Purification of a liver alkaline protease which degrades oxidatively modified glutamine synthetase. Characterization as a high molecular weight cysteine proteinase

A proteasome-related gene between the two ABC transporter loci in the class II region of the human MHC

It is now possible to paint a detailed picture of how cytoplasmic proteins are handled by the immune system. They are apparently degraded in the cytoplasm into peptides. These are then transported into the endoplasmic reticulum where they encounter class I major histocompatibility complex (MHC) molecules. Once loaded with peptide, the HLA molecules move through the Golgi apparatus to the cell membrane. Until recently, it had not been established how peptides without signal sequences cross the ER membrane. However, a number of papers have now described a pair of membrane transporter genes of the ABC (ATP-binding cassette) super-family which are attractive candidates for this function. Both transporter genes, which may encode two halves of a heterodimer, are situated in the class II region of the MHC. There is evidence that other putative components of the processing machinery, the LMPs (low molecular mass polypeptides), are also encoded in the MHC. Similarities between the properties of the LMPs and a large intracellular protease complex, called proteasome, have led to the suggestion that LMPs are involved in processing antigens. We have now identified a human gene with sequence homology to proteasome components. Remarkably, this gene maps between the two putative peptide transporter genes.

Conserved N-terminal sequences in homologous subunits of the multicatalytic proteinase complex (proteasome)

The bovine lens multicatalytic proteinase complex (MPC) (MW 700 kDa) comprises at least twelve subunits in the molecular mass range 22-35 kDa. Three of the subunits, L1 (27 kDa), L2 (24 kDa) and L3 (29 kDa), were purified by reverse phase HPLC. Their amino acid composition and N-terminal sequences indicate that they are not identical. L1 and L2 subunits show very high (greater than 90%) sequence homology with specific subunits of rat liver and human reticulocyte MPC and these are considered to be homologous components of the MPC which are highly conserved in evolution.

Proteasome (multicatalytic proteinase) of sea urchin sperm and its possible participation in the acrosome reaction

The egg jelly-induced acrosome reaction of the sea urchin, Strongylocentrotus intermedius, was inhibited by succinyl-Leu-Leu-Val-Tyr-4-methyl-coumaryl-7-amide (Suc-Leu-Leu-Val-Tyr-MCA), but not by Suc-Ala-Ala-Pro-Phe-MCA. The proteases with hydrolytic activity toward the former were purified from sperm extract by DEAE-Sephacel and hydroxylapatite chromatographies, Sephacryl S-300 gel filtration, and heparin-Sepharose CL-6B chromatography. Two types of protease were separated, and the molecular weights were estimated to be 65 and 700 kDa, respectively, by gel filtration. The former was accompanied by hydrolytic activity toward Suc-Ala-Ala-Pro-Phe-MCA, which was not hydrolyzed by the latter. Polyacrylamide gel electrophoresis of 700 kDa protease gave a single protein band under nondenaturing conditions and at least eight bands in the range of 22-33 kDa in the presence of sodium dodecyl sulfate (SDS). The substrate specificity and the inhibitor sensitivity of 700 kDa protease indicate that it contains two types of the activity, one is chymotrypsin-type and the other trypsin-type. The former activity was enhanced by poly-L-lysine or SDS. These properties of 700 kDa protease are similar to those of proteasomes (multicatalytic proteinases) isolated from various eukaryotic sources. We had previously shown that inhibitors of chymotrypsin-like proteases inhibit the increase of intracellular Ca2+ concentration by egg jelly, resulting in the inhibition of the acrosome reaction of St. intermedius (Matsumura and Aketa, Gamete Res 23:255-266, 1989). Bringing these findings together, we suggest that the chymotrypsin-like activity of sperm proteasome participates in the onset of the acrosome reaction of St. intermedius.

The major component of a large, intracellular proteinase accumulated by inhibitors is a complex of alpha 2-macroglobulin and thrombin

A large, intracellular proteinase accumulated by inhibitors (PABI) was found in cultured mammalian cells as a large, multicatalytic proteinase with a greatly elevated concentration in the presence of small peptide proteinase inhibitors (Tsuji and Kurachi (1989) J. Biol. Chem. 264, 16093). Electron microscopic analysis showed that the tertiary structure of PABI highly resembled that of alpha 2-macroglobulin complexed with a proteinase(s). Isolation of the anti-PABI cross-reacting material from calf serum added to the culture media of baby hamster kidney cells further supported that the primary component of PABI was alpha 2-macroglobulin. Immunoblot analyses and the substrate specificity of PABI indicated that the major proteinase component contained in PABI was thrombin. When alpha 2-macroglobulin was added to the PABI-depleted serum, a significant accumulation or a degradation of the intracellular alpha 2-macroglobulin was observed in the presence or absence of leupeptin, respectively. Similarly, when thrombin was added to the PABI-depleted fetal calf serum supplemented with fresh alpha 2-macroglobulin, a significant amount of intracellular thrombin was found only in the presence of leupeptin. These results indicate that the major component of the intracellular PABI molecules is a complex of alpha 2-macroglobulin with thrombin which is internalized from the culture media. Intracellular accumulation of PABI, therefore, is a phenomenon primarily relevant to the culture cells. Whether or not PABI is also generated in certain physiological or pathological conditions requires further study.

Covalent labelling of bovine lens multicatalytic proteinase complex with [3H]di-isopropyl fluorophosphate

Enzymatically active lens multicatalytic proteinase complex bound [3H]iPr2P-F after incubation for 3 hours at ambient temperature. Label was associated with the lowest molecular weight band (Mr 22,000) on sodium dodecyl sulfate polyacrylamide gels. This binding was inhibited by preincubation of the enzyme with the cysteine-directed reagent, p-chloromercuribenzoate, which inhibits all three hydrolytic activities of the enzyme. Leupeptin, which inhibits the arginyl-hydrolyzing component, but not the iPr2P-F-inhibitable leucyl-hydrolyzing component of the enzyme, does not inhibit [3H]iPr2P-F binding. These data suggest that the leucy-hydrolyzing component of the lens multicatalytic proteinase complex is localized to the 22,000 Mr subunit and is a member of the thiol-dependent subclass of serine proteinases.

