Rpn7 Is required for the structural integrity of the 26 S proteasome of Saccharomyces cerevisiae

Rpn7 is one of the lid subunits of the 26 S proteasome regulatory particle. The RPN7 gene is known to be essential, but its function remains to be elucidated. To explore the function of Rpn7, we isolated and characterized temperature-sensitive rpn7 mutants. All of the rpn7 mutants obtained accumulated poly-ubiquitinated proteins when grown at the restrictive temperature. The N-end rule substrate (Ub-Arg-beta-galactosidase), the UFD pathway substrate (Ub-Pro-beta-galactosidase), and cell cycle regulators (Pds1 and Clb2) were found to be stabilized in experiments using one of the rpn7 mutants termed rpn7-3 at the restrictive temperature, indicating its defect in the ubiquitin-proteasome pathway. Subsequent analysis of the structure of the 26 S proteasome in rpn7-3 cells suggested that the defect was in the assembly of the 26 S holoenzyme. The most striking characteristic of the proteasome of the rpn7-3 mutant was that a lid subcomplex affinity-purified from the rpn7-3 cells grown at the restrictive temperature contained only 5 of the 8 lid components, a phenomenon that has not been reported in the previously isolated lid mutants. From these results, we concluded that Rpn7 is required for the integrity of the 26 S complex by establishing a correct lid structure.     

Rpn5 is a conserved proteasome subunit and required for proper proteasome localization and assembly

Proper function of the 26 S proteasome requires assembly of the regulatory complex, which is composed of the lid and base subcomplexes. We characterized Rpn5, a lid subunit, in fission yeast. We show that Rpn5 associates with the proteasome rpn5. Deletion (rpn5Delta) exacerbates the growth defects in proteasome mutants, leading to mitotic abnormalities, which correlate with accumulation of polyubiquitinated proteins, such as Cut2/securin. Rpn5 expression is tightly controlled; both overexpression and deletion of rpn5 impair proteasome functions. The proteasome is assembled around the inner nuclear membrane in wild-type cells; however, in rpn5Delta cells, proteasome subunits are improperly assembled and/or localized. In the lid mutants, Rpn5 is mislocalized in the cytosol, while in the base mutants, Rpn5 can enter the nucleus, but is left in the nucleoplasm, and not assembled into the nuclear membrane. These results suggest that Rpn5 is a dosage-dependent proteasome regulator and plays a role in mediating proper proteasome assembly. Moreover, the Rpn5 assembly may be a cooperative process that involves at least two steps: 1) nuclear import and 2) subsequent assembly into the nuclear membrane. The former step requires other components of the lid, while the latter requires the base. Human Rpn5 rescues the phenotypes associated with rpn5Delta and is incorporated into the yeast proteasome, suggesting that Rpn5 functions are highly conserved.     

The assembly pathway of the 19S regulatory particle of the yeast 26S proteasome

The 26S proteasome consists of the 20S proteasome (core particle) and the 19S regulatory particle made of the base and lid substructures, and it is mainly localized in the nucleus in yeast. To examine how and where this huge enzyme complex is assembled, we performed biochemical and microscopic characterization of proteasomes produced in two lid mutants, rpn5-1 and rpn7-3, and a base mutant DeltaN rpn2, of the yeast Saccharomyces cerevisiae. We found that, although lid formation was abolished in rpn5-1 mutant cells at the restrictive temperature, an apparently intact base was produced and localized in the nucleus. In contrast, in DeltaN rpn2 cells, a free lid was formed and localized in the nucleus even at the restrictive temperature. These results indicate that the modules of the 26S proteasome, namely, the core particle, base, and lid, can be formed and imported into the nucleus independently of each other. Based on these observations, we propose a model for the assembly process of the yeast 26S proteasome.     

