Degradation signals recognized by the Ubc6p-Ubc7p ubiquitin-conjugating enzyme pair.

Proteolysis by the ubiquitin-proteasome system is highly selective. Specificity is achieved by the cooperation of diverse ubiquitin-conjugating enzymes (Ubcs or E2s) with a variety of ubiquitin ligases (E3s) and other ancillary factors. These recognize degradation signals characteristic of their target proteins. In a previous investigation, we identified signals directing the degradation of beta-galactosidase and Ura3p fusion proteins via a subsidiary pathway of the ubiquitin-proteasome system involving Ubc6p and Ubc7p. This pathway has recently been shown to be essential for the degradation of misfolded and regulated proteins in the endoplasmic reticulum (ER) lumen and membrane, which are transported to the cytoplasm via the Sec61p translocon. Mutant backgrounds which prevent retrograde transport of ER proteins (hrd1/der3Delta and sec61-2) did not inhibit the degradation of the beta-galactosidase and Ura3p fusions carrying Ubc6p/Ubc7p pathway signals. We therefore conclude that the ubiquitination of these fusion proteins takes place on the cytosolic face of the ER without prior transfer to the ER lumen. The contributions of different sequence elements to a 16-amino-acid-residue Ubc6p-Ubc7p-specific signal were analyzed by mutation. A patch of bulky hydrophobic residues was an essential element. In addition, positively charged residues were found to be essential. Unexpectedly, certain substitutions of bulky hydrophobic or positively charged residues with alanine created novel degradation signals, channeling the degradation of fusion proteins to an unidentified proteasomal pathway not involving Ubc6p and Ubc7p.

Heat-induced cell cycle arrest of Saccharomyces cerevisiae: involvement of the RAD6/UBC2 and WSC2 genes in its reversal.

The Saccharomyces cerevisiae RAD6 (UBC2 ) gene encodes a ubiquitin-conjugating enzyme that is involved in a wide range of cellular processes including DNA repair, sporulation and N-end rule protein degradation. Under mild heat stress conditions (37-38 degrees C) rad6 null and rad6-149 mutant cells are unable to grow. The molecular basis for this failure to grow is unknown. Here we show that the heat sensitivity of rad6 mutants is not due to cell death but to an inability to progress in the cell cycle. The temperature-induced cell cycle arrest of these mutants is due to a block in a branch of the RAD6 pathway distinct from the DNA repair and the N-end rule protein degradation pathways. Wild-type cells heated to 38 degrees C arrest transiently in the late G1 phase and then resume growth. At 38 degrees C rad6 mutant cells arrest in late G1 but, unlike wild-type cells, are unable to resume cell cycle progression. In both wild-type and in rad6 mutant cells, CLN1 and CLN2 transcript levels fall sharply upon temperature increase. In wild-type cells levels of these transcripts recover rapidly, whereas in the rad6 mutant they recover slowly. As rad6 cells remain arrested even after CLN1 and CLN2 mRNAs regain their preheat stress levels, factors additional to reduced G1 cyclin gene expression must cause the temperature-induced cell cycle block of the mutant. To identify genes involved in the relief of the cell cycle arrest under heat stress, we screened a multicopy yeast genomic library for clones that restore the growth of the rad6-149 mutant. A plasmid was isolated carrying the WSC2 gene, which is closely related to WSC1/SLG1/HCS77, a putative membrane heat sensor. Overexpression of WSC2 reverses the heat-induced cell cycle arrest of rad6-149 but not of rad6 null mutants. Taken together the findings point to the existence of an unidentified heat stress-activated cell cycle checkpoint pathway, which is antagonized by Rad6p by a mechanism also involving Wsc2p.

Degradation signals for ubiquitin system proteolysis in Saccharomyces cerevisiae.

