Binding of hydrophobic peptides to several non-catalytic sites promotes peptide hydrolysis by all active sites of 20 S proteasomes. Evidence for peptide-induced channel opening in the alpha-rings

The eukaryotic 20 S proteasome contains the following 6 active sites: 2 chymotrypsin-like, 2 trypsin-like, and 2 caspase-like. We previously showed that hydrophobic peptide substrates of the chymotrypsin-like sites allosterically stimulate peptide hydrolysis by the caspase-like sites and their own cleavage. More thorough analysis revealed that these peptides also stimulate peptide hydrolysis by the trypsin-like site. This general activation by hydrophobic peptides occurred even if the chymotrypsin-like sites were occupied by a covalent inhibitor and was highly cooperative, with an average Hill coefficient of 7. Therefore, this stimulation of peptide hydrolysis at all active sites occurs upon binding of hydrophobic peptides to several non-catalytic sites. The stimulation by hydrophobic peptides was not observed in the yeast Delta N alpha 3 mutant 20 S proteasomes, in 20 S-PA26 complexes, or SDS-activated proteasomes and was significantly lower in 26 S proteasomes, all of which appear to have the gated channel in the alpha-rings in an open conformation and hydrolyze peptides at much faster rates than 20 S proteasomes. Also the hydrophobic peptides altered K(m), V(max) of active sites in a similar fashion as PA26 and the Delta N alpha 3 mutation. The activation by hydrophobic peptides was decreased in K(+)-containing buffer, which favors the closed state of the channels. Therefore, hydrophobic peptides stimulate peptide hydrolysis most likely by promoting the opening of the channels in the alpha-rings. During protein breakdown, this peptide-induced channel opening may function to facilitate the release of products from the proteasome.     

Amino acid identity and/or position determines the proteasomal cleavage of the HLA-A*0201-restricted peptide tumor antigen MAGE-3271-279

The proteasome plays a crucial role in the proteolytic processing of antigens presented to T cells in the context of major histocompatibility complex class I molecules. However, the rules governing the specificity of cleavage sites are still largely unknown. We have previously shown that a cytolytic T lymphocyte-defined antigenic peptide derived from the MAGE-3 tumor-associated antigen (MAGE-3(271-279), FLWGPRALV in one-letter code) is not presented at the surface of melanoma cell lines expressing the MAGE-3 protein. By using purified proteasome and MAGE-3(271-279) peptides extended at the C terminus by 6 amino acids, we identified predominant cleavages after residues 278 and 280 but no detectable cleavage after residue Val(279), the C terminus of the antigenic peptide. In the present study, we have investigated the influence of Pro(275), Leu(278), and Glu(280) on the proteasomal digestion of MAGE-3(271-285) substituted at these positions. We show that positions 278 and 280 are major proteasomal cleavage sites because they tolerate most amino acid substitutions. In contrast, the peptide bond after Val(279) is a minor cleavage site, influenced by both distal and proximal amino acid residues.     

Antigenic determinants in the disulfide regions of bovine fibrinogen.

Rabbit antibodies to bovine fibrinogen were used to study the antigenic activity of four cyanogen bromide peptides containing the disulfide regions of this molecule. In precipitation tests the highest activity was associated with the peptide F-CB3 which is exclusively derived from the alpha-chain. Reduction of the single disulfide bridge in peptide F-CB3 did not influence its serologic activity. Weaker reactions were observed with the N-terminal multichain peptide F-CB1. The antigenicity of peptide F-CB1 was not affected by removal of fibrinopeptides A and B but it was lost after reduction. The immunological activity of the multichain peptide F-CB2 was even less than that of peptide F-CB1 and the antigenic determinants were destroyed by reduction. A large fragment essentially composed of peptides F-CB1 and F-CB2 could be obtained by limited cyanogen bromide cleavage and showed considerably better immunological activity than peptides F-CB1 and F-CB2 together. Apparently no activity was associated with a mixture of small hydrophobic, disulfide-loop peptides tentatively called peptide F-CB4. The large loss of antigenic activity in cyanogen bromide digests of fibrinogen suggests that the disulfide-stabilized regions do not have an important role in maintaining conformational antigenic determinants of fibroinogen. Changes in noncovalently stabilized conformation requiring uncleaved chains is considered as a possible reason for the findings observed.     

