Martin Eilers

The β-catenin/TCF-4 complex imposes a crypt progenitor phenotype on colorectal cancer cells

The transactivation of TCF target genes induced by Wnt pathway mutations constitutes the primary transforming event in colorectal cancer (CRC). We show that disruption of β-catenin/TCF-4 activity in CRC cells induces a rapid G1 arrest and blocks a genetic program that is physiologically active in the proliferative compartment of colon crypts. Coincidently, an intestinal differentiation program is induced. The TCF-4 target gene c-MYC plays a central role in this switch by direct repression of the p21CIP1/WAF1 promoter. Following disruption of β-catenin/TCF-4 activity, the decreased expression of c-MYC releases p21CIP1/WAF1 transcription, which in turn mediates G1 arrest and differentiation. Thus, the β-catenin/TCF-4 complex constitutes the master switch that controls proliferation versus differentiation in healthy and malignant intestinal epithelial cells.

Repression of p15INK4b expression by Myc through association with Miz-1

Deregulated expression of c-myc can induce cell proliferation in established cell lines and in primary mouse embryonic fibroblasts (MEFs), through a combination of both transcriptional activation and repression by Myc. Here we show that a Myc-associated transcription factor, Miz-1, arrests cells in G1 phase and inhibits cyclin D-associated kinase activity. Miz-1 upregulates expression of the cyclin-dependent kinases (CDK) inhibitor p15INK4b by binding to the initiator element of the p15INK4b promoter. Myc and Max form a complex with Miz-1 at the p15 initiator and inhibit transcriptional activation by Miz-1. Expression of Myc in primary cells inhibits the accumulation of p15INK4b that is associated with cellular senescence; conversely, deletion of c-myc in an established cell line activates p15INK4b expression. Alleles of c-myc that are unable to bind to Miz-1 fail to inhibit accumulation of p15INK4b messenger RNA in primary cells and are, as a consequence, deficient in immortalization.

TGF|[beta]| influences Myc, Miz-1 and Smad to control the CDK inhibitor p15INK4b

Transforming growth factor-β (TGFβ) is a cytokine that arrests epithelial cell division by switching off the proto-oncogene c-myc and rapidly switching on cyclin-dependent kinase (CDK) inhibitors such as p15INK4b. Gene responses to TGFβ involve Smad transcription factors that are directly activated by the TGFβ receptor. Why downregulation of c-myc expression by TGFβ is required for rapid activation of p15INK4b has remained unknown. Here we provide evidence that TGFβ signalling prevents recruitment of Myc to the p15INK4b transcriptional initiator by Myc-interacting zinc-finger protein 1 (Miz-1). This relieves repression and enables transcriptional activation by a TGFβ-induced Smad protein complex that recognizes an upstream p15INK4b promoter region and contacts Miz-1. Thus, two separate TGFβ-dependent inputs — Smad-mediated transactivation and relief of repression by Myc — keep tight control over p15INK4b activation.

The ubiquitin ligase HectH9 regulates transcriptional activation by Myc and is essential for tumor cell proliferation.

The Myc oncoprotein forms a binary activating complex with its partner protein, Max, and a ternary repressive complex that, in addition to Max, contains the zinc finger protein Miz1. Here we show that the E3 ubiquitin ligase HectH9 ubiquitinates Myc in vivo and in vitro, forming a lysine 63-linked polyubiquitin chain. Miz1 inhibits this ubiquitination. HectH9-mediated ubiquitination of Myc is required for transactivation of multiple target genes, recruitment of the coactivator p300, and induction of cell proliferation by Myc. HectH9 is overexpressed in multiple human tumors and is essential for proliferation of a subset of tumor cells. Our results suggest that site-specific ubiquitination regulates the switch between an activating and a repressive state of the Myc protein, and they suggest a strategy to interfere with Myc function in vivo.

Activation of an inducible c-FosER fusion protein causes loss of epithelial polarity and triggers epithelial-fibroblastoid cell conversion

As a novel approach to studying the modulation of the polarized epithelial phenotype, we have expressed c-Fos and c-Myc estrogen receptor fusion proteins (c-FosER and c-MycER) in mammary epithelial cells. The hybrid proteins could be activated by estrogen for defined time periods and after the cells had achieved their fully polarized organization. Activation of c-MycER deregulated proliferation but did not affect epithelial polarity. Short-term activation of c-FosER induced the reversible loss of morphological and functional cell polarity. In contrast, long-term stimulation of c-FosER caused the cells to depolarize irreversibly, to invade collagen gels, and to undergo epithelial-fibroblastoid cell conversion. Our data suggest that Fos proteins are important in modulating the epithelial phenotype both in normal tissue development and in invasive processes.

Control of cell proliferation by Myc

Myc proteins are key regulators of mammalian cell proliferation. They are transcription factors that activate genes as part of a heterodimeric complex with the protein Max. This review summarizes recent progress in understanding how Myc stimulates cell proliferation and how this might contribute to cellular transformation and tumorigenesis.

