Developmental regulation of proteolytic activities and subunit pattern of 20 S proteasome in chick embryonic muscle

Roles of the proteasome and inhibitor of DNA binding 1 protein in myoblast differentiation

This study was conducted to further understand the mechanism that controls myoblast differentiation, a key step in skeletal muscle formation. RNA sequencing of primary bovine myoblasts revealed many genes encoding the ubiquitin-proteasome system were up-regulated during myoblast differentiation. This up-regulation was accompanied by increased proteasomal activity. Treating myoblasts with the proteasome-specific inhibitor lactacystin impeded myoblast differentiation. Adenovirus-mediated overexpression of inhibitor of DNA binding 1 (ID1) protein inhibited myoblast differentiation too. Further experiments were conducted to determine whether the proteasome promotes myoblast differentiation by degrading ID1 protein. Both ID1 protein and mRNA expression decreased during myoblast differentiation. However, treating myoblasts with lactacystin reversed the decrease in ID1 protein but not in ID1 mRNA expression. Surprisingly, this reversal was not observed when myoblasts were also treated with the mRNA translation inhibitor cycloheximide. Direct incubation of ID1 protein with proteasomes from myoblasts did not show differentiation stage-associated degradation of ID1 protein. Furthermore, ubiquitinated ID1 protein was not detected in lactacystin-treated myoblasts. Overall, the results of this study suggest that, during myoblast differentiation, the proteasomal activity is up-regulated to further myoblast differentiation and that the increased proteasomal activity improves myoblast differentiation partly by inhibiting the synthesis, not the degradation, of ID1 protein.-Leng, X., Ji, X., Hou, Y., Settlage, R., Jiang, H. Roles of the proteasome and inhibitor of DNA binding 1 protein in myoblast differentiation.

Role of proteasomes in cellular regulation

The 26S proteasome is the key enzyme of the ubiquitin-dependent pathway of protein degradation. This energy-dependent nanomachine is composed of a 20S catalytic core and associated regulatory complexes. The eukaryotic 20S proteasomes demonstrate besides several kinds of peptidase activities, the endoribonuclease, protein-chaperone and DNA-helicase activities. Ubiquitin-proteasome pathway controls the levels of the key regulatory proteins in the cell and thus is essential for life and is involved in regulation of crucial cellular processes. Proteasome population in the cell is structurally and functionally heterogeneous. These complexes are subjected to tightly organized regulation, particularly, to a variety of posttranslational modifications. In this review we will summarize the current state of knowledge regarding proteasome participation in the control of cell cycle, apoptosis, differentiation, modulation of immune responses, reprogramming of these particles during these processes, their heterogeneity and involvement in the main levels of gene expression.

Peculiarities of proteasome pool formation in rat spleen and liver during postnatal development

Changes in the specific activity and amounts of 26S and 20S proteasome pools in rat spleen and liver during postnatal development and appearance in them of immune subunits were studied. Two decreases in chymotrypsin-like activity of the proteasome pools were recorded during the first three weeks after birth. The activity minimum fell on the 11th and 19th days, and the first decrease was more prolonged and pronounced than the second. The decrease in the specific activity of the 26S proteasome pools was associated with a reduction of their quantity. The 20S proteasome pools displayed no such decreases. Noticeable quantities of immune subunits LMP7 and LMP2 were revealed by Western blotting in the spleen on the 7th day and on the 19th day in the liver, concurrently with the beginning of the decrease in the proteasome activity. It was concluded that during the first three weeks of postnatal development the proteasome pools in rat spleen and liver were replaced twice, and in the spleen (a lymphoid organ) a qualitatively new pool containing immune subunits appeared nearly two weeks earlier than in the liver (a non-lymphoid organ). The appearance of immune proteasomes in different organs and tissues during some weeks after birth seems to explain the immune system inefficiency during embryogenesis and early postnatal development.

Selective upregulation of the ubiquitin-proteasome proteolytic pathway proteins, proteasome zeta chain and isopeptidase T in fetal Down syndrome