Multicatalytic, high-Mr endopeptidase from postmortem human brain

The main high molecular weight (650K) multicatalytic endopeptidase has been purified from postmortem human cerebral cortex. As in other tissues and species, this enzyme is composed of several subunits of 24-31K and has three distinct catalytic activities, as shown by the hydrolysis of the fluorogenic tripeptide substrates glutaryl-Gly-Gly-Phe-7-amido-4-methylcoumarin, benzyloxycarboxyl-Gly-Gly-Arg-7-amido-4-methylcoumarin, and benzyloxycarboxyl-Leu-Leu-Glu-2-naphthylamide with hydrophobic (Phe), basic (Arg), and acidic (Glu) residues in the P1 position, respectively. These activities are distinguishable by their differential sensitivity to peptidase inhibitors. The enzyme hydrolysed neuropeptides at pH 7.4 at multiple sites with widely differing rates, ranging from 113 nmol/min/mg for substance-P, down to 2 nmol/min/mg for bradykinin. The enzyme also had proteinase activity as shown by the hydrolysis of casein. For the hydrolysis of the Tyr5-Gly6 bond in luteinizing hormone-releasing hormone, the Km was 0.95 mM and the specificity constant (kcat/Km) was 4.7 X 10(3) M-1 s-1. The bond specificity of the enzyme at neutral pH was determined by identifying the degradation products of 15 naturally occurring peptide sequences. The bonds most susceptible to hydrolysis had a hydrophobic residue at P1 and either a small (e.g., -Gly or -NH2) or hydrophobic residue at P'1. Hydrolysis of -Glu-X bonds (most notably in neuropeptide Y) and the Arg6-Arg7 bond in dynorphin peptides was also seen. Thus the three activities identified with fluorogenic substrates appear to be expressed against oligopeptides.

ATP-stimulated degradation of endogenous proteins in cell-free extracts of BHK 21/C13 fibroblasts. A key role for the proteinase, macropain, in the ubiquitin-dependent degradation of short-lived proteins

Baby hamster kidney (BHK) 21/C13 cell proteins, labeled with [35S]methionine, [14C]leucine or [3H]leucine in intact cells, were degraded in soluble, cell-free extracts by an ATP-stimulated process. The stimulatory effect of ATP appeared to require ATP hydrolysis and was mediated to a large extent by ubiquitin. Although the cell extracts contained endogenous ubiquitin, supplementation with exogenous ubiquitin increased ATP-dependent proteolysis by up to 2-fold. Furthermore, antibodies against the E1 ubiquitin conjugating enzyme specifically inhibited both conjugation of [125I]ubiquitin to endogenous proteins and ATP/ubiquitin-dependent proteolysis. Addition of purified E1 to antibody-treated extracts restored conjugation and proteolysis. Proteins containing the amino acid analogues canavanine and azatryptophan were also degraded in vitro by an ATP/ubiquitin-dependent process but at a rate up to 2-fold faster than normal proteins. These results indicate that soluble, cell-free extracts of BHK cells can selectively degrade proteins whose rates of degradation are increased in intact cells. Treatment of cell-free extracts with antibodies against the high molecular weight proteinase, macropain, also greatly inhibited the ATP/ubiquitin-dependent degradation of endogenous proteins. Proteolysis was specifically restored when purified macropain L was added to the antibody-treated extracts. Treatment of cell extracts with both anti-macropain and anti-E1 antibodies reduced ATP/ubiquitin-dependent proteolysis to the same extent as treatment with either antibody alone. Furthermore, proteolysis could be restored to the double antibody treated extracts only after addition of both purified E1 and macropain. These results provide strong evidence for an important role for macropain in the ATP/ubiquitin-dependent degradation of endogenous proteins in BHK cell extracts.

Phosphorylation of the multicatalytic proteinase complex from bovine pituitaries by a copurifying cAMP-dependent protein kinase

The multicatalytic proteinase complex (MPC) constitutes a major nonlysosomal proteolytic system that may play an important role in the processing of biologically active peptides and enzymes, as well as in intracellular metabolism. We report that at least two of its subunits of MW 28,800 (S2) and 27,000 (S3) are phosphorylated by a cAMP-dependent protein kinase (PK-A) that copurifies with the complex isolated from bovine pituitaries. The cAMP-induced phosphorylation was time dependent and inhibited by a PK-A inhibitor. Although not an integral part of the complex, PK-A activity was still present even in 1700-fold-purified and apparently homogeneous preparations by criteria of nondissociating polyacrylamide gel electrophoresis. Furthermore, we present evidence that the copurification of the two enzymes is not species or tissue specific, or dependent on a single method of purification. The copurifying kinase was stimulated 10-fold by cAMP (10 microM) and 2- to 3-fold by a peptide substrate of the MPC, but was unaffected by protein kinase C activators (calcium and a phospholipid mixture). These findings suggest that protein phosphorylation may represent a mechanism for regulating the activity of the multicatalytic proteinase complex.

Isolation of two high-molecular-mass proteinases from human erythrocytes

Two forms of a neutral--alkaline high-molecular-mass proteinase (termed A1 and A2) have been purified from human erythrocytes by a procedure including a DEAE-cellulose batchwise treatment of erythrocyte cytosol, gel filtration and DEAE-cellulose chromatography. Both enzymes show distinctive properties of multicatalytic proteinases. They have an apparent molecular mass of 700 kDa and are composed by eight major subunits (23-32 kDa). Both enzymes show a proteinase activity towards casein and hydrolyze synthetic peptides with tyrosine, arginine or lysine at the P1 position. Among the synthetic peptides tested, the tetrapeptide succinyl-leucyl-leucyl-valyl-tyrosyl-7-amido-4-methylcoumarin and tripeptides with arginine in the P1 position (benzyloxycarbonyl-valyl-leucyl-arginyl-4-methoxy-2-naphthylamide and benzyloxycarbonyl-alanyl-arginyl-arginyl-4-methoxy-2-naphthylamide) are the most effective substrates. The proteinases are devoid of amino and diaminopeptidase activity. Both enzymes are completely inhibited by hemin, chymostatin and thiol-group reagents. However, the enzymes can be distinguished by the isoelectric point, the different effect of nucleotides, glutathione disulphide, sodium dodecyl sulfate and cations on the catalytic activity.

