MHC class I-restricted exogenous presentation of a synthetic 102-mer malaria vaccine polypeptide

The circumsporozoite (CS) is the most abundant surface protein of the Plasmodium sporozoite, and is also present early in the liver stage of the infection. Following successful protective experiments in mice and monkeys, the synthetic 102-mer malaria vaccine polypeptide representing the C-terminal region of the CS of Plasmodium falciparum was tested in a clinical trial with healthy human volunteers. This vaccine induced strong CD8(+), CD4(+) T lymphocyte and antibody responses specific for the immunizing peptide. CD8(+) T lymphocyte responses elicited in HLA-A*0201 volunteers recognized two well-defined cytotoxic T lymphocyte epitopes within the CS. Here, we show that both monocyte-derived dendritic cells (Mo-DC) and Epstein-Barr virus-transformed B-lymphoblastoid cells (LCL) can present a cytotoxic T lymphocyte epitope contained within the 102-mer synthetic peptide. Paraformaldehyde and low temperature inhibited presentation, indicating that cellular processing was required. Using specific inhibitors, we show that, in both cell types, processing requires the proteasome and the MHC class I pathway, while the endosomal compartment appears to be critical only for the presentation by Mo-DC. Antigen uptake is associated with actin polymerization in both cell types. These in vitro results demonstrate the likely pathway of antigen presentation achieved via vaccination with this synthetic peptide.     

Mechanisms of MHC class I-restricted antigen processing and cross-presentation

Summary: In this review, we discuss recent data from our laboratory that address two aspects of major histocompatibility complex (MHC) class I‐restricted antigen processing. First, we consider the nature of the peptide‐loading complex, which is the assembly of proteins in the endoplasmic reticulum (ER) into which newly synthesized MHC class I‐β₂ microglobulin (β₂m) heterodimers are incorporated, and the mechanisms involved in MHC class I assembly and peptide loading that are facilitated by the peptide‐loading complex. Second, we discuss mechanisms of cross‐presentation, the phenomenon whereby extracellular and luminal protein antigens can be processed by antigen‐presenting cells, particularly dendritic cells, and presented by MHC class I molecules to CD8⁺ T cells. The focus of the discussion is mainly on the human MHC class I system.     

Generation of MHC class I-restricted cytotoxic T lymphocytes by expression of a viral protein in muscle cells: antigen presentation by non-muscle cells.

Expression of reporter genes in muscle cells has been achieved by intramuscular (i.m.) injection of plasmid DNA expression vectors. We previously demonstrated that this technique is an effective means of immunization to elicit both antibodies capable of conferring homologous protection and cell-mediated immunity leading to cross-strain protection against influenza virus challenge in mice. These results suggested that expression of viral proteins by muscle cells can result in the generation of cellular immune responses, including cytotoxic T lymphocytes (CTL). However, because DNA has the potential to be internalized and expressed by other cell types, we sought to determine whether or not induction of CTL required synthesis of antigen in non-muscle cells and if not whether transfer of antigen to antigen-presenting cells from muscle cells may be involved. In the present study we demonstrate that transplantation of nucleoprotein (NP)-transfected myoblasts into syngeneic mice led to the generation of NP-specific antibodies and CTL and cross-strain protective immunity against a lethal challenge with influenza virus. Furthermore transplantation of NP-expressing myoblasts (H-2k) intraperitoneally into F1 hybrid mice (H-2d x H-2k) elicited NPCTL restricted by the MHC haplotype of both parental strains. These results indicate that NP expression by muscle cells after transplantation was sufficient to generate protective cell-mediated immunity and that induction of the CTL response was mediated at least in part, by transfer of antigen from the transplanted muscle cells to a host cell.     

Major histocompatibility complex class I-restricted antigen processing and presentation

Major histocompatibility complex (MHC) class I molecules present antigenic peptides to CD8-expressing cytotoxic T lymphocytes (CTLs). This antigen recognition system is critically important for immune surveillance against viruses and tumors. Most class I-binding peptides are generated in the cytosol, as side products from the degradation of misfolded proteins by proteasomes. A subset of the resulting peptides are translocated across the endoplasmic reticulum (ER) membrane by a dedicated peptide transporter, and these peptides are then loaded onto peptide-receptive class I molecules in the ER. The stable assembly of class I molecules with peptides is controlled by a variety of accessory proteins, including chaperones with general housekeeping functions and factors with dedicated roles in class I assembly. Peptide-filled class I molecules are then delivered to the cell surface for recognition by CTLs. This highly regulated process permits the host to rapidly counter invading pathogens with strong and sustained CTL responses and, at the same time, avoid misguided attacks. Here, how the class I antigen processing machinery accomplishes this daunting task is reviewed.     

