Yeast counterparts of subunits S5a and p58 (S3) of the human 26S proteasome are encoded by two multicopy suppressors of nin1-1

Exploring disease-causing traits for drug repurposing in critically ill COVID-19 patients: A causal inference approach

Despite recent development of vaccines to prevent SARS-CoV-2 infection, treatment of critically ill COVID-19 patients remains an important goal. In principle, genome-wide association studies (GWASs) provide a shortcut to the clinical evidence needed to repurpose existing drugs; however, genes identified frequently lack a causal disease link. We report an alternative method for finding drug repurposing targets, focusing on disease-causing traits beyond immediate disease genetics. Sixty blood cell types and biochemistries, and body mass index, were screened on a cohort of critically ill COVID-19 cases and controls that exhibited mild symptoms after infection, yielding high neutrophil cell count as a possible causal trait for critical illness. Our methodology identified CDK6 and janus kinase (JAK) inhibitors as treatment targets that were validated in an ex vivo neutrophil extracellular trap (NET) formation assay. Our methodology demonstrates the increased power for drug target identification by leveraging large disease-causing trait datasets.

Defects in Mitochondrial Functions Affect the Survival of Yeast Cells Treated with Non-Thermal Plasma

Exposure of living cells to non-thermal plasma produced in various electrical discharges affects cell physiology and often results in cell death. Even though plasma-based techniques have started finding practical applications in biotechnology and medicine, the molecular mechanisms of interaction of cells with plasma remain poorly understood. In this study, the involvement of selected cellular components or pathways in plasma-induced cell killing was studied employing yeast deletion mutants. The changes in yeast sensitivity to plasma-activated water were observed in mutants with the defect in mitochondrial functions, including transport across the outer mitochondrial membrane (∆por1), cardiolipin biosynthesis (∆crd1, ∆pgs1), respiration (ρ⁰) and assumed signaling to the nucleus (∆mdl1, ∆yme1). Together these results indicate that mitochondria play an important role in plasma-activated water cell killing, both as the target of the damage and the participant in the damage signaling, which may lead to the induction of cell protection. On the other hand, our results show that neither mitochondria-ER contact sites, UPR, autophagy, nor proteasome play a major role in the protection of yeast cells from plasma-induced damage.

The pluripotency factor Tex10 finetunes Wnt signaling for PGC and male germline development

Testis-specific transcript 10 (Tex10) is a critical factor for pluripotent stem cell maintenance and preimplantation development. Here, we dissect its late developmental roles in primordial germ cell (PGC) specification and spermatogenesis using cellular and animal models. We discover that Tex10 binds the Wnt negative regulator genes, marked by H3K4me3, at the PGC-like cell (PGCLC) stage in restraining Wnt signaling. Depletion and overexpression of Tex10 hyperactivate and attenuate the Wnt signaling, resulting in compromised and enhanced PGCLC specification efficiency, respectively. Using the Tex10 conditional knockout mouse models combined with single-cell RNA sequencing, we further uncover critical roles of Tex10 in spermatogenesis with Tex10 loss causing reduced sperm number and motility associated with compromised round spermatid formation. Notably, defective spermatogenesis in Tex10 knockout mice correlates with aberrant Wnt signaling upregulation. Therefore, our study establishes Tex10 as a previously unappreciated player in PGC specification and male germline development by fine-tuning Wnt signaling.

¹H, ¹³C and ¹⁵N resonance assignments of the VWA domain of Saccharomyces cerevisiae Rpn10, a regulatory subunit of 26S proteasome

Rpn10 is a ubiquitin receptor of the 26S proteasome, and plays an important role in poly-ubiquitinated proteins recognition in the ubiquitin-proteasome protein degradation pathway. It is located in the 19S regulatory particle and interacts with several subunits of both lid and base complexes. Bioinformatics analysis of yeast Rpn10 suggests that it contains a von Willebrand (VWA domain) and a C-terminal tail containing a Ub-interacting motif. Studies of Saccharomyces cerevisiae Rpn10 suggested that its VWA domain might participate in interactions with subunit from both lid and base subcomplexes of the 19S regulatory particle. Herein, we report the chemical shift assignments of (1)H, (13)C and (15)N atoms of the VWA domain of S. cerevisiae Rpn10, which provide the basis for further structural and functional studies of Rpn10 by solution NMR technique.

The C-terminal residues of Saccharomyces cerevisiae Mec1 are required for its localization, stability, and function

Mec1, a member of the phosphoinositide three-kinase-related kinase (PIKK) family of proteins, is involved in the response to replicative stress and DNA damage and in telomere maintenance. An essential 30 to 35 residue, the FATC domain is found at the C-terminus of all PIKK family members. To investigate the roles of the C-terminal residues of Mec1, we characterized alleles of Saccharomyces cerevisiae mec1 that alter the FATC domain. A change of the terminal tryptophan to alanine resulted in temperature-sensitive growth, sensitivity to hydroxyurea, and diminished kinase activity in vitro. Addition of a terminal glycine or deletion of one, two, or three residues resulted in loss of cell viability and kinase function. Each of these Mec1 derivatives was less stable than wild-type Mec1, eluted abnormally from a size exclusion column, and showed reduced nuclear localization. We identified rpn3-L140P, which encodes a component of the 19S proteasomal regulatory particle of the 26S proteasome, as a suppressor of the temperature-sensitive growth caused by mec1-W2368A. The rpn3-L140P allele acted in a partially dominant fashion. It was not able to suppress the inviability of the C-terminal truncations or additions or the hydroxyurea sensitivity of mec1-W2368A. The rpn3-L140P allele restored Mec1-W2368A to nearly wild-type protein levels at 37°, an effect partially mimicked by the proteasome inhibitor MG-132. Our study supports a role for the C-terminus in Mec1 folding and stability, and suggests a role for the proteasome in regulating Mec1 levels.

A proteasome assembly defect in rpn3 mutants is associated with Rpn11 instability and increased sensitivity to stress

Rpn11 is a proteasome-associated deubiquitinating enzyme that is essential for viability. Recent genetic studies showed that Rpn11 is functionally linked to Rpn10, a major multiubiquitin chain binding receptor in the proteasome. Mutations in Rpn11 and Rpn10 can reduce the level and/or stability of proteasomes, indicating that both proteins influence its structural integrity. To characterize the properties of Rpn11, we examined its interactions with other subunits in the 19S regulatory particle and detected strong binding to Rpn3. Two previously described rpn3 mutants are sensitive to protein translation inhibitors and an amino acid analog. These mutants also display a mitochondrial defect. The abundance of intact proteasomes was significantly reduced in rpn3 mutants, as revealed by strongly reduced binding between 20S catalytic with 19S regulatory particles. Proteasome interaction with the shuttle factor Rad23 was similarly reduced. Consequently, higher levels of multiUb proteins were associated with Rad23, and proteolytic substrates were stabilized. The availability of Rpn11 is important for maintaining adequate levels of intact proteasomes, as its depletion caused growth and proteolytic defects in rpn3. These studies suggest that Rpn11 is stabilized following its incorporation into proteasomes. The instability of Rpn11 and the defects of rpn3 mutants are apparently caused by a failure to recruit Rpn11 into mature proteasomes.

