The predictive value of initial cytogenetic studies in 148 adults with acute nonlymphocytic leukemia: a 12-year study (1970-1982)

When leukemic blood or marrow specimens from 148 adults with newly diagnosed acute nonlymphocytic leukemia (ANLL) were studied with chromosome banding techniques, 79 were found to have clonal abnormalities. Among 130 treated patients, the 53 with initially normal karyotypes had a significantly longer survival rate than the 16 in whom no normal metaphases were observed (p = 0.02). The 55 patients with both normal and abnormal metaphase cells had an intermediate survival. Once a complete remission had been attained, however, there was no significant difference in median survival between those patients with entirely normal karyotypes and those with abnormal karyotypes. Among the various FAB morphologic subsets of ANLL, the differences in complete remission rate and overall survival between the various cytogenetic subsets were greatest in acute myelogenous leukemia (AML, M1 + M2). The presence of an abnormal clone was a more important predictor of clinical outcome (p = 0.02) than the presence of normal stem cell clones. Aneuploidy alone (hyperdiploidy or hypodiploidy) was not of predictive value, indicating that the use of banding techniques to identify structural rearrangements in pseudodiploid cells was essential. Clonal chromosomal abnormalities were nonrandom and acquired, and specific abnormalities were closely associated with specific clinical-pathologic subsets of ANLL. All 13 patients with acute promyelocytic leukemia and adequate cytogenetic specimens had t(15;17); this translocation was not found in any other subset of ANLL. Six patients with AML (M2) had t(8;21) or a variant of this rearrangement. Seven patients had inv(16)(p13q22) associated with acute myelomonocytic leukemia (AMMoL, M4) and abnormal marrow eosinophils. Two patients had ins(3;3) and thrombocytosis. Four patients had a translocation involving 11q, but none of these had acute monocytic leukemia (AMoL, M5); no patient had del(11q).     

Chromosomal banding patterns in patients with acute nonlymphocytic leukemia

Approximately 50% of acute nonlymphocytic leukemia (ANLL) patients studied with banding techniques have detectable clonal karyotypic abnormalities. Although there is considerable variability, certain nonrandom abnormalities are observed, including trisomy 8, monosomy 7, and the 8;21 translocation (frequently accompanied by loss of an X or Y). The 15; 17 translocation is highly specific for acute promyelocytic leukemia. Clonal evolution of the karyotype can be observed in a significant number of ANLL patients for whom serial cytogenetic analyses are obtained. Gain of a No. 8 is the most frequently observed evolutionary change. Bone marrow cells from patients who develop ANLL following treatment of a previous malignancy often have hypodiploid modal numbers and frequently show loss of all or part of a chromosome No. 5 or No. 7.     

Chromosome studies in patients with acute nonlymphocytic or acute lymphocytic leukemia submitted to bone marrow transplantation--results of a European cooperative study

The chromosomal data of 58 acute nonlymphocytic leukemia (ANLL) patients and of 32 acute lymphocytic leukemia (ALL) patients submitted to bone marrow transplantation and collected from nine institutions are reported. Chromosomal studies were available at diagnosis in 19 cases with ANLL: seven had a partially or completely abnormal pattern. Forty-one patients had a chromosome study before bone marrow transplantation and all had a normal pattern. Thirteen patients with ALL were studied at diagnosis: five had a partially or completely abnormal karyotype. Of 20 cases analyzed before bone marrow transplantation, only one has maintained the abnormal pattern of diagnosis in part of the cells. Karyotypes were available in nine ANLL patients relapsed after bone marrow transplantations. Two showed the same clonal abnormalities seen at diagnosis; in three other cases the leukemic clone of relapse carried an additional chromosome abnormality with respect to the pattern at diagnosis and four more cases presented at relapse complex abnormalities; two of them had a cytogenetically normal pattern at diagnosis. In four of ten relapsed ALL cases chromosomes analyses were available. A relapse in donor cells and a hyperdiploid pattern were observed in two cases, respectively, while a normal, recipient pattern was documented in the other two cases. Serial chromosome studies performed in acute leukemia patients after bone marrow transplantation may allow the detection of different chromosomal patterns of relapse. In those cases who relapsed with a cell clone cytogenetically different from the pattern at diagnosis, a direct role played by the conditioning treatment in the pathogenesis of the relapsing disease may be hypothesized.     

