The Immunoproteasomes Regulate LPS-Induced TRIF/TRAM Signaling Pathway in Murine Macrophages

We have proposed the novel concept that the macrophage ubiquitin-proteasome pathway functions as a key regulator of Lipopolysaccharide (LPS)-induced inflammation signaling. These findings suggest that proteasome-associated protease subunits X, Y, and Z are replaced by LMP subunits after LPS treatment of RAW 264.7 cells. The objective here was to determine the contribution of selective LMP proteasomal subunits to LPS-induced nitric oxide (NO) and TNF-α production in primary murine macrophages. Accordingly, thioglycollate-elicited macrophages from LMP7, LMP2, LMP10 (MECL-1), and LMP7/MECL-1 double knockout mice were stimulated in vitro with LPS, and were found to generate markedly reduced NO levels compared to wild-type (WT) mice, whereas TNF-α levels responses were essentially unaltered relative to wild-type responses. The recent studies suggest that the TRIF/TRAM pathway is defective in LMP knockouts which may explain why iNOS/NO are not robustly induced in LPS-treated macrophages from knockouts. Treating these macrophages with IFN-γ and LPS, however, reverses this defect, leading to robust NO induction. TNF-α is induced by LPS in the LMP knockout macrophages because IκB and IRAK are degraded normally via the MyD88 pathway. Collectively, these findings strongly support the concept that LMP7/MECL-1 proteasomes subunits actively function to regulate LPS-induced NO production by affecting the TRIF/TRAM pathway.     

Proteasomes on thyroid tissue allotransplantation under induction of donor-specific tolerance in rats

Proteasomes in the liver of August rats (RT1^c) were investigated 30 days after allotransplantation of Wistar rat (RT1^u) thyroid tissue under renal capsule with/without induction of donor-specific tolerance by donor splenocyte intraportal administration. The levels of total proteasome pool, immune proteasomes containing subunits LMP2 and/or LMP7, and proteasome regulators 19S and 11S were defined. Intact and sham-operated August rats were used as control groups. The level of all immune proteasome forms and 11S regulator increased while the level of the total proteasome pool and 19S regulator decreased in the liver of experimental animals compared to the control groups, which indicated changes of liver functional state after transplantation. The 19S/11S ratio increased in the liver of nontolerant rats compared to tolerant animals. In the liver of tolerant rats with accepted grafts, the number of mononuclear cells expressing the immune subunit LMP2 greatly increased in comparison with control and nontolerant animals. Study of accepted grafts showed an increase in the ratio of LMP2/LMP7 immune subunits and 19S/11S regulators in them, compared to the tissue replacing the rejected grafts. Immune proteasomes were almost completely absent from the control intact thyroid tissue, while 19S/11S ratio was maximal in it. Thus, the development of the immune reaction or its suppression are accompanied by a change in the balance between different proteasome forms. Immune subunit LMP7 and 11S regulator are associated with the response against donor tissue. On the contrary, immune subunit LMP2 and 19S regulator are likely to be important for the development of immune tolerance and surviving tissue functioning. Immunofluorescence assay revealed a low content of the immune proteasomes in the follicle cells. Probably, formation of antigens for the major histocompatibility complex class I molecules was impaired by the low content of immune proteasomes, which led to immunological tolerance of hormone-producing follicle cells.     

Interferon-gamma inducible exchanges of 20S proteasome active site subunits: why?

When cells are stimulated with the cytokines IFN-gamma or TNF-alpha, the synthesis of three proteasome subunits LMP2 (beta1i), LMP7 (beta5i), and MECL-1 (beta2i) is induced. These subunits replace the three subunits delta (beta1), MB1 (beta5), and Z (beta2), which bear the catalytically active sites of the proteasome, during proteasome neosynthesis. The cytokine-induced exchanges of three active site subunits of a complex protease is unprecedented in biology and one may expect a strong functional driving force for this system to evolve. These cytokine-induced replacements of proteasome subunits are believed to favour the production of peptide ligands of major histocompatibility complex (MHC) class I molecules for the stimulation of cytotoxic T cells. Although the peptide production by constitutive proteasomes is able to maintain peptide-dependent MHC class I cell surface expression in the absence of LMP2 and LMP7, these subunits were recently shown to be pivotal for the generation or destruction of several unique epitopes. In this review we discuss the recent data on LMP2/LMP7/MECL-1-dependent epitope generation and the functions of each of these subunit exchanges. We propose that these subunit exchanges have evolved not only to optimize class I peptide loading but also to generate LMP2/LMP7/MECL-1-dependent epitopes in inflammatory sites which are not proteolytically generated in uninflamed tissues. This difference in epitope generation may serve to better stimulate T cells in the sites of an ongoing immune response and to avoid autoimmunity in uninflamed tissues.     

