20S proteasome assembly is orchestrated by two distinct pairs of chaperones in yeast and in mammals

The 20S proteasome is the catalytic core of the 26S proteasome, a central enzyme in the ubiquitin-proteasome system. Its assembly proceeds in a multistep and orderly fashion. Ump1 is the only well-described chaperone dedicated to the assembly of the 20S proteasome in yeast. Here, we report a phenotype related to the DNA damage response that allowed us to isolate four other chaperones of yeast 20S proteasomes, which we named Poc1-Poc4. Poc1/2 and Poc3/4 form two pairs working at different stages in early 20S proteasome assembly. We identify PAC1, PAC2, the recently described PAC3, and an uncharacterized protein that we named PAC4 as functional mammalian homologs of yeast Poc factors. Hence, in yeast as in mammals, proteasome assembly is orchestrated by two pairs of chaperones acting upstream of the half-proteasome maturase Ump1. Our findings provide evidence for a remarkable conservation of a pairwise chaperone-assisted proteasome assembly throughout evolution.     

Identification of Proteassemblin,a Mammalian Homologue of the Yeast Protein,Ump1p,That Is Required for Normal Proteasome Assembly

We have identified a mammalian homologue of yeast Ump1p by searching for similar proteins in human and mouse expressed sequence tag (EST) databases. Ump1p is an accessory protein that is required for normal proteasome assembly in yeast (1). A mammalian homologue, which we refer to as “proteassemblin,” is a constituent of proteasome assembly intermediates (preproteasomes), but not fully assembled 20S proteasomes, as is Ump1p in yeast. We also provide evidence that proteassemblin is a constituent of pre-immunoproteasomes that contain the precursor of the interferon-γ-inducible subunit LMP2. By analogy with Ump1p, we hypothesize that proteassemblin is required for normal mammalian proteasome assembly.     

beta-Subunit appendages promote 20S proteasome assembly by overcoming an Ump1-dependent checkpoint

Proteasomes are responsible for most intracellular protein degradation in eukaryotes. The 20S proteasome comprises a dyad-symmetric stack of four heptameric rings made from 14 distinct subunits. How it assembles is not understood. Most subunits in the central pair of beta-subunit rings are synthesized in precursor form. Normally, the beta5 (Doa3) propeptide is essential for yeast proteasome biogenesis, but overproduction of beta7 (Pre4) bypasses this requirement. Bypass depends on a unique beta7 extension, which contacts the opposing beta ring. The resulting proteasomes appear normal but assemble inefficiently, facilitating identification of assembly intermediates. Assembly occurs stepwise into precursor dimers, and intermediates contain the Ump1 assembly factor and a novel complex, Pba1-Pba2. beta7 incorporation occurs late and is closely linked to the association of two half-proteasomes. We propose that dimerization is normally driven by the beta5 propeptide, an intramolecular chaperone, but beta7 addition overcomes an Ump1-dependent assembly checkpoint and stabilizes the precursor dimer.     

Structure of a Proteasome Pba1-Pba2 Complex: IMPLICATIONS FOR PROTEASOME ASSEMBLY,ACTIVATION, AND BIOLOGICAL FUNCTION*

The 20S proteasome is an essential, 28-subunit protease that sequesters proteolytic sites within a central chamber, thereby repressing substrate degradation until proteasome activators open the entrance/exit gate. Two established activators, Blm10 and PAN/19S, induce gate opening by binding to the pockets between proteasome α-subunits using C-terminal HbYX (hydrophobic-tyrosine-any residue) motifs. Equivalent HbYX motifs have been identified in Pba1 and Pba2, which function in proteasome assembly. Here, we demonstrate that Pba1-Pba2 proteins form a stable heterodimer that utilizes its HbYX motifs to bind mature 20S proteasomes in vitro and that the Pba1-Pba2 HbYX motifs are important for a physiological function of proteasomes, the maintenance of mitochondrial function. Other factors that contribute to proteasome assembly or function also act in the maintenance of mitochondrial function and display complex genetic interactions with one another, possibly revealing an unexpected pathway of mitochondrial regulation involving the Pba1-Pba2 proteasome interaction. Our determination of a proteasome Pba1-Pba2 crystal structure reveals a Pba1 HbYX interaction that is superimposable with those of known activators, a Pba2 HbYX interaction that is different from those reported previously, and a gate structure that is disrupted but not sufficiently open to allow entry of even small peptides. These findings extend understanding of proteasome interactions with HbYX motifs and suggest multiple roles for Pba1-Pba2 interactions throughout proteasome assembly and function.     

