Core Particle Assembly Research Articles

Structure of Blm10:13S proteasome intermediate reveals parallel assembly pathways for the proteasome core particle.

Proteasomes are formed by chaperone-assisted assembly of core particles (CPs) and regulatory particles (RPs). The CP chaperone dimer Pba1/Pba2 binds early to proteasome subunits, and is thought to be replaced by Blm10 to form Blm10:CP, which promotes ATP-independent degradation of disordered proteins. Here, we present evidence of distinct parallel assembly pathways for CP by solving five cryo-EM structures including a Blm10:13S pre-assembly intermediate. Our data conflict with the current model of Blm10 and Pba1/Pba2 sequential activity in a single assembly pathway, as we find their CP binding is mutually exclusive and both are present on early and late assembly intermediates. CP affinity for Pba1/Pba2 is reduced during maturation, promoting Pba1/Pba2 release. We find Blm10 undergoes no such affinity switch, suggesting this pathway predominantly yields mature Blm10-bound CP. Altogether, our findings conflict with the current paradigm of sequential CP binding to instead indicate parallel assembly pathways by Pba1/Pba2 and Blm10.

Structure of the preholoproteasome reveals late steps in proteasome core particle biogenesis.

Assembly of the proteasome's core particle (CP), a barrel-shaped chamber of four stacked rings, requires five chaperones and five subunit propeptides. Fusion of two half-CP precursors yields a complete structure but remains immature until active site maturation. Here, using Saccharomyces cerevisiae, we report a high-resolution cryogenic electron microscopy structure of preholoproteasome, a post-fusion assembly intermediate. Our data reveal how CP midline-spanning interactions induce local changes in structure, facilitating maturation. Unexpectedly, we find that cleavage may not be sufficient for propeptide release, as residual interactions with chaperones such as Ump1 hold them in place. We evaluated previous models proposing that dynamic conformational changes in chaperones drive CP fusion and autocatalytic activation by comparing preholoproteasome to pre-fusion intermediates. Instead, the data suggest a scaffolding role for the chaperones Ump1 and Pba1/Pba2. Our data clarify key aspects of CP assembly, suggest that undiscovered mechanisms exist to explain CP fusion/activation, and have relevance for diseases of defective CP biogenesis.

Peptidyl-prolyl cis/trans isomerase Pin1 interacts with hepatitis B virus core particle, but not with HBc protein, to promote HBV replication.

Here, we demonstrate that the peptidyl-prolyl cis/trans isomerase Pin1 interacts noncovalently with the hepatitis B virus (HBV) core particle through phosphorylated serine/threonine-proline (pS/TP) motifs in the carboxyl-terminal domain (CTD) but not with particle-defective, dimer-positive mutants of HBc. This suggests that neither dimers nor monomers of HBc are Pin1-binding partners. The 162TP, 164SP, and 172SP motifs within the HBc CTD are important for the Pin1/core particle interaction. Although Pin1 dissociated from core particle upon heat treatment, it was detected as an opened-up core particle, demonstrating that Pin1 binds both to the outside and the inside of the core particle. Although the amino-terminal domain S/TP motifs of HBc are not involved in the interaction, 49SP contributes to core particle stability, and 128TP might be involved in core particle assembly, as shown by the decreased core particle level of S49A mutant through repeated freeze and thaw and low-level assembly of the T128A mutant, respectively. Overexpression of Pin1 increased core particle stability through their interactions, HBV DNA synthesis, and virion secretion without concomitant increases in HBV RNA levels, indicating that Pin1 may be involved in core particle assembly and maturation, thereby promoting the later stages of the HBV life cycle. By contrast, parvulin inhibitors and PIN1 knockdown reduced HBV replication. Since more Pin1 proteins bound to immature core particles than to mature core particles, the interaction appears to depend on the stage of virus replication. Taken together, the data suggest that physical association between Pin1 and phosphorylated core particles may induce structural alterations through isomerization by Pin1, induce dephosphorylation by unidentified host phosphatases, and promote completion of virus life cycle.

PPIases Par14/Par17 Affect HBV Replication in Multiple Ways.

