Robert W. Karr

HPRT mutant T-cell lines from multiple sclerosis patients recognize myelin proteolipid protein peptides

Mutation of the hypoxanthine-guanine phosphoribosyl transferase (HPRT) gene in a T-cell is believed to be an indication that the T-cell has been activated and has proliferated in vivo. HPRT mutant T-cell lines were generated from peripheral blood mononuclear cells from patients with MS and control subjects. More lines were isolated from the MS patients than from the control subjects. Using stringent criteria for recognition, none of the lines from MS-affected or control subjects recognized intact myelin basic protein (MBP) or myelin proteolipid protein (PLP) molecules. Using stringent criteria, two of the 10 MS patients harbored mutant lines each recognizing distinct PLP peptides (PLP peptide 40-60 recognized by 3 lines from one patient and PLP peptide 178-191 recognized by 2 lines from the other patient). A single line recognizing PLP peptide 89-106 was derived from 1 of 7 normal controls. HPRT mutant lines recognizing multiple epitopes of PLP which spanned much of the molecule could be isolated from MS patients, and to a lesser extent, normal subjects.

CTLA-4-Fc treatment of ongoing EAE improves recovery, but has no effect upon relapse rate.: Implications for the mechanisms involved in disease perpetuation

Several laboratories including ours have shown that T cell co-stimulation mediated through B7-1 or B7-2 is critical to the initiation of EAE. The role of T cell co-stimulation in ongoing EAE is less clear. In the present study, 32 mice with established EAE were randomly assigned to receive treatment with either CTLA-4-Fc or control Ig. Mice were followed daily by clinical scoring for 2 months post-immunization. A significant improvement in the degree of recovery following the acute episode and following relapses of EAE was observed in those mice randomized to CTLA-4-Fc treatment. Full clinical remission occurred twice as often in the CTLA-4-Fc group as in those mice receiving placebo, whereas placebo-treated mice were more likely to develop a stable prolonged neurologic deficit. Serial clinical scoring revealed no effect of CTLA-4-Fc upon relapse rate, with greater than 80% of the mice in each group displaying at least one clinical EAE relapse. In that the activation of memory T cells is relatively independent of T cell co-stimulation, these results indicate that development of chronic disease is associated with the activation of naive T cells and the recruitment of the latter cells into the disease process. Blocking B7 molecules may be beneficial in the treatment of established CNS inflammatory demyelinating diseases such as multiple sclerosis.

Functional activity of staphylococcal enterotoxin a requires interactions with both the alpha and beta chains of HLA-DR

The staphylococcal enterotoxins, SEA and SEE, bind one zinc atom per molecule of protein. The presence of this metal atom enhances the binding of the toxins to MHC class II molecules, presumably through an interaction with histidine 81 of the beta chain. L cell transfectants expressing HLA-DR1 and HLA-DR7 molecules, with mutations in either the alpha1 or beta1 domains, were tested for their ability to bind SEA and present it to T cells. Cells expressing DR1 molecules with alanine at positions 77, 78, 80, 83, 84 and 85, or serine at position 79 could all bind SEA and present it to either polyclonal or monoclonal T cells. Most point mutations within the alpha-helical portion of the DR7 beta chain had no effect on binding and presentation. However, substitution of histidine 81 with alanine, glutamate, or aspartate, abrogated SEA binding as well as T cell stimulation by the superantigen. This effect was also observed when the non-polymorphic aspartate, at position 76 was changed to alanine. Mutation of the asparagine at position 82 had an intermediate effect. Point mutations of the DR alpha chain had little effect on binding of SEA as determined by a flow cytometric assay. However, mutation of lysine at position 39 of the alpha chain and, to a lesser extent methionine at position 36, markedly decreased the ability of SEA to stimulate toxin-responsive mouse T cell hybridomas. Finally, the monoclonal antibody, L243 binds to the alpha chain of HLA-DR, and was able to block T cell activation by SEA without blocking SEA binding. These data support the model whereby HLA-DR has two binding sites for SEA. A low affinity site, present on the alpha chain, is required for T cell stimulation by the superantigen, but is insufficient to mediate toxin binding. High affinity binding of HLA-DR to SEA occurs solely through residues on the beta chain, including both histidine 81 and aspartate 76.

HLA-DR residues accessible under the peptide-binding groove contribute to polymorphic antibody epitopes

Many residues involved in polymorphic antibody-binding epitopes on class II molecules are located on the alpha-helix of DR beta chains. Although they have received less attention, residues in the peptide-binding groove and second domain of the DR beta chain may also be critical for polymorphic anti-DR antibody epitopes. In this study, we used transfectants expressing site-directed mutations at positions in the HLA-DR beta 1 and beta 2 domains and flow cytometry to define the epitopes of several polymorphic anti-DR antibodies. Both DR(beta 1*0403) residues 14 and 25 were shown to be involved in the epitopes of mAbs DA6. 164, HU-20, Q5/6, and 50D6, and DR(beta 1*0701) residue 14 was shown to be critical for the epitopes of two DR7-specific mAbs, SFR 16-DR7M and TAL13.1. Unlike most other residues shown to be important in antibody-binding epitopes, residue 14 is located in the floor of the peptide-binding groove and residue 25 is in an outer loop, each with their side chains pointing down, such that antibodies may directly contact these residues from below the binding groove. Two residues in the beta 2 domain, beta 180 and beta 181, were also shown to be involved in the epitopes of three polymorphic anti-DR mAbs, NFLD.D1, NFLD.M1, and LY9. Although these two residues are close to the transmembrane domain in the linear sequence, their solvent accessibility in the DR1 structures is quite impressive. Our data provide new evidence that residues accessible under the peptide-binding groove contribute to polymorphic antibody-binding epitopes.

Substitutions in the HLA-DRα chain differentially affect DR7-restricted T-cell recognition of rabies virus antigen

To investigate the functional roles of DR alpha residues in T-cell recognition, 20 mutants of the DR alpha chain were constructed by site-directed mutagenesis. These DR alpha mutants were expressed with WT DR(beta 1*0701) on mouse L cells and used as APC for four DR7-restricted T-cell clones specific for rabies virus antigens. The results indicate that the DR alpha residues are differentially involved in recognition of rabies virus antigen by different T-cell clones. Mutations in the floor of the antigen-binding groove (positions 9, 11, 22, and 24), on the alpha-helix (47, 55, 65, 66, and 72), and surprisingly on the outer loop (15, 18, and 19), abrogated recognition by at least one T-cell clone. Most of these residues appear to be involved in either peptide or TCR contact, based on the DR1 crystal structure. The involvement in T-cell recognition of DR alpha residues located in the outer loop outside the binding groove suggests that these residues may directly contact TCR, or indirectly contribute to the conformation of peptide sitting in the groove.