Recruitment of TRRAP required for oncogenic transformation by E1A (original) (raw)

TRRAP-Dependent and TRRAP-Independent Transcriptional Activation by Myc Family Oncoproteins

Molecular and Cellular Biology, 2002

We demonstrate that transformation-transactivation domain-associated protein (TRRAP) binding and the recruitment of histone H3 and H4 acetyltransferase activities are required for the transactivation of a silent telomerase reverse transcriptase (TERT) gene in exponentially growing human fibroblasts by c-Myc or N-Myc protein. However, recruitment of TRRAP by c-or N-Myc is dispensable for the partial induction of several basally expressed genes in exponentially growing primary and immortalized fibroblasts. Furthermore, recruitment of TRRAP is required for c-Myc-or N-Myc-mediated oncogenic transformation but not for the partial restoration of the growth defect in myc-null fibroblasts. A segment of the adenovirus E1A protein fused to a transformation-defective N-Myc protein carrying a small deletion in the transactivation domain specifically restores interaction with TRRAP, activates the silent TERT gene, induces acetylation of histones H3 and H4 at the TERT promoter, and transforms primary cells. Accordingly, wild-type L-Myc is much less efficient in TRRAP binding, activation of the silent TERT gene, and transformation of primary fibroblasts. Nevertheless, L-Myc is a potent activator of several basally expressed genes and can fully restore the growth defect of myc-null cells. These results suggest a differential requirement for TRRAP for several Myc-mediated activities.

Adenovirus Small e1a Alters Global Patterns of Histone Modification

Science, 2008

Adenovirus small early region 1a (e1a) protein drives cells into S phase by binding RB family proteins and the closely related histone acetyl transferases p300 and CBP. The interaction with RB proteins displaces them from DNA-bound E2F transcription factors, reversing their repression of cell cycle genes. However, it has been unclear how the e1a interaction with p300 and CBP promotes passage through the cell cycle. We show that this interaction causes a threefold reduction in total cellular histone H3 lysine 18 acetylation (H3K18ac). CBP and p300 are required for acetylation at this site because their knockdown causes specific hypoacetylation at H3K18. SV40 T antigen also induces H3K18 hypoacetylation. Because global hypoacetylation at this site is observed in prostate carcinomas with poor prognosis, this suggests that processes resulting in global H3K18 hypoacetylation may be linked to oncogenic transformation.

Adenovirus Transforming Protein E1A Induces c-Myc in Quiescent Cells by a Novel Mechanism

Journal of Virology, 2009

Previously we showed that the E1A binding proteins p300 and CBP negatively regulate c-Myc in quiescent cells and that binding of E1A to p300 results in the induction of c-Myc and thereby induction of S phase. We demonstrated that p300 and HDAC3 cooperate with the transcription factor YY1 at an upstream YY1 binding site and repress the Myc promoter. Here we show that the small E1A protein induces c-Myc by interfering with the protein-protein interaction between p300, YY1, and HDAC3. Wild-type E1A but not the E1A mutants that do not bind to p300 interfered in recruitment of YY1, p300, and HDAC3 to the YY1 binding site. As E1A started to accumulate after infection, it transiently associated with promoter-bound p300. Subsequently, YY1, p300, and HDAC3 began to dissociate from the promoter. Later in infection, E1A dissociated from the promoter as well as p300, YY1, and HDAC3. Removal of HDAC3 from the promoter correlated with increased acetylation of Myc chromatin and induction. In vivo ...

Adenovirus E1A oncoprotein liberates c‐Myc activity to promote cell proliferation through abating Bin1 expression via an Rb/E2F1‐dependent mechanism

Journal of cellular …, 2008

Adenovirus E1A oncogene transforms primary rodent fibroblasts in cooperation with activated Ras. Conversely, the c-Myc oncoprotein-binding tumor suppressor, Bin1, inhibits Ras/E1A-mediated cell transformation. Since E1A does not directly bind to and inhibit Bin1, the primary mechanism by which E1A counteracts Bin1 to liberate oncogenic c-Myc activity is poorly understood. Here we show that wild-type E1A, but not an Rb binding-defective E1A mutant, suppresses endogenous Bin1 expression in cultured rodent fibroblasts. Similarly, other anti-Rb agents, such as human papillomavirus E7, mitogenic stimuli, and small interfering RNA (siRNA) for Rb, consistently decrease Bin1 promoter activity. In contrast, serum starvation, which activates Rb, enhances endogenous Bin1 levels. These findings suggest that Bin1 may be a novel component of Rb-mediated G1 arrest. Consistent with this premise, chromatin immunoprecipitation assays demonstrate that Rb protein directly interacts with the Bin1 promoter only upon removal of serum. Furthermore, ectopically expressed E2F1, which is primarily inhibited by Rb under serum-starved condition, represses Bin1 promoter activity in a manner that is dependent on the DNA-binding and transactivation domains of E2F1. Lastly, depletion of endogenous Bin1 per se is biologically meaningful since antisense or siRNA of Bin1 transfection releases endogenous c-Myc transcriptional activity and, concomitantly, accelerates cell proliferation. Our results suggest that Bin1 gene suppression caused by oncogenic E1A via Rb inactivation is an essential step in cell cycle progression promoted by c-Myc, and subsequently, E1A transformation. We propose a novel G1 arrest signaling mechanism by which Rb indirectly curbs oncogenic c-Myc activity via sustaining Bin1 expression.

