Tatos Akopian

The Sizes of Peptides Generated from Protein by Mammalian 26 and 20 S Proteasomes IMPLICATIONS FOR UNDERSTANDING THE DEGRADATIVE MECHANISM AND ANTIGEN PRESENTATION

Knowledge about the sizes of peptides generated by proteasomes during protein degradation is essential to fully understand their degradative mechanisms and the subsequent steps in protein turnover and generation of major histocompatibility complex class I antigenic peptides. We demonstrate here that 26 S and activated 20 S proteasomes from rabbit muscle degrade denatured, nonubiquitinated proteins in a highly processive fashion but generate different patterns of peptides (despite their containing identical proteolytic sites). With both enzymes, products range in length from 3 to 22 residues, and their abundance decreases with increasing length according to a log-normal distribution. Less than 15% of the products are the length of class I presented peptides (8 or 9 residues), and two-thirds are too short to function in antigen presentation. Surprisingly, these mammalian proteasomes, which contain two “chymotryptic,” two “tryptic,” and two “post-acidic” active sites, generate peptides with a similar size distribution as do archaeal 20 S proteasomes, which have 14 identical sites. Furthermore, inactivation of the “tryptic” sites altered the peptides produced without significantly affecting their size distribution. Therefore, this distribution is not determined by the number, specificity, or arrangement of the active sites (as proposed by the “molecular ruler” model); instead, we propose that proteolysis continues until products are small enough to diffuse out of the proteasomes.

Lactacystin and clasto-Lactacystin β-Lactone Modify Multiple Proteasome β-Subunits and Inhibit Intracellular Protein Degradation and Major Histocompatibility Complex Class I Antigen Presentation

The antibiotic lactacystin was reported to covalently modify β-subunit X of the mammalian 20 S proteasome and inhibit several of its peptidase activities. However, we demonstrate that [3H]lactacystin treatment modifies all the proteasome’s catalytic β-subunits. Lactacystin and its more potent derivative β-lactone irreversibly inhibit protein breakdown and the chymotryptic, tryptic, and peptidylglutamyl activities of purified 20 S and 26 S particles, although at different rates. Exposure to these agents for 1 to 2 h reduced the degradation of short- and long-lived proteins in four different mammalian cell lines. Unlike peptide aldehyde inhibitors, lactacystin and the β-lactone do not inhibit lysosomal degradation of an endocytosed protein. These agents block class I antigen presentation of a model protein, ovalbumin (synthesized endogenously or loaded exogenously), but do not affect presentation of the peptide epitope SIINFEKL, which does not require proteolysis for presentation. Generation of most peptides required for formation of stable class I heterodimers is also inhibited. Because these agents inhibited protein breakdown and antigen presentation similarly in interferon-γ-treated cells (where proteasomes contain LMP2 and LMP7 subunits in place of X and Y), all β-subunits must be affected similarly. These findings confirm our prior conclusions that proteasomes catalyze the bulk of protein breakdown in mammalian cells and generate the majority of class I-bound epitopes for immune recognition.

Range of sizes of peptide products generated during degradation of different proteins by archaeal proteasomes.

The 20 S proteasome processively degrades cell proteins to peptides. Information on the sizes and nature of these products is essential for understanding the proteasome’s degradative mechanism, the subsequent steps in protein turnover, and major histocompatibility complex class I antigen presentation. Using proteasomes from Thermoplasma acidophilum and four unfolded polypeptides as substrates (insulin-like growth factor, lactalbumin, casein, and alkaline phosphatase, whose lengths range from 71 to 471 residues), we demonstrate that the number of cuts made in a polypeptide and the time needed to degrade it increase with length. The average size of peptides generated from these four polypeptides was 8 ± 1 residues, but ranged from 6 to 10 residues, depending on the protein, as determined by two new independent methods. However, the individual peptide products ranged in length from approximately 3 to 30 residues, as demonstrated by mass spectrometry and size-exclusion chromatography. The sizes of individual peptides fit a log-normal distribution. No length was predominant, and more than half were shorter than 10 residues. Peptide abundance decreased with increasing length, and less than 10% exceeded 20 residues. These findings indicate that: 1) the proteasome does not generate peptides according to the “molecular ruler” hypothesis, and 2) other peptidases must function after the proteasome to complete the turnover of cell proteins to amino acids.

