The TEL/AML1 fusion associated with t(12;21)(p13;q22) is the most common gene rearrangement in childhood leukemia, occurring in approximately 25% of pediatric acute lymphoblastic leukemia (ALL), and is associated with a favorable prognosis. For example, a cohort of pediatric patients with ALL retrospectively analyzed for theTEL/AML1 fusion treated on Dana-Farber Cancer Institute (DFCI) ALL Consortium protocols between 1980 to 1991 demonstrated a 100% relapse-free survival in TEL/AML1-positive patients with a median of 8.3 years of follow-up. However, two recent studies analyzing pediatric patients with relapsed ALL have reported the same incidence of the TEL/AML1 rearrangement as in patients with newly diagnosed ALL, suggesting that TEL/AML1 positivity is not a favorable prognostic indicator. To clarify this apparent discrepancy, 48 pediatric patients treated on Dana-Farber Cancer Institute (DFCI) protocols with ALL at first or second relapse were tested forTEL/AML1 using reverse transcriptase-polymerase chain reaction (RT-PCR). The TEL/AML1 fusion was identified in only 1 of 32 analyzable relapsed ALL patients, in concordance with our previous reports of improved disease-free survival in TEL/AML1-positive patients. The low frequency of TEL/AML1-positive patients at relapse is significantly different than that reported in other studies. Although there are several potential explanations for the observed differences in TEL/AML1-positive patients at relapse, it is plausible that relapse-free survival in TEL/AML1-positive patients may be changed with different therapeutic approaches. Taken together, these results support the need for prospective analysis of prognosis in TEL/AML1-positive patients.

THE TEL/AML1 REARRANGEMENT in pediatric acute lymphoblastic leukemia (ALL) is the consequence of t(12;21)(p13;q22).1,2 The gene rearrangement is cryptic by standard cytogenetics but can be detected using reverse transcriptase-polymerase chain reaction (RT-PCR), Southern blot, or fluorescence in situ hybridization (FISH). TEL/AML1 occurs in 20% to 25% of children with B-progenitor ALL and is the most common gene rearrangement yet identified in any pediatric leukemia.1,3-13 The TEL/AML1 fusion frequently occurs in patients previously characterized as low or standard risk. A retrospective analysis of 81 patients treated on Dana-Farber Cancer Institute (DFCI)-ALL Consortium protocols demonstrated that 22 (27%) were TEL/AML1-positive.3 Of these, 11 patients were treated as high risk, although with current risk criteria, 7 patients would be identified as high risk.14 Moreover, 100% of the 22 TEL/AML1-positive patients remained in complete continuous remission (CCR) with no relapses observed at a median follow-up of 8.3 years.3 One TEL/AML1-positive patient died of a brain tumor. Sixteen of 54 TEL/AML1-negative patients relapsed.3 

Other investigators have also reported favorable outcomes forTEL/AML1-positive patients in both retrospective analyses and prospective analyses with relatively short follow-up (Table 1).4,6,7,12,13,15,16However, at least four analyses of patients with relapsed ALL have shown that the frequency of TEL/AML1 positivity at relapse is similar to that at diagnosis (Table2).7,17-19 One study retrospectively identified 9 of 35 (26%) patients who were TEL/AML1-positive at relapse.17 In another retrospective analysis, 32 of 146 (22%) patients enrolled on relapse protocols of the Berlin-Frankfurt-Munster (BFM) group were TEL/AML1-positive at first or second relapse.18 Although the incidence ofTEL/AML1-positive patients at relapse approximates that reported at diagnosis, both studies showed that the duration of initial remissions was longer in TEL/AML1-positive patients.17,18,TEL/AML1-positive relapsed patients also had a significantly higher probability of event-free survival after relapse therapy.18 In a smaller study of 16 relapsed cases of B-progenitor leukemia, 3 patients who experienced late relapses (>30 months) had evidence of TEL/AML1rearrangement.7 It is not clear if these patients were screened for the TEL/AML1 rearrangement at initial diagnosis. In a study that assessed the use of the TEL/AML1 fusion transcript as a marker of minimal residual disease, 2 of 7 patients relapsed with TEL/AML1 rearrangements in their bone marrow.19 

Table 1.

Summary of Reports of Incidence of TEL/AML1Fusion in Newly Diagnosed Pediatric Patients

Author Type of Analysis Rx Reg. All Pts*B Lineage TA+ (% B-cell) TA+ Relapse
McLean 3 R  DFCI  81  68  22 (32%) 0  
  80-01  
  81-01  
  85-01 
  87-01  
Shurtleff12 R/P  SJCRH  160 126  35 (28%) Not reported  
Romana10 R  EORTC  36  36  8 (22%)  
Kobayashi5 R  Saitama,  Japan  93  75 9 (12%)  2  
Raynaud9 R  France  66 50  17 (34%) 3  
Liang6 R  Taiwan 41  36  7 (19%)  0  
   POG 
Nakao7 R  CCLSG  
  Japan  108  70 11 (16%)  1  
Cayuela16 R  FRALLE 93 76  69  16 (23%)  Not reported 
Borkhardt4 R  BFM-90  
  AEIOP-91 342  337  99 (29%)  3  
 P  BFM-95 
  AEIOP-95  334  2801-153 63 (22%) Not reported  
Rubnitz11 R  SJCRH XI 188  188  44 (23%)1-155 3  
  SJCRH XII 
Lanza13 R/P  AEIOP  51  Not reported  11 (22%)  
Author Type of Analysis Rx Reg. All Pts*B Lineage TA+ (% B-cell) TA+ Relapse
McLean 3 R  DFCI  81  68  22 (32%) 0  
  80-01  
  81-01  
  85-01 
  87-01  
Shurtleff12 R/P  SJCRH  160 126  35 (28%) Not reported  
Romana10 R  EORTC  36  36  8 (22%)  
Kobayashi5 R  Saitama,  Japan  93  75 9 (12%)  2  
Raynaud9 R  France  66 50  17 (34%) 3  
Liang6 R  Taiwan 41  36  7 (19%)  0  
   POG 
Nakao7 R  CCLSG  
  Japan  108  70 11 (16%)  1  
Cayuela16 R  FRALLE 93 76  69  16 (23%)  Not reported 
Borkhardt4 R  BFM-90  
  AEIOP-91 342  337  99 (29%)  3  
 P  BFM-95 
  AEIOP-95  334  2801-153 63 (22%) Not reported  
Rubnitz11 R  SJCRH XI 188  188  44 (23%)1-155 3  
  SJCRH XII 
Lanza13 R/P  AEIOP  51  Not reported  11 (22%)  