The perpetual movements of anaphase

One of the most extraordinary events in the lifetime of a cell is the coordinated separation of sister chromatids during cell division. This is truly the essence of the entire mitotic process and the reason for the most profound morphological changes in cytoskeleton and nuclear organization that a cell may ever experience. It all occurs within a very short time window known as "anaphase", as if the cell had spent the rest of its existence getting ready for this moment in an ultimate act of survival. And there is a good reason for this: no space for mistakes. Problems in the distribution of chromosomes during cell division have been correlated with aneuploidy, a common feature observed in cancers and several birth defects, and the main cause of spontaneous abortion in humans. In this paper, we critically review the mechanisms of anaphase chromosome motion that resisted the scrutiny of more than 100 years of research, as part of a tribute to the pioneering work of Miguel Mota.

Anchoring of the 26S proteasome to the organellar membrane by FKBP38

FK506-binding protein 38 (FKBP38) is a member of the immunophilin family that resides in the mitochondrial outer membrane and the endoplasmic reticulum (ER) membrane. To investigate the physiological function of FKBP38, we performed a comprehensive search for proteins with which it interacts in human cells by liquid chromatographic and mass spectrometric analysis of FKBP38 immunoprecipitates. Almost all subunits of the 26S proteasome were thus found to interact with FKBP38. In vivo co-immunoprecipitation analyses confirmed that FKBP38 indeed associates with the 26S proteasome via its three tandem tetratricopeptide repeats (TPRs). Binding assays in vitro also revealed that FKBP38 directly interacts with the S4 subunit of the 19S proteasome. Immunofluorescence analysis demonstrated that the subcellular distributions of FKBP38 and the 26S proteasome partially overlapped at mitochondria. Both the abundance and activity of the proteasome in a membrane fraction were markedly reduced for mouse embryonic fibroblasts prepared from Fkbp38(-/-) mice compared with those prepared from wild-type mice. These results suggest that FKBP38 functions to anchor the 26S proteasome at the organellar membrane.

Rpn13p and Rpn14p are involved in the recognition of ubiquitinated Gcn4p by the 26S proteasome

The 26S proteasome, composed of the 20S core and 19S regulatory complexes, is important for the turnover of polyubiquitinated proteins. Each subunit of the complex plays a special role in proteolytic function, including substrate recruitment, deubiquitination, and structural contribution. To assess the function of some non-essential subunits in the 26S proteasome, we isolated the 26S proteasome from deletion strains of RPN13 and RPN14 using TAP affinity purification. The stability of Gcn4p and the accumulation of ubiquitinated Gcn4p were significantly increased, but the affinity in the recognition of proteasome was decreased. In addition, the subcomplexes of the isolated 26S proteasomes from deletion mutants were less stable than that of the wild type. Taken together, our findings indicate that Rpn13p and Rpn14p are involved in the efficient recognition of 26S proteasome for the proteolysis of ubiquitinated Gcn4p.

Proteasome activator enhances survival of Huntington's disease neuronal model cells

In patients with Huntington's disease (HD), the proteolytic activity of the ubiquitin proteasome system (UPS) is reduced in the brain and other tissues. The pathological hallmark of HD is the intraneuronal nuclear protein aggregates of mutant huntingtin. We determined how to enhance UPS function and influence catalytic protein degradation and cell survival in HD. Proteasome activators involved in either the ubiquitinated or the non-ubiquitinated proteolysis were overexpressed in HD patients' skin fibroblasts or mutant huntingtin-expressing striatal neurons. Following compromise of the UPS, overexpression of the proteasome activator subunit PA28γ, but not subunit S5a, recovered proteasome function in the HD cells. PA28γ also improved cell viability in mutant huntingtin-expressing striatal neurons exposed to pathological stressors, such as the excitotoxin quinolinic acid and the reversible proteasome inhibitor MG132. These results demonstrate the specific functional enhancements of the UPS that can provide neuroprotection in HD cells.

Proteasome substrate degradation requires association plus extended peptide

To determine the minimum requirements for substrate recognition and processing by proteasomes, the functional elements of a ubiquitin-independent degradation tag were dissected. The 37-residue C-terminus of ornithine decarboxylase (cODC) is a native degron, which also functions when appended to diverse proteins. Mutating the cysteine 441 residue within cODC impaired its proteasome association in the context of ornithine decarboxylase and prevented the turnover of GFP-cODC in yeast cells. Degradation of GFP-cODC with C441 mutations was restored by providing an alternate proteasome association element via fusion to the Rpn10 proteasome subunit. However, Rpn10-GFP was stable, unless extended by cODC or other peptides of similar size. In vitro reconstitution experiments confirmed the requirement for both proteasome tethering and a loosely structured region. Therefore, cODC and degradation tags in general must serve two functions: proteasome association and a site, consisting of an extended peptide region, used for initiating insertion into the protease.

Adrm1, a putative cell adhesion regulating protein, is a novel proteasome-associated factor

We have identified Adrm1 as a novel component of the regulatory ATPase complex of the 26 S proteasome: Adrm1 was precipitated with an antibody to proteasomes and vice versa. Adrm1 co-migrated with proteasomes on gel-filtration chromatography and non-denaturing polyacrylamide gel electrophoresis. Adrm1 has been described as an interferon-gamma-inducible, heavily glycosylated membrane protein of 110 kDa. However, we found Adrm1 in mouse tissues only as a 42 kDa peptide, corresponding to the mass of the non-glycosylated peptide chain, and it could not be induced in HeLa cells with interferon. Adrm1 was present almost exclusively in soluble 26 S proteasomes, albeit a small fraction was membrane-associated, like proteasomes. Adrm1 was found in cells in amounts equimolar with S6a, a 26 S proteasome subunit. HeLa cells contain no pool of free Adrm1 but recombinant Adrm1 could bind to pre-existing 26 S proteasomes in cell extracts. Adrm1 may be distantly related to the yeast proteasome subunit Rpn13, mutants of which are reported to display no obvious phenotype. Accordingly, knock-down of Adrm1 in HeLa cells had no effect on the amount of proteasomes, or on degradation of bulk cell protein, or accumulation of polyubiquitinylated proteins. This indicates that Adrm1 has a specialised role in proteasome function.

