An immunoregulatory function for the CD8 molecule

CD4-1 and CD8α T lymphocytes subsets in spotted sea bass (Lateolabrax maculatus) and comparison on antigenicity of T lymphocytes subsets in other three marine fish species

CD4 and CD8 molecules play an important role in the identification of T lymphocytes, and diverse among fish species. In this study, CD4-1 and CD8α gene of spotted sea bass (Lateolabrax maculatus) were cloned, polyclonal antibodies against CD4-1 (CD4-1 pAbs) and CD8α (CD8α pAbs) were produced, respectively. And the variations in CD4-1⁺ and CD8α⁺ T-lymphocytes in spotted sea bass and the cross-reactivity with leukocytes in pearl gentian grouper (Epinephelus fuscoguttatus x E. lanceolatus), schlegel's black rockfish (Sebastes schlegelii) and flounder (Paralichthys olivaceus) were investigated using CD4-1 pAbs and CD8α pAbs. The results showed that CD4-1 molecule ORF was 1413 bp and CD8α was 690 bp, both molecules are transmembrane glycoproteins with high amino acid homology to grouper. The CD4-1 pAbs specifically recognized both the CD4-1 recombinant and natural proteins, as does the CD8α pAbs to CD8α molecule, and no cross-reactivity between the two antibodies. CD4-1⁺ and CD8α⁺ T lymphocytes were detected in peripheral blood, spleen and head kidney leukocytes in spotted sea bass. In cross-reactivity assay with other three fish, CD4-1 pAbs could recognize the lymphocytes from pearl gentian grouper and schlegel's black rockfish, both with highest proportions in the spleen leukocytes, 5.3 ± 0.4% and 2.6 ± 0.3%, respectively, and CD8α pAbs could only recognize the lymphocytes in pearl gentian grouper, and no cross-reactivities to lymphocytes of flounder. These data suggested that the CD4-1 and CD8α molecules varied by fish species in the genes features and antigenicity, which might result in the diversities of T lymphocytes subpopulations. This will be a key to elucidating the classification and evolution of T lymphocytes in fish.

CD4+/CD8+ double-positive T cells: more than just a developmental stage?

CD4(+)/CD8(+) DP thymocytes are a well-described T cell developmental stage within the thymus. However, once differentiated, the CD4(+) lineage or the CD8(+) lineage is generally considered to be fixed. Nevertheless, mature CD4(+)/CD8(+) DP T cells have been described in the blood and peripheral lymphoid tissues of numerous species, as well as in numerous disease settings, including cancer. The expression of CD4 and CD8 is regulated by a very strict transcriptional program involving the transcription factors Runx3 and ThPOK. Initially thought to be mutually exclusive within CD4(+) and CD8(+) T cells, CD4(+)/CD8(+) T cell populations, outside of the thymus, have recently been described to express concurrently ThPOK and Runx3. Considerable heterogeneity exists within the CD4(+)/CD8(+) DP T cell pool, and the function of CD4(+)/CD8(+) T cell populations remains controversial, with conflicting reports describing cytotoxic or suppressive roles for these cells. In this review, we describe how transcriptional regulation, lineage of origin, heterogeneity of CD4 and CD8 expression, age, species, and specific disease settings influence the functionality of this rarely studied T cell population.

CTLA-4.FasL inhibits allogeneic responses in vivo

CTLA-4.Fas ligand (CTLA-4.FasL), a paradigmatic 'trans signal converter protein (TSCP)', can attach to APC (via CTLA-4 binding to B7) and direct intercellular inhibitory signals to responding T cells (via FasL binding to Fas receptor), converting an activating APC-to-T cell signal into an inhibitory one. Our previous studies established that CTLA-4.FasL inhibits human primary mixed lymphocyte reactions (MLR) and induces alloantigen-specific hyporesponsiveness ex vivo. The present study extends this to an in vivo context. Using splenocytes from MHC-mismatched C57BL/6 and Balb/c mice, we demonstrated that his(6)CTLA-4.FasL, effectively inhibits murine MLR. Moving in vivo, we demonstrated that subcutaneously administered his(6)CTLA-4.FasL modulates the in vivo response of infused allogeneic splenocytes. his(6)CTLA-4.FasL reduces the number of cells in each cell division, and increases the percentage of dead cells in each division. These findings are consistent with an antigen-induced cell death of the alloreactive cells, and bolsters recombinant TCSP promise as a therapeutic for transplantation diseases.