Combinations of different ubiquitin-conjugating (Ubc) enzymes and other factors constitute subsidiary pathways of the ubiquitin system, each of which ubiquitinates a specific subset of proteins. There is evidence that certain sequence elements or structural motifs of target proteins are degradation signals which mark them for ubiquitination by a particular branch of the ubiquitin system and for subsequent degradation. Our aim was to devise a way of searching systematically for degradation signals and to determine to which ubiquitin system subpathways they direct the proteins. We have constructed two reporter gene libraries based on the lacZ or URA3 genes which, in Saccharomyces cerevisiae, express fusion proteins with a wide variety of C-terminal extensions. From these, we have isolated clones producing unstable fusion proteins which are stabilized in various ubc mutants. Among these are 10 clones whose products are stabilized in ubc6, ubc7 or ubc6ubc7 double mutants. The C-terminal extensions of these clones, which vary in length from 16 to 50 amino acid residues, are presumed to contain degradation signals channeling proteins for degradation via the UBC6 and/or UBC7 subpathways of the ubiquitin system. Some of these C-terminal tails share similar sequence motifs, and a feature common to almost all of these sequences is a highly hydrophobic region such as is usually located inside globular proteins or inserted into membranes.

Role of the conserved carboxy-terminal alpha-helix of Rad6p in ubiquitination and DNA repair.

RAD6 in the yeast Saccharomyces cerevisiae encodes a ubiquitin-conjugating enzyme essential for DNA repair as well as for a number of other biological processes. It is believed that the functions of Rad6p require the ubiquitination of target proteins, but its substrates as well as other interacting proteins are largely unknown. Rad6p homologues of higher eukaryotes have a number of amino acid residues in the C-terminal alpha-helix, which are conserved from yeast to man but are absent from most other yeast ubiquitin-conjugating enzymes (Ubcs). This specific conservation suggests that the C-terminal alpha-helix is important for the unique activities of the Rad6p family of Ubcs. We have investigated the effects of mutating this highly conserved region on the ubiquitination of model substrates in vitro and on error-free DNA repair in vivo. C-terminal point and deletion mutants of Rad6p differentially affected its in vitro activity on various substrates, raising the possibility that Rad6p interacts with its substrates in vivo by similar mechanisms. The distal part of the C-terminal alpha-helix is also essential for error-free DNA repair in vivo. Overexpression of Rad18p, a single-stranded DNA-binding protein that also interacts with Rad6p, alleviates the DNA repair defects of the C-terminal alpha-helix mutants to different degrees. This indicates that the C-terminal alpha-helix of Rad6p mediates its interaction with Rad18p, an essential step in DNA repair. Models of Rad6p action propose that its ubiquitination function is followed by proteolysis of unknown ubiquitinated targets. Mutants affecting several functions of the 26S proteasome retain wild-type capacity for error-free DNA repair. This raises the possibility that ubiquitination by Rad6p in DNA repair does not target proteins for proteasomal degradation.

Regulated degradation of the transcription factor Gcn4.

We report that Gcn4, a yeast transcriptional activator of the bZIP family involved in the regulation of the biosynthesis of amino acids and purines, is rapidly turned over. This degradation is inhibited under conditions of starvation for amino acids. Degradation is also inhibited by single amino acid alterations in a region adjacent to the Gcn4 activation domain. Furthermore, we show that degradation of Gcn4 proceeds through the ubiquitin pathway, a major proteolytic system for cytoplasmic proteins, and is dependent on two specific ubiquitin conjugating enzymes, Cdc34 (Ubc3) and Rad6 (Ubc2). As a first step towards reconstituting the Gcn4 degradation pathway in vitro, we show that purified Cdc34 and Rad6 proteins are able to direct the specific ubiquitination of Gcn4.

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

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, beta-casein, beta-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 beta-casein, beta-lactoglobulin or oxidized RNase in the presence or absence of E3-R.

Selective ubiquitination of calmodulin by UBC4 and a putative ubiquitin protein ligase (E3) from Saccharomyces cerevisiae.

A putative ubiquitin protein ligase (E3-CaM) which cooperates with UBC4 in selectively ubiquitinating calmodulin has been partially purified from Saccharomyces cerevisiae. Ca2+ was required for this activity and monoubiquitinated calmodulin was the main product of the reaction. The apparent Km of E3-CaM for calmodulin was approximately 1 microM which is of the same order of magnitude as the concentration of calmodulin in yeast cells. Proteins which are good substrates for other E3s (E3 alpha or E3-R) were not ubiquitinated by E3-CaM. Lower but significant activities of E3-CaM were observed when UBC1 replaced UBC4.

RAD6 gene product of Saccharomyces cerevisiae requires a putative ubiquitin protein ligase (E3) for the ubiquitination of certain proteins.

