De novo acute myeloid leukemia with near-pentaploidy: diploid karyotype and lymphoblastic phenotype at relapse

Hyperploidy is a rare finding in leukemias, with isolated cases of tetraploidy reported in acute myeloblastic and acute lymphblastic leukemias. We report the first case of acute myeloid leukemia with near-pentaploidy (5 n+/-) which was present in 100% of metaphases at diagnosis. By light microscopy, the leukemic blasts were exceptionally large and coarsely granulated. Following one cycle of induction chemotherapy, complete morphologic and cytogenetic remission was documented. Four weeks later relapse occured, at which time the karyotype was diploid and the morphological and immunophenotypic characteristics were those of a lymphoid leukemia. However, the presence of three aberrant chromosomes (5q+, 6q+ and 20q+) confirmed that this was clonal evolution of the original myeloid leukemia. To the best of our knowledge, this case represents the first report of near-pentaloidy in de novo, pretreatment human leukemia.     

Cytogenetic studies of acute promyelocytic leukemia

Translocation t(15;17) is reported in bone marrow cells from six of seven patients with active acute promyelocytic leukemia (APL). One patient who showed t(15;17) at final relapse did not show it in directly prepared or cultured cells taken from a previous relapse. Bone marrow samples from two patients showed only cells with a normal karyotype in the direct preparation, whereas more than 60% of cells cultured for 24 hr showed t(15;17). R-Banding, G-banding, and an attempt at high-resolution banding indicated the break points t(15;17)(q24;21) for one of our patients.     

t(8;21)急性髓系白血病患者MICM分型及预后的回顾性分析

目的 分析t(8;21)急性髓系白血病(AML)患者的细胞形态学、免疫表型、遗传学、分子生物学(MICM)分型及临床治疗疗效.方法 运用瑞特染色法、FAB细胞形态分类标准、流式细胞术(FCM)直接免疫荧光标记技术、遗传学染色体吉姆萨显带技术及RT-PCR技术对70例确认有t(8;21)与AML1-ETO融合基因双阳性的AML患者及70例正常染色体核型的AML患者进行分析和比较.结果 70例t(8;21)AML患者中M11例,M2 64例,M4 3例,无法分型的急性白血病(AL)2例;免疫表型分析发现CD13、CD33、CD34、CD117高表达,40%表达CD19,11%表达CD15,10%表达CD11b,7%表达CD7;遗传学显示50%的t(8;21)AML患者有附加染色体异常,主要为性染色体丢失、9q-及超二倍体;RT-PCR检测AML1-ETO融合基因100%阳性.CD+19t(8;21)AML患者完全缓解(CR)率72%,CD+19伴CD+7t(8;21)AML患者CR率为0,正常核型CR率31%.结论 t(8;21)AML患者主要在M2中集中出现,附加染色体异常较多见.CD19表达较高,而CD7表达极低,CD34、CD117高表达,这些抗原的表达可能与核型密切相关.CD+19是预后良好的指标,但同时出现CD+7,则预后不良.     

Role of second-look surgery in treatment of ovarian neoplasms

The study of chromosomal abnormalities in AML has become very important in the diagnosis and in the characterization of subtypes since they are related to defined clinical, morphological and immunological features as well as treatment outcome and survival. PURPOSE: To evaluate the relative importance of cytogenetic abnormalities may have in AML patients. METHODS: 13 AML patients were studied during diagnosis. Cytogenetic study was performed on bone marrow aspirate material. RESULTS: M1 and M2 FAB subtypes were the most frequent (61.6%). The patients' median age was 38 years. Cytogenetic analysis showed abnormal karyotype in 61.5% of the cases and 15.3% of whom had abnormalities considered as good prognosis [t(15;17) and t(8;21)]. At the evaluation day there were 3 patients alive, two in continuous complete remission and 1 in a second remission. The median total survival time was 7 months. Patients were divided into two groups: a "good prognosis" one, that joined 5 patients with normal karyotype and 2 with the translocations t(15;17) and t(8;21) and another, the "bad prognosis" one, with 8 patients with unfavorable chromosomal abnormalities. The good prognosis group had a median survival time of 9 months versus 6.2 months in the other, but this was not statistically significant (p = 0.18), probably owing to the small number of cases in the groups. But when one observes the cases separately see that patients with translocations (8;21) and (15;17), known as good prognosis, had longer survivals. CONCLUSION: The different survival time between the two groups showed the importance of cytogenetic study to distinguish the patient who will have favorable evolution.     

