Interaction analysis of the AAA ATPase TAA43 by the bacterial two-hybrid system

The TAA43 ATPase of Thermoplasma acidophilum, an archaeal member of the AAA protein family, is known to have an atypical oligomeric state and a nonspecific association with high-molecular-weight protein complexes. We assessed the in vivo binding pattern of TAA43 using the bacterial two-hybrid system. We found 36 positive isolates interacting with TAA43. Our analysis showed that TAA43 interacts preferentially with nonribosomal proteins containing ribosomal domains and regions involved in RNA metabolism.     

Localization of a sequence motif complementary to the nuclear localization signal in proteasomes from Thermoplasma acidophilum by immunoelectron microscopy.

A sequence motif complementary to the nuclear localization signal (NLS) has been localized in proteasomes from Thermoplasma acidophilum by immunoelectron microscopy using sequence-specific antibodies. The antibodies were generated in two different ways: by immunization with a carrier-coupled peptide and by isolation of the sequence-specific antibody from an immune serum against native proteasomes using a peptide-affinity column. The sequence specificity of the isolated antibody was confirmed by a PEPSCAN-ELISA performed on overlapping nonapeptides deduced from the sequence of the alpha-subunit of the Thermoplasma proteasome. Compared to the antibody induced by the carrier-coupled peptide this antibody fraction showed a much higher affinity for native proteasomes. The attachment site of the Fab portion of the antibody to the proteasome was mapped by electron microscopy in conjunction with image processing. The antibody was found to bind to the periphery of the two outer "disks" of the proteasome complex formed by the alpha-subunits.     

The Archaeal Proteasome Is Regulated by a Network of AAA ATPases

The proteasome is the central machinery for targeted protein degradation in archaea, Actinobacteria, and eukaryotes. In its basic form, it consists of a regulatory ATPase complex and a proteolytic core particle. The interaction between the two is governed by an HbYX motif (where Hb is a hydrophobic residue, Y is tyrosine, and X is any amino acid) at the C terminus of the ATPase subunits, which stimulates gate opening of the proteasomal α-subunits. In archaea, the proteasome-interacting motif is not only found in canonical proteasome-activating nucleotidases of the PAN/ARC/Rpt group, which are absent in major archaeal lineages, but also in proteins of the CDC48/p97/VAT and AMA groups, suggesting a regulatory network of proteasomal ATPases. Indeed, Thermoplasma acidophilum, which lacks PAN, encodes one CDC48 protein that interacts with the 20S proteasome and activates the degradation of model substrates. In contrast, Methanosarcina mazei contains seven AAA proteins, five of which, both PAN proteins, two out of three CDC48 proteins, and the AMA protein, function as proteasomal gatekeepers. The prevalent presence of multiple, distinct proteasomal ATPases in archaea thus results in a network of regulatory ATPases that may widen the substrate spectrum of proteasomal protein degradation.     

A conserved role of Caenorhabditis elegans CDC-48 in ER-associated protein degradation

Protein degradation mediated by the ubiquitin/proteasome system is essential for the elimination of misfolded proteins from the endoplasmic reticulum (ER) to adapt to ER stress. It has been reported that the AAA ATPase p97/VCP/CDC48 is required in this pathway for protein dislocation across the ER membrane and subsequent ubiquitin dependent degradation by the 26S proteasome in the cytosol. Throughout ER-associated protein degradation, p97 cooperates with a binary Ufd1/Npl4-complex. In Caenorhabditis elegans two homologs of p97, designated CDC-48.1 and CDC-48.2, exist. Our results indicate that both p97 homologs interact with UFD-1/NPL-4 in a similar CDC-48(UFD-1/NPL-4) complex. RNAi mediated depletion of the corresponding genes induces ER stress resulting in hypersensitivity to conditions which induce increased levels of unfolded proteins in the ER lumen. Together, these data suggest an evolutionarily conserved retro-translocation machinery at the endoplasmic reticulum.     

