Crystal structure of a dodecameric tetrahedral-shaped aminopeptidase

Protein turnover is an essential process in living cells. The degradation of cytosolic polypeptides is mainly carried out by the proteasome, resulting in 7-9-amino acid long peptides. Further degradation is usually carried out by energy-independent proteases like the tricorn protease from Thermoplasma acidophilum. Recently, a novel tetrahedral-shaped dodecameric 480-kDa aminopeptidase complex (TET) has been described in Haloarcula marismortui that differs from the known ring- or barrel-shaped self-compartmentalizing proteases. This complex is capable of degrading most peptides down to amino acids. We present here the crystal structure of the tetrahedral aminopeptidase homolog FrvX from Pyrococcus horikoshii. The monomer has a typical clan MH fold, as found for example in Aeromonas proteolytica aminopeptidase, containing a dinuclear zinc active center. The quaternary structure is built by dimers with a length of 100 A that form the edges of the tetrahedron. All 12 active sites are located on the inside of the tetrahedron. Substrate access is granted by pores with a maximal diameter of 10 A, allowing only small peptides and unfolded proteins access to the active site.     

Regulation of the 26S proteasome activities by peptides mimicking cleavage products

The implication of the released peptides in allosteric effects during protein degradation catalyzed by the proteasome is an important question not completely resolved. We present here data showing modulation of 26S proteasome activities by peptides composed of 5 or 6 natural amino acids that mimic the products generated during protein breakdown. Several of these peptides inhibit the chymotrypsin-like activity of the Xenope 26S proteasome whereas its trypsin-like activity is enhanced. The basic peptides produced competitive inhibition of the chymotrypsin-like activity and the acidic peptides, parabolic inhibition involving two different binding sites. Our results are in agreement with a model involving hypothetical non-catalytic sites interacting with effectors to modulate the peptidase activities of the proteasome. They also suggest that allosteric effects may occur in the proteasome during protein degradation.     

Critical amino acids of ornitin decarboxylase degron: the presence and C-terminal arrangement is insufficient for alfa-fetoprotein degradation

Mouse ornithine decarboxylase (ODC) degrades in proteasome in an ubiquitin-independent manner with an averagehalf-life of 2 h. The 37 amino acid long C-terminal fragment known as a degradation signal (degron) is responsible for the effective degradation of ODC. Recently, amino acids being critical for degradation in the ODC-degron have been mapped. Mutations of Cys441 and Ala442 led to protein stabilization, while a substitution of other amino acids composing ODC-degron had almost no effect on the protein turnover; whereas insertions or deletions in region between Ala442 and ODC C-terminus diminished greatly rate of protein degradation, e.g. positioning of the key amino acids from the C-terminus was shown to be crucial. Using these data we introduced both key amino acids into the alfa-fetoprotein with truncated exportation signal (deltaAFP), at the same distance from the C-terminus as they being in the ODC (deltaAFPCAG and deltaAFPLCAG). Removal of N-terminal exportation signal prevented secretion of modified proteins. Using in silico approach we demonstrated no significant difference in hydrophobicity or secondary structure between C-terminus of deltaAFP and mutated proteins. The degradation kinetics of deltaAFP, deltaAFPCAG, deltaAFPLCAG in cyloheximide-chase and proteasome inhibition assay (using MG132) was identical. Obtained results suggest that introduced substitutions are insufficient for effective recognition of mutated deltaAFP by26S proteasome. We assume thatadditional amino aci ds composing ODC-degron or their combine action could also affect degradation. Besides that, one cannot exclude that conformation of the mutated deltaAFP limits its C-terminus accessibility to proteasome.     

Support for a potential role of E. coli oligopeptidase A in protein degradation

Protein degradation is an essential quality control and regulatory function in organisms ranging from bacteria to eukaryotes. In bacteria, this process is initiated by ATP-dependent proteases which digest proteins to short peptides that are subsequently hydrolyzed to smaller fragments and free amino acids. While the entire genome of Escherichia coli has been sequenced, identification of endopeptidases that perform this downstream hydrolysis remains incomplete. However, in eukaryotes, thimet oligopeptidases (TOP) has been shown to hydrolyze peptides generated by the degradation of proteins by the 26S proteasome. These findings motivated us to investigate whether E. coli oligopeptidase A (OpdA), a homolog of TOP might play a similar general role in bacterial protein degradation. Herein, we provide initial support for this hypothesis by demonstrating that OpdA efficiently cleaves the peptides generated by the activity of the three primary ATP-dependent proteases from E. coli-Lon, HslUV, and ClpAP.     