Dissection of the assembly pathway of the proteasome lid in Saccharomyces cerevisiae

The 26S proteasome is a highly conserved multisubunit protease that degrades ubiquitinated proteins in eukaryotic cells. It comprises a 20S core particle and two 19S regulatory particles that are further divided into the lid and base complexes. The lid is a nine subunits complex that is structurally related to the COP9 signalosome and the eukaryotic initiation factor 3. Although the assembly pathway of the 20S and the base are well described, that of the lid is still unclear. In this study, we dissected the lid assembly using yeast lid mutant cells, rpn7-3, Δrpn9, and rpn12-1. Using mass spectrometry, we identified a number of lid subassemblies, such as Rpn3-Rpn7 pair and a lid-like complex lacking Rpn12, in the mutants. Our analysis suggests that the assembly of the lid is a highly ordered and multi-step process; first, Rpn5, 6, 8, 9, and 11 are assembled to form a core module, then a second module, consisting of Rpn3, 7, and Sem1, is attached, followed by the incorporation of Rpn12 to form the lid complex.     

Genetic dissection of the yeast 26S proteasome: cell cycle defects caused by the Deltarpn9 mutation

Rpn9 is one of the subunits of the regulatory particle of the yeast 26S proteasome and is needed for stability or efficient assembly of the 26S proteasome. As anticipated from the fact that the rpn9 disruptant grew at 25 degrees C but arrested in G2/M phase at 37 degrees C, the CDK inhibitor Sic1p was found to be degraded at the G1/S boundary in the Deltarpn9 cells. The degradation of the anaphase inhibitor Pds1p was delayed in the Deltarpn9 cells. Clb2p in M phase, as well as that ectopically expressed in G1 and S phases, was degraded more slowly in the Deltarpn9 cells than in the wild type cells, indicating that the 26S proteasome lacking Rpn9 uses Sic1p as a better substrate than Pds1p and Clb2p. These results, in addition to the fact that multiubiquitinated proteins were accumulated in the Deltarpn9 cells incubated at 37 degrees C, strongly suggest that Rpn9 is involved in the proteolysis of a subset of the substrates degraded by the 26S proteasome. The Deltarpn9 Deltapds1 double mutant was unable to elongate spindle at a restrictive temperature, suggesting that some protein(s) other than Scc1 (cohesin) should be degraded during progression of anaphase.     

Complementary roles for Rpn11 and Ubp6 in deubiquitination and proteolysis by the proteasome

Substrates destined for degradation by the 26 S proteasome are labeled with polyubiquitin chains. These chains can be dismantled by deubiquitinating enzymes (DUBs). A number of reports have identified different DUBs that can hydrolyze ubiquitin from substrates bound to the proteasome. We measured deubiquitination by both isolated lid and base-core particle subcomplexes, suggesting that at least two different DUBs are intrinsic components of 26 S proteasome holoenzymes. In agreement, we find that highly purified proteasomes contain both Rpn11 and Ubp6, situated within the lid and base subcomplexes, respectively. To study their relative contributions, we purified proteasomes from a mutant in the putative metalloprotease domain of Rpn11 and from a ubp6 null. Interestingly, in both preparations we observed slower deubiquitination rates, suggesting that Rpn11 and Ubp6 serve complementary roles. In accord, the double mutant is synthetically lethal. In contrast to WT proteasomes, proteasomes lacking the lid subcomplex or those purified from the rpn11 mutant are less sensitive to metal chelators, supporting the prediction that Rpn11 may be a metalloprotein. Treatment of proteasomes with ubiquitin-aldehyde or with cysteine modifiers also inhibited deubiquitination but simultaneously promoted degradation of a monoubiquitinated substrate along with the ubiquitin tag. Degradation is unique to 26 S proteasome holoenzymes; we could not detect degradation of a ubiquitinated protein by "lidless" proteasomes, although they were competent for deubiquitination. The fascinating observation that a single ubiquitin moiety is sufficient for targeting an otherwise stable substrate to proteasomes exposes how rapid deubiquitination of poorly ubiquitinated substrates may counteract degradation.     