New designs for cancer vaccine and artificial veto cells: an emerging palette of protein paints

Antigen-presenting cells (APC) can be refaced with "protein paints" that change the appearance of their T cell-oriented trans signal arrays. Our group has developed three categories of protein paints suitable for this kind of APC engineering: artificial glycosylphosphatidylinositol (GPI) proteins, palmitated-protein A:Fc*1 fusion protein conjugates, and trans signal converter proteins. Protein paints have been devised with either immune enhancement or suppression in mind. Costimulator * GPI and palmitated-protein A costimulator * Fcgamma1 conjugates can be used to augment the immune-activating potential of tumor cells. Alternatively, protein paints can be designed to transform APC into artificial veto cells, in essence creating Trojan horses capable of inhibiting pathogenic T cells. Trans signal converter proteins (TSCP) have been devised for this purpose. Our first paradigmatic inhibitory TSCP, CTLA-4 * Fas ligand, binds to APC, and in so doing, simultaneously blocks B7 costimulation (via CTLA-4) and sends inhibitory trans signals (via Fas ligand) to T cells with dramatic efficacy. Protein transfer offers a number of advantages over gene transfer in facilitating quantitative and combinatorial protein expression and simplifying in vivo applications; the palette of protein paints with immunotherapeutic potential will undoubtedly continue to evolve.

CTLA-4. FasL induces alloantigen-specific hyporesponsiveness

The APC:T cell interface can be effectively targeted with immunotherapeutic proteins. We previously described a unique trans signal converter protein, CTLA-4. Fas ligand (FasL), that has the inherent capacities to tether the T cell inhibitor FasL (CD95 ligand) to the surfaces of B7 (CD80 and CD86)-positive APC (via CTLA-4:B7 interaction), and in so doing, to simultaneously interfere with B7-to-CD28 T cell activation signals. Given the continuing need for agents capable of inducing allograft tolerance without generalized immunosuppression, we have explored in depth the functional activity of CTLA-4. FasL in human allogeneic MLR. CTLA-4. FasL inhibits 1 degrees MLR and induces specific hyporesponsiveness in 2 degrees MLR, with both effects only partially reversible with exogenous IL-2. Moreover, the presence of exogenous IL-2 during the 1 degrees MLR does not affect the induction of hyporesponsiveness upon restimulation. Furthermore, CTLA-4. FasL enables partial activation of allostimulated T cells, reduces the fraction of actively dividing cells, and increases the percentage of dead cells among dividing T cells. Taken together, these findings suggest that CTLA-4. FasL-mediated inhibition of secondary alloantigenic responses involves both anergy induction and clonal deletion. Thus, CTLA-4. FasL, a paradigmatic trans signal converter protein, manifests unique functional properties and emerges as a potentially useful immunotherapeutic for modulating alloresponsiveness.

Tolerance induction by megadose hematopoietic progenitor cells: expansion of veto cells by short-term culture of purified human CD34(+) cells

Stem cell-dose escalation is one way to overcome immune rejection of incompatible stem cells. However, the number of hematopoietic precursors required for overcoming the immune barrier in recipients pretreated with sublethal regimens cannot be attained with the state-of-the-art technology for stem cell mobilization. This issue was addressed by the observation that cells within the human CD34(+) population are endowed with veto activity. In the current study, we demonstrated that it is possible to harvest about 28- to 80-fold more veto cells on culturing of purified CD34(+) cells for 7 to 12 days with an early-acting cytokine mixture including Flt3-ligand, stem cell factor, and thrombopoietin. Analysis of the expanded cells with fluorescence-activated cell-sorter scanning revealed that the predominant phenotype of CD34(+)CD33(-) cells used at the initiation of the culture was replaced at the end of the culture by cells expressing early myeloid phenotypes such as CD34(+)CD33(+) and CD34(-)CD33(+). These maturation events were associated with a significant gain in veto activity as exemplified by the minimal ratio of veto to effector cells at which significant veto activity was detected. Thus, whereas purified unexpanded CD34(+) cells exhibited veto activity at a veto-to-effector cell ratio of 0.5, the expanded cells attained an equivalent activity at a ratio of 0.125. The availability of novel sources of veto cells such as those in this study might contribute to the realization of immunologic tolerance in "minitransplants," without any risk of graft-versus-host disease.

