A soluble ATP-dependent system for protein degradation from murine erythroleukemia cells. Evidence for a protease which requires ATP hydrolysis but not ubiquitin

A soluble ATP-dependent system for protein degradation has been demonstrated in reticulocyte lysates, but not in extracts of nucleated cells. We report that extracts of undifferentiated murine erythroleukemia (MEL) cells contain a labile ATP-stimulated proteolytic system. The addition of ATP to MEL cell extracts at alkaline pH enhances degradation of endogenous cell proteins and various radiolabeled exogenous polypeptides from 2-15-fold. Nonhydrolyzable ATP analogs had no effect. In reticulocytes, one role of ATP in proteolysis is for ubiquitin conjugation to protein substrates. MEL cells also contain ubiquitin and extracts can conjugate 125I-ubiquitin to cell proteins; however, this process in MEL cells seems unrelated to protein breakdown. After removal of ubiquitin from these extracts by DEAE- or gel chromatography, the stimulation of proteolysis by ATP was maintained and readdition of purified ubiquitin had no further effect. In addition, these extracts degraded in an ATP-dependent fashion casein whose amino groups were blocked and could not be conjugated to ubiquitin. After gel filtration or DEAE-chromatography of the MEL cell extracts (unlike those from reticulocytes), we isolated a high molecular weight (600,000) ATP-dependent proteolytic activity, which exhibits many of the properties of energy-dependent proteolysis seen in crude cell extracts. For example, both the protease and crude extracts are inhibited by hemin and N-ethylmaleimide and both hydrolyze casein, globin, and lysozyme rapidly and denatured albumin relatively slowly. The protease, like the crude extracts, is also stimulated by UTP, CTP, and GTP, although not as effectively as ATP. Also, nonhydrolyzable ATP analogs and pyrophosphate do not stimulate the protease. Thus, some mammalian cells contain a cytosolic proteolytic pathway that appears independent of ubiquitin and involves and ATP-dependent protease, probably similar to that found in Escherichia coli or mitochondria.     

Degradation of ornithine decarboxylase in reticulocyte lysate is ATP-dependent but ubiquitin-independent

Reticulocyte lysate contains all the components of the ubiquitin-dependent proteolytic system. Several proteins are degraded in reticulocyte lysate in a ubiquitin-dependent manner. However, none of the proteins studied has a short intracellular half-life. We have investigated the degradation of ornithine decarboxylase (ODC), one of the most labile proteins in mammalian cells. ODC is efficiently degraded in reticulocyte lysate depleted of the ubiquitin activating enzyme, E1, in fraction II of reticulocyte lysate completely lacking ubiquitin, and in fraction II depleted of the entire complex of enzymes responsible for the ligation of ubiquitin to target proteins. The degradation of ODC is ATP dependent. Therefore, our results demonstrate that in addition to the ubiquitin-dependent proteolytic pathway, reticulocyte lysate contains at least one additional ATP-dependent proteolytic pathway. In vitro synthesized ODC served as a substrate in the present degradation study. Its successful utilization establishes a general strategy for investigating the degradation of short-lived proteins (for which a corresponding cDNA is available), that constitute a very small fraction of cellular proteins and for which purification is difficult or impossible. In contrast to ODC synthesized in vitro, that isolated from cells was not degraded by the reticulocyte lysate degradation system, suggesting that post-translational modifications may be involved in regulating ODC degradation.     

ATP serves two distinct roles in protein degradation in reticulocytes, one requiring and one independent of ubiquitin

