Antigen-specific development of primary and memory T cells in vivo

Orally tolerized T cells are only able to enter B cell follicles following challenge with antigen in adjuvant, but they remain unable to provide B cell help

Although it is well documented that feeding Ag can tolerize or prime systemic humoral and cell-mediated immune responses, the mechanisms involved remain unclear. Elucidation of these mechanisms remains, in part, complicated by the inability to assess responses by individual lymphocyte populations. In the past, in vivo studies have examined T cell responses at the gross level by examining their ability to support B cell Ab production. However, as the fed Ag has the capacity to affect B cells directly, analyzing the functional capacity of a single Ag-specific T cell population in vivo has been difficult. Using a double-adoptive transfer system, we have primed or tolerized T cells, independently of B cells with a high dose of fed Ag, and examined the ability of these primed or tolerized T cells to support B cell clonal expansion in response to a conjugated Ag in vivo. We have been able to show that primed T cells support B cell clonal expansion and Ab production whereas tolerized T cells do not. Thus, we have provided direct evidence that tolerized T cells are functionally unable to help B cells in vivo. Furthermore, we have shown that this inability of tolerized T cells to support fulminant B cell responses is not a result of defective clonal expansion or follicular migration, since following challenge tolerized T cells are similar to primed T cells in both of these functions.

Adapting a transforming growth factor beta-related tumor protection strategy to enhance antitumor immunity

Transforming growth factor beta (TGF-beta), a pleiotropic cytokine that regulates cell growth and differentiation, is secreted by many human tumors and markedly inhibits tumor-specific cellular immunity. Tumors can avoid the differentiating and apoptotic effects of TGF-beta by expressing a nonfunctional TGF-beta receptor. We have determined whether this immune evasion strategy can be manipulated to shield tumor-specific cytotoxic T lymphocytes (CTLs) from the inhibitory effects of tumor-derived TGF-beta. As our model we used Epstein-Barr virus (EBV)-specific CTLs that are infused as treatment for EBV-positive Hodgkin disease but that are vulnerable to the TGF-beta produced by this tumor. CTLs were transduced with a retrovirus vector expressing the dominant-negative TGF-beta type II receptor HATGF-betaRII-Deltacyt. HATGF-betaRII-Deltacyt- but not green fluorescence protein (eGFP)-transduced CTLs was resistant to the antiproliferative and anticytotoxic effects of exogenous TGF-beta. Additionally, receptor-transduced cells continued to secrete cytokines in response to antigenic stimulation. TGF-beta receptor ligation results in phosphorylation of Smad2, and this pathway was disrupted in HATGF-betaRII-Deltacyt-transduced CTLs, confirming blockade of the signal transduction pathway. Long-term expression of TGF-betaRII-Deltacyt did not affect CTL function, phenotype, or growth characteristics. Tumor-specific CTLs expressing HATGF-betaRII-Deltacyt should have a selective functional and survival advantage over unmodified CTLs in the presence of TGF-beta-secreting tumors and may be of value in treatment of these diseases.

Predominant role of T cell receptor (TCR)-alpha chain in forming preimmune TCR repertoire revealed by clonal TCR reconstitution system

The CDR3 regions of T cell receptor (TCR)-alpha and -beta chains play central roles in the recognition of antigen (Ag)-MHC complex. TCR repertoire is created on the basis of Ag recognition specificity by CDR3s. To analyze the potential spectrum of TCR-alpha and -beta to exhibit Ag specificity and generate TCR repertoire, we established hundreds of TCR transfectants bearing a single TCR-alpha or -beta chain derived from a cytotoxic T cell (CTL) clone, RT-1, specific for HIVgp160 peptide, and randomly picked up TCR-beta or -alpha chains. Surprisingly, one-third of such TCR-beta containing random CDR3 beta from naive T cells of normal mice could reconstitute the antigen-reactive TCR coupling with RT-1 TCR-alpha. A similar dominant function of TCR-alpha in forming Ag-specific TCR, though low-frequency, was obtained for lymphocytic choriomeningitis virus-specific TCR. Subsequently, we generated TCR-alpha and/or -beta transgenic (Tg) mice specific for HIVgp160 peptide, and analyzed the TCR repertoire of Ag-specific CTLs. Similar to the results from TCR reconstitution, TCR-alpha Tg generated CTLs with heterogeneous TCR-beta, whereas TCR-beta Tg-induced CTLs bearing a single TCR-alpha. These findings of Ag recognition with minimum involvement of CDR3 beta expand our understanding regarding the flexibility of the spectrum of TCR and suggest a predominant role of TCR-alpha chain in determining the preimmune repertoire of Ag-specific TCR.

Clonal selection, clonal senescence, and clonal succession: the evolution of the T cell response to infection with a persistent virus

We have analyzed the CD8(+) T cell response to EBV and find that a larger primary burst size is associated with proportionally greater decay during the development of memory. Consequently, immunodominance and clonal dominance are less marked in memory than primary responses. An intuitive interpretation of this finding is that there is a limit to the number of cell divisions a T cell clone can undergo, and that the progeny of clones that have expanded massively during a primary immune response are more prone to die as a result of senescence. To test this hypothesis, we have derived a mathematical model of the response of different T cell clones of varying avidity for Ag in the primary and persistent phases of viral infection. When cellular survival and replication are linked to T cell avidity for Ag and Ag dose, then high-avidity T cells dominate both the primary and secondary responses. We then incorporated a limit in the number of cell divisions of individual T cell clones to test whether such a constraint could reproduce the observed association between cell division number and alterations in the contribution of clones to the response to persistent infection. Comparison of the model output with the experimental results obtained from primary and persistent EBV infection suggests that there is indeed a role for cellular senescence in shaping the immune response to persistent infection.

CD4 T cells selected by antigen under Th2 polarizing conditions favor an elongated TCR alpha chain complementarity-determining region 3

The affinity of the MHC/peptide/TCR interaction is thought to be one factor determining the differentiation of CD4+ T cells into Th1 or Th2 phenotypes. To study whether CD4+ cells generated under conditions favoring Th1 or Th2 responses select structurally different TCRs, Th1 and Th2 clones and lines were generated from nonobese diabetic and nonobese diabetic H2-E transgenic mice against the peptides proteolipoprotein 56-70, glutamic acid decarboxylase(65) 524-543, and heat shock protein-60 peptides 168-186 and 248-264. Th1/Th2 polarization allowed the generation of clones and lines with fixed peptide specificity and class II restriction but differing in Th1/Th2 phenotype in which the impact on TCR selection and structure could be studied. The Th2 clones tended to use longer TCR complementarity-determining region (CDR)3alpha loops than their Th1 counterparts. This trend was confirmed by analyzing TCRalpha transcripts from Th1 and Th2 polarized, bulk populations. Molecular modeling of Th1- and Th2-derived TCRs demonstrated that Th2 CDR3alpha comprised larger side chain residues than Th1 TCRs. The elongated, bulky Th2 CDR3alpha loops may be accommodated at the expense of less optimal interactions between the MHC class II/peptide and other CDR loops of the TCR. We propose that CD4+ T cells selected from the available repertoire under Th2 polarizing conditions tend to have elongated TCR CDR3alpha loops predicted to alter TCR binding, reducing contact at other interfaces and potentially leading to impeded TCR triggering.

