Quantification of minimal residual disease in T-lineage acute lymphoblastic leukemia with the TAL-1 deletion using a standardized real-time PCR assay.

Hematologic relapse remains the greatest obstacle to the cure of children with acute lymphoblastic leukemia (ALL). Recent studies have shown that patients with increased risk of relapse can be identified by measuring residual leukemic cells, called minimal residual disease (MRD), during clinical remission. Current PCR methods, however, for measuring MRD are cumbersome and time-consuming. To improve and simplify MRD assessment, we developed a real-time quantitative PCR (RQ-PCR) assay for detection of leukemic cells that harbor the TAL-1 deletion. We studied serial dilutions of leukemic DNA and found the assay had a sensitivity of detection of one leukemic cell among 100,000 normal cells. We then investigated 23 samples from eight children with ALL in clinical remission. We quantified residual leukemic cells by using the TAL-1 RQ-PCR assay and by using limiting dilution analysis. In 17 samples, both methods detected MRD levels > or =0.001%. The percentages of leukemic cells measured by the two methods correlated well (r2 = 0.926). In the remaining six samples, both methods detected fewer than 0.001% leukemic cells. We conclude the TAL-1 RQ-PCR assay can be used for rapid, sensitive and accurate assessment of MRD in T-lineage ALL with the TAL-1 deletion.     

DNA diagnosis of human cancers: lymphoid malignancies and leukemia

Usefulness of DNA analysis in diagnosis of hematopoietic malignancy was discussed. Examination on the presence of rearrangement in immunoglobulin (Ig) and T cell receptor (TCR) was the first DNA analysis used for clinical diagnosis of lymphoid malignancy to determine the cell-lineage and clonality of proliferating lymphoid cells. One point mutation in ras oncogene has also been used to detect residual leukemic cells as well as diagnosis of the early relapse of leukemia, although not all leukemic cells have this mutation. Presence of BCR-abl fused gene is a genetic marker for Ph1 chromosome. Analysis of BCR-abl gene has made it possible to diagnose the Ph1 ALL and masked Ph1 CML. Development of PCR technique markedly increased the possibility for the use of DNA analysis in clinical medicine. In addition to Ph1 chromosome, various chromosomal abnormalities resulted in a reciprocal translocation between Ig or TCR gene and other genes in various lymphoid malignancies, such as Burkitt lymphoma and follicular lymphoma. These translocations can be analyzed by Southern hybridization and used for clinical diagnosis.     

Identification of early relapsing patients with adult acute nonlymphocytic leukemia by bone marrow biopsy after initial induction chemotherapy

Bone marrow biopsies obtained from 69 adult patients with acute nonlymphocytic leukemia (ANLL) six to 10 days after initial induction chemotherapy were reviewed blindly to detect the presence of residual leukemia. Discrimination between the presence or absence of leukemic cells was provided by assessment of the numbers, clustering, and nuclear morphology of blasts and promyelocytes. Twenty-six patients had frank leukemia, 25 had no apparent leukemic cells, and 18 had focal residual leukemia. Of 25 patients whose bone marrow contained no detectable residual leukemic cells, 21 gained complete remission without further chemotherapy. These patients had a median duration of remission of 278 days, with five patients still remaining in remission for 578-882 days. Similarly, all of the 18 patients who had focal residual leukemia achieved complete remission without additional chemotherapy; however, all have relapsed with a median duration of remission of 163 days. This study indicates that patients with foci of residual leukemia in their one-week posttreatment bone marrow samples readily achieve remission, but carry a substantial leukemic burden that increases the likelihood of early relapse.     

Quantitation of minimal residual disease in acute myelogenous leukemia and myelodysplastic syndromes in complete remission by molecular cytogenetics of progenitor cells.

Detection of karyotypic clonal abnormalities are prognostically useful in patients with acute myelogenous leukemia (AML) and myelodysplastic syndromes (MDS), but cytogenetic methods are not sensitive enough to detect low numbers of residual leukemic cells in patients who have achieved complete remission (CR). Fluorescence in situ hybridization (FISH) and fluorescence activated cell sorting (FACS) were used to investigate the frequency and presence of minimal residual disease (MRD) in AML and MDS patients (n = 28) with monosomy of chromosomes 7, 17 and 18 and trisomy of chromosomes 6, 8, 9 and 10 in CR. MRD was detected in all patients with monosomy 7 (n = 10) and followed by relapse in eight patients after 4.8 +/- 3.1 months. In contrast, persistent leukemic cells occurred in 11/12 patients with trisomy 8, but only three of them relapsed after 7.7 +/- 4.0 months. Cox regression analysis showed that cytogenetic class and levels of clonal cells at CR were related to time to relapse (P = 0.001). The level of MRD identified patients at high and low risk of relapse. High absolute levels of proliferating residual leukemic cells correlated with monosomy 7 and high risk of relapse.     

