Richard Garand

The clinical presentation and prognosis of diffuse large B-cell lymphoma with t(14;18) and 8q24/c-MYC rearrangement

Background and Objectives Diffuse large B-cell lymphomas (DLBCL) are common lymphomas that have been classified into three subgroups on the basis of their patterns of gene expression. The aim of this study was to characterize the clinical, biological, immunophenotypic and cytogenetic features of DLBCL with concurrent t(14;18) and 8q24/c-MYC rearrangement. Design and Methods Sixteen cases of DLBCL with the dual translocation were identified between 1998 and January 2006. The clinical features of these cases were examined and morphological, immunohistochemical, flow cytometric and cytogenetic analyses were performed. Results All patients had aggressive features: B symptoms (81%), ECOG performance status >2 (81%), elevated lactate dehydrogenase (100%), stage IV disease (100%) with at least one extra-nodal localization (bone marrow, blood and central nervous system involvement in 93%, 50% and 50%, respectively) and age-adjusted IPI score of 3 in 81%. Despite intensive chemotherapy regimens (including allogeneic transplants), all patients died of disease progression. Progression-free and overall survival was 4 and 5 months, respectively. Immunophenotyping analysis (CD20, CD10, Bcl-6, Mum-1, Bcl-2 CD138, MIB1, CD19, CD5, CD38 and sIg) was performed and showed DLBCL with a germinal center (GC) profile. Ki-67 staining ranged from 70 to 90%. All cases assessed by cytogenetics analysis [conventional cytogenetic and/or fluorescence in situ hybridization (FISH)] had a complex karyotype. In one case, we identified a 8q24/c-MYC translocation variant never reported in DLBCL before: t(8;9)(q24;p13) and t(14;18)(q32;q21). The BCL-6 rearrangement was investigated by FISH and found to rearranged in four cases. Interpretation and Conclusions In conclusion, DLBCL with concurrent t(14;18) and 8q24/c-MYC rearrangement is a subgroup of GC-DLBCLwith poor outcome. It is worth searching for the coexistence of dual translocations in Bcl-2-positive DLBCL with unusual aggressive presentation.

CD38 expression and secondary 17p deletion are important prognostic factors in chronic lymphocytic leukaemia.

Summary. CD38 expression and chromosomal abnormalities are novel prognostic factors in chronic lymphocytic leukaemia (CLL). However, their value remains undetermined. CD38 was evaluated in 123 patients and chromosomal aberrations in 111 cases with fluorescence in situ hybridization (FISH). CD38 expression was found in 27% ofthe cases. In addition, seven out of 32 CD38– patients became CD38+ during evolution of the disease. Chromosomal abnormalities included isolated 13q deletion (40%), 12q trisomy (14%), 11q deletion (without 17p deletion) (14%) and 17p deletion (7%). CD38 expression was significantly associated with Binet stages B and C, atypical morphology and 11q deletion. On univariate analysis of survival estimates, advanced Binet stages, CD38+ phenotype, atypical morphology and 11q or 17p deletions were associated with shorter event‐free survival (EFS), treatment‐free interval (TFI) and overall survival (OS). Multivariate analysis identified both Binet stages and CD38 as independent prognostic factors with regard to EFS and TFI. However, CD38 appeared as an independent factor for OS when restricted to Binet stage A. Chromosomal aberrations were re‐evaluated during evolution in 31 cases. The 17p deletion was the most frequent new chromosomal abnormality (35%) and significantly associated with death (64%). In conclusion, CD38 expression and secondary 17p deletion are important poor prognostic indicators, especially in Binet stage A CLL.