Human parvulin 14 (Par14) and parvulin 17 (Par17) are peptidyl-prolyl cis/trans isomerases that upregulate hepatitis B virus (HBV) replication by binding to the conserved 133Arg-Pro134 (RP) motif of HBc and core particles, and 19RP20-28RP29 motifs of HBx. In the absence of HBx, Par14/Par17 have no effect on HBV replication. Interaction with Par14/Par17 enhances the stability of HBx, core particles, and HBc. Par14/Par17 binds outside and inside core particles and is involved in HBc dimer-dimer interaction to facilitate core particle assembly. Although HBc RP motif is important for HBV replication, R133 residue is solely important for its interaction with Par14/Par17. Interaction of Par14 and Par17 with HBx involves two substrate-binding residues, Glu46/Asp74 (E46/D74) and E71/D99, respectively, and promotes HBx translocation to the nucleus and mitochondria. In the presence of HBx, Par14/Par17 are efficiently recruited to cccDNA and promote transcriptional activation via specific DNA-binding residues Ser19/44 (S19/44). S19 and E46/D74 of Par14, and S44 and E71/D99 of Par17, are also involved in the recruitment of HBc onto cccDNA. Par14/Par17 upregulate HBV replication via various effects that are mediated in part through the HBx-Par14/Par17-cccDNA complex and triple HBc, Par14/Par17, and cccDNA interactions in the nucleus, as well as via core particle-Par14/Par17 interactions in the cytoplasm.

Hsp70 and Hsp110 Chaperones Promote Early Steps of Proteasome Assembly

Whereas assembly of the 20S proteasome core particle (CP) in prokaryotes apparently occurs spontaneously, the efficiency of this process in eukaryotes relies on the dedicated assembly chaperones Ump1, Pba1-Pba2, and Pba3-Pba4. For mammals, it was reported that CP assembly initiates with formation of a complete α-ring that functions as a template for β subunit incorporation. By contrast, we were not able to detect a ring composed only of a complete set of α subunits in S. cerevisiae. Instead, we found that the CP subunits α1, α2, and α4 each form independent small complexes. Purification of such complexes containing α4 revealed the presence of chaperones of the Hsp70/Ssa and Hsp110/Sse families. Consistently, certain small complexes containing α1, α2, and α4 were not formed in strains lacking these chaperones. Deletion of the SSE1 gene in combination with deletions of PRE9 (α3), PBA3, or UMP1 genes resulted in severe synthetic growth defects, high levels of ubiquitin-conjugates, and an accumulation of distinct small complexes with α subunits. Our study shows that Hsp70 and Hsp110 chaperones cooperate to promote the folding of individual α subunits and/or their assembly with other CP subunits, Ump1, and Pba1-Pba4 in subsequent steps.

Understanding the separation of timescales in bacterial proteasome core particle assembly

The 20S proteasome core particle (CP) is a molecular machine that is a key component of cellular protein degradation pathways. Like other molecular machines, it is not synthesized in an active form but rather as a set of subunits that assemble into a functional complex. The CP is conserved across all domains of life and is composed of 28 subunits, 14 α and 14 β, arranged in four stacked seven-member rings (α7β7β7α7). While details of CP assembly vary across species, the final step in the assembly process is universally conserved: two half proteasomes (HPs; α7β7) dimerize to form the CP. In the bacterium Rhodococcus erythropolis, experiments have shown that the formation of the HP is completed within minutes, while the dimerization process takes hours. The N-terminal propeptide of the β subunit, which is autocatalytically cleaved off after CP formation, plays a key role in regulating this separation of timescales. However, the detailed molecular mechanism of how the propeptide achieves this regulation is unclear. In this work, we used molecular dynamics simulations to characterize HP conformations and found that the HP exists in two states: one where the propeptide interacts with key residues in the HP dimerization interface and likely blocks dimerization, and one where this interface is free. Furthermore, we found that a propeptide mutant that dimerizes extremely slowly is essentially always in the nondimerizable state, while the wild-type rapidly transitions between the two. Based on these simulations, we designed a propeptide mutant that favored the dimerizable state in molecular dynamics simulations. In vitro assembly experiments confirmed that this mutant dimerizes significantly faster than wild-type. Our work thus provides unprecedented insight into how this critical step in CP assembly is regulated, with implications both for efforts to inhibit proteasome assembly and for the evolution of hierarchical assembly pathways.

Chaperone-mediated assembly of the proteasome core particle - recent developments and structural insights.