The ubiquitin-proteasome proteolytic pathway is involved in an important non-lysosomal proteolytic pathway that is responsible for the highly selective turnover of cellular proteins both under basal metabolic conditions as well as stress. Protein degradation by this pathway is attributed to the 20S proteasome that forms the catalytic core of the complex. Recently there has been increasing interest in the proteasome because of its possible role in neuron degeneration and death. Fetal Down syndrome (DS) neurons were demonstrated to degenerate and undergo apoptosis in vitro. We therefore investigated the expression of different proteins involved in this degradative pathway, including subunits of the 20S proteasome, ubiquitinating and deubiquitinating enzymes, and regulatory subunits of the 26S proteasome in control and DS fetal brains by two-dimensional electrophoresis (2-DE). After 2-DE, approximately 389 protein spots were successfully identified by matrix-associated laser desorption ionization mass spectroscopy (MALDI-MS) and this was followed by quantification of twenty three proteins of the pathway. The results indicate that all but two proteins exhibited no apparent alterations in their pattern of expression. Proteasome zeta chain, an alpha subunit of the 20S proteasome (P < 0.05) and ubiquitin carboxy-terminal hydrolase T (Isopeptidase T), a deubiquitinating enzyme (P < 0.001) were significantly increased in fetal DS compared to controls. Whilst the expression of proteasome iota (n = 9, r = -0.9489, P = 0.0004) and proteasome epsilon (n = 9, r = -0.7227, P = 0.0311) chains was decreased with age in fetal DS brain, no significant correlation was obtained in the other proteins with age. The data suggest that such selective upregulation may have relevance to the developmental abnormalities that characterize this disorder.

Two proteins, a goldfish 20S proteasome subunit and the protein interacting with 26S proteasome, change in the meiotic cell cycle

To investigate the regulatory mechanism for the proteasome in the meiotic cell cycle, we purified the 26S proteasome from immature (in G2-phase) and mature (in M-phase) oocytes, and compared its subunits by immunoblotting. At least two protein bands, at 30 kDa (detected by GC3beta antibody) and 62 kDa (detected by 1-4D5 antibody), differed between 26S proteasomes. A monoclonal antibody, GC3beta cross-reacted with two bands in the 26S proteasome from immature oocytes, however, the upper band was absent in the 26S proteasome from mature oocytes. The 62-kDa protein band detected by 1-4D5 antibody was not detected in the immature oocyte 26S proteasome; however, a band was detected in mature oocyte 26S proteasome. The cDNAs encoding these proteins were isolated by an immunoscreening method using the monoclonal antibodies. The 30-kDa protein was an alpha4 subunit, which is one of the alpha-subunit group of the 20S proteasome, and the 62-kDa protein was a homologue of CCTepsilon, one of the components of eukaryotic molecular chaperones. Phosphatase treatment of the 26S proteasome revealed that a part of the alpha4 subunit of goldfish 20S proteasome, alpha4_ca, is phosphorylated in G2-phase and dephosphorylated in M-phase. A binding assay using a recombinant goldfish CCTepsilon revealed that unmodified CCTepsilon interacts with the 26S proteasome. Fertilization triggers a transition from meiotic metaphase to mitotic interphase. During fertilization, a GC3beta cross-reacting upper band reappeared. The 62-kDa band dissociated from the 26S proteasome. As a result, the 26S proteasome changed to an immature type from a mature type during fertilization. These results suggest that the 26S proteasome is changed reversibly during the meiotic cell cycle by modification of its subunits and interactions between regulators.

Inhibitors of the proteasome block the myogenic differentiation of rat L6 myoblasts

Myogenesis is characterized by membrane fusion and accumulation of muscle specific proteins. We have previously shown that nitric oxide acts as a messenger for membrane fusion. Here we show that inhibitors of the proteasome, such as lactacystin, reversibly block both the fusion of L6 myoblasts and the accumulation of muscle specific proteins, such as myosin heavy chain (MHC). The inhibitors also reversibly prevented the induction of the NF-kappaB activity, which is required for the expression of nitric oxide synthase (NOS). Moreover, the inhibition of the NF-kappaB activity occurred in parallel with that of the NOS activity upon treatment with increasing concentrations of lactacystin. While pyrrolidine dithiocarbamate, an inhibitor of NF-kappaB, blocked both membrane fusion and accumulation of MHC, N(G)-monomethyl-L-arginine, a specific inhibitor of NOS, inhibited only the fusion. These results suggest that the proteasome plays an essential role in the regulation of myogenic differentiation through the activation of NF-kappaB and that the target of NF-kappaB for the expression of muscle specific proteins is distinct from that for myoblast fusion.

