Stabilization of nuclear oncoproteins by RNF4 and the ubiquitin system in cancer.

RNF4, a SUMO-targeted ubiquitin ligase, stabilizes a selected group of oncoproteins. It potentiates oncoprotein activity and serves as a positive feedback agonist of Wnt and Notch pathways. RNF4 is essential for cancer cell survival and its levels are elevated in human cancers, correlating with poor outcome in a subset of cancer patients.

Genomic binding and transcriptional regulation by the Drosophila Myc and Mnt transcription factors.

Deregulated expression of members of the myc oncogene family has been linked to the genesis of a wide range of cancers, whereas their normal expression is associated with growth, proliferation, differentiation, and apoptosis. Myc proteins are transcription factors that function within a network of transcriptional activators (Myc) and repressors (Mxd/Mad and Mnt), all of which heterodimerize with the bHLHZ protein Mad and bind E-box sequences in DNA. These transcription factors recruit coactivator or corepressor complexes that in turn modify histones. Myc, Mxd/Max, and Mnt proteins have been thought to act on a specific subset of genes. However, expression array studies and, most recently, genomic binding studies suggest that these proteins exhibit widespread binding across the genome. Here we demonstrate by immunostaining of Drosophila polytene chromosome that Drosophila Myc (dMyc) is associated with multiple euchromatic chromosomal regions. Furthermore, many dMyc-binding regions overlap with regions containing active RNA polymerase II, although dMyc can also be found in regions lacking active polymerase. We also demonstrate that the pattern of dMyc expression in nuclei overlaps with histone markers of active chromatin but not pericentric heterochromatin. dMyc binding is not detected on the X chromosome rDNA cluster (bobbed locus). This is consistent with recent evidence that in Drosophila cells dMyc regulates rRNA transcription indirectly, in contrast to mammalian cells where direct binding of c-Myc to rDNA has been observed. We further show that the dMyc antagonist dMnt inhibits rRNA transcription in the wing disc. Our results support the view that the Myc/Max/Mad network influences transcription on a global scale.

TGF-beta flips the Myc switch.

Although transforming growth factor-beta (TGF-beta) can affect cell cycle arrest, not much molecular detail is known about how TGF-beta-dependent arrest is mediated. Two recent papers shed some light on how this is accomplished. Orian and Eisenman discuss how Myc interacts with Miz-1 to block the expression of a cell cycle inhibitory protein, p15(INK4b), and how TGF-beta is able to unblock Myc-dependent repression of Miz-1.

Processing of p105 is inhibited by docking of p50 active subunits to the ankyrin repeat domain, and inhibition is alleviated by signaling via the carboxyl-terminal phosphorylation/ ubiquitin-ligase binding domain.

Processing of the p105 precursor to generate the p50 subunit of the nuclear factor kappaB transcription factor is an exceptional case in which the ubiquitin system is involved in limited processing rather than in complete destruction of the target substrate. A Gly-rich region "stop" signal in the middle of the molecule along with a neighboring downstream ubiquitination, and probably an E3 anchoring domain, have been demonstrated to be important for processing. In addition, we have shown that IkappaB kinase-mediated phosphorylation of the C-terminal domain leads to recruitment of the SCF(beta)-TrCP ubiquitin ligase with subsequent accelerated ubiquitination and processing/degradation of the precursor (Orian, A., Gonen, H., Bercovich, B., Fajerman, I., Eytan, E., Israël, A., Mercurio, F., Iwai, K., Schwartz, A. L., and Ciechanover, A. (2000) EMBO J. 19, 2580-2591). Here we show that processing of p105 molecules that contain more then four ankyrin repeats, but lack the C-terminal phosphorylation/ubiquitin ligase binding domain, is strongly inhibited by docked p50 subunits. Inhibition is caused by interference with the function of the proteasome, as conjugation is not affected. Inhibition is alleviated after IkappaB kinase phosphorylation of the C-terminal domain leads to accelerated, beta-TrCP-mediated ubiquitination and processing/degradation of p105. We suggest that under basal conditions, slow generation of p50 probably involves the mid-molecule ubiquitination/E3 recognition motif. Following stimulation, the C-terminal domain is involved in rapid processing/degradation of p105 with release of a large amount of the stored subunits that now become transcriptionally active.

