c-Myc, Genomic Instability and Disease.

The proto-oncogene c-myc has been the subject of intensive research since its discovery. It is already known that this oncogene targets multiple pathways for the initiation and promotion of tumor formation, and that deregulation of this protein is observed in numerous cancers. However, despite the plethora of information gathered, the exact role and mechanism of action of the protein still remains enigmatic. This review focuses on the role of the c-Myc protein in the induction of genomic instability and its link with the development of cancer. We briefly describe c-Myc protein, its binding partners and downstream targets as well as its role in inducing genomic instability and the c-myc-related diseases in humans and mice with regard to genomic instability. This review emphasizes the notions that c-Myc is a multifunctional protein which also affects the stability of the whole genome and triggers the initiation of a complex network of genomic instability and therefore acts beyond the characteristics of classical transcription factors that only regulate a limited number of downstream targets. We propose that c-Myc is a structural modifier of the genome that affects the nuclear organization and an important molecule in tumor cell progression through the induction of genomic instability.

Relationship between expression of genes involved in cell cycle control and apoptosis in diffuse large B cell lymphoma: a preferential survivin-cyclin B link.

Accumulating evidence suggests that lack of balance between proliferation and apoptosis may lead to clonal expansion and cancer emergence. In diffuse large B cell lymphoma (DLBCL), survivin expression by tumor cells has been recently described as a poor prognostic marker. We assessed the relationship between survivin gene up-regulation and several other factors involved in either cell cycle or apoptosis control. The expression of 34 genes from 27 cases of DLBCL with typical IPI factor-related poor prognostic outcome was analyzed by RNase protection assay. Using non-neoplastic tissues and low grade lymphomas as control, survivin expression was high in 80% of the cases without significant relation to patient overall survival (P = 0.64). However, the expression of several genes encoding for cell cycle inhibitors, cyclins, Bcl-2 or IAP family factors was significantly associated with the survivin up-regulation. Gene expression profiling showed that both survivin and cyclin B expression can define two subgroups of DLBCL: the previously described germinal center-like and activated B-like lymphomas, determined by protein expression analysis. We also identified a preferential survivin-cyclin B relationship (P = 0.017), suggesting that cyclin B over-expression, when linked to survivin over-expression in aggressive forms of lymphoma, might demonstrate a specific G2/M transition promotion.

c-myc box II mutations in Burkitt's lymphoma-derived alleles reduce cell-transformation activity and lower response to broad apoptotic stimuli.

In addition to c-myc rearrangement, over 50% of Burkitt's lymphoma cases present clustered mutations in exon 2, where many of the functional activities of c-Myc protein are based. This report describes the functional consequences induced by tumour-derived c-myc mutations located in c-myc box II. Two mutated alleles were studied, focusing on the P138C mutation, and compared to wild-type c-myc. The c-Myc transformation, transactivation and apoptosis activities were explored based on cells over-expressing c-Myc. While the transcriptional activation activity was not affected, our experiments exploring the anchorage-independent growth capacity of c-Myc-transfected Rat1a cells showed that c-Myc box II mutants were less potent than wild-type c-Myc in promoting cell transformation. Considering the possibility that these mutations could be interfering with the ability of c-Myc to promote apoptosis, we tested c-Myc-transfected Rat1a fibroblasts under several conditions: serum deprivation-, staurosporine- and TNFalpha-induced cell death. Interestingly, the mutated alleles were characterized by an overall decrease in ability to mediate apoptosis. Our study indicates that point mutations located in c-Myc box II can decrease the ability of the protein to promote both transformation and apoptosis without modifying its transactivating activity.

Effect of granulocyte colony-stimulating factor mobilization on phenotypical and functional properties of immune cells.

Some phenotypic and functional properties of lymphocytes from bone marrow or peripheral blood stem cell donors were compared in a randomized study. Lymphocyte subsets were analyzed by immunocytometry in blood harvested from bone marrow donors (n = 27) and from peripheral blood stem cell donors before and after granulocyte colony-stimulating factor mobilization (n = 23) and in bone marrow and peripheral blood stem cell grafts. Granulocyte colony-stimulating factor mobilization increased the blood T and B, but not NK, lymphocyte counts. All lymphocyte counts were approximately 10-fold higher in peripheral blood stem cell grafts than in bone marrow grafts. Analysis of CD25, CD95, HLA-DR, and CD45RA expression shows that T-cell activation level was lower after granulocyte colony-stimulating factor mobilization. Similarly, granulocyte colony-stimulating factor reduced by twofold to threefold the percentage of interferon-gamma, interleukin-2, and tumor necrosis factor-alpha-secreting cells within the NK, NK-T, and T-cell subsets and severely impaired the potential for interferon-gamma production at the single-cell level. mRNA levels of both type 1 (interferon-gamma, interleukin-2) and type 2 (interleukin-4, interleukin-13) cytokines were approximately 10-fold lower in peripheral blood stem cell grafts than in bone marrow grafts. This reduced potential of cytokine production was not associated with a preferential mobilization of so-called "suppressive" cells (CD3+CD4-CD8-, CD3+CD8+CD56+, or CD3+TCRVA24+CD161+), nor with a modulation of killer cell receptors CD161, NKB1, and CD94 expression by NK, NK-T, or T cells. Our data demonstrate in a randomized setting that quantitative as well as qualitative differences exist between a bone marrow and a peripheral blood stem cell graft, whose ability to produce type 1 and type 2 cytokines is impaired.