Enhanced activation of CD83-positive T cells.

CD83 is a marker molecule for mature dendritic cells (DCs) but is also substantially expressed on activated T cells in humans and mice. Its function is unknown, but CD83 knockout mice show an impaired thymic maturation of CD4-positive cells and soluble CD83 inhibits partially antigen-specific responses in vitro pointing to a role of CD83 in the immune system. Here we show that CD83-positive T cells produce strongly increased amounts of interferon-gamma and interleukin-2. In contrast, constitutive expression of CD83 on DCs alters neither the activation of DCs following addition of lipopolysaccharide nor the ability to present antigenic peptides. Thus, the expression of CD83 on T cells has direct functional consequences for tuning the activation threshold.

'Ignorance' of antigen-specific murine CD4+ and CD8+ T cells is overruled by lipopolysaccharide and leads to specific induction of IFN-gamma.

Lipopolysaccharide (LPS) can activate human and murine T cells in vivo and in vitro. Here we analysed the effects of LPS on T cells with defined specificities in T-cell receptor (TCR)-transgenic systems. LPS rapidly induced high amounts of interferon (IFN)-gamma in a subpopulation of purified T cells from DO11.10 (OVA323-339/H2-Ad) and OT-1 (OVA257-264/H2-Kb) mice when coincubated with antigen-pulsed peritoneal exudate cells (PECs). LPS induced IFN-gamma in T cell cultures even when the number of antigenic major histocompatibility complex (MHC) class-I complexes was too small to stimulate the T cells. LPS, thus, overruled the unresponsiveness of the otherwise 'antigen-ignorant' T cells. The release of IFN-gamma strictly correlates with the PECs' ability to produce interleukin (IL)-12. In contrast to the induction of IFN-gamma, antigen-specific IL-2 secretion and proliferation of T cells were rather decreased in the presence of LPS. Only very few IFN-gamma-secreting natural killer (NK) cells and natural killer T (NKT) cells in the given experimental system could be detected using intracellular fluorescence-activated cell sorter (FACS) staining. Taken together, our results indicate that LPS has the potential to activate quiescent T cells and to specifically induce IFN-gamma in CD4 and CD8 T cells. This may have direct consequences for the activation of autoreactive T cells following bacterial infections.

Eukaryotic heat shock proteins as molecular links in innate and adaptive immune responses: Hsp60-mediated activation of cytotoxic T cells.

Heat shock proteins (HSP) like Hsp60, Hsp70 and gp96 act directly on antigen-presenting cells (APC), e.g. by inducing the secretion of cytokines. Here we analyzed the impact of Hsp60 on the antigen-specific activation of CD8(+) T cells in a TCR transgenic system. Hsp60 induced low amounts of IFN-gamma in the absence of antigenic peptide; however, the release of IFN-gamma is increased by a factor of 3-10 following the addition of Hsp60 to purified populations of OT-1 [ovalbumin (OVA)257-264/H2-K(b)-restricted] T cells and antigen-pulsed peritoneal exudate cells (PEC) as APC. This effect is strictly correlated with the PEC ability to produce IL-12. In contrast, antigen-specific IL-2 secretion and T cell proliferation was not changed in the presence of Hsp60. Hsp60-containing OT-1 T cell cultures produced IFN-gamma even when the number of antigenic MHC class I complexes was too low to be stimulatory and could not be detected with specific mAb. Hsp60, thus, acts as a catalyzing molecule to initiate both innate and adaptive immune responses, and its presence (e.g. during an infection with cellular destruction) has direct consequences for the activation of otherwise 'ignorant' antigen-specific T cells.

Heat shock proteins as "danger signals": eukaryotic Hsp60 enhances and accelerates antigen-specific IFN-gamma production in T cells.