11q23 abnormalities in children with acute nonlymphocytic leukemia (M4-M5). Association with previous chemotherapy

Cytogenetic studies of 12 patients aged less than 14 years with acute nonlymphoblastic leukemia (ANLL) (M4-M5) showed structural abnormalities on chromosome 11 at band q23-q24 in five cases (41.8%). Four of these 12 patients had ANLL (M4-M5) after treatment with cytostatics for non-Hodgkin lymphoma in one case and for an acute lymphoblastic leukemia (ALL) in the other three. Three of these four cases had 11q23 abnormalities [one [one 46,XY,t(11;17)(q23;25); another 47,XY,+8,-15,del(11)(q23),+der(15)t(15;?)(p11;?); the third 47,XX,+8,t(3;17) (p11;q25),t(4;11)(q21;q23)] and one had a normal karyotype on being diagnosed ANLL (M4-M5). The notable increase of ANLL (M4-M5) in our patients who had received cytostatics as treatment for a previous neoplasia makes evaluation of our results timely in comparison with those of other groups who use these therapeutic protocols.     

XIth International Symposium for Comparative Research on Leukemia and Related Diseases

Cytogenetic and immunologic studies were performed on the cells of an 18-year-old female with ataxia telangiectasia (AT) associated with acute lymphocytic leukemia (ALL). At the onset of the leukemia 15.4% of peripheral blood cells stimulated with phytohemagglutinin (PHA) contained a tandem translocation of the long arm of chromosome #14, i.e., t(14;14). To ascertain if these karyotypically abnormal cells and the leukemic cells had a common lineage, chromosome analyses were performed on bone marrow cells. Examination of the marrow cells on the seven occasions when leukemic cells were present in the marrow, including times when they were predominant, showed only a normal karyotype without the presence of t(14;14). However, an abnormal clone, which had the karyotype 45,XX,?9,t(9;6)(q12;p13), was identified in the marrow cells on the last examination during the terminal phase of the leukemia.Immunologically, the ALL was classified as an atypical type which had characteristics in common with certain T-cell subsets. We suggest that the malignant cells did not originate from the preexisting cells with a tandem duplication of the 14q.     

Chromosome patterns in 26 South African children with acute nonlymphocytic leukemia (ANLL)

Of 46 black leukemic children 52% had acute nonlymphocytic leukemia (ANLL), whereas only 11% of 62 white leukemic children had the disease. An abnormal karyotype was found in 73% of the 26 children with ANLL, and the majority of abnormal karyotypes were pseudodiploid. "Balanced" translocations were noted in 10 children, of whom four had t(8;21) associated with M2 ANLL, two had t(15;17) and M3 ANLL, two had a t(9;22), one child with M5 ANLL had t(10p;11q), and an infant with congenital M5 ANLL had t(8;16). Monosomy #7 was detected in two preleukemic children who subsequently developed M4 ANLL. Hyperdiploidy was present in only three cases. These patterns were compared with those of other published series, confirming the increased frequency of chromosome abnormalities in children with ANLL. The differing ratio of ANLL:ALL, some of the distinctive clinical features, and the high frequency of detectable chromosome abnormalities in black children may be reflections of a particular oncogenic agent(s) within their environmental background that could be responsible for the initiation of the leukemic process.     

A possible specific chromosome marker for monocytic leukemia: three more patients with t(9;11)(p22;q24) and another with t(11;17)(q24;q21), each with acute monoblastic leukemia

An apparently balanced 9;11 reciprocal translocation with break points most likely at 9p22 and 11q24 was found in 3 patients with acute monocytic leukemia [M5 in the French-American-British (FAB) classification schema]. This translocation was not observed in 6 other patients with M5 acute nonlymphocytic leukemia (ANLL) or in chromosome studies on 143 patients with other types of ANLL. This study supports the previously published suggestion that such 9;11 translocations may be associated with some patients with M5 ANLL. In this report, we have also included a patient with M5 ANLL who had an 11;17 translocation with break points apparently at 11q24 and 17q21. Perhaps this is a variant translocation of chromosome No. 11, which may also be associated with monocytic leukemia.     

The nature and mechanisms of chromosome banding

Cytogenetic, morphologic, and clinical data of 33 acute nonlymphocytic leukemia (ANLL) patients with t(8q?;21q+) and 19 patients with acute promyelocytic leukemia (APL) were collected from seven laboratories in Japan. The latter class included 18 patients with t(15q+;17q?) and one with a normal karyotype. The t(8q?;21q+) and t(15q+;17q?) translocations were each shown to be associated with a specific type of ANLL, namely, AML-M2 and APL-M3, respectively. No patient with APL had the M3 variant. The t(8q?;21q+) translocation seems to be more common as an abnormalitu in ANLL in Japan as compared to findings in other countries. The high incidence of t(15q+;17q?) among Japanese patients with APL indicated in this study, however, still awaits confirmation.     

