Characterization of the human CD4+ T‐cell repertoire specific for major histocompatibility class I‐restricted antigens

While CD4⁺ T lymphocytes usually recognize antigens in the context of major histocompatibility (MHC) class II alleles, occurrence of MHC class‐I restricted CD4⁺ T cells has been reported sporadically. Taking advantage of a highly sensitive MHC tetramer‐based enrichment approach allowing detection and isolation of scarce Ag‐specific T cells, we performed a systematic comparative analysis of HLA‐A*0201‐restricted CD4⁺ and CD8⁺ T‐cell lines directed against several immunodominant viral or tumoral antigens. CD4⁺ T cells directed against every peptide‐MHC class I complexes tested were detected in all donors. These cells yielded strong cytotoxic and T helper 1 cytokine responses when incubated with HLA‐A2⁺ target cells carrying the relevant epitopes. HLA‐A2‐restricted CD4⁺ T cells were seldom expanded in immune HLA‐A2⁺ donors, suggesting that they are not usually engaged in in vivo immune responses against the corresponding peptide‐MHC class I complexes. However, these T cells expressed TCR of very high affinity and were expanded following ex vivo stimulation by relevant tumor cells. Therefore, we describe a versatile and efficient strategy for generation of MHC class‐I restricted T helper cells and high affinity TCR that could be used for adoptive T‐cell transfer‐ or TCR gene transfer‐based immunotherapies.     

The WT hemochromatosis protein HFE inhibits CD8+ T‐lymphocyte activation

MHC class I (MHC I) antigen presentation is a ubiquitous process by which cells present endogenous proteins to CD8⁺ T lymphocytes during immune surveillance and response. Hereditary hemochromatosis protein, HFE, is involved in cellular iron uptake but, while structurally homologous to MHC I, is unable to bind peptides. However, increasing evidence suggests a role for HFE in the immune system. Here, we investigated the impact of HFE on CD8⁺ T‐lymphocyte activation. Using transient HFE transfection assays in a model of APCs, we show that WT HFE (HFE_WT), but not C282Y‐mutated HFE, inhibits secretion of MIP‐1β from antigen‐specific CD8⁺ T lymphocytes. HFE_WT expression also resulted in major decreases in CD8⁺ T‐lymphocyte activation as measured by 4–1BB expression. We further demonstrate that inhibition of CD8⁺ T‐lymphocyte activation was independent of MHC I surface levels, β2‐m competition, HFE interaction with transferrin receptor, antigen origin, or epitope affinity. Finally, we identified the α1–2 domains of HFE_WT as being responsible for inhibiting CD8⁺ T‐lymphocyte activation. Our data imply a new role for HFE_WT in altering CD8⁺ T‐lymphocyte reactivity, which could modulate antigen immunogenicity.     

Sustained cross‐presentation capacity of murine splenic dendritic cell subsets in vivo

An exclusive feature of dendritic cells (DCs) is their ability to cross‐present exogenous antigens in MHC class I molecules. We analyzed the fate of protein antigen in antigen presenting cell (APC) subsets after uptake of naturally formed antigen‐antibody complexes in vivo. We observed that murine splenic DC subsets were able to present antigen in vivo for at least a week. After ex vivo isolation of four APC subsets, the presence of antigen in the storage compartments was visualized by confocal microscopy. Although all APC subsets stored antigen for many days, their ability and kinetics in antigen presentation was remarkably different. CD8α⁺ DCs showed sustained MHC class I‐peptide specific CD8⁺ T‐cell activation for more than 4 days. CD8α^? DCs also presented antigenic peptides in MHC class I but presentation decreased after 48 h. In contrast, only the CD8α^? DCs were able to present antigen in MHC class II to specific CD4⁺ T cells. Plasmacytoid DCs and macrophages were unable to activate any of the two T‐cell types despite detectable antigen uptake. These results indicate that naturally occurring DC subsets have functional antigen storage capacity for prolonged T‐cell activation and have distinct roles in antigen presentation to specific T cells in vivo.     