The heat shock proteins (HSP) gp96, Hsp70 and Hsp60 activate professional antigen-presenting cells (APC) to secrete proinflammatory cytokines and to express costimulatory molecules. Here, we analyze the impact of Hsp60 as a hypothetical danger signal on the antigen-specific activation of T cells derived from DO11.10 TCR-transgenic mice. The release of IFN-gamma, induced by the antigenic OVA(323-339)-peptide, is increased and accelerated dramatically by the addition of Hsp60 to ex vivo purified populations of T cells and peritoneal macrophages (PEC), while the antigen-specific IL-2 production or proliferation of the T cells remain unchanged. In contrast, "effector" T cells, undergoing secondary stimulation, displayed almost unchanged activation kinetics in the presence of Hsp60. The presence of Hsp60 induces IFN-gamma and up-regulation of CD69 in T cell/PEC cocultures even in the absence of antigenic peptide and this induction of IFN-gamma is strictly dependent on the ability of the macrophages to produce IL-12. Taken together, our data strongly suggest that the presence of eukaryotic mitochondrial Hsp60 allows antigen-specific IFN-gamma secretion under conditions when an antigenic stimulus alone is not sufficient to activate T cells.

Activation-induced expression of murine CD83 on T cells and identification of a specific CD83 ligand on murine B cells.

Human CD83 is a cell surface protein expressed predominantly by dendritic cells (DC) and lymphoid cells. So far, there exists no information on the function and distribution of mCD83. Here we demonstrate that mCD83 is moderately expressed on resting T cells and DC, but strongly increases in its expression on T cells following activation with antigenic peptides or T cell receptor-specific mAb. When returning to the resting state, T cells down-regulate CD83 again. Ig fusion proteins which express the extracellular part of the mCD83 molecule (mCD83-Ig) specifically inhibit antigen-specific T cell proliferation and IL-2 secretion in spleen cell cultures from DO11.10 T cell receptor transgenic mice. Staining of spleen cells from BALB/c, XID and mu MT (B cell) knockout mice with mCD83-Ig proteins reveals the presence of a CD83 ligand predominantly expressed most likely by B220(+) cells since spleen cells from mu MT knockout mice do not bind mCD83-Ig. CD83, besides its established expression on human dendritic cells, thus, also represents a new marker molecule on activated T cells which with its specific ligand is involved in the regulation of T cell responses.

Molecular analysis of CD26-mediated signal transduction in T cells.

CD26 or dipeptidylpeptidase IV (DPP IV) is a cell surface protease involved in T cell activation. It is a type II transmembrane glycoprotein consisting of a large extracellular part, a single transmembrane region and a short cytoplasmic tail without any common signalling motifs. To eluciate the mechanisms involved in CD26-mediated signalling we have constructed C-terminal deletion mutants of the human CD26 molecule and transfected them into murine T cell hybridomas. Stimulation experiments show that most of the extracellular part of CD26 can be deleted without affecting its costimulatory activity. The membrane proximal glycosylation rich region of CD26 is sufficient to transduce costimulatory signals. Activation of T cells via CD26, however, is not mediated by the important T cell receptor associated adaptor proteins LAT and TRIM as shown in colocalization assays.

Activation of cytotoxic T cells in vitro by recombinant gp96 fusion proteins irrespective of the 'fused' antigenic peptide sequence.

Heat shock proteins (HSP) like Hsp70 and gp96 are potent molecules to induce MHC class I-restricted cytotoxic T cells against antigens present in the cells from which the HSP were isolated. Fusion proteins consisting of mycobacterial Hsp70 covalently linked to antigenic peptide sequences are also capable of generating CTL specific for the peptide-encoded antigens. For effective CTL induction direct binding of the peptide or covalent association of the peptide in the case of antigenic fusion proteins is required. Since mycobacterial Hsp70 and eukaryotic Hsp70 differ significantly in their primary structure, and since gp96 compared to Hsp70 is more efficient in priming antigen specific CTL in our hands, we created fusion proteins consisting of His-tagged eukaryotic gp96 fused C-terminally to various peptide antigens. Here, we used antigenic sequences derived from the established ovalbumin (OVA) and beta-galactosidase (beta-GAL) model systems. We show that in vitro established OVA and beta-GAL specific CTL clones release TNF-alpha and IFN-gamma when incubated with recombinant gp96 irrespective of the antigenic peptide sequences hooked to the C-terminus of gp96. In contrast to gp96 preparations purified from beta-GAL expressing cell lines, recombinant gp96/beta-GAL fusion proteins were not able to generate beta-GAL-specific T cells in vivo. Possible explanations for the lack of antigen-specific immunogenicity of gp96 fusion proteins in vivo are discussed.