Minimal residual disease in childhood acute lymphoblastic leukemia: analysis of patients in continuous complete remission or with consecutive relapse.

Differences in tumor cell burden among acute lymphoblastic leukemia (ALL) patients are largely unexplored, because methods of detecting residual malignant cells have not been sufficiently sensitive. Using the polymerase chain reaction (PCR) amplification of rearranged T-cell receptor delta(TCR delta)-chain junctional sequences for the preparation of clonospecific probes, we performed a retrospective PCR study of remission bone marrow (BM) samples in seven pediatric patients with ALL who subsequently relapsed (the largest series studied so far) and in 10 patients who were in longterm (greater than 39 to greater than 72 months) remission. Following two rounds of PCR primed by nested amplimers, 1 x 10(-4) to 1 x 10(-6) cells could be identified in 16 out of 17 cases. PCR analysis of 39 BM and peripheral blood samples obtained from ALL patients considered to be in complete remission according to morphological criteria revealed the following results. In BM remission specimens of all 10 patients in continuous complete remission for a long time (median 55 months), no residual leukemic cells could be identified in the latest remission sample available for PCR analysis. In three patients the persistence of residual leukemic cells, or the continuous increase of residual blasts to the point of clinical manifestation, were indicative of impending relapse. In three patients PCR analysis failed to identify residual leukemic cells in BM samples obtained 2, 6 and 16 months respectively before clinical relapse. Differences in the duration of minimal residual disease were not associated with distinct clinical-hematological features. In one patient a different pattern of V delta 2 recombination occurred in leukemic cells from diagnosis to relapse, thus preventing the further monitoring of the patient by the initial clonospecific probe.     

Intratesticular transplantation of testicular cells from leukemic rats causes transmission of leukemia

A rat T-cell leukemia model was used to study the safety of germ cell transplantation as a mean of preventing infertility in males undergoing gonadotoxic cancer treatment. Donor germ cells were harvested from the testes of terminally ill leukemic rats and were either used directly or cryopreserved and thawed before transplantation by rete testis microinjection. All rats transplanted with testicular cells from leukemic donors developed signs of terminal rat T-cell leukemia, whereas control animals remained healthy. Cryopreservation of the donor germ cells caused a 3- to 6-day delay in the terminal phase of leukemia. When a known number of leukemic cells were mixed with germ cells and microinjected into the testis, the rate of appearance of terminal leukemia was directly related to the number of transferred leukemic lymphoblasts. As few as 20 leukemic cells were able to cause a cancer relapse resulting in terminal leukemia 21 days after transplantation in three of five transplanted animals. Our results demonstrate that germ cell transplantation with the presently used techniques is not safe enough for clinical use. Improved methods for purging testicular specimens of cancer cells or totally new approaches with transient xenogenetic host models to detect contamination of malignant cells must be developed before this technique can be offered to patients without fear of disease relapse.     

In vitro growth response to G-CSF and GM-CSF by bone marrow cells of patients with acute myeloid leukemia.

The in vitro growth response of bone marrow and blood cells to granulocyte/macrophage colony-stimulating factor (GM-CSF) and granulocyte colony-stimulating factor (G-CSF) was studied in 18 acute myeloid leukemia (AML) patients using semisolid and suspension cultures. In 80% of the cases growth of leukemic progenitor cells was stimulated by GM-CSF and/or G-CSF, as judged by colony or cluster formation. In acute promyelocytic leukemia [t(15;17)], G-CSF stimulated and maintained the leukemic progenitors only transiently but fully stimulated the residual normal granulocyte/macrophage colony-forming units (CFU-GM). In some cases of M2 and M4 leukemia, G-CSF enhanced markedly the production of mature but cytochemically abnormal neutrophils. In some cases of M1 leukemia, neither CSF stimulated leukemic progenitors but instead stimulated only residual normal granulopoiesis. Spontaneous colony formation was observed in 20% of cases and was correlated with high-grade leukemic growth in vivo and a poor response to chemotherapy. The differing effects of the CSFs upon leukemic cells and residual normal granulopoiesis may have some implications for the clinical use of GM-CSF and G-CSF to overcome infectious complications.     

