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.     

Backbone 1H, 13C,and 15N assignments of yeast Ump1, an intrinsically disordered protein that functions as a proteasome assembly chaperone

Eukaryotic proteasome assembly is a highly organized process mediated by several proteasome-specific chaperones, which interact with proteasome assembly intermediates. In yeast, Ump1 and Pba1-4 have been identified as assembly chaperones that are dedicated to the formation of the proteasome 20S catalytic core complex. The crystal structures of Pba chaperones have been reported previously, but no detailed information has been provided for the structure of Ump1. Thus, to better understand the mechanisms underlying Ump1-mediated proteasome assembly, we characterized the conformation of Ump1 in solution using NMR. Backbone chemical shift data indicated that Ump1 is an intrinsically unstructured protein and largely devoid of secondary structural elements.     

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.     

Protein-protein interactions among human 20S proteasome subunits and proteassemblin

Immunoproteasomes and standard proteasomes assemble by alternative pathways that bias against the formation of certain "mixed" proteasomes. Differences between beta subunit propeptides contribute to assembly specificity and an assembly chaperone, proteassemblin, may be involved via differential propeptide interactions. We investigated possible mechanisms of biased proteasome assembly and the role of proteassemblin by identifying protein-protein interactions among human 20S proteasome subunits and proteassemblin using a yeast two-hybrid interaction assay. Forty-one interactions were detected, including five involving proteassemblin and contiguous beta subunits, which suggests that proteassemblin binds to preproteasomes via a beta subunit surface. Interaction between proteassemblin and beta5, but not beta5i, suggests that proteassemblin may be involved in the propeptide-dependent differential incorporation of these subunits. Interactions between proteassemblin and beta1, beta1i, and beta7 suggest that proteassemblin may regulate preproteasome dimerization via interactions with the C-termini of these subunits, which in the mature 20S structure extend to contact opposing beta subunit rings.     

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.     

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。     

Characterisation of the newly identified human Ump1 homologue POMP and analysis of LMP7(beta 5i) incorporation into 20 S proteasomes

Biogenesis of mammalian 20 S proteasomes occurs via precursor complexes containing alpha and unprocessed beta subunits. A human homologue of the yeast proteasome maturation factor Ump1 was identified in 2D gels of 16 S precursor preparations and designated as POMP (proteasome maturation protein). We show that POMP is detected only in precursor fractions and not in fractions containing mature 20 S proteasome. Northern blot experiments revealed that expression of POMP is induced after treatment with interferon gamma. To analyse the role of the beta 5 propeptide for proper maturation and incorporation of the beta 5 subunit into the complex, human T2 cells, which highly express derivatives of the beta 5i subunit (LMP7), were studied. In contrast to yeast, the presence of the beta 5 propeptide is not essential for incorporation of LMP7 into the proteasome complex. Mutated LMP7 subunits either carrying the prosequence of beta 2i (LMP2) or containing a mutation in the active threonine site are incorporated like wild-type LMP7, while a LMP7 derivative lacking the prosequence completely is incorporated to a lesser extent. Although the absence of the prosequence does not affect incorporation of LMP7, its deletion leads to delayed proteasome maturation and thereby to an accumulation of precursor complexes. As a result of the precursor accumulation, an increased amount of the POMP protein can be detected in these cells.     

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.     

Moe1 and spInt6, the fission yeast homologues of mammalian translation initiation factor 3 subunits p66 (eIF3d) and p48 (eIF3e), respectively, are required for stable association of eIF3 subunits

The protein encoded by the fission yeast gene, moe1(+) is the homologue of the p66/eIF3d subunit of mammalian translation initiation factor eIF3. In this study, we show that in fission yeast, Moe1 physically associates with eIF3 core subunits as well as with 40 S ribosomal particles as a constituent of the eIF3 protein complex that is similar in size to multisubunit mammalian eIF3. However, strains lacking moe1(+) (Deltamoe1) are viable and show no gross defects in translation initiation, although the rate of translation in the Deltamoe1 cells is about 30-40% slower than wild-type cells. Mutant Deltamoe1 cells are hypersensitive to caffeine and defective in spore formation. These phenotypes of Deltamoe1 cells are similar to those reported previously for deletion of the fission yeast int6(+) gene that encodes the fission yeast homologue of the p48/Int6/eIF3e subunit of mammalian eIF3. Further analysis of eIF3 subunits in Deltamoe1 or Deltaint6 cells shows that in these deletion strains, while all the eIF3 subunits are bound to 40 S particles, dissociation of ribosome-bound eIF3 results in the loss of stable association between the eIF3 subunits. In contrast, eIF3 isolated from ribosomes of wild-type cells are associated with one another in a protein complex. These observations suggest that Moe1 and spInt6 are each required for stable association of eIF3 subunits in fission yeast.     

