The HECT E3 ubiquitin ligase Rsp5 is important for ubiquitin homeostasis in yeast

The HECT E3 ubiquitin ligase Rsp5, a yeast member of the Nedd4 family, has been implicated in many different aspects of cell physiology. Here, we present evidence that Rsp5 function is important for ubiquitin homeostasis. Several observations suggest that ubiquitin is limiting in the rsp5-1 mutant. Reduced synthesis of ubiquitin appears to contribute to ubiquitin depletion. A transient inhibition of general protein synthesis is observed in a wildtype strain upon heat-shock. While the wildtype cells quickly recover from this transient arrest, the rsp5-1 cells remain arrested. This suggests that Rsp5 is important for recovery from heat-induced protein synthesis arrest. Our results suggest that rsp5 phenotypes should be interpreted with caution, since some of the phenotypes could be simply the result of ubiquitin limitation.     

Stimulation of ATP-dependent proteolysis requires ubiquitin with the COOH-terminal sequence Arg-Gly-Gly

It was previously shown that ubiquitin is very similar to the polypeptide cofactor of the ATP-dependent protein degradation system from rabbit reticulocytes (Wilkinson, K. D., Urban, M. K., and Haas, A. L. (1980) J. Biol. Chem. 255, 7529-7532). We have extended this work to show that the peptic peptide maps are identical for bovine ubiquitin and the polypeptide cofactor isolated from human erythrocytes. It was noted however that ubiquitin preparations were less active in stimulating proteolysis than preparations of the polypeptide cofactor. This decreased activity has been shown to be due to the presence of an inactive form of ubiquitin in some preparations. The two forms of ubiquitin are separable by high performance liquid chromatography. The active form of ubiquitin has the COOH-terminal sequence -Arg-Gly-Gly at residues number 74 to 76. The inactive form terminates in -Arg74 as previously reported in the sequence studies of ubiquitin. Limited tryptic digestion of active ubiquitin yields the inactive, later eluting form and the dipeptide glycylglycine. This preteolytic cleavage apparently occurs during purification from most tissues. We thus propose reserving the term ubiquitin for the intact 76-amino acid sequence and designating the 74-amino acid sequence as ubiquitin-t to indicate its derivation by a tryptic-like protease cleavage. This 76-residue sequence is consistent with the covalent structure of protein A-24, a conjugate where carboxyl group of the COOH-terminal glycylglycine of ubiquitin is linked by an amide bond to the epsilon-amino group of Lys-119 of histone H2A. Thus, the structural requirements of the protein and ubiquitin molecules are identical for formation of protein A-24 and for forming the covalent conjugates thought to be intermediates in ATP-dependent protein degradation.     

Purification of a ubiquitin protein peptidase from yeast with efficient in vitro assays

In eukaryotic cells ubiquitin is synthesized as a polyubiquitin protein or as a protein fused at the carboxyl terminus to other polypeptides. An enzyme activity, ubiquitin protein peptidase, has been proposed to process these precursors by cleaving the peptide bond between adjoining ubiquitin molecules or between ubiquitin and the fused peptides. Using the cleavage of a 35S-labeled yeast ubiquitin protein fused to a synthetic 38-residue peptide obtained by in vivo metabolic labeling in Escherichia coli in an expression system based on the interaction of bacteriophage T7 RNA polymerase and its promoter, it is possible to detect a processing activity in soluble yeast extract. The specificity of the cleavage suggests this activity could be the in vivo processing activity for various ubiquitin precursor proteins in yeast cells. A similarly labeled ubiquitin protein fused to one cysteine residue was also utilized to detect an activity capable of removing a single cysteine residue from ubiquitin in a soluble extract. Employing assays based on the cleavage of labeled ubiquitin protein fusions, a ubiquitin protein peptidase activity from Saccharomyces cerevisiae was purified about 15,000-fold to yield a protein mixture consisting of only a few protein species. The major protein band which comigrated with the activities in in vitro assays has an apparent molecular weight of 29,000 when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Two other protein species, about 20,000 and 10,000 in molecular weight, also comigrated with the in vitro activities throughout the purification procedure. Though our most purified protein fraction was shown to cleave various artificial ubiquitin protein fusions under our experimental conditions, it cannot cleave a ubiquitin dimer protein, suggesting the existence of functionally distinct ubiquitin protein peptidases. Our experimental protocol for preparing various labeled ubiquitin protein precursors provides a means to explore various processing enzymes existing in cells. The same protocol may also be adapted to prepare substrates for the study of other specific protein processing enzymes.     