Positive selection of self‐antigen‐specific CD8+ T cells by hematopoietic cells

In contrast to thymic epithelial cells, which induce the positive selection of conventional CD8⁺ T cells, hematopoietic cells (HCs) select innate CD8⁺ T cells whose Ag specificity is not fully understood. Here we show that CD8⁺ T cells expressing an H‐Y Ag‐specific Tg TCR were able to develop in mice in which only HCs expressed MHC class I, when HCs also expressed the H‐Y Ag. These HC‐selected self‐specific CD8⁺ T cells resemble innate CD8⁺ T cells in WT mice in terms of the expression of memory markers and effector functions, but are phenotypically distinct from the thymus‐independent CD8⁺ T‐cell population. The peripheral maintenance of H‐Y‐specific CD8⁺ T cells required presentation of the self‐Ag and IL‐15 on HCs. HC‐selected CD8⁺ T cells in mice lacking the Tg TCR also showed these features. Furthermore, by using MHC class I tetramers with a male Ag peptide, we found that self‐Ag‐specific CD8⁺ T cells in TCR non‐Tg mice could develop via HC‐induced positive selection, supporting results obtained from H‐Y TCR Tg mice. These findings indicate the presence of self‐specific CD8⁺ T cells that are positively selected by HCs in the peripheral T‐cell repertoire.     

Glatiramer acetate ameliorates inflammatory bowel disease in mice through the induction of Qa‐1‐restricted CD8+ regulatory cells

Inflammatory bowel diseases (IBDs) are complex multifactorial immunological disorders characterized by dysregulated immune reactivity in the intestine. Here, we investigated the contribution of Qa‐1‐restricted CD8⁺ Treg cells in regulating experimental IBD in mice. We found that CD8⁺ T cells induced by T‐cell vaccination ameliorated the pathological manifestations of dextran sulfate sodium induced IBD when adoptively transferred into IBD mice. In addition, CD8⁺ cell suppressive activity was induced by vaccination with glatiramer acetate (GA), an FDA‐approved drug for multiple sclerosis (MS). We next showed that GA‐induced CD8⁺ Treg cells worked in a Qa‐1‐dependent manner and their suppressive activity depends on perforin‐mediated cytotoxicity. Finally, we confirmed the role of CD4⁺ T cells in dextran sulfate sodium induced colitis progression, and clarified that GA‐induced CD8⁺ T cells exerted their therapeutic effects on colitis by targeting pathogenic CD4⁺ T cells. Our results reveal a new regulatory role of Qa‐1‐restricted CD8⁺ Treg cells in IBD and suggest their induction by GA vaccination as a potential therapeutic approach to IBD.     

Extensive major histocompatibility complex class I binding promiscuity for Mycobacterium tuberculosis TB10.4 peptides and immune dominance of human leucocyte antigen (HLA)‐B*0702 and HLA‐B*0801 alleles in TB10.4 CD8+ T‐cell responses

The molecular definition of major histocompatibility complex (MHC) class I‐presented CD8⁺ T‐cell epitopes from clinically relevant Mycobacterium tuberculosis (Mtb) target proteins will aid in the rational design of T‐cell‐based diagnostics of tuberculosis (TB) and the measurement of TB vaccine‐take. We used an epitope discovery system, based on recombinant MHC class I molecules that cover the most frequent Caucasian alleles [human leucocyte antigen (HLA)‐A*0101, A*0201, A*0301, A*1101, A*2402, B*0702, B*0801 and B*1501], to identify MHC class I‐binding peptides from overlapping 9‐mer peptides representing the Mtb protein TB10.4. A total of 33 MHC class I‐binding epitopes were identified, spread across the entire amino acid sequence, with some clustering at the N‐ and C‐termini of the protein. Binding of individual peptides or closely related peptide species to different MHC class I alleles was frequently observed. For instance, the common motif of xIMYNYPAMx bound to six of eight alleles. Affinity (50% effective dose) and off‐rate (half life) analysis of candidate Mtb peptides will help to define the conditions for CD8⁺ T‐cell interaction with their nominal MHC class I‐peptide ligands. Subsequent construction of tetramers allowed us to confirm the recognition of some of the epitopes by CD8⁺ T cells from patients with active pulmonary TB. HLA‐B alleles served as the dominant MHC class I restricting molecules for anti‐Mtb TB10.4‐specific CD8⁺ T‐cell responses measured in CD8⁺ T cells from patients with pulmonary TB.     