Evidence for the participation of the proteasome and calpain in early phases of muscle cell differentiation

Objectives were to investigate the role of the proteasome and m-calpain to muscle cell differentiation. Accordingly, we investigated the effects of lactacystin, a proteasome inhibitor, and calpain inhibitor-II (CI-II) on L8 muscle cell differentiation and assessed concentrations of proteasomal and calpain subunit mRNAs during differentiation. L8 myoblasts were induced to differentiate by culturing in mitogen-depleted medium. To assess the importance of the proteasome and calpain to differentiation, we examined effects of lactacystin and CI-II on creatine kinase (CK) activity. In the absence of inhibitor, CK activity was detectable within 48 h of mitogen depletion and myotubes were formed. Addition of lactacystin or CI-II to cultures drastically reduced CK activity and prevented formation of myotubes. Hence, proteasome and calpain are both necessary for differentiation. In order to identify which proteasomal subunits were regulated during differentiation, we examined the concentrations of two 20S core subunits (C8 and C9) and three 22S ATPases (MSS1, S4 and TBP1) during differentiation. Concentrations of m-calpain and beta-tubulin mRNAs were also assessed. Differentiation was associated with slight increases (ca. 30%) in concentrations of mRNAs encoding the proteasomal 20S core subunits (C8 and C9) and with large increases (approximately 2-fold) in mRNAs encoding the regulatory subunit ATPases. m-calpain mRNA concentration also increased two-fold following mitogen depletion. beta-Tubulin mRNA concentration remained unchanged early in the differentiation process and thereafter declined. Of interest, changes in proteasomal and m-calpain mRNAs occurred within 6-24 h of mitogen depletion (i.e., at least 24-36 h prior to detectable changes in creatine kinase activity). These results indicate that changes in expression of proteasome and calpains subunits occur early in the differentiation process. These changes may be required for the normal course of differentiation to proceed. Differentiation is associated with larger changes in proteasomal ATPase mRNAs than in 20S core particle mRNAs indicating that either turnover rates of the 22S ATPase subunits are more rapid in differentiating cells than of the 20S core particles or that functions of the regulatory subunits become more important during muscle cell differentiation.

Subcellular distribution and profiles of prosomes (proteasomes-MCP) during differentiation of human lymphoblastic cell line

The human lymphoblastoid leukemic cell line (CCRF-CEM) was induced to differentiate with phorbol 12-myristate 13-acetate (PMA). During differentiation, assessed by monitoring the cluster of differentiation (CD) profile, the prosome (proteasomes, multi-catalytic proteinase) distribution and composition were studied by microscopy, flow cytometry and Western blot analysis. Changes in prosome subunits were monitored using 3 monoclonal antibodies anti-p23K, p29K and p31K. There were changes in the subcellular distribution of prosome antigens in PMA treated cells compared to untreated cells. The amount of cytoplasmic prosomal antigens decreased during the first three days of differentiation and the membrane antigens increased; meanwhile there was an increase of p53 and no change in actin protein levels. As mitotic cyclins are degraded by the ubiquitin pathway and therefore via the prosome, the decrease observed in differentiated cells suggests that prosomes are involved in the cell cycle and thus in cell proliferation.

Members of the AAA-gene family are involved in early embryogenesis of vertebrates

Here the nucleotide sequence of three cDNAs from Xenopus laevis are reported. The corresponding genes belong to the AAA-family of genes showing the strongest sequence homology to the human HIV-1 Tat binding protein 1 (TBP-1) and to the yeast SUG1 gene, respectively. Analysis of their expression pattern indicate that they are maternally stored in oocytes and involved in very early stages of vertebrate embryogenesis.

Changes in the subunit distribution of prosomes (MCP-proteasomes) during the differentiation of human leukemic cells

The subunit composition of cell-internal and surface prosomes during phorbol myristate acetate (PMA)-induced differentiation of human leukemic T lymphocytes (CCRF-CEM cell line) was studied in relation to clusters of differentiation (CD) markers. PMA inhibited cell growth and decreased the amounts of CD1a and CD4 while CD3, CD8, CD25, CD45, CD57 and MHCI increased it; the p53 anti-oncogene increased while actin levels remained constant. Cells incubated with the inducer PMA for 3 days and placed in fresh inhibitor-free medium resumed growth at a low rate, while the CD values slowly reverted to those of the initial phenotype. The presence and relative amounts of prosome subunits were analyzed by flow cytometry, light and fluorescent microscopy and Western blotting using 3 monoclonal antibodies (p25K, p27K and p30-33K MAbs). The decrease in cytoplasmic antigens on day 3 was remarkable (cells followed for 7 days) while increased surface antigens were observed. Changes in the subcellular distributions of prosome antigens, particularly the p25K and p30-33K subunit, were correlated with a partial arrest of the cell cycle. Interestingly, the composition of cell internal and surface prosomes showed different patterns of change.

