CD 56-positive acute myeloid leukemia (AML-M 1) with t(16;21) (p11;q22) presenting an extramedullary tumor in the right breast at relapse

A 46-year-old woman was diagnosed as having acute myeloid leukemia (M 1) with translocation t(16;21) (p11;q22). The leukemic cells were positive for CD 13, CD 33, CD 34, CD 41, CD 56 and HLA-DR. After induction chemotherapy, the patient achieved complete remission (CR). However, 8 months later she relapsed with various additional chromosomal abnormalities. Although the patient achieved a 2nd CR after re-induction chemotherapy, the patient had extramedullary tumors in the right breast twice and relapse occurred frequently. The tumor cells were characterized by the same immunophenotypes and t(16;21) with additional 1 q trisomy. Although there was no evidence of hematological relapse, another type of 1 q trisomy was observed. Furthermore, an increase of abnormalities with 1 q trisomy was noted concomitant with re-increase in the number of blasts. The patient underwent allogeneic bone marrow transplantation (BMT), but she died from BMT complications. The case could have been a karyotype of t(16;21) with additional chromosomal abnormalities through consecutive approaches. Because of the high occurrence rate of relapse, we consider various additional chromosomal abnormalities and the expression of CD 56 as prognostic factors of this condition.     

Recurrent extramedullary relapse of acute myelogenous leukemia after allogeneic hematopoietic stem cell transplantation in a patient with the chromosomal abnormality t(8;21) and CD56-positivity

Isolated extramedullary (EM) relapse of acute myelogenous leukemia (AML) after allogeneic hematopoietic stem cell transplantation (allo-HSCT) is rare. Predisposing factors include CD56 expression and the chromosomal abnormality t(8;21). We describe an AML patient showing the chromosomal abnormality t(8;21) and CD56 expression who experienced a unique EM relapse after allo-HSCT. Approximately 10 months after allo-HSCT, he experienced relapse involving the femur and lumbar vertebrae and, subsequently, an EM relapse of the stomach. Although we administered only local radiotherapy and not systemic chemotherapy, he showed no bone marrow relapse on long-term follow-up after achieving complete hematological remission. These findings suggest that the graft-versus-leukemia effect may preferentially maintain marrow remission rather than prevent EM relapse. In addition, our findings show that extended survival is possible after EM relapse following allo-HSCT in patients with marrow hematopoiesis of donor origin, and that augmentation of the graft-versus-leukemia effect may be useful.     

Acute promyelocytic leukemia with t(11;17)(q23;q21)

We report the first Japanese case of acute promyelocytic leukemia with t(11;17)(q23;q21) and CD56. A 41-year-old man with schizophrenia was hospitalized because of the appearance of blasts with Auer bodies in his peripheral blood. A bone marrow smear showed an abundance of abnormal cells with scanty azurophile granules in the cytoplasm and somewhat lobulated nuclei. Because the abnormal cells demonstrated strongly positive peroxidase reactivity with a few faggot bodies, the patient was given a diagnosis of acute promyelocytic leukemia (M3v according to the FAB classification). However, chromosome analysis revealed t(11;17)(23; q21). All-trans retinoic acid (ATRA) was not effective. Mitoxantrone was more effective than daunorubicin, and resulted in a complete remission with a normal karyotype. About 9 months later, the patient suffered a relapse. Surface marker analysis demonstrated blasts that were positive for CD56, CD13, and CD33. MEC (mitoxantrone, etoposide, cytarabine) therapy was ineffective. Although ATRA was administered at a dose of 80 mg/day for more than 2 months, the number of myelocytes and promyelocytes increased Finally CAG (cytarabine, aclarubicin, G-CSF) therapy was initiated, but the patient died due to intracranial invasion and hemorrhage accompanied by disseminated intravascular coagulation.     