Mechanisms of ubiquitin-mediated, limited processing of the NF-kappaB1 precursor protein p105.

In most cases, target proteins of the ubiquitin system are completely degraded. In several exceptions, such as the first step in the activation of the transcriptional regulator NF-kappaB, the substrate, the precursor protein p105, is processed in a limited manner to yield the active subunit p50. p50 is derived from the N-terminal domain of p105, whereas the C-terminal domain is degraded. The mechanisms involved in this unique process have remained elusive. We have shown that a Gly-rich region (GRR) at the C-terminal domain of p50 is one important processing signal and that it interferes with processing of the ubiquitinated precursor by the 26S proteasome. Also, amino acid residues 441-454 are important for processing under non-stimulated conditions. Lys 441 and 442 serve as ubiquitination targets, whereas residues 446-454 may serve as a ligase recognition motif. Following IkappaB kinase (IKK)-mediated phosphorylation, the C-terminal domain of p105, residues 918-934, recruits the SCF(beta-TrCP) ubiquitin ligase, and ubiquitination by this complex leads to accelerated processing. The two sites appear to be recognized under different physiological conditions by two different ligases, targeting two distinct recognition motifs. We have shown that ubiquitin conjugation and processing of a series of precursors of p105 that lack the C-terminal IKK phosphorylation/TrCP binding domain, is progressively inhibited with increasing number of ankyrin repeats. Inhibition is due to docking of active NF-kappaB subunits to the ankyrin repeat domain in the C-terminal half of p105 (IkappaBgamma). Inhibition is alleviated by phosphorylation of the C-terminal domain that leads to ubiquitin-mediated degradation of the ankyrin repeat domain and release of the anchored subunits. We propose a model that may explain the requirement for two sites: a) a basal site that may be involved in co-translational processing prior to the synthesis of the ankyrin repeat domain; and b) a signal-induced site that is involved in processing/degradation of the complete molecule following cell activation, with rapid release of stored, transcriptionally active subunits.

SCF(beta)(-TrCP) ubiquitin ligase-mediated processing of NF-kappaB p105 requires phosphorylation of its C-terminus by IkappaB kinase.

Processing of the p105 precursor to form the active subunit p50 of the NF-kappaB transcription factor is a unique case in which the ubiquitin system is involved in limited processing rather than in complete destruction of the target substrate. A glycine-rich region along with a downstream acidic domain have been demonstrated to be essential for processing. Here we demonstrate that following IkappaB kinase (IkappaK)-mediated phosphorylation, the C-terminal domain of p105 (residues 918-934) serves as a recognition motif for the SCF(beta)(-TrCP) ubiquitin ligase. Expression of IkappaKbeta dramatically increases processing of wild-type p105, but not of p105-Delta918-934. Dominant-negative beta-TrCP inhibits IkappaK-dependent processing. Furthermore, the ligase and wild-type p105 but not p105-Delta918-934 associate physically following phosphorylation. In vitro, SCF(beta)(-TrCP) specifically conjugates and promotes processing of phosphorylated p105. Importantly, the TrCP recognition motif in p105 is different from that described for IkappaBs, beta-catenin and human immunodeficiency virus type 1 Vpu. Since p105-Delta918-934 is also conjugated and processed, it appears that p105 can be recognized under different physiological conditions by two different ligases, targeting two distinct recognition motifs.

Ubiquitin-mediated proteolysis: biological regulation via destruction.

