Induction of differential T-cell epitope by plain- and liposome-coupled antigen

The T-cell receptors of CD4(+) T lymphocytes recognize immunogenic peptide sequences bound within the groove of MHC class II molecules, and the peptides that bind to these molecules are known to share common structural motifs. For example, OVA(323-339), an I-A(d)-binding peptide, involves a motif of the I-A(d) peptide-binding groove. In the present study, OVA peptides of up to 26-mer were sequentially synthesized and screened, and two additional I-A(d) binding OVA peptides, OVA(20-43) and OVA(264-286), were found to stimulate CD4(+) T cells of OVA-immune BALB/c mice. OVA(20-43) involved structural motifs of the I-A(d) peptide-binding groove, while OVA(264-286) did not. The ability of these three I-A(d) binding OVA peptides to induce antigen-specific cytokine production was compared among CD4(+) T cells of mice immunized either with alum-adsorbed OVA (OVA-alum) or OVA chemically coupled to the surface of liposome (OVA-liposome). CD4(+) T cells of mice immunized with OVA-alum produced more cytokines when stimulated with OVA(264-286) than with OVA(323-339), while CD4(+) T cells of mice immunized with OVA-liposome conjugates produced more cytokines when stimulated with OVA(323-339) than with OVA(264-286). OVA(20-43) induced production of comparable levels of cytokines in mice immunized either with OVA-alum or OVA-liposome. Confocal laser scanning microscopic analysis demonstrated that chemically coupled OVA and liposomes were colocalized in APCs until OVA received processing. Three-dimensional structural analysis demonstrated that both OVA(264-286) and OVA(323-339) were present on the surface of OVA, but OVA(20-43) was not. These results suggested that the chemical coupling of OVA to liposome affected antigen processing in APCs and thus resulted in the induction of differential T-cell epitopes as compared with those induced by plain OVA.     

DO11.10 and OT-II T cells recognize a C-terminal ovalbumin 323-339 epitope

The OVA323-339 epitope recognized by DO11.10 (H-2d) and OT-II (H-2b) T cells was investigated using amino- and carboxy-terminal truncations to locate the approximate ends of the epitopes and single amino acid substitutions of OVA323-339 to identify critical TCR contact residues of the OVA323-339 peptide. DO11.10 and OT-II T cells are both specific for a C-terminal epitope whose core encompasses amino acids 329-337. Amino acid 333 was identified as the primary TCR contact residue for both cells, and amino acid 331 was found to be an important secondary TCR contact residue; however, the importance of other secondary TCR contact residues and peptide flanking residues differ between the cells. Additional OVA323-339-specific clones were generated that recognized epitopes found in the N-terminal end or in the center of the peptide. These findings indicate that OVA323-339 can be presented by I-Ad in at least three binding registers. This study highlights some of the complexities of peptide Ags such as OVA323-339, which contain a nested set of overlapping T cell epitopes and MHC binding registers.     

Polarized uterine epithelial cells preferentially present antigen at the basolateral surface: role of stromal cells in regulating class II-mediated epithelial cell antigen presentation

To study Ag presentation in the female reproductive tract, DO11.10 TCR transgenic mice specific for the class II MHC-restricted OVA(323-339) peptide and non-transgenic BALB/c mice were used. We report here that freshly isolated uterine epithelial cells, uterine stromal, and vaginal APCs present OVA and OVA(323-339) peptide to naive- and memory T cells, which is reduced when cells are incubated with Abs to CD80 and 86. To determine whether polarized primary epithelial cells present Ags, uterine epithelial cells were cultured on cell inserts in either the upright or inverted position. After reaching confluence, as indicated by high transepithelial resistance (>2000 ohms/well), Ag presentation by epithelial cells incubated with memory T cells and OVA(323-339) peptide placed on the basolateral surface (inverted) was 2- to 3-fold greater than that seen with epithelial cells in contact with T cells and peptide on the apical surface (upright). In contrast, whereas freshly isolated epithelial cells process OVA, polarized epithelial cells did not. When epithelial cells grown upright on inserts were incubated with T cells and OVA(323-339) peptide, coculture with either hepatocyte growth factor or conditioned stromal medium increased epithelial cell Ag presentation (approximately 90% higher than controls). These studies indicate that uterine stromal cells produce a soluble factor(s) in addition to a hepatocyte growth factor, which regulates epithelial cell Ag presentation. Overall, these results demonstrate that polarized epithelial cells are able to present Ags and suggest that uterine stromal cells communicate with epithelial cells via a soluble factor(s) to regulate Ag presentation in the uterus.     