Lysine 188 substitutions convert the pattern of proteasome activation by REGgamma to that of REGs alpha and beta.

11S REGs (PA28s) are multimeric rings that bind proteasomes and stimulate peptide hydrolysis. Whereas REGalpha activates proteasomal hydrolysis of peptides with hydrophobic, acidic or basic residues in the P1 position, REGgamma only activates cleavage after basic residues. We have isolated REGgamma mutants capable of activating the hydrolysis of fluorogenic peptides diagnostic for all three active proteasome beta subunits. The most robust REGgamma specificity mutants involve substitution of Glu or Asp for Lys188. REGgamma(K188E/D) variants are virtually identical to REGalpha in proteasome activation but assemble into less stable heptamers/hexamers. Based on the REGalpha crystal structure, Lys188 of REGgamma faces the aqueous channel through the heptamer, raising the possibility that REG channels function as substrate-selective gates. However, covalent modification of proteasome chymotrypsin-like subunits by 125I-YL3-VS demonstrates that REGgamma(K188E)'s activation of all three proteasome active sites is not due to relaxed gating. We propose that decreased stability of REGgamma(K188E) heptamers allows them to change conformation upon proteasome binding, thus relieving inhibition of the CT and PGPH sites normally imposed by the wild-type REGgamma molecule.     

Evidence for the existence of a non-catalytic modifier site of peptide hydrolysis by the 20 S proteasome

The 20 S proteasome is an endoprotease complex that preferentially cleaves peptides C-terminal of hydrophobic, basic, and acidic residues. Recently, we showed that these specific activities, classified as chymotrypsin-like, trypsin-like, and peptidylglutamyl peptide-hydrolyzing (PGPH) activity, are differently affected by Ritonavir, an inhibitor of human immunodeficiency virus-1 protease. Ritonavir competitively inhibited the chymotrypsin-like activity, whereas the trypsin-like activity was enhanced. Here we demonstrate that the Ritonavir-mediated up-regulation of the trypsin-like activity is not affected by specific active site inhibitors of the chymo-trypsin-like and PGPH activity. Moreover, we show that the mutual regulation of chymotrypsin-like and PGPH activities by their substrates as described previously by a "cyclical bite-chew" model is not affected by selective inhibitors of the respective active sites. These data challenge the bite-chew model and suggest that effectors of proteasome activity can act by binding to non-catalytic sites. Accordingly, we propose a kinetic "two-site modifier" model that assumes that the substrate (or effector) may bind to an active site as well as to a second non-catalytic modifier site. This model appears to be valid as it describes the complex kinetic effects of Ritonavir very well. Since Ritonavir partially inhibits major histocompatibility complex class I restricted antigen presentation, the postulated modifier site may be required to coordinate the active centers of the proteasome for the production of class I peptide ligands.     

Inhibition of intraerythrocytic proteasome retards the generation of hemorphins

Hemorphins are a set of hemoglobin-derived opioid peptides. The production mechanism of these structural overlap peptides remains unclear. Based on the sequences of hemorphins, it could be inferred that hemorphins are probably generated by cleavage of hemoglobin β chain at sites favored by the chymotrypsin-like protease. 20S proteasome possesses the chymotrypsin-like activity and still persists in mature erythrocytes. This study attempts to clarify whether the intraerythrocytic proteasome involves in the formation of hemorphins. Hemorphins containing hemorphin-7 and V-hemorphin-7 are isolated by immunoprecipitation from culture supernatant of human erythrocytes. Bortezomib inhibits the chymotrypsin-like activity of intraerythrocytic proteasome and prevents the yield of hemorphins in a dose-dependent manner. The present study suggests that intraerythrocytic proteasome contributes to the generation of hemorphins.     