Mechanism of proteasome gate modulation by assembly chaperones Pba1 and Pba2

The active sites of the proteasome are housed within its central core particle (CP), a barrel-shaped chamber of four stacked heptameric rings, and access of substrates to the CP interior is mediated by gates at either axial end. These gates are constitutively closed and may be opened by the regulatory particle (RP), which binds the CP and facilitates substrate degradation. We recently showed that the heterodimeric CP assembly chaperones Pba1/2 also mediate gate opening through an unexpected structural arrangement that facilitates the insertion of the N terminus of Pba1 into the CP interior; however, the full mechanism of Pba1/2-mediated gate opening is unclear. Here, we report a detailed analysis of CP gate modulation by Pba1/2. The clustering of key residues at the interface between neighboring α-subunits is a critical feature of RP-mediated gate opening, and we find that Pba1/2 recapitulate this strategy. Unlike RP, which inserts at six α-subunit interfaces, Pba1/2 insert at only two α-subunit interfaces. Nevertheless, Pba1/2 are able to regulate six of the seven interfacial clusters, largely through direct interactions. The N terminus of Pba1 also physically interacts with the center of the gate, disrupting the intersubunit contacts that maintain the closed state. This novel mechanism of gate modulation appears to be unique to Pba1/2 and therefore likely occurs only during proteasome assembly. Our data suggest that release of Pba1/2 at the conclusion of assembly is what allows the nascent CP to assume its mature gate conformation, which is primarily closed, until activated by RP.     

Ump1 extends yeast lifespan and enhances viability during oxidative stress: Central role for the proteasome?

Increasing evidence suggests that the proteasome may play an important role in both oxidative stress response and cellular aging, although considerable controversy exists as to the exact role the proteasome plays in each of these paradigms. In the present study we examined the contribution of impaired proteasome function to the regulation of oxidative damage (oxidized protein levels) following the administration of oxidative stressors, and to the cytotoxicity observed in aging and oxidatively challenged cells. In these studies the preservation of proteasome-mediated protein degradation was achieved via increased expression of the proteasome assembly protein Ump1. We observed that Saccharomyces cerevisiae transformed to express increased levels of Ump1 exhibited increased viability in response to a variety of oxidative stressors (menadione, hydrogen peroxide, 4-hydroxynonenal). The increased viability observed in each of these paradigms was associated with an enhanced preservation of proteasome-mediated protein degradation, consistent with the preservation of proteasome function being sufficient to ameliorate oxidative stress-induced cytotoxicity. Interestingly, cells expressing Ump1 were observed to initially have robust elevations in oxidized protein levels following the addition of oxidative stressors, but exhibited a significantly reduced level of oxidized proteins following the removal of oxidative stressors. Cells expressing elevated levels of Ump1 also exhibited an enhanced preservation of proteasome-mediated protein degradation, and enhanced viability during stationary-phase aging. Taken together these data strongly support a role for the proteasome serving as a central regulator of cellular viability during oxidative stress and during aging.     

Crystal structure of human proteasome assembly chaperone PAC4 involved in proteasome formation

The 26S proteasome is a large protein complex, responsible for degradation of ubiquinated proteins in eukaryotic cells. Eukaryotic proteasome formation is a highly ordered process that is assisted by several assembly chaperones. The assembly of its catalytic 20S core particle depends on at least five proteasome‐specific chaperones, i.e., proteasome‐assembling chaperons 1–4 (PAC1–4) and proteasome maturation protein (POMP). The orthologues of yeast assembly chaperones have been structurally characterized, whereas most mammalian assembly chaperones are not. In the present study, we determined a crystal structure of human PAC4 at 1.90‐Å resolution. Our crystallographic data identify a hydrophobic surface that is surrounded by charged residues. The hydrophobic surface is complementary to that of its binding partner, PAC3. The surface also exhibits charge complementarity with the proteasomal α4–5 subunits. This will provide insights into human proteasome‐assembling chaperones as potential anticancer drug targets.     