The ubiquitin proteolytic system plays an important role in a broad array of basic cellular processes. Among these are regulation of cell cycle, modulation of the immune and inflammatory responses, control of signal transduction pathways, development and differentiation. These complex processes are controlled via specific degradation of a single or a subset of proteins. Degradation of a protein by the ubiquitin system involves two successive steps, conjugation of multiple moieties of ubiquitin and degradation of the tagged protein by the 26S proteasome. An important question concerns the identity of the mechanisms that underlie the high degree of specificity of the system. Substrate recognition is governed by a large family ubiquitin ligases that recognize the substrates, bind them and catalyze/facilitate their interaction with ubiquitin.

The ubiquitin-mediated proteolytic pathway: mode of action and clinical implications.

Proteolysis via the ubiquitin system plays important roles in a variety of basic cellular processes. Among these are regulation of cell cycle and division, modulation of the immune and inflammatory responses, and development and differentiation. In all cases studied, these complex processes are mediated via degradation or processing of a single or a subset of specific proteins. Ubiquitin-mediated degradation of a protein involves two discrete and successive steps: (1) conjugation of multiple moieties of ubiquitin to the protein, and (2) degradation of the conjugated protein by the 26S proteasome complex with the release of free and reutilizable ubiquitin. In a few cases, it has been reported that ubiquitination targets membrane-anchored proteins to degradation in the lysosome/vacuole. An important yet largely unresolved problem involves the mechanisms that endow the system with the high degree specificity and selectivity toward its many substrates. These are determined by a large family of ubiquitin-protein ligases that recognize different primary and/or secondary/post-translational motifs in the different substrates and by a wide array of modifying enzymes, such as protein kinases, and ancillary proteins, such as molecular chaperones, that render them susceptible for recognition by the ligases via modification or association with protein substrates. With the broad spectrum of protein substrates and the complex enzymatic machinery involved in targeting them, it is not surprising that the system was recently implicated in the pathogenesis of several important diseases. In addition, genetic studies in animals underscore the role of the system in normal development. We briefly review the enzymatic cascade involved in ubiquitin-mediated degradation, describe some of the structural motifs identified by the conjugating machinery, and summarize recent developments in the involvement of the system in the pathogenesis of selected disease states.

Identification of the ubiquitin carrier proteins, E2s, involved in signal-induced conjugation and subsequent degradation of IkappaBalpha.

The last step in the activation of the transcription factor NF-kappaB is signal-induced, ubiquitin- and proteasome-mediated degradation of the inhibitor IkappaBalpha. Although most of the components involved in the activation and degradation pathways have been identified, the ubiquitin carrier proteins (E2) have remained elusive. Here we show that the two highly homologous members of the UBCH5 family, UBCH5b and UBCH5c, and CDC34/UBC3, the mammalian homolog of yeast Cdc34/Ubc3, are the E2 enzymes involved in the process. The conjugation reaction they catalyze in vitro is specific, as they do not recognize the S32A,S36A mutant species of IkappaBalpha that cannot be phosphorylated and conjugated following an extracellular signal. Furthermore, the reaction is specifically inhibited by a doubly phosphorylated peptide that spans the ubiquitin ligase recognition domain of the inhibitor. Cys-to-Ala mutant species of the enzymes that cannot bind ubiquitin inhibit tumor necrosis factor alpha-induced degradation of the inhibitor in vivo. Not surprisingly, they have a similar effect in a cell-free system as well. Although it is clear that the E2 enzymes are not entirely specific to IkappaBalpha, they are also not involved in the conjugation and degradation of the bulk of cellular proteins, thus exhibiting some degree of specificity that is mediated probably via their association with a defined subset of ubiquitin-protein ligases. The mechanisms that underlie the involvement of two different E2 species in IkappaBalpha conjugation are not clear at present. It is possible that different conjugating machineries operate under different physiological conditions or in different cells.

Structural motifs involved in ubiquitin-mediated processing of the NF-kappaB precursor p105: roles of the glycine-rich region and a downstream ubiquitination domain.