Indolent course as a relatively frequent presentation in T‐prolymphocytic leukaemia

T‐prolymphocytic leukaemia (T‐PLL) is a rare disorder with a poor outcome. Presentation features were studied in 78 T‐PLL cases. Although 53 patients (group A) presented with typical progressive disease including rapidly increasing leucocytosis, 25 patients (group B) experienced an initial indolent clinical course with stable moderate leucocytosis. The morphology and antigenic profile of abnormal cells were similar in both groups, except for a lower incidence of CD45RO+ CD45RA− pattern in group B. A high incidence of inv(14)(q11;q32), t(14;14)(q11;q32) and i(8)(q10) chromosomal abnormalities were found in both groups. After an initial indolent phase (median 33 months; 6–103 months), 16 group B patients progressed to an aggressive stage with clinical and laboratory features similar to group A. Moreover, median survival after progression was short in both groups. In conclusion, T‐PLL may start as an indolent disease similar to that reported in ataxia telangectasia. In this rare genetic disorder, some patients develop stable T‐cell clones which progress toward T‐PLL‐like leukaemia. Moreover, ATM gene mutations have been reported in T‐PLL. Thus, both diseases are likely to be closely related.

Extended diagnostic criteria for plasmacytoid dendritic cell leukaemia.

The diagnosis of plasmacytoid dendritic cell leukaemia (pDCL) is based on the immunophenotypic profile: CD4+ CD56+ lineageneg CD45RA+/ROneg CD11cneg CD116low CD123+ CD34neg CD36+ HLA‐DR+. Several studies have reported pDCL cases that do not express this exact profile or expressing some lineage antigens that could thus be misdiagnosed. This study aimed to validate pDCL‐specific markers for diagnosis by flow‐cytometry or quantitative reverse transcription polymerase chain reaction on bone marrow samples. Expression of markers previously found in normal pDC was analysed in 16 pDCL, four pDCL presenting an atypical phenotype (apDCL) and 113 non‐pDC – lymphoid or myeloid – acute leukaemia. CD123 was expressed at significantly higher levels in pDCL and apDCL. BDCA‐2 was expressed on 12/16 pDCL and on 2/4 apDCL, but was never detected in the 113 non‐pDC acute leukaemia cases. BDCA‐4 expression was found on 13/16 pDCL, but also in 12% of non‐pDC acute leukaemia. High levels of LILRA4 and TCL1A transcripts distinguished pDCL and apDCL from all other acute leukaemia (except B‐cell acute lymphoblastic leukaemia for TCL1A). We thus propose a diagnosis strategy, scoring first the CD4+ CD56+/− MPOneg cCD3neg cCD79aneg CD11cneg profile and then the CD123high, BDCA‐2 and BDCA‐4 expression. Atypical pDCL can be also identified this way and non‐pDC acute leukaemia excluded: this scoring strategy is useful for diagnosing pDCL and apDCL.

Immunological classification of acute myeloblastic leukemias : Relevance to patient outcome

Immunophenotyping is a major tool to assign acute leukemia blast cells to the myeloid lineage. However, because of the large heterogeneity of myeloid-related lineages, no clinically relevant immunological classification of acute myeloblastic leukemia (AML) has been devised so far. To attempt at formulating such a classification, we analyzed the pattern of expression of selected antigens, on blast cells collected at AML diagnosis. Patients were eligible if they had a first diagnosis of de novo AML and a sufficient number of blast cells for proper immunophenotyping. The relative expression of CD7, CD13, CD14, CD15, CD33, CD34, CD35, CD36, CD65, CD117, and HLA-DR were analyzed by cytometry in a test series of 176 consecutive AML cases. Statistical tools of clusterization allowed to remove antigens with overlapping distribution, leading us to propose an AML classification that was validated in a second AML cohort of 733 patients. We identified five AML subsets (MA to ME) based on the expression of seven antigens within four groups (CD13/CD33/CD117, CD7, CD35/CD36, CD15).-MA and MB-AML have exclusively myeloid features with seldom extramedullary disease and rare expression of lymphoid antigens. No cases of acute promyelocytic leukemia (APL) were observed within MB AML. MC AML have either myeloid or erythroblastic features. MD AML have more frequently high WBC counts than other subsets, which were related to the expression of CD35/CD36 and CD14 and to monoblastic differentiation. ME AML lack CD13, CD33, and CD117 but display signs of terminal myeloid differentiation. Specific independent prognostic factors were related to poor overall survival in each immunological subset: CD34+ (P<3 × 10−4) in MA AML, CD7+ in MB AML, non-APL cases (P<0.03) in MC AML, CD34+ (P<0.002) and CD14+ (P<0.03) in MD AML, CD14+ in ME AML (P<0.01). The inclusion of seven key markers in the immunophenotyping of AML allows a stratification into clinically relevant subsets with individual prognostic factors, which should be considered to define high-risk AML populations.

