Search and Destroy: ER Quality Control and ER-Associated Protein Degradation

Abstract

Proteins synthesized in the endoplasmic reticulum (ER) encounter quality control checkpoints that verify their fitness to proceed in the secretory pathway. Molecules undergoing folding and assembly are kept out of the exocytic pathway until maturation is complete. Misfolded side products that inevitably form are removed from the mixture of conformers and returned to the cytosol for degradation. How unfolded proteins are recognized and how irreversibly misfolded proteins are sorted to ER-associated degradation pathways was poorly understood. Recent developments from a combination of genetic and biochemical analyses has revealed new insights into these mechanisms. The emerging view shows distinct pathways working in collaboration to filter the diverse range of unfolded proteins from the transport flow and to divert misfolded molecules for destruction.     

蛋白质的选择性降解机制——2004年诺贝尔化学奖部分工作介绍

如何识别和选择性降解蛋白质是细胞生命过程中的重要环节.泛素-蛋白酶体需能降解途径的发现,揭示了蛋白质在细胞内选择性降解的普遍方式.对于需要清除的蛋白质,通过其赖氨酸残基侧链ε-氨基连接多聚泛素链（降解标签）,继而在蛋白酶体中被降解.这种选择性降解机制对于维持蛋白质在细胞内含量的动态平衡起到了关键性作用.     

Protein Degradation and Apoptotic Death in Lymphocytes during Fiv Infection: Activation of the Ubiquitin–Proteasome Proteolytic System

The movement of a cell through the sequential phases of apoptosis is accompanied by a progressive decrease in cell size with loss in protein mass. In lymphocytes from Hiv-infected persons, protein loss during apoptosis is due to increased protein degradation rather than decreased synthesis. To identify and characterize the proteolytic enzymes or enzyme systems involved in this process, we studied several features of protein turnover in lymphocytes from peripheral blood and lymph nodes during the natural and experimental infection by feline immunodeficiency virus (Fiv). This animal model allowed us to integratein vivoresults within vitroobservations of protein damage. Here we report that protein breakdown in apoptotic cells is concomitant with the activation of the ATP and ubiquitin-dependent multicatalytic system (proteasome). We suggest that proteasome activation is part of the proteolytic cascade in the execution phases of apoptosis in AIDS.     

植物泛素/26S蛋白酶体途径研究进展

泛素/26S蛋白酶体途径是最重要的,有高度选择性的蛋白质降解途径,由泛素激活酶、泛素结合酶、泛素蛋白连接酶和26S蛋白酶体组成,参与调控植物生长发育的多个方面。泛素蛋白酶体途径参与植物体内的众多生理过程,如植物激素信号,光形态建成、自交不亲和反应和细胞周期等。本文就泛素/26S蛋白酶体途径以及在植物生长发育中的作用的研究近况做一综述。     

The Capture of a Disabled Proteasome Identifies Erg25 as a Substrate for Endoplasmic Reticulum Associated Degradation

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Highlights

• •Epitope-tagging of a proteasome subunit allows for facile immuno-isolation.
• •An engineered yeast strain permits capture of proteasome-associated substrates.
• •MS/MS identified all 33 resident proteasome subunits in the 20S and 19S particles.
• •Analysis of associated proteins and characterization of newly identified ERAD substrate.

     

The Ubiquitin–Proteasome System and Cellular Proliferation and Regulation in Osteoblastic Cells

The 26S proteasome is the macromolecular assembly that mediates ATP- and ubiquitin-dependent extralysosomal intracellular protein degradation in eukaryotes. However, its contribution to the regulation of osteoblast proliferation and hormonal regulation remains poorly defined. Treating osteoblasts with MG-132 or lactacystin (membrane-permeable proteasome inhibitors) attenuates proliferation. Three proteasome activities (peptidylglutamyl–peptide bond hydrolase-, chymotrypsin-, and trypsin-like) were detected in osteoblasts. Catabolic doses of PTH stim-ulated these activities, and cotreatment with PTH and MG-132 blocked stimulation. The proteasome α- and β-subunits, polyubiquitins, and large ubiquitin–protein conjugates were detected by Western blotting. A 90-min treatment with 10 nM PTH had no effect on the amount of proteasome α or β subunit protein, but increased the relative amount of large ubiquitin-protein conjugates by 200%. MG-132 inhibited deubiquitination of large ubiquitin–protein conjugates. The protein kinase A inhibitor SQ22536 blocked much of the PTH-induced stimulation of MCP activities, while dibutyryl cAMP stimulated it, suggesting that protein kinase A-dependent phosphorylation is important in PTH stimulation of proteasome activities. In conclusion, the ubiquitin–proteasome system is essential for osteoblast proliferation under control and PTH-treated conditions. PTH mediates its metabolic effects on the osteoblast, in part, by enhancing ubiquitinylation of protein substrates and stimulating three major proteasome activities by a cAMP-dependent mechanism.     