Blm3 is part of nascent proteasomes and is involved in a late stage of nuclear proteasome assembly

Proteasomes are multisubunit proteases that are responsible for regulated proteolysis. The degradation of the proteasomal maturation factor, named Ump1 in yeast, completes the autocatalytic processing of inactive precursor complexes into the proteolytically active core particle (CP) of the proteasome. We have identified Blm3, a conserved nuclear protein, as a new component of Ump1-associated precursor complexes. A lack of Blm3 resulted in an increased rate of precursor processing and an accelerated turnover of Ump1, which suggests that Blm3 prevents premature activation of proteasomal CPs. On the basis of biochemical fractionation experiments combined with in vivo localization studies, we propose that Blm3 joins nascent CPs inside the nucleus to coordinate late stages of proteasome assembly in yeast.     

26S蛋白酶体组装的分子机制研究

26S蛋白酶体广泛分布于真核细胞中的胞质和胞核,主要是由20S核心复合物(coreparticle,CP)和19S调节复合物(regulatory particle,RP)组成,它负责细胞大多数蛋白质的降解,在几乎所有生命活动中具有关键的调控作用。26S蛋白酶体的组装是一个非常复杂且高度条理的过程,不同的分子伴侣,如PAC1-4、Ump1、p27、p28和s5b等,参与其中发挥识别及调节作用,以确保高效准确地完成蛋白酶体的组装。本文系统总结分析了20S核心复合物和19S调节复合物的组装过程及调控机制的最近研究进展。     

Yeast Nst1 is a novel component of P-bodies and is a specific suppressor of proteasome base assembly defects

Proteasome assembly utilizes multiple dedicated assembly chaperones and is regulated by signaling pathways that respond to diverse stress conditions. To discover new factors influencing proteasome base assembly, we screened a tiled high-copy yeast genomic library to identify dosage suppressors of a temperature-sensitive proteasome regulatory particle (RP) base mutant. The screen identified negative salt tolerance 1 (Nst1), a protein that when overexpressed specifically suppressed the temperature sensitivity and proteasome-assembly defects of multiple base mutants. Nst1 overexpression reduced cytosolic RP ATPase (Rpt) aggregates in nas6Δ rpn14Δ cells, which lack two RP assembly chaperones. Nst1 is highly polar and predicted to have numerous intrinsically disordered regions, characteristics commonly found in proteins that can segregate into membraneless condensates. In agreement with this, both endogenous and overexpressed Nst1 could form cytosolic puncta that colocalized with processing body (P-body) components. Consistent with the accumulation of translationally inactive mRNAs in P-bodies, Nst1 overexpression inhibited global protein translation in nas6Δ rpn14Δ cells. Translational inhibition is known to suppress aggregation and proteasome assembly defects in base mutants under heat stress. Our data indicate that Nst1 is a previously overlooked P-body component that, when expressed at elevated levels inhibits translation, prevents Rpt subunit aggregation and rescues proteasome assembly under stress conditions.     

20S proteasome biogenesis

26S proteasomes are multi-subunit protease complexes responsible for the turnover of short-lived proteins. Proteasomal degradation starts with the autocatalytic maturation of the 20S core particle. Here, we summarize different models of proteasome assembly. 20S proteasomes are assembled as precursor complexes containing alpha and unprocessed beta subunits. The propeptides of the beta subunits are thought to prevent premature conversion of the precursor complexes into matured particles and are needed for efficient beta subunit incorporation. The complex biogenesis is tightly regulated which requires additional components such as the maturation factor Ump1/POMP, an ubiquitous protein in eukaryotic cells. Ump1/POMP is associated with precursor intermediates and degraded upon final maturation. Mammalian proteasomes are localized all over the cell, while yeast proteasomes mainly localize to the nuclear envelope/endoplasmic reticulum (ER) membrane network. The major localization of yeast proteasomes may point to the subcellular place of proteasome biogenesis.     

