Here we report the isolation of a cDNA encoding a new p53‐associating protein. This new protein has been called MDMX on the basis of its structural similarity to MDM2, which is especially notable in the p53‐binding domain. In addition, the putative metal binding domains in the C‐terminal part of MDM2 are completely conserved in MDMX. The middle part of the MDMX and MDM2 proteins shows a low degree of conservation. We can show by co‐immunoprecipitation that the MDMX protein interacts specifically with p53 in vivo. This interaction probably occurs with the N‐terminal part of p53, because the activity of the transcription activation domain of p53 was inhibited by co‐transfection of MDMX. Northern blotting showed that MDMX, like MDM2, is expressed in all tissues tested, and that several mRNAs for MDMX can be detected. Interestingly, the level of MDMX mRNA is unchanged after UV irradiation, in contrast to MDM2 transcription. This observation suggests that MDMX may be a differently regulated modifier of p53 activity in comparison with MDM2. Our study indicates that at least one additional member of the MDM protein family exists which can modulate p53 function.
Functional inactivation of the pRB pathway is a very frequent event in human cancer, resulting in deregulated activity of the E2F transcription factors. To understand the functional role of the E2Fs in cell proliferation, we have developed cell lines expressing E2F-1, E2F-2, and E2F-3 fused to the estrogen receptor ligand binding domain (ER). In this study, we demonstrated that activation of all three E2Fs could relieve the mitogen requirement for entry into S phase in Rat1 fibroblasts and that E2F activity leads to a shortening of the G 0 -G 1 phase of the cell cycle by 6 to 7 h. In contrast to the current assumption that E2F-1 is the only E2F capable of inducing apoptosis, we showed that deregulated E2F-2 and E2F-3 activities also result in apoptosis. Using the ERE2F-expressing cell lines, we demonstrated that several genes containing E2F DNA binding sites are efficiently induced by the E2Fs in the absence of protein synthesis. Furthermore, CDC25A is defined as a novel E2F target whose expression can be directly regulated by E2F-1. Data showing that CDC25A is an essential target for E2F-1, since its activity is required for efficient induction of S phase by E2F-1, are provided. Finally, our results show that expression of two E2F target genes, namely CDC25A and cyclin E, is sufficient to induce entry into S phase in quiescent fibroblasts. Taken together, our results provide an important step in defining how E2F activity leads to deregulated proliferation.
E2F transcription factors are key regulators of transcription during the cell cycle. E2F activity is regulated at the level of transcription and DNA binding and by complex formation with the retinoblastoma pocket protein family. We show here that free E2F-1 and E2F-4 transcription factors are unstable and that their degradation is mediated by the ubiquitin-proteasome pathway. Both E2F-I and E2F-4 are rendered unstable by an epitope in the carboxyl terminus of the proteins, in close proximity to their pocket protein interaction surface. We show that binding of E2F-1 to pRb or E2F-4 to p107 or p130 protects E2Fs from degradation, causing the complexes to be stable. The increased stability of E2F-4 pocket protein complexes may contribute to the maintenance of active transcriptional repression in quiescent cells. Surprisingly, adenovirus transforming proteins, which release pocket protein-E2F complexes, also inhibit breakdown of free E2F. These data reveal an additional level of regulation of E2F transcription factors by targeted proteolysis, which is inhibited by pocket protein binding and adenovirus early region 1 transforming proteins.