Lysozyme degradation by the bovine multicatalytic proteinase complex (proteasome): evidence for a nonprocessive mode of degradation.

The multicatalytic proteinase complex (MPC, proteasome) is composed of 28 subunits organized into four rings surrounding a water-filled canal. The catalytic centers face the inner canal confining protein substrates to an enclosed space. Experimental findings obtained with MPC from archaebacteria suggest that degradation of proteins by the complex is processive and have led to the proposal that the lengths of the peptides formed during degradation depend on the distances between active sites in the catalytic chamber. To test whether these postulates are valid for the MPC from a higher organism, we examined the size distributions of products formed early versus late in the course of protein degradation using reduced carboxamidomethylated lysozyme (RCM-lysozyme) and MPC from bovine spleen and pituitary. The majority of final degradation products ranged in length from 6 to 20 amino acids without a clear predilection for peptides of a particular, uniform size. Our observations suggest that selection of cleavage sites is governed by the amino acid sequence specificity of the MPC catalytic sites rather than the distances between the active sites. Early in the course of degradation, peptides with masses between 5 and 10 kDa accumulated in more than 80-fold molar excess over the MPC, indicating dissociation of large, partially degraded intermediates. Initial cleavages occurred at distances between 10 and 44 amino acids from the N- or C-terminus of the molecule and often involved removal of a fragment from both the N- and C-termini of RCM-lysozyme. Our data indicate that degradation of proteins by MPCs from higher organisms involves a nonprocessive mechanism comprised of multiple, independent cleavages with dissociation of degradation intermediates. A general model for protein degradation by the MPC is discussed.     

Availability and canonical positioning of key amino acids of ornithine-decarboxylase degron is insufficient for alpha-fetoprotein degradation

Ornithine decarboxylase (ODC) degrades in proteasome in a ubiquitin-independent manner with the half life of approximately 2 h. Thirty seven C-terminal amino acids of this enzyme constitute a fragment known as the degradation signal (degron), which is responsible for the effectiveness of protein degradation. Among these amino acids, the key positions have recently been mapped (Cys441 and Ala442). Mutations of the key amino acids led to ODC general stabilization, whereas substitution of other amino acids had no significant influence on the ODC degron activity. In addition, deletions or insertions into the region located between the key amino acids and ODC C-end diminished significantly the rate of protein degradation; hence, the distance (remoteness) of these amino acids from ODC C-end is, probably, of crucial importance. Taking into account these data, we have introduced the key amino acids that determine ODC-degron activity into alpha-fetoprotein with the truncated export signal (ΔAFP) so that their positioning was 20 amino-acid away from the C-end (ΔAFPCAG and ΔAFPLCAG). Secretion of ΔAFP and the modified proteins from cells was impossible because of a removal of the N-terminal export signal. Computer analysis of ΔAFP and the derivative ΔAFPCAG and ΔAFPLCAG revealed no significant changes in protein hydrophobicity or in the secondary structure of C-terminal region. The in vitro experiments on HEK293T cells using MG132 proteasome inhibitor and translation inhibitor cycloheximide have demonstrated similar stability of ΔAFP and the derivative ΔAFPCAG and ΔAFPLCAG in cells. Thus, introduction of the key amino acids of ODC degron at the key positions relative to the C-end of ΔAFP did not change the parameters of protein degradation. Perhaps, some other still unknown amino acids are important for ODC-degron functioning. It may well be that ΔAFP conformation prevents interaction of the protein C-end with proteasome.     

Tetrahedral aminopeptidase: a novel large protease complex from archaea

A dodecameric protease complex with a tetrahedral shape (TET) was isolated from Haloarcula marismortui, a salt-loving archaeon. The 42 kDa monomers in the complex are homologous to metal-binding, bacterial aminopeptidases. TET has a broad aminopeptidase activity and can process peptides of up to 30-35 amino acids in length. TET has a central cavity that is accessible through four narrow channels (<17 A wide) and through four wider channels (21 A wide). This architecture is different from that of all the proteolytic complexes described to date that are made up by rings or barrels with a single central channel and only two openings.     