Protein degradation in rabbit reticulocytes is a nonlysosomal process requiring ATP. Recently, appreciable evidence has been presented that ATP is required for the covalent binding of the polypeptide ubiquitin to epsilon-amino groups on protein substrates. To test whether linkage of ubiquitin to substrates is required for ATP-dependent proteolysis, the amino groups of 3H-methyl-casein and denatured 125I-bovine serum albumin (BSA) were completely (93-99%) blocked by methylation, acetylation, carbamylation, or succinylation. In each case, the proteins lacking amino groups were still degraded by an ATP-stimulated process, although these various treatments altered absolute rates of proteolysis and reduced the magnitude of the ATP stimulation (two- to fourfold) below that seen measured with the unmodified substrates. When ubiquitin was removed by ion exchange chromatography, ATP still stimulated breakdown of casein and carbamylated casein twofold. The addition of ubiquitin in the presence of ATP caused a further twofold increase in the hydrolysis of unmodified casein but did not affect the degradation of casein lacking amino groups. Thus ubiquitin conjugation to substrates appears important in the breakdown of certain substrates (especially of BSA), but this reaction is not essential for ATP- stimulated proteolysis. The ATP-activated step that is independent of ubiquitin probably is also involved in the degradation of unblocked proteins, since both processes require Mg++ and ATP hydrolysis and are inhibited by hemin but not by protoporphyrin IX. These results suggest that ATP has distinct roles at different steps in the degradative pathway.     

Polyamines inhibit the ATP-dependent proteolytic pathway in rabbit reticulocyte lysates

Reticulocytes contain a soluble nonlysosomal proteolytic pathway that requires ATP and ubiquitin. Polyamines at physiological concentrations were found to inhibit rapidly the ATP-dependent proteolytic system in reticulocyte lysates; spermidine and putrescine inhibited this process by 26-72% and spermine by 71-96%. Spermine had little effect on the ATP-independent breakdown of oxidant-treated hemoglobin. By fractionating the ATP-dependent system, we show that polyamines inhibit the ATP-dependent degradation of ubiquitin-protein conjugates.     

Vanadate inhibits the ATP-dependent degradation of proteins in reticulocytes without affecting ubiquitin conjugation

Reticulocytes contain a nonlysosomal, ATP-dependent system for degrading abnormal proteins and normal proteins during cell maturation. Vanadate, which inhibits several ATPases including the ATP-dependent proteases in Escherichia coli and liver mitochondria, also markedly reduced the ATP-dependent degradation of proteins in reticulocyte extracts. At low concentrations (K1 = 50 microM), vanadate inhibited the ATP-dependent hydrolysis of [3H]methylcasein and denatured 125I-labeled bovine serum albumin, but it did not reduce the low amount of proteolysis seen in the absence of ATP. This inhibition by vanadate was rapid in onset, reversed by dialysis, and was not mimicked by molybdate. Vanadate inhibits proteolysis at an ATP-stimulated step which is independent of the ATP requirement for ubiquitin conjugation to protein substrates. When the amino groups on casein and bovine serum albumin were covalently modified so as to prevent their conjugation to ubiquitin, the derivatized proteins were still degraded by an ATP-stimulated process that was inhibited by vanadate. In addition, vanadate did not reduce the ATP-dependent conjugation of 125I-ubiquitin to endogenous reticulocyte proteins, although it markedly inhibited their degradation. In intact reticulocytes vanadate also inhibited the degradation of endogenous proteins and of abnormal proteins containing amino acid analogs. This effect was rapid and reversible; however, vanadate also reduced protein synthesis and eventually lowered ATP levels in the intact cells. Vanadate (10 mM) has also been reported to decrease intralysosomal proteolysis in hepatocytes. However, in liver extracts this effect on lysosomal proteases required high concentrations of vanadate (K1 = 500 microM) and was also observed with molybdate, unlike the inhibition of ATP-dependent proteolysis in reticulocytes.     

Red blood cells contain a pathway for the degradation of oxidant-damaged hemoglobin that does not require ATP or ubiquitin