Inositol deacylation by Bst1p is required for the quality control of glycosylphosphatidylinositol-anchored proteins

Misfolded proteins are recognized in the endoplasmic reticulum (ER), transported back to the cytosol, and degraded by the proteasome. A number of proteins are processed and modified by a glycosylphosphatidylinositol (GPI) anchor in the ER, but the quality control mechanisms of GPI-anchored proteins remain unclear. Here, we report on the quality control mechanism of misfolded GPI-anchored proteins. We have constructed a mutant form of the beta-1,3-glucanosyltransferase Gas1p (Gas1*p) as a model misfolded GPI-anchored protein. Gas1*p was modified with a GPI anchor but retained in the ER and was degraded rapidly via the proteasome. Disruption of BST1, which encodes GPI inositol deacylase, caused a delay in the degradation of Gas1*p. This delay was because of an effect on the deacylation activity of Bst1p. Disruption of genes involved in GPI-anchored protein concentration and N-glycan processing caused different effects on the degradation of Gas1*p and a soluble misfolded version of carboxypeptidase Y. Furthermore, Gas1*p associated with both Bst1p and BiP/Kar2p, a molecular chaperone, in vivo. Our data suggest that GPI inositol deacylation plays important roles in the quality control and ER-associated degradation of GPI-anchored proteins.

The simple ultrastructure of the maize kinetochore fits a two-domain model

Light microscope observations suggest there are two discrete biochemical domains in the plant kinetochore, an inner domain containing structural proteins, and an outer domain containing proteins involved in motility. We analyzed the ultrastructure of maize meiotic kinetochores following high pressure freezing and freeze substitution, a method that provides excellent sample preservation. Data from meiosis II support previous descriptions of plant kinetochores as diffuse, nearly invisible domains, sometimes nesting in a cup of darkly staining chromatin. The ultrastructure is similar in meiosis I but there are two sister kinetochores that each protrude away from the chromosome and form their own distinct kinetochore fibers. Microtubules terminate within kinetochores where their ends are splayed in a cone-shaped configuration suggestive of microtubule disassembly. We could not detect any significant substructure within the kinetochore proper. We suggest that the diffuse structure classically defined as the kinetochore represents only the outer domain of a two-domain organelle. The inner domain, known to contain chromatin-binding proteins, probably extends into the electron-dense chromatin of the primary constriction.

Budding yeast Dsk2 protein forms a homodimer via its C-terminal UBA domain

Budding yeast Dsk2 is a family of UbL-UBA proteins that can interact with both polyubiquitin and the proteasome, and is thereby thought to function as a shuttle protein in the ubiquitin-proteasome pathway. Here we show that Dsk2 can homodimerize via its C-terminal UBA domain in the absence of ubiquitin. Dsk2 mutants defective in the UBA domain do not dimerize and do not bind polyubiquitin. The expression of Dsk2 UBA mutants fails to restore the growth defect caused by DSK2 disruption although that of wild-type Dsk2 can restore the defect. These results suggest that Dsk2 homodimerization via the UBA domain plays a role in regulating polyubiquitin binding in the ubiquitin-proteasome pathway.

Mechanisms of delivery of ubiquitylated proteins to the proteasome: new target for anti-cancer therapy?

The proteasome is the main proteolytic machinery of the cell. It is responsible for the basal turnover of many intracellular polypeptides, the elimination of abnormal proteins and the generation of the vast majority of peptides presented by class I major histocompatibility complex molecules. Proteasomal proteolysis is also involved in the control of virtually all cellular functions and major decisions through the spatially and timely regulated destruction of essential cell regulators. Therefore, the elucidation of its molecular mechanisms is crucial for the full understanding of the physiology of cells and whole organisms. Conversely, it is increasingly clear that proteasomal degradation is either altered in numerous pathological situations, including many cancers and diseases resulting from aberrant cell differentiation, or instrumental for the development of these pathologies. This, consequently, makes it an attractive target for therapeutical intervention. There is ample evidence that most cell proteins must be polyubiquitylated prior to proteasomal degradation. If the structure and the mode of functioning of the proteasome, as well as the enzymology of ubiquitylation, are relatively well understood, how substrates are delivered to and recognized by the proteolytic machine has remained mysterious till recently. The recent literature indicates that the mechanisms involved are multiple, complex and exquisitely regulated and provides new potential targets for anti-cancer pharmacological intervention.

Functional Analysis of Rpn6p, a Lid Component of the 26 S Proteasome, Using Temperature-sensitive rpn6 Mutants of the Yeast Saccharomyces cerevisiae

Rpn6p is a component of the lid of the 26 S proteasome. We isolated and analyzed two temperature-sensitive rpn6 mutants in the yeast, Saccharomyces cerevisiae. Both mutants showed defects in protein degradation in vivo. However, the affinity-purified 26 S proteasome of the rpn6 mutants grown at the permissive temperature degraded polyubiquitinated Sic1p efficiently, even at a higher temperature. Interestingly, their enzyme activity was even higher at a higher temperature, indicating that once made mutant proteasomes are stable and have little defect in the proteolytic function. These results suggest that the deficiency in protein degradation observed in vivo is rather due to a defect in the assembly of a holoenzyme at the restrictive temperature. Indeed, both rpn6 mutants grown at the restrictive temperature were defective in assembling the 26 S proteasome. A striking feature of the rpn6 mutants at the restrictive temperature was that there appeared a protein complex composed of only four of the nine lid components, Rpn5p, Rpn8p, Rpn9p, and Rpn11p. Altogether, we conclude that Rpn6p is essential for the integrity/assembly of the lid in the sense that it is necessary for the incorporation of Rpn3p, Rpn7p, Rpn12p, and Sem1p (Rpn15p) into the lid, thereby playing an essential role in the proper function of the 26 S proteasome.

Production of antipolyubiquitin monoclonal antibodies and their use for characterization and isolation of polyubiquitinated proteins

Formation of a Lys48-linked polyubiquitin chain is required for destruction of targeted proteins by the 26S proteasome, whereas formation of a Lys63-linked polyubiquitin chain is required for modulation of protein-protein interaction, enzyme activity, and intracellular localization. In addition, monoubiquitination plays key roles in endocytosis and protein trafficking. To gain a better understanding of the role of polyubiquitination, we attempted to produce monoclonal antibodies against the polyubiquitin chains, two of which were designated as FK1 and FK2 and were extensively characterized. Both FK1 and FK2 antibodies recognize the polyubiquitin moiety but not free ubiquitin, whereas FK2 antibody, but not FK1 antibody, can recognize monoubiquitinated proteins. The FK1/FK2 antibodies can be applied to ELISA for quantification of polyubiquitin chains, to immunocytochemistry for staining of intracellular polyubiquitin chains, and also to immunoaffinity chromatography for isolation of polyubiquitinated proteins. Thus, these two antibodies are useful for isolating polyubiquitin chain-tagged proteins and for probing proteins that are modified through polyubiquitination or monoubiquitination in various cells and tissues under physiological and pathological conditions.