Donor T cells are not required for induction of allograft tolerance in mice treated with antilymphocyte serum, rapamycin, and donor bone marrow cells

BACKGROUND

Postgraft infusion of donor bone marrow cells (BMC) effectively induces tolerance to skin allografts in antilymphocyte serum- and rapamycin-treated recipients in fully major histocompatibility complex-mismatched mouse strain combinations. We used various gene knockout mice to examine the role of donor T cells and B cells in BMC-induced allograft tolerance.

METHODS

All recipient mice received ALS on days -1 and 2 and rapamycin (6 mg/kg) on day 7 relative to fully major histocompatibility complex-mismatched skin grafting on day 0. Donor BMC prepared either from mice lacking CD4- and/or CD8a-, or CD3epsilon-expressing cells or B cells, or from corresponding wildtype mice, were given on day 7. The level and phenotypes of chimerism was determined by flow cytometry.

RESULTS

All T cell- and B cell-deficient BMC were as effective as wild-type BMC in inducing prolongation of skin graft survival. A low degree of chimerism without donor type T cells was detected in tolerant mice given T cell-deficient BMC or wild-type BMC 60 days after transplantation. Chimeric cells were composed of B cells and macrophages/monocytes. Low level chimerism without donor T or B cells was also present in tolerant mice given B cell-deficient BMC.

CONCLUSION

Donor type T cells and T cell chimerism are not required for induction of allograft tolerance by the antilymphocyte serum/rapamycin/donor BMC-infusion protocol. Donor B cells also do not participate in tolerance induction. Thus, infusion of T cell-depleted BMC in conjunction with conventional immunosuppressive regimens will be a simple, safe, and effective way to induce allograft tolerance in clinical organ transplantation.

A differential requirement for CD8+ donor cells in the augmentation of allograft survival by posttransplantation administration of donor spleen cells and donor bone marrow cells

BACKGROUND

Peritransplant treatment with antithymocyte serum (ATS) and posttransplantation administration of donor bone marrow or donor splenocytes results in extended skin allograft survival. In this study, we examined the molecular basis of the tolerance promoting effect of donor bone marrow (BMC) cells and splenocytes with emphasis on the role of CD8 expression on the donor cells.

METHODS

(C57BL/6J x A/J)F1 mice were treated on days -1 and +2 with ATS relative to transplantation with C3H/HeJ skin. On day +7, they were infused with CD8+ BMC, CD8- BMC, CD8+ splenocytes, or CD8- splenocyte donor subpopulations isolated by magnetic or fluorescence-based sorting. In additional experiments, B10.D2(R107) mice were treated in the same manner with C57BL/6 skin and BMC or splenocytes from C57BL/6 mice in which the CD8alpha gene had been inactivated.

RESULTS

CD8+ donor bone marrow cells induced operational tolerance (defined as graft acceptance in the absence of chronic immunosuppression) in skin graft recipients at a dose that was reduced by 250-fold relative to unfractionated bone marrow cells (1.0x10(5) cells per recipient, median survival time (MST)=41 days vs. 2.5x10(7) cells per recipient, MST=49 days, P=0.40). Similarly, donor bone marrow cells from CD8 knockout mice did not promote graft acceptance (MST=98 days vs. animals not treated with bone marrow cells, MST=70 days, P=0.16). In contrast, the extension of graft survival by donor splenocytes did not require the presence of CD8+ donor cells because splenocytes depleted of CD8+ cells extended graft survival (MST=55 days) as well as unsorted splenocytes (44 days, P=0.2), and splenocytes from CD8 knockout animals (MST=145 days) extended graft survival at least as well as unsorted splenocytes (MST=74 days, P=0.4)

CONCLUSIONS

These results suggest that the prolongation of graft survival by donor bone marrow is dependent on the presence of the CD8 molecule, whereas prolongation by donor splenocytes is not. Therefore, we suggest that the prolongation of graft survival by these cell types occurs via distinct molecular mechanisms probably mediated by different cell types.