Classification of ninety-eight adult cases of acute leukemia according to morphology, immunology and cytogenetics]

Ninety-eight cases of adult acute leukemia (AL) were diagnosed and classified based on morphologic, immunologic and cytogenetic (MIC) features. The results showed that: the conformity rate of cytomorphologic/cytochemical classification with MIC classification was 90.8%. For ALL, the conformity rate of immunologic classification with MIC classification was 95.6%, but it was only 70.8% for AML. Of the 48 AML, 10 expressed lymphoid lineage, associated antigens and 8 of 43 ALL expressed myeloid lineage-associated antigens. Seven cases were diagnosed as hybrid acute leukemia according to Catovsky criterion. The chromosome aberrations were found in 70 cases, of them 46 cases showed characteristic abnormalities including t(9;22), t(4;11), t(11;14), t(8;12), t(8;14), 6q-, 9p-, and t(15;17), t(8;21), inv(16), etc.     

CADASIL: 2 case reports of hereditary multi-infarct dementia

OBJECTIVE: To further investigate the role that cytogenetic may play in the diagnosis and prognosis of leukemia, a study was conducted in 319 acute leukemias. METHODS: 100 patients with acute lymphoblastic leukemia (ALL) and 219 patients with acute non-lymphoblastic leukemia (ANLL) were from Rui Jin Hospital, Xin Hua Hospital, Ren Ji Hospital and Shanghai Children's Hospital. Their cytogenetic data were analyzed together with those of morphology, immunology and clinical prognosis. RESULTS: In ALL group, 48 cases were karyotypically normal whereas 52 cases revealed chromosomal changes, among which 32 had quantitative abnormalities and 20 had qualitative abnormalities. The translocation t(9; 22) was identified in 11 out of 20 cases of structural aberrations (55%). Specific structural aberrations t(9; 22) and t(8; 14) were detected to be related to B-lineage associated differentiation antigens and t(8; 14) also with ALL-L3 according to FAB classification. With regard to clinical prognosis, the survival rate of structural aberration subset decreased significantly compared with the normal karyotype subset (P < 0.05). However, no statistically significant difference was found between hyperdiploidy subset (not including near-triploidy) and normal karyotype subset (P > 0.75). In ANLL group, 80% of de novo patients and relapsed patients had chromosomal abnormalities. Importantly, structural aberrations accounted for 73% of these abnormalities and frequently corresponded to specific types of FAB classification. Relevant prognostic studies demonstrated that t(15; 17) subset had the best overall survival probability, followed by t(8; 21) and normal karyotype subset, while the numerical aberration subset showed a relatively poor prognosis. CONCLUSION: Our data confirmed that cytogenetic study is important for the molecular study of the leukemogenesis. On the other hand, it also provides an independent parameter for prognosis in acute leukemia.     

Chromosomes and causation of human cancer and leukemia. XLVIII. T-cell acute leukemia in ataxia telangiectasia

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;q13), 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.     

Treatment results of intermittent and cyclic regimen with ATRA and chemotherapy in childhood acute promyelocytic leukemia. Children's Cancer and Leukemia Study Group