PURGING OF ACUTE NON-LYMPHOCYTIC LEUKEMIA PROGENITORS BY PROCAINE AND HYPERTHERMIA

Procaine and hyperthermia have been shown to possess a relatively selective cytotoxicity to leukemlc cells. In this study, the combined effects of procaine and hyperthermia on the growth of hematopoietic progenitors (GM-CFU) and ieukemic progenitors (L-CFU) were examined to determine if this combination resulted in a great selective killing of leukemlc cells than that achieved by procaine or heat alone. When the cells were treated simutaneously with procaine (2 mM) and hyperthermia (42℃) for one hour, the killing of L-CFU was enhanced considerably whereas GM-CFU were not markedly affected. These data Indicate that the combined treatment with procain and hyperthermia might offer an efficient mean to selectively purge residual leukemlc cells in vitro. Procaine with hyperthermia may have a role in clinical autoiogous bone marrow transplantation for acute leukemia.     

Tandem application of flow cytometry and polymerase chain reaction for comprehensive detection of minimal residual disease in childhood acute lymphoblastic leukemia.

Children with acute lymphoblastic leukemia (ALL) with > or = 0.01% leukemic cells in the bone marrow after remission induction are at a greater risk of relapse. The most promising methods of detecting minimal residual disease (MRD) are flow cytometric identification of leukemia-associated immunophenotypes and polymerase chain reaction (PCR) amplification of antigen-receptor genes. However, neither assay can be applied to all patients. Moreover, both assays carry the risk of false-negative findings due to clonal evolution. The simultaneous use of both assays might resolve these problems, but the correlation between the methods is unknown. We studied serial dilutions of normal and leukemic cells by flow cytometry and PCR amplification of IgH genes and found the two methods highly sensitive (one leukemic cell among 10(4) or more normal cells), accurate (r2 was 0.999 for flow cytometry and 0.960 for PCR by regression analysis) and concordant (r2 = 0.962). We then examined 62 bone marrow samples collected from children with ALL in clinical remission. In 12 samples, both techniques detected MRD levels > or = 1 in 10(4). The percentages of leukemic cells measured by the two methods correlated well (r2 = 0.978). Of the remaining 50 samples, 48 had MRD levels < 1 in 10(4). In only two samples results were discordant: 2 in 10(4) and 5 in 10(4) leukemic cells by PCR but < 1 in 10(4) by flow cytometry. We conclude that immunologic and molecular techniques can be used in tandem for universal monitoring of MRD in childhood ALL.     

Minimal residual disease in leukemia

Recently, detection of the minimal residual disease (MRD) has become possible by polymerase chain reaction (PCR) using leukemia specific DNA or mRNA sequences originated from t(9; 22), t(1; 19) and t(14; 18) translocations, T cell receptor or immunoglobulin CDRIII. This method made possible to detect one leukemic cell out of 10(4)-10(5) cells, and the presence of MDR became clear during complete remission after chemotherapy or bone marrow transplantation. This suggests the usefulness of this method in the treatment of leukemia.     

New definition of remission in childhood acute lymphoblastic leukemia.

The extent of clearance of leukemic cells from the blood or bone marrow during the early phase of therapy is an independent prognostic factor in acute lymphoblastic leukemia (ALL). Several methods are available to measure the minimal residual disease (MRD) remaining after initial intensive chemotherapy. The most promising are flow cytometric detection of aberrant immunophenotypes and polymerase chain reaction analysis of clonal antigen-receptor gene rearrangements. When applied together, these techniques enable one to monitor MRD in virtually all cases of ALL. Patients who achieve an 'immunologic' or 'molecular' remission (ie leukemic involvement of <0.01% of nucleated bone marrow cells at the end of remission induction therapy) are predicted to have a better clinical outcome than patients whose remission is defined solely by morphologic criteria. In studies to date, patients with MRD at a level of 10(-2) or more at the end of induction have fared almost as poorly as those with > or =5% blast cells in the bone marrow (ie induction failures). Sequential monitoring of MRD can improve the clinical utility of risk assessment still further. Additional studies are needed to determine the critical levels of MRD at various times of treatment and whether therapeutic intervention based on MRD findings can improve clinical outcome.     