Inhibition of the chymotrypsin-like activity of the pituitary multicatalytic proteinase complex.

The multicatalytic proteinase complex (MPC), also referred to as proteasome, is a large molecular mass intracellular particle (approximately 700 kDa), which exhibits three distinct proteolytic activities designated as chymotrypsin-like, trypsin-like, and peptidylglutamyl-peptide hydrolyzing (PGPH), all sensitive to inhibition by 3,4-dichloroisocoumarin (DCI). The presence of a component resistant to inhibition by DCI with an apparent preference toward bonds on the carboxyl side of branched-chain amino acids has also been recently established. Peptide aldehydes and peptide alpha-keto esters containing a hydrophobic residue in the P1 position have been tested as potential inhibitors of the chymotrypsin-like activity. Three peptide aldehydes (benzyloxycarbonyl)-Leu-Leu-phenylalaninal (Z-LLF-CHO), N-acetyl-Leu-Leu-norleucinal (Ac-LLnL-CHO), and N-acetyl-Leu-Leu-methioninal (Ac-LLM-CHO) were found to be slow-binding reversible inhibitors with Ki values of 0.46, 5.7, and 33 microM, respectively. The simplest kinetic model for inhibition is consistent with a mechanism involving a slow and reversible association of the enzyme with the inhibitor to form a EI complex. The aldehyde inhibitors also inhibited the trypsin-like and PGPH activities of the complex albeit with much higher Ki values than those for chymotrypsin-like activity. Z-LLF-CHO, the most selective of the three aldehydes, did not inhibit the PGPH activity at concentrations of up to 200 microM and inhibited the trypsin-like activity with a Ki approximately 2 orders of magnitude higher than that for the chymotrypsin-like activity. The activity of the DCI-resistant component was not affected by Z-LLF-CHO.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sequence signals for generation of antigenic peptides by the proteasome: implications for proteasomal cleavage mechanism

Proteasomal cleavage of proteins is the first step in the processing of most antigenic peptides that are presented to cytotoxic T cells. Still, its specificity and mechanism are not fully understood. To identify preferred sequence signals that are used for generation of antigenic peptides by the proteasome, we performed a rigorous analysis of the residues at the termini and flanking regions of naturally processed peptides eluted from MHC class I molecules. Our results show that both the C terminus (position P1 of the cleavage site) and its immediate flanking position (P1') possess significant signals. The N termini of the peptides show these signals only weakly, consistent with previous findings that antigenic peptides may be cleaved by the proteasome with N-terminal extensions. Nevertheless, we succeed to demonstrate indirectly that the N-terminal cleavage sites contain the same preferred signals at position P1'. This reinforces previous findings regarding the role of the P1' position of a cleavage site in determining the cleavage specificity, in addition to the well-known contribution of position P1. Our results apply to the generation of antigenic peptides and bare direct implications for the mechanism of proteasomal cleavage. We propose a model for proteasomal cleavage mechanism by which both ends of cleaved fragments are determined by the same cleavage signals, involving preferred residues at both P1 and P1' positions of a cleavage site. The compatibility of this model with experimental data on protein degradation products and generation of antigenic peptides is demonstrated.     

Pathway for degradation of peptides generated by proteasomes: a key role for thimet oligopeptidase and other metallopeptidases