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.     

AAA-ATPase p97/Cdc48p, a Cytosolic Chaperone Required for Endoplasmic Reticulum-Associated Protein Degradation

Endoplasmic reticulum-associated degradation (ERAD) disposes of aberrant proteins in the secretory pathway. Protein substrates of ERAD are dislocated via the Sec61p translocon from the endoplasmic reticulum to the cytosol, where they are ubiquitinated and degraded by the proteasome. Since the Sec61p channel is also responsible for import of nascent proteins, this bidirectional passage should be coordinated, probably by molecular chaperones. Here we implicate the cytosolic chaperone AAA-ATPase p97/Cdc48p in ERAD. We show the association of mammalian p97 and its yeast homologue Cdc48p in complexes with two respective ERAD substrates, secretory immunoglobulin M in B lymphocytes and 6myc-Hmg2p in yeast. The membrane 6myc-Hmg2p as well as soluble lumenal CPY*, two short-lived ERAD substrates, are markedly stabilized in conditional cdc48 yeast mutants. The involvement of Cdc48p in dislocation is underscored by the accumulation of ERAD substrates in the endoplasmic reticulum when Cdc48p fails to function, as monitored by activation of the unfolded protein response. We propose that the role of p97/Cdc48p in ERAD, provided by its potential unfoldase activity and multiubiquitin binding capacity, is to act at the cytosolic face of the endoplasmic reticulum and to chaperone dislocation of ERAD substrates and present them to the proteasome.     

Possible tetramerisation of the proteasome maturation factor POMP/proteassemblin/hUmp1 and its subcellular localisation

The proteasome is a multisubunit complex with a central role in non-lysosomal proteolysis and the processing of proteins for presentation by the MHC class I pathway. The 16 kDa proteasome maturation protein POMP (also named proteassemblin or hUmp1) acts as a chaperone and is essential for the maturation of the 20S proteasome proteolytic core complex. However, the exact mechanism, timing and localisation of mammalian proteasome assembly remains elusive. We sought to investigate the localisation of POMP within the cell and therefore purified the protein and produced a polyclonal antibody. For immunisation, POMP was overexpressed and purified from a bacterial GST-system. Interestingly, after removal of the GST-tag, POMP was hardly detectable by Coomassie blue- and Ponceau red-staining. However, with a reverse zinc-staining, the protein could easily be visualised. POMP was gel-filtrated and eluted from a calibrated chromatography column with an apparent molecular weight of approximately 64 kDa, suggesting that it forms tetramers. Moreover, localisation studies by immunofluorescence stainings and confocal microscopy revealed that POMP is present in the cytoplasm as well as in the nucleus.     

Saccharomyces cerevisiae Npc2p is a functionally conserved homologue of the human Niemann-Pick disease type C 2 protein, hNPC2

Niemann-Pick Disease Type C (NP-C) is a fatal neurodegenerative disease, which is biochemically distinguished by the lysosomal accumulation of exogenously derived cholesterol. Mutation of either the hNPC1 or hNPC2 gene is causative for NP-C. We report the identification of the yeast homologue of human NPC2, Saccharomyces cerevisiae Npc2p. We demonstrate that scNpc2p is evolutionarily related to the mammalian NPC2 family of proteins. We also show, through colocalization, subcellular fractionation, and secretion analyses, that yeast Npc2p is treated similarly to human NPC2 when expressed in mammalian cells. Importantly, we show that yeast Npc2p can efficiently revert the unesterified cholesterol and GM1 accumulation seen in hNPC2-/- patient fibroblasts demonstrating that it is a functional homologue of human NPC2. The present study reveals that the fundamental process of NPC2-mediated lipid transport has been maintained throughout evolution.     

