Regulation of chromatin is an important aspect of controlling promoter activity and gene expression. Posttranslational modifications of core histones allow proteins associated with gene transcription to access chromatin. Closely associated with promoters of actively transcribed genes, trimethylation of histone H3 at lysine 4 (H3K4me3) is a core histone mark set by several protein complexes. Some of these protein complexes contain the trithorax protein ASH2 combined with the MLL oncoproteins. We identified human ASH2 in a complex with the oncoprotein MYC. This finding, together with the observation that hASH2 interacts with MLL, led us to test whether hASH2 itself is involved in transformation. We observed that hASH2 cooperates with Ha-RAS to transform primary rat embryo fibroblasts (REF). Furthermore, transformation of REFs by MYC and Ha-RAS required the presence of rAsh2. In an animal model, the hASH2/Ha-RAS-transformed REFs formed rapidly growing tumors characteristic of fibrosarcomas that, compared with tumors derived from MYC/Ha-RAS transformed cells, were poorly differentiated. This finding suggests that ASH2 functions as an oncoprotein. Although hASH2 expression at the mRNA level was generally not deregulated, hASH2 protein expression was increased in most human tumors and tumor cell lines. In addition, knockdown of hASH2 inhibited tumor cell proliferation. Taken together, these observations define hASH2 as a novel oncoprotein. [Cancer Res 2008;68(3):749-58]
Poly(ADP-ribosyl)ation of mutant and wild-type p53 was studied in transformed and nontransformed rat cell lines constitutively expressing the temperature-sensitive p53135val. It was found that in both cell types at 37.5 degrees C, where overexpressed p53 exhibits mutant conformation and cytoplasmic localization, a considerable part of the protein was poly(ADP-ribosyl)ated. Using densitometric scanning, the molecular mass of the modified protein was estimated as 64 kD. Immunofluorescence studies with affinity purified anti-poly(ADP-ribose) transferase (pADPRT) antibodies revealed that, contrary to predictions, the active enzyme was located in the cytoplasm, while in nuclei chromatin was depleted of pADPRT. A distinct intracellular localization and action of pADPRT was found in the cell lines cultivated at 32.5 degrees C, where p53 adopts wild-type form. Despite nuclear coexistence of both proteins no significant modification of p53 was found. Since the strikingly shared compartmentalization of p53 and pADPRT was indicative of possible complex formation between the two proteins, reciprocal immunoprecipitation and immunoblotting were performed with anti-p53 and anti-pADPRT antibodies. A poly(ADP-ribosyl)ated protein of 116 kD constantly precipitated at stringent conditions was identified as the automodified enzyme. It is concluded that mutant cytoplasmic p53 is tightly complexed to pADPRT and becomes modified. At 32.5 degrees C binding to DNA of p53 or its temperature-dependent conformational alteration might prevent an analogous modification of the tumor suppressor protein.
The proto-oncoprotein c-Myc and the multifunctional transcriptional regulator YY1 have been shown previously to interact directly in a manner that excludes Max from the complex (Shrivastava et al., 1993). As binding to Max is necessary for all known c-Myc activities we have analysed the in¯uence of YY1 on cMyc function. We demonstrate that YY1 is a potent inhibitor of c-Myc transforming activity. The region in YY1 required for inhibition corresponds to a functional DNA-binding domain and is distinct from the domains necessary for direct binding to c-Myc. Furthermore the transactivation domain of YY1 was not necessary suggesting that gene regulation by YY1, for example through DNA bending or displacement of regulators from DNA, could be the cause for the negative regulation of c-Myc. This model of indirect regulation of c-Myc by YY1 was supported by the ®nding that although YY1 did not bind to the c-Myc transactivation domain (TAD) in vitro it was able to inhibit transactivation by Gal4-MycTAD fusion proteins in transient transfections. As for the inhibition of transformation, an intact DNA-binding domain of YY1 was necessary and sucient for this eect. In addition YY1 did not alter c-Myc/Max DNA binding, further supporting an indirect mode of action. Our ®ndings point to a role of YY1 as a negative regulator of cell growth with a possible involvement in tumor suppression.
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