Rapid identification of MHC class I-restricted antigens relevant to autoimmune diabetes using retrogenic T cells

The method described herein provides a novel strategy for the rapid identification of CD8(+) T cell epitopes relevant to type 1 diabetes in the context of the nonobese diabetic (NOD) mouse model of disease. Obtaining the large number of antigen-sensitive monospecific T cells required for conventional antigen discovery methods has historically been problematic due to (1) difficulties in culturing autoreactive CD8(+) T cells from NOD mice and (2) the large time and resource investments required for the generation of transgenic NOD mice. We circumvented these problems by exploiting the rapid generation time of retrogenic (Rg) mice, relative to transgenic mice, as a novel source of sensitive monospecific CD8(+) T cells, using the diabetogenic AI4 T cell receptor on NOD.SCID and NOD.Rag1(-/-) backgrounds as a model. Rg AI4 T cells are diabetogenic in vivo, demonstrating for the first time that Rg mice are a means for assessing the pathogenic potential of CD8(+) T cell receptor specificities. In order to obtain a sufficient number of Rg CD8(+) T cells for antigen screens, we optimized a method for their in vitro culture that resulted in a approximately 500 fold expansion. We demonstrate the high sensitivity and specificity of expanded Rg AI4 T cells in the contexts of (1) specific peptide challenge, (2) islet cytotoxicity, and (3) their ability to resolve previously defined mimotope candidates from a positional scanning peptide library. Our method is the first to combine the speed of Rg technology with an optimized in vitro Rg T cell expansion protocol to enable the rapid discovery of T cell antigens.     

Alternative pathways for processing exogenous and endogenous antigens that can generate peptides for MHC class I-restricted presentation

Summary: The concept of distinct endogenous and exogenous pathways for generating peptides for MHC-I and MHC-II-restricted presemation to CD4⁺ or CD8⁺ T cells fits well with the bulk of experimental data. Nevertheless, evidence is emerging for alternative processing pathways that generate peptides for MHC-I-restricted presentation. Using a well characterized, particulate viral antigen of prominent medical importance (the hepatitis B surface antigen), we summarize our evidence that the efficient, endolysosomal processing of exogenous antigens can lead to peptide-loaded MHC-I molecules. In addition, we describe evidence for endolysosomal processing of mutant, stress protein-bound, endogenous antigens that liberate peptides binding to (and presented by) MHC-I molecules. The putative biological role of alternative processing of antigens generating cytotoxic T lymphocyte-stimulating epitopes is discussed.     

Antigen processing for presentation by MHC class I molecules.

The association of peptide fragments with MHC class I molecules is believed to be a requirement for the assembly of the MHC class I molecules in the endoplasmic reticulum, and transportation of the MHC molecules from the endoplasmic reticulum to the cell surface. Recently, investigators have begun to elucidate the mechanisms of fragmentation and transport of peptide fragments within antigen-presenting cells, and to define size and structure of naturally processed peptides bound to MHC complexes.     

Alternative processing for MHC class I presentation by immature and CpG-activated dendritic cells

Exogenous proteins can be processed by antigen-presenting cells for the generation of MHC class I-restricted T cell responses. Where this occurs is not clear, although both transfer of internalized antigen into the cytosol and alternative processing in endolysosomes and phagosomes have been reported. Here we have studied the capacity of bone marrow-derived mouse myeloid dendritic cells (DC) to process the OVA protein for peptide presentation by H2-K(b). We have found that immature DC (iDC), both wild-type and transporter associated with antigen processing (TAP)-deficient cells, can transiently process OVA in a pathway which is resistant to inhibitors of the classical MHC class I pathway including the Golgi inhibitor Brefeldin A (BFA) and the proteasome inhibitor lactacystin. This alternative pathway is not found in subcultured DC with an intermediate maturity (imDC) or in resting, IL-3 expanded macrophages but can be re-expressed in imDC if these are activated by an immunostimulatory CpG oligonucleotide. Both iDC and CpG-activated DC were found to process OVA by regurgitation. In addition, we found that iDC secrete proteolytic enzymes into the supernatant, which can process OVA in the extracellular phase. These results suggest that multiple pathways exist for the processing of exogenous protein antigens into MHC class I-binding peptides.     