Donor MHC class II antigen is essential for induction of transplantation tolerance by bone marrow cells

Posttransplant infusion of donor bone marrow cells (BMC) induces tolerance to allografts in adult mice, dogs, nonhuman primates, and probably humans. Here we used a mouse skin allograft model and an allogeneic radiation chimera model to examine the role of MHC Ags in tolerance induction. Infusion of MHC class II Ag-deficient (CIID) BMC failed to prolong C57BL/6 (B6) skin grafts in ALS- and rapamycin-treated B10.A mice, whereas wild-type B6 or MHC class I Ag-deficient BMC induced prolongation. Removal of class II Ag-bearing cells from donor BMC markedly reduced the tolerogenic effect compared with untreated BMC, although graft survival was significantly longer in mice given depleted BMC than that in control mice given no BMC. Infusion of CIID BMC into irradiated syngeneic B6 or allogeneic B10.A mice produced normal lymphoid cell reconstitution including CD4+ T cells except for the absence of class II Ag-positive cells. However, irradiated B10.A mice reconstituted with CIID BMC rejected all B6 and a majority of CIID skin grafts despite continued maintenance of high degree chimerism. B10.A mice reconstituted with B6 BMC maintained chimerism and accepted both B6 and CIID skin grafts. Thus, expression of MHC class II Ag on BMC is essential for allograft tolerance induction and peripheral chimerism with cells deficient in class II Ag does not guarantee allograft acceptance.

Signal transduction by the major histocompatibility complex class I molecule

Ligation of cell surface major histocompatibility class I (MHC-I) proteins by antibodies, or by their native counter receptor, the CD8 molecule, mediates transduction of signals into the cells. MHC-I-mediated signaling can lead to both increased and decreased activity of the MHC-I-expressing cell depending on the fine specificity of the anti-MHC-I antibodies, the context of CD8 ligation, the nature and cell cycle state of the MHC-I-expressing cell and the presence or absence of additional cellular or humoral stimulation. This paper reviews the biochemical, physiological and cellular events immediately after and at later intervals following MHC-I ligation. It is hypothesized that MHC-I expression, both ontogenically and in evolution, is driven by a cell-mediated selection pressure advantageous to the MHC-I-expressing cell. Accordingly, in addition to their role in T-cell selection and functioning, MHC-I molecules might be of importance for the maintenance of cellular homeostasis not only within the immune system, but also in the interplay between the immune system and other organ systems.

Treatment of an autoimmune disease with "classical" T cell veto: a proposal

Immune responses protect against infectious diseases and cancers. In normal circumstances, the immune system is tolerant to self. However, under certain conditions this tolerance is broken. The immune system attacks otherwise normal tissue. An autoimmune disease ensues. Strategies are now being sought that remove the pathogenic T cells without affecting other immune functions. "Classical" veto has been described as an immune suppressive mechanism able to remove T cells in a highly specific and effective manner. The present article briefly reviews the current knowledge on the development of autoreactive T cells and their regulation in the periphery. It describes "classical" veto, its mechanisms, and its novel applications. Finally, it argues that "classical" veto can be adapted to treat an autoimmune disease, such as type I diabetes mellitus.

Immunoregulatory role of CD8alpha in the veto effect

BACKGROUND

Allogeneic bone marrow cell (allo-BMC) infusion induces tolerance to incompatible renal allografts in rhesus macaques after depletion of peripheral T lymphocytes with cytolytic anti-T cell antibodies. The tolerogenic effect of allo-BMC, ascribed to a veto mechanism, associates with specific functional deletion of antidonor cytotoxic T lymphocyte precursor (CTLp), and is dependent on a CD8+ donor BMC subset. In previous studies, the CD8 molecule was implicated by loss of suppression after blocking interaction between CD8 on allo-BMC and major histocompatibility complex class Ialpha3 domain on CTLp. CD8 cross-linking on BMC induced secretion of active transforming growth factor-beta1 (TGF-beta1), suggesting a regulatory mechanism(s) operating via a CD8-mediated signaling pathway.

METHODS

CD8 on rhesus cells was cross-linked using IgG-conjugated beads, and TGF-beta1 mRNA and protein were quantified. CD8+ cells were tested for veto activity by mixed lymphocyte reaction (MLR)-induced cell-mediated lymphocytotoxicity (CML) assay. Activated rhesus T cells exposed to TGF-beta1 were examined for apoptosis by TdT-mediated end-labeling and annexin staining.

RESULTS

CD8 cross-linking induces accumulation of TGF-beta1 mRNA and protein. Both CD3- CD8+CD16+ and CD3+ CD8+CD16- subsets of allo-BMC up-regulate TGF-beta1 mRNA after CD8 cross-linking, and exhibit veto activity. The CD3-CD8+CD16+ subset expresses more TGF-beta1 mRNA and increased veto activity at low BMC/CTLp ratios. Exposure of activated T cells to TGF-beta1 induces apoptosis.