The degradation of cellular proteins by proteasomes generates peptides 2-24 residues long, which are hydrolyzed rapidly to amino acids. To define the final steps in this pathway and the responsible peptidases, we fractionated by size the peptides generated by proteasomes from beta-[14C]casein and studied in HeLa cell extracts the degradation of the 9-17 residue fraction and also of synthetic deca- and dodecapeptide libraries, because peptides of this size serve as precursors to MHC class I antigenic peptides. Their hydrolysis was followed by measuring the generation of smaller peptides or of new amino groups using fluorescamine. The 14C-labeled peptides released by 20 S proteasomes could not be degraded further by proteasomes. However, their degradation in the extracts and that of the peptide libraries was completely blocked by o-phenanthroline and thus required metallopeptidases. One such endopeptidase, thimet oligopeptidase (TOP), which was recently shown to degrade many antigenic precursors in the cytosol, was found to play a major role in degrading proteasome products. Inhibition or immunodepletion of TOP decreased their degradation and that of the peptide libraries by 30-50%. Pure TOP failed to degrade proteasome products 18-24 residues long but degraded the 9-17 residue fraction to peptides of 6-9 residues. When aminopeptidases in the cell extract were inhibited with bestatin, the 9-17 residue proteasome products were also converted to peptides of 6-9 residues, instead of smaller products. Accordingly, the cytosolic aminopeptidase, leucine aminopeptidase, could not degrade the 9-17 residue fraction but hydrolyzed the peptides generated by TOP to smaller products, recapitulating the process in cell extracts. Inactivation of both TOP and aminopeptidases blocked the degradation of proteasome products and peptide libraries nearly completely. Thus, degradation of most 9-17 residue proteasome products is initiated by endoproteolytic cleavages, primarily by TOP, and the resulting 6-9 residue fragments are further digested to amino acids by aminopeptidases.     

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.     

The internal sequence of the peptide-substrate determines its N-terminus trimming by ERAP1

Background

Endoplasmic reticulum aminopeptidase 1 (ERAP1) trims N-terminally extended antigenic peptide precursors down to mature antigenic peptides for presentation by major histocompatibility complex (MHC) class I molecules. ERAP1 has unique properties for an aminopeptidase being able to trim peptides in vitro based on their length and the nature of their C-termini.

Methodology/Principal Findings

In an effort to better understand the molecular mechanism that ERAP1 uses to trim peptides, we systematically analyzed the enzyme''s substrate preferences using collections of peptide substrates. We discovered strong internal sequence preferences of peptide N-terminus trimming by ERAP1. Preferences were only found for positively charged or hydrophobic residues resulting to trimming rate changes by up to 100 fold for single residue substitutions and more than 40,000 fold for multiple residue substitutions for peptides with identical N-termini. Molecular modelling of ERAP1 revealed a large internal cavity that carries a strong negative electrostatic potential and is large enough to accommodate peptides adjacent to the enzyme''s active site. This model can readily account for the strong preference for positively charged side chains.

Conclusions/Significance

To our knowledge no other aminopeptidase has been described to have such strong preferences for internal residues so distal to the N-terminus. Overall, our findings indicate that the internal sequence of the peptide can affect its trimming by ERAP1 as much as the peptide''s length and C-terminus. We therefore propose that ERAP1 recognizes the full length of its peptide-substrate and not just the N- and C- termini. It is possible that ERAP1 trimming preferences influence the rate of generation and the composition of antigenic peptides in vivo.     

Proteolysis of ProPTHrP(1-141) by "prohormone thiol protease" at multibasic residues generates PTHrP-related peptides: implications for PTHrP peptide production in lung cancer cells

The parathyroid hormone-related protein (PTHrP) precursor requires proteolytic processing to generate PTHrP-related peptide products that possess regulatory functions in the control of PTH-like (parathyroid-like) actions and cell growth, calcium transport, and osteoclast activity. Biologically active peptide domains within the PTHrP precursor are typically flanked at their NH2- and COOH-termini by basic residue cleavage sites consisting of multibasic, dibasic, and monobasic residues. These basic residues are predicted to serve as proteolytic cleavage sites for converting the PTHrP precursor into active peptide products. The coexpression of the prohormone processing enzyme PTP ("prohormone thiol protease") in PTHrP-containing lung cancer cells, and the lack of PTP in cell lines that contain little PTHrP, implicate PTP as a candidate processing enzyme for proPTHrP. Therefore, in this study, PTP cleavage of recombinant proPTHrP(1-141) precursor was evaluated by MALDI mass spectrometry to identify peptide products and cleavage sites. PTP cleaved the PTHrP precursor at the predicted basic residue cleavage sites to generate biologically active PTHrP-related peptides that correspond to the NH2-terminal domain (residues 1-37) that possesses PTH-like and growth regulatory activities, the mid-region domain (residues 38-93) that regulates calcium transport, and the COOH-terminal domain (residues 102-141) that modulates osteoclast activity. Lack of cleavage at other types of amino acids demonstrated the specificity of PTP processing at basic residue cleavage sites. Overall, these results demonstrate the ability of PTP to cleave the PTHrP precursor at multibasic, dibasic, and monobasic residue cleavage sites to generate active PTHrP-related peptides. The presence of PTP immunoreactivity in PTHrP-containing lung cancer cells suggests PTP as a candidate processing enzyme for the PTHrP precursor.     

