Immunological definition of acute promyelocytic leukemia (FAB M3): a study of 39 cases

Complex genetic structural aberrations revealed by optical genome mapping in a case of APL-like morphology

We present a detailed cytogenomic analysis from a patient with suspected acute promyelocytic leukemia (APL), based on morphological and immunophenotypic characteristics. Initial testing with fluorescence in situ hybridization (FISH) and chromosome analysis was negative for the canonical PML::RARA and other RARA partners translocations. Polymerase chain reaction (PCR) did not detect PML::RARA transcripts. However, chromosome analysis results revealed loss of 5q and 17p, as well as the presence of double minutes (dmin). To further assess the involvement of other retinoic acid receptor (RAR) partners, such as RARB and RARG, and to elucidate the origin of the dmin, we conducted genome-wide structural variant analysis (gwSVA) using optical genome mapping (OGM) as part of a research and confirmatory follow-up. Using gwSVA, we identified the double minutes to be of MYC origin, with approximately 44 copies. Additionally, gwSVA revealed a loss of TP53, along with polyploidy showing loss of chromosomes 1, 2, 8, 9 (including CDKN2A), 10, 11, 15 and gains of chromosomes 3, 6, and 7 indicating distinct clonal events in a diagnostic and follow up bone marrow. Next generation sequencing (NGS) with an exome-based heme targeted panel identified a Tier I deleterious TP53 single nucleotide variant (p.S241C). The follow-up bone marrow analyzed with gwSVA, four months post-induction therapy, showed a reduction in number of cells exhibiting MYC amplification. This study provides a rare instance of a TP53 positive case with APL-like bone marrow morphology, no RARA rearrangement, and MYC amplification. It further lends evidence towards comprehensive cytogenomic and molecular analyses for accurate risk stratification and subsequent disease tracking.

The Role of Epithelial-to-Mesenchymal Transition Transcription Factors (EMT-TFs) in Acute Myeloid Leukemia Progression

Acute myeloid leukemia (AML) is a diverse malignancy originating from myeloid progenitor cells, with significant genetic and clinical variability. Modern classification systems like those from the World Health Organization (WHO) and European LeukemiaNet use immunophenotyping, molecular genetics, and clinical features to categorize AML subtypes. This classification highlights crucial genetic markers such as FLT3, NPM1 mutations, and MLL-AF9 fusion, which are essential for prognosis and directing targeted therapies. The MLL-AF9 fusion protein is often linked with therapy-resistant AML, highlighting the risk of relapse due to standard chemotherapeutic regimes. In this sense, factors like the ZEB, SNAI, and TWIST gene families, known for their roles in epithelial-mesenchymal transition (EMT) and cancer metastasis, also regulate hematopoiesis and may serve as effective therapeutic targets in AML. These genes contribute to cell proliferation, differentiation, and extramedullary hematopoiesis, suggesting new possibilities for treatment. Advancing our understanding of the molecular mechanisms that promote AML, especially how the bone marrow microenvironment affects invasion and drug resistance, is crucial. This comprehensive insight into the molecular and environmental interactions in AML emphasizes the need for ongoing research and more effective treatments.

Microgranular acute promyelocytic leukemia presenting with leukopenia and an unusual immunophenotype

The microgranular variant (M3v) of acute promyelocytic leukemia (APL) is rare, and the diagnosis can be delayed due to variability in how this condition presents. M3v blasts often have folded nuclei, but unlike traditional APL blasts, they often possess faint granules without Auer rods. In addition, microgranular APL often presents with an elevated or normal white blood cell count in contrast with the leukopenia seen in traditional APL. In APL, delayed diagnosis can lead to early death from disseminated intravascular coagulation (DIC), which is the main cause of mortality in an otherwise treatable, and often curable, leukemia. We describe a 19-year-old male with microgranular APL who presented with leukopenia and many blasts resembling non-APL AML blasts with an unexpected immunophenotypic pattern. He was treated for DIC and initiated on all-trans-retinoic acid and arsenic trioxide; he achieved complete molecular remission after induction therapy. Suspicion for APL should always remain high in the presence of clinical manifestations of the disease in order that appropriate treatment can be initiated rapidly to prevent early death.