CONCLUSIONS

CD8+ allo-BMC are enriched for veto activity and activation via CD8 induces TGF-beta1 mRNA and protein accumulation. These results agree with the hypothesis that paracrine TGF-beta1 may be involved in peripheral deletion of alloreactive CTLp by CD8+ allo-BMC. We suggest that TGF-beta1 overexpression by donor lymphohematopoietic cells may enhance tolerance induction.

Inhibition of cytotoxic alloreactivity by human allogeneic mononuclear cells: evidence for veto function of CD2+ cells

In animal models of organ transplantation, infusion of donor-derived leucocytes or bone marrow cells can support tolerance induction. To date, little is known about the suppressive effects of human allogeneic mononuclear cells on alloreactivity in the human system. To study this, mixed leucocyte cultures (MLC) were incubated in the presence and absence of viable allogeneic mononuclear cells (MNC) (modulator cells) of stimulator/donor origin, and the cytotoxic and proliferative potential of the resulting effector cells was determined. The experiments showed that: viable allogeneic MNC from bone marrow and from lymph nodes and peripheral blood (PBMC) were able to suppress allospecific cytotoxicity by an average of 60%; that allospecific as well as non-specific inhibitory effects could be observed with unseparated PBMC; that CD2+ PMNC showed predominantly allospecific inhibition of cytotoxicity with little effect on proliferation whereas CD2- PBMC showed non-specific inhibitory effects (both for cytotoxicity and proliferation), which could be eliminated by indomethacin; that addition of interleukin-2 (IL-2) up to 50 U/ml to the MLC could not reverse the inhibitory effect; and that selective removal of CD8+ cells from the CD2+ modulator population diminished the specific inhibitory effect only partially. These findings demonstrate that viable human MNC from different compartments can have a marked suppressive effect on alloreactivity in vitro. For peripheral blood mononuclear cells (PBMC) the data suggest that various mechanisms can contribute to allosuppression, including specific suppressive veto effects by CD2+ cells. Such inhibitory effects might be applicable in vivo for down-regulating allospecific cytotoxicity and to facilitate the acceptance of allografts.

Monoclonal antibody to the HLA class I alpha 3 domain inhibits T cell activation and prolongs cardiac allograft survival in HLA-transgenic mice

Antibodies recognizing MHC class I molecules expressed on the surface of T cells have been shown to inhibit T cell responses in vitro. These findings suggested that therapy with such an antibody may prevent rejection and promote graft acceptance. We therefore tested the effect of an anti-HLA class I alpha 3 domain antibody (TP25.99) in vivo using transgenic C57BL/6 mice expressing HLA-B2705. Flow cytometric analysis confirmed the binding of TP25.99 to normal human peripheral blood lymphocytes and to mouse spleen cells, bone marrow cells and thymocytes isolated from hemizygous (+/-) transgenic littermates but not from homozygous (-/-) littermates. TP25.99 inhibited OKT-3-induced, but not PMA+ionomycin-induced, proliferation of human peripheral blood lymphocyte as well as anti-CD3 or Con A-induced proliferation of HLA+ mouse T cells. Both intact monoclonal antibody TP25.99 and TP25.99 Fab inhibited T cell proliferation. Reduced proliferation was associated with suppressed production of interleukin-2 as measured by ELISA. The efficacy of TP25.99 Fab in vivo was evaluated in a heart allograft model. Antibody therapy of (H-2h, B2705+) transgenic recipients of allogeneic Balb/c (H-2d) heart grafts prolonged graft survival significantly (MST = 19.8 +/- 6.4, p = 0.003) compared to treated (H-2b, B2705-) (MST = 9.17 +/- 2.2) or untreated (H-2b, B2705+) (MST = 10.0 +/- 2.8) transgenic recipients. This demonstrates that immunomodulation through anti-HLA class I antibody therapy can lead to prolongation of graft survival.

Soluble CD8 and ICAM-1 in serum and CSF of MS patients treated with 6-methylprednisolone

OBJECTIVE

We studied the effects of large doses of 6-methylprednisolone (6-MP) on serum and cerebrospinal fluid (CSF) soluble CD8 (sCD8) and intercellular adhesion molecule-1 (sICAM-1) levels in clinically active multiple sclerosis (MS) patients.

MATERIAL AND METHODS

Paired serum and CSF samples were from 16 patients with definite MS, treated with 6-MP (1 g daily for 6 d) during an active phase of the disease. sCD8 and sICAM-1 levels were determined with ELISA before and after the therapy.