Dendritic cells pulsed with exogenous hepatitis B surface antigen particles efficiently present epitopes to MHC class I-restricted cytotoxic T cells

L(d)- and K(b)-binding epitopes processed by murine dendritic cells (DC) pulsed with exogenous, particulate hepatitis B surface antigen (HBsAg) are presented to cytotoxic T lymphocytes (CTL). The specific and dose-dependent induction of IFN-gamma release and cytotoxicity in CTL by metabolically active DC did not depend on antigenic peptides contaminating the particles, was cytochalasin D resistant, independent of the maturation state of DC, and blocked by primaquine, amiloride and NH(4)Cl (indicating involvement of acid proteolysis). The specific immunostimulatory phenotype of pulsed DC was maintained for about 3 h after the end of the pulse but rapidly decayed thereafter. Processing of L(d)- and K(b)-binding epitopes from exogenous HBsAg particles by pulsed DC for presentation was TAP independent. Surface-associated 'empty' (presentation-deficient) 64(+) L(d) molecules (defined by the mAb 64-3-7), but not trimeric (presentation-competent) 30(+) L(d) molecules (defined by the mAb 30-5-7) had to be available during the pulse of DC with exogenous HBsAg particles to generate 30(+) L(d)molecules that present the antigenic S(28-39) peptide. Exogenous beta2-microglobulin present during the pulse of DC with HBsAg particles facilitated presentation of L(d)- and K(b)-restricted epitopes. DC generated from bone marrow progenitors in vitro, as well as splenic and liver DC (generated in vivo) presented epitopes to specific CTL. HBsAg particles thus efficiently enter an alternative processing pathway in DC that leads to presentation of epitopes to MHC class I-restricted CTL.     

Yersinia enterocolitica-mediated translocation of defined fusion proteins to the cytosol of mammalian cells results in peptide-specific MHC class I-restricted antigen presentation

Yersinia enterocolitica delivers a set of effector proteins [Yersinia outer proteins (Yop)] into the cytosol of target cells to modulate host cell signal transduction pathways required for the extracellular survival of the bacterium. Secretion and subsequent translocation of Yop across the eukaryotic cell membrane are achieved via a type III secretion system. About 50 - 100 amino acids of the N terminus of Yop are required for chaperone-directed secretion and translocation. In this study, it is demonstrated by immunoblot analysis of Yersinia-infected cultured epithelial cells that one ot these proteins, YopE, can serve as a molecular carrier to deliver protein fragments of the heterologous p60 antigen of Listeria monocytogenes into the cytosol of target cells. T cell activation assays revealed that the observed type III-mediated antigen translocation led to a p60 peptide-specific MHC class I-restricted antigen presentation. Efficient translocation and antigen presentation were strictly dependent on the co-localized expression of hybrid YopE-p60 proteins and the YopE-specific chaperone SycE. These results suggest that the Yersinia type III secretion system may serve as an attractive tool for antigen delivery in Yersinia-based live vaccines to induce cellular immune responses.     

Major histocompatibility complex class I-restricted presentation of protein antigens without prior intracellular processing

Proteins in their native form are incapable of stimulating antigen (Ag)-specific T cells, which can only recognize major histocompatibility complex (MHC)-bound peptides that have been generated by intracellular processing within antigen-presenting cells (APCs). Here, we show that APCs can trigger MHC class I-restricted T-cell responses after presenting proteins without conventional intracellular processing, provided the immunostimulatory MHC class I-binding peptide sequence is incorporated at the carboxy-terminal position. Such MHC-bound proteins do not stimulate T cells directly, because the contact between MHC/peptide complex and its cognate ligand is sterically hindered by the amino-terminal bulk of the protein. Removal of the latter via an extracellular Ag proteolysis by the T-cell- and/or APC-derived enzymes is required for effective T-cell stimulation. Our data challenge the established concept that only small peptides can bind to the MHC class I molecules.     