The biological characteristics of adult CD34+ acute promyelocytic leukemia

We aimed to explore the expression of CD34 and its impact on the disease outcome in patients with APL. The study comprised 40 de novo APL patients. Diagnostic tools included peripheral blood and bone marrow morphology and cytochemistry, immunophenotyping, cytogenetic studies, and PML/RARα fusion gene detection using RT-PCR. CD34 was expressed in 13 (32.5%) of cases with higher expression in M3v compared to M3 subtype. All M3v cases were CD34+, while only 7.4% of M3 cases were CD34+. CD34+ cases were associated with significant higher white blood cell count and peripheral blood promyelocytes. No significant association was found between PML/RAR-α isoform and molecular remission. CD34+ expression was significantly associated with decreased incidence of molecular remission and increased incidence of early death. The overall survival of patients with WBC count >11 × 103/μl was inferior to patients with WBC count <11 × 103/μl, but no significant differences were observed in overall survival between CD34- and CD34+ or between bcr1 and bcr3 groups. Immunophenotypic analysis for CD34 could distinguish an APL subset with different biological characteristics and adverse prognostic outcome.

Flow cytometry rapidly identifies all acute promyelocytic leukemias with high specificity independent of underlying cytogenetic abnormalities

Acute promyelocytic leukemia (APL) is a highly aggressive disease requiring prompt diagnosis and specific early intervention. Immunophenotyping by flow cytometry (FCM) facilitates a rapid diagnosis, but commonly used criteria are neither sufficiently sensitive nor specific. With an antibody panel for diagnostic screening in routine practice, we found all 149 APL cases in this study exhibited a unique immunophenotypic profile, ie, a characteristic CD11b- myeloid population and absent CD11c expression in all myeloid populations; 96.6% of cases also lacked HLA-DR expression. These distinctive features allowed recognition of all unusual cases phenotypically resembling the regular myeloblasts (CD34+/HLA-DR+) or granulocytes (CD117-/CD34-/HLA-DR-). FCM effectively identified all 19 APL cases with variant translocations, including cases with a normal karyotype due to a cryptic submicroscopic t(15;17)(q22;q21), t(11;17)(q23;q21) that escaped the detection by fluorescence in situ hybridization for t(15;17) and der(15)ider(17)(q10) that lacked a simple reciprocal t(15;17). When APL-associated profiles were validated against 107 AML cases of non-APL subtypes, including 51 HLA-DR- cases, the diagnostic specificity and positive predictive value were 98%. FCM effectively provides independent detection of APL during diagnostic workup and harmonizes with the subsequent molecular cytogenetic diagnosis.

Primary myeloid sarcoma of the testicle with t(15;17)

The first case of acute promyelocytic leukemia presenting as a solitary testicular mass (myeloid sarcoma) that relapsed in the contralateral testicle is described. The neoplastic cells strongly expressed chloroacetate esterase, myeloperoxidase, CD33, CD43, and weakly, CD117. The presence of many azurophil granules and Auer rods was detected by electron microscopy. Translocation (15;17)(q22;q21.1) was revealed by cytogenetics and was verified by fluorescence in situ hybridization. Contralateral testicle is a favorite site for recurrence in a subset of testicular myeloid sarcomas. Subclassification of all cases of myeloid sarcoma ought to be attempted.

A surrogate marker profile for PML/RAR alpha expressing acute promyelocytic leukemia and the association of immunophenotypic markers with morphologic and molecular subtypes

BACKGROUND

The availability of genotype-specific therapy for PML/RAR alpha(pos) acute promyelocytic leukemia (APL) requires that this disease be precisely diagnosed. Immunophenotypic characteristics heretofore proclaimed as reliably characterizing APL (HLA-DR(low), CD34(low), P-glycoprotein(low) myeloid phenotype) do not differentiate from APL-like immune profiles unassociated with the PML/RAR alpha fusion transcript.

METHODS

To establish a surrogate marker profile for APL, we explored 19 potentially predictive markers compared with differentiated acute myeloid leukemia using the classification tree approach with recursive partitioning.

RESULTS

In a test group of 58 APL patients, the most predictive immune profile was HLA-DR(low), CD11a(low) (alpha(L) subunit of the leukocyte integrin LFA-1), CD18(low) (beta(2) subunit of LFA-1). APL cells always expressed CD117 (c-kit) but lacked the progenitor antigen CD133 and the more mature myeloid antigen, CD11b (alpha(M) leukocyte integrin). This antigen pattern was validated in 90 additional APL patients. M3v APLs (n = 30) had more leukemic promyelocytes expressing the T-cell antigen, CD2 (P < 0.0001) or the stem cell marker, CD34 (P = 0.0003) and demonstrated higher fluorescence intensity for the binding of antibody to the common leukocyte antigen, CD45 (P = 0.0008) than M3 (n = 102). S-form APL (n = 45) had a higher percent of cells expressing CD2 or CD34 (P < 0.0001 for both) or the neural cell adhesion molecule CD56 (P = 0.001) than L-form APL (n = 66).