RESULTS

Before 6-MP treatment, sCD8 levels in CSF were higher in MS patients than in patients with noninflammatory neurological disease and in healthy controls; sICAM-1 levels in serum and in CSF were higher in MS patients than in the two control groups. Ten of the 16 patients showed clinical improvement at the end of the treatment. After the therapy, serum and CSF sCD8 levels increased, whereas serum and CSF sICAM-1 levels decreased. There was no correlation between clinical improvement and laboratory parameters. We evaluated sCD8 and sICAM-1 in serum samples from 10 patients 6 months after the 6-MP treatment, when the disease was clinically silent. Neither sCD8 nor sICAM-1 levels differed from those of the control groups.

CONCLUSIONS

Our results suggest that high doses of 6-MP can influence serum and CSF sCD8 and sICAM-1 levels in active MS. At least part of the efficacy of corticosteroid treatment in MS might be ascribed to its effect both on the suppressive circuits of immune response, and on the expression of an adhesion molecule that favours lymphocyte trafficking across the blood-brain barrier.

AKR.H-2b lymphocytes inhibit the secondary in vitro cytotoxic T-lymphocyte response of primed responder cells to AKR/Gross murine leukemia virus-induced tumor cell stimulation

We have previously shown that AKR.H-2b congenic mice, though carrying the responder H-2b major histocompatibility complex haplotype, are unable to generate secondary cytolytic T-lymphocyte (CTL) responses specific for AKR/Gross murine leukemia virus (MuLV). Our published work has shown that this nonresponsive state is specific and not due to clonal deletion or irreversible functional inactivation of antiviral CTL precursors. In the present study, an alternative mechanism based on the presence of inhibitory AKR.H-2b cells was examined. Irradiated or mitomycin C-treated AKR.H-2b spleen cells function as in vitro stimulator cells in the generation of C57BL/6 (B6) anti-AKR/Gross virus CTL, consistent with their expression of viral antigens. In contrast, untreated viable AKR.H-2b spleen cells functioned very poorly as stimulators in vitro. Viable AKR.H-2b spleen cells were also able to cause dramatic (up to > or = 25-fold) inhibition of antiviral CTL responses stimulated in vitro by standard AKR/Gross MuLV-induced tumor cells. This inhibition was specific: AKR.H-2b modulator spleen cells did not inhibit allogeneic major histocompatibility complex-specific CTL production, even when a concurrent antiviral CTL response in the same culture well was inhibited by the modulator cells. These results and those of experiments in which either semipermeable membranes were used to separate AKR.H-2b modulator spleen cells from AKR/Gross MuLV-primed responder cells or the direct transfer of supernatants from wells where inhibition was demonstrated to wells where there was antiviral CTL responsiveness argued against a role for soluble factors as the cause of the inhibition. Rather, the inhibition was dependent on direct contact of AKR.H-2b cells in a dose-dependent manner with the responder cell population. Inhibition was shown not to be due to the ability of AKR.H-2b cells to function as unlabeled competitive target cells. Exogenous interleukin-2 added at the onset of the in vitro CTL-generating cultures partially restored the antiviral response that was decreased by AKR.H-2b spleen cells. Positive and negative cell selection studies and the development of inhibitory cell lines indicated that B lymphocytes and both CD4- CD8+ and CD4+ CD8- T lymphocytes from AKR.H-2b mice could inhibit the generation of AKR/Gross virus-specific CTL in vitro. AKR.H-2b macrophages were shown not to be required to demonstrate AKR/Gross MuLV-specific inhibition, however, confirming that the inhibition by T-cell (or B-cell)-depleted spleen populations was dependent on the enriched B-cell (T-cell) population per se.(ABSTRACT TRUNCATED AT 250 WORDS)

Nonresponsiveness of AKR.H-2b congenic mice for anti-AKR/Gross MuLV CTL responses: involvement of inhibitory cells as defined by adoptive transfer experiments

