T-cell acute lymphoblastic leukemia with t(11;14) in children.

We review and update our examination of the clinical and biologic findings in 19 cases of acute lymphoblastic leukemia (ALL) with the t(11;14) and discuss the literature relevant to the clinical, biologic, and molecular aspects of these translocations. In nine consecutively diagnosed cases at St. Jude Children's Research Hospital and 10 cases reported by other institutions, clinical features did not differ among T-cell ALL patients with and without the t(11;14), although leukemic cells with this translocation were more likely to coexpress CD4 and CD8 antigens. The t(11;14)(p13;q11) appears to occur exclusively in T-cell malignancies of intermediate- or late-stage thymocyte differentiation; further studies will be needed to determine whether it has prognostic significance.     

Expression pattern of hybrid phenotype in adult acute lymphoblastic leukemia.

We examined the expression of hybrid phenotype in 236 adults with acute lymphoblastic leukemia (ALL; 188 B-lineage ALL and 48 T-lineage ALL). In B-lineage ALL, myeloid antigen (mAg) CD15 was concentrated in CD10-CD20- cases (49%); CD13 (42%); and CD33 (43%) in CD10+CD20- cases. This trend had no correlation with the presence of Ph1 or t(4;11) chromosomal abnormality. T-cell antigen CD2, CD4, and CD7 was seen in four, four, and two cases, respectively, and CD4+ and CD7+ cases commonly expressed CD13 and/or CD33 (CD13/CD33). In T-lineage ALL, expression of mAg, CD11b (47%), CD13 (38%), CD15 (28%), and CD33 (51%) was restricted to CD3- cases. B-cell antigen CD19 was found in two cases with CD7 solely as T-cell antigen, and these cases possessed CD13/CD33. CD21 was detected in three cases with CD3. In whole ALL, CD13/CD33 was associated closely with the presence of stem-cell antigen CD34, and in T-lineage ALL, CD13/CD33 had a significant correlation with additional stem-cell features, such as HLA-DR, multidrug resistance 1 (MDR1) and c-kit gene expression. Our results suggest that immature ALL cells frequently express B+M+, T+M+, and occasionally B+T+M+ phenotype; that B+T+M- phenotype is extremely rare; and that mAg expression in B-lineage ALL is complicated as compared to T-lineage ALL.     

Hemophagocytic syndrome complicating T-cell acute lymphoblastic leukemia with a novel t(11;14)(p15;q11) chromosome translocation

A case of hemophagocytic syndrome that developed in a patient with T-cell acute lymphoblastic leukemia (ALL) with a novel chromosome translocation involving 14q11 is reported. A 15-year-old boy with T-cell ALL in relapse showed leukemic cells with an abnormal karyotype of 46,XY,-15,t(11;14)(p15;q11), +der(15)t(15;?)(p11;?). Pancytopenia and extensive hemophagocytosis by macrophages in the bone marrow were observed after reinduction chemotherapy and again at the terminal stage. At autopsy, infiltration of such cells was also found in other organs. The findings suggested occurrence of hemophagocytic syndrome probably associated with cytomegalovirus (CMV) infection. The t(11;14)(p15;q11) may be a novel translocation specific for T-cell ALL, and conceivably, the association of T-cell ALL with the histiocytosis in this patient may not have been coincidental.     

Acute lymphoblastic leukemia with the (4;11) translocation: combined cytogenetic, immunological and molecular genetic analyses.

Five cases of acute leukemia (AL) with the t(4;11) translocation were investigated for the immunoglobulin heavy chain, kappa, lambda, TCR beta and TCR gamma gene rearrangements. All patients presented with high-risk features and had survival times of less than two years. Two cases were classified by immunological phenotyping as acute null-AL(L), one case as pre B-cell ALL (CD10+) and two cases expressed both immature B-cell markers CD19 and CD24 and myelomonocytic markers CD15 and CD14, suggesting mixed lineage leukemia. In two cases more than two rearranged fragments for the immunoglobulin heavy chain gene could be detected by Southern blot analysis. In the other cases at least one allele of the immunoglobulin heavy chain gene was rearranged. Germline configuration of the T-cell receptor genes and lack of light chain gene rearrangement suggest that an early B-precursor cell is involved in the transformational events in these cases of ALL. Our own and published data indicate that acute leukemia with t(4;11) translocation might be more frequently associated with more than two rearranged fragments for the immunoglobulin heavy chain genes and run a very aggressive course.     

