The DRiP hypothesis decennial: support, controversy, refinement and extension

Regulation of MHC class I assembly and peptide binding

Peptide binding to MHC class I molecules is a component of a folding and assembly process that occurs in the endoplasmic reticulum (ER) and uses both cellular chaperones and dedicated factors. The involvement of glycoprotein quality-control chaperones and cellular oxidoreductases in peptide binding has led to models that are gradually being refined. Some aspects of the peptide loading process (e.g., the biosynthesis and degradation of MHC class I complexes) conform to models of glycoprotein quality control, but other aspects (e.g., the formation of a stable disulfide-linked dimer between tapasin and ERp57) deviate from models of chaperone and oxidoreductase function. Here we review what is known about the intersection of glycoprotein folding, oxidative reactions, and MHC class I peptide loading, emphasizing events that occur in the ER and within the MHC class I peptide loading complex.

A distinct translation initiation mechanism generates cryptic peptides for immune surveillance

MHC class I molecules present a comprehensive mixture of peptides on the cell surface for immune surveillance. The peptides represent the intracellular protein milieu produced by translation of endogenous mRNAs. Unexpectedly, the peptides are encoded not only in conventional AUG initiated translational reading frames but also in alternative cryptic reading frames. Here, we analyzed how ribosomes recognize and use cryptic initiation codons in the mRNA. We find that translation initiation complexes assemble at non-AUG codons but differ from canonical AUG initiation in response to specific inhibitors acting within the peptidyl transferase and decoding centers of the ribosome. Thus, cryptic translation at non-AUG start codons can utilize a distinct initiation mechanism which could be differentially regulated to provide peptides for immune surveillance.

Remodelling of the ubiquitin–proteasome system in response to interferons

Peptide generation by the UPS (ubiquitin–proteasome system) is rate-limiting in MHC class I-restricted antigen presentation in response to virus-induced IFNs (interferons). In this process, the role of IFN-induced rapid remodelling of the UPS is less defined. IFN-mediated de novo formation of different proteasome compositions as i20S (immunoproteasomes) or m20S (mixed-type proteasomes) essentially supports the rapid adjustment of the mammalian immune system to pathogens. This adjustment is of particular importance for the immune response to rapidly replicating viruses. In agreement, i20S formation has been shown to be an accelerated and transient response. Moreover, i20S and/or PA28 (proteasome activator 28) are essentially required for the generation of certain viral epitopes. In the present paper, we discuss how IFNs consecutively regulate the UPS at different levels, thereby improving the immune responsiveness of target cells.

Targeting HIV-1 Gag into the defective ribosomal product pathway enhances MHC class I antigen presentation and CD8+ T cell activation

The main source for endogenous peptides presented by the MHC class I (MHC-I) pathway are de novo-synthesized proteins which are degraded via the ubiquitin proteasome pathway. Different MHC-I Ag pools can be distinguished: first, short-lived defective ribosomal products, which are degraded in concert with or shortly after their synthesis, and, second, functional proteins that enter the standard protein life cycle. To compare the contribution of these two Ag sources to the generation of MHC-I-presented peptides, we established murine cell lines which express as a model Ag the HIV-1 Gag polyprotein fused to ubiquitin (Ub) carrying the epitope SIINFEKL (SL). Gag was expressed either in its wild-type form (UbMGagSL) or as a variant UbRGagSL harboring an N-end rule degron signal. Although UbRGagSL displayed wild-type protein stability, its inherent defective ribosomal products rate observed after proteasome shutdown was increased concomitant with enhanced presentation of the SL epitope. In addition, UbRGagSL induces enhanced T cell stimulation of SL-specific B3Z hybridoma cells as measured in vitro and of adoptively transferred TCR-transgenic OT-1 T cells in vivo. Furthermore, an elevated frequency of SL-specific T cells was detected by IFN-gamma ELISPOT after immunization of naive C57BL/6 mice with UbRGagSL/EL4 cells. These results further underline the role of the defective ribosomal product pathway in adaptive immunity.

