Deferasirox-Dependent Iron Chelation Enhances Mitochondrial Dysfunction and Restores p53 Signaling by Stabilization of p53 Family Members in Leukemic Cells.

Iron is crucial to satisfy several mitochondrial functions including energy metabolism and oxidative phosphorylation. Patients affected by Myelodysplastic Syndromes (MDS) and acute myeloid leukemia (AML) are frequently characterized by iron overload (IOL), due to continuous red blood cell (RBC) transfusions. This event impacts the overall survival (OS) and it is associated with increased mortality in lower-risk MDS patients. Accordingly, the oral iron chelator Deferasirox (DFX) has been reported to improve the OS and delay leukemic transformation. However, the molecular players and the biological mechanisms laying behind remain currently mostly undefined. The aim of this study has been to investigate the potential anti-leukemic effect of DFX, by functionally and molecularly analyzing its effects in three different leukemia cell lines, harboring or not p53 mutations, and in human primary cells derived from 15 MDS/AML patients. Our findings indicated that DFX can lead to apoptosis, impairment of cell growth only in a context of IOL, and can induce a significant alteration of mitochondria network, with a sharp reduction in mitochondrial activity. Moreover, through a remarkable reduction of Murine Double Minute 2 (MDM2), known to regulate the stability of p53 and p73 proteins, we observed an enhancement of p53 transcriptional activity after DFX. Interestingly, this iron depletion-triggered signaling is enabled by p73, in the absence of p53, or in the presence of a p53 mutant form. In conclusion, we propose a mechanism by which the increased p53 family transcriptional activity and protein stability could explain the potential benefits of iron chelation therapy in terms of improving OS and delaying leukemic transformation.

Significant correlation between the degree of WT1 expression and the International Prognostic Scoring System Score in patients with myelodysplastic syndromes.

PURPOSE: To determine whether pattern of WT1 gene expression is a useful marker for establishing prognosis and tracking disease progression in patients with myelodysplastic syndromes (MDS). PATIENTS AND METHODS: We performed a quantitative assessment of the WT1 transcript amount by real-time quantitative polymerase chain reaction (RQ-PCR) in 173 samples (131 bone marrow samples and 42 peripheral-blood samples) from 131 patients with MDS (79 patients with refractory anemia [RA], 31 with RA with excess blasts [RAEB], 18 with secondary acute myeloid leukemia [s-AML] evolved from MDS, and three with deletion of 5q as the sole cytogenetic abnormality). Values obtained were correlated with the blast percentage and International Prognostic Scoring System (IPSS) score. RESULTS: Sixty-five percent of BM and 78% of PB samples for RA and 100% of BM and PB samples of RAEB and s-AML expressed WT1 transcript amounts greater than the level observed in healthy volunteers. The degree of WT1 expression was highly correlated with the type of MDS, was much higher in RAEB and s-AML compared with RA, and increased during disease progression. Moreover, a significant correlation was found between WT1 expression levels, blast cell percentage, and the presence of cytogenetic abnormalities. Therefore, we found a significant correlation between the amount of WT1 transcripts and the IPSS score, which currently represents the most reliable risk index of disease progression available for MDS patients. CONCLUSION: WT1 is a useful molecular marker for risk assessment in MDS patients.

Trisomy 11 in myeloid malignancies is associated with internal tandem duplication of both MLL and FLT3 genes.

In 20 patients with myeloid malignancies and isolated trisomy 11 an internal tandem duplication of the MLL and FLT3 genes was observed in 41% and 31% of the cases, respectively; 80% of the FLT3+ cases showed MLL self-fusion. Concomitant presence of MLL and FLT3 anomalies could be relevant in determining the poor outcome of patients with acute myeloid leukemia with trisomy 11.

From genes to therapy: the case of Philadelphia chromosome-positive leukemias.