In vivo and in vitro activation of T cells after administration of Ag-negative heat shock proteins.

Heat shock proteins (HSP) Hsp70 and gp96 prime class I-restricted cytotoxic T cells against Ags present in the cells from which they were isolated. The immunization capacity of HSPs is believed to rely on their ability to bind antigenic peptides. In this study, we employed the well-established OVA and beta-galactosidase (beta-gal) antigenic model systems. We show that in vitro long-term established OVA and beta-gal-specific CTL clones release TNF-alpha and IFN-gamma when incubated with Ag-negative Hsp70 and gp96. In the absence of antigenic peptides, HSP-mediated secretion of TNF-alpha and IFN-gamma requires cell contact of the APC with the T cell but is not MHC-I restricted. Moreover, Hsp70 molecules purified from Ag-negative tissue, e.g., negative for antigenic peptide, are able to activate T cells in vivo, leading to significant higher frequencies in OVA-specific CD8+ T cells. In unprimed animals, these T cells lyse OVA-transfected cell lines and produce TNF-alpha and IFN-gamma after Ag stimulus. Taken together our data show that, besides the well-established HSP/peptide-specific CTL induction and activation, a second mechanism exists by which Hsp70 and gp96 molecules activate T cells in vivo and in vitro.

The adenosine deaminase-binding region is distinct from major anti-CD26 mAb epitopes on the human dipeptidyl peptidase IV(CD26) molecule.

CD26 or dipeptidyl peptidase IV (DPP-IV) is a cell surface protease involved in T cell activation. Monoclonal antibodies (mAbs) directed against the CD26 molecule are able to stimulate CD26-expressing T cells. Although many different CD26-specific mAbs exist which are able to provide a triggering signal in T cells, little is known about their specific epitopes on the CD26 molecule. Whereas some mAbs were shown to compete with each other and to inhibit the association of adenosine deaminase (ADA) and human immunodeficiency virus 1 (HIV-1)-derived Tat protein with CD26, other CD26-specific mAbs obviously bind to distinct regions on DPP-IV. In the present study we have generated truncated versions of the human CD26 molecule and expressed them in COS-1 cells to study the binding pattern of a panel of 14 CD26-specific mAbs in confocal microscopy and, thus, correlated the CD26-specific mAbs epitopes with the binding region of ADA. We show that the majority of anti-CD26 mAbs is directed against the glycosylation-rich region of the molecule whereas the ADA-binding site could be located in the cysteine-rich region of DPP-IV. In contrast to binding experiments with purified ADA, which revealed a specific association with CD26 on CD26-positive Jurkat cells, HIV-derived Tat protein did not interact specifically with CD26 on transfected Jurkat cells, nor could Tat binding be competed by anti-CD26-specific mAbs.

Partial agonism and independent modulation of T cell receptor and CD8 in hapten-specific cytotoxic T cells.

We recently demonstrated antagonism for hapten-reactive T cells by altered hapten ligands. Here we investigated partial peptide- or hapten-agonism and effects of antigen stimulation on the expression of TCR and the CD8 coreceptor using a set of DNP- or TNP-peptide-induced, H-2Kb-restricted mouse CTL clones. Various Kb-binding TNP- and DNP-peptides acted as partial agonists, cross-reactively stimulating individual clones for cytotoxicity and IFN-gamma secretion, but failing to induce proliferation or TNF-alpha production. Full agonism, i.e. activation of all possible functions, was usually restricted to those hapten-peptide combinations used for the induction of the respective clones. Our data imply distinctive kinetic optima for TCR antigen contacts in the induction of the various T cell effector functions. Down-regulation of TCR was efficiently induced by full, but with one exception not by partial, agonists, indicating the independence of cytotoxicity or IFN-gamma secretion from TCR modulation. On the other hand, a reduction of TCR expression induced by full agonists was usually not accompanied by synchronous down-modulation of CD8 as reported by others for human T cells. In fact, three of four full agonists and all partial agonists markedly enhanced rather than reduced the expression of CD8. Increased CD8 surface levels enhanced cytolytic potential and increased cross-reactivity patterns of individual clones. Brefeldin A blocked this CD8 induction by partial agonists, and in the case of full agonists resulted in a parallel reduction of both, TCR and CD8. Thus, antigenic stimulation of mouse T cells initially down-modulates CD8 together with TCR, but the loss of coreceptor is over-compensated by a signal for increased CD8 export.