The MHC class I peptide repertoire is molded by the transcriptome

Under steady-state conditions, major histocompatibility complex (MHC) I molecules are associated with self-peptides that are collectively referred to as the MHC class I peptide (MIP) repertoire. Very little is known about the genesis and molecular composition of the MIP repertoire. We developed a novel high-throughput mass spectrometry approach that yields an accurate definition of the nature and relative abundance of unlabeled peptides presented by MHC I molecules. We identified 189 and 196 MHC I-associated peptides from normal and neoplastic mouse thymocytes, respectively. By integrating our peptidomic data with global profiling of the transcriptome, we reached two conclusions. The MIP repertoire of primary mouse thymocytes is biased toward peptides derived from highly abundant transcripts and is enriched in peptides derived from cyclins/cyclin-dependent kinases and helicases. Furthermore, we found that approximately 25% of MHC I-associated peptides were differentially expressed on normal versus neoplastic thymocytes. Approximately half of those peptides are derived from molecules directly implicated in neoplastic transformation (e.g., components of the PI3K-AKT-mTOR pathway). In most cases, overexpression of MHC I peptides on cancer cells entailed posttranscriptional mechanisms. Our results show that high-throughput analysis and sequencing of MHC I-associated peptides yields unique insights into the genesis of the MIP repertoire in normal and neoplastic cells.

PRDM1/BLIMP-1 modulates IFN-gamma-dependent control of the MHC class I antigen-processing and peptide-loading pathway

A diverse spectrum of unique peptide-MHC class I complexes guides CD8 T cell responses toward viral or stress-induced Ags. Multiple components are required to process Ag and facilitate peptide loading in the endoplasmic reticulum. IFN-gamma, a potent proinflammatory cytokine, markedly up-regulates transcription of genes involved in MHC class I assembly. Physiological mechanisms which counteract this response are poorly defined. We demonstrate that promoters of functionally linked genes on this pathway contain conserved regulatory elements that allow antagonistic regulation by IFN-gamma and the transcription factor B lymphocyte-induced maturation protein-1 (also known as PR domain-containing 1, with ZNF domain (PRDM1)). Repression of ERAP1, TAPASIN, MECL1, and LMP7 by PRDM1 results in failure to up-regulate surface MHC class I in response to IFN-gamma in human cell lines. Using the sea urchin prdm1 ortholog, we demonstrate that the capacity of PRDM1 to repress the IFN response of such promoters is evolutionarily ancient and that dependence on the precise IFN regulatory factor element sequence is highly conserved. This indicates that the functional interaction between PRDM1 and IFN-regulated pathways antedates the evolution of the adaptive immune system and the MHC, and identifies a unique role for PRDM1 as a key regulator of Ag presentation by MHC class I.

Phagocytosis and antigen presentation in dendritic cells

Like macrophages and neutrophils, dendritic cells (DCs) are considered professional phagocytes. Even if the three cell types phagocytose parasites, bacteria, cell debris, or even intact cells very efficiently, the functional outcomes of the phagocytic event are quite different. Macrophages and neutrophils scavenge and destroy phagocytosed particles, a critical step in innate immunity. DCs, in contrast, have developed means to 'preserve' useful information from the ingested particles that serve to initiate adaptive immune responses. Thus, both phagosomal degradation and acidification are much lower in DCs than in macrophages or neutrophils. Reduced degradation results in the conservation of antigenic peptides and in their increased presentation on major histocompatibility complex class I and II molecules. In this article, we review the mechanisms that control this delicate equilibrium between phagosomal degradation/cytotoxicity and antigen presentation in the different families of phagocytes.

A deterministic model for the processing and presentation of bacteria-derived antigenic peptides

The amount and the dynamics of antigen supply to the cellular antigen processing and presentation machinery differ largely among diverse microbial antigens and various types of antigen presenting cells. The precise influence, however, of antigen supply on the antigen presentation pattern of cells is not known. Here, we provide a basic deterministic mathematical model of antigen processing and presentation of microbial antigens. The model predicts that different types of antigen presenting cells e.g. cells presenting or cross-presenting exogenous antigens, cells infected with replicating microbes, or cells in which microbial antigen synthesis is blocked after a certain period of time have inherently different antigen presentation patterns which are defined by the kinetics of antigen supply. The reevaluation of existing experimental data [Sijts, A.J., Pamer, E.G., 1997. Enhanced intracellular dissociation of major histocompatibility complex class I-associated peptides: a mechanism for optimizing the spectrum of cell surface-presented cytotoxic T lymphocyte epitopes. J. Exp. Med. 185, 1403-1411] describing the processing and presentation of two antigenic peptides derived from the p60 proteins of the facultatively intracellular bacterium Listeria monocytogenes shows that p60 proteins accumulating intracellularly during bacterial infection of cells play no measurable role as substrate for the cytosolic antigen presentation pathway.

