PCR) allows identification of a few neoplastic cells in 10(4) to 10(6) normal cells. Depending on the underlying malignant disease and therapeutic treatment, the presence of residual tumor cells in an individual patient may herald relapse, but a long-term stable situation or slowly vanishing tumor cells are also possible. Molecular monitoring of residual leukemia and lymphoma cells by quantitative PCR techniques has provided important information about the effectiveness of treatment and the risk of recurrent disease as shown by minimal residual disease (MRD) analysis in patients with various malignant diseases. Such diseases include childhood acute lymphoblastic leukemia, after induction therapy; acute promyelocytic leukemia, during and after chemotherapy; and chronic myelogenous leukemia, during treatment with alpha-interferon and after allogeneic bone marrow transplantation. Evaluation of the predictive value of the detection of MRD has to take into account its evolution and course, the pathogenesis, biology, and natural course of the underlying malignant disease, the molecular genetic lesion, and finally, the type of treatment. Quantification of minimal residual cells by the recently developed real-time quantitative PCR technique will surely have a major impact on our therapeutic strategies for patients with leukemia, lymphomas, and solid tumors. Based on quantitative PCR data, the terms molecular remission and molecular relapse have to be exactly defined and validated in prospective clinical trials to assess the biological and clinical significance of MRD in various types of malignancies.

Pre-clinical validation of a novel, highly sensitive assay to detect PML-RARalpha mRNA using real-time reverse-transcription polymerase chain reaction

We have developed a sensitive and quantitative reverse-transcription polymerase chain reaction (RT-PCR) assay for detection of PML-RARalpha, the fusion oncogene present as a specific marker in >99% of cases of acute promyelocytic leukemia (APL). The assay is linear over at least 5 orders of magnitude of input DNA or RNA, and detects as few as 4 copies of PML-RARalpha plasmid DNA. PML-RARalpha transcripts could be detected in mixtures containing 2 to 5 pg of RNA from fusion-containing cells in a background of 1 microg of RNA from PML-RARalpha-negative cells. Using 1.0 to 2.5 microg of input RNA, the sensitivity of the assay was between 10(-5) and 10(-6). Furthermore, determination of GAPDH copy number in each reaction allowed an accurate assessment of sample-to-sample variation in RNA quality and reaction efficiency, with consequent definition of a detection limit for each sample assayed. Using an internal calibrator, assay precision was high, with coefficients of variation between 10 and 20%. An interlaboratory study using coded samples demonstrated excellent reproducibility and high concordance between laboratories. This assay will be used to test the hypothesis that sensitive and quantitative measurement of leukemic burden, during or after therapy of APL, can stratify patients into discrete risk groups, and thereby serve as a basis for risk-adapted therapy in APL.

Quantitative determination of gene expression in human lymphocytes assessed by reverse transcription-polymerase chain reaction coupled to high-performance liquid chromatography

Gene expression in human lymphocytes was assessed using reverse transcription and polymerase chain reaction amplification followed by ion-pair reversed-phase chromatography analysis. Competitive PCR was used to quantitate the desired cDNAs with a polivalent competitor adaptable to multiple novel mRNAs estimations with minor changes. Accuracy was 11.27+/- 11.87% (n = 7), as determined using standards. The coefficients of variation of the assessment of human OK12b were 7% (n = 6), 7.68 attmol/microg of total RNA, and 21% (n = 6), 0.93 attmol/microg of total RNA. Sample-to-sample variation in the reverse transcription and in the quantity and quality of RNA was attenuated by normalising results to beta-actin mRNA expression. The correlation between the OK12b/beta-actin ratio and competitive assessments of OK12b was 0.984, n = 6. The correlation between HPLC results and an independent method based on radionuclide uptake by the product, detected by electrophoretic separation, was 0.848, n = 10.

