ADP ribosylation factor like 2 (Arl2) regulates breast tumor aggressivity in immunodeficient mice.

We have previously reported that ADP ribosylation factor like 2 (Arl2), a small GTPase, content influences microtubule dynamics and cell cycle distribution in breast tumor cells, as well as the degree and distribution of phosphorylated P53. Here we show, in two different human breast adenocarcinoma models, that Arl2 content has a major impact on breast tumor cell aggressivity both in vitro and in vivo. Cells with reduced content of Arl2 displayed reduced contact inhibition, increased clonogenic or cluster formation as well as a proliferative advantage over control cells in an in vitro competition assay. These cells also caused larger tumors in SCID mice, a phenotype which was mimicked by the in vivo administration of siRNA directed against Arl2. Cells with increased Arl2 content displayed reduced aggressivity, both in vitro and in vivo, with enhanced necrosis and were also found to contain increased PP2A phosphatase activity. A rt-PCR analysis of fresh human tumor breast samples suggested that low Arl2 expression was associated with larger tumor size and greater risk of lymph node involvement at diagnosis. These data underline the role of Arl2, a small GTPase, as an important regulator of breast tumor cell aggressivity, both in vitro and in vivo.

Dysregulation of ribosome biogenesis and translational capacity is associated with tumor progression of human breast cancer cells.

Protein synthesis is a fundamental cell process and ribosomes - particularly through the ribosomal RNA that display ribozyme activity--are the main effectors of this process. Ribosome biogenesis is a very complex process involving transcriptional aswell as many post-transcriptional steps to produce functional ribosomes. It is now well demonstrated that ribosome production is enhanced in cancer cells and that ribosome biogenesis plays a crucial role in tumor progression. However, at present there is an important lack of data to determine whether the entire process of ribosome biogenesis and ribosome assembly is modified during tumor progression and what could be the potential impact on the dysregulation of translational control that is observed in cancer cells. In breast cancer cells displaying enhanced aggressivity, both in vitro and in vivo, we have analyzed the major steps of ribosome biogenesis and the translational capacity of the resulting ribosome. We show that increased tumorigenicity was associated with modifications of nucleolar morphology and profound quantitative and qualitative alterations in ribosomal biogenesis and function. Specifically cells with enhanced tumor aggressivity displayed increased synthesis of 45S pre-rRNA, with activation of an alternative preRNA synthetic pathway containing a 43S precursor and enhanced post-transcriptional methylation of specifc sites located in the 28S rRNA. While the global translational activity was not modified, IRES-initiated translation, notably that of p53 mRNA, was less efficient and the control of translational fidelity was importantly reduced in cells with increased aggressivity. These results suggest that acquisition of enhanced tumor aggressivity can be associated with profound qualitative alterations in ribosomal control, leading to reduced quality control of translation in cancer cells.

In vivo model of follicular lymphoma resistant to rituximab.

PURPOSE: Follicular lymphoma (FL) is the most common subtype of indolent lymphomas. Rituximab is widely used alone or in combination therapy for the treatment of FL. Despite its well-established clinical efficacy, a subpopulation of patients does not respond to rituximab and most patients will relapse after therapy. The mechanisms of action and resistance to rituximab are not fully understood. EXPERIMENTAL DESIGN: To study these mechanisms we developed an in vivo model of FL resistant to rituximab. This model was developed using the human RL line, isolated from a patient with FL, grown as xenotransplants in severe combined immunodeficient mice, exposed weekly to rituximab in vivo, followed by serial reimplantation and reexposure to rituximab, until a resistant phenotype was obtained. RESULTS: RL-derived tumors unexposed to rituximab were grown as controls and compared with the resistant tumors. Although the expression of CD46 and CD55 antigens were not differently expressed in the resistant cells, the complement inhibitor CD59 was overexpressed in a subpopulation and CD20 was found to be expressed at a lower level in a minority of cells. Bcl-X(L) and YY1 were also found more highly expressed in rituximab-resistant cells. CONCLUSION: This model provides insight on potential in vivo resistance mechanisms to rituximab and could help contribute to the development of novel therapies in rituximab-refractory diseases.

Expression of Arl2 is associated with p53 localization and chemosensitivity in a breast cancer cell line.

In mammalian cells, ADP ribosylation factor like 2 (Arl2) has been shown to form a complex with tubulin binding cofactor D (TBC-D) and the tumor suppressor protein phosphatase 2A (PP2A). We have previously shown that alterations in Arl2 protein content were associated with corresponding modifications of the tumor suppressor PP2Ac protein content in breast cancer cells. Here, we show that modified Arl2 expression level influences sensitivity to various anticancer compounds such as taxol, navelbine, gemcitabine and doxorubicin in MCF7 derived cell lines. Modifications of Arl2 expression levels were also associated with an altered phosphorylation status and/or cellular sublocalization of certain PP2A targets such as p53, a key mediator of chemotherapy-induced apoptosis. A decreased level of Arl2 expression was associated with an increase of phospho-ser15-p53, a form which was found to be preferentially bound to microtubules. Assays using okadaic and cantharidic acid, two different PP2A inhibitors, showed an increase in microtubule-bound phospho-p53 and reduced sensitivity to chemotherapy. Our results suggest that Arl2 could, via PP2A, influence p53 phosphorylation status. Certain forms of phosphorylated p53 demonstrating increased binding to microtubules appear to be less prone to nuclear translocation after exposure to chemotherapeutic agents, thereby possibly contributing to reduced chemosensitivity.