An intermittent and cyclic regimen with All-Trans Retinoic Acid (ATRA) and intensive chemotherapy was conducted due to pharmacokinetic studies on ATRA for acute promyelocytic leukemia (APL) in children. We have treated 17 children with APL using ATRA for remission induction followed by an intermittent schedule of ATRA plus intensive chemotherapy (APL-ATRA protocol). There were 10 males and 7 females. The median age was 9.0 years old. The median baseline white blood cell count was 12.1 x 10(3)/microliter, hemoglobin 7.8 g/dl, platelet 4.5 x 10(4) microliters at diagnosis. Sixteen patients showed t(15; 17) translocation. RT-PCR analysis was available in 15 patients and showed PML/RAR alpha rearrangement in all patients. Overall, 13 or 17 newly diagnosed patients (88%) achieved complete remission and EFS was 67%. Compared to the control (same chemotherapy without ATRA regimen), remission induction and EFS were significantly increased. The toxicity of ATRA consisted of retinoic acid syndrome in 1 and pseudotumor cerebli in another. Other toxicities included headache, chelitis, gastrointestinal trouble and bone pain. These results suggest that intermittent and cyclic regimen with ATRA and intensive chemotherapy (APL-ATRA protocol) is highly effective for APL patients.     

Colony growth in cultures from bone marrow and peripheral blood after curative treatment for leukemia and severe aplastic anemia

The recovery of colony-forming cell numbers after curative treatment for leukemia and severe aplastic anemia (SAA) was studied. We examined 191 patients (85 acute myeloid leukemia [AML], 48 acute lymphocytic leukemia [ALL], 32 chronic myeloid leukemia [CML], 17 SAA, and nine myelodysplastic syndrome [MDS]) who were in hematologic remission 6 months to 13 years after either curative chemotherapy (n = 69) or allogeneic bone marrow transplantation (BMT) (n = 122) by culturing their precursor cells from bone marrow (BM) (n = 548) and peripheral blood (PB) (n = 529) in methylcellulose. Thirty-six BM donors and 25 PB donors served as controls. BM colony-forming cell numbers were abnormally low in all patients (p < 0.002) irrespective of underlying disorder and type of treatment (chemotherapy or irradiation). These numbers did not normalize with time--colony-forming cells were still strongly reduced up to 10 years after therapy, whether or not the patient had received an allogeneic bone marrow graft (p < 0.002). We also compared patients who remained in stable hematologic remission with those who later relapsed (6 months to 2 years after treatment). BM colony-forming cell numbers were significantly lower in patients who subsequently relapsed (p = 0.004). In contrast to BM cultures, we found normal colony-forming capacity by PB precursors in all patients. We conclude that (1) after chemotherapy or BMT, colony-forming cell numbers of BM in culture are permanently reduced; (2) this defect is probably due to a dysfunction of the BM environment rather than to a numerical reduction of the precursor cell pool; and (3) very low colony-forming capacity may be related to relapse.     

Recent advances in the treatment of acute leukemia

This review briefly summarizes literature considered noteworthy in the field of adult acute leukemia published during 1996. Does intensity remains a controversial issue in both acute myelogenous and lymphoblastic leukemia. The most convincing data showing efficacy of high dose fractionated chemotherapy was presented in patients with Burkitt's lymphoma/leukemia; the remainder of clinical studies failed to show a definitive advantage to high-dose therapy. Numerous studies addressed the role of the multidrug resistant phenotype and, at least in adult disease, demonstrated that the presence of this particular phenotype was a poor prognostic indicator. In the pediatric population, the significance of multidrug resistance expression appeared less clear. Discrepancies between protein expression and function were also evaluated in clinical samples and outcomes reported in large clinical series. Among the most interesting scientific investigations were those focused on the molecular mechanisms involved in the specific translocations t(15;17) and t(8;21) in acute myelogenous leukemia and t(12;21) in acute lymphoblastic leukemia. The genes PML and AML1, and ETO were examined in normal hematopoietic progenitors and their fusions proteins, PML/RAR alpha and AML1/ETO, measured in patients in clinical remission, and important data were presented concerning these proteins and measurement of minimal residual disease. Provocative data were also presented suggesting that retinoic acid may induce synthesis of a protein that selectively degrades PML/RAR alpha, and that interferons may regulate PML/RAR alpha expression.     