Minimal residual disease (MRD) in remission t(8;21) AML and in vivo differentiation detected by FISH and CD34+ cell sorting

Many patients with t(8;21) AML have residual positive cells during remission. We previously developed D-FISH probes that detect both derivative chromosomes and the normal alleles. In negative controls, only 2/44,000 (0.0045%) positive signals were observed. To investigate MRD, we examined specimens from 29 patients who had initially obtained CR. In remission patients, 61% had 1-4/2000 positive cells (0.05-0.19%). Higher frequencies were found in two patients in early relapse and in one patient in early remission. However, a negative test did not exclude relapse. Since false positives were negligible and because most t(8;21) AMLs express CD34, we asked whether cell sorting combined with FISH would increase the sensitivity. In one patient, we observed that 80% of CD34+ cells were t(8;21)+ at 2 months from initial clinical and cytogenetic remission. However, by 5 months the pre- and post-sorted populations contained 0.15% and 0.06% t(8;21) cells, respectively. Whereas essentially all t(8;21) cells in the initial specimen expressed CD34, only 0.6% were subsequently CD34+. These results are consistent with in vitro assays showing that residual t(8;21) cells undergo differentiation. Thus, FISH can identify MRD in a majority of t(8;21) patients and, combined with CD34+ selection, may provide an indirect assessment of the differentiation state of residual t(8;21) cells.

The clinical significance of cytogenetic abnormalities in acute myeloid leukaemia

During the last three decades it has become apparent that the majority of cases of acute myeloid leukaemia (AML) are characterized by at least one of a variety of recurrent chromosomal abnormalities. These changes have been found in many instances to correlate closely with distinct morphological features and clinical characteristics, the molecular basis of which is becoming increasingly understood. Furthermore, diagnostic karyotype has been shown to be a key determinant of outcome in AML, with mounting evidence to support the notion that cytogenetic analysis can serve to identify biologically distinct subsets of disease that demand tailored therapeutic approaches. This has led to a rising trend towards routine cytogenetic and molecular characterization of newly diagnosed acute leukaemia, providing a framework for treatment stratification.

Current recommendations for positive controls in RT-PCR assays

The choice of adequate controls for reverse transcriptase (RT-) PCR analysis has been the focus of a debate pursued in Leukemia over the past 3 years. Twenty-six authors from 15 different centers contributed to the Debate, and the points presented have been carefully evaluated. This survey reviews the issues discussed, and presents current options for appropriate positive controls in RT-PCR assays which are based on the views shared by the majority of participants in the Debate. It is understood, however, that the recommendations presented cannot be regarded as definitive guidelines. They reflect the present state of knowledge, and certainly need to be revisited.

Monitoring minimal residual disease and predicting relapse in APL by quantitating PML-RARalpha transcripts with a sensitive competitive RT-PCR method

Qualitative RT-PCR methods used for monitoring minimal residual disease (MRD) in APL patients fail to predict relapse in up to 25% of patients in remission. We report here the development and evaluation of a highly sensitive (10(-5) and 10(-6) with one round and two rounds of PCR, respectively) competitive RT-PCR method to quantitate the PML-RARalpha fusion transcripts. PML-RARalpha transcript's levels were normalised to 10(5) copies of ABL transcript. Serial BM and PB samples from 16 patients with APL and t(15;17) were examined. Presentation samples from three patients (three BM, one PB) showed levels in the range of 0.7 x 10(6)-3.5 x 10(6) and 1.2 x 10(5) molecules in BM and PB samples respectively. Serial quantitation of MRD in both BM and PB samples showed significantly lower levels of PML-RARalpha transcripts in remission, although the majority of samples remain positive for the PML-RARalpha transcripts even those in long-term remission (up to 94 months). Levels of PML-RARalpha in remission samples were up to 2 x 10(2) and up to 5.2 x 10(1) molecules in BM and PB respectively. BM and PB samples taken from two patients 2-4 months before relapse showed significantly higher levels of PML-RARalpha transcripts (1.2 x 10(4) molecules in BM; 3.5 x 102, 1.2 x 10(2) and 1.2 x 10(3) in PB). The same samples, when tested with a standard qualitative RT-PCR for the amplification of PML-RARalpha (with a sensitivity of 10(-4)) produced negative results. This indicates that the qualitative methods would not have predicted relapse in these patients. Our data show that quantitating PML-RARalpha transcripts with a sensitive method may provide a superior approach for monitoring MRD in APL and identifying patients at high risk of relapse.