The transmembrane region of CD2-associated signal-transducing proteins is crucial for the outcome of CD2-mediated T-cell activation.

Signalling through the CD2 molecule was shown previously to employ similar signalling molecules as the T-cell receptor (TCR). Here, we show that CD2-mediated signalling is strongly influenced by the expressed transmembrane region of the employed signal-transducing molecule. We used TCR-negative cells expressing chimeric fusion proteins that consist of human interleukin-2 (IL-2) receptor alpha-chain-derived sequences (hCD25) fused to mouse-specific zeta-chain segments (hCD25-zeta). One set of TCR-negative cell lines expressed the hCD25-derived extracellular part fused to mouse-specific transmembrane and cytoplasmic zeta-protein sequences ('TZZ'). The second type of cell lines expressed the hCD25-derived extracellular and transmembrane portions fused to the mouse-specific zeta-chain cytoplasmic segment ('TTZ'). After cross-linking the hCD25-zeta molecules with specific monoclonal antibodies (mAb), all TCR-negative cell lines produced similar amounts of IL-2. Cross-linking with stimulating pairs of CD2-specific mAb, however, led to IL-2 production only in cell lines expressing the zeta-chain-specific transmembrane segment. Co-cross-linking of CD25 and CD2 molecules resulted in an effective stimulation of both TZZ- and TTZ-expressing cell lines. Moreover, TTZ- and TZZ-expressing cell lines differed in their pattern of tyrosine-phosphorylated proteins after stimulation with hCD25-specific mAb. Thus, although CD2 and TCR molecules share signalling components and pathways, the fine tuning of CD2 co-receptor function appears to be regulated in part by transmembrane regions of signal-transducing molecules like the TCR-associated zeta-chain.

Dipeptidyl-peptidase IV/CD26 on T cells: analysis of an alternative T-cell activation pathway.

CD26 is a proteolytic enzyme (dipeptidyl-peptidase IV) with a wide tissue distribution and a unique specificity that was already described 27 years ago. CD26 is expressed on a fraction of resting T cells at low density but is strongly upregulated following T-cell activation. Recent results indicate that CD26 is a multifunctional molecule that may have important functions on T cells and in the immune system. It is associated with molecules of immunological importance such as the protein tyrosine phosphatase CD45 and adenosine deaminase (ADA) on the cell surface. Synthetic inhibitors of the enzymatic activity of CD26 have been shown to suppress certain immune reactions in vitro and in vivo. An interesting feature of CD26 is its ability to transmit a transmembrane signal to trigger functional programs in T cells. This triggering requires crosslinking of CD26 on a cell membrane. The enzymatic activity of CD26 is not obligatory for the activation of T cells via CD26. Since CD26 is a type II membrane protein with only six intracellular amino acids, it must deliver its signal via a signal-transducing molecule. Signaling is dependent on the expression of the T-cell receptor (TCR) complex with a special need for a functional zeta-chain. In this context the zeta-chain of the TCR complex is required for CD26-mediated signaling but, in contrast to other co-stimulatory molecules such as the CD2 molecule, is not sufficient for triggering the T cell.

Isolation of processed, H-2Kb-binding ovalbumin-derived peptides associated with the stress proteins HSP70 and gp96.