Significance of abnormalities involving chromosomal segment 11q22-25 in acute leukemia

Six hundred and thirty unselected cases of acute leukemia, with complete data regarding age, karyotype (with breakpoints), and the diagnosis according to the FAB classification, were available in the literature and from our unpublished cases for comparing the incidence of chromosomal abnormalities involving the long arm of chromosome #11 among age groups in acute nonlymphocytic leukemia (ANLL) and acute lymphocytic leukemia (ALL). A statistically highly significant difference (p less than 0.001) was observed between the incidence of ANLL cases with chromosome aberrations involving 11q22-25 in childhood (less than or equal to 15 years) versus that in adults (greater than 15 yr). This statistical difference was not only related to infant cases (less than or equal to 12 months), but also to cases of children over 1 year of age. The incidence of the 11q22-25 abnormality in childhood cases (greater than 1 yr to less than or equal to 15 yr) was statistically significant (0.025 less than p less than 0.05) when compared to the incidence in adult cases. The incidence of the 11q22-25 abnormality in infant cases was much higher when compared to that of older cases with either ANLL or ALL (p less than 0.001 in each leukemia). This trend was not observed in cases with the 11q11-21 abnormality and this may imply that the origin and meaning of the 11q11-21 abnormality may differ from that of the 11q22-25 abnormality. Twenty-three infants with acute leukemia (AL) with the 11q22-25 abnormality were available from previous reports and our unpublished case. The median ages of ANLL, ALL, and all AL cases were 16 weeks, 9 weeks, and 15 weeks, respectively. The tendency of the 11q22-25 abnormality to be common in infants with ANLL or ALL under 6 months of age may suggest that it has a close correlation with the origin(s) or mechanism(s) related to the occurrence of infant AL.     

Hematologic manifestations associated with deletions of the long arm of chromosome 20

We investigated 20 patients with hematologic disorders who had a clone of cells with a deletion of most of a chromosome #20 long arm (20q?) in the bone marrow. Three patients had polycythemia vera (PV), 6 had acute nonlymphocytic leukemia (ANLL), 8 had preleukemia (PL), and 3 had other myeloproliferative disorders. In our laboratory, a 20q? chromosome is found in 6% of patients with PV, 3% of patients with ANLL, and 1% of patients with PL. Among the 6 patients with ANLL and a 20q? abnormality, 3 had erythroleukemia. There were no apparent clinical differences among our patients with 20q? chromosomes compared with other patients with similar disorders who did not have a 20q? chromosome. The breakpoint of the 20q? anomaly, in each instance, was in band 20q11, but it occurred near the centromere at 20q1101 in 16 patients and at the distal part of this band at 20q1109 in 4 patients. Three of the 4 patients with a breakpoint at 20q1109 had PL.     

Involvement of bands 9q21-q22 in five cases of acute nonlymphocytic leukemia

Five patients with acute nonlymphocytic leukemia (ANLL) with chromosomal aberrations involving bands 9q21-q22 are described. The abnormalities were an interstitial deletion in two cases of ANLL FAB type M4 and M4 with eosinophilia, a terminal deletion in two cases of M4 and M5 type ANLL, and a translocation in an M2 ANLL. A review of reported cases of ANLL with abnormalities of chromosome 9 revealed a clustering of breaks at the region 9q21-q22, suggesting a possible role for these bands in leukemogenesis.     

Chromosome study of 85 patients with myelodysplastic syndrome

We studied bone marrow chromosomes in 85 consecutive patients with myelodysplastic syndrome (MDS). Fifty-seven (67%) had a clone with an abnormal karyotype at diagnosis. Eight had secondary MDS, all with abnormal karyotypes. The frequency of abnormal karyotypes in the primary MDS was 64.9%. During subsequent follow-up, five patients acquired chromosome abnormalities; thus, at the end of the study, 72.0% of patients had an abnormal karyotype. The most frequent chromosome abnormalities were 5q-, +8, -7, -5, and -22. Forty patients (i.e., 70% of those with an abnormal karyotype and 47% of the whole group) had one of the karyotype abnormalities associated with secondary MDS or acute nonlymphocytic leukemia; in other words, 5q- or -5, or -7. Of all patients, 21.1% progressed into ANLL. Unfavorable prognostic factors associated with the risk of evolution into ANLL and with shorter overall survival were the presence of greater than 5% of bone marrow blasts, major chromosome abnormalities, and monosomy 7.     