Withdrawal of stimulation may initiate the transition of effector to memory CD4 cells

The initial steps that determine development of memory in CD4 cells are unknown. To distinguish an intrinsic capacity of effectors to become memory cells from contributions of as yet undefined survival factors, we analyzed the effects of withdrawal of signals via TCR, costimulation, and cytokines from Th1 or Th2 primary effectors induced in vitro from TCR-transgenic CD4 cells. Withdrawal of stimulation caused the transition of effectors to resting populations with a memory phenotype that did not undergo division following transfer to normal syngeneic recipients. The return of effectors to rest was accompanied by acquisition of the capacity to function as memory cells in vivo as defined by extended persistence and a more rapid response to Ag in vivo than naive cells in adoptive hosts. Upon challenge with Ag, these in vitro-rested Th1 and Th2 cells were similar to long-term in vivo-rested memory cells, but distinct from in vitro-generated primary effectors and in vivo-restimulated memory effectors by their ability to resist apoptosis. Cessation of stimulation may occur when activated CD4 cells exit lymphoid tissues after priming and transition to memory may be initiated if effectors either fail to gain access to Ag in peripheral tissues where restimulation can lead to activation-induced cell death or do not receive sufficient stimuli to continue a response. Our results suggest that the first stage leading to stable CD4 memory could occur stochastically and independently of instructional processes and as such, the development of memory may be a default pathway when signals that direct responses are not received.

Immunological approach in the evaluation of regional lymph nodes of patients with squamous cell carcinoma of the head and neck

In cancer, regional lymph node (LN) cells are one of the first components of the immune system to have contact with tumor cells or their products. Therefore, the phenotype and functional properties of hematopoietic cells present within the tumor-draining LN are important to understanding their role in the control of malignant cells. Based on the locoregional metastatic behavior of squamous cell carcinoma of the head and neck (SCCH&N) region, we analyzed tumor-draining lymph nodes from SCCH&N patients to obtain insights into regional tumor immunity. Using a three-color fluorescent labeling technique, surface antigen expression was visualized in mononuclear cells of lymph nodes that were obtained from head and neck cancer patients and compared to mononuclear cells of normal lymph nodes. Cell cycle analyses were performed using propidium iodide. Proliferation after phytohemagglutinin stimulation was measured by a sodium tetrazolium-based assay. LN histology was correlated with flow cytometric findings. Regional lymph nodes of head and neck cancer patients undergo morphologic and functional changes. Flow cytometry revealed a decrease in CD8(+) T cells and in some lymph nodes the presence of second or third populations of larger cells with distinct size and granularity that expressed both T (gammadelta/alphabeta) and different natural killer cell markers. Moreover, cell cycle analyses and proliferation assays showed a diminished response to mitogenic stimuli. These changes were found in both metastatic and hyperplastic lymph nodes from head and neck cancer patients; however, no alterations were found in control lymph nodes or peripheral blood mononuclear cells from noncancer patients. The immune alterations detected in lymphocytes present within the draining lymph nodes of head and neck cancer patients may improve our understanding of how tumor cells escape host immunosurveillance. However, this dysfunction in local draining lymph nodes may not be detected systemically.

T cells down-modulate peptide-MHC complexes on APCs in vivo

T cells compete in the response to antigen in vivo and this competition may drive the affinity maturation of a secondary T cell response. Here we show that high-affinity T cells out-competed lower affinity T cells during a response to antigenic challenge in vivo. Although competition between T cells specific for different peptide-major histocompatibility complexes (MHC) occurred, it was less efficient than competition between T cells of the same peptide-MHC specificity. In addition, high-affinity T cells efficiently induced antigen loss from the surface of antigen-presenting cells. Thus T cells that responded to the same peptide-MHC competed with each other by lowering the amount of ligand with which the cells could react. As a result, the activation of high-affinity cells was favored. This provides a mechanism for the affinity maturation of a secondary T cell response.

Homeostatic competition among T cells revealed by conditional inactivation of the mouse Cd4 gene

Absence of CD4 impairs the efficiency of T cell receptor (TCR) signaling in response to major histocompatibility complex (MHC) class II-presented peptides. Here we use mice carrying a conditional Cd4 allele to study the consequences of impaired TCR signaling after the completion of thymocyte development. We show that loss of CD4 decreases the steady-state proliferation of T cells as monitored by in vivo labeling with bromo-deoxyuridine. Moreover, T cells lacking CD4 compete poorly with CD4-expressing T cells during proliferative expansion after transfer into lymphopenic recipients. The data suggest that T cells compete with one another during homeostatic proliferation, and indicate that the basis of this competition is TCR signaling.

Increased resistance to collagen-induced arthritis in CD44-deficient DBA/1 mice

OBJECTIVE

To study the role of CD44, the principal hyaluronan (HA) receptor, in experimental arthritis.

METHODS

We generated CD44 gene deficiency in arthritis-susceptible DBA/1LacJ mice to study the role of CD44 directly in collagen-induced arthritis (CIA). Wild-type and CD44-deficient mice were immunized with chicken type II collagen, and the onset and severity of CIA were monitored up to day 64. The immune status of immunized mice was determined at the end of the experiments. Cell transfer experiments were performed to monitor lymphocyte traffic to the inflamed joints.

RESULTS

Mice homozygous for the CD44 mutation developed normally and showed no phenotypic defects. Although they showed a normal response to immunization with type II collagen and had Th1/Th2 ratios comparable with those in wild-type animals, CD44-deficient mice exhibited significant reductions in both the incidence and severity of CIA. This was accompanied by altered serum levels of HA, reduced expression of L-selectin, and a delayed entry of intravenously injected CD44-deficient donor lymphocytes into the arthritic joints of recipient mice.

CONCLUSION

While CD44 is not essential for morphogenesis and autoimmunity, this cell surface receptor seems to play an important role in the development of arthritis, most likely by directing leukocyte traffic to the site of inflammation.

Learning to remember: generation and maintenance of T-cell memory

Immunologic memory results from a carefully coordinated interplay between cells of the immune system. In this review, we explore various aspects of the nature, generation, and maintenance of T lymphocyte-mediated immunologic memory. In light of the demonstrated heterogeneity of the memory T-cell pool, we hypothesize that subsets of memory T cells instructed to mature to distinct differentiation stages may differ, not only in functional and homing properties, but also in the conditions they require for survival, including antigen persistence and cytokine environment. Hence, according to this hypothesis, distinct memory T-cell subsets result from the nature and timing of the signals provided by the immune environment and occupy distinct niches. Intracellular and extracellular molecular mechanisms that underlie and modulate T-cell memory are discussed.

