Showing papers on "Ubiquitin ligase published in 1994"

Split ubiquitin as a sensor of protein interactions in vivo

Abstract: We describe an assay for in vivo protein interactions. Protein fusions containing ubiquitin, a 76-residue, single-domain protein, are rapidly cleaved in vivo by ubiquitin-specific proteases, which recognize the folded conformation of ubiquitin. When a C-terminal fragment of ubiquitin (C(ub)) is expressed as a fusion to a reporter protein, the fusion is cleaved only if an N-terminal fragment of ubiquitin (Nub) is also expressed in the same cell. This reconstitution of native ubiquitin from its fragments, detectable by the in vivo cleavage assay, is not observed with a mutationally altered Nub. However, if C(ub) and the altered Nub are each linked to polypeptides that interact in vivo, the cleavage of the fusion containing C(ub) is restored, yielding a generally applicable assay for kinetic and equilibrium aspects of in vivo protein interactions. This method, termed USPS (ubiquitin-based split-protein sensor), makes it possible to monitor a protein-protein interaction as a function of time, at the natural sites of this interaction in a living cell.

Inhibition of proteolysis and cell cycle progression in a multiubiquitination-deficient yeast mutant.

Abstract: The degradation of many proteins requires their prior attachment to ubiquitin. Proteolytic substrates are characteristically multiubiquitinated through the formation of ubiquitin-ubiquitin linkages. Lys-48 of ubiquitin can serve as a linkage site in the formation of such chains and is required for the degradation of some substrates of this pathway in vitro. We have characterized the recessive and dominant effects of a Lys-48-to-Arg mutant of ubiquitin (UbK48R) in Saccharomyces cerevisiae. Although UbK48R is expected to terminate the growth of Lys-48 multiubiquitin chains and thus to exert a dominant negative effect on protein turnover, overproduction of UbK48R in wild-type cells results in only a weak inhibition of protein turnover, apparently because the mutant ubiquitin can be removed from multiubiquitin chains. Surprisingly, expression of UbK48R complements several phenotypes of polyubiquitin gene (UB14) deletion mutants. However, UbK48R cannot serve as a sole source of ubiquitin in S. cerevisiae, as evidenced by its inability to rescue the growth of ubi1 ubi2 ubi3 ubi4 quadruple mutants. When provided solely with UbK48R, cells undergo cell cycle arrest with a terminal phenotype characterized by replicated DNA, mitotic spindles, and two-lobed nuclei. Under these conditions, degradation of amino acid analog-containing proteins is severely inhibited. Thus, multiubiquitin chains containing Lys-48 linkages play a critical role in protein degradation in vivo.

The ubiquitin-mediated proteolytic pathway: mechanisms of recognition of the proteolytic substrate and involvement in the degradation of native cellular proteins

Abstract: Ubiquitin modification of a variety of protein targets within the cell plays important roles in many cellular processes. Among these are regulation of gene expression, regulation of cell cycle and division, involvement in the cellular stress response, modification of cell surface receptors, DNA repair, import of proteins into mitochondria, uptake of precursors into neurons, and biogenesis of mitochondria, ribosomes, and peroxisomes. The best studied modification occurs in the ubiquitin-mediated proteolytic pathway. Degradation of a protein via the ubiquitin system involves two discrete steps. Initially, multiple ubiquitin molecules are covalently linked in an ATP-dependent mode to the protein substrate. The targeted protein is then degraded by a specific and energy-dependent high molecular mass protease into free amino acids, and free and reutilizable ubiquitin is released. In addition, stable mono-ubiquitin adducts are also found in the cell, for example, those involving nucleosomal histones. Despite the considerable progress that has been made in elucidating the mode of action and roles of the ubiquitin system, many problems remain unsolved. For example, little is known on the signals that target proteins for degradation. Although mechanistic aspects of recognition via the N-terminal residue have been studied thoroughly, it is clear that the vast majority of cellular proteins are targeted by other signals. The identity of the native cellular substrates of the system is another important, yet unresolved, problem: only few proteins have been recognized so far as substrates of the system in vivo. The scope of this review is to discuss the mechanisms involved in ubiquitin activation, selection of substrates for conjugation, and degradation of ubiquitin-conjugated proteins in the cell-free system. In addition, we shall summarize what is currently known of the physiological roles of ubiquitin-mediated proteolysis in vivo.

