Newly identified pair of proteasomal subunits regulated reciprocally by interferon gamma.

Interferon (IFN) gamma induces replacements of the proteasomal subunits X and Y by LMP7 and LMP2, respectively, resulting in an alteration of the proteolytic specificity. We found a third pair of proteasome subunits expressed reciprocally in response to IFN-gamma. Molecular cloning of a cDNA encoding one subunit designated as Z, downregulated by IFN-gamma, showed that it is a novel proteasomal subunit with high homology to MECL1, which is markedly induced by IFN-gamma. Thus, IFN-gamma induces subunit replacements of not only X and Y by LMP7 and LMP2, respectively, but also of Z by MECL1, producing proteasomes responsible for immunological processing of endogenous antigens. When processed from their precursors, three pairs of the 10 homologous, but distinct, beta-type subunits of eukaryotic proteasomes, that is, X/LMP7, Y/LMP2, and Z/MECL1, have an NH2-terminal threonine residue, assumed to be part of a catalytic center. These findings suggest that the altered molecular organization of the proteasome induced by IFN-gamma may be responsible for acquisition of its functional change.

cDNA cloning and interferon gamma down-regulation of proteasomal subunits X and Y.

Proteasomes are the proteolytic complex responsible for major histocompatibility complex (MHC) class I-restricted antigen presentation. Interferon gamma treatment increases expression MHC-encoded LMP2 and LMP7 subunits of the proteasome and decreases expression of two proteasome subunits, named X and Y, which alters the proteolytic specificity of proteasomes. Molecular cloning of complementary DNAs encoding X and Y showed that their proteins are proteasomal subunits with high amino acid similarity to LMP7 and LMP2, respectively. Thus, interferon gamma may induce subunit replacements of X and Y by LMP7 and LMP2, respectively, producing proteasomes perhaps more appropriate for the immunological processing of endogenous antigens.

Splice acceptor site mutation of the transporter associated with antigen processing-1 gene in human bare lymphocyte syndrome.

Expression of histocompatibility leukocyte antigen (HLA) class I molecules on the cell surface depends on the heterodimer of the transporter associated with antigen processing 1 and 2 (TAP1 and TAP2), which transport peptides cleaved by proteasome to the class I molecules. Defects in the TAP2 protein have been reported in two families with HLA class I deficiency, the so-called bare lymphocyte syndrome (BLS) type I. We have, to our knowledge, identified for the first time a splice site mutation in the TAP1 gene of another BLS patient. In addition, class I heavy chains (HCs) did not form the normal complex with tapasin in the endoplasmic reticulum (ER) of the cells of our patient.

Yeast counterparts of subunits S5a and p58 (S3) of the human 26S proteasome are encoded by two multicopy suppressors of nin1-1.

Nin1p, a component of the 26S proteasome of Saccharomyces cerevisiae, is required for activation of Cdc28p kinase at the G1-S-phase and G2-M boundaries. By exploiting the temperature-sensitive phenotype of the nin1-1 mutant, we have screened for genes encoding proteins with related functions to Nin1p and have cloned and characterized two new multicopy suppressors, SUN1 and SUN2, of the nin1-1 mutation. SUN1 can suppress a null nin1 mutation, whereas SUN2, an essential gene, does not. Sun1p is a 268-amino acid protein which shows strong similarity to MBP1 of Arabidopsis thaliana, a homologue of the S5a subunit of the human 26S proteasome. Sun1p binds ubiquitin-lysozyme conjugates as do S5a and MBP1. Sun2p (523 amino acids) was found to be homologous to the p58 subunit of the human 26S proteasome. cDNA encoding the p58 component was cloned. Furthermore, expression of a derivative of p58 from which the N-terminal 150 amino acids had been removed restored the function of a null allele of SUN2. During glycerol density gradient centrifugation, both Sun1p and Sun2p comigrated with the known proteasome components. These results, as well as other structural and functional studies, indicate that both Sun1p and Sun2p are components of the regulatory module of the yeast 26S proteasome.