AKR.H-2b mice are unable to elicit AKR/Gross murine leukemia virus (MuLV)-specific cytolytic T lymphocyte (CTL) responses. The participation of inhibitory cells was addressed through adoptive transfer experiments utilizing young AKR.H-2b:Fv-1b congenic responder mice as the recipients of AKR.H-2b donor cells. The adoptive transfer of unfractionated viable splenocytes led to inhibition of virus-specific CTL responsiveness without affecting minor histocompatibility or allogeneic (H-2d)-specific CTL responses. Negative cell selection studies indicated that of the donor AKR.H-2b spleen cells that mediate specific inhibition, B lymphocytes, CD4-CD8+ and CD4+CD8- T lymphocytes, but not macrophages, even though they are viral antigen positive (as are B and T lymphocytes), were the cells responsible for the diminution of the generation of AKR/Gross virus-specific CTL by AKR.H-2b:Fv-1b mice. To evoke maximal inhibition, the adoptive transfer of AKR.H-2b cells had to be performed prior to in vivo priming with viral antigen. Anti-AKR/Gross MuLV nonresponsiveness of AKR.H-2b mice could not be overcome through utilization of exogenous IL-2 at either the priming or in vitro restimulation phases of CTL generation. These results illustrate the complex interaction between retroviruses and lymphocytes and are relevant to understanding how retrovirus-infected cells may not only escape immune surveillance themselves, but also may inhibit the cytolytic T cell response directed at other infected cells, such as tumor cells.

CD8 and beta 2-microglobulin-free MHC class I molecules in T cell immunoregulation

Intracellular assembly of MHC class I heavy chains with beta 2-microglobulin occurs prior to the expression of the antigen-presenting complex on the cell surface. The association of beta 2-microglobulin with newly synthesized class I heavy chains is thought to be a strict prerequisite for their transport to the cell surface. However, MHC class I molecules not associated with beta 2-microglobulin (beta 2-microglobulin-free class I heavy chains) have been detected on the surface of activated lymphoid cells. These molecules have different conformations. Therefore, their interactions with other membrane proteins and biological functions may be different from those assigned to beta 2-microglobulin-associated MHC class I molecules. The two forms of MHC class I molecules on the surface of activated cells can self-associate and also form complexes with distinct proteins. Upon interaction with the appropriate ligands these molecular complexes transduce signals regulating cell activation. The ligand for beta 2-microglobulin-free class I heavy chains appears to be soluble CD8. A model is presented describing a novel mechanism of immunoregulation mediated by both soluble and membrane-bound forms of CD8 and beta 2-microglobulin-free class I heavy chains.

Clone-specific T cell receptor antagonists of major histocompatibility complex class I-restricted cytotoxic T cells

A previous report showed that the proliferative response of helper T cells to class II major histocompatibility complex (MHC)-restricted antigens can be inhibited by analogues of the antigen, which act as T cell receptor (TCR) antagonists. Here we define and analyze peptide variants that antagonize various functions of class I MHC-restricted cytotoxic T lymphocyte (CTL) clones. Of 64 variants at individual TCR contact sites of the Kb-restricted octamer peptide ovalbumin257-264 (OVAp), a very high proportion (40%) antagonized lysis by three OVAp-specific CTL clones. This effect was highly clone specific, since many antagonists for one T cell clone have differential effects on another. We show that this inhibition of CTL function is not a result of T cell-T cell interaction, precluding veto-like phenomena as a mechanism for antagonism. Moreover, we present evidence for direct interaction between the TCR and antagonist-MHC complexes. In further analysis of the T cell response, we found that serine esterase release and cytokine production are susceptible to TCR antagonism similarly to lysis. Ca2+ flux, an early event in signaling, is also inhibited by antagonists but may be more resistant to the antagonist effect than downstream responses.

MHC-specific graft-protective and delayed-type hypersensitivity (DTH) suppressive activity of a CD4+ CD8+, alpha beta T cell receptor (TCR) positive lymphoma isolated from a tolerant mouse

Two lymphomas were found in, and isolated from A (H-2a) mice in which permanent transplantation tolerance was induced to CBA (H-2k) histocompatibility antigens by the neonatal injection of (CBAxA)F1 spleen cells. They proved to be of recipient origin and were transferable to syngeneic A mice, growing as disseminated lymphomas (L33 and L46) and killing the recipients rapidly. Analysis of the cell surface antigens disclosed that both lymphomas had an immature T cell phenotype [Thy-1+, CD5+, CD3low, TCR alpha beta low, CD4low, CD8high, heat-stable antigen (HSA) positive, and CD44-, MHC class II-, CD45R-, sIg-, Gr-1-, CD11b-]. Intraperitoneal (i.p.) injection of syngeneic A mice with viable L33 lymphoma cells resulted in a dose-dependent, significant prolongation of the mean survival times of "specific" CBA and MHC-identical B10.BR skin allografts as compared to the survival of appropriate grafts in non-lymphoma-bearing controls. The survival times of third party MHC-incompatible B10 (H-2b) and B10.D2 (H-2d) allografts were only slightly prolonged in A mice inoculated with L33 cells. The graft-protective effect was not abrogated if the proliferative capacity of the L33 cells was blocked by in vitro mitomycin C (MMC) pretreatment. Furthermore, the inoculation of L33 lymphoma into A mice significantly inhibited their DTH response to the sensitizing CBA histocompatibility antigens. In contrast, the L46 lymphoma had no effect on the survival of CBA allografts and the DTH reactivity. These data suggest that the CD4+CD8+TCR alpha beta + L33 T cell lymphoma originating from a neonatally tolerant mouse has a specific immunosuppressive effect on the in vivo reactivity of syngeneic mice to the tolerance-inducing (MHC class I) alloantigens.