The tetramer model: a new view of class II MHC molecules in antigenic presentation to T cells

Crystallographic studies suggest a plausible divalent interaction between T-cell receptor (TCR) and MHC class II molecules. In addition, biochemical data suggest that these divalent MHC molecules are preformed at the membrane of the antigen-presenting cell. The tetramer model is based on these preformed tetrameric class II molecules that can be loaded with identical or different peptides in their two grooves. This enables divalent class II molecules to deliver two different messages to T cell: 1) a two-peptide message, in which the tetramer with two identical peptides is able to cross-link two TCRs triggering full activation of a T cell. At the thymic level we propose that this message induces negative selection; or 2) a one-peptide message: only one of the peptides loaded in the class II tetramer is able to interact with that TCR. This message would be involved in triggering partial activation phenomena in mature lymphocytes, whereas in thymocytes this message would mediate positive selection. Since high concentrations of a peptide would favor the load of tetramers with identical peptides, the tetramer could therefore be viewed as a quantitative-qualitative transducer that would trigger different responses depending on the concentration of antigenic peptides.     

Effective and selective immune surveillance of the brain by MHC class I-restricted cytotoxic T lymphocytes

Cytotoxic CD8(+) T cells are abundantly present in human virus-induced or putative autoimmune diseases of the central nervous system (CNS). Their direct role in the induction of inflammatory brain damage is, however, poorly understood. We have studied CD8(+) T cell-mediated brain inflammation by transferring MHC class I-restricted hemagglutinin (HA)-reactive T cells from a TCR transgenic mouse line into transgenic mice, which express HA in astrocytes. We show that activated CD8(+) T cells alone can induce monophasic brain inflammation in immunocompetent recipient animals. Similar to previous studies, involving transfer of CD4(+) cells, brain inflammation peaks after 5-7 days and then declines. The pathology of brain inflammation, however, differs fundamentally from that induced by CD4(+) cells. The inflammatory reaction is dominated by T cells and activated microglia in the virtual absence of hematogenous macrophages. This is associated with exquisitely specific destruction of antigen-containing astrocytes in the absence of any bystander damage of myelin, oligodendrocytes or neurons. Furthermore, in contrast to CD4(+) T cells, some CD8(+) cells accumulate in the brain and activate microglia in recipient animals, even in the absence of the specific antigen in the CNS. These data indicate that CD8(+) T cells are prime candidates for immune surveillance of the CNS.     

Intrathymic deletion of MHC class I-restricted cytotoxic T cell precursors by constitutive cross-presentation of exogenous antigen.

Cross-priming of cytotoxic T lymphocytes by professional antigen-presenting cells (APC) is a potential hazard to self tolerance because it exposes naive T cells to tissue-specific self antigens in the context of co-stimulatory signals. Here we show that cross-presentation of exogenous material occurs constitutively within the thymus. Although efficient cross-presentation is a property of relatively few APC it results in thymocyte deletion both in vitro and in vivo, suggesting that intrathymic cross-presentation can operate as an effective component of tolerance to circulating self antigens. The capacity of minor cell populations to mediate thymocyte deletion but not positive selection reflects an underlying difference in the biology of these two processes.     

Transduction of dendritic cells by antigen-encoding lentiviral vectors permits antigen processing and MHC class I-dependent presentation

BACKGROUND: Because antigen-presenting dendritic cells (DCs) play a major role in the polarization of T cells, including T(H)2 cells involved in allergy, strategies to modify DCs genetically are required. OBJECTIVE: The purpose of this investigation was to transduce murine bone marrow-derived DCs with lentiviral vectors encoding antigen to demonstrate antigen processing and MHC class I-dependent presentation. METHODS: Bone marrow leukocytes were incubated with antigen-encoding lentiviral constructs and cultured with GM-CSF, IL-4, and Flt-3 ligand. The capacity of the resulting DCs to express, process, and present antigen was tested in vitro. RESULTS: An average of 40% of DCs expressed antigen after 1 week of culture when antigen encoded by the lentiviral vector construct was green fluorescent protein. To demonstrate that transduced antigen can be presented by DCs on MHC class I, we chose the lymphocytic choriomeningitis virus glycoprotein (gp) as a model antigen, inasmuch as it is recognized by CD8 T cells from transgenic mice expressing an MHC class I-restricted T-cell receptor specific for the epitope of positions 33 through 41 of gp. DCs transduced with lentiviral construct encoding gp and matured with LPS activated transgenic T cells in an antigen-specific fashion. Using transporter associated with antigen presentation (TAP)-deficient mice, we show that presentation of the gp33-41 epitope is TAP-dependent, confirming processing of gp by the endogenous pathway. CONCLUSIONS: These results demonstrate that CD8 T cells can recognize MHC class I epitopes processed from antigen in DCs transduced with lentiviral vectors. Lentiviral transduction of DCs and antigen presentation to CD8 T cells could be exploited for immunotherapy, because allergen-specific CD8 T cells have been shown to be suppressive in IgE-dependent allergy models.     

