Phosphorylation of proteasomes and alpha-RNP from rat liver cells

In eukaryotic cells the population of proteasomes is heterogeneous. Here we have shown that proteasomes from nuclei and cytoplasm of rat liver cells differ in their subunit patterns. The subunit pattern of alpha-RNP differs from that of proteasomes, however, alpha-RNP particles contain the number of 26S proteasome subunits. Moreover, the proteasomes contain subunits of alpha-RNP. We have shown for the first time that nuclear proteasomes and alpha-RNP are hyperphosphorylated on threonine residues. Differences in phosphorylation state of subunits of nuclear and cytoplasmic proteasomes and alpha-RNP on threonine and tyrosine residues have been revealed. A suggestion is put forward that hyperphosphorylation of subunits may determine nuclear localization of these complexes in rat liver cells. The results obtained suggest that a highly specialized system of protein kinases and phosphatases may be involved in the regulation of phosphorylation state of different populations of proteasomes and alpha-RNP in rat liver cells.     

Isolation and characterization of two 20S proteasomes from the endoplasmic reticulum of rat liver microsomes.

Two new forms of proteasomes, designated as the endoplasmic reticulum (ER) membrane-associated proteasome (ERa proteasome) and ER membrane-bound proteasome (ERb proteasome), were purified to homogeneity from 0.0125 and 2.5% sodium cholate extracts, respectively, of a rat liver microsomal fraction. SDS-PAGE analysis revealed that the purified ERa and ERb proteasomes were composed of multiple subunits similar to the cytosolic 20S proteasome. However, electrophoretic, structural and immunochemical differences between the ERa, ERb and cytosolic 20S proteasomes were observed on native PAGE, two-dimensional (2D) PAGE, and immunoblot analyses. Purification of ERb from a 2.5% sodium cholate extract of the trypsin-treated microsomal fraction yielded a trypsin-modified form of ERb (tERb), which lacked the C2 subunit at least. On the other hand, no ERa proteasome was obtained from the 0.0125% sodium cholate extract of the trypsin-treated microsomes, suggesting that ERa and ERb are ER membrane-associated and -bound proteasomes, respectively. The ERa, ERb, and cytosolic 20S proteasomes exhibited similar specificities as to peptide hydrolyzing activity, although differences in their activities were noted in the presence of SDS and phospholipid. With respect to the proteolysis of protein substrates, only the ERb proteasome cleaved beta-casein, and it also degraded reduced and carboxymethylated lysozyme considerably faster than the cytosolic 20S and ERa proteasomes. Collectively our results suggest that the ERa and ERb proteasomes may play roles in intracellular proteolysis distinct from that of the cytosolic 20S proteasome.     

New crystal forms and low resolution structure analysis of 20S proteasomes from bovine liver

20S proteasomes from higher eukaryotes have immunological functions rather than those from archibacteria or yeast. To clarify the mechanism of the sorting and production of antigen-presenting peptides, it is important and worthwhile to determine the structure of mammalian proteasomes using a third generation synchrotron radiation source. Here we report new crystal forms of 20S proteasomes from bovine liver and preliminary structure analysis of them. The crystals belong to the same space group but have different cell dimensions. One crystal (form I) belongs to space group P2(1)2(1)2(1) with unit cell dimensions of a = 124.8, b =197.4, c =323.8 A, and diffracts to 3.0 A resolution. The other crystal (form II) belongs to the same space group with a =115.1, b =205.6, c =316. 0 A, and diffracts to 4.0 A resolution. The diffraction data for the form I crystal provided an interpretable electron density map for presenting the structural differences from yeast proteasomes.     

Native structure of rat liver immune proteasomes

Native structure of active forms of rat liver immune proteasomes has been studied by two-dimensional electrophoresis method modified for analysis of unpurified protein fractions. The developed method allowed revealing the proteasome immune subunits LMP7 and LMP2 in 20S subparticles and in the structures bound to one or two PA28αβ activators, but not to the PA700 activator, which is involved in the hydrolysis of ubiquitinated proteins. The results obtained indicate the participation of the immune proteasomes in delicate regulatory mechanisms based on the production of biologically active peptides and exclude their participation in processes of crude degradation of “rotated” ubiquitinated proteins.     

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.     

Immunoproteasomes largely replace constitutive proteasomes during an antiviral and antibacterial immune response in the liver.