It is generally accepted that ATP is required for intracellular protein breakdown. Reticulocytes contain a soluble ATP-dependent pathway for the degradation of highly abnormal proteins and for the elimination of certain proteins during cell maturation. Reticulocytes and erythrocytes also selectively degrade proteins damaged by oxidation. When these cells were exposed to oxidants, such as phenylhydrazine or nitrite, they showed a large increase in protein breakdown. This oxidant-induced proteolysis was not inhibited in cells depleted of ATP. However, ATP depletion did prevent the degradation of pre-existent cell proteins. In reticulocyte extracts, phenylhydrazine-treated hemoglobin is also degraded rapidly by an ATP-independent process, unlike endogenous proteins and many exogenous polypeptides. This lack of an ATP requirement means that the degradation of oxidant-damaged proteins does not require ligation to ubiquitin (even though phenylhydrazine treatment does make hemoglobin a very good substrate for ubiquitin conjugation). In many respects, the pathway for breakdown of oxidant-treated hemoglobin differs from the ATP-dependent process. The latter has a much higher activation energy than the degradation of oxidized proteins. The ATP-dependent process is inhibited by hemin, 3,4-dichloroisocoumarin, diisopropylfluorophosphate and N-ethylmaleimide. The ATP-independent pathway is less sensitive to N-ethylmaleimide, hemin, and 3,4-dichloroisocoumarin and is not affected by diisopropylfluorophosphate. In addition, only the ATP-dependent proteolytic process is inactivated by dilution or incubation at 37 degrees C in the absence of nucleotides. Reticulocytes thus contain multiple soluble systems for degrading proteins and can rapidly hydrolyze certain types of abnormal proteins by either an ATP-independent or ATP-dependent process. Erythrocytes lack the ATP-dependent process present in reticulocytes; however, erythrocytes retain the capacity to degrade oxidant-damaged hemoglobin. These two processes probably are active in the elimination of different types of abnormal proteins.     

Transfer RNA is required for conjugation of ubiquitin to selective substrates of the ubiquitin- and ATP-dependent proteolytic system

Degradation of intracellular proteins via the ubiquitin- and ATP-dependent proteolytic pathway involves several steps. In the initial event, ubiquitin, an abundant 76-residue polypeptide is covalently linked to the protein substrate in an ATP-requiring reaction. Proteins marked by ubiquitin are selectively proteolyzed in a reaction that also requires ATP. Ubiquitin conjugation to proteins appears also to be involved in regulation of cell cycle and cell division, and probably in the regulation of gene expression at the level of chromatin structure. We have previously shown (Ciechanover, A., Wolin, S. L., Steitz, J. A., and Lodish, H. F. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 1341-1345) that transfer RNA is an essential component of the ubiquitin pathway. Ribonucleases strongly and specifically inhibited the degradation of 125I-labeled bovine serum albumin, while tRNA purified from reticulocyte extract could restore the proteolytic activity. Specifically, pure tRNAHis isolated by immunoprecipitation with human autoimmune serum could restore the proteolytic activity. Here we demonstrate that tRNA is required for conjugation of ubiquitin to some but not all proteolytic substrates of the ubiquitin mediated pathway. Conjugation of 125I-labeled ubiquitin to reduced carboxymethylated bovine serum albumin, alpha-lactalbumin, and soybean trypsin inhibitor was strongly and specifically inhibited by ribonucleases. Consequently, the ATP-dependent degradation of these substrates in the cell-free ubiquitin-dependent reticulocyte system was inhibited as well. Addition of tRNA to the ribonuclease inhibited system (following inhibition of the ribonuclease) restored both the conjugation activity and the ubiquitin- and ATP-dependent degradation of these substrates. Conjugation of ubiquitin to some endogenous reticulocyte proteins was also inhibited by ribonucleases and could be restored by the addition of tRNA. In striking contrast, the conjugation of radiolabeled ubiquitin to lysozyme, oxidized RNase A, alpha-casein, and beta-lactoglobulin was not affected by the ribonuclease treatment, and the degradation of these substrates was significantly accelerated by the ribonucleases. These findings indicate that there are at least two distinct ubiquitin conjugation systems. One requires tRNA, and the other is tRNA independent. These pathways, however, must share some common component(s) of the system, since the inhibition of one system accelerates the other. The possible function of tRNA in the selective conjugation reaction and the possible role of the two distinct ubiquitin marking mechanisms are discussed.     

A heat-stable polypeptide component of an ATP-dependent proteolytic system from reticulocytes

The degradation of denatured globin in reticulocyte lysates is markedly stimulated by ATP. This system has now been resolved into two components, designated fractions I and II, in the order of their elution from DEAE-cellulose. Fraction II has a neutral protease activity but is stimulated only slightly by ATP, whereas fraction I has no proteolytic activity but restores ATP-dependent proteolysis when combined with fraction II. The active principle of fraction I is remarkably heat-stable, but it is non-dialysable, precipitable with ammonium sulfate and it is destroyed by treatment with proteolytic enzymes. In gel filtration on Sephadex-G-75, it behaves as a single component with a molecular weight of approximately 9,000.     