Base-CP proteasome can serve as a platform for stepwise lid formation

26S proteasome, a major regulatory protease in eukaryotes, consists of a 20S proteolytic core particle (CP) capped by a 19S regulatory particle (RP). The 19S RP is divisible into base and lid sub-complexes. Even within the lid, subunits have been demarcated into two modules: module 1 (Rpn5, Rpn6, Rpn8, Rpn9 and Rpn11), which interacts with both CP and base sub-complexes and module 2 (Rpn3, Rpn7, Rpn12 and Rpn15) that is attached mainly to module 1. We now show that suppression of RPN11 expression halted lid assembly yet enabled the base and 20S CP to pre-assemble and form a base-CP. A key role for Regulatory particle non-ATPase 11 (Rpn11) in bridging lid module 1 and module 2 subunits together is inferred from observing defective proteasomes in rpn11–m1, a mutant expressing a truncated form of Rpn11 and displaying mitochondrial phenotypes. An incomplete lid made up of five module 1 subunits attached to base-CP was identified in proteasomes isolated from this mutant. Re-introducing the C-terminal portion of Rpn11 enabled recruitment of missing module 2 subunits. In vitro, module 1 was reconstituted stepwise, initiated by Rpn11–Rpn8 heterodimerization. Upon recruitment of Rpn6, the module 1 intermediate was competent to lock into base-CP and reconstitute an incomplete 26S proteasome. Thus, base-CP can serve as a platform for gradual incorporation of lid, along a proteasome assembly pathway. Identification of proteasome intermediates and reconstitution of minimal functional units should clarify aspects of the inner workings of this machine and how multiple catalytic processes are synchronized within the 26S proteasome holoenzymes.     

Integrity of the Saccharomyces cerevisiae Rpn11 Protein Is Critical for Formation of Proteasome Storage Granules (PSG) and Survival in Stationary Phase

Decline of proteasome activity has been reported in mammals, flies and yeasts during aging. In the yeast Saccharomyces cerevisiae, the reduction of proteolysis in stationary phase is correlated with disassembly of the 26S proteasomes into their 20S and 19S subcomplexes. However a recent report showed that upon entry into the stationary phase, proteasome subunits massively re-localize from the nucleus into mobile cytoplasmic structures called proteasome storage granules (PSGs). Whether proteasome subunits in PSG are assembled into active complexes remains an open question that we addressed in the present study. We showed that a particular mutant of the RPN11 gene (rpn11-m1), encoding a proteasome lid subunit already known to exhibit proteasome assembly/stability defect in vitro, is unable to form PSGs and displays a reduced viability in stationary phase. Full restoration of long-term survival and PSG formation in rpn11-m1 cells can be achieved by the expression in trans of the last 45 amino acids of the C-terminal domain of Rpn11, which was moreover found to co-localize with PSGs. In addition, another rpn11 mutant leading to seven amino acids change in the Rpn11 C-terminal domain, which exhibits assembled-26S proteasomes, is able to form PSGs but with a delay compared to the wild type situation. Altogether, our findings indicate that PSGs are formed of fully assembled 26S proteasomes and suggest a critical role for the Rpn11 protein in this process.     

Increased degradation of oxidized proteins in yeast defective in 26 S proteasome assembly

An Rpn9-disrupted yeast strain, Delta rpn9, whose growth is temperature sensitive with defective assembly of the 26 S proteasome complex, was studied. This mutant yeast was more resistant to hydrogen peroxide treatment and able to degrade carbonylated proteins more efficiently than wild type. Nondenaturing gel electrophoresis followed by activity staining revealed that Delta rpn9 yeast cells had a higher activity of 20 S proteasome than wild type and that in both Delta rpn9 and wild-type cells treated with hydrogen peroxide, 20 S proteasome activity was increased with a concomitant decrease in 26 S proteasome activity. Protein multiubiquitination was not observed in the hydrogen peroxide-treated cells. Taken together, these results suggest that the 20 S proteasome degrades oxidized proteins without ubiquitination of target proteins.     

Rpn9 Is Required for Efficient Assembly of the Yeast 26S Proteasome

We have isolated the RPN9 gene by two-hybrid screening with, as bait, RPN10 (formerly SUN1), which encodes a multiubiquitin chain receptor residing in the regulatory particle of the 26S proteasome. Rpn9 is a nonessential subunit of the regulatory particle of the 26S proteasome, but the deletion of this gene results in temperature-sensitive growth. At the restrictive temperature, the Deltarpn9 strain accumulated multiubiquitinated proteins, indicating that the RPN9 function is needed for the 26S proteasome activity at a higher temperature. We analyzed the proteasome fractions separated by glycerol density gradient centrifugation by native polyacrylamide gel electrophoresis and found that a smaller amount of the 26S proteasome was produced in the Deltarpn9 cells and that the 26S proteasome was shifted to lighter fractions than expected. The incomplete proteasome complexes were found to accumulate in the Deltarpn9 cells. Furthermore, Rpn10 was not detected in the fractions containing proteasomes of the Deltarpn9 cells. These results indicate that Rpn9 is needed for incorporating Rpn10 into the 26S proteasome and that Rpn9 participates in the assembly and/or stability of the 26S proteasome.     

