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Myelomastocytic leukemia versus mast cell leukemia versus systemic mastocytosis associated with acute myeloid leukemia: A diagnostic challenge

2010; Wiley; Volume: 85; Issue: 8 Linguagem: Inglês

10.1002/ajh.21713

1096-8652

Angela R. Arredondo, Jason Gotlib, Luke Shier, Bruno C. Medeiros, Kathleen Wong, Athena M. Cherry, Christopher L. Corless, Daniel A. Arber, Peter Valent, Tracy I. George,

Drug-Induced Adverse Reactions

A 35-year-old woman presented in September 2006 with progressive urticaria, which was refractory to increasing doses of antihistamines and prednisone. Features of urticaria pigmentosa were not present. She presented 11 months later with fatigue and petechiae. An initial bone marrow (BM) biopsy was hypercellular with left-shifted myelopoiesis, mild reticulin fibrosis, and diffuse infiltration by mast cells (MCs). No compact dense MC infiltrates were detected on BM biopsy. Mastocytosis is currently defined as a clonal, neoplastic proliferation, and accumulation of MCs in one or multiple organs [1]. Clinical symptoms are caused by the release of chemical mediators and by infiltration of tissues by neoplastic MCs. In cutaneous mastocytosis, MC infiltration is limited to the skin and typically presents in childhood with urticarial symptoms. It has a benign clinical course and may regress spontaneously [2]. In adults, cutaneous disease is more frequently associated with indolent rather than aggressive forms of systemic mastocytosis (SM). Although a diagnosis of SM was considered, the lack of compact dense aggregates was considered atypical, and full criteria for SM were not met. In the 2008 WHO classification, SM is diagnosed when one major criterion and one minor criterion, or at least three minor criteria are present (Table I). The major diagnostic criterion for SM is fulfilled by the presence of multifocal dense MC infiltrates (≥15 MCs per aggregate) detected histologically in the BM or in another extracutaneous organ(s). Minor criteria include: (1) ≥25% of the MCs in the infiltrate are spindle-shaped or show atypical morphology or, ≥25% are immature or atypical on BM aspirate smears; (2) a serum tryptase level persistently greater than 20 ng/mL (this parameter is not valid if there is an associated clonal myeloid disorder); (3) detection of the characteristic D816V KIT mutation in BM, blood, or another extracutaneous organ; and (4) expression of CD2, CD25, or both in neoplastic MCs [1-3]. Indolent forms of systemic MC disease may be characterized by one or more "B" findings (Table II). If two or more B findings are present the disease is called smouldering SM. Treatment of mediator-related symptoms, when present, is commonly employed in all SM variants, whereas cytoreductive agents are not prescribed. In contrast, aggressive systemic mastocytosis (ASM) and mast cell leukemia (MCL) are characterized by one or more "C" findings (Table II), which often require cytoreductive therapy. SM may also be associated with a clonal hematologic disease that is not of mast cell origin (SM-AHNMD), such as myelodysplastic syndromes (MDS), myeloproliferative neoplasms (MPN), acute leukemia, lymphoma, or plasma cell myeloma. In SM-AHNMD, full WHO diagnostic criteria for both SM and the AHNMD are met [4]. A BM aspirate smear showed intermediate size blasts with open chromatin, single prominent nucleoli, and agranular basophilic cytoplasm and metachromatic blasts with large deeply basophilic granules (Fig. 1). An abdominal ultrasound showed no organomegaly. Top row: Case 1, myelomastocytic leukemia; (A) BM aspirate demonstrates a metachromatic blast with abundant metachromatic granules, immature nuclear chromatin, and high N:C ratio (top left), a myeloblast with high N:C ratio, fine nuclear chromatin, and scant basophilic cytoplasm (top right), a dysplastic erythroid precursor with an enlarged nucleus, irregular nuclear contours, and pale basophilic cytoplasm (bottom left), and another metachromatic blast with an enlarged nucleus, fine nuclear chromatin, scent basophilic cytoplasm, and azurophilic granules (bottom right). (B) ×100 view of BM biopsy demonstrating no focal lesions (C) ×400 H&E BM biopsy demonstrating immature mononuclear cells with some cells showing granulocytic differentiation. (D) ×400 BM biopsy with IHC staining for tryptase highlighting the interstitial pattern of MC infiltration, an immunohistochemical stain for CD34 was negative (inset); (E) ×400 BM biopsy with IHC staining for CD25 showing cytoplasmic staining in scattered interstitial MC and no staining in adjacent blasts. Middle row: Case 2, myelomastocytic transformation in