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.     

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.     

Thermo-resistant intrinsically disordered proteins are efficient 20S proteasome substrates

Based on software prediction, intrinsically disordered proteins (IDPs) are widely represented in animal cells where they play important instructive roles. Despite the predictive power of the available software programs we nevertheless need simple experimental tools to validate the predictions. IDPs were reported to be preferentially thermo-resistant and also are susceptible to degradation by the 20S proteasome. Analysis of a set of proteins revealed that thermo-resistant proteins are preferred 20S proteasome substrates. Positive correlations are evident between the percent of protein disorder and the level of thermal stability and 20S proteasomal susceptibility. The data obtained from these two assays do not fully overlap but in combination provide a more reliable experimental IDP definition. The correlation was more significant when the IUPred was used as the IDPs predicting software. We demonstrate in this work a simple experimental strategy to improve IDPs identification.     

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.     

The alpha4 and alpha7 subunits and assembly of the 20S proteasome

The presence of a high-K_m hexokinase activity was tested in both dog and boar spermatozoa. Hexokinase kinetics from dog extracts showed the presence of a specific activity (dog-sperm glucokinase-like protein, DSGLP), in the range of glucose concentrations of 4–10 mM, whereas boar sperm did not show any DSGLP activity. Furthermore, dog-sperm cells, but not those of boar, showed the presence of a protein which specifically reacted against a rat-liver anti-glucokinase antibody. This protein also had a molecular weight equal to that observed in rat-liver extracts, suggesting a close similarity between both the proteins. This glucokinase-like protein was distributed in the peri- and post-acrosomal zones of the head, and the midpiece and principal piece of tail of dog spermatozoa. These results indicate that dog spermatozoa have functional high-K_m hexokinase activity, which could contribute to a very fine regulation of their hexose metabolism. This strict regulation could ultimately be very important in optimizing dog-sperm function along its life-time.     

Purification and characterization of Candida albicans 20S proteasome: identification of four proteasomal subunits

The 20S proteasome from yeast cells of Candida albicans was purified by successive chromatographic steps to apparent homogeneity, as judged by nondenaturing and denaturing polyacrylamide gel electrophoresis. Its molecular mass was estimated to be 640 kDa by gel filtration. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate gave at least 10 bands in the range 20-32 kDa. Two-dimensional electrophoresis revealed the presence of at least 14 polypeptides. By electron microscopy after negative staining, the proteasome preparation appeared as typical symmetrical barrel-shaped particles. The enzyme cleaved the peptidyl-arylamide bonds in the model synthetic substrates Cbz-G-G-L-p-nitroanilide, Cbz-G-G-R-beta-naphthylamide, and Cbz-L-L-E-beta-naphthylamide (chymotrypsin-like, trypsin-like, and peptidylglutamyl-peptide-hydrolyzing activities). The differential sensitivity of these activities to aldehyde peptides and sodium dodecyl sulfate supported the multicatalytic nature of this enzyme. Three proteasomal subunits were identified as alpha6/Pre5, alpha3/Y13, and alpha5/Pup2 by internal sequencing of tryptic fragments. Their sequences perfectly matched the corresponding deduced amino acid sequences of the C. albicans genes. A fourth subunit was identified as alpha7/Prs1 by immunorecognition with a monoclonal antibody specific for C8, the human proteasome subunit homologue. Treatment of the intact isolated 20S proteasome with acid phosphatase and Western blot analysis of the separated components indicated that the alpha7/Prs1 subunit is obtained as a multiply phosphorylated protein.     

Primary structural features of the 20S proteasome subunits of rice (Oryza sativa)

The 20S proteasome is the proteolytic complex that is involved in removing abnormal proteins, and it also has other diverse biological functions. Its structure comprises 28 subunits arranged in four rings of seven subunits, and exists as a hollow cylinder. The two outer rings and two inner rings form an 7β7β77 structure, and each subunit, and β, exists as seven different types, thus giving 14 kinds of subunits. In this study, we report the primary structures of the 14 proteasomal subunit subfamilies in rice (Oryza sativa), representing the first set for all of the subunits from monocots. Amino acid sequence homology within the rice family (-type: 28.9–42.1%; β-type: 17.2–31.9%) were lower than those between rice subunits and corresponding orthologs from Arabidopsis and yeast (-type: 49.2–94.5%; β-type: 34.8–87.7%). Structural features observed in eukaryotic proteasome subunits, i.e., - or β-type signature at the N-termini, Thr active sites in β1, β2 and β5 subunits, and nuclear localization signal-like sequences in some -type subunits, were shown to be conserved in rice.     