Role of CTLA-4 in the activation of single- and double-positive thymocytes

CTLA-4, a homologue of CD28, is a negative regulator of T cell activation in the periphery and is transiently expressed on the cell surface after T cell activation. However, the role of CTLA-4 in T cell activation in the thymus is not clear. This investigation was initiated to determine the role of CTLA-4 in the activation of CD4(+)CD8(+) double-positive (DP) and CD4(+)CD8(-) and CD4(-)CD8(+) single-positive (SP) thymocytes using fetal thymic organ cultures (FTOC) of MHC class II-restricted, OVA(323-339)-restricted TCR transgenic mice (DO11.10). We found that treatment of the FTOC with anti-CTLA-4-blocking Ab during activation with OVA(323-339) increased the proportion and number of DP thymocytes, but decreased the proportion and number of SP thymocytes compared with OVA(323-339)-stimulated FTOC without anti-CTLA-4 Ab treatment. In addition, anti-CTLA-4 Ab treatment inhibited OVA(323-339)-induced expression of the early activation marker, CD69, in DP thymocytes, but increased CD69 in SP thymocytes. Similarly, CTLA-4 blockage decreased phosphorylation of ERK in DP thymocytes by Ag-specific TCR engagement, but increased phosphorylation of ERK in SP thymocytes. CTLA-4 blockage inhibited deletion of DP thymocytes treated with a high dose of OVA(323-339), whereas CTLA-4 blockage did not inhibit deletion of DP thymocytes treated with a low dose of OVA(323-339). We conclude that CTLA-4 positively regulates the activation of DP thymocytes, resulting in their deletion, whereas blocking CTLA-4 suppresses the activation of DP thymocytes, leading to inhibition of DP thymocyte deletion. In contrast, CTLA-4 negatively regulates the activation of SP thymocytes.     

Detection of antigen-specific T cells in experimental immune-mediated blepharoconjunctivitis in DO11.10 T cell receptor transgenic mice

Antigen (Ag)-specific T cells are thought to play a key role in pathogenesis of chronic allergic conjunctivitis (AC) such as atopic keratoconjunctivitis (AKC) and vernal keratoconjunctivitis (VKC). In order to investigate the trafficking of Ag-specific T cells in experimental immune-mediated blepharoconjunctivitis (EC), we established a novel AC model in DO11.10 T cell receptor (TcR) transgenic (Tg) mice. DO11.10 TcR-Tg mice were challenged with eye drops of whole OVA protein, OVA peptide 1-15, 321-335, or 323-339. Their eyes were histologically examined. Conventional proliferation assay was performed against each Ag. Phenotypes of infiltrating cells and kinetics of Ag-specific T cells were investigated by immunohistochemistry. Adoptive transfer of CD4(+) Ag-specific T cells from DO11.10 TcR-Tg to WT mice was performed. The distribution of KJ1-26(+) cells was investigated in recipient mice. The challenge of OVA peptide 323-339 induced infiltration of inflammatory cells in conjunctivae in a dose dependent manner, accompanied by the proliferative responses of splenocytes. Immunohistochemical analysis revealed Agspecific/ non-Ag-specific T cells, macrophages, and eosinophils in conjunctivae. Infiltration of Ag-specific T cells increased 24 hr later. Transfer of CD4(+) cells from DO11.10 TcR-Tg to WT mice induced EC depending on the number of transferred cells. Ag-specific T cells were detected in the conjunctivae and spleens of recipient mice, though its numbers were significantly smaller compared to DO11.10 TcR-Tg mice. The challenge of OVA peptide 323-339 induced EC in DO11.10 TcR-Tg mice without prior sensitization. The response was mediated by CD4(+) Ag-specific T cells. The trafficking of Ag-specific T cells in EC was clearly visualized.     

