The inactivation of ubiquitin accounts for the inability to demonstrate ATP, ubiquitin-dependent proteolysis in liver extracts

Ubiquitin and its role in proteolisis: the 2004 Nobel prize in chemistry

In the early 1980-s, Aaron Ciechanover, Avram Hershko, and Irwin Rose discovered one of the most important cyclic cellular processes – a regulated ATP-dependent protein degradation, for which they were awarded the 2004 Nobel Prize in Chemistry. These scientists proved the existence of a non-lysosomal proteolysis pathway and completely changed the perception of intracellular protein degradation mechanisms. They demonstrated pre-labelling of a doomed protein in a cell with a biochemical marker called ubiquitin. Polyubiquitylation of a protein as a signal for its proteolysis was a new mechanism discovered as a result of collaborative efforts of three scientists on isolation of enzymes involved in this sequential process, clarification of the biochemical stages, and substantiating the energy dependence mechanism. The article contains biographical data of the Nobel laureates, the methods applied, and the history of the research resulted in the discovery of the phenomenon of proteasomal degradation of ubiquitin-mediated proteins. Keywords: PROTAC, regulated protein degradation, ubiquitin, І. Rose, А. Ciechanover, А. Hershko

Specificity of the E1-E2-E3 enzymatic cascade for ubiquitin C-terminal sequences identified by phage display

Ubiquitin (UB) is a protein modifier that regulates many essential cellular processes. To initiate protein modification by UB, the E1 enzyme activates the C-terminal carboxylate of UB to launch its transfer through the E1-E2-E3 cascade onto target proteins. In this study, we used phage display to profile the specificity of the two human E1 enzymes, Ube1 and Uba6, toward the C-terminal sequence of UB ending with (71)LRLRGG(76). Phage selection revealed that while Arg72 of UB is absolutely required for E1 recognition, UB residues at positions 71, 73, and 74 can be replaced with bulky aromatic side chains, and Gly75 of UB can be changed to Ser, Asp, and Asn for efficient E1 activation. We have thus found that the E1 enzymes have substantial promiscuity regarding the UB C-terminal sequence. The UB variants from phage selection can also be transferred from E1 to E2 enzymes; however, they are blocked from further transfer to the E3 enzymes. This suggests that the C-terminal sequence of UB is important for its discharge from E2 and subsequent transfer to E3. In addition, we observed that the Leu73Phe and Leu73Tyr single mutants of UB are resistant to cleavage by deubiquitinating enzymes (DUBs), although they can be assembled by the E1-E2-E3 cascade into poly-UB chains, thus indicating differences in UB C-terminal specificities between the E1 and DUBs. Consequently these UB mutants may provide stability to UB polymers attached to cellular proteins and facilitate the elucidation of the biological signals encoded in the UB chains.

Activation of ubiquitin and ubiquitin-like proteins

Attachment of ubiquitin and ubiquitin-like proteins to cellular targets represents a fundamental regulatory strategy within eukaryotes and exhibits remarkably pleiotropic effects on cell function. These posttranslational modifications share a common mechanism comprised of three steps: an activating enzyme to couple ATP hydrolysis to formation of a high-energy intermediate at the carboxyl terminus of ubiquitin or the ubiquitin-like protein, a ligase to couple aminolysis of the activated polypeptide to formation of the new peptide bond and a carrier protein to link the two half reactions. The activating enzymes play pivotal roles in defining pathway specificity for ubiquitin or the ubiquitin-like protein and for target protein specificity in charging the cognate carrier protein supporting downstream ligation steps. Therefore, the family of activating enzymes are critical components of cell regulation that have only recently been recognized as important pharmacological targets.

Ubiquitin and ubiquitin-derived peptides as substrates for peptidylglycine alpha-amidating monooxygenase

Ubiquitin (Ub) and the ubiquitin-like proteins (UBLs) mediate an array of cellular functions. These proteins contain a C-terminal glycine residue that is key to their function. Oxidative conversion of C-terminal glycine-extended prohormones to the corresponding alpha-amidated peptide is one step in the biosynthesis of bioactive peptide hormones. The enzyme catalyzing this reaction is peptidylglycine alpha-amidating monooxygenase (PAM). We report herein that Ub is a PAM substrate with a (V/K)(amidation) that is similar to other known peptide substrates. This work is significant because PAM and the UBLs co-localize to the hypothalamus and the adrenal medulla and are both over-expressed in glioblastomas.

CYTOCHROME P450 UBIQUITINATION: Branding for the Proteolytic Slaughter?

