Self-recognition of CD1 by gamma/delta T cells: implications for innate immunity.

The specificity of immunoglobulins and alpha/beta T cell receptors (TCRs) provides a framework for the molecular basis of antigen recognition. Yet, evolution has preserved a separate lineage of gamma/delta antigen receptors that share characteristics of both immunoglobulins and alpha/beta TCRs but whose antigens remain poorly understood. We now show that T cells of the major tissue gamma/delta T cell subset recognize nonpolymorphic CD1c molecules. These T cells proliferated in response to CD1+ presenter cells, lysed CD1c+ targets, and released T helper type 1 (Th1) cytokines. The CD1c-reactive gamma/delta T cells were cytotoxic and used both perforin- and Fas-mediated cytotoxicity. Moreover, they produced granulysin, an important antimicrobial protein. Recognition of CD1c was TCR mediated, as recognition was transferred by transfection of the gamma/delta TCR. Importantly, all CD1c-reactive gamma/delta T cells express V delta 1 TCRs, the TCR expressed by most tissue gamma/delta T cells. Recognition by this tissue pool of gamma/delta T cells provides the human immune system with the capacity to respond rapidly to nonpolymorphic molecules on professional antigen presenting cells (APCs) in the absence of foreign antigens that may activate or eliminate the APCs. The presence of bactericidal granulysin suggests these cells may directly mediate host defense even before foreign antigen-specific T cells have differentiated.

Molecular recognition of lipid antigens by T cell receptors.

The T cell antigen receptor (TCR) mediates recognition of peptide antigens bound in the groove of major histocompatibility complex (MHC) molecules. This dual recognition is mediated by the complementarity-determining residue (CDR) loops of the alpha and beta chains of a single TCR which contact exposed residues of the peptide antigen and amino acids along the MHC alpha helices. The recent description of T cells that recognize hydrophobic microbial lipid antigens has challenged immunologists to explain, in molecular terms, the nature of this interaction. Structural studies on the murine CD1d1 molecule revealed an electrostatically neutral putative antigen-binding groove beneath the CD1 alpha helices. Here, we demonstrate that alpha/beta TCRs, when transferred into TCR-deficient recipient cells, confer specificity for both the foreign lipid antigen and CD1 isoform. Sequence analysis of a panel of CD1-restricted, lipid-specific TCRs reveals the incorporation of template-independent N nucleotides that encode diverse sequences and frequent charged basic residues at the V(D)J junctions. These sequences permit a model for recognition in which the TCR CDR3 loops containing charged residues project between the CD1 alpha helices, contacting the lipid antigen hydrophilic head moieties as well as adjacent CD1 residues in a manner that explains antigen specificity and CD1 restriction.

CD1-restricted microbial lipid antigen-specific recognition found in the CD8+ alpha beta T cell pool.

It is generally accepted that TCR alphabeta+ CD8+ T cells recognize immunogenic peptides bound to MHC-encoded class I molecules. This recognition is a major component of the cellular response mediating immune protection and recovery from viral infections and from certain intracellular bacterial infections. Here, we report two human CD8+ TCR alphabeta+ T cell lines specific for Mycobacterium tuberculosis Ags presented in the context of CD1a or CD1c Ag-presenting molecules. These T cells recognize lipid Ags and display cytotoxicity as well as strong Th cell type I cytokine responses. By extending presentation by the CD1 system to the major TCR alphabeta+ CD8+ T cell pool, this system gains wider applicability beyond the double negative subset of T cells previously shown to have this reactivity. This implies that previous assumptions about the role of CD8+ T cells in microbial immunity may require revision as the relative proportions of CD1-restricted and MHC class I-restricted CD8+ T cells are further defined.

Separate pathways for antigen presentation by CD1 molecules.

The ability to sample relevant intracellular compartments is necessary for effective antigen presentation. To detect peptide antigens, MHC class I and II molecules differentially sample cytosolic and endosomal compartments. CD1 constitutes another lineage of lipid antigen-presenting molecules. We show that CD1b traffics deeply into late endosomal compartments, while CD1a is excluded from these compartments and instead traffics independently in the recycling pathway of the early endocytic system. Further, CD1b but not CD1a antigen presentation is dependent upon vesicular acidification. Since lipids and various bacteria are known to traffic differentially, either penetrating deeply into the endocytic system or following the route of recycling endosomes, these findings elucidate efficient monitoring of distinct components of the endocytic compartment by CD1 lipid antigen-presenting molecules.

CD1--a new paradigm for antigen presentation and T cell activation.

Despite identification of the CD1 family of molecules in the late 1970s, the function of CD1 was undetermined for more than a decade. Recent evidence has established that CD1 molecules comprise a novel lineage of antigen-presenting molecules, distinct from major histocompatibility complex (MHC) class I and class II molecules. Unlike the MHC molecules, which bind short peptides in their antigen-binding groove for presentation to either CD4+ or CD8+ T cells bearing alpha beta T cell receptors, the CD1 molecules appear to accommodate lipid and glycolipid antigens in their hydrophobic cavity for presentation to a wide variety of T cells, including double-negative alpha beta and gamma delta T cells and CD8+ alpha beta T cells. By using a unique cytoplasmic signal, some CD1 molecules traffic to endosomal compartments for sampling mycobacteria-derived lipid antigens, and subsequently lipid antigen-loaded CD1 molecules are expressed on the cell surface to activate specific T cells. These CD1-restricted T cells kill mycobacteria-infected cells and secrete interferon-gamma, indicating a potential role of CD1-mediated T cell responses in clearing mycobacterial infection. The identification of an MHC-independent antigen presentation pathway for nonpeptide antigens provides new insights into immunoregulation and host defense.

