Genes encoded in the major histocompatibility complex affecting the generation of peptides for TAP transport

Processing of some antigens by the standard proteasome but not by the immunoproteasome results in poor presentation by dendritic cells

By stimulating human lymphocytes with an autologous renal carcinoma, we obtained CTL recognizing an antigen derived from a novel, ubiquitous protein. The CTL failed to lyse autologous EBV-transformed B cells, even though the latter express the protein. This is due to the presence in these cells of immunoproteasomes, which, unlike standard proteasomes, cannot produce the antigenic peptide. We show that dendritic cells also carry immunoproteasomes and fail to present this antigen. This may explain why the relevant CTL escape thymic deletion and are not regularly activated in the periphery. Lack of cleavage by the immunoproteasome was also observed for melanoma differentiation antigen Melan-A26-35/HLA-A2, currently used for antitumoral vaccination. For immunization with such antigens, proteins should be less suitable than peptides, which do not require proteasome digestion in dendritic cells.

Distinct functions of tapasin revealed by polymorphism in MHC class I peptide loading

Peptide assembly with class I molecules is orchestrated by multiple chaperones including tapasin, which bridges class I molecules with the TAP and is critical for efficient Ag presentation. In this paper, we show that, although constitutive levels of endogenous murine tapasin apparently are sufficient to form stable and long-lived complexes between the human HLA-B*4402 (B*4402) and mouse TAP proteins, this does not result in normal peptide loading and surface expression of B*4402 molecules on mouse APC. However, increased expression of murine tapasin, but not of the human TAP proteins, does restore normal cell surface expression of B*4402 and efficient presentation of viral Ags to CTL. High levels of soluble murine tapasin, which do not bridge TAP and class I molecules, still restore normal surface expression of B*4402 in the tapasin-deficient human cell line 721.220. These findings indicate distinct roles for tapasin in class I peptide loading. First, tapasin-mediated bridging of TAP-class I complexes, which despite being conserved across the human-mouse species barrier, is not necessarily sufficient for peptide loading. Second, tapasin mediates a function which probably involves stabilization of empty class I molecules and which is sensitive to structural compatibility of components within the loading complex. These discrete functions of tapasin predict limitations to the study of HLA molecules across some polymorphic and species barriers.

The specificity of proteasomes: impact on MHC class I processing and presentation of antigens

We have studied polypeptide processing by purified proteasomes, with regard to proteolytic specificity and cytotoxic T-lymphocyte (CTL) epitope generation. Owing to defined preferences with respect to cleavage sites and fragment length, proteasomes degrade polypeptide substrates into cohorts of overlapping oligopeptides. Many of the proteolytic fragments exhibit structural features in common with major histocompatibility complex (MHC) class I ligands including fragment size and frequencies of amino acids at fragment boundaries. Proteasomes frequently generate definitive MHC class I ligands and/or slightly longer peptides, while substantially larger peptides are rare. Individual CTL epitopes are produced in widely varying amounts, often consistent with immunohierarchies among CTL epitopes. We further found that polypeptide processing is remarkably conserved among proteasomes of eukaryotic origin and that invertebrate proteasomes can efficiently produce known high-copy MHC class I ligands, suggesting evolutionary adaptation of the transporter associated with antigen processing and MHC class I to ancient constraints imposed by proteasomal protein degradation.

Proteolysis and class I major histocompatibility complex antigen presentation

The class I major histocompatibility complex (MHC class I) presents 8-10 residue peptides to cytotoxic T lymphocytes. Most of these antigenic peptides are generated during protein degradation in the cytoplasm and are then transported into the endoplasmic reticulum by the transporter associated with antigen processing (TAP). Several lines of evidence have indicated that the proteasome is the major proteolytic activity responsible for generation of antigenic peptides--probably most conclusive has been the finding that specific inhibitors of the proteasome block antigen presentation. However, other proteases (e.g. the signal peptidase) may also generate some epitopes, particularly those on certain MHC class I alleles. The proteasome is responsible for generating the precise C termini of many presented peptides, and appears to be the only activity in cells that can make this cleavage. In contrast, aminopeptidases in the cytoplasm and endoplasmic reticulum can trim the N terminus of extended peptides to their proper size. Interestingly, the cellular content of proteases involved in the production and destruction of antigenic peptides is modified by interferon-gamma (IFN-gamma) treatment of cells. IFN-gamma induces the expression of three new proteasome beta subunits that are preferentially incorporated into new proteasomes and alter their pattern of peptidase activities. These changes are likely to enhance the yield of peptides with C termini appropriate for MHC binding and have been shown to enhance the presentation of at least some antigens. IFN-gamma also upregulates leucine aminopeptidase, which should promote the removal of N-terminal flanking residues of antigenic peptides. Also, this cytokine downregulates the expression of a metallo-proteinase, thimet oligopeptidase, that actively destroys many antigenic peptides. Thus, IFN-gamma appears to increase the supply of peptides by stimulating their generation and decreasing their destruction. The specificity and content of these various proteases should determine the amount of peptides available for antigen presentation. Also, the efficiency with which a peptide is presented is determined by the protein's half life (e.g. its ubiquitination rate) and the sequences flanking antigenic peptides, which influence the rates of proteolytic cleavage and destruction.

Generation of an Immunodominant CTL Epitope Is Affected by Proteasome Subunit Composition and Stability of the Antigenic Protein

Generation of the HLA-A0201 (A2) influenza Matrix 58–66 epitope contained within the full-length Matrix protein is impaired in cells lacking the proteasome subunits low molecular protein 2 (LMP2) and LMP7. This Ag presentation block can be relieved by transfecting the wild-type LMP7 cDNA into LMP7-deficient cells. A mutated form of LMP7, lacking the two threonines at the catalytic active site, was equally capable of relieving the block in presentation of the influenza Matrix A2 epitope. These observations were extended by analyzing whether modification of the influenza Matrix protein could overcome the block in presentation of the A2 Matrix epitope. Expression of either a rapidly degraded form of the full-length Matrix protein or shorter Matrix fragments led to an efficient presentation of the A2 influenza Matrix epitope by LMP7-negative cells. These findings demonstrate two main points: 1) LMP7 incorporation into the proteasome is of greater importance for the generation of the influenza A2 Matrix epitope than the presence of the LMP7’s catalytic site; and 2) the interplay between cytosolic proteases and stability of target proteins is of importance in optimization of Ag presentation. These observations may have relevance to the immunodominance of tumor and viral epitopes and raise the possibility that generation of shorter protein fragments could be a mechanism to ensure optimal Ag presentation by cells expressing low levels of LMP7.