AML; (F) diagnostic BM aspirate showing numerous enlarged myeloblasts with high N:C ratio, fine nuclear chromatin, and scant basophilic cytoplasm along with scattered atypical MC (inset). (G) ×100 H&E diagnostic BM biopsy showing hypercellularity, FISH analysis demonstrated interphase nuclei with 1 red, 1 green, and 2 fusion signals, consistent with the t(8:21)(q22;q22) translocation fusion product (inset). (H) ×400 postinduction BM aspirate showing numerous MC with enlarged bilobed nuclei and abundant cytoplasmic granules without increased blasts. (I) ×200 H&E postinduction BM biopsy showing a marked decrease in cellularity from the previous biopsy. (J) ×200 postinduction BM biopsy with IHC staining for mast cell tryptase which highlights the interstitial pattern of MC infiltration, an immunohistochemical stain for CD25 showed absent expression in mast cells and blasts (inset). Bottom row: Case 3, MCL; (K) ×100 BM aspirate showing metachromatic blast with enlarged nucleus, fine nuclear chromatin, basophilic cytoplasm, and scattered metachromatic granules (top) and multinucleated MC with small round nuclei, fine nuclear chromatin, and abundant cytoplasmic granules (bottom). (L) ×100 H&E BM biopsy showing hypercellularity and scattered giant cells, ×100 BM biopsy with IHC staining for mast cell tryptase, which highlights the diffuse pattern of MC infiltration (inset). (M) ×400 H&E BM biopsy showing numerous immature mononuclear cells and occasional multinucleated cells. (N) ×400 BM biopsy with IHC staining for CD117 showing strong membranous and cytoplasmic staining. (O) ×200 BM biopsy with IHC staining for CD25 showing lack of expression in MC. BM, bone marrow; N:C, nuclear to cytoplasmic; H&E, hematoxylin and eosin; IHC, immunohistochemical; MC, mast cell(s); FISH, fluorescence in situ hybridization; MCL, mast cell leukemia. Reactive tissue MC are small with round centrally located nuclei, indistinct to absent nucleoli, abundant cytoplasm, and faint cytoplasmic granules on H&E stained tissue sections; in Romanowsky stained smears, MCs contain tightly packed uniform metachromatic granules with round to oval shaped nuclei (Table III). Neoplastic MC morphology has been classified into three subtypes: (1) Metachromatic blasts with high nuclear to cytoplasmic ratio, fine nuclear chromatin, prominent nucleoli, and several metachromatic granules; (2) atypical MC type I with elongated cytoplasmic projections, oval eccentric nuclei, and hypogranulated cytoplasm; and (3) atypical MC type II with bi- or polylobed nuclei (Table III) [4, 5]. Recognition of neoplastic MC morphology has been shown to correlate with clinical outcome [4]. Atypical MC type I are more commonly seen in SM with a clinically indolent course whereas atypical MC type II and metachromatic blasts are more common in patients with MML and MCL, which are associated with a poor prognosis and short survival [1, 4, 5]. In light of the similarities in morphology between MCs and basophils, the differential diagnosis of MML also includes basophilic leukemia (BAL), a very rare neoplasm accounting for <1% of all AML cases [1]. Neoplastic cells are medium-sized blasts with round or oval bilobed nuclei, basophilic cytoplasm, and a variable number of metachromatic granules, and are morphologically indistinguishable from metachromatic blasts seen in MML [1]. Blasts typically express myeloid markers including CD13 and CD33 and are usually negative for CD117 and chymase, and express only low amounts of tryptase, which differentiates them from cells of the MC lineage [1]. Definitive diagnosis of BAL is now more easily undertaken with the introduction of basophil-specific immunohistochemical antibodies 2D7 and BB1 [6]. Two months later, she was admitted to the hospital for febrile neutropenia. A serum tryptase level was 156 ng/mL (reference range <12 ng/mL). A complete blood count (CBC) showed neutropenia with an absolute neutrophil count of 0.4 × 109/L and thrombocytopenia with a platelet count of 42 × 109/L. A peripheral blood smear contained 10% blasts and 5%) as well as >10% metachromatic blasts in the peripheral blood and/or BM but without focal dense MC infiltrates, without MC expression of CD2 or CD25, and without evidence of the D816V KIT mutation by PCR [2, 3, 8, 9]. Similar to patients with MDS or AML without MML, dysplastic features are seen in one or more myeloid cell lineages [3]. Mature MCs and basophils may also be observed. In Case 1, the finding of numerous metachromatic blasts together with the diffuse infiltration pattern suggested either MML or MCL, as metachromatic blasts are rarely observed in SM or SM-AHNMD (Table III). Although CD25 expression was detected