26S proteasomes are the key enzyme complexes responsible for selective turnover of short-lived and misfolded proteins. Based on the assumption that they are dispersed over the nucleoplasm and cytoplasm in all eukaryotic cells, we wanted to determine the subcellular distribution of 26S proteasomes in living yeast cells. For this purpose, we generated yeast strains that express functional green fluorescent protein (GFP) fusions of proteasomal subunits. An alpha subunit of the proteolytically active 20S core complex of the 26S proteasome, Pre6/YOL038w, as well as an ATPase-type subunit of the regulatory 19S cap complex, Cim5/YOL145w, were tagged with GFP. Both chimeras were shown to be incorporated completely into active 26S proteasomes. Microscopic analysis revealed that GFP-labelled 20S as well as 19S subunits are accumulated mainly in the nuclear envelope (NE)-endoplasmic reticulum (ER) network in yeast. These findings were supported by the co-localization and co-enrichment of 26S proteasomes with NE-ER marker proteins. A major location of proteasomal peptide cleavage activity was visualized in the NE-ER network, indicating that proteasomal degradation takes place mainly in this subcellular compartment in yeast.
Proteasome-catalyzed peptide splicing represents an additional catalytic activity of proteasomes contributing to the pool of MHC-class I-presented epitopes. We here biochemically and functionally characterized a new melanoma gp100 derived spliced epitope. We demonstrate that the gp100mel47–52/40–42 antigenic peptide is generated in vitro and in cellulo by a not yet described proteasomal condensation reaction. gp100mel47–52/40–42 generation is enhanced in the presence of the β5i/LMP7 proteasome-subunit and elicits a peptide-specific CD8+ T cell response. Importantly, we demonstrate that different gp100mel-derived spliced epitopes are generated and presented to CD8+ T cells with efficacies comparable to non-spliced canonical tumor epitopes and that gp100mel-derived spliced epitopes trigger activation of CD8+ T cells found in peripheral blood of half of the melanoma patients tested. Our data suggest that both transpeptidation and condensation reactions contribute to the frequent generation of spliced epitopes also in vivo and that their immune relevance may be comparable to non-spliced epitopes.
Proteasomes are multisubunit proteases that are responsible for regulated proteolysis. The degradation of the proteasomal maturation factor, named Ump1 in yeast, completes the autocatalytic processing of inactive precursor complexes into the proteolytically active core particle (CP) of the proteasome. We have identified Blm3, a conserved nuclear protein, as a new component of Ump1-associated precursor complexes. A lack of Blm3 resulted in an increased rate of precursor processing and an accelerated turnover of Ump1, which suggests that Blm3 prevents premature activation of proteasomal CPs. On the basis of biochemical fractionation experiments combined with in vivo localization studies, we propose that Blm3 joins nascent CPs inside the nucleus to coordinate late stages of proteasome assembly in yeast.
Ubiquitination is a posttranslational modification that regulates many cellular processes including protein degradation, intracellular trafficking, cell signaling, and protein-protein interactions. Deubiquitinating enzymes (DUBs), which reverse the process of ubiquitination, are important regulators of the ubiquitin system. OTUD6B encodes a member of the ovarian tumor domain (OTU)-containing subfamily of deubiquitinating enzymes. Herein, we report biallelic pathogenic variants in OTUD6B in 12 individuals from 6 independent families with an intellectual disability syndrome associated with seizures and dysmorphic features. In subjects with predicted loss-of-function alleles, additional features include global developmental delay, microcephaly, absent speech, hypotonia, growth retardation with prenatal onset, feeding difficulties, structural brain abnormalities, congenital malformations including congenital heart disease, and musculoskeletal features. Homozygous Otud6b knockout mice were subviable, smaller in size, and had congenital heart defects, consistent with the severity of loss-of-function variants in humans. Analysis of peripheral blood mononuclear cells from an affected subject showed reduced incorporation of 19S subunits into 26S proteasomes, decreased chymotrypsin-like activity, and accumulation of ubiquitin-protein conjugates. Our findings suggest a role for OTUD6B in proteasome function, establish that defective OTUD6B function underlies a multisystemic human disorder, and provide additional evidence for the emerging relationship between the ubiquitin system and human disease.