SEL1L is required for endoplasmic reticulum-associated degradation of misfolded luminal proteins but not transmembrane proteins in chicken DT40 cell line

Proteins misfolded in the endoplasmic reticulum (ER) are degraded in the cytosol by a ubiquitin-dependent proteasome system, a process collectively termed ER-associated degradation (ERAD). Unraveling the molecular mechanisms of mammalian ERAD progresses more slowly than that of yeast ERAD due to the laborious procedures required for gene targeting and the redundancy of components. Here, we utilized the chicken B lymphocyte-derived DT40 cell line, which exhibits an extremely high homologous recombination frequency, to analyze ERAD mechanisms in higher eukaryotes. We disrupted the SEL1L gene, which encodes the sole homologue of yeast Hrd3p in both chickens and mammals; Hrd3p is a binding partner of yeast Hrd1p, an E3 ubiquitin ligase. SEL1L-knockout cells grew only slightly more slowly than the wild-type cells. Pulse chase experiments revealed that chicken SEL1L was required for ERAD of misfolded luminal proteins such as glycosylated NHK and unglycosylated NHK-QQQ but dispensable for that of misfolded transmembrane proteins such as NHK(BACE) and CD3-δ, as in mammals. The defect of SEL1L-knockout cells in NHK degradation was restored by introduction of not only chicken SEL1L but also mouse and human SEL1L. Deletion analysis showed the importance of Sel1-like tetratricopeptide repeats but not the fibronectin II domain in the function of SEL1L. Thus, our reverse genetic approach using the chicken DT40 cell line will provide highly useful information regarding ERAD mechanisms in higher eukaryotes which express ERAD components redundantly.     

Analysis of intracellular distribution and apoptosis involvement of the Ufd1l gene product by over-expression studies

UFD1L is the human homologue of the yeast ubiquitin fusion degradation 1 (Ufd1) gene and maps on chromosome 22q11.2 in the typically deleted region (TDR) for DiGeorge/velocardiofacial syndromes (DGS/VCFS). In yeast, Ufd1 protein is involved in a degradation pathway for ubiquitin fused products (UFD pathway). Several studies have demonstrated that Ufd1 is a component of the Cdc48-Ufd1-Npl4 multiprotein complex which is active in the recognition of several polyubiquitin-tagged proteins and facilitates their presentation to the 26S proteasome for protein degradation or even more specific processing. The multiprotein complex Cdc48-Ufd-Npl4 is also active in mammalian cells. The biochemical role of UFD1L protein in human cells is unknown, even though the interaction between UFD1L and NPL4 proteins has been maintained. In order to clarify this issue, we examined the intracellular distribution of the protein in different mammalian cells and studied its involvement in the Fas and ceramide factors-mediated apoptotic pathways. We established that in mammalian cells, Ufd1l is localized around the nucleus and that it does not interfere with Fas-and ceramide-mediated apoptosis.     

ADD66, a gene involved in the endoplasmic reticulum-associated degradation of alpha-1-antitrypsin-Z in yeast, facilitates proteasome activity and assembly

Antitrypsin deficiency is a primary cause of juvenile liver disease, and it arises from expression of the "Z" variant of the alpha-1 protease inhibitor (A1Pi). Whereas A1Pi is secreted from the liver, A1PiZ is retrotranslocated from the endoplasmic reticulum (ER) and degraded by the proteasome, an event that may offset liver damage. To better define the mechanism of A1PiZ degradation, a yeast expression system was developed previously, and a gene, ADD66, was identified that facilitates A1PiZ turnover. We report here that ADD66 encodes an approximately 30-kDa soluble, cytosolic protein and that the chymotrypsin-like activity of the proteasome is reduced in add66Delta mutants. This reduction in activity may arise from the accumulation of 20S proteasome assembly intermediates or from qualitative differences in assembled proteasomes. Add66p also seems to be a proteasome substrate. Consistent with its role in ER-associated degradation (ERAD), synthetic interactions are observed between the genes encoding Add66p and Ire1p, a transducer of the unfolded protein response, and yeast deleted for both ADD66 and/or IRE1 accumulate polyubiquitinated proteins. These data identify Add66p as a proteasome assembly chaperone (PAC), and they provide the first link between PAC activity and ERAD.     