Deletion of the β-turn/α-helix motif at the exon 2/3 boundary of human c-Myc leads to the loss of its immortalizing function

Gene, 1993

The protein product (c-Myc) of the human c-myc proto-oncogene carries a B-turn/a-helix motif at the exon2/exon3 boundary. The amino acid (aa) sequence and secondary structure of this motif are highly conserved among several nuclearly localized oncogene products, c-Myc, N-Myc, c-Fos, SV40 large T and adenovirus (Ad) Ela. Removal of this region from Ad Ela results in the loss of the transforming properties of the virus without destroying its known transregulatory functions. In order to analyse whether deletion of the above-mentioned region from c-Myc has a similar effect on its transformation activity, we constructed a deletion mutant (c-mycA) lacking the respective aa at the exon2/exon3 boundary. In contrast to the c-myc wild-type gene product, constitutive expression of c-mycA does not lead to the immortalization of primary mouse embryo fibroblast cells (MEF cells). This result indicates that c-Myc and Ad Ela share a common domain which is involved in the transformation process by both oncogenes.

Relationship between E1A binding to cellular proteins, c-myc activation and S-phase induction

Oncogene, 2006

We recently showed that p300/CREB-binding protein (CBP) plays an important role in maintaining cells in G0/ G1 phase by keeping c-myc in a repressed state. Consistent with this, adenovirus E1A oncoprotein induces c-myc in a p300-dependent manner, and the c-myc induction is linked to S-phase induction. The induction of S phase by E1A is dependent on its binding to and inactivating several host proteins including p300/CBP. To determine whether there is a correlation between the host proteins binding to the N-terminal region of E1A, activation of c-myc and induction of S phase, we assayed the c-myc and S-phase induction in quiescent human cells by infecting them with Ad N-terminal E1A mutants with mutations that specifically affect binding to different chromatin-associated proteins including pRb, p300, p400 and p300/CBP-associated factor (PCAF). We show that the mutants that failed to bind to p300 or pRb were severely defective for c-myc and S-phase induction. The induction of c-myc and S phase was only moderately affected when E1A failed to bind to p400. Furthermore, analysis of the E1A mutants that fail to bind to p300, and both p300 and PCAF suggests that PCAF may also play a role in c-myc repression, and that the two chromatinassociated proteins may repress c-myc independently. In summary, these results suggest that c-myc deregulation by E1A through its interaction with these chromatin-associated proteins is an important step in the E1A-mediated cell cycle deregulation and possibly in cell transformation.

The Essential Cofactor TRRAP Recruits the Histone Acetyltransferase hGCN5 to c-Myc

Molecular and Cellular Biology, 2000

The c-Myc protein functions as a transcription factor to facilitate oncogenic transformation; however, the biochemical and genetic pathways leading to transformation remain undefined. We demonstrate here that the recently described c-Myc cofactor TRRAP recruits histone acetylase activity, which is catalyzed by the human GCN5 protein. Since c-Myc function is inhibited by recruitment of histone deacetylase activity through Mad family proteins, these opposing biochemical activities are likely to be responsible for the antagonistic biological effects of c-Myc and Mad on target genes and ultimately on cellular transformation.

Epigenetic Reprogramming by Adenovirus e1a

Science, 2008

Adenovirus e1a induces quiescent human cells to replicate. We found that e1a causes global relocalization of the RB (retinoblastoma) proteins (RB, p130, and p107) and p300/CBP histone acetyltransferases on promoters, the effect of which is to restrict the acetylation of histone 3 lysine-18 (H3K18ac) to a limited set of genes, thereby stimulating cell cycling and inhibiting antiviral responses and cellular differentiation. Soon after expression, e1a binds transiently to promoters of cell cycle and growth genes, causing enrichment of p300/CBP, PCAF (p300/CBP-associated factor), and H3K18ac; depletion of RB proteins; and transcriptional activation. e1a also associates transiently with promoters of antiviral genes, causing enrichment for RB, p130, and H4K16ac; increased nucleosome density; and transcriptional repression. At later times, e1a and p107 bind mainly to promoters of development and differentiation genes, repressing transcription. The temporal order of e1a binding requires its interactions with p300/CBP and RB proteins. Our data uncover a defined epigenetic reprogramming leading to cellular transformation.

Large E1B proteins of adenovirus types 5 and 12 have different effects on p53 and distinct roles in cell transformation

Journal of Virology, 1993

The formation of complexes between oncoproteins of DNA tumor viruses and the cellular protein p53 is thought to result in inactivation of the growth suppressor function of p53. In cells transformed by nononcogenic human adenovirus type 5 (Ad5), the 55-kDa protein encoded by E1B forms a stable complex with p53 and sequesters it in the cytoplasm. However, the homologous 54-kDa protein of highly oncogenic Ad12 does not detectably associate with p53. Yet in Ad12-transformed cells, p53 is metabolically stable, is present at high levels in the nucleus, and contributes to the oncogenicity of the cells. Such properties have previously been described for mutant forms of p53. Here, we show that stable p53 in Ad12-transformed cells is wild type rather than mutant and that stabilization of p53 is a direct consequence of the expression of the Ad12 E1B protein. We also compared the effects of the E1B proteins on transformation of rodent cells by different combinations of oncogenes. A synergistic ...