PACemakers of proteasome core particle assembly

The 26S proteasome mediates ubiquitin-dependent proteolysis in eukaryotic cells. A number of studies including very recent ones have revealed that assembly of its 20S catalytic core particle is an ordered process that involves several conserved proteasome assembly chaperones (PACs). Two heterodimeric chaperones, PAC1-PAC2 and PAC3-PAC4, promote the assembly of rings composed of seven alpha subunits. Subsequently, beta subunits join to form half-proteasome precursor complexes containing all but one of the 14 subunits. These complexes lack the beta7 subunit but contain UMP1, another assembly chaperone, and in yeast, at least to some degree, the activator protein Blm10. Dimerization of two such complexes is triggered by incorporation of beta7, whose C-terminal extension reaches out into the other half to stabilize the newly formed 20S particle. The process is completed by the maturation of active sites and subsequent degradation of UMP1 and PAC1-PAC2.     

PAC1 Gene Knockout Reveals an Essential Role of Chaperone-Mediated 20S Proteasome Biogenesis and Latent 20S Proteasomes in Cellular Homeostasis

The 26S proteasome, a central enzyme for ubiquitin-dependent proteolysis, is a highly complex structure comprising 33 distinct subunits. Recent studies have revealed multiple dedicated chaperones involved in proteasome assembly both in yeast and in mammals. However, none of these chaperones is essential for yeast viability. PAC1 is a mammalian proteasome assembly chaperone that plays a role in the initial assembly of the 20S proteasome, the catalytic core of the 26S proteasome, but does not cause a complete loss of the 20S proteasome when knocked down. Thus, both chaperone-dependent and -independent assembly pathways exist in cells, but the contribution of the chaperone-dependent pathway remains unclear. To elucidate its biological significance in mammals, we generated PAC1 conditional knockout mice. PAC1-null mice exhibited early embryonic lethality, demonstrating that PAC1 is essential for mammalian development, especially for explosive cell proliferation. In quiescent adult hepatocytes, PAC1 is responsible for producing the majority of the 20S proteasome. PAC1-deficient hepatocytes contained normal amounts of the 26S proteasome, but they completely lost the free latent 20S proteasome. They also accumulated ubiquitinated proteins and exhibited premature senescence. Our results demonstrate the importance of the PAC1-dependent assembly pathway and of the latent 20S proteasomes for maintaining cellular integrity.The 26S proteasome is a eukaryotic ATP-dependent protease responsible for the degradation of proteins tagged with polyubiquitin chains (21). The ubiquitin-dependent proteolysis by the proteasome plays a pivotal role in various cellular processes by catalyzing the selective degradation of short-lived regulatory proteins as well as damaged proteins. Thus, the proteasome is essential for the viability of all eukaryotic cells.The 26S proteasome is a large protein complex consisting of two portions; one is the catalytic 20S proteasome of approximately 700 kDa (also called the 20S core particle), and the other is the 19S regulatory particle (RP; also called PA700) of approximately 900 kDa, both of which are composed of a set of multiple distinct subunits (70). The 20S proteasome is a cylindrically shaped stack of four heptameric rings, where the outer and inner rings each are composed of seven homologous α subunits (α1 to α7) and seven homologous β subunits (β1 to β7), respectively (5). The proteolytic active sites reside within the central chamber enclosed by the two inner β-rings, while a small channel formed by the outer α-ring, which is primarily closed, restricts the access of native proteins to the catalytic chamber. Thus, the 20S proteasome is a latent enzyme. Appending 19S RP, which consists of 19 different subunits, to the α-ring enables the 20S proteasome to degrade native proteins; 19S RP accepts ubiquitin chains of substrate proteins, removes ubiquitin chains while unfolding the substrates, and feeds the substrates into the interior proteolytic chamber of the 20S proteasome through the α-ring that is opened when the C-terminal tails of the ATPase subunits of 19S RP are inserted into the intersubunit spaces of the α-ring (24, 62, 74). However, it also has been reported that some denatured or unstructured proteins can be degraded directly by the 20S proteasome even in the absence of 19S RP and ubiquitination (37, 39).Much attention has been focused on how such a highly elaborate structure is achieved. Recent studies have identified various proteasome-dedicated chaperones that assist in the assembly of the proteasome in eukaryotic cells (23, 40, 56, 57, 65, 66). In yeast, while most of the proteasome subunits are essential for viability, the deletion of any of these chaperones does not cause lethality. In fact, many, if not all, of the deletions exhibit subtle phenotypes. In mammalian cells, although the knockdown of the assembly chaperones reduced proteasome assembly and thus proteasome activity, leading to slow cell growth, the degree of reduction was much lower than that which occurred following the knockdown of the proteasome subunit itself (33, 35, 40). These results indicate that the assembly chaperones play an auxiliary role in proteasome biogenesis.Proteasome assembly chaperone 1 (PAC1) is one of the assembly chaperones originally identified in mammalian cells (34). PAC1 plays a role in α-ring formation that occurs during the initial assembly of the 20S proteasome; it also prevents the aberrant dimerization of the α-ring. As is the case for most assembly chaperones, the knockdown of PAC1 in mammalian cells decreases proteasome activity but to a lesser extent than that in, for example, β2 knockdown (34, 35). Therefore, both PAC1-dependent and -independent assembly pathways exist in cells, but the importance of the PAC1-dependent pathway remains elusive. To further elucidate the biological significance of PAC1 and PAC1-dependent proteasome biogenesis, we generated conditional mouse mutants carrying an inactivating mutation in Psmg1, the gene coding for PAC1 protein, in the whole body, the nervous system, and in the liver. Our results demonstrate that PAC1 is essential for the development of a mouse, and that it plays important roles in maintaining cellular integrity in quiescent tissue. Our study revealed for the first time the importance of chaperone-mediated proteasome biogenesis in a whole-body mammalian system and may provide valuable knowledge in medical drug development targeting proteasomes.     