Quantitation of the endopeptidase activity generating gamma-endorphin from beta-endorphin in rat brain synaptic membranes by a radiometric assay

gamma-Endorphin is a naturally occurring biologically active peptide that is produced by an endopeptidase activity cleaving its precursor beta-endorphin. This enzyme was termed gamma-endorphin generating enzyme (gamma-EGE). In order to quantitate gamma-EGE activity by means of a simple and sensitive assay two synthetic peptides derived from the sequence surrounding the gamma-EGE cleavage site in beta-endorphin were tested as substrates. One of these peptides Ac-Val-Thr-Leu-Phe-Lys-NHCH3 fulfilled all criteria for a suitable gamma-EGE substrate. The peptide was exclusively cleaved at the correct bond for gamma-EGE upon incubation with brain synaptic membranes, and this cleavage was inhibited by the naturally occurring substrate beta-endorphin. The peptide was insensitive to cleavage by exopeptidases and cathepsin D. Addition of a 14C-labeled methyl group at the lysine residue of this peptide by reductive methylation did not alter its properties as a substrate for gamma-EGE activity. The use of the 14C-labeled peptide allowed sensitive quantitation of its radioactive products after simple separation by hydrophobic chromatography on minicolumns containing polystyrene beads. gamma-EGE activity increased linearly with a protein concentration and incubation time. This assay can be used for reliable quantitation of gamma-EGE activity and permits investigations on the regulation of gamma-endorphin production.     

Modulation of the chymotrypsin-like activity of the 20S proteasome by intracellular redox status: effects of glutathione peroxidase-1 overexpression and antioxidant drugs

ATP- and ubiquitin-independent proteolysis by the 20S proteasome is responsible for the selective degradation of oxidized proteins. In vitro, the 20S proteasome shows an increased proteolytic activity toward oxidized polypeptides and the suc-LLVY-MCA peptide specific for its chymotrypsin-like activity. We have analyzed the effect of the intracellular redox status on the chymotrypsin-like activity of the 20S proteasome in human T47D cells overexpressing the detoxifiant enzyme seleno-glutathione peroxidase-1 (GPx-1). We report a 30% decreased activity of the chymotrypsin-like activity in cells overexpressing GPx-1. This phenomenon correlated with a 2-fold increase in IkappaB alpha half-life, a protein whose basal turnover is 20S proteasome-dependent. Following exposure to H2O2, these cells showed a seleno-dependently decreased accumulation of intracellular reactive oxygen species and 20S proteasome chymotrypsin-like activity. Similar results were obtained in HeLa cells transiently overexpressing human GPx-1. Moreover, exposure of HeLa cells to antioxidant compounds reduced the proteasome 20S chymotrypsin-like activity. In contrast, no effects were observed when HeLa cell extracts used to determine proteasome activity were incubated with either reduced or oxidized glutathione. These results suggest that GPx-1 activity or pro-reducing conditions can downregulate basal 20S proteasome activity. Hence, the intracellular redox status, probably through the level of oxidized proteins, is an important element that can either activate or down-regulate the 20S proteasome chymotrypsin-like activity in living cells.     