Review of published reports assessing incidence and prognosis ofTEL/AML1 rearrangement at de novo diagnosis of ALL.

Abbreviations: R, retrospective; P, prospective; Rx reg., treatment regimen; DFCI, Dana-Farber Cancer Institute; SJCRH, St. Jude Childrens Research Hospital; EORTC, European Organization for Research & Treatment of Cancer—Childhood Leukemia Cooperative Group; Taiwan POG, Taiwan Pediatric Oncology Group; CCLSG, Children’s Cancer and Leukemia Study Group, Japan; BFM, Berlin-Frankfurt-Muenster; AEIOP, Associazonie Italiana Ematologia Oncologia Pediatrica; TA+,TEL/AML1-positive; TA−, TEL/AML1negative.

*

When available, “All pts” data are given as the number of pediatric ALL patients.

Three additional patients had TEL rearrangement but were negative for TEL/AML1 by RT-PCR.

One additional patient had TEL rearrangement but was negative for TEL/AML1 by FISH or RT/PCR.

F1-153

This number was derived by subtracting T-cell, mature B, and unknown immunophenotyped ALL from the total 334 patients analyzed.

F1-155

Four additional patients had TEL rearrangement but three did not have samples for RT-PCR and one was negative forTEL/AML1 by RT-PCR. The remaining 44 were RT-PCR positive for TEL/AML1. Additionally, 38 of these 48 patients were previously reported by Shurtleff et al.12 

Table 2.

Summary of Reports of Incidence of TEL/AML1Fusion in Relapsed Patients

Author Type of Analysis Rx Reg. All PtsRelapsed B-Cell Pts TA+ (%) TA Pts at Rel. 1TA Pts at Rel. 2
Nakao7 R  CCLSG  19 16  3 (19%)  3  0  
Satake19 Tokyo  CCSG  7  7  2 (28%)  2  
  Tokai  CCSG  
  CCLSG  
Harbott17 R  BFM-86  46  35  9 (26%)  5  
  BFM-90  
  Co-ALL05-92 
Seeger18 R  ALL-REZBFM* 146  133 32 (24%)  27  
Author Type of Analysis Rx Reg. All PtsRelapsed B-Cell Pts TA+ (%) TA Pts at Rel. 1TA Pts at Rel. 2
Nakao7 R  CCLSG  19 16  3 (19%)  3  0  
Satake19 Tokyo  CCSG  7  7  2 (28%)  2  
  Tokai  CCSG  
  CCLSG  
Harbott17 R  BFM-86  46  35  9 (26%)  5  
  BFM-90  
  Co-ALL05-92 
Seeger18 R  ALL-REZBFM* 146  133 32 (24%)  27  

Review of published reports assessing the incidence ofTEL/AML1 rearrangement in relapsed patients.

Abbreviations: R, retrospective; Rx reg., treatment regimen; pts, patients; TA+, TEL/AML1-positive; TA−,TEL/AML1-negative; Rel., relapse; CCLSG, Children’s Cancer and Leukemia Study Group, Japan; BFM, Berlin-Frankfurt-Muenster; ALL-REZ-BFM, ALL relapse protocol for the BFM.

*

Therapy received at relapse. Initial therapy consisted of unspecified BFM or Co-ALL protocols.

Taken together, these analyses show that the frequency of theTEL/AML1 rearrangement in relapsed patients is similar to that reported at diagnosis. This suggests that TEL/AML1 positivity may not be as favorable a prognostic indicator as previously reported.3,4,6,12,15 16 To clarify the apparent discrepancy between the favorable prognosis of TEL/AML1 in our previous study and reports of high TEL/AML1 frequency at relapse, we screened for the TEL/AML1 fusion using RT-PCR from available bone marrow from relapsed ALL patients initially treated on DFCI ALL Consortium protocols from 1981 through 1995.

Patients and specimens.

Between January 1, 1981 and December 31, 1995, 683 children (<18 years of age) with newly diagnosed ALL were treated on four consecutive DFCI ALL Consortium protocols (81-01, 85-01, 87-01, and 91-01) at three institutions: Boston Children’s Hospital and the Dana-Farber Cancer Institute, International Hospital of Puerto Rico, and, for 81-01 only, Eastern Maine Medical Center. The initial diagnosis was made at the treating institution. Informed consent for sample acquisition and treatment was obtained from parents or guardians at the time of diagnosis. The therapy delivered to patients on the four DFCI ALL Consortium protocols is summarized in Table3. Details of protocols 81-01 and 85-01 have been previously published.20 21 Treatment was based on risk group assignment at the time of diagnosis (Table4).