The hepatic cytochromes P450 (P450s) are monotopic endoplasmic reticulum (ER)-anchored hemoproteins engaged in the enzymatic oxidation of a wide variety of endo- and xenobiotics. In the course of these reactions, the enzymes generate reactive O2species and/or reactive metabolic products that can attack the P450 heme and/or protein moiety and structurally and functionally damage the enzyme. The in vivo conformational unraveling of such a structurally damaged P450 signals its rapid removal via the cellular sanitation system responsible for the proteolytic disposal of structurally aberrant, abnormal, and/or otherwise malformed proteins. A key player in this process is the ubiquitin (Ub)-dependent 26S proteasome system. Accordingly, the structurally deformed P450 protein is first branded for recognition and proteolytic removal by the 26S proteasome with an enzymatically incorporated polyUb tag. P450s of the 3A subfamily such as the major human liver enzyme CYP3A4 are notorious targets for this process, and they represent excellent prototypes for the understanding of integral ER protein ubiquitination. Not all the participants in hepatic CYP3A ubiquitination and subsequent proteolytic degradation have been identified. The following discussion thus addresses the various known and plausible events and/or cellular participants involved in this multienzymatic P450 ubiquitination cascade, on the basis of our current knowledge of other eukaryotic models. In addition, because the detection of ubiquitinated P450s is technically challenging, the critical importance of appropriate methodology is also discussed.

Ubiquitin at Fox Chase

My interest in protein breakdown as a research problem began in 1955. In 1963, when we relocated from Yale to the Institute for Cancer Research of Fox Chase, Philadelphia, nothing new was being reported. Here, I review how we get the ubiquitin proteasome system all together.

Real-time monitoring of ubiquitination in living cells by BRET

Ubiquitin has emerged as an important regulator of protein stability and function in organisms ranging from yeast to mammals. The ability to detect in situ changes in protein ubiquitination without perturbing the physiological environment of cells would be a major step forward in understanding the ubiquitination process and its consequences. Here, we describe a new method to study this dynamic post-translational modification in intact human embryonic kidney cells. Using bioluminescence resonance energy transfer (BRET), we measured the ubiquitination of beta-arrestin 2, a regulatory protein implicated in the modulation of G protein-coupled receptors. In addition to allowing the detection of basal and GPCR-regulated ubiquitination of beta-arrestin 2 in living cells, real-time BRET measurements permitted the recording of distinct ubiquitination kinetics that are dictated by the identity of the activated receptor. The ubiquitination BRET assay should prove to be a useful tool for studying the dynamic ubiquitination of proteins and for understanding which cellular functions are regulated by this post-translational event.

Hepatic cytochrome P450 degradation: mechanistic diversity of the cellular sanitation brigade

Hepatic cytochromes P450 (P450s) are monotopic endoplasmic reticulum (ER)-anchored hemoproteins that exhibit heterogenous physiological protein turnover. The molecular/cellular basis for such heterogeneity is not well understood. Although both autophagic-lysosomal and nonlysosomal pathways are available for their cellular degradation, native P450s such as CYP2B1 are preferentially degraded by the former route, whereas others such as CYPs 3A are degraded largely by the proteasomal pathway, and yet others such as CYP2E1 may be degraded by both. The molecular/structural determinants that dictate this differential proteolytic targeting of the native P450 proteins remain to be unraveled. In contrast, the bulk of the evidence indicates that inactivated and/or otherwise posttranslationally modified P450 proteins undergo adenosine triphosphate-dependent proteolytic degradation in the cytosol. Whether this process specifically involves the ubiquitin (Ub)-/26S proteasome-dependent, the Ub-independent 20S proteasome-dependent, or even a recently characterized Ub- and proteasome-independent pathway may depend on the particular P450 species targeted for degradation. Nevertheless, the collective evidence on P450 degradation attests to a remarkably versatile cellular sanitation brigade available for their disposal. Given that the P450s are integral ER proteins, this mechanistic diversity in their cellular disposal should further expand the repertoire of proteolytic processes available for ER proteins, thereby extending the currently held general notion of ER-associated degradation.