Peptidomic analysis of HEK293T cells: effect of the proteasome inhibitor epoxomicin on intracellular peptides

Peptides derived from cytosolic, mitochondrial, and nuclear proteins have been detected in extracts of animal tissues and cell lines. To test whether the proteasome is involved in their formation, HEK293T cells were treated with epoxomicin (0.2 or 2 μM) for 1 h and quantitative peptidomics analysis was performed. Altogether, 147 unique peptides were identified by mass spectrometry sequence analysis. Epoxomicin treatment decreased the levels of the majority of intracellular peptides, consistent with inhibition of the proteasome beta-2 and beta-5 subunits. Treatment with the higher concentration of epoxomicin elevated the levels of some peptides. Most of the elevated peptides resulted from cleavages at acidic residues, suggesting that epoxomicin increased the processing of proteins through the beta-1 subunit. Interestingly, some of the peptides that were elevated by the epoxomicin treatment had hydrophobic residues in P1 cleavage sites. Taken together, these findings suggest that, while the proteasome is the major source of intracellular peptides, other peptide-generating mechanisms exist. Because intracellular peptides are likely to perform intracellular functions, studies using proteasome inhibitors need to be interpreted with caution, as it is possible that the effects of these inhibitors are due to a change in the peptide levels rather than inhibition of protein degradation.     

Release of signal peptide fragments into the cytosol requires cleavage in the transmembrane region by a protease activity that is specifically blocked by a novel cysteine protease inhibitor

Signal peptides of secretory and membrane proteins are generated by proteolytic processing of precursor proteins after insertion into the endoplasmic reticulum membrane. Liberated signal peptides can be further processed, and the resulting N-terminal fragments are released toward the cytosol, where they may interact with target proteins like calmodulin. We show here that the processing of signal peptides requires a protease activity distinct from signal peptidase. This activity is inhibited specifically with a newly developed cysteine protease inhibitor, 1, 3-di-(N-carboxybenzoyl-l-leucyl-l-leucyl)amino acetone ((Z-LL)(2) ketone). Inhibitor studies revealed that the final, (Z-LL)(2) ketone-sensitive cleavage event occurs within the hydrophobic transmembrane region of the signal peptide, thus promoting the release of an N-terminal fragment into the cytosol.     

Selective activation of the 20 S proteasome (multicatalytic proteinase complex) by histone h3.

Two distinct activities cleaving bonds after hydrophobic amino acids have been identified in the bovine pituitary 20 S proteasome. One, expressed by the X subunit, that cleaves bonds after aromatic and branched chain amino acids was designated as chymotrypsin-like (ChT-L).(1) The second, expressed by the Y subunit, that cleaves bonds after acidic amino acids was designated as peptidylglutamyl-peptide hydrolyzing (PGPH) but also cleaves bonds after branched chain amino acids. Low micromolar concentrations of the arginine-rich histone H3 (H3) are shown to induce changes in the specificity of the proteasome by selectively activating cleavages after branched chain and acidic amino acids while inhibiting cleavage of peptidyl-arylamide bonds in synthetic substrates. H3 activates 15-fold cleavage after leucine but not phenylalanine residues in model synthetic substrates. The activation is associated with a decrease in K(m) and an increase in V(max), suggesting positive allosteric activation. H3 activates more than 60-fold degradation of the oxidized B-chain of insulin, by cleaving mainly bonds after acidic and branched chain amino acids, and accelerates the degradation of casein and lysozyme, the latter in the presence of dithiothreitol. The degradation of lysozyme in the presence of H3 generates fragments that differ from those in its absence, indicating H3-induced specificity changes. H3 inhibits cleavage of the Trp3-Ser4 and Tyr5-Gly6 bonds in gonadotropin releasing hormone, bonds cleaved by the ChT-L activity in the absence of H3. The results suggest H3-selective activation of the Y subunit and specificity changes that could potentially affect proteasomal function in the nuclear compartment.     

Enhancement of protein translocation across the membrane by specific mutations in the hydrophobic region of the signal peptide.