The Drosophila PROS-28.1 gene is a member of the proteasome gene family

In the present communication, we report the identification of a new gene family which encodes the protein subunits of the proteasome. The proteasome is a high-Mr complex possessing proteolytic activity. Screening a Drosophila lambda gt11 cDNA expression library with the proteasome-specific antibody N19-28 we isolated a clone encoding the 28-kDa No. 1 proteasome protein subunit. In accordance with the nomenclature of proteasome subunits in Drosophila, the corresponding gene is designated PROS-28.1, and it encodes an mRNA of 1.1 kb with an open reading frame of 249 amino acids (aa). Genomic Southern-blot hybridization shows PROS-28.1 to be a member of a family of related genes. Analysis of the predicted aa sequence reveals a potential nuclear targeting signal, a potential site for tyrosine kinase and a potential cAMP/cGMP-dependent phosphorylation site. The aa sequence comparison of the products of PROS-28.1 and PROS-35 with the C2 proteasome subunit of rat shows a strong sequence similarity between the different proteasome subunits. The data suggest that at least a subset of the proteasome-encoding genes belongs to a family of related genes (PROS gene family) which may have evolved from a common ancestral PROS gene.

Metal-catalyzed oxidation of Escherichia coli glutamine synthetase: correlation of structural and functional changes

Metal-catalyzed oxidation of proteins has been implicated in a variety of biological processes, particularly in the marking of proteins for subsequent proteolytic degradation. The metal-catalyzed oxidation of bacterial glutamine synthetase causes conformational, covalent, and functional alterations in the protein. To understand the structural basis of the functional changes, the time course of oxidative modification of glutamine synthetase was studied utilizing a nonenzymic model oxidation system consisting of ascorbate, oxygen, and iron. The structural modifications induced included: decreased thermal stability; weakening of subunit interactions; decrease in isoelectric point; introduction of carbonyl groups into amino acid side chains; and loss of two histidine residues. These changes did not denature the protein, but instead induced relatively subtle changes. Indeed, even the most extensively modified protein had a sedimentation velocity which was identical to that of the native enzyme. Comparison of the time courses of the structural and functional changes established that: (i) Loss of the metal binding site and of catalytic activity occurred with loss of one histidine per subunit; (ii) increased susceptibility to proteolysis occurred with loss of two histidine residues per subunit. Thus, oxidation at one site suffices to inactivate the enzyme, but two sites must be modified to induce susceptibility to proteolysis. The limited and specific changes induced by metal-catalyzed oxidation are consistent with a site-specific free radical mechanism.

Lens proteasome shows enhanced rates of degradation of hydroxyl radical modified alpha-crystallin

Proteasome, a high molecular weight protease complex (HMP, approximately 600 kDa) was isolated from bovine eye lens epithelium tissue. In contrast with prior reports, lens proteasome degraded the major lens protein alpha-crystallin and S-carboxymethylated bovine serum albumin at 37 degrees C, mostly to trichloroacetic acid precipitable polypeptides. The proteasome, thus isolated, was labile at 55 degrees C. As indicated by the ability of p-chloromercuribenzoate and N-ethylmaleimide to block activity, a thiol group is required for activity. Alpha-crystallin was oxidized by exposure to 60Co-irradiation under an atmosphere of N2O (1-50 kilorads). This dose delivered 0.1-5.7 mol of hydroxyl radicals per mol of crystallin. Irradiation resulted in increased heterogeneity, aggregation, and fragmentation of the crystallin preparation. The proteolytic susceptibility of alpha-crystallin to the lens HMP was enhanced by the irradiation in a dose-dependent manner up to 20 kilorads (.OH concentration up to 2.3 mol per mol of alpha-crystallin). When 50 kilorads (5.7 mol .OH per mol of alpha-crystallin) was used, there was extensive aggregation and no enhancement in proteolysis over the unirradiated sample. The data indicate that the lens HMP can degrade mildly photooxidized lens proteins, but proteins which are extensively damaged are not degraded and may accumulate. This may be related to cataract formation.

Metal ion-catalyzed oxidation of proteins: biochemical mechanism and biological consequences

In the presence of O2, Fe(III) or Cu(II), and an appropriate electron donor, a number of enzymic and nonenzymic oxygen free radical-generating systems are able to catalyze the oxidative modification of proteins. Whereas random, global modification of many different amino acid residues and extensive fragmentation occurs when proteins are exposed to oxygen radicals produced by high energy radiation, only one or a few amino acid residues are modified and relatively little peptide bond cleavage occurs when proteins are exposed to metal-catalyzed oxidation (MCO) systems. The available evidence indicates that the MCO systems catalyze the reduction of Fe(III) to Fe(II) and of O2 to H2O2 and that these products react at metal-binding sites on the protein to produce active oxygen (free radical?) species (viz; OH, ferryl ion) which attack the side chains of amino acid residues at the metal-binding site. Among other modifications, carbonyl derivatives of some amino acid residues are formed; prolyl and arginyl residues are converted to glutamylsemialdehyde residues, lysyl residues are likely converted to 2-amino-adipylsemialdehyde residues; histidyl residues are converted to asparagine and/or aspartyl residues; prolyl residues are converted to glutamyl or pyroglutamyl residues; methionyl residues are converted to methionylsulfoxide residues; and cysteinyl residues to mixed-disulfide derivatives. The biological significance of these metal ion-catalyzed reactions is highlighted by the demonstration: (i) that oxidative modification of proteins "marks" them for degradation by most common proteases and especially by the cytosolic multicatalytic proteinase from mammalian cells; (ii) protein oxidation contributes substantially to the intracellular pool of catalytically inactive and less active, thermolabile forms of enzymes which accumulate in cells during aging, oxidative stress, and in various pathological states, including premature aging diseases (progeria, Werner's syndrome), muscular dystrophy, rheumatoid arthritis, cataractogenesis, chronic alcohol toxicity, pulmonary emphysema, and during tissue injury provoked by ischemia-reperfusion. Furthermore, the metal ion-catalyzed protein oxidation is the basis of biological mechanisms for regulating changes in enzyme levels in response to shifts from anaerobic to aerobic metabolism, and probably from one nutritional state to another. It is also involved in the killing of bacteria by neutrophils and in the loss of neutrophil function following repeated cycles of respiratory burst activity.

