Cooperation of MLL/AF10(OM-LZ) with PTPN11 activating mutation induced monocytic leukemia with a shorter latency in a mouse bone marrow transplantation model.

PTPN11 mutation, a RAS signaling pathway mutation, is associated with MLL translocations in acute leukemia. A girl with MLL/AF10 AML was found to carry PTPN11G503A . To study the impact of PTPN11G503A cooperating with MLL/AF10 on leukemogenesis, we established a retroviral transduction/transplantation mouse model. Compared to the MLL/AF10(OM-LZ) leukemia cells harboring PTPN11wt , the cells harboring PTPN11G503A were hypersensitive to GM-CSF and IL3, and more resistant to death upon treatment with daunorubicin but sensitive to cytarabine. The cells harboring PTPN11G503A autonomously differentiated into macrophages (1.8%) in the medium containing IL3. Further studies showed that the cells had an elevated (∼2.9-fold) Csf1 transcription level and secreted more (∼4.5-fold) M-CSF to the medium which can stimulate monocyte/macrophage differentiation of BM cells. Mice transplanted with the cells harboring PTPN11G503A had a higher concentration of M-CSF in plasma. When mixed with the MLL/AF10(OM-LZ) leukemia cells harboring PTPN11wt , the cells harboring PTPN11G503A had an increased competitive engraftment and clonal expansion in the BM and spleen of recipient mice, although no competitive growth advantage was observed in the in vitro co-culturing assays. The mice transplanted with the MLL/AF10(OM-LZ) cells harboring PTPN11wt developed myelomonocytic leukemia, while those transplanted with the cells harboring PTPN11G503A -induced monocytic leukemia in a shorter latency. Our results demonstrated that addition of PTPN11G503A to MLL/AF10 affected cell proliferation, chemo-resistance, differentiation, in vivo BM recruitment/clonal expansion and accelerated disease progression.

[Successful treatment of acute myelomonocytic leukemia developed from essential thrombocythemia with cytarabine plus etoposide].

A 77-year-old man was diagnosed as having essential thrombocythemia (ET) in 1994. He had been treated with hydroxyurea (HU) for six years, and 9 years after the diagnosis of ET, he then developed acute myelomonocytic leukemia (AMMoL) following myelodysplastic syndrome (MDS). Since he suffered from ischemic heart disease, we chose the ara-C+VP-16 therapy. Two courses of the ara-C+VP-16 therapy resulted in partial remission in the bone marrow and a prolonged hematological response. This case seemed rare, since in previous reports, prognosis of ET patients developing MDS and AML was very poor and most of the patients expired within six months.

Coexistence of treatment-related MLL cleavage and rearrangement in a child with haemophagocytic lymphohistiocytosis.

Treatment-related acute myeloid leukaemia (t-AML) is a serious complication of topoisomerase 2 inhibitor therapy and is characterised by the presence of mixed lineage leukaemia (MLL) rearrangement. By molecular tracking, we were able to show that MLL cleavage preceded gene rearrangement by 3 months and before the clinical diagnosis of t-AML in a patient with haemophagocytic lymphohistiocytosis. This is the first report on the sequential detection of the two biomarkers in treatment-related leukaemogenesis.

Expression of AML1-ETO in human myelomonocytic cells selectively inhibits granulocytic differentiation and promotes their self-renewal.

The t(8;21) translocation is one of the most frequent translocations in acute myeloid leukaemia (AML), giving rise to the AML1-ETO fusion protein (or RUNX1-CBF2T1). This abnormality is associated with myelocytic leukaemia with dysplastic granulopoiesis. Here, we demonstrate that when expressed in a normal human (CD34(+)) progenitor population, AML1-ETO selectively inhibits granulocyte colony formation but not monocyte colony formation. In bulk liquid culture, we found that though AML1-ETO transiently inhibited the proliferation of CD34(+) cells, it promoted long-term growth of myeloid cells for more than 80 days, suggesting that differentiation was inhibited. In support of this, cultures expressing AML1-ETO demonstrated enhanced retention of colony-forming capacity. Phenotypic examination of AML1-ETO cultures revealed a defect in granulocytic differentiation in terms of retention of CD34(+) cells within the culture and delayed CD11b upregulation. Morphologically, granulocyte terminal differentiation in AML1-ETO-expressing cells was inhibited by 83+/-5%, giving rise to a build-up of early to intermediate granulocytes that exhibited a number of morphological features associated with t(8;21) leukaemias. In contrast, AML1-ETO had little or no effect on monocytic differentiation. Taken together, these results suggest that expression of AML1-ETO selectively inhibits the differentiation of granulocytic cells and promoted extensive self-renewal, supporting a causal role for t(8;21) translocations in leukaemogenesis.

Acute lymphoblastic leukemia followed by a clonally-unrelated EBV-positive non-Hodgkin lymphoma and a clonally-related myelomonocytic leukemia cutis.