ATP-dependent degradation of 125I-bovine serum albumin by rabbit reticulocytes does not need repression of an endogenous inhibitor

The ubiquitin-dependent proteolysis of 125I-bovine serum albumin in rabbit reticulocytes has been investigated. Using various reticulocyte fractions (reticulocyte protease, inhibitor-free protease, "ubiquitin" and "inhibitor") in the presence or absence of ATP, we found that the repression of an endogenous inhibitor, as suggested by others for alpha-casein proteolysis, is unlikely for bovine serum albumin. Therefore, differences exist in the ATP-dependent proteolytic pathway of rabbit reticulocytes depending on the substrate. Fractionation of the reticulocyte ATP-dependent proteolytic system revealed at least two proteolytic and two inhibitory fractions involved in the proteolysis of bovine serum albumin.     

Oxidatively denatured proteins are degraded by an ATP-independent proteolytic pathway in Escherichia coli

E. coli contains a soluble proteolytic pathway which can recognize and degrade oxidatively denatured proteins and protein fragments, and which may act as a "secondary antioxidant defense." We now provide evidence that this proteolytic pathway is distinct from the previously described ATP-dependent, and protease "La"-dependent, pathway which may degrade other abnormal proteins. Cells (K12) which were depleted of ATP, by arsenate treatment or anaerobic incubation (after growth on succinate), exhibited proteolytic responses to oxidative stress which were indistinguishable from those observed in cells with normal ATP levels. Furthermore, the proteolytic responses to oxidative damage by menadione or H2O2 were almost identical in the isogenic strains RM312 (a K12 derivative) and RM1385 (a lon deletion mutant of RM312). Since the lon (or capR) gene codes for the ATP-dependent protease "La," these results indicate that neither ATP nor protease "La" are required for the degradation of oxidatively denatured proteins. We next prepared cell-free extracts of K12, RM312, and RM1385 and tested the activity of their soluble proteases against proteins (albumin, hemoglobin, superoxide dismutase, catalase) which had been oxidatively denatured (in vitro) by exposure to .OH, .OH + O2- (+O2), H2O2, or ascorbate plus iron. The breakdown of oxidatively denatured proteins was several-fold higher than that of untreated proteins in extracts from all three strains, and ATP did not stimulate degradation. Incubation of extracts at 45 degrees C, which inactivates protease "La," actually stimulated the degradation of oxidatively denatured proteins. Although Ca2+ had little effect on proteolysis, serine reagents, transition metal chelators, and hemin effectively inhibited the degradation of oxidatively denatured proteins in both intact cells and cell-free extracts. Degradation of oxidatively denatured proteins in cell-free extracts was maximal at pH 7.8, and was unaffected by dialysis of the extracts against membranes with molecular weight cutoffs as high as 50,000. Our results indicate the presence of a neutral, ATP- and calcium- independent proteolytic pathway in the E. coli cytosol, which contains serine- and metallo- proteases (with molecular weights greater than 50,000), and which preferentially degrades oxidatively denatured proteins.     

Ubiquitin-lysozyme conjugates. Purification and susceptibility to proteolysis

To produce ubiquitinated substrates for studies on ATP-dependent proteolysis, 125I-lysozyme was incubated in hemin-inhibited rabbit reticulocyte lysates. A portion of the labeled molecules became linked to ubiquitin in large covalent complexes. When these were partially purified and returned to uninhibited lysates containing ATP, the conjugated lysozyme molecules were degraded 10 times faster than free lysozyme. Purification of covalently modified lysozyme from hemin-inhibited lysates containing 125I-ubiquitin and 131I-lysozyme confirmed that both molecules were present in the complexes. The doubly labeled conjugates also permitted us to determine the fate of each molecule in uninhibited lysates. Besides degradation of lysozyme, there was a progressive release of intact lysozyme molecules from the complexes. This disassembly, which was the only fate of the complexes in the absence of ATP, proceeded through a series of smaller intermediates, several having molecular weights expected for ubiquitin-lysozyme conjugates, and eventually free lysozyme was regenerated. The behavior of labeled ubiquitin was similar, though not identical, to that of lysozyme. Even in lysates containing ATP ubiquitin emerged from the complex undegraded. Furthermore, ubiquitin was present in a greater number of species than was lysozyme. The demonstration that ubiquitin-lysozyme conjugates are rapidly degraded provides support for the hypothesis of Hershko, Rose, Ciechanover, and their colleagues that a key function of ubiquitin is to modify the proteolytic substrate. Further support for the hypothesis is presented in the following paper where we show that the conjugated lysozyme molecules are substrates for an ATP-dependent protease that does not degrade free lysozyme.     