A proteasome assembly defect in rpn3 mutants is associated with Rpn11 instability and increased sensitivity to stress

Rpn11 is a proteasome-associated deubiquitinating enzyme that is essential for viability. Recent genetic studies showed that Rpn11 is functionally linked to Rpn10, a major multiubiquitin chain binding receptor in the proteasome. Mutations in Rpn11 and Rpn10 can reduce the level and/or stability of proteasomes, indicating that both proteins influence its structural integrity. To characterize the properties of Rpn11, we examined its interactions with other subunits in the 19S regulatory particle and detected strong binding to Rpn3. Two previously described rpn3 mutants are sensitive to protein translation inhibitors and an amino acid analog. These mutants also display a mitochondrial defect. The abundance of intact proteasomes was significantly reduced in rpn3 mutants, as revealed by strongly reduced binding between 20S catalytic with 19S regulatory particles. Proteasome interaction with the shuttle factor Rad23 was similarly reduced. Consequently, higher levels of multiUb proteins were associated with Rad23, and proteolytic substrates were stabilized. The availability of Rpn11 is important for maintaining adequate levels of intact proteasomes, as its depletion caused growth and proteolytic defects in rpn3. These studies suggest that Rpn11 is stabilized following its incorporation into proteasomes. The instability of Rpn11 and the defects of rpn3 mutants are apparently caused by a failure to recruit Rpn11 into mature proteasomes.     

Functional Characterization of Rpn3 Uncovers a Distinct 19S Proteasomal Subunit Requirement for Ubiquitin-Dependent Proteolysis of Cell Cycle Regulatory Proteins in Budding Yeast

By selectively eliminating ubiquitin-conjugated proteins, the 26S proteasome plays a pivotal role in a large variety of cellular regulatory processes, particularly in the control of cell cycle transitions. Access of ubiquitinated substrates to the inner catalytic chamber within the 20S core particle is mediated by the 19S regulatory particle (RP), whose subunit composition in budding yeast has been recently elucidated. In this study, we have investigated the cell cycle defects resulting from conditional inactivation of one of these RP components, the essential non-ATPase Rpn3/Sun2 subunit. Using temperature-sensitive mutant alleles, we show that rpn3 mutations do not prevent the G(1)/S transition but cause a metaphase arrest, indicating that the essential Rpn3 function is limiting for mitosis. rpn3 mutants appear severely compromised in the ubiquitin-dependent proteolysis of several physiologically important proteasome substrates. Thus, RPN3 function is required for the degradation of the G(1)-phase cyclin Cln2 targeted by SCF; the S-phase cyclin Clb5, whose ubiquitination is likely to involve a combination of E3 (ubiquitin protein ligase) enzymes; and anaphase-promoting complex targets, such as the B-type cyclin Clb2 and the anaphase inhibitor Pds1. Our results indicate that the Pds1 degradation defect of the rpn3 mutants most likely accounts for the metaphase arrest phenotype observed. Surprisingly, but consistent with the lack of a G(1) arrest phenotype in thermosensitive rpn3 strains, the Cdk inhibitor Sic1 exhibits a short half-life regardless of the RPN3 genotype. In striking contrast, Sic1 turnover is severely impaired by a temperature-sensitive mutation in RPN12/NIN1, encoding another essential RP subunit. While other interpretations are possible, these data strongly argue for the requirement of distinct RP subunits for efficient proteolysis of specific cell cycle regulators. The potential implications of these data are discussed in the context of possible Rpn3 function in multiubiquitin-protein conjugate recognition by the 19S proteasomal regulatory particle.     