Prosome cytodistribution relative to desmin and actin filaments in dividing C2.7 myoblasts and during myotube formation in vitro

Prosomes constitute the multicatalytic proteinase (MCP) core of the 26S proteasomes, but were first observed as subcomplexes of untranslated mRNP; this suggests that they play a putative role in the control of protein biosynthesis in addition to their catabolic enzymatic function. In previous investigations it was shown that some prosomes colocalize with the intermediate filaments (IF) of the cytoskeleton, of the cytokeratin type in epithelial cells, and of the vimentin type in fibroblasts. Studies on adult rat muscle carried out with prosome-specific monoclonal antibodies (p-mAbs) have shown, surprisingly, that specific types of prosomes predominantly occupy a particular zone in between the M and the Z lines of the sarcomeric structure. The data presented here show that the subunit composition of prosomes changes when the dividing C2.7 myoblasts fuse into myotubes. We show furthermore that, in dividing C2.7 myoblasts, prosomes colocalize with the desmin network as well as with that of actin, in a distribution that changes with the subunit pattern of the prosomes investigated by individual p-mAbs. Surprisingly, when myogenic fusion is induced, specific types of prosomes move first to the nuclei; later on, they reappear in the cytoplasm. There, superimposing initially onto the reorganizing desmin filaments that run from one pole of the prefusion myoblast to the other, prosomes gradually colocalize with the actin fibers in the fusing myotubes, finally forming a "pearl on a string" pattern. These results are discussed in relation to parallel observations of prosome distribution between the actin and IF networks not only in epithelial cells but also in fusing muscle satellite cells, which made it possible to monitor the complete buildup of the sarcomeric structure.

Changes in the amount and distribution of prosomal subunits during the differentiation of U937 myeloid cells: high expression of p23K

Prosomes (Proteasomes/Multicatalytic proteinase (MCP)-complexes) are protein particles built of 28 subunits in variable composition, having proteinase activity. We have studied the changes in prosomal subunits p29K, p31K and the highly expressed p23K during the differentiation of U937 cells. Control cells had little prosomal subunit p31K in the cytoplasm, while p29K antigen was detected in both the nucleus and cytoplasm; more p23K antigen was found in the cytoplasm than in the nucleus. Flow cytometry demonstrated a biphasic intracellular decrease in prosomes during differentiation induced by phorbol-myristic-acetate (PMA) and retinoic acid plus 1,25-dihydroxycholecalciferol (RA + VD). p23K and p29K decreased both in the cytoplasm and the nucleus of differentiated cells, though the p23K antigen was concentrated near vesicles and the plasma membrane in PMA-induced cells. The p31K antigens disappeared from RA + VD-induced cells, while in PMA-induced cells, cytoplasmic labelling was unchanged and nuclear labelling was increased. Small amounts of prosomal proteins p23K and p29K were found on the outer membrane of un-induced cells. While there was no labelling on the outer membrane of RA + VD-induced cells, p23K protein increased on the plasma membrane of PMA-induced cells. The prosome-like particle protein p21K was not present to any significant extent in the intracellular compartment of control or induced cells; however, p21K was detected on the outer surface of control cells and was increased only in PMA-induced cells. The culture medium of control and induced cells contained no p21K, p23K, p29K or p31K. RA + VD seemed to induce a general decrease of prosomal subunits within the cells and at the outer surface, whereas PMA caused a migration toward the plasma membrane and an increase at the outer surface. These changes in the distribution and type of prosomes in RA + VD- and PMA-induced cells indicate that prosomes may play a part in differentiation, especially p23K which is the most highly expressed protein among those studied and presents the more important changes.

Purification and characterization of proteasomes from Trypanosoma brucei

Proteasomes are multisubunit proteases that exist universally among eukaryotes. They have multiple proteolytic activities, and are believed to have important roles in regulating cell cycle, selective intracellular proteolysis, and antigen presentation. To determine the possible role that proteasomes may play in controlling the life cycle of African trypanosomes, we have isolated proteasomes from the bloodstream and the insect (procyclic) forms of Trypanosoma brucei by DEAE-cellulose chromatography and glycerol gradient fractionation in the presence of ATP. No 26 S proteasome homologs was identified in T. brucei under these experimental conditions. The proteasomes isolated from these two forms of T. brucei are very similar to the rat blood cell 20 S proteasome in their general appearance under the electron microscope. The profile of trypanosome proteasome subunits in sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) has eight visible protein bands with molecular weights ranging from 23 to 34 kDa, and cross-reacted very poorly with the anti-human 20 S proteasome antibodies on immunoblots. Two-dimensional gel electrophoresis of the parasite proteasomes shows a similar number of major subunits with pI's ranging from 4.5 to 7. Using a variety of fluorogenic peptides as substrates, the trypanosome proteasomes exhibited unusually high trypsin-like, but somewhat lower chymotrypsin-like activities, as compared to the rat 20 S proteasome. These proteolytic activities were, however, insensitive to phenylmethylsulfonyl fluoride (PMSF), tosyl-phenylalanine chloromethylketone (TPCK), tosyl-lysine chloromethylketone (TLCK) and trans-epoxy succinyl-L-leucylamido-(4 guanidino) butane (E-64), but the trypsin-like activity of trypanosome proteasomes was inhibited by leupeptin, an aldehyde known to inhibit the trypsin-like activity of mammalian proteasomes, thus ruling out possible contamination by other serine or cysteine proteases. Some quantitative differences in the substrate specificities between the proteasomes from bloodstream and procyclic forms were indicated, which may play a role in determining the differential protein turnovers at two different stages of development of T. brucei.