Rejection antigen peptides on BALB/c RL male 1 leukemia recognized by cytotoxic T lymphocytes: derivation from the normally untranslated 5' region of the c-akt proto-oncogene activated by long terminal repeat.

Tumor antigen peptides on BALB/c leukemia RL male 1 that were recognized by cytotoxic T lymphocytes were shown to be derived from a normally untranslated region of the akt proto-oncogene (Uenaka, A. et al., J. Exp. Med., 180: 1599, 1994). We show here that the murine leukemia virus (MuLV) long terminal repeat (LTR) was inserted directly into the exon of c-akt in RL male 1 leukemia and that transcription started from the cap site of the LTR. Translation appeared to start from the ATG codon created in the six nucleotides of unknown origin, which were inserted into the LTR/akt junction. The deduced molecular size is approximately M(r) 59,000 due to the addition of 33 amino acid residues to the normally expressed c-AKT protein. Western blot analysis demonstrated the presence of M(r) 59,000 molecules in an RL male 1 lysate, and their expression at about ten times the level of normal AKT molecules of M(r) 56,000, which is consistent with the increased expression of akt mRNA demonstrated by Northern blot analysis. The findings show that the molecular alteration of AKT protein by insertion of MuLV LTR is the mechanism for creating rejection antigen peptides derived from the untranslated region of akt.

Changes in expressions of proteasome and ubiquitin genes in human renal cancer cells.

Proteasomes and ubiquitin (Ub) are essential components of the energy-dependent, nonlysosomal proteolytic pathway. To clarify the physiological role of this proteasome/Ub-dependent pathway, we meaured the levels of expressions of proteasomes and Ub in human renal cancers by Northern blot and immunochemical analyses. The mRNAs for two of the multiple subunits of proteasomes, C2 and C9, were expressed at abnormally high levels in most neoplastic lesions of patients with various primary renal cell carcinomas and in all renal cancer cell lines examined. However, no significant difference was found by enzyme immunoassay in the proteasomal contents of cancerous and normal parts of the kidney. The levels of mRNAs for the subunits of proteasomes were high in rapidly proliferating renal cells and appeared to be correlated with the activities of these cells for proteasome synthesis, but the cellular contents of proteasomes in these cells were normal, suggesting rapid turnover of proteasomes in rapidly proliferating cancer cells. Consistent with the increased expressions of proteasomal mRNAs, the expressions of three Ub genes, mono-UbA80, mono-UbA52, and poly-UbC, were found to be greatly increased in these renal cancer cells. Immunohistochemical staining of normal kidney showed that the levels of both proteasomes and Ub were high in cells of renal tubules and collecting ducts, but low in the glomerulus. The levels of both proteins appeared to be considerably increased in the nuclei of granular and clear carcinoma cells of the kidney. Moreover, the profiles of cellular proteins conjugated with Ub in normal kidney tissues were different from those in cancerous parts of the kidney and in established renal cancer cells. These results suggest that the proteasome- and ubiquitin-mediated system is functionally involved in the cancerous state in human kidney.

Covalent modification of all members of human cullin family proteins by NEDD8.

Recently we found that NEDD8, a ubiquitin-like protein, was linked covalently to human cullin-4A (abbreviated Cul-4A) by a new ubiquitin-related pathway that is analogous to but distinct from the ligating system for SUMO1, another ubiquitin-like protein. However, it remained unknown whether the other five members of the family of human cullin/Cdc53 proteins are modified by NEDD8. Here we report that all Hs-Cul family proteins, such as Cul-1, Cul-2, Cul-3, Cul-4B, and Cul-5, in addition to Cul-4A, were modified by covalent attachment of NEDD8 in rabbit reticulocyte lysates. Moreover, by comprehensive Northern-blot analyses, we examined multiple tissue distributions of the messages for all Cul-family proteins, NEDD8, and the NEDD8-ligating system consisting of APP-BP1/hUba3, and hUbc12, which function as E1- and E2-like enzymes, respectively. The expressions of Cul-1, Cul-2, and Cul-3 resembled each other and were apparently correlated to those of NEDD8 and the NEDD8-ligating system in various human cells and tissues. However, the mRNA levels of Cul-4A, Cul-4B, and Cul-5 differed considerably from each other as well as from other Cul-family proteins. The enhanced expression of all Cul-family proteins except Cul-5 was observed in a variety of tumor cell lines.