Monitoring of minimal residual disease in children with acute promyelocytic leukemia by RT-PCR detecting PML/RARalpha chimeric gene: a retrospective study of clinical feasibility

We studied retrospectively the clinical feasibility of minimal residual disease (MRD) monitoring by reverse transcription-polymerase chain reaction (RT-PCR) detecting the PML/retinoic acid receptor alpha (RARalpha) chimeric gene in children with acute promyelocytic leukemia (APL). MRD monitoring of APL was performed with standard and nested RT-PCR for PML/RARalpha gene, the sensitivity of which was 1 leukemic cell in 10(3)-10(4) and 1 in 10(4)-10(5) cells, respectively. Patients were nine children with APL (average age: 8.3 year; average period of follow-up: 69.2 months) who, after achieving remission with all-trans retinoic acid (ATRA), received treatment either with multidrug chemotherapy or with a combination of chemotherapy and ATRA. Out of six patients treated with multidrug-combined chemotherapy, two patients exhibited PCR positivity after six months of post- remission therapy, which shifted from the detectable range of the nested PCR to that of the standard PCR. These two patients subsequently relapsed and, together with two of the other patients receiving multidrug-combined chemotherapy, underwent allogeneic bone marrow transplantation. No MRD was detected in these patients after transplantation. In the remaining three patients who underwent cyclic treatment with alternative chemotherapy and ATRA, two showed positive RT-PCR at the nested or standard level, respectively, after six months of combined therapy, and one of them relapsed. Overall, three of four patients with MRD detected in post-remission period ultimately relapsed, while all of five patients without detectable MRD had a good prognosis. These findings suggest that impending relapse may be predicted by the detection of preceding PCR positivity with an increasing quantity of the PML/RARalpha mRNA that appears beyond six months of post-remission chemotherapy, with or without combined ATRA therapy.

Fluorescence in situ hybridization: molecular probes for diagnosis of pediatric neoplastic diseases

Fluorescence in situ hybridization (FISH) has become an important tool for diagnosing neoplasia in children. With probes designed to identify specific chromosomes and chromosomal regions, FISH is commonly used to detect the specific chromosomal abnormalities associated with hematologic diseases and solid tumors. Variations of FISH currently being investigated, such as comparative genomic hybridization, multicolor FISH, and microchip arrays, will probably result in additional uses of FISH in both research and clinical cytogenetic laboratories. Although FISH has disadvantages when compared with conventional cytogenetics and molecular methods, FISH will continue to be important in analyzing chromosomal abnormalities of tumors in children.

Presenting White Blood Cell Count and Kinetics of Molecular Remission Predict Prognosis in Acute Promyelocytic Leukemia Treated With All-Trans Retinoic Acid: Result of the Randomized MRC Trial