Much of cellular activity is mediated by large multisubunit complexes. However, many of these complexes are too complicated to assemble spontaneously. Instead, their biogenesis is facilitated by dedicated chaperone proteins, which are themselves excluded from the final product. This is the case for the proteasome, a ubiquitous and highly conserved cellular regulator that mediates most selective intracellular protein degradation in eukaryotes. The proteasome consists of two subcomplexes: the core particle (CP), where proteolysis occurs, and the regulatory particle (RP), which controls substrate access to the CP. Ten chaperones function in proteasome biogenesis. Here, we review the pathway of CP biogenesis, which requires five of these chaperones and proceeds through a highly ordered multistep pathway. We focus on recent advances in our understanding of CP assembly, with an emphasis on structural insights. This pathway of CP biogenesis represents one of the most dramatic examples of chaperone-mediated assembly and provides a paradigm for understanding how large multisubunit complexes can be produced.

Structures of chaperone-associated assembly intermediates reveal coordinated mechanisms of proteasome biogenesis.

The proteasome mediates most selective protein degradation. Proteolysis occurs within the 20S core particle (CP), a barrel-shaped chamber with an α7β7β7α7 configuration. CP biogenesis proceeds through an ordered multistep pathway requiring five chaperones, Pba1-4 and Ump1. Using Saccharomyces cerevisiae, we report high-resolution structures of CP assembly intermediates by cryogenic-electron microscopy. The first structure corresponds to the 13S particle, which consists of a complete α-ring, partial β-ring (β2-4), Ump1 and Pba1/2. The second structure contains two additional subunits (β5-6) and represents a later pre-15S intermediate. These structures reveal the architecture and positions of Ump1 and β2/β5 propeptides, with important implications for their functions. Unexpectedly, Pba1's N terminus extends through an open CP pore, accessing the CP interior to contact Ump1 and the β5 propeptide. These results reveal how the coordinated activity of Ump1, Pba1 and the active site propeptides orchestrate key aspects of CP assembly.

A novel proteasome assembly intermediate bypasses the need to form α-rings first

Proteasomes provide the main route of intracellular protein degradation. They consist of a central protease, termed the 20S proteasome, or core particle (CP), that partners with one or more regulatory complexes. The quaternary structure of the CP is conserved across all domains of life and is comprised of four coaxially stacked heptameric rings formed by structurally related α and β subunits. In eukaryotes, biogenesis of the CP is generally assumed to involve the obligate formation of α-rings. These serve as templates upon which β subunits assemble to form half-proteasomes which dimerize to give rise to CP. Here, we demonstrate the in vivo existence of an assembly-competent intermediate containing an incomplete set of both α and β subunits. The novel intermediate exhibits a precursor-product relationship with the well characterized CP assembly intermediate, the 13S. This is the first evidence that eukaryotic CP, like its archaeal and bacterial counterparts, can assemble in an α-ring independent manner.

Proteasome subunit \u03b11 overexpression preferentially drives canonical proteasome biogenesis and enhances stress tolerance in yeast

The 26S proteasome conducts the majority of regulated protein catabolism in eukaryotes. At the heart of the proteasome is the barrel-shaped 20S core particle (CP), which contains two β-rings sandwiched between two α-rings. Whereas canonical CPs contain α-rings with seven subunits arranged α1-α7, a non-canonical CP in which a second copy of the α4 subunit replaces the α3 subunit occurs in both yeast and humans. The mechanisms that control canonical versus non-canonical CP biogenesis remain poorly understood. Here, we have repurposed a split-protein reporter to identify genes that can enhance canonical proteasome assembly in mutant yeast producing non-canonical α4-α4 CPs. We identified the proteasome subunit α1 as an enhancer of α3 incorporation, and find that elevating α1 protein levels preferentially drives canonical CP assembly under conditions that normally favor α4-α4 CP formation. Further, we demonstrate that α1 is stoichiometrically limiting for α-ring assembly, and that enhancing α1 levels is sufficient to increase proteasome abundance and enhance stress tolerance in yeast. Together, our data indicate that the abundance of α1 exerts multiple impacts on proteasome assembly and composition, and we propose that the limited α1 levels observed in yeast may prime cells for alternative proteasome assembly following environmental stimuli.

Dissecting protein-protein interactions in proteasome assembly: Implication to its self-assembly.

