The structure of the mammalian 20S proteasome at 2.75 A resolution

The 20S proteasome is the catalytic portion of the 26S proteasome. Constitutively expressed mammalian 20S proteasomes have three active subunits, beta 1, beta 2, and beta 5, which are replaced in the immunoproteasome by interferon-gamma-inducible subunits beta 1i, beta 2i, and beta 5i, respectively. Here we determined the crystal structure of the bovine 20S proteasome at 2.75 A resolution. The structures of alpha 2, beta 1, beta 5, beta 6, and beta 7 subunits of the bovine enzyme were different from the yeast enzyme but enabled the bovine proteasome to accommodate either the constitutive or the inducible subunits. A novel N-terminal nucleophile hydrolase activity was proposed for the beta 7 subunit. We also determined the site of the nuclear localization signals in the molecule. A model of the immunoproteasome was predicted from this constitutive structure.     

26S蛋白酶体的结构生物学研究进展

26S蛋白酶体是真核细胞内负责蛋白质降解的主要分子机器,通过特异性降解目的蛋白质,几乎参与了生物体的绝大多数生命活动.26S蛋白酶体在结构上可分为19S调节颗粒和20S核心颗粒两部分.19S调节颗粒负责识别带有泛素链标记的蛋白质底物及对其进行去折叠,并最终将去折叠的蛋白质底物传送至20S核心颗粒中进行降解.由于26S蛋白酶体的结构组成复杂,分子量十分巨大,现有的X-ray技术和NMR技术对其完整结构的解析都无能为力,仅能解析出部分单个蛋白成员或分子量较低的亚复合物晶体结构.而冷冻电镜技术在相当一段时间内处于发展的初级阶段,导致其三维结构的研究进展曾经十分缓慢,严重阻碍了人们对其结构和功能的了解.近年来,随着在X-ray技术领域对大分子复合物结构解析的经验积累和冷冻电镜技术领域的技术革命,完整的26S蛋白酶体三维结构解析取得了飞速的发展.本文回顾了近几年在26S蛋白酶体结构生物学领域的重要进展,并展望了该领域未来的发展及面临的挑战.     

Modeling of the binding mode of a non-covalent inhibitor of the 20S proteasome. Application to structure-based analogue design

The 2-aminobenzvlstatine derivative I is a 20S proteasome inhibitor of a novel chemical type identified by high throughput screening. The compound specifically inhibits the chymotrypsin-like catalytic activity of the human proteasome with an IC50 value in the micromolar range. Using the crystal structure of the yeast proteasome, we modeled the structure of the human proteasome in complex with 1. As one of the first applications of the model in our oncology programme targeting the proteasome, we designed an analogue of the inhibitor having enhanced stacking/hydrophobic interactions with the enzyme. One order of magnitude in inhibitory potency was gained.     

The pore of activated 20S proteasomes has an ordered 7-fold symmetric conformation

The 20S proteasome is a large multisubunit assembly that performs most of the intracellular non-lysosomal proteolysis of eukaryotes. Substrates access the proteasome active sites, which are sequestered in the interior of the barrel-shaped structure, through pores that are opened by binding of activator complexes. The crystal structure of yeast proteasome in complex with an 11S activator suggested that activation results from disordering of the proteasome gate residues. Here we report further analysis of this structure, which demonstrates that, in contrast to earlier models, the activated proteasome adopts an ordered 7-fold symmetric pore conformation that is stabilized by interactions formed by a cluster of highly conserved proteasome residues (Tyr8, Asp9, Pro17 and Tyr26). One non-canonical cluster, which appears to be mandated by the requirement that eukaryotic proteasomes also form an ordered closed conformation, explains all deviations from perfect conservation of these residues. We also demonstrate the importance of these conserved residues for proteolysis by an archaeal proteasome. Evolutionary considerations suggest that other activators might induce the same open proteasome conformation as seen with the 11S activator.     

Interactions of PAN's C‐termini with archaeal 20S proteasome and implications for the eukaryotic proteasome–ATPase interactions

Protein degradation in the 20S proteasome is regulated in eukaryotes by the 19S ATPase complex and in archaea by the homologous PAN ATPase ring complex. Subunits of these hexameric ATPases contain on their C‐termini a conserved hydrophobic‐tyrosine‐X (HbYX) motif that docks into pockets in the 20S to stimulate the opening of a gated substrate entry channel. Here, we report the crystal structure of the archaeal 20S proteasome in complex with the C‐terminus of the archaeal proteasome regulatory ATPase, PAN. This structure defines the detailed interactions between the critical C‐terminal HbYX motif and the 20S α‐subunits and indicates that the intersubunit pocket in the 20S undergoes an induced‐fit conformational change on binding of the HbYX motif. This structure together with related mutagenesis data suggest how in eukaryotes certain proteasomal ATPases bind to specific pockets in an asymmetrical manner to regulate gate opening.     