The Philadelphia chromosome (Ph-chromosome) has long represented the only cytogenetic abnormality known to be associated with a specific malignant disease in humans, being present in more than 95% of patients with chronic myelogenous leukemia. This abnormality is the result of a reciprocal translocation between the long arms of chromosome 9 and 22, t(9;22)(q34;q11), and its presence is not restricted to chronic myelogenous leukemia, but can also be found in 30% of cases of acute lymphoblastic leukemia in adults. In the 1980s, the molecular counterpart of the chromosomal rearrangement was identified to consist of the juxtaposition of parts of the BCR and ABL genes to form a BCR-ABL hybrid gene. The resulting chimeric proteins (P210 and P190), which retain constitutively activated tyrosine kinase activity, have demonstrated a causative role in the genesis of the leukemic process. Although many aspects of the BCR-ABL driven transformation remain unsolved, great advances in understanding the molecular pathology of Ph-positive leukemias resulted in meaningful improvement in the clinical setting. Molecular tools to diagnose disease (PCR, FISH, and southern blot) and to monitor minimal residual disease after potential curative treatment are now in current practice, and new powerful therapeutic tools have emerged that target the molecular oncogenic pathways activated in Ph-positive cells. Among them, specific ABL tyrosine kinase inhibitors recently obtained extraordinary results in many clinical protocols. This review summarizes the most recent advances in this field with special focus on the putative mechanisms of the transformation and progression of chronic myelogenous leukemia and on the major impact that understanding the molecular biology of these diseases is having in clinical practice.

Detection of minimal residual disease in peripheral blood stem cells from two acute myeloid leukemia patients with trisomy 8 predicts early relapse after autologous bone marrow transplantation.

We report two cases of acute myeloid leukemia (AML) French-American-British M4 classification with trisomy 8 at diagnosis as the sole chromosome abnormality. Both patients were treated with the GIMEMA AML-10 protocol and underwent autologous bone marrow transplantation (ABMT) in hematologic remission. Peripheral blood stem cells (PBSC), and bone marrow in one patient, were collected after consolidation therapy and tested by fluorescence in situ hybridization (FISH) analysis with an alpha-satellite probe for chromosome 8. It revealed that all samples were positive for minimal residual disease (MRD) as the value of trisomic cells exceeded the mean +3 standard deviations of the controls. ABMT was done following a myeloablative regimen (busulphan/cyclophosphamide) and PBSC were reinfused. Both patients relapsed, 4 and 2 months, respectively, after autotransplant. Although more data are needed, these results suggest that the persistence of MRD, as detected by FISH, in stem cell collections, is associated with a poor outcome in AML patients with trisomy 8 undergoing ABMT.

Myelodysplastic disorders carrying both isolated del(5q) and JAK2(V617F) mutation: concise review, with focus on lenalidomide therapy.

The concomitant presence of del(5q) and JAK2(V617F) mutation is an infrequent event which occurs in rare patients with peculiar cytogenetic, molecular, morphological and clinical features, resembling those of both myelodysplastic syndromes and myeloproliferative neoplasms. Lenalidomide may induce rapid, profound, and long-lasting responses in a subset of these patients. However, the mechanism(s) by which the drug acts in these conditions remain not completely elucidated. A new case report and a review of all cases published so far in this setting are provided. Furthermore, the possibility of categorizing - from a clinical, pathological, and biological point of view - for at least some of these patients as a potential distinct entity is discussed.

Two new translocations involving the 11q23 region map outside the MLL locus in myeloid leukemias.

BACKGROUND AND OBJECTIVES: In acute leukemias, chromosomal translocations involving the 11q23 band are frequently, but not invariably, associated with MLL gene rearrangement and their finding is associated with a poor prognosis. We observed two new translocations with a breakpoint in the 11q23 region at standard cytogenetic analysis: a previously undescribed t(3;11)(q21;q23) in a 70-year old woman with a fulminating form of AML-M1 and a new translocation t(6;11)(q15;q23) in a 61-year old man with an atypical chronic myelogenous leukemia. In these two patients, involvement of the MLL gene was analyzed by molecular cytogenetic techniques which also allowed a more precise mapping of the breakpoints. DESIGN AND METHODS: The MLL gene was analyzed by Southern blot and by fluorescent in situ hybridization (FISH) with a double-color MLL probe. A panel of 11q, 3q and 6q cosmid/YAC probes mapping around the breakpoints was used for breakpoint mapping. RESULTS: In both patients, FISH analysis and Southern blot showed that the MLL gene was not rearranged; in patient 1, MLL was retained on the 11q+ derivative, whereas in patient 2 it moved to the 6q- chromosome. In the t(3;11) we localized the chromosome 11 breakpoint at 11q23.3, in a region flanked by CP-939H3 and cos1p3, distal to the MLL locus; in the t(6;11) the break occurred at 11q21, in a region flanked by CP-819A5 and CP-829A6, proximal to the MLL locus. INTERPRETATION AND CONCLUSIONS: Our cases add two new translocations to the list of chromosomal anomalies involving the long arm of chromosome 11, and show that apparent translocation t(11q23) may involve loci and genes other than MLL. Characterizing the molecular heterogeneity of 11q23 translocations may identify some prognostic significance.