Hematological malignancies with t(9;11)(p21-22;q23)--a laboratory and clinical study of 125 cases. European 11q23 Workshop participants

This paper reports clinical and cytogenetic data from 125 cases with t(9;11)(p21-22;q32) which were accepted for a European Union Concerted Action Workshop on 11q23. This chromosome abnormality is known to occur predominantly in acute myeloid leukemia (AML) FAB type M5a and less often in AML M4; in this series it was also found to occur, uncommonly, in other AML FAB types, in childhood acute lymphoblastic leukemia (ALL) (nine cases), in relatively young patients with myelodysplastic syndrome (MDS) (five cases), acute biphenotypic leukemia (two cases), and acute undifferentiated leukemia (one case). All age groups were represented but 50% of the patients were aged less than 15 years. The t(9;11) was the sole abnormality in 57 cases with AML; trisomy 8 was the most common additional abnormality (23 cases, including seven with further abnormalities), and 28 cases had other additional abnormalities. Among the t(9;11)+ve patients with AML, the white cell count (WBC) and age group were significant predictors of event-free survival; central nervous system (CNS) involvement or karyotype class (sole, with trisomy 8, or with other), also contributed to prognosis although our data could not show these to be independent factors. The best outcome was for patients aged 1-9 years, with low WBC, and with absence of CNS disease or presence of trisomy 8. For patients aged less than 15 years, the event-free survival for ALL patients was not significantly worse than that of AML patients.     

Follow-up of residual disease using metaphase-FISH in patients with acute lymphoblastic leukemia in remission

Metaphase-FISH (fluorescence in situ hybridization) was used to detect cells with a chromosomal trisomy and/or translocation in 25 patients with acute lymphoblastic leukemia (ALL) in remission. Twelve patients were treated with chemotherapy alone and 13 patients received bone marrow transplantation after initial chemotherapy. Patients were followed up for 8-56 months (median 18 months). In this study, a total of 82 bone marrow samples were analyzed. Metaphase-FISH identified chromosome morphology, even banding, in cells from which FISH signals were studied. Thus, it is as reliable as standard karyotype analysis and does not cause false positive results. Furthermore, more than 1000 cells can be analyzed in 3-6 h which equals the time it takes to analyze 20 metaphases by standard karyotype. The time span before the first positive sample seems to be insignificant with regard to the outcome of relapse. All six patients, who had more than 1% of abnormal cells detected at any sampling or whose consecutive follow-up samples showed an increasing frequency (up to 1%) of abnormal cells, relapsed. Absence or occurrence of low numbers of abnormal cells at a frequency of 0.05-0.8% followed by their disappearance was in agreement with continuing complete clinical and hematologic remission (CR) in 16 (84%) of 19 patients. Our results indicate that metaphase-FISH is a reliable technique for quantifying residual leukemic cells. The technique is available in standard cytogenetic laboratories and can be applied to routine follow-up of ALL patients who have a suitable chromosomal aberration.     

MT方案治疗急性单核细胞白血病的疗效及其与染色体核型的关系

目的 研究米托蒽醌联合替尼泊苷(MT)方案在急性单核细胞白血病(M5)诱导缓解中的疗效及患者不良反应,并观察疗效与白血病染色体核型的关系.方法 将33例M5患者按治疗史分两组:初治组23例(A组)、DA(柔红霉素联合阿糖胞苷)或HDA(三尖杉酯碱、柔红霉素和阿糖胞苷)1个疗程无效组10例(B组).按核型预后分两组:预后中等组29例(C组),预后不良组4例(D组),均采用MT方案2个疗程诱导缓解,分别统计4组的临床疗效及患者不良反应.结果 MT方案对A、B组的M5诱导完全缓解(CR)率分别为83%(19/23)及60%(6/10),有效率达91%(21/23)及70%(7/10).C、D组CR率分别为83%(24/29)及25%(1/4),有效率为88%(26/29)及50%(2/4),其中复杂核型CR率为0(0/3),非复杂核型的11q23染色体异常患者一次化疗达CR率100%(4/4).MT方案对M5化疗后白细胞最低点在第(7±3)天出现,为(0.4±0.2)×109/L,白细胞<1×109/L时间达(8±5)d,未见化疗相关死亡病例.结论 MT方案简单有效、较安全,是治疗M5的较佳化疗方案,对1个疗程DA、HDA方案无效者亦可试用.MT方案化疗疗效与核型预后分组有关,对11q23染色体异常的M5患者疗效较好,对复杂核型患者疗效欠佳.     

