1,721,040 research outputs found
What does it mean i have a monoclonal B-cell lymphocytosis?: Recent insights and new challenges
No full textMonoclonal B-cell lymphocytosis (MBL) is defined as a laboratory abnormality where small (<5 x 109/L) clonal B-cell populations are detected in the peripheral blood of otherwise healthy subjects. According to the immunophenotype, MBL is labeled as chronic lymphocytic leukemia (CLL)-like (75% of cases), atypical CLL, and CD5-negative. Concentration of clonal B cells differentiates low- (LC) and high-count (HC)-MBL (< or ≥ 0.5 x 109/L, respectively). Thanks to technical improvements, we are able to identify CLL-like clonal B-cell populations at increased frequency with age, but we are still far from understanding its relationship with clinically overt CLL. LC-MBL, requiring high-throughput screening technique to be identified in population studies, seems to be a bird of a different feather and several hints suggest that LC-MBL is related to aging and/or chronic antigenic stimulation. Immunogenetic, cytogenetic and genetic data support the notion that HC-MBL, usually identified in the clinical setting, is a premalignant condition and, based on biological parameters, it is frequently difficult to differentiate it from early stage CLL. The rapid improvement and widespread availability of cutting-edge technology, in particular next-generation sequencing (NGS), raises hope that we are getting closer to unveiling the fundamental nature of MBL and CLL and how they are related to each other
Reprogramming cell death: BCL2 family inhibition in hematological malignancies
No full textThe BCL2 family members play a central role in regulating programmed cell death (apoptosis) and arbitrating the cellular fate through an accurate balance between pro-apoptotic (BAX, BAK, and BH3-only proteins) and pro-survival (BCL2 and its closest homologues, BCLXL, BCLW and MCL-1) factors. Deregulation of BCL2 family proteins contributes to programmed cell death evasion, that is a hallmark of human cancers and it is often related to (chemo)therapy resistance. High BCL2 levels have been detected in most human lymphoid malignancies, not limited to follicular lymphoma (where the role of BCL2 overexpression is driven by the 414;181 translocation) but also B-cell chronic lymphocytic leukemia (CLL) and multiple myeloma. For all these reasons, the opportunity to induce apoptosis by targeting BCL2 proteins is considered a potentially promising therapeutic approach in hematological malignancies. BCL2 family inhibition strategies currently explored in phase 1,2 and 3 clinical trials are essentially two: (1) the use of antisense-based strategies to knockdown BCL2 or BCLXL expression (e.g. oblimersen) or (2) the use of synthetic BH3 mimetics i.e. small molecules binding to anti-apoptotic inhibitors thereby allowing the pro-apoptotic activity of BH3-only molecules (e.g. obatoclax, AT-101, ABT-737 and its derivatives ABT-263 and ABT-199). Several of these drugs demonstrated relevant clinical activity as single-agent or in combination therapy, with the most significant drawbacks in clinical use being represented by challenging pharmacokinetic profile (e.g. iv administration, high-levels of plasma proteins binding) and on-target side effects (e.g. gastrointestinal toxicity and thrombocytopenia). Further clinical development of the current compounds (e.g. ABT-199), showing high efficacy but devoid of the most threatening drug-related toxicities, is eagerly awaited. Hopefully, in the next future, BCL2 inhibitors (alone or in combination with immuno- and/or chemo-therapeutic agents). will represent target-specific drugs expanding our therapeutic armamentarium in the fight against hematologic malignancies. (C) 2013 Elsevier B.V. All rights reserved
Recent advances in lymphoma biology
No full textThis review highlights three topics in which major contributions to lymphoma biology have recently been achieved. First, the use of single-cell polymerase chain reaction analysis has allowed for a better understanding of the origin of several entities, eg, Hodgkin's, Burkitt's, and marginal zone B-cell lymphomas. Second, the studies of mechanisms regulating apoptosis and survival of the neoplastic clones have opened a whole area of research with promising expectations for new therapeutical approaches. Finally, the recent cloning of genes involved in several chromosomal translocations is likely to shed more light on the molecular mechanisms responsible for the neoplastic transformation. The survey presents the main results obtained in these three areas and critically discusses them in the light of the current debat
Monoclonal B-cell lymphocytosis: right track or red herring?