Cloning and characterization of angiocidin, a tumor cell binding protein for thrombospondin-1

Thrombospondin-1 (TSP-1) is a matrix protein that has been implicated in mechanisms of tumor progression. Our laboratory previously showed that the CSVTCG (cys-ser-val-thr-cys-gly) sequence of TSP-1 functioned as a tumor cell adhesion domain and CSVTCG peptides as well as an anti-peptide antibody possessed anti-metastatic activity in a murine model of lung metastasis. In a subsequent study, a putative TSP-1 binding protein from lung carcinoma was isolated by CSVTCG-peptide affinity chromatography. In this study, we present the full-length cDNA of this binding protein isolated from a prostate cancer cell (PC3-NI) cDNA library. The purified recombinant protein, termed angiocidin, is a potent inhibitor of tumor growth of Lewis Lung carcinoma in vivo and tumor invasion and angiogenesis in vitro. In addition, the recombinant protein inhibits tumor and endothelial cell proliferation and induces apoptosis. The activity of angiocidin both in vivo and in vitro is partially dependent on its TSP-1 binding activity, since an angiocidin deletion mutant missing a high affinity-binding site for TSP-1 failed to inhibit tumor growth in vivo and was less active in its anti-tumor and anti-angiogenic activities in vitro. These results suggest that the anti-tumor activity of TSP-1 reported in many studies may be mediated in part by binding proteins such as angiocidin. Such proteins may function as tumor-suppressor proteins, which limit the growth of tumors by inhibiting angiogenesis and cell matrix interaction.

Getting into position: the catalytic mechanisms of protein ubiquitylation

The role of protein ubiquitylation in the control of diverse cellular pathways has recently gained widespread attention. Ubiquitylation not only directs the targeted destruction of tagged proteins by the 26 S proteasome, but it also modulates protein activities, protein-protein interactions and subcellular localization. An understanding of the components involved in protein ubiquitylation (E1s, E2s and E3s) is essential to understand how specificity and regulation are conferred upon these pathways. Much of what we know about the catalytic mechanisms of protein ubiquitylation comes from structural studies of the proteins involved in this process. Indeed, structures of ubiquitin-activating enzymes (E1s) and ubiquitin-conjugating enzymes (E2s) have provided insight into their mechanistic details. E3s (ubiquitin ligases) contain most of the substrate specificity and regulatory elements required for protein ubiquitylation. Although several E3 structures are available, the specific mechanistic role of E3s is still unclear. This review will discuss the different types of ubiquitin signals and how they are generated. Recent advances in the field of protein ubiquitylation will be examined, including the mechanisms of E1, E2 and E3. In particular, we discuss the complexity of molecular recognition required to impose selectivity on substrate selection and topology of poly-ubiquitin chains.

Sem1p Is a Novel Subunit of the 26 S Proteasome from Saccharomyces cerevisiae

The 26 S proteasome, which catalyzes degradation of polyubiquitinated proteins, is composed of the 20 S proteasome and the 19 S regulatory particle (RP). The RP is composed of the lid and base subcomplexes and regulates the catalytic activity of the 20 S proteasome. In this study, we carried out affinity purification of the lid and base subcomplexes from the tagged strains of Saccharomyces cerevisiae, and we found that the lid contains a small molecular mass protein, Sem1. The Sem1 protein binds with the 26 S proteasome isolated from a mutant with deletion of SEM1 but not with the 26 S proteasome from the wild type. The lid lacking Sem1 is unstable at a high salt concentration. The 19 S RP was immunoprecipitated together with Sem1 by immunoprecipitation using hemagglutinin epitope-tagged Sem1 as bait. Degradation of polyubiquitinated proteins in vivo or in vitro is impaired in the Sem1-deficient 26 S proteasome. In addition, genetic interaction between SEM1 and RPN10 was detected. The human Sem1 homologue hDSS1 was found to be a functional homologue of Sem1 and capable of interacting with the human 26 S proteasome. The results suggest that Sem1, possibly hDSS1, is a novel subunit of the 26 S proteasome and plays a role in ubiquitin-dependent proteolysis.

Rpn7 Is Required for the Structural Integrity of the 26 S Proteasome of Saccharomyces cerevisiae

Rpn7 is one of the lid subunits of the 26 S proteasome regulatory particle. The RPN7 gene is known to be essential, but its function remains to be elucidated. To explore the function of Rpn7, we isolated and characterized temperature-sensitive rpn7 mutants. All of the rpn7 mutants obtained accumulated poly-ubiquitinated proteins when grown at the restrictive temperature. The N-end rule substrate (Ub-Arg-beta-galactosidase), the UFD pathway substrate (Ub-Pro-beta-galactosidase), and cell cycle regulators (Pds1 and Clb2) were found to be stabilized in experiments using one of the rpn7 mutants termed rpn7-3 at the restrictive temperature, indicating its defect in the ubiquitin-proteasome pathway. Subsequent analysis of the structure of the 26 S proteasome in rpn7-3 cells suggested that the defect was in the assembly of the 26 S holoenzyme. The most striking characteristic of the proteasome of the rpn7-3 mutant was that a lid subcomplex affinity-purified from the rpn7-3 cells grown at the restrictive temperature contained only 5 of the 8 lid components, a phenomenon that has not been reported in the previously isolated lid mutants. From these results, we concluded that Rpn7 is required for the integrity of the 26 S complex by establishing a correct lid structure.