BACKGROUND: Complicating malignant hematopoietic proliferations might severely hamper the course of acute lymphoblastic leukemia (ALL) in patients with an otherwise good prognosis. It is important to distinguish whether such neoplastic proliferations represent ALL relapses or secondary treatment-related malignancies. PROCEDURE: We present an 11-year-old girl with precursor-B-ALL in whom maintenance treatment was complicated by an isolated ALL relapse in the brain, nodular lymphoproliferations in the liver, and an isolated myelo-monocytic leukemia cutis. All these hemato-oncologic malignancies occurred in the background of a secondary immunodeficiency, most likely caused by cytotoxic treatment. RESULTS AND CONCLUSIONS: Using a stepwise molecular approach, we were able to demonstrate that the liver infiltrates were Epstein-Barr virus (EBV)-positive, contained monoclonal mature B-cells with immunoglobulin heavy chain gene (IGH) gene rearrangements unrelated to the primary ALL, and thus represented a true secondary non-Hodgkin lymphoma (NHL). In contrast, the skin infiltrates consisted of myelo-monocytic cells with clonal IGH and T-cell receptor gamma gene rearrangements, identical to the precursor-B-ALL blasts at diagnosis. Thus, the disease course of the precursor-B-ALL patient was complicated by two different isolated extramedullary relapses (brain and skin) and a secondary EBV(+) B-NHL.

[Successful treatment with G-CSF and continuous infusion of low-dose cytarabine and etoposide for therapy-related acute myeloid leukemia developed during chemotherapy for malignant lymphoma].

In March 2000, a 30-year-old Chinese male was initially diagnosed as having non-Hodgkin's lymphoma because of right cervical lymphadenopathy. He had received 8 cycles of chemotherapy including doxorubicin in China. As of February 2001, he was treated in our hospital with the CEPP regimen including etoposide, and was admitted in June 2001 because of leukopenia and thrombocytopenia. Peripheral blood showed hemoglobin 12.7 g/dl, platelets 4.1 x 10(4)/microliter and white blood cells 2300/microliter with 15% blasts. Bone marrow was hypocellular with 48% blasts, which were positive for myeloperoxidase, CD13 and CD33. Chromosome analysis showed 46,XY, t(9;11) (p21;q23) in all 20 metaphase spreads. He was diagnosed as having therapy-related acute myeloblastic leukemia (AML). Because of hypoplastic bone marrow, induction therapy with the CAG regimen including cytarabine, aclarubicin and granulocyte-colony stimulating factor (G-CSF) was started, but no apparent effect was observed. The patient was then treated with the AVG regimen comprising 250 micrograms of G-CSF and continuous infusion with 20 mg of cytarabine and 50 mg of etoposide for 14 days. Complete hematological and cytogenetic remission was achieved after two courses of the AVG regimen. Although it has been shown that the CAG regimen is effective for refractory and/or secondary AML, our results indicate that the AVG regimen should be tried for cases of AML resistant to the CAG regimen.

Coexistence of chronic neutrophilic leukemia with multiple myeloma.

A case report of simultaneous presentation of chronic neutrophilic leukemia and multiple myeloma (IgG kappa) in a 71-year-old male is described. The patient showed mature neutrophilic leukocytosis, hepatosplenomegaly, high neutrophil alkaline phosphatase score, hyperuricemia, neutrophils with toxic granulation and Döhle bodies, absence of Philadelphia chromosome and of the bcr-abl fusion gene. Moreover, a monoclonal IgG kappa paraproteinemia (36.93 g l(-1)) was detected. Bence-Jones proteinuria was 3.84 g l(-1). The bone marrow was grossly hypercellular with marked myeloid hyperplasia and aggregates of plasma cells. The patient died of severe bronchopneumonia after the transformation of chronic neutrophilic leukemia to acute myelomonocytic leukemia, 1.5 years following diagnosis.

High frequency of Ikaros isoform 6 expression in acute myelomonocytic and monocytic leukemias: implications for up-regulation of the antiapoptotic protein Bcl-XL in leukemogenesis.

While studying Ikaros proteins in childhood acute myeloid leukemia (AML), Ikaros isoform 6 (Ik6) expression was detected in 7 of 10 cases of M4 and M5 leukemia, but in none of the remaining French-American-British subtypes (M2, 8 cases; M7, 6 cases). The spliced Ikaros isoforms 4 to 8 (Ik4-8) suppress the function of full-length Ik1 or Ik2 in a dominant-negative manner, owing to their reduced numbers of DNA binding sites. Thus, dominant-negative Ikaros isoforms may inhibit the normal transcriptional regulation of hematopoietic cell development. To clarify the function of Ik6 in developing blood cells, this isoform was transiently transfected into an Ik2(+), interleukin-3 (IL-3)-dependent 32D murine myeloid precursor cell line and studied the expression of Bcl-2 family proteins in relation to in vitro cell growth, using a tetracycline-inducible TREx system. The possibility of aberrant cell regulation due to Ikaros functional changes was examined by cotransfecting both Ik2 and Ik6 into Ikaros/Aiolos/Helios triple-negative Cos-7 cells. The results demonstrated IL-3-independent growth by Ik6-transfected 32D clones coincident with up-regulation of the antiapoptotic protein Bcl-XL. Up-regulation of Bcl-XL, but not of other Bcl-2 family proteins, was associated with the suppression of functional Ik2 by Ik6 in a dominant-negative fashion. Thus, the pathogenesis of myelomonocytic/monocytic AML may involve aberrant regulation of apoptosis due to unscheduled expression of the Ik6 isoform.