Assembly of the 20S proteasome

The proteasome is a cellular protease responsible for the selective degradation of the majority of the intracellular proteome. It recognizes, unfolds, and cleaves proteins that are destined for removal, usually by prior attachment to polymers of ubiquitin. This macromolecular machine is composed of two subcomplexes, the 19S regulatory particle (RP) and the 20S core particle (CP), which together contain at least 33 different and precisely positioned subunits. How these subunits assemble into functional complexes is an area of active exploration. Here we describe the current status of studies on the assembly of the 20S proteasome (CP). The 28-subunit CP is found in all three domains of life and its cylindrical stack of four heptameric rings is well conserved. Though several CP subunits possess self-assembly properties, a consistent theme in recent years has been the need for dedicated assembly chaperones that promote on-pathway assembly. To date, a minimum of three accessory factors have been implicated in aiding the construction of the 20S proteasome. These chaperones interact with different assembling proteasomal precursors and usher subunits into specific slots in the growing structure. This review will focus largely on chaperone-dependent CP assembly and its regulation.     

The catalytic activity of Ubp6 enhances maturation of the proteasomal regulatory particle

The 26S proteasome is a 2.5 MDa macromolecular machine responsible for targeted protein degradation. Recently, four chaperones were identified that promote the assembly of the 19S regulatory particle (RP). Here, we probe the dynamic architecture of the proteasome by applying quantitative proteomics and mass spectrometry (MS) of intact complexes to provide a detailed characterization of how Ubp6 assists this assembly process. Our MS data demonstrate stoichiometric binding of chaperones and Ubp6 to the basal part of the RP. Genetic interactions of Ubp6 with Hsm3, but not with the other chaperones, indicate a functional overlay with Hsm3. Our biochemical data identified Ubp6 as an additional member of the Hsm3 module. Deletions of ubp6 with hsm3 perturb 26S proteasome assembly, which we attribute to an accumulation of ubiquitylated substrates on these assembly precursors. We therefore propose that Ubp6 facilitates proteasomal assembly by clearing ubiquitylated substrates from assembly precursors by its deubiquitylating activity.     