Getting in and out of the proteasome

By far the best understood role of the proteasome is to remove ubiquitin-conjugated proteins from eukaryotric cells by hydrolysing them into small peptides of varying lengths. These include both misfolded/abnormal proteins, as well as 'normal' proteins that need to be rapidly removed for regulatory purposes. However, the proteasome is also present in numerous prokaryotic organisms, while ubiquitin, and the ubiquitin conjugating system, are not. The eukaryotic proteasome has been adapted to degrading proteins in a ubiquitin-dependent fashion by the addition of regulatory factors that assemble in different layers onto the proteolytic core of the proteasome, and by increasing the diversity of the core subunits as well. In addition to hydrolysing ubiquitinated proteins into amino acids, the proteasome can also proteolyse selected non-ubiquitinated proteins, process proteins, and possibly refold misfolded proteins. This review will focus on the different proteasome functions, and how these are used in the multiple regulatory roles the proteasome plays in eukaryotic cells.     

The human 26 S and 20 S proteasomes generate overlapping but different sets of peptide fragments from a model protein substrate

Intracellular protein degradation is a major source of short antigenic peptides that can be presented on the cell surface in the context of major histocompatibility class I molecules for recognition by cytotoxic T lymphocytes. The capacity of the most important cytosolic protease, the 20 S proteasome, to generate peptide fragments with an average length of 7-8 amino acid residues has been thoroughly investigated. It has been shown that the cleavage products are not randomly generated, but originate from the commitment of the catalytically active subunits to complex recognition motifs in the primary amino acid sequence. The role of the even larger 26 S proteasome is less well defined, however. It has been demonstrated that the 26 S proteasome can bind and degrade ubiquitin-tagged proteins and minigene translation products in vivo and in vitro, but the nature of the degradation products remains elusive. In this study, we present the first analysis of cleavage products from in vitro digestion of the unmodified model substrate beta-casein with both the 26 S and 20 S proteasome. The data we obtained show that 26 S and 20 S proteasomes generate overlapping, but at the same time substantially different, sets of fragments by following very similar instructions.     

Proteinase yscE, the yeast proteasome/multicatalytic-multifunctional proteinase: mutants unravel its function in stress induced proteolysis and uncover its necessity for cell survival.

Proteinase yscE is the yeast equivalent of the proteasome, a multicatalytic-multifunctional proteinase found in higher eukaryotic cells. We have isolated three mutants affecting the proteolytic activity of proteinase yscE. The mutants show a specific reduction in the activity of the complex against peptide substrates with hydrophobic amino acids at the cleavage site and define two complementation groups, PRE1 and PRE2. The PRE1 gene was cloned and shown to be essential. The deduced amino acid sequence encoded by the PRE1 gene reveals weak, but significant similarities to proteasome subunits of other organisms. Two-dimensional gel electrophoresis identified the yeast proteasome to be composed of 14 different subunits. Comparison of these 14 subunits with the translation product obtained from PRE1 mRNA synthesized in vitro demonstrated that PRE1 encodes the 22.6 kd subunit (numbered 11) of the yeast proteasome. Diploids homozygous for pre1-1 are defective in sporulation. Strains carrying the pre1-1 mutation show enhanced sensitivity to stresses such as incorporation of the amino acid analogue canavanine into proteins or a combination of poor growth medium and elevated temperature. Under these stress conditions pre1-1 mutant cells exhibit decreased protein degradation and accumulate ubiquitin-protein conjugates.     

The role of the proteasome in generating cytotoxic T-cell epitopes: insights obtained from improved predictions of proteasomal cleavage

Cytotoxic T cells (CTLs) perceive the world through small peptides that are eight to ten amino acids long. These peptides (epitopes) are initially generated by the proteasome, a multi-subunit protease that is responsible for the majority of intra-cellular protein degradation. The proteasome generates the exact C-terminal of CTL epitopes, and the N-terminal with a possible extension. CTL responses may diminish if the epitopes are destroyed by the proteasomes. Therefore, the prediction of the proteasome cleavage sites is important to identify potential immunogenic regions in the proteomes of pathogenic microorganisms (or humans). We have recently shown that NetChop, a neural network-based prediction method, is the best method available at the moment to do such predictions; however, its performance is still lower than desired. Here, we use novel sequence encoding methods and show that the new version of NetChop predicts approximately 10% more of the cleavage sites correctly while lowering the number of false positives with close to 15%. With this more reliable prediction tool, we study two important questions concerning the function of the proteasome. First, we estimate the N-terminal extension of epitopes after proteasomal cleavage and find that the average extension is relatively short. However, more than 30% of the peptides have N-terminal extensions of three amino acids or more, and thus, N-terminal trimming might play an important role in the presentation of a substantial fraction of the epitopes. Second, we show that good TAP ligands have an increased chance of being cleaved by the proteasome, i.e., the specificity of TAP has evolved to fit the specificity of the proteasome. This evolutionary relationship allows for a more efficient antigen presentation.The new version of NetChop (NetChop 3.0) is available at .     

