Edward M. Bertram

The B7 family member B7-H3 preferentially down-regulates T helper type 1-mediated immune responses.

We investigated the in vivo function of the B7 family member B7-H3 (also known as B7RP-2) by gene targeting. B7-H3 inhibited T cell proliferation mediated by antibody to T cell receptor or allogeneic antigen-presenting cells. B7-H3-deficient mice developed more severe airway inflammation than did wild-type mice in conditions in which T helper cells differentiated toward type 1 (TH1) rather than type 2 (TH2). B7-H3 expression was consistently enhanced by interferon-γ but suppressed by interleukin 4 in dendritic cells. B7-H3-deficient mice developed experimental autoimmune encephalomyelitis several days earlier than their wild-type littermates, and accumulated higher concentrations of autoantibodies to DNA. Thus, B7-H3 is a negative regulator that preferentially affects TH1 responses.

Temporal segregation of 4-1BB versus CD28-mediated costimulation: 4-1BB ligand influences T cell numbers late in the primary response and regulates the size of the T cell memory response following influenza infection.

In this report, we demonstrate that CD28−/− mice are severely impaired in the initial expansion of Db/NP366-374-specific CD8 T cells in response to influenza virus infection, whereas 4-1BB ligand (4-1BBL)−/− mice show no defect in primary T cell expansion to influenza virus. In contrast, 4-1BBL−/− mice show a decrease in Db/NP366-374-specific T cells late in the primary response. Upon secondary challenge with influenza virus, 4-1BBL−/− mice show a decrease in the number of Db/NP366-374-specific T cells compared to wild-type mice such that the level of the CD8 T cell expansion during the in vivo secondary response is reduced to the level of a primary response, with concomitant reduction of CTL effector function. In contrast, Ab responses, as well as secondary CD4 T cell responses, to influenza are unaffected by 4-1BBL deficiency. Thus, CD28 is critical for initial T cell expansion, whereas 4-1BB/4-1BBL signaling affects T cell numbers much later in the response and is essential for the survival and/or responsiveness of the memory CD8 T cell pool.

4-1BB and OX40 Act Independently to Facilitate Robust CD8 and CD4 Recall Responses

Mice deficient in OX40 or 4-1BB costimulatory pathways show defects in T cell recall responses, with predominant effects on CD4 vs CD8 T cells, respectively. However, OX40L can also stimulate CD8 T cells and 4-1BBL can influence CD4 T cells, raising the possibility of redundancy between the two TNFR family costimulators. To test this possibility, we generated mice deficient in both 4-1BBL and OX40L. In an adoptive transfer model, CD4 T cells expressed 4-1BB and OX40 sequentially in response to immunization, with little or no overlap in the timing of their expression. Under the same conditions, CD8 T cells expressed 4-1BB, but no detectable OX40. Thus, in vivo expression of 4-1BB and OX40 can be temporally and spatially segregated. In the absence of OX40L, there were decreased CD4 T cells late in the primary response and no detectable secondary expansion of adoptively transferred CD4 T cells under conditions in which primary expansion was unaffected. The 4-1BBL had a minor effect on the primary response of CD4 T cells in this model, but showed larger effects on the secondary response, although 4-1BBL−/− mice show less impairment in CD4 secondary responses than OX40L−/− mice. The 4-1BBL−/− and double knockout mice were similarly impaired in the CD8 T cell response, whereas OX40L−/− and double knockout mice were similarly impaired in the CD4 T cell response to both protein Ag and influenza virus. Thus, 4-1BB and OX40 act independently and nonredundantly to facilitate robust CD4 and CD8 recall responses.

A Switch in Costimulation from CD28 to 4-1BB during Primary versus Secondary CD8 T Cell Response to Influenza In Vivo

4-1BBL−/− mice exhibit normal primary CD8 T cell responses to influenza virus, but show decreased CD8 T cell numbers late in the primary response as well as decreased secondary responses. In contrast, CD28−/− mice are defective in initial CD8 T cell expansion. Using agonistic anti-4-1BB Ab to replace the CD28 or 4-1BB signal, we examined the timing of the required signals for CD28 vs 4-1BB costimulation. A single dose of agonistic anti-4-1BB Ab added only during priming restores the secondary CD8 T cell response in CD28−/− mice. Once the T cell numbers in the primary response reach a minimum threshold, a full secondary response is achieved even in the absence of CD28. In contrast, anti-4-1BB added during priming fails to correct the defective secondary response in 4-1BBL−/− mice, whereas addition of anti-4-1BB during challenge fully restores this response. Thus, there is a switch in costimulatory requirement from CD28 to 4-1BB during primary vs recall responses. Adoptive transfer studies show that T cells primed in 4-1BBL−/− or wild-type mice are equally capable of re-expansion when rechallenged in wild-type mice. These studies rule out a model in which signals delivered through 4-1BB during priming program the T cells to give a full recall response and suggest that 4-1BB-4-1BBL interactions take place at later stages in the immune response. The results indicate that anti-4-1BB or 4-1BBL therapy will be most effective during the boost phase of a prime-boost vaccination strategy.