Selective generation of CD8+ T-cell clones from the peripheral blood of patients with cutaneous reactions to beta-lactam antibiotics

The presence, phenotype, and functional characteristics of peripheral blood penicillin-specific T lymphocytes in individuals with cutaneous allergic reactions to penicillin were investigated using in vitro long-term culture techniques. Peripheral blood mononuclear cells from two penicillin-allergic patients were stimulated in vitro with penicillin, and T-cell blasts were clonally expanded by limiting dilution. Seven T-cell clones were derived, all of which were CD3+ CD4- CD8+ HLA-DR+, and produced IL-2 and IFN-gamma upon stimulation. T-cell proliferation required the presence of antigen and autologous, but not allogeneic, antigen-presenting cells. In addition to the parent compound, the T-cell clones also developed a proliferative response to penicilloyl, the major metabolite of penicillin. The cloned T-cell lines were found to exhibit marked suppressor activity for Con A mitogenesis. The observed suppressor activity required cell-to-cell contact, as supernatants from these T-cell clones had no comparable inhibitory effect. These findings indicate that there is a predominance of penicillin-specific CD8+ T cells in the peripheral blood of individuals sensitized to beta-lactam antibiotics.

Engagement of class I major histocompatibility complex molecules by cell surface CD8 delivers an activation signal

Recent evidence has demonstrated that cross-linking class I major histocompatibility complex (MHC) molecules on human T cells with monoclonal antibodies (mAb) triggers T cell activation. The only known natural ligand for MHC class I molecules is CD8. Therefore, the possibility that CD8+ T cells might provide activation signals to other T cells by engaging MHC class I molecules was examined by culturing CD4+ peripheral blood T cells with Chinese hamster ovary cells (CHO) cells that had been transfected with the alpha chain or alpha and beta chains of CD8 and assessing interleukin (IL)-2 production. CD4+ T cells did not secrete IL-2 when cultured alone, with control or CD8+ CHO cells. In contrast, CD4+ T cells produced IL-2 when cultured with CD8+ CHO cells and co-stimulated with phorbol myristate acetate (PMA) or mAb to CD3 or CD28. PMA stimulated substantially less IL-2 when control CHO cells were employed and the mAb to CD3 and CD28 did not stimulate IL-2 production in the presence of control CHO cells. The co-stimulatory activity of CD8+ CHO cells was completely eliminated by mAb to CD8 or MHC class I molecules. The data demonstrate that CD8 can interact with MHC class I molecules expressed on T cells and deliver a costimulatory signal that increases IL-2 production. Thus, engagement of MHC class I molecules by its natural ligand, CD8, provides an activation signal to T cells. Under some circumstances, such interactions may amplify the responses of T cells.

Programmed cell death of T cells signaled by the T cell receptor and the alpha 3 domain of class I MHC

As well as being activated or rendered unresponsive, mature T lymphocytes can be deleted, depending on the signals received by the cell. Deletion by programmed cell death (apoptosis) is triggered if a T cell that has received a signal through its T cell receptor complex also receives a signal through the alpha 3 domain of its class I major histocompatibility complex (MHC) molecule. Such a signal can be delivered by a CD8 molecule, which recognizes the alpha 3 domain, or by an antibody to this domain. Precursors of both cytotoxic T lymphocytes (CTL's) and T helper cells are sensitive to this signal but become resistant at some point before completing differentiation into functioning CTL's or T helper cells. Because CTL's carry CD8, they can induce cell death in T cells that recognize them. This pathway may be important in both removal of autoreactive T cells and immunoregulation.