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 COOH-terminal domain of wild-type Cot regulates its stability and kinase specific activity

Cot, initially identified as an oncogene in a truncated form, is a mitogen-activated protein kinase kinase kinase implicated in cellular activation and proliferation. Here, we show that this truncation of Cot results in a 10-fold increase in its overall kinase activity through two different mechanisms. Truncated Cot protein exhibits a lower turnover rate (half-life, 95 min) than wild-type Cot (half-life, 35 min). The degradation of wild-type and truncated Cot can be specifically inhibited by proteasome inhibitors in situ. The 20S proteasome also degrades wild-type Cot more efficiently than the truncated protein. Furthermore, the amino acid 435 to 457 region within the wild-type Cot COOH-terminal domain confers instability when transferred to the yellow fluorescent protein and targets this fusion protein to degradation via the proteasome. On the other hand, the kinase specific activity of wild-type Cot is 3.8-fold lower than that of truncated Cot, and it appears that the last 43 amino acids of the wild-type Cot COOH-terminal domain are those responsible for this inhibition of kinase activity. In conclusion, these data demonstrate that the oncogenic activity of truncated Cot is the result of its prolonged half-life and its higher kinase specific activity with respect to wild-type Cot.     

BIOACTIVE PROTEINS,PEPTIDES, AND AMINO ACIDS FROM MACROALGAE1

Macroalgae are a diverse group of marine organisms that have developed complex and unique metabolic pathways to ensure survival in highly competitive marine environments. As a result, these organisms have been targeted for mining of natural biologically active components. The exploration of marine organisms has revealed numerous bioactive compounds that are proteinaceous in nature. These include proteins, linear peptides, cyclic peptides and depsipeptides, peptide derivatives, amino acids, and amino acid–like components. Furthermore, some species of macroalgae have been shown to contain significant levels of protein. While some protein‐derived bioactive peptides have been characterized from macroalgae, macroalgal proteins currently still represent good candidate raw materials for biofunctional peptide mining. This review will provide an overview of the important bioactive amino‐acid‐containing compounds that have been identified in macroalgae. Moreover, the potential of macroalgal proteins as substrates for the generation of biofunctional peptides for utilization as functional foods to provide specific health benefits will be discussed.     

Starving to succeed

Cancer cells rely on the efficient and effective turnover of cell signaling molecules to ensure their continued survival, and hence depend on specific amino acids (AAs) for their growth and metastatic capabilities. This dependence has been exploited by the recent, successful development of the proteasome inhibitor, bortezomib, which inhibits the degradation of proteins; and suggests that inhibitors of other essential steps in the mechanisms of cellular protein turnover may provide novel therapeutic targets. The provision of free AAs within cancer cells is controlled by aminopeptidases which are responsible for the cleavage of AAs from the amino terminus of proteins or peptides. Recent studies have demonstrated that the expression of aminopeptidases is upregulated in cancer cells compared to normal cells, providing a rationale for further study and development of clinical grade aminopeptidase inhibitors.     

Sequence- and species-dependence of proteasomal processivity

The proteasome is the degradation machine at the center of the ubiquitin-proteasome system and controls the concentrations of many proteins in eukaryotes. It is highly processive so that substrates are degraded completely into small peptides, avoiding the formation of potentially toxic fragments. Nonetheless, some proteins are incompletely degraded, indicating the existence of factors that influence proteasomal processivity. We have quantified proteasomal processivity and determined the underlying rates of substrate degradation and release. We find that processivity increases with species complexity over a 5-fold range between yeast and mammalian proteasome, and the effect is due to slower but more persistent degradation by proteasomes from more complex organisms. A sequence stretch that has been implicated in causing incomplete degradation, the glycine-rich region of the NFκB subunit p105, reduces the proteasome's ability to unfold its substrate, and polyglutamine repeats such as found in Huntington's disease reduce the processivity of the proteasome in a length-dependent manner.     