Function of the inv(16) fusion gene CBFB-MYH11.

Inv(16)(p13q22) is associated with acute myeloid leukemia subtype M4Eo, which is characterized by the presence of myelomonocytic blasts and atypical eosinophils. This chromosomal rearrangement results in the fusion of CBFB and MYH11 genes. Mouse models indicate that the fusion gene, Cbfb-MYH11, inhibits differentiation of hematopoietic cells. Although expression of Cbfb-MYH11 is not sufficient for leukemogenesis, a combination of Cbfb-MYH11 and additional mutations can lead specifically to the development of myeloid leukemia. Normally, CBFbeta interacts with CBFalpha to form a transcriptionally active nuclear complex. In vitro studies indicate that expression of CBFB-MYH11 leads to sequestration of CBFalpha2 in the cytoplasm. It also has been shown to inhibit CBF-mediated transactivation, slow cell cycle progression, delay the apoptotic response to DNA damaging agents, and protect CBFalpha2 from degradation. The importance of these functions in vivo remains to be determined.

Activating mutations of c-kit at codon 816 confer drug resistance in human leukemia cells.

An improved understanding of how leukemia cells grow and become resistant to treatment remains critical for developing more effective therapies. We have identified activating mutations of c-kit at codon 816 (Asp(816) ) from a revertant of the cytokine-dependent acute myeloid leukemia (AML) cell line, MO7e (D816H), and de novo childhood AML (D816N). Following transduction of the mutant c-kit cDNAs, MO7e cells acquire a growth advantage and resistance to apoptosis in response to chemotherapeutic drugs and ionizing radiation, in addition to cytokine-independent survival. Although stimulation of mutant c-kit-bearing MO7e cells with stem cell factor (SCF), a ligand for c-Kit, does not have a significant effect on cell proliferation, SCF further inhibits apoptosis induced by cytotoxic agents. These results suggest a potentially important role of Asp(816) mutations of c-kit in both malignant cell proliferation and resistance to therapy.

Simultaneous occurrence of advanced neuroblastoma and acute myeloid leukemia.

The authors report the case of a 4-year-old boy with a diagnosis of stage IV neuroblastoma (NB), who had been treated with 6 cycles of cyclophosphamide, doxorubicin, cisplatin, and etoposide for 12 months. The patient reached partial remission and presented a diagnosis of acute myelomonocytic leukemia (M4 AML), confirmed by immunophenotyping. After 2 months of therapy for leukemia, the child died with both malignancies in activity. A necropsy histologically confirmed the simultaneity of the two diseases. The authors review the possibilities of this association. The review leads to the conclusion that AML can occur as a secondary malignancy after the onset of the neuroblastoma, or be suggested by a misdiagnosis. The simultaneous occurrence of both as described here is not, however, found in the literature, to the best of the authors' knowledge.

t(3;11) translocation in treatment-related acute myeloid leukemia fuses MLL with the GMPS (GUANOSINE 5' MONOPHOSPHATE SYNTHETASE) gene.

The partner gene of MLL was identified in a patient with treatment-related acute myeloid leukemia in which the karyotype suggested t(3;11)(q25;q23). Prior therapy included the DNA topoisomerase II inhibitors, teniposide and doxorubicin. Southern blot analysis indicated that the MLL gene was involved in the translocation. cDNA panhandle polymerase chain reaction (PCR) was used, which does not require partner gene-specific primers, to identify the chimeric transcript. Reverse-transcription of first-strand cDNAs with oligonucleotides containing known MLL sequence at the 5' ends and random hexamers at the 3' ends generated templates with an intra-strand loop for PCR. In-frame fusions of either MLL exon 7 or exon 8 with the GMPS (GUANOSINE 5'-MONOPHOSPHATE SYNTHETASE) gene from chromosome band 3q24 were detected. The fusion transcript was alternatively spliced. Guanosine monophosphate synthetase is essential for de novo purine synthesis. GMPS is the first partner gene of MLL on chromosome 3q and the first gene of this type in leukemia-associated translocations. (Blood. 2000;96:4360-4362)

Evidence that juvenile myelomonocytic leukemia can arise from a pluripotential stem cell.

Children with neurofibromatosis type 1 (NF1) carry germline mutations in one allele of the NF1 gene and are predisposed to myeloid malignancies, particularly juvenile myelomonocytic leukemia (JMML). Disruption of the remaining NF1 allele can be found in malignant cells. Flow cytometric cell sorting techniques to isolate the malignant cell populations and molecular genetic methods to assay for somatic loss of the normal NF1 allele were used to study an unusual child with NF1 and JMML who subsequently had T-cell lymphoma. The data show that malignant JMML and lymphoma cells share a common loss of genetic material involving the normal NF1 gene and approximately 50 Mb of flanking sequence, suggesting that the abnormal T-lymphoid and myeloid populations were derived from a common precursor cell. These data support the hypothesis that JMML can arise in a pluripotent hematopoietic cell.