DC‐induced CD8+ T‐cell response is inhibited by MHC class II‐dependent DX5+CD4+ Treg

CD4⁺ T cells are important for CD8⁺ T‐cell priming by providing cognate signals for DC maturation. We analyzed the capacity of CD4⁺ T cells to influence CD8⁺ T‐cell responses induced by activated DC. Surprisingly, mice depleted for CD4⁺ cells were able to generate stronger antigen‐specific CD8⁺ T‐cell responses after DC vaccination than non‐depleted mice. The same observation was made when mice were vaccinated with MHC class II^?/? DC, indicating the presence of a MHC class II‐dependent CD4⁺ T‐cell population inhibiting CD8⁺ T‐cell responses. Recently we described the expansion of DX5⁺CD4⁺ T cells, a T‐cell population displaying immune regulatory properties, upon vaccination with DC. Intriguingly, we now observe an inverse correlation between CD8⁺ T‐cell induction and expansion of DX5⁺CD4⁺ T cells as the latter cells did not expand after vaccination with MHC class II^?/? DC. In vitro, DX5⁺CD4⁺ T cells were able to limit proliferation, modulate cytokine production and induce Foxp3⁺ expression in OVA‐specific CD8⁺ T cells. Together, our data show an inhibitory role of CD4⁺ T cells on the induction of CD8⁺ T‐cell responses by activated DC and indicate the involvement of DX5⁺CD4⁺, but not CD4⁺CD25⁺, T cells in this process.     

Efficient and versatile manipulation of the peripheral CD4+ T‐cell compartment by antigen targeting to DNGR‐1/CLEC9A

DC NK lectin group receptor‐1 (DNGR‐1, also known as CLEC9A) is a C‐type lectin receptor expressed by mouse CD8α⁺ DC and by their putative equivalents in human. DNGR‐1 senses necrosis and regulates CD8⁺ T‐cell cross‐priming to dead‐cell‐associated antigens. In addition, DNGR‐1 is a target for selective in vivo delivery of antigens to DC and the induction of CD8⁺ T‐cell and Ab responses. In this study, we evaluated whether DNGR‐1 targeting can be additionally used to manipulate antigen‐specific CD4⁺ T lymphocytes. Injection of small amounts of antigen‐coupled anti‐DNGR‐1 mAb into mice promoted MHC class II antigen presentation selectively by CD8α⁺ DC. In the steady state, this was sufficient to induce proliferation of antigen‐specific naïve CD4⁺ T cells and to drive their differentiation into Foxp3⁺ regulatory lymphocytes. Co‐administration of adjuvants prevented this induction of tolerance and promoted immunity. Notably, distinct adjuvants allowed qualitative modulation of CD4⁺ T‐cell behavior: poly I:C induced a strong IL‐12‐independent Th1 response, whereas curdlan led to the priming of Th17 cells. Thus, antigen targeting to DNGR‐1 is a versatile approach for inducing functionally distinct CD4⁺ T‐cell responses. Given the restricted pattern of expression of DNGR‐1 across species, this strategy could prove useful for developing immunotherapy protocols in humans.     

Circulating specific antibodies enhance systemic cross-priming by delivery of complexed antigen to dendritic cells in vivo

Increasing evidence suggests that antibodies can have stimulatory effects on T‐cell immunity. However, the contribution of circulating antigen‐specific antibodies on MHC class I cross‐priming in vivo has not been conclusively established. Here, we defined the role of circulating antibodies in cross‐presentation of antigen to CD8⁺ T cells. Mice with hapten‐specific circulating antibodies, but na?ve for the T‐cell antigen, were infused with haptenated antigen and CD8⁺ T‐cell induction was measured. Mice with circulating hapten‐specific antibodies showed significantly enhanced cross‐presentation of the injected antigen compared with mice that lacked these antibodies. The enhanced cross‐presentation in mice with circulating antigen‐specific antibodies was associated with improved antigen capture by APCs. Importantly, CD11c⁺ APCs were responsible for the enhanced and sustained cross‐presentation, although CD11c^? APCs had initially captured a significant amount of the injected antigen. Thus, in vivo formation of antigen‐antibody immune complexes improves MHC class I cross‐presentation, and CD8⁺ T‐cell activation, demonstrating that humoral immunity can aid the initiation of systemic cellular immunity. These findings have important implications for the understanding of the action of therapeutic antibodies against tumor‐associated antigens intensively used in the clinic nowadays.     

