Sp1 is required for transforming growth factor-beta-induced mesenchymal transition and migration in pancreatic cancer cells.

Transition from a sessile epithelial phenotype to a migrating mesenchymal phenotype is a crucial step in transforming growth factor-beta (TGF-beta)-induced pancreatic cancer cell migration and invasion. These profound morphologic and functional alterations are associated with characteristic changes in TGF-beta-regulated gene expression, defined by rapid repression of epithelial markers and a strong and sustained transcriptional induction of mesenchymal markers such as the intermediate filament vimentin. In this study, we have analyzed the role of the transcription factor Sp1 in TGF-beta-induced and Smad-mediated gene regulation during epithelial to mesenchymal transition (EMT) and migration of pancreatic cancer cells. Here, we show that Sp1 is required for TGF-beta-induced EMT, and that this function is especially mediated through transcriptional induction of vimentin. Our results emphasize the functional relevance of vimentin in TGF-beta-induced EMT because prevention of its induction strongly reduces cell migration. Altogether, this study helps to better understand the role of Sp1 in TGF-beta-induced progression of pancreatic cancer. It suggests that Sp1, via transcriptional induction of vimentin, cooperates with activated Smad complexes in mesenchymal transition and migration of pancreatic cancer cells upon TGF-beta stimulation.

A quasi-lentiviral green fluorescent protein reporter exhibits nuclear export features of late human immunodeficiency virus type 1 transcripts.

We have previously shown that Rev-dependent expression of HIV-1 Gag from CMV immediate early promoter critically depends on the AU-rich codon bias of the gag gene. Here, we demonstrate that adaptation of the green fluorescent protein (GFP) reporter gene to HIV codon bias is sufficient to turn this hivGFP RNA into a quasi-lentiviral message following the rules of late lentiviral gene expression. Accordingly, GFP expression was significantly decreased in transfected cells strictly correlating with reduced RNA levels. In the presence of the HIV 5' major splice donor, the hivGFP RNAs were stabilized in the nucleus and efficiently exported to the cytoplasm following fusion of the 3' Rev-responsive element (RRE) and coexpression of HIV-1 Rev. This Rev-dependent translocation was specifically inhibited by leptomycin B suggesting export via the CRM1-dependent pathway used by late lentiviral transcripts. In conclusion, this quasi-lentiviral reporter system may provide a new platform for developing sensitive Rev screening assays.

Smad-Sp1 complexes mediate TGFbeta-induced early transcription of oncogenic Smad7 in pancreatic cancer cells.

The transcription factor Sp1 has been implicated in cell-type-specific activation of transforming growth factor-beta (TGFbeta) target genes in normal epithelial cells as well as in aberrant gene activation by TGFbeta in epithelial tumor cells. Here, we have examined the interaction of Sp1 with components of the Smad signaling cascade and its role in TGFbeta-induced early gene expression in pancreatic cancer cells. Gene expression profiling was carried out in mithramycin-A-treated cells to identify Sp1-regulated TGFbeta early response genes. We found that in pancreatic cancer cells Smad proteins and Sp1 cooperatively regulate expression of a distinct set of TGFbeta target genes potentially involved in tumor progression, including MMP-11, cyclin D1 and Smad7. Mechanistically, TGFbeta rapidly induces nuclear translocation of Smad proteins and subsequently stimulates Smad-Sp1 complex formation. Using the Smad7 promoter as a model for Smad-/Sp1-induced early gene activation, we demonstrated that this interaction increases Sp1 binding to GC-rich promoter boxes and results in superinduction of Sp1-mediated transcription. Moreover, inhibition of Sp1-DNA binding or transfection of Sp1-specific siRNA prevents TGFbeta-induced Smad7 expression and consequently enhances Smad signaling in pancreatic cancer cells, as indicated by increased receptor-mediated phosphorylation of Smad3. We thus conclude that Sp1 strongly contributes to the aberrant transcriptional response of transformed epithelial cells to TGFbeta stimulation.

KLF11 mediates a critical mechanism in TGF-beta signaling that is inactivated by Erk-MAPK in pancreatic cancer cells.

BACKGROUND & AIMS: Smad-regulated transcription plays a central role in transforming growth factor (TGF)-beta-induced cell growth inhibition and tumor suppression. Like the Smads, KLF11 is an early response transcription factor that mediates TGF-beta-induced growth inhibition in untransformed epithelial cells. Here, we investigated the functional implications of KLF11 in TGF-beta signaling and transcription in normal epithelial as well as pancreatic cancer cells. METHODS: The effects of KLF11 on TGF-beta signaling and transcription were examined on the levels of reporter transactivation, Smad2 phosphorylation, and expression of endogenous TGF-beta-regulated genes. Promoter analysis, real-time polymerase chain reaction, and coimmunoprecipitation studies were performed to study KLF11-induced and mSin3A corepressor-mediated repression of Smad7. Erk-induced KLF11 phosphorylation was examined in vitro and in vivo, and its impact on KLF11-mSin3A-mediated Smad7 repression was verified in pancreatic cancer cells using site-directed mutagenesis. RESULTS: KLF11 potentiates TGF-beta signaling by terminating the inhibitory Smad7 loop. Mechanistically, KLF11 represses TGF-beta-induced transcription from the Smad7 promoter by recruiting mSin3a via GC-rich sites. This function is inhibited in pancreatic cancer cells with oncogenic Ras mutations, in which Erk/mitogen-activated protein kinase phosphorylates KLF11, leading to disruption of KLF11-mSin3a interaction. Expression of an Erk-insensitive KLF11 mutant restores both mSin3a binding and Smad7 repression and results in enhanced TGF-beta signaling in pancreatic cancer cells. CONCLUSIONS: These results define a novel mechanism in TGF-beta-regulated gene expression. KLF11 potentiates Smad-signaling activity in normal epithelial cells through termination of the negative feedback loop imposed by Smad7. The fact that this function of KLF11 is inhibited by oncogenic Erk/mitogen-activated protein kinase in pancreatic cancer cells emphasizes the importance of this mechanism for oncogenesis.