Cellular content of ubiquitin and formation of ubiquitin conjugates during chicken spermatogenesis.

Ubiquitin was purified from chicken testis and its content, biosynthesis and formation of conjugates was determined in germinal cells at successive stages of spermatogenesis. Free ubiquitin increased markedly during spermatogenesis, reaching its maximum level in early spermatids. High levels of ubiquitin were still present in late spermatids but were not detectable in mature spermatozoa. Biosynthesis of ubiquitin occurred in vitro in a fraction containing meiotic and pre-meiotic cells, and during spermiogenesis, in early and late spermatids. The cellular content of free ubiquitin increased after ATP depletion, especially in early spermatids. Lysates of chicken testis cells, particularly those obtained from spermatids, were able to form nuclear (24 and 27 kDa) and extranuclear (55-90 kDa) ubiquitin conjugates in vitro. The presence of increasing levels of ubiquitin and ubiquitin conjugates in chicken spermatids may suggest a possible involvement of this protein in the marked changes of protein turnover, chromatin structure and cell-cell interactions that spermatids undergo during spermiogenesis.     

Interferon induces a 15-kilodalton protein exhibiting marked homology to ubiquitin

Immunochemical methods were used to examine the effect of viral infection on the dynamics of intracellular ubiquitin pools. Infection of either the human lung carcinoma line A-549 or the mouse fibroblast line L929 with encephalomyocarditis virus had little effect on either the distribution or fractional level of intracellular ubiquitin conjugates. In contrast, viral infection resulted in a significant decline in the steady state content of the mono-ubiquitin conjugate to histone 2A (uH2A). Prior treatment with interferons protected against this decrease of uH2A. Furthermore, interferons induced the de novo synthesis of a 15-kDa protein immunologically related to ubiquitin. The ubiquitin cross-reactive protein (UCRP) was not constitutively present in control cells but was significantly induced in various cells sensitive to the biological effects of interferons. Induction of UCRP with respect to both time and interferon concentration dependence closely paralleled the appearance of resistance to viral infection and could be blocked by low levels of actinomycin D. Subsequent studies demonstrated that UCRP was identical to an interferon-induced 15-kDa protein whose sequence has recently been reported (Blomstrom, D. C., Fahey, D., Kutny, R., Korant, B. D., and Knight, E. (1986) J. Biol. Chem. 261, 8811-8816). An authentic sample of the 15-kDa protein was found to co-migrate with UCRP and to cross-react with two different anti-ubiquitin antibodies. Using the authentic 15-kDa protein as a standard, UCRP accumulated to 6.2 +/- 0.5 pmol/10(6) cells and 34 +/- 2 pmol/10(6) cells in interferon-treated A-549 and L929 cultures, respectively. Comparison of the primary sequence of the 15-kDa protein to that of ubiquitin indicated that the former is composed of two domains, each of which bears striking homology to ubiquitin. These observations suggest that the 15-kDa protein may represent one example of a functionally distinct family of ubiquitin-like proteins.     