VAT, the thermoplasma homolog of mammalian p97/VCP, is an N domain-regulated protein unfoldase

The Thermoplasma VCP-like ATPase from Thermoplasma acidophilum (VAT) ATPase is a member of the two-domain AAA ATPases and homologous to the mammalian p97/VCP and NSF proteins. We show here that the VAT ATPase complex unfolds green fluorescent protein (GFP) labeled with the ssrA-degradation tag. Increasing the Mg2+ concentration derepresses the ATPase activity and concomitantly stimulates the unfolding activity of VAT. Similarly, the VATDeltaN complex, a mutant of VAT deleted for the N domain, displays up to 24-fold enhanced ATP hydrolysis and 250-fold enhanced GFP unfolding activity when compared with wild-type VAT. To determine the individual contribution of the two AAA domains to ATP hydrolysis and GFP unfolding we performed extensive site-directed mutagenesis of the Walker A, Walker B, sensor-1, and pore residues in both AAA domains. Analysis of the VAT mutant proteins, where ATP hydrolysis was confined to a single AAA domain, revealed that the first domain (D1) is sufficient to exert GFP unfolding indistinguishable from wild-type VAT, while the second AAA domain (D2), although active, is significantly less efficient than wild-type VAT. A single conserved aromatic residue in the D1 section of the pore was found to be essential for GFP unfolding. In contrast, two neighboring residues in the D2 section of the pore had to be exchanged simultaneously, to achieve a drastic inhibition of GFP unfolding.     

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.     

Homologs of eukaryotic Ras superfamily proteins in prokaryotes and their novel phylogenetic correlation with their eukaryotic analogs

Ras superfamily proteins are key regulators in a wide variety of cellular processes. Previously, they were considered to be specific to eukaryotes, and MglA, a group of obviously different prokaryotic proteins, were recognized as their only prokaryotic analogs or even ancestors. Here, taking advantage of quite a current accumulation of prokaryotic genomic databases, we have investigated the existence and taxonomic distribution of Ras superfamily protein homologs in a much wider prokaryotic range, and analyzed their phylogenetic correlation with their eukaryotic analogs. Thirteen unambiguous prokaryotic homologs, which possess the GDP/GTP-binding domain with all the five characteristic motifs of their eukaryotic analogs, were identified in 12 eubacteria and one archaebacterium, respectively. In some other archaebacteria, including four methanogenic archaebacteria and three Thermoplasmales, homologs were also found, but with the GDP/GTP-binding domains not containing all the five characteristic motifs. Many more MglA orthologs were identified than in previous studies mainly in delta-proteobacteria, and all were shown to have common unique features distinct from the Ras superfamily proteins. Our phylogenetic analysis indicated eukaryotic Rab, Ran, Ras, and Rho families have the closest phylogenetic correlation with the 13 unambiguous prokaryotic homologs, whereas the other three eukaryotic protein families (SRbeta, Sar1, and Arf) branch separately from them, but have a relatively close relationship with the methanogenic archaebacterial homologs and MglA. Although homologs were identified in a relative minority of prokaryotes with genomic databases, their presence in a relatively wide variety of lineages, their unique sequence characters distinct from those of eukaryotic analogs, and the topology of our phylogenetic tree altogether do not support their origin from eukaryotes as a result of lateral gene transfer. Therefore, we argue that Ras superfamily proteins might have already emerged at least in some prokaryotic lineages, and that the seven eukaryotic protein families of the Ras superfamily may have two independent prokaryotic origins, probably reflecting the 'fusion' evolutionary history of the eukaryotic cell.     

Cloning and sequencing of the gene encoding the large (alpha-) subunit of the proteasome from Thermoplasma acidophilum

The gene encoding the alpha-subunit of the proteasome from the archaebacterium Thermoplasma acidophilum was cloned and sequenced. The gene encodes for a polypeptide with 233 amino acid residues and a calculated molecular weight of 25870. Sequence similarity of the alpha-subunit with the Saccharomyces cerevisiae wild-type suppressor gene scll+ encoded polypeptide, which is probably identical with the subunit YC7-alpha of the yeast proteasome, lends support to a putative role of proteasomes in the regulation of gene expression. The significant sequence similarity to the various subunits of eukaryotic proteasomes make it likely that proteasomal proteins are encoded by one gene family of ancient origin.     