CD4 positive peripheral T cells from patients with systemic lupus erythematosus (SLE) are clonally expanded

T cell activation was analysed in peripheral CD4+ T cells from both systemic lupus erythematosus (SLE) patients with active and inactive disease as well as in normal healthy donors (NHD) to investigate the involvement of CD4+ T cells in the etiopathogenesis of SLE. CD4+ T cell receptor (TCR) beta-chain transcripts, containing the complementarity determining region 3 (CDR3), were amplified by reverse transcriptase-polymerase chain reaction (RT-PCR) and analysed by high-resolution polyacrylamide gel electrophoresis. In addition the CDR3 of both clonally activated as well as heterogeneous Vbeta families from SLE patients were analysed at the molecular level. We observed a restricted CDR3 length polymorphism in peripheral CD4+ T cells from SLE patients compared with NHD, more pronounced in patients with high disease activity. Furthermore, in some Vbeta families single peaks in the histogram indicated nearly monoclonal T cell expansion. Sequencing of selected TCR beta-chains revealed a increased content of acidic amino acids in the CDR3 encoded by either proximal Jbeta elements or N nucleotides. We conclude that CD4+ T cells from peripheral blood of SLE patients display features of a secondary antigen driven immune response. The bias of the CDR3 towards acidic amino acids suggests the involvement of positively charged antigens.

Influenza A antigen exposure selects dominant Vbeta17+ TCR in human CD8+ cytotoxic T cell responses

During acute human viral infections, such as influenza A, specific cytotoxic T lymphocytes (CTL) are generated which aid virus clearance. We have observed that in HLA-A*0201+ subjects, CTL expressing Vbeta17+ TCR and recognizing a peptide from the influenza A matrix protein (M1(58-66)) dominate this response. In experimental models of infection such dominance can be due to inheritance of a restricted T cell repertoire or acquired consequent on expansion of CTL bearing an optimum TCR conformation against the MHC-peptide complex. To examine how influenza A infection might influence the development of TCR Vbeta17 expansion, we studied influenza A-specific CTL in a cross-sectional study of 82 HLA-A*0201+ individuals from birth (cord blood) to adulthood. Primary M1(58-66) -specific CTL were detected in cord blood, but their TCR were diverse and depletion of Vbeta17+ cells did not abrogate specific cytotoxicity. In contrast following natural influenza A infection, TCR Vbeta17+ CTL dominated to the extent that only one of nine adult CTL lines retained any functional activity after in vitro depletion of Vbeta17+ CTL. These results suggest that the dominance of Vbeta17+ TCR among adult M1(58-66)-specific CTL results from maturation and focussing of the response driven by exposure to influenza, and have implications for optimum immunization strategies.

Functional differences between influenza A-specific cytotoxic T lymphocyte clones expressing dominant and subdominant TCR

We have shown that the dominance of CD8+ T cells expressing TCR Vbeta17 in the adult HLA-A*0201-restricted influenza A/M1(58-66)-specific response is acquired following first antigen exposure. Despite the acquired dominance of Vbeta17+ cells, subdominant M1(58-66)-specific clones expressing non-Vbeta17+ TCR persist in all individuals. To determine whether the affinity of the expressed TCR for the HLA-A*0201/M1(58-66) complex could influence functional properties, M1(58-66)-specific clones expressing subdominant (non-Vbeta17+) TCR were compared to cytotoxic T lymphocyte (CTL) clones expressing dominant (Vbeta17+) TCR. The Vbeta17+ CTL required up to 10,000-fold lower amounts of M1 peptide to mediate lysis compared to CTL clones expressing other Vbeta gene segments. All Vbeta17+ CTL clones tested bound HLA-A*0201/M1(58-66) tetramer, but two of three CTL clones expressing other TCR did not bind tetramer. The inability of non-Vbeta17+ CTL to bind tetramer did not correlate with phenotype, CD8 dependence or with cytokine production profiles. This suggests a limitation for the use of tetramers in examining subdominant T cell responses. Together these findings suggest that Vbeta17+ CTL which dominate the HLA-A*0201-restricted CTL response against influenza A are not functionally distinct from subdominant non-Vbeta17+ CTL. The dominance of Vbeta17+ CTL is likely to result from a competitive advantage due to superior CTL avidity for the HLA-A*0201/M1(58-66) complex.

Interleukin-10 promotes the maintenance of antitumor CD8(+) T-cell effector function in situ

Interleukin-10 (IL-10) is a multifunctional cytokine that can exert suppressive and stimulatory effects on T cells. It was investigated whether IL-10 could serve as an immunostimulant for specific CD8(+) cytotoxic T cell (CTL) in vivo after vaccination and, if so, under what conditions. In tumor prevention models, administration of IL-10 before, or soon after, peptide-pulsed primary dendritic cell immunization resulted in immune suppression and enhanced tumor progression. Injection of IL-10, however, just after a booster vaccine significantly enhanced antitumor immunity and vaccine efficacy. Analysis of spleen cells derived from these latter animals 3 weeks after IL-10 treatment revealed that the number of CD8(+) CD44(hi) CD122(+) T cells had increased and that antigen-specific proliferation in vitro was enhanced. Although cytotoxicity assays did not support differences between the various treatment groups, 2 more sensitive assays measuring antigen-specific interferon-gamma production at the single-cell level demonstrated increases in the number of antigen-specific responder T cells in animals in the vaccine/IL-10 treatment group. Thus, IL-10 may maintain the number of antitumor CD8(+) T cells. In adoptive transfer studies, the ability of IL-10 to maintain CTL function could be enhanced by the depletion of CD4(+) T cells. This suggests that IL-10 mediates contrasting effects on both CD4(+) and CD8(+) T cells that result in either immune dampening or immune potentiation in situ, respectively. Appreciation of this dichotomy in IL-10 immunobiology may allow for the design of more effective cancer vaccines designed to activate and maintain specific CD8(+) T-cell effector function in situ.

In vivo activation of antigen-specific CD4 T cells

Physical detection of antigen-specific CD4 T cells has revealed features of the in vivo immune response that were not appreciated from in vitro studies. In vivo, antigen is initially presented to naïve CD4 T cells exclusively by dendritic cells within the T cell areas of secondary lymphoid tissues. Anatomic constraints make it likely that these dendritic cells acquire the antigen at the site where it enters the body. Inflammation enhances in vivo T cell activation by stimulating dendritic cells to migrate to the T cell areas and display stable peptide-MHC complexes and costimulatory ligands. Once stimulated by a dendritic cell, antigen-specific CD4 T cells produce IL-2 but proliferate in an IL-2--independent fashion. Inflammatory signals induce chemokine receptors on activated T cells that direct their migration into the B cell areas to interact with antigen-specific B cells. Most of the activated T cells then die within the lymphoid tissues. However, in the presence of inflammation, a population of memory T cells survives. This population is composed of two functional classes. One recirculates through nonlymphoid tissues and is capable of immediate effector lymphokine production. The other recirculates through lymph nodes and quickly acquires the capacity to produce effector lymphokines if stimulated. Therefore, antigenic stimulation in the presence of inflammation produces an increased number of specific T cells capable of producing effector lymphokines throughout the body.