N-end rule specificity within the ubiquitin/proteasome pathway is not an affinity effect

The N-end rule relates the amino terminus to the rate of degradation through the ubiquitin/26 S proteasome pathway. Proteins bearing basic (type 1) or large hydrophobic (type 2) amino termini are assumed to be targeted through this pathway by their higher affinity for binding to the responsible E3 ligase compared with proteins bearing other residues (type 3). Paradoxically, a significant fraction of eukaryotic protein degradation occurs through the N-end rule pathway, although the majority of cellular proteins are type 3 substrates. We have exploited specific interactions between ubiquitin carrier proteins (E2/Ubc) and their cognate E3 ligases to purify for the first time the mammalian N-end rule ligase E3alpha/Ubr1 to near homogeneity. In vitro studies show that E3alpha forms lysine 48-linked polyubiquitin degradation signals on type 1-3 substrates and is absolutely dependent on Ubc2/Rad6 orthologs. Biochemically defined kinetic studies show that the basis of N-end rule specificity is a k(cat) rather than the K(m) effect originally proposed, since all three substrate classes show similar binding affinities (K(m) approximately 5 microm) but V(max) values that are 100- and 50-fold greater for type 1 and 2 versus type 3 model substrates, respectively. In addition, the N-end rule dipeptides lysylalanine and phenylalanylalanine are general noncompetitive inhibitors for E3alpha-catalyzed ubiquitination of type 1-3 substrates rather than type-specific competitive inhibitors as predicted. These observations are consistent with a model in which the N-end rule effect reflects substrate binding-induced transitions in E3alpha to a catalytically competent conformer, the equilibrium for which depends on the identity of the amino terminus or the presence of basic or hydrophobic surface features. The model reconciles conflicts between specific predictions and empirical observations relating N-end rule targeting in addition to explicating the efficacy of selected dipeptides as potent in vivo inhibitors of this pathway.

Conjugation of phenylalanine hydroxylase with polyubiquitin chains catalysed by rat liver enzymes

Phenylalanine hydroxylase (PAH, EC 1.14.16.1) is a highly regulated liver enzyme which catalyses the conversion of L-phenylalanine to L-tyrosine, the rate-limiting step in the catabolic pathway of this amino acid. Among the approx. 400 different mutations of human (h) PAH, frequently associated with the metabolic disease phenylketonuria, a low stability is a characteristic property when expressed in eucaryotic cells. In this study, the pathway of hPAH degradation is addressed with focus on its conjugation with polyubiquitin chains catalysed by the ubiquitin-conjugating enzyme system (E1, E2, E3) isolated from rat liver by covalent affinity chromatography on ubiquitin-Sepharose. In the reconstituted in vitro ubiquitination assay, the enzyme system catalysed both the formation of free polyubiquitin chains and the polyubiquitination of wild-type (wt) hPAH and its 'catalytic domain' (DeltaN102/DeltaC24-hPAH) as visualized by two-dimensional electrophoresis. The ubiquitination of wt-PAH may play a role in the degradation of this liver enzyme notably of its many unstable disease-associated mutant forms. The present approach may also have a more general application in the study of liver proteins as possible targets for ubiquitination.

Proteolytic degradation of heme-modified hepatic cytochromes P450: A role for phosphorylation, ubiquitination, and the 26S proteasome?

The resident integral hepatic endoplasmic reticulum (ER) proteins, cytochromes P450 (P450s), turn over in vivo with widely varying half-lives. We and others (Correia et al., Arch. Biochem. Biophys. 297, 228, 1992; and Tierney et al., Arch. Biochem. Biophys. 293, 9, 1992) have previously shown that in intact animals, the hepatic P450s of the 3A and 2E1 subfamilies are first ubiquitinated and then proteolyzed after their drug-induced suicide inactivation. Our findings with intact rat hepatocytes and ER preparations containing native P450s and P450s inactivated via heme modification of the protein have revealed that the proteolytic degradation of heme-modified P450s requires a cytosolic ATP-dependent proteolytic system rather than lysosomal or ER proteases (Correia et al., Arch. Biochem. Biophys. 297, 228, 1992). Using purified cumene hydroperoxide-inactivated P450s (rat liver P450s 2B1 or 3A and/or a recombinant human liver P450 3A4) as models, we now document that these heme-modified enzymes are indeed ubiquitinated and then proteolyzed by the 26S proteasome, but not by its 20S proteolytic core. In addition, our studies indicate that the ubiquitination of these heme-modified P450s is preceded by their phosphorylation. It remains to be determined whether, in common with several other cellular proteins, such P450 phosphorylation is indeed required for their degradation. Nevertheless, these findings suggest that the membrane-anchored P450s are to be included in the growing class of ER proteins that undergo ubiquitin-dependent 26S proteasomal degradation.