Distinct Proteolytic Processes Generate the C and N Termini of MHC Class I-Binding Peptides

Most of the MHC class I peptides presented to the immune system are generated during the course of protein breakdown by the proteasome. However, the precise role of the proteasome, e.g., whether this particle or some other protease generates the carboxyl (C) and amino (N) termini of the presented 8- to 10-residue peptides, is not clear. Here, we show that presentation on Db of ASNENMETM, a peptide from influenza nucleoprotein, and on Kb of FAPGNYPAL, a peptide from Sendai virus nucleoprotein, was blocked by the proteasome inhibitor, lactacystin. Using plasmid minigene constructs encoding oligopeptides of various lengths, we found that presentation of ASNENMETM from C-terminally extended peptides that contain this antigenic peptide plus three or five additional amino acids and presentation of FAPGNYPAL from a peptide containing FAPGNYPAL plus one additional C-terminal residue required the proteasome. In contrast, the proteasome inhibitor did not reduce presentation of cytosolically expressed ASNENMETM or FAPGNYPAL or N-terminally extended versions of these peptides, suggesting involvement of aminopeptidase(s) in trimming these N-extended variants. Accordingly, when the N termini of these 3N-extended peptides were blocked by acetylation, they were resistant to hydrolysis by cellular aminopeptidases and pure leucine aminopeptidase. Moreover, if introduced into the cytosol, Ag presentation of these peptides occurred to a much lesser extent than from their nonacetylated counterparts. Thus, the proteasome is essential for the generation of ASNENMETM and FAPGNYPAL peptides from the full-length nucleoproteins. Although it generates the C termini of these presented peptides, distinct aminopeptidase(s) can trim the N termini of these presented peptides to their proper size.

Halophilic 20S proteasomes of the archaeon Haloferax volcanii: purification, characterization, and gene sequence analysis

A 20S proteasome, composed of alpha(1) and beta subunits arranged in a barrel-shaped structure of four stacked rings, was purified from a halophilic archaeon Haloferax volcanii. The predominant peptide-hydrolyzing activity of the 600-kDa alpha(1)beta-proteasome on synthetic substrates was cleavage carboxyl to hydrophobic residues (chymotrypsin-like [CL] activity) and was optimal at 2 M NaCl, pH 7.7 to 9.5, and 75 degrees C. The alpha(1)beta-proteasome also hydrolyzed insulin B-chain protein. Removal of NaCl inactivated the CL activity of the alpha(1)beta-proteasome and dissociated the complex into monomers. Rapid equilibration of the monomers into buffer containing 2 M NaCl facilitated their reassociation into fully active alpha(1)beta-proteasomes of 600 kDa. However, long-term incubation of the halophilic proteasome in the absence of salt resulted in hydrolysis and irreversible inactivation of the enzyme. Thus, the isolated proteasome has unusual salt requirements which distinguish it from any proteasome which has been described. Comparison of the beta-subunit protein sequence with the sequence deduced from the gene revealed that a 49-residue propeptide is removed to expose a highly conserved N-terminal threonine which is proposed to serve as the catalytic nucleophile and primary proton acceptor during peptide bond hydrolysis. Consistent with this mechanism, the known proteasome inhibitors carbobenzoxyl-leucinyl-leucinyl-leucinal-H (MG132) and N-acetyl-leucinyl-leucinyl-norleucinal (calpain inhibitor I) were found to inhibit the CL activity of the H. volcanii proteasome (K(i) = 0.2 and 8 microM, respectively). In addition to the genes encoding the alpha(1) and beta subunits, a gene encoding a second alpha-type proteasome protein (alpha(2)) was identified. All three genes coding for the proteasome subunits were mapped in the chromosome and found to be unlinked. Modification of the methods used to purify the alpha(1)beta-proteasome resulted in the copurification of the alpha(2) protein with the alpha(1) and beta subunits in nonstoichometric ratios as cylindrical particles of four stacked rings of 600 kDa with CL activity rates similar to the alpha(1)beta-proteasome, suggesting that at least two separate 20S proteasomes are synthesized. This study is the first description of a prokaryote which produces two separate 20S proteasomes and suggests that there may be distinct physiological roles for the two different alpha subunits in this halophilic archaeon.

26 S proteasome-mediated production of an authentic major histocompatibility class I-restricted epitope from an intact protein substrate

Peptides displayed on the cell surface by major histocompatibility class I molecules (MHC class I) are generated by proteolytic processing of protein-antigens in the cytoplasm. Initially, antigens are degraded by the 26 S proteasome, most probably following ubiquitination. However, it is unclear whether this proteolysis results in the generation of MHC class I ligands or if further processing is required. To investigate the role of the 26 S proteasome in antigen presentation, we analyzed the processing of an intact antigen by purified 26 S proteasome. A recombinant ornithine decarboxylase was produced harboring the H-2K(b)-restricted peptide epitope, derived from ovalbumin SIINFEKL (termed ODC-ova). Utilizing recombinant antizyme to target the antigen to the 26 S proteasome, we found that proteolysis of ODC-ova by the 26 S proteasome resulted in the generation of the K(b)-ligand. Mass spectrometry analysis indicated that in addition to SIINFEKL, the N-terminally extended ligand, HSIINFEKL, was also generated. Production of SIINFEKL was linear with time and directly proportional to the rate of ODC-ova degradation. The overall yield of SIINFEKL was approximately 5% of the amount of ODC-ova degraded. The addition of PA28, the 20 S, or the 20 S-PA28 complex to the 26 S proteasome did not significantly affect the yield of the antigenic peptide. These findings demonstrate that the 26 S proteasome can efficiently digest an intact physiological substrate and generate an authentic MHC class I-restricted epitope.

Effect of epitope flanking residues on the presentation of N-terminal cytotoxic T lymphocyte epitopes

We here demonstrate that placing two distinct influenza virus nucleoprotein epitopes at the N terminus of a cytosolic protein selectively blocks their presentation to specific cytotoxic T lymphocytes. The block is a cytosolic phenomenon, which can be overcome by distancing the epitope from the protein N terminus by two or more amino acids. Shortening the protein's C terminus fails to relieve the antigen presentation block. These results demonstrate that events at the N terminus of the target protein, rather than at its C terminus, are responsible for the lack of presentation of N-terminal epitopes. We also show that lack of presentation of N terminal epitopes is associated with a modification of the target protein which affects its electrophoretic mobility and isoelectric focusing point. This modification can be prevented by mutating the epitope's N-terminal flanking sequence, which results in an efficient presentation of the N-terminal epitope. Lack of presentation of the N-terminal epitopes results in a reduced ability of influenza-primed mice to clear acute infection with vaccinia virus encoding an N-terminal nucleoprotein epitope. Our results demonstrate that presentation of epitopes localized at the N terminus of cytosolic proteins can be modulated by events occurring at early stages of antigen processing.