Novel propeptide function in 20 S proteasome assembly influences beta subunit composition

The assembly of eukaryotic 20 S proteasomes involves the formation of half-proteasomes where precursor beta-type subunits gather in position on an alpha-subunit ring, followed by the association of two half-proteasomes and beta-subunit processing. In vertebrates three additional beta-subunits (beta1i/LMP2, beta2i/MECL1, and beta5i/LMP7) can be synthesized and substituted for constitutive homologues (beta1/delta, beta2/Z, and beta5/X) to yield immunoproteasomes, which are important for generating certain antigenic peptides. We have shown previously that when all six beta-subunits are present, cooperative assembly mechanisms limit the diversity of proteasome populations. Specifically, LMP7 is incorporated preferentially over X into preproteasomes containing LMP2 and MECL1. We show here that the LMP7 propeptide is responsible for this preferential incorporation, and it also enables LMP7 to incorporate into proteasomes containing delta and Z. In contrast, the X propeptide restricts incorporation to proteasomes with delta and Z. Furthermore, we demonstrate that the LMP7 propeptide can function in trans when expressed on LMP2, and that its NH(2)-terminal and mid-regions are particularly critical for function. In addition to identifying a novel propeptide function, our results raise the possibility that one consequence of LMP7 incorporation into both immunoproteasomes and delta/Z proteasomes may be to increase the diversity of antigenic peptides that can be generated.     

Biogenesis, structure and function of the yeast 20S proteasome.

Intracellular degradation of many eukaryotic proteins requires their covalent ligation to ubiquitin. We previously identified a ubiquitin-dependent degradation pathway in the yeast Saccharomyces cerevisiae, the DOA pathway. Independent work has suggested that a major mechanism of cellular proteolysis involves a large multisubunit protease(s) called the 20S proteasome. We demonstrate here that Doa3 and Doa5, two essential components of the DOA pathway, are subunits of the proteasome. Biochemical analyses of purified mutant proteasomes suggest functions for several conserved proteasome subunit residues. All detectable proteasome particles purified from doa3 or doa5 cells have altered physical properties; however, the mutant particles contain the same 14 different subunits as the wild-type enzyme, indicating that most or all yeast 20S proteasomes comprise a uniform population of hetero-oligomeric complexes rather than a mixture of particles of variable subunit composition. Unexpectedly, we found that the yeast Doa3 and Pre3 subunits are synthesized as precursors which are processed in a manner apparently identical to that of related mammalian proteasome subunits implicated in antigen presentation, suggesting that biogenesis of the proteasome particle is highly conserved between yeast and mammals.     

Redundancy of mammalian proteasome beta subunit function during endoplasmic reticulum associated degradation.

Misfolded proteins in the endoplasmic reticulum (ER) are degraded by N-terminal threonine proteases within the 26S proteasome. Each protease is formed by an activated beta subunit, beta5/X, beta1/Y, or beta2/Z, that exhibits chymotrypsin-like, peptidylglutamyl-peptide hydrolyzing, or trypsin-like activity, respectively. Little is known about the relative contribution of specific beta subunits in the degradation of endogenous protein substrates. Using active site proteasome inhibitors and a reconstituted degradation system, we now show that all three active beta subunits can independently contribute to ER-associated degradation of the cystic fibrosis transmembrane conductance regulator (CFTR). Complete inactivation (>99.5%) of the beta5/X subunit decreased the rate of ATP-dependent conversion of CFTR to trichloroacetic acid soluble fragments by only 40%. Similarly, proteasomes containing only active beta1/Y or beta2/Z subunits degraded CFTR at approximately 50% of the rate observed for fully functional proteasomes. Simultaneous inhibition (>93%) of all three beta subunits blocked CFTR degradation by approximately 90%, and inhibition of both protease and ATPase activities was required to completely prevent generation of small peptide fragments. Our results demonstrate both a conserved hierarchy (ChT-L > PGPH > or = T-L) as well as a redundancy of beta subunit function and provide insight into the mechanism by which active site proteasome inhibitors influence degradation of endogenous protein substrates at the ER membrane.     