Useful panel of antibodies for the classification of acute leukemia by immunohistochemical methods in bone marrow trephine biopsy specimens

To evaluate the feasibility of acute leukemia typing on routinely processed bone marrow biopsy specimens, 72 cases of previously established acute leukemia covering the spectrum of 17 known subtypes were studied immunohistochemically. Most leukemic myeloblasts were positive for myeloperoxidase in 16 (84%) of 19 cases of acute myeloid leukemia, M1-M4, and M6. Most leukemic cells in 11 of 12 M4 and M5 cases were positive for CD68 (PG-M1). All six M6 cases stained with hemoglobin. Leukemic megakaryoblasts in three of four M7 cases were positive for factor VIII-related antigen. Almost all leukemic cells of 8 T-lineage acute lymphoblastic leukemia (ALL) and 19 B-lineage ALL cases were positive for CD3 and CD79a (HM57), respectively. Staining with CD20 (L26) was positive in the more differentiated B-lineage ALL cases and strongest in L3. Immunohistochemical typing of acute leukemia is possible for most types using this panel of cell lineage-specific antibodies.     

Primary blasts from infants with acute lymphoblastic leukemia cause overt leukemia in SCID mice

The establishment of an in vivo animal model system for infant acute lymphoblastic leukemia (ALL) would allow the testing of new agents against primary leukemic cells from infant ALL patients. We have demonstrated previously that growth of B-lineage leukemic cells in mice with severe combined immunodeficiency (SCID) was a significant prognostic factor for children with high risk ALL. We now have examined the significance of this prognostic variable for 13 infants with newly diagnosed ALL treated at participating institutions of the Children's Cancer Group (CCG). Chromosomal translocations were detected in 10/12 evaluated cases, including five with t(4;11), one each with t(7;9) and t(7;11), t(1;19), and t(9;22), and two with t(11;19). Twelve of the thirteen infants with ALL achieved remissions following induction chemotherapy. Primary leukemic cells from 8 of the 13 infants caused overt leukemia in SCID mice. Among these 8 SCID+ infants, 7 were CD10- and seven had cytogenetic or molecular evidence of an 11q23 rearrangement. Six of the 8 SCID+ infants have relapsed; only 2 remain in remission following chemotherapy or bone marrow transplant. However, among the 5 SCID- infants there were also two relapses. These data are suggestive of a poorer outcome for SCID+ infants, but larger numbers of patients must be analyzed to assess their statistical significance. In summary, we have established a SCID mouse model for human infant ALL that will be useful for 1) predicting short-term and long-term outcome of patients, 2) testing pharmacokinetics, efficacy, and toxicity of new agents, and 3) elucidating the in vivo mechanisms of chemotherapeutic drug resistance in infant ALL.     

Hematologic, clinical, and cytogenetic analysis in 109 patients with primary myelodysplastic syndrome. Prognostic significance of morphology and chromosome findings

One hundred and nine patients with primary myelodysplastic syndrome (MDS) were classified according to the French-American-British (FAB) criteria: 27 refractory anemia (RA, 25%), 26 RA with ringed sideroblasts (RARS, 24%), 16 RA with excess of blasts (RAEB, 15%), 10 RAEB in transformation (RAEB-t, 9%), 25 chronic myelomonocytic leukemia (CMMoL, 23%), and five unclassifiable MDS (4%). Forty-three were women and 66 were men (sex ratio 2:3). Age ranged from 30-92 years (mean 69 years) with nine patients aged less than 50 years (8%). A cytogenetic result was obtained in all cases. At initial study, a chromosome defect was observed in 56% of patients. Rates of abnormality depended on FAB subtype: 52% in RA, 100% in RA 5q-, 50% in RARS, 56% in RAEB, 70% in RAEB-t and 44% in CMMoL. The most frequent single defects were del(5q), -7/del(7q), del(20q), Y loss, and +8. Except for the 5q- syndrome entity, specific chromosome defects were not associated with particular FAB subtypes. Bone marrow (BM) insufficiency (22%) and leukemic transformation (21%) were the most important causes of death. The rate of leukemic transformation increased with the number of dysplastic BM cell lineages and was also associated with karyotype complexity and the proportion of abnormal/normal metaphases. The longest median survivals were observed in RARS (142 months) and RA/RA5q- (91 months) types. Median survivals decreased with increasing Bournemouth score values. Patients with three abnormal cell lineages had a median survival shorter than those with one or two abnormal lineages. Similarly, patients with complex defects had shorter survival than those with single or double defects or a normal karyotype. There was no statistically significant difference between survival of NN (normal), AN (abnormal/normal), and AA patients or between survival of patients with del(5q), -7/del(7q), +8 or del(20q).     

