Klavs B. Hendil

Proteasomal Inhibition by α-Synuclein Filaments and Oligomers

A unifying feature of many neurodegenerative disorders is the accumulation of polyubiquitinated protein inclusions in dystrophic neurons, e.g. containing α-synuclein, which is suggestive of an insufficient proteasomal activity. We demonstrate that α-synuclein and 20 S proteasome components co-localize in Lewy bodies and show that subunits from 20 S proteasome particles, in contrast to subunits of the 19 S regulatory complex, bind efficiently to aggregated filamentous but not monomeric α-synuclein. Proteasome binding to insoluble α-synuclein filaments and soluble α-synuclein oligomers results in marked inhibition of its chymotrypsin-like hydrolytic activity through a non-competitive mechanism that is mimicked by model amyloid-Aβ peptide aggregates. Endogenous ligands of aggregated α-synuclein like heat shock protein 70 and glyceraldehyde-6-phosphate dehydrogenase bind filaments and inhibit their anti-proteasomal activity. The inhibitory effect of amyloid aggregates may thus be amenable to modulation by endogenous chaperones and possibly accessible for therapeutic intervention.

A heterodimeric complex that promotes the assembly of mammalian 20S proteasomes

The 26S proteasome is a multisubunit protease responsible for regulated proteolysis in eukaryotic cells. It comprises one catalytic 20S proteasome and two axially positioned 19S regulatory complexes. The 20S proteasome is composed of 28 subunits arranged in a cylindrical particle as four heteroheptameric rings, α1–7β1–7β1–7α1–7 (refs 4, 5), but the mechanism responsible for the assembly of such a complex structure remains elusive. Here we report two chaperones, designated proteasome assembling chaperone-1 (PAC1) and PAC2, that are involved in the maturation of mammalian 20S proteasomes. PAC1 and PAC2 associate as heterodimers with proteasome precursors and are degraded after formation of the 20S proteasome is completed. Overexpression of PAC1 or PAC2 accelerates the formation of precursor proteasomes, whereas knockdown by short interfering RNA impairs it, resulting in poor maturation of 20S proteasomes. Furthermore, the PAC complex provides a scaffold for α-ring formation and keeps the α-rings competent for the subsequent formation of half-proteasomes. Thus, our results identify a mechanism for the correct assembly of 20S proteasomes.

Proteasome Subunits X and Y Alter Peptidase Activities in Opposite Ways to the Interferon-γ-induced Subunits LMP2 and LMP7

Most antigenic peptides presented on major histocompatibility complex class I molecules are generated by proteasomes. Interferon-γ, which stimulates antigen presentation, induces new proteasome β-subunits LMP2 and LMP7, which replace the homologous β-subunits Y (δ) and X (ε). As a result, the capacity of the proteasome to cleave model peptides increases after hydrophobic and basic residues and falls after acidic residues. To clarify the function of these subunits, we examined the effects of overexpressing subunits X (δ) and Y (ε). Transfection of the Y gene into HeLa cells stimulated the proteasomal cleavage after acidic residues without altering other peptidase activities. This effect was proportional to the amount of the Y subunits and opposite to the effect of its homolog, LMP2. Y appears to promote cleavages after acidic residues. Furthermore, in mutants lacking the LMP genes (in contrast to wild-type cells), interferon-γ treatment increased the proteasome content of Y subunits and enhanced postacidic cleavages. Transfection with cDNA for the X subunit reduced hydrolysis after hydrophobic and basic residues, an effect opposite to transfection of LMP2 and LMP7. Surprisingly, transfection of X increased the amounts not only of X, but also of Y, while decreasing LMP2 content. Thus, the loss of the Y subunit upon interferon-γ treatment or LMP2 transfection accounts for the suppression of postacidic cleavages, and the loss of X contributes to the increased hydrolysis after hydrophobic and basic residues. These adaptations should favor the production of the kinds of peptides that are presented on major histocompatibility complex class I molecules.

