Yeast Hct1 recognizes the mitotic cyclin Clb2 and other substrates of the ubiquitin ligase APC.

Ubiquitin-mediated proteolysis has emerged as a key mechanism of regulation in eukaryotic cells. During cell division, a multi-subunit ubiquitin ligase termed the anaphase promoting complex (APC) targets critical regulatory proteins such as securin and mitotic cyclins, and thereby triggers chromosome separation and exit from mitosis. Previous studies in the yeast Saccharomyces cerevisiae identified the conserved WD40 proteins Cdc20 and Hct1 (Cdh1) as substrate-specific activators of the APC, but their precise mechanism of action has remained unclear. This study provides evidence that Hct1 functions as a substrate receptor that recognizes target proteins and recruits them to the APC for ubiquitylation and subsequent proteolysis. By co-immunoprecipitation, we found that Hct1 interacted with the mitotic cyclins Clb2 and Clb3 and the polo-related kinase Cdc5, whereas Cdc20 interacted with the securin Pds1. Failure to interact with Hct1 resulted in stabilization of Clb2. Analysis of Hct1 derivatives identified the C-box, a motif required for APC association of Hct1 and conserved among Cdc20-related proteins. We propose that proteins of the Cdc20 family are substrate recognition subunits of the ubiquitin ligase APC.

Asymmetric spindle pole localization of yeast Cdc15 kinase links mitotic exit and cytokinesis.

The inactivation of mitotic cyclin-dependent kinases (CDKs) during anaphase is a prerequisite for the completion of nuclear division and the onset of cytokinesis [1, 2]. In the budding yeast Saccharomyces cerevisiae, the essential protein kinase Cdc15 [3] together with other proteins of the mitotic exit network (Tem1, Lte1, Cdc5, and Dbf2/Dbf20 [4-7]) activates Cdc14 phosphatase, which triggers cyclin degradation and the accumulation of the CDK inhibitor Sic1 [8]. However, it is still unclear how CDK inactivation promotes cytokinesis. Here, we analyze the properties of Cdc15 kinase during mitotic exit. We found that Cdc15 localized to the spindle pole body (SPB) in a unique pattern. Cdc15 was present at the SPB of the mother cell until late mitosis, when it also associated with the daughter pole. High CDK activity inhibited this association, while dephosphorylation of Cdc15 by Cdc14 phosphatase enabled it. The analysis of Cdc15 derivatives indicated that SPB localization was specifically required for cytokinesis but not for mitotic exit. These results show that Cdc15 has two separate functions during the cell cycle. First, it is required for the activation of Cdc14. CD14, in turn, promotes CDK inactivation and also dephosphorylates of Cdc15. As a consequence, Cdc15 binds to the daughter pole and triggers cytokinesis. Thus, Cdc15 helps to coordinate mitotic exit and cytokinesis.

Control of cyclin ubiquitination by CDK-regulated binding of Hct1 to the anaphase promoting complex.

Proteolysis of mitotic cyclins depends on a multisubunit ubiquitin-protein ligase, the anaphase promoting complex (APC). Proteolysis commences during anaphase, persisting throughout G1 until it is terminated by cyclin-dependent kinases (CDKs) as cells enter S phase. Proteolysis of mitotic cyclins in yeast was shown to require association of the APC with the substrate-specific activator Hct1 (also called Cdh1). Phosphorylation of Hct1 by CDKs blocked the Hct1-APC interaction. The mutual inhibition between APC and CDKs explains how cells suppress mitotic CDK activity during G1 and then establish a period with elevated kinase activity from S phase until anaphase.

Yeast Hct1 is a regulator of Clb2 cyclin proteolysis.

Stage-specific proteolysis of mitotic cyclins is fundamental to eukaryotic cell cycle regulation. We found that yeast Hct1, a conserved protein of eukaryotes, is a necessary and rate-limiting component of this proteolysis pathway. In hct1 mutants, the mitotic cyclin Clb2 is highly stabilized and inappropriately induces DNA replication, while G1 cyclins and other proteolytic substrates remain short-lived. Viability of hct1 mutants depends on SIC1. This and further results suggest that inhibition of cyclin-dependent kinases may compensate for defects in cyclin proteolysis. Remarkably, elevated levels of Hct1 ectopically activate destruction box- and Cdc23-dependent degradation of Clb2 and cause phenotypic effects characteristic for a depletion of M-phase cyclins. Hct1 and the related Cdc20 may function as substrate-specific regulators of proteolysis during mitosis.

A yeast Ubc9 mutant protein with temperature-sensitive in vivo function is subject to conditional proteolysis by a ubiquitin- and proteasome-dependent pathway.