Processive Degradation of Proteins and Other Catalytic Properties of the Proteasome from Thermoplasma acidophilum

Although the structure of the 20 S proteasome from Thermoplasma acidophilum has been elucidated, its enzymatic properties have not been explored in depth. Thermoplasma proteasomes, which contain one type of active site, exhibit not only “chymotrypsin-like” activity (as reported), but also some “post-glutamyl” and “trypsin-like” activities. Like eukaryotic proteasomes, its activity can be stimulated by SDS, Mg2+, and also guanidine HCl, but not urea. The enzyme was strongly inhibited by novel peptide aldehydes with hydrophobic P4 residues, and was rapidly inactivated by 3,4-dichloroisocoumarin (DCI). DCI modified the N-terminal threonine of the catalytic β-subunit, the presumed active site nucleophile. To define how proteins are degraded, casein was derivatized with fluorescein isothiocyanate to facilitate detection of released products by the proteasome. Many fluorescent peptides were generated, but the relative amounts of different peptides were independent of the duration of the reaction. The rate of disappearance of protein substrates paralleled the rate of appearance of small products. Unlike conventional proteases, proteasome degrades proteins processively without release of polypeptide intermediates. Upon activation by SDS, guanidine, heat (55°C), or partial inhibition with DCI, proteasomes still functioned processively, but generated a different pattern of peptides under each condition. Thus, processivity is an inherent feature of the 20 S proteasome, not requiring all active sites or ATP hydrolysis.

Mycobacterium tuberculosis ClpP1 and ClpP2 Function Together in Protein Degradation and Are Required for Viability in vitro and During Infection

In most bacteria, Clp protease is a conserved, non-essential serine protease that regulates the response to various stresses. Mycobacteria, including Mycobacterium tuberculosis (Mtb) and Mycobacterium smegmatis, unlike most well studied prokaryotes, encode two ClpP homologs, ClpP1 and ClpP2, in a single operon. Here we demonstrate that the two proteins form a mixed complex (ClpP1P2) in mycobacteria. Using two different approaches, promoter replacement, and a novel system of inducible protein degradation, leading to inducible expression of clpP1 and clpP2, we demonstrate that both genes are essential for growth and that a marked depletion of either one results in rapid bacterial death. ClpP1P2 protease appears important in degrading missense and prematurely terminated peptides, as partial depletion of ClpP2 reduced growth specifically in the presence of antibiotics that increase errors in translation. We further show that the ClpP1P2 protease is required for the degradation of proteins tagged with the SsrA motif, a tag co-translationally added to incomplete protein products. Using active site mutants of ClpP1 and ClpP2, we show that the activity of each subunit is required for proteolysis, for normal growth of Mtb in vitro and during infection of mice. These observations suggest that the Clp protease plays an unusual and essential role in Mtb and may serve as an ideal target for antimycobacterial therapy.

The active ClpP protease from M. tuberculosis is a complex composed of a heptameric ClpP1 and a ClpP2 ring

Mycobacterium tuberculosis (Mtb) contains two clpP genes, both of which are essential for viability. We expressed and purified Mtb ClpP1 and ClpP2 separately. Although each formed a tetradecameric structure and was processed, they lacked proteolytic activity. We could, however, reconstitute an active, mixed ClpP1P2 complex after identifying N‐blocked dipeptides that stimulate dramatically (>1000‐fold) ClpP1P2 activity against certain peptides and proteins. These activators function cooperatively to induce the dissociation of ClpP1 and ClpP2 tetradecamers into heptameric rings, which then re‐associate to form the active ClpP1P2 2‐ring mixed complex. No analogous small molecule‐induced enzyme activation mechanism involving dissociation and re‐association of multimeric rings has been described. ClpP1P2 possesses chymotrypsin and caspase‐like activities, and ClpP1 and ClpP2 differ in cleavage preferences. The regulatory ATPase ClpC1 was purified and shown to increase hydrolysis of proteins by ClpP1P2, but not peptides. ClpC1 did not activate ClpP1 or ClpP2 homotetradecamers and stimulated ClpP1P2 only when both ATP and a dipeptide activator were present. ClpP1P2 activity, its unusual activation mechanism and ClpC1 ATPase represent attractive drug targets to combat tuberculosis.