Proteasome function is required to maintain muscle cellular architecture

BACKGROUND INFORMATION: Protein degradation via the UPS (ubiquitin-proteasome system) plays critical roles in muscle metabolism and signalling pathways. The present study investigates temporal requirements of the UPS in muscle using conditional expression of mutant proteasome beta subunits to cause targeted inhibition of proteasome function. RESULTS AND CONCLUSIONS: The Drosophila GeneSwitch system was used, with analyses of the well-characterized larval somatic body wall muscles. This method acutely disrupts proteasome function and causes rapid accumulation of polyubiquitinated proteins, specifically within the muscle. Within 12 h of transgenic proteasome inhibition, there was a gross disorganization of muscle architecture and prominent muscle atrophy, progressing to the arrest of all co-ordinated movement by 24 h. Progressive muscle architecture changes include rapid loss of sarcomere organization, loss of nuclei spacing/patterning, vacuole formation and the accumulation of nuclear and cytoplasmic aggregates at the ultrastructural level. At the neuromuscular junction, the highly specialized muscle membrane folds of the subsynaptic reticulum were rapidly lost. Within 24 h after transgenic proteasome inhibition, muscles contained numerous autophagosomes and displayed highly elevated expression of the endoplasmic reticulum chaperone GRP78 (glucose-regulated protein of 78 kDa), indicating that the loss of muscle maintenance correlates with induction of the unfolded protein response. Taken together, these results demonstrate that the UPS is acutely required for maintenance of muscle and neuromuscular junction architecture, and provides a Drosophila genetic model to mechanistically evaluate this requirement.     

Cryo-EM Reveals Unanchored M1-Ubiquitin Chain Binding at hRpn11 of the 26S Proteasome

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泛素/26S蛋白酶体途径与显花植物自交不亲和反应

植物的生长和发育离不开短命调控蛋白的有选择性降解,其中一种重要的降解方式就是泛素,26S蛋白酶体途径。在这个途径中,泛素（ubiquitin）和26S蛋白酶体起着至关重要的作用,需要被降解的蛋白会通过E1-E2-E3酶接合反应由Ub进行标记,随后标记蛋白会被26s蛋白酶体识别并降解。自交不亲和反应也正是通过此途径实现的,ARC1（arm repeat containing 1）和SCFs（skp1-cul1-F-box-proteins）作为E3s分别在孢子体自交不亲和和配子体自交不亲和反应中起作用。本文综述了就泛素/26S蛋白酶体途径的组成及其在自交不亲和反应中的作用。     

Proteasome and myogenesis

In this report, we examine the involvement of the ubiquitin-proteasome pathway during fusion and differentiation of myoblast primary cell cultures. Up-regulation of proteasome was observed at the maximum fusion rate and was preceded by an increase of unidentified ubiquitin-conjugates. Cell permeable proteasome inhibitors prevent fusion as do antisense oligodesoxyribonucleotides targetted to three proteasome subunits. Identical results were obtained using E3 ubiquitin-ligases dipeptide inhibitor. Involvement of the ubiquitin-proteasome pathway in the regulation of myogenic factors was hypothetized.     

Substrate selection by the proteasome through initiation regions

Proteins in the cell have to be eliminated once their function is no longer desired or they become damaged. Most regulated protein degradation is achieved by a large enzymatic complex called the proteasome. Many proteasome substrates are targeted for degradation by the covalent attachment of ubiquitin molecules. Ubiquitinated proteins can be bound by the proteasome, but for proteolysis to occur the proteasome needs to find a disordered tail somewhere in the target at which it initiates degradation. The initiation step contributes to the specificity of proteasomal degradation. Here, we review how the proteasome selects initiation sites within its substrates and discuss how the initiation step affects physiological processes.     