IFN-γ Exposes a Cryptic Cytotoxic T Lymphocyte Epitope in HIV-1 Reverse Transcriptase

The proteasome, an essential component of the ATP-dependent proteolytic pathway in eukaryotic cells, is responsible for the degradation of most cellular proteins and is believed to be the main source of MHC class I-restricted antigenic peptides for presentation to CTL. Inhibition of the proteasome by lactacystin or various peptide aldehydes can result in defective Ag presentation, and the pivotal role of the proteasome in Ag processing has become generally accepted. However, recent reports have challenged this observation. Here we examine the processing requirements of two HLA A*0201-restricted epitopes from HIV-1 reverse transcriptase and find that they are produced by different degradation pathways. Presentation of the C-terminal ILKEPVHGV epitope is impaired in ME275 melanoma cells by treatment with lactacystin, and is independent of expression of the IFN-γ-inducible proteasome β subunits LMP2 and LMP7. In contrast, both lactacystin treatment and expression of LMP7 induce the presentation of the N-terminal VIYQYMDDL epitope. Consistent with these observations we show that up-regulation of LMP7 by IFN-γ enhances presentation of the VIYQYMDDL epitope. Hence interplay between constitutive and IFN-γ-inducible β-subunits of the proteasome can qualitatively influence Ag presentation. These observations may have relevance to the patterns of immunodominance during the natural course of viral infection.

Degradation of cell proteins and the generation of MHC class I-presented peptides

Major histocompatibility complex (MHC) class I molecules display on the cell surface 8- to 10-residue peptides derived from the spectrum of proteins expressed in the cells. By screening for non-self MHC-bound peptides, the immune system identifies and then can eliminate cells that are producing viral or mutant proteins. These antigenic peptides are generated as side products in the continual turnover of intracellular proteins, which occurs primarily by the ubiquitin-proteasome pathway. Most of the oligopeptides generated by the proteasome are further degraded by distinct endopeptidases and aminopeptidases into amino acids, which are used for new protein synthesis or energy production. However, a fraction of these peptides escape complete destruction and after transport into the endoplasmic reticulum are bound by MHC class I molecules and delivered to the cell surface. Herein we review recent discoveries about the proteolytic systems that degrade cell proteins, how the ubiquitin-proteasome pathway generates the peptides presented on MHC-class I molecules, and how this process is stimulated by immune modifiers to enhance antigen presentation.

Sequence information within proteasomal prosequences mediates efficient integration of beta-subunits into the 20 S proteasome complex

The maturation of proteases is governed by prosequences. During the biogenesis of the highly oligomeric eukaryotic 20 S proteasome five different prosequence-containing subunits have to be integrated and processed either by autocatalysis or by neighbouring subunits. To analyse the functional impact of proteasomal prosequences during complex formation, the propeptide of the facultative subunit beta1i/LMP2 was truncated to nine amino acid residues or completely deleted. Additionally, the charged residues within the truncated beta1i/LMP2 version were replaced by neutral residues. While deletion did not affect subunit incorporation, the presence of charged residues within the truncated version of the LMP2 propeptide diminished incorporation efficiency, an effect that was restored upon replacement of the charged amino acids against neutral components. During immunoproteasome formation, incorporation and processing of inducible proteasome beta-subunits are cooperative processes. We demonstrate a linear correlation of the levels of beta2i/MECL1 and beta1i/LMP2 within 20 S proteasomes, suggesting a physical interaction to be the molecular basis for the biased incorporation of both subunits. In the absence of beta5i/LMP7, precursor complexes containing unprocessed beta1i/LMP2 accumulated. The contribution of beta5i/LMP7 on the cooperative formation of a homogeneous population of immunoproteasome is therefore most likely based on an acceleration of the beta1i/LMP2 and potentially of beta2i/MECL1 processing kinetics.

Modulation of proteasomal activity required for the generation of a cytotoxic T lymphocyte-defined peptide derived from the tumor antigen MAGE-3

We have analyzed the presentation of human histocompatability leukocyte antigen-A*0201-associated tumor peptide antigen MAGE-3271-279 by melanoma cells. We show that specific cytotoxic T lymphocyte (CTL)-recognizing cells transfected with a minigene encoding the preprocessed fragment MAGE-3271-279 failed to recognize cells expressing the full length MAGE-3 protein. Digestion of synthetic peptides extended at the NH2 or COOH terminus of MAGE-3271-279 with purified human proteasome revealed that the generation of the COOH terminus of the antigenic peptide was impaired. Surprisingly, addition of lactacystin to purified proteasome, though partially inhibitory, resulted in the generation of the antigenic peptide. Furthermore, treatment of melanoma cells expressing the MAGE-3 protein with lactacystin resulted in efficient lysis by MAGE-3271-279-specific CTL. We therefore postulate that the generation of antigenic peptides by the proteasome in cells can be modulated by the selective inhibition of certain of its enzymaticactivities.

Novel Splicing of the Human MHC-Encoded Peptide Transporter Confers Unique Properties

Presentation of intracellularly derived antigenic peptides to T cells requires their assembly together with MHC class I molecules in the endoplasmic reticulum (ER). Such peptides are delivered to the ER by an MHC-encoded transporter composed of TAP1 and TAP2 protein delivery. Here, the first alternative splicing of Tap2 is described. The human splice variant, termed Tap2iso, lacks exon 11 and original 3′ untranslated region and contains a newly identified exon 12 and 3′ untranslated region. The full-length Tap2iso cDNA (2496 bp) predicts a protein of 653 amino acids. Tap2iso mRNA was normally coexpressed with Tap2 mRNA in all human lymphocyte cell lines examined. Function of TAP2iso was evaluated at multilevel in TAP1/2iso and TAP1/2 cotransfected T2 cells, a mutant cell line deplete of endogenous Tap gene products. The TAP1-TAP2iso transporter facilitated the maturation of MHC class I molecules in the ER and restored surface expression of class I. Importantly, TAP1-TAP2iso transporters expressed in T2 cells exhibited distinct and opposing influences on peptide selectivities, at times exceeding 30-fold differences in competition experiments and attributable to diversity in the 3′-COOH tail. The common coexpression of an alternative splice product of the Tap2 gene may contribute to broaden immune diversity, a mechanism previously described to occur predominantly at the level of the TCR and MHC class I gene products.