Purification of the Arabidopsis 26 S Proteasome

The 26 S proteasome is a multisubunit protease complex responsible for degrading a wide range of intracellular proteins in eukaryotes, especially those modified with polyubiquitin chains. It is composed of a self-compartmentalized core protease (CP) that houses the peptidase active sites appended on either or both ends by a regulatory particle (RP) that identifies appropriate substrates and translocates them into the lumen of the CP for breakdown. Here, we describe the molecular and biochemical properties of the 26 S proteasome from the plant Arabidopsis thaliana. Like the CP and the ATPase ring of the RP, the RP non-ATPase subunits are often encoded by two transcriptionally active genes with some pairs displaying sufficient sequence divergence to suggest functional differences. Most RPN subunits could functionally replace their yeast counterparts, implying that they have retained their positions and activities within the complex. A method was developed to purify the 26 S proteasome intact from whole Arabidopsis seedlings. These preparations are biochemically indistinguishable from those from yeast and mammals, including the need for ATP to maintain integrity and a strong sensitivity to the inhibitors MG115, MG132, lactacystin, and epoxomicin. Mass spectrometric analysis of the complex detected the presence of almost all CP and RP subunits. In many cases, both products of paralogous genes were detected, demonstrating that each isoform assembles into the mature particle. As with the yeast and animal 26 S proteasomes, attenuation of individual RP genes induces a coordinated up-regulation of many of the other 26 S proteasome genes, suggesting that plants contain a negative feedback mechanism to regulate the 26 S proteasome levels. The incorporation of paralogous subunits into the Arabidopsis holoprotease raises the intriguing possibility that plants synthesize multiple 26 S proteasome types with unique properties and/or target specificities.

The molecular chaperone Hsp90 plays a role in the assembly and maintenance of the 26S proteasome

Hsp90 has a diverse array of cellular roles including protein folding, stress response and signal transduction. Herein we report a novel function for Hsp90 in the ATP-dependent assembly of the 26S proteasome. Functional loss of Hsp90 using a temperature-sensitive mutant in yeast caused dissociation of the 26S proteasome. Conversely, these dissociated constituents reassembled in Hsp90-dependent fashion both in vivo and in vitro; the process required ATP-hydrolysis and was suppressed by the Hsp90 inhibitor geldanamycin. We also found genetic interactions between Hsp90 and several proteasomal Rpn (Regulatory particle non-ATPase subunit) genes, emphasizing the importance of Hsp90 to the integrity of the 26S proteasome. Our results indicate that Hsp90 interacts with the 26S proteasome and plays a principal role in the assembly and maintenance of the 26S proteasome.

The pleiotropic role of the 26S proteasome subunit RPN10 in Arabidopsis growth and development supports a substrate-specific function in abscisic acid signaling

The 26S proteasome is an essential protease complex responsible for removing most short-lived intracellular proteins, especially those modified with polyubiquitin chains. We show here that an Arabidopsis mutant expressing an altered RPN10 subunit exhibited a pleiotropic phenotype consistent with specific changes in 26S proteasome function. rpn10-1 plants displayed reduced seed germination, growth rate, stamen number, genetic transmission through the male gamete, and hormone-induced cell division, which can be explained partially by a constitutive downregulation of the key cell cycle gene CDKA;1. rpn10-1 also was more sensitive to abscisic acid (ABA), salt, and sucrose stress and to DNA-damaging agents and had decreased sensitivity to cytokinin and auxin. Most of the phenotypes can be explained by a hypersensitivity to ABA, which is reflected at the molecular level by the selective stabilization of the short-lived ABA-signaling protein ABI5. Collectively, these results indicate that RPN10 affects a number of regulatory processes in Arabidopsis likely by directing specific proteins to the 26S proteasome for degradation. A particularly important role may be in regulating the responses to signals promulgated by ABA.

The pleiotropic role of the 26S proteasome subunit RPN10 in Arabidopsis growth and development supports a substrate-specific function in abscisic acid signaling

The 26S proteasome is an essential protease complex responsible for removing most short-lived intracellular proteins, especially those modified with polyubiquitin chains. We show here that an Arabidopsis mutant expressing an altered RPN10 subunit exhibited a pleiotropic phenotype consistent with specific changes in 26S proteasome function. rpn10-1 plants displayed reduced seed germination, growth rate, stamen number, genetic transmission through the male gamete, and hormone-induced cell division, which can be explained partially by a constitutive downregulation of the key cell cycle gene CDKA;1. rpn10-1 also was more sensitive to abscisic acid (ABA), salt, and sucrose stress and to DNA-damaging agents and had decreased sensitivity to cytokinin and auxin. Most of the phenotypes can be explained by a hypersensitivity to ABA, which is reflected at the molecular level by the selective stabilization of the short-lived ABA-signaling protein ABI5. Collectively, these results indicate that RPN10 affects a number of regulatory processes in Arabidopsis likely by directing specific proteins to the 26S proteasome for degradation. A particularly important role may be in regulating the responses to signals promulgated by ABA.

Interaction of NtCDPK1 calcium-dependent protein kinase with NtRpn3 regulatory subunit of the 26S proteasome in Nicotiana tabacum

Using a yeast two-hybrid system, we identified NtRpn3, a regulatory subunit of 26S proteasome, as an interacting protein of NtCDPK1 calcium-dependent protein kinase in Nicotiana tabacum. Rpn3 in yeast is an essential protein involved in proteolysis of cell cycle regulatory proteins, and the carrot homolog of Rpn3 was previously isolated as a nuclear antigen that is mainly expressed in the meristem. NtCDPK1 physically interacts with NtRpn3 in vitro in a Ca2+-independent manner and phosphorylates NtRpn3 in a Ca2+-dependent manner with Mg2+ as a cofactor. NtCDPK1 and NtRpn3 are co-localized in the nucleus, nuclear periphery, and around plasma membrane in vivo. Both NtCDPK1 and AtRpn3, an NtRpn3 homolog of Arabidopsis, are mainly expressed in the rapidly proliferating tissues including shoot and root meristems, and developing floral buds. Virus-induced gene silencing of either NtRpn3 or NtCDPK1 resulted in the phenotypes of abnormal cell morphology and premature cell death in newly emerged leaves. Finally, NtCDPK1 interacts with NtRpn3 in vivo as shown by co-immunoprecipitation. Based on these results, we propose that NtCDPK1 and NtRpn3 are interacting in a common signal transduction pathway possibly for regulation of cell division, differentiation, and cell death in tobacco.

Transferring substrates to the 26S proteasome

Ubiquitin-dependent protein degradation is not only involved in the recycling of amino acids from damaged or misfolded proteins but also represents an essential and deftly controlled mechanism for modulating the levels of key regulatory proteins. Chains of ubiquitin conjugated to a substrate protein specifically target it for degradation by the 26S proteasome, a huge multi-subunit protein complex found in all eukaryotic cells. Recent reports have clarified some of the molecular mechanisms involved in the transfer of ubiquitinated substrates from the ubiquitination machinery to the proteasome. This novel substrate transportation step in the ubiquitin-proteasome pathway seems to occur either directly or indirectly via certain substrate-recruiting proteins and appears to involve chaperones.