CD4(+) T cell effectors can become memory cells with high efficiency and without further division

Whether memory T lymphocytes are derived directly from effector T cells or via a separately controlled pathway has long been debated. Here we present evidence that, after adoptive transfer, a large fraction of in vitro--derived effector CD4(+) T cells have the potential to become memory T cells and that this transition can occur without further division. This data supports a linear pathway from effector to memory cells and suggests that most properties of memory cells are predetermined during effector generation. We suggest, therefore, that evaluation of vaccine efficacy in the induction of memory CD4(+) T cells should focus on the effector stage.

Evidence of T cell clonality in the infectious tolerance pathway: implications toward identification of regulatory T cells

We have shown that a rare population of regulatory CD4+ T cells plays a key role in the acquisition of infectious tolerance in rat sensitized recipients of cardiac allografts pretreated with nondepleting anti-CD4 mAb. This study was designed to analyze the TCR Vbeta expression patterns in this transplantation model. First, we used Vbeta-specific RT-PCR to show that there was no differential usage of TCR Vbeta genes by T cells mediating rejection or tolerance. Indeed, graft-infiltrating lymphocytes expressed most of the 22 known rat TCR Vbeta genes in both recipient groups, suggesting unrestricted TCR Vbeta repertoire in alloreactive T cells. Then, we applied CDR3 spectrotyping of TCR beta-chain to assess the clonality of T cells at different anatomic sites. CDR3 size restriction, indicative of the presence of T cell clones, was observed in graft-infiltrating lymphocytes but not in draining lymph nodes or spleen of tolerant hosts. Consisent with the clonal expansion, T cells in tolerated grafts exhibited the memory phenotype at a much higher percentage as compared with peripheral lymphoid organs. Moreover, in tolerated graft-infiltrating lymphocytes, the CD3 size restriction occurred in limited Vbeta gene families, with Vbeta8.1 and Vbeta18 most frequently detected. Hence, T cells at the graft site of tolerant recipients contain T cell clones expressing selective Vbeta genes. This phenotypic characteristics of the tolerogenic GILs may potentially be used as a novel marker to identify operational regulatory T cells in organ allograft recipients.

Antigen decoding by T lymphocytes: from synapses to fate determination

Naïve T lymphocytes sense foreign antigens by establishing contacts with dendritic cells (DCs). At the immunological synapse between the T cell and a DC, T cell receptors (TCRs) are serially engaged and triggered by specific ligands. The amount and duration of TCR triggering and the efficiency of signal amplification determine T cell commitment to proliferation and differentiation. The nature and availability of DCs bearing antigen and costimulatory molecules shape the T cell response, giving rise to distinct functional outputs such as effector and memory T cell generation or T cell tolerance.

The instructive role of dendritic cells on T cell responses: lineages, plasticity and kinetics

Dendritic cells are responsible for directing different types of T cell responses, from thymic negative selection to the generation of effector and memory cells and the induction of peripheral tolerance. Recent studies indicate that the dendritic cell lineage, the extent of recruitment into inflamed tissues and migration to lymph nodes, the nature of maturation stimuli and the kinetics of activation have a quantitative and qualitative impact on T cell stimulation, thus exerting an instructive control on T cell responses.

Identification of the T cell clones expanding within both CD8+CD28+ and CD8+CD28− T cell subsets in recipients of allogeneic hematopoietic cell grafts and its implication in post-transplant skewing of T cell receptor repertoire

We have previously reported that skewed repertoires of T cell receptor-beta chain variable region (TCRBV) and TCR-alpha chain variable region (TCRAV) are observed at an early period after allogeneic hematopoietic cell transplantation. Furthermore, we found that T lymphocytes using TCRBV24S1 were increased in 28% of the recipients of allogeneic grafts and an increase of TCRBV24S1 usage was shown to result from clonal expansions. Interestingly, the arginine residue was frequently present at the 3' terminal of BV24S1 segment and was followed by an acidic amino acid residue within the CDR3 region. These results suggest that these clonally expanded T cells are not randomly selected, but are expanded by stimulation with specific antigens. This study was undertaken to elucidate the mechanisms of the post-transplant skewing of TCR repertoires. Since the CD8(+)CD28(-)CD57(+) T cell subset has been reported to expand in the peripheral blood of patients receiving allogeneic hematopoietic cell grafts, we examined the TCRAV and TCRBV repertoires of the CD8(+)CD28(-) T cell and CD8(+)CD28(+) T cell subsets, and also determined the clonality of both T cell populations. In all three recipients examined, the CD8(+)CD28(-) T cell subset appeared to define the post-transplant TCR repertoire of circulating blood T cells. Moreover, the CDR3 length of TCRBV imposed constraints in both CD8(+)CD28(-) T cell and CD8(+)CD28(+) T cell subsets. The DNA sequences of the CDR3 region were determined, and the same clones were identified within both CD8(+)CD28(-) and CD8(+)CD28(+) T cell subsets in the same individuals. These results suggest that the clonally expanded CD8(+)CD28(-) T cells after allogeneic hematopoietic cell transplantation derive from the CD8(+)CD28(+) T cell subset, possibly by an antigen-driven mechanism, resulting in the skewed TCR repertoire.

Oligoclonal expansion of CD4(+)CD28(-) T lymphocytes in recipients of allogeneic hematopoietic cell grafts and identification of the same T cell clones within both CD4(+)CD28(+) and CD4(+)CD28(-) T cell subsets

Recipients of allogeneic bone marrow grafts have clonally expanded CD8(+)CD28(-) T lymphocytes during the early period after transplantation, which leads to skewing of T cell receptor (TCR) repertoires. Here, we have addressed the question of whether clonal expansion of CD28(-) T cells is also observed in CD4(+) T lymphocytes after human allogeneic hematopoietic cell transplantation. We found that the fraction of T cells lacking CD28 expression in the CD4(+) subset was increased after transplantation, and expanded CD4(+)CD28(-) T lymphocytes carrying certain TCRBV subfamilies showed limited TCR diversity. In order to further study the ontogeny of CD4(+)CD28(-) T cells, we analyzed the complementarity-determining region 3 (CDR3) of the TCR-beta chain of CD4(+)CD28(+) and CD4(+)CD28(-) cells. We identified the same T cell clones within both CD4(+)CD28(-) and CD4(+)CD28(+) T cell subsets. These results suggest that both subsets are phenotypic variants of the same T cell lineage.