Calorie restriction, stress and the ubiquitin-dependent pathway in mouse livers

Calorie restriction (R) is the only known method to delay the aging process and extend mean and maximal lifespan in rodents. R has been shown to delay the age-related accumulation of damaged proteins and to protect organisms from various stresses which can produce damaged proteins. Such stresses include irradiation, heat shock, and oxidative stress. The ubiquitin- and ATP-dependent proteolytic pathway (UPP) has been associated with the degradation of abnormal and/or damaged proteins. We examined the effect of diet and oxidative stress on activities of the UPP in supernatants from livers taken from 23-month-old Emory mice which had been exposed to an in-vivo injection of paraquat. Paraquat induces oxidative stress by generating superoxide radicals. In livers from non-stressed animals, steady-state levels of endogenous ubiquitin conjugates, de novo conjugate formation, and E1 and E2 activities were significantly lower in R animals than in control (C) animals. However, after exposure to paraquat, levels of endogenous ubiquitin conjugates were significantly higher in R versus C animals, and de novo conjugate formation and E1 and E2 activities in R animals rose to levels which were indistinguishable from levels of these activities noted in C animals. R was associated with an increased ability to degrade beta-lactoglobulin by the UPP after an oxidative stress was imposed. Ability to degrade beta-lactoglobulin by the C or R livers in non-stressed animals was not significantly different. Taken together, these data indicate that oxidative stress in R animals is associated with enhanced levels of ubiquitin conjugates and that this enhancement may be due to an increase in UPP activity. These data also indicate that the ability to form ubiquitin conjugates and the UPP system does not change with oxidative stress in C animals. The latter is consistent with prior reports that suggests that older C animals may already be in a state of enhanced oxidative stress and that activities of the UPP provide a sensitive indicator of levels of cellular redox status.

Aging, calorie restriction and ubiquitin-dependent proteolysis in the livers of Emory mice

Calorie restriction (R), the only known method to delay the aging process and extend mean and maximal lifespan, has been shown to delay the age-related decline in protein degradation. There are several proteolytic pathways. The ubiquitin- and ATP-dependent proteolytic pathway (UPP) is frequently associated with degradation of damaged abnormal and/or regulatory proteins. We examined the effect of aging and R on supernatants of livers taken from young (4.5 months) and old (23 months) Emory mice. Aging was associated with increased levels of endogenous ubiquitin conjugates, enhanced ability to form high molecular weight conjugates and ubiquitin activating (E1) and ubiquitin conjugating (E2) activity in the control (C) liver supernatants. The age-related increase in levels of endogenous ubiquitin conjugates in liver appears to be primarily due to increased E1 and E2 activities. R prevented the age-related increase in E1 and E2 activity, and thus prevented the age-related increase in levels of ubiquitin conjugates. In spite of the age-related increase in ubiquitin conjugates, no age-related changes in ubiquitin-dependent proteolytic pathway were observed in the C animals. R was associated with an enhanced ability (130%) to degrade beta-lactoglobulin by the ubiquitin-dependent proteolytic pathway in livers from 4.5-month-old animals relative to age-matched C livers. However, rates of the ubiquitin-dependent degradation of beta-lactoglobulin in the 23-month-old C and R animals were indistinguishable. There were no age- or diet-related differences in the ability to degrade another substrate, oxidized ribonuclease (RNase).

Ability of ubiquitin radioimmunoassay to discriminate between monoubiquitin and multi-ubiquitin chains

Free ubiquitin (mainly monoubiquitin) and multi-ubiquitin chains coexist in eukaryote cells and serve distinct cellular roles. However, any immunoassay systems established previously have not been proved to be applicable for measuring the former without cross-reactive responses with the latter. For this purpose, we developed a radioimmunoassay specific to monoubiquitin by employing antiserum US-1 against ubiquitin. In this assay, ubiquitin-protein conjugates, prepared by a reticulocyte lysate fraction II and fractionated on Moro Q and Superdex 200 columns, exhibited practically no cross-reactivity. The cross-reactivity of fractionated ubiquitin-lysozyme conjugates was also analyzed as a function of their multi-ubiquitin chain size. As a result, the larger the conjugates were found to be, the weaker were the cross-reactive responses they showed, and the multi-ubiquitin chains (n > approx. 20) were substantially unreactive in the radioimmunoassay. By using the radioimmunoassay, heat-shock-induced decrease in the level of cellular free (mono)ubiquitin was detected. In addition, the standard preparation of multi-ubiquitin chains was not cross-reactive in all other five radioimmunoassays employing distinct antibodies to ubiquitin (four antisera and a monoclonal antibody). These data suggest that radioimmunoassays employing ubiquitin antibodies raised by the general methods can discriminate between monoubiquitin and multi-ubiquitin chains and quantitate cellular free ubiquitin.