Protein oxidation and proteolysis during aging and oxidative stress

Previous studies in this laboratory have shown that glutamine synthetase (GS) and other key metabolic enzymes are inactivated by metal-catalyzed oxidation reactions in vitro. Oxidative inactivation renders these proteins highly susceptible to proteolysis, especially to a class of newly identified alkaline proteases which exhibit little or no activity against the native enzymes. These studies have suggested that oxidative inactivation may be an important marking step for intracellular protein degradation. Because many of the enzymes which have been shown to accumulate as inactive or less active forms during aging are readily inactivated by metal-catalyzed oxidation reactions in vitro, we have investigated the possible relationship between protein oxidation and proteolysis during aging and oxidative stress in vivo. Oxidized proteins accumulate in hepatocytes of rats exposed to 100% oxygen during the first 48 h of oxygen treatment. In the interval between 48 and 54 h the levels of oxidized proteins decline sharply. The specific activities of at least two liver enzymes, glutamine synthetase and glucose-6-phosphate dehydrogenase (G-6-PDH), decrease during the 54-h experiment. GS and G-6-PDH specific immunological cross-reactivity remains high during the first 48 h of oxygen treatment and then declines in the interval between 48 and 54 h. During this same interval the levels of alkaline proteases which degrade oxidized proteins increase, indicating that these activities are induced or activated in response to oxidative stress and subsequently degrade the proteins which have become oxidized during the initial phase of oxygen treatment. Oxidized proteins accumulate progressively during aging in hepatocytes from rats 3 to 26 months old, with the largest incremental increase between 20 and 26 months. The increase in protein oxidation is correlated with a loss of specific activity of GS and G-6-PDH without a concomitant loss of immunological cross-reactivity. The levels of alkaline proteases which degrade oxidized proteins in hepatocytes from 26-month-old rats is only 20% that of 3-month-old rats, suggesting that oxidized proteins accumulate in hepatocytes from old rats, in part, because the proteases which degrade them are deficient or defective. moreover, when old rats are subjected to treatment with 100% oxygen, the levels of oxidized proteins continue to increase and the alkaline protease activity remains low, indicating that these protease activities are not increased in response to oxidative stress in old rats.

Oxidation of Neurospora crassa NADP-specific glutamate dehydrogenase by activated oxygen species

The glutamine synthetase and the NADP-specific glutamate dehydrogenase activities of Neurospora crassa were lost in a culture without carbon source only when in the presence of air. Glutamine synthetase was previously reported to be liable to in vitro and in vivo inactivation by activated oxygen species. Here we report that NADP-specific glutamate dehydrogenase was remarkably stable in the presence of activated oxygen species but was rendered susceptible to oxidative inactivation when chelated iron was bound to the enzyme and either ascorbate or H2O2 reacted on the bound iron. This reaction gave rise to further modifications of the enzyme monomers by activated oxygen species, to partial dissociation of the oligomeric structure, and to precipitation and fragmentation of the enzyme. The in vitro oxidation reaction was affected by pH, temperature, and binding to the enzyme of NADPH. Heterogeneity in total charge was observed in the purified and immunoprecipitated enzymes, and the relative amounts of enzyme monomers with different isoelectric points changes with time of the oxidizing reaction.

Purification and characterization of a multicatalytic proteinase from crustacean muscle: comparison of latent and heat-activated forms

A high-molecular-weight (Mr 740,000) multicatalytic proteinase (MCP) was purified over 3100-fold from soluble extracts of lobster claw and abdominal muscles. The enzyme was extracted from muscle in a latent state; brief (3 min) heating of an ammonium sulfate fraction (45-65% saturation) at 60 degrees C irreversibly activated the proteinase while denaturing about 55% of the protein. MCP was further purified by chromatography on two sequential arginine-Sepharose columns and a Mono Q column with a yield of 60%. About 1.12 mg MCP was obtained for every 100 g tissue. In addition to [14C]methylcasein, the MCP hydrolyzed synthetic peptide substrates of trypsin and chymotrypsin at pH 7.75. Serine protease inhibitors (diisopropyl fluorophosphate, phenylmethanesulfonyl fluoride, aprotinin, benzamidine, soybean trypsin inhibitor, chloromethyl ketones), leupeptin, antipain, hemin, sulfhydryl-blocking reagents (N-ethylmaleimide, mersalyl acid, p-chloromercurisulfonic acid, iodoacetamide) suppressed activity while Ep-475, a specific inhibitor of cysteine proteinases, had no effect, suggesting the MCP is a serine proteinase with one or more cysteine residues indirectly involved in catalysis. The latent MCP was purified using the same procedure as that for the active form, except that thermal activation was omitted. The elution characteristics of latent MCP from the arginine-Sepharose and Mono Q columns were identical to those of active MCP. Since the purified latent form could still be activated by heating, activation did not involve denaturation of an endogenous inhibitor or substrate. Subunit compositions of both forms were identical in two-dimensional polyacrylamide gels; each was composed of eight polypeptides with molecular weights between 25,000 and 32,500 and a ninth polypeptide with a molecular weight of 41,000. Electron microscopy of negatively stained material showed that each form was a cylinder-shaped particle (approximately 10 x 15 nm) consisting of a stack of four rings with a hollow center; no differences in shape, dimensions, or submolecular structure were observed. These results suggest that activation probably involved small conformational changes rather than covalent modifications or rearrangement of subunits within the complex.