26 S proteasomes fulfill final steps in the ubiquitin-dependent degradation pathway by recognizing and hydrolyzing ubiquitylated proteins. As the 26 S proteasome mainly localizes to the nucleus in yeast, we addressed the question how this 2-MDa multisubunit complex is imported into the nucleus. 26 S proteasomes consist of a 20 S proteolytically active core and 19 S regulatory particles, the latter composed of two subcomplexes, namely the base and lid complexes. We have shown that 20 S core particles are translocated into the nucleus as inactive precursor complexes via the classic karyopherin ␣ import pathway. Here, we provide evidence that nuclear import of base and lid complexes also depends on karyopherin ␣. Potential classic nuclear localization sequences (NLSs) of base subunits were analyzed. Rpn2 and Rpt2, a non-ATPase subunit and an ATPase subunit of the base complex, harbor functional NLSs. The Rpt2 NLS deletion yielded wild type localization. However, the deletion of the Rpn2 NLS resulted in improper nuclear proteasome localization and impaired proteasome function. Our data support the model by which nuclear 26 S proteasomes are assembled from subcomplexes imported by karyopherin ␣.26 S proteasomes are complex macromolecular assemblies essential for regulated protein turnover in eukaryotic organisms ranging from yeasts to mammals. Substrates are shortlived, misfolded proteins, and most of them are targeted to degradation by covalent attachment of polyubiquitin chains.26 S proteasomes are composed of proteolytically active complexes, known as 20 S core particles, and regulatory complexes, called 19 S cap complexes. The 19 S cap complex itself is composed of two subcomplexes, the base and lid complexes. The base complex consists of six AAA-ATPases, numbered from Rpt1 to Rpt6, and two high molecular mass non-ATPases, Rpn1 and Rpn2. Rpn10 connects the base and lid complexes, though it is not essential. The lid complex consists of eight Rpn subunits (1).20 S core particles are only able to degrade peptides and unfolded proteins. Proteolysis of ubiquitylated proteins is ATPdependent and requires the association of 20 S core with 19 S cap complexes, which regulate substrate recognition and unfolding. Ubiquitin moieties of the substrate are recognized by at least two subunits, namely Rpt5 and Rpn10 (2-4). The lid subunit Rpn11 harbors a deubiquitinating metalloprotease activity, which allows ubiquitin peptide recycling before substrate degradation (5, 6). The base ATPases possess chaperone functions, which promote substrate translocation into the catalytic chamber of the core particle (7). Apart from key roles of 19 S cap complexes in proteasomal proteolysis, base complexes were proposed to serve separate functions in transcription control (8). Despite the importance of the 19 S cap complex, the functions of most of its subunits remain unknown. In yeasts 80% of 26 S proteasomes are localized inside the nucleus. Core and cap subunits are present in roughly equal stoichiometry with an abundance of 15,000 -30,00...
The proteasome, the central protease of eukaryotic cells, is composed of one core particle (CP) and one or two adjacent regulatory particles (RP), which contain multiple subunits. Several proteasome-dedicated chaperones govern the assembly of CP and RP, respectively. We sought for proteins that regulate final steps of RP-CP assembly in yeast and found Ecm29, a conserved HEAT-like repeat protein. Here, we show that Ecm29 controls the integrity of RP-CP assemblies. Ecm29 recognizes RP-CP species in which CP maturation is stalled due to the lack of distinct beta subunits. Reconstitution assays revealed that Ecm29 functions as scaffold protein during the remodeling of incompletely matured RP-CP assemblies into regular enzymes. Upon the completion of CP maturation, Ecm29 is degraded and RP-CP is dissociated.
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