Stress-induced proteins or heat shock proteins (HSP) of 96 kDa mass (gp96) and 70 kDa mass (HSP70) have been shown previously to elicit specific immunity to tumors from which they are isolated. This immunity is dependent on CD8+ cytotoxic T cells which are readily primed in vivo by immunization with HSP. The immunization capacity of HSP relies on their ability to bind antigenic peptides. Here we show that HSP70 and gp96 preparations purified from the ovalbumin (OVA)-transfected cell line E.G7 are associated with processed H-2Kb-binding peptides which contain the major H-2Kb-associated epitope SIINFEKL (OVA257-264). Our data show for the first time in the well-defined OVA antigen system that not only endoplasmic reticulum-resident HSP, like gp96, are associated with processed antigenic peptides but that also the cytosolic HSP70 protein forms complexes with major finally processed MHC-binding epitopes.

CD2-mediated signaling in T cells lacking the zeta-chain-specific immune receptor tyrosine-based activation (ITAM) motif.

T lymphocytes can be activated via the T cell receptor (TCR) or by triggering through a number of other surface structures, including the CD2 co-receptor molecule. Signaling through the CD2 molecule was shown previously to be dependent on the TCR-associated zeta-chain. Here, we show that CD2-induced activation also functions in T cells which express zeta-chains lacking a functional immune-receptor tyrosine-based activation motif (ITAM). TCR-positive T cells that express only the transmembrane part of the zeta-chain protein and thus lack a functional zeta-derived ITAM readily produce interleukin (IL)-2 when cross-linked with CD2-specific monoclonal antibodies (mAb). TCR-negative T cell hybridomas expressing minimal receptors consisting of an extracellular CD25 and an intracellular zeta-chain-derived segment were effectively stimulated via CD2-specific mAb. For CD2-mediated co-stimulation of TCR-negative cells, two zeta-chain-derived ITAM were sufficient to induce IL-2 when the CD2 molecules were co-cross-linked with the chimeric CD25-zeta molecules. Taken together, our results show that CD2-induced signaling does not necessarily employ the zeta-chain in TCR-positive cells and that CD2-dependent co-stimulation in TCR-negative cells can be mediated via two functional zeta-chain-derived ITAM.

The T-cell receptor associated zeta-chain is required but not sufficient for CD26 (dipeptidylpeptidase IV) mediated signaling.

CD26 or dipeptidylpeptidase IV (DPP IV) is a cell surface protease involved in T-cell activation. Triggering or costimulation of T-cells via CD26 was shown to be dependent on the expression of the T-cell receptor (TCR) associated zeta-chain with at least one functional immune receptor tyrosine based activation motif (ITAM). Here we tested T-cell lines expressing chimeric proteins (hCD25-zeta) consisting of human IL-2 receptor-alpha chain derived extracellular sequences (hCD25) fused to mouse-specific zeta-chain segments, for their capacity to transfer CD26 mediated signals. Although these 'minimal receptor' expressing T-cell lines were capable of transmitting signals from other costimulatory molecules (e.g. CD2), crosslinking of CD26 did not induce IL-2 secretion. Co-cross-linking of hCD25 and CD26 molecules, however, resulted in the stimulation of the T-cells. Thus, although the zeta-chain is a prerequisite for CD26 mediated signaling events, the sole expression of zeta-protein as a signaling molecule is not sufficient for CD26 mediated triggering but permits CD26 induced costimulation in TCR negative cells.

A biological function for the XP motif within the N terminus of major histocompatibility complex class II-associated peptides.

A high proportion (up to 30%) of major histocompatibility complex (MHC) class II-bound peptides in the mouse and humans contains a proline residue at the N-terminal penultimate position (XP motif). We used a set of ovalbumin (OVA)-specific and hen egg lysozyme (HEL)-specific T cell hybridomas and asked whether the XP motif in MHC class II-associated peptides might influence the stimulation of T cells. We created N-terminally substituted variants of OVA323-339, an H2-Ad restricted OVA epitope and of HEL50-63, a dominant epitope in the context of H2-Ak. Our results show that the N-terminal sequence of MHC class II-bound peptides has a strong impact for the overall stimulation of specific T cells. Proline at the N terminus of antigenic peptides, in contrast to other amino acids, is tolerated or even enhances the recognition of MHC class II-bound peptides significantly.

Analysis of major histocompatibility complex class I-restricted hapten recognition by mutation of the V-J joining of T cell receptor alpha chains.