The high molecular weight multicatalytic proteinase, macropain, exists in a latent form in human erythrocytes

The high molecular weight multicatalytic proteinase, macropain, has been purified from human erythrocytes in two forms that differ in caseinolytic activity up to 100-fold. Each form has a native molecular weight of 600,000 and is composed of a number of subunits ranging in molecular weights from 35,000 to 21,000. Although the two proteinase forms share a number of electrophoretically indistinguishable subunits, there are also subunits unique to the respective forms. The less active proteinase represents a latent enzyme because it was fully activated by two procedures including dialysis against water and pretreatment with low concentrations of sodium dodecyl sulfate. These procedures caused differential changes in the caseinolytic and two peptidase activities of the proteinase. An Mr 35,000 subunit, characteristic of latent macropain, is immunologically related to at least one of the other components of active macropain and disappeared after proteinase activation by dialysis. Nevertheless, loss of this subunit was not the cause of the increased activity. These results suggest that the proteolytic activity of cells may be regulated by the activation of the latent form of macropain.

Direct evidence for nuclear and cytoplasmic colocalization of proteasomes (multiprotease complexes) in liver

Subcellular localization of the large multicatalytic protease complexes called proteasomes, which have been found in soluble fractions of various cells, was examined by biochemical, immunological, and immunohistological methods. Rat liver nuclei, purified by two different procedures, showed high activities for degrading [3H]methylcasein and various fluorogenic oligopeptides with neutral and weakly alkaline pH optima. On gel filtration, all of these peptidase activities were recovered in a single peak with the unusually large molecular weight of about 600,000. Properties of the proteolytic activity in crude extracts of the nucleus and the cytoplasm were very similar. Immunoelectrophoretic blot analysis showed the presence of appreciable concentrations of proteasomes with similar immunoreactivity in isolated nuclear and cytosolic fractions. Moreover, immunohistochemical staining of human liver showed that proteasomes were predominantly localized in the nuclear matrix but also were present diffusely in the cytoplasm of hepatocytes. These findings indicate the nuclear and cytoplasmic colocalization of proteasomes.

Half-life of proteasomes (multiprotease complexes) in rat liver

Proteasomes (large multicatalytic proteinase complexes) are abundant in rat liver, constituting approximately 1.0% of the total soluble proteins. In the present study, the apparent half-life of the proteasomes was determined to be 12-15 days from the decay curve of isotopically labeled enzymes in vivo, suggesting their slow turnover. This finding together with the ubiquitous distribution of proteasomes in eukaryotic cells (Tanaka et al., 1988 J. Biol. Chem. 263, 16209-16217) indicates that proteasomes belong to a family of proteins with house-keeping function.

Autodegradation of rat liver proteasomes (large multicatalytic proteinase complexes)

Purified proteasomes (large multicatalytic proteinase complexes) were found to be very stable, showing no change in activities or structures during prolonged incubation in medium of pH 7.5 at 37 degrees C. However, on addition of urea they were degraded autocatalytically in a time- and dose-dependent manner, suggesting that destruction of the proteasomal complexes acts as a signal for their autolysis. ATP at a physiological concentration greatly stimulated the urea-dependent breakdown of proteasomes. The autolysis induced by urea was almost completely inhibited by hemin, but not by other protease inhibitors tested, such as leupeptin, chymostation and Ep-475. Thus, autolytic degradation of proteasomes appears to be important for the regulation of enzyme levels in eukaryotic cells.

Macroxyproteinase (M.O.P.): a 670 kDa proteinase complex that degrades oxidatively denatured proteins in red blood cells

Erythrocytes and reticulocytes are shown to undergo rapid rates of protein degradation following exposure to oxidative stress. Experiments with ATP depletion revealed that, unlike the proteolysis of many other abnormal proteins, the degradation of oxidatively modified proteins is an ATP-independent process. Ion exchange chromatography (DEAE Sepharose CL-6B), ammonium sulfate precipitation, gel filtration chromatography (Sephacryl S-300 or Sepharose CL-6B), and a second ion exchange step were used to resolve the activity responsible for degrading oxidatively modified proteins from (dialyzed) cell-free extracts of erythrocytes and reticulocytes. Gel filtration studies revealed that some 70-80% of the activity in erythrocytes, and some 60-70% of the activity in reticulocytes, is expressed by a 670 kDa proteinase complex that is not stimulated by ATP (in fact, ATP is slightly inhibitory). This proteinase complex is inhibited by sulfhydryl reagents, serine reagents, and transition metal chelators, and has a pH optimum of 7.8. We propose the trivial name "macroxyproteinase" or "M.O.P." (abbreviated from Macro-Oxy-Proteinase) for the complex because of its large size, substrate preference (oxidatively modified proteins), and inhibitor profile (which indicates multiple catalytic sites). Electrophoresis studies of the 670 kDa M.O.P. complex revealed the presence of 8 distinct polypeptide subunits with the following apparent molecular sizes: 21.5, 25.3, 26.2, 28.1, 30.0, 31.9, 33.3, and 35.7 kDa. The large molecular size of the M.O.P. complex, its ATP- and ubiquitin-independence, its inhibitor profile, its distinctive subunit banding pattern in denaturing electrophoresis gels, its pH optimum, and its proteolytic profile with fluorogenic peptide substrates all indicate that M.O.P. is identical to 600-700 kDa neutral/alkaline proteinase complexes that have been isolated from a wide variety of eucaryotic cells and tissues, but for which no function has previously been clear. We propose that macroxyproteinase is responsible for catalyzing most of the selective degradation of oxidatively denatured proteins in red blood cells. We further suggest that M.O.P. may perform the same function in other eucaryotic cells and tissues.