Protein interactions within the N-end rule ubiquitin ligation pathway

Rate studies have been employed as a reporter function to probe protein-protein interactions within a biochemically defined reconstituted N-end rule ubiquitin ligation pathway. The concentration dependence for E1-catalyzed HsUbc2b/E2(14kb) transthiolation is hyperbolic and yields K(m) values of 102 +/- 13 nm and 123 +/- 19 nm for high affinity binding to rabbit and human E1/Uba1 orthologs. Competitive inhibition by the inactive substrate and product analogs HsUbc2bC88A (K(i) = 104 +/- 15 nm) and HsUbc2bC88S-ubiquitin oxyester (K(i) = 169 +/- 17 nm), respectively, indicates that the ubiquitin moiety contributes little to E1 binding. Under conditions of rate-limiting E3alpha-catalyzed conjugation to human alpha-lactalbumin, HsUbc2b-ubiquitin thiolester exhibits a K(i) of 54 +/- 18 nm and is competitively inhibited by the substrate analog HsUbc2bC88S-ubiquitin oxyester (K(i) = 66 +/- 29 nm). In contrast, the ligase product analog HsUbc2bC88A exhibits a K(i) of 440 +/- 55 nm with respect to the wild type HsUbc2b-ubiquitin thiolester, demonstrating that ubiquitin binding contributes to the ability of E3alpha to discriminate between substrate and product E2. A survey of E1 and E2 isoform distribution in selected cell lines demonstrates that Ubc2 isoforms are the predominant intracellular ubiquitin carrier protein. Intracellular levels of E1 and Ubc2 are micromolar and approximately equal based on in vitro quantitation by stoichiometric (125)I-ubiquitin thiolester formation. Comparison of intracellular E1 and Ubc2 pools with the corresponding ubiquitin pools reveals that most of the free ubiquitin in cells is present as thiolesters to the components of the conjugation pathways. The present data represent the first comprehensive analysis of protein interactions within a ubiquitin ligation pathway.     

Ubiquitin function studied by disulfide engineering

Disulfide engineering was used to probe the role of conformational mobility in ubiquitin-mediated proteolysis. Six genes that encode cysteine-containing mutants of ubiquitin were constructed, expressed in Escherichia coli and the proteins purified. Single cysteine-containing mutants and a 4/14 disulfide were active in degradation of a substrate protein in vitro, while the 4/66 disulfide, which cross-links the NH2- and COOH-terminal strands of the protein, was only 20-30% active. The solution structure of the 4/66 mutant was solved: the disulfide is left-handed with no perturbations in the backbone from that of wild type ubiquitin. The results suggest that conformational mobility is required for the activity of ubiquitin in signaling proteolysis.     

Demonstration of a factor in fraction I of reticulocyte lysates necessary for the steady state accumulation of ubiquitin conjugates of des-75-76-ubiquitin.

Addition of des-75-76-ubiquitin (ubiquitin lacking its two C-terminal glycine residues) to reticulocyte lysates leads to the inhibition of proteolysis and the formation of conjugates between it and native ubiquitin, as demonstrated by the incorporation of both 125I-labeled des-75-76-ubiquitin and 125I-labeled ubiquitin into these conjugates. Conjugate formation is blocked by methylation of the amino groups of des-75-76-ubiquitin, consistent with the concept that the conjugates represent attachment of the ubiquitin alpha-carboxyl group to amino groups of des-75-76-ubiquitin. The lack of significant direct competition for conjugate formation by typical ubiquitinatable proteolysis substrates or by des-73-76-ubiquitin, together with differences in conjugate formation between des-73-76-ubiquitin and des-75-76-ubiquitin demonstrated earlier, indicates that the enzyme involved recognizes the ubiquitin sequence as a substrate for ubiquitination. Increasing concentrations of native ubiquitin first increase and then reduce the steady state level of conjugates of the des-75-76-protein, the inhibitory effects of high concentrations consistent with competition by native ubiquitin for conjugate formation. Upon fractionation of reticulocyte lysates, a factor essential to the net synthesis of conjugates of des-75-76-ubiquitin was demonstrated to be present in Fraction I and to behave as a protein of molecular weight 38,000. The role in this system of a factor from Fraction I other than ubiquitin indicates that a novel pathway is involved.     