CONCLUSIONS

PML/RAR alpha(pos) APL cells typically lack leukocyte integrins. HLA-DR(low), CD11a(low), CD18(low) is a reliable surrogate antigen expression profile for PML/RAR alpha(pos) APL, irrespective of morphology and transcript isoform.

Microgranular and t(11;17)/PLZF-RARalpha variants of acute promyelocytic leukemia also present the flow cytometric pattern of CD13, CD34, and CD15 expression characteristic of PML-RARalpha gene rearrangement

Acute promyelocytic leukemia (APL) is a subtype acute myeloid leukemia in which leukemic promyelocytes predominate in the bone marrow (BM). Rapid diagnosis is critical for treatment decision since all-trans-retinoic acid must be administrated promptly. The microgranular variant may be of difficult diagnosis, as it may be confused with other diseases on morphological grounds. The purpose of this study was to determine if the microgranular variant has the same antigenic profile as the classical hypergranular type. The immunophenotype of leukemic cells from the bone marrow of 50 patients, with the PML-RARalpha gene rearrangement confirmed by RT-PCR, was determined by flow cytometry using a large panel of 22 monoclonal antibodies and a polyclonal anti-TdT antibody. Thirty-four cases were classified as classical APL and 16 as microgranular APL. The immunophenotypic profile of the two subtypes was indistinguishable concerning the presence or absence of these antigens, including the absence of reactivity for the HLA-DR antigen. The simultaneous immunophenotypic combination of a unique major cell population, heterogeneous intensity of expression of CD13, and the typical pattern of CD15/CD34 expression were similarly present in the hypergranular and microgranular subtypes. Homogeneous expression of CD33 was observed in 76% of the classical APL cases and in 100% of the microgranular cases. Additionally, we have studied two cases of PLZF-RARalpha APL that also displayed the same immunophenotype described for classical APL. Thus, the immunophenotypic profile highly characteristic of the PML-RARalpha gene rearrangement was also observed in microgranular and PLZF-RARalpha variants of APL.

Expression of cell-surface antigens in acute promyelocytic leukaemia

Acute promyelocytic leukaemia (APL) with M3 (or M3v) morphology is the only AML subtype to date for which morphology and immunophenotype agree. In other words, FAB M3 is interchangeable with a unique marker profile. More precisely, we have finally recognized a surrogate marker profile for leukaemia derived from the (15;17) translocation and expressing PML/RARalpha transcripts. To present this as a new development may come as a surprise to many. After all, the antigen expression pattern of AML-M3 was well recognized for many years: absence or weak expression of HLA-DR, CD117, CD15, CD11b and CD34 in the context of a myeloid phenotype (CD33 and CD13 expression) and frequently associated with moderate to high side-scatter appearance upon flow cytometric evaluation, depending upon the degree of granularity of the leukaemic cells. While partially correct, this established APL phenotype is both flawed and limited in its ability to distinguish APL from other AML subtypes, such as natural-killer-cell AML. Given the availability of phenotype-specific therapy for APL, such as all-trans retinoic acid or arsenic trioxide, failing to diagnose APL or misdiagnosing a case of AML with an APL-like phenotype will result in serious clinical consequences. Faced with this dilemma, we have recently performed a comprehensive immunophenotypic analysis of APL patients entered on Eastern Cooperative Oncology Group trials. Our results give diagnostic power to only three antigens, HLA-DR, CD11a and CD18, all of which are characteristically expressed at low levels by APL cells. Despite some significant antigenic differences (e.g. in CD34 expression), this surrogate marker profile for t(15;17) APL applies to both the M3 and the M3v FAB phenotypes and to all three isoforms of the PML/RARalpha transcript.

Acute promyelocytic leukemia: a case-based review

Retinoid therapy for acute promyelocytic leukemia (APL) is one of the major achievements of leukemia research in the last 15 years. Use of all trans retinoic acid (ATRA) has changed the prognosis of APL from a fatal leukemia to a highly curable disease. This case-based review examines the available clinical and scientific data to form evidence-based decisions in the management of APL. The main aim of this review is to highlight recent progress made in the management of APL and address the role of maintenance therapy, prognostic factors for relapse and treatment of relapsed disease.