Substrate inactivation of enzymes in vitro and in vivo

Some enzymes are inactivated by their natural substrates during catalytic turnover, limiting the ultimate extent of reaction. These enzymes can be separated into three broad classes, depending on the mechanism of the inactivation process. The first type is enzymes which use molecular oxygen as a substrate. The second type is inactivated by hydrogen peroxide, which is present either as a substrate or a product, and are stabilized by high catalase activity. The oxidation of both types of enzymes shares common features with oxidation of other enzymes and proteins. The third type of enzyme is inactivated by non-oxidative processes, mainly reversible loss of cofactors or attached groups. Sub classes are defined within each broad classification based on kinetics and stoichiometry. Reaction-inactivation is in part a regulatory mechanism in vivo, because specific proteolytic systems give rapid turnover of such labelled enzymes. The methods for enhancing the stability of these enzymes under reaction conditions depends on the enzyme type. The kinetics of these inactivation reactions can be used to optimize bioreactor design and operation.

The multicatalytic proteinase of mammalian cells

A high-molecular-weight nonlysosomal proteinase has recently been discovered in mammalian cells. It is a widely distributed and abundant enzyme which has attracted attention because of its complex multisubunit structure and its unusual catalytic properties. The 700-kDa proteinase is composed of many different types of low-molecular-weight subunits (Mr 21,000-34,000) arranged in a hollow cylindrical structure. This 20 S complex is very similar, if not identical, to the 19-20 S cylindrical particles, ring-type particles, or prosomes which have been isolated from several different types of eukaryotic cells. The proteinase appears to have at least two distinct catalytic sites and can cleave bonds on the carboxyl side of basic, hydrophobic, or acidic amino acid residues. Inhibition of proteinase activity by thiol reagents supports the suggestion that the enzyme is a cysteine proteinase but there is some evidence that it may be a serine proteinase and the catalytic mechanism is at present unknown. ATP has little effect on proteinase activity in most purified preparations but recently the proteinase has been implicated in ATP-dependent pathways of protein degradation. Ther is a second type of high-molecular-weight complex multisubunit proteinase, a 26 S particle, which catalyzes the ATP-dependent degradation of ubiquitin-protein conjugates. The precise function of these two complex proteinases in intracellular proteolysis remains to be elucidated.

Multicatalytic proteinase in fish muscle

Proteinase II, a high-molecular-mass proteinase previously identified in white croaker skeletal muscle, was purified to apparent homogeneity by DEAE-Sephacel, phenyl-Sepharose CL 4B, and Sephacryl S-300 chromatographies. Under denaturing conditions, the enzyme dissociated into a cluster of subunits with Mr ranging from 18,000 to 26,000 and a large subunit with a Mr 60,000. The proteinase was able to hydrolyze N-terminal-blocked 4-methyl-7-coumarylamide substrates having either an aromatic amino acid (chymotrypsin-like activity) or an arginine residue (trypsin-like activity) adjacent to the fluorogenic group. The trypsin-like activity of the enzyme was inhibited by fatty acids and sodium dodecyl sulfate, whereas the chymotrypsin-like activity was stimulated by those compounds but inhibited by nonionic and cationic detergents. Several thiol reagents inhibited both proteinase II activities. However, leupeptin and Cu2+ strongly inhibited its trypsin-like activity but only slightly affected its chymotrypsin-like activity. Dithiothreitol stimulated both activities, but at different extents and in different concentration ranges. These results suggest that the enzyme is multicatalytic, having at least two different active sites.

An enzyme related to the high molecular weight multicatalytic proteinase, macropain, participates in a ubiquitin-mediated, ATP-stimulated proteolytic pathway in soluble extracts of BHK 21/C13 fibroblasts

Soluble, cell-free extracts of BHK 21/C13 fibroblasts degraded a variety of exogenous proteins to acid-soluble peptides at pH 8.0. ATP stimulated the rates of proteolysis. Both the absolute rate of proteolysis and the magnitude of the ATP effect depended on the specific substrate. For example, casein was degraded approximately 10-fold faster than lysozyme, but lysozyme degradation was more highly stimulated by ATP than was casein degradation. Ubiquitin enhanced the ATP-stimulated proteolysis of each substrate in both postmicrosomal extracts and DEAE-cellulose fractionated extracts. In each extract, ubiquitin enhanced the ATP-stimulated degradation of lysozyme to a greater degree than that of casein. These results suggested that lysozyme was degraded by a pathway that was more dependent upon ubiquitin than was casein. Further evidence for this conclusion was obtained in studies using substrates whose amino groups were blocked by extensive methylation or carbamoylation. The high molecular weight proteinase, macropain, appears to be involved in the ATP-stimulated degradation of both substrates. Specific immunoprecipitation of macropain with polyclonal antibodies resulted in the inhibition of ATP-stimulated proteinase activity both in the absence and presence of ubiquitin. These results indicate that macropain plays a role in both ubiquitin-mediated and ubiquitin-independent ATP-stimulated proteolysis in BHK cell extracts.

Proteinase yscE of yeast shows homology with the 20 S cylinder particles of Xenopus laevis

Proteinase yscE of the yeast Saccharomyces cerevisiae has been compared with the 20 S cylinder particles of Xenopus laevis. Both proteins are characterized by a similar group of 10-12 polypeptides with molecular masses ranging between 21 and 38 kDa. Antibodies generated against the 20 S Xenopus cylinder particles show cross-reactivity with yeast proteinase yscE subunits. The Xenopus particles and yeast proteinase yscE exhibit an identical image in electron microscopy. Both proteins appear as hollow cylinders mostly composed of four stacked annuli. The Xenopus 20 S particles exhibit proteolytic activity against the three peptide derivatives known to be substrates of proteinase yscE. The pH optimum for activity and the inhibition spectrum of the proteolytic activities of Xenopus 20 S particles and of yeast proteinase yscE are identical. The RNA content of the cylinder particles and of proteinase yscE is below 0.1 RNA chain per molecule. Our data suggest that proteinase yscE from yeast and the 20 S cylinder particles of X. laevis are homologous, highly conserved proteins carrying the catalytic character of a peptidase.

