Highly efficient peptide binding and T cell activation by MHC class II molecules of CIITA-transfected cells.

Expression of MHC class II, DM and Ii genes is controlled by the transactivator CIITA, a mediator of the activation of these genes by IFN-gamma. Surprisingly, MHC class II molecules expressed on CIITA transfectants behave very differently from those expressed at the same level on IFN-gamma-induced cells in terms of peptide binding and peptide-specific T cell activation. MHC class II-positive CIITA transfectants exhibit an unusually high capacity for binding exogenous peptides, with a higher percentage of DR molecules occupied by a given peptide and are much more efficient at peptide-specific, HLA-DR-restricted activation of T lymphocytes. This unexpected phenotype reflects the antigen processing defect observed in CIITA transfectants. It suggests novel strategies for the use of CIITA-transformed cells in peptide-based immunization.

Regulation of MHC class II genes: lessons from a disease.

Precise regulation of major histocompatibility complex class II (MHC-II) gene expression plays a crucial role in the control of the immune response. A major breakthrough in the elucidation of the molecular mechanisms involved in MHC-II regulation has recently come from the study of patients that suffer from a primary immunodeficiency resulting from regulatory defects in MHC-II expression. A genetic complementation cloning approach has led to the isolation of CIITA and RFX5, two essential MHC-II gene transactivators. CIITA and RFX5 are mutated in these patients, and the wild-type genes are capable of correcting their defect in MHC-II expression. The identification of these regulatory factors has furthered our understanding of the molecular mechanisms that regulate MHC-II genes. CIITA was found to be a non-DNA binding transactivator that functions as a molecular switch controlling both constitutive and inducible MHC-II expression. The finding that RFX5 is a subunit of the nuclear RFX-complex has confirmed that a deficiency in the binding of this complex is indeed the molecular basis for MHC-II deficiency in the majority of patients. Furthermore, the study of RFX has demonstrated that MHC-II promoter activity is dependent on the binding of higher-order complexes that are formed by highly specific cooperative binding interactions between certain MHC-II promoter-binding proteins. Two of these proteins belong to families of which the other members, although capable of binding to the same DNA motifs, are probably not directly involved in the control of MHC-II expression. Finally, the facts that CIITA and RFX5 are both essential and highly specific for MHC-II genes make possible novel strategies designed to achieve immunomodulation via transcriptional intervention.

A novel antigen-processing-defective phenotype in major histocompatibility complex class II-positive CIITA transfectants is corrected by interferon-gamma.

Presentation of exogenous protein antigens to T lymphocytes is based on the intersection of two complex pathways: (a) synthesis, assembly, and transport of major histocompatibility complex (MHC) class II-invariant chain complexes from the endoplasmic reticulum to a specialized endosomal compartment, and (b) endocytosis, denaturation, and proteolysis of antigens followed by loading of antigenic peptides onto newly synthesized MHC class II molecules. It is believed that expression of MHC class II heterodimers, invariant chain and human leukocyte antigen-DM is both necessary and sufficient to reconstitute a functional MHC class II loading compartment in antigen-presenting cells. Expression of each of these essential molecules is under the control of the MHC class II transactivator CIITA. Unexpectedly, however, whereas interferon gamma stimulation does confer effective antigen-processing function to nonprofessional antigen presenting cells, such as melanoma cells, expression of the CIITA transactivator alone is not sufficient. Activation of antigen-specific T cells thus requires additional CIITA-independent factor(s), and such factor(s) can be induced by interferon gamma.

An HLA-DRB alpha-helix motif shared by DR11 and DR8 alleles is implicated in the pluriallelic restriction of peptide-specific T-cell lines.

The T-cell recognition of HLA-DR-peptide complexes is generally restricted by the polymorphism of the DRB molecules but pluriallelic restriction has been described. The molecular basis of restriction and promiscuity of such peptide-specific responses is poorly understood. We isolated a panel of T-cell lines specific for the tetanus toxin peptide p2 (TT830-843) exhibiting pluriallelic restriction by DR11 and DR8 alleles. Fine restriction specificity of the T-cell lines was examined in functional assays against DR oligotyped APCs expressing different variants of DR11 and DR8 alleles. Our results show that (a) polymorphisms between serologically related alleles are relevant in terms of restriction of the peptide-specific T-cell response; in some instances, a single amino acid substitution can determine the restriction of a T-cell line; (b) different patterns of restriction are not the result of specific differences in DR-p2 binding as p2 peptide binds to all DR11 and DR8 alleles tested (DRB1* 1101, -1102, -1103, -1104, 110X, -0801, -0802, -0803, and -0806); and (c) pluriallelic restriction of the peptide-specific T-cell response correlates with the presence of a DRB1 alpha-helix motif (67-71-86) shared by some DR11 and DR8 alleles. Possible implications of pluriallelic restriction of peptide-specific T-cell response in autoimmune disorders associated with DR11 and DR8 are discussed.

Functional dissection of the serological DR LYGUE and genotypic DRB1*1303 specificities using a tetanus toxin-specific T-cell clone.

The DRB1 sequence of the homozygous cell line HAG (DR13-DwHAG-DQ7) represents a new DRB allele assigned DRB1*1103, whereas its DRB3 sequence corresponds to the previously described DRB3*0101 (DR52a) allele. The DRB1*1303 gene product is undetectable by current sera used in routine serology typing. We report here direct evidence that the MHC molecule encoded by the DRB1*1303 gene is functional in antigen presentation and in T-cell restriction. We describe a T-cell clone specific for tetanus toxin whose restriction pattern strictly follows the DRB1*1303 allele, as defined by oligonucleotide typing. It also follows the serologic reactivity with the serum LYGUE and also the DwHAG MLC-defined specificity pattern, with one exception. The potential functional sites for the DRB1*1303 gene product involved in T-cell restriction were deduced from sequence comparisons between DRB1*1303 and closely related DRB1 alleles. The relevant as substitutions were located within close proximity to each other on the HLA class II structural model. Our results demonstrate that 1) DRB1*1303 is functional in antigen presentation and T-cell restriction 2) the functional region involved in antigen presentation and T-cell restriction by DRB1*1303 can be defined structurally.