Secondary chromosome aberrations in the acute leukemias

Information was retrieved from a computer-based data bank about additional chromosome aberrations in patients with acute lymphatic or nonlymphatic leukemia (ALL or ANLL) and one of the following primary rearrangements: In ALL t(9;22), t(11;14), t(1;19), t(4;11), t(8;14), and del(6q); in ANLL t(9;22), t(6;9), t(8;21), t(15;17), t(9;11), inv(16), and del(20q). The distribution of secondary changes was nonrandom. Chromosomes #1, #7, #8, and #9 were frequently involved in both disease groups, albeit with some pointed differences regarding the types of rearrangements making up the majority of aberrations. Chromosome #6 was clearly more affected in ALL, whereas, loss of a sex chromosome was largely restricted to ANLL patients. Differences between specific subtypes were detectable in both ALL and ANLL. Sex chromosome loss occurred almost exclusively in patients with t(8;21), who also tended to have del(9q) and/or trisomy 8. On the other hand, patients with t(15;17) often had del(7q) or monosomy 7, trisomy 8, and del (9q) as part of their karyotypes. None of the patients with inv(16) had del(9q). Instead, structural aberrations of chromosomes #7, #16, and #19 were fairly numerous in this subgroup, as was trisomy 8. Structural changes of #1, particularly translocations and duplications, were especially frequent in ALL patients with primary rearrangements t(8;14) or del(6q). In both ALL and ANLL, patients with t(9;22) had similar additional changes, often +8, -7, and/or +Ph. The findings indicate that the initial cytogenetic change is an important factor in determining the nature of subsequent chromosomal abnormalities developing in the malignant clone.     

Unusual translocations and other changes in acute leukemia

We report three cases of ANLL and one case of ALL in which we found chromosome abnormalities not previously described. The first patient had a (9;11;16)(p22;q23;p13) translocation in the relapse after bone marrow transplantation. In the second case, a secondary leukemia following a Wilms' tumor, there was a single chromosome anomaly, an inversion of chromosome 13. The third case also presented an isochromosome 13q. In the fourth patient we observed a translocation between two achrocentric chromosomes, as in the third patient, but not of the Robertsonian type: t(21;21)(q22.1;q22.5).     

Cytogenetics of three cases of ANLL M2 and M4. Involvement of chromosomal region 8q22 in all three but 21q22 in only one

Cytogenetic investigation of the bone marrow of two patients with acute nonlymphocytic leukemia (ANLL), French-American-British Cooperative group (FAB) classification M2, revealed a translocation (8;22)(q22.1;q13.3), without involving chromosome 21, and a variant translocation (8;21)(q22;q22). These findings, together with a del(8)(q22) found in a patient with refractory anemia, erythroblastic (RAEB)-t with progression to acute myelogenous leukemia (AML)-M4, are discussed in relation to the possible role of abnormalities of chromosomes 8 and 21 in the oncogenesis of ANLL M2 and M4.     

Geographic heterogeneity of neoplasia-associated chromosome aberrations

Using a database comprising 13,266 cytogenetically abnormal neoplasms, the geographic heterogeneity of neoplasia-associated chromosomal abnormalities was investigated by comparing the frequencies of characteristic aberrations in consecutive series of patients with the same diagnosis. Significant frequency differences between geographic areas were found for the aberrations +8, i(17q), +19, and an additional Ph1 chromosome in chronic myeloid leukemia (CML); -5, 5q-, and +8 in acute nonlymphocytic leukemia (ANLL); t(8;21) in ANLL-M2; t(15;17) in ANLL-M3; 5q- and -7 in myelodysplastic syndromes (MDS); t(9;22) and +21 in acute lymphocytic leukemia (ALL); t(14;18) in follicular lymphoma; -8 and -22/22q- in meningioma; and structural abnormalities of 12q in pleomorphic adenoma of the salivary glands (PAS). No geographic incidence variation was detected for -7 and +21 in ANLL; +8 in MDS; 6q- and +8 in ALL; +12 in chronic lymphocytic leukemia; 6q- in non-Hodgkin's lymphoma (NHL); t(8;14) in Burkitt's lymphoma; t(11;22) in Ewing's sarcoma; i(12p) in germ cell tumors; 1p- in neuroblastoma; structural abnormalities of 3q, 8q, and 9p in PAS; or 3p- in renal cell carcinoma. Intraregional frequency similarities between cytogenetically identical abnormalities in related tumor types were also analyzed. No significant correlations were found regarding the incidence of 5q- in ANLL and MDS, 6q- in ALL and NHL, -7 in ANLL and MDS, +8 in ANLL and CML, +8 in ANLL and MDS, +8 in ALL and ANLL, or +21 in ALL and ANLL. The findings indicate that some geographic heterogeneity of tumor-associated aberrations exists both in hematologic neoplasms and in solid tumors.(ABSTRACT TRUNCATED AT 250 WORDS)     