Regulatory features of multicatalytic and 26S proteases

It should be clear from the foregoing accounts that our understanding of MCP and 26S regulation is still rudimentary. Moreover, we have only recently identified about a dozen natural substrates of these two proteases. Those outside the field may view the situation with some dismay. Those who study the MCP and 26S enzymes are provided with rich opportunities to address fundamental questions of protein catabolism and metabolic regulation.

Proteolysis in cultured liver epithelial cells during oxidative stress. Role of the multicatalytic proteinase complex, proteasome

Exposure to various forms of mild oxidative stress significantly increased the intracellular degradation of both "short-lived" and "long-lived," metabolically radiolabeled, cell proteins in cultures of Clone 9 liver cells (normal liver epithelia). The oxidative stresses employed were bolus H2O2 addition; continuous H2O2 flux; the redox cycling quinones, menadione and paraquat; and the aldehydic products of lipid peroxidation, 4-hydroxynonenal, malonyldialdehyde, and hexenal. In general, exposure to more severe oxidative stress produced a concentration-dependent decline in intracellular proteolysis, in some cases to below baseline levels. Oxidatively modified "foreign" proteins (superoxide dismutase and hemoglobin) were also selectively degraded, in comparison with untreated foreign proteins, when added to lysates of Clone 9 liver cells. As with intracellular proteolysis, the degradation of foreign proteins added to cell lysates was greatly increased by mild oxidative modification, but depressed by more severe oxidative modification. The proteinase activity was recovered in > 300-kDa cell fractions, and inhibitor profiles and immunoprecipitation studies indicated that the multicatalytic proteinase complex, proteasome, was responsible for most of the selective degradation observed with mild oxidative stress; up to approximately 95% for intracellular proteolysis and 65-80% for degradation of foreign modified proteins. Seven days of daily treatment with an antisense oligodeoxynucleotide, directed against the initiation codon region of the proteasome C2 subunit gene, severely depressed the intracellular levels of several proteasome subunit polypeptides (by Western blot analysis), and also depressed the H2O2 induced increase in intracellular proteolysis by approximately 95%, without significantly affecting baseline proteolytic rates. Extensive studies revealed only small or no increases in the overall capacity of oxidatively stressed cells to degrade oxidatively modified protein substrates; a finding supported by both Western blot and Northern blot analyses which revealed no significant increase in the levels of proteasome subunit polypeptides or mRNA transcripts. We conclude that mild oxidative stress increases intracellular proteolysis by modifying cellular proteins, thus increasing their proteolytic susceptibility. In contrast, severe oxidative stress diminishes intracellular proteolysis, probably by generating severely damaged cell proteins that cannot be easily degraded (e.g. cross-linked/aggregated proteins), and by damaging proteolytic enzymes. We further conclude that the multicatalytic proteinase complex proteasome is responsible for most of the recognition and selective degradation of oxidatively modified proteins in Clone 9 liver cells.

The 20S/26S proteasomal pathway of protein degradation in muscle tissue

Similar to all other eukaryotic cells and tissues muscle tissue contains the proteolytic system of 20S/26S proteasomes with the 20S proteasome existing predominantly in a latent state. Unlike with the mammalian enzyme in vitro transition from the latent to the activated state of the 20S proteasomes isolated from muscle of several fish species and from lobster can be achieved by heat shock. It is very likely that the activated state of the 20S proteasome corresponds to the physiologically active form of the enzyme since only that one is able to attack sarcoplasmic and myofibrillar proteins to any significant extent. As perfusion of rat hindquarters with presumptive low molecular mass activators like free fatty acids does not result in an activation of the muscle proteasome other--possibly protein activators--may serve this purpose in vivo. The 26S proteasome complex may be regarded as such a proteasome/activator complex. The 26S proteasome complex has the ability to degrade protein (-ubiquitin-conjugates) by an ATP-consuming reaction. Since increased amounts of ubiquitinated proteins as well as an enhanced activity of the ATP (-ubiquitin)-dependent proteolytic system have been measured in rat muscle tissue during various catabolic conditions, it is not unlikely that this pathway is responsible for catalysis of muscle protein breakdown.