Independent contributions of HLA epitopes and killer inhibitory receptor expression to the functional alloreactive specificity of natural killer cells

Human NK cells express receptors (KIR) which inhibit lysis through binding to HLA class I on target cells. KIR expression in different individuals has not been intensively investigated and it is not known how the KIR repertoire relates to HLA type or influences the overall activity of NK populations. This may be important in the response of NK cells to HLA-mismatched organ transplants since the ligands for KIR are supertypic epitopes shared between certain HLA alleles. We studied the effect of matching for HLA on the cytotoxicity of NK cells from individuals homozygous or heterozygous for relevant HLA class I epitopes and correlated this with KIR expression and genotype. Considerable variation in the KIR repertoire of different donors was evident, including functional KIR expressed in the absence of specific HLA ligands. We confirmed the predominant influence of HLA-C in a hierarchy of inhibitory effects mediated by HLA class I loci. In certain individuals, inhibition patterns are more complicated and may be due to the relative expression of the CD94/NKG2 receptors. Our study reveals the separate contributions of HLA and KIR molecules to NK cell alloreactivity and provides a basis for consideration of the functional diversity of KIR genes in transplantation.

The ubiquitin system

The selective degradation of many short-lived proteins in eukaryotic cells is carried out by the ubiquitin system. In this pathway, proteins are targeted for degradation by covalent ligation to ubiquitin, a highly conserved small protein. Ubiquitin-mediated degradation of regulatory proteins plays important roles in the control of numerous processes, including cell-cycle progression, signal transduction, transcriptional regulation, receptor down-regulation, and endocytosis. The ubiquitin system has been implicated in the immune response, development, and programmed cell death. Abnormalities in ubiquitin-mediated processes have been shown to cause pathological conditions, including malignant transformation. In this review we discuss recent information on functions and mechanisms of the ubiquitin system. Since the selectivity of protein degradation is determined mainly at the stage of ligation to ubiquitin, special attention is focused on what we know, and would like to know, about the mode of action of ubiquitin-protein ligation systems and about signals in proteins recognized by these systems.

Expression of HLA class I antigens in transporter associated with antigen processing (TAP)-deficient mutant cell lines

Cells lacking expression of the transporter associated with antigen processing (TAP) are deficient in surface HLA class I, yet express reduced levels of HLA-A2 antigen through TAP-independent processing pathways. We have analysed the expression of HLA-A, -B and -C antigens on the 721.174 and T2 TAP-deficient mutant cell lines using a panel of monoclonal antibodies specific for the HLA antigens encoded by the genotype of these cells. Our study has shown the constitutive expression of HLA-Cw1 molecules on the cell surface of both T2 and 721.174 cells and has confirmed that HLA-A2 and HLA-B51 are expressed at low levels. Transfection of 721.174 cells with cDNAs encoding TAP1 and TAP2 proteins did not fully restore HLA class I antigen expression on these cells, which appeared to be mainly due to a deficiency in expression of the HLA-B51-associated Bw4 epitope. This suggests that additional antigen-processing genes may be required for optimal generation of HLA-B-binding peptides. Our results indicate that TAP-independent pathways of antigen-processing provide peptides for functional expression of all three classical HLA class I molecules.

The sequence alteration associated with a mutational hotspot in p53 protects cells from lysis by cytotoxic T lymphocytes specific for a flanking peptide epitope

A high proportion of tumors arise due to mutation of the p53 tumor suppressor protein. A p53 hotspot mutation at amino acid position 273 from R to H, flanking a peptide epitope that spans residues 264-272, renders cells resistant to killing by human histocompatibility leukocyte antigen (HLA)-A*0201-restricted cytotoxic T lymphocytes (CTLs) specific for this epitope. Acquisition of the R to H mutation at residue 273 of the human p53 protein promotes tumor growth in vivo by selective escape from recognition by p53.264-272 peptide-specific CTLs. Synthetic 27-mer p53 polypeptides covering the antigenic nonamer region 264-272 of p53 were used as proteasome substrates to investigate whether the R to H mutation at the P1' position of the COOH terminus of the epitope affects proteasome-mediated processing of the protein. Analysis of the generated products by tandem mass spectrometry and the kinetics of polypeptide processing in conjunction with CTL assays demonstrate that the R to H mutation alters proteasomal processing of the p53 protein by inhibiting proteolytic cleavage between residues 272 and 273. This prevents the release of the natural CTL epitope that spans flanking residues 264-272 as well as a putative precursor peptide. These results demonstrate that mutation of p53 not only leads to malignant transformation but may also, in some instances, affect immune surveillance and should be considered in the design of cancer vaccines.

Altered properties of the branched chain amino acid-preferring activity contribute to increased cleavages after branched chain residues by the "immunoproteasome"

The multicatalytic proteinase complex (MPC, proteasome) is assembled from 14 nonidentical protein subunits. It expresses five distinct proteolytic activities, including a chymotrypsin-like activity, cleaving after hydrophobic residues, and a branched chain amino acid-preferring component (BrAAP), cleaving preferentially after branched chain residues. Exposure of cells to interferons leads to replacement of the X, Y, and Z subunits by the LMP2, LMP7, and MECL1 subunits. This "immunoproteasome" is critical to processing of certain antigens. The enzymatic basis for enhanced antigen processing has not been determined. To gain insight into this question, we examined sites and relative rates of cleavage of bonds in denatured, reduced, carboxyamidomethylated lysozyme, a 129-amino acid protein, by MPC from bovine spleen, in which the X, Y, and Z subunits are replaced by LMP2, LMP7, and MECL1. We compared cleavages to those catalyzed by MPC from bovine pituitary, which contains only the X, Y, and Z subunits. We found marked increases in the rates and number of cleavages after branched chain residues in reduced, carboxyamidomethylated lysozyme by the spleen MPC. This was largely due to accelerated cleavages of bonds after a Phi-X-Br motif, where Phi is a hydrophobic residue, X is a small neutral or polar residue, and Br is a branched chain residue. Inhibitors with these structural properties were selective and potent inhibitors of the BrAAP activity of the spleen MPC. The above findings indicate that alterations in activity and substrate specificity of the BrAAP activity are important factors underlying the altered cleavages after hydrophobic residues associated with incorporation of interferon-inducible subunits. The potential relevance of the findings to antigen processing functions of MPC is discussed.

Mechanisms of MHC class I--restricted antigen processing

Classical class I molecules assemble in the endoplasmic reticulum (ER) with peptides mostly generated from cytosolic proteins by the proteasome. The activity of the proteasome can be modulated by a variety of accessory protein complexes. A subset of the proteasome beta-subunits (LMP2, LMP7, and MECL-1) and one of the accessory complexes, PA28, are upregulated by gamma-interferon and affect the generation of peptides to promote more efficient antigen recognition. The peptides are translocated into the ER by the transporter associated with antigen processing (TAP). A transient complex containing a class I heavy chain-beta 2 microglobulin (beta 2 m) dimer is assembled onto the TAP molecule by successive interactions with the ER chaperones calnexin and calreticulin and a specialized molecule, tapasin. Peptide binding releases the class I-beta 2 m dimer for transport to the cell surface, while lack of binding results in proteasome-mediated degradation. The products of certain nonclassical MHC-linked class I genes bind peptides in a similar way. A homologous set of beta 2 m-associated membrane glycoproteins, the CD1 molecules, appears to bind lipid-based ligands within the endocytic pathway.