The 26S proteasome is a multi-catalytic ATP-dependent protease complex that recognizes and cleaves damaged or misfolded proteins to maintain cellular homeostasis. The 26S subunit consists of 20S core and 19S regulatory particles. 20S core particle consists of a stack of heptameric alpha and beta subunits. To elucidate the structure-function relationship, we have dissected protein-protein interfaces of 20S core particle and analyzed structural and physiochemical properties of intra-alpha, intra-beta, inter-beta, and alpha-beta interfaces. Furthermore, we have studied the evolutionary conservation of 20S core particle. We find the size of intra-alpha interfaces is significantly larger and is more hydrophobic compared with other interfaces. Inter-beta interfaces are well packed, more polar, and have higher salt-bridge density than other interfaces. In proteasome assembly, residues in beta subunits are better conserved than alpha subunits, while multi-interface residues are the most conserved. Among all the residues at the interfaces of both alpha and beta subunits, Gly is highly conserved. The largest size of intra-alpha interfaces complies with the hypothesis that large interfaces form first during the 20S assembly. The tight packing of inter-beta interfaces makes the core particle impenetrable from outer wall of the cylinder. Comparing the three domains, eukaryotes have large and well-packed interfaces followed by archaea and bacteria. Our findings provide a structural basis of assembly of 20S core particle in all the three domains of life.

Cooperativity in Proteasome Core Particle Autocatalytic Processing

Proteasomes are complex proteases that can be found in bacteria, archaea, and eukaryotes. The formation of core particle (CP) is not trivial as it involves 28 polypeptides forming a cylindrical structure that undergoes maturation by processing of propeptides present on the β subunits. The propeptides play an important role during assembly and different roles have been described. Here, using bioinformatics approaches we identified three distinct regions in bacterial β propeptides. Molecular Dynamics simulations indicated the presence of a flexible loop‐like region (region III) that extended out of the half CP assembly intermediate for periods. We therefore hypothesized a role for region III in the dimerization of two half CPs. To test this, we used in vitro reconstitution assays with Rhodococcus erythropolis α and β subunits. Mutations in region III caused a severely reduced rate of dimerization. Region II has previously been shown to be structured and function in the association of β with two α's. When we mutated the N‐terminal region, region I, we saw an increase in rate of dimerization but a much slower rate of maturation. Since maturation requires autocatalytic removal of β‐propeptides, this suggests that the region I plays a role in efficient cleavage of the propeptide from β. The reduced maturation rate of Region I mutants allowed us to capture both pre‐holoproteasome (i.e. assembled CP with propeptides present) and holoproteasome complexes simultaneously in a reconstitution. The absence of any other intermediate forms, where a subset of the propeptides were processed, indicates that while the propeptides are processed slowly in general, the switch to holoproteasome happens within a very short time frame. This suggests the existence of cooperativity phenomenon in CP maturation. Probing for mechanisms that might explain this cooperativity, we tested for the ability of a processed β subunit to trim the propeptide of a neighboring β subunit, which we could envision as a trigger for faster processing or a conformational change. Indeed, we were able to detect cross processing of propeptides in this Rhodococcus erythropolis reconstitution assay by neighboring active β subunits both from within the same β ring as well as across the dimer interface. In conclusion, we identified novel roles of the bacterial propeptide in regulating the dimerization through region III, as well as its role in the regulating the maturation of pre‐holoproteasome through region I. Presence of two distinct populations of active and inactive CPs shows that dimerization and maturation are distinct processes.Support or Funding InformationNIGMS R15 GM112142, R01 GM118660, K‐INBRE P20 GM103418This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Modeling Proteasome Assembly Pathways in Bacteria

Cells employ various systems to remove unwanted or damaged proteins. The proteasome is one such system, which is a large macromolecular machine that functions in degrading proteins and regulating cellular processes. It consists of a 20S Core Particle (CP) capped by a Regulatory Particle (RP). The CP is comprises of four stacked rings each made up of seven monomers (α and β) stacked in a barrel-shaped architecture. Modulating proteasome function for therapeutic purposes has gained significant interest during the past decade to combat diseases like cancer and drug resistant tuberculosis. Recent findings suggest that Mycobacterium tuberculosis(Mtb) is an attractive target for proteasome inhibitors. The CP of Rhodococcus erythroplisshares about 64% sequence identity to Mtband its assembly has been well-characterized experimentally. In all organisms, CP assembly follows a hierarchical pathway where two Half Proteasomes (HP: α7β7) are formed first and then dimerize to form CP (α7β7β7α7). It is hypothesized that HP formation follows different pathways in archaea, bacteria and eukaryotes, but we currently lack definitive evidence for these hypotheses. In this work, we employed mathematical models to study the CP assembly pathway in R. erythropolis. Specifically, we found that more hierarchical assembly pathways provide the system with greater robustness against kinetic trapping at high concentration. The robustness of these pathways comes at the cost of significantly slower assembly kinetics. Comparison of our simulations with experimental data suggests that the CP in R. erythropolisemploys an assembly pathway that is much less hierarchical than has been previously proposed. Further experimental and theoretical investigation of CP assembly will be crucial to efforts aimed at inhibiting or modulating proteasome function in bacteria and other organisms.