Structural basis for specific recognition of Rpt1p, an ATPase subunit of 26 S proteasome, by proteasome-dedicated chaperone Hsm3p

The 26 S proteasome is a 2.5-MDa molecular machine that degrades ubiquitinated proteins in eukaryotic cells. It consists of a proteolytic core particle and two 19 S regulatory particles (RPs) composed of 6 ATPase (Rpt) and 13 non-ATPase (Rpn) subunits. Multiple proteasome-dedicated chaperones facilitate the assembly of the proteasome, but little is known about the detailed mechanisms. Hsm3, a 19 S RP dedicated chaperone, transiently binds to the C-terminal domain of the Rpt1 subunit and forms a tetrameric complex, Hsm3-Rpt1-Rpt2-Rpn1, during maturation of the ATPase ring of 19 S RP. To elucidate the structural basis of Hsm3 function, we determined the crystal structures of Hsm3 and its complex with the C-terminal domain of the Rpt1 subunit (Rpt1C). Hsm3 has a C-shaped structure that consists of 11 HEAT repeats. The structure of the Hsm3-Rpt1C complex revealed that the interacting surface between Hsm3 and Rpt1 is a hydrophobic core and a complementary charged surface. Mutations in the Hsm3-Rpt1 surface resulted in the assembly defect of the 26 S proteasome. Furthermore, a structural model of the Hsm3-Rpt ring complex and an in vitro binding assay suggest that Hsm3 can bind Rpt2 in addition to Rpt1. Collectively, our results provide the structural basis of the molecular functions of Hsm3 for the RP assembly.     

Dissecting beta-ring assembly pathway of the mammalian 20S proteasome

The 20S proteasome is the catalytic core of the 26S proteasome. It comprises four stacked rings of seven subunits each, alpha(1-7)beta(1-7)beta(1-7)alpha(1-7). Recent studies indicated that proteasome-specific chaperones and beta-subunit appendages assist in the formation of alpha-rings and dimerization of half-proteasomes, but the process involved in the assembly of beta-rings is poorly understood. Here, we clarify the mechanism of beta-ring formation on alpha-rings by characterizing assembly intermediates accumulated in cells depleted of each beta-subunit. Starting from beta2, incorporation of beta-subunits occurs in an orderly manner dependent on the propeptides of beta2 and beta5, and the C-terminal tail of beta2. Unexpectedly, hUmp1, a chaperone functioning at the final assembly step, is incorporated as early as beta2 and is required for the structural integrity of early assembly intermediates. We propose a model in which beta-ring formation is assisted by both intramolecular and extrinsic chaperones, whose roles are partially different between yeast and mammals.     

Molecular chaperones: assisting assembly in addition to folding

The common perception that molecular chaperones are involved primarily with assisting the folding of newly synthesized and stress-denatured polypeptide chains ignores the fact that this term was invented to describe the function of a protein that assists the assembly of folded subunits into oligomeric structures and only later was extended to embrace protein folding. Recent work has clarified the role of nuclear chaperones in the assembly of nucleosomes and has identified a cytosolic chaperone required for mammalian proteasome assembly, suggesting that the formation of other oligomeric complexes might be assisted by chaperones.     

Characterization of the 20S proteasome of the lepidopteran,Spodoptera frugiperda

Multiple complexes of 20S proteasomes with accessory factors play an essential role in proteolysis in eukaryotic cells. In this report, several forms of 20S proteasomes from extracts of Spodoptera frugiperda (Sf9) cells were separated using electrophoresis in a native polyacrylamide gel and examined for proteolytic activity in the gel and by Western blotting. Distinct proteasome bands isolated from the gel were subjected to liquid chromatography-tandem mass spectrometry and identified as free core particles (CP) and complexes of CP with one or two dimers of assembly chaperones PAC1-PAC2 and activators PA28γ or PA200. In contrast to the activators PA28γ and PA200 that regulate the access of protein substrates to the internal proteolytic chamber of CP in an ATP-independent manner, the 19S regulatory particle (RP) in 26S proteasomes performs stepwise substrate unfolding and opens the chamber gate in an ATP-dependent manner. Electron microscopic analysis suggested that spontaneous dissociation of RP in isolated 26S proteasomes leaves CPs with different gate sizes related presumably to different stages in the gate opening. The primary structure of 20S proteasome subunits in Sf9 cells was determined by a search of databases and by sequencing. The protein sequences were confirmed by mass spectrometry and verified by 2D gel electrophoresis. The relative rates of sequence divergence in the evolution of 20S proteasome subunits, the assembly chaperones and activators were determined by using bioinformatics. The data confirmed the conservation of regular CP subunits and PA28γ, a more accelerated evolution of PAC2 and PA200, and especially high divergence rates of PAC1.