Explore the vast range of titles available.

Fos-related antigen 1 (Fra-1) is a Fos family member overexpressed in several types of human cancers. Here, we report that Fra-1 is highly expressed in the muscle-invasive form of the carcinoma of the bladder (80%) and to a lesser extent in superficial bladder cancer (42%). We demonstrate that in this type of cancer Fra-1 is regulated via a C-terminal instability signal and C-terminal phosphorylation. We show that manipulation of Fra-1 expression levels in bladder cancer cell lines affects cell morphology, motility and proliferation. The gene coding for AXL tyrosine kinase is directly upregulated by Fra-1 in bladder cancer and in other cell lines. Importantly, our data demonstrate that AXL mediates the effect of Fra-1 on tumour cell motility but not on cell proliferation. We suggest that AXL may represent an attractive therapeutic target in cancers expressing high Fra-1 levels.

Fra-1 is aberrantly expressed in a large number of cancer cells and tissues, and emerging evidence suggests an important role for this Fos family protein in both oncogenesis and the progression or maintenance of many tumour types. Here, we show that the concentration of Fra-1 is high in invasive oestrogen receptor (ER)-negative (ER−) breast cancer cell lines, regardless of their Ras pathway status. All of the ER− cells express high levels of activated PKCθ, and the inhibition of PKCθ activity using RNA interference or the expression of a dominant-negative mutant results in a dramatic reduction in Fra-1 abundance. Conversely, the ectopic expression of constitutively active PKCθ leads to Fra-1 phosphorylation and accumulation in poorly invasive ER+ cells. This accumulation is due to the stabilisation of the Fra-1 protein through PKCθ signalling, whereas other members of the PKC family are ineffective. Both Ste20-related proline-alanine-rich kinase (SPAK) and ERK1/2, whose activities are upregulated by PKCθ, participate in PKCθ-driven Fra-1 stabilisation. Interestingly, their relative contributions appear to be different depending on the cell line studied. ERK1/2 signalling has a major role in ER− MDA-MB-231 cells, whereas Fra-1 accumulation occurs mainly through SPAK signalling in ER− BT549 cells. Fra-1 mutational analysis shows that the phosphorylation of S265, T223 and T230 is critical for PKCθ-driven Fra-1 stabilisation. Phosphorylation of the protein was confirmed using specific antisera against Fra-1 phosphorylated on T223 or S265. In addition, Fra-1 participates in PKCθ-induced cell invasion and is necessary for PKCθ-induced cell migration. In summary, we identified PKCθ signalling as an important regulator of Fra-1 accumulation in ER− breast cancer cells. Moreover, our results suggest that PKCθ could participate in progression of some breast cancers and could be a new therapeutic target.

The inducible proto-oncogenic (c-Fos:c-Jun)/AP-1 transcription complex binds 12-O-tetradecanoylphorbol 13-acetate (TPA)-responsive elements (TRE) in its target genes. It is tightly controlled at multiple levels to avoid the deleterious effects of its inappropriate activation. In particular, SUMOylation represses its transactivation capacity in transient reporter assays using constitutively expressed proteins. This led to the presumption that (c-Fos:c-Jun)/AP-1 SUMOylation would be required to turn-off transcription of its target genes, as proposed for various transcription factors. Instead, thanks to the generation of an antibody specific for SUMO-modified c-Fos, we provide here direct evidence that SUMOylated c-Fos is present on a stably integrated reporter TPA-inducible promoter at the onset of transcriptional activation and colocalizes with RNA polymerase II within chromatin. Interestingly, (c-Fos:c-Jun)/AP-1 SUMOylation limits reporter gene induction, as well as the appearance of active transcription-specific histone marks on its promoter. Moreover, non-SUMOylatable mutant (c-Fos:c-Jun)/AP-1 dimers accumulate to higher levels on their target promoter, suggesting that SUMOylation might facilitate the release of (c-Fos:c-Jun)/AP-1 from promoters. Finally, activation of GADD153 , an AP-1 target gene, is also associated with a rapid increase in SUMOylation at the level of its TRE and c-Fos SUMOylation dampens its induction by TPA. Taken together, our data suggest that SUMOylation could serve to buffer transcriptional activation of AP-1 target genes.

Heat shock protein 27 (HSP27) accumulates in stressed cells and helps them to survive adverse conditions. We have already shown that HSP27 has a function in the ubiquitination process that is modulated by its oligomerization/phosphorylation status. Here, we show that HSP27 is also involved in protein sumoylation, a ubiquitination-related process. HSP27 increases the number of cell proteins modified by small ubiquitin-like modifier (SUMO)-2/3 but this effect shows some selectivity as it neither affects all proteins nor concerns SUMO-1. Moreover, no such alteration in SUMO-2/3 conjugation is achievable by another HSP, such as HSP70. Heat shock factor 1 (HSF1), a transcription factor responsible for HSP expression, is one of the targets of HSP27. In stressed cells, HSP27 enters the nucleus and, in the form of large oligomers, binds to HSF1 and induces its modification by SUMO-2/3 on lysine 298. HSP27-induced HSF1 modification by SUMO-2/3 takes place downstream of the transcription factor phosphorylation on S303 and S307 and does not affect its DNA-binding ability. In contrast, this modification blocks HSF1 transactivation capacity. These data show that HSP27 exerts a feedback inhibition of HSF1 transactivation and enlighten the strictly regulated interplay between HSPs and HSF1. As we also show that HSP27 binds to the SUMO-E2-conjugating enzyme, Ubc9, our study raises the possibility that HSP27 may act as a SUMO-E3 ligase specific for SUMO-2/3.