HLA-DR antigen-negative acute myeloid leukemia

Human leukocyte antigen (HLA) Class II antigens are variably expressed on acute myeloid leukemia (AML) blasts. The biological and clinical significance of HLA Class II antigen expression by AML cells is not known. Therefore, we sought to characterize cases of AML without detectable HLA-DR expression. Samples from 248 consecutive adult AML patients were immunophenotyped by multiparameter flow cytometry at diagnosis. HLA-DR antigens were not detected on AML cells from 43 patients, including 20 with acute promyelocytic leukemia (APL), and 23 with other subtypes of AML. All APL cases had t(15;17), but there were no characteristic chromosome abnormalities in non-APL cases. No direct expression of other antigens was identified in HLA-DR-negative APL and non-APL cases. Interestingly, cells from three HLA-DR-negative non-APL patients had similar morphology to that of the hypogranular variant of APL. This morphology, however, was not present in any HLA-DR-positive AML cases. Treatment response was similar in the 23 HLA-DR-negative non-APL and the 205 HLA-DR-positive patients. Finally, relapse was infrequently associated with changes in HLA-DR antigen expression, as the HLA-DR antigen was lost at relapse in only 4% of HLA-DR-positive cases, and was gained at relapse in only 17% of HLA-DR-negative cases. We conclude that HLA-DR-negative AML includes approximately equal numbers of APL and non-APL cases, and that the morphology of HLA-DR-negative non-APL cases can mimic the hypogranular variant of APL. The diagnosis of APL cannot be based on morphology and lack of HLA-DR antigen expression; rather, it requires cytogenetic or molecular confirmation.

Antigen expression patterns reflecting genotype of acute leukemias

Multi-parameter flow cytometry, molecular genetics, and cytogenetic studies have all contributed to new classification of leukemia. In this review we discuss immunophenotypic characteristics of major genotypic leukemia categories. We describe immunophenotype of: B-lineage ALL with MLL rearrangements, TEL/AML1, BCR/ABL, E2A/PBX1 translocations, hyperdiploidy, and myc fusion genes; T-ALL with SCL gene aberrations and t(5;14) translocation; and AML with AML1/ETO, PML/RARalpha, OTT/MAL and CBFbeta/MYH11 translocations, trisomies 8 or 11 and aberrations of chromosomes 7 and 5. Whereas some genotypes associate with certain immunophenotypic features, others can present with variable immunophenotype. Single molecules (as NG2, CBFbeta/SMMHC and PML/RARalpha proteins) associated with or derived from specific translocations have been described. More often, complex immunophenotype patterns have been related to the genotype categories. Most known associations between immunophenotype and genotype have been defined empirically. Therefore, these associations should be validated in independent patient cohorts before they can be widely used for prescreening of leukemia. Progress in our knowledge on leukemia will show how the molecular-genetic changes modulate the immunophenotype as well as how the expressed protein molecules further modulate cell behavior.

Leukemias resembling acute promyelocytic leukemia, microgranular variant

Acute promyelocytic leukemia (APL) should be distinguished from other subtypes of acute myeloid leukemia (AML) because of the increased risk of disseminated intravascular coagulation (DIC) and its response to arsenic compounds and retinoids. Some cases of AML seem morphologically similar to the microgranular variant of APL (French-American-British [FAB] AML-M3v) but lack the t(15;17). We evaluated 8 cases of APL-like leukemias for subtle morphologic, cytochemical, immunophenotypic, and cytogenetic differences compared with 5 cases of promyelocytic leukemia/retinoic receptor alpha (PML/RARalpha)-positive APL (FAB AML-M3v). We also evaluated both groups for the presence of DIC. No differences among the groups were noted in blast size, chromatin pattern, nuclear morphologic features, intensity of myeloperoxidase staining, or presence of Auer rods. Immunophenotypes were similar; both types of cases lacked CD34 and HLA-DR and were CD13+ and CD33+. Two cases of APL-like leukemias also were CD56+. DIC was present in 2 patients with M3v. Our study shows that there are no definitive morphologic, cytochemical, or immunophenotypic findings that can distinguish these cases from PML/RARalpha-positive APL.

Advances in the understanding and management of acute promyelocytic leukemia

Considerable progress has been made over the past decade in the understanding and management of acute promyelocytic leukemia (APL). At the laboratory level, molecular mechanisms underlying the arrest of differentiation that typically features in this malignancy, have been clarified and currently provide important models for addressing future investigation aimed at releasing the maturation block in other malignancies. In the clinic, advances in the management of APL have converted this rapidly fatal disease into the most frequently curable leukemia in adults. Use of retinoids in combinatorial protocols with anthracycline-based chemotherapy for front line treatment currently results in long-term survival and potential cure in at least 60% of newly diagnosed patients. Even after relapse, the disease is still curable in a high percentage of cases by various approaches including combinations of chemotherapy, retinoids, arsenic trioxide, stem cell transplantation and antibody-targeted chemotherapy. Genetic testing for identification of the disease-specific gene rearrangement and monitoring of residual disease have proved critical in establishing correct diagnosis and better evaluate the response to therapy at the molecular level. Current 'hot' issues for clinical investigation include: (i) better understanding and management of the severe coagulopathy present at diagnosis in most patients; (ii) the definition of risk categories to improve identification of patients at highest risk of relapse and (iii) the translation of successful differentiation therapy to other leukemia subsets.