Kinetics of TCR use in response to repeated epitope-specific immunization

Selection of T cell-directed immunization strategies is based extensively on discordant information derived from preclinical models. We characterized the kinetics of T cell selection in response to repeated antigenic challenge. By enumerating with epitope/HLA tetrameric complexes (tHLA) vaccine-elicited T cell precursor frequencies (Tc-pf) in melanoma patients exposed to the modified gp100 epitope gp100:209-217 (g209-2M) we observed in most patients that the Tc-pf increased with number of immunizations. One patient's kinetics were further characterized. Dissociation kinetics of g209-2M/tHLA suggested enrichment of T cell effector populations expressing TCR with progressively higher affinity. Furthermore, vaccine-elicited T cells maintained the ability to express IFN-gamma ex vivo and proliferate in vitro. Thus, repeated exposure to immunogenic peptides benefited immune competence. These results provide a rationale for immunization strategies.

Potent effector function of tumor-sensitized L-selectin(low) T cells against subcutaneous tumors requires LFA-1 co-stimulation

OBJECTIVE

Animal tumor models have demonstrated that adoptive transfer of tumor-draining lymph node (TDLN) T lymphocytes can cure established tumors in many anatomic sites. However, subcutaneous tumors are relatively refractory and have required maximally tolerated doses of cells. The goals of this study were to determine whether a subset of TDLN T lymphocytes varying in expression of the cell adhesion molecule L-selectin (CD62L) had augmented therapeutic efficacy and to determine the co-stimulatory requirements for trafficking and anti-tumor effector function.

STUDY DESIGN

TDLNs were recovered from mice bearing progressive MCA 205 fibrosarcomas, and the T lymphocytes were segregated into CD62L(low) and CD62L(high) subsets and activated ex vivo with anti-CD3 mAb and IL-2. Mice bearing established subcutaneous MCA 205 tumors were treated with activated T cell subsets and in some experiments with additional mAb against cell adhesion molecules.

RESULTS

Adoptive transfer of as few as 5 x 10(6) activated cells cured mice bearing 3-day subcutaneous MCA 205 tumors initiated with 6 x 10(6) cells, and the tumors demonstrated a dense infiltrate of CD62L(low) cells. In marked contrast, adoptive transfer of 10 times as many T cells derived from the reciprocal CD62L(high) compartment had no effect on tumor growth. The effector function of the CD62L(low) T cells was clearly dependent on co-stimulation through the cell adhesion molecule LFA-1, because anti-LFA-1 mAb completely abrogated the anti-tumor reactivity of the transferred cells against subcutaneous tumors and inhibited tumor infiltration. In contrast, blockade of ICAM-1, VLA-4, or VCAM-1 had no inhibitory effect on the anti-tumor function.

CONCLUSION

These studies demonstrate the high therapeutic activity of the CD62L(low) subset of tumor-draining LN T cells against subcutaneous tumors, a relatively refractory site, and confirm the essential role of LFA-1 for effector T cell function.

SIGNIFICANCE

Identification of the phenotype and requirements for effector function of T lymphocytes sensitized to tumor antigens has implications for clinical trials of adoptive immunotherapy for head and neck carcinoma using a similar approach.

Longitudinal analysis of T cells responding to tetanus toxoid in healthy subjects as well as in pediatric patients after bone marrow transplantation: the identification of identical TCR-CDR3 regions in time suggests long-term stability of at least part of the antigen-specific TCR repertoire

To understand the nature of long-term Th immune responses, we investigated in the present study the TCRBV gene repertoire of CD4(+) T cells specific for the recall antigen tetanus toxoid (TT) in recipients of an allogeneic bone marrow transplantation (allo-BMT) at several time points after transplantation and in their BM donors. We observed that the TCR repertoire of TT-specific CD4(+) Th cells was heterogeneous, and differed between allo-BMT recipients and their respective donors. Some individuals, however, used similar TCR-complementarity-determining region (CDR) 3 motifs that could reflect recognition of and selection by similar promiscuous epitopes of TT. Longitudinal analysis of this TT-specific T cell response revealed that T cells with completely identical TCR were present at several time points after the first analysis in allo-BMT recipients, most probably reflecting long-term stability of at least part of the antigen-specific TCR repertoire. Similar stability of the TT-specific TCR repertoire in time was also noted in the allo-BMT donors. These observations reveal that within a given individual the dominant antigen-specific T cell clones persist in time in an otherwise diverse TT-specific CD4(+) T cell immune response.

Extensive clonal expansion of T lymphocytes causes contracted diversity of complementarity-determining region 3 and skewed T cell receptor repertoires after allogeneic hematopoietic cell transplantation

We previously described skewed repertoires of the T cell receptor-beta chain variable region (TCRBV) and the TCR-alpha chain variable region (TCRAV) soon after allogeneic hematopoietic cell transplantation. To determine the characteristics of skewed TCRBV after transplantation, we examined the clonality of T lymphocytes carrying skewed TCRBV subfamilies and determined the CDR3 sequences of expanded T cell clones. In all 11 recipients examined, TCR repertoires were skewed, with an increase of certain TCRBV subfamilies that differed among individuals. In nine of 11 patients, clonal/oligoclonal T cell expansion was observed, although the expanded T cells were not necessarily oligoclonal. The extent of expansion after transplantation appeared to predict clonality. The arginine (R)-X-X-glycine (G) sequence was identified in clonally expanded T cells from four of five recipients examined, and glutamic acid (E), aspartic acid (D) and alanine (A) were frequently inserted between R and G. These results suggest that T lymphocyte expansion may result from the response to antigens widely existing in humans, and that the extensive clonal expansion of a limited number of T cells leads to contracted CDR3 diversity and post-transplant skewed TCR repertoires.

Prevalence of an ulcerative colitis-associated CD8+ T cell receptor beta-chain CDR3-region motif and its association with disease activity

The normal human intestinal mucosa contains clonal T cell expansions. Clonal populations of T cells can be determined through evaluation of the idiotypic, hypervariable region of their T cell receptor (TCR). We have previously reported that there exists a highly conserved TCR pattern among intestinal CD8+ T cells in the majority of ulcerative colitis (UC) patients undergoing colectomy that was not present in normal control individuals. This TCR pattern, or motif, was characterized by particular beta-chain usage (TCRBV3 and TCRBJ1S6) and a defined length in the hypervariable third complementarity determining region (CDR3). The aim of this study was to assess the motif's relationship to disease activity. Subjects were 66 with UC, 19 with Crohn's disease, 14 inflammatory controls, and 6 normal controls. cDNA and gDNA were prepared from colonic biopsies and paraffin blocks, respectively, obtained from study subjects and used to assess TCRBV CDR3 region length and usage, as well as for cloning and sequencing of TCRs. The TCRBV CDR3 region was present in 25 of a series of 48 UC subjects but only 3 of 19 Crohn's disease patients and 3 of 14 inflammatory controls. The motif was more common in UC than either Crohn' s disease or inflammatory controls (chi2 = 7.5, P = 0.006, and chi2 = 4.1, P = 0.04, respectively). The motifs presence was not dependent upon histologic disease activity (either active or inactive UC). Clinical UC disease activity was also not significantly associated with an increased presence of the motif in 14 paired biopsies, which were taken during times of clinical activity or inactivity. There was a trend toward persistence of the motif, as it was present in 6 of 14 subjects over a 3- to 6-month time period. The previously described UC-associated TCRBV CDR3 region motif located in the intestinal CD8+ T-cell subset is found in a significant proportion of UC subjects. The TCR motif does not significantly discriminate active from inactive disease states. The persistent and diffuse nature of this TCR-associated motif in UC suggests that an ongoing T-cell response to a particular antigen(s) is occuring in this disorder.