The Cyclic Peptide Ecumicin Targeting ClpC1 Is Active against Mycobacterium tuberculosis In Vivo

ABSTRACT Drug-resistant tuberculosis (TB) has lent urgency to finding new drug leads with novel modes of action. A high-throughput screening campaign of >65,000 actinomycete extracts for inhibition of Mycobacterium tuberculosis viability identified ecumicin, a macrocyclic tridecapeptide that exerts potent, selective bactericidal activity against M. tuberculosis in vitro, including nonreplicating cells. Ecumicin retains activity against isolated multiple-drug-resistant (MDR) and extensively drug-resistant (XDR) strains of M. tuberculosis. The subcutaneous administration to mice of ecumicin in a micellar formulation at 20 mg/kg body weight resulted in plasma and lung exposures exceeding the MIC. Complete inhibition of M. tuberculosis growth in the lungs of mice was achieved following 12 doses at 20 or 32 mg/kg. Genome mining of lab-generated, spontaneous ecumicin-resistant M. tuberculosis strains identified the ClpC1 ATPase complex as the putative target, and this was confirmed by a drug affinity response test. ClpC1 functions in protein breakdown with the ClpP1P2 protease complex. Ecumicin markedly enhanced the ATPase activity of wild-type (WT) ClpC1 but prevented activation of proteolysis by ClpC1. Less stimulation was observed with ClpC1 from ecumicin-resistant mutants. Thus, ClpC1 is a valid drug target against M. tuberculosis, and ecumicin may serve as a lead compound for anti-TB drug development.

PROTEIN DEGRADATION BY THE PROTEASOME AND DISSECTION OF ITS IN VIVO IMPORTANCE WITH SYNTHETIC INHIBITORS

Despite extensive progress in recent years in knowledge about the structure, catalytic mechanism, and peptidase activities of the 20S proteasome [1], many fundamental questions about its function remain unclear. For example, the mechanisms by which protein substrates are hydrolyzed by the 20S and 26S proteasomes and the nature of the peptides generated have not been systematically investigated, although these questions have important biological implications. Our recent studies have established that these particles degrade each protein in a highly processive manner to generate small peptides. This behavior raises many mechanistic questions and clearly distinguishes it from conventional proteases. In addition, much remains to be learned concerning the physiological importance of this particle in intracellular proteolysis both in mammalian cells and lower eukaryotes. Until recently, the physiological importance of these particles has been quite unclear, in large part due to the lack of selective inhibitors of its activity. The present article summarizes recent progress made in our knowledge about this processive mechanism and also about the proteasome’s function in vivo obtained through the use of inhibitors that enter cells and selectively block its activity. Many of the present studies have utilized the 20S proteasome from Thermoplasma acidophilum, which has proven a very valuable model for understanding proteasome structure. However, its enzymatic properties have not been explored in depth. The Thermoplasma particle offers many advantages for studies of the mechanism of the 20S proteasome in digesting proteins. Unlike the eukaryotic proteasome, it contains only one type of -subunit and one type of -subunit, and its structure has been resolved by X-ray diffraction [2]. The important X-ray diffraction and mutagenesis studies by Baumeister, Huber and coworkers have suggested a novel proteolytic mechanism, in which the nucleophilic attack on the peptide bond is initiated by the hydroxyl group on the N-terminal threonine of the -subunit [2, 3]. Our initial studies were undertaken to define its catalytic properties more precisely than previously. The recombinant archael proteasome, which contains only one type of active site, was found to exhibit not only strong ‘chymotrypsin-like’ activity (as had been found previously), but also some ‘post-glutamyl’ and some ‘trypsin-like’ activities. Thus, its one active site has rather broad specificity. In contrast to prior reports, we found that the Thermoplasma particle is relatively inactive when isolated, but can be activated 2to 4-fold by ionic detergents (SDS) and also by guanidine HCl. In this feature, the archael particle resembles the 20S particles from eukaryotes. Its activity was inhibited reversibly by peptide aldehydes and especially well by several novel peptide aldehydes with large hydrophobic residues in the P4 position, which seems to be an important residue in determining activity. Like the mammalian particle, this proteasome was inactivated irreversibly by 3,4 dichloroisocoumarin (DCI), but quite resistant to lactacystin or its -lactone derivative, which inhibits eukaryotic proteasomes. Sequence analysis indicated that DCI covalently modified the hydroxyl group of the N-terminal threonine of the subunit, the presumed active site nucleophile.

