The coactivator CBP has been proposed to stimulate the expression of certain signal-dependent genes via its association with RNA polymerase II complexes. Here we show that complex formation between CBP and RNA polymerase II requires RNA helicase A (RHA), a nuclear DNA/RNA helicase that is related to the Drosophila male dosage compensation factor mle. In transient transfection assays, RHA was found to cooperate with CBP in mediating target gene activation via the CAMP responsive factor CREB. As a mutation in RHA that compromised its helicase activity correspondingly reduced CREB-dependent transcription, we propose that RHA may induce local changes in chromatin structure that promote engagement of the transcriptional apparatus on signal responsive promoters.
Nuclear factor 90 (NF90) and its C-terminally extended isoform, NF110, have been isolated as DNA-and RNA-binding proteins together with the less-studied protein NF45. These complexes have been implicated in gene regulation, but little is known about their cellular roles and whether they are redundant or functionally distinct. We show that heterodimeric core complexes, NF90-NF45 and NF110-NF45, exist within larger complexes that are more labile and contain multiple NF90/110 isoforms and additional proteins. Depletion of the NF45 subunit by RNA interference is accompanied by a dramatic decrease in the levels of NF90 and NF110. Reciprocally, depletion of NF90 but not of NF110 greatly reduces the level of NF45. Coregulation of NF90 and NF45 is a posttranscriptional phenomenon, resulting from protein destabilization in the absence of partners. Depletion of NF90-NF45 complexes retards cell growth by inhibition of DNA synthesis. Giant multinucleated cells containing nuclei attached by constrictions accumulate when either NF45 or NF90, but not NF110, is depleted. This study identified NF45 as an unstable regulatory subunit of NF90-NF45 complexes and uncovered their critical role in normal cell division. Furthermore, the study revealed that NF90 is functionally distinct from NF110 and is more important for cell growth.Human nuclear factor 90 (NF90) and nuclear factor 45 (NF45) were originally purified as a sequence-specific DNA binding complex regulating the interleukin-2 (IL-2) promoter (10, 17). NF90 is the founder member of a family of proteins generated from differentially spliced transcripts of the ILF3 gene (12). NF90 and NF110, which differ at their C termini, are the two most prominent ILF3 isoforms in cells (12,33,42,55). Both have been repeatedly isolated in diverse studies and have been given a variety of names. For example, MPP4 (M-phase phosphoprotein 4) is similar, if not identical, to NF90 and is phosphorylated during M phase (23), and closely related proteins 4F.1 and 4F.2 were characterized in Xenopus as doublestranded RNA (dsRNA)-binding proteins (3). NF90 is also known as DRBP76, NFAR1, and TCP80 (34, 43, 55), and NF110 is also known as ILF3, NFAR2, TCP110, and CBTF 122 (4,43,53,55). Underlining the importance of these proteins, knockout of the mouse ILF3 gene led to muscle degeneration, respiratory failure, and death soon after birth (44).NF90 and NF110 contain two dsRNA binding motifs (dsRBMs) which are responsible for their ability to interact with structured RNA. They also have an RGG domain that is capable of nucleic acid binding, and NF110 has an additional GQSY region that can interact with nucleic acids. Although characterized as DNA-binding proteins (17,36,40,41), NF90 and NF45 do not contain a recognized sequence-specific DNAbinding domain and the complex containing NF90 and NF45 does not appear to interact with DNA directly. NF90 and NF45 have been purified in complexes containing the Ku proteins and DNA-protein kinase (PK), as well as eukaryotic initiation factor 2 (eIF2), and it is likely ...