Phylogenic relationships of the amino acid sequences of prosome (proteasome, MCP) subunits

Prosomes [or proteasomes, Multi-Catalytic Proteinase (MCP) are multisubunit protein complexes, found from archaebacteria to man, the structure of which (a 4-layer cylinder) is remarkable conserved. They were first observed as subcomplexes of untranslated mRNP, and then as a multicatalytic proteinase with several proteolytic activities. A number of sequences from subunits of these complexes are now available. Analysis of the sequences shows that these subunits are evolutionarily related, and reveals three highly conserved amino acid stretches. Based on a phylogenic approach, we propose to classify the sequenced subunits into 14 families, which fall into two superfamilies, of the alpha- and beta-type. These data, together with several recently published observations, suggest that some subunits may be interchangeable within the complexes, which would thus constitute a population of heterogenous particles.

Proteasome-associated RNAs are non-specific

The RNA isolated from RNase-treated proteasome preparations from human erythrocytes, HeLa cells, the archaeon Thermoplasma acidophilum and also from recombinant proteasomes of T. acidophilum expressed in Escherichia coli was characterized. The RNA associated with structurally similar protein particles, namely with the two molecular chaperones, groEL from E. coli and with the thermosome from T. acidophilum, served as controls. Electrophoretic analysis on polyacrylamide gels of the radioactively end-labelled RNA revealed a very similar size distribution pattern, irrespectively of the protein particles from which they had been isolated. The predominant RNA species were in the size ranges 80 nucleotides and 120 nucleotides, respectively. Partial sequencing of their terminal regions by mobility-shift analysis revealed that, of the proteasomes from human erythrocytes, the approximately 80-nucleotide-long RNA consists of a heterogenous population of mostly tRNA species because they carried the tRNA-specific 3'-terminal sequence motif 5'-CCA-3'. The RNA in the size range 120 nucleotides isolated from the proteasomes of human erythrocytes and of T. acidophilum was also heterogeneous and displayed, in the terminal regions, a remarkable sequence similarity to the corresponding regions of the 5S rRNA from the same and different organisms. The total content of RNA of all the protein particles was quantified and found to be consistently sub-stoichiometric. All these findings strongly suggest that RNA associated with the proteasomes and with the molecular chaperones originate from the abundant cellular pool of the tRNAs and 5S rRNAs which bind non-specifically to these large protein particles.

DFP-sensitive multicatalytic protease complexes (proteasomes) involved in the control of oocyte maturation in the toad, Bufo japonicus

The inhibition of progesterone-induced oocyte maturation by diisopropylfluorophosphate (DFP), a typical serine protease inhibitor, was investigated in oocytes of the Japanese toad Bufo japonicus for the first time. Oocytes to which DFP was externally applied did not undergo germinal vesicle breakdown (GVBD), which is an early signal of oocyte maturation, in response to progesterone. The more inhibitory period was found to be 0-0.5 GVBD50 on a relative time scale [when the time at which 50% of the oocytes had completed GVBD (GVBD50) was set at 1.0], namely, before the beginning of GVBD. DFP-sensitive proteases, which seem to be multifunctional nonlysosomal protease complexes (proteasomes), may already be present in the cytosol of premature oocytes. Peptide hydrolyzing activity, as reflected by proteasome activity, was found to be regulated before and after GVBD. In addition, immunoblotting regarding the native electrophoretic protein profile of the proteasomes throughout the maturational process demonstrated that they undergo alterations in mobility dependent upon the maturational process. These findings raise the possibility that the activities of some endogenous DFP-sensitive proteasomes play distinct, essential roles in oocyte maturation triggered by progesterone in Bufo.

Nongranular proteolytic enzymes of rat IL-2-activated natural killer cells. II. Purification and identification of rat A-NKP 1 and A-NKP 2 as constituents of the multicatalytic proteinase (proteasome) complex