Protein synthesis elongation factor EF-1 alpha is essential for ubiquitin-dependent degradation of certain N alpha-acetylated proteins and may be substituted for by the bacterial elongation factor EF-Tu.

Abstract: Targeting of different cellular proteins for conjugation and subsequent degradation via the ubiquitin pathway involves diverse recognition signals and distinct enzymatic factors. A few proteins are recognized via their N-terminal amino acid residue and conjugated by a ubiquitin-protein ligase that recognizes this residue. Most substrates, including the N alpha-acetylated proteins that constitute the vast majority of cellular proteins, are targeted by different signals and are recognized by yet unknown ligases. We have previously shown that degradation of N-terminally blocked proteins requires a specific factor, designated FH, and that the factor acts along with the 26S protease complex to degrade ubiquitin-conjugated proteins. Here, we demonstrate that FH is the protein synthesis elongation factor EF-1 alpha. (a) Partial sequence analysis reveals 100% identity to EF-1 alpha. (b) Like EF-1 alpha, FH binds to immobilized GTP (or GDP) and can be purified in one step using the corresponding nucleotide for elution. (c) Guanine nucleotides that bind to EF-1 alpha protect the ubiquitin system-related activity of FH from heat inactivation, and nucleotides that do not bind do not exert this effect. (d) EF-Tu, the homologous bacterial elongation factor, can substitute for FH/EF-1 alpha in the proteolytic system. This last finding is of particular interest since the ubiquitin system has not been identified in prokaryotes. The activities of both EF-1 alpha and EF-Tu are strongly and specifically inhibited by ubiquitin-aldehyde, a specific inhibitor of ubiquitin isopeptidases. It appears, therefore, that EF-1 alpha may be involved in releasing ubiquitin from multiubiquitin chains, thus rendering the conjugates susceptible to the action of the 26S protease complex.

Site-directed mutagenesis of ubiquitin. Differential roles for arginine in the interaction with ubiquitin-activating enzyme.

Abstract: The strict evolutionary conservation of ubiquitin suggests an essential role for each residue in the folding, stability, or function of the protein but precludes identification of such contributions through interspecies comparison of ubiquitin sequences. However, site-directed mutagenesis potentially allows assignment of specific function(s) for each residue. The four arginines present on ubiquitin at positions 42, 54, 72, and 74 were independently mutated to leucine and their effects on the interaction of the resulting polypeptides with ubiquitin-activating enzyme (E1) were characterized. All of the mutants except UbR54L exhibited altered kinetics for E1-catalyzed ATP:PPi exchange compared to wild-type ubiquitin. In addition, the UbR72L mutant altered the mechanism of E1 from strictly order addition of substrates to random addition with respect to ATP and ubiquitin. Values for the intrinsic Kd of ubiquitin binding were determined by coupling the net forward reaction of E1 to the E232K-catalyzed conjugation of histone H2B. Only R54 and R72 residues participate in the initial binding of free ubiquitin, resulting in a 6- or 58-fold increase in Kd for UbR54L or UbR72L, respectively, compared to wild type. More significant effects of the UbR42L and UbR72L mutants were observed for binding of their respective ubiquitin adenylate intermediates within the E1 active site. Wild-type ubiquitin adenylate binds to E1 with an estimated Kd or = 7 kcal/mol.(ABSTRACT TRUNCATED AT 250 WORDS)