CD34-positive acute promyelocytic leukemia is associated with leukocytosis, microgranular/hypogranular morphology, expression of CD2 and bcr3 isoform

Acute promyelocytic leukemia (APL) has a favorable prognosis. Current therapy includes chemotherapy used in combination with all-trans-retinoic acid (ATRA). Although the differentiating effects of ATRA on promyelocytes have been well established, in vitro studies have shown that less-differentiated APL blasts (CD34(+)) demonstrate a variable responsiveness to ATRA. To assess the clinical relevance of this finding, we analyzed a cohort of 38 patients with t(15;17) and/or PML-RARalpha APL to determine the incidence and laboratory features of CD34(+) APL. Thirty-two percent (12/38) of cases were CD34(+). There was a difference in WBC at presentation between CD34(+) and CD34(-) cases (34.6 +/- 9.2, mean +/- standard error vs. 5.4 +/- 2.0, P = 0.009). Patients with CD34(+) APL demonstrated a micro/hypogranular phenotype (75%) (P = 0.001), co-expression of CD2(+) (83%) (P = 0.001), and the bcr3 isoform (100%) (P = 0.017). In contrast, CD34(-) cases demonstrated hypergranular morphology (65%), CD2(+) (15%), and the bcr1 isoform (50%). A high presenting WBC count (\G10 x 10(9)/L) was associated with an inferior overall survival (Log rank = 0.0047). Patients with CD34(+) APL demonstrated an incidence of early mortality of 50%. Despite a marked correlation between CD34 positivity and increased WBC count, overall survival of CD34(+) and CD34(-) cases did not differ significantly in our small cohort. Immunophenotypic analysis for CD34 expression should be included in future large APL trials to determine if detection of CD34(+) blasts represents an independent adverse prognostic factor.

Trilineage phenotypic compromise in acute leukemia

The expression of three lineage specific antigens in the leukemic blasts is extremely infrequent. We here report a case of triphenotypic acute leukemia with involvement of the myeloid and B and T lineages. The morphology of the blasts showed promyelocytic features with agranular cytoplasm, suggesting a M3-variant of AML. The blasts were positive for myeloperoxidase PAS and Sudan Black. Immunophenotype and cytogenetics did not confirm M3-AML diagnosis, showing a trilineage compromise (myeloid and T and B lymphoid markers) and the cytogenetic alterations +8 and +11, respectively. This report highlights the importance of correlating the results of multiple diagnostic methods in order to establish a correct diagnosis of mixed lineage acute leukemias, and allows evaluation of the prognostic importance of this subgroup of patients.

Ultrastructural characteristics and lysozyme content in hypergranular and variant type of acute promyelocytic leukaemia

We investigated the electronmicroscopic (EM) features and cellular lysozyme (LZ) content in 16 cases of acute promyelocytic leukaemia (APL): 11 cases of the hypergranular form (M3) and five cases of the microgranular variant (M3-V). The main EM features in all cases were: irregular, folded or bilobed nuclei, many cytoplasmic granules, distended rough endoplasmic reticulum (RER) cisternae which, in some cases, presented as stellate forms (more frequent in M3-V), and bundles of cytoplasmic microfilaments. Many Auer rods were present in M3 cases and few in M3-V; most of these disclosed parallel tubular arrays (PTA) with a varied periodicity ranging from 13 to 26 nm. There was a significant difference between M3 and M3-V (P<0.0001) in both the number of granules per cell section (62.9 +/- 34.5 v 38.0 +/- 23.6) and in the granule section area (0.044 +/- 0.033 v 0.026 +/- 0.015 microm2). In some cases, mainly in M3-V, we found cells with large granules containing PTA which probably represent poorly developed Auer rods. Intracellular LZ content assayed by a post-embedding immunogold method, showed high granular LZ density (in the range of that found in M4 and M5) in M3 cells and very low granular LZ content in M3-V. This study adds new objective parameters for the diagnosis of these two types of APL and provides new information on their LZ pattern of expression.