No full text"Monoclonal B-cell lymphocytosis (MBL), a newly recognized entity found in approximately 3% of normal persons, precedes chronic lymphocytic leukemia. However, MBLs progress into overt malignancy only in a very minor portion of cases, thus raising the clinical concern of whether and how we can discriminate at diagnosis which rare cases will evolve into a fully fledged tumor. Understanding the molecular\/biologic features underlying the risk of progression may significantly modify our strategies for correctly managing B-cell premalignant states. MBL cells bear the same chromosomal abnormalities of chronic lymphocytic leukemia. Genome-wide sequencing and animal models indicate that genetic abnormalities disrupting the control of cell growth and survival cooperate with microenvironment-triggered events, mainly represented by antigen-mediated B-cell receptor and co-receptor stimulation, to trigger and fuel clonal expansion. The initial functional activation of survival\/proliferation pathways may later become subsidized by autonomous genetic abnormalities (eg, a single mutation) affecting the same or parallel critical signaling pathway(s). (Blood. 2012;119(19):4358-4362)
Management of chronic lymphocytic leukemia
Full text linkIn the last decade, the management of chronic lymphocytic leukemia has undergone profound changes that have been driven by an improved understanding of the biology of the disease and the approval of several new drugs. Moreover, many novel drugs are currently under evaluation for rapid approval or have been approved by regulatory agencies, further broadening the available therapeutic armamentarium for patients with chronic lymphocytic leukemia. The use of novel biological and genetic parameters combined with a careful clinical evaluation allows us to dissect some of the heterogeneity of the disease and to distinguish patients with a very mild onset and course, who often will not need any treatment, from those with an intermediate prognosis and a third group with a very aggressive course (high-risk leukemia). On this background, it becomes increasingly challenging to select the right treatment strategy. In this paper, we describe our own approach to the management of different patients with chronic lymphocytic leukemia
Chronic lymphocytic leukaemia
No full textChronic lymphocytic leukaemia (CLL) is the most common leukaemia among the adults in the Western World. CLL (and the corresponding nodal entity small lymphocytic lymphoma, SLL) is classified as a lymphoproliferative disorder characterised by the relentless accumulation of mature B-lymphocytes showing a peculiar immunophenotype in the peripheral blood, bone marrow, lymph nodes and spleen. CLL clinical course is very heterogeneous: the majority of patients follow an indolent clinical course with no or delayed treatment need and with a prolonged survival, while others experience aggressive disease requiring early treatment followed by frequent relapses. In the last decade, the improved understanding of CLL pathogenesis shed light on premalignant conditions (i.e., monoclonal B-cell lymphocytosis, MBL), defined new prognostic and predictive markers, improving patient stratification, but also broadened the therapeutic armamentarium with novel agents, targeting fundamental signaling pathways
Mouse models in the study of chronic lymphocytic leukemia pathogenesis and therapy
No full textMouse models that recapitulate human malignancy are valuable tools for the elucidation of the underlying pathogenetic mechanisms and for preclinical studies. Several genetically engineered mouse models have been generated, either mimicking genetic aberrations or deregulated gene expression in chronic lymphocytic leukemia (CLL). The usefulness of such models in the study of the human disease may potentially be hampered by species-specific biological differences in the target cell of the oncogenic transformation. Specifically, do the genetic lesions or the deregulated expression of leukemia-associated genes faithfully recapitulate the spectrum of lymphoproliferations in humans? Do the CLL-like lymphoproliferations in the mouse have the phenotypic, histological, genetic, and clinical features of the human disease? Here we compare the various CLL mouse models with regard to disease phenotype, penetrance, and severity. We discuss similarities and differences of the murine lymphoproliferations compared with human CLL. We propose that the Eμ-TCL1 transgenic and 13q14-deletion models that have been comprehensively studied at the levels of leukemia phenotype, antigen-receptor repertoire, and disease course show close resemblance to the human disease. We conclude that modeling CLL-associated genetic dysregulations in mice can provide important insights into the molecular mechanisms of disease pathogenesis and generate valuable tools for the development of novel therapies
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