Transformation of bilineal hybrid acute leukemia to acute lymphoid leukemia: a case report with serial analyses of cytogenetics and gene rearrangement

A 17-year-old male with bilineal hybrid acute leukemia is described. Two-color flow cytometric analysis of blast surface phenotype revealed that there were two groups of blasts which showed either CD 10+ CD 19+ CD 13- CD 33- or CD 10- CD 19- CD 13+ CD 33+, but not both. He developed a complete remission by treatment with vincristine, prednisolone, adriamycin, and L-asparaginase. After 8 months, however, leukemia relapsed and lymphoid blasts were dominant. Cytogenetic analysis at presentation showed 46,XY,t(3;9)(p21;p22), and at relapse it showed 46,XY,t(1;3;9)(1pter----1q32::3p25----3pter;3 qter----3p21::9p22----9pter; 9qter----9p22::3p21----3p25::1q32----1q ter),t(2;19)(p21;q13). Analysis of the heavy chain joining region at diagnosis showed three hybridizing bands, all rearranged, but at relapse only one rearranged band. Analysis of the constant region for the beta T-cell receptor gene (TCR beta) both at diagnosis and at relapse showed one rearranged and one germline band, suggesting that rearrangement of one allele of TCR beta of not only lymphoid but also myeloid blasts occurred. It is considered that the target cell of lymphoid leukemia cells and that of myeloid leukemia cells at diagnosis were the same, which differentiated to two lineages, and the clone which evolved from lymphoid lineage proliferated at relapse.     

Cerebellar myeloblastoma formation in CD7-positive, neural cell adhesion molecule (CD56)-positive acute myelogenous leukemia (M1)

 We present a first report of a CD7⁺ acute myelogenous leukemia patient who developed intracranial myeloblastomas. The patient was neurologically normal on physical examination at presentation. The peripheral leukocyte count was extremely high (203.6×10⁹/l). The blasts expressed CD7 and CD56 (neural cell adhesion molecule) in addition to CD13, CD33, CD34, and HLA-DR. The karyotype of bone marrow cells was normal. The patient was diagnosed as having acute myelogenous leukemia (AML, M1). Following a short period of complete remission, bone marrow relapse and meningeal leukemia occurred, and the patient died of respiratory failure. Autopsy revealed that blasts had invaded the subarachnoid space and cerebellum, and two myeloblastomas were found in the cerebellar hemisphere. Both CD7⁺ and CD56⁺ AML have been reported to have a high incidence of central nervous system involvement. CD7⁺ CD56⁺ AML calls for prophylaxis of central nervous system leukemia. Received: 2 May 1997 / Accepted: 17 July 1997     

Childhood t(8;21) acute myelocytic leukemia: a comparison of clinical features and risk factors with adult cases

Despite the abundance of reports describing adult cases of t(8;21) acute myelocytic leukemia (AML), childhood cases have received little attention. We retrospectively investigated 14 childhood cases of t(8;21) AML, and compared their clinical characteristics with those of adult cases, focusing on the risk factors for poor prognosis. Seventy-one percent of the patients had fever. Their mean leukocyte count was 12,700/microliter, and they showed decreased NAP activity. The cell surface showed positivity for CD13, 33, 19, 34, and HLA-DR. The complete remission rate was 100%, and relapse was observed in three of the patients. Bone marrow eosinophilia was present in a smaller proportion of the childhood cases than in the adult cases. Although an increased leukocyte count, tumor formation, and other risk factors have been reported in adults, there was no correlation between these factors and prognosis in our childhood cases. As children who showed AML relapse had TdT-positive blasts, detectable blast TdT activity may be a risk factor for relapse in childhood cases of t(8;21) AML. However, to confirm this, a study with a larger subject base should be conducted.     

Lineage switch on recurrence from minimally differentiated acute leukemia (M0) to acute megakaryocytic leukemia (M7)

Phenotypic switch in acute leukemia is a rare phenomenon. We report on a female infant with minimally differentiated acute leukemia (M 0) which underwent a lineage switch on relapse. In March 1997, a 1-year-8-month old girl was admitted to our hospital with a high-grade fever and generalized purpura. Bone marrow showed 84% blasts. The blasts were negative for peroxidase, periodic acid-Schiff and alpha-naphthyl butyrate esterase. Immunophenotypic analyses of the blast cells were positive for CD 13, CD 33 antigens, as well as CD 34. Lymphoid markers all were negative. Though some blasts morphologically demonstrated cytoplasmic blebs, CD 41 was negative and ultrastructural platelet peroxidase was absent. Based on these hematological features, the patient was diagnosed as having AML-M 0. She was treated according to the Children's Cancer and Leukemia Study Group schedule and a complete remission was achieved 1.5 months after starting induction therapy. However, she relapsed in spite of continued chemotherapy in July 1997, when the cytomorphological pattern changed and the patient was diagnosed both morphologically and immunologically as having M 7. Electron microscopy revealed platelet peroxidase (+) and CD 41 (+). Cytogenetic studies on relapse demonstrated inv(3) (q 21 p 25). We attempted aggressive reinduction therapy, but without effect. The patient simultaneously developed severe pneumonia and died in February, 1998. A lineage switch on relapse and resistance to chemotherapy may be associated with the occurrence of genetic aberration.     