The role of amino acids and taurine in isosmotic intracellular regulation in Ehrlich ascites mouse tumour cells

Summary1.Ehrlich ascites tumour cells swollen in hypotonic medium reduce their volumes towards that found in isotonic medium.2.This regulation of cell volume implies an adjustment of the intracellular amount of osmotically active substances, i.e. a type of “isosmotic intracellular regulation”.3.Non-protein ninhydrin-positive substances were lost from the cells during this volume regulation.4.Amino acid analyses show that the non-essential amino acids play a significant role in this process.5.The relative decrease in concentration was larger for taurine than for any other measured inorganic and organic substance. The absolute change in intracellular taurine concentration is third only to changes in chloride and potassium. The role of taurine in osmoregulation is similar to that observed in many aquatic invertebrates.6.The steady state distribution of amino acids varies with the magnitude of the Na+ and K+ concentration gradients between the cells and their environment. The ion gradient hypothesis fits our data only if we introduce a leakage pathway for the amino acids which is independent of the amino acid pump and which varies with the cell volume.

The Ubx2 and Ubx3 Cofactors Direct Cdc48 Activity to Proteolytic and Nonproteolytic Ubiquitin-Dependent Processes

Valosin-containing protein, VCP/p97 or Cdc48, is a eukaryotic ATPase involved in membrane fusion, protein transport, and protein degradation. We describe two proteins, Ubx2 and Ubx3, which interact with Cdc48 in fission yeast. Ubx3 is the ortholog of p47/Shp1, a previously described Cdc48 cofactor involved in membrane fusion, whereas Ubx2 is a novel protein. Cdc48 binds the UBX domains present in both Ubx2 and Ubx3, indicating that this domain is a general Cdc48-interacting module. Ubx2 and Ubx3 also interact with ubiquitin chains. Disruption of the ubx3(+)-gene causes both temperature and canavanine sensitivity and stabilizes some ubiquitin-protein conjugates including the CDK inhibitor Rum1, but not a model substrate of the ER-degradation pathway. Moreover the ubx3 null displays synthetic lethality with a pus1 null mutant, a multiubiquitin binding subunit of the 26S proteasome. In contrast, the ubx2 null mutant did not display any obvious protein-degradation phenotype. In conclusion Ubx3/p47 is not, as previously thought, only important for membrane fusion; its also important for the specific degradation of a subset of cell proteins. Our genetic analyses revealed that Ubx3/p47 functionally parallels a substrate receptor of the 26S proteasome, Pus1/Rpn10, indicating that the Cdc48-Ubx3 complex is involved in delivering substrates to the 26S proteasome.

Association of immunoproteasomes with the endoplasmic reticulum.

Proteasomes are complex multisubunit proteases which play a critical role in intracellular proteolysis. Immunoproteasomes, which contain three gamma-interferon-inducible subunits, are a subset of proteasomes which have a specialized function in antigen processing for presentation by the MHC class I pathway. Two of the gamma-interferon inducible subunits, LMP2 and LMP7, are encoded within the MHC class II region adjacent to the two TAP (transporter associated with antigen presentation) genes. We have investigated the localization of immunoproteasomes using monoclonal antibodies to LMP2 and LMP7. Immunoproteasomes were strongly enriched around the endoplasmic reticulum as judged by double-immunofluorescence experiments with anti-calreticulin antibodies, but were also present in the nucleus and throughout the cytosol. In contrast, proteasome subunit C2, which is present in all proteasomes, was found to be evenly distributed throughout the cytoplasm and in the nucleus, as was the delta subunit, which is replaced by LMP2 in immunoproteasomes. gamma-Interferon increased the level of immunoproteasomes, but had no effect on their distribution. Our results provide the first direct evidence that immunoproteasomes are strongly enriched at the endoplasmic reticulum, where they may be located close to the TAP transporter to provide efficient transport of peptides into the lumen of the endoplasmic recticulum for association with MHC class I molecules.