11;14 translocation in childhood T-cell acute lymphoblastic leukemia

No consistent chromosome abnormalities have been reported so far in T-cell lymphoma-leukemia. We report here two children suffering from T-cell acute lymphoblastic leukemia (ALL) with t(11;14)(q13;p11). Even though the breakpoints we claim are different from those in a recent report, we believe that their cases and ours have the same abnormality and that patients with this abnormality constitute a distinct subgroup of T-cell ALL positive for sheep erythrocyte receptor (E+) in children.     

急性淋巴细胞白血病染色体核型分析

 【摘要】　目的　研究急性淋巴细胞白血病（ALL）患者的染色体异常核型及其与临床特征和近期疗效的关系。方法　采用骨髓细胞短期培养法、吉姆萨显带对110例ALL患者进行染色体核型分析。结果　110例ALL患者中,正常核型71例（64.5 %）,异常核型39例（35.5 %）,染色体核型结构异常者24例（21.8 %）,数目异常者11例（10.0 %）,结构及数目异常者3例（2.7 %）,异常复杂核型1例。伴有t(9;22) (q34;q11)的ALL患者疗效差于其他患者（确切概率法,P＝0.045）,伴有t(9;22)(q34;q11)的成年人ALL与儿童ALL疗效差异无统计学意义（确切概率法,P＝0.506）。结论　ALL患者的染色体核型异常具有随机性,较常见的有t(9;22)(q34;q11)、 t(4;11)(q21;q23),其疗效较差。     

Pediatric leukemia/lymphoma with t(8;14)(q24;q11).

A variety of chromosomal translocations occur in pediatric T-cell acute lymphoblastic leukemia (T-ALL) in which a cellular oncogene or growth-related gene is translocated to the alpha/delta locus of the T-cell receptor gene. The t(8;14)(q24;q11) has been described at the cytogenetic and molecular level, but the disease associated with this translocation has not been defined clinically. Fifteen pediatric cases of leukemia/lymphoma with a t(8;14)(q24;q11) chromosomal translocation were collected from previous publications and institutional records. The estimated prevalence of this abnormality among all cases of ALL was 1%. The t(8;14)(q24;q11) disease was characterized by male predominance (10/15), a median age of 5.5 years (range 1.8-17 years), high white blood cell count (median 95 x 10(9)/l), central nervous system infiltration (4/11), bulky extramedullary leukemia (10/11), and T-cell immunophenotype (12/15). The median event-free survival was 4 months, and the median survival, 11 months. Seven cell lines with t(8;14)(q24;q11) were established from six of the cases; four were T-lymphoblastic, one was T-lymphoblastic, but expressed myeloid-related antigens, and two were predominantly myeloid. t(8;14)(q24;q11) leukemia/lymphoma and other ALLs involving 13(q11) have in common a high tumor burden, early spread to extramedullary sites, a propensity to form T-lymphoblastic or T-myeloid cell lines and, usually, an aggressive clinical course.     

Review of the incidence and clinical relevance of myeloid antigen-positive acute lymphoblastic leukemia

An increasing number of papers document cases of acute leukemia in which individual blast cells co-express markers normally restricted to a single cell lineage. Numerous terms are used to refer to cases with unscheduled expression of lineage-foreign proteins; the best defined categories were hybrid acute leukemia and acute mixed-lineage leukemia. The incidence of phenotypically variant acute leukemia varies with the quality and quantity of parameters used and the stringency of the criteria employed for its definition. Considerable interest has focused on acute lymphoblastic leukemia (ALL) cells expressing one or several myeloid lineage-associated antigens (My+ ALL), CD13, CD14, CD15, CD33, and CDw65. Owing to legitimate and cryptic expression on lymphoid cells, CD11b and CD15 reagents may not be considered as specific indicators of myeloid differentiation. The reported incidence ranged from 5 to 46% in 14 studies on My+ ALL, totalling 3817 patients. Several detailed reports documented a higher incidence of My+ ALL in adults (realistically in the range 10-20%) than in children (5-10%) and in B-lineage ALL as opposed to T-lineage ALL. My+ ALL cases are more likely to display unique cytogenetic [t(9;22), 11q23, 14q32] features than My-neg ALL. There appears to be no predominant expression of a single myeloid-associated antigen among those analyzed. As the morphological diagnosis of a leukemia subtype is often imprecise, some T-neg B-neg My+ ALL cases might actually contain FAB AML-M0 populations. While the expression of myeloid-associated antigens has no apparent prognostic significance in the majority of childhood ALL subtypes, in adults myeloid antigens seem to identify a high risk group of ALL patients with a poorer response to standard ALL therapy.     