Rearrangement of the 16S precursor subunits is essential for the formation of the active 20S proteasome

Proteasome-dependent proteolysis is essential for a number of key cellular processes and requires a sophisticated biogenesis pathway to function. Here, we have arrested the assembly process in its dynamic progression at the short-lived 16S state. Structural analysis of the 16S proteasome precursor intermediates by electron microscopy, and single particle analysis reveals major conformational changes in the structure of the beta-ring in comparison with one-half of the 20S proteasome. The individual beta-subunits in the 16S precursor complex rotate with respect to their positions in the x-ray crystallographic structure of the fully assembled 20S. This rearrangement results in a movement of the catalytic residue threonine-1 from the protected location in 16S precursor complexes to a more exposed position in the 20S structure. Thereby, our findings provide a molecular explanation for the structural rearrangements necessary for the dimerization of two 16S precursor complexes and the subsequent final maturation to active 20S proteasomes.     

Atomic force microscopy reveals two conformations of the 20 S proteasome from fission yeast

The proteasome is a major cytosolic proteolytic complex, indispensable in eukaryotic cells. The barrel-shaped core of this enzyme, the 20 S proteasome, is built from 28 subunits forming four stacked rings. The two inner beta-rings harbor active centers, whereas the two outer alpha-rings play a structural role. Crystal structure of the yeast 20 S particle showed that the entrance to the central channel was sealed. Because of this result, the path of substrates into the catalytic chamber has remained enigmatic. We have used tapping mode atomic force microscopy (AFM) in liquid to address the dynamic aspects of the 20 S proteasomes from fission yeast. We present here evidence that, when observed with AFM, the proteasome particles in top view position have either open or closed entrance to the central channel. The preferred conformation depends on the ligands present. Apparently, the addition of a substrate to the uninhibited proteasome shifts the equilibrium toward the open conformation. These results shed new light on the possible path of the substrate into the proteolytic chamber.     

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.     

Transferring substrates to the 26S proteasome

Ubiquitin-dependent protein degradation is not only involved in the recycling of amino acids from damaged or misfolded proteins but also represents an essential and deftly controlled mechanism for modulating the levels of key regulatory proteins. Chains of ubiquitin conjugated to a substrate protein specifically target it for degradation by the 26S proteasome, a huge multi-subunit protein complex found in all eukaryotic cells. Recent reports have clarified some of the molecular mechanisms involved in the transfer of ubiquitinated substrates from the ubiquitination machinery to the proteasome. This novel substrate transportation step in the ubiquitin-proteasome pathway seems to occur either directly or indirectly via certain substrate-recruiting proteins and appears to involve chaperones.     

The 26S proteasome: subunits and functions

The 26S proteasome is an eukaryotic ATP-dependent, dumbbell-shaped protease complex with a molecular mass of approximately 2000 kDa. It consists of a central 20S proteasome, functioning as a catalytic machine, and two large V-shaped terminal modules, having possible regulatory roles, composed of multiple subunits of 25–110 kDa attached to the central portion in opposite orientations. The primary structures of all the subunits of mammalian and yeast 20S proteasomes have been determined by recombinant DNA techniques, but structural analyses of the regulatory subunits of the 26S proteasome are still in progress. The regulatory subunits are classified into two subgroups, a subgroup of at least 6 ATPases that constitute a unique multi-gene family encoding homologous polypeptides conserved during evolution and a subgroup of approximately 15 non-ATPase subunits, most of which are structurally unrelated to each other.     