Protein Expression Using Cotranslational Fusion and Cleavage of Ubiquitin

Abstract: Expression of cloned genes in prokaryotes such as Escherichia coli is a widely used technique in both basic research and biotechnology. Despite the availability of several E. coli expression vector systems, adequate levels of expression may not be achieved. Expressing proteins as fusions to the highly conserved eukaryotic protein ubiquitin has been reported by several investigators to enhance protein yield in both bacterial and eukaryotic systems. We have modified this technique by the co-expression in E. coli of a ubiquitin-fusion protein and the Saccharomyces cerevisiae ubiquitin-specific protease Ubp2. This allows the co-translational cleavage of engineered ubiquitin-fusion proteins expressed in E. coli. This system was used to express a human Pi class glutathione S-transferase (GST) GSTPl as well as two mutant GSTPl derivatives, TrpsO+Cys and GlnS2+Glu. The yield of these enzymes was improved 40-fold by using the ubiquitin-fusiodco-translational cleavage technique, and no uncleaved product was detected. The TrpsO+Cys mutant was totally devoid of GST activity, while the activity of the Glns2+Glu mutant was reduced to 6% of wild-type GSTP1-1. As both of the mutated residues map within the glutathione-binding site, the reduced GST activity is consistent with a marked reduction in glutathione binding ability.

Nuclear localization of the ubiquitin-activating enzyme, E1, is cell-cycle-dependent.

Abstract: The mechanisms that regulate ubiquitin-mediated degradation of proteins such as the mitotic cyclins at defined stages of the cell cycle are poorly understood. The initial step in the conjugation of ubiquitin to substrate proteins involves the activation of ubiquitin by the ubiquitin-activating enzyme, E1. Previously we have described the subcellular localization of this enzyme to both nuclear and cytoplasmic compartments. In the present study, we have used the 1C5 anti-E1 monoclonal antibody in immunofluorescent-microscopy and subcellular-fractionation techniques to examine the distribution of E1 during the HeLa cell cycle. E1 is both cytoskeletal and nuclear during the G1-phase. As the cells progress into S-phase, E1 is exclusively cytoskeletal and has a perinuclear distribution. During G2-phase, E1 reappears in the nucleus before breakdown of the nuclear envelope. In mitotic cells, E1 localizes to both the mitotic spindle and the cytosol, but is absent from the chromosomes. Immunoblot analysis reveals multiple forms of E1 in HeLa whole cell extract. This heterogeneity is not a result of polyubiquitination and may represent inactive pools of E1. Only the characteristic E1 doublet is able to activate ubiquitin. Cell-fractionation studies reveal a differential distribution of specific E1 isoforms throughout the cell cycle. Therefore we propose that the subcellular localization of E1 may play a role in regulating cell-cycle-dependent conjugation of ubiquitin to target proteins.

Split ubiquitin protein sensor

Abstract: Disclosed are novel compositions and methods useful for studying interactions between proteins. An N-terminal subdomain and a C-terminal subdomain of ubiquitin are linked to a pair of proteins or peptides to be examined for their ability to interact. When contacted with one another, a quasi-native ubiquitin moiety is reconstituted provided that the protein or peptide pair do, in fact, interact (bind) with one another. The quasi-native ubiquitin moiety is recognized and cleaved by ubiquitin-specific proteases after the last residue of ubiquitin. The cleavage at the quasi-native ubiquitin moiety within a linear protein fusion is the indication of interaction between the protein or peptide pair.