Outcome of acute myelogenous leukemia in 41 patients treated with idarubicin: the prognosis of t(8;21) cases

Idarubicin (IDR) has been used as the main drug in induction chemotherapy for acute myelogenous leukemia (AML) in the USA and Europe. Between May 1995 and October 1998, we treated 41 cases of fresh AML using IDR induction chemotherapy and analyzed the clinical course, remission rate, relapse rate and prognosis. The results obtained in these cases were similar to those in 26 cases treated with daunorubicin (DNR) in our hospital according to JALSG-AML92. The outcome in cases with abnormal chromosomes and cases showing relapse was very poor. In particular, all 5 t(8;21) cases in our series relapsed, suggesting that t(8;21) cannot be considered a favorable prognostic factor in cases treated with IDR-containing regimens. However, 3 of the 5 t(8;21) cases were positive for CD56, which itself is an unfavorable prognostic factor. Thus it is possible that CD56 was related to the poor outcome. Intensive post-remission induction chemotherapies will be required in order to obtain prolonged disease-free survival.     

Testicular infiltration in acute myeloid leukemia with complex karyotype including t(8;21)

Testicular infiltration is a well-known complication in acute lymphoblastic leukemia. In acute myeloid leukemia (AML), it has rarely been described and preferably occurred in cases with myelomonocytic or monoblastic differentiation. We report on a patient with AML with complex karyotype including translocation t(8;21) who presented with testicular infiltration at the time of his third bone marrow relapse. Cytological analysis of the specimen showed infiltration with blasts displaying the typical morphology of AML with translocation t(8;21) and comparable to those detected in the bone marrow. Fine needle aspiration cytology might suffice in these cases and should be performed if testicular involvement is suspected.     

Predictable prognostic factor of CD56 expression in patients with acute myeloid leukemia with t(8:21) after high dose cytarabine or allogeneic hematopoietic stem cell transplantation

CD56 expression in acute myeloid leukemia (AML) has been associated with extramedullary leukemia and multidrug resistance, but its clinical and prognostic significance has not been clearly identified. This study examined CD56 expression in 37 adult de novo AML patients with t(8:21). CD56 was expressed in 25 cases (67.6%). Complete remission (CR) rates were similar in both groups (91.7% vs. 88.7%; P = 0.73), but the relapse rates differed considerably (60% vs. 25%; P = 0.02). The median duration of disease-free survival (DFS) was significantly shorter in the CD56+ (median, 12.2 +/- 6.4 months) than in the CD56- group (median, not reached) (P = 0.02). In addition, the median duration of survival differed significantly in the CD56+ group (median, 14.9 +/- 4.4 months) compared with the CD56- group (median, not reached) (P = 0.01). Of the fifteen transplanted patients who achieved CR, allogeneic HST was performed from their siblings. The median duration of DFS in the CD56+ patients was significantly shorter than the CD56- patients (median, 24.4 +/- 4.5 months vs. median, not reached; P = 0.02). We concluded that CD56 expression correlates to a reduced DFS and survival for AML patients with t(8:21), including those patients who underwent transplantation.     

Conversion of acute leukemia from a T-lymphoid to a myeloid phenotype

A 7-year-old girl with an acute leukemia was reported whose blasts showed conversion from a T-lymphoid to a myeloid phenotype. At the onset of the disease, the blasts were negative for peroxidase and displayed FAB L1 morphology. Surface marker analysis revealed only CD7 antigen. Although complete remission was achieved, an extramedullary relapse was identified as having a several subcutaneous tumors 15 months later. Tumor cells showed the same marker expression as that of the blasts at the onset. After short term culture without an addition of any differentiation stimulators, the blast cells expressed CD2, CD3, CD4, CD8, and CD25 antigens. The karyotype was 46, XX, t(12; 21) (p11; q22). The intensive chemotherapy and radiation therapy were carried out, however, a hematological relapse occurred 12 months later. At this time, the blasts were strongly positive for peroxidase and expressed HLA-DR and CD33 antigens with disappearance of the CD7 antigen. Chromosome analysis revealed the additional abnormalities (del (7) (p15), -17, +der (17) t (17;?) (p13;?].     