Dissociation of Proteasomal Degradation of Biosynthesized Viral Proteins from Generation of MHC Class I-Associated Antigenic Peptides

To study the role of proteasomes in Ag presentation, we analyzed the effects of proteasome inhibitors Cbz-Leu-Leu-Leucinal and lactacystin on the ability of mouse fibroblast cells to present recombinant vaccinia virus gene products to MHC class I-restricted T cells. The effects of the inhibitors depended on the determinant analyzed. For influenza virus nucleoprotein (NP), presentation of the immunodominant Kk-restricted determinant (NP50–57) was marginally inhibited, whereas presentation of the immunodominant Kd-restricted determinant (NP147–155) was enhanced, particularly by lactacystin. Biochemical purification of peptides confirmed that lactacystin enhanced the generation of Kd-NP147–155 complexes fourfold. Lactacystin also enhanced the recovery of one Kd-restricted vaccinia virus determinant from HPLC fractions, while inhibiting recovery of another. The inhibitors were used at sufficient concentrations to block presentation of biosynthesized full-length OVA and to completely stabilize a rapidly degraded chimeric ubiquitin-NP fusion protein. Strikingly, presentation of antigenic peptides from this protein was unaffected by proteasome inhibitors. We also observed that proteasome inhibitors induced expression of cytosolic and endoplasmic reticulum stress-responsive proteins. These data demonstrate first that the processes of protein degradation and generation of antigenic peptides from cytosolic proteins can be dissociated, and second that effects of proteasome inhibitors on Ag presentation may reflect secondary effects on cellular metabolism.

HLA-B27-restricted antigen presentation in the absence of tapasin reveals polymorphism in mechanisms of HLA class I peptide loading

Tapasin is a resident ER protein believed to be critical for antigen presentation by HLA class I molecules. We demonstrate that allelic variation in MHC class I molecules influences their dependence on tapasin for peptide loading and antigen presentation. HLA-B*2705 molecules achieve high levels of surface expression and present specific viral peptides in the absence of tapasin. In contrast, HLA-B*4402 molecules are highly dependent upon human tapasin for these functions, while HLA-B8 molecules are intermediate in this regard. Significantly, HLA-B*2705 like HLA-B*4402, requires tapasin to associate efficiently with TAP (transporters associated with antigen processing). The unusual ability of HLA-B*2705 to form peptide complexes without associating with TAP or tapasin confers flexibility in the repertoire of peptides presented by this molecule. We speculate that these properties might contribute to the role of HLA-B27 in conferring susceptibility to inflammatory spondyloarthropathies.

Promiscuous liberation of MHC-class I-binding peptides from the C termini of membrane and soluble proteins in the secretory pathway

TAP can efficiently transport peptides up to twice as long as those bound to MHC class I molecules, suggesting a role for endoplasmic reticulum (ER) proteases in the trimming of TAP-transported peptides. To better define ER processing of antigenic peptides, we examined the capacity of TAP-deficient cells to present determinants derived from ER-targeted proteins encoded by recombinant vaccinia viruses. TAP-deficient cells failed to present antigenic peptides from internal locations in secreted proteins to MHC class I-restricted T lymphocytes. The same peptides were liberated from the C termini of a secreted protein and the lumenal domains of two membrane proteins delivered to the ER via different routes. These findings suggest that proteases in the secretory compartment can liberate C-terminal antigenic peptides from virtually any context. We propose that this activity often participates in the removal of N-terminal extensions from TAP-transported peptides, thereby creating optimally sized products for MHC class I binding. We further demonstrate that ER trimming of C termini can occur if we express an appropriate carboxypeptidase in the secretory pathway. The absence of such trimming under normal circumstances suggests that carboxypeptidase activity is generally deficient in the ER, consistent with the concordance between the specificity of TAP and MHC class I molecules for the same types of C-terminal residues.

Constitutive and interferon-gamma-induced expression of the human proteasome subunit multicatalytic endopeptidase complex-like 1

Proteasomes generate peptides from intracellular endogenous and viral proteins for presentation by MHC class I molecules. During viral infection, interferon-gamma (IFN-gamma) acts as a cytokine altering the catalytic specificity of proteasomes by inducing the synthesis of the three proteasome subunits, low molecular weight protein (LMP) 2, LMP7 and multicatalytic endopeptidase complex-like 1 (MECL1). LMP2 and LMP7 have been shown to favour the presentation of certain antigenic peptides. These subunits are constitutively expressed in cell lines related to the immune system and IFN-gamma-inducible in other cell lines. Less is known about MECL1. To reveal the extent of constitutive and IFN-gamma-induced expression of MECL1, we studied MECL1 in different cell lines by Northern and Western blotting. The two B cell lines IM9 and Reh showed high constitutive expression of MECL1, only slightly induced by IFN-gamma stimulation. The B cell line Daudi and the monocyte cell line THP-1 expressed MECL1 constitutively at an intermediate level. The MECL1 protein level in the THP-1 cells increased markedly in response to IFN-gamma. In cells unrelated to the immune system, a very low constitutive expression of MECL1 was detected, highly inducible by IFN-gamma. These results indicate that, similar to LMP2 and LMP7, MECL1 is constitutively expressed at high levels only in certain cell lines and can be induced by IFN-gamma in other cell lines. The differential expression of MECL1 may be of importance for which antigenic peptides are presented by different cells as well as by the same cells at different IFN-gamma levels.

Differential processing of influenza nucleoprotein in human and mouse cells

To investigate how early events in antigen processing affect the repertoire of peptides presented by MHC class I molecules, we compared the presentation of the influenza A nucleoprotein epitope 265-273 by HLA-A3 class I molecules in human and mouse cells. Mouse cells that express HLA-A3 failed to present the NP265-273 peptide when contained within the full-length nucleoprotein, to HLA-A3-restricted human cytotoxic T lymphocytes. However, when the epitope was generated directly in the cytosol using a recombinant vaccinia virus that expressed the nonamer peptide, mouse cells were recognized by HLA-A3-restricted CTL. Poor transport of the peptide by mouse TAP was not responsible for the defect as co-infection of mouse cells with recombinant vaccinia viruses encoding the full-length nucleoprotein and the human TAP1 and TAP2 peptide transporter complex failed to restore presentation. These results therefore demonstrate a differential processing of the influenza nucleoprotein in mouse and human cells. This polymorphism influences the repertoire of peptides presented by MHC class I molecules at the cell surface.