Inhibition of ubiquitin-dependent proteolysis by non-ubiquitinatable proteins

The effect in reticulocyte lysates of proteins with blocked amino groups on the ATP-dependent degradation of casein and serum albumin was studied in order to assess the extent to which proteins with blocked and with free amino groups share common paths of proteolytic degradation. Completely acetylated or succinylated casein and acetylated or succinylated serum albumin (reduced and carboxymethylated), in addition to other amino-modified proteins, inhibited the ATP-dependent proteolysis of both casein and reduced carboxymethylated serum albumin. Inhibition of serum albumin degradation by acetylated serum albumin was competitive, whereas inhibition of casein degradation by acetylated casein was largely competitive with evidence of mixed kinetics. The different amino-blocked proteins studied, which were largely unfolded under assay conditions, were similarly effective as inhibitors on a weight basis, with Ki values in the range 0.2-0.6 mg/ml; there was no correlation between the ability of the blocked proteins to serve as proteolysis substrates and their effectiveness as inhibitors. Studies of the effects of acetylated proteins on the conjugation of ubiquitin to serum albumin and casein demonstrated that the acetylated proteins blocked formation of ubiquitin-albumin conjugates and of selected casein conjugates; the steady state concentration of selected conjugates of endogenous lysate proteins was increased in the presence of amino-blocked proteins. The results suggest that proteins with blocked amino groups, which cannot serve as substrates for ubiquitin conjugation, can compete for binding to those ubiquitin conjugation factors that recognize and ubiquitinate potential substrates of the ubiquitin pathway. The similar inhibitory properties of the different blocked proteins in turn suggest that a common factor in binding to these conjugation factors may be recognition of the polypeptide backbone.     

Expression and accurate processing of yeast penta-ubiquitin in Escherichia coli

An expression vector (pSJyub-5) was constructed which contained five repeats of the "yeast ubiquitin gene" regulated by a heat-inducible lambda PL promoter. The vector, when expressed in Escherichia coli, produced a penta-ubiquitin of approximately 42 kDa. Purified penta-ubiquitin was found to be as active as the human mono-ubiquitin in the in vitro ATP/ubiquitin-dependent proteolytic assay of the reticulocyte lysate, indicating that the expressed gene product was recognized by the enzymes involved in the ATP/ubiquitin-dependent proteolytic pathway. The inability of penta-ubiquitin to act as a substrate in the pyrophosphate exchange reaction with the ubiquitin-activating enzyme E1 suggested that it had a carboxyl-terminal Asn, in agreement with the nucleotide sequence. In E. coli, the expressed penta-ubiquitin was processed correctly to mono-ubiquitin. The fidelity of processing in E. coli was confirmed by the following observations. The amino acid compositions of the processed mono-ubiquitin and human ubiquitin were similar. The 1H NMR spectrum of peaks representing amide hydrogens of the carboxyl-terminal Arg-74, Gly-75, and Gly-76 of the processed mono-ubiquitin was identical with that of human ubiquitin. The immunoreactivity of processed mono-ubiquitin and human ubiquitin against polyclonal antibodies that recognized epitope(s) only on the carboxyl terminus of ubiquitin were similar. The human and processed mono-ubiquitin were equally active in degrading 125I-bovine serum albumin in the ATP/ubiquitin-dependent in vitro proteolytic assay with reticulocyte lysates. In the pyrophosphate exchange assay with isolated ubiquitin activating enzyme E1, they were also equally reactive, confirming that the expressed and processed ubiquitin contained an intact carboxyl-terminal Gly-76. Purified penta-ubiquitin should prove to be a useful substrate for identifying and isolating processing enzyme(s) involved in the ATP/ubiquitin-dependent proteolytic pathway.     