CLASSIFICATION OF NINETY-EIGHT ADULT CASES OF ACUTE LEUKEMIAS ACCORDING TO MORPHOLOGY,IMMUNOLOGY AND CYTOGENETICS

In the present study,98 cases of acute leukemias(AL) were diagnosed and classified based on morphologic,immunologic and cytogenetic(MIC)features to assesstheir diagnostic value in AL.The results showed that:the conformity rate of cytomorphologic/cytochemicalclassification with MIC classification was 90.8%.ForALL,the conformity rate of imnunologic classificationwith MIC classifcation was 95.6% while it was only70.8% for AML.Of the 48 AML,10 expressed lymphoid-lineage-associated antigens and 8 of 43 ALL expressedmyeloid-lineage-associated antigens.Seven cases werediagnosed as hybrid acute leukemia according toCatovsky’s scoring criterion.The clona chromosomalaberrations were found in 70 cases,of them 46 casesshowed Characteristic changes includhg 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.These data suggested that MIL classi-fication of acute leukemias could provide move diagnosticand biologic information than traditional FAB classi-fication.     

Acute leukemia expressing the normal human hematopoietic stem cell membrane glycoprotein CD34 (MY10)

Thirty-one cases of acute leukemia with blast cells greater than or equal to 70% positive for the hematopoietic stem cell Ag, CD34 (MY10, HPCA-1), were identified from the University of Nebraska Medical Center and The Johns Hopkins Oncology Center over an 18-month period. Fourteen of the cases were classified as early B-lineage ALL, 3 cases were other ALL subtypes, and 14 of the cases were ANLL. Five of the 17 cases of ALL expressed one or more myeloid-associated surface Ags, 3 ANLL cases expressed CD10 (CALLA, J5), and T-lymphoid Ags were present in 12 of 31 cases (1 T-cell ALL, 3 of 16 B-lineage ALL cases, and 8 of 14 ANLL cases). Eleven of 12 CD34+ ALL cases studied had abnormal karyotypes; only 7 of 12 CD34+ ANLL cases studied had abnormal karyotypes, and 3 of these were CD10+ ANLL. Six cases were Ph1 positive, including the one mature B cell ALL, 4 early B-lineage ALL, and 1 CD10+ ANLL case. Good and poor prognosis subgroups of high frequency of expression of CD34 leukemias could be identified, generally, as would have been predicted by previously defined criteria. Thus, of the 10 Ph1-negative early B-lineage ALL patients, 9 achieved CR (90%). At the other extreme, the CR rate of CD10- ANLL was 4 of 11 (36%). The leukemias characterized by greater than or equal to 70% of cells positive for CD34 form a relatively undifferentiated subset of the leukemias which may show features associated with more than one lineage, and if CD10- and myeloid morphology, may respond poorly to therapy.     

Clinical Significance of Co-expression of Aberrant Antigens in Acute Leukemia: A Retrospective Cohort Study in Makah Al Mukaramah,Saudi Arabia

Background: Aberrant phenotypes in acute leukemia have variable frequency and their prognostic andpredictive relevance is controversial, despite several reports of clinical significance. Aims: To determinethe prevalence of aberrant antigen expression in acute leukemia, assess clinical relevance and demonstrateimmunophenotype-karyotype correlations. Materials and Methods: A total of 73 (40 AML and 33 ALL) newlydiagnosed acute leukemia cases presenting to KAMC, Kingdom of Saudi Arabia, were included. Diagnosis wasbased on WHO criteria and FAB classification. Immunophenotyping by flow cytometry, conventional karyotypingand fluorescence in situ hybridization for gene rearrangements were performed. Results: Aberrant antigens weredetected in 27/40 (67.5%) of AML and in 14/33 (42.4%) in ALL cases. There were statistically significant higherTLC in Ly+ AML than in Ly-AML (p=0.05) and significant higher blast count in ALL with aberrant antigensat presentation and day 14 (p=0.005, 0.046). There was no significant relation to clinical response, relapse freesurvival (RFS) or overall survival (p>0.05), but AML cases expressing ≥2 Ly antigens showed a lower medianRFS than those expressing a single Ly antigen. In AML, CD 56 was expressed in 11/40. CD7 was expressed in7/40, having a significant relation with an unfavorable cytogenetic pattern (p=0.046). CD4 was expressed in 5/40.CD19 was detected in 4/40 AML associated with M2 and t (8; 21). In ALL cases, CD33 was expressed in 7/33and CD13 in 5/33. Regarding T Ag in B-ALL CD2 was expressed in 2 cases and CD56 in 3 cases. Conclusions:Aberrant antigen expression may be associated with adverse clinical data at presentation. AML cases expressing≥2 Ly antigens may have shorter median RFS. No specific cytogenetic pattern is associated with aberrant antigenexpression but individual antigens may be related to particular cytogenetic patterns. Immunophenotype-karyotypecorrelations need larger studies for confirmation.     