on MCs and MCs were atypical (2 minor criteria), the patient lacked the following findings: (1) focal dense MC aggregates; (2) an activating codon 816 KIT mutation; and (3) serum tryptase level was excluded from consideration given that a clonal myeloid cell population was present. Therefore, full criteria for SM were not met which also excluded MCL from the differential diagnosis. Metachromatic blasts were clearly MCs, not basophils, as these cells expressed high levels of KIT and tryptase. Histopathologic features included: (1) 5% metachromatic blasts in BM smears; (2) greater than 5% blasts in peripheral blood/BM smears; and (3) an interstitial MC infiltrate on biopsy. Immunophenotyping confirmed both myeloblast and MC populations, of which the latter appeared to be greater than 30% on the BM biopsy; this discrepancy with the percentage of metachromatic blasts in the BM smears appears due to the lack of particles present on the smears. Thus, Case 1 had findings diagnostic of MML with the unusual finding of CD25 expression and a normal karyotype, findings not described previously in MML. Our review of the literature identified seven cases of MML [9-12]. Three of these cases were published in 1994, before the term "myelomastocytic leukemia" was adopted, but the reported clinical and histopathologic features were highly suggestive of MML. Two patients had MDS/RAEB and one patient had blast crisis of chronic myeloid leukemia. All patients had increased blasts and metachromatic cells, complex karyotypes, a poor prognosis and did not meet criteria for SM [12]. The remaining four cases were described between 1999 and 2006 [9-11]. All cases described the presence of metachromatic blasts. Two cases exhibited elevated blasts, diffuse MC infiltrates, and the absence of the D816V KIT mutation [9, 10]. One patient had a diagnosis of MDS/RAEB with complex karyotype [10]. The other patient had AML with t(8;21) variant and was shown to have AML1/ETO fusion genes in both myeloblasts and MC [9]. The remaining two cases were reported to have findings of MML and did not meet criteria for SM; however, specific data was not provided by the authors [11]. Her clinical status rapidly deteriorated and she expired shortly thereafter, ∼2 years after initial presentation. The diagnosis of MML was made posthumously. Advanced MC neoplasms are notoriously difficult to manage and no curative treatments are currently available. Treatment for advanced SM may include standard therapy for mediator symptoms [4] along with cytoreductive therapy including interferon-α with or without corticosteroids, and cladribine in those who have slowly progressing ASM [6]. However, major and partial responses are observed in only a subset of patients [4, 6]. The initial three cases of MML described had complex karyotypes and poor prognosis [12]. In the more recent literature, one patient with MML went into complete remission with polychemotherapy [10], and another patient went into complete remission following myeloablative stem cell transplantation [9]. A 64-year-old man with a medical history of diabetes mellitus, coronary artery disease, and hypertension presented to an outside hospital with fever, fatigue, and left flank pain in late August 2007. A BM biopsy showed a normocellular marrow with increased myeloblasts. He was initially diagnosed with myelodysplastic syndrome and was transfused four units of packed red blood cells. He was subsequently evaluated at Stanford Hospital where a CBC revealed a white blood cell (WBC) count of 32.5 × 109/L, hemoglobin 8.6 g/dL, and platelet count 12 × 109/L. The peripheral blood smear showed 80% blasts, and no circulating MCs (Table IV). Blasts were intermediate to large in size with slightly irregular nuclear membranes, sparse cytoplasmic granulation, occasional large cytoplasmic salmon granules, and smooth chromatin. A BM biopsy exhibited hypercellularity and 78% blasts were enumerated on aspirate smears (Fig. 1, Table IV). Blasts expressed myeloid markers (CD15, dim CD33, CD34, CD38, CD117, and MPO) as well as HLA-DR and CD19. A diagnosis of AML was rendered. Cytogenetic analysis showed t(8;21)(q22;q22), representing the RUNX1-RUNX1T1 rearrangement. Induction chemotherapy was initiated with cytarabine, daunorubicin, and p-glycoprotein inhibitor zosuquidar on a clinical trial basis. A postinduction BM unmasked a previously unrecognized interstitial (diffuse) MC infiltrate (20% MCs) and <5% blasts (Table IV). MCs were round with bilobed nuclei and fine granules (Fig. 1). MCs expressed CD117 and tryptase, and lacked expression of CD25 and CD2 (Fig. 1). PCR revealed the N822K KIT mutation [7], previously reported to