Effects of weak bases on the degradation of endogenous and exogenous proteins by rat yolk sacs.

In rat yolk sacs incubated in vitro, the rates of degradation of endogenous [3H]leucine-labelled proteins and of pinocytically ingested 125I-labelled bovine serum albumin were both decreased in the presence of either ammonium, methylammonium or ethylammonium ions (0-20 mM) or much lower concentrations of chloroquine (0-500 microM). These effects were also accompanied by an inhibition of pinocytosis, as measured by the rate of uptake of 125I-labelled polyvinylpyrrolidone, and by a fall in the [ATP]/[ADP] ratio within the tissue. Re-incubation in inhibitor-free medium of yolk sacs previously exposed to a weak base restored pinocytic and proteolytic capacities, except for tissues exposed to chloroquine at concentrations above 0.1 mM (these appeared to be cytotoxic); an attendent rise in [ATP]/[ADP] ratios to near normal values was also observed. Weak bases, at concentrations that fully arrested the breakdown of 125I-labelled albumin, failed to inhibit by more than 45% the degradation of [3H]leucine-labelled endogenous proteins. Since 125I-labelled bovine serum albumin has been shown to be degraded entirely intralysosomally by yolk sacs, this suggests either that the hydrolysis of endogenous proteins is shared between lysosomes and some other site or that, unlike 125I-labelled albumin, some endogenous proteins can be degraded within lysosomes at abnormally high pH.     

Ubiquitin carboxyl-terminal peptides. Substrates for ubiquitin activating enzyme

The carboxyl terminus of ubiquitin is activated in the presence of ATP to enter the ubiquitin cycle in cells. Peptides corresponding to the COOH-terminal region of ubiquitin were synthesized to investigate their effects on the ATP/ubiquitin-dependent proteolytic pathway. Their activities in the PPi exchange assay with ubiquitin activating enzyme (E1) were proportional to their length. The hexapeptide Ac-Leu-Arg-Leu-Arg-Gly-Gly reacted with ATP to form an enzyme-adenylate-hexapeptide complex and at high concentrations was 20-25% as active as human ubiquitin in the PPi exchange assay with E1. However, the hexapeptide was not transferred to the sulfhydryl "thiol" site on E1. In addition, the COOH-terminal peptides did not support the degradation of 125I-bovine serum albumin in the reticulocyte lysate system. A nonhomologous peptide of equivalent length was inactive in all assays. Thus, synthetic COOH-terminal peptide(s) of ubiquitin can partially substitute for ubiquitin in its reactions with E1 but do not support subsequent steps of the energy-dependent proteolytic pathway. These results show that it may be possible to design small molecules that either serve as substrates or inhibitors for other specific steps in ubiquitin-dependent pathways.     

Circular pancreatic trypsin inhibitor. A novel substrate for studies on intracellular proteolysis

Several recent studies indicate that substrates for ubiquitin-dependent proteolysis must possess unblocked alpha-amino termini. To examine further the importance of free amino groups for proteolytic susceptibility we selected pancreatic trypsin inhibitor (PTI) as a test substrate. PTI can be circularized to form cPTI, a molecule that lacks alpha-amino groups in the absence of an endoproteolytic cleavage. We compared the breakdown of radioiodinated PTI and cPTI in rabbit reticulocyte lysate and found that cPTI was not stabilized relative to PTI. In addition, proteolysis of PTI or cPTI was not inhibited upon conversion of their lysine residues to homoarginine. However, neither degradation of PTI nor cPTI required ATP, and ubiquitin conjugation to either molecule was minor relative to known substrates of the ubiquitin pathway. Thus, PTI and cPTI are cleaved by an ATP-independent endoprotease(s) that does not require the substrate to be ubiquitinated. Such an activity was identified in low salt fractions obtained upon DEAE chromatography of reticulocyte lysate. The ubiquitin/ATP-dependent protease and another large multisubunit protease, both of which elute from DEAE-Fractogel at higher salt concentrations, do not degrade PTI or cPTI. Although monomeric PTI was rapidly degraded in reticulocyte lysate, cross-linked PTI molecules were stable both in reticulocyte lysate and following introduction into cultured cells using red blood cell-mediated microinjection. Thus, increased rates of turnover do not necessarily correlate with greater molecular mass of the substrate.     