Conjugation of the 15-kDa interferon-induced ubiquitin homolog is distinct from that of ubiquitin

The biological effect of type 1 interferons is proposed to arise in part from the conjugation of ubiquitin cross-reactive protein (UCRP), the ISG15 gene product, to intracellular target proteins in a process analogous to that of its sequence homolog ubiquitin, a highly conserved 8.6-kDa polypeptide whose ligation marks proteins for degradation via the 26 S proteasome. Inclusion of CoCl2 during the purification of recombinant UCRP blocks the proteolytic inactivation of the polypeptide occurring by cleavage of the carboxyl-terminal glycine dipeptide required for activation and subsequent ligation. Intact UCRP supports a low rate of ubiquitin-activating enzyme (E1)-dependent ATP:PPi exchange but fails to form a stoichiometric E1-UCRP thiol ester or undergo transfer to ubiquitin carrier protein (E2). The binding affinity of E1 for UCRP is significantly diminished relative to that of ubiquitin. These results suggest that UCRP conjugation proceeds through an enzyme pathway distinct from that of ubiquitin, at least with respect to the step of activation. This was confirmed for an in vitro conjugation assay in which 125I-UCRP could be ligated in an ATP-dependent reaction to proteins present within an A549 human lung carcinoma cell extract and could be competitively inhibited by excess unlabeled UCRP but not ubiquitin. Other results demonstrate that 125I-UCRP conjugation is significantly increased in cell extracts after 24 h of incubation in the presence of interferon-beta, consistent with the late induction of UCRP conjugating activity. Thus, interferon-responsive cells contain a pathway for UCRP ligation that is parallel but distinct from that of ubiquitin.

Ubiquitin and the enigma of intracellular protein degradation

Contrary to widespread belief, the regulation and mechanism of degradation for the mass of intracellular proteins (i.e. differential, selective protein turnover) in vertebrate tissues is still a major biological enigma. There is no evidence for the conclusion that ubiquitin plays any role in these processes. The primary function of the ubiquitin-dependent protein degradation pathway appears to lie in the removal of abnormal, misfolded, denatured or foreign proteins in some eukaryotic cells. ATP/ubiquitin-dependent proteolysis probably also plays a role in the degradation of some so-called 'short-lived' proteins. Evidence obtained from the covalent modification of such natural substrates as calmodulin, histones (H2A, H2B) and some cell membrane receptors with ubiquitin indicates that the reversible interconversion of proteins with ubiquitin followed by concomitant functional changes may be of prime importance.

Coordinated induction of the ubiquitin conjugation pathway accompanies the developmentally programmed death of insect skeletal muscle

The developmentally programmed cell death of abdominal intersegmental muscles in the tobacco hawk-moth Manduca sexta is coincident with a 10-fold induction of the polyubiquitin gene as a hormonally regulated event (Schwartz, L. M., Myer, A., Kosz, L., Engelstein, M., and Maier, C. (1990) Neuron 5, 411-419). Solid phase immunochemical assays measuring intersegmental muscle pools of free and conjugated ubiquitin reveal that the induction of polyubiquitin mRNA is accompanied by a proportional increase in total ubiquitin polypeptide. Ubiquitin conjugate pools increase 10-fold at eclosion, during which loss of muscle protein mass is maximum. A smaller but measurable increase in ubiquitin conjugates is observed earlier in pupal development coincident with a modest enhanced degradation of myofibrillar proteins. Accumulation of ubiquitin conjugates is accompanied by induction in the pathway for polypeptide ligation, including the activating enzyme (E1), several carrier protein (E2) isoforms, and ubiquitin:protein isopeptide ligase (E3). Both accumulation of ubiquitin polypeptide and the enzymes of the conjugation pathway are subject to regulation by declining titers of the insect molting hormone 20-hydroxyecdysone, which signals onset of programmed cell death in the intersegmental muscles. Thus, programmed cell death within the intersegmental muscles is accomplished in part by stimulation of the ubiquitin-mediated degradative pathway through a coordinated induction of ubiquitin and the enzymes responsible for its conjugation to yield proteolytic intermediates. This suggests enzymes required for ubiquitin conjugation may represent additional genes recruited for developmentally programmed death.