myc and sis expression in acute myelogenous leukemia

Several oncogenes have been reported to be expressed in normal and malignant hematopoietic cells. Since these studies have almost exclusively been done by Northern and dot blot hybridization techniques using mixed populations of cells, any conclusions concerning quantitative changes in gene expression are difficult to document. We have developed a rapid and sensitive RNA-in situ hybridization technique permitting detection of as few as five copies of mRNA per cell. Using this technique we have studied the expression of two genes, c-myc and c-sis, in acute leukemia patients as well as hematologically normal individuals. We have found that expression levels of myc and often sis are higher (greater than 5-fold) in hematopoietic cells obtained from leukemia patients than in normal hematopoietic cells. In regenerating marrow, there is a dramatic increase in the frequency of cells expressing myc at the level of five to 10 copies without the presence of any cells expressing myc at the high levels found in acute leukemia. This is completely different from leukemic remission marrow in which we find a subpopulation of cells which express myc at very high levels. At this time, the leukemic origin of this abnormal cell population is likely because of the close correlation we find between gene overexpression and leukemic phenotype as identified by double-labeling experiments. It appears that gene overexpression may be a more sensitive or an earlier marker for leukemic cells and that such an assay could be used in the detection of residual disease.     

Detection of minimal residual disease in leukemic patients with the t(10;14)(q24;q11) chromosomal translocation

Early relapse and minimal residual disease during clinical remission was examined in two patients having acute T-cell leukemia/lymphoma with the t(10;14)(q24;q11) chromosomal translocation. Molecular probes which can detect T-cell receptor alpha/delta clonal rearrangements and a TCL-3 probe which can detect the clonal rearrangement due to the chromosomal translocation failed to detect the leukemic clones during clinical remission by Southern filter hybridization. However, application of the polymerase chain reaction technology in amplification of the t(10;14)(q24;q11) chromosomal juncture during clinical remission permitted us to increase the detection level of neoplastic cells up to 1 leukemic cell/125,000 normal cells using 1 microgram of DNA. Amplified junction fragments were detected in both patients. In one case, during the period of clinical remission no amplified fragments were detected.     

BCG treatment of residual disease in acute leukemia: studies in a rat model for human acute myelocytic leukemia (BNML)

The effect of a single injection of Pasteur BCG on the growth of a myelocytic leukemia transplantable in the Brown Norway rat (BNML) was studied. BCG (3.0 mg i.v.) caused a 6-fold increase in spleen weight with marked granuloma formation. After aspecific immunostimulation the TD50 for leukemic cells increased from 38.8 to 302.2 cells. Cyclophosphamide (100 mg/kg) given 48 h prior to BCG did not influence the anti-tumor immune response. However, cyclophosphamide injected after BCG partly abolished its activity. After high-dose chemo-radiotherapy of leukemic rats BCG significantly hampered the outgrowth of residual leukemic cells. Relapse from leukemia could even be avoided completely when BCG was injected after cyclophosphamide (100 mg/kg) and total body irradiation (7.0 Gy) followed by isologous bone marrow transplantation. These results are discussed in relation with the tumor load at the time of maximal immunostimulation. Finally, the data are extrapolated to those of the many controversial clinical studies.     

Autologous bone marrow transplantation in acute myelogenous leukemia.

Autologous bone marrow transplantation (ABMT) is a therapeutic approach that permits the administration of high-dose chemoradiotherapy followed by the infusion of the patient's own marrow, previously collected during remission and cryopreserved. In recent years, ABMT has been increasingly used as a treatment for acute leukemias. The mechanisms underlying leukemic relapse represent the most exciting and controversial aspects of ABMT. At least three factors may be responsible for leukemic relapse in patients receiving ABMT: (a) minimal residual disease; (b) leukemic cells reinfused with the graft; and (c) the lack of a graft-versus-leukemia effect. Techniques for pharmacological marrow decontamination, clinical results obtained with ABMT, and new perspectives opened by growth factors and cytokines are reviewed.     

Clinical significance of minimal residual disease in leukemia

Considerable progress has been made in the treatment of acute and chronic leukemias. Remission rates are generally high and cure rates of up to 80% can be achieved in children with acute lymphoblastic leukemia (ALL). However, in many patients the disease will ultimately recur. In most if not all of these patients, relapse is thought to result from subclinical levels of residual leukemia, termed minimal residual disease (MRD). Therefore, the study of MRD holds a significant potential to understand the biology of relapse and remission and to design new therapies to improve the cure rate of patients. A major goal of these studies is to be able and identify patients at a defined risk of relapse which can lead to risk-adapted therapy approaches. Laboratory assays such as polymerase chain reaction (PCR) and multicolor flow cytometry are sensitive enough to detect one leukemic cell in up to 104-105 normal cells and have become ideal tools to monitor MRD. Especially PCR has been used extensively. Although a wealth of data has been generated, some questions remain as to the impact of monitoring MRD on clinical outcome and are the object of this review.     