Expression of random peptide fused to invasin on bacterial cell surface for selection of cell-targeting peptides.

The protein invasin expressed on the cell surface of the pathogenic bacteria Yersinia pseudotuberculosis mediates the entry of this bacterium into cultured mammalian cells. We have developed a system for expression of random peptides on the cell surface of Escherichia coli (E. coli) by creation of a fusion hybrid between a peptide and the invasin protein. The fusion protein constructs consist of part of the outer membrane domain of the invasin protein, six proline spacers, and a decamer of random peptides flanked by cysteine residues (CX(10)C). Peptides were constitutively expressed on the cell surface in the resulting random decamer peptide library, which we designated as ESPEL (E. coli Surface Peptide Expression Library). The ESPEL was systematically screened for its binding affinity toward human cultured cells. Several bacterial clones were identified whose binding to human cells was mediated by peptides expressed on the bacterial cell surface. Flow cytometric analysis showed that both the identified bacterial clones and these corresponding chemically synthesized peptides bound to human cells specifically. The techniques described provide a new method that uses E. coli random peptide library to select targeting peptides for mammalian cells without any knowledge of the human cellular receptors.

Down-regulation of ubiquitin gene expression during differentiation of human leukemia cells.

Ubiquitin, which is ligated covalently to target proteins for their acquisition of a variety of functions, is encoded by multiple unique genes in human cells: two distinct poly-ubiquitin genes with tandemly repeated sequences of 3 or 9 moieties and two mono-ubiquitin genes fused with small and large ribosomal proteins. We found that all classes of ubiquitin genes as well as the two genes encoding the ribosomal proteins S17 and L31 were expressed at abnormally high levels in various hematopoietic malignant tumor cells. In contrast, in vitro terminal differentiation of various immature leukemic cell lines, such as HL-60 promyelocytic leukemia cells and K562 erythroleukemia cells into monocytic, granulocytic and erythroid cells, induced by various agents was found to cause rapid and marked down-regulation of ubiquitin expression, irrespective of the cell type, direction of differentiation or type of signal. These findings suggest that the expressions of the multiple ubiquitin genes, coordinated with those of the ribosomal protein genes, are in a dynamic state during growth and differentiation of leukemia cells.

cDNA cloning of rat proteasome subunit RC1, a homologue of RING10 located in the human MHC class II region.

The nucleotide sequence of a cDNA that encodes a new subunit, named RCl, of rat proteasomes (multicatalytic proteinase complexes) has been determined. The polypeptide predicted from the open reading frame consisted of 208 amino acid residues with a calculated molecular mass of 23, 130, which is consistent with the size obtained by electrophoretic analysis of purified RCl. The partial amino acid sequences of several fragments of RCl, obtained by protein chemical analyses, were found to be in excellent accordance with those deduced from the cDNA sequence. Surprisingly, the overall structure of RCl was found to be almost identical to that of recently isolated RING10, whose gene is located in the class II region of the human MHC gene cluster. This finding suggests that RCl is a homologue of human RING10, supporting the proposal that proteasomes are involved in the antigen processing pathway.

Replacement of proteasome subunits X and Y by LMP7 and LMP2 induced by interferon-gamma for acquirement of the functional diversity responsible for antigen processing.

