Exogenous antigen targeted to FcgammaRI on myeloid cells is presented in association with MHC class I

Vaccine therapy is attractive for prostate cancer patients because the tumor is slow growing (allowing time to augment host responses) and occurs in an older population less likely to tolerate more toxic treatments. We have constructed an expression vector based on a monoclonal antibody (mAb) that targets the high affinity receptor for IgG (FcgammaRI, CD64) which is exclusively expressed on myeloid cells including dendritic cells (DC). The heavy chain of mAb H22 CH2 and CH3 domains were removed and replaced with the gene for prostate specific antigen (PSA). Using that vector, we have constructed and purified FPH22.PSA, a fusion protein that targets PSA to FcgammaRI on antigen presenting cells (APC). This fusion protein has an apparent molecular mass of 80-83 kDa, binds to FcgammaRI with high affinity and expresses PSA. We demonstrate that FPH22.PSA targeted PSA was internalized and processed by the human myeloid THP-1 cell line resulting in presentation of MHC class I-associated PSA peptides and lysis of THP-1 by PSA-specific human CTL. Moreover, pretreatment of THP-1 cells with antibodies to block either FcgammaRI or MHC class I, blocked lysis indicating that targeting to FcgammaRI results in presentation of exogenous antigen on MHC class I molecules. These data demonstrate that FPH22.PSA was processed in such a manner by the myeloid cell line to allow for presentation of immunodominant peptides in MHC class I molecules and suggests that uptake of antigen via FcgammaRI results in cross-priming.     

Genes regulating MHC class I processing of antigen

The principal pathway of antigen processing that is associated with MHC class I involves three main steps: cytosolic peptide generation, peptide transport into the endoplasmic reticulum and peptide assembly with class I molecules. Recent advances suggest that additional cytosolic proteases complement the proteasome as a source of antigenic peptides. Peptide assembly involves several novel cofactors - including the proteins tapasin and ERp57, which may be important for stabilisation of empty class I molecules as well as quality control after peptide binding. Finally, genetic evidence suggests an important influence of an unidentified gene, in the MHC complex, on MHC class I processing.     

Involvement of autophagy in MHC class I antigen presentation

MHC class I molecules on the cellular surface display peptides that either derive from endogenous proteins (self or viral), or from endocytosis of molecules, dying cells or pathogens. The conventional antigen-processing pathway for MHC class I presentation depends on proteasome-mediated degradation of the protein followed by transporter associated with antigen-processing (TAP)-mediated transport of the generated peptides into the endoplasmic reticulum (ER). Here, peptides are loaded onto MHC I molecules before transportation to the cell surface. However, several alternative mechanisms have emerged. These include TAP-independent mechanisms, the vacuolar pathway and involvement of autophagy. Autophagy is a cell intrinsic recycling system. It also functions as a defence mechanism that removes pathogens and damaged endocytic compartments from the cytosol. Therefore, it appears likely that autophagy would intersect with the MHC class I presentation pathway to alarm CD8⁺ T cells of an ongoing intracellular infection. However, the importance of autophagy as a source of antigen for presentation on MHC I molecules remains to be defined. Here, original research papers which suggest involvement of autophagy in MHC I antigen presentation are reviewed. The antigens are from herpesvirus, cytomegalovirus and chlamydia. The studies point towards autophagy as important in MHC class I presentation of endogenous proteins during conditions of immune evasion. Because autophagy is a regulated process which is induced upon activation of, for example, pattern recognition receptors (PRRs), it will be crucial to use relevant stimulatory conditions together with primary cells when aiming to confirm the importance of autophagy in MHC class I antigen presentation in future studies.     

The cell biology of MHC class I antigen presentation

MHC class I antigen presentation refers to the co-ordinated activities of many intracellular pathways that promote the cell surface appearance of MHC class I/beta2m heterodimers loaded with a spectrum of self or foreign peptides. These MHC class I peptide complexes form ligands for CD8 positive T cells and NK cells. MHC class I heterodimers are loaded within the endoplasmic reticulum (ER) with peptides derived from intracellular proteins. Alternatively, MHC class I molecules may be loaded with peptides derived from extracellular proteins in a process called MHC class I cross presentation. This pathway is less well defined but can overlap those pathways operating in classical MHC class I presentation and has recently been reviewed elsewhere (1). This review will address the current concepts regarding the intracellular assembly of MHC class I molecules with their peptide cargo within the ER and their subsequent progress to the cell surface.     