泛素/26S蛋白酶体途径与植物的生长发育

泛素/26S蛋白酶体途径在植物蛋白降解系统中起重要作用,泛素分子主要通过泛素活化酶(E1)、泛素结合酶(E2)和泛素连接酶(E3)将靶蛋白泛素化,泛素化的蛋白最后被26S蛋白酶体识别和降解。泛素蛋白酶体途径参与植物体内的多种生理过程,如花和胚的发育、光形态建成、植物生长物质等几乎所有的生长发育过程,本文主要对泛素/26S蛋白酶体途径及其在植物生长发育过程中的精确调控作用进行综述。     

Thiostrepton interacts covalently with Rpt subunits of the 19S proteasome and proteasome substrates

Here, we report a novel mechanism of proteasome inhibition mediated by Thiostrepton (Thsp), which interacts covalently with Rpt subunits of the 19S proteasome and proteasome substrates. We identified Thsp in a cell‐based high‐throughput screen using a fluorescent reporter sensitive to degradation by the ubiquitin–proteasome pathway. Thiostrepton behaves as a proteasome inhibitor in several paradigms, including cell‐based reporters, detection of global ubiquitination status, and proteasome‐mediated labile protein degradation. In vitro, Thsp does not block the chymotrypsin activity of the 26S proteasome. In a cell‐based IκBα degradation assay, Thsp is a slow inhibitor and 4 hrs of treatment achieves the same effects as MG‐132 at 30 min. We show that Thsp forms covalent adducts with proteins in human cells and demonstrate their nature by mass spectrometry. Furthermore, the ability of Thsp to interact covalently with the cysteine residues is essential for its proteasome inhibitory function. We further show that a Thsp modified peptide cannot be degraded by proteasomes in vitro. Importantly, we demonstrate that Thsp binds covalently to Rpt subunits of the 19S regulatory particle and forms bridges with a proteasome substrate. Taken together, our results uncover an important role of Thsp in 19S proteasome inhibition.     

26 S proteasomes function as stable entities.

Most proteins in eukaryotic cells are degraded by 26-S proteasomes, usually after being conjugated to ubiquitin. In the absence of ATP, 26-S proteasomes fall apart into their two sub-complexes, 20-S proteasomes and PA700, which reassemble upon addition of ATP. Conceivably, 26-S proteasomes dissociate and reassemble during initiation of protein degradation in a ternary complex with the substrate, as in the dissociation-reassembly cycles found for ribosomes and the chaperonin GroEL/GroES. Here we followed disassembly and assembly of 26-S proteasomes in cell extracts as the exchange of PA700 subunits between mouse and human 26-S proteasomes. Compared to the rate of proteolysis in the same extract, the disassembly-reassembly cycle was much too slow to present an obligatory step in a degradation cycle. It has been suggested that subunit S5a (Mcb1, Rpn10), which binds poly-ubiquitin substrates, shuttles between a free state and the 26-S proteasome, bringing substrate to the complex. However, S5a was not found in the free state in HeLa cells. Besides, all subunits in PA700, including S5a, exchanged at similar low rates. It therefore seems that 26-S proteasomes function as stable entities during degradation of proteins.     

Proteasome dynamics between proliferation and quiescence stages of Saccharomyces cerevisiae

The ubiquitin-proteasome system (UPS) plays a critical role in cellular protein homeostasis and is required for the turnover of short-lived and unwanted proteins, which are targeted by poly-ubiquitination for degradation. Proteasome is the key protease of UPS and consists of multiple subunits, which are organized into a catalytic core particle (CP) and a regulatory particle (RP). In Saccharomyces cerevisiae, proteasome holo-enzymes are engaged in degrading poly-ubiquitinated substrates and are mostly localized in the nucleus during cell proliferation. While in quiescence, the RP and CP are sequestered into motile and reversible storage granules in the cytoplasm, called proteasome storage granules (PSGs). The reversible nature of PSGs allows the proteasomes to be transported back into the nucleus upon exit from quiescence. Nuclear import of RP and CP through nuclear pores occurs via the canonical pathway that includes the importin-αβ heterodimer and takes advantage of the Ran-GTP gradient across the nuclear membrane. Dependent on the growth stage, either inactive precursor complexes or mature holo-enzymes are imported into the nucleus. The present review discusses the dynamics of proteasomes including their assembly, nucleo-cytoplasmic transport during proliferation and the sequestration of proteasomes into PSGs during quiescence.