Myeloid surface antigen expression in adult acute lymphoblastic leukemia.

The expression of myeloid surface markers was investigated in 41 cases of untreated adult acute lymphoblastic leukemia (ALL). Nineteen cases (46%) reacted with at least one myeloid monoclonal antibody (CD15 in 16 cases, CD13 in 10 cases, CD14 in five cases, and CD33 in four cases). Double-staining confirmed the coexpression of myeloid and lymphoid markers. In addition, 35 samples were tested for CD34 expression. Fourteen of the 17 myeloid-positive cases tested were positive for CD34 vs. eight of 18 negative cases (p less than 0.05). A t(9;22) translocation was found in eight cases, and a t(4;11) translocation in two cases, all expressing CD34 and myeloid antigens. These findings confirm the high frequency of myeloid markers on the surface of adult ALL blasts, and suggest that these leukemias may originate in a poorly differentiated precursor cell with mixed differentiation capacities.     

Immunological phenotypic pattern of acute lymphoblastic leukaemia in Egypt

We have performed immunophenotyping studies on 186 untreated cases of acute lymphoblastic leukemia (ALL) in an Egyptian population, using panels of monoclonal antibodies (mAb) and an avidin-biotin-immunoperoxidase detection system. Sixty-two of these cases were tested with a panel of mAb directed against the T-cell markers CD2, CD4, CD8, B-cell markers CD20, kappa and lambda, the common ALL antigen (common ALLa) and class II HLA antigens. The remaining 124 cases were also tested with additional markers of T- and B-cell precursors, namely CD7 and CD19. The common leukocyte antigen, T200, was used to exclude nonhemopoietic neoplasms. Cases that remained unclassifiable were further tested with a wider panel of T-cell markers, including CD1, CD2, CD3 and CD5. In some cases multiple mAb directed against the same antigens were used. The relative frequencies of common ALL and B ALL were calculated from the total number of cases and were found to be 39.2% and 3.2%, respectively. The proportions of T-cell and null leukemias were calculated from the better characterized subgroup of 124 cases, and were found to be 50% and 4.8%, respectively. In our series, the age distribution of common ALL revealed a peak at 2-5 yr, but this was partially obscured in the entire series by the high proportion of T-cell cases, which had an age peak between 4 and 12 yr of age. Our results demonstrate marked differences in the phenotypic pattern of ALL in Egypt compared to Western Countries, the predominant finding being a relative excess of T-cell ALL and a paucity of common ALL cases. At present it is not clear whether this results from an increased incidence of T-cell ALL or a decreased incidence of common ALL.     

Determination of Myloid Antigen Expression on Childhood Acute Lymphoblastic Leukaemia Cells: Discrepancies Using Different Monoclonal Antibody Clones

Prospective clinical studies including large numbers of patients have led to the conclusion that co-expression of myeloid antigens in childhood acute lymphoblastic leukaemia (My+ ALL) does not have prognostic significance. However, reports of the frequency of My+ ALL in children vary widely across laboratories using different mAb clones and staining and analysing procedures. Taking two commonly accepted thresholds of positivity for myeloid antigens (20 and 30%), we analysed the immunoreactivity of the most widely employed mAb clones against CD13 (SJ1D1, L138 and My7) and CD33 (My9, P67.6 and D3HL60) and compared the proportions of My+ ALL detected by these clones in childhood ALL. The correlation between myeloid antigen expression and the presence of the t(12;21) translocation was analysed concomitantly in the same samples.

The percentage of ALL cases positive for myeloid markers varied significantly depending on the mAb clone and the positive threshold. Among patients with B-ALL, the proportion of CD13+ ALL was significantly lower using SJ1D1 than using L138 or My7, while the proportion of CD33+ ALL was significantly higher for My9 than for P67.6 or D3HL60. Analysis of the co-expression of CD13 and CD33 on B-ALL cells using combinations of mAb clones showed that this frequency was either underestimated by the SJ1D1/D3HL60 or overestimated by the L138/P67.6 and My7/My9 combinations. A correlation between CD13/CD33 positivity and the t(12;21) translocation was uniformly observed in B-ALL patients for a positive threshold of 30%, whereas SJ1D1/D3HL60 detected no correlation between t(12;21) and CD13/CD33 ppositivity when the threshold was lowered to 20%. These data show that the mAb clones commonly used to detect the CD13 and CD33 surface antigens have variable immunoreactivity against childhood ALL cells, which may partly explain the conflicting reports concerning the prognostic significance of myeloid antigen expression in paediatric ALL and its association with different translocations. The present findings may also be of clinical importance for therapeutic choices.     