Acute myelocytic leukemia with ins(21;8)(q22;q13q22) presenting with AML1/MTG8 chimeric mRNA

We report a case of acute myelocytic leukemia (AML) showing a chromosomal abnormality, ins(21;8), with AML1/MTG8 chimeric mRNA. The patient, a 73-year-old woman, was admitted to our hospital because of AML relapse. Bone marrow aspiration showed 44% blasts and ins(21;8)(q12;q13q22) by cytogenetic study. Moreover, the size of chimeric AML1/MTG8 mRNA detected by RT-PCR in this case was shorter than that of previously reported. The patient was diagnosed as having relapse of AML (M2), but achieved complete remission with DCP therapy. Four months later, extramedullary relapse occurred, and this was followed five months later by bone marrow relapse. However, the patient again achieved complete remission. Most cases of AML1/MTG8 fusion gene are caused by t(8;21), and only very rarely by ins(21;8). In this case, the AML1/MTG8 fusion gene is thought to have been involved in the onset of leukemia.     

Acute basophilic leukemia: case report

The term "basophilic leukemia" has been in use for 75 years. However, consistent diagnostic criteria are lacking. This is due to the rarity of the disease and to the routine unavailability of special tests that are often required to confirm a diagnosis. We report an unusual case of acute basophilic leukemia in a child who was referred to our Center, arriving with partially treated acute lymphoblastic leukemia. Basophilic differentiation on light microscopy was evident from the coarse basophilic granules in blasts, a progressive maturation of blasts toward basophils, and toluidine positivity on cytochemistry. Blasts showed a myeloid immunophenotype (CD13+, CD33+, CD117+) with a characteristic dual positivity for CD34 and CD25, highly suggestive of basophilic nature of the blasts. Conventional cytogenetic studies revealed translocation t(8;21)(q22;q22). A diagnosis of acute basophilic leukemia with t(8;21) was made. Review of pre-therapy slides showed features consistent with AML-M2 with basophilia. There were no basophilic blasts. With these features, a diagnosis of acute basophilic leukemia secondary to AML-M2 was made. In our patient, basophilic leukemia appears to have evolved from selective clonal proliferation of "basophil-committed blasts" during the course of the disease in a case of AML-M2 with basophilia.     

Prognostic significance of CD56 antigen expression in acute myeloid leukemia

BACKGROUND AND OBJECTIVES. CD56 antigen expression has been reported in several hematologic malignancies. In acute myeloid leukemia (AML)M2 with t(8;21) and acute promyelocytic leukemia (APL) it has been found to be consistently associated with an unfavorable prognosis, whereas in other AML subtypes its role remains uncertain. We investigated CD56 expression in a cohort of AML patients in order to assess its frequency and prognostic relevance. DESIGN AND METHODS. Immunophenotypic analysis including that of CD56 antigen was available for 171 consecutive AML patients (139 with AML and 32 with APL), enrolled between December 1995 and December 1999 at a single institution. A sample of fresh bone marrow cells taken at diagnosis was recorded as positive when at least 20% of the cells double-stained with specific monoclonal antibodies against CD56 and CD33 antigens. RESULTS. CD56 positivity was demonstrated in 37 cases (21.6%). Its frequency was lower in M4 (6%) and higher in M5 (37%). The median percentage for CD56+ blasts was 56% (range 21-99%). CD56 positivity did not correlate with age, sex, blast count, favorable or unfavorable cytogenetics at diagnosis, nor did it influence the outcome in terms of complete remission (CR) duration (606 vs. 417 days, p=n.s.) or overall survival (OS) (210 vs. 277 days, p= n.s.). In the APL subgroup a significant difference in relapse rate was found at 3 years (71.4% in the CD56 positive group vs. 12% in the CD56 negative group, p=0.005). INTERPRETATION AND CONCLUSIONS. Our data confirm that CD56 positivity in APL patients at diagnosis is associated with a worse prognosis, suggesting that close molecular monitoring is necessary in CD56 positive APL patients. In contrast, the prognostic role of CD56 remains uncertain in the other AML subtypes.     