The proteasome is critically involved in the production of MHC class I-restricted T cell epitopes. Proteasome activity and epitope production are altered by IFN-gamma treatment, which leads to a gradual replacement of constitutive proteasomes by immunoproteasomes in vitro. However, a quantitative analysis of changes in the steady state subunit composition of proteasomes during an immune response against viruses or bacteria in vivo has not been reported. Here we show that the infection of mice with lymphocytic choriomeningitis virus or Listeria monocytogenes leads to an almost complete replacement of constitutive proteasomes by immunoproteasomes in the liver within 7 days. Proteasome replacements were markedly reduced in IFN-gamma(-/-) mice, but were only slightly affected in IFN-alphaR(-/-) and perforin(-/-) mice. The proteasome regulator PA28alpha/beta was up-regulated, whereas PA28gamma was reduced in the liver of lymphocytic choriomeningitis virus-infected mice. Proteasome replacements in the liver strongly altered proteasome activity and were unexpected to this extent, since an in vivo half-life of 12 days had been previously assigned to constitutive proteasomes in the liver. Our results suggest that during the peak phase of viral and bacterial elimination the antiviral cytotoxic T lymphocyte response is directed mainly to immunoproteasome-dependent T cell epitopes, which would be a novel parameter for the design of vaccines.     

Proteasomes and proteasome activator 200 kDa (PA200) accumulate on chromatin in response to ionizing radiation

Proteasome activator 200 kDa (PA200) forms nuclear foci after exposure of cells to ionizing radiation and enhances proteasome activity in vitro. Within cells, it is unclear whether PA200 responds to radiation alone or in association with proteasomes. In the present study, we identified three forms of cellular PA200 (termed PA200i, ii and iii) at the mRNA and protein levels. Neither PA200ii nor PA200iii appears to associate with proteasomes. All detectable PA200i is associated with proteasomes, which indicates that PA200i and proteasomes function together within the cell. Consistent with this idea, we find that exposure of cells to radiation leads to an equivalent accumulation of both PA200i and core proteasomes on chromatin. This increase in PA200 and proteasomes on chromatin is not specific to the stage of cell cycle arrest since it occurs in cells that arrest in G(2)/M and cells that arrest in G(1)/S after exposure to radiation. These data provide evidence that PA200 and proteasomes function together within cells and respond to a specific radiation-induced damage independent of the stage of cell cycle arrest.     

Hyperphosphorylation of rat liver proteasome subunits: the effects of ethanol and okadaic acid are compared

In experimental alcoholic liver disease, protein degradation by the ATP-ubiquitin-proteasome pathway is inhibited. Failure of the proteasome to eliminate cytoplasmic proteins leads to the accumulation of oxidized and otherwise modified proteins. One possible explanation for the inhibition of the proteasome is hyperphosphorylation of proteasome subunits. To examine this possibility, the 26S proteasomes from the liver of rats fed ethanol and a pair-fed control were studied by isolating the proteasomes in a purified fraction. The effect of ethanol on the phosphorylation of proteasomal subunits was compared with the hyperphosphorylation of the proteasomes caused by okadaic acid given to rats in vivo. Ethanol ingestion caused an inhibition of the chymotrypsin-like activity of the purified proteasome. The 2D electrophoresis and Western blot analysis of the purified 20S and 26S proteasomes from the ethanol-fed rats indicated that hyperphosphorylation of proteasomal subunits had occured. The proteasomal alpha type subunits C9/alpha3 and C8/alpha7 were hyperphosphorylated compared to the controls. Chymotrypsin-like activity was also inhibited by okadaic acid treatment similar to ethanol feeding. The 26S proteasome fraction examined by isoelectric focusing gel revealed many hyperphosphorylated bands in the proteasomes from the okadaic acid treated and the ethanol fed rat livers compared with the controls. In conclusion hyperphosphorylation of the proteasome subunits occurs in the ethanol treated proteasomal subunits which could be one mechanism of the inhibition of the 26S proteasome caused by ethanol feeding.     

Exclusion of immune proteasomes from mouse ascitic carcinoma Krebs-II cells

Pools of 26S and 20S proteasomes were studied in the spleen, liver, lung, and ascitic carcinoma Krebs-II of mouse. Western blotting demonstrated that the pool of 26S proteasomes in ascitic carcinoma Krebs-II was twice that in control lung cells and did not significantly differ by total 26S proteasome quantities from the spleen and liver. At the same time, the level of immune subunit LMP7 was 12 times lower in it compared to lung proteasomes and 4–5 times lower compared to spleen and liver proteasomes. Immune subunit LMP2 was undetectable by this technique in the ascitic carcinoma in contrast to the lung, spleen, and liver. All immune subunits in the studied organs and ascitic carcinoma Krebs-II are components of 26S but not 20S proteasomes.     