How not to be seen: immune-evasion strategies in gene therapy

The development of efficient and safe vectors for gene delivery paved the way for evolution of gene therapy as a new modality for treatment of various inherited disorders and for cancer. The current vectors, viral and non-viral, have their limitations. Innate and adaptive immune responses to vector particles and components may restrict the efficiency of gene transfer and the persistence of expression of the transgene. Results from preclinical studies in animals and more recently data from clinical studies have demonstrated the potential impact of the cellular and the humoral immune response on the therapeutic efficacy. Not only the vector components, but also the transgene products may induce an immune response that negatively affects the therapeutic efficacy. The induction of a cytotoxic T-cell response to transgene-encoded peptides, as well as the production of antibodies directed against secreted proteins have been reported in preclinical and clinical studies, and these may thwart those applications that require long-term expression. Here we will review some of the options to blunt the acquired immune responses to transgene-encoded polypeptides.

Recent advances in antigen processing and presentation

Heterogeneous intracellular pathways and biochemical mechanisms are responsible for generating the glycoprotein complexes of peptide and major histocompatibility complex that are displayed on the surfaces of antigen-presenting cells for recognition by T lymphocytes. These pathways have a profound influence on the specificity of adaptive immunity and tolerance, as well as the context and consequences of antigen recognition by T cells in the thymus and periphery. The field of antigen processing and presentation has continued to advance since the publication of a focus issue on the topic in Nature Immunology in July 2004. Progress has been made on many fronts, including advances in understanding how proteases, accessory molecules and intracellular pathways influence peptide loading and antigen presentation in various cell types.

AIDS virus specific CD8+ T lymphocytes against an immunodominant cryptic epitope select for viral escape

Cryptic major histocompatibility complex class I epitopes have been detected in several pathogens, but their importance in the immune response to AIDS viruses remains unknown. Here, we show that Mamu-B*17(+) simian immunodeficiency virus (SIV)mac239-infected rhesus macaques that spontaneously controlled viral replication consistently made strong CD8(+) T lymphocyte (CD8-TL) responses against a cryptic epitope, RHLAFKCLW (cRW9). Importantly, cRW9-specific CD8-TL selected for viral variation in vivo and effectively suppressed SIV replication in vitro, suggesting that they might play a key role in the SIV-specific response. The discovery of an immunodominant CD8-TL response in elite controller macaques against a cryptic epitope suggests that the AIDS virus-specific cellular immune response is likely far more complex than is generally assumed.

New lane in the information highway: alternative reading frame peptides elicit T cells with potent antiretrovirus activity

CD8(+) T cells rapidly recognize virus-infected cells due to the generation of antigenic peptides from defective ribosomal products (DRiPs) that are encoded by standard open reading frames (ORFs). New data now show that alternative reading frame (ARF) DRiPs can also induce robust CD8(+) T cell responses. ARF-specific T cells control retroviral replication and select for viral escape in monkeys, providing the most compelling evidence to date for the biological relevance of ARF immunosurveillance.

Intrinsic and cooperative antigen-presenting functions of dendritic-cell subsets in vivo

Dendritic cells (DCs) comprise several subsets, and their roles in the presentation of antigens derived from pathogens, vaccines and self tissues are now beginning to be elucidated. Differences in location, life cycle and intrinsic abilities to capture, process and present antigens on their MHC class I and class II molecules enable each DC subset to have distinct roles in immunity to infection and in the maintenance of self tolerance. Unexpected interactions among DC subsets have also been revealed. These interactions, which allow the integration of the intrinsic abilities of different DC types, enhance the ability of the DC network to respond to multiple scenarios of infection.