The ubiquitin proteolytic system plays a major role in a variety of basic cellular processes. In the majority of these processes, the target proteins are completely degraded. In one exceptional case, generation of the p50 subunit of the transcriptional regulator NF-kappaB, the precursor protein p105 is processed in a limited manner: the N-terminal domain yields the p50 subunit, whereas the C-terminal domain is degraded. The identity of the mechanisms involved in this unique process have remained elusive. It has been shown that a Gly-rich region (GRR) at the C-terminal domain of p50 is an important processing signal. Here we show that the GRR does not interfere with conjugation of ubiquitin to p105 but probably does interfere with the processing of the ubiquitin-tagged precursor by the 26S proteasome. Structural analysis reveals that a short sequence containing a few Gly residues and a single essential Ala is sufficient to generate p50. Mechanistically, the presence of the GRR appears to stop further degradation of p50 and to stabilize the molecule. It appears that the localization of the GRR within p105 plays an important role in directing processing: transfer of the GRR within p105 or insertion of the GRR into homologous or heterologous proteins is not sufficient to promote processing in most cases, which is probably due to the requirement for an additional specific ubiquitination and/or recognition domain(s). Indeed, we have shown that amino acid residues 441 to 454 are important for processing. In particular, both Lys 441 and Lys 442 appear to serve as major ubiquitination targets, while residues 446 to 454 are independently important for processing and may serve as the ubiquitin ligase recognition motif.

Degradation of the proto-oncogene product c-Fos by the ubiquitin proteolytic system in vivo and in vitro: identification and characterization of the conjugating enzymes.

The transcription factor c-Fos is a short-lived cellular protein. The levels of the protein fluctuate significantly and abruptly during changing pathophysiological conditions. Thus, it is clear that degradation of the protein plays an important role in its tightly regulated activity. We examined the involvement of the ubiquitin pathway in c-Fos breakdown. Using a mutant cell line, ts20, that harbors a thermolabile ubiquitin-activating enzyme, E1, we demonstrate that impaired function of the ubiquitin system stabilizes c-Fos in vivo. In vitro, we reconstituted a cell-free system and demonstrated that the protein is multiply ubiquitinated. The adducts serve as essential intermediates for degradation by the 26S proteasome. We show that both conjugation and degradation are significantly stimulated by c-Jun, with which c-Fos forms the active heterodimeric transcriptional activator AP-1. Analysis of the enzymatic cascade involved in the conjugation process reveals that the ubiquitin-carrier protein E2-F1 and its human homolog UbcH5, which target the tumor suppressor p53 for degradation, are also involved in c-Fos recognition. The E2 enzyme acts along with a novel species of ubiquitin-protein ligase, E3. This enzyme is distinct from other known E3s, including E3 alpha/UBR1, E3 beta, and E6-AP. We have purified the novel enzyme approximately 350-fold and demonstrated that it is a homodimer with an apparent molecular mass of approximately 280 kDa. It contains a sulfhydryl group that is essential for its activity, presumably for anchoring activated ubiquitin as an intermediate thioester prior to its transfer to the substrate. Taken together, our in vivo and in vitro studies strongly suggest that c-Fos is degraded in the cell by the ubiquitin-proteasome proteolytic pathway in a process that requires a novel recognition enzyme.

Stimulation-dependent I kappa B alpha phosphorylation marks the NF-kappa B inhibitor for degradation via the ubiquitin-proteasome pathway.

The nuclear translocation of NF-kappa B follows the degradation of its inhibitor, I kappa B alpha, an event coupled with stimulation-dependent inhibitor phosphorylation. Prevention of the stimulation-dependent phosphorylation of I kappa B alpha, either by treating cells with various reagents or by mutagenesis of certain putative I kappa B alpha phosphorylation sites, abolishes the inducible degradation of I kappa B alpha. Yet, the mechanism coupling the stimulation-induced phosphorylation with the degradation has not been resolved. Recent reports suggest a role for the proteasome in I kappa B alpha degradation, but the mode of substrate recognition and the involvement of ubiquitin conjugation as a targeting signal have not been addressed. We show that of the two forms of I kappa B alpha recovered from stimulated cells in a complex with RelA and p50, only the newly phosphorylated form, pI kappa B alpha, is a substrate for an in vitro reconstituted ubiquitin-proteasome system. Proteolysis requires ATP, ubiquitin, a specific ubiquitin-conjugating enzyme, and other ubiquitin-proteasome components. In vivo, inducible I kappa B alpha degradation requires a functional ubiquitin-activating enzyme and is associated with the appearance of high molecular weight adducts of I kappa B alpha. Ubiquitin-mediated protein degradation may, therefore, constitute an integral step of a signal transduction process.