Table 3.

Treatment on DFCI ALL Consortium Protocols (1981-1995)

Induction therapy  (∼4 wk)  Vincristine q week Prednisone q day Doxorubicin × 1-2 doses Methotrexate × 1 dose (low or high dose) ± asparaginase IM × 1 dose IT ara-C × 2 doses  
CNS treatment  (∼2 wk)  SR: No cranial XRT3-150 or 1,800 cGy cranial XRT3-151  IT methotrexate/ara-C × 4 doses  
 HR/VHR: 1,800-2,800 cGy cranial XRT  
 IT methotrexate/ara-C × 4 doses 
Intensification therapy (∼9 mo)  SR: Vincristine q 3 weeks  6-MP po3-152 × 14 days  Prednisone3-153 po × 5 days  Methotrexate IV/IM q week  Asparaginase IM q week  
 IT methotrexate/ara-C q18 weeks  
 HR: As described above, except doxorubicin q 3 weeks instead of methotrexate  
 VHR: Same as HR, except preceded by one month of:  High dose methotrexate IV weeks 1, 2  IT methotrexate weeks 1, 2  High dose ara-C week 3  Asparaginase IM q week  Vincristine weeks 1-4  6-MP po × 14 days  
Continuation therapy (until 2 yr CCR)  Three week cycles of:  Vincristine q 3 weeks  6-MP po × 14 days  Prednisone3-153 po × 5 days  Methotrexate IV/IM q week 
Induction therapy  (∼4 wk)  Vincristine q week Prednisone q day Doxorubicin × 1-2 doses Methotrexate × 1 dose (low or high dose) ± asparaginase IM × 1 dose IT ara-C × 2 doses  
CNS treatment  (∼2 wk)  SR: No cranial XRT3-150 or 1,800 cGy cranial XRT3-151  IT methotrexate/ara-C × 4 doses  
 HR/VHR: 1,800-2,800 cGy cranial XRT  
 IT methotrexate/ara-C × 4 doses 
Intensification therapy (∼9 mo)  SR: Vincristine q 3 weeks  6-MP po3-152 × 14 days  Prednisone3-153 po × 5 days  Methotrexate IV/IM q week  Asparaginase IM q week  
 IT methotrexate/ara-C q18 weeks  
 HR: As described above, except doxorubicin q 3 weeks instead of methotrexate  
 VHR: Same as HR, except preceded by one month of:  High dose methotrexate IV weeks 1, 2  IT methotrexate weeks 1, 2  High dose ara-C week 3  Asparaginase IM q week  Vincristine weeks 1-4  6-MP po × 14 days  
Continuation therapy (until 2 yr CCR)  Three week cycles of:  Vincristine q 3 weeks  6-MP po × 14 days  Prednisone3-153 po × 5 days  Methotrexate IV/IM q week 

Summary of treatment on DFCI ALL Consortium protocols 81-01 to 91-01. High-risk criteria on protocols 81-01 to 91-01 included the presence of any one of the following: WBC >20,000/μL, age <1.99 years or >9.0 years, CNS involvement, anterior mediastinal mass, or T-cell immunophenotype. Very high-risk criteria used in 85-01 and 87-01 included the presence of any one of the following: WBC >100,000/μL, age <1 year, t(9;22). Very high-risk criteria used in 91-01 included only those patients less than 1 year of age.

Abbreviations: SR, standard risk; HR, high risk; VHR, very high risk; IM, intramuscularly; IT, intrathecal; ara-C, Cytosine arabinoside; XRT, radiation therapy; 6-MP, 6-mercaptopurine; IV, intravenous; po, per orum; CCR, complete continuous remission.

F3-150

All SR patients on 87-01. Only SR girls on 91-01.

F3-151

All SR patients on 81-01 and 85-01. Only SR boys on 91-01.

F3-152

On 91-01, patients randomized to oral 6-MP or IV 6-MP.

F3-153

On 91-01, dexamethasone instead of prednisone.

Table 4.

Clinical Characteristics of Relapsed Patients

TEL/AML1 Not TestedTotal
Negative Positive
Initial protocol 
 81-01  11  0  38  49  
 85-01  7  0  15 22  
 87-01  9  0  24  33  
 91-01  4  16  21  
Risk category4-150 
 Standard  4  0  30 34  
 High  25  1  51  77  
 Very High  0  12  14  
Age at Dx  
 <1 yr  2  0  3  
 1.01-9.9 yr  18  1  68  87  
 >10 yr  11 0  22  33  
Immunophenotype  
 B-cell  30  84  115  
 T-cell  1  0  6  7  
 Unknown  0  3  3  
t(9;22)  
 Yes  3  0  8  11 
 No  26  1  65  92  
 Unknown  2  0  20 22  
WBC  
 <50K/μL  25  1  67  93 
 50K/μL ≤ 100K/μL  0  0  7  7  
 ≥100K/μL 6  0  19  25  
CNS leukemia  
 Yes  3  0  7  
 No  27  1  89  117  
 Unknown  1  0  1  
Sex  
 Male  22  1  52  75  
 Female 9  0  41  50  
Duration of 1st CR4-151 
 <18 mo  0  29  33  
 18-30 mo  6  1  26  33 
 >30 mo  21  0  38  59  
 Median (month)  37.8 22.3  26.9  29 
TEL/AML1 Not TestedTotal
Negative Positive
Initial protocol 
 81-01  11  0  38  49  
 85-01  7  0  15 22  
 87-01  9  0  24  33  
 91-01  4  16  21  
Risk category4-150 
 Standard  4  0  30 34  
 High  25  1  51  77  
 Very High  0  12  14  
Age at Dx  
 <1 yr  2  0  3  
 1.01-9.9 yr  18  1  68  87  
 >10 yr  11 0  22  33  
Immunophenotype  
 B-cell  30  84  115  
 T-cell  1  0  6  7  
 Unknown  0  3  3  
t(9;22)  
 Yes  3  0  8  11 
 No  26  1  65  92  
 Unknown  2  0  20 22  
WBC  
 <50K/μL  25  1  67  93 
 50K/μL ≤ 100K/μL  0  0  7  7  
 ≥100K/μL 6  0  19  25  
CNS leukemia  
 Yes  3  0  7  
 No  27  1  89  117  
 Unknown  1  0  1  
Sex  
 Male  22  1  52  75  
 Female 9  0  41  50  
Duration of 1st CR4-151 
 <18 mo  0  29  33  
 18-30 mo  6  1  26  33 
 >30 mo  21  0  38  59  
 Median (month)  37.8 22.3  26.9  29 