be imatinib-sensitive [13]. A serum tryptase level was elevated at 55 ng/mL (reference range <11.5 ng/mL). Complete remission of AML was achieved with induction chemotherapy. At this time, <1% blasts and 5% MCs were enumerated on the aspirate, and the RUNX1-RUNX1T1 rearrangement was detected by FISH in cells with bilobed nuclei (data not shown). He received three cycles of high-dose cytarabine consolidation chemotherapy with concurrent imatinib. Surveillance BM biopsies at 1 and 7 months postinduction were free of leukemia and contained 95% MCs. She was started on imatinib and prednisone for 2 weeks without clinical or laboratory improvement. She was subsequently initiated on a phase 2 clinical trial of the KIT tyrosine kinase inhibitor midostaurin. At that time, a serum tryptase level was elevated at 467 ng/mL. A peripheral blood smear after a 1-month cycle of midostaurin showed >10% circulating MCs and a BM specimen showed a hypercellular marrow with diffusely infiltrating MCs (90%) with a stable expression pattern from previous biopsies. A repeat serum tryptase level was markedly increased at 1913 ng/mL. She was deemed to have progressive disease, was discontinued from the trial, and expired 5 months after initial presentation. MCL is a rare subtype of SM characterized by leukemic spread of MC and an aggressive rapidly progressing clinical course [24]. MCL, by definition, meets criteria for SM with additional features including (1) leukemic infiltration of the BM and other extracutaneous organs by neoplastic MCs, (2) at least 20% MCs in BM and/or blood smears, and (3) high-grade cytologic findings [1, 18]. Case 3 met criteria for SM given that diffuse and multifocal dense MC infiltrates were present, >25% of all MC were immature/atypical and serum tryptase was persistently elevated, and no associated clonal myeloid disorder was found. "C" findings are commonly associated with MCL and in this case included BM dysfunction characterized by persistent pancytopenia and transfusion dependence, as well as hypoalbuminemia. MCL is the only advanced mastocytic disorder for which a cytologic diagnosis on an aspirate smear preparation is required to make the diagnosis [25]. A review of the literature by Noack et al. in 2004 identified <50 cases of MCL, which were reduced to 17 cases when strict WHO criteria were applied [24]. The clinical presentation and median overall survival in these cases was similar to that of our patient. Our review of the literature identified a more recent report of 10 cases of MCL, which met WHO criteria for MCL [25]. Three patients had typical MCL and seven patients had the aleukemic variant, as defined by 50% of all cases, the KIT mutation D816V is detectable. Therefore, even in the absence of multifocal dense infiltrates, most cases of MCL would likely meet three of the minor criteria as is required for the WHO diagnosis of SM. Although the aggressive nature of MCL commands early consideration of polychemotherapy and/or BM transplantation, the experience with these therapeutic modalities is limited in scope and has generally not been successful. Novel tyrosine kinase inhibitors, including midostaurin and dasatinib, have exhibited partial remitting activity in patients with advanced SM characterized by improvement in one or more C findings [26-28]. Advanced MC neoplasms are a group of heterogeneous disorders that often share a similar clinical presentation, which does not allow them to be distinguished on the basis of clinical findings alone. Therefore, histopathology and molecular genetic studies play a key role in the diagnosis of these neoplasms (Table V) and can provide useful information about the disease prognosis and potential treatment options. The diagnosis of any MC neoplasm requires a high degree of clinical suspicion and collaboration with a pathologist with specific expertise in evaluating the histopathology of these rare tumors. The current diagnostic criteria are helpful in assisting with the diagnosis of these myeloproliferative neoplasms. However, as with our experience, some challenging cases and more recently described variants such as MML do not fit into the current WHO classification scheme. The authors thank Professor H.-P. Horny for his advice on these cases. Dr. George proposed the idea for this manuscript. Drs. Arredondo, Gotlib, and George wrote the manuscript and all authors reviewed the manuscript. Drs. Arredondo, Gotlib, Shier, Wong, Arber, Valent, and George reviewed pathology. Drs. Gotlib, Shier, Medeiros, and Valent contributed clinical and treatment information. Dr. Cherry performed cytogenetic and FISH studies. Dr. Corless performed molecular genetic studies.