Role of ICOS versus CD28 in antiviral immunity.

The costimulatory protein ICOS is inducibly expressed on activated T cells. Previous results have shown that ICOS–/– mice are defective in germinal center formation, antibody (Ab) production and class switch as well as Th1 and Th2 cytokine production in response to protein or parasite antigens. However, ICOS‐Ig failed to block antiviral Ab responses. To date the immune response to viruses has not been examined in ICOS–/– mice. In this report we compared antiviral Ab responses to LCMV, VSV and influenza virus in ICOS–/– versus wild‐type mice. Our results show that ICOS is important in the Ab response to all three viruses, with greater effects on primary as compared to secondary responses. Although ICOS–/– mice are impaired in some immune responses following influenza infection, the effects were less severe than for CD28–/– mice. There was no defect in initial influenza‐specific CD8 T cell expansion in ICOS–/– mice or in cytotoxic effector function. However, ICOS was important in maintaining CD4 cytokine production and CD8 T cell numbers late in the primary response. Upon secondary infection, ICOS–/– mice show wild‐type levels of influenza‐specific CD8 T cells, whereas CD28–/– mice show greatly impaired secondary CD8 T cell expansion. Overall, our results show that ICOS plays a clear role in the primary response to viruses at the level of Ab production, germinal center formation and Th cytokine production, but has diminished effects following secondary viral challenge.

A novel cytotoxicity assay to evaluate antigen-specific CTL responses using a colorimetric substrate for Granzyme B.

We have utilized the unique enzymatic properties of a key cytotoxic mediator in target cell destruction, Granzyme B (GrB), to establish an attractive alternative to 51Cr-release assays for the assessment of antigen-specific CTL responses. A number of potential colorimetric peptide substrates were compared to evaluate levels of GrB activity in cytolytic cells. The most specific and sensitive substrate for GrB was Ac-IEPD-pNA, as shown by the minimal enzymatic hydrolysis in apoptotic Jurkat cells and strong hydrolysis in human NK cells. When human peripheral blood lymphocytes were stimulated in vitro, elevated GrB levels were detected by both Ac-IEPD-pNA and a GrB ELISA. Analysis of allo-antigen-specific murine CTLs revealed that GrB exocytosis was only detectable upon challenge with appropriate allogeneic target cells and strongly correlated to 51Cr-release data. The validity of using Ac-IEPD-pNA in vaccine trials was demonstrated in mice immunized with allogeneic P815 cells, where GrB enzymatic activity was measurable in ex vivo splenocytes cell cultures only upon co-incubation with P815 targets. Additionally, influenza-infected mice were also assessed for GrB activity following in vitro peptide-stimulation of splenocytes and strongly reflected both peptide-specific tetramer staining and 51Cr-release results. The novel cytotoxic assay presented here should give investigators a sensitive, cross-species, nonradioactive alternative to 51Cr-release assays as a means to assess antigen-specific CTL responses in vaccine trials.

Cutting Edge: Profound Defect in T Cell Responses in TNF Receptor-Associated Factor 2 Dominant Negative Mice

TNFR-associated factor 2 (TRAF2) is an adapter protein that links several members of the TNFR family to downstream signaling pathways. Mice expressing a dominant negative form of TRAF2 in their lymphoid cells (TRAF2.DN mice) have a profound defect in T cell responses to allogeneic APC. In contrast, APC from wild-type or TRAF2.DN mice show an equivalent level of stimulation in a MLR. Ab production and class switch are unimpaired in TRAF2.DN mice. Thus, defects in the TRAF.DN mice appear to be limited to T cells. TRAF2.DN mice demonstrate an impaired T cell response to influenza virus, including decreased secondary expansion of IFN-γ-secreting T cells as well as a decrease in CTL activity. CD4 T cell production of IL-2 was also dramatically impaired in TRAF2.DN mice. These studies suggest an essential role of TRAF2-linked receptors in secondary CD4 and CD8 T cell responses and have important implications for transplantation.

T Cell Costimulatory Molecules in Anti-Viral Immunity: Potential Role in Immunotherapeutic Vaccines

T lymphocyte activation is required to eliminate or control intracellular viruses. The activation of T cells requires both an antigen specific signal, involving the recognition of a peptide/major histocompatibility protein complex by the T cell receptor, as well as additional costimulatory signals. In chronic viral diseases, T cell responses, although present, are unable to eliminate the infection. By providing antigens and costimulatory molecules together, investigators may be able to increase and broaden the immune response, resulting in better immunological control or even elimination of the infection. Recent progress in understanding the function of costimulatory molecules suggests that different costimulatory molecules are involved in initial immune responses than are involved in recall responses. These new developments have important implications for therapeutic vaccine design. In this review the authors discuss the function of T cell costimulatory molecules in immune system activation and their potential for enhancing the efficacy of therapeutic vaccines.