We have recently described nongranular, cytosolic, high-molecular-weight trypsin-like (A-NKP 1) and chymotrypsin-like (A-NKP 2) proteases of interleukin-2-activated rat natural killer (A-NK) cells. A functional correlation between the inactivation of A-NKP 2 and the inhibition of rat A-NK cell-mediated cytotoxicity was found. Herein we describe the 6,000-fold purification of A-NKP 2 to apparent homogeneity following: isopycnic sucrose gradient fractionation of postnuclear supernatants, molecular sieve chromatography, and heparin-Sepharose chromatography. We also report the novel finding that A-NKP 2 as well as A-NKP 1, derived from either rat A-NK cells or the rat NK leukemic cell line CRNK-16, are constituents of the multicatalytic proteinase (MCP/proteasome) complexes of these cells. Characteristic biochemical, biophysical, and electron microscopic/ultrastructural similarity to the rat liver proteasome was observed. However, Western blot analysis using polyclonal antibodies to the rat liver proteasome clearly indicated differences in the rat hepatic proteasome and the CRNK-16-derived proteasomal subunits. The identification, characterization, and purification of A-NKP 1 and A-NKP 2, described herein, now allow for further investigation of the potential role of these proteasome components in NK cell function. Moreover, the proteasome of NK and A-NK cells can now be compared and contrasted to the granzymes of lytic granules with respect to their role in cell-mediated cytotoxicity.

Cytolocation of prosome antigens on intermediate filament subnetworks of cytokeratin, vimentin and desmin type

Analysis by double-label indirect immunofluorescence of PtK1 and HeLa cells had previously demonstrated that prosome* antigens form networks that superimpose on those of the intermediate filaments of the cytokeratin type. We show here that in PtK1 cells various prosomal antigens also reside to a variable extent on intermediate filaments subnetworks of the vimentin type. In proliferating human fibroblasts the prosome and vimentin networks were found to coincide, while in proliferating myoblasts of the C2.7 mouse myogenic cell line the prosomal antigens seem to superimpose on the intermediate filaments of the desmin type. Thus, the prosomes, which are RNP particles of variable composition and subcomplexes of untranslated mRNP, and carry a multicatalytic proteinase activity, seem to co-localize with the specific kind of cytoplasmic intermediate filament in relation to the cell type. These results, which generalize the previous data, are discussed in view of possible role(s) for prosomes in mRNA metabolism and/or intermediate filaments remodelling.

Gamma-interferon and expression of MHC genes regulate peptide hydrolysis by proteasomes

The presentation of intracellular proteins to the immune system requires their degradation to small peptides that then become associated with major histocompatibility complex (MHC) class I molecules. The generation of these peptides may involve the 20S or 26S proteasome particles, which contain multiple proteolytic activities including distinct sites that preferentially cleave small peptides on the carboxyl side of hydrophobic, basic or acidic residues. Degradation of most cell proteins requires their conjugation to ubiquitin before hydrolysis by the 26S proteasome. This large complex contains the 20S proteasome as its proteolytic core. This ubiquitin-dependent proteolytic pathway is implicated in MHC class I presentation. gamma-Interferon (gamma-IFN), a stimulator of antigen presentation, induces a subclass of proteasomes that contain two MHC-encoded subunits, LMP2 and 7 (refs 5-10). Here we show that gamma-interferon alters the peptidase activities of the 20S and 26S proteasomes without affecting the rates of breakdown of proteins or of ubiquitinated proteins. By enhancing the expression of MHC genes, gamma-IFN increases the proteasomes' capacity to cleave small peptides after hydrophobic and basic residues but reduces cleavage after acidic residues. Moreover, proteasomes of mutants lacking LMP subunits show decreased rates of cleavage after hydrophobic and basic residues. Thus, gamma-IFN and expression of these MHC genes should favour the production by proteasomes of the types of peptides found on MHC class I molecules, which terminate almost exclusively with hydrophobic or basic residues.

Regulation of proteasome expression in developing and transformed cells

The proteasome is a unique protease complex found in all eukaryotic cells and has multiple functions for essential activities. In this work we showed that it is expressed at high level in immature, rapidly growing cells, such as those in early embryonic tissues and cancer cells (Fig. 7). The increase of its expression is down-regulated on differentiation of the cells. However, lymphatic blastocytes grow rapidly and express high levels of proteasomes, but are differentiated. Therefore, the proteasome is not expressed at high levels only in immature cells, but is also involved specifically in nuclear activities of cells during rapid growth, possibly regulating proteinous factors in the cell cycle.