The UBC9 gene of the yeast Saccharomyces cerevisiae is essential for cell viability and encodes a soluble protein of the nucleus that is metabolically stable. Products of mutant alleles selected to confer temperature-sensitive in vivo function were found to be extremely short-lived at the restrictive but long-lived at the permissive condition. An extragenic suppressor mutation was isolated which increased thermoresistance of a ubc9-1 strain. This suppressor turned out to stabilize the mutated gene product, indicating that the physiological activity of ubc9-1 protein is primarily controlled by conditional proteolysis. The labile ubc9-1 protein appears to be a substrate for ubiquitination, and its turnover was substantially reduced by expression of a ubiquitin derivative that interferes with formation of multi-ubiquitin chains. Stabilization resulted also from competitive inhibition of Ubc4-related ubiquitin-conjugating enzymes. Activity of the proteasome complex was crucial to rapid breakdown, whereas vacuolar proteases were dispensable. Thus, the heat-denatured ubc9-1 protein is targeted for proteolysis by the ubiquitin-proteasome pathway and may serve as a useful tool to further define the process by which a misfolded polypeptide is recognized.

Molecular cloning of the cDNA and chromosome localization of the gene for human ubiquitin-conjugating enzyme 9.

We report a novel human gene whose product specifically associates with the negative regulatory domain of the Wilms' tumor gene product (WT1) in a yeast two-hybrid screen and with WT1 in immunoprecipitation and glutathione S-transferase (GST) capture assays. The gene encodes a 17-kDa protein that has 56% amino acid sequence identity with yeast ubiquitin-conjugating enzyme (yUBC) 9, a protein required for cell cycle progression in yeast, and significant identity with other subfamilies of ubiquitin-conjugating enzymes. The human gene fully complements yeast that have a temperature-sensitive yUBC9 gene mutation to fully restore normal growth, indicating that we have cloned a functionally conserved human (h) homolog of yUBC9. Transcripts of hUBC9 of 4.4 kilobases (kb), 2.8 kb, and 1.3 kb were found in all human tissues tested. A single copy of the hUBC9 gene was found and localized to human chromosome 16p13.3. We conclude that hUBC9 retains striking structural and functional conservation with yUBC9 and suggest a possible link of the ubiquitin/proteosome proteolytic pathway and the WT1 transcriptional repressor system.

pMPY-ZAP: a reusable polymerase chain reaction-directed gene disruption cassette for Saccharomyces cerevisiae.

Gene disruption is an important method for genetic analysis in Saccharomyces cerevisiae. We have designed a polymerase chain reaction-directed gene disruption cassette that allows rapid disruption of genes in S. cerevisiae without previously cloning them. In addition, this cassette allows recycling of URA3, generating gene disruptions without the permanent loss of the ura3 marker. An indefinite number of disruptions can therefore be made in the same strain.

Use of polymerase chain reaction epitope tagging for protein tagging in Saccharomyces cerevisiae.

Epitope tagging is the insertion of a short stretch of amino acids constituting an epitope into another protein. Tagged proteins can be identified by Western, immunoprecipitation and immunofluorescence assays using pre-existing antibodies. We have designed vectors containing the URA3 gene flanked by direct repeats of epitope tags. We use the polymerase chain reaction (PCR) to amplify the tag-URA3-tag cassette such that the ends of the PCR fragments possess homology to the gene of interest. In vivo recombination is then used to direct integration of the fragment to the location of interest, and transformants are selected by their Ura+ phenotype. Finally, selection for Ura- cells on 5-fluoro-orotic acid plates yields cells where recombination between the repeated epitopes has 'popped out' the URA3 gene, leaving a single copy of the epitope at the desired location. PCR epitope tagging (PET) provides a rapid and direct technique for tagging that does not require any cloning steps. We have used PET to tag three Saccharomyces cerevisiae proteins, Cln1, Sic1 and Est1.

Role of a ubiquitin-conjugating enzyme in degradation of S- and M-phase cyclins.

Cell cycle progression in eukaryotes is controlled by the p34cdc2/CDC28 protein kinase and its short-lived, phase-specific regulatory subunits called cyclins. In Xenopus oocytes, degradation of M-phase (B-type) cyclins is required for exit from mitosis and is mediated by the ubiquitin-dependent proteolytic system. Here we show that B-type-cyclin degradation in yeast involves an essential nuclear ubiquitin-conjugating enzyme, UBC9. Repression of UBC9 synthesis prevents cell cycle progression at the G2 or early M phase, causing the accumulation of large budded cells with a single nucleus, a short spindle and replicated DNA. In ubc9 mutants both CLB5, an S-phase cyclin, and CLB2, an M-phase cyclin, are stabilized. In wild-type cells the CLB5 protein is unstable throughout the cell cycle, whereas CLB2 turnover occurs only at a specific cell-cycle stage. Thus distinct degradation signals or regulated interaction with the ubiquitin-protein ligase system may determine the cell-cycle specificity of cyclin proteolysis.

A human ubiquitin-conjugating enzyme homologous to yeast UBC8.