The role of tapasin in MHC class I antigen assembly

The discovery of tapasin has shed new light on the mechanisms of major histocompatibility complex (MHC) class I assembly in the endoplasmic reticulum (ER). Tapasin appears to play an important role in the stable assembly of class I molecules with peptide, however, the precise function of tapasin remains elusive. The pursuit of tapasin function is complicated by the observation that tapasin is not required for successful antigen presentation by all class I molecules. In addition, current data suggest that the putative role of tapasin as a bridging molecule between transporter associated with antigen presentation (TAP) and class I is only of minor importance in tapasin action, and tapasin' s major role appears to be as an active cofactor in the assembly of class I. Furthermore, it is clear that class I molecules can follow multiple pathways for successful assembly in the ER. These pathways may or may not include the interaction of class I molecules with the accessory proteins tapasin, calreticulin, ERp57, or TAP. I would like to suggest that the particular pathway utilized by a given class I molecule depends more upon the availability of appropriate peptides rather than on an intrinsic property of the class I molecule, and that tapasin may serve a peptide editing function.     

Inhibition of MHC class I antigen presentation by viral proteins

 An essential part of the immune response to viral infections is the recognition and elimination of infected cells by cytotoxic T lymphocytes. For this purpose a display mechanism has evolved which is present in almost all nucleated cells: the major histocompatibility complex class I antigen processing pathway. Both self and foreign antigens are degraded in the cytosol to peptides which are translocated into the endoplasmic reticulum where they are loaded onto MHC class I molecules. Pathogens living inside the cell are evolving under the constant selection pressure of such immune surveillance. As a result such infectious organisms have developed a variety of strategies to prevent their antigens from being presented. Since our understanding of the cell biology of antigen presentation has greatly advanced in recent years, it has now become possible to unravel several of the molecular mechanisms by which viruses interfere with MHC class I antigen presentation. Examples for the interference of viral molecules with components of the MHC class I pathway are presented in this review. Received: 12 June 1996 / Accepted: 24 July 1996     

The role of tapasin in MHC class I antigen assembly

The discovery of tapasin has shed new light on the mechanisms of major histocompatibility complex (MHC) class I assembly in the endoplasmic reticulum (ER). Tapasin appears to play an important role in the stable assembly of class I molecules with peptide, however, the precise function of tapasin remains elusive. The pursuit of tapasin function is complicated by the observation that tapasin is not required for successful antigen presentation by all class I molecules. In addition, current data suggest that the putative role of tapasin as a bridging molecule between transporter associated with antigen presentation (TAP) and class I is only of minor importance in tapasin action, and tapasin’s major role appears to be as an active cofactor in the assembly of class I. Furthermore, it is clear that class I molecules can follow multiple pathways for successful assembly in the ER. These pathways may or may not include the interaction of class I molecules with the accessory proteins tapasin, calreticulin, ERp57, or TAP. I would like to suggest that the particular pathway utilized by a given class I molecule depends more upon the availability of appropriate peptides rather than on an intrinsic property of the class I molecule, and that tapasin may serve a peptide editing function.     

Aldehyde-mannan antigen complexes target the MHC class I antigen-presentation pathway

Antigens such as MUC1 coupled to oxidized mannan lead to rapid and efficient MHC class I presentation to CD8+ cells and a preferential T1 response; after reduction there is class II presentation and a T2 immune response. We now show that the selective advantage of the oxidized mannan-MUC1 is due to the presence of aldehydes and not Schiff bases, and that oxidized mannan-MUC1 binds to the mannose and not scavenger receptors and is internalized and presented by MHC class I molecules 1,000 times more efficiently than when reduced. After internalization there is rapid access to the class I pathway via endosomes but not lysosomes, proteasomal processing and transport to the endoplasmic reticulum, Golgi apparatus and cell surface. Aldehydes cause rapid entry into the class I pathway, and can therefore direct the subsequent immune response.     

Crystal structure of an MHC class I presented glycopeptide that generates carbohydrate-specific CTL

T cell receptor (TCR) recognition of nonpeptidic and modified peptide antigens has been recently uncovered but is still poorly understood. Immunization with an H-2Kb-restricted glycopeptide RGY8-6H-Gal2 generates a population of cytotoxic T cells that express both alpha/beta TCR, specific for glycopeptide, and gamma/delta TCR, specific for the disaccharide, even on glycolipids. The crystal structure of Kb/RGY8-6H-Gal2 now demonstrates that the peptide and H-2Kb structures are unaffected by the peptide glycosylation, but the central region of the putative TCR binding site is dominated by the extensive exposure of the tethered carbohydrate. These features of the Kb/RGY8-6H-Gal2 structure are consistent with the individual ligand binding preferences identified for the alpha/beta and gamma/delta TCRs and thus explain the generation of a carbohydrate-specific T cell response.     

Fc receptors for IgG and antigen presentation on MHC class I and class II molecules

Antigens internalized through specific membrane receptors are presented to helper CD4(+) T cells at antigen concentrations 10(3) to 10(4) fold lower than antigens internalized by fluid phase. B lymphocyte antigen receptors, mannose receptors and receptors for the Fc region of immunoglobulins, promote both internalization and efficient presentation at low antigen concentrations. Thus, binding to specific membrane receptors concentrate antigens on antigen presenting cells and mediates efficient uptake. Is this 'quantitative' concentration of antigens on antigen presenting cells the end of the story? Or may 'quality', i.e. selective intracellular antigen targeting, somehow influence the efficiency or specificity of MHC class I and class II-restricted antigen presentation?     