Proteasomes catalyze the non-lysosomal, ATP-dependent selective breakdown of ubiquitinated proteins and are thought to be responsible for MHC class I-restricted antigen presentation. Recently, we reported that gamma interferon (IFN-gamma) induced not only marked synthesis of the MHC-encoded proteasome subunits LMP2 and LMP7, but also almost complete loss of two unidentified proteasome subunits tentatively designated as X and Y in various human cells. Here, we show that subunit X is a new proteasomal subunit highly homologous to LMP7, and that subunit Y is identical to the LMP2-related proteasomal subunit delta. Thus, IFN-gamma appears to induce subunit replacements of X and Y by LMP7 and LMP2, respectively, producing 'immuno-proteasomes' with the functional diversity responsible for processing of endogenous antigens.

cDNA cloning of a new putative ATPase subunit p45 of the human 26S proteasome, a homolog of yeast transcriptional factor Sug1p.

The nucleotide sequence of a cDNA that encodes a new regulatory subunit, named p45, of the 26S proteasome of human hepatoblastoma HepG2 cells has been determined. The polypeptide predicted from the open reading frame consists of 406 amino acid residues with a calculated molecular weight of 45770 and isoelectric point of 8.35. The sequences of several fragments of bovine p45, determined by protein chemical analyses, spanning 27% of the complete structure, were found to be in excellent accord with those deduced from the human cDNA sequence. Computer analysis showed that p45 belongs to a family of putative ATPases which includes regulatory components of 26S proteasomes. The overall structure of p45 was found to be homologous to that of yeast Sug1p, which has been identified as a transcriptional factor. It is closely similar, but not identical to the sequence reported for Trip1, a functional homolog of Sug1p in human tissues. These results are consistent with the possibility that Sug1-like proteins with distinct sequence function in transcription and protein degradation in human cells. However, the alternative hypothesis, that the same gene locus encodes both p45 and Trip1, cannot be excluded on the basis of such closely similar sequences. In either case, both proteins are likely to function equivalently well in either transcription or protein degradation.

Molecular cloning of cDNAs for rat proteasomes: deduced primary structures of four other subunits.

Proteasomes (multi-protease complexes) are composed of approximately 15 non-identical subunits of similar sizes (molecular weight = 21-32 kDa), but different charges (isoelectric point = 4-9). Previously, we deduced the primary structures of 6 subunits of rat proteasomes by recombinant DNA techniques. In this paper we report the nucleotide sequences of 4 other subunits, rIOTA, rZETA, rDELTA, and rRING12, determined from cDNA clones isolated by screening a rat H4TG hepatoma cell cDNA library with the cDNAs of their human counterparts as probes. The polypeptides deduced from their nucleotide sequences consisted of 246, 241, 202, and 219 amino acid residues with calculated molecular weights of 27,399, 26,391, 21,649, and 23,324, and calculated isoelectric points of 6.37, 4.65, 4.84, and 4.70, respectively. These results and previous findings indicate that the primary structures of the subunits of rat proteasomes show considerably high inter-subunit homology, but can be classified into apparently distinct sub-groups, suggesting that rat proteasome genes form a multi-gene family with the same evolutionary origin, but have diverged during evolution to acquire possibly subunit-specific functions.

Interferon-gamma induces different subunit organizations and functional diversity of proteasomes.

To obtain information on the role of proteasomes in the immune system, we examined the effect of a major immunomodulatory cytokine, gamma interferon (IFN-gamma), on the expressions, structures, and functions of proteasomes. IFN-gamma greatly increased the levels of the mRNAs encoding LMP2 and LMP7, putative immuno-proteasome subunits encoded by genes within the class II MHC region, and these two subunits synthesized were assembled completely into the proteasomal multi-subunit complex in various types of human cells. The subunit organization of proteasome changed in response to IFN-gamma stimulation, due to assembly of newly synthesized subunits through up- and down-expressions of at least 6 proteasome genes including LMP2/LMP7 without change in the structure of pre-existing proteasomes. Interestingly, IFN-gamma dramatically stimulated the trypsin-like and chymotrypsin-like activities of the multifunctional proteasome and depressed the peptidylglutamyl-peptide-hydrolyzing activity, without affecting the activity for ATP-, ubiquitin-dependent proteolysis. These results indicate that IFN-gamma modifies not only the structural organization of the proteasome, but also its functions. Based on these findings, we discuss the role in the antigen processing/presentation pathway of proteasomes with functional diversity acquired through alteration of their subunit assembly in response to IFN-gamma stimulation.