Tricorn protease in bacteria: characterization of the enzyme from Streptomyces coelicolor

Tricorn protease is believed to act downstream of the proteasome, or of other ATP-dependent proteases, cleaving the oligopeptides (mostly 6 to 12 residues) released by them into small peptides (2 to 4 residues), before an array of aminopeptidases finally converts them into free amino acids. Hitherto, the occurrence of Tricorn protease seemed to be limited to some archaea, but genes encoding Tricorn homologs have now been found in several bacterial genomes. Among them is Streptomyces coelicolor A3(2), which has, in fact, two Tricorn-like genes, ScC77.16c and ScE87.19. The proteins encoded by them (TRI-ScC77 and TRI-ScE87) are very similar in their PDZ and TSP domains, but rather divergent in their beta-propeller domains. We have expressed one of them, TRI-ScC77, in E. coil and characterized the recombinant protein structurally and functionally. TRI-ScC77 forms a homohexameric complex of approximately 700 kDa, both in E. coil and in S. coelicolor, with enzymatic properties very similar to the complex from the archaeon Thermoplasma acidophilum. The fact that Tricorn-like proteins exist not only in thermoacidophiles, but also in bacteria inhabiting radically different environments, rules out the possibility that Tricorn protease is an adaptive element that helps to meet the challenges of an extreme habitat.     

Phylogenetic analysis of AAA proteins

AAA ATPases form a large protein family with manifold cellular roles. They belong to the AAA+ superfamily of ringshaped P-loop NTPases, which exert their activity through the energy-dependent unfolding of macromolecules. Phylogenetic analyses have suggested the existence of five major clades of AAA domains (proteasome subunits, metalloproteases, domains D1 and D2 of ATPases with two AAA domains, and the MSP1/katanin/spastin group), as well as a number of deeply branching minor clades. These analyses however have been characterized by a lack of consistency in defining the boundaries of the AAA family. We have used cluster analysis to delineate unambiguously the group of AAA sequences within the AAA+ superfamily. Phylogenetic and cluster analysis of this sequence set revealed the existence of a sixth major AAA clade, comprising the mitochondrial, membrane-bound protein BCS1 and its homologues. In addition, we identified several deep branches consisting mainly of hypothetical proteins resulting from genomic projects. Analysis of the AAA N-domains provided direct support for the obtained phylogeny for most branches, but revealed some deep splits that had not been apparent from phylogenetic analysis and some unexpected similarities between distant clades. It also revealed highly degenerate D1 domains in plant MSP1 sequences and in at least one deeply branching group of hypothetical proteins (YC46), showing that AAA proteins with two ATPase domains arose at least three times independently.     

Biochemical and physical properties of the Methanococcus jannaschii 20S proteasome and PAN, a homolog of the ATPase (Rpt) subunits of the eucaryal 26S proteasome