Kinetic Trapping and Robustness in Proteasome Assembly

Many macromolecular machines are involved in cellular functions like protein homeostasis, cellular transport, cell fate determination, etc. These machines are synthesized as a set of subunits that must be assembled in order for the complex to be functional. Kinetic trapping, where large intermediates are formed that cannot proceed to the fully-assembled structure, can drastically reduce assembly yields. It is thus likely that macromolecular machines have evolved assembly pathways that avoid kinetic trapping. In this study we have chosen the 20S proteasome Core Particle (CP) from the actinomycete Rhodococcus erythropolis as our model system to characterize kinetic trapping, since it's subunits can be purified and they readily self-assemble into functional CPs in vitro. The proteasome CP is made up of four stacked rings of either seven α or seven β subunits; these rings are arranged in an α7β7β7α7 order. Using mathematical models and experimental data, we have shown that CP assembly in Rhodococcus likely involves a trade-off between assembly speed and robustness to kinetic trapping. These findings not only provide insight into the evolutionary pressures on macromolecular assemblies but also can be used to develop novel drugs that inhibit CP assembly (particularly for the treatment of Mycobacterium tuberculosis infections). Our results are also important for the engineering of protein nano machines that self-assemble quickly and efficiently.

PAC1-PAC2 proteasome assembly chaperone retains the core α4-α7 assembly intermediates in the cytoplasm.

The proteasome core particle (CP) is a cytoplasmic and nuclear protease complex and is comprised of two α-rings and two β-rings stacked in order of αββα. The assembly of CP proceeds by ordered recruitment of β-subunits on an α-ring with help of assembly chaperones PAC1-PAC2, PAC3-PAC4, and UMP1. However, the mechanism of α-ring formation remains unsolved. Here, we show that α4, α5, α6, and α7 form a core intermediate as the initial process of α-ring assembly, which requires PAC3-PAC4. α1 and α3 can be incorporated independently into the core α4-α7 intermediate, whereas α2 incorporation is dependent on preceding incorporation of α1. Through these processes, PAC1-PAC2 prevents nonproductive dimerization of α-ring assembly intermediates. We also found that PAC1-PAC2 overrides the effect of nuclear localization signals of α-subunits and retains α-ring assembly intermediates in the cytoplasm. Our results first show a detailed assembly pathway of proteasomal α-ring and explain the mechanism by which CP assembly occurs in the cytoplasm.

The inhibition effect of GLS4JHS on the transcription activity of covalently closed circular DNA in HepAD38 cells

Objective The hepatitis B virus (HBV) core protein assembly inhibitors GLS4JHS could destroy HBV capsid assembly and the formation of non-capsid polymer structure. The aim of this study is to explore the mechanisms of GLS4JHS in inhibiting HBV replication. Methods HepAD38 cells was used as the study model. TaqMan real-time polymerase chain reaction (PCR) and quantitative real-time PCR with specific primers were used to measure the change in pregenomic RNA (pgRNA) and covalently closed circular DNA (cccDNA) levels under different concentrations. ChIP assay in HepAD38 cells was used to assess the recruitment of HBV core protein and histone modifications. Results The amount of cccDNA and pgRNA decreased with the increasing GLS4JHS concentrations. After the drug concentrations reached 400 nmol/L, cccDNA and pgRNA declined by 94% and 84%, respectively. Both HBV core protein occupancy on the cccDNA and cccDNA-bound H3 histone acetylation were reduced by GLS4JHS. Conclusions GLS4JHS decreases transcriptional activity of cccDNA and reduces pgRNA production by inhibiting cccDNA minichromosome bound to HBV core protein and acetylated histone H3, which results in HBV DNA formation. Key words: Hepatitis B virus; Inhibitor of core particle assembly; GLS4JHS; Covalently closed circular DNA

Molecular chaperones of the Hsp70 family assist in the assembly of 20S proteasomes