Crystal structure of human ornithine decarboxylase at 2.1 A resolution: structural insights to antizyme binding

The polyamines spermidine and spermine are ubiquitous and required for cell growth and differentiation in eukaryotes. Ornithine decarboxylase (ODC, EC 4.1.1.17) performs the first step in polyamine biosynthesis, the decarboxylation of ornithine to putrescine. Elevated polyamine levels can lead to down-regulation of ODC activity by enhancing the translation of antizyme mRNA, resulting in subsequent binding of antizyme to ODC monomers which targets ODC for proteolysis by the 26S proteasome. The crystal structure of ornithine decarboxylase from human liver has been determined to 2.1 A resolution by molecular replacement using truncated mouse ODC (Delta425-461) as the search model and refined to a crystallographic R-factor of 21.2% and an R-free value of 28.8%. The human ODC model includes several regions that are disordered in the mouse ODC crystal structure, including one of two C-terminal basal degradation elements that have been demonstrated to independently collaborate with antizyme binding to target ODC for degradation by the 26S proteasome. The crystal structure of human ODC suggests that the C terminus, which contains basal degradation elements necessary for antizyme-induced proteolysis, is not buried by the structural core of homodimeric ODC as previously proposed. Analysis of the solvent-accessible surface area, surface electrostatic potential, and the conservation of primary sequence between human ODC and Trypanosoma brucei ODC provides clues to the identity of potential protein-binding-determinants in the putative antizyme binding element in human ODC.     

Inactivation of the proteasome by 4-hydroxy-2-nonenal is site specific and dependant on 20S proteasome subtypes

The proteasome represents a major intracellular proteolytic system responsible for the degradation of oxidized and ubiquitinated proteins in both the nucleus and cytoplasm. We have previously reported that proteasome undergoes modification by the lipid peroxidation product 4-hydroxy-2-nonenal (HNE) and exhibits declines in peptidase activities during cardiac ischemia/reperfusion. This study was undertaken to characterize the effects of HNE on the structure and function of the 20S proteasome. To assess potential tissue-specific differences in the response to HNE, we utilized purified 20S proteasome from heart and liver, tissues that express different proteasome subtypes. Following incubation of heart and liver 20S proteasome with HNE, changes in the 2D gel electrophoresis patterns and peptidase activities of the proteasome were evaluated. Proteasome subunits were identified by mass spectrometry prior to and following treatment with HNE. Our results demonstrate that specific subunits of the 20S proteasome are targeted for modification by HNE and that modified proteasome exhibits selective alterations in peptidase activities. The results provide evidence for a likely mechanism of proteasome inactivation in response to oxidative stress particularly during cardiac ischemia/reperfusion.     

Investigations on the maturation and regulation of archaebacterial proteasomes

The 20S proteasome (core particle, CP) is a multifunctional protease complex and composed of four heptameric subunit rings arranged in a hollow, barrel-shaped structure. Here, we report the crystal structure of the CP from Archaeoglobus fulgidus at 2.25A resolution. The analysis of the structure of early and late assembly intermediates of this CP gives new insights in the maturation of archaebacterial CPs and indicates similarities to assembly intermediates observed in eukaryotes. We also show a striking difference in mechanism and regulation of substrate access between eukaryotic and archaebacterial 20S proteasomes. While eukaryotic CPs are auto-inhibited by the N-terminal tails of the outer alpha-ring by imposing topological closure with a characteristic sequence motif (YDR-motif) and show regulatory gating this segment is disordered in the CP and differently structured in the alpha(7)-sub-complex of A.fulgidus leaving a pore leading into the particle with a diameter of 13A. Mutagenesis and functional studies indicate the absence of regulatory gating in the archaeal 20S proteasome.     

cDNA cloning, expression, and functional characterization of PI31, a proline-rich inhibitor of the proteasome

The primary structure of PI31, a protein inhibitor of the 20 S proteasome, was deduced by cDNA cloning and sequencing. The human protein has a calculated molecular weight of 29,792, a value in excellent accord with 31,000, as estimated by SDS-polyacrylamide gel electrophoresis for purified bovine PI31, and is not similar to any other protein in current data bases. PI31 is a proline-rich protein, particularly within its carboxyl-terminal half where 26% of the amino acids are proline. Wild-type PI31 and various truncation mutants were expressed in Escherichia coli and purified to homogeneity. Recombinant wild-type PI31 displayed structural and functional properties similar to those of PI31 purified from bovine red blood cells and inhibited the hydrolysis of protein and peptide substrates by the 20 S proteasome. Analysis of truncation mutants demonstrated that proteasome inhibition was conferred by the carboxyl-terminal proline-rich domain of PI31, which appears to have an extended secondary structure. Inhibition of the 20 S proteasome by PI31 involved formation a proteasome-PI31 complex. In addition to its direct inhibition of the 20 S proteasome, PI31 inhibited the activation of the proteasome by each of two proteasome regulatory proteins, PA700 and PA28. These results suggest that PI31 plays an important role in control of proteasome function, including that in ubiquitin-dependent pathways of protein degradation.     