The proteasome system in infection: impact of β5 and LMP7 on composition, maturation and quantity of active proteasome complexes

Proteasomes are the major enzyme complexes for non-lysosomal protein degradation in eukaryotic cells. Mammals express two sets of catalytic subunits: the constitutive subunits β1, β2 and β5 and the immunosubunits LMP2 (β1i), MECL-1 (β2i) and LMP7 (β5i). The LMP7-propeptide (proLMP7) is required for optimal maturation of LMP2/MECL-1-containing precursors to mature immunoproteasomes, but can also mediate efficient integration into mixed proteasomes containing β1 and β2. In contrast, the β5-propeptide (proβ5) has been suggested to promote preferential integration into β1/β2-containing precursors, consequently favouring the formation of constitutive proteasomes. Here, we show that proβ5 predominantly promotes integration into LMP2/MECL-1-containing precursors in IFNγ-stimulated, LMP7-deficient cells and infected LMP7-deficient mice. This demonstrates that proβ5 does not direct preferential integration into β1/β2-containing precursors, but instead promotes the formation of mixed LMP2/MECL-1/β5 proteasomes under inflammatory conditions. Moreover, the propeptides substantially differ in their capacity to promote proteasome maturation, with proLMP7 showing a significantly higher chaperone activity as compared to proβ5. Increased efficiency of proteasome maturation mediated by proLMP7 is required for optimal MHC class I cell surface expression and is equally important as the catalytic activity of immunoproteasomes. Intriguingly, induction of LMP7 by infection not only results in rapid exchange of constitutive by immunosubunits, as previously suggested, but also increases the total proteasome abundance within the infected tissue. Hence our data identify a novel LMP7-dependend mechanism to enhance the activity of the proteasome system in infection, which is based on the high chaperone activity of proLMP7 and relies on accelerated maturation of active proteasome complexes.     

Immune proteasomes in the developing rat thymus

The age dynamics of the content of the immune proteasome subunits LMP2 and LMP7 in rat thymus during prenatal and early postnatal ontogeny was studied. The LMP2 and LMP7 immune subunits were detected by Western blotting already by the 18th day of embryonic development, their amount increased to the 21st day to the level characteristic of the postnatal state. Double immunofluorescent labeling showed that in the thymus tissue the largest amount of LMP2 and LMP7 is localized in epithelial cells, whereas the level of their expression in thymocytes is lower. The results suggest that the establishment in thymus of selection processes, which depend on activity of immune proteasomes, can take place already in prenatal ontogeny. Analysis of age dynamics of the natural apoptosis level in thymocytes also favors this supposition. The presence of immune proteasomes in thymocytes during perinatal ontogeny suggests that, besides the antigen presentation, immunoproteasomes may possess other important functions.     

Beta 2 subunit propeptides influence cooperative proteasome assembly

Vertebrate proteasomes are structurally heterogeneous, consisting of both "constitutive" (or "standard") proteasomes and "immunoproteasomes." Constitutive proteasomes contain three ubiquitously expressed catalytic subunits, Delta (beta 1), Z (beta 2), and X (beta 5), whereas immunoproteasomes contain three interferon-gamma-inducible catalytic subunits, LMP2 (beta 1i), MECL (beta 2i), and LMP7 (beta 5i). We recently have demonstrated that proteasome assembly is biased to promote immunoproteasome homogeneity when both types of catalytic subunits are expressed in the same cell. This cooperative assembly is due in part to differences between the LMP7 (beta 5i) and X (beta 5) propeptides. In the current study we demonstrate that differences between the MECL (beta 2i) and Z (beta2) propeptides also influence cooperative assembly. Specifically, replacing the MECL propeptide with that of Z enables MECL incorporation into otherwise constitutive (Delta(+)/X(+)) proteasomes and facilitates X incorporation into otherwise immunoproteasomes (MECL(+)/LMP2(+)). We also show, using MECL(-/-) mice, that LMP2 incorporation does not require MECL, in contrast with previous suggestions that their incorporation is mutually codependent. These results enable us to refine our model for cooperative proteasome assembly by determining which combinations of inducible and constitutive subunits are favored over others, and we propose a mechanism for how propeptides mediate cooperative assembly.     

