ZAP-70 is expressed by normal and malignant human B-cell subsets of different maturational stage.

ZAP-70 tyrosine kinase is involved in signalling pathways following T-cell receptor stimulation and was originally described only in T cells and natural killer cells. ZAP-70 expression has been reported in normal mouse B lineage cells and in human malignant B lymphocytes, mainly in chronic lymphocytic leukemia (CLL) where it correlates with clinical outcome. We analyzed several B-cell lines and ex vivo malignant B cells, ranging from acute lymphoblastic leukemia to multiple myeloma and reflecting different stages of B-cell differentiation, and they showed ZAP-70 expression regardless their maturation stage. We then analyzed by Western blot and flow cytometry different human normal B-lymphocyte subpopulations: naïve, germinal center and memory B cells from tonsils, CD19+ CD5+ cells from cord blood and CD19+ lymphocytes from peripheral blood. All expressed ZAP-70 protein, though at different levels depending on their differentiation, activation and tissue localization. In addition, ZAP-70 expression levels could be modulated following stimulation via the B-cell receptor. These findings implicate a potential role of ZAP-70 in the signalling pathway of B lymphocytes at different maturational stages, indicate that ZAP-70 expression is not a CLL-specific feature among B-cell malignancies and suggest that the absence of ZAP-70 rather than its presence should be considered abnormal for malignant B lymphocytes.

Differential effects on CLL cell survival exerted by different microenvironmental elements.

Selected microenvironmental stimuli confer to leukemic cells a growth advantage and an extended survival. We aimed at dissecting the differential support provided by the different cellular components of the microenvironment where CLL cells accumulate. To this end we cultured purified CLL cells in vitro in the presence or absence of different accessory cells (stromal cells, autologous T lymphocytes) and/or soluble molecules (IL-4, sCD40L) and assessed the leukemic cell response in terms of cell viability and chemoattracting capacity. The results indicate that both T lymphocytes and stromal cells are involved in sustaining the survival of leukemic B cells, but indicate that their support is different in terms of time of onset and duration. T cells have a short-term support activity while stromal cells provide long-term support.

Xenograft models of chronic lymphocytic leukemia: problems, pitfalls and future directions.

Xenotransplantation of human tumor cells into immunodeficient mice has been a powerful preclinical tool in several hematological malignancies, with the notable exception of chronic lymphocytic leukemia (CLL). For several decades, this possibility was hampered by the inefficient and/or short-term engrafment of CLL cells into available animals. The development of new generations of immunocompromised mice has allowed to partially overcome these constraints. Novel humanized animal models have been created that allow to recapitulate the pathogenesis of the disease and the complex in vivo relationships between leukemic cells and the microenvironment. In this review we discuss the development of xenograft models of CLL, how they may help elucidating the mechanisms that account for the natural history of the disease and facilitating the design of novel therapeutic approaches.

The functional in vitro response to CD40 ligation reflects a different clinical outcome in patients with chronic lymphocytic leukemia.

Malignant B lymphocytes from chronic lymphocytic leukemia (CLL) patients maintain the capacity to respond to CD40 ligation, among other microenvironmental stimuli. In this study, we show that (i) leukemic CLL cells stimulated with the soluble form of CD40L in vitro show differential responses in terms of upregulation of surface markers (CD95 and CD80) and induction of chemokines (CCL22 and CCL17) expression/secretion, and that (ii) these changes are mirrored by a distinct activation of intracellular signalling pathways including increase in IKKalpha/beta phosphorylation and upregulation of antiapoptotic proteins (BCL-2 and MCL-1). CLL patients can then be segregated into two distinct functional subsets. We defined the responsive subset of cases CD40L dependent, considering the capacity to respond as a sign of persistent need of this stimulation for the leukemic expansion. Conversely, we named the unresponsive cases CD40L independent, considering them less dependent on this microenvironmental signal, presumably because of a higher autonomous proliferative and survival potential. Importantly, we report that (iii) the two functional subsets show an opposite clinical outcome, with CD40L-independent cases having a shorter time to progression. This indicates that the functional differences observed in vitro may reflect a different leukemic potential in vivo likely responsible for a distinct clinical course.

An overview of chronic lymphocytic leukaemia biology.

Chronic lymphocytic leukaemia (CLL) is characterised by accumulation of CD5(+) monoclonal B cells in primary and secondary lymphoid tissues. Genetic defects and stimuli originating from the microenvironment concur to the selection and expansion of the malignant clone. Several lines of evidence, including molecular and functional analysis of the monoclonal immunoglobulin, support the hypothesis that stimulation through the B-cell receptor affects life and death of leukaemic cells. The microenvironment also has a critical role in the survival and accumulation of leukaemic cells within lymphoid organs where signals delivered from the surrounding cells are likely crucial in inducing proliferation. Nevertheless, several major biological issues still remain to be solved including regulation of the balance between proliferation and survival of leukaemic cells and the links between emerging gene abnormalities and microenvironment. In this context, mouse models are helpful tools in understanding disease mechanisms and in evaluating the efficacy of novel therapeutic agents.