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.

The involvement of proteasome in myogenic differentiation of murine myocytes and human rhabdomyosarcoma cells.

The murine C2C12 myocytes terminally differentiate to myotubes in the mitogen-depletion, and a portion of the cells undergo apoptosis. In this study, a specific proteasome inhibitor lactacystin induced cell cycle withdrawal and precocious expression of myosin in C2C12 cells in mitogen-enriched medium, but these cells did not fuse to form myotubes. Mitogen-starved myocytes could not differentiate to myotubes under the proteasome inhibition. The genes for p21, MyoD, Myogenin and RB were activated, and p27 gene was repressed under the proteasome inhibition, suggesting the transcriptional regulation of these genes linked to the proteasome activity. The induction of p21 prior to MyoD may contribute to the incomplete myogenesis in the presence of lactacystin. In addition, lactacystin-treated C2C12 cells did not undergo apoptosis, while proteasome accumulated in the nuclei of apoptotic cells but not in those of myotubes during mitogen-depleted differentiation. Further, lactacystin induced similarly incomplete differentiation in human RD embryonal rhabdomyosarcoma cells. Our findings demonstrated that proteasome has an essential role in myogenesis, especially in transcriptional control of myogenic and cell cycle regulators, cell fusion forming myotubes, and apoptosis.

Functional maintenance of hepatocytes on collagen gel cultured with simple serum-free medium containing sodium selenite.

We found that simple serum-free medium containing sodium selenite (Se) is effective for long-term maintenance of functional hepatocytes cultured on a pepsin-digested collagen gel (DC-gel). The concentration of Se was important for maintenance of hepatocytes, and its optimal concentration was 10(-7) approximately 10(-6)M. The effect of Se was specific, as other metals did not have the same effect. The effect was equal to that of fetal bovine serum for maintenance of functional hepatocytes. Using this medium, we could obtained a high level of hepatocellular function including the production of albumin and transferrin, and activity of p450 throughout a long-term culture. Matrigel was almost equal to DC-gel for albumin secretion, but less effective for transferrin secretion, and P450 activity in long-term cultures. The growth of cells on DC-gel or matrigel was not observed, and cell morphology of a round-shaped form was similar on both substrata. These results indicate that serum-free medium containing Se in a DC-gel culture system provides a simple method for long-term culture of hepatocytes.

Tissue and cell distribution of a mammalian proteasomal ATPase, MSS1, and its complex formation with the basal transcription factors.

The proteasome is an eukaryotic multi-subunit protease complex composed of one 20S core component and two 19S regulatory complexes. The regulatory complex contains 6 putative ATPases. We investigated tissue and cell distribution of one of these ATPases, MSS1 (mammalian suppressor of sgv1). MSS1 was ubiquitously present in rat tissues as was the 20S core component of proteasome. However, the ratio of MSS1 to 20S varied greatly among tissues and MSS1 was concentrated in the thymus. Glycerol gradient sedimentation analysis revealed that MSS1 is included in protein complexes whose density is lighter than that of the proteasome. MSS1 was distributed in mammalian cells ubiquitously, while proteasome was rather concentrated in the nuclei. Hence, a novel molecular status of MSS1 distinct from proteasome is implicated. Interestingly, multiple basal transcription factors for RNA polymerase II, including TBP, TFIIB, TFIIH, and TFIIF, were found to be associated with MSS1. These results suggest that MSS1, in addition to proteolysis, plays a role in DNA metabolism including transcriptional regulation.