Proteasomes in the brain of β2-microglobulin knockout mice

MHC class I molecules play an important role in synaptic plasticity of the mammalian nervous system. Proteolytic complexes (proteasomes) produce oligopeptides that are presented on cell surfaces in complexes with MHC class I molecules and regulate many cellular processes beside this. The goal of the present work was to study peculiarities in functioning of proteasomes and associated signaling pathways along with evaluation of NeuN and gFAP expression in different sections of the brain in mice with knockout of β2-microglobulin, a constituent of MHC class I molecules. It was found that the frontal cortex and the brainstem, structures with different ratio of NeuN and gFAP expression, are characterized by opposite changes in the proteasome pool under constant total proteasome levels in B2m-knockout mice in comparison with those in control animals. ChTL-activity as well as expression of LMP7 immune subunit and PA28 regulator of proteasomes was elevated in the cortex of B2m-knockout mice, while these indicators were decreased in the brainstem. The concentrations of the signaling molecules nNOS and HSP70 in B2m-knockout mice were increased in the cortex, while being decreased in the brainstem, and this indicates the possibility of control of expression of the LMP7 subunit and the regulator PA28 by these molecules. Changes in the proteasome pool observed in striatum of B2m-knockout mice are similar to those observed in the brainstem. At the same time, the cerebellum is characterized by a specific pattern of proteasome functioning in comparison with that in all other brain structures. In cerebellum the expression of immune subunits LMP7 and LMP2 and the regulator PA28 was increased, while expression of regulator PA700 was decreased. Deficiency of NeuN and gFAP was revealed in most brain compartments of B2m-knockout mice. Thus, increased expression of the above-mentioned immune subunits and the proteasome regulator PA28 in the cortex and cerebellum may compensate disturbances revealed in the brain structures and the absence of MHC class I molecules. Apparently, this promotes production of peptides necessary for cell-to-cell interactions and maintains nervous system plasticity in B2m-knockout mice.     

Characterisation of the newly identified human Ump1 homologue POMP and analysis of LMP7(beta 5i) incorporation into 20 S proteasomes

Biogenesis of mammalian 20 S proteasomes occurs via precursor complexes containing alpha and unprocessed beta subunits. A human homologue of the yeast proteasome maturation factor Ump1 was identified in 2D gels of 16 S precursor preparations and designated as POMP (proteasome maturation protein). We show that POMP is detected only in precursor fractions and not in fractions containing mature 20 S proteasome. Northern blot experiments revealed that expression of POMP is induced after treatment with interferon gamma. To analyse the role of the beta 5 propeptide for proper maturation and incorporation of the beta 5 subunit into the complex, human T2 cells, which highly express derivatives of the beta 5i subunit (LMP7), were studied. In contrast to yeast, the presence of the beta 5 propeptide is not essential for incorporation of LMP7 into the proteasome complex. Mutated LMP7 subunits either carrying the prosequence of beta 2i (LMP2) or containing a mutation in the active threonine site are incorporated like wild-type LMP7, while a LMP7 derivative lacking the prosequence completely is incorporated to a lesser extent. Although the absence of the prosequence does not affect incorporation of LMP7, its deletion leads to delayed proteasome maturation and thereby to an accumulation of precursor complexes. As a result of the precursor accumulation, an increased amount of the POMP protein can be detected in these cells.     