Clinical characteristics of patients studied.

Abbreviations: Dx, Diagnosis; WBC, white blood cell count; CNS, central nervous system; CR, clinical remission.

F4-150

Among tested and not tested (P = .04).

F4-151

There was a longer duration of first remission in the tested group that was statistically significant (P = .01). Note that the median of 37.8 months reflects the patients who were tested, excluding the TEL/AML1-positive patient. The median duration of first remission of all patients tested, including theTEL/AML1-positive patient, is 35.6 months.

A total of 125 patients initially treated at these three institutions subsequently relapsed after achieving first clinical remission. Bone marrow samples obtained at diagnosis and relapse were sent to the DFCI immunophenotyping lab and tumor bank. Only those patients with cells obtained in excess of immunophenotyping requirements had samples viably frozen. Samples were selected without knowledge of age at diagnosis, sex, race, immunophenotype, cytogenetics, initial risk stratification, or duration of first clinical remission. When available, paired samples from initial diagnosis and relapse were analyzed.

Forty-seven patients had 64 available cryopreserved bone marrow samples obtained from the DFCI tumor bank. Samples from 8 of these patients failed to yield analyzable RNA. Thirty-nine patients with cryopreserved bone marrow samples yielded RNA of sufficient quality for analysis ofTEL/AML1 gene rearrangement. In summary, a total of 51 samples from these 39 patients had adequate RNA for analysis.

RNA extraction and RNA-based PCR.

Total RNA was extracted from cryopreserved bone marrow or peripheral blood mononuclear cells using guanidinium/acid phenol extraction (RNA STAT-60; Tel-Test, Friendwood, TX) according to the manufacturer’s instructions. Total RNA (4 μg) was reverse transcribed as previously described.22 An aliquot of cDNA was then used in a control PCR reaction to verify the integrity of the RNA sample using TELspecific primers 458 (5′AGGTCATACTGCATCAGAAC3′) and 750R (5′ATTATTCTCCATGGGAGACA3′) to amplify a 292-bpTEL fragment spanning exons 4 and 5. Forty cycles of PCR (94°C for 1 minute, 56°C for 1 minute, and 72°C for 1 minute) were performed as previously described on an MJ Research thermal cycler (Watertown, MA), and 10 μL of the PCR product was visualized on 2.5% agarose gels stained with ethidium bromide. Samples that were negative for the control TEL expression were excluded from further analysis.

Amplification of the TEL/AML1 fusion was performed in a nested PCR reaction. First-round PCR used TEL primer 937 (5′AACCTCTCTCATCGGGAAGA3′) and AML1 primer 1142R (5′CAGAGTGCCATCTGGAACAT3′). Forty cycles of PCR were performed at an initial denaturing step of 94°C for 5 minutes, followed by cycles of 94°C for 1 minute, 62°C for 1 minute, and 72°C for 1 minute. Four microliters of PCR product was reamplified with second-round PCR using TEL primer 969 and AML1 primer Z3R.TEL primer 969 (5′GAACCACATCATGGTCTCTG3′) and AML1 primer Z3R (5′AACGCCTCGCTCATCTTGCCTG3′) amplify a 174-bp fragment in 40 cycles of PCR (initial step of 94°C for 5 minutes, followed by cycles of 94°C for 1 minute, 60°C for 1 minute, and 72°C for 1 minute). Subsequent analysis of the PCR product (10 μL) was visualized on 1% agarose/3% NuSieve (Pharmacia, Piscataway, NJ) gels stained with ethidium bromide.

All assays were confirmed at least once. The positive control was RNA extracted from the Reh cell line that harbors the TEL/AML1 gene rearrangement.23 24 Negative controls contained PCR reaction mixture without added cDNA. Appropriate positive and negative controls were used in each reaction. Template cDNA was added in a separate lab after the PCR master mix was aliquoted into 96-well reaction plates.

Statistics.