Immunophenotype of adult and childhood acute promyelocytic leukaemia: correlation with morphology, type of PML gene breakpoint and clinical outcome. A cooperative Italian study on 196 cases

Acute promyelocytic leukaemia (APL), characterized by a specific PML-RARalpha fusion gene resulting from translocation t(15;17) and by a high response rate to differentiation therapy with all-trans retinoic acid, presents clinical (varying WBC counts, age and treatment outcome), morphological (hypergranular M3 and hypogranular M3V) and molecular (three isoforms of PML breakpoint) heterogeneity. We correlated leukaemic immunophenotype with these aspects in 196 molecularly confirmed APLs (63 children and 133 adults) in Italy. The bcr3 isoform (P = 0.05) and FAB M3V (P = 0.05) were more frequent in children. We confirmed in APL an immunophenotype characterized by frequent expression of CD13, CD33 and CD9 and rare expression of HLA-DR, CD10, CD7 and CD11b. However, we recognized CD2 in 28%, CD34 in 23% and CD19 in 11% of cases and demonstrated by double labelling that CD34 and CD2 may be co-expressed. CD2, CD34 and CD19 were significantly intercorrelated, and variably associated to other features: CD2 and CD34 with PML bcr3 (P < 0.001 and P < 0.001, respectively) and with M3V (P < 0.001 and P = 0.002), whereas only CD19 was directly correlated with WBC counts and only CD2 positively influenced CR rate (logistic model) and event-free survival (Cox model). We conclude that immunophenotype plays a role in the determination of the biological and clinical heterogeneity of childhood and adult APL.

Morphology of acute promyelocytic leukemia with cytogenetic or molecular evidence for the diagnosis: characterization of additional microgranular variants

Early diagnosis of t(15;17) acute promyelocytic leukemia (APL) is essential because of the associated disseminated intravascular coagulation and the unique response of the disease to all-trans retinoic acid (ATRA) therapy. Early diagnosis depends primarily on morphological recognition. The French-American-British (FAB) classification, however, does not describe all morphological variations that occur in APL. In 25 cases with evidence of APL confirmed by cytogenetic and/or molecular analysis, we found a heterogeneous morphological group. The most common form of APL was heterogeneous and consisted of various combinations of cells in which hypergranular cells and some cells with multiple Auer rods were obvious. In some cases, one cell predominated. This led to the description of five subcategories. These included the classical FAB M3 with hypergranular cells and multiple Auer rods; the FAB variant with hypogranular bilobed cells; the basophilic cell type of McKenna et al. [Br. J. Haematol 50:201, 1982]; and two additional subtypes, one consisting of differentiated promyelocytes and a few blast cells (M2-like), and the other consisting largely of blast cells and a few early promyelocytes (M1-like). Immunophenotyping revealed a pattern of CD33 and/or CD13 positivity, and CD14 and HLA-DR negativity in 96% of cases. CD2 was positive in the FAB variant and in the subtype with basophilic cells, but negative with other subtypes. Three out of five cases with basophilic cell predominance [McKenna et al.: Br J Haematol 50:201, 1982], and one out of two M2-like cases, responded to ATRA therapy. Awareness of the heterogeneity and the atypical morphologic subtypes found in t(15;17) APL will contribute to improved recognition and early institution of ATRA therapy.

Variant and masked translocations in acute promyelocytic leukemia

Acute promyelocytic leukemia (APL) is characterized by a unique hemorrhagic syndrome, disseminated intravascular coagulation, and the association with the specific (15;17 chi q22-23:q12-21) translocation, which disrupts the retinoic acid receptor alpha (RARA) and the promyelocytic leukemia (PML) genes. The t(15;17) leads to the formation of two reciprocal fusion genes, PML/RARA on chromosome 15 and RARA/PML on chromosome 17; it is responsible for the unique response of the disease to retinoic acid (ATRA) treatment. As was described for chronic myeloid leukemia and its associated t(9;22) [Philadelphia chromosome], variant translocations have been reported in APL, which are either complex translocations involving additional chromosome(s), or simple variant translocations involving only either one chromosome 15 or 17 and any of several chromosomes. Rearrangements of RARA and PML were documented in some of these variant translocations. In contrast, recent molecular analysis of APL cases with cytogenetically normal chromosomes 15 and 17 revealed the occurrence of submicroscopic translocations, leading to the formation of non reciprocal fusion genes, either PML/RARA or RARA/PML only. Detailed analysis of such cases may shed light on the mechanisms of translocation, on the selection of oncogenic products, and on the respective role(s) of the products of the translocation. Demonstration of the existence, in some APL-like leukemias, of masked translocations with involvement of PML and RARA, thus allows to (i) confirm the diagnosis of APL, (ii) adapt the treatment and (iii) monitor the residual disease. Finally APL-like leukemias were recently reported, with either a t(11;17) or t(5;17), resulting in the fusion of RARA to genes other than PML; these patients do not appear to respond to ATRA treatment. Altogether, these results emphasize the usefulness of a molecular definition of APL.