Ubiquitin-conjugating enzymes catalyze the covalent attachment of ubiquitin to cellular substrates. Here we describe the isolation of a novel ubiquitin-conjugating enzyme from human placenta and the cloning of the corresponding cDNA. DNA sequencing revealed that this gene, UbcH2, encodes a protein with significant sequence similarity to yeast UBC8. In contrast to a previous report (Qin, S., Nakajima, B., Nomura, M., and Arfin, S. M. (1991) J. Biol. Chem. 266, 15549-15554), we discovered that UBC8 is interrupted by a single intron bearing an unusual branch point sequence. The revised amino acid sequence of yeast UBC8 exhibits 54% amino acid sequence identity to human UbcH2. Moreover, full-length UbcH2 and UBC8 enzymes expressed from their cDNAs show similar enzymatic activities in vitro by catalyzing the ubiquitination of histones, suggesting that the two enzymes may fulfill similar functions in vivo. Interestingly, comparison of the enzymatic activities of a truncated UBC8 (Qin, S., Nakajima, B., Nomura, M. and Arfin, S. M. (1991) J. Biol. Chem. 266, 15549-15554) and of the full-length enzyme (this report) suggests, that the first 12 amino-terminal residues of UBC8 are required for ubiquitination of histones in vitro but not for thiolester formation with ubiquitin. This suggests that the NH2 terminus of UBC8 may be necessary either for substrate recognition or for the transfer of ubiquitin onto substrates. The UbcH2 gene is located on chromosome 7 and shows a complex expression pattern with at least five different mRNAs.

In vivo function of the proteasome in the ubiquitin pathway.

A major eukaryotic proteolytic system is known to require the covalent attachment of ubiquitin to substrates prior to their degradation, yet the proteinase involved remains poorly defined. The proteasome, a large conserved multi-subunit protein complex of the cytosol and the nucleus, has been implicated in a variety of cellular functions. It is shown here that a yeast mutant with a defective proteasome fails to degrade proteins which are subject to ubiquitin-dependent proteolysis in wild-type cells. Thus, the proteasome is part of the ubiquitin system and mediates the degradation of ubiquitin-protein conjugates in vivo.

Ubiquitin as a degradation signal.

For many short-lived eukaryotic proteins, conjugation to ubiquitin, yielding a multiubiquitin chain, is an obligatory pre-degradation step. The conjugated ubiquitin moieties function as a 'secondary' signal for degradation, in that their posttranslational coupling to a substrate protein is mediated by amino acid sequences of the substrate that act as a primary degradation signal. We report that the fusion protein ubiquitin--proline--beta-galactosidase (Ub-P-beta gal) is short-lived in the yeast Saccharomyces cerevisiae because its N-terminal ubiquitin moiety functions as an autonomous, primary degradation signal. This signal mediates the formation of a multiubiquitin chain linked to Lys48 of the N-terminal ubiquitin in Ub-P-beta gal. The degradation of Ub-P-beta gal is shown to require Ubc4, one of at least seven ubiquitin-conjugating enzymes in S.cerevisiae. Our findings provide the first direct evidence that a monoubiquitin moiety can function as an autonomous degradation signal. This generally applicable, cis-acting signal can be used to manipulate the in vivo half-lives of specific intracellular proteins.

Genetic analysis of ubiquitin-dependent protein degradation.

Selective degradation of cellular proteins serves to eliminate abnormal proteins and to mediate the turnover of certain short-lived proteins, many of which have regulatory functions. In eukaryotes a major pathway for selective protein degradation is ATP-dependent and is mediated by the ubiquitin system. This pathway involves substrate recognition by components of a ubiquitin-protein ligase system, covalent attachment of ubiquitin moieties to proteolytic substrates, and subsequent degradation of these conjugates by a multicatalytic protease complex. Recent genetic evidence suggests that the remarkable selectivity of this process is largely controlled at the level of substrate recognition by the ubiquitin ligase system. In Saccharomyces cerevisiae, ubiquitin-conjugating enzymes UBC1, UBC4 and UBC5 have been identified as key components of this highly conserved degradation pathway. Genetic analysis indicates that ubiquitin-dependent proteolysis is essential for cell viability and that UBC4 and UBC5 enzymes are essential components of the eukaryotic stress response.

Drosophila UbcD1 encodes a highly conserved ubiquitin-conjugating enzyme involved in selective protein degradation.

Ubiquitin-dependent selective protein degradation serves to eliminate abnormal proteins and provides controlled short half-lives to certain cellular proteins, including proteins of regulatory function such as phytochrome, yeast MAT alpha 2 repressor, p53 and cyclin. Moreover, ubiquitin-dependent proteolysis is thought to play an essential role during development and in programmed cell death. We have cloned a gene from Drosophila melanogaster, UbcD1, coding for a protein with striking sequence similarity to the yeast ubiquitin-conjugating enzymes UBC4 and UBC5. These closely related yeast enzymes are known to be central components of a major proteolytic pathway of Saccharomyces cerevisiae. By doing a precise open reading frame replacement in the yeast genome we could show that the Drosophila UbcD1 enzyme can functionally substitute for yeast UBC4. UbcD1 driven by the UBC4 promoter rescues growth defects and temperature sensitivity of yeast ubc4 ubc5 double mutant cells. Moreover, expression of UbcD1 restores proteolysis proficiency in the ubc4 ubc5 double mutant, indicating that the Drosophila enzyme also mediates protein degradation. This structural and functional conservation suggests that the UbcD1-UBC4-UBC5 class of enzymes defines a major proteolytic pathway in probably all eukaryotes.