The 20S proteasome is a self-compartmentalized protease which degrades unfolded polypeptides and has been purified from eucaryotes, gram-positive actinomycetes, and archaea. Energy-dependent complexes, such as the 19S cap of the eucaryal 26S proteasome, are assumed to be responsible for the recognition and/or unfolding of substrate proteins which are then translocated into the central chamber of the 20S proteasome and hydrolyzed to polypeptide products of 3 to 30 residues. All archaeal genomes which have been sequenced are predicted to encode proteins with up to approximately 50% identity to the six ATPase subunits of the 19S cap. In this study, one of these archaeal homologs which has been named PAN for proteasome-activating nucleotidase was characterized from the hyperthermophile Methanococcus jannaschii. In addition, the M. jannaschii 20S proteasome was purified as a 700-kDa complex by in vitro assembly of the alpha and beta subunits and has an unusually high rate of peptide and unfolded-polypeptide hydrolysis at 100 degrees C. The 550-kDa PAN complex was required for CTP- or ATP-dependent degradation of beta-casein by archaeal 20S proteasomes. A 500-kDa complex of PAN(Delta1-73), which has a deletion of residues 1 to 73 of the deduced protein and disrupts the predicted N-terminal coiled-coil, also facilitated this energy-dependent proteolysis. However, this deletion increased the types of nucleotides hydrolyzed to include not only ATP and CTP but also ITP, GTP, TTP, and UTP. The temperature optimum for nucleotide (ATP) hydrolysis was reduced from 80 degrees C for the full-length protein to 65 degrees C for PAN(Delta1-73). Both PAN protein complexes were stable in the absence of ATP and were inhibited by N-ethylmaleimide and p-chloromercuriphenyl-sulfonic acid. Kinetic analysis reveals that the PAN protein has a relatively high V(max) for ATP and CTP hydrolysis of 3.5 and 5.8 micromol of P(i) per min per mg of protein as well as a relatively low affinity for CTP and ATP with K(m) values of 307 and 497 microM compared to other proteins of the AAA family. Based on electron micrographs, PAN and PAN(Delta1-73) apparently associate with the ends of the 20S proteasome cylinder. These results suggest that the M. jannaschii as well as related archaeal 20S proteasomes require a nucleotidase complex such as PAN to mediate the energy-dependent hydrolysis of folded-substrate proteins and that the N-terminal 73 amino acid residues of PAN are not absolutely required for this reaction.     

Structural and biochemical properties of an extreme ‘salt-loving’ proteasome activating nucleotidase from the archaeon Haloferax volcanii

In eukaryotes, the 26S proteasome degrades ubiquitinylated proteins in an ATP-dependent manner. Archaea mediate a form of post-translational modification of proteins termed sampylation that resembles ubiquitinylation. Sampylation was identified in Haloferax volcanii, a moderate halophilic archaeon that synthesizes homologs of 26S proteasome subunits including 20S core particles and regulatory particle triple-A ATPases (Rpt)-like proteasome-associated nucleotidases (PAN-A/1 and PAN-B/2). To determine whether sampylated proteins associate with the Rpt subunit homologs, PAN-A/1 was purified to homogeneity from Hfx. volcanii and analyzed for its subunit stoichiometry, nucleotide-hydrolyzing activity and binding to sampylated protein targets. PAN-A/1 was found to be associated as a dodecamer (630 kDa) with a configuration in TEM suggesting a complex of two stacked hexameric rings. PAN-A/1 had high affinity for ATP (K _m of ~0.44 mM) and hydrolyzed this nucleotide with a specific activity of 0.33 ± 0.1 μmol Pi/h per mg protein and maximum at 42 °C. PAN-A1 was stabilized by 2 M salt with a decrease in activity at lower concentrations of salt that correlated with dissociation of the dodecamer into trimers to monomers. Binding of PAN-A/1 to a sampylated protein was demonstrated by modification of a far Western blotting technique (derived from the standard Western blot method to detect protein–protein interaction in vitro) for halophilic proteins. Overall, our results support a model in which sampylated proteins associate with the PAN-A/1 AAA+ ATPase in proteasome-mediated proteolysis and/or protein remodeling and provide a method for assay of halophilic protein–protein interactions.     

Subunit stoichiometry and three-dimensional arrangement in proteasomes from Thermoplasma acidophilum.