The yeast ubiquitin genes: a family of natural gene fusions.

Ubiquitin is a 76-residue protein highly conserved among eukaryotes. Conjugation of ubiquitin to intracellular proteins mediates their selective degradation in vivo. We describe a family of four ubiquitin-coding loci in the yeast Saccharomyces cerevisiae. UB11, UB12 and UB13 encode hybrid proteins in which ubiquitin is fused to unrelated ('tail') amino acid sequences. The ubiquitin coding elements of UB11 and UB12 are interrupted at identical positions by non-homologous introns. UB11 and UB12 encode identical 52-residue tails, whereas UB13 encodes a different 76-residue tail. The tail amino acid sequences are highly conserved between yeast and mammals. Each tail contains a putative metal-binding, nucleic acid-binding domain of the form Cys-X2-4-Cys-X2-15-Cys-X2-4-Cys, suggesting that these proteins may function by binding to DNA. The fourth gene, UB14, encodes a polyubiquitin precursor protein containing five ubiquitin repeats in a head-to-tail, spacerless arrangement. All four ubiquitin genes are expressed in exponentially growing cells, while in stationary-phase cells the expression of UB11 and UB12 is repressed. The UB14 gene, which is strongly inducible by starvation, high temperatures and other stresses, contains in its upstream region strong homologies to the consensus 'heat shock box' nucleotide sequence. Elsewhere we show that the essential function of the UB14 gene is to provide ubiquitin to cells under stress.     

Microinjection of ubiquitin: intracellular distribution and metabolism in HeLa cells maintained under normal physiological conditions

Radioiodinated ubiquitin was introduced into HeLa cells by erythrocyte-mediated microinjection. Subsequent electrophoretic analyses revealed that the injected ubiquitin molecules were rapidly conjugated to HeLa proteins. At equilibrium, 10% of the injected ubiquitin was conjugated to histones and 40% was distributed among conjugates of higher molecular weight. Although the remaining ubiquitin molecules appeared to be unconjugated, the free pool of ubiquitin decreased by one-third and additional conjugates were present when electrophoresis was performed at low temperature under nonreducing conditions. Molecular weights of these labile conjugates suggest that they are ubiquitin adducts in thiolester linkage to activating enzymes. Despite the fairly rapid degradation of injected ubiquitin (t1/2 approximately 10-20 h), the size distribution of ubiquitin conjugates within interphase HeLa cells remained constant for at least 24 h after injection. The intracellular locations of ubiquitin and ubiquitin conjugates were determined by autoradiography, by differential sedimentation of subcellular fractions in sucrose, and by extraction of injected cells with buffer containing Triton X-100. Free ubiquitin was found mostly in the cytosolic or Triton X-100-soluble fractions. As expected, histone conjugates were located predominately in the nuclear fraction and exclusively in the Triton X-100-insoluble fraction. Although high molecular weight conjugates were enriched in the Triton X-100-insoluble fraction, their size distribution was similar to that of soluble conjugates. When injected HeLa cells were exposed to cycloheximide to inhibit protein synthesis, the size distribution of ubiquitin conjugates was similar to that found in untreated cells. Moreover, high molecular weight conjugates decreased less than 20% after inhibition of protein synthesis. These results indicate that most ubiquitin conjugates are not newly synthesized proteins which have been marked for destruction.     

Preparation of distinct ubiquitin chain reagents of high purity and yield

The complexity of protein ubiquitination signals derives largely from the variety of polyubiquitin linkage types that can modify a target protein, each imparting distinct functional consequences. Free ubiquitin chains of uniform linkages and length are important tools in understanding how ubiquitin-binding proteins specifically recognize these different polyubiquitin modifications. While some free ubiquitin chain species are commercially available, mutational analyses and labeling schemes are limited to select, marketed stocks. Furthermore, the multimilligram quantities of material required for detailed biophysical and/or structural studies often makes these reagents cost prohibitive. To address these limitations, we have optimized known methods for the synthesis and purification of linear, K11-, K48-, and K63-linked ubiquitin dimers, trimers, and tetramers on a preparative scale. The high purity and relatively high yield of these proteins readily enables material-intensive experiments and provides flexibility for engineering specialized ubiquitin chain reagents, such as fluorescently labeled chains of discrete lengths.     

