Showing papers by "Mark M. Davis published in 1993"

Activation and differentiation requirements of primary T cells in vitro.

Abstract: The progression of T cells from a quiescent or resting state to fully activated, proliferating cells is a crucial step in the initiation of an immune response. We have developed an in vitro system to study the requirements for triggering or hindering this pathway by using naive T cells derived from T-cell antigen receptor alpha beta transgenic animals and peptide-major histocompatibility (MHC) complexes coated on plates. Whereas previously stimulated T cells require only peptide-MHC complexes to produce interleukin 2 (IL-2), naive cells require at least one additional signal, which can be provided by either an anti-CD28 antibody or the protein kinase C stimulant phorbol 12-myristate 13-acetate. In contrast, the anti-CD28 antibody augments IL-2 production by primed T cells but is not required, and phorbol 12-myristate 13-acetate has no discernable effect. Thus we find that native T cells have significantly more stringent requirements for IL-2 production than primed cells and that this fits well with previous observations in other in vitro systems as well as in vivo models of autoimmunity. We also find that peptide-MHC complex stimulation of naive T cells, together with exogenous IL-2, is sufficient to convert these cells to primed T cells in vitro in 2 days, as assayed both by surface marker analysis and stimulation requirements. Taken together with the above results, this suggests that the activation of primary T cells requires at least two signals and that IL-2 produced by naive T cells in vivo may act in an autocrine fashion to allow them to proliferate and differentiate.

T cell receptor interaction with peptide/major histocompatibility complex (MHC) and superantigen/MHC ligands is dominated by antigen.

Abstract: While recent evidence strongly suggests that the third complementarity determining regions (CDR3s) of T cell receptors (TCRs) directly contact antigenic peptides bound to major histocompatibility complex (MHC) molecules, the nature of other TCR contact(s) is less clear. Here we probe the extent to which different antigens can affect this interaction by comparing the responses of T cells bearing structurally related TCRs to cytochrome c peptides and staphylococcal enterotoxin A (SEA) presented by 13 mutant antigen-presenting cell (APC) lines. Each APC expresses a class II MHC molecule (I-Ek) with a single substitution of an amino acid residue predicted to be located on the MHC alpha helices and to point "up" towards the TCR. We find that very limited changes (even a single amino acid) in either a CDR3 loop of the TCR or in a contact residue of the antigenic peptide can have a profound effect on relatively distant TCR/MHC interactions. The extent of these effects can be as great as that observed between T cells bearing entirely different TCRs and recognizing different peptides. We also find that superantigen presentation entails a distinct mode of TCR/MHC interaction compared with peptide presentation. These data suggest that TCR/MHC contacts can be made in a variety of ways between the same TCR and MHC, with the final configuration apparently dominated by the antigen. These observations suggest a molecular basis for recent reports in which either peptide analogues or superantigens trigger distinct pathways of T cell activation.

Transfer of putative complementarity-determining region loops of T cell receptor V domains confers toxin reactivity but not peptide/MHC specificity.

Abstract: We have used multiple-amino acid replacement mutagenesis to examine the roles of the TCR homologues of Ig complementarity-determining regions (CDR) and framework sequences in Ag-MHC and Staphylococcus aureus enterotoxin reactivity. In the three cases examined, transplantation of Ig CDR3 homologues between I-Ek-restricted TCR that recognize distinct peptides did not result in transfer of peptide reactivity. Thus the structural context of the CDR3 loops, e.g., both neighboring CDR and the V beta structure, must play a crucial, albeit supporting, role in ligand recognition. The extreme lability of this context was also shown by the fact that transplantation of the CDR1, -2, and -3 loops from the beta chain of 5C.C7 onto a V beta 1 framework failed to transfer MHC-peptide specificity even when the TCR-alpha chains were identical. In contrast, superantigen reactivity was readily transferred in several cases, with CDR2 transplants conferring strong staphylococcal enterotoxin B and A reactivity and CDR1 transplants yielding weak reactivities. This suggests that bacterial (and perhaps other) superantigens bind to many of the same regions of the TCR V beta that are believed to interact with MHC molecules. These regions of V beta may be ideal targets for superantigen binding precisely because they interact with MHC molecules and thus may be relatively conserved.