Development and evaluation of a sandwich ELISA for quantification of the 20S proteasome in human plasma

Because quantification of the 20S proteasome by functional activity measurements is difficult and inaccurate, we have developed an indirect sandwich enzyme-linked immunosorbent assays (ELISA) for quantification of the 20S proteasome in human plasma. This sandwich ELISA uses a combination of a monoclonal antibody (mcp 20) recognizing the C2-beta subunit of human 20S proteasome (Mr approximately 30,000) and a polyclonal rabbit anti-20S antibody which labels different subunits of the complex. The detection limit of the assay was established as 10 ng/ml (n=10, mean of zero standard+2 S.D.) and the recovery rate ranged from 96% to 104%. The within-run and between-run coefficients of variation (CV) ranges were 2.8-3.3 and 3.0-3.4, respectively. Using serial dilutions of plasma to which various amounts of purified 20S proteasome were added, a linear dose-response was observed between 102 and 2050 ng/ml with a slope of 1.004 and a coefficient of determination r(2) of 0.99. In a preliminary experiment performed on a limited number of patients, the present assay was used to quantify the 20S proteasome in plasma from healthy subjects (n=11) and from a limited number of patients with various diseases (two patients with each of the following diagnoses: acute myeloid leukaemia, chronic myeloproliferative syndromes, Hodgkins disease and solid tumors). The average concentration of 20S proteasome in plasma from normal subjects was found to be 2319+/-237 ng/ml (n=11). With reference to this normal range, the plasma proteasome concentration was found to be increased in most of these pathological state and as high as 1200% when solid tumors had been detected. For patients with Hodgkins disease, the changes were more variable whereas in patients with chronic lymphocytic leukaemia, the proteasome concentration was raised during the acute phase of disease and decreased during therapy. We suggest that this robust, accurate and highly reproducible assay could be used to quantify proteasome in human plasma and investigate its value as a biological marker for various malignant and nonmalignant diseases.

Ubiquitin binding proteins protect ubiquitin conjugates from disassembly

As a step in their turnover proteins in eukaryotic cells are coupled to a small protein, ubiquitin, before they are recognised by 26S proteasomes and degraded. However, cells also contain many deubiquitinating enzymes, which can rescue proteins by cleaving off the ubiquitin chains. Here we report that three ubiquitin binding proteins, Rhp23, Dph1 and Pus1, from fission yeast can protect multiubiquitin conjugates against deubiquitination. This protection depends on the ubiquitin binding domains and may promote degradation of ubiquitinated proteins.

Thioredoxin Txnl1/TRP32 Is a Redox-active Cofactor of the 26 S Proteasome

The 26 S proteasome is a large proteolytic machine, which degrades most intracellular proteins. We found that thioredoxin, Txnl1/TRP32, binds to Rpn11, a subunit of the regulatory complex of the human 26 S proteasome. Txnl1 is abundant, metabolically stable, and widely expressed and is present in the cytoplasm and nucleus. Txnl1 has thioredoxin activity with a redox potential of about-250 mV. Mutant Txnl1 with one active site cysteine replaced by serine formed disulfide bonds to eEF1A1, a substrate-recruiting factor of the 26 S proteasome. eEF1A1 is therefore a likely physiological substrate. In response to knockdown of Txnl1, ubiquitin-protein conjugates were moderately stabilized. Hence, Txnl1 is the first example of a direct connection between protein reduction and proteolysis, two major intracellular protein quality control mechanisms.

Regulation of NF-κB activity and inducible nitric oxide synthase by regulatory particle non-ATPase subunit 13 (Rpn13)

Human Rpn13, also known as adhesion regulating molecule 1 (ADRM1), was recently identified as a novel 19S proteasome cap-associated protein, which recruits the deubiquitinating enzyme UCH37 to the 26S proteasome. Knockdown of Rpn13 by siRNA does not lead to global accumulation of ubiquitinated cellular proteins or changes in proteasome expression, suggesting that Rpn13 must have a specialized role in proteasome function. Thus, Rpn13 participation in protein degradation, by recruiting UCH37, is rather selective to specific proteins whose degradation critically depends on UCH37 deubiquitination activity. The specific substrates for the Rpn13/UCH37 complex have not been determined. Because of a previous discovery of an interaction between Rpn13 and inducible nitric oxide synthase (iNOS), we hypothesized that iNOS is one of the substrates for the Rpn13/UCH37 complex. In this study, we show that Rpn13 is involved in iNOS degradation and is required for iNOS interaction with the deubiquitination protein UCH37. Furthermore, we discovered that IκB-α, a protein whose proteasomal degradation activates the transcription factor NF-κB, is also a substrate for the Rpn13/UCH37 complex. Thus, this study defines two substrates, with important roles in inflammation and host defense for the Rpn13/UCH37 pathway.