Residual leukemia cannot be detected in very early remission peripheral blood stem cell collections in acute non-lymphoblastic leukemia

We have used a combined cell culture and cytogenetic approach to study the level of residual leukemia during the very early remission (VER) phase of acute non-lymphoblastic leukemia. Clonogenic leukemic cells were induced to proliferate by phytohemagglutinin-stimulated leucocyte conditioned medium and identified by a leukemia-associated karyotype t(8;21) and a morphological marker (Auer rod). When leukemic blasts were cultured, the leukemic karyotype and Auer rods were most readily detected after 3-9 days. When VER blood cells were cultured, no leukemia-associated karyotype or Auer rods could be detected. Based on the number of VER blood cell derived metaphases analysed, the incidence of leukemic blasts among dividing cells is less than 2%.     

The BN acute myelocytic leukemia (BNML) (a rat model for studying human acute myelocytic leukemia (AML))

Even if animal models have many properties in common with the human disease, as is the case for the BNML and human AML, they have their limitations with respect to the extrapolation to the clinical situation. This also holds for the BNML; thus, conclusions should only be drawn with great caution. Nevertheless, the studies in the BNML model have added considerably to the understanding of various processes that occur during the development of leukemia, e.g., the interaction of leukemic cells and normal hemopoietic stem cells in relation to the microenvironment. The methodology developed in the BNML model allows the quantification of the relative effectiveness of any given treatment with regard to the antileukemic activity compared with the toxicity for normal host tissues. Furthermore, the cell kinetic studies performed in the BNML as a consequence of timed sequential chemotherapy has been helpful in designing an approach to take advantage of this phenomenon in the treatment of acute leukemia. The comparison of the various treatment modalities, employed for the conditioning prior to bone marrow transplantation, made it possible to determine the relative effectiveness of the various approaches. The fractionation of total body irradiation for conditioning purposes was supposed to have a negligible effect with regard to a reduced antileukemic effect. Detailed studies that were conducted in the BNML model did not confirm this hypothesis indicating that (hyper-)fraction of TBI results in a reduced antileukemic effect. The in vitro purging studies in the BNML aimed at the elimination of residual leukemic cells in autologous bone marrow transplantation contributed to the introduction of this method in clinical practice. However, extended studies in the BNML model also indicated that the contribution of the residual leukemia cell in the patient contributed to a much greater extend to the recurrence of leukemia then did the residual cells in the autologous marrow graft. A major contribution of the BNML was achieved in the study of the area of so-called "minimal residual disease" (MRD). A number of so-far unknown aspects of relapsing leukemia could be identified and studied. A new concept of discriminating locally relapsing leukemia and a delayed occurrence of generalized spreading of leukemia formed the basis for the explanation of the observed heterogeneity in the distribution of leukemic cells during the remission and the subsequent relapse phase. In conclusion, it is obvious that proper comparison of the human disease as well as the counterpart in the animal model requires a detailed knowledge of both.(ABSTRACT TRUNCATED AT 400 WORDS)     

DBA／2 小鼠微小残留白血病模型的构建

 目的　探讨建立一种细胞系和种鼠传代方便、重复性好的微小残留白血病模型的方法。方法　选用国际标准近交系DBA／2小鼠84只，接种不同数量L1210白血病细胞，观察接种白血病细胞数量与小鼠存活时间之间的关系；每只小鼠接种L1210白血病细胞1×106个后，第3天行不同剂量环磷酰胺（CTX）化疗，观察化疗剂量与小鼠存活时间之间的关系。结果　小鼠存活时间随接种细胞数量增加而逐渐缩短；白血病小鼠存活时间随化疗剂量增加而逐渐延长；观察接种不同数量白血病细胞的小鼠和接受不同剂量CTX化疗的白血病小鼠的生存趋势，显示接种500个白血病细胞小鼠的存活时间相当于用CTX剂量125 mg／kg化疗白血病小鼠生存时间，两者均为28 d左右。结论　DBA／2小鼠接种L1210白血病细胞1×106个／只后第3天采用CTX 125 mg／kg化疗可以成功建立微小残留白血病模型，此时小鼠体内白血病细胞数约为500个。