Childhood acute leukemia with t(11;19) (q23;p13).

From 583 cases of acute lymphoblastic leukemia (ALL) and 181 cases of acute myeloid leukemia (AML) in childhood, seven patients were identified to have t(11;19) (q23;p13) by sequential cytogenetic analyses. The t(11;19) was associated with B-precursor ALL at diagnosis in three patients and at relapse in one patient. All four tested patients with B-precursor failed to express the CD10 antigen when the t(11;19) was detected, and one of three patients tested expressed myeloid-associated markers. In three other patients the translocation was detected either at lineage conversion from ALL to M5 AML (n = 2) or from AML to CD10- B-precursor ALL (n = 1). Leukemic blasts of four patients had an entirely different karyotype at the time of lineage conversion or loss of CD10 expression, suggesting an induction of a second neoplasm. Thus the t(11;19) can be found in de novo or secondary acute leukemia with lymphoid (CD10-) or myeloid (monoblastic) phenotype. Further investigation of the gene(s) involved in the 11q23 chromosomal region and the breakpoints in the 19p13 region is needed to understand the leukemogenesis of this apparently heterogeneous group of disorders.     

Rearrangement of T-cell receptor delta chain gene as a marker of lineage and clonality in T-cell lymphoproliferative disorders

We analyzed the rearrangement of T-cell receptor (TcR) delta chain gene in 88 cases of lymphoproliferative disorders; 31 acute lymphoblastic leukemias/lymphoblastic lymphomas (ALL/LBL); 27 adult T-cell leukemias/lymphomas, 9 angioimmunoblastic lymphoadenopathies (AILD); 10 T-cell lymphomas (non-Hodgkin's lymphoma); and 11 Hodgkin's disease. All of 9 T-ALL/LBL cases, of which 4 cases have neither beta nor gamma gene rearrangement, had a new rearranged band of TcR delta locus. Ten of 16 B-lineage ALL/LBL had rearranged band(s) or deletion of TcR delta locus. The rearranged bands were recognized in 2 cases of AILD and 1 case of T-cell lymphoma. All cases of adult T-cell leukemias/lymphomas, 4 of AILD, 4 of T-cell lymphoma, and 8 of Hodgkin's disease had deleted TcR delta locus. Heterogeneous findings of TcR delta locus analysis were observed in AILD, T-cell lymphoma, and Hodgkin's disease. In 16 cases with TcR delta rearrangement, the J delta 1 region was frequently used and the J delta 2 region was rearranged in one AILD. It is suspected that J delta 3 was used in one T-ALL/LBL. There was no correlation between the phenotypic pattern of CD3, CD4, CD8 in T-cell disorders and the rearrangement of the TcR delta gene. These findings suggest that the newly identified TcR delta chain gene rearranges at a very early stage of T-cell ontogeny; prior to the other TcR genes and perhaps at almost the same stage with CD7 expression. The TcR delta gene is useful in assessing clonality for the most immature T-cell neoplasms not showing rearrangement of the other TcR genes. This gene is not lineage specific; however, when used in conjunction with immunoglobulin heavy chain gene, it may be a useful tool to distinguish lymphoid lineage of ALL/LBL.     

Acute leukemias with the t(4;11)(q21;q23).

The t(4;11)(q21;q23) has been associated with marked lineage heterogeneity. Most of the reported cases were classified as acute lymphoblastic leukemia (ALL). The t(4;11) is one of the commonest specific chromosomal translocations in ALL, occurring in 2% of childhood and 5% of adult cases. In childhood ALL, this translocation is associated with female sex, age less than 1 year, hyperleukocytosis, CD10-/CD19+ B-precursor cell immunophenotype, and myeloid-associated antigen (CD15) expression. There also appears to be an age-related difference in treatment outcome. Adults had the worst prognosis, and children aged 1 to 9 years appeared to have a better outcome than infants or adolescents. Reported cases of acute myeloid leukemia (AML) or secondary leukemia with the t(4;11) have not been well characterized. It is intriguing that virtually all of the reported cases with secondary leukemia had received epipodophyllotoxins or doxorubicin, agents that affect topoisomerase II and are associated with secondary AML characterized by 11q23 abnormalities. Identification of the involved gene(s) in the t(4;11) will provide a molecular approach permitting more accurate classification of these cases.