The proteasome or multicatalytic proteinase from the archaebacterium Thermoplasma acidophilum is a 700 kDa multisubunit protein complex. Unlike proteasomes from eukaryotic cells which are composed of 10-20 different subunits, the Thermoplasma proteasome is made of only two types of subunit, alpha and beta, which have molecular weights of 25.8 and 22.3 kDa, respectively. In this communication we present a three-dimensional stoichiometric model of the archaebacterial proteasome deduced from electron microscopic investigations. The techniques which we have used include image analysis of negatively stained single particles, image analysis of metal decorated small three-dimensional crystals after freeze-etching and STEM mass measurements of freeze-dried particles. The archaebacterial and eukaryotic proteasomes are almost identical in size and shape; the subunits are arranged in four rings which are stacked together such that they collectively form a barrel-shaped complex. According to a previous immunoelectron microscopic investigation, the alpha-subunits form the two outer rings of the stack, while the two rings composed of beta-subunits, which are supposed to carry the active sites, are sandwiched between them. Each of the alpha- and beta-rings contains seven subunits; hence the stoichiometry of the whole proteasome is alpha 14 beta 14 and the symmetry is 7-fold. Image simulation experiments indicate that the alpha- and beta-subunits are not in register along the cylinder axis; rather it appears that the beta-rings are rotated with respect to the alpha-rings by approximately 25 degrees. In contrast to some previous reports we have not been able to find stoichiometric amounts of RNA associated with highly purified proteolytically active proteasome preparations.     

The 26S proteasome negatively regulates the level of overall genomic nucleotide excision repair

Regulation of protein expression can be achieved through destruction of proteins by the 26S proteasome. Cellular processes that are regulated by proteolysis include cell cycle progression, stress responses and differentiation. Several nucleotide excision repair proteins in yeast and humans, such as Rad23, Rad4 and XPB, have been shown to co-purify with Cim3 and Cim5, AAA ATPases of the 19S proteasome regulatory subunit. However, it has not been determined if nucleotide excision repair is regulated through protein destruction. We measured nucleotide excision repair in yeast mutants that are defective in proteasome function and found that the repair of the transcribed and non-transcribed strands of an RNA polymerase II-transcribed reporter gene was increased in the absence of proteasome function. Additionally, overexpression of the Rad4 repair protein, which is bound to the repair/proteolytic factor Rad23, conferred higher rates of nucleotide excision repair. Based on our data we suggest that a protein (or proteins) involved in nucleotide excision repair or in regulation of repair is degraded by the 26S proteasome. We propose that decreased proteasome function enables increased DNA repair, due to the transient accumulation of a specific repair factor, perhaps Rad4.     

Quality control: linking retrotranslocation and degradation

Misfolded proteins in the ER require the p97 AAA ATPase for dislocation across the membrane prior to degradation by the cytosolic proteasome. The mechanism by which dislocated proteins are delivered to the proteasome from p97 is unclear, but recent studies suggest an important regulatory role for the protein ataxin-3.     

Rpn9 Is Required for Efficient Assembly of the Yeast 26S Proteasome

We have isolated the RPN9 gene by two-hybrid screening with, as bait, RPN10 (formerly SUN1), which encodes a multiubiquitin chain receptor residing in the regulatory particle of the 26S proteasome. Rpn9 is a nonessential subunit of the regulatory particle of the 26S proteasome, but the deletion of this gene results in temperature-sensitive growth. At the restrictive temperature, the Deltarpn9 strain accumulated multiubiquitinated proteins, indicating that the RPN9 function is needed for the 26S proteasome activity at a higher temperature. We analyzed the proteasome fractions separated by glycerol density gradient centrifugation by native polyacrylamide gel electrophoresis and found that a smaller amount of the 26S proteasome was produced in the Deltarpn9 cells and that the 26S proteasome was shifted to lighter fractions than expected. The incomplete proteasome complexes were found to accumulate in the Deltarpn9 cells. Furthermore, Rpn10 was not detected in the fractions containing proteasomes of the Deltarpn9 cells. These results indicate that Rpn9 is needed for incorporating Rpn10 into the 26S proteasome and that Rpn9 participates in the assembly and/or stability of the 26S proteasome.     