Single epitope multiple staining to detect ultralow frequency B cells

Here we describe a method for detecting ultralow frequency target cells from within a high background of irrelevant cells by a novel method, single epitope multiple staining (SEMS). Samples of murine splenocytes were seeded with a low number of splenocytes from mice transgenic for a hen eggwhite lysozyme (HEL)-specific immunoglobulin (Ig). These samples were stained with two reagents specific for the same epitope expressed by the transgenic B cells, which had been conjugated to two different detectable labels (FITC and biotin). This dual staining of a single epitope allowed us to reduce the background due both to non-specific binding of reagents and to probabilistic distribution of the cells. We also were able to detect the cells based on knowing only one thing about them, namely, their antigen specificity. The SEMS method allowed us to reproducibly detect transgenic cells at frequencies below one cell in one million cells. SEMS could be used to increase the sensitivity of numerous fluorescence-based applications in addition to the detection and isolation of antigen-specific lymphocytes, including the detection and highly specific isolation of genetically modified cells, transformed cells, stem cells, fetal cells, or infectious organisms.

A kinetic window constricts the T cell receptor repertoire in the thymus

To characterize the ligand binding properties of a naive T cell repertoire capable of responding to a foreign antigen, we analyzed T cell populations from T cell receptor (TCR) beta transgenic mice using a novel, single cell peptide/major histocompatibility complex (MHC) tetramer dissociation assay. The largely CD4+CD8(-/low) antigen-specific thymocyte repertoire exhibited a broad, bimodal distribution of tetramer binding half-lives (t(1/2)s), with a significant underrepresentation in the intermediate half-life range in which the majority of the peripheral repertoire lies. Thus, cells with the potential to bind foreign antigen with the lowest and highest stability are likely to be selectively removed from the repertoire prior to their establishment in the periphery. These studies provide direct evidence that thymic selection biases the naive peripheral T cell repertoire toward TCR-ligand interactions that fall within a moderate half-life "window."

Visualizing the generation of memory CD4 T cells in the whole body

It is thought that immunity depends on naive CD4 T cells that proliferate in response to microbial antigens, differentiate into memory cells that produce anti-microbial lymphokines, and migrate to sites of infection. Here we use immunohistology to enumerate individual naive CD4 T cells, specific for a model antigen, in the whole bodies of adult mice. The cells resided exclusively in secondary lymphoid tissues, such as the spleen and lymph nodes, in mice that were not exposed to antigen. After injection of antigen alone into the blood, the T cells proliferated, migrated to the lungs, liver, gut and salivary glands, and then disappeared from these organs. If antigen was injected with the microbial product lipopolysaccharide, proliferation and migration were enhanced, and two populations of memory cells survived for months: one in the lymph nodes that produced the growth factor interleukin-2, and a larger one in the non-lymphoid tissues that produced the anti-microbial lymphokine interferon-gamma. These results show that antigen recognition in the context of infection generates memory cells that are specialized to proliferate in the secondary lymphoid tissues or to fight infection at the site of microbial entry.

Early commitment of adoptively transferred CD4+ T cells following particle-mediated DNA vaccination: implications for the study of immunomodulation

The early responses of CD4+ T cells to particle-mediated DNA immunisation were investigated using OVA-specific TCR-transgenic CD4+ T cells. Following adoptive transfer of these cells, mice were immunised by delivery into the skin of a plasmid encoding ovalbumin. Transgenic T cells underwent a rapid and transient antigen-specific activation, followed by clonal expansion (up to approximately 6% of total lymphocytes). Immunisation with ovalbumin in CFA evoked similar responses with slightly faster kinetics. Numerous antigen-specific T cells synthesising IFN-gamma (Th1) and IL-4 (Th2) were detectable using both intracellular staining and ELISPOT assays. This study provides a quantitative analysis of both T cell proliferation and Th1/Th2 balance following particle-mediated DNA immunisation and establishes a robust and sensitive model in which to assess modulation of helper T cell responses in DNA vaccination.

Pulmonary T cell repertoire in patients with graft-versus-host disease following blood and marrow transplantation

Pulmonary inflammation is one of the risk factors associated with blood and marrow transplantation (BMT). To determine the potential role of T cells in pulmonary complications after transplantation, we analyzed the T-cell repertoire expressed in bronchoalveolar lavage fluids from eleven patients with graft-versus-host disease following BMT. A reverse transcriptase-polymerase chain reaction was used to amplify rearranged TCR transcripts in unfractionated, CD4+, and CD8+ T cells from bronchoalveolar lavage fluids. The relative expression of TCR variable (V) gene families and the diversity of junctional region lengths associated with different AV and BV gene families were analyzed. Nearly all TCR AV and BV gene families were detected in bronchoalveolar lavage cells from BMT recipients. Oligoclonal patterns of TCR junctional region lengths were observed in unfractionated, CD4+, and CD8+ bronchoalveolar T cells. The oligoclonal expansion of bronchoalveolar T cells in patients was confirmed by DNA sequencing. TCRV gene expression is almost completely restored in the lungs of BMT recipients as early as two weeks after transplantation. Increased oligoclonality among TCR gene families suggests either an incomplete restoration of TCR diversity or an antigen-driven expansion of T cells in the lungs of BMT recipients with graft-versus-host disease, not necessarily related to pulmonary infection.

T cell receptor (TCR)-mediated repertoire selection and loss of TCR vbeta diversity during the initiation of a CD4(+) T cell response in vivo

We recently described a novel way to isolate populations of antigen-reactive CD4(+) T cells with a wide range of reactivity to a specific antigen, using immunization with a fixed dose of nominal antigen and FACS((R)) sorting by CD4(high) expression. Phenotypic, FACS((R)), functional, antibody inhibition, and major histocompatibility complex-peptide tetramer analyses, as well as T cell receptor Vbeta sequence analyses, of the antigen-specific CD4(high) T cell populations demonstrated that a diverse sperm whale myoglobin 110-121-reactive CD4(+) T cell repertoire was activated at the beginning (day 3 after immunization) of the immune response. Within 6 d of immunization, lower affinity clones were lost from the responding population, leaving an expanded population of oligoclonal, intermediate affinity (and residual high affinity) T cells. This T cell subset persisted for at least 4 wk after immunization and dominated the secondary immune response. These data provide evidence that CD4(+) T cell repertoire selection occurs early in the immune response in vivo and suggest that persistence and expansion of a population of oligoclonal, intermediate affinity T cells is involved in CD4(+) T cell memory.