Acyldepsipeptide antibiotics kill mycobacteria by preventing the physiological functions of the ClpP1P2 protease.

The Clp protease complex in Mycobacterium tuberculosis is unusual in its composition, functional importance and activation mechanism. Whilst most bacterial species contain a single ClpP protein that is dispensable for normal growth, mycobacteria have two ClpPs, ClpP1 and ClpP2, which are essential for viability and together form the ClpP1P2 tetradecamer. Acyldepsipeptide antibiotics of the ADEP class inhibit the growth of Gram‐positive firmicutes by activating ClpP and causing unregulated protein degradation. Here we show that, in contrast, mycobacteria are killed by ADEP through inhibition of ClpP function. Although ADEPs can stimulate purified M. tuberculosis ClpP1P2 to degrade larger peptides and unstructured proteins, this effect is weaker than for ClpP from other bacteria and depends on the presence of an additional activating factor (e.g. the dipeptide benzyloxycarbonyl‐leucyl‐leucine in vitro) to form the active ClpP1P2 tetradecamer. The cell division protein FtsZ, which is a particularly sensitive target for ADEP‐activated ClpP in firmicutes, is not degraded in mycobacteria. Depletion of the ClpP1P2 level in a conditional Mycobacterium bovis BCG mutant enhanced killing by ADEP unlike in other bacteria. In summary, ADEPs kill mycobacteria by preventing interaction of ClpP1P2 with the regulatory ATPases, ClpX or ClpC1, thus inhibiting essential ATP‐dependent protein degradation.

Cleavage Specificity of Mycobacterium tuberculosis ClpP1P2 Protease and Identification of Novel Peptide Substrates and Boronate Inhibitors with Anti-bacterial Activity

Background: ClpP1P2 is a novel protease complex essential for viability of Mycobacterium tuberculosis. Results: Cleavage preferences of ClpP1P2 were defined, which allowed us to design potent substrate-based boronate inhibitors showing anti-mycobacterial activity. Conclusion: Excellent new fluorogenic peptide substrates of ClpP1P2 were obtained, and novel enzyme properties were identified. Significance: Selective inhibition of ClpP1P2 activity is a promising approach for drug development. The ClpP1P2 protease complex is essential for viability in Mycobacteria tuberculosis and is an attractive drug target. Using a fluorogenic tripeptide library (Ac-X3X2X1-aminomethylcoumarin) and by determining specificity constants (kcat/Km), we show that ClpP1P2 prefers Met ≫ Leu > Phe > Ala in the X1 position, basic residues or Trp in the X2 position, and Pro ≫ Ala > Trp in the X3 position. We identified peptide substrates that are hydrolyzed up to 1000 times faster than the standard ClpP substrate. These positional preferences were consistent with cleavage sites in the protein GFPssrA by ClpXP1P2. Studies of ClpP1P2 with inactive ClpP1 or ClpP2 indicated that ClpP1 was responsible for nearly all the peptidase activity, whereas both ClpP1 and ClpP2 contributed to protein degradation. Substrate-based peptide boronates were synthesized that inhibit ClpP1P2 peptidase activity in the submicromolar range. Some of them inhibited the growth of Mtb cells in the low micromolar range indicating that cleavage specificity of Mtb ClpP1P2 can be used to design novel anti-bacterial agents.