t(11;14) and t(4;14) translocations correlated with mature lymphoplasmacytoid and immature morphology, respectively, in multiple myeloma

Recent studies have shown that two recurrent translocations, t(4;14)(p16;q32) and t(11;14)(q13;q32), define distinct entities with different prognosis in multiple myeloma (MM). We addressed the issue of whether these illegitimate IGH rearrangements could contribute to the morphological heterogeneity of the malignant plasma cells (PC). Bone marrow aspirates of 178 untreated MM cases with successful molecular cytogenetics analysis using fluorescence in situ hybridization were reviewed. PC of 25/48 (52%) patients with t(11;14) exhibited a lymphoplasmacytoid morphology. Moreover, 25/27 (93%) of the cases with this morphological profile bore the t(11;14). In addition, both cytogenetics and morphological subtypes shared higher incidence of nonsecretory MM. In contrast, 17 out of 28 cases (61%) with t(4;14) exhibited PC with diffuse chromatin pattern. Interestingly, both t(4;14) translocation and immature morphology correlated with higher incidence of high tumor mass and chromosome 13 abnormality. In conclusion, our results suggest that a particular morphology can be the signature of chromosomal abnormalities in MM.

A complex pattern of recurrent chromosomal losses and gains in T-cell prolymphocytic leukemia

T‐cell prolymphocytic leukemia (T‐PLL) is a rare malignant proliferation of lymphoid cells with a postthymic phenotype. Previous cytogenetic and molecular studies reported complex karyotypes with recurrent chromosomal abnormalities, including translocations involving either TCL1 at 14q32.1 or MTCP1 at Xq28, inactivation of the ATM gene by deletion and/or mutation, and isochromosomes 8. For extensive study of chromosomal imbalances in T‐PLL, we analyzed 22 tumoral DNAs using comparative genomic hybridization (CGH). Abnormal CGH profiles were detected in all cases, demonstrating highly recurrent gains and losses and largely extending the abnormalities previously established. Only a few nonrecurrent abnormalities were observed, in contrast to the genetic instability anticipated from ATM inactivation. Nine recurrent regions of loss were identified at 8p (frequency 86%), 11q (68%), 22q11 (45%), 13q (41%), 6q (36%), 9p (27%), 12p (23%), 11p11–p14 (23%), and 17p (23%), as well as four regions of gain at 8q (82%), 14q32 (50%), 22q21–qter (41%), and 6p (23%). Several recurrent chromosomal abnormalities were simultaneously present in each case (mean, 5.7; up to 10), none being mutually exclusive of another. Fluorescence in situ hybridization analysis confirmed and extended 22q11 and 13q losses, giving final frequencies of 55% and 45%, respectively. Analysis of one case over a 7‐year period confirmed the overall genetic stability of T‐PLL and showed that tumor progression was associated with the onset of a few chromosomal abnormalities. This study establishes a complex pattern of highly recurrent chromosomal abnormalities in T‐PLL, including some, such as chromosome 13 deletion, commonly found in other lymphoid malignancies.

Long-Term Disease-Free Survival After Gemtuzumab, Intermediate-Dose Cytarabine, and Mitoxantrone in Patients With CD33+ Primary Resistant or Relapsed Acute Myeloid Leukemia