Selective activation and expansion of high-affinity CD4+ T cells in resistant mice upon infection with Leishmania major

Using multimers of MHC class II molecules linked to a peptide derived from the Leishmania LACK antigen, we have compared the fate of parasite-specific CD4+ T cells in resistant and susceptible mice transgenic for the beta chain of a LACK-specific TCR. Activated T cells were readily detected in the draining lymph nodes of infected animals. Although the kinetics of activation and expansion were similar in both strains, T cells from susceptible and resistant mice expressed low- and high-affinity TCR, respectively. As T cells from resistant mice produced more IFN-gamma and less IL-4 than those from susceptible animals, our results suggest that differences in TCR usage between MHC-matched animals may influence the development of the antiparasite immune response.

Evolution of the T cell repertoire during primary, memory, and recall responses to viral infection

Many viral infections induce a broad repertoire of CD8(+) T cell responses that initiate recognition and elimination of infected cells by interaction of TCRs with viral peptides presented on infected cells by MHC class I proteins. Following clearance of the infection, >90% of activated CD8(+) T cells die, leaving behind a stable pool of memory CD8(+) T cells capable of responding to subsequent infections with enhanced kinetics. To probe the mechanisms involved in the generation of T cell memory, we compared primary, memory, and secondary challenge virus-specific T cell repertoires using a combination of costaining with MHC class I tetramers and a panel of anti-Vss Abs, as well as complementarity-determining region 3 length distribution analysis of TCR Vss transcripts from cells sorted according to tetramer binding. Following individual mice over time, we found identity between primary effector and memory TCR repertoires for each of three immunodominant epitopes from lymphocytic choriomeningitis virus. During secondary responses, we found quantitative changes in epitope-specific T cell hierarchies but little evidence for changes in Vss usage or complementarity-determining region 3 length distributions within epitope-specific populations. We conclude that 1) selection of memory T cell populations is stochastic and not determined by a distinct step of clonal selection necessary for survival from the acute responding population, and 2) maturation of the T cell repertoire during secondary lymphocytic choriomeningitis virus infection alters the relative magnitudes of epitope-specific responses but does not significantly modify the repertoire of T cells responding to a given epitope.

Visualizing T cell competition for peptide/MHC complexes: a specific mechanism to minimize the effect of precursor frequency

In vivo antigenic competition of naive CD4+ TCR transgenic T cells was visualized by tracking cell division. Competition reduced both recruitment into cell division and burst size per recruited precursor cell, minimizing the effect of differences in precursorfrequency while maintaining the dose-response relationship with antigen. Competition was restricted to T cells of the same specificity, indicating that cells were competing for access to Ag-MHC complexes rather than for Ag nonspecific factors. Moreover, the qualitative distinction between the responses to i.v. peptide and s.c. peptide/CFA was unaffected by precursor frequency. These data explain the paradoxical ability of the immune system to tailor responses to the type and dose of Ag even in individuals with large differences in initial precursor frequency.

Impact of negative selection on the T cell repertoire reactive to a self-peptide: a large fraction of T cell clones escapes clonal deletion

How negative selection shapes a polyclonal population of self-reactive T cells has been difficult to address directly because of the lack of means to isolate T cells reactive to a particular self-peptide. Here, using mice transgenic for the TCR-beta chain of a CTL clone directed against a male-specific peptide, we compared the preimmune repertoire reactive to this peptide in male and female animals. Surprisingly, in the presence of the deleting ligand, as many as 25%-40% of reactive T cells escaped clonal deletion. A correlation was found between T cell avidity, TCRalpha structures, and susceptibility to negative selection. These results suggest that numerous low-affinity self-specific T cells persist in the periphery and show that a deleting ligand can specifically narrow the structural diversity of the TCR repertoire.

Characterization at the single-cell level of naive and primed CD8 T cell cytokine responses

The aim of this study was to characterize differences between naive and primed CD8 T cells. Our results show that (i) naive and primed CD8 T cells display similar activation thresholds, with no direct evidence for a difference in their TCR signals, and (ii) primed cells differ mainly in their capacity to secrete IFN-gamma. A comparison of the two populations at the single-cell level demonstrated that the increased production of IFN-gamma by the primed cell subset is due to a larger proportion of single cells that are able to synthesize this cytokine early following activation. These results indicate that the intrinsic effector capabilities of individual CD8 T cells expressing the same TCR are heterogeneous and that cells with identical antigen specificity but increased effector capacities are generated or selected during the primary response.

Antigen-specific T helper cell function: differential cytokine expression in primary and memory responses

Distinguishing between the development of functional potential in antigen-specific T helper (Th) cells and the delivery of these specialized functions in vivo has been difficult to resolve. Here, we quantify the frequency of cytokine-producing cells within the primary and memory B10.BR Th cell response to pigeon cytochrome c (PCC). In vitro analysis of acquired functional potential indicated no Th1/Th2 cytokine polarity at the peak of the primary response with surprisingly little evidence for the selective preservation of interleukin (IL)-2, tumor necrosis factor (TNF)-alpha, IL-4, and interferon (IFN)-gamma potentials into the memory compartment. However, the expression of these functional potentials appears tightly regulated in vivo. The staggered appearance of primary response cytokines directly ex vivo contrasts markedly with their rapid coordinate expression in the memory response. Frequencies of IL-2-, TNF-alpha-, IFN-gamma-, and IL-10-expressing memory responders increased over their primary response counterparts, but were still markedly lower than revealed in vitro. IL-4-, IFN-gamma-, and IL-10-expressing Th cells remained at low but stable frequencies over the first 6 d of the memory response. Analysis of T cell receptor beta chain sequences of IL-4- and TNF-alpha-expressing PCC-specific Th cells provides evidence for early functional commitment among clonal progeny. These data indicate that the development of functional potential is a consequence of initial antigen experience, but delivery of specialized functions is differentially regulated in primary and memory immune responses.

Changing patterns of dominant TCR usage with maturation of an EBV-specific cytotoxic T cell response

Infection with EBV provides a unique opportunity to follow the human CD8(+) T cell response to a persistent, genetically stable agent from the primary phase, as seen in infectious mononucleosis (IM) patients, into long-term memory. This study focuses on the response to an immunodominant HLA-A2.01-restricted epitope, GLCTLVAML, from the EBV-lytic cycle Ag BMLF1. TCR analysis of the highly amplified primary response to this epitope revealed markedly oligoclonal receptor usage among in vitro-derived clones, with similar clonotypes dominant in all three IM patients studied. Direct staining of IM T cell preparations with the A2.01/GLCTLVAML tetramer linked this oligoclonal epitope-specific response with appropriate Vbeta subset expansions in the patients' blood. These patients were studied again >2 years later, at which time TCR analysis of in vitro-reactivated clones suggested that rare clonotypes within the primary response had now come to dominate memory. Five additional A2. 01-positive IM patients were studied prospectively for Vbeta subset representation within primary and memory epitope-specific populations as identified by tetramer staining. In each case, the primary response contained large Vbeta2, Vbeta16, or Vbeta22 components, and in three of five cases the originally dominant Vbeta was represented very poorly, if at all, in memory. We conclude 1) that an EBV epitope-specific primary response large enough to account for up to 10% CD8(+) T cells in IM blood may nevertheless be dominated by just a few highly expanded clonotypes, and 2) that with persistent viral challenge such dominant T cell clonotypes may be lost and replaced by others in memory.