Different roles for thiol and aspartyl proteases in antigen presentation of ovalbumin.

By using the model Ag, chicken OVA, the proteolytic events required for effective presentation of the antigenic epitope, OVA323-339 to H-2d-restricted Th cells were investigated. First, the ability of aspartyl and thiol proteases to generate antigenic fragments of Ova in vitro was determined. It was found that cathepsin D, an aspartyl protease, digested OVA to fragments that could be recognized by Th cells without further processing by APC. Cathepsin B, a thiol protease, was unable to generate antigenic fragments of OVA in vitro. These results provide evidence that APC do not require thiol protease activity for processing OVA. In contrast, APC were unable to present OVA to Th cells when thiol protease inhibitors were added to the incubation. Taken together, these observations indicate that thiol proteases may be important, not for processing, OVA, but for presentation of processed fragments by APC. This conclusion is supported by evidence obtained from experiments in which APC were treated with thiol protease inhibitors before addition of the antigenic peptide, OVA323-339. Under these conditions, the capacity of I-Ad at the cell surface to present OVA323-339 to Th cells was reduced. The results of these experiments provide evidence that Ag presentation of OVA may be achieved through the action of two different classes of proteases: aspartyl proteases such as cathepsin D, which process OVA to antigenic fragments, and thiol proteases such as cathepsin B, which are important for expression of functional MHC II molecules by APC.     

Modulation of Th2 responses by peptide analogues in a murine model of allergic asthma: amelioration or deterioration of the disease process depends on the Th1 or Th2 skewing characteristics of the therapeutic peptide

Allergen-specific CD4+ Th2 cells play an important role in the immunological processes of allergic asthma. Previously we have shown that, by using the immunodominant epitope OVA323-339, peptide immunotherapy in a murine model of OVA induced allergic asthma, stimulated OVA-specific Th2 cells, and deteriorated airway hyperresponsiveness and eosinophilia. In the present study, we defined four modulatory peptide analogues of OVA323-339 with comparable MHC class II binding affinity. These peptide analogues were used for immunotherapy by s.c. injection in OVA-sensitized mice before OVA challenge. Compared with vehicle-treated mice, treatment with the Th2-skewing wild-type peptide and a Th2-skewing partial agonistic peptide (335N-A) dramatically increased airway eosinophilia upon OVA challenge. In contrast, treatment with a Th1-skewing peptide analogue (336E-A) resulted in a significant decrease in airway eosinophilia and OVA-specific IL-4 and IL-5 production. Our data show for the first time that a Th1-skewing peptide analogue of a dominant allergen epitope can modulate allergen-specific Th2 effector cells in an allergic response in vivo. Furthermore, these data suggest that the use of Th1-skewing peptides instead of wild-type peptide may improve peptide immunotherapy and may contribute to the development of a successful and safe immunotherapy for allergic patients.     

Relationship between T cell receptors and antigen-binding factors. II. Common antigenic determinants and epitope recognition shared by T cell receptors and antigen-binding factors

The T cell hybridomas 231F1 and 12H5 constitutively secrete glycosylation-inhibiting factor (GIF) and glycosylation-enhancing factor (GEF), respectively, which lack affinity for OVA-coupled Sepharose. When the 231F1 and 12H5 cells were stimulated by OVA-pulsed syngeneic macrophages, however, GIF and GEF produced by the cells had affinity for OVA. Both the OVA-binding GIF from the 231F1 cells and OVA-binding GEF from the 12H5 cells bound to a mAb against TCR-alpha beta and a mAb against TCR-alpha, suggesting a serologic relationship between TCR and OVA-binding factors. However, the OVA-binding GIF and GEF bound to mAb 14-12 and 14-30, respectively. Because these mAb do not bind TcR alpha beta-chains, it appears that the Ag-binding factors are different from TCR itself. The OVA-binding factors from both 12H5 cells and 231F1 cells do not bind to urea-denatured OVA. The binding of the factors to OVA Sepharose was inhibited by a peptide corresponding to residues 307-317 (P307-317) in the native OVA, but not by the peptide corresponding to residues 323-339 (P323-339). Furthermore, the OVA-binding factors bound to P306-319-coupled Sepharose but not to P323-339-coupled Sepharose, and were recovered by elution of the former Sepharose at acid pH. The binding of OVA to anti-OVA antibodies was not inhibited by either peptide. Inasmuch as the 231F1 cells and 12H5 cells can be stimulated by P307-317 in the context of a MHC product, it appears that the Ag-binding factors and TCR-alpha beta on the cell sources of the factors may recognize the same epitope in the OVA molecules. The results also showed that Ag-binding factors and antibodies recognize distinct epitopes in the Ag molecules.     