The Fisher’s Exact25 test was used for comparison of categorical data, and the Wilcoxon Exact test was used when the categories were ordered.25 Mantel’s log rank test was used to compare duration of first remission between relapsed patients who were tested and relapsed patients who were not tested.26The survival distribution for time to relapse data was estimated according to Kaplan and Meier.27 

Fifty-one cryopreserved bone marrow samples from 39 patients treated on four consecutive DFCI protocols provided quality RNA for analysis. Paired bone marrow samples were available in 13 patients at initial diagnosis and relapse, in 19 patients at relapse only, and in 7 relapsed patients at initial diagnosis only. Four of the 13 patients for whom bone marrow samples were available at initial diagnosis and at relapse were previously analyzed at diagnosis and have been reported.3 The seven relapsed patients who had bone marrow samples only available at initial diagnosis are reported here but are not included in the group that was tested. For statistical analysis, these 7 patients are included in the 93 patients who were not tested. The presenting characteristics of the remaining 32 patients analyzed are presented in Table 4 and are compared with the presenting characteristics of the 93 relapsed patients who were not tested. No significant differences were found in age at diagnosis, immunophenotype, sex, presence of central nervous system (CNS) leukemia, or presence of t(9;22) between the two groups. Analyzed patients were more likely to have been treated as high risk or very high risk (P = .04). When using current DFCI risk classification criteria (high risk includes the presence of any one of the following: age <1.0 years or ≥10 years, white blood cell count [WBC] ≥50,000/μL, T-cell phenotype, presence of anterior mediastinal mass, any CNS leukemia), this difference is no longer significant (P = .22).14 There was a significantly longer duration of first clinical remission in the 32 patients who were tested compared with the 93 patients who were not tested (log rank,P = .01; Table 4). The median follow-up of the remaining 558 patients who were treated on these protocols and did not relapse was 7.8 years.

Only 1 relapsed patient of 32 (90% confidence interval, 0% to 14%) was found to be TEL/AML1-positive. Additionally, none of the 7 relapsed patients with samples at initial diagnosis only wasTEL/AML1-positive. The relapsed patient harboring theTEL/AML1 fusion was a male diagnosed at 43 months of age with a B-progenitor, CD10+ phenotype with a presenting WBC of 40,200/dL and normal cytogenetics. He was stratified and treated as high-risk on DFCI 91-01 because of a WBC greater than 20,000/μL at presentation (Table 3). The patient relapsed in bone marrow and cerebrospinal fluid (CSF) after 23 months of CCR, 2 months before completion of continuation therapy. Reinduction was unsuccessful, and he underwent allogeneic bone marrow transplantation with persistent leukemia. He died of progressive bone marrow and CNS disease with concomitant bacterial sepsis approximately 6 months after initial relapse. A bone marrow sample at initial diagnosis wasTEL/AML1-positive. Peripheral blood mononuclear cells were positive for the TEL/AML1 fusion on day 29 after bone marrow transplantation, 2 weeks before obtaining a bone marrow aspirate demonstrating refractory ALL with 58% lymphoblasts. Although no blood samples were available at initial relapse, the patient had refractory ALL throughout the last 6 months of his life and never achieved a clinical remission.

Comparison of these results with other reported analyses ofTEL/AML1 frequency in relapsed patients is shown in Table 5. Clinical characteristics of the patients reported in other series appear to be similar to those reported here. The median duration of first clinical remission for all relapsed patients and all tested patients appears in concordance with other reports. However, there is a significant difference between the incidence of TEL/AML1 in relapsed patients with B-progenitor ALL treated on DFCI ALL Consortium protocols and the incidence ofTEL/AML1 in relapsed patients with B-progenitor ALL reported by other investigators.

Table 5.

Comparison of TEL/AML1 Rearrangement in Reports of Relapsed Patients

Immunophenotype Institutions TA+ TA− PValue
B-cell only  DFCI  1  30  
 Nakao7 3  13  .11  
B-cell only  DFCI  1  30 
 Harbott17 9  26  .01  
B-cell  DFCI 1  27  
t(9;22)negative  Seeger18 32 101  .02 
Immunophenotype Institutions TA+ TA− PValue
B-cell only  DFCI  1  30  
 Nakao7 3  13  .11  
B-cell only  DFCI  1  30 
 Harbott17 9  26  .01  
B-cell  DFCI 1  27  
t(9;22)negative  Seeger18 32 101  .02 

Fisher’s exact test comparing results between DFCI series and other reported series.

Only 1 of 32 relapsed patients initially treated on DFCI ALL Consortium protocols was TEL/AML1-positive. When considering only patients with a B-progenitor phenotype that did not have the presence of t(9;22), only 1 of 28 (3.6%) patients was TEL/AML1-positive. This low frequency is consistent with our previous study, in which a retrospective analysis of newly diagnosed pediatric ALL patients showed 0 of 22 relapsed TEL/AML1-positive patients with 8.3 years of median follow-up.3 Our results are significantly different when compared with other reported analyses of the incidence ofTEL/AML1 in relapsed patients (Table 5).

There are several potential explanations for the differences between our results and the reports of other investigators. First, there might be a selection bias in our analysis, because samples were tested retrospectively based on availability. It is possible that the incidence of TEL/AML1 rearrangement is lower because a disproportionately higher number of high/very high-risk patients had samples available for analysis (Table 4). However, the clinical features of our study cohort appear similar to those reported by other investigators, including the median length of remission.17,18,TEL/AML1 positivity at relapse has been associated with a longer duration of remission.7,17 18The majority of our study cohort (60%) had a clinical remission that exceeded 36 months. Therefore, it is unlikely that selection bias alone explains the low incidence of TEL/AML1 positivity in our series. To fully address the potential problem of selection bias inherent in this and other retrospective studies, we are prospectively analyzing the prognostic significance of TEL/AML1 in all newly diagnosed patients with ALL treated on the current DFCI ALL Consortium protocol (95-01).