The RAD6 (UBC2) gene of Saccharomyces cerevisiae which is involved in DNA repair, induced mutagenesis, and sporulation, encodes a ubiquitin-conjugating enzyme (E2). Since the RAD6 gene product can transfer ubiquitin directly to histones in vitro without the participation of a ubiquitin protein ligase (E3), it has been suggested that in vivo it also acts by the unassisted conjugation of ubiquitin to histones or to other target proteins. Here we show that the RAD6 protein can ligate ubiquitin in vitro to a hitherto unknown set of exogenous target proteins (alpha-, beta-, and kappa-casein and beta-lactoglobulin) when supplemented by a putative ubiquitin protein ligase (E3-R) from S. cerevisiae. RAD6 supplemented with E3-R ligates 1 or, sometimes, 2 ubiquitin molecules to the target protein molecule. UBC3 (CDC34) protein in the presence of E3-R has barely detectable activity on the non-histone substrates. Other ubiquitin-conjugating enzymes tested (products of the UBC1 and UBC4 genes) do not cooperate with E3-R in conjugating ubiquitin to the same substrates. Thus, E3-R apparently interacts selectively with RAD6 protein. These findings suggest that some of the in vivo activities of the RAD6 gene may involve E3-R.

Effect of stress on protein degradation: role of the ubiquitin system.

Many factors which induce the stress response (heat shock protein synthesis) in eukaryotes also cause the formation of aberrant proteins. Such aberrant proteins are usually rapidly and selectively degraded in cells. Temperature step-up accelerates the degradation of a subset of normally stable proteins. This effect is transient and is confined to a narrow range of heat shock temperatures above which proteolysis is inhibited. The time course and extent of proteolysis elicited by a mild heat shock is consistent with data on the thermal transitions of cellular proteins. Biochemical and genetic evidence strongly supports the view that the ubiquitin system is primarily responsible for heat- or stress-damaged protein degradation in eukaryotic cells. It still remains to be determined how stress-damaged proteins are recognized by the ubiquitin system and selected for degradation. Ubiquitin-protein ligases (E3's) which attach multi-ubiquitin chains to proteins are thought to be responsible for the selection of proteins for degradation. Several species of E3 have recently been characterized. However, none of the known E3's seems to fulfil the role of selecting aberrant proteins for breakdown. Heat shock proteins which are thought to repair unfolded or misfolded proteins probably have a complementary function to the ubiquitin system which destroys damage proteins. The relationship between the ubiquitin system and the regulation of heat shock protein synthesis, which is still not understood, is discussed.

Ubiquitin in Chlamydomonas reinhardii. Distribution in the cell and effect of heat shock and photoinhibition on its conjugate pattern.

Ubiquitin, a highly conserved 76-amino-acid protein, is involved in the response of many types of eukaryotic cells to stress but little is known about its role in lower plants. In the present study we have investigated the distribution of ubiquitin in the unicellular alga Chlamydomonas reinhardii as well as the effect of heat and light stress on its conjugation to cellular proteins. Immunoelectron microscopy shows that ubiquitin is located in the chloroplast, nucleus, cytoplasm, pyrenoid and on the plasma membrane. The location of ubiquitin within chloroplasts has not been observed previously. In immunoblots of whole cell extracts with an antibody to ubiquitin a prominent conjugate band with an apparent molecular mass of 29 kDa and a broad region of high-molecular-mass conjugates (apparent molecular mass greater than 45 kDa) were observed. Exposure of cells to a 41.5 degrees C heat shock in both the dark and light caused the disappearance of the 29-kDa conjugate and an increase in the high-molecular-mass conjugates. After step down to 25 degrees C the 29-kDa conjugate reappeared while the levels of high-molecular-mass conjugates decreased. In light, the recovery of the 29-kDa band was more rapid than in the dark. Photoinhibition alters the ubiquitin conjugation pattern similarly to heat shock, but to a lesser degree. These observations imply that, in Chlamydomonas, ubiquitin has a role in the chloroplast and in the response to heat and light stress.

Modulation of protein degradation in mammalian cells by ligands and stress.