Two mRNAs exist for the Hs PROS-30 gene encoding a component of human prosomes

Screening of a lambda gt11 cDNA expression library of the HeLa cell genome with a monoclonal antibody that specifically recognizes prosomal 30-33-kDa proteins, allowed isolation of a 1264-nucleotide (nt) recombinant cDNA containing a 327-nt untranslated 5'-end. The amino acid (aa) sequence deduced from this cDNA revealed a protein of 269 aa (M(r) of 30,227) that includes a consensus box characteristic for Tyr phosphorylation, also observed in other prosomal proteins. Comparison with another prosomal 27-kDa protein, cloned in our laboratory, indicated the presence of three prosome-specific homology boxes observed in these proteins from archaebacteria to man. Interestingly, except for the untranslated 5'-end, as well as the sequence coding for the N-terminal six aa, this cDNA is identical to two recently published cDNAs encoding subunit C2 of human liver proteasome [Tamura et al., Biochim. Biophys. Acta 1089 (1991) 95-102] and subunit NU of human erythrocyte macropain [DeMartino et al., Biochim. Biophys. Acta 1079 (1991) 29-38]. Primer extension and Northern blot analysis using two specific 18-mer oligodeoxyribonucleotides indicated the presence of two mRNAs that have divergent 5'-ends. These results, as confirmed by the polymerase chain reaction, establish the existence of two distinct Hs PROS-30 mRNAs, differing in their 5'-noncoding regions and in the N-terminal six aa of their protein products.

Immunocytochemical localization of the multicatalytic proteinase (proteasome) in crustacean striated muscles

Multicatalytic proteinase (MCP) is thought to play a central role in the processing and turnover of intracellular proteins in eukaryotic cells. Immunocytochemistry was used to determine the intracellular distribution of the MCP in the claw muscles of the land crab, Gecarcinus lateralis, and the claw and abdominal muscles of the American lobster, Homarus americanus. Cryosections were stained with an affinity-purified polyclonal antibody to lobster MCP that cross-reacted with the land crab enzyme. Two types of staining were observed: a diffuse cytoplasmic staining, and a dense aggregate staining primarily associated with invaginations of the cell membrane. The cytoplasmic staining appeared reticulated in favorable transverse sections due to a preferential localization of MCP to the intermyofibrillar space. The aggregate staining was associated with neither nuclei nor mitochondria, since stains specific for these organelles (Hoechst stain and nicotinamide adenine dinucleotide diaphorase histochemistry, respectively) did not colocalize with the aggregates. Trypsinlike peptidase activities of isolated microsomal and postmicrosomal fractions indicated that less than 1% of the total MCP was associated with the microsomal fraction. Immunoprecipitation of the same fractions confirmed the presence of MCP in the microsomes as well as in the cytosol. These results suggest that the MCP is primarily associated with cytoplasmic components; the aggregate staining may result from the association of the MCP with cellular membrane systems.

Prosomes and their multicatalytic proteinase activity

Prosomes were first described as being mRNA-associated RNP (ribonucleoprotein) particles and subcomponents of repressed mRNPs (messenger ribonucleoprotein). We show here that prosomes isolated from translationally inactive mRNP have a protease activity identical to that described by others for the multicatalytic proteinase complex (MCP, 'proteasome'). By RNase or non-ionic detergent treatment, the MCP activity associated with repressed non-globin mRNP from avian erythroblasts, sedimenting at 35 S, could be quantitatively shifted on sucrose gradients to the 19-S sedimentation zone characteristic of prosomes, which were identified by monoclonal antibodies. The presence of small RNA in the enzymatic complex was shown by immunoprecipitation of the protease activity out of dissociated mRNP using a mixture of anti-prosome monoclonal antibodies; a set of small RNAs 80-120 nucleotides long was isolated from the immunoprecipitate. Furthermore, on CsCl gradients, colocalisation of the MCP activity with prosomal proteins and prosomal RNA was found, and no difference in the prosomal RNA pattern was observed whether the particles were fixed or not prior to centrifugation. These data indicate that the MCP activity is a property of prosomes, shown to be in part RNP and subcomplexes of in vivo untranslated mRNP. A hypothesis for the role of the prosome-MCP particles in maintaining homeostasis of specific protein levels is proposed.

Proteolysis, proteasomes and antigen presentation

Proteins presented to the immune system must first be cleaved to small peptides by intracellular proteinases. Proteasomes are proteolytic complexes that degrade cytosolic and nuclear proteins. These particles have been implicated in ATP-ubiquitin-dependent proteolysis and in the processing of intracellular antigens for cytolytic immune responses.

Structure and RNA content of the prosomes

Duck erythroblasts prosomes were analysed by small angle neutron scattering (SANS), dynamic light scattering and (cryo-)electron microscopy. A molecular weight of approximately 720,000 +/- 50,000, a radius of gyration of 64 +/- 2 A and a hydrodynamic radius of approximately 86 A were obtained. Electron micrographs show a hollow cylinder-like particle with a diameter of 120 A, a height of 170 A and a diameter of 40 A for the cavity, built of four discs, the two outer ones being more pronounced than those in the center. Results from SANS indicate less then 5% of RNA in the purified prosomes, but nuclease protection assays confirm its presence.