Dynamics of ubiquitin conjugation during erythroid differentiation in vitro

To gain insight into the role of ubiquitin-mediated proteolysis in erythroid differentiation, levels of ubiquitin conjugating enzymes (E2s) and ubiquitin conjugates were analyzed during in vitro differentiation of murine erythroleukemic (MEL) cells. After 4 days of culture in the presence of the inducer dimethyl sulfoxide, MEL cells expressed high levels of the erythroid-specific proteins, globin, and band 3. During the same interval, cellular contents (mol/cell) of E2-14K, E2-25K, and E2-35K decreased up to approximately 5-fold; as suggested by results obtained with E2-25K, this reflected a lower level of mRNA in differentiating cells. Concentrations of these E2s changed more modestly during in vitro differentiation, since cellular volume also decreased. Comparison of levels of the three E2s in undifferentiated MEL cells and reticulocytes suggests that their concentrations remain fairly constant during in vivo differentiation of proerythroblasts into reticulocytes. Thus, these components of the ubiquitin-mediated proteolytic pathway are likely to function constitutively during this interval. Two-dimensional Western blots showed a broad spectrum of ubiquitin conjugates, including free multiubiquitin chains, in undifferentiated MEL cells. As seen for several E2s, the concentration of ubiquitin conjugates (including free chains) decreased modestly during in vitro differentiation. E2-20K and E2-230K, which are abundant in reticulocytes, were low or absent in undifferentiated and differentiated MEL cells. In erythroid cells these two E2s are reticulocyte-specific; apparently MEL cells do not differentiate far enough to allow induction of their expression.

Ubiquitin is attached to membranes of baculovirus particles by a novel type of phospholipid anchor

Purified budded virions of Autographa californica nuclear polyhedrosis virus (AcNPV) contain abundant amounts of free ubiquitin, which has an altered electrophoretic mobility on SDS gels as compared with standard ubiquitin. Phase extraction of virion proteins with Triton X-114 indicated that the modified form of ubiquitin behaved as an integral membrane protein. The membrane-bound form of ubiquitin was labeled with both phosphate and palmitate, and its electrophoretic mobility was altered by treatment with phospholipase A2 and a phosphatidylcholine-specific phospholipase D. Mild trypsin digestion indicated that the acyl group was not linked to the C-terminus of the protein. Acylated ubiquitin could not be radiolabeled with a membrane-impermeable Bolton-Hunter reagent unless virus was pretreated with detergent. Together, these experiments suggest that ubiquitin is attached to the inner face of the viral membrane by a novel type of phospholipid anchor.

Differential feeding-related regulation of ubiquitin and calbindin9kDa in rat duodenum

Analyses of the calcium-binding protein, calbindin9kDa, purified to apparent homogeneity (SDS-PAGE) from rat duodenum, revealed variable contamination by two other 9 kDa proteins (up to 0.2 mol equivalent each) which were identified as ubiquitin and its C-terminal variant, des-Gly-Gly-ubiquitin. We found that the co-purification of these proteins did not reflect a tight molecular interaction but instead their unexpectedly similar physical characteristics in nondenaturing conditions. Like calbindin9kDa, free ubiquitin was abundant (1% and 0.4% of soluble protein, respectively) in duodenum mucosa of 7-8-week-old rats and its concentration varied daily and with feeding status. In rats fed from midnight to 8.30 a.m., the ubiquitin concentration was specifically higher at 10 pm than at 10 a.m. (11.2 +/- 0.7 and 7.7 +/- 0.8 nmol per g wet weight, respectively, P < 0.02), whereas calbindin9kDa tended towards an opposite variation (18.0 +/- 1.9 and 21.8 +/- 1.7 nmol per g, respectively). Based on its unusually high abundance and novel feeding-related variations, ubiquitin must have an important functional role in the rat duodenum which is distinctly regulated from the calcium transport-associated role of calbindin9kDa.

Rat retina has an active and stable ubiquitin-protein conjugating system

We describe here the presence of ubiquitin and its conjugation system in the rat retina. Retinal homogenates and supernatants conjugate [125I]human ubiquitin with either endogenous or exogenous proteins. The conjugating activity is relatively stable over time, requires ATP, and has a pH optimum of approximately 8. The most prominent [125I]ubiquitin conjugates formed are larger than 130 kDa. Several other minor conjugates are also formed between the molecular weights 17 and 75 kDa. The endogenous levels of free and conjugated forms of ubiquitin have been determined in the rat retina. More than 50% of retinal ubiquitin is covalently bound to target proteins. In addition, activities responsible for the ATP-dependent degradation and disassembly of both endogenous and exogenous ubiquitin conjugates have been detected in vitro. These results provide evidence that the retina contains active and stable ubiquitin-conjugating enzymes that recognize retinal proteins and have ATP-dependent proteolytic activity.