An Archaeal Homolog of Proteasome Assembly Factor Functions as a Proteasome Activator

Assembly of the eukaryotic 20S proteasome is an ordered process involving several proteins operating as proteasome assembly factors including PAC1-PAC2 but archaeal 20S proteasome subunits can spontaneously assemble into an active cylindrical architecture. Recent bioinformatic analysis identified archaeal PAC1-PAC2 homologs PbaA and PbaB. However, it remains unclear whether such assembly factor-like proteins play an indispensable role in orchestration of proteasome subunits in archaea. We revealed that PbaB forms a homotetramer and exerts a dual function as an ATP-independent proteasome activator and a molecular chaperone through its tentacle-like C-terminal segments. Our findings provide insights into molecular evolution relationships between proteasome activators and assembly factors.     

Crystal structures of the Rhodococcus proteasome with and without its pro-peptides: implications for the role of the pro-peptide in proteasome assembly

To understand the role of the pro-peptide in proteasome assembly, we have determined structures of the Rhodococcus proteasome and a mutant form that prevents the autocatalytic removal of its pro-peptides. The structures reveal that the pro-peptide acts as an assembly-promoting factor by linking its own beta-subunit to two adjacent alpha-subunits, thereby providing a molecular explanation for the observed kinetics of proteasome assembly. The Rhodococcus proteasome has been found to have a substantially smaller contact region between alpha-subunits compared to those regions in the proteasomes of Thermoplasma, yeast, and mammalian cells, suggesting that a smaller contact area between alpha-subunits is likely the structural basis for the Rhodococcus alpha-subunits not assembling into alpha-rings when expressed alone. Analysis of all available beta-subunit structures shows that the contact area between beta-subunits within a beta-ring is not sufficient for beta-ring self-assembly without the additional contact provided by the alpha-ring. This appears to be a fail-safe mechanism ensuring that the active sites on the beta-subunits are activated only after proteasome assembly is complete.     

Proteomics analysis of Thermoplasma acidophilum with a focus on protein complexes

Two-dimensional gel electrophoresis (2DE) and MALDI-TOF MS were used to obtain a global view of the cytoplasmic proteins expressed by Thermoplasma acidophilum. In addition, glycerol gradient ultracentrifugation coupled to 2DE-MALDI-TOF MS analysis was used to identify subunits of macromolecular complexes. With the 2DE proteomics approach, over 900 spots were resolved of which 271 proteins were identified. A significant number of these form macromolecular complexes, among them the ribosome, proteasome, and thermosome, which are expressed at high levels. In the glycerol gradient heavy fractions, 10 as yet uncharacterized proteins (besides the well known ribosomal subunits, translation initiation factor eIF-6-related protein, elongation factor 1, and DNA-dependent RNA polymerase) were identified that are putative building blocks of protein complexes. These proteins belong to the categories of hypothetical or conserved hypothetical proteins, and they are present in the cytosol at low concentrations. Although these proteins exhibit homology to known sequences, their structures, subunit compositions, and biological functions are not yet known.     

Proteomic characterization of aggregating proteins after the inhibition of the ubiquitin proteasome system

Protein aggregation, which is associated with the impairment of the ubiquitin proteasome system, is a hallmark of many neurodegenerative diseases. To better understand the contribution of proteasome inhibition in aggregation, we analyzed which proteins may potentially localize in chemically induced aggregates in human neuroblastoma tissue culture cells. We enriched for proteins in high-density structures by using a sucrose gradient in combination with stable isotope labeling with amino acids in cell culture (SILAC). The quantitative analysis allowed us to distinguish which proteins were specifically affected by the proteasome inhibition. We identified 642 potentially aggregating proteins, including the p62/sequestosome 1 and NBR1 ubiquitin-binding proteins involved in aggregation. We also identified the ubiquitin-associated protein 2 like (UBAP2L). We verified that it cofractionated with ubiquitin in the high-density fraction and that it was colocalized in the ubiquitin-containing aggregates after proteasome inhibition. In addition, we identified several chaperone proteins and used data from protein interaction networks to show that they potentially interact with distinct subgroups of proteins within the aggregating structures. Several other proteins associated with neurodegenerative diseases, like UCHL1, were identified, further underlining the potential of our analysis to better understand the aggregation process and proteotoxic stress caused by proteasome inhibition.