PURPOSE To determine the antitumor activity and safety of a combination of gemtuzumab ozogamicin (GO), intermediate-dose cytarabine, and mitoxantrone (MIDAM) in patients with refractory or relapsed CD33(+) acute myeloid leukemia (AML). PATIENTS AND METHODS We treated 62 patients with refractory (n = 18) or relapsed (n = 44) CD33(+) AML. Median age was 55.5 years. Salvage regimen consisted of GO 9 mg/m(2) on day 4, cytarabine 1 g/m(2) every 12 hours on days 1 through 5, and mitoxantrone 12 mg/m(2)/d on days 1 through 3. Median follow-up time was 26.5 months. RESULTS Thirty-one patients (50%) achieved complete remission (CR), and eight patients (13%) had CR with delayed platelet recovery (CRp); the overall response (OR; CR + CRp) rate was 63%. A significantly higher OR rate was achieved in patients who had relapsed versus refractory AML (73% v 39%, respectively; P = .007) and patients with CD33 expression more than 98% of the blast population versus less than 98% (79% v 52.3%, respectively; P = .03). The overall, event-free, and disease-free survival rates were 41%, 33%, and 53% at 2 years, respectively. Leukocytosis more than 20,000/microL at MIDAM therapy, high-risk cytogenetics, and absence of postremission therapy were adverse prognostic factors. Age, disease status, and/or CD33 expression did not influence survival parameters. Four early toxic deaths occurred; a grade 3 to 4 hyperbilirubinemia rate of 16% was observed, and two patients had veno-occlusive disease (3%). CONCLUSION The MIDAM regimen seems to be an effective salvage regimen for refractory/relapsed CD33(+) AML patients. These encouraging results support the need for a randomized phase III trial before considering this combination of GO and chemotherapy as superior or the standard of care treatment for refractory/relapsed CD33(+) AML patients.

Acute Megakaryoblastic Leukaemia: A National Clinical and Biological Study of 53 Adult and Childhood Cases by the Groupe Français d'Hématologie Cellulaire (GFHC)

Since the WHO classification of haematological malignancies recommended the description of global entities, we performed a national M7-AML study to correlate morphological, immunological and cytogenetic features, and to find new clinically relevant M7 entities. This study is based on accurate morphological and immunological study to select pure megakaryoblastic proliferations and to eliminate megakaryocytic participation in haemopathies. We collected 53 cases: 23 adults and 30 children. We confirm the wide heterogeneity of adult M7. In adults, the cytogenetic abnormalities are frequently those of secondary leukaemia while a few patients have a previous history and morphological features of dyshaematopoiesis; their outcome is very poor. Among children, besides the well-known Down syndrome M7, we in particular, studied ten t(1;22) M7 and one OTT-MAL transcript positive case with normal karyotype presenting specific features. We were already aware of their younger age, female and tumoral presentation, but we also found a lower percentage of bone marrow blasts, sometimes without any megakaryoblastic bone marrow involvement, but always, with a dysmegakaryocytopoiesis associated with micromegakaryocytes. They are generally good responders to intensive AML chemotherapy with very long disease-free survivals (DFS). Accordingly, OTT-MAL transcript study, in infant M7 with normal karyotype, is recommended and we feel that this entity should be added to the WHO AML classification.

Detection of t(11;14) using interphase molecular cytogenetics in mantle cell lymphoma and atypical chronic lymphocytic leukemia

The chromosomal translocation t(11;14)(q13;q32) fuses the IGH and CCND1 genes and leads to cyclin D1 overexpression. This genetic abnormality is the hallmark of mantle cell lymphoma (MCL), but is also found in some cases of atypical chronic lymphocytic leukemia (CLL), characterized by a poor outcome. For an unequivocal assessment of this specific chromosomal rearrangement on interphase cells, we developed a set of probes for fluorescence in situ hybridization (FISH). Northern blotting was performed for analysis of the cyclin D1 expression in 18 patients. Thirty‐eight patients, with either a typical MCL leukemic phase (17 patients) or atypical CLL with an MCL‐type immunophenotype, i.e., CD19+, CD5+, CD23−/low, CD79b/sIgM(D)++, and FMC7+ (21 patients), were analyzed by dual‐color interphase FISH. We selected an IGH‐specific BAC probe (covering the JH and first constant regions) and a commercially available CCND1 probe. An IGH–CCND1 fusion was detected in 28 of the 38 patients (17 typical MCL and 11 cases with CLL). Cyclin D1 was not overexpressed in two patients with typical MCL and an IGH–CCND1 fusion. In view of the poor prognosis associated with MCL and t(11;14)‐positive CLL, we conclude that this set of probes is a valuable and reliable tool for a rapid diagnosis of these entities. Genes Chromosomes Cancer 23:175–182, 1998.