Functional characterization of the 11 non-ATPase subunit proteins in the trypanosome 19 S proteasomal regulatory complex

The ubiquitin-proteasome pathway is responsible for selective degradation of short-lived and dysfunctional proteins in eukaryotes. The recently demonstrated presence of a functional 26 S proteasome in Trypanosoma brucei led to the identification and isolation of genes encoding all 11 non-ATPase (Rpn) subunit proteins in the trypanosome 19 S regulatory complex. Using the technique of RNA interference, expression of individual RPN genes was disrupted in the procyclic form of T. brucei, resulting, in each case, in intracellular accumulation of polyubiquitinated protein, cell arrest at the G2/M phase, and eventual cell death. With the exception of Rpn10, depletion of individual Rpn proteins disrupted also trypanosome 19 S complex formation, with the complex virtually depleted in the cell lysate. This functional and structural essentiality of 10 of the 11 Rpn proteins in T. brucei differs significantly from that observed in other organisms. When Rpn10 was deficient in trypanosomes, a 19 S complex without Rpn10 was still formed, whereas cell growth was arrested. This structural dispensability but functional indispensability of Rpn10 may constitute another unique aspect of the proteasomes in T. brucei.

[Structures and functions of the 26S proteasome Rpn10 family]

The ubiquitin-dependent proteolytic pathway is thought to be one of the vital systems for cellular regulations, including control of the cell cycle, differentiation and apoptosis. In this pathway, poly-ubiquitinated proteins are selectively degraded by the 26S proteasome, a multisubunit proteolytic machinery. Recognition of the poly-ubiquitin chain by the 26S proteasome should be a key step leading to the selective degradation of target proteins, and the Rpn10 subunit of the 26S proteasome has been shown to preferentially bind the poly-ubiquitin chain in vitro. We previously reported that the mouse Rpn10 mRNA family is generated from a single gene by developmentally regulated, alternative splicing. To determine whether such alternative splicing mechanisms occur in organisms other than the mouse, we searched for Rpn10 isoforms in various species. Here we summarize the gene organization of the Rpn10 in lower species and provide evidence that the competence for generating all distinct forms of Rpn10 alternative splicing has expanded through evolution. Some of the Rpn10 family genes were found to be expressed in distinct developmental stages, suggesting that they have distinct functions during embryogenesis. For example, Rpn10c and Rpn10e were exclusively expressed at specific developmental stages and in specific tissues, while Rpn10a was expressed constitutively. Our experimental results indicate that the respective Rpn10 proteins possess distinct roles in the progression of development. Furthermore, some of the Rpn10 variants specifically interacted with important developmental regulators.

Identification of ubiquitin-like protein-binding subunits of the 26S proteasome

Ubiquitin-like proteins Rad23 and Dsk2 have recently been shown to be capable of binding both polyubiquitin chains and the 26S proteasome. The ubiquitin-like domains (Ubls) of Rad23 and Dsk2 are indispensable for their interaction with the 26S proteasome, but the proteasome subunits capable of binding the Ubl have not been identified. Here, we report that the Ubls of both Rad23 and Dsk2 can bind with the 19S regulatory particle (RP) of the 26S proteasome in vivo and in vitro. A competition assay using the respective Ubls of Rad23 and Dsk2 revealed that they bind to the RP in a competitive manner. The base subcomplex of the RP was found to have the ability to bind the Ubl. By cross-linking experiments, Rpn1 and Rpn2 were identified as Ubl-binding subunits. Taken together, the results suggest that the Rpn1 and Rpn2 in the base subcomplex form the receptor for the ubiquitin-like protein.

The 26S proteasome Rpn10 gene encoding splicing isoforms: evolutional conservation of the genomic organization in vertebrates

Recognition of polyubiquitinated substrates by the 26S proteasome is a key step in the selective degradation of various cellular proteins. The Rpn10 subunit of the 26S proteasome can bind polyubiquitin conjugates in vitro. We have previously reported the unique diversity of Rpn10, which differs from other multiple proteasome subunits, and that the mouse Rpn10 mRNA family is generated from a single gene by developmentally regulated alternative splicing. To determine whether such alternative splicing mechanisms occur in other species, we searched for Rpn10 isoforms in databases and in our original PCR products. Here we report the genomic organization of the Rpn10 gene in lower vertebrates and provide evidence for the competent generation of distinct forms of Rpn10 by alternative splicing through evolution.

Cell-cycle dependent dynamic change of 26S proteasome distribution in tobacco BY-2 cells

The 26S proteasome is known to play pivotal roles in cell-cycle progression in various eukaryotic cells; however, little is known about its role in higher plants. Here we report that the subcellular distribution of the 26S proteasome is dynamically changed in a cell-cycle dependent manner in tobacco BY-2 cells as determined by immunostaining with anti-Rpn10 (a regulatory PA700 subunit) and anti-20S catalytic proteasome antibodies. The 26S proteasome was found to localize not only in nuclear envelopes and mitotic spindles but also in preprophase bands (PPBs) and phragmoplasts appearing in G(2) and M phases, respectively. MG132, a proteasome inhibitor, exclusively caused cell-cycle arrest not only at the metaphase but also the early stage of PPB formation at the G(2) phase and the collapse of the phragmoplast, which seems to be closely related to proteasome distribution in the cells.

Ubiquitin-like proteins and Rpn10 play cooperative roles in ubiquitin-dependent proteolysis

Rpn10, a subunit of the 26S proteasome, has been proposed to act as a receptor for multiubiquitin chains in ubiquitin-dependent proteolysis. However, studies on RPN10-deleted mutants in yeasts have suggested the presence of other multiubiquitin chain-binding factors functioning in ubiquitin-dependent proteolysis. Here, we report that a mutant with a triple deletion of RAD23, DSK2, and RPN10 genes accumulates large amounts of polyubiquitinated proteins, as is the case with a mutant with RAD23 and DSK2 deletions under restrictive conditions. Dsk2, Rad23, and Rpn10 have different capacities to bind multiubiquitin chains. Another ubiquitin-like protein, Ddi1, has similar activity to those of Rad23 and Dsk2. Taken together, the results suggest that ubiquitin-like proteins, Rad23, Dsk2, possibly Ddi1, and Rpn10 play cooperative roles in ubiquitin-dependent proteolysis, serving as multiubiquitin chain-binding proteins.