Developmentally regulated loss of ubiquitin and ubiquitinated proteins during pollen maturation in maize

Abstract: Eukaryotic cells typically contain 0.2-1.0% of their total protein as the highly conserved protein ubiquitin, which exists both free and covalently attached to cellular proteins. The attachment of ubiquitin to cellular proteins occurs posttranslationally by a three-enzyme pathway and results in a peptide linkage of the C terminus of ubiquitin either to a lysyl epsilon-amino group of a substrate protein or to a lysyl epsilon-amino group of a previously linked ubiquitin molecule. The multiple conjugation of ubiquitin to substrate proteins via ubiquitin-ubiquitin linkages is thought to be necessary, but not sufficient, for recognition and degradation by a ubiquitin-dependent protease. In higher plant cells the steady-state level of ubiquitinated proteins is generally constant and can be readily detected in all somatic tissues. In contrast, we have found that a developmentally regulated loss of free ubiquitin and ubiquitinated proteins occurs during maize (Zea mays L.) pollen maturation. This dramatic loss of ubiquitin correlates temporally with commitment to the gametophytic developmental program. Northern blot analysis indicates that the loss of ubiquitin is not due to low levels of ubiquitin mRNA, suggesting that a posttranscriptional regulatory mechanism is responsible.

Homologues of wheat ubiquitin-conjugating enzymes--TaUBC1 and TaUBC4 are encoded by small multigene families in Arabidopsis thaliana.

Abstract: Covalent attachment of ubiquitin to other cellular proteins has been implicated in a multitude of diverse physiological processes in eukaryotes including selective protein degradation. This attachment is carried out by a multi-enzyme pathway consisting of three classes of enzymes: ubiquitin-activating enzymes (E1s), ubiquitin-conjugating enzymes (E2s), and ubiquitin-protein ligases (E3s). E2s accept activated ubiquitin from E1 and conjugate it to target proteins with or without the participation of specific E3s. Previously, we have isolated wheat cDNAs encoding 16 and 23 kDa E2s, TaUBC1 and TaUBC4, respectively. TaUBC1 shows structural homology to the yeast RAD6 E2 that is essential for DNA repair whereas TaUBC4 is related to the yeast ScUBC8 E2, both of which effectively conjugate ubiquitin to histones in vitro but as yet are without a known in vivo function. Here, we report the isolation of genomic and cDNA homologues of these genes from Arabidopsis thaliana. In Arabidopsis, both of these E2s are encoded by three member gene families. Members of the AtUBC1 gene family, comprising AtUBC1, 2 and 3, encode 150–152 amino acid proteins that are 83–99% identical to each other and TaUBC1 and contain four introns that are conserved with respect to position. Members of the AtUBC4 gene family, comprising AtUBC4, 5 and 6, encode 187–191 amino acid proteins that are 73–88% identical to each other and TaUBC4 and contain five introns that are conserved with respect to position. In contrast, AtUBC1-3 gene products are only 31–36% identical to those derived from AtUBC4-6. mRNA for each family was detected in Arabidopsis roots, leaves, stems, and flowers indicating that members of each family are expressed in most if not all tissues.

Rescue of the complex temperature-sensitive phenotype of Chinese hamster ovary E36ts20 cells by expression of the human ubiquitin-activating enzyme cDNA.

Abstract: The ubiquitin conjugation system is a multi-step pathway in which ubiquitin is activated and conjugated to acceptor proteins, one function of which is to target acceptor proteins for rapid degradation within the cell. The conjugation system is involved in many aspects of cellular functions, including the cell cycle. Several cell-cycle arrest mutant cell lines have been characterized and appear to harbour a mutant ubiquitin-activating enzyme, E1, as their primary defect. One such cell line is ts20, which is derived from Chinese hamster ovary E36 cells. This cell line has been used to characterize some of the potential functions of the ubiquitin conjugation system in vivo, such as its involvement in the maturation of autophagic vacuoles. The present study describes the complete rescue of the complex ts20 phenotype following the expression of the cDNA for human E1. Stable transfectants expressing the human E1 cDNA in the CMVneo expression vector were measured for ubiquitin-conjugation activity, protein degradation and growth in culture at the nonpermissive temperature. This rescue confirms that the phenotype observed in the ts20 cells is due to a defect in the E1 enzyme. Thus, the ts20 cell line will serve as a useful tool to delineate the functions of the ubiquitin system in vivo.

Overexpression of the gene for polyubiquitin in yeast confers increased secretion of a human leucocyte protease inhibitor.