Endoplasmic reticulum stress: signaling the unfolded protein response

The endoplasmic reticulum (ER) is the cellular site of newly synthesized secretory and membrane proteins. Such proteins must be properly folded and posttranslationally modified before exit from the organelle. Proper protein folding and modification requires molecular chaperone proteins as well as an ER environment conducive for these reactions. When ER lumenal conditions are altered or chaperone capacity is overwhelmed, the cell activates signaling cascades that attempt to deal with the altered conditions and restore a favorable folding environment. Such alterations are referred to as ER stress, and the response activated is the unfolded protein response (UPR). When the UPR is perturbed or not sufficient to deal with the stress conditions, apoptotic cell death is initiated. This review will examine UPR signaling that results in cell protective responses, as well as the mechanisms leading to apoptosis induction, which can lead to pathological states due to chronic ER stress.

Identification of T-cell epitopes for cancer immunotherapy

The effectiveness of T-cell-mediated immunotherapy of cancer depends on both an optimal immunostimulatory context of the therapy and the proper selection with respect to quality and quantity of the targeted tumor-associated antigens (TAA), and, more precisely, the T-cell epitopes contained in these tumor proteins. Our progressing insight in human leukocyte antigen (HLA) class I and class II antigen processing and presentation mechanisms has improved the prediction by reverse immunology of novel cytotoxic T lymphocyte and T-helper cell epitopes within known antigens. Computer algorithms that in silico predict HLA class I and class II binding, proteasome cleavage patterns and transporter associated with antigen processing translocation are now available to expedite epitope identification. The advent of genomics allows a high-throughput screening for tumor-specific transcripts and mutations, with that identifying novel shared and unique TAA. The increasing power of mass spectrometry and proteomics will lead to the direct identification from the tumor cell surface of numerous novel tumor-specific HLA class I and class II presented ligands. Together, the expanded repertoire of tumor-specific T-cell epitopes will enable more precise immunomonitoring and the development of effective epitope-defined adoptive T-cell transfer and multi-epitope-based vaccination strategies targeting epitopes derived from a wider diversity of TAA presented in a broader array of HLA molecules.

Rethinking peptide supply to MHC class I molecules

The notion that peptides bound to MHC class I molecules are derived mainly from newly synthesized proteins that are defective, and are therefore targeted for immediate degradation, has gained wide acceptance. This model, still entirely hypothetical, has strong intuitive appeal and is consistent with some experimental results, but it is strained by other findings, as well as by established and emerging concepts in protein quality control. While not discounting defectiveness as a driving force for the processing of some proteins, we propose that MHC-class-I-restricted epitopes are derived mainly from nascent proteins that are accessed by the degradation machinery prior to any assessment of fitness, and we outline one way in which this could be accomplished.

DC-based cancer vaccines

Because of the large preexisting antigenic load and immunosuppressive environment within a tumor, inducing therapeutically useful antitumor immunity in cancer patients requires the development of powerful vaccination protocols. An approach gaining increasing popularity in the tumor vaccine field is to immunize cancer patients with their own DCs loaded ex vivo with tumor antigens. The underlying premise of this approach is that the efficiency and control over the vaccination process provided by ex vivo manipulation of the DCs generates an optimally potent APC and a superior method for stimulating antitumor immunity in vivo compared with the more conventional direct vaccination methods, offsetting the added cost and complexity associated with this form of customized cell therapy.

Cowpox virus evades CTL recognition and inhibits the intracellular transport of MHC class I molecules

Orthopoxviruses evade host immune responses by using a number of strategies, including decoy chemokine receptors, regulation of apoptosis, and evasion of complement-mediated lysis. Different from other poxviral subfamilies, however, orthopoxviruses are not known to evade recognition by CTL. In fact, vaccinia virus (VV) is used as a vaccine against smallpox and a vector for eliciting strong T cell responses to foreign Ags. and both human and mouse T cells are readily stimulated by VV-infected APC in vitro. Surprisingly, however, CD8(+) T cells of mice infected with cowpox virus (CPV) or VV recognized APC infected with VV but not APC infected with CPV. Likewise, CD8(+) T cells from vaccinated human subjects could not be activated by CPV-infected targets and CPV prevented the recognition of VV-infected APC upon coinfection. Because CD8(+) T cells recognize viral peptides presented by MHC class I (MHC I), we examined surface expression, total levels, and intracellular maturation of MHC I in CPV- and VV-infected human and mouse cells. Although total levels of MHC I were unchanged, CPV reduced surface levels and inhibited the intracellular transport of MHC I early during infection. CPV did not prevent peptide loading of MHC I but completely inhibited MHC I exit from the endoplasmic reticulum. Because this inhibition was independent of viral replication, we conclude that an early gene product of CPV abrogates MHC I trafficking, thus rendering CPV-infected cells "invisible" to T cells. The absence of this immune evasion mechanism in VV likely limits virulence without compromising immunogenicity.