Immune reconstitution and early infectious complications following nonmyeloablative hematopoietic stem cell transplantation.

Non-myeloablative stem cell transplantation (NMT) has been increasingly used in compromised patients who would otherwise have been unable to undergo allotransplant. There is little understanding of the kinetics of immune reconstitution and its influence on infective complications following NMT. The aim of present study was to evaluate lymphocyte subset reconstitution over the first 12 months post-transplant in 15 adult patients receiving NMT with comparison to that of 30 patients grafted with a conventional hemopoietic stem cell transplantation (HSCT). NMT recipients were conditioned with fludarabine-based conditioning regimens. Peripheral blood stem cell (PBSC) was the source of stem cells in 13 NMT recipients and in 24 conventional HSCT recipients. Absolute numbers of helper (CD4+) T cells, naive (CD4+ CD45RA+) and memory (CD4+ CD45RO+) T cells as well as suppressor (CD8+) T cells, CD19+ B cells and NK cells were comparable in the two groups at all time points after transplantation. A median value of 200 CD4+ T cells/microl was achieved at 2 months post-transplant by the NMT and HSCT recipients. The CD4:CD8 ratio remained severely depressed throughout the study period. Almost all CD4+ lymphocytes expressed CD45RO antigen in the both groups of patients B lymphocytes showed low counts throughout the entire study period in both groups. Bacteremia and CMV antigenemia occurred respectively in 13 and 36% of the patients in the NMT group and in 15 and 39% of the patients in the HSCT group. Our preliminary data indicate that patients receiving a NMT have a lymphocyte reconstitution similar to that observed in patients who received a conventional HSCT. The incidence of bacteremia and CMV infection were not significantly different between the groups. Nevertheless, due to the small sample size, these results should be considered suggestive rather than definitive.

A 76-kb duplicon maps close to the BCR gene on chromosome 22 and the ABL gene on chromosome 9: possible involvement in the genesis of the Philadelphia chromosome translocation.

A patient with a typical form of chronic myeloid leukemia was found to carry a large deletion on the derivative chromosome 9q+ and an unusual BCR-ABL transcript characterized by the insertion, between BCR exon 14 and ABL exon 2, of 126 bp derived from a region located on chromosome 9, 1.4 Mb 5' to ABL. This sequence was contained in the bacterial artificial chromosome RP11-65J3, which in fluorescence in situ hybridization experiments on normal metaphases was found to detect, in addition to the predicted clear signal at 9q34, a faint but distinct signal at 22q11.2, where the BCR gene is located, suggesting the presence of a large region of homology between the two chromosomal regions. Indeed, blast analysis of the RP11-65J3 sequence against the entire human genome revealed the presence of a stretch of homology, about 76 kb long, located approximately 150 kb 3' to the BCR gene, and containing the 126-bp insertion sequence. Evolutionary studies using fluorescence in situ hybridization identified the region as a duplicon, which transposed from the region orthologous to human 9q34 to chromosome 22 after the divergence of orangutan from the human-chimpanzee-gorilla common ancestor about 14 million years ago. Recent sequence analyses have disclosed an unpredicted extensive segmental duplication of our genome, and the impact of duplicons in triggering genomic disorders is becoming more and more apparent. The discovery of a large duplicon relatively close to the ABL and BCR genes and the finding that the 126-bp insertion is very close to the duplicon at 9q34 open the question of the possible involvement of the duplicon in the formation of the Philadelphia chromosome translocation.