Ubiquitin-mediated processing of NF-kappa B transcriptional activator precursor p105. Reconstitution of a cell-free system and identification of the ubiquitin-carrier protein, E2, and a novel ubiquitin-protein ligase, E3, involved in conjugation.

In most cases, the transcriptional factor NF-kappa B is a heterodimer consisting of two subunits, p50 and p65, which are encoded by two distinct genes of the Rel family. p50 is translated as a precursor of 105 kDa. The C-terminal domain of the precursor is rapidly degraded, forming the mature p50 subunit consisted of the N-terminal region of the molecule. The mechanism of generation of p50 is not known. It has been suggested that the ubiquitin-proteasome system is involved in the process; however, the specific enzymes involved and the mechanism of limited proteolysis, in which half of the molecule is spared, have been obscure. Palombella and colleagues (Palombella, V. J., Rando, O. J., Goldberg, A. L., and Maniatis, T. (1994) Cell 78, 773-785) have shown that ubiquitin is required for the processing in a cell-free system of a truncated, artificially constructed, 60-kDa precursor. They have also shown that proteasome inhibitors block the processing both in vitro and in vivo. In this study, we demonstrate reconstitution of a cell-free processing system and demonstrate directly that: (a) the ubiquitin-proteasome system is involved in processing of the intact p105 precursor, (b) conjugation of ubiquitin to the precursor is an essential intermediate step in the processing, (c) the recently discovered novel species of the ubiquitin-carrier protein, E2-F1, that is involved in the conjugation and degradation of p53, is also required for the limited processing of the p105 precursor, and (d) a novel, approximately 320-kDa species of ubiquitin-protein ligase, is involved in the process. This novel enzyme is distinct from E6-AP, the p53-conjugating ligase, and from E3 alpha, the "N-end rule" ligase.

Degradation of nuclear oncoproteins by the ubiquitin system in vitro.

Nuclear oncoproteins are among the most rapidly degraded intracellular proteins. Previous work has implicated the ubiquitin-mediated proteolytic system in the turnover of short-lived intracellular proteins. In the present study, we have evaluated the potential role of the ubiquitin system in the degradation of the specific nuclear oncoproteins encoded by the N-myc, c-myc, c-fos, p53 and E1A genes. Each of these nuclear oncoproteins was synthesized in vitro by transcription of the appropriate cDNA and translation of the resulting mRNA in the presence of [35S]methionine. Degradation of labeled proteins was monitored in the ubiquitin cell-free system. ATP stimulated the degradation of all the proteins between 3- and 10-fold. The degradation was completely inhibited by neutralizing antibody directed against the ubiquitin-activating enzyme, E1, the first enzyme in the ubiquitin-mediated proteolytic cascade. Moreover, degradation in E1-depleted lysates could be restored in each case by the addition of affinity-purified E1. These data suggest that the ubiquitin system mediates the degradation of these oncoproteins in vitro. Degradation of other proteins, such as superoxide dismutase, cytochrome c, enolase, RNase A, and ornithine decarboxylase, is not mediated by the ubiquitin cell-free system. This suggests that the nuclear oncoproteins studied here possess specific signals that target them for rapid turnover by this proteolytic pathway. Furthermore, the relative sensitivity to degradation of various E1A mutants in vivo is also maintained in the cell-free system, suggesting that the ubiquitin pathway may play a role in the cellular degradation of these proteins as well.