The eukaryotic 26S proteasome is a large protease comprised of two major sub assemblies, the 20S proteasome, or core particle (CP), and the 19S regulatory particle (RP). Assembly of the CP and RP is assisted by an expanding list of dedicated assembly factors. For the CP, this includes Ump1 and the heterodimeric Pba1–Pba2 and Pba3–Pba4 proteins. It is not known how many additional proteins that assist in proteasome biogenesis remain to be discovered. Here, we demonstrate that two members of the Hsp70 family in yeast, Ssa1 and Ssa2, play a direct role in CP assembly. Ssa1 and Ssa2 interact genetically and physically with proteasomal components. Specifically, they associate tightly with known CP assembly intermediates, but not with fully assembled CP, through an extensive purification protocol. And, in yeast lacking both Ssa1 and Ssa2, specific defects in CP assembly are observed.

The Casein Kinase 2-Dependent Phosphorylation of NS5A Domain 3 from Hepatitis C Virus Followed by Time-Resolved NMR Spectroscopy.

Hepatitis C virus (HCV) chronically affects millions of individuals worldwide. The HCV nonstructural protein 5A (NS5A) plays a critical role in the viral assembly pathway. Domain 3 (D3) of NS5A is an unstructured polypeptide responsible for the interaction with the core particle assembly structure. Casein kinase 2 (CK2) phosphorylates NS5A-D3 at multiple sites that have mostly been predicted and only observed indirectly. In order to identify the CK2-dependent phosphorylation sites, we monitored the reaction between NS5A-D3 and CK2 in vitro by time-resolved NMR. We unambiguously identified four serine residues as substrates of CK2. The apparent rate constant for each site was determined from the reaction curves. Ser408 was quickly phosphorylated, whereas the three other serine residues reacted more slowly. These results provide a starting point from which to elucidate the role of phosphorylation in the mechanisms of viral assembly-and in the modulation of the viral activity-at the molecular level.

Nucleosome Core Particle Disassembly and Assembly Kinetics Studied Using Single-Molecule Fluorescence

The stability of the nucleosome core particle (NCP) is believed to play a major role in regulation of gene expression. To understand the mechanisms that influence NCP stability, we studied stability and dissociation and association kinetics under different histone protein (NCP) and NaCl concentrations using single-pair Förster resonance energy transfer and alternating laser excitation techniques. The method enables distinction between folded, unfolded, and intermediate NCP states and enables measurements at picomolar to nanomolar NCP concentrations where dissociation and association reactions can be directly observed. We reproduced the previously observed nonmonotonic dependence of NCP stability on NaCl concentration, and we suggest that this rather unexpected behavior is a result of interplay between repulsive and attractive forces within positively charged histones and between the histones and the negatively charged DNA. Higher NaCl concentrations decrease the attractive force between the histone proteins and the DNA but also stabilize H2A/H2B histone dimers, and possibly (H3/H4)2 tetramers. An intermediate state in which one DNA arm is unwrapped, previously observed at high NaCl concentrations, is also explained by this salt-induced stabilization. The strong dependence of NCP stability on ion and histone concentrations, and possibly on other charged macromolecules, may play a role in chromosomal morphology.

N-terminal α7 deletion of the proteasome 20S core particle substitutes for yeast PI31 function.

The proteasome core particle (CP) is a conserved protease complex that is formed by the stacking of two outer α-rings and two inner β-rings. The α-ring is a heteroheptameric ring of subunits α1 to α7 and acts as a gate that restricts entry of substrate proteins into the catalytic cavity formed by the two abutting β-rings. The 31-kDa proteasome inhibitor (PI31) was originally identified as a protein that binds to the CP and inhibits CP activity in vitro, but accumulating evidence indicates that PI31 is required for physiological proteasome activity. To clarify the in vivo role of PI31, we examined the Saccharomyces cerevisiae PI31 ortholog Fub1. Fub1 was essential in a situation where the CP assembly chaperone Pba4 was deleted. The lethality of Δfub1 Δpba4 was suppressed by deletion of the N terminus of α7 (α7ΔN), which led to the partial activation of the CP. However, deletion of the N terminus of α3, which activates the CP more efficiently than α7ΔN by gate opening, did not suppress Δfub1 Δpba4 lethality. These results suggest that the α7 N terminus has a role in CP activation different from that of the α3 N terminus and that the role of Fub1 antagonizes a specific function of the α7 N terminus.