Crystal structure of the boronic acid-based proteasome inhibitor bortezomib in complex with the yeast 20S proteasome

The dipeptide boronic acid bortezomib, also termed VELCADE, is a proteasome inhibitor now in use for the treatment of multiple myeloma, and its use for the treatment of other malignancies is being explored. We determined the crystal structure of the yeast 20S proteasome in complex with bortezomib to establish the specificity and binding mode of bortezomib to the proteasome's different catalytically active sites. This structure should enable the rational design of new boronic acid derivatives with improved affinities and specificities for individual active subunits.     

Refinement of the crystal structure of ribonuclease S. Comparison with and between the various ribonuclease A structures.

Ribonuclease S (RNase-S) is a complex that consists of two proteolytic fragments of bovine pancreatic ribonuclease A (RNase-A): the S-peptide (residues 1-20) and S-protein (residues 21-124). We have refined the crystal structures of three RNase-S complexes. The first two contain the full-length 20-residue S-peptide and were studied at pHs of 4.75 and 5.5. The third one consists of a truncated form of S-peptide (residues 1-15) and was studied at pH 4.75 as the reference structure for a series of mutant peptide complexes to be reported separately. Excluding residues 16-23 which are either missing (in the S15 complex) or disordered (in both S20 complexes), all three structures refined at 1.6-A resolution are identical within the estimated errors in the coordinates (0.048 A for the backbone atoms). The R-values, residual error, range from 17.4% to 18.6%. The final model of S20, pH 4.75, includes 1 sulfate and 84 water molecules. The side chains of 11 residues were modeled in two discrete conformations. The final structures were independent of the particular RNase-A or RNase-S used as a starting model. An extensive comparison with refined crystal structures of RNase-A reveals that the core of the molecule which is held together with extensive hydrogen bonds is in identical pattern in all cases. However, the loop regions vary from one structure to another and are often characterized by high B-factors. The pattern of thermal parameters appears to be dependent on crystal packing and correlates well with the accessibility calculated in the crystal. Gln60 is a conserved residue in all sequences known to date for this class of ribonucleases. However, it is the only residue that is clearly defined in an unfavorable position (phi = -100 degrees, psi = -130 degrees) on the Ramachandran plot. The origin of the substantial differences between RNase-A and RNase-S in stability to both acid and temperature denaturation and in susceptibility to proteolysis at neutral pH is not obvious in our visual comparison of these two structures.     

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.     

Scaled-down purification protocol to access proteomic analysis of 20S proteasome from human tissue samples: comparison of normal and tumor colorectal cells

The proteasome is a proteolytic complex that constitutes the main pathway for degradation of intracellular proteins in eukaryotic cells. It regulates many physiological processes and its dysfunction can lead to several pathologies like cancer. To study the 20S proteasome structure/activity relationship in cells that derive from human biopsy samples, we optimized an immuno-purification protocol for the analysis of samples containing a small number of cells using magnetic beads. This scaled-down protocol was used to purify the cytoplasmic 20S proteasome of adjacent normal and tumor colorectal cells arising from tissue samples of several patients. Proteomic analyses based on two-dimensional gel electrophoresis (2DE) and mass spectrometry showed that the subunit composition of 20S proteasomes from these normal and tumor cells were not significantly different. The proteasome activity was also assessed in the cytoplasmic extracts and was similar or higher in tumor colorectal than in the corresponding normal cells. The scaled-down 20S proteasome purification protocol developed here can be applied to any human clinical tissue samples and is compatible with further proteomic analyses.     

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.     

High-resolution AFM-imaging and mechanistic analysis of the 20 S proteasome.