Second, it is notable that half of the TEL/AML1-positive patients identified in our previous report were treated as high risk based on a presenting WBC greater than 20,000/μL. The treatment that these patients received may have been more intense than patients treated on other protocols reporting a higher relapse rate who may use a higher WBC for risk classification. Only those patients meeting other standard risk criteria with a WBC greater than 50,000/μL will be treated as high risk on the current DFCI ALL Consortium protocol. Our prospective analysis should determine whether the change in risk stratification based on WBC will influence the outcome ofTEL/AML1-positive patients. However, it should be noted that the 1 TEL/AML1-positive patient in the currently reported analysis was treated as high risk and still failed to sustain a clinical remission.

Third, it is possible that the high incidence of TEL/AML1 at relapse reflects a therapy-related malignancy that isTEL/AML1-positive; that is, the patients were TEL/AML1negative at initial diagnosis but were TEL/AML1-positive at relapse. Many of the patients in the other reports were only analyzed at relapse and not at initial diagnosis.7,17,18 To date, there has been 1 case report of a 4-year-old patient with a B-progenitor, CD10+ ALL whose diagnostic cytogenetics demonstrated del(6q) and no abnormalities of 12p.28 Bone marrow obtained at relapse 7 years after CCR demonstrated absence of the original del(6q) clonal abnormality. Instead, a subtle deletion of 12p on the relapse karyotype led to FISH analysis, which detected the t(12;21) rearrangement.28 Subsequent RT-PCR identified theTEL/AML1 gene rearrangement.1 There was no bone marrow available to determine whether the patient wasTEL/AML1-positive at initial diagnosis.

Although the TEL/AML1 rearrangement has not been shown to occur in therapy related leukemias, it is usually a cryptic translocation and may have yet to be identified. Balanced translocations involvingAML1 with other fusion partners (ETO, EVI1) have been demonstrated in therapy-related acute myeloid leukemias (t-AML), particularly in association with exposure to topoisomerase II inhibitors, including epipodophyllotoxins and anthracyclines.29-33 In fact, the majority of relapsed patients reported by Seeger et al18 and Harbott et al17 were treated initially on BFM or Co-ALL protocols, both of which include therapy with these agents.34-36Additionally, the BFM and CoALL protocols also incorporate the use of alkylating agents that have an association with myelodysplasia and t-AML demonstrating unbalanced translocations.29 34-36Whereas the patients treated on DFCI ALL Consortium protocols received anthracyclines, none has received epipodophyllotoxins or alkylating agents as part of their initial therapy (Table 3).

Finally, it is possible that the low incidence ofTEL/AML1-positive relapses in this study reflects differences in the efficacy of the up-front therapy TEL/AML1-positive patients. Historically, the DFCI and BFM treatment programs have achieved similar outcome results in children with newly diagnosed ALL, but with different treatment strategies.34 The intensive BFM regimens, which include 2 months of induction therapy and a delayed reinduction phase, use a greater number of drugs.34,36 The DFCI regimens, distinguished by early consolidation with intensive asparaginase for all patients and doxorubicin for higher risk patients, have used fewer agents but at higher cumulative dosages.20,21 34 It is possible thatTEL/AML1-positive patients represent a biologically distinct subset of patients whose leukemia is more effectively treated by the agents used more intensively by the DFCI group, such as asparaginase. Ongoing prospective trials may help clarify whether a particular treatment strategy more effectively treats patients withTEL/AML1-positive ALL. Additionally, the development of quantitative minimal residual disease assays may prove crucial to following TEL/AML1-positive patients on different protocols.

At a minimum, these data strongly suggest that the presence ofTEL/AML1 at diagnosis is a favorable prognostic indicator but that treatment specific variables may influence outcome in this potentially curable cohort. Taken together with other published reports, our data would not support consideration of decrements in therapy for TEL/AML1-positive patients at this time. Rather, they emphasize the ongoing need to confirm the prognostic significance of TEL/AML1 prospectively and to develop sensitive quantitative minimal residual disease assays to follow TEL/AML1-positive patients on therapy.

The authors thank Virginia Dalton, Gaylord Garroway, Jennifer Peppe-Bonasera, and Stacey Waters for assistance in obtaining clinical data and members of the Connell-O’Reilly Cell manipulation and Gene transfer laboratories at the Dana-Farber Cancer Institute for their assistance in obtaining samples.

Supported in part by the Howard Hughes Medical Institute and Grant No. CA68484 from the National Institutes of Health. D.G.G. is the Stephen Birnbaum Scholar of the Leukemia Society of America and an investigator in the Howard Hughes Medical Institute.

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. section 1734 solely to indicate this fact.