Molecular organization of a high molecular weight multi-protease complex from rat liver

A latent multifunctional protease with a molecular weight of 722,000 to 760,000 purified from rat liver cytosol has been reported. This paper reports on the structure and subunit composition of the enzyme. Electron microscopy showed that the enzyme was a ring-shaped particle of 160(+/- 7) A diameter and 110(+/- 10) A height with a small hole of 10 to 30 A diameter (1 A = 0.1 nm). Small-angle X-ray scattering analysis indicated that the enzyme had a prolate ellipsoidal structure with an ellipsoid cavity in the center. The maximum dimension of the enzyme was estimated to be 210 A from a pair-distance distribution function. The radius of gyration obtained from a Guinier plot and the Stokes radius based on the ellipsoidal model were 66 A and 76 A, respectively. On two-dimensional gel electrophoresis, the purified enzyme separated into 13 to 15 characteristic components with molecular weights of 22,000 to 33,000 and isoelectric points of 4 to 9. These multiple components were not artifacts produced by limited proteolysis during purification of the enzyme, because the cell-free translation products in a reticulocyte lysate with poly(A)-mRNA of rat liver consisted of multiple components of similar sizes, and because peptide mapping analyses with lysylendopeptidase and V8 protease demonstrated clear differences in the primary structures of these components. The 13 main components were isolated from the purified enzyme by reverse-phase high performance liquid chromatography and shown to be non-identical. A model of the enzyme is proposed on the basis of these observations and previous physicochemical studies. Interestingly, the morphology of this protease is similar to that of the 16 to 22 S ring-shaped particles found in a variety of eukaryotic organisms. The structural similarity between this multi-protease complex and various reported subcellular particles is discussed.

Involvement of proteasomes (multicatalytic proteinase) in ATP-dependent proteolysis in rat reticulocyte extracts

The role of proteasomes, particles with latent multicatalytic proteinase, in ATP-dependent proteolysis in rat reticulocyte extracts was examined. Removal of proteasomes from the extracts by immunoprecipitation caused almost complete inhibition of ATP-dependent degradation of [3H]methylcasein, without affecting ATP-dependent proteolysis. Peptide fragments of [3H]casein, obtained by cyanogen bromide cleavage, were rapidly degraded in an ATP-independent fashion and this activity was not affected by removal of the proteasomes. These results suggest that proteasomes are involved in ATP-dependent proteolysis in the extracts and that they catalyze the initial cleavage of large proteins.

Characterization of hydrazine-stimulated proteolysis in human erythrocytes

The ability of hydrazine, acetylphenylhydrazine, methylhydrazine, and phenylhydrazine to stimulate proteolysis in red cells has been characterized. All four hydrazines effectively stimulated proteolysis in red cells and in hemolysate as evidenced by a two- to threefold increase in the rate of tyrosine release. The rate of tyrosine release varied linearly with time, increased with increasing concentration of hydrazine, and also increased as a function of hematocrit. The rank order for stimulation of proteolysis in red cells was phenylhydrazine greater than methylhydrazine greater than hydrazine approximately equal to acetylphenylhydrazine. Inhibitors of glycolysis in red cells only minimally (13-27%) decreased the rate of tyrosine release stimulated by the different hydrazines. Agents which diminished electron transport decreased the rate of tyrosine release. NADP inhibited the rate of tyrosine release stimulated by hydrazine, methylhydrazine, and acetylphenylhydrazine by approximately 36 to 41%; 2'-AMP was less effective. The rate of tyrosine release resulting from insult by the hydrazines was increased slightly by methylene blue, moderately inhibited (approximately 10 to 27%) by the chelator o-phenanthroline and inhibited approximately 30 to 40% by N-ethylmaleimide. Use of an oxygen-depleted atmosphere (N2) increased slightly the rate of tyrosine release stimulated by the hydrazines; in contrast, carbon monoxide decreased proteolysis stimulated by hydrazine, methylhydrazine, and acetylphenylhydrazine by approximately 50%. Although the antioxidants dimethylfuran, dimethylthiourea, and methylsulfoxide failed to diminish proteolysis stimulated by the hydrazines, N-acetylcysteine exerted a protective effect, decreasing hydrazine-stimulated tyrosine release in red cells approximately 30 to 50%. Inclusion of 3-amino-1,2,4-triazole in the incubation failed to increase further the rate of hydrazine-stimulated proteolysis. These data suggest that more reactive free radicals generated from the hydrazine are responsible for protein damage, that damaged protein (hemoglobin) is degraded via proteolysis, and that an ATP-independent process primarily participates in the degradation of abnormal proteins in the red cell. Thus, proteolytic enzymes present in the erythrocyte appear to exert a protective effect against cellular damage through the removal of abnormal proteins generated as a consequence of xenobiotic insult. The ability of proteolytic enzymes to recognize and degrade abnormal proteins may be of importance in using protein (hemoglobin)-xenobiotic adducts to assess exposure to toxic agents (risk assessment).