Purification and partial characterization of ubiquitin-activating enzyme from Saccharomyces cerevisiae

Ubiquitin-activating enzyme was purified from the yeast Saccharomyces cerevisiae by covalent affinity chromatography on ubiquitin-Sepharose followed by HPLC anion-exchange chromatography. Enzyme activity was monitored by the ubiquitin-dependent ATP: 32PPi exchange assay. The purified enzyme has a specific activity of 1.5 mumol 32PPi incorporated into ATP.min-1.mg-1 at 37 degrees C and pH 7.0 under standard conditions for substrate concentrations as described by Ciechanover et al. (1982) J. Biol. Chem. 257, 2537-2542. The catalytic activity showed a maximum at pH 7.0. Its molecular weight both in non-denaturing and in SDS-gel electrophoresis was estimated to be 115 kDa, suggesting a monomeric form. The isoelectric point determined by gel electrofocusing was approximately 4.7. Two protein bands differing slightly in electrophoretic mobility could be distinguished when SDS gels were loaded with very small amounts of purified E1 and immunoblotted, the one with higher molecular weight being clearly predominant. The same two bands were also found in anti-E1 immunoblots of crude yeast lysates prepared under broad protease inhibition.

Ubiquitin-mediated processes in erythroid cell maturation

Response of the ATP, ubiquitin-dependent system during the enhanced degradation of erythrocyte maturation conforms to the general regulatory features common to several similar but unrelated systems. In erythroid cells enhanced degradation follows three phases: (1) Onset of degradation characterized by an increase in the intracellular concentration of free and conjugated ubiquitin, brought about by reduction in mean cell volume; (2) Active enhanced degradation during cellular remodeling; and (3) Loss of activity as a consequence of spontaneous inactivation of components required for ubiquitin conjugation. The extent of degradative remodeling is probably functionally limited by the loss of these critical ligation enzymes.

Effect of osmotic stress on protein turnover in Lemna minor fronds

Evidence is presented that although many proteins from the fronds of Lemna minor L. undergo enhanced degradation during osmotic stress, ribulose-1,5-bisphosphate carboxylase (RuBPCase) is not degraded. Instead RuBPCase is converted in a series of steps to a very high-molecular-weight form. The first step involves the induction of an oxidase system which after 24 h of stress converts RuBPCase to an acidic and catalytically inactive form. Subsequently, the oxidised RuBPCase protein is gradually polymerized to a number of very large aggregates (molecular weight of several million).The conversion of RuBPCase to a high-molecular-weight form appears to be correlated with (i) a reduction in the number of-SH residues and (ii) the susceptibility to in-vitro proteolysis. Indeed, the number of-SH groups per RuBPCase molecule decreases from 89 in the native enzyme to 54 and 22 in the oxidised and polymerized forms, respectively. On the other hand, the oxidised enzyme is more susceptible to in-vitro proteolysis than the native form. However, it is the polymerized form of RuBPCase which is particularly susceptible to in-vitro proteolysis.Western-blotting experiments and anti-ubiquitin antibodies were used to detect the presence of ubiquitin conjugates in extracts from osmotically stressed Lemna fronds. The possible involvement of ubiquitin in the formation of the aggregates is discussed.

Inhibition of ubiquitin-dependent proteolysis by des-Gly-Gly-ubiquitin: implications for the mechanism of polyubiquitin synthesis

Cleavage of the two carboxyl-terminal glycine residues from native ubiquitin yields the proteolysis-incompetent derivative des-Gly-Gly-ubiquitin. We report here that this derivative inhibits the ATP-dependent degradation of casein and is multi-ubiquitinated but not degraded by reticulocyte lysates. Inhibition of proteolysis diminished with increasing concentration of native ubiquitin, but was not reduced by increased casein concentration. Cleavage of the last four residues from ubiquitin yielded a derivative that was a weaker inhibitor of proteolysis and a poorer substrate for ubiquitination. These results suggest that the conjugation of ubiquitin to ubiquitin during polyubiquitin synthesis involves a specific conjugation system that recognizes ubiquitin and some of its derivatives, but not general proteolysis substrates, as ubiquitin acceptors.

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.