Consequences of COP9 signalosome and 26S proteasome interaction

The COP9 signalosome (CSN) occurs in all eukaryotic cells. It is a regulatory particle of the ubiquitin (Ub)/26S proteasome system. The eight subunits of the CSN possess sequence homologies with the polypeptides of the 26S proteasome lid complex and just like the lid, the CSN consists of six subunits with PCI (proteasome, COP9 signalosome, initiation factor 3) domains and two components with MPN (Mpr-Pad1-N-terminal) domains. Here we show that the CSN directly interacts with the 26S proteasome and competes with the lid, which has consequences for the peptidase activity of the 26S proteasome in vitro. Flag-CSN2 was permanently expressed in mouse B8 fibroblasts and Flag pull-down experiments revealed the formation of an intact Flag-CSN complex, which is associated with the 26S proteasome. In addition, the Flag pull-downs also precipitated cullins indicating the existence of super-complexes consisting of the CSN, the 26S proteasome and cullin-based Ub ligases. Permanent expression of a chimerical subunit (Flag-CSN2-Rpn6) consisting of the N-terminal 343 amino acids of CSN2 and of the PCI domain of S9/Rpn6, the paralog of CSN2 in the lid complex, did not lead to the assembly of an intact complex showing that the PCI domain of CSN2 is important for complex formation. The consequence of permanent Flag-CSN2 overexpression was de-novo assembly of the CSN complex connected with an accelerated degradation of p53 and stabilization of c-Jun in B8 cells. The possible role of super-complexes composed of the CSN, the 26S proteasome and of Ub ligases in the regulation of protein stability is discussed.     

Rpn6p,a proteasome subunit from Saccharomyces cerevisiae,is essential for the assembly and activity of the 26 S proteasome

We report the functional characterization of RPN6, an essential gene from Saccharomyces cerevisiae encoding the proteasomal subunit Rpn6p. For this purpose, conditional mutants that are able to grow on galactose but not on glucose were obtained. When these mutants are shifted to glucose, Rpn6p depletion induces several specific phenotypes. First, multiubiquitinated proteins accumulate, indicating a defect in proteasome-mediated proteolysis. Second, mutant yeasts are arrested as large budded cells with a single nucleus and a 2C DNA content; in addition, the spindle pole body is duplicated, indicating a general cell cycle defect related to the turnover of G(2)-cyclins after DNA synthesis. Clb2p and Pds1p, but not Sic1p, accumulate in the arrested cells. Depletion of Rpn6p affects both the structure and the peptidase activity of proteasomes in the cell. These results implicate Rpn6p function in the specific recognition of a subset of substrates and point to a role in maintaining the correct quaternary structure of the 26 S proteasome.     

Incorporation of the Rpn12 subunit couples completion of proteasome regulatory particle lid assembly to lid-base joining

The 26S proteasome, the central eukaryotic protease, comprises a core particle capped by a 19S regulatory particle (RP). The RP is divisible into base and lid subcomplexes. Lid biogenesis and incorporation into the RP remain poorly understood. We report several lid intermediates, including the free Rpn12 subunit and a lid particle (LP) containing the remaining eight subunits, LP2. Rpn12 binds LP2 in vitro, and each requires the other for assembly into 26S proteasomes. Stable Rpn12 incorporation depends on all other lid subunits, indicating that Rpn12 distinguishes LP2 from smaller lid subcomplexes. The highly conserved C terminus of Rpn12 bridges the lid and base, mediating both stable binding to LP2 and lid-base joining. Our data suggest a hierarchical assembly mechanism where Rpn12 binds LP2 only upon correct assembly of all other lid subunits, and the Rpn12 tail then helps drive lid-base joining. Rpn12 incorporation thus links proper lid assembly to subsequent assembly steps.     

Subunit interaction maps for the regulatory particle of the 26S proteasome and the COP9 signalosome.