Isolated Mammalian and Schizosaccharomyces pombe Ran-binding Domains Rescue S. pombe sbp1 (RanBP1) Genomic Mutants

Mammalian Ran-binding protein-1 (RanBP1) and its fission yeast homologue, sbp1p, are cytosolic proteins that interact with the GTP-charged form of Ran GTPase through a conserved Ran-binding domain (RBD). In vitro, this interaction can accelerate the Ran GTPase-activating protein-mediated hydrolysis of GTP on Ran and the turnover of nuclear import and export complexes. To analyze RanBP1 function in vivo, we expressed exogenous RanBP1, sbp1p, and the RBD of each in mammalian cells, in wild-type fission yeast, and in yeast whose endogenous sbp1 gene was disrupted. Mammalian cells and wild-type yeast expressing moderate levels of each protein were viable and displayed normal nuclear protein import. sbp1(-) yeast were inviable but could be rescued by all four exogenous proteins. Two RBDs of the mammalian nucleoporin RanBP2 also rescued sbp1(-) yeast. In mammalian cells, wild-type yeast, and rescued mutant yeast, exogenous full-length RanBP1 and sbp1p localized predominantly to the cytosol, whereas exogenous RBDs localized predominantly to the cell nucleus. These results suggest that only the RBD of sbp1p is required for its function in fission yeast, and that this function may not require confinement of the RBD to the cytosol. The results also indicate that the polar amino-terminal portion of sbp1p mediates cytosolic localization of the protein in both yeast and mammalian cells.     

Isolation of the Schizosaccharomyces pombe proteasome subunit Rpn7 and a structure-function study of the proteasome-COP9-initiation factor domain

Proper assembly of the 26 S proteasome is required to efficiently degrade polyubiquitinated proteins. Many proteasome subunits contain the proteasome-COP9-initiation factor (PCI) domain, thus raising the possibility that the PCI domain may play a role in mediating proteasome assembly. We have previously characterized the PCI protein Yin6, a fission yeast ortholog of the mammalian Int6 that has been implicated in breast oncogenesis, and demonstrated that it binds and regulates the assembly of the proteasome. In this study, we isolated another PCI proteasome subunit, Rpn7, as a high copy suppressor that rescued the proteasome defects in yin6 null cells. To better define the function of the PCI domain, we aligned protein sequences to identify a conserved leucine residue that is present in nearly all known PCI domains. Replacing it with aspartate in yeast Rpn7, Yin6, and Rpn5 inactivated these proteins, and mutant human Int6 mislocalized in HeLa cells. Rpn7 and Rpn5 bind Rpn9 with high affinity, but their mutant versions do not. Our data suggest that this leucine may interact with several hydrophobic amino acid residues to influence the spatial arrangement either within the N-terminal tandem alpha-helical repeats or between these repeats and the more C-terminal winged helix subdomain. Disruption of such an arrangement in the PCI domain may substantially inactivate many PCI proteins and block their binding to other proteins.     

Mps3p is a novel component of the yeast spindle pole body that interacts with the yeast centrin homologue Cdc31p

Accurate duplication of the Saccharomyces cerevisiae spindle pole body (SPB) is required for formation of a bipolar mitotic spindle. We identified mutants in SPB assembly by screening a temperature-sensitive collection of yeast for defects in SPB incorporation of a fluorescently marked integral SPB component, Spc42p. One SPB assembly mutant contained a mutation in a previously uncharacterized open reading frame that we call MPS3 (for monopolar spindle). mps3-1 mutants arrest in mitosis with monopolar spindles at the nonpermissive temperature, suggesting a defect in SPB duplication. Execution point experiments revealed that MPS3 function is required for the first step of SPB duplication in G1. Like cells containing mutations in two other genes required for this step of SPB duplication (CDC31 and KAR1), mps3-1 mutants arrest with a single unduplicated SPB that lacks an associated half-bridge. MPS3 encodes an essential integral membrane protein that localizes to the SPB half-bridge. Genetic interactions between MPS3 and CDC31 and binding of Cdc31p to Mps3p in vitro, as well as the fact that Cdc31p localization to the SPB is partially dependent on Mps3p function, suggest that one function for Mps3p during SPB duplication is to recruit Cdc31p, the yeast centrin homologue, to the half-bridge.