Hapten-specific T cell responses are responsible for chemically induced immune disorders. However, the molecular details of hapten interactions with T cell receptors (TCR) are poorly understood. Recent studies of trinitrophenyl (TNP)-specific responses revealed major histocompatibility complex-associated TNP-peptides as dominant epitopes for CD8+ and CD4+ T cells. The present study is based on the observation that two H-2Kb/TNP-specific CTL clones (II/7 and III/1), differing exclusively in two amino acids of their TCR alpha chains, also differed in their carrier specificities for various TNP-peptides. The genes of the two alpha chains and the common beta chain were cloned into expression vectors. Transfection of the TCR alpha chain of clone III/1 into a hybridoma of clone II/7 also transferred the fine specificity of clone III/1, indicating that the small alpha chain variations were indeed responsible for the different carrier specificities. Point mutations bridging the difference between the alpha chains of clones II/7 and III/1 and functional studies of the respective TCR alpha beta transfectants into a TCR-negative hybridoma revealed an unexpected result: the two receptors did not represent examples of structural complementarity for different sets of hapten-peptide conjugates; rather, they resembled two structures of principally similar specificity but of significantly different overall affinity. This was demonstrated more directly by comparing the fine specificities of III/1 transfectants expressing or not expressing the co-receptor CD8: the CD8-negative III/1 transfectant assumed a specificity pattern indistinguishable from that of a CD8-expressing, II/7-derived transfectant. Hence, comparable alterations of antigen recognition may be induced either by subtle TCR alterations or by removal of CD8, i.e. by the presence or absence of a non-polymorphic adhesion molecule.

Major histocompatibility complex class II-associated peptides determine the binding of the superantigen toxic shock syndrome toxin-1.

Superantigens bind to major histocompatibility complex (MHC) class II proteins and interact with variable parts of the T cell antigen receptor (TCR) beta-chain. Cross-linking the TCR with MHC class II molecules on the antigen-presenting cell by the superantigen leads to T cell activation that plays an essential role in pathogenesis. Recent crystallographic data have resolved the structure of the complexes between HLA-DR1 and staphylococcal enterotoxin B (SEB) and toxic shock syndrome toxin-1 (TSST-1), respectively. For TSST-1, these studies have revealed possible contact sites between the superantigen and the HLA-DR1-bound peptide. Here, we show that TSST-1 binding is dependent on the MHC-II-associated peptides by employing variants of T2 mutant cells deficient in loading of peptides to MHC class II molecules as superantigen-presenting cells. On HLA-DR3-transfected T2 cells, presentation of TSST-1, but not SEB, was dependent on HLA-DR3-associated peptides. Thus, although these superantigens can be recognized in the context of multiple MHC class II alleles and isotypes, they clearly bind to specific subsets of MHC molecules displaying appropriate peptides.

The beta D-sheet residues of the Lck-derived SH2 domain determine specificity of the interaction with tyrosine-phosphorylated ligands in Ramos B cells.

Src homology 2 (SH2) domains are noncatalytic regions that are conserved among a group of cellular signaling proteins. SH2 domains share the common property of binding phosphotyrosine-containing peptides. Previously, we showed that SH2 domains expressed as recombinant glutathione S-transferase-fusion proteins (GST-SH2) from GTPase-activating protein, Shc, zeta-chain-associated protein tyrosine kinase Zap-70, and Src-like tyrosine kinases precipitated distinct sets of phospho-proteins from activated B cells. To determine the intrinsic structural motifs responsible for the binding specificity within the different SH2 domains, we created chimeric SH2 domains especially focusing on crystal structure-defined contact residues. Recombinant SH2 domains of Lck, Zap-70, and Shc were tested in Ramos B cell lysates for phosphotyrosine-dependent protein binding. Biomolecular interaction analysis (BIAcore) was used to characterize the interaction between the various recombinant SH2 molecules and defined phosphorylated peptides. In agreement with the crystal structure data from the Src and the Lck SH2 domains, our results show that most of the "specificity information" of the Lck SH2 domain is provided by the beta D-sheet, located downstream of the SH2 conserved consensus motif GTFLVRES. In addition, the overall affinity is critically influenced by residues located at the N terminus of the SH2 domain.