Changes in Proteasome Activity and Subunit Composition during Postnatal Development of Rat

The dynamics of the activities of 26S and 20S proteasomes in the rat liver and spleen have been studied during postnatal development from 1 to 90 days. The activities of proteasome forms both in spleen and in liver increased in adult animals as compared to one day rats. The activities of both proteasome forms in the liver did not differ significantly from those in the spleen at all stages of postnatal development. Using Western blot with monoclonal antibodies to Rpt6 subunit, we confirmed the presence of 26S proteasome in both organs at all stages of postnatal development. Studies with polyclonal antibodies to β1i (LMP2) subunit showed the appearance of the immune subunit in the spleen by day 9 and in the liver only by day 23 of postnatal development. This result suggests the earlier formation of the spleen as an organ with immune functions.__________Translated from Ontogenez, Vol. 36, No. 3, 2005, pp. 205–210.Original Russian Text Copyright © 2005 by Abramova, Astakhova, Sharova.     

Tissue specificity of subunit composition and EGF-dependent changes in the subunit pattern of 20S-proteasomes

The subunit pattern of 20S proteasomes from rat kidney, rat liver, human A-431 cells, human K-562 cells and mouse NIH 3T3 cells were studied. Proteasomes in cells of a common tissue origin appeared to be similar, independently of the intensity of cell proliferation. Unlike, proteasomes in cells of various types of tissue specificity differed from each other. Besides, EGF was shown to induce changes in the subunit pattern of proteasomes in A-431 cells.     

PiZ Mouse Liver Accumulates Polyubiquitin Conjugates That Associate with Catalytically Active 26S Proteasomes

Accumulation of aggregation-prone human alpha 1 antitrypsin mutant Z (AT-Z) protein in PiZ mouse liver stimulates features of liver injury typical of human alpha 1 antitrypsin type ZZ deficiency, an autosomal recessive genetic disorder. Ubiquitin-mediated proteolysis by the 26S proteasome counteracts AT-Z accumulation and plays other roles that, when inhibited, could exacerbate the injury. However, it is unknown how the conditions of AT-Z mediated liver injury affect the 26S proteasome. To address this question, we developed a rapid extraction strategy that preserves polyubiquitin conjugates in the presence of catalytically active 26S proteasomes and allows their separation from deposits of insoluble AT-Z. Compared to WT, PiZ extracts had about 4-fold more polyubiquitin conjugates with no apparent change in the levels of the 26S and 20S proteasomes, and unassembled subunits. The polyubiquitin conjugates had similar affinities to ubiquitin-binding domain of Psmd4 and co-purified with similar amounts of catalytically active 26S complexes. These data show that polyubiquitin conjugates were accumulating despite normal recruitment to catalytically active 26S proteasomes that were available in excess, and suggest that a defect at the 26S proteasome other than compromised binding to polyubiquitin chain or peptidase activity played a role in the accumulation. In support of this idea, PiZ extracts were characterized by high molecular weight, reduction-sensitive forms of selected subunits, including ATPase subunits that unfold substrates and regulate access to proteolytic core. Older WT mice acquired similar alterations, implying that they result from common aspects of oxidative stress. The changes were most pronounced on unassembled subunits, but some subunits were altered even in the 26S proteasomes co-purified with polyubiquitin conjugates. Thus, AT-Z protein aggregates indirectly impair degradation of polyubiquitinated proteins at the level of the 26S proteasome, possibly by inducing oxidative stress-mediated modifications that compromise substrate delivery to proteolytic core.     

Contrasting proteome biology and functional heterogeneity of the 20 S proteasome complexes in mammalian tissues

The 20 S proteasome complexes are major contributors to the intracellular protein degradation machinery in mammalian cells. Systematic administration of proteasome inhibitors to combat disease (e.g. cancer) has resulted in positive outcomes as well as adversary effects. The latter was attributed to, at least in part, a lack of understanding in the organ-specific responses to inhibitors and the potential diversity of proteomes of these complexes in different tissues. Accordingly, we conducted a proteomic study to characterize the 20 S proteasome complexes and their postulated organ-specific responses in the heart and liver. The cardiac and hepatic 20 S proteasomes were isolated from the same mouse strain with identical genetic background. We examined the molecular composition, complex assembly, post-translational modifications and associating partners of these proteasome complexes. Our results revealed an organ-specific molecular organization of the 20 S proteasomes with distinguished patterns of post-translational modifications as well as unique complex assembly characteristics. Furthermore, the proteome diversities are concomitant with a functional heterogeneity of the proteolytic patterns exhibited by these two organs. In particular, the heart and liver displayed distinct activity profiles to two proteasome inhibitors, epoxomicin and Z-Pro-Nle-Asp-H. Finally, the heart and liver demonstrated contrasting regulatory mechanisms from the associating partners of these proteasomes. The functional heterogeneity of the mammalian 20 S proteasome complexes underscores the concept of divergent proteomes among organs in the context of an identical genome.     