Direct inhibition of T-cell responses by the Cryptococcus capsular polysaccharide glucuronoxylomannan

The major virulence factor of the pathogenic fungi Cryptococcus neoformans and C. gattii is the capsule. Glucuronoxylomannan (GXM), the major component of the capsule, is a high-molecular-weight polysaccharide that is shed during cryptococcosis and can persist in patients after successful antifungal therapy. Due to the importance of T cells in the anticryptococcal response, we studied the effect of GXM on the ability of dendritic cells (DCs) to initiate a T-cell response. GXM inhibited the activation of cryptococcal mannoprotein-specific hybridoma T cells and the proliferation of OVA-specific OT-II T cells when murine bone marrow-derived DCs were used as antigen-presenting cells. Inhibition of OT-II T-cell proliferation was observed when either OVA protein or OVA323-339 peptide was used as antigen, indicating GXM did not merely prevent antigen uptake or processing. We found that DCs internalize GXM progressively over time; however, the suppressive effect did not require DCs, as GXM directly inhibited T-cell proliferation induced by anti-CD3 antibody, concanavalin A, or phorbol-12-myristate-13-acetate/ionomycin. Analysis of T-cell viability revealed that the reduced proliferation in the presence of GXM was not the result of increased cell death. GXM isolated from each of the four major cryptococcal serotypes inhibited the proliferation of human peripheral blood mononuclear cells stimulated with tetanus toxoid. Thus, we have defined a new mechanism by which GXM can impart virulence: direct inhibition of T-cell proliferation. In patients with cryptococcosis, this could impair optimal cell-mediated immune responses, thereby contributing to the persistence of cryptococcal infections.     

Cutting edge: Immunosuppressant as adjuvant for tolerogenic immunization

Vaccination for autoimmune and alloimmune diseases has long been an attractive idea. Yet, there is no suitable adjuvant to forcefully steer the immune response toward tolerance. In this study we show that dexamethasone, a potent glucocorticoid immunosuppressant, can function as a tolerogenic adjuvant when applied together with peptide immunogen. BALB/c mice with pre-established delayed-type hypersensitivity to hen OVA were immunized with an OVA-derived, MHC II-restricted peptide (OVA(323-339)) in the presence of dexamethasone. The treatment caused long-term desensitization in treated animals to hen OVA via a dexamethasone-dependent tolerogenic mechanism that blocks maturation of dendritic cells and expands OVA(323-339)-specific CD4(+)CD25(+)Foxp3(+) regulatory T cells in vivo. Similar treatment of NOD mice using dexamethasone and an insulin-derived, MHC II-restricted peptide (B:9-23) prevented predisposed spontaneous diabetes. Remarkably, in both models, dexamethasone-augmented immunization induced long-term persistent, Ag-specific regulatory T cells responsive to recall Ags. These results reveal for the first time the potential usefulness of immunosuppressants as tolerogenic adjuvants.     