CD8(+) T-cell selection, function, and death in the primary immune response in vivo

The primary immune response to Epstein Barr virus (EBV) is characterized by striking proliferation of EBV-specific CD8(+) T cells. In this study we have investigated the clonal composition and functional properties of the cells mediating this primary response and have analyzed the mechanisms that control the downregulation of the primary response and the selection of memory cells. We show that massively expanded T-cell clones often dominate the primary antigen-specific T-cell response. Despite the enormous extent of expansion, the virus-specific T cells express high levels of intracellular perforin and are potently cytotoxic. They are, however, functionally heterogeneous in their ability to secrete proinflammatory cytokines, with subpopulations of the antigen-specific T cells being hyporesponsive. The primary response is closely regulated, and the majority of cells are programmed to die via a cytokine-rescuable pathway, leaving only small populations of memory T cells surviving. Comparison of the clonal composition of primary and memory responses in vivo shows that the clones that dominate the primary response are relatively heavily culled during the downregulation of the primary response and the establishment of T-cell memory.

Lymphocytes rearrange, edit and revise their antigen receptors to be useful yet safe

Pamela Fink and Catherine McMahan discuss how B and T cells test for useful antigen receptors and weed out potentially harmful ones, with special attention paid to T-cell receptor revision, a newly described mechanism by which mature T cells can maintain self tolerance.

Regulating T helper cell immunity through antigen responsiveness and calcium entry

We evaluated changes in the signaling potentials and proliferative capacity of single antigen-specific T helper (TH) cells during a primary immune response to a protein antigen. At the peak of cellular expansion in vivo all antigen-specific TH cells exhibited a profound block in CD3- and CD4-mediated mobilization of intracellular calcium together with a more global block in T cell receptor-independent capacitative calcium entry (CCE). The proliferative response of these antigen-specific TH cells to anti-CD3, anti-CD28 and IL-2 was also severely blunted. Cross-linking CD69 on a substantial fraction of CD69+ antigen-specific TH cells relieved this block in CCE and restored proliferative capacity in vitro. The CCE rescue operated through a CD69-coupled G protein and required calcium-bound calmodulin and calcineurin. These data reveal critical changes in the responsiveness of antigen-specific TH cells and provide evidence of new mechanisms for the regulation of antigen-specific TH cell development in vivo.

Coupling CD28 co-stimulation to immunoglobulin T-cell receptor molecules: the dynamics of T-cell proliferation and death

Immunoglobulin T-cell receptor (IgTCR) molecules are potentially potent immune response modifiers because they allow T cells to bypass tolerance. Tolerance to self antigens has been one of the major barriers to the development of effective adoptive immunotherapies for treating cancer. In vitro studies in several laboratories have shown that cross-linking IgTCR molecules with the target antigen leads to cytolytic activity, cytokine release, and T-cell proliferation in model systems. However, many of these studies have used established T-cell lines rather than normal T cells or indirect assays of cytotoxicity, proliferation, and cytokine release. We have sought to establish the validity of these model systems while developing more effective adoptive immunotherapies using normal human T cells. In the present study the activation of T-cell proliferation after IgTCR cross-linking was evaluated. The results show that, in addition to IgTCR signals, CD28 costimulation is required to induce expansions of normal peripheral blood mononuclear cell-derived T cells. Signals from IgTCR alone can induce transient cell division, but they do not induce the prolonged polyclonal expansions that are characteristic of native immune responses. Very strong IgTCR signals could circumvent the CD28 requirement, but only at levels that are unlikely to be physiologically relevant. CD28 costimulation also suppressed the deletion of tumor-reactive subclones by activation-induced cell death. These studies confirm the importance of CD28 costimulation to the proliferation of IgTCR-modified human T cells, a key feature of an effective, reconstructed antitumor response.

Detection of autoreactive T cells in H-2u mice using peptide-MHC multimers

Myelin basic protein (MBP)-specific T cells play a critical role in the pathogenesis of experimental autoimmune encephalomyelitis (EAE), a prototype for T cell-mediated autoimmunity. In PL/J and B10.PL mice (H-2(u) haplotype), the immunodominant epitope of MBP is represented by an N-terminal nonameric peptide, MBP1-9. To date, the MBP1-9-specific T cell repertoire has not been analyzed in quantitative terms. In the present study we demonstrate, using MHC class II tetramers, that 15,000-70,000 self-antigen-specific T(h) cells accumulate in the draining lymph nodes following immunization with spinal cord homogenate or MBP1-9. In contrast, MBP1-9-specific T cells are undetectable in unimmunized H-2(u) mice and represent >60% of the CD4 cells in naive mice transgenic for a TCR specific for this epitope. The results suggest that the extremely low affinity of the N-terminal peptide for I-A(u) does not limit the MBP1-9-specific T cells from expanding into a sizeable pool of autoreactive T cells. Therefore, the primary immune response to MBP1-9 does not differ quantitatively from previously reported CD4(+) T cell responses to foreign antigens.

T cells compete for access to antigen-bearing antigen-presenting cells

These studies tested whether antigenic competition between T cells occurs. We generated CD8(+) T cell responses in H-2(b) mice against the dominant ovalbumin epitope SIINFEKL (ova8) and subdominant epitope KRVVFDKL, using either vaccinia virus expressing ovalbumin (VV-ova) or peptide-pulsed dendritic cells. CD8(+) T cell responses were visualized by major histocompatibility complex class I-peptide tetrameric molecules. Transfer of transgenic T cells with high affinity for ova8 (OT1 T cells) completely inhibited the response of host antigen-specific T cells to either antigen, demonstrating that T cells can directly compete with each other for response to antigen. OT1 cells also inhibited CD8(+) T cell responses to an unrelated peptide, SIYRYGGL, providing it was presented on the same dendritic cells as ova8. These inhibitions were not due to a more rapid clearance of virus or antigen-presenting cells (APCs) by the OT1 cells. Rather, the inhibition was caused by competition for antigen and antigen-bearing cells, since it could be overcome by the injection of large numbers of antigen-pulsed dendritic cells. These results imply that common properties of T cell responses, such as epitope dominance and secondary response affinity maturation, are the result of competitive interactions between antigen-bearing APC and T cell subsets.