Influence of translation efficiency of homologous viral proteins on the endogenous presentation of CD8+ T cell epitopes

A significant proportion of endogenously processed CD8(+) T cell epitopes are derived from newly synthesized proteins and rapidly degrading polypeptides (RDPs). It has been hypothesized that the generation of rapidly degrading polypeptides and CD8(+) T cell epitopes from these RDP precursors may be influenced by the efficiency of protein translation. Here we address this hypothesis by using the Epstein-Barr virus-encoded nuclear antigen 1 protein (EBNA1), with or without its internal glycine-alanine repeat sequence (EBNA1 and EBNA1DeltaGA, respectively), which display distinct differences in translation efficiency. We demonstrate that RDPs constitute a significant proportion of newly synthesized EBNA1 and EBNA1DeltaGA and that the levels of RDPs produced by each of these proteins directly correlate with the translation efficiency of either EBNA1 or EBNA1DeltaGA. As a consequence, a higher number of major histocompatibility complex-peptide complexes can be detected on the surface of cells expressing EBNA1DeltaGA, and these cells are more efficiently recognized by virus-specific cytotoxic T lymphocytes compared to the full-length EBNA1. More importantly, we also demonstrate that the endogenous processing of these CD8(+) T cell epitopes is predominantly determined by the rate at which the RDPs are generated rather than the intracellular turnover of these proteins.

Proximal effects of Toll-like receptor activation in dendritic cells

Toll-like receptor (TLR) signals induce dendritic cell (DC) differentiation and influence the immunological outcome of their interactions with T cells. Recent in vitro studies demonstrate that TLR signals also trigger striking reorganisation of the DC vacuolar compartments, the cytoskeleton and the machinery of protein translation and turnover. Moreover, TLR ligation within endosomes and phagosomes appears to establish organelle autonomous signals. These changes, which mostly occur within minutes to a few hours after TLR engagement, are adaptations relevant to the antigen capture, processing and migratory phases of the DC life history.

Interplay between protein synthesis and degradation in the CNS: physiological and pathological implications

Compromise of the ubiquitin-proteasome system (UPS) is a potential basis for multiple physiological abnormalities and pathologies in the CNS. This could be because reduced protein turnover leads to bulk intracellular protein accumulation. However, conditions associated with compromised UPS function are also associated with impairments in protein synthesis, and impairment of UPS function is sufficient to inhibit protein synthesis. These data suggest that the toxicity of UPS inhibition need not depend on gross intracellular protein accumulation, and indicate the potential for crosstalk between the UPS and protein-synthesis pathways. In this review, we discuss evidence for interplay between the UPS and protein-synthesis machinery, and outline the implications of this crosstalk for physiological and pathological processes in the CNS.

Plumbing the sources of endogenous MHC class I peptide ligands

From fish to fowl to pharaohs, nearly all cells in jawed vertebrates constitutively process and present peptides derived from endogenously synthesized polypeptides. Such peptides, snug in the binding groove of cell surface MHC class I molecules, enable CD8(+) T cell mediated immunosurveillance of viruses, other intracellular pathogens, and spontaneously arising tumors. The MHC class I system also plays an important role in olfactory-based vertebrate mate selection and perhaps even in preventing direct transmission of tumors between individuals. Recent findings indicate that MHC class I bound peptides are generated at higher efficiency from rapidly degraded polypeptides (including defective ribosomal products) than from old proteins. Intimately linking translation and antigen presentation makes perfect sense for immunosurveillance of acute virus infections, in which speed is of the essence to minimize viral replication, pathogenesis and transmission. The intriguing question of how translation is linked to presentation has prompted the immunoribosome hypothesis of immunosurveillance, which posits that MHC class I peptide ligands are preferentially generated from a subset of translation products.