Inhibition by brefeldin A of the specific B cell antigen presentation to MHC class II-restricted T cells

We have shown previously that specific Ag presentation is prevented by the inhibition of protein synthesis but nonspecific presentation is not. In the present paper, Ag presentation by Ag-specific B cells was examined for sensitivity to brefeldin A (BFA), which blocks protein export from the endoplasmic reticulum. A20-HL B lymphoma expressing surface receptors specific for TNP was used as a B cell, and TNP-OVA was used as a specific Ag. The presence of BFA during pulsing of A20-HL cells with TNP-OVA inhibited the ability of the pulsed cells to stimulate 42-6A T cell clone, specific for OVA323-339 and Iad. The inhibition was not due to nonspecific toxicity of BFA, because the presence of BFA during pulsing of A20-HL cells with OVA323-339 did not affect their APC function. Ag binding to the receptor on A20-HL cells and internalization by the cells were observed in the presence of BFA. Thus, BFA might inhibit intracellular processing of specific Ag or intracellular complex formation of antigenic peptide from specific Ag with MHC class II molecules. Nonspecific Ag presentation by A20-HL cells, however, was resistant to BFA. A20-HL cells pulsed with OVA in the presence of BFA, even after fixation, could stimulate 42-6A cells to produce IL-2, although the IL-2 production was lower than that induced by A20-HL cells pulsed in the absence of BFA. These results suggest that the processing pathways for specific Ag and nonspecific Ag are different from each other, at least partly, in A20-HL cells.     

A novel approach to the generation of high affinity class II-binding peptides

We have found that if core regions crucial for class II binding are incorporated in multiple copies in the same peptide molecule ("reiterative motifs"), marked enhancement of the binding capacity occurs. Isotype specificity (IAd vs IEd binding capacities) is retained in all three antigenic determinants so far analyzed (lambda rep 12-26, OVA 323-339, and hen egg lysozyme 105-120). The mechanism involved in such an effect is not clear, but experiments involving introduction of a peptide spacer between two repeated core regions do not support the notion that the effect is mediated by cross-linking of more than one MHC molecule, favoring the possibility that conformational effects or distinct subsites of interaction on the MHC molecule may be involved. Based on reiterative structures, a peptide molecule composed of only two different amino acids (Ala and His) has been produced that still retains a very high binding affinity. An 125I-radiolabeled form of this peptide has been used to demonstrate that the high binding detected is mediated by the same binding site involved in the interaction of IAd and OVA 323-339. Inhibition of Ag presentation studies further supports the immunologic relevance of the phenomena observed. Finally, we observed naturally occurring clustered binding sites in proximity of immunodominant protein regions, raising the possibility that the phenomenon might have a physiologic counterpart.     

Primary response of naive CD4(+) T cells to amino acid-substituted analogs of an antigenic peptide can show distinct activation patterns: Th1- and Th2-type cytokine secretion, and helper activity for antibody production without apparent cytokine secretion

Naive CD4(+) T cells differentiate into two types of helper T cells showing an interferon-gamma-predominant (Th1) or an interleukin-4-predominant (Th2) cytokine secretion profile after repeated antigenic stimulation. Their differentiation can be influenced by slight differences in the interaction between the T cell receptor (TCR) and its ligand at the time of primary activation. However, the primary response of freshly isolated naive CD4(+) T cells to altered TCR ligands is still unclear. Here, we investigated the primary response of splenic naive CD4(+) T cells derived from transgenic mice expressing TCR specific for residues 323-339 of ovalbumin (OVA323-339) bound to I-A(d) molecules. Naive CD4(+) T cells secreted either Th1- or Th2-type cytokines immediately after stimulation with OVA323-339 or its single amino acid-substituted analogs. Helper activity for antibody secretion by co-cultured resting B cells was also found in the primary response, accompanied by either low-level Th2-type cytokine secretion or no apparent cytokine secretion. Our results clearly indicate that dichotomy of the Th1/Th2 cytokine secretion profile can be elicited upon primary activation of naive CD4(+) T cells. We also demonstrate that the helper activity of naive CD4(+) T cells for antibody production does not correspond to the amounts of the relevant cytokines secreted.     