Human T-cell leukemia virus type 1 Tax protein binds to assembled nuclear proteasomes and enhances their proteolytic activity

The human T-cell leukemia virus type 1 (HTLV-1) Tax protein activates the HTLV-1 long terminal repeat and key regulatory proteins involved in inflammation, activation, and proliferation and may induce cell transformation. Tax is also the immunodominant target antigen for cytotoxic T cells in HTLV-1 infection. We found that Tax bound to assembled nuclear proteasomes, but Tax could not be detected in the cytoplasm. Confocal microscopy revealed a partial colocalization of Tax with nuclear proteasomes. As Tax translocated into the nucleus very quickly after synthesis, this process probably takes place prior to and independent of proteasome association. Tax mutants revealed that both the Tax N and C termini play a role in proteasome binding. We also found that proteasomes from Tax-transfected cells had enhanced proteolytic activity on prototypic peptide substrates. This effect was not due to the induction of the LMP2 and LMP7 proteasome subunits. Furthermore, Tax appeared to be a long-lived protein, with a half-life of around 15 h. These data suggest that the association of Tax with the proteasome and the enhanced proteolytic activity do not target Tax for rapid degradation and may not determine its immunodominance.     

Proteasome subunits are regulated and expressed in comparable concentrations as a functional cluster

The proteasome is the main proteolytic enzyme that functions in the ubiquitin-proteasome system. The 26S proteasome has multi-subunit protease complexes consisting of 20S subunits composed of four seven-numbered rings with two outer rings containing α subunits and two central rings composed of β subunits, and 19S caps of 6 ATPase and 11 non-ATPase subunits; however, it is unclear how these subunits are regulated and the 26S proteasomes assembled. To verify whether each subunit’s mRNA expression is associated with the mRNA expression of other proteasome subunits, we carried out expression analysis of 34 proteasome subunits mRNA on peripheral blood from 75 subjects. The expression of proteasome subunits mRNA was comparable in each individual of the studied population and the mRNA expression has been investigated in each 20S or 19S proteasome. Our results suggest that each type of subunit is regulated by respectively common factors, and that the 20S and 19S proteasomes are regulated by different systems.     

Intermediates in the formation of mouse 20S proteasomes: implications for the assembly of precursor beta subunits.

The assembly of individual proteasome subunits into catalytically active mammalian 20S proteasomes is not well understood. Using subunit-specific antibodies, we characterized both precursor and mature proteasome complexes. Antibodies to PSMA4 (C9) immunoprecipitated complexes composed of alpha, precursor beta and processed beta subunits. However, antibodies to PSMA3 (C8) and PSMB9 (LMP2) immunoprecipitated complexes made up of alpha and precursor beta but no processed beta subunits. These complexes possess short half-lives, are enzymatically inactive and their molecular weight is approximately 300 kDa. Radioactivity chases from these complexes into mature, long-lived approximately 700 kDa proteasomes. Therefore, these structures represent precursor proteasomes and are probably made up of two rings: one containing alpha subunits and the other, precursor beta subunits. The assembly of precursor proteasomes occurs in at least two stages, with precursor beta subunits PSMB2 (C7-I), PSMB3 (C10-II), PSMB7 (Z), PSMB9 (LMP2) and PSMB10 (LMP10) being incorporated before others [PSMB1 (C5), PSMB6 (delta), and PSMB8 (LMP7)]. Proteasome maturation (processing of the beta subunits and juxtaposition of the two beta rings) is accompanied by conformational changes in the (outer) alpha rings, and may be inefficient. Finally, interferon-gamma had no significant effect on the half-lives or total amounts of precursor or mature proteasomes.     

Studies on immunoproteasome in human liver. Part I: Absence in fetuses, presence in normal subjects, and increased levels in chronic active hepatitis and cirrhosis

Despite the central role of proteasomes in relevant physiological pathways and pathological processes, this topic is unexpectedly largely unexplored in human liver. Here we present data on the presence of proteasome and immunoproteasome in human livers from normal adults, fetuses and patients affected by major hepatic diseases such as cirrhosis and chronic active hepatitis. Immunohistochemistry for constitutive (α4 and β1) and inducible (LMP2 and LMP7) proteasome subunits, and for the PA28αβ regulator, was performed in liver samples from 38 normal subjects, 6 fetuses, 2 pediatric cases, and 19 pathological cases (10 chronic active hepatitis and 9 cirrhosis). The immunohistochemical data have been validated and quantified by Western blotting analysis. The most striking result we found was the concomitant presence in hepatocyte cytoplasm of all healthy subjects, including the pediatric cases, of constitutive proteasome and immunoproteasome subunits, as well as PA28αβ. At variance, immunoproteasome was not present in hepatocytes from fetuses, while a strong cytoplasmic and nuclear positivity for LMP2 and LMP7 was found in pathological samples, directly correlated to the histopathological grade of inflammation. At variance from other organs such as the brain, immunoproteasome is present in livers from normal adult and pediatric cases, in apparent absence of pathological processes, suggesting the presence of a peculiar regulation of the proteasome/immunoproteasome system, likely related to the physiological stimuli derived from the gut microbiota after birth. Other inflammatory stimuli contribute in inducing high levels of immunoproteasome in pathological conditions, where its role deserve further attention.     