Chemical denaturation and modification of ovalbumin alters its dependence on ubiquitin conjugation for class I antigen presentation.

Class I presentation of microinjected native OVA by a temperature-sensitive ubiquitin conjugation mutant, ts85, but not wild-type murine cells, was markedly inhibited following incubation at a nonpermissive temperature. In contrast, the nonpermissive temperature did not affect class I presentation of a minimal OVA peptide expressed in the cytosol. Therefore, these results provide a second example in which a temperature sensitive mutation in the ubiquitin conjugation pathway inhibits MHC class I presentation of native OVA. Surprisingly, incubation at the nonpermissive temperature did not inhibit class I presentation of chemically denatured and alkylated OVA microinjected into the cytosol of mutant cells. Similarly, the presentation of endogenously synthesized OVA (which is expressed from a recombinant vaccinia virus and, presumably, is misfolded in the cytosol) was also not inhibited in both mutant cell lines. Methylation of the lysine groups in denatured OVA, which blocks ubiquitin conjugation, reduced but did not eliminate the presentation of denatured OVA, providing evidence for both ubiquitin-dependent and ubiquitin-independent pathways for class I presentation. In contrast, a proteasome inhibitor blocked class I presentation of all forms of OVA, while a control peptide aldehyde was not inhibitory. These results indicate that modification of the structure of a protein can influence its requirements for ubiquitin conjugation for efficient class I presentation, with the key alteration possibly being the loss of proper conformation. However, regardless of the form of the Ag, the proteasome appears to be required for generating peptides from both endogenously synthesized and microinjected OVA for class I presentation.

Rate of antigen degradation by the ubiquitin-proteasome pathway influences MHC class I presentation.

The effect on MHC class I Ag presentation of enhancing a protein's rate of degradation by the ubiquitin-proteasome pathway was investigated. In extracts of mouse B-lymphoblasts and reticulocytes, as in rabbit reticulocytes, proteins with acidic or basic N-termini are conjugated to ubiquitin and degraded by the 26S proteasome very rapidly. We found that the rate of MHC class I presentation of microinjected beta-galactosidase was enhanced when this antigenic protein was modified with such a destabilizing amino-terminal residue. This enhanced presentation was inhibited by blocking potential ubiquitination sites on the protein through methylation of amino groups and by peptide aldehyde inhibitors of the proteasome. Furthermore, in B lymphoblast cell extracts, the rapid degradation of these beta-galactosidase constructs required ATP and ubiquitin and was blocked by inhibitors of proteasomes. Their rates of degradation in extracts correlated with their rates of class I Ag presentation in vivo. These results indicate that ubiquitin conjugation is a key rate-limiting step in Ag presentation and provide further evidence for a critical role of ubiquitin and the 26S proteasome in generating MHC class I-presented peptides.

A role for the ubiquitin-dependent proteolytic pathway in MHC class I-restricted antigen presentation.

The degradation of most cellular proteins starts with their covalent conjugation with ubiquitin. This labels the proteins for rapid hydrolysis to oligopeptides by a (26S) proteolytic complex containing a (20S) degradative particle called the proteasome. Some system in the cytosol also generates antigenic peptides from endogenously synthesized cellular and viral proteins. These peptides bind to newly synthesized class I major histocompatibility complex molecules in the endoplasmic reticulum and peptide/class I complexes are then transported to the cell surface for presentation to cytotoxic T cells. How these peptides are produced is unknown, although a modification that promotes ubiquitin-dependent degradation of a viral protein enhances its presentation with class I13 and indirect evidence suggests a role for proteolytic particles closely resembling and perhaps identical to the proteasome. Using cells that exhibit a temperature-sensitive defect in ubiquitin conjugation, we report here that non-permissive temperature inhibited class I-restricted presentation of ovalbumin introduced into the cytosol, but did not affect presentation of an ovalbumin peptide synthesized from a minigene. These results implicate the ubiquitin-dependent proteolytic pathway in the production of antigenic peptides.

MHC class I-restricted presentation of exogenous antigen by thymic antigen-presenting cells in vitro and in vivo.

We have used a T-T hybridoma, RF33.70, to detect the MHC class I-restricted presentation of exogenous native OVA by thymic APC in vitro. Presentation of OVA with class I molecules by thymic APC requires intracellular processing. Phenotypic analyses indicated that low bouyant density, MHC class II+, FcR+ cells are capable of using this presentation pathway. In order to determine whether thymic APC have this function in vivo, thymic APC were isolated from mice after i.v. injection of native OVA. We find that OVA is presented in association with MHC class I, but not class II, molecules in the thymus. This is in contrast to splenic APC, which present exogenous OVA with both class I and class II molecules under these conditions. Our findings have implications for the repertoire of self-peptides that might be presented by thymic APC to developing T lymphocytes.