ATP-stimulated proteolysis in soluble extracts of BHK 21/C13 cells. Evidence for multiple pathways and a role for an enzyme related to the high-molecular-weight protease, macropain

Soluble extracts of cultured cells (BHK 21/C13) degraded a variety of exogenous proteins to acid-soluble peptides at pH 8.0. ATP stimulated this proteolytic activity up to 10-fold. The ATP effect was dependent on Mg2+ and was not elicited by nonhydrolyzable analogs of ATP. After the extract was fractionated on DEAE-cellulose, ATP-stimulated protease activity was in the fraction that bound to the resin and eluted in buffer containing 0.4 M NaCl. This activity had characteristics that were indistinguishable from those of the unfractionated extract but the degree of ATP stimulation was two- to three-fold lower. Although no protease activity was detected in the unbound fraction, reconstitution of this material with the bound fraction enhanced the ATP stimulation up to twofold. The component responsible for the enhancement of the ATP stimulation had properties similar to ubiquitin and purified ubiquitin enhanced the ATP-stimulated protease activity in the fractionated extract. Substrates whose amino groups were almost completely blocked by various chemical modifications were still degraded in an ATP-stimulated fashion, but the degradation of these substrates was not affected by ubiquitin. The protease activity isolated by ion-exchange chromatography was fractionated further by gel filtration chromatography on Sephacryl S-300. ATP-stimulated protease activity eluted with an apparent molecular weight of 750,000. Protease activity was enhanced up to eightfold by Mg2+-ATP but was not increased further by ubiquitin. An activity that hydrolyzed the synthetic peptide Z-Val-Leu-Arg-MNA coeluted with ATP-stimulated protease activity, but peptide hydrolysis was not affected by ATP. These and other catalytic and biochemical characteristics suggested that the protease might be related to the high-molecular-weight protease, macropain, recently purified by us from human erythrocytes (M. J. McGuire and G. N. DeMartino Biochim. Biophys. Acta (1986) 873, 279-289). Antibodies raised against macropain specifically reacted with proteins characteristic of macropain in the column fractions containing ATP-stimulated protease activity. These antibodies also specifically immunoprecipitated 70-100% of the ATP-stimulated protease activity as well as Z-Val-Leu-Arg-MNA hydrolyzing activity. Thus BHK cell extracts appear to contain both ubiquitin-mediated and ubiquitin-independent pathways for the ATP-stimulated degradation of proteins. Furthermore, at least one of these pathways appears to involve a high-molecular-weight, ATP-stimulated protease related to macropain.

Identity of the 19S 'prosome' particle with the large multifunctional protease complex of mammalian cells (the proteasome)

There have been many reports that eukaryotic cells contain ring-shaped 19S or 20S particles which are composed of numerous polypeptide subunits ranging in size between 25 and 35 kilodaltons. Because these particles seemed to copurify with inactive mRNA, they were assumed to function in regulating mRNA translation and hence were named 'prosomes' (for 'programmed-o-some'). A number of properties have been reported for these structures, including an association with specific RNA species or with certain heat-shock proteins and involvement in tRNA processing or aminoacyl tRNA synthesis. However, these proposed activities have not been supported by definitive evidence. During studies of the proteolytic systems in mammalian tissues, we noted many similarities between these 19S particles and the high molecular weight protease complexes that are present in most or all eukaryotic cells. This (700 kilodalton) enzyme complex, designated here as LAMP for 'large alkaline multi-functional protease', contains three distinct endoproteolytic sites which function at neutral or alkaline pH and are specific for hydrolysis of proteins, hydrophobic peptides, or basic peptides. This protease also exists in a latent form which can be activated by polylysine, fatty acids, or ATP. In this report, we show that the prosomes and these protease complexes are very similar or identical with respect to their size, polypeptide composition, immunological cross-reactivity, appearance in the electron microscope, radial symmetry of subunits, subcellular localization, and proteolytic activities. Therefore, the 'prosome' probably plays a critical role in intracellular protein breakdown, and we propose that it be renamed 'proteasome'.

Drosophila small cytoplasmic 19S ribonucleoprotein is homologous to the rat multicatalytic proteinase

All eukaryotic cells so far analysed contain 19S particles which share a cylinder-like shape and are composed of a set of proteins of relative molecular mass ranging typically from 19,000 to 36,000 (refs 1-10). Proposed functions have included synthetase activity, transfer RNA processing or messenger RNA repression, but their biological importance remains obscure. A multicatalytic proteinase (MCP) of similar size and shape has been isolated from mammalian tissues. The apparent similarities of these high molecular weight complexes suggest a biochemical and functional homology between the small cytoplasmic 19S particle from Drosophila melanogaster (19S-scRNP) (ref. 7) and rat MCP (ref. 14). By means of electron microscopy, immunological techniques, RNA identification and proteinase activity assays, we were able to show that the two structurally similar complexes are immunologically related ribonucleoproteins (RNPs) with similar proteolytic activity.

Enhanced degradation of oxidized glutamine synthetase in vitro and after microinjection into hepatoma cells

Mixed-function oxidation of Escherichia coli glutamine synthetase has previously been suggested to mark the enzyme for intracellular degradation, and in vitro studies have demonstrated that oxidation renders the enzyme susceptible to proteolytic attack. In this study, the susceptibility of glutamine synthetase to degradation by purified proteases has been compared with the rate of degradation after microinjection into hepatoma cells. Upon exposure to an ascorbate mixed-function oxidation system the enzyme rapidly loses most of its activity, but further oxidation is required to cause susceptibility to extensive proteolytic attack either by a high-molecular-weight liver cysteine proteinase or by trypsin. The rate of degradation of biosynthetically 14C-labeled native and oxidized glutamine synthetase preparations after injection into hepatoma cells parallels their susceptibility to proteolysis in vitro. Native enzyme preparations and enzyme oxidatively inactivated, but not susceptible to extensive degradation by purified proteases, had similar intracellular half-lives; however, oxidized enzyme preparations that were susceptible to proteolytic breakdown in vitro were degraded almost ten times faster than the native enzyme within the growing hepatoma cells. These results suggest that the same features of the oxidized enzyme that render it susceptible to proteolysis in vitro are also recognized by the intracellular degradation system. In addition, they show that loss of enzyme activity does not necessarily imply decreased metabolic stability.