     

The ubiquitin-specific protease UBP14 is essential for early embryo development in Arabidopsis thaliana

The ubiquitin/26S proteasome pathway is a major route for selectively degrading cytoplasmic and nuclear proteins in eukaryotes. In this pathway, chains of ubiquitins become attached to short-lived proteins, signalling recognition and breakdown of the modified protein by the 26S proteasome. During or following target degradation, the attached multi-ubiquitin chains are released and subsequently disassembled by ubiquitin-specific proteases (UBPs) to regenerate free ubiquitin monomers for re-use. Here, we describe Arabidopsis thaliana UBP14 that may participate in this recycling process. Its amino acid sequence is most similar to yeast UBP14 and its orthologues, human IsoT1-3 and Dictyostelium UbpA, and it can functionally replace yeast UBP14 in a ubp14Delta mutant. Like its orthologues, AtUBP14 can disassemble multi-ubiquitin chains linked internally via epsilon-amino isopeptide bonds using Lys48 and can process some, but not all, translational fusions of ubiquitin linked via alpha-amino peptide bonds. However, unlike its yeast and Dictyostelium orthologues, AtUBP14 is essential in Arabidopsis. T-DNA insertion mutations in the single gene that encodes AtUBP14 cause an embryonic lethal phenotype, with the homozygous embryos arresting at the globular stage. The arrested seeds have substantially increased levels of multi-ubiquitin chains, indicative of a defect in ubiquitin recycling. Taken together, the data demonstrate an essential role for the ubiquitin/26S proteasome pathway in general and for AtUBP14 in particular during early plant development.     

Ubiquitin‐like domains can target to the proteasome but proteolysis requires a disordered region

Ubiquitin and some of its homologues target proteins to the proteasome for degradation. Other ubiquitin‐like domains are involved in cellular processes unrelated to the proteasome, and proteins containing these domains remain stable in the cell. We find that the 10 yeast ubiquitin‐like domains tested bind to the proteasome, and that all 11 identified domains can target proteins for degradation. Their apparent proteasome affinities are not directly related to their stabilities or functions. That is, ubiquitin‐like domains in proteins not part of the ubiquitin proteasome system may bind the proteasome more tightly than domains in proteins that are bona fide components. We propose that proteins with ubiquitin‐like domains have properties other than proteasome binding that confer stability. We show that one of these properties is the absence of accessible disordered regions that allow the proteasome to initiate degradation. In support of this model, we find that Mdy2 is degraded in yeast when a disordered region in the protein becomes exposed and that the attachment of a disordered region to Ubp6 leads to its degradation.     

Crystal structures of Lys‐63‐linked tri‐ and di‐ubiquitin reveal a highly extended chain architecture

The covalent attachment of different types of poly‐ubiquitin chains signal different outcomes for the proteins so targeted. For example, a protein modified with Lys‐48‐linked poly‐ubiquitin chains is targeted for proteasomal degradation, whereas Lys‐63‐linked chains encode nondegradative signals. The structural features that enable these different types of chains to encode different signals have not yet been fully elucidated. We report here the X‐ray crystal structures of Lys‐63‐linked tri‐ and di‐ubiquitin at resolutions of 2.3 and 1.9 Å, respectively. The tri‐ and di‐ubiquitin species adopt essentially identical structures. In both instances, the ubiquitin chain assumes a highly extended conformation with a left‐handed helical twist; the helical chain contains four ubiquitin monomers per turn and has a repeat length of ～110 Å. Interestingly, Lys‐48 ubiquitin chains also adopt a left‐handed helical structure with a similar repeat length. However, the Lys‐63 architecture is much more open than that of Lys‐48 chains and exposes much more of the ubiquitin surface for potential recognition events. These new crystal structures are consistent with the results of solution studies of Lys‐63 chain conformation, and reveal the structural basis for differential recognition of Lys‐63 versus Lys‐48 chains. Proteins 2009. © 2009 Wiley‐Liss, Inc.