All-trans retinoic acid (ATRA) is an essential component of the treatment of acute promyelocytic leukemia (APL), but the optimal timing and duration remain to be determined. Molecular characterization of this disease can refine the diagnosis and could be potentially useful in monitoring response to treatment. Patients defined morphologically to have APL were randomized to receive a 5-day course of ATRA before commencing chemotherapy or to receive daily ATRA commencing with chemotherapy and continuing until complete remission (CR). The chemotherapy was that used in current MRC Leukaemia Trials. Outcome comparisons were by intention to treat with additional analysis for relevant risk factors. Patients were characterized by molecular techniques for the fusion products of the t(15;17) and monitored by reverse transcriptase-polymerase chain reaction (RT-PCR) during and after treatment. Two hundred thirty-nine patients were randomized. Treatment with extended ATRA resulted in a superior remission rate (87% v 70%, P < .001), due to fewer early and induction deaths (12% v 23%, P = .02), and less resistant disease (2% v 7%, P = .03), which was associated with a significantly more rapid recovery of neutrophils and platelets. Extended ATRA reduced relapse risk (20%v 36% at 4 years, P = .04) and resulted in superior survival (71% v 52% at 4 years, P = .005). Presenting white blood cell count (WBC) was a key determinant of outcome. The 70% of patients who presented with a WBC less than 10 × 109/L had a better CR (85% v62%, P = .0001) and reduced relapse risk (22% v42%, P = .002) and superior survival (69%v 43%, P < .0001). Within the low count group, extended ATRA resulted in a better CR (94% v 76%, P= .001), reduced relapse risk (13% v 35%, P = .04), and improved survival (80% v 57%, P = .0009). There was no evidence of benefit in patients presenting with a higher WBC (>10 × 109/L). Molecular monitoring after the third chemotherapy course had a correlation with risk of relapse. The relapse risk was 57% if the RT-PCR was positive versus 27% if the RT-PCR was negative (P = .006). APL patients who present with a low WBC derive substantial benefit from combining ATRA with induction chemotherapy until remission is achieved, whereas patients with a higher WBC did not benefit. Molecular characterization of disease can improve diagnostic precision and a positive RT-PCR after consolidation identifies patients at a higher risk of relapse.

Presenting White Blood Cell Count and Kinetics of Molecular Remission Predict Prognosis in Acute Promyelocytic Leukemia Treated With All-Trans Retinoic Acid: Result of the Randomized MRC Trial

All-trans retinoic acid (ATRA) is an essential component of the treatment of acute promyelocytic leukemia (APL), but the optimal timing and duration remain to be determined. Molecular characterization of this disease can refine the diagnosis and could be potentially useful in monitoring response to treatment. Patients defined morphologically to have APL were randomized to receive a 5-day course of ATRA before commencing chemotherapy or to receive daily ATRA commencing with chemotherapy and continuing until complete remission (CR). The chemotherapy was that used in current MRC Leukaemia Trials. Outcome comparisons were by intention to treat with additional analysis for relevant risk factors. Patients were characterized by molecular techniques for the fusion products of the t(15;17) and monitored by reverse transcriptase-polymerase chain reaction (RT-PCR) during and after treatment. Two hundred thirty-nine patients were randomized. Treatment with extended ATRA resulted in a superior remission rate (87% v 70%, P &lt; .001), due to fewer early and induction deaths (12% v 23%, P = .02), and less resistant disease (2% v 7%, P = .03), which was associated with a significantly more rapid recovery of neutrophils and platelets. Extended ATRA reduced relapse risk (20%v 36% at 4 years, P = .04) and resulted in superior survival (71% v 52% at 4 years, P = .005). Presenting white blood cell count (WBC) was a key determinant of outcome. The 70% of patients who presented with a WBC less than 10 × 109/L had a better CR (85% v62%, P = .0001) and reduced relapse risk (22% v42%, P = .002) and superior survival (69%v 43%, P &lt; .0001). Within the low count group, extended ATRA resulted in a better CR (94% v 76%, P= .001), reduced relapse risk (13% v 35%, P = .04), and improved survival (80% v 57%, P = .0009). There was no evidence of benefit in patients presenting with a higher WBC (&gt;10 × 109/L). Molecular monitoring after the third chemotherapy course had a correlation with risk of relapse. The relapse risk was 57% if the RT-PCR was positive versus 27% if the RT-PCR was negative (P = .006). APL patients who present with a low WBC derive substantial benefit from combining ATRA with induction chemotherapy until remission is achieved, whereas patients with a higher WBC did not benefit. Molecular characterization of disease can improve diagnostic precision and a positive RT-PCR after consolidation identifies patients at a higher risk of relapse.