Adult acute leukemia

Untreated acute leukemia is a uniformly fatal disease with a median survival time shorter than 3 months. Current treatment strategies provide a significant increase in survival time for most patients, some of whom may be cured. The majority of patients with acute leukemia, however, ultimately die of the disease or complications of treatment. The effective treatment of acute leukemia requires (1) differentiation of acute myeloid leukemia (AML) from acute lymphoblastic leukemia (ALL) and recognition of clinically relevant subtypes; (2) identification of patients who are more likely or less likely than average to benefit from a conventional treatment; and (3) selection of therapy that provides a reasonable likelihood of response with acceptable risk of toxic effects. The diagnosis of acute leukemia is established in most cases by a bone marrow aspirate that demonstrates at least 30% blast cells. The traditional criteria to distinguish between AML and ALL rely on morphology and cytochemical reactions. Immunologic analysis of antigen expression and analysis for numerical or structural chromosomal abnormalities of leukemia cells are routinely feasible. Karyotypic analysis is of prognostic importance and should be performed on all diagnostic specimens of bone marrow aspirate. Immunophenotypic analysis may be useful to confirm the disease classification in selected cases. The importance of the routine immunophenotypic characterization of acute leukemia, however, is controversial. The subtypes that must be recognized because of the need for specific treatment include (a) acute promyelocytic leukemia (APL), which is the M3 subtype of AML, and (b) the L3 subtype or mature B-cell ALL. Induction therapy for acute leukemia is treatment intended to achieve induction of complete remission (CR). Complete remission is defined as the absence of morphologic evidence of leukemia after recovery of the peripheral blood cell counts. Failure to achieve CR may be attributed to death during chemotherapy-induced bone marrow hypoplasia or to drug resistance manifested either as failure to achieve hypoplasia or as persistent leukemia after recovery from hypoplasia. Postremission therapy is treatment administered in CR to prevent or delay relapse of the leukemia. However, the majority of patients have disease relapse. Intensification of therapy is a treatment strategy designed to overcome resistance to chemotherapy. Recent clinical trials of intensified induction or postremission therapy suggest improved outcome. However, the toxic effects of dose intensification can be substantial, limiting any potential benefit of this approach. Identification of prognostic factors may allow one to estimate the likelihood of an outcome, to determine an optimal treatment strategy. It is well established that age at the time of diagnosis, leukemia cell karyotype, and whether the leukemia is de novo or secondary are factors that influence treatment decisions. Patients with favorable prognostic factors should probably receive conventional therapy. Patients with unfavorable prognostic factors have shown little benefit from conventional therapy. In addition, factors that indicate poor outcome with conventional therapy are also predictive of poor outcome with intensified therapy. Consequently, these patients should be considered for investigational therapeutic strategies. The bias may be to counsel them to accept the potential increased morbidity of such treatment before there is definite evidence of the possibility of improved outcome. Induction chemotherapy for younger patients with AML (less than 55 years of age) in general consists of one or more courses of cytarabine (ara-C) and an anthracycline or an anthracycline derivative. Randomized trials have failed to confirm that treatment with either etoposide or high-dose ara-C induces disease remission. Patients with secondary AML, high levels of CD34 antigen expression, or an unfavorable karyotype, however, may benefit from ind