A new MHC locus that influences class I peptide presentation

We have investigated the HLA-B27-restricted CTL response to HY minor histocompatibility antigens in rats and mice transgenic for HLA-B27 and human beta2-microglobulin. A polymorphism was found at a locus within the H2 complex, producing two distinct but overlapping sets of B27-presented HY peptides. The locus, named Cim2, mapped between the K and Pb loci, and its product is therefore distinct from TAP, LMP, and tapasin. Identical findings in rats and mice, including identical HY peptide sequences and the failure of a rat Tap2A transgene to alter CTL recognition, suggest that a homologous locus with similar polymorphism exists in the rat. Cim2, or a closely linked locus, was found to exert a broad effect on peptide loading of both HLA-B27 and mouse class I alleles. The data thus establish a strong, previously unrecognized MHC-encoded influence on the class I antigen pathway.

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

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

Production of a specific major histocompatibility complex class I-restricted epitope by ubiquitin-dependent degradation of modified ovalbumin in lymphocyte lysate

Peptide epitopes presented through class I major histocompatability complex (MHC class I) on the cell surface, are generated by proteolytic processing of protein-antigens in the cytoplasm. The length and amino acid sequence determine whether a given peptide can fit into the peptide binding groove of class I heavy chain molecules and subsequently be presented to the immune system. The mode of action of the processing pathway is therefore of great interest. To study the processing mechanism of MHC class I-restricted intracellular antigens, we reconstituted the proteolytic processing of a model antigen in a cell-free system. Incubation of oxidized and urea-treated OVA in lymphocyte lysate resulted in partial degradation of the antigen. Degradation of the antigen depended on the presence of ATP. Addition of methylated ubiquitin abolished the reaction which was then restored by addition of an excess of native ubiquitin, indicating that the breakdown of the antigen in lymphocyte lysate is mediated by the ubiquitin proteolytic system. Upon incubation of modified OVA in lymphocyte lysate, a specific antigenic peptide was generated. The peptide was recognized by cytotoxic T lymphocytes directed against OVA-derived, H-2Kb-restricted peptide (SIINFEKL), and by a monoclonal antibody that recognizes cell-bound Kb-SIINFEKL complexes. Formation of the peptide epitope depended on the presence of ATP and ubiquitin. These results indicate that proteolytic processing of modified OVA is carried out by the ubiquitin-mediated degradation system. The experimental system described provides a tool to analyze the molecular mechanisms underlying the generation of specific, MHC class I-restricted peptide epitopes.

The subunits MECL-1 and LMP2 are mutually required for incorporation into the 20S proteasome

Processing of antigens for presentation by major histocompatibility complex (MHC) class I molecules requires the activity of the proteasome. The 20S proteasome complex is composed of 14 different subunits, 2 of which can be substituted by the interferon gamma (IFN-gamma)-inducible and MHC-encoded subunits LMP2 and LMP7 (low molecular mass poylpeptides 2 and 7). A third subunit, MECL-1, is inducible by IFN-gamma but is encoded outside the MHC. Here we show by cotransfection experiments that the incorporation of MECL-1 into the 20S proteasome is directly dependent on the expression of LMP2 but independent of LMP7. Conversely, the uptake of LMP2 is strongly enhanced by MECL-1 expression. The expression of MECL-1 caused a replacement of the homologous subunit Z in the 20S proteasome complex. LMP2 is required for MECL-1 incorporation at the level of proteasome precursor formation that guarantees the concerted incorporation of two IFN-gamma-inducible proteasome subunits encoded inside and outside the MHC. The obligatory coincorporation of MECL-1 and LMP2 is an important parameter for the interpretation of results obtained with LMP2-deficient cell lines and mice as well as for the design of experiments addressing the function of MECL-1 in antigen presentation.

A case of primary immunodeficiency due to a defect of the major histocompatibility gene complex class I processing and presentation pathway

INTRODUCTION

We report a case of primary immunodeficiency due to a defect of the TAP transporter, an heterodimeric complex which controls the expression of HLA class I molecule by delivering peptides from the cytosol into the lumen of the endoplasmic reticulum. Since childhood, the 36 year old female suffered from recurrent sinusitis/bronchitis. She later developed bronchiectasis and destructive nasal epitheloid granulomata in conjunction with a generalized vasculitic syndrome that did not improve upon immunosuppression and antibiotics.

METHODS

The class I monomorphic W6/32 was used for cell surface staining and immunoprecipitation of MHC class I molecules. Peptide transport assay was carried out in semi-permeabilized cells with iodinated peptides. Antigen presentation experiments were performed using chromium 51 labelled patient B cell line and EBV specific CTL. TAP1 and TAP2 specific antibodies were used for Western blotting and immunoprecipitation of the TAP complex.

RESULTS AND CONCLUSIONS

A severe reduction of MHC class I molecules at the cell surface of the B-cell lines was observed, whereas MHC class II expression was not altered. Isoelectric focusing of metabolically labelled MHC class I molecules revealed that class I heavy chains remain unsialylated, consistent with a block of TAP dependent peptide translocation. These conclusions were confirmed by further experiments showing that peptide translocation was completely abolished. We also demonstrated that presentation of viral antigens through endogenous class I molecules was severely impaired. Immunoprecipitation and Western blotting of TAP1/2 complex showed that TAP2 was not detectable. Further, experiments are in progress to identify the site of the mutation.

Lactacystin and clasto-lactacystin beta-lactone modify multiple proteasome beta-subunits and inhibit intracellular protein degradation and major histocompatibility complex class I antigen presentation

The antibiotic lactacystin was reported to covalently modify beta-subunit X of the mammalian 20 S proteasome and inhibit several of its peptidase activities. However, we demonstrate that [3H]lactacystin treatment modifies all the proteasome's catalytic beta-subunits. Lactacystin and its more potent derivative beta-lactone irreversibly inhibit protein breakdown and the chymotryptic, tryptic, and peptidylglutamyl activities of purified 20 S and 26 S particles, although at different rates. Exposure to these agents for 1 to 2 h reduced the degradation of short- and long-lived proteins in four different mammalian cell lines. Unlike peptide aldehyde inhibitors, lactacystin and the beta-lactone do not inhibit lysosomal degradation of an endocytosed protein. These agents block class I antigen presentation of a model protein, ovalbumin (synthesized endogenously or loaded exogenously), but do not affect presentation of the peptide epitope SIINFEKL, which does not require proteolysis for presentation. Generation of most peptides required for formation of stable class I heterodimers is also inhibited. Because these agents inhibited protein breakdown and antigen presentation similarly in interferon-gamma-treated cells (where proteasomes contain LMP2 and LMP7 subunits in place of X and Y), all beta-subunits must be affected similarly. These findings confirm our prior conclusions that proteasomes catalyze the bulk of protein breakdown in mammalian cells and generate the majority of class I-bound epitopes for immune recognition.