The 26S proteasome plays a major role in eukaryotic protein breakdown, especially for ubiquitin-tagged proteins. Substrate specificity is conferred by the regulatory particle (RP), which can dissociate into stable lid and base subcomplexes. To help define the molecular organization of the RP, we tested all possible paired interactions among subunits from Saccharomyces cerevisiae by yeast two-hybrid analysis. Within the base, a Rpt4/5/3/6 interaction cluster was evident. Within the lid, a structural cluster formed around Rpn5/11/9/8. Interactions were detected among synonymous subunits (Csn4/5/7/6) from the evolutionarily related COP9 signalosome (CSN) from Arabidopsis, implying a similar quaternary arrangement. No paired interactions were detected between lid, base or core particle subcomplexes, suggesting that stable contacts between them require prior assembly. Mutational analysis defined the ATPase, coiled-coil, PCI and MPN domains as important for RP assembly. A single residue in the vWA domain of Rpn10 is essential for amino acid analog resistance, for degrading a ubiquitin fusion degradation substrate and for stabilizing lid-base association. Comprehensive subunit interaction maps for the 26S proteasome and CSN support the ancestral relationship of these two complexes.     

Functional analysis of the proteasome regulatory particle

We have developed S. cerevisiae as a model system for mechanistic studies of the 26S proteasome. The subunits of the yeast 19S complex, or regulatory particle (RP), have been defined, and are closely related to those of mammalian proteasomes. The multiubiquitin chain binding subunit (S5a/Mcb1/Rpn10) was found, surprisingly, to be nonessential for the degradation of a variety of ubiquitin-protein conjugates in vivo. Biochemical studies of proteasomes from rpn10 mutants revealed the existence of two structural subassemblies within the RP, the lid and the base. The lid and the base are both composed of 8 subunits. By electron microscopy, the base and the lid correspond to the proximal and distal masses of the RP, respectively. The base is sufficient to activate the 20S core particle for degradation of peptides, but the lid is required for ubiquitin-dependent degradation. The lid subunits share sequence motifs with components of the COP9/signalosome complex, suggesting that these functionally diverse particles have a common evolutionary ancestry. Analysis of equivalent point mutations in the six ATPases of the base indicate that they have well-differentiated functions. In particular, mutations in one ATPase gene, RPT2, result in an unexpected defect in peptide hydrolysis by the core particle. One interpretation of this result is that Rpt2 participates in gating of the channel through which substrates enter the core particle.     

1H, 13C and 15N resonance assignments of Rpn9, a regulatory subunit of 26S proteasome from Saccharomyces cerevisiae

The 26S proteasome is an essential molecular machine for specific protein degradation in eukaryotic cells. The 26S proteasome is formed by a central 20S core particle capped by two 19S regulatory particle (RP) at both ends. The Rpn9 protein is a non-ATPase subunit located in the lid complex of the 19S RP, and is identified to be essential for efficient assembly of yeast 26S proteasome. Bioinformatics analysis of Saccharomyces cerevisiae Rpn9 suggested it contains a PCI domain at the C-terminal region. However, high-resolution structures of either the PCI domain or the full-length Rpn9 still remain elusive. Herein, we report the chemical shift assignments of ¹H, ¹³C and ¹⁵N atoms of the individual N- and C-domains, as well as full-length S. cerevisiae Rpn9, which provide the basis for further structural and functional studies of Rpn9 using solution NMR technique.     

Proteasome Assembly Influences Interaction with Ubiquitinated Proteins and Shuttle Factors

A major fraction of intracellular protein degradation is mediated by the proteasome. Successful degradation of these substrates requires ubiquitination and delivery to the proteasome followed by protein unfolding and disassembly of the multiubiquitin chain. Enzymes, such as Rpn11, dismantle multiubiquitin chains, and mutations can affect proteasome assembly and activity. We report that different rpn11 mutations can affect proteasome interaction with ubiquitinated proteins. Moreover, proteasomes are unstable in rpn11-1 and do not form productive interactions with multiubiquitinated proteins despite high levels in cell extracts. However, increased levels of ubiquitinated proteins were found associated with shuttle factors. In contrast to rpn11-1, proteasomes expressing a catalytically inactive mutant (rpn11^AXA) were more stable and bound very high amounts of ubiquitinated substrates. Expression of the carboxyl-terminal domain of Rpn11 partially suppressed the growth and proteasome stability defects of rpn11-1. These results indicate that ubiquitinated substrates are preferentially delivered to intact proteasome.