Nedd8 activates ubiquitination by increasing the efficiency of polyubiquitin chain assembly through its covalent conjugation to cullin molecules. Here we report the isolation, cloning, and characterization of a novel human Nedd8-specific protease called DEN1. Human DEN1 is encoded by AAH31411.1, a previously uncharacterized protein of 212 amino acids that shares homology with the Ulp1 cysteinyl SUMO deconjugating enzyme family. Recombinant human DEN1, purified from bacteria, selectively binds to Nedd8 and hydrolyzes Cterminal derivatives of Nedd8. Interestingly, DEN1 deconjugates cullin 1 (CUL1)-Nedd8 in a concentration-dependent manner. At a low concentration, DEN1 processes hyper-neddylated CUL1 to yield a mononeddylated form, which presumably contains the Lys-720 CUL1 -Nedd8 linkage. At elevated concentrations, DEN1 is able to complete the removal of Nedd8 from CUL1. These activities distinguish DEN1 from the COP9 signalosome, which is capable of efficiently cleaving the Lys-720 CUL1 -Nedd8 conjugate, but lacks Nedd8 Cterminal hydrolytic activity and poorly processes hyperneddylated CUL1. These results suggest a unique role for DEN1 in regulating the modification of cullins by Nedd8.Nedd8 is a small ubiquitin (Ub) 1 -like protein that plays a critical regulatory role in cell proliferation and development. In fission yeast, Nedd8 is essential for cell viability (1). In animals, Nedd8 is required for development as inactivation of the Nedd8 pathway in either mouse (2) or Drosophila (3) results in embryonic lethality. The critical biological function of Nedd8 is conferred by its biochemical activity as a protein modifier, being covalently attached to nearly all members of the cullin family (4). This modification, neddylation, is reminiscent of the ubiquitination reaction. Neddylation occurs by the formation of an isopeptide-bond linking the ⑀-amino group of a conserved lysine residue typically within the C terminus of a cullin to the carboxyl-end of Nedd8 Gly-76 (5). The enzyme components of the neddylation reaction include a Nedd8-specific E1 activating enzyme comprised of the APP-BP1/Uba3 heterodimer, an E2 conjugating enzyme known as Ubc12 (6), and the ROC1/Rbx1 RING finger protein (7).Using in vitro systems, several studies have shown that Nedd8 activates the ubiquitination of IB␣ (8) or p27 (9), through its conjugation to cullin 1 (CUL1). These reactions are mediated by SCF E3 Ub ligases, in which CUL1 functions as a molecular scaffold (10 -12). Subsequently, it was observed that degradation of HIF-␣ by von Hippel-Lindau tumor suppressor required Nedd8 (13). In this case, Nedd8 was conjugated to CUL2 that assembles the von Hippel-Lindau protein E3 Ub ligase (reviewed in Ref. 14). These studies thus suggest a role for Nedd8 in the assembly of an active cullin-based E3 Ub ligase.We initially reported that conjugation of Nedd8 to CUL1 increases the ability of ROC1-CUL1, a sub-complex within the SCF E3 Ub ligase, to assemble polyubiquitin chains in a reaction catalyzed by the Cdc34 E2 conjugating enzyme (15). S...
Mdm2 is an E3 ubiquitin ligase for the p53 tumor suppressor protein. We demonstrate that Mdm2 is conjugated with SUMO-1 (sumoylated) at Lys-446, which is located within the RING finger domain and plays a critical role in Mdm2 self-ubiquitination. Whereas mutant Mdm2(K446R) is stabilized, it elicits increased degradation of p53 and concomitant inhibition of p53-mediated apoptosis. In vitro sumoylation of Mdm2 abrogates its self-ubiquitination and increases its ubiquitin ligase activity toward p53. Radiation caused a dose- and time-dependent decrease in the degree of Mdm2 SUMO-1 modification, which is inversely correlated with the levels of p53. Our results suggest that the maintenance of the intrinsic activity of a RING finger E3 ubiquitin ligase is sumoylation dependent and that reduced Mdm2 sumoylation in response to DNA damage contributes to p53 stability.
The HIV-1 Tat protein is required for viral replication and is a potent stimulator of viral transcription. Although Tat has been extensively studied in various reductive paradigms, to date there is little information as to how this activator mediates transcription from natural nucleosomally packaged long terminal repeats. Here we show that CREB-binding protein (CBP)/p300 interacts with the HIV-1 Tat protein and serves as a coactivator of Tat-dependent HIV-1 gene expression on an integrated HIV-1 provirus. The site of acetylation of Tat was mapped to the double-lysine motif in a highly conserved region, (49)RKKRRQ(54), of the basic RNA-binding motif of Tat. Using HLM1 cells (HIV-1(+)/Tat(-)), which contain a single copy of full-length HIV-1 provirus with a triple termination codon at the first AUG of the Tat gene, we find that only wild type, and not K50A, K51A, or K50A/K51A alone or in combination of ectopic CBP/p300, is able to produce full-length infectious virions, as measured by p24 gag ELISAs. Tat binds CBP/p300 in the minimal histone acetyltransferase domain (1253-1710) and the binding is stable up to 0.85 M salt wash conditions. Interestingly, wild-type peptide 41-54, and not other Tat peptides, changes the conformation of the CBP/p300 such that it can acquire and bind better to basal factors such as TBP and TFIIB, indicating that Tat may influence the transcription machinery by helping CBP/p300 to recruit new partners into the transcription machinery. Finally, using biotinylated wild-type or acetylated peptides, we find that acetylation decreases Tat's ability to bind the TAR RNA element, as well as to bind basal factors such as TBP, CBP, Core-Pol II, or cyclin T. However, the acetylated Tat peptide is able to bind to core histones on a nucleosome assembled HIV-1 proviral DNA.
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