Molecular cloning of the mouse proteasome subunits MC14 and MECL-1: reciprocally regulated tissue expression of interferon-gamma-modulated proteasome subunits

The primary structures of the interferon-gamma-inducible mouse 20S proteasome subunit MECL-1 and its alternate homolog MC14 were determined. Northern analysis of mouse tissues revealed that MECL-1 mRNA predominantly occurred in thymus, lymph nodes, and spleen, whereas small amounts were detected in non-lymphoid tissues such as kidney, muscle, and testis. Unexpectedly, probing RNA blots with MC14 showed that tissues with high MECL-1 expression contained little MC14 and vice versa. A very similar reciprocal tissue expression was subsequently found for the homologous subunit pairs LMP2 and delta as well as LMP7 and MB1. The subunit protein composition of 20S proteasomes purified from liver, thymus, and lung reflected RNA expression. The impact of a regulated reciprocal tissue expression is discussed with respect to thymic selection and the induction of tolerance in potentially autoreactive T cells.

Intracellular location, complex formation, and function of the transporter associated with antigen processing in yeast

Peptide transport across the membrane of the endoplasmic reticulum (ER) gains increasing importance in view of its potential function in selective protein degradation and antigen processing. An example for peptide transport in the ER is the transporter associated with antigen processing (TAP), which supplies peptides for the formation of major-histocompatibility-complex class-I complexes. Here, we have expressed human TAP1 and TAP2 in the yeast Saccharomyces cerevisiae. Expression of both genes resulted in the formation of a stable TAP heterodimer that was localized mainly in the ER. Although a minor fraction of TAP is found in the plasma membrane, TAP is unable to restore a-factor secretion in a mutant cell line that lacks the yeast mating-factor transporter Ste6. Nevertheless, in vitro studies with microsomal vesicles demonstrated that the TAP complex is fully functional in the ER membrane in terms of selective peptide binding, ATP-dependent transport, and specific inhibition by the viral protein of herpes simplex virus ICP47. This offers opportunities for topological, structural and mechanistic studies as well as genetic screenings for TAP functionality.

Structure of 20S proteasome from yeast at 2.4 A resolution

The crystal structure of the 20S proteasome from the yeast Saccharomyces cerevisiae shows that its 28 protein subunits are arranged as an (alpha1...alpha7, beta1...beta7)2 complex in four stacked rings and occupy unique locations. The interior of the particle, which harbours the active sites, is only accessible by some very narrow side entrances. The beta-type subunits are synthesized as proproteins before being proteolytically processed for assembly into the particle. The proforms of three of the seven different beta-type subunits, beta1/PRE3, beta2/PUP1 and beta5/PRE2, are cleaved between the threonine at position 1 and the last glycine of the pro-sequence, with release of the active-site residue Thr 1. These three beta-type subunits have inhibitor-binding sites, indicating that PRE2 has a chymotrypsin-like and a trypsin-like activity and that PRE3 has peptidylglutamyl peptide hydrolytic specificity. Other beta-type subunits are processed to an intermediate form, indicating that an additional nonspecific endopeptidase activity may exist which is important for peptide hydrolysis and for the generation of ligands for class I molecules of the major histocompatibility complex.

Structural and functional properties of proteasome activator PA28

The proteasome activator PA28 or 11S regulator is a protein complex composed of two different but homologous polypeptides, termed PA28alpha and PA28beta. The purified activator protein (approximately 200 kDa) is a ring-shaped heteromultimer containing the two polypeptides, possibly with an (alpha3beta3 stoichiometry. The activator, which by itself shows no hydrolytic activity elicits activation of the proteasome's multiple peptidase activities by binding to the terminal rings of the proteinase. In vitro, active PA28 can be reconstituted from isolated alpha and beta subunits, yielding two different oligomers: with the single alpha subunit, PA28alpha homomultimers with moderate stimulatory activity toward 20S proteasomes are obtained whereas isolated beta-subunits are unable to form oligomers and are devoid of stimulatory activity. However, in the presence of both subunits, alphabeta heteromultimers form, concomitant with restoration of full stimulatory activity. The recent finding that PA28 modulates the proteasome-catalyzed production of antigenic peptides presented to the immune system on MHC class I molecules indicates a cellular function of the activator in antigen processing.

The proteasome-specific inhibitor lactacystin blocks presentation of cytotoxic T lymphocyte epitopes in human and murine cells

We describe the effect of the proteasome specific inhibitor lactacystin on the metabolic stability of influenza nucleoprotein (NP) and on the generation of antigens presented by human and murine class I molecules of the major histocompatibility complex to cytotoxic T lymphocytes (CTL). We show that cells treated with lactacystin fail to present influenza antigens to influenza-specific CTL, but retain the capacity to present defined epitopes expressed as peptides intracellularly by recombinant vaccinia viruses. This block in antigen presentation can be overcome by expressing the viral protein within the lumen of the endoplasmic reticulum, confirming the specificity of lactacystin for cytosolic proteases. We also show that the effect of lactacystin on antigen presentation correlates with the block of breakdown of a rapidly degraded form of the influenza NP linked to ubiquitin. These results demonstrate that proteasome-dependent degradation plays an important role in the cytosolic generation of CTL epitopes.

Regulation of LMP2 and TAP1 genes by IRF-1 explains the paucity of CD8+ T cells in IRF-1-/- mice

The TAP1 and LMP2 genes are central for class I MHC function and share a common promoter. Here, we analyze the molecular mechanism of IFN gamma up-regulation of TAP1 and LMP2. In vivo footprinting indicates IFN gamma up-regulates protein-DNA contacts at an IRF-E that is essential for the up-regulation of TAP1 and LMP2 by IFN gamma. Gel shift analysis indicates that this site binds IRF-1. The expression of TAP1 and LMP2 are both greatly reduced in IRF-1-deficient mice. Surface class I MHC as well as CD8+ T cells are reduced in IRF-1-/- mice. The role of IRF-1 in the regulation of TAP1 and LMP2 suggests a mechanism for the antiviral properties of IRF-1 and the unexpected deficiency of CD8+ T cells observed in IRF-1-/- mice.