A near‐haploid clone harboring a BCR/ABL1 gene fusion in an adult patient with newly diagnosed B‐lymphoblastic leukemia

The detection of recurrent genetic abnormalities in B‐lymphoblastic leukemia (B‐ALL) is critical for risk stratification and therapy‐related decisions. Near‐haploidy (24‐30 chromosomes), a subgroup of hypodiploidy (<46 chromosomes), and BCR/ABL1 gene fusions are both recurrent genetic abnormalities in B‐ALL and are considered adverse prognostic findings, although outcomes in BCR/ABL1‐positive patients have improved with tyrosine kinase inhibitor therapy. While near‐haploid clones are primarily observed in children and rarely harbor structural abnormalities, BCR/ABL1‐positive B‐ALL is primarily observed in adults. Importantly, recurrent genetic abnormalities are considered mutually exclusive and rarely exist within the same neoplastic clone. We report only the second case to our knowledge of a near‐haploid clone that harbors a BCR/ABL1 fusion in an adult with newly diagnosed B‐ALL. Conventional chromosome studies revealed a near‐haploid clone (27 chromosomes) along with a der(22)t(9;22)(q34.1;q11.2) in 17 of 20 metaphases analyzed. Our B‐ALL fluorescence in situ hybridization (FISH) panel confirmed the BCR/ABL1 fusion and monosomies consistent with chromosome studies in approximately 95% of interphase nuclei. Moreover, no evidence of a “doubled” near‐haploid clone was observed by chromosome or FISH studies. This highly unusual case illustrates that while rare, recurrent genetic abnormalities in B‐ALL can exist within the same neoplastic clone.     

11q23异常恶性血液病的临床和细胞遗传学研究

目的 评估１１ｑ２３异常与恶性血液病的临床,血液学和预后的相互联系。方法 采用骨髓直接法和（或）培养法制备色体标本,用Ｒ显带技术,对６０００例恶性血液病进行核型分析。结果 ６０００例恶性血液病中发现２８例有１１ｑ２３异常,发生率为０．４７％。异常类型有７种：ｔ（４;１１）（ｑ２１;ｑ２３）１０例;ｔ（１１;１９）（ｑ２３;ｐ１３）５例;ｔ（９;１１）（ｐ１２;ｑ２３）２例;ｔ（１０;１１）（ｐ１５     

Translocation X;10 in a case of congenital acute monocytic leukemia

Unusual cytogenetic findings were noted in the leukemic cells from a patient with congenital acute monocytic leukemia (AMol or M5, according to the FAB classification), whereas, the chromosomes of cultured skin fibroblasts were normal. G-banded karyotypes of leukemic cells showed an X-autosome translocation, 46,X,t(X;10)(Xpter----q13::10q11.2----qter)(10pter---- q11.2::Xq28----q13:: Xq28----qter). Review of reported cases of acute nonlymphocytic leukemia (ANLL) with rearrangements involving chromosomes #10 or X showed a high frequency of abnormalities of the short arm of #10 in myelomonocytic (M4) and monocytic (M5) leukemias, particularly in patients less than 2-yr-of-age. Although previously reported cases of ANLL in infants are predominantly of these types, the translocation observed in this case is unique. Fragile sites known to exist on chromosomes #10 and X are not associated with neoplasia and, except for Xq27-28, were not at the breakpoints of the case presented. The precise location of a human cellular oncogene recently identified on the X chromosome remains unknown.     

Infantile acute leukemia with 11q23 chromosome abnormality and lineage infidelity

An infant case of acute leukemia (AL) showed lineage infidelity and a chromosome rearrangement involving 11q23. This case was morphologically diagnosed as ALL-L2 according to the FAB classification. However, the blast cells were highly positive for monoclonal antimyeloid antigens (Mol and TG-8) and lymphoid markers (B1, J5 and TdT). These immunologic findings indicated that the blast cells had characteristics of lymphoid B-cell and myeloid lines. In the literature, so-called "11q23 chromosome abnormalities," commonly observed in acute nonlymphoblastic leukemia (ANLL) and in a subtype of acute lymphoblastic leukemia (ALL) with t(4;11) were observed in both lymphoid and myeloid acute leukemias, with some of them recently reported to have lineage infidelity. These unique characteristics may indicate the possibility that the latter is a variation of the former, and support the hypothesis that the chromosomal rearrangement at 11q23 occurs at a multipotent stem-cell level.