Viral immune evasion: Lessons in MHC class I antigen presentation

The MHC class I antigen presentation pathway enables cells infected with intracellular pathogens to signal the presence of the invader to the immune system. Cytotoxic T lymphocytes are able to eliminate the infected cells through recognition of pathogen-derived peptides presented by MHC class I molecules at the cell surface. In the course of evolution, many viruses have acquired inhibitors that target essential stages of the MHC class I antigen presentation pathway. Studies on these immune evasion proteins reveal fascinating strategies used by viruses to elude the immune system. Viral immunoevasins also constitute great research tools that facilitate functional studies on the MHC class I antigen presentation pathway, allowing the investigation of less well understood routes, such as TAP-independent antigen presentation and cross-presentation of exogenous proteins. Viral immunoevasins have also helped to unravel more general cellular processes. For instance, basic principles of ER-associated protein degradation via the ubiquitin-proteasome pathway have been resolved using virus-induced degradation of MHC class I as a model. This review highlights how viral immunoevasins have increased our understanding of MHC class I-restricted antigen presentation.     

Viral and bacterial minigene products are presented by MHC class I molecules with similar efficiencies

MHC class I molecules present short peptides, usually 8-10 amino acids in length, to CD8⁺ T cells. These peptides are typically generated from full-length endogenously synthesized proteins degraded by the antigen processing machinery of the target cell. However, exogenous proteins, whether originating from intracellular bacteria or parasites or via phagocytosis during cross-presentation, can also be processed for presentation by MHC class I molecules. It is currently not known whether endogenously synthesized proteins and proteins acquired from exogenous sources follow the same presentation pathway. One clue that the processing pathways followed by endogenous and exogenous proteins may not be identical is the vastly different presentation efficiencies reported for viral versus bacterial antigens. Because class I antigen processing involves multiple steps, we sought to determine where in the processing pathway these differences in efficiency occur. To accomplish this, we expressed identical minimal peptide determinants from viral and bacterial vectors using a minigene expression system and determined the rate of peptide-MHC generation per molecule of minigene product synthesized. We found that peptides expressed from either the viral or bacterial vector were presented with virtually identical efficiencies. These results suggest that differences in the processing pathways followed by endogenous versus exogenous proteins most likely occur at a point prior to where free peptide is liberated from full-length protein.     

Axotomy induces MHC class I antigen expression on rat nerve cells

Immunomorphological staining demonstrates that class I major histocompatibility complex (MHC)-coded antigen expression can be selectively induced on otherwise class I-negative rat nerve cells by peripheral axotomy. Induction of class I as well as class II antigen expression was simultaneously seen on non-neural cells in the immediate vicinity of the injured nerve cells. As nerve regeneration after axotomy includes growth of new nerve cell processes and formation of new nerve cell contacts, the present findings raise the question of a role for MHC-coded molecules in cell-cell interactions during nerve cell growth.     

New tools for antigen delivery to the MHC class I pathway

At the beginning of this new millennium, pathogens and cancer remain the leading causes of death worldwide. The development of vaccines to prevent diseases for which no vaccine currently exists, such as AIDS or malaria, or to treat chronic infections or cancers, as well as the improvement of efficacy and safety of existing vaccines, remains a high priority. In most cases, the development of such vaccines requires strategies capable of stimulating CD8(+) cytotoxic T lymphocytes (CTLs) and thus, to deliver antigen to MHC class I molecules. There exists several different pathways for loading antigenic peptides onto MHC class I molecules, either based on the endogenous cytosolic MHC I pathway or on cross-presentation. The understanding of the relevance of each of these mechanisms in CTL activation will help vaccine design to progress more rationally.     

DRiPs solidify: progress in understanding endogenous MHC class I antigen processing

Defective ribosomal products (DRiPs) are a subset of rapidly degraded polypeptides that provide peptide ligands for major histocompatibility complex (MHC) class I molecules. Here, recent progress in understanding DRiP biogenesis is reviewed. These findings place DRiPs at the center of the MHC class I antigen processing pathway, linking immunosurveillance of viruses and tumors to mechanisms of specialized translation and cellular compartmentalization. DRiPs enable the immune system to rapidly detect alterations in cellular gene expression with great sensitivity.     

The role of mRNA translation in direct MHC class I antigen presentation

It has been over 40 years since it was discovered that the major histocompatibility (MHC) class I molecules present peptides for the CD8 T cell-mediated immune response. The pathways for delivering and processing peptides for the MHC class I complexes have since been thoroughly studied but it is only until more recently that we start to understand the mechanisms that provide peptide material for the endogenous MHC class I pathway. Interestingly, the main source of antigenic peptide substrates does not come from the same mRNA translation mechanism that produces full length proteins but from ribosomes which products sole purpose might be to produce antigenic peptide substrates. We will discuss the latest development in this field and its implications for a better understanding of one of the corner stones for how the immune system distinguishes between self and non-self.