The hydrophobic region of the signal peptide of the OmpA protein of the Escherichia coli outer membrane was extensively altered in its hydrophobicity and predicted secondary structure by site-specific mutagenesis. The mutated signal peptides were fused to nuclease A from Staphylococcus aureus, and the function of the signal peptide was examined by measuring the rate of processing of the signal peptide. Six of the 12 mutated signal peptides in the nuclease hybrid were processed faster than the wild-type. In particular, the processing of the mutated signal peptide in which the alanine residue at position 9 was substituted with a valine residue was enhanced almost twofold over the processing of the wild-type signal peptide. In addition, the production of nuclease A fused with this mutated signal peptide also increased twofold. However, these effects were not observed when the mutated signal peptide was fused to TEM beta-lactamase. Analysis of the present mutations suggests that both overall hydrophobicity and distinct structural requirements in the hydrophobic region have important roles in signal peptide function.     

3,4-dichloroisocoumarin-induced activation of the degradation of beta-casein by the bovine pituitary multicatalytic proteinase complex.

The breakdown of beta-casein (caseinolytic activity) by the bovine pituitary multicatalytic proteinase complex (MPC) is initiated by a fourth active site different from the previously described chymotrypsin-like activity (cleavage of Cbz-Gly-Gly-Leu-p-nitroanilide, where Cbz is benzyloxycarbonyl), trypsin-like activity (cleavage of Cbz-D-Ala-Leu-Arg-2-naphthylamide), and peptidylglutamyl peptide bond-hydrolyzing (PGP) activity (cleavage of Cbz-Leu-Leu-Glu-2-naphthylamide) (Yu, B., Pereira, M. E., and Wilk, S. (1991) J. Biol. Chem. 266, 17396-17400). 3,4-Dichloroisocoumarin, a serine proteinase inhibitor, stimulated the caseinolytic activity of bovine pituitary or lens MPC, 3-18-fold under conditions under which the other three catalytic activities were inactivated. Addition of hydroxylamine to the modified enzyme did not reverse the effects of the inhibitor. A form of the proteinase exhibiting only 2-4% of control chymotrypsin-like, trypsin-like, and PGP activities degraded beta-casein with no accumulation of intermediate peptides. 3,4-Dichloroisocoumarin, by reacting with the chymotrypsin-like, trypsin-like, and/or PGP-active sites, may promote a conformational change of MPC, rendering the caseinolytic active site accessible to the substrate. Once bound to the active site, beta-casein is rapidly degraded either by the caseinolytic component itself or by a cooperative interaction with catalytic centers that are not affected by the serine proteinase inhibitor. These results imply that the caseinolytic component does not belong to the class of serine proteinases. Other proteins tested were not degraded by the 3,4-dichloroisocoumarin-treated enzyme, suggesting that the conformation of beta-casein may be more adequate for degradation by the caseinolytic component.     

Suppression of the Macrophage Proteasome by Ethanol Impairs MHC Class I Antigen Processing and Presentation

Alcohol binge-drinking (acute ethanol consumption) is immunosuppressive and alters both the innate and adaptive arms of the immune system. Antigen presentation by macrophages (and other antigen presenting cells) represents an important function of the innate immune system that, in part, determines the outcome of the host immune response. Ethanol has been shown to suppress antigen presentation in antigen presenting cells though mechanisms of this impairment are not well understood. The constitutive and immunoproteasomes are important components of the cellular proteolytic machinery responsible for the initial steps critical to the generation of MHC Class I peptides for antigen presentation. In this study, we used an in-vitro cell culture model of acute alcohol exposure to study the effect of ethanol on the proteasome function in RAW 264.7 cells. Additionally, primary murine peritoneal macrophages obtained by peritoneal lavage from C57BL/6 mice were used to confirm our cell culture findings. We demonstrate that ethanol impairs proteasome function in peritoneal macrophages through suppression of chymotrypsin-like (Cht-L) proteasome activity as well as composition of the immunoproteasome subunit LMP7. Using primary murine peritoneal macrophages, we have further demonstrated that, ethanol-induced impairment of the proteasome function suppresses processing of antigenic proteins and peptides by the macrophage and in turn suppresses the presentation of these antigens to cells of adaptive immunity. The results of this study provide an important mechanism to explain the immunosuppressive effects of acute ethanol exposure.