Ubiquitin conjugation is not required for the degradation of oxidized proteins by proteasome

Oxidatively modified proteins that accumulate in aging and many diseases can form large aggregates because of covalent cross-linking or increased surface hydrophobicity. Unless repaired or removed from cells, these oxidized proteins are often toxic, and threaten cell viability. Most oxidatively damaged proteins appear to undergo selective proteolysis, primarily by the proteasome. Previous work from our laboratory has shown that purified 20 S proteasome degrades oxidized proteins without ATP or ubiquitin in vitro, but there have been no studies to test this mechanism in vivo. The aim of this study was to determine whether ubiquitin conjugation is necessary for the degradation of oxidized proteins in intact cells. We now show that cells with compromised ubiquitin-conjugating activity still preferentially degrade oxidized intracellular proteins, at near normal rates, and this degradation is still inhibited by proteasome inhibitors. We also show that progressive oxidation of proteins such as lysozyme and ferritin does not increase their ubiquitinylation, yet the oxidized forms of both proteins are preferentially degraded by proteasome. Furthermore, rates of oxidized protein degradation by cell lysates are not significantly altered by addition of ATP, excluding the possibility of an energy requirement for this pathway. Contrary to earlier popular belief that most proteasomal degradation is conducted by the 26 S proteasome with ubiquitinylated substrates, our work suggests that oxidized proteins are degraded without ubiquitin conjugation (or ATP hydrolysis) possibly by the 20 S proteasome, or the immunoproteasome, or both.     

Mechanisms of intracellular protein catabolism. Intracellular fate of microinjected polypeptides translated in vitro.

Erythrocyte-mediated microinjection was used to introduce [35S]polypeptides translated in vitro into 3T3-L1 cells. Such [35S]polypeptides are not degraded after loading into erythrocytes and are stable for the first 2 h after microinjection into growing 3T3-L1 cells. Similarly, little or no degradation of microinjected [35S]polypeptides is observed in either growing or confluent 3T3-L1 cells over a 70 h period. Microinjection of reticulocyte lysate alone does not affect the rate of degradation of long-lived endogenous protein. Reductively [3H]methylated lysate haemoglobin is degraded after microinjection by a cytosolic mechanism. Microinjected 125I-labelled bovine serum albumin is rapidly degraded by a cytosolic mechanism at the same rate in the absence or presence of reticulocyte lysate. The data do not support the notion that the observed lack of degradation of microinjected [35S]polypeptides translated in vitro is due to the presence of proteolytic inhibitors in reticulocyte lysates which can inhibit the degradation of microinjected or cellular proteins.     

Murine erythroleukemia cells possess an active ubiquitin- and ATP-dependent proteolytic pathway

The ubiquitin (Ub)-dependent proteolytic pathway may function in selective elimination of cellular proteins during erythroid differentiation. Murine erythroleukemia (MEL) cells, which can be induced to differentiate to reticulocytes in culture, may provide a convenient system for studying the role of Ub-dependent proteolysis in erythroid differentiation. The following observations indicate that MEL cells possess an active Ub-dependent proteolytic pathway. (i) Addition of purified Ub to MEL cell fraction II (Ub-depleted lysate) stimulated ATP-dependent degradation of radioiodinated proteins. (ii) Covalent conjugation of carboxyl termini of Ub molecules to substrate protein amino groups is a necessary step in Ub-dependent degradation. Des-glygly-Ub (Ub lacking its carboxyl-terminal glygly moiety) did not stimulate protein degradation in MEL cell fraction II. (iii) The Ub-dependent component of protein degradation in MEL cell fraction II was specifically inhibited by amino acid derivatives that are inhibitors of Ub-protein ligase. (iv) MEL cell fraction II contained apparent homologs of all of the rabbit reticulocyte Ub carrier proteins (E2's) except E2(20K) and E2(230K). Ub-dependent proteolysis was seen only in MEL cell lysates prepared in the presence of leupeptin; an enzyme of the proteolytic pathway was inactivated if leupeptin was omitted.     

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.