Two types of environmental effect on intracellular proteolysis in mammalian cells are surveyed. One is the effect of products on the in vivo half-lives of certain enzymes. The other is the effect of stress on the degradation of cellular proteins. The degradation rates of glutamine synthetase (GS), ornithine decarboxylase (ODC) and 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase are markedly accelerated by their products. The ligand binding sites responsible for the product-accelerated degradation of the enzymes are unknown. In all three cases the labilizing effect of the product molecule is not due to its attachment to the catalytic site. The modes of action of product molecules on GS and ODC degradation have many features in common. Heat shock or other stress cause damage to cellular proteins and induce the synthesis of a small set of heat shock proteins (hsp). Many stressing agents or conditions also accelerate the breakdown of cellular proteins. Current evidence supports the view that the ubiquitin system is responsible for the disposal of aberrant proteins formed by stress. Many observations support the hypothesis that hsp gene expression is induced when abnormal proteins are produced in amounts that exceed the cell's degradative capacity. However, it is still not clear how aberrant proteins induce hsp.

A Chinese hamster cell cycle mutant arrested at G2 phase has a temperature-sensitive ubiquitin-activating enzyme, E1.

The effect of restrictive temperature on ubiquitin conjugation activity has been studied in cells of ts20, a temperature-sensitive cell cycle mutant of the Chinese hamster cell line E36. Ts20 is arrested in early G2 phase at nonpermissive temperature. Immunoblotting with antibodies to ubiquitin conjugates shows that conjugates disappear rapidly at restrictive temperatures in ts20 mutant but not in wild type E36 cells. The incorporation of 125I-ubiquitin into permeabilized ts20 cells is temperature-sensitive. Addition of extracts of another G2 phase mutant, FM3A ts85, with a temperature-sensitive ubiquitin activation enzyme (E1), to permeabilized ts20 cells at restrictive temperatures fails to complement their ubiquitin ligation activity. This indicates that the lesions in the two mutants are similar. Purified E1 from reticulocytes restores the conjugation activity of heat-inactivated permeabilized ts20 cells. Ubiquitin conjugation activity of cell-free extracts of ts20 cells was temperature-sensitive and could be restored by adding purified reticulocyte E1. Purified reticulocyte E2 or E3, on the other hand, did not restore the ubiquitin conjugation activity of heat-treated ts20 extracts. These results are consistent with the conclusion that ts20 has temperature-sensitive ubiquitin-activating enzyme (E1). The fact that two E1 mutants (ts20 and ts85) derived from different cell lines are arrested at the S/G2 boundary at restrictive temperatures strongly indicates that ubiquitin ligation is necessary for passage through this part of the cell cycle. The temperature thresholds of heat shock protein synthesis of ts20 and wild type E36 cells were identical. The implications of these findings with respect to a suggested role of ubiquitin in coupling between protein denaturation and the heat shock response are discussed.

Effect of heat shock on protein degradation in mammalian cells: involvement of the ubiquitin system.

Exposure of cultured rat hepatoma (HTC) cells to a 43 degrees C heat shock transiently accelerates the degradation of the long-lived fraction of cellular proteins. The rapid phase of proteolysis which lasts approximately 2 h after temperature step-up is followed by a slower phase of proteolysis. During the first 2 h after temperature step-up there is a wave of ubiquitin conjugation to cellular proteins which is accompanied by a fall in ubiquitin and ubiquitinated histone 2A (uH2A) levels. Upon continued incubation at 43 degrees C the levels of ubiquitin conjugates fall with a corresponding increase of ubiquitin and uH2A to initial levels. The burst of protein degradation and ubiquitin conjugation after temperature step-up is not affected by the inhibition of heat shock protein synthesis. Cells of the FM3A ts85 mutant, which have a thermolabile ubiquitin activating enzyme (E1), do not accelerate protein degradation in response to a 43 degrees C heat shock, whereas wild-type FM3A mouse cells do. This observation indicates that the ubiquitin system is involved in the degradation of heat-denatured proteins. Sequential temperature jump experiments show that the extent of proteolysis at temperatures up to 43 degrees C is related to the final temperature and not to the number of steps taken to attain it. Temperature step-up to 45 degrees C causes the inhibition of intracellular proteolysis. We propose the following explanation of the above observations. Heat shock causes the conformational change or denaturation of a subset of proteins stable at normal temperatures.(ABSTRACT TRUNCATED AT 250 WORDS)

Conjugation of [125I]ubiquitin to cellular proteins in permeabilized mammalian cells: comparison of mitotic and interphase cells.