The E2F transcription factors are essential regulators of cell growth in multicellular organisms, controlling the expression of a number of genes whose products are involved in DNA replication and cell proliferation. In Saccharomyces cerevisiae, the MBF and SBF transcription complexes have functions similar to those of E2F proteins in higher eukaryotes, by regulating the timed expression of genes implicated in cell cycle progression and DNA synthesis. The CDC6 gene is a target for MBF and SBF-regulated transcription. S. cerevisiae Cdc6p induces the formation of the prereplication complex and is essential for initiation of DNA replication. Interestingly, the Cdc6p homolog in Schizosaccharomyces pombe, Cdc18p, is regulated by DSC1, the S. pombe homolog of MBF. By cloning the promoter for the human homolog of Cdc6p and Cdc18p, we demonstrate here that the cell cycle-regulated transcription of this gene is dependent on E2F. In vivo footprinting data demonstrate that the identified E2F sites are occupied in resting cells and in exponentially growing cells, suggesting that E2F is responsible for downregulating the promoter in early phases of the cell cycle and the subsequent upregulation when cells enter S phase. Our data also demonstrate that the human CDC6 protein (hCDC6) is essential and limiting for DNA synthesis, since microinjection of an anti-CDC6 rabbit antiserum blocks DNA synthesis and CDC6 cooperates with cyclin E to induce entry into S phase in cotransfection experiments. Furthermore, E2F is sufficient to induce expression of the endogenous CDC6 gene even in the absence of de novo protein synthesis. In conclusion, our results provide a direct link between regulated progression through G 1 controlled by the pRB pathway and the expression of proteins essential for the initiation of DNA replication.Although E2F was originally defined as a factor that binds specifically to an element in the adenovirus E2 promoter (42), it is now evident that E2F is essential for coordinating transcription during the mammalian cell cycle (for reviews, see references 12 and 72). A number of genes are found to be regulated by E2F, particularly during the transition from G 1 to S phase. To date, six members of the E2F family are known: E2F-1 through E2F-5 and the recently identified E2F-6 (11). Furthermore, two heterodimerization partners of the E2Fs, DP-1 and DP-2, have been isolated. The E2F transcription factors appear to be key downstream targets for the retinoblastoma protein pRB and two pRB-related proteins, p107 and p130 (reviewed in references 12 and 70). Binding of pRB family members (also called pocket proteins) to the E2F transcription factors results in transcriptional repression of E2F-regulated genes. Phosphorylation of the pocket proteins by cyclin-dependent kinases releases the pocket proteins from E2F, leading to derepression and/or activation of E2F-dependent genes and subsequent entry into S phase. The demonstration that deregulated E2F activity is sufficient to induce S phase in quiescent cells has provided a m...
Murine/human ubiquitin-conjugating enzyme Ubc9 is a functional homolog of Saccharomyces cerevisiae Ubc9 that is essential for the viability of yeast cells with a specific role in the G 2 -M transition of the cell cycle. The structure of recombinant mammalian Ubc9 has been determined from two crystal forms at 2.0 Å resolution. Like Arabidopsis thaliana Ubc1 and S. cerevisiae Ubc4, murine/human Ubc9 was crystallized as a monomer, suggesting that previously reported hetero-and homointeractions among Ubcs may be relatively weak or indirect. Compared with the known crystal structures of Ubc1 and Ubc4, which regulate different cellular processes, Ubc9 has a 5-residue insertion that forms a very exposed tight -hairpin and a 2-residue insertion that forms a bulge in a loop close to the active site. Mammalian Ubc9 also possesses a distinct electrostatic potential distribution that may provide possible clues to its remarkable ability to interact with other proteins. The 2-residue insertion and other sequence and structural heterogeneity observed at the catalytic site suggest that different Ubcs may utilize catalytic mechanisms of varying efficiency and substrate specificity.Conjugation of ubiquitin to various eukaryotic cellular proteins regulates their activities by controlling protein concentration through ubiquitin-directed degradation (1-4) or by directly modifying protein function through the attached ubiquitin molecules (5). The formation of ubiquitin-protein conjugates proceeds via a cascade of reactions that involve two, or often three, enzymes: the ubiquitin-activating enzyme E1, 1 the ubiquitin-conjugating enzyme Ubc (E2), and the ubiquitin-ligating enzyme E3 (6 -8). The first step is the ATP-assisted formation of a high energy thioester bond between ubiquitin and E1. Ubiquitin is then transferred to a conserved cysteine group of Ubc. In some ubiquitin pathways, Ubc alone, or in cooperation with E3, attaches ubiquitin to the ⑀-amino group of a lysine residue of a substrate via an isopeptide bond. In others, Ubc first passes ubiquitin to a thiol group of E3, and then E3 attaches it to the substrate. Repeated conjugation of ubiquitin to lysine residues of previously bound ubiquitin moieties is required for proteolysis of the substrates by the 26 S proteasome (9). A large body of genetic and biochemical evidence indicates that the Ubcs, together with E3s, are the primary determi-
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.