1
Golub
TR
Barker
GF
Bohlander
SK
Hiebert
SW
Ward
DC
Bray-Ward
P
Morgan
E
Raimondi
SC
Rowley
JD
Gilliland
DG
Fusion of the TEL gene on 12p13 to the AML1 gene on 21q22 in acute lymphoblastic leukemia.
Proc Natl Acad Sci USA
92
1995
4917
2
Romana
SP
Mauchauffe
M
Le Coniat
M
Chumakov
I
Le Paslier
D
Berger
R
Bernard
OA
The t(12;21) of acute lymphoblastic leukemia results in a tel-AML1 gene fusion.
Blood
85
1995
3662
3
McLean
TW
Ringold
S
Neuberg
D
Stegmaier
K
Tantravahi
R
Ritz
J
Koeffler
HP
Takeuchi
S
Janssen
JW
Seriu
T
Bartram
CR
Sallan
SE
Gilliland
DG
Golub
TR
TEL/AML-1 dimerizes and is associated with a favorable outcome in childhood acute lymphoblastic leukemia.
Blood
88
1996
4252
4
Borkhardt
A
Cazzaniga
G
Viehmann
S
Valsecchi
MG
Ludwig
WD
Burci
L
Mangioni
S
Schrappe
M
Riehm
H
Lampert
F
Basso
G
Masera
G
Harbott
J
Biondi
A
Incidence and clinical relevance of TEL/AML1 fusion genes in children with acute lymphoblastic leukemia enrolled in the German and Italian multicenter therapy trials. Associazione Italiana Ematologia Oncologia Pediatrica and the Berlin-Frankfurt-Munster Study Group.
Blood
90
1997
571
5
Kobayashi
H
Satake
N
Maseki
N
Sakashita
A
Kaneko
Y
The der(21)t(12;21) chromosome is always formed in a 12;21 translocation associated with childhood acute lymphoblastic leukaemia.
Br J Haematol
94
1996
105
6
Liang
DC
Chou
TB
Chen
JS
Shurtleff
SA
Rubnitz
JE
Downing
JR
Pui
CH
Shih
LY
High incidence of TEL/AML1 fusion resulting from a cryptic t(12;21) in childhood B-lineage acute lymphoblastic leukemia in Taiwan.
Leukemia
10
1996
991
7
Nakao
M
Yokota
S
Horiike
S
Taniwaki
M
Kashima
K
Sonoda
Y
Koizumi
S
Takaue
Y
Matsushita
T
Fujimoto
T
Misawa
S
Detection and quantification of TEL/AML1 fusion transcripts by polymerase chain reaction in childhood acute lymphoblastic leukemia.
Leukemia
10
1996
1463
8
Raimondi
SC
Shurtleff
SA
Downing
JR
Rubnitz
J
Mathew
S
Hancock
M
Pui
CH
Rivera
GK
Grosveld
GC
Behm
FG
12p abnormalities and the TEL gene (ETV6) in childhood acute lymphoblastic leukemia.
Blood
90
1997
4559
9
Raynaud
S
Cave
H
Baens
M
Bastard
C
Cacheux
V
Grosgeorge
J
Guidal-Giroux
C
Guo
C
Vilmer
E
Marynen
P
Grandchamp
B
The 12;21 translocation involving TEL and deletion of the other TEL allele: Two frequently associated alterations found in childhood acute lymphoblastic leukemia.
Blood
87
1996
2891
10
Romana
SP
Poirel
H
Leconiat
M
Flexor
MA
Mauchauffe
M
Jonveaux
P
Macintyre
EA
Berger
R
Bernard
OA
High frequency of t(12;21) in childhood B-lineage acute lymphoblastic leukemia.
Blood
86
1995
4263
11
Rubnitz
JE
Downing
JR
Pui
CH
Shurtleff
SA
Raimondi
SC
Evans
WE
Head
DR
Crist
WM
Rivera
GK
Hancock
ML
Boyett
JM
Buijs
A
Grosveld
G
Behm
FG
TEL gene rearrangement in acute lymphoblastic leukemia: A new genetic marker with prognostic significance.
J Clin Oncol
15
1997
1150
12
Shurtleff
SA
Buijs
A
Behm
FG
Rubnitz
JE
Raimondi
SC
Hancock
ML
Chan
GC
Pui
CH
Grosveld
G
Downing
JR
TEL/AML1 fusion resulting from a cryptic t(12;21) is the most common genetic lesion in pediatric ALL and defines a subgroup of patients with an excellent prognosis.
Leukemia
9
1995
1985
13
Lanza
C
Volpe
G
Basso
G
Gottardi
E
Barisone
E
Spinelli
M
Ricotti
E
Cilli
V
Perfetto
F
Madon
E
Saglio
G
Outcome and lineage involvement in t(12;21) childhood acute lymphoblastic leukaemia [see comments].
Br J Haematol
97
1997
460
14
Smith
M
Arthur
D
Camitta
B
Carroll
AJ
Crist
W
Gaynon
P
Gelber
R
Heerema
N
Korn
EL
Link
M
Murphy
S
Pui
CH
Pullen
J
Reamon
G
Sallan
SE
Sather
H
Shuster
J
Simon
R
Trigg
M
Tubergen
D
Uckun
F
Ungerleider
R
Uniform approach to risk classification and treatment assignment for children with acute lymphoblastic leukemia [see comments].
J Clin Oncol
14
1996
18
15
Rubnitz
JE
Shuster
JJ
Land
VJ
Link
MP
Pullen
DJ
Camitta
BM
Pui
CH
Downing
JR
Behm
FG
Case-control study suggests a favorable impact of TEL rearrangement in patients with B-lineage acute lymphoblastic leukemia treated with antimetabolite-based therapy: A Pediatric Oncology Group study.
Blood
89
1997
1143
16
Cayuela
JM
Baruchel
A
Orange
C
Madani
A
Auclerc
MF
Daniel
MT
Schaison
G
Sigaux
F
TEL-AML1 fusion RNA as a new target to detect minimal residual disease in pediatric B-cell precursor acute lymphoblastic leukemia.
Blood
88
1996
302
17
Harbott
J
Viehmann
S
Borkhardt
A
Henze
G
Lampert
F
Incidence of TEL/AML1 fusion gene analyzed consecutively in children with acute lymphoblastic leukemia in relapse.