The ubiquitin superfamily: members,features, and phylogenies

The ubiquitin superfamily is a rich repository of small, conserved, functionally unique, and important proteins. Its member proteins fold simply and similarly, with kinetic and thermodynamic ease (Sorenson, J. M.; Head-Gordon, T. Toward minimalist models of larger proteins: A ubiquitin-like protein. Proteins 2002, 46, 368-379). They have been implicated in numerous cancers, neurodegenerations, inflammations, and various disorders affecting signal transduction or protein half-life. These proteins serve the cell generally as portable recognition tags with distinct intracellular roles; indeed, tagging with small protein modifiers has become a new hallmark of post-translational modifications and other signal transduction phenomenon (Finley, D. J. Signal transduction. An alternative to destruction. Nature 2001, 412, 283, 285-286). Because many ubiquitin-like proteins bear similarities in sequence, structure, and function, we gathered protein sequences containing the ubiquitin domain from public databases and created a highly granular and defined protein catabolism database to catalog, summarize, reference, and relate them to their targets and specific ligases (to be described elsewhere). In this paper, we reveal a compilation of proteins possessing the ubiquitin domain. This comprises the first and most important part of our database content. We searched available organismal proteomes for sequence-related members of the ubiquitin superfamily and here present over 200 proteins possessing this domain. These proteins were organized phylogenetically and functionally, thereby defining several new families. To our knowledge, this is the most complete assemblage of ubiquitin domains to date.     

Ubiquitin carboxyl-terminal hydrolase acts on ubiquitin carboxyl-terminal amides

Ubiquitin carboxyl-terminal hydrolase (formerly known as ubiquitin carboxyl-terminal esterase), from rabbit reticulocytes, has been shown to hydrolyze thiol esters formed between the ubiquitin carboxyl terminus and small thiols (e.g. glutathione), as well as free ubiquitin adenylate (Rose, I. A., and Warms, J. V. B. (1983) Biochemistry 22, 4234-4237). We now show that this enzyme hydrolyzes amide derivatives of the ubiquitin carboxyl terminus, including those of lysine (epsilon-amino), glycine methyl ester, and spermidine. It also hydrolyzes ubiquitin COOH-terminal hydroxamic acid, but is inactivated under the conditions for assaying ubiquitin-hydroxylamine adduct hydrolysis. Amide adducts formed between ubiquitin and epsilon-amino groups of protein lysine residues are much poorer substrates than is the ubiquitin amide of the epsilon-amino group of free lysine. The enzyme is thus a general hydrolase that recognizes the ubiquitin moiety, but is highly selective for small ubiquitin derivatives. It probably functions to regenerate ubiquitin from adventitiously formed ubiquitin amides and thiol esters. It also has the correct specificity to function in regenerating ubiquitin from small ubiquitin peptides that are probable end products of ubiquitin-dependent proteolysis. A simple, large-scale preparation of the enzyme from human erythrocytes is described.     