Controlled potential enzymology of methyl transfer reactions involved in acetyl-CoA synthesis by CO dehydrogenase and the corrinoid/iron-sulfur protein from Clostridium thermoaceticum

Many anaerobic bacteria fix CO2 via the Wood pathway of acetyl-CoA synthesis. Carbon monoxide dehydrogenase (CODH), also called acetyl-CoA synthase, accepts the methyl group from the methylated corrinoid/iron-sulfur protein (C/Fe-SP), binds a carbonyl group from CO, CO2, or the carboxyl of pyruvate, and binds coenzyme A. Then CODH catalyzes the synthesis of acetyl-CoA from these enzyme-bound groups. Here, we have characterized the methyl transfer steps involved in acetyl-CoA synthesis. We have studied the reactions leading to methylation of CODH by methyl iodide and shown an absolute requirement of the C/Fe-SP in this reaction. In addition, we have discovered and partly characterized two previously unknown exchange reactions catalyzed by CODH: between the methylated C/Fe-SP and methylated CODH and between methylated CODH and the methyl moiety of acetyl-CoA. We have performed these two exchange reactions, methylation of the C/Fe-SP, and methylation of CODH at controlled potentials. The rates of all these reactions except the exchange between methylated C/Fe-SP and methylated CODH are accelerated (from 1 to 2 orders of magnitude) when run at low potentials. Our results provide strong evidence for a nucleophilic redox-active metal center on CODH as the initial acceptor of the methyl group from the methylated C/Fe-SP. This metal center also is proposed to be involved in the cleavage of acetyl-CoA in the reverse reaction.     

Phagosomes are fully competent antigen-processing organelles that mediate the formation of peptide:class II MHC complexes

During the processing of particulate Ags, it is unclear whether peptide:class II MHC (MHC-II) complexes are formed within phagosomes or within endocytic compartments that receive Ag fragments from phagosomes. Murine macrophages were pulsed with latex beads conjugated with OVA. Flow or Western blot analysis of isolated phagosomes showed extensive acquisition of MHC-II, H-2M, and invariant chain within 30 min, with concurrent degradation of OVA. T hybridoma responses to isolated subcellular fractions demonstrated OVA (323-339):I-Ad complexes in phagosomes and plasma membrane but not within dense late endocytic compartments. Furthermore, when two physically separable sets of phagosomes were present within the same cells, OVA(323-339):I-Ad complexes were demonstrated in latex-OVA phagosomes but not in phagosomes containing latex beads conjugated with another protein. This implies that these complexes were formed specifically within phagosomes and were not formed elsewhere and subsequently transported to phagosomes. In addition, peptide:MHC-II complexes were shown to traffic from phagosomes to the cell surface. In conclusion, phagosomes are fully competent to process Ags and generate peptide:MHC-II complexes that are transported to the cell surface and presented to T cells.     

Peripheral tolerance to a nuclear autoantigen: dendritic cells expressing a nuclear autoantigen lead to persistent anergic state of CD4+ autoreactive T cells after proliferation.

It remains unknown why the T cell tolerance to nuclear autoantigens is impaired in systemic autoimmune diseases. To clarify this, we generated transgenic mice expressing OVA mainly in the nuclei (Ld-nOVA mice). When CD4+ T cells from DO11.10 mice expressing a TCR specific for OVA(323-339) were transferred into Ld-nOVA mice, they were rendered anergic, but persisted in vivo for at least 3 mo. These cells expressed CD44(high), CD45RB(low), and were generated after multiple cell divisions, suggesting that anergy is not the result of insufficient proliferative stimuli. Whereas dendritic cells (DCs) from Ld-nOVA (DCs derived from transgenic mice (TgDCs)), which present rather low amount of the self-peptide, efficiently induced proliferation of DO11.10 T cells, divided T cells stimulated in vivo by TgDCs exhibited a lower memory response than T cells stimulated in vitro by peptide-pulsed DCs. Furthermore, we found that repeated transfer of either TgDCs or DCs derived from wild-type mice pulsed with a lower concentration of OVA(323-339) induced a lower response of DO11.10 T cells in Ag-free wild-type recipients than DCs derived from wild-type mice. These results suggest that peripheral tolerance to a nuclear autoantigen is achieved by continuous presentation of the self-peptide by DCs, and that the low expression level of the peptide might also be involved in the induction of hyporesponsiveness.     