As macromolecular protease complex, the 20 S proteasome is responsible for the degradation of cellular proteins and the generation of peptide epitopes for antigen presentation. Here, structural and functional aspects of the 20 S proteasome from Thermoplasma acidophilum have been investigated by atomic force microscopy (AFM) and surface plasmon resonance (SPR). Due to engineered histidine tags introduced at defined positions, the proteasome complex was pre-oriented at ultra-flat chelator lipid membranes allowing for high-resolution imaging by AFM. Within these two-dimensional protein arrays, the overall structure of the proteasome and the organization of individual subunits was resolved under native conditions without fixation or crosslinking. In addition, the substrate-proteasome interaction was monitored in real-time by SPR using a novel approach. Instead of following enzyme activity by product formation, the association and dissociation kinetics of the substrate-proteasome complex were analyzed during proteolysis of the polypeptide chain. By blocking the active sites with a specific inhibitor, the substrate binding step could be dissected from the degradation step thus resolving mechanistic details of substrate recognition and cleavage by the 20 S proteasome.     

Impact of ageing on proteasome structure and function in human lymphocytes

Key actors of the immune response, lymphocytes exhibit functional deficits with advancing age. For instance, the age-related decline in lymphocyte proliferation may be related to alteration in the degradation of crucial proteins such as cell-cycle regulators. Degradation of these proteins is mediated by the ubiquitin-26S proteasome system. The proteasome is also the major "housekeeping" proteolytic complex responsible for eliminating intracellular damaged proteins. To investigate the occurrence of proteasome structural and functional age-related alterations, 26S proteasome was purified from peripheral blood lymphocytes of 20-63-year-old donors. Changes in peptidase activity were measured and modifications in the proteasome particle structure were analysed using bi-dimensional electrophoresis. We found the age-related decline of 26S proteasome-specific activity to be associated with an increased yield of post-translational modifications of proteasome subunits, while proteasome content and subunit composition were unchanged. In particular, some catalytic and assembly subunits of the 20S proteasome were preferentially modified with age. Western blotting of proteasome subunits resolved by bi-dimensional electrophoresis showed some of these modified subunits to be glycated, conjugated with a lipid peroxidation product and/or ubiquitinated. In conclusion, it is suggested that structural alterations of proteasome subunits may contribute to the observed decline of proteasome activity with age and could play a major role in immune senescence.     

Structure of the human 26S proteasome: subunit radial displacements open the gate into the proteolytic core

The 26S proteasome plays an essential role in regulating many cellular processes by the degradation of proteins targeted for breakdown by ubiquitin conjugation. The 26S complex is formed from the 20S core, which contains the proteolytic active sites, and 19S regulatory complexes, which bind to the 20S core to activate it and confer specificity for ubiquitinated protein substrates. We have determined the structure of the human 26S proteasome by electron microscopy and single particle analysis. In our reconstructions the crystallographic structure of each of the subunits of the 20S core can be unambiguously docked by direct recognition of each of their densities. Our results show for the first time that binding of the 19S regulatory particle results in the radial displacement of the adjacent subunits of the 20S core leading to opening of a wide channel into the proteolytic chamber. The analysis of a proteasome complex formed from one 20S core with a single 19S regulatory particle attached serve as control to our observations. We suggest locations for some of the 19S regulatory particle subunits.     

Role of glutaredoxin 2 and cytosolic thioredoxins in cysteinyl-based redox modification of the 20S proteasome

The yeast 20S proteasome is subject to sulfhydryl redox alterations, such as the oxidation of cysteine residues (Cys-SH) into cysteine sulfenic acid (Cys-SOH), followed by S-glutathionylation (Cys-S-SG). Proteasome S-glutathionylation promotes partial loss of chymotrypsin-like activity and post-acidic cleavage without alteration of the trypsin-like proteasomal activity. Here we show that the 20S proteasome purified from stationary-phase cells was natively S-glutathionylated. Moreover, recombinant glutaredoxin 2 removes glutathione from natively or in vitro S-glutathionylated 20S proteasome, allowing the recovery of chymotrypsin-like activity and post-acidic cleavage. Glutaredoxin 2 deglutathionylase activity was dependent on its entry into the core particle, as demonstrated by stimulating S-glutathionylated proteasome opening. Under these conditions, deglutathionylation of the 20S proteasome and glutaredoxin 2 degradation were increased when compared to non-stimulated samples. Glutaredoxin 2 fragmentation by the 20S proteasome was evaluated by SDS-PAGE and mass spectrometry, and S-glutathionylation was evaluated by either western blot analyses with anti-glutathione IgG or by spectrophotometry with the thiol reactant 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole. It was also observed in vivo that glutaredoxin 2 was ubiquitinated in cellular extracts of yeast cells grown in glucose-containing medium. Other cytoplasmic oxido-reductases, namely thioredoxins 1 and 2, were also active in 20S proteasome deglutathionylation by a similar mechanism. These results indicate for the first time that 20S proteasome cysteinyl redox modification is a regulated mechanism coupled to enzymatic deglutathionylase activity.     

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.