Phosphorylation of ATPase subunits of the 26S proteasome

The 26S proteasome complex plays a major role in the non-lysosomal degradation of intracellular proteins. Purified 26S proteasomes give a pattern of more than 40 spots on 2D-PAGE gels. The positions of subunits have been identified by mass spectrometry of tryptic peptides and by immunoblotting with subunit-specific antipeptide antibodies. Two-dimensional polyacrylamide gel electrophoresis of proteasomes immunoprecipitated from [³²P]phosphate-labelled human embryo lung L-132 cells revealed the presence of at least three major phosphorylated polypeptides among the regulatory subunits as well as the C8 and C9 components of the core 20S proteasome. Comparison with the positions of the regulatory polypeptides revealed a minor phosphorylated form to be S7 (MSS1). Antibodies against S4, S6 (TBP7) and S12 (MOV34) all cross-reacted at the position of major phosphorylated polypeptides suggesting that several of the ATPase subunits may be phosphorylated. The phosphorylation of S4 was confirmed by double immunoprecipitation experiments in which 26S proteasomes were immunoprecipitated as above and dissociated and then S4 was immunoprecipitated with subunit-specific antibodies. Antibodies against the non-ATPase subunit S10, which has been suggested by others to be phosphorylated, did not coincide with the position of a phosphorylated polypeptide. Some differences were observed in the 2D-PAGE pattern of proteasomes immunoprecipitated from cultured cells compared to purified rat liver 26S proteasomes suggesting possible differences in subunit compositions of 26S proteasomes.     

Regulation of proteasome complexes by gamma-interferon and phosphorylation

Proteasomes play a major role in non-lysosomal proteolysis and also in the processing of proteins for presentation by the MHC class I pathway. In animal cells they exist in several distinct molecular forms which contribute to the different functions. 26S proteasomes contain the core 20S proteasome together with two 19S regulatory complexes. Alternatively, PA28 complexes can bind to the ends of the 20S proteasome to form PA28-proteasome complexes and PA28-proteasome-19S hybrid complexes have also been described. Immunoproteasome subunits occur in 26S proteasomes as well as in PA28-proteasome complexes. We have found differences in the subcellular distribution of the different forms of proteasomes. The gamma-interferon inducible PA28 alpha and beta subunits are predominantly located in the cytoplasm, while 19S regulatory complexes (present at significant levels only in 26S complexes) are present in the nucleus as well as in the cytoplasm. Immunoproteasomes are greatly enriched at the endoplasmic reticulum (ER) where they may facilitate the generation of peptides for transport into the lumen of the ER. We have also investigated the effects of gamma-interferon on the levels and subcellular distribution of inducible subunits and regulator subunits. In each case gamma-interferon was found to increase the level but not to alter the distribution. Several subunits of proteasomes are phosphorylated including alpha subunits C8 (alpha7) and C9 (alpha3), and ATPase subunit S4 (rpt2). Our studies have shown that gamma-interferon treatment decreases the level of phosphorylation of proteasomes. We have investigated the role of phosphorylation of C8 by casein kinase II by site directed mutagenesis. The results demonstrate that phosphorylation at either one of the two sites is essential for the association of 19S regulatory complexes and that the ability to undergo phosphorylation at both sites gives the most efficient incorporation of C8 into the 26S proteasome.     

Direct evidence for nuclear and cytoplasmic colocalization of proteasomes (multiprotease complexes) in liver

Subcellular localization of the large multicatalytic protease complexes called proteasomes, which have been found in soluble fractions of various cells, was examined by biochemical, immunological, and immunohistological methods. Rat liver nuclei, purified by two different procedures, showed high activities for degrading [3H]methylcasein and various fluorogenic oligopeptides with neutral and weakly alkaline pH optima. On gel filtration, all of these peptidase activities were recovered in a single peak with the unusually large molecular weight of about 600,000. Properties of the proteolytic activity in crude extracts of the nucleus and the cytoplasm were very similar. Immunoelectrophoretic blot analysis showed the presence of appreciable concentrations of proteasomes with similar immunoreactivity in isolated nuclear and cytosolic fractions. Moreover, immunohistochemical staining of human liver showed that proteasomes were predominantly localized in the nuclear matrix but also were present diffusely in the cytoplasm of hepatocytes. These findings indicate the nuclear and cytoplasmic colocalization of proteasomes.     