Abstract: We have found an influence of cellular ubiquitin levels over the secretion of human leucocyte elastase inhibitor (elafin) by Saccharomyces cerevisiae. Inactivation of the UBI4 polyubiquitin gene reduced elafin secretion 3 to 4-fold. Conversely ubiquitin overexpression, by galactose induction of an integrated UBI4 gene under GAL1 promoter control, enhanced elafin secretion 7-fold compared to cells wild-type for ubiquitin genes. This influence of ubiquitin levels is exerted at a post-transcriptional step in elafin gene expression, and may represent a chaperone-like action. Ubiquitin overexpression did not affect production of α-factor and of certain natural yeast extracellular enzymes even though appreciable free ubiquitin became associated with the yeast periplasm.

Ubiquitin conjugating enzyme (E2) fusion proteins

Abstract: A novel class of fusion proteins based on the ubiquitin-conjugating enzyme, or E2, is described. The fusion proteins include, in addition to the E2 activity, a protein binding ligand having a specific affinity for a target protein. It has been discovered that under cytosolic conditions, such E2 fusions will add a ubiquitin moiety to a target protein. Since ubiquitin addition triggers the endogenous cellular protein degradation pathway, such E2 fusion proteins can be used to selectively target proteins in a host for degradation. Thus, E2 fusion proteins genes can be introduced into transgenic organisms to defeat or inhibit natural activities or traits. The E2 fusion proteins can also be used by introduction into hosts for similar effects.

Role of the C-terminus of Saccharomyces cerevisiae ubiquitin-conjugating enzyme (Rad6) in substrate and ubiquitin-protein-ligase (E3-R) interactions.

Abstract: The product of the RAD6 (UBC2) gene of Saccharomyces cerevisiae is a ubiquitin-conjugating enzyme (Rad6) which is implicated in DNA repair, induced mutagenesis, retrotransposition, sporulation and the degradation of proteins with destabilizing N-terminal amino acid residues. Deletion of the 23-residue acidic C-terminus of Rad6 impairs sporulation and N-end rule protein degradation in vivo but does not affect other functions such as DNA repair and induced mutagenesis. We have investigated the role of the C-terminus of Rad6 in in vitro interactions with various substrates and with a putative ubiquitin-protein ligase, E3-R. The removal of the Rad6 C-terminus had significant different effects on enzyme activity for individual substrates. Although the 23-residue truncated Rad6-149 protein had markedly impaired activity for histone H2B and micrococcal nuclease, the activity for cytochrome c was the same as that of the intact Rad6 protein. Similarly, truncation of Rad6 had no effect on its activity for several poor substrates, namely, β-casein, β-lactoglobulin and oxidized RNase. E3-R stimulated the activities of both Rad6 and Rad6-149 for the latter three substrates to similar degrees. E3-R appears to act by enhancing the low intrinsic affinity of Rad6 and Rad6-149 for these substrates. Thus Rad6 can act in three different modes in vitro depending on the substrate, namely unassisted C-terminus-dependent, unassisted C-terminus-independent and E3-R-assisted C-terminus-independent modes. We also examined the results of removing the C-terminal acidic region of Cdc34 (Ubc3), a ubiquitin-conjugating enzyme closely related to Rad6. Truncation of Cdc34 like that of Rad6 had no effect on activity for β-casein, β-lactoglobulin or oxidized RNase in the presence or absence of E3-R.

Ubiquitin-dependent proteolysis in plants - a key metabolic pathway influencing plant-pathogen interaction

Abstract: Ubiquitin-dependent protein degradation is an essential pathway for turnover of cellular proteins under all growth conditions In addition, it may participate in cell differentiation processes which involve extensive tissue remodeling such as erythroid differentiation in vertebrates or insect metamorphosis Because a large number of short-lived cellular substrates for the ubiquitin pathway are regulator molecules, this “housekeeping” system has an influence on many regulatory events