Compassionate use of sorafenib in FLT3-ITD-positive acute myeloid leukemia: sustained regression before and after allogeneic stem cell transplantation.

Acute myeloid leukemia (AML) patients with internal tandem duplication (ITD) mutations in the Fms-like tyrosine-3 (FLT3) gene have a dismal prognosis. Here we report compassionate-use results with the multikinase and FLT3-ITD inhibitor sorafenib for the treatment of relapsed or refractory FLT3-ITD-positive AML. Sorafenib induced clinically meaningful and very rapid responses in all 6 patients treated either before (n = 2), after (n = 3), or both before and after (n = 1) allogeneic stem cell transplantation (allo-SCT). Sorafenib-induced remissions facilitated allo-SCT in 2 of the 3 refractory patients. Two of the 4 patients who were treated after allo-SCT survived 216 and 221 days, respectively, whereas the other 2 remain in ongoing complete molecular remission. Sorafenib response was associated with an inhibition of the antiapoptotic FLT3-ITD target Stat-5 in vivo. Together, sorafenib monotherapy before or after allo-SCT has remarkable clinical activity in poor risk FLT3-ITD-positive AML and deserves further evaluation in prospective clinical trials.

Activation and repression by oncogenic MYC shape tumour-specific gene expression profiles

In mammalian cells, the MYC oncoprotein binds to thousands of promoters. During mitogenic stimulation of primary lymphocytes, MYC promotes an increase in the expression of virtually all genes. In contrast, MYC-driven tumour cells differ from normal cells in the expression of specific sets of up- and downregulated genes that have considerable prognostic value. To understand this discrepancy, we studied the consequences of inducible expression and depletion of MYC in human cells and murine tumour models. Changes in MYC levels activate and repress specific sets of direct target genes that are characteristic of MYC-transformed tumour cells. Three factors account for this specificity. First, the magnitude of response parallels the change in occupancy by MYC at each promoter. Functionally distinct classes of target genes differ in the E-box sequence bound by MYC, suggesting that different cellular responses to physiological and oncogenic MYC levels are controlled by promoter affinity. Second, MYC both positively and negatively affects transcription initiation independent of its effect on transcriptional elongation. Third, complex formation with MIZ1 (also known as ZBTB17) mediates repression of multiple target genes by MYC and the ratio of MYC and MIZ1 bound to each promoter correlates with the direction of response.

Cdk2-dependent phosphorylation of p27 facilitates its Myc-induced release from cyclin E/cdk2 complexes

Activation of Myc triggers a rapid induction of cyclin E/cdk2 kinase activity and degradation of p27. Overt degradation of p27 is preceded by a specific dissociation of p27 from cyclin E/cdk2, but not from cyclin D/cdk4 complexes. We now show that cyclin E/cdk2 phosphorylates p27 at a carboxy-terminal threonine residue (T187) in vitro; mutation of this residue to valine stabilises cyclin E/cdk2 complexes. This reaction is not significantly inhibited by high concentrations of p27, suggesting that cdk2 bound to p27 is catalytically active. In vivo, p27 bound to cyclins E and A, but not to D-type cyclins is phosphorylated. Myc-induced release of p27 from cdk2 requires cdk2 kinase activity and is delayed in a T187V mutant of p27. After induction of Myc, p27 phosphorylated at threonine 187 transiently accumulates in a non cdk2 bound form. Our data suggest a mechanism in which p27 is released from cyclin E/cdk2 upon phosphorylation; in Myc-transformed cells, release is efficient as phosphorylated p27 is transiently bound in a non-cdk2 containing complex and subsequently degraded.

Transcriptional activation by Myc is under negative control by the transcription factor AP-2.

The Myc protein binds to and transactivates the expression of genes via E‐box elements containing a central CAC(G/A)TG sequence. The transcriptional activation function of Myc is required for its ability to induce cell cycle progression, cellular transformation and apoptosis. Here we show that transactivation by Myc is under negative control by the transcription factor AP‐2. AP‐2 inhibits transactivation by Myc via two distinct mechanisms. First, high affinity binding sites for AP‐2 overlap Myc‐response elements in two bona fide target genes of Myc, prothymosin‐alpha and ornithine decarboxylase. On these sites, AP‐2 competes for binding of either Myc/Max heterodimers or Max/Max homodimers. The second mechanism involves a specific interaction between C‐terminal domains of AP‐2 and the BR/HLH/LZ domain of Myc, but not Max or Mad. Binding of AP‐2 to Myc does not preclude association of Myc with Max, but impairs DNA binding of the Myc/Max complex and inhibits transactivation by Myc even in the absence of an overlapping AP‐2 binding site. Taken together, our data suggest that AP‐2 acts as a negative regulator of transactivation by Myc.