Combined cytogenetic, FISH and molecular analysis in acute promyelocytic leukaemia at diagnosis and in complete remission

This study reports the results of a simultaneous application of cytogenetic fluorescence in situ hybridization (FISH) and molecular analysis (RT-PCR) in 28 APL cases (23 M3 and five M3v; 26 studied at diagnosis and two at relapse). FISH on metaphases identified the t(15;17) in all cases who were positive for the PML/RAR alpha transcript by RT-PCR. Conventional cytogenetics revealed the t(15;17) in only 68% of cases. However, it enabled the detection of additional chromosome changes in five cases, three of whom were M3v. 11 patients were also investigated during complete remission (CR) by both FISH and RT-PCR, in order to evaluate residual disease; the duration of CR at the time of analysis ranged between 1 and 16 months, with three patients being studied twice. Comparison of RT-PCR and FISH results showed a very good correlation. In fact, of the 10 samples which were RT-PCR positive for residual disease, all were also recognized by interphase FISH, and eight were positive by metaphase FISH. Of the three samples negative at RT-PCR, all were also negative at the interphase FISH. The results of this study indicate that: (a) the t(15;17) is present in all cases positive for the PML/RAR alpha rearrangement, thus in virtually all true APLs; (b) standard cytogenetics, capable of unravelling the t(15;17) in only 68% of cases, enables recognition of additional chromosome changes of potential clinical and prognostic significance; (c) FISH on interphase nuclei is a reliable tool for the monitoring of residual disease, with a sensitivity greater than that of FISH on metaphase cells and superimposable to that of RT-PCR.

Unique immunophenotype of acute promyelocytic leukaemia as defined by CD9 and CD68 antibodies

Twenty-one cases of acute promyelocytic leukaemia (FAB M3) demonstrating t(15,17) chromosomal translocation were studied in detail by immunocytochemical techniques using a panel of monoclonal antibodies. A characteristic myeloid phenotype of the leukaemic cells, co-expression of CD9 and CD68 antigens and absence of HLA-DR, was noted in all cases. Although the cellular morphology of acute promyelocytic leukaemia provides the most rapid means for diagnosis, this unique leukaemic cell phenotype provides confirmatory diagnostic evidence. In view of the new therapeutic options and prognosis in acute promyelocytic leukaemia, the detection of cases with atypical morphology based on this unique phenotype would be of value. In addition, the phenotype of acute promyelocytic leukaemia is similar to that of basophils and mast cells and raises the possibility that the leukaemic cells may have undergone a degree of basophilic differentiation.

Possibilities and limitations of cytochemical methods in diagnosis of acute leukemia

Accurate identification and classification of leukemic blast cells is a very important prerequisite of the precise diagnosis of acute leukemia and has a great impact on therapy and prognosis. The purpose of this review is to consider, in the broad sense of the word, the present possibilities and limitations of enzyme cytochemistry and to emphasize how cytochemistry may contribute, on integration with the other methods of study, to the final classification and differential diagnosis of acute leukemia, a highly variable hematological disorder. In this review, the role of conventional enzyme cytochemistry, either dominant or subsidiary, in the discrimination of acute leukemia subtypes is discussed. The survey confirms the absolute necessity of immunologic marker analysis in the accurate diagnosis of acute lymphoblastic leukemia, undifferentiated or minimally differentiated leukemia and mixed-lineage leukemia because in these cases, the cytochemical evaluation provides insufficiently relevant information regarding blast cell origin, specificity of leukemia subtypes and the discrete stages of leukemic cell maturation. On the other hand, cytochemical investigation is appreciated to be dominant over immunophenotyping in characterizing acute myeloid leukemia, because of the lack of specificity of the majority of immunological markers against myeloid antigens and, because of the availability of standardized and sufficiently specific cytochemical reactions. The cytogenetic, molecular biological and electron microscopic studies mentioned in this review supplement the important information for correct differential diagnosis of acute leukemia. The prognostic impact of enzyme cytochemistry in correlation to other methods is evaluated.