26 S proteasomes function as stable entities

Most proteins in eukaryotic cells are degraded by 26-S proteasomes, usually after being conjugated to ubiquitin. In the absence of ATP, 26-S proteasomes fall apart into their two sub-complexes, 20-S proteasomes and PA700, which reassemble upon addition of ATP. Conceivably, 26-S proteasomes dissociate and reassemble during initiation of protein degradation in a ternary complex with the substrate, as in the dissociation-reassembly cycles found for ribosomes and the chaperonin GroEL/GroES. Here we followed disassembly and assembly of 26-S proteasomes in cell extracts as the exchange of PA700 subunits between mouse and human 26-S proteasomes. Compared to the rate of proteolysis in the same extract, the disassembly-reassembly cycle was much too slow to present an obligatory step in a degradation cycle. It has been suggested that subunit S5a (Mcb1, Rpn10), which binds poly-ubiquitin substrates, shuttles between a free state and the 26-S proteasome, bringing substrate to the complex. However, S5a was not found in the free state in HeLa cells. Besides, all subunits in PA700, including S5a, exchanged at similar low rates. It therefore seems that 26-S proteasomes function as stable entities during degradation of proteins.

Budding yeast Dsk2p is a polyubiquitin-binding protein that can interact with the proteasome

Dsk2p from Saccharomyces cerevisiae belongs to the class of proteins that contain a ubiquitin-like (UbL) domain at the N terminus together with a ubiquitin-associated (UBA) domain at the C terminus. We show here that the C-terminal UBA domain of Dsk2p binds to K48-linked polyubiquitin chains, and the N-terminal UbL domain of Dsk2p interacts with the proteasome. Overexpression of Dsk2p caused the accumulation of large amounts of polyubiquitin, and extragenic suppressors of the Dsk2p-mediated lethality proved to be temperature-sensitive mutations in two proteasome subunits, rpn1 and pre2. K48-linked ubiquitin-dependent degradation was impaired by disruption of the DSK2 gene. These results indicate that Dsk2p is K48-linked polyubiquitin-binding protein and also interacts with the proteasome. We discuss a possible role of adaptor function of Dsk2p via its UbL and UBA domains in the ubiquitin-proteasome pathway.

Quaternary structure of the ATPase complex of human 26S proteasomes determined by chemical cross-linking

The 26S proteasome is the major protease responsible for nonlysosomal protein degradation in eukaryotic cells. The enzyme is composed of two subparticles: the 20S proteasome, and a 19S regulatory particle (PA700) which binds to the ends of the 20S proteasome cylinder and accounts for ATP dependence and substrate specificity. Among the approximately 18 subunits of PA700 regulator, six are ATPases. The ATPases presumably recognize, unfold, and translocate substrates into the interior of the 26S proteasome. It is generally believed that the ATPases form a hexameric ring. By means of chemical cross-linking, immunoprecipitation, and blotting, we have determined that the ATPases are organized in the order S6-S6'-S10b-S8-S4-S7. Additionally, we found cross-links between the ATPase S10b and the 20S proteasome subunit alpha6. Together with the previously known interaction between S8 and alpha1 and between S4 and alpha7, these data establish the relative orientations of ATPases with respect to the 20S proteasome.

Identification of virulence mutants of the fungal pathogen Cryptococcus neoformans using signature-tagged mutagenesis

Cryptococcus neoformans var. neoformans is an important opportunistic fungal pathogen of patients whose immune system has been compromised due to viral infection, antineoplastic chemotherapy, or tissue transplantation. As many as 13% of all AIDS patients suffer a life-threatening cryptococcal infection at some time during the course of their HIV disease. To begin to understand the molecular basis for virulence in Cryptococcus neoformans var. neoformans serotype A, we have employed signature-tagged mutagenesis (STM) to identify mutants with altered virulence in a mouse model. The critical parameters of signature-tagged mutagenesis in C. neoformans are explored. Data are presented showing that at least 100 different strains can be mixed together in a single animal with each participating in the infection and that there is no apparent interaction between a virulent strain and an avirulent strain in our animal model. Using signature-tagged mutagenesis, we identified 39 mutants with significantly altered growth in a competitive assay. Molecular analyses of these mutants indicated that 19 (49%) contained an insertion in the actin promoter by homologous recombination from a single crossover event, creating a duplication of the actin promoter and the integration of single or multiple copies of the vector. Analysis of the chromosomal insertion sites of those mutants that did not have an integration event in the actin promoter revealed an approximately random distribution among the chromosomes. Individual challenge of the putative mutants in a mouse model revealed five hypovirulent mutants and one hypervirulent mutant.

Genetic dissection of the yeast 26S proteasome: cell cycle defects caused by the Deltarpn9 mutation

Rpn9 is one of the subunits of the regulatory particle of the yeast 26S proteasome and is needed for stability or efficient assembly of the 26S proteasome. As anticipated from the fact that the rpn9 disruptant grew at 25 degrees C but arrested in G2/M phase at 37 degrees C, the CDK inhibitor Sic1p was found to be degraded at the G1/S boundary in the Deltarpn9 cells. The degradation of the anaphase inhibitor Pds1p was delayed in the Deltarpn9 cells. Clb2p in M phase, as well as that ectopically expressed in G1 and S phases, was degraded more slowly in the Deltarpn9 cells than in the wild type cells, indicating that the 26S proteasome lacking Rpn9 uses Sic1p as a better substrate than Pds1p and Clb2p. These results, in addition to the fact that multiubiquitinated proteins were accumulated in the Deltarpn9 cells incubated at 37 degrees C, strongly suggest that Rpn9 is involved in the proteolysis of a subset of the substrates degraded by the 26S proteasome. The Deltarpn9 Deltapds1 double mutant was unable to elongate spindle at a restrictive temperature, suggesting that some protein(s) other than Scc1 (cohesin) should be degraded during progression of anaphase.

A nonproteolytic function of the proteasome is required for the dissociation of Cdc2 and cyclin B at the end of M phase

Inactivation of cyclin B-Cdc2 kinase at the exit from M phase depends on the specific proteolysis of the cyclin B subunit, whereas the Cdc2 subunit remains present at nearly constant levels throughout the cell cycle. It is unknown how Cdc2 escapes degradation when cyclin B is destroyed. In Xenopus egg extracts that reproduce the exit from M phase in vitro, we have found that dissociation of the cyclin B-Cdc2 complex occurred under conditions where cyclin B was tethered to the 26S proteasome but not yet degraded. The dephosphorylation of Thr 161 on Cdc2 was unlikely to be necessary for the dissociation of the two subunits. However, the dissociation was dependent on the presence of a functional destruction box in cyclin B. Cyclin B ubiquitination was also, by itself, not sufficient for separation of Cdc2 and cyclin B. The 26S proteasome, but not the 20S proteasome, was capable of dissociating the two subunits. These results indicate that the cyclin B and Cdc2 subunits are separated by the proteasome through a mechanism that precedes proteolysis of cyclin B and is independent of proteolysis. As a result, cyclin B levels decrease on exit from M phase but Cdc2 levels remain constant.