Characterization of a transport activity for long-chain peptides in barley mesophyll vacuoles

The plant vacuole is the largest compartment in a fully expanded plant cell. While only very limited metabolic activity can be observed within the vacuole, the majority of the hydrolytic activities, including proteolytic activities reside in this organelle. Since it is assumed that protein degradation by the proteasome results in the production of peptides with a size of 3-30 amino acids, we were interested to show whether the tonoplast exhibits a transport activity, which could deliver these peptides into the vacuole for final degradation. It is shown here that isolated barley mesophyll vacuoles take up peptides of 9-27 amino acids in a strictly ATP-dependent manner. Uptake is inhibited by vanadate, but not by NH(+)(4), while GTP could partially substitute for ATP. The apparent affinity for the 9 amino acid peptide was 15 μM, suggesting that peptides are efficiently transferred to the vacuole in vivo. Inhibition experiments showed that peptides with a chain length below 10 amino acids did not compete as efficiently as longer peptides for the uptake of the 9 amino acid peptide. Our results suggest that vacuoles contain at least one peptide transporter that belongs to the ABC-type transporters, which efficiently exports long-chain peptides from the cytosol into the vacuole for final degradation.     

Functional Characterization of Two M42 Aminopeptidases Erroneously Annotated as Cellulases

Several aminopeptidases of the M42 family have been described as tetrahedral-shaped dodecameric (TET) aminopeptidases. A current hypothesis suggests that these enzymes are involved, along with the tricorn peptidase, in degrading peptides produced by the proteasome. Yet the M42 family remains ill defined, as some members have been annotated as cellulases because of their homology with CelM, formerly described as an endoglucanase of Clostridium thermocellum. Here we describe the catalytic functions and substrate profiles CelM and of TmPep1050, the latter having been annotated as an endoglucanase of Thermotoga maritima. Both enzymes were shown to catalyze hydrolysis of nonpolar aliphatic L-amino acid-pNA substrates, the L-leucine derivative appearing as the best substrate. No significant endoglucanase activity was measured, either for TmPep1050 or CelM. Addition of cobalt ions enhanced the activity of both enzymes significantly, while both the chelating agent EDTA and bestatin, a specific inhibitor of metalloaminopeptidases, proved inhibitory. Our results strongly suggest that one should avoid annotating members of the M42 aminopeptidase family as cellulases. In an updated assessment of the distribution of M42 aminopeptidases, we found TET aminopeptidases to be distributed widely amongst archaea and bacteria. We additionally observed that several phyla lack both TET and tricorn. This suggests that other complexes may act downstream from the proteasome.     

Lipopolysaccharide causes Sp1 protein degradation by inducing a unique trypsin-like serine protease in rat lungs

We have previously demonstrated that challenge of rat or mice with lipopolysaccharide (LPS) in vivo promotes Sp1 protein degradation. The protease responsible for the LPS-induced Sp1 degradation has not been identified. In this study, we have identified, characterized and partially purified an LPS-inducible Sp1-degrading enzyme (LISPDE) activity from rat lungs. LISPDE activity selectively degraded Sp1, but not nuclear protein, C-fos, p65, I-kappaBalpha and protein actin. Nuclear extract contains approximately 14-fold of the LISPDE activity as that detected in cytoplasmic extract, suggesting that LISPDE is predominantly a nuclear protease. Using biochemical reagents, protease inhibitors and peptide substrates, we have characterized the LISPDE activity. Based on biochemical characteristics, inhibitor profile, and substrate specificity, we have shown that LISPDE activity is not 26S proteasome, caspase or cathepsin-like activity, but is a trypsin-like serine protease activity. Using soybean trypsin inhibitor (SBTI)-sepharose affinity column, we have partially purified the LISPDE protein, which has an estimated molecular mass of 33 kDa and selectively degrades native Sp1 protein. We mapped the initial site for proteolytic cleavage of Sp1 by LISPDE to be located within the region between amino acids 181-328. We conclude that LPS causes Sp1 degradation by inducing a unique trypsin-like serine protease, LISPDE.