Prognostic impact of karyotype and immunologic phenotype in 125 adult patients with de novo AML

One hundred-twenty-five adult patients with de novo acute myeloid leukemia (AML) were treated according to a standard 7 + 3 induction regimen. Karyotype and immunological phenotype of blasts examined prior to treatment were correlated with each other, with response to treatment and duration of survival. The following monoclonal antibodies (mAbs) were used for immunological phenotyping: VIM-D5 (CD15), MY7 (CD13), MY9 (CD33), VIM-2 (CDw65), VIM-13 (CD14), 63D3 (CD14), VID-1 (anti HLA-DR), WT1 (CD7), CLB-Ery3 (antiblood group H antigen), C17-27 (CD61), and an antiserum against TdT. Despite a considerable overlap between the individual groups, patients with specific aberrations as defined by the MIC classification (n = 39) showed distinct, characteristic, myeloid or myelomonocytic immunophenotypes. In M2/t(8;21) there was a significant association with negativity to CD13, in M3/t(15;17) with negativity to CD15 and HLA-DR, whereas in M4/inv(16) expression of blood group H antigen was unexpectedly found. The response to therapy, as well as rate of complete remission as duration of survival, was better in patients with M2/t(8;21), M3/t(15;17), and M4Eo/inv(16) as compared to all other patients and significantly worse in patients with M5a/t/del(11)(q23). In 35 patients with normal karyotype and 16 patients with cytogenetic anomalies not presently associated with FAB subtypes the expected correlations of rather immature myeloid immunologic phenotypes with M1 and M2 morphology and CD14 expression in monoblastic leukemias was found. Remission rate and survival were significantly worse in 19 patients with complex nonrandom aberrations, where blast cell expression of blood group H antigen and of TdT were significantly increased.

PML/RAR-alpha rearrangement in acute promyelocytic leukaemias apparently lacking the t(15;17) translocation

Recent investigations have clarified some of the molecular mechanisms underlying the t(15;17) translocation specific for acute promyelocytic leukaemia (APL). Together with providing new insights into the pathogenesis of the disease, the identification of breakpoints within the RAR-alpha and PML loci on chromosomes 17 and 15 has allowed a new relevant diagnostic tool for the recognition of this leukaemic form. We report the molecular characterization of 6 cases of acute myelogenous leukaemia (AML) in which a diagnosis of typical M3 by conventional morphocytochemistry (FAB criteria) was not accompanied by cytogenetic evidence of the specific t(15;17) aberration. DNA rearrangements were documented in all cases at the PML and RAR-alpha loci. Moreover, in 4 cases also analysed by Northern blot hybridization, we could detect aberrant RAR-alpha transcripts. These findings highlight the specificity of PML/RAR-alpha rearrangements in APL, whereas the lack of t(15;17) may be attributed to sub-microscopic translocations as well as to the presence of non-neoplastic cells undergoing mitosis in the samples examined for karyotype.

Rearrangements of the RAR-alpha gene in acute promyelocytic leukaemia: correlations with morphology and immunophenotype

We have used genomic probes which specifically recognize DNA rearrangements of the RAR-alpha locus on chromosome 17q21 in patients with acute promyelocytic leukaemia (APL) and acute myeloid leukaemia (AML) subtypes. Molecular data were examined in comparison with morphological and immunophenotypic characterization at diagnosis in 20 hypergranular FAB M3 cases, five microgranular APL (M3v), 51 non-M3 AML and 12 myeloid CML blast crises. Rearrangements of the RAR-alpha locus were only detected in 23/25 APL cases and in none of the other FAB subtypes analysed. Surface marker characterization showed a consistent immunophenotypic profile--HLADR negative, CD9 and CD13/33 positive--in all M3 and M3v cases. Neither HLADR negativity nor CD9 positivity were associated with RAR-alpha rearrangements in non M3 AML. Our data indicate that RAR-alpha gene rearrangements are relevant diagnostic features of both M3 and M3v, and may prove useful molecular marker for follow-up analysis in APL patients.

Epidemiology of acute promyelocytic leukemia in Italy. APL Collaborating Group

This retrospective epidemiologic study on 256 cases of Acute Promyelocytic Leukemia (APL) observed in 20 Italian hematology centers between 1980 and 1988 demonstrated that APL is different from the other acute non-lymphocytic leukemias (ANLL). The male/female ratio was 0.9; median age at diagnosis was 40 years (with 80% of patients between 15 and 54 years of age). The minimal annual incidence of APL in Italy per 1,000,000 inhabitants was estimated to be 0.6; an increased incidence was observed in spring and in autumn. The overall median survival duration of APL patients was 12.6 months. From an epidemiological point of view APL is a distinctive subtype of ANLL.