Developmentally regulated, alternative splicing of the Rpn10 gene generates multiple forms of 26S proteasomes

The 26S proteasome is a multisubunit protein- destroying machinery that degrades ubiquitin-tagged proteins. To date only a single species of Rpn10, which possibly functions as a multiubiquitin chain-binding subunit, has been identified in various organisms. Here we report that mouse Rpn10 mRNAs occur in at least five distinct forms, named Rpn10a to Rpn10e, and that they are generated from a single gene by developmentally regulated, alternative splicing. Rpn10a is ubiquitously expressed, whereas Rpn10e is expressed only in embryos, with the highest levels of expression in the brain. Both forms of Rpn10 are components of the 26S proteasome, with an apparently similar affinity for multiubiquitylated [(125)I]lysozyme in vitro. However, they exert markedly divergent effects on the destruction of B-type cyclin in Xenopus egg extracts. Thus, the 26S proteasome occurs in at least two functionally distinct forms: one containing a ubiquitously expressed Rpn10a and the other a newly identified, embryo-specific Rpn10e. While the former is thought to perform proteolysis constitutively in a wide variety of cells, the latter may play a specialized role in early embryonic development.

The 26S proteasome: a molecular machine designed for controlled proteolysis

In eukaryotic cells, most proteins in the cytosol and nucleus are degraded via the ubiquitin-proteasome pathway. The 26S proteasome is a 2.5-MDa molecular machine built from approximately 31 different subunits, which catalyzes protein degradation. It contains a barrel-shaped proteolytic core complex (the 20S proteasome), capped at one or both ends by 19S regulatory complexes, which recognize ubiquitinated proteins. The regulatory complexes are also implicated in unfolding and translocation of ubiquitinated targets into the interior of the 20S complex, where they are degraded to oligopeptides. Structure, assembly and enzymatic mechanism of the 20S complex have been elucidated, but the functional organization of the 19S complex is less well understood. Most subunits of the 19S complex have been identified, however, specific functions have been assigned to only a few. A low-resolution structure of the 26S proteasome has been obtained by electron microscopy, but the precise arrangement of subunits in the 19S complex is unclear.

Rapid isolation and characterization of the yeast proteasome regulatory complex

The 26S proteasome, which catalyzes degradation of ubiquitinated proteins, is composed of the 20S proteasome and the 19S complex. Recently, it has been reported that the 26S complex can be dissociated into the lid complex and the 20S-proteasome-base complex in a mutant yeast and that the lid complex is required for ubiquitin-dependent proteolysis. In the present study, we established methods for rapid isolation of the 19S complex, the lid complex, and the base complex from wild-type yeast. The isolated 19S complex was capable of binding to the 20S proteasome to reconstitute the 26S proteasome. In contrast with the previously reported result showing that Rpn10, a multiubiquitin chain binding subunit, is a component of the base complex, we present evidence that the lid complex isolated from wild-type yeast contains Rpn10.

Getting in and out of the proteasome

By far the best understood role of the proteasome is to remove ubiquitin-conjugated proteins from eukaryotric cells by hydrolysing them into small peptides of varying lengths. These include both misfolded/abnormal proteins, as well as 'normal' proteins that need to be rapidly removed for regulatory purposes. However, the proteasome is also present in numerous prokaryotic organisms, while ubiquitin, and the ubiquitin conjugating system, are not. The eukaryotic proteasome has been adapted to degrading proteins in a ubiquitin-dependent fashion by the addition of regulatory factors that assemble in different layers onto the proteolytic core of the proteasome, and by increasing the diversity of the core subunits as well. In addition to hydrolysing ubiquitinated proteins into amino acids, the proteasome can also proteolyse selected non-ubiquitinated proteins, process proteins, and possibly refold misfolded proteins. This review will focus on the different proteasome functions, and how these are used in the multiple regulatory roles the proteasome plays in eukaryotic cells.

Analysis of a gene encoding Rpn10 of the fission yeast proteasome reveals that the polyubiquitin-binding site of this subunit is essential when Rpn12/Mts3 activity is compromised

Substrates are targeted for proteolysis by the ubiquitin pathway by the addition of a polyubiquitin chain before being degraded by the 26 S proteasome. Previously, a subunit of the proteasome, S5a, was identified that was able to bind to polyubiquitin in vitro and thus proposed to act as a substrate recognition component. Deletion of the corresponding Saccharomyces cerevisiae gene, MCB1/RPN10, rendered cells viable indicating that other proteasomal polyubiquitin receptors must exist. In this study, we describe pus1(+), the fission yeast homologue of RPN10. This gene is also not required for cell viability; however, the Deltapus1 mutant is synthetically lethal with mutations in other proteasomal component-encoding genes, namely mts3, pad1, and mts4 (RPN12, RPN11, and RPN1). Overexpression of pus1(+) is able to rescue mts3-1 at 32 degrees C but overexpression of a cDNA encoding a version of Pus1 that does not bind to polyubiquitin cannot and leads to greatly reduced viability when used to rescue the mts3-1Deltapus1 double mutant. The Mts3 protein was unable to bind to polyubiquitin in vitro, but the Pus1 and Mts3 proteins were found to bind to one another in vitro, which taken together with the genetic data suggests that they are also closely associated in vivo.

Hybrid proteasomes. Induction by interferon-gamma and contribution to ATP-dependent proteolysis

Eukaryotic cells contain various types of proteasomes. Core 20 S proteasomes (abbreviated 20 S below) have two binding sites for the regulatory particles, PA700 and PA28. PA700-20 S-PA700 complexes are known as 26 S proteasomes and are ATP-dependent machines that degrade cell proteins. PA28 is found both in previously described complexes of the type PA28-20 S-PA28 and in complexes that also contain PA700, as PA700-20 S-PA28. We refer to the latter as "hybrid proteasomes." The relative amounts of the various types of proteasomes in HeLa extracts were determined by a combination of immunoprecipitation and immunoblotting. Hybrid proteasomes accounted for about a fourth of all proteasomes in the extracts. Association of PA28 and proteasomes proved to be ATP-dependent. Hybrid proteasomes catalyzed ATP-dependent degradation of ornithine decarboxylase (ODC) without ubiquitinylation, as do 26 S proteasomes. In contrast, the homo-PA28 complex (PA28-20 S-PA28) was incapable of degrading ODC. Intriguingly, a major immunomodulatory cytokine, interferon-gamma, appreciably enhanced the ODC degradation in HeLa and SW620 cells through induction of the hybrid proteasome, which may also be responsible for the immunological processing of intracellular antigens. Taken together, we report here for the first time the existence of two types of ATP-dependent proteases, the 26 S proteasome and the hybrid proteasome, which appear to share the ATP-dependent proteolytic pathway in mammalian cells.