[125I]Ubiquitin introduced into permeabilized hepatoma tissue culture (HTC) cells rapidly forms conjugates with endogenous proteins. A characteristic pattern of low mol. wt conjugates is obtained which includes the ubiquitinated histone, uH2A, and unknown molecular species with MrS of 14, 23, 26 (two bands) and 29 kd. A broad spectrum of higher mol. wt conjugates is also produced. The formation of all conjugates is absolutely dependent on ATP, and upon depletion of ATP they are rapidly broken down. The 14, 23 and 29 kd species are found in all subcellular fractions examined. uH2A is located exclusively in the nuclear fraction. The pair of 26 kd bands is specifically associated with the ribosome fraction. A considerable percentage of the higher mol. wt conjugates sediments with the small particle (100,000 g) fraction in the ultracentrifuge but is solubilized with deoxycholate, indicating that there are many membrane-associated conjugates. The pattern of ubiquitin conjugation in interphase and metaphase cells was compared. The incorporation of ubiquitin into uH2A was markedly reduced in metaphase cells whereas its incorporation into other low mol. wt conjugates and into high mol. wt conjugates was affected slightly, if at all. This shows that the known decrease of uH2A levels in metaphase is due to a specific effect on histone ubiquitination and not to a general decrease in ubiquitination activity or increase of isopeptidase activity. Changes in the levels of uH2A during mitosis measured by immunoblotting were similar to those estimated in permeabilized cells. These experiments indicate that permeabilized cells provide a useful approach to the study of rapidly turning over ubiquitin conjugates in mammalian cells.

Effects of denaturation and methylation on the degradation of proteins in cultured hepatoma cells and in reticulocyte cell-free systems.

Radioiodinated, native and denatured bovine serum albumin (albumin) beta-lactoglobulin and cytochrome c were introduced into hepatoma tissue culture cells by erythrocyte-ghost-mediated microinjection, and their rates of degradation were compared. Denatured albumin was degraded at 20% of the rate of undenatured albumin, denatured beta-lactoglobulin was degraded three times faster than undenatured beta-lactoglobulin, while denatured and undenatured cytochrome c were degraded at the same rate. Thus, denaturation does not affect the rates of intracellular breakdown of microinjected proteins in a simple predictable way. Exhaustive methylation did not inhibit the degradation of denatured beta-lactoglobulin or albumin, indicating that, like their undenatured counterparts, they are not degraded via the ubiquitin pathway. In reticulocyte lysates, in the presence of ATP, denatured albumin and beta-lactoglobulin were broken down at slightly slower rates than the parent proteins. Exhaustive methylation of both denatured and undenatured proteins completely abolished their ATP-dependent breakdown. This inhibition is consistent with the hypothesis that free -NH2 groups are required for the attachment of ubiquitin prior to degradation in this system. Removal of an ammonium sulfate fraction from reticulocyte lysates produces a proteolytic system markedly different from the whole lysate [Speiser, S. & Etlinger, J. D. (1983) Proc. Natl Acad. Sci. USA 80, 3577-3580]. In this system both denatured and undenatured albumin and beta-lactoglobulin were degraded essentially independently of ATP. Methylation only slightly decreased the breakdown of denatured proteins, suggesting that they are not degraded via the ubiquitin pathway. A possible explanation of these results is that removal of the ammonium sulfate fraction unmasks an ATP-independent proteolytic system unrelated to the ubiquitin pathway.

Degradation of microinjected methylated and unmethylated proteins in hepatoma tissue culture cells.

Radioiodinated proteins were introduced into hepatoma tissue culture (HTC) cells by erythrocyte ghost-mediated microinjection, and their degradation was studied. 125I-bovine serum albumin and 125I-lysozyme were degraded with half-lives of about 7 and 11 h, respectively. The process was ATP-dependent. The breakdown of these proteins was not inhibited by the following inhibitors of lysosomal proteolysis: NH4Cl, methylamine, chloroquine, leupeptin, or antipain. Methylation of 94% of the amino groups of bovine serum albumin or 99% of the amino groups of lysozyme had little effect on the rates of their degradation in HTC cells. In contrast, methylation almost completely inhibited the ATP-dependent proteolysis of both proteins in reticulocyte lysates. Methylated bovine serum albumin was not detectably demethylated in HTC cells. It is concluded that in HTC cells, bovine serum albumin and lysozyme are degraded by a nonlysosomal pathway which differs from the ubiquitin-dependent proteolysis system of reticulocytes in that it does not require free amino groups.