T helper epitopes enhance the cytotoxic response of mice immunized with MHC class I-restricted malaria peptides.

We have previously derived MHC class I (H-2Kd) restricted cytotoxic T lymphocytes (CTL) from BALB/c mice immunized with irradiated sporozoites from Plasmodium (P.) berghei and P. yoelii. The CTL recognize synthetic peptides corresponding to a region of the circumsporozoite (CS) protein that is homologous in the two species. In the present study, we have attempted to induce CS-specific CTL by immunization with those peptides in incomplete Freund's adjuvant. Only a low level CTL response was detected in BALB/c mice immunized with synthetic peptides corresponding to the Pb or Py CTL epitopes. In contrast, CS-specific CTL responses could be readily detected in mice injected with mixtures of peptides that combined the P. berghei or P. yoelii CTL epitopes with previously defined T helper epitopes. Several different T helper epitopes were shown to enhance the response when injected as separate peptides in a mixture, or when covalently linked to a CTL epitope. These results may have general implications for the elicitation of CTL responses to defined CTL epitopes and for the design of peptide-based synthetic vaccines.     

Dynamic quantification of MHC class I-peptide presentation to CD8+ T cells via intracellular cytokine staining

In order to further our basic understanding of antigen processing and presentation as well as to translate that knowledge into clinically effective vaccines and immunotherapies, having appropriate tools to study MHC class I-peptide presentation is highly desirable. Current methods are based upon HPLC fractionation of extracted peptides, monoclonal Ab, multivalent T cell receptors (TCR), T cell hybridomas, TCR transgenic cells, and T cell lines. However, each of these is associated with problems that make them either difficult to apply generally or too insensitive to adequately quantitate antigen presentation. We have developed a method based upon intracellular cytokine staining (ICS) that dynamically and relatively quantitates MHC class I-peptide presentation to CD8+ T cells in a manner that is both widely applicable and highly sensitive. It is well-suited to assess antigen presentation in its early stages, does not require fixation nor labeling of antigen presenting cells (APC), can be used to examine cross-presentation, and is able to directly employ ex vivo T cells which obviates the need for the development and maintenance of T cell lines and hybridomas. Our method represents a simple yet powerful tool that others interested in studying antigen processing and presentation should find of great practical value.     

Carrier-mediated uptake and presentation of a major histocompatibility complex class I-restricted peptide

Antigenic peptides derived from endogenous or viral proteins can associate with class I or class II major histocompatibility complex (MHC) molecules, while exogenous antigens are endocytosed, processed intracellularly and presented on MHC class II molecules. Here we describe a method that allows the presentation of an MHC class I-restricted antigenic peptide on MHC class I molecules, although it was taken up from the outside. The HLA-A2-restricted influenza virus matrix protein-derived peptide (flu, 57–68) was used either in soluble form or coupled via an S-S bridge to transferrin (Tf-flu). Target cells were incubated with flu or Tf-flu and the effective antigen presentation was detected in a cytotoxicity assay using flu peptide-specific, HLA-A2-restricted CD8⁺ cytotoxic T lymphocytes. Sensitization of target cells with Tf-flu required 5 to 10 times higher molar concentrations of peptide compared to sensitization with soluble free peptide. The Tf-flu construct was taken up by the cells via the Tf receptor (CD71) as the binding of Tf-flu was blocked by an excess of Tf. In contrast to the flu peptide, cytotoxicity elicited by Tf-flu was blocked by brefeldin A but not by chloroquine nor inhibitors of intracellular reducing steps, like 1-buthionine-(s, r)-sulfoximine or n-ethylmaleimide. Presentation of the flu peptide derived from Tf-flu construct is not hindered in the mutant T2 cell line, which lacks genes coding for transporter proteins for antigenic peptides (TAP1/TAP2) and proteasomes subunits, suggesting that the processing pathway described in this report may involve TAP-independent steps.