Transporter (TAP)-independent processing of a multiple membrane-spanning protein, the Epstein-Barr virus latent membrane protein 2

Antigen presentation to CD8+ cytotoxic T lymphocytes (CTL) usually involves proteolytic cleavage of antigen in the cytosol and the delivery of epitope peptides onto major histocompatibility complex class I molecules in the endoplasmic reticulum (ER) via the heterodimeric peptide transporter TAP1/TAP2. In the few exceptional cases where TAP-independent presentation of an endogenously expressed protein has been observed, the epitope-containing domain of the protein either has naturally accessed or has been directed into the ER lumen where it is thought to become susceptible to ER proteases. Here, we describe a novel example of TAP-independent processing involving the Epstein-Barr virus (EBV) latent membrane protein LMP2, a multiple membrane-spanning protein with minimal projection into the ER. Expression of LMP2 in the TAP-T2 cell line, whether from the resident EBV genome or from a recombinant vaccinia virus vector vacc-LMP2, rendered the cells sensitive to recognition by CTL clones specific for two HLA-A2.1-restricted peptide epitopes, LMP2 329-337 or 426-434. Vacc-LMP2-mediated sensitization to lysis required expression of the antigen de novo in T2 cells and was blocked by brefeldin A. In the same experiments, two other EBV-specific CTL epitopes, one derived from LMP2 but restricted through a different HLA allele (A11), the other restricted through A2.1 but derived from a different viral protein (BMLF1), did not display TAP-independent processing. The results are discussed in relation to the unusual topology of LMP2 in the membrane and the position of the epitope peptides within that structure.

A third interferon-gamma-induced subunit exchange in the 20S proteasome

The 20S proteasome is a protease complex of functional importance for antigen processing. Two of the 14 proteasome subunits, delta and MB1, can be replaced by the major histocompatibility complex (MHC)-encoded and interferon-gamma (IFN-gamma)-inducible subunits LMP2 and LMP7, respectively. LMP2 and LMP7 alter the cleavage site specificity of the 20S proteasome and are required for the efficient generation of T cell epitopes from a number of viral proteins and for optimal MHC class I cell surface expression. We compared the 20S proteasome subunit pattern from IFN-gamma-induced and non-induced mouse fibroblasts on two-dimensional gels and identified a third subunit exchange by microsequencing: the non-MHC-encoded subunit MECL-1 is induced by IFN-gamma and replaces a sofar barely characterized beta subunit designated 'MC14'. In analogy to LMP2 and LMP7, MECL-1 may be functional in MHC class I-restricted antigen presentation.

Antigen processing and presentation by the class I major histocompatibility complex

Major histocompatibility complex (MHC) class I molecules bind peptides derived from cellular proteins and display them for surveillance by the immune system. These peptide-binding molecules are composed of a heavy chain, containing an antigen-binding groove, which is tightly associated with a light chain (beta 2-microglobulin). The majority of presented peptides are generated by degradation of proteins in the cytoplasm, in many cases by a large multicatalytic proteolytic particle, the proteasome. Two beta-subunits of the proteasome, LMP2 and LMP7, are inducible by interferon-gamma and alter the catalytic activities of this particle, enhancing the presentation of at least some antigens. After production of the peptide in the cytosol, it is transported across the endoplasmic reticulum (ER) membrane in an ATP-dependent manner by TAP (transporter associated with antigen presentation), a member of the ATP-binding cassette family of transport proteins. There are minor pathways for generating presented peptides directly in the ER, and some evidence suggests that peptides may be further trimmed in this location. The class I heavy chain and beta 2-microglobulin are cotranslationally translocated into the endoplasmic reticulum where their assembly may be facilitated by the sequential association of the heavy chain with chaperone proteins BiP and calnexin. The class I molecule then associates with the lumenal face of TAP where it is retained, presumably awaiting a peptide. After the class I molecule binds a peptide, it is released for exocytosis to the cell surface where cytotoxic T lymphocytes examine it for peptides derived from foreign proteins.

LMP-associated proteolytic activities and TAP-dependent peptide transport for class 1 MHC molecules are suppressed in cell lines transformed by the highly oncogenic adenovirus 12

Expression of class I major histocompatibility complex antigens on the surface of cells transformed by adenovirus 12 (Ad12) is generally very low, and correlates with the in vivo oncogenicity of this virus. In primary embryonal fibroblasts (H-2b) that express transgenic swine class I antigen (PD1), Ad12-mediated transformation results in inhibition in transport of newly synthesized class I molecules, as well as significant reduction in transporter associated with antigen presentation (TAP) gene expression. In this report we show that reexpression of TAP molecules either by stable transfection of mouse TAP genes or by infection with recombinant vaccinia viruses expressing human TAP genes, only partially reconstitutes the expression and transport of the class I molecules. Further analysis of Ad12-transformed cells revealed that the expression of both LMP2 and LMP7, but not of other proteasome complex components, was downregulated, resulting in altered proteolytic activities of the 20S proteasomes. Reconstitution of both TAP and LMP expression resulted in complete restoration of PD1 cell surface expression and enhanced expression of the endogenous H-2D(b) molecules encoded by recombinant vaccinia viruses, in reconstituted Ad12-transformed cells, efficient transport of H-2 class I molecules could only be achieved by treatment of the cells with gamma-interferon. These data suggest that an additional factor(s) that is interferon-regulated plays a role in the biosynthetic pathway of the class I complex, and that its function is deficient in this cell system. Thus, Ad12 viral transformation appears to suppress the expression of multiple genes that are important for antigen processing and presentation, which allows such transformed cells to escape immune surveillance. This coordinate downregulation of immune response genes must likely occur through their use of common regulatory elements.

LMP2+ proteasomes are required for the presentation of specific antigens to cytotoxic T lymphocytes

BACKGROUND

Major histocompatibility complex (MHC) class I molecules present short peptides generated by intracellular protein degradation to cytotoxic T lymphocytes (CTL). The multisubunit, non-lysosomal proteinases known as proteasomes have been implicated in the generation of these peptides. Two interferon-gamma (IFN-gamma)-inducible proteasome subunits, LMP2 and LMP7, are encoded within the MHC gene cluster in a region associated with antigen presentation. The incorporation of these LMP subunits into proteasomes may alter their activity so as to favour the generation of peptides able to bind to MHC class I molecules. It has been difficult, however, to demonstrate a specific requirement for LMP2 or LMP7 in the presentation of peptide epitopes to CTL.

RESULTS

We describe a T-cell lymphoma, termed SP3, that displays a novel selective defect in MHC class I-restricted presentation of influenza virus antigens. Of the MHC-encoded genes implicated in the class I pathway, only LMP2 is underexpressed in SP3 cells. Expression of IFN-gamma in transfected SP3 cells simultaneously restores LMP2 expression and antigen presentation to CTL. Expression of antisense-LMP2 mRNA in these IFN-gamma-transfected cells selectively represses antigen recognition and the induction of surface class I MHC expression. Moreover, the expression of this antisense-LMP2 mRNA in L929 fibroblast cells, which constitutively express LMP2 and have no presentation defect, blocks the presentation of the same influenza virus antigens that SP3 cells are defective in presenting.

CONCLUSIONS

Our results show that the LMP2 proteasome subunit can directly influence both MHC class I-restricted antigen presentation and class I surface expression.