Phosphorylation of ATPase subunits of the 26S proteasome

The 26S proteasome complex plays a major role in the non-lysosomal degradation of intracellular proteins. Purified 26S proteasomes give a pattern of more than 40 spots on 2D-PAGE gels. The positions of subunits have been identified by mass spectrometry of tryptic peptides and by immunoblotting with subunit-specific antipeptide antibodies. Two-dimensional polyacrylamide gel electrophoresis of proteasomes immunoprecipitated from [³²P]phosphate-labelled human embryo lung L-132 cells revealed the presence of at least three major phosphorylated polypeptides among the regulatory subunits as well as the C8 and C9 components of the core 20S proteasome. Comparison with the positions of the regulatory polypeptides revealed a minor phosphorylated form to be S7 (MSS1). Antibodies against S4, S6 (TBP7) and S12 (MOV34) all cross-reacted at the position of major phosphorylated polypeptides suggesting that several of the ATPase subunits may be phosphorylated. The phosphorylation of S4 was confirmed by double immunoprecipitation experiments in which 26S proteasomes were immunoprecipitated as above and dissociated and then S4 was immunoprecipitated with subunit-specific antibodies. Antibodies against the non-ATPase subunit S10, which has been suggested by others to be phosphorylated, did not coincide with the position of a phosphorylated polypeptide. Some differences were observed in the 2D-PAGE pattern of proteasomes immunoprecipitated from cultured cells compared to purified rat liver 26S proteasomes suggesting possible differences in subunit compositions of 26S proteasomes.     

HC-Pro protein of Potato virus Y can interact with three Arabidopsis 20S proteasome subunits in planta

The multifunctional protein helper component proteinase (HC-Pro) is thought to interfere with the activity of the 20S proteasome; however, no sites of interaction have been identified for either protein. Here, we first show that the Potato virus Y (PVY) HC-Pro protein can interact with three Arabidopsis 20S proteasome subunits (PAA, PBB, and PBE), using a yeast two-hybrid system and the bimolecular fluorescence complement assay. In addition, yeast two-hybrid analysis of the interaction between several mutant subunits of the 20S proteasome and PVY HC-Pro confirmed that residues 81 to 140 of PAA, 1 to 80 of PBB, and 160 to 274 of PBE are necessary for binding PAA, PBB, and PBE to PVY HC-Pro, respectively. Deletion mutant analysis of PVY HC-Pro showed that the N terminus (residues 1 to 97) is necessary for its interaction with three Arabidopsis 20S proteasome subunits. The ability of HC-Pro to interact and interfere with the activity of the 20S proteasome may help explain the molecular basis of its multifunctional character.     

Mass spectrometry reveals the missing links in the assembly pathway of the bacterial 20 S proteasome

The 20 S proteasome is an essential proteolytic particle, responsible for degrading short-lived and abnormal intracellular proteins. The 700-kDa assembly is comprised of 14 alpha-type and 14 beta-type subunits, which form a cylindrical architecture composed of four stacked heptameric rings (alpha7beta7beta7alpha7). The formation of the 20 S proteasome is a complex process that involves a cascade of folding, assembly, and processing events. To date, the understanding of the assembly pathway is incomplete due to the experimental challenges of capturing short-lived intermediates. In this study, we have applied a real-time mass spectrometry approach to capture transient species along the assembly pathway of the 20 S proteasome from Rhodococcus erythropolis. In the course of assembly, we observed formation of an early alpha/beta-heterodimer as well as an unprocessed half-proteasome particle. Formation of mature holoproteasomes occurred in concert with the disappearance of half-proteasomes. We also analyzed the beta-subunits before and during assembly and reveal that those with longer propeptides are incorporated into half- and full proteasomes more rapidly than those that are heavily truncated. To characterize the preholoproteasome, formed by docking of two unprocessed half-proteasomes and not observed during assembly of wild type subunits, we trapped this intermediate using a beta-subunit mutational variant. In summary, this study provides evidence for transient intermediates in the assembly pathway and reveals detailed insight into the cleavage sites of the propeptide.     