JunB, an activator protein-1 (AP-1) transcription factor component, acts either as a tumor suppressor or as an oncogene depending on the cell context. In particular, JunB is strongly upregulated in anaplastic lymphoma kinase (ALK)-positive anaplastic large cell lymphoma (ALCL) where it enhances cell proliferation. Although its overexpression is linked to lymphomagenesis, the mechanisms whereby JunB promotes neoplastic growth are still largely obscure. Here, we show that JunB undergoes coordinated phosphorylation-dependent ubiquitylation during the G2 phase of the cell cycle. We characterized a critical consensus phospho-degron that controls JunB turnover and identified GSK3 and SCF FBXW7 as, respectively, the kinase and the E3 ubiquitin ligase responsible for its degradation in G2. Pharmacological or genetic inactivation of the GSK3-FBXW7-JunB axis induced accumulation of JunB in G2/M and entailed transcriptional repression of the DNA helicase DDX11, leading to premature sister chromatid separation. This abnormal phenotype due to dysregulation of the GSK3β/JunB/DDX11 pathway is phenocopied in ALK-positive ALCL. Thus, our results reveal a novel mechanism by which mitosis progression and chromatid cohesion are regulated through GSK3/SCF FBXW7 -mediated proteolysis of JunB, and suggest that JunB proteolysis in G2 is an essential step in maintaining genetic fidelity during mitosis.

Multiple tumorigenic pathways converge on the activating protein-1 (AP-1) family of dimeric transcription complexes by affecting transcription, mRNA decay, posttranslational modifications, as well as stability of its JUN and FOS components. Several mechanisms have been implicated in the phosphorylation- and ubiquitylation-dependent control of c-Jun protein stability. Although its dimer composition has a major role in the regulation of AP-1, little is known about the influence of heterodimerization partners on the half-life of c-Jun. The FOS family member Fra-1 is overexpressed in various tumors and cancer cell lines wherein it controls motility, invasiveness, cell survival and cell division. Oncogene-induced accumulation of Fra-1 results from both increased transcription and phosphorylation-dependent stabilization of the protein. In this report, we describe a novel role of Fra-1 as a posttranslational regulator of c-Jun. By using both constitutively and inducible transformed rat thyroid cell lines, we found that c-Jun is stabilized in response to RAS oncoprotein expression. This stabilization requires the activity of the extracellular signal-related kinase (ERK) pathway, along with c-Jun heterodimerization with Fra-1. In particular, heterodimerization with Fra-1 inhibits c-Jun breakdown by a mechanism dependent on the phosphorylation of the Fra-1 C-terminal domain that positively controls the stability of the protein in response to ERK signaling. Therefore, Fra-1 modulates AP-1 dimer composition by promoting the accumulation of c-Jun in response to oncogenic RAS signaling.

JunB, an activator protein-1 (AP-1) transcription factor component, acts either as a tumor suppressor or as an oncogene depending on the cell context. In particular, JunB is strongly upregulated in anaplastic lymphoma kinase (ALK)-positive anaplastic large cell lymphoma (ALCL) where it enhances cell proliferation. Although its overexpression is linked to lymphomagenesis, the mechanisms whereby JunB promotes neoplastic growth are still largely obscure. Here, we show that JunB undergoes coordinated phosphorylation-dependent ubiquitylation during the G2 phase of the cell cycle. We characterized a critical consensus phosphodegron that controls JunB turnover and identified GSK3 and [SCF.sup.FBXW7] as, respectively, the kinase and the E3 ubiquitin ligase responsible for its degradation in G2. Pharmacological or genetic inactivation of the GSK3-FBXW7-JunB axis induced accumulation of JunB in G2/M and entailed transcriptional repression of the DNA helicase DDX11, leading to premature sister chromatid separation. This abnormal phenotype due to dysregulation of the GSK3P/JunB/DDX11 pathway is phenocopied in ALK-positive ALCL. Thus, our results reveal a novel mechanism by which mitosis progression and chromatid cohesion are regulated through GSK3/[SCF.sup.FBXW7]-mediated proteolysis of JunB, and suggest that JunB proteolysis in G2 is an essential step in maintaining genetic fidelity during mitosis.

Meeting abstracts - A single PDF containing all abstracts in this Supplement is available at http://www.biomedcentral.com/content/files/pdf/1742-4690-6-S2-full.pdf.EMPTYUrl: http://www.biomedcentral.com/content/pdf/1742-4690-6-S2-info.pdf HIV-1 can infect and replicate in both CD4 T cells and macrophages, and direct cell-to-cell spread is an important route of HIV-1 propagation. Furthermore, this autophagy process is required to trigger CD4 T cell apoptosis since blockade of autophagy at different steps, by either drugs or short interfering RNAs specific for autophagy genes, totally inhibits Env-mediated apoptosis.

Cyclin C belongs to the cyclin family of proteins that control cell cycle transitions through activation of specific catalytic subunits, the cyclin-dependent kinases (CDKs). However, there is as yet no evidence for any role of cyclin C and its partner, cdk8, in cell cycle regulation. Rather, the cyclin C-cdk8 complex was found associated with the RNA polymerase II transcription machinery. The periodic degradation of bona fide cyclins is crucial for cell-cycle progression and depends on the catalytic activity of the associated CDK. Here we show that endogenous cyclin C protein is quite stable with a half-life of 4 h. In contrast, exogenously expressed cyclin C is very unstable (half-life 15 min) and degraded by the ubiquitin-proteasome pathway. Co-expression with its associated cdk, however, strongly stabilizes cyclin C and results in a protein half-life near that of endogenous cyclin C. In stark contrast to data reported for other members of the cyclin family, both catalytically active and inactive cdk8 induce cyclin C stabilization. Moreover, this stabilization is accompanied in both cases by phosphorylation of the cyclin, which is not detectable when unstable. Our results indicate that cyclin C has apparently diverged from other cyclins in the regulation of its stability by its CDK partner.