Blood
90
1997
4933
18
Seeger
K
Adams
HP
Buchwald
D
Beyermann
B
Kremens
B
Niemeyer
C
Ritter
J
Schwabe
D
Harms
D
Schrappe
M
Henze
G
TEL-AML1 fusion transcript in relapsed childhood acute lymphoblastic leukemia.
Blood
91
1998
1716
19
Satake
N
Kobayashi
H
Tsunematsu
Y
Kawasaki
H
Horikoshi
Y
Koizumi
S
Kaneko
Y
Minimal residual disease with TEL-AML1 fusion transcript in childhood acute lymphoblastic leukaemia with t(12;21).
Br J Haematol
97
1997
607
20
Clavell
LA
Gelber
RD
Cohen
HJ
Hitchcock-Bryan
S
Cassady
JR
Tarbell
NJ
Blattner
SR
Tantravahi
R
Leavitt
P
Sallan
SE
Four-agent induction and intensive asparaginase therapy for treatment of childhood acute lymphoblastic leukemia.
N Engl J Med
315
1986
657
21
Schorin
MA
Blattner
S
Gelber
RD
Tarbell
NJ
Donnelly
M
Dalton
V
Cohen
HJ
Sallan
SE
Treatment of childhood acute lymphoblastic leukemia: Results of Dana-Farber Cancer Institute/Children’s Hospital Acute Lymphoblastic Leukemia Consortium Protocol 85-01.
J Clin Oncol
12
1994
740
22
Sambrook
J
Fritsch
EF
Maniatis
T
Molecular Cloning: A Laboratory Manual
ed 2
1989
New York, Cold Spring Harbor Laboratory
Cold Spring Harbor
23
Venuat
AM
Testu
MJ
Rosenfeld
C
Cytogenetic abnormalities in a human null cell leukemia line (REH).
Cancer Genet Cytogenet
3
1981
327
24
Uphoff
CC
MacLeod
RA
Denkmann
SA
Golub
TR
Borkhardt
A
Janssen
JW
Drexler
HG
Occurrence of TEL-AML1 fusion resulting from (12;21) translocation in human early B-lineage leukemia cell lines.
Leukemia
11
1997
441
25
Cox
DR
Analysis of Binary Data.
1970
Methuen
London, UK
26
Mantel
N
Evaluation of survival data and two new rank order statistics arising in its consideration.
Cancer Chemother Rep
50
1966
163
27
Kaplan
E
Meier
P
Nonparametric estimation from incomplete observations.
J Am Stat Assoc
53
1958
457
28
Filatov
LV
Saito
M
Behm
FG
Rivera
GK
Raimondi
SC
A subtle deletion of 12p by routine cytogenetics is found to be a translocation to 21q by fluorescence in situ hybridization: t(12;21)(p13;q22).
Cancer Genet Cytogenet
89
1996
136
29
Pedersen-Bjergaard
J
Rowley
JD
The balanced and the unbalanced chromosome aberrations of acute myeloid leukemia may develop in different ways and may contribute differently to malignant transformation.
Blood
83
1994
2780
30
Pedersen-Bjergaard
J
Johansson
B
Philip
P
Translocation (3;21)(q26;q22) in therapy-related myelodysplasia following drugs targeting DNA-topoisomerase II combined with alkylating agents, and in myeloproliferative disorders undergoing spontaneous leukemic transformation.
Cancer Genet Cytogenet
76
1994
50
31
Pedersen-Bjergaard
J
Pedersen
M
Roulston
D
Philip
P
Different genetic pathways in leukemogenesis for patients presenting with therapy-related myelodysplasia and therapy-related acute myeloid leukemia.
Blood
86
1995
3542
32
Nucifora
G
Begy
CR
Kobayashi
H
Roulston
D
Claxton
D
Pedersen-Bjergaard
J
Parganas
E
Ihle
JN
Rowley
JD
Consistent intergenic splicing and production of multiple transcripts between AML1 at 21q22 and unrelated genes at 3q26 in (3;21)(q26;q22) translocations.
Proc Natl Acad Sci USA
91
1994
4004
33
Pui
CH
Relling
MV
Rivera
GK
Hancock
ML
Raimondi
SC
Heslop
HE
Santana
VM
Ribeiro
RC
Sandlund
JT
Mahmoud
HH
Evans
WE
Crist
WM
Krance
RA
Epipodophyllotoxin-related acute myeloid leukemia: A study of 35 cases.
Leukemia
9
1995
1990
34
Niemeyer
CM
Reiter
A
Riehm
H
Donnelly
M
Gelber
RD
Sallan
SE
Comparative results of two intensive treatment programs for childhood acute lymphoblastic leukemia: The Berlin-Frankfurt-Munster and Dana-Farber Cancer Institute protocols.
Ann Oncol
2
1991
745
35
Janka-Schaub
GE
Harms
D
Goebel
U
Graubner
U
Gutjahr
P
Haas
RJ
Juergens
H
Spaar
HJ
Winkler
K
Randomized comparison of rotational chemotherapy in high-risk acute lymphoblastic leukaemia of childhood—Follow up after 9 years. Coall Study Group.
Eur J Pediatr
155
1996
640
36
Reiter
A
Schrappe
M
Ludwig
W-D
Hiddemann
W
Sauter
S
Henze
G
Zimmermann
M
Lampert
F
Havers
W
Niethammer
D
Odenwald
E
Ritter
J
Mann
G
Welte
K
Gadner
H
Riehm
H
Chemotherapy in 998 unselected childhood acute lymphoblastic leukemia patients. Results and conclusions of the multicenter trial ALL-BFM 86.
Blood
84
1994
3122

Author notes

Address reprint requests to D. Gary Gilliland, PhD, MD, Harvard Institute of Human Genetics, Howard Hughes Medical Institute, 4 Blackfan Circle, Room 421, Boston, MA 02115.

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