Isolation and characterization of bovine thymus multicatalytic proteinase complex

The multicatalytic proteinase complex (MPC or proteasome) from bovine thymus was isolated and purified to homogeneity applying a protocol utilizing ion exchange and gel permeation chromatography as major purification tools. The purified complex shows molecular properties that are common for proteasomal molecules (high molecular mass, multisubunit organization, and multiple proteolytic activities) even though a peculiar subunit composition and the presence of specific regulatory mechanisms affecting the assembled proteolytic activities suggest a specialized function for this complex. Thymus proteasome is characterized by the presence of LMP2, LMP7, and LMP10 (MECL1) subunits, which replace the X, Y, and Z subunits. Since a similar complex was previously isolated in bovine spleen, it appears that the proteasomal population containing the LMP subunits is characteristic for organs involved in immune response. Both the thymus and spleen proteasomes are characterized by a marked efficiency in cleaving peptide bonds after branched-chain and aromatic amino acids, indicating that this proteasomal population is most likely involved in intracellular processing of class I antigenic peptides and is an example of an "in vivo" functioning immunoproteasome. However, in spite of several similarities, the complexes isolated from the two lymphoid organs do not show superimposable functional properties, which suggests the presence of organ-specific regulatory mechanisms affecting each of the proteolytic components assembled in the complex.     

Ontogenesis of rat immune system: Proteasome expression in different cell populations of the developing thymus

Immune proteasomes in thymus are involved in processing of self-antigens, which are presented by MHC class I molecules for rejection of autoreactive thymocytes in adults and probably in perinatal rats. The distribution of immune proteasome subunits LMP7 and LMP2 in thymic cells have been investigated during rat perinatal ontogenesis. Double immunofluorescent labeling revealed LMP7 and LMP2 in thymic epithelial and dendritic cells, as well as in CD68 positive cells - macrophages, monocytes - at all developmental stages. LMP2 and LMP7 were also detected by flow cytometry in almost all thymic CD90 lymphocytes through pre- and postnatal ontogenesis. Our results demonstrate that the immune proteasomes are expressed in all types of thymic antigen presenting cells during perinatal ontogenesis, suggesting the establishment of the negative selection in the thymus at the end of fetal life. The observation of the immune proteasome expression in T lymphocytes suggests their role in thymocyte differentiation besides antigen processing in thymus.     

Changes in proteasome pool in human papillary thyroid carcinoma development

Searching the antitumor drug targets among proteasomes, “ubiquitous” enzyme systems, may provide a new impulse to the antitumor drug discovery. In this study, changes in the proteasome pool in the development of human papillary thyroid carcinoma were determined. Proteasome activities were evaluated by hydrolysis of commercial fluorogenic peptides. Changes in the expression of the total proteasome pool, proteasome 19S activator and proteolytic constitutive subunits X(β5), Y(β1) and immune subunits LMP7 (β5i) and LMP2 (β1i) were investigated by Western blotting. The distribution of the proteasome subunits in thyroid gland cells was detected by immunohistochemistry. It was shown that the chymotrypsin- and caspase-like activities as well as the expression of the total proteasome pool, proteasome 19S activator and immune subunits increased gradually in the tumors at the T₂N₀M₀ and T₃N₀M₀ stages in comparison with the control tissues. Among the structures studied, the expression of the 19S activator and immune proteasomes, which contain the LMP2 (β1i) subunit, was enhanced to the largest degree in tumor cells. The data obtained may be implicated in a new therapeutic strategy. Taking into consideration the antitumor function of the immune proteasomes, we advance the 19S activator as the target for the development of a novel antitumor therapy.