Specific orientation and two-dimensional crystallization of the proteasome at metal-chelating lipid interfaces

The potential of a protein-engineered His tag to immobilize macromolecules in a predictable orientation at metal-chelating lipid interfaces was investigated using recombinant 20 S proteasomes His-tagged in various positions. Electron micrographs demonstrated that the orientation of proteasomes bound to chelating lipid films could be controlled via the location of their His tags: proteasomes His-tagged at their sides displayed exclusively side-on views, while proteasomes His-tagged at their ends displayed exclusively end-on views. The activity of proteasomes immobilized at chelating lipid interfaces was well preserved. In solution, His-tagged proteasomes hydrolyzed casein at rates comparable with wild-type proteasomes, unless the His tags were located in the vicinity of the N termini of alpha-subunits. The N termini of alpha-subunits might partly occlude the entrance channel in alpha-rings through which substrates enter the proteasome for subsequent degradation. A combination of electron micrographs and atomic force microscope topographs revealed a propensity of vertically oriented proteasomes to crystallize in two dimensions on fluid lipid films. The oriented immobilization of His-tagged proteins at biocompatible lipid interfaces will assist structural studies as well as the investigation of biomolecular interaction via a wide variety of surface-sensitive techniques including single-molecule analysis.     

Tissue distribution of constitutive proteasomes, immunoproteasomes, and PA28 in rats

We investigated the expression of standard proteasomes, immunoproteasomes, and their regulators, PA28, and PA700, in rat tissues. Immunoproteasomes (with subunits LMP2, LMP7, and MECL1) were abundant in the spleen but almost absent in the brain. In contrast, standard proteasomes (with X, Y, and Z) were highly expressed in the brain but not in the spleen. Both proteasome types were present in the lung and the liver. PA700 subunits (p112, S5a, and p45) were found in all tissues. PA28alpha, PA28beta, and PA28gamma were also expressed in all tissues, except for the brain which contained very little PA28beta. The results did not depend on rat sex or age. The cleavage specificity for peptide substrates differed greatly between brain and spleen proteasomes. Hybrid proteasomes, containing both PA28alphabeta and PA700, were not present in the brain but in all other tissues examined.     

Immune proteasomes and immunity

A lot of facts that require understanding have been accumulated since immune proteasomes were discovered and their relationship with the immune response was established. For example, why are immune proteasomes present in all studied mammalian organs and tissues, including nonlymphoid tissues? What is responsible for differences in the ratio of immune to constitutive proteasomes in different organs? Are the functions of immune proteasomes related to the immune response alone, as was shown initially, or not? Are immune proteasomes formed simultaneously in different organs during ontogenesis? An attempt is made in this review to answer these and other related questions.     

Characterization of the 20S proteasome of the lepidopteran,Spodoptera frugiperda

Multiple complexes of 20S proteasomes with accessory factors play an essential role in proteolysis in eukaryotic cells. In this report, several forms of 20S proteasomes from extracts of Spodoptera frugiperda (Sf9) cells were separated using electrophoresis in a native polyacrylamide gel and examined for proteolytic activity in the gel and by Western blotting. Distinct proteasome bands isolated from the gel were subjected to liquid chromatography-tandem mass spectrometry and identified as free core particles (CP) and complexes of CP with one or two dimers of assembly chaperones PAC1-PAC2 and activators PA28γ or PA200. In contrast to the activators PA28γ and PA200 that regulate the access of protein substrates to the internal proteolytic chamber of CP in an ATP-independent manner, the 19S regulatory particle (RP) in 26S proteasomes performs stepwise substrate unfolding and opens the chamber gate in an ATP-dependent manner. Electron microscopic analysis suggested that spontaneous dissociation of RP in isolated 26S proteasomes leaves CPs with different gate sizes related presumably to different stages in the gate opening. The primary structure of 20S proteasome subunits in Sf9 cells was determined by a search of databases and by sequencing. The protein sequences were confirmed by mass spectrometry and verified by 2D gel electrophoresis. The relative rates of sequence divergence in the evolution of 20S proteasome subunits, the assembly chaperones and activators were determined by using bioinformatics. The data confirmed the conservation of regular CP subunits and PA28γ, a more accelerated evolution of PAC2 and PA200, and especially high divergence rates of PAC1.