A transgenic mouse strain with antigen-specific T cells (RAG1KO/sf/OVA) demonstrates that the scurfy (sf) mutation causes a defect in T-cell tolerization

The scurfy (sf) murine mutation causes severe lymphoproliferation, which results in death of hemizygous males (sf/Y) by 22 to 26 days of age. The CD4+ T cells are crucial mediators of this disease. Recent publications have not only identified this mutation as the genetic equivalent of the human disease X-linked neonatal diabetes mellitus, enteropathy, and endocrinopathy syndrome, but also have indicated that the defective protein-scurfin-is a new forkhead/winged-helix protein with a frameshift mutation, resulting in a product without the functional forkhead. These results have lead to speculation that the scurfy gene acts by disrupting the T-cell tolerance mechanism, resulting in hyperresponsiveness and lack of down-regulation. The Rag1KO/sf/Y OVA strain, with virtually 100% of its CD4+ T cells reactive strictly to ovalbumin (OVA) peptide 323-339, is an excellent model for determination of the sf mutation's ability to disrupt tolerance. We hypothesized that Rag1KO/sf/OVA mice would not be tolerant to antigen at a dose that tolerizes control animals. We found that splenic cells from Rag1KO/sf/Y OVA mice injected with the same dose of OVA peptide that induces tolerance in cells from control mice proliferate in vitro in response to OVA peptide. These results are consistent with a defect in the pathway responsible for peripheral T-cell tolerization.     

Functional reconstitution of class II MHC-restricted T cell immunity mediated by retroviral transfer of the alpha beta TCR complex

Transfer of the alphabeta TCR genes into T lymphocytes will provide a means to enhance Ag-specific immunity by increasing the frequency of tumor- or pathogen-specific T lymphocytes. We generated an efficient alphabeta TCR gene transfer system using two independent monocistronic retrovirus vectors harboring either of the class II MHC-restricted alpha or beta TCR genes specific for chicken OVA. The system enabled us to express the clonotypic TCR in 44% of the CD4+ T cells. The transduced cells showed a remarkable response to OVA323-339 peptide in the in vitro culture system, and the response to the Ag was comparable with those of the T lymphocytes derived from transgenic mice harboring OVA-specific TCR. Adoptive transfer of the TCR-transduced cells in mice induced the Ag-specific delayed-type hypersensitivity in response to OVA323-339 challenge. These results indicate that alphabeta TCR gene transfer into peripheral T lymphocytes can reconstitute Ag-specific immunity. We here propose that this method provides a basis for a new approach to manipulation of immune reactions and immunotherapy.     

In vivo methylation of prokaryotic elongation factor Tu.

In Salmonella typhimurium and Escherichia coli, elongation factor Tu (EF-Tu) is methylated as shown by its incorporation of labeled methyl residues from [methyl-3H]methionine. Analysis of the nature of the methyl-containing residues by protein hydrolysis, followed by paper chromatography and high voltage electrophoresis showed that both mono- and dimethyllysine are present. Eighty per cent of the EF-Tu molecules are methylated if methylation occurs at a unique lysine residue. The EF-Tu fraction which is not methylated is still able to accept methyl groups, as shown by methylation of approximately 10% of the EF-Tu after addition of chloramphenicol (D-(-)-threo-2,2-dichloro-N-[beta-hydroxy-alpha-(hydroxymethyl)-o-nitrophenethyl] acetamide) to inhibit further protein synthesis. There is no evidence of turnover of the methyl residues. We attempted to separate the methylated from the nonmethylated form of EF-Tu by isoelectric focusing on polyacrylamide gel, but were unable to do so.     

Rapid synthesis and introduction of a protected EDTA-like group during the solid-phase assembly of peptides.

A simple two-step procedure is reported for the synthesis of a tert-butyl ester protected form of an EDTA-like bifunctional chelating agent. This reagent can be easily introduced on any available amino group during the assembly of peptides on solid-phase supports. Using the model tetradecapeptide OVA(323-336), we have introduced an EDTA group at the N-terminus of this T-cell epitope and confirmed that the EDTA group is present on the molecule, can chelate metals, and does not affect the biological activity of the peptide.