Infant leukemia with t(1;22) presenting proliferation of erythroid and megakaryocytic cell lineages

We report a case of infant leukemia with the proliferation of both erythroblast and megakaryoblast lineages. The blasts became double-positive for both erythroblastic and megakaryoblastic surface markers at the time of bone marrow relapse. A 9-month-old girl was admitted to our hospital presenting chiefly poor with weight gain and anemia. She also had splenomegaly, pleural effusion, leukocytosis, and thrombocytopenia. A bone marrow specimen showed 53.2% erythroblasts (PAS positive, alpha-NA positive, CD41 negative, MPO negative) and 20.4% megakaryoblasts with marked cytoplasmic blebs. We examined specimens by two-color flow cytometric analysis. At the onset, CD41+ glycophorin A- fraction and CD41- glycophorin A+ fraction were two major components. At the bone marrow relapse, the majority of blasts had altered to double-positive. Chromosomal analysis showed t (1; 22) (p13; q13), which has been reported to be specific for acute megakaryoblastic leukemia (M7) in infants. We reasoned that a leukemia had occurred in this patient at a progenitor cell level common to both erythroid and megakaryocytic lineages.     

A case of T-lineage lymphoblastic lymphoma/leukemia with t(4;11)(q21;p15) that switched to myelomonocytic leukemia at relapse

A 51-year-old Japanese woman, initially diagnosed with T-lineage (CD2+, CD7+, CD3-, CD4-, CD8-) lymphoblastic lymphoma with t(4;11)(q21;p15), relapsed with acute myelomonocytic leukemia with the identical chromosomal abnormality. Southern-blot analysis revealed clonal rearrangements of an immunoglobulin heavy chain gene (JH) and T-cell receptor genes (J delta 1, J gamma 1, C beta 1) at first presentation, but germ line configurations of these genes at relapse. Leukemias with t(4;11)(q21;p15) may involve a hematopoietic progenitor capable of multilineage differentiation.     

Aberrant co-expression of CD19 and CD56 as surrogate markers of acute myeloid leukemias with t(8;21) in Taiwan

Aberrant antigen expression in acute myeloid leukemia (AML) has been extensively studied in the West with limited reports from Taiwan. We carried out this retrospective study to characterize the frequency and significance of aberrant antigen expression of AML in Taiwan. Among 111 cases, 58 (52%) showed aberrant antigen expression, most frequently CD7 (27%) and CD56 (23%). Aberrant CD7 expression was observed in all non-AML-M3 subtypes, most frequently in AML-M7 (4/6, 67%); while CD19 expression was only observed in AML-M2 (5/36, 14%). CD56 expression was most common in AML-M5 (4/8, 50%). The relative frequency of CD19 and CD56 expression in AML with t(8;21) was higher than those with other chromosomal abnormalities or normal karyotype (P = 0.011 and 0.005, respectively). In non-M3 AML, aberrant antigen expression was identified in 56/96 (58%) cases, in contrast to 2/15 (13%) AML-M3 cases (P = 0.001). CD7, CD19 and CD56 expression was not correlated with remission rate. We concluded that aberrant immunophenotype was more frequent in non-M3 leukemias in Taiwan. The relative frequency of CD19 and/or CD56 expression in AML with t(8;21) was significantly higher than those without this translocation and co-expression of these two antigens may serve as the surrogate markers for AML with t(8;21).     

Immunophenotypic analysis enables the correct prediction of t(8;21) in acute myeloid leukaemia

Immunophenotypic findings from 14 patients affected by acute myeloid leukaemia (AML) with t(8;21) were compared to those obtained from 79 AML patients with normal or other aberrant karyotypes. Classic lineage markers, adhesion molecules, surface enzymes, stem-cell- related antigens and HLA-DR were investigated. Following evaluation by the Mann-Whitney test, we found that t(8;21) AMLs showed a significantly higher expression of CD19, CD34, CD56, CD45RA and CD54. Conversely, blasts from patients in the control group significantly expressed higher levels of CD45R0, CD33, CD36, CD11b and CD14. In order to split the data at the best cut-off point to achieve the most homogenous subset with regard to cytogenetic pattern, i.e. t(8;21) or not, the CART (Classification and Regression Trees) method was applied. In the univariate analysis by CART, statistically significant differences were found when CD19 was dichotomized at 10%, CD34 at 37%, CD45RA at 84%, CD54 at 21%, CD56 at 12% , CD36 at 14%, CD45R0 at 25%, CD11b at 18% and CD14 at 12%. Once cut-off points were established by CART, we applied the logistic regression model to establish which combination of two or more antigens was most predictive for t(8;21). The combination CD19-CD34 at the cut-off points indicated above correctly classified 92/93 cases (98.9%). The addition of any other antigen combination to the CD19/CD34 model failed to improve the level of prediction. We conclude that AML with t(8;21) displays an exclusive immunophenotype that is highly predictive of the cytogenetic pattern.