Substrate properties of ubiquitin carboxyl-terminally derived peptide probes for protein ubiquitination

Protein ubiquitination is a widespread protein posttranslational modification in eukaryotes that regulates essentially every aspect of cellular processes. The attachment of ubiquitin to a protein substrate is accomplished through an enzymatic cascade involving the actions of an activating enzyme (E1), a conjugating enzyme (E2), and a ligase (E3). There are more than 600 E3 ligases estimated to exist in the human genome that regulate the targeting specificity of protein ubiquitination. To understand the dynamic role of protein ubiquitination in biological processes, robust tools need to be developed which can be employed to establish the substrate specificity of each of these E3 ligases. In this report, we show that the ubiquitin carboxyl-terminally derived peptide probes can serve as modest ubiquitin surrogates for the ubiquitination pathway. In the E1-catalyzed probe adenylation assay, peptide probe 3 with a RLRGG recognition sequence exhibited the highest activity, with the k cat/ K 1/2 determined to be 1.1 x 10 (4) M (-1) s (-1), roughly 470-fold lower than that of ubiquitin. The rate of transfer from the E1 peptide probe thioesters to E2 showed clear sequence dependency, with peptide probe 4 with an LRLRGG recognition sequence showed the fastest rate ( t 1/2 = 0.9 min), essentially identical to that of ubiquitin ( t 1/2 = 0.8 min) under our assay conditions. Furthermore, peptide probes 4 and 8 also exhibited the selective, parkin-mediated labeling of tubulins in a semipurified tubulin-parkin complex. Finally, these carboxyl-terminally derived peptide probes were shown to label the ubiquitination substrates in fraction II of the rabbit reticulocyte lysate with an efficiency parallel to their substrate properties. The selective use of these ubiquitin carboxyl-terminally derived peptide probes by the ubiquitination pathway suggests that perhaps more potent peptide ubiquitination probes based on the ubiquitin C-terminal scaffold can be developed through additional structural optimization.     

Ubiquitylation of BAG-1 suggests a novel regulatory mechanism during the sorting of chaperone substrates to the proteasome

BAG-1 is a ubiquitin domain protein that links the molecular chaperones Hsc70 and Hsp70 to the proteasome. During proteasomal sorting BAG-1 can cooperate with another co-chaperone, the carboxyl terminus of Hsc70-interacting protein CHIP. CHIP was recently identified as a Hsp70- and Hsp90-associated ubiquitin ligase that labels chaperone-presented proteins with the degradation marker ubiquitin. Here we show that BAG-1 itself is a substrate of the CHIP ubiquitin ligase in vitro and in vivo. CHIP mediates attachment of ubiquitin moieties to BAG-1 in conjunction with ubiquitin-conjugating enzymes of the Ubc4/5 family. Ubiquitylation of BAG-1 is strongly stimulated when a ternary Hsp70.BAG-1.CHIP complex is formed. Complex formation results in the attachment of an atypical polyubiquitin chain to BAG-1, in which the individual ubiquitin moieties are linked through lysine 11. The noncanonical polyubiquitin chain does not induce the degradation of BAG-1, but it stimulates a degradation-independent association of the co-chaperone with the proteasome. Remarkably, this stimulating activity depends on the simultaneous presentation of the integrated ubiquitin-like domain of BAG-1. Our data thus reveal a cooperative recognition of sorting signals at the proteolytic complex. Attachment of polyubiquitin chains to delivery factors may represent a novel mechanism to regulate protein sorting to the proteasome.     

Occurrence of a polyubiquitin structure in ubiquitin-protein conjugates

In the ubiquitin-mediated pathway for the degradation of intracellular proteins, several molecules of ubiquitin are linked to the protein substrate by amide linkages. It was noted that the number of ubiquitin-protein conjugates and their apparent molecular size are higher than expected from the number of amino groups in the protein. When the amino groups of ubiquitin were blocked by reductive methylation, it was efficiently conjugated to lysozyme, but the higher-molecular-weight conjugates were not formed. This suggests that the higher-molecular-weight conjugates with native ubiquitin contain structures in which one molecule of ubiquitin is linked to an amino group of another molecule of ubiquitin. Methylated ubiquitin stimulated protein breakdown at about one half the rate obtained with native ubiquitin, and isolated conjugates of 125I-lysozyme with methylated ubiquitin were broken down by reticulocyte extracts. These findings indicate that the formation of polyubiquitin chains is not obligatory for protein breakdown, though it may accelerate the rate of this process.