Lipid‐mediated presentation of MHC class II molecules guides thymocytes to the CD4 lineage

Previous studies on the MHC class‐specific differentiation of CD4⁺CD8⁺ thymocytes into CD4⁺ and CD8⁺ T cells have focused on the role of coreceptor molecules. However, CD4 and CD8 T cells develop according to their MHC class specificities even in these mice lacking coreceptors. This study investigated the possibility that lineage is determined not only by coreceptors, but is also guided by the way how MHC molecules are presented. MHC class II molecules possess a highly conserved Cys in their transmembrane domain, which is palmitoylated and thereby associates with lipid rafts, whereas neither palmitoylation nor raft association was observed with MHC class I molecules. The generation of CD4 T cells was impaired and that of CD8 T cells was augmented when the rafts on the thymic epithelial cells were disrupted. This was due to the conversion of MHC class II‐specific thymocytes from the CD4 lineage to CD8. The ability of I‐A^d molecule to associate with rafts was lost when its transmembrane Cys was replaced. The development of DO11.10 thymocytes recognizing this mutant I‐A^dm was converted from CD4 to CD8. These results suggest that the CD4 lineage commitment is directed by the raft‐associated presentation of MHC class II molecules.     

A novel T‐cell receptor mimic defines dendritic cells that present an immunodominant West Nile virus epitope in mice

We used a newly generated T‐cell receptor mimic monoclonal antibody (TCRm MAb) that recognizes a known nonself immunodominant peptide epitope from West Nile virus (WNV) NS4B protein to investigate epitope presentation after virus infection in C57BL/6 mice. Previous studies suggested that peptides of different length, either SSVWNATTAI (10‐mer) or SSVWNATTA (9‐mer) in complex with class I MHC antigen H‐2D^b, were immunodominant after WNV infection. Our data establish that both peptides are presented on the cell surface after WNV infection and that CD8⁺ T cells can detect 10‐ and 9‐mer length variants similarly. This result varies from the idea that a given T‐cell receptor (TCR) prefers a single peptide length bound to its cognate class I MHC. In separate WNV infection studies with the TCRm MAb, we show that in vivo the 10‐mer was presented on the surface of uninfected and infected CD8α⁺CD11c⁺ dendritic cells, which suggests the use of direct and cross‐presentation pathways. In contrast, CD11b⁺CD11c^? cells bound the TCRm MAb only when they were infected. Our study demonstrates that TCR recognition of peptides is not limited to certain peptide lengths and that TCRm MAbs can be used to dissect the cell‐type specific mechanisms of antigen presentation in vivo.     

Enhancing antitumor immune responses: intracellular peptide delivery and identification of MHC class II-restricted tumor antigens

Summary: The importance of T‐cell‐mediated antitumor immunity has been demonstrated in both animal models and human cancer therapy. The identification of major histocompatibility complex (MHC) class I‐restricted tumor antigens has generated a resurgence of interest in immunotherapy for cancer. However, recent studies suggest that therapeutic strategies that have mainly focused on the use of CD8⁺ T cells (and MHC class I‐restricted tumor antigens) may not be effective in eliminating cancer cells in patients. Novel strategies have been developed for enhancing T‐cell responses against cancer by prolonging antigen presentation of dendritic cells to T cells and the inclusion of MHC class II‐restricted tumor antigens. identification of MHC class II‐restricted tumor antigens, which are capable of stimulating CD4⁺ T cells, not only aids our understanding of the host immune responses against cancer antigens, but also provides opportunities for developing effective cancer vaccines.     

Salivary gland resident APCs are Flt3L‐ and CCR2‐independent macrophage‐like cells incapable of cross‐presentation

Cytomegaloviruses (CMVs) disseminate within the human population via mucosal excretions, for example, from the salivary glands (SGs), which represent a privileged site of viral immune evasion and persistence. The murine CMV (MCMV) model has served to identify factors that maintain a unique virus–host relationship in this organ. In contrast to all other organs, the SG is resistant to CD8⁺ T‐cell mediated control of MCMV replication due to virally induced MHC class I downregulation, which is exceptionally efficient in acinar glandular epithelial cells. Uniquely to the SG, IFN‐γ producing CD4⁺ T cells are required for virus control. While T‐cell responses have been extensively characterized in the SG, the ontogeny and function of APCs in this organ remain to be assessed. Here, we show that macrophage‐like cells constitute the population of SG‐resident APCs in steady state and during MCMV‐induced inflammation in mice. Inflammatory monocytes, monocyte‐derived DCs as well as conventional, Flt3L‐dependent DCs do not contribute to this population. Despite supporting contact formation to CD4⁺ and CD8⁺ T cells in principle, SG‐resident APCs fail to activate the latter due to their inability to cross‐present MCMV‐derived antigen.     

Going Pro to enhance T‐cell immunogenicity: Easy as π?