Formation of functional peptide complexes of class II major histocompatibility complex proteins from subunits produced in Escherichia coli

Abstract: Class II major histocompatibility complex molecules play a major role in the immune response by binding peptide fragments of exogenous antigens and displaying them on the surfaces of antigen-presenting cells, where they can be recognized by T cells. To facilitate structural and functional studies of these molecules, we have produced truncated alpha and beta chains of the murine class II molecule I-Ek in Escherichia coli (Ec-I-Ek) and have developed conditions to fold them in the presence of specific peptides with yields of complex approaching 2%. Reconstitution is specific since only unlabeled peptide known to bind I-Ek compete with biotinylated peptide, as assessed by ELISA. Complexes of the refolded heterodimer (Ec-I-Ek) with either of two different peptide antigens remain associated during nonreducing SDS/PAGE. Immobilized Ec-I-Ek-peptide complexes stimulate lymphokine production by three T-cell clones in an antigen-specific manner with a dose-response relation comparable to previously described soluble I-Ek molecules produced in CHO cells. These results demonstrate that folding of Ek alpha and Ek beta polypeptides does not require any other protein to produce the biologically relevant conformation and that carbohydrate modification of this class II molecule is not necessary for alpha beta T-cell recognition.

An Analysis of T Cell Receptor–Ligand Interaction Using a Transgenic Antigen Model for T Cell Tolerance and T Cell Receptor Mutagenesis

Abstract: Publisher Summary This chapter presents an analysis of T cell receptor-ligand interaction using a transgenic antigen model for T-cell tolerance and T-cell receptor mutagenesis. It presents an analysis of the molecular basis of T-cell receptor (TCR) recognition of foreign peptide-major histocompatibility complexes (MHC). The chapter presents a few experiments that succeeded in transferring Staphylococcus aureus enterotoxin B (SEB) reactivity. T-cell receptor sequences, particularly V regions, are very similar to immunoglobulins, and the consensus of a number of experts is that they probably fold and pair in much the same way. However, the preponderance of their sequence diversity lies in the V(D)J junctional or CDR3-equivalent region, exceeding the diversity of immunoglobulin CDR3s by many orders of magnitude in the absence of somatic mutation.

pH affects both the mechanism and the specificity of peptide binding to a class II major histocompatibility complex molecule.

Abstract: We have compared the contribution of electrostatic forces in the binding of antigenic peptides to the class II MHC molecule, IEk, at weakly acidic (pH 5.4) and neutral (pH 7.5) pH values. The binding of specific moth cytochrome c (MCC) and hemoglobin (Hb) peptides to IEk is very sensitive to ionic strength at pH 7.5 but not at pH 5.4, indicating that the mechanism of peptide binding is pH-dependent. Substitution of the C-terminal Lys in MCC for an Ala residue selectively destroyed peptide binding at neutral pH and increased the dissociation rate at least 30-fold, implicating this residue in the pH-dependent electrostatic interaction. The presence of a C-terminal Lys in many of the peptides that are restricted to IEk suggests that this electrostatic interaction is widely used to bind peptides to this MHC molecule. We also probed the electrostatic environment of the peptide binding groove adjacent to the N-terminus of the bound peptide by rapid-diffusion fluorescence energy transfer using a terbium-labeled MCC peptide. In this region of the peptide binding groove, more negative charge is present at pH 7.5 than at pH 5.4. These findings indicate the importance of MHC carboxylates to the mechanism and specificity of peptide binding. The biological importance of having two distinct mechanisms of peptide binding at different pH may be that it acts to broaden the spectrum of antigenic peptides that can be presented to T-cells.