Simplified methods for isolation of ubiquitin from erythrocytes. Generation of ubiquitin polymers

1. Ubiquitin has been isolated from bovine erythrocytes by procedures in which the hemoglobin was removed by denaturation with either ethanol-chloroform mixtures or by heating. 2. The proteins soluble to the denaturation step were removed by 3% sodium trichloroacetate (TCA) at pH 2.0-2.5 or by 5% TCA. 3. Ubiquitin was isolated in relatively high yield from the TCA insoluble fraction by use of single ion-exchange chromatographic and gel permeation steps. 4. Ubiquitin shows relatively little cross-linking upon treatment with glutaraldehyde or with dimethyl suberimidate. Heating of the glutaraldehyde treated material in 4 M guanidine, however, leads to marked aggregation. 5. The polymers of ubiquitin react strongly with antibody in an immunoblot assay.

Role of ubiquitin conformations in the specificity of protein degradation: iodinated derivatives with altered conformations and activities

Three iodinated derivatives of ubiquitin have been synthesized and these derivatives have been characterized in the ubiquitin-dependent protein degradation system. With chloramine-T as the oxidant, a derivative containing monoiodotyrosine is formed in the presence of 1 M KI and a derivative containing diiodotyrosine is produced in the presence of 1 mM KI. These derivatives exhibit phenolate ionizations at pH 9.2 and 7.9 with absorbance maxima at 305 and 314 nm, respectively. In addition to modification of the tyrosine residue, these conditions lead to the oxidation of the single methionine residue and iodination of the single histidine residue [M.J. Cox, R. Shapira, and K.D. Wilkinson (1986) Anal. Biochem. 154, 345-352]. Iodination of ubiquitin under these conditions renders the protein sensitive to hydrolysis by trypsin and results in an enhanced susceptibility to alcohol-induced helix formation. When the derivatives are tested in the ATP: pyrophosphate exchange reaction catalyzed by the ubiquitin adenylating enzyme, they are found to exhibit activity comparable to the native protein. When these derivatives are tested for the ability to act as a cofactor in the ubiquitin-dependent protein degradation system, they are both found to support a rate of protein degradation that is twice that of native ubiquitin. At high concentrations of derivatives, the rate of protein degradation is inhibited, while the steady state level of conjugates increases. Thus, the free derivatives inhibit the protease portion of the reaction, but are fully active in the activation and conjugation portions of the reaction. With iodine as the modification reagent, monoiodination of tyrosine is the predominant reaction. This derivative exhibits activity similar to native ubiquitin. Thus, it appears that modification of the histidine residue is responsible for the increased activity of the more highly iodinated derivatives. The enzymes of the system must recognize different portions of the ubiquitin structure, or different conformations of ubiquitin that are affected by the iodination of the histidine residue. These results suggest a conformational change of the ubiquitin molecule may be important in determining the rate and specificity of proteolysis.

Lens proteins are substrates for the reticulocyte ubiquitin conjugation system

In the aged lens postsynthetically altered molecules comprise the majority of lens proteins. Many proteolytic activities have been observed in lens supernatants. Since damaged or altered proteins are usually selectively and rapidly degraded in other cells and tissues, the accumulation of these species in the lens seemed enigmatic. Initiation of proteolysis has been studied most extensively in reticulocytes and ts 85 cells. In these systems proteolysis is absolutely ATP dependent, occurs effectively on high molecular weight substrates and, at least for a majority of proteolytic reactions, requires conjugation of ubiquitin to putative substrates. It seemed plausible that the accumulation of high molecular weight protein aggregates in older lenses might be due to the attenuated function of these ubiquitin- and ATP-dependent components in the initial committing processes of proteolysis. This research shows that: ubiquitin is present in the lens; lens proteins are conjugated to 125I-ubiquitin using reticulocyte conjugating systems; the reaction is ATP dependent; proteins from lens epithelium/outer cortex and core form different ubiquitin conjugates; lens proteins compete with lysozyme and reticulocyte proteins for the ubiquitin conjugating apparatus; most of the conjugates are of very high molecular weight; there is a temporal nature to the pattern of conjugates observed; and the ubiquitin conjugation system shows extreme selectivity.

Role of methionine-1 in ubiquitin conformation and activity

Methionine-1 of ubiquitin was oxidized to the sulfone without significant effect on biological activity or conformation at neutral pH. However, at low pH, the oxidized protein expanded to a more open conformation, similar in gel sieving properties to denatured ubiquitin but similar in secondary structure to native ubiquitin. This conformational transition was absent in the native protein. Interpretation of these results in the light of X-ray data suggests that ubiquitin contains two independently folded domains that are held together in part by a hydrogen bond between Met-1 and Lys-63 and which can be separated when this bond is broken. It is suggested that separation of these domains may occur upon ubiquitin conjugation.