Probing the activation requirements for naive CD8+ T cells with Drosophila cell transfectants as antigen presenting cells.

Activation of T cells involves multiple receptor-ligand interactions between T cells and antigen presenting cells (APC). At least two signals are required for T-cell activation: Signal 1 results from recognition of MHC/peptide complexes on the APC by cell surface T-cell receptors (TCR), whereas Signal 2 is induced by the interactions of co-stimulatory molecules on APC with their complementary receptors on T cells. This review focuses on our attempts to understand these various signals in a model system involving the 2C TCR. The structural basis of Signal 1 was investigated by determining the crystal structure of 2C TCR alone and in complex with MHC/peptide. Analysis of these structures has provided some basic rules for how TCR and MHC/peptide interact; however, the critical question of how this interaction transduces Signal 1 to T cells remains unclear. The effects of Signal 1 and Signal 2 on T-cell activation were examined with naive T cells from the 2C TCR transgenic mice, defined peptides as antigen and transfected Drosophila cells as APC. The results suggest that, except under extreme conditions, Signal 1 alone is unable to activate naive CD8 T cells despite the induction of marked TCR downregulation. Either B7 or intercellular adhesion molecule (ICAM)-1 can provide the second signal for CD8 T-cell activation. However, especially at low MHC/peptide densities, optimal activation and differentiation of CD8 T cells required interaction with both B7 and ICAM-1 on the same APC. Thus, the data suggest that at least two qualitatively different co-stimulation signals are required for full activation of CD8 T cells under physiological conditions.

Requirements for stimulating naive CD8+ T cells via signal 1 alone.

In the absence of costimulation, TCR recognition of peptide/MHC complexes is generally considered to be nonimmunogenic. In agreement with this view, naive TCR transgenic CD8+ cells failed to respond to specific peptides presented by MHC class I (Ld) molecules bound to mouse RBC. However, peptide/Ld complexes presented by cell-sized beads or bound to plastic led to overt proliferative responses in the absence of added cytokines. Significantly, equivalent strong proliferative responses occurred when mouse RBC were fixed with glutaraldehyde before Ld coupling. The implication therefore is that the intensity of signaling via the TCR is a reflection of the mobility of the ligand being recognized; TCR signaling is weak when the ligand can move laterally on the cell membrane but strong when the ligand is immobilized.

Biomagnetic isolation of antigen-specific CD8+ T cells usable in immunotherapy.

Isolating antigen-specific T lymphocytes is hampered by the low frequency of the cells and the low affinity between T-cell receptors (TCR) and antigen. We describe the isolation and purification of antigen-specific CD8+ T lymphocytes from mixed T-cell populations. Magnetic beads coated with major histocompatibility complex class I molecules loaded with specific peptide were used as a substrate for T-cell capture. Low-frequency T cells, as well as T cells with TCR of low affinity for the antigen were captured on the beads. Following isolation and expansion, recovered cells specifically killed target cells in vitro, and displayed antiviral effect in vivo.

Epstein-Barr virus binding to CD21, the virus receptor, activates resting B cells via an intracellular pathway that is linked to B cell infection.

Epstein-Barr virus (EBV) initiates infection of normal B lymphocytes by binding to CD21, a complement receptor. Since EBV, unlike most viruses, preferentially infects resting (non-activated) cells, the present studies were undertaken to evaluate the hypothesis that intracellular signalling pathway(s) triggered by EBV binding to CD21 activate the expression of certain cellular genes, as well as the initially expressed viral genes, and thus enable EBV to infect resting B cells. Experiments with nontransforming EBV, recombinant virus ligand and anti-CD2 1 MAbs show that EBV binding to CD21 on resting B cells increases CD23 mRNA levels independently of viral gene expression. A panel of five protein kinase C (PKC) and tyrosine kinase (PTK) inhibitors, all with different modes of action, exhibited a distinctive pattern of effects on the EBV induced induction of CD23 expression, ranging from nearly complete inhibition to no influence. The results suggest that distinct PKC isoforms and PTKs are involved in the signalling pathway(s) triggered by EBV binding to CD21. Significantly, the five inhibitors showed the same pattern of effects on the earliest stages of infection (EBNA-2 transcription) and B cell transformation (mitogenesis and colony formation). The identical pattern of effects of these PKC and PTK inhibitors with diverse mechanisms of action on the EBV induced increase in both CD23 and EBNA-2 mRNA levels strongly suggests that their transcription is mediated by an intracellular signalling pathway which shares, at least in part, common members.

Modulation of signaling via the B cell antigen receptor by CD21, the receptor for C3dg and EBV.

CD21 is the receptor for C3dg and EBV. Several reports have shown that these CD21 ligands, and certain anti-CD21 mAb, trigger B cell activation, particularly when combined with Ag receptor ligation. However, the characteristics, biologic functions, and importance of this CD21-signaling pathway are unknown. We have used a model we recently developed to study B cell activation induced by complex particulate Ag, such as immune complexes and viruses, to begin to examine these questions. In the current studies, we incubated purified small resting B cells with 100-nm latex beads bearing various combinations of CD21 ligands and mAbs to CD19, CD35, and the Ag receptor. CD21, CD19, and CD35 have all been implicated in modulating membrane IgM initiated signaling. Beads coated with mAb to the C3dg/EBV-binding portion of CD21, but not mAb to other portions of the CD21 molecule, triggered B cell homotypic aggregation. Beads coated with the same CD21 ligands, although inactive alone, synergized with anti-IgM mAb in greatly increasing (20- to 180-fold) mRNA levels of the c-fos nuclear proto-oncogene. Signaling via CD21 was tyrosine kinase dependent. Levels of c-myc mRNA were not altered by CD21 ligands. Anti-CD19 and anti-CD35 mAb did not augment signaling via membrane IgM as assessed by changes in c-fos mRNA levels. These findings indicate that CD21 ligands binding to the C3dg/EBV-binding site of CD21 markedly augment B cell activation initiated by Ag receptor ligation via a selective, c-fos-dependent signaling pathway.

T cell-dependent, B cell-activating properties of antibody-coated small latex beads. A new model for B cell activation.

We have developed a new model to study B cell activation induced by complex particulate Ag, immune complexes, and viruses. As the surrogate for such Ag, we have used 100-nm fluorescent latex beads bearing mAb to IgM and IgD. Anti-IgM- and anti-IgD-coated small latex beads bind readily to tonsil resting B cells and induce homotypic B cell aggregation. Aggregation induced by anti-IgM-coated beads but not by anti-IgD-coated beads was massively enhanced by IL-2 and IL-4. Anti-IgM- and anti-IgD-coated beads increased (4- to 12-fold) c-fos and c-myc mRNA levels in resting B cells in a dose-dependent manner; this increase was tyrosine kinase dependent. Anti-IgM- and anti-IgD-coated beads were mitogenic for resting B cells, but unlike other B cell activation models, mitogenesis was absolutely dependent on the presence of IL-2 or IL-4. Finally, anti-IgM-coated beads but not anti-IgD-coated beads were internalized as single beads into small, thin-walled endocytic vesicles; internalization was absolutely dependent on the presence of IL-4. Binding and internalization can be readily quantified because the beads are fluorescent. This model can also be used to study the functions of other cell surface molecules that modulate Ag-specific B cell immune responses. It will also be used for examining multiple aspects of T-B cell interactions during immune responses and Ag processing because of the dependence on T cell factors for B cell activation, coupled with the finding that the Ab-coated beads are internalized.