MHC class I molecules bind intracellular oligopeptides and present them on the cell surface for CD8⁺ T‐cell activation and recognition. Strong peptide/MHC class I (pMHC) interactions typically induce the best CD8⁺ T‐cell responses; however, many immunotherapeutic tumor‐specific peptides bind MHC with low affinity. To overcome this, immunologists can carefully alter peptides for enhanced MHC affinity but often at the cost of decreased T‐cell recognition. A new report published in this issue of the European Journal of Immunology [Eur. J. Immunol. 2013. 43:3051–3060] shows that the substitution of proline at the third residue (p3P) of a common tumor peptide increases pMHC affinity and complex stability while enhancing T‐cell receptor recognition. X‐ray crystallography indicates that stability is generated through newly introduced CH‐π bonding between p3P and a conserved residue (Y159) in the MHC heavy chain. This finding highlights a previously unappreciated role for CH‐π bonding in MHC peptide binding, and importantly, arms immunologists with a novel and possibly general approach for increasing pMHC stability without compromising T‐cell recognition.     

Accessory molecules in the assembly of major histocompatibility complex class I/peptide complexes: how essential are they for CD8+ T‐cell immune responses?

Summary: Assembly of major histocompatibility complex (MHC) class I molecules in the endoplasmic reticulum is a highly coordinated process that results in abundant class I/peptide complexes at the cell surface for recognition by CD8⁺ T cells and natural killer cells. During the assembly process, a number of chaperones and accessory molecules, such as transporter associated with antigen processing, tapasin, ER60, and calreticulin, assist newly synthesized class I molecules to facilitate loading of antigenic peptides and to optimize the repertoire of surface class I/peptide complexes. This review focuses on the relative importance of these accessory molecules for CD8⁺ T‐cell responses in vivo and discusses reasons that may help explain why some CD8⁺ T‐cell responses develop normally in mice deficient in components of class I assembly, despite impaired antigen presentation.     

Stress‐activated dendritic cells interact with CD4+ T cells to elicit homeostatic memory

Evidence is presented that thermal or oxidizing stress‐activated DC interact with CD4⁺ T cells to induce and maintain a TCR‐independent homeostatic memory circuit. Stress‐activated DC expressed endogenous intra‐cellular and cell surface HSP70. The NF‐κB signalling pathway was activated and led to the expression of membrane‐associated IL‐15 molecules. These interacted with the IL‐15 receptor complex on CD4⁺ T cells, thus activating the Jak3 and STAT5 phosphorylation signalling pathway to induce CD40 ligand expression, T‐cell proliferation and IFN‐γ production. CD40 ligand on CD4⁺ T cells in turn re‐activated CD40 molecules on DC, inducing DC maturation and IL‐15 expression thereby maintaining the feedback circuit. The proliferating CD4⁺ T cells were characterized as CD45RA^? CD62L⁺ central memory cells, which underwent homeostatic proliferation. The circuit is independent of antigen and MHC‐class‐II‐TCR interaction as demonstrated by resistance to TCR inhibition by ZAP70 inhibitor or MHC‐class II antibodies. These findings suggest that stress can activate a DC‐CD4⁺ T‐cell interacting circuit, which may be responsible for maintaining a homeostatic antigen‐independent memory.     

Co‐expression of HLA‐B7 and HLA‐B27 alleles is associated with B7‐restricted immunodominant responses following influenza infection

It is recognized that host response following viral infection is characterized by immunodominance, but deciphering the different factors contributing to immunodominance has proved a challenge due to concurrent expression of multiple MHC class I alleles. To address this, we generated H2‐K^?/?/D^?/? double‐knockout transgenic mice expressing either one or two human MHC‐I alleles. We hypothesized that co‐expression of different allele combinations figures critically in immunodominance and examined this in influenza‐infected, double Tg MHC‐I mice. In A2/B7 or A2/B27 mice, using ELISpot assays with the A2‐restricted matrix I.58–66, the B7‐restricted NP418–426 or the B27‐restricted NP383–391 influenza A (flu) epitopes, we observed the expected recognition of both peptides for both alleles. In contrast, in flu‐infected B7/B27 mice, a significantly reduced level of B27/NP383‐restricted CTL response was detected while there was no change in the B7/NP418‐restricted CTL response. Flu‐specific tetramer studies revealed a partial deletion of Vβ8.1⁺ NP383/B27‐restricted CD8⁺ T cells, and a diminished Vβ12⁺ CD8⁺ T‐cell expansion in B7/B27 Tg mice. Using HLA Tg chimeric mice, we confirmed these findings. These findings shed light on the immune consequences of co‐dominant expression of MHC‐I alleles for host immune response to pathogens.