A self-compartmentalizing protease in Rhodococcus: the 20S proteasome

The 26S proteasome represents a major, energy-dependent and self- compartmentalizing protease system in eukaryotes. The proteolytic core of this complex, the 20S proteasome, is also ubiquitous in archaea. Although absent from most eubacteria, this multi- subunit protease was recently discovered in Rhodococcus and appears to be confined to actinomycetes. The eubacterial 20S proteasome represents an attractive complementary system to study proteasome assembly, quaternary structure, and catalytic mechanism. In addition, it is likely to contribute substantially to our understanding of the role of various self-compartmentalizing proteases in bacterial cells.     

A kinetic model of vertebrate 20S proteasome accounting for the generation of major proteolytic fragments from oligomeric peptide substrates

There is now convincing evidence that the proteasome contributes to the generation of most of the peptides presented by major histocompatibility complex class I molecules. Here we present a model-based kinetic analysis of fragment patterns generated by the 20S proteasome from 20 to 40 residues long oligomeric substrates. The model consists of ordinary first-order differential equations describing the time evolution of the average probabilities with which fragments can be generated from a given initial substrate. First-order rate laws are used to describe the cleavage of peptide bonds and the release of peptides from the interior of the proteasome to the external space. Numerical estimates for the 27 unknown model parameters are determined across a set of five different proteins with known cleavage patterns. Testing the validity of the model by a jack knife procedure, about 80% of the observed fragments can be correctly identified, whereas the abundance of false-positive classifications is below 10%. From our theoretical approach, it is inferred that double-cleavage fragments of length 7-13 are predominantly cut out in "C-N-order" in that the C-terminus is generated first. This is due to striking differences in the further processing of the two fragments generated by the first cleavage. The upstream fragment exhibits a pronounced tendency to escape from second cleavage as indicated by a large release rate and a monotone exponential decline of peptide bond accessibility with increasing distance from the first scissile bond. In contrast, the release rate of the downstream fragment is about four orders of magnitude lower and the accessibility of peptide bonds shows a sharp peak in a distance of about nine residues from the first scissile bond. This finding strongly supports the idea that generation of fragments with well-defined lengths is favored in that temporary immobilization of the downstream fragment after the first cleavage renders it susceptible for a second cleavage.     

Identification of ubiquitin-like protein-binding subunits of the 26S proteasome

The high resolution structure of hemalbumin was determined by single crystal X-ray diffraction to a resolution of 1.9 A. The structure revealed the protoporphyrin IX bound to a single site within a hydrophobic cavity in subdomain IB, one of the principal binding sites for long chain fatty acid. The iron is penta coordinated with the fifth ligand comprised of the hydroxyl oxygen of Tyr-161 (phenolic oxygen to heme plane distance: 2.73 A) in an otherwise completely hydrophobic pocket. The heme propionic acid residues form salt bridges with His-142 and Lys-190, which together with a series of hydrophobic interactions, enclose and secure the heme within the IB helical motif. A detailed discussion of the structure together with its implications for the development of potential blood substitutes is presented.     

Genetic evidence for selective degradation of RNA polymerase subunits by the 20S proteasome in Saccharomyces cerevisiae.

scs32 was isolated as an extragenic suppressor of a temperature-sensitive (ts) mutation (rpo26-31) in the gene encoding Rpo26p, a subunit common to yeast nuclear RNA polymerases (RNAPs). rpo26-31 also confers inositol auxotrophy, inhibits the assembly of RNAPI and RNAPII and reduces the steady-state level of Rpo26p and the largest subunit of RNAPI (Rpo11p or A190p) and RNAPII (Rpo21p). rpo26-31p accumulated to wild-type levels in the scs32 strain; nevertheless, the amount of assembled RNAPII remained at a reduced level at high temperature. Hence, scs32 only partially suppressed the ts phenotype and was unable to suppress the Ino-phenotype of rpo26-31. SCS32 is identical to PUP3, which encodes a subunit of the yeast proteasome. scs32 was able to suppress the phenotype of other ts alleles of RPO26, all of which reduce the steady-state level of this subunit. However, scs32 was unable to suppress the ts phenotype of mutant alleles of RPO21, or result in accumulation of the unstable rpo21-4p. These observations suggest that the stability of non-functional or unassembled forms of Rpo26p and Rpo21p are regulated independently.