Direct stimulation of T lymphocytes by antigen-conjugated beads

To examine T lymphocyte recognition of foreign antigen, specific responses to the photoreactive antigen N-hydroxysuccinimidyl 4-azidobenzoate (HSAB) were determined by using an HSAB/I-Ad-reactive murine T cell hybridoma. It was found that covalent coupling of HSAB to aminoethyl polyacrylamide beads at particular densities directly activated the T cells for IL 2 production, and beads conjugated at higher or lower doses of HSAB were nonstimulatory. This stimulation was specific for the phenyl ring composition of HSAB and for HSAB-reactive T cells. In addition, T cell activation by HSAB-coupled beads was specifically inhibited by soluble monomeric HSAB-glycine. These results indicate that HSAB-specific T cells may be directly stimulated by insolubilized HSAB in the absence of Ia antigens, suggesting direct T cell binding of foreign antigen.     

Effect of prostaglandin E2 on the gamma-interferon induction of antigen-presenting ability in P388D1 cells and on IL-2 production by T-cell hybridomas

The effect of prostaglandin E2 on the gamma-interferon (IFN-gamma)-mediated induction of Ia expression and antigen-presenting activity in macrophage cell lines was studied. Using a lymphokine preparation obtained from the T-cell hybridoma FS7-20.6.18 (known to produce interferon) to induce the expression of Ia in P388D1 cells, the influence of PGE2 on this phenomenon was studied. Screening of the cell cultures by indirect immunofluorescence using an anti-I-Ad monoclonal antibody confirmed the inhibitory effect of PGE2 in the induction of I-Ad. However, the inhibition of the antigen-presenting ability of these cells, as measured by their capacity to stimulate interleukin 2 (IL-2) production by antigen-specific, I-region-restricted (Ag/I) T-cell hybridomas, was more difficult to demonstrate and was only evident when using low concentrations of Ia-inducing lymphokines or when using "low avidity" T-cell hybridomas. The latter were distinguished by the limited response (in the form of IL-2 production) that was observed when they were tested with P388D1 cells that had been induced with IFN-gamma. By contrast, PGE2 had profound inhibitory effects on the ability of T-cell hybridomas to secrete IL-2 in response to Ag/I or concanavalin A. These results suggest that although PGE2 inhibits the full induction of Ia on macrophages, it has little effect on the induction of Ag/I presentation by the same cells, probably because most T cells require relatively low levels of Ia on the surface of presenting cells. T-cell responses to Ag/I are inhibited, however, because of the effects of PGE2 on the T cells themselves.     

Adherent Ia+ murine cell lines with characteristics of dendritic cells. II. Characteristics of I region-restricted antigen presentation

The ability of an adherent Ia+, interleukin 1+ (IL-1) tumor cell line (P388AD) to present turkey gamma-globulin (TGG) to primed T lymphocytes was demonstrated and compared with normal antigen-presenting cells (APC) found in mouse spleen. P388AD tumor cells presented TGG to long-term cultures of TGG-reactive T cells (LTTC) and to lymph node-derived T cells which were enriched on nylon wool columns and subsequently depleted of endogenous antigen-presenting cells with anti-Ia antisera and complement. MHC-restricted antigen presentation by P388AD was observed when long-term cultures of TGG-reactive T cells were used as the responding T-cell population. Furthermore, antisera directed against I-region determinants expressed on the P388AD tumor cells inhibited TGG-specific T-cell proliferation in a dose-related fashion, suggesting a functional role for the tumor cell-associated Ia molecules. The kinetics of antigen presentation to LTTC by P388AD were similar to the kinetics observed for splenic APC, although the magnitude of the proliferative response to LTTC to TGG was generally lower when antigen (Ag) was presented by the tumor cells compared to splenic antigen-presenting cells (APC). However, the magnitude of T-cell proliferation of immune lymph node (LN) T cells was comparable when Ag was presented on tumor cells or splenic APC. Several experiments suggested that Ag uptake and/or processing may be less effective in P388AD tumor cells as compared to normal splenic APC. A nonadherent Ia+, IL-1- tumor cell line (P388NA), which was isolated from the same parental tumor as P388AD, was also tested for the ability to present Ag to primed T lymphocytes and Ag-reactive LTTC. In contrast, to P388AD, the nonadherent tumor cell failed to present TGG under identical culture conditions even though Ia molecules were expressed on the tumor cells and Ag uptake had occurred. However, the defect in Ag presentation by P388NA could be corrected if an exogenous source of purified interleukin 1 was supplied to the cultures. A unique opportunity thus exists with both the P388AD and P388NA tumor cell lines to decipher some of the molecular interactions leading to T-cell proliferation during antigen presentation.     

Transfer of antigen-presenting capacity to Ia-negative cells upon fusion with Ia-bearing liposomes

The role of Ia in T cell activation was investigated by incorporating affinity-purified I-Ad molecules into synthetic liposomal membranes and by using these as antigen-presenting units. IL 2 production by I-Ad-restricted, chicken ovalbumin-specific T cell hybridomas was measured in a system in which antigen processing by the presenter was not required. I-Ad-bearing liposomes were found to have no antigen-presenting capacity. It was shown, however, that antigen-presenting capacity could be conferred on Ia-negative cells by fusion of these cells with liposomes bearing I-Ad molecules, together with Sendai virus envelope glycoproteins, as fusogenic agents. Both Ia-negative B lymphoma cells and mouse L cells were capable of antigen presentation of predigested ovalbumin after fusion with vesicles formed from phosphatidylserine and phosphatidylethanolamine in a 1:1 w:w ratio. The cell surface expression of the transferred Ia remained stable for at least 7 hr. These results indicate that Ia is the only additional cell surface molecule required, at least by Ia-negative B cell lymphomas and L cells, to convert them into effective antigen-presenting cells. This system should be useful in future studies of the cellular requirements for antigen processing and presentation.     

Cellular requirements for antigen processing by antigen-presenting cells: evidence for different pathways in forming the same antigenic determinants

In this report we examined the antigen-presenting cell (APC) requirements for activation of T-cell hybridomas specific for the protein antigen PPD (purified protein derivative of tuberculin). During the course of these studies we observed that glutaraldehyde fixation of Ia-positive A20.2JAD (A20) and P388D1 stimulator cells had different effects on T-cell activation. A20 cells fixed with glutaraldehyde stimulated the T cells in the presence of PPD as efficiently as nonfixed A20 cells. By contrast, glutaraldehyde treatment of Ia-positive P388D1 cells dramatically inhibited their ability to process and/or present PPD to T cells. This was not due to nonspecific effects on the P388D1 cells since cells prepulsed with PPD prior to glutaraldehyde treatment stimulated T cells as efficiently as non-glutaraldehyde-treated P388D1 cells. In addition, there was no apparent difference in "fixing" of the two cell types as determined by the uptake of radiolabeled thymidine. These observations suggested that P388D1, but not A20, cells required PPD internalization to form the relevant antigenic determinants. This was substantiated by showing that treatment of P388D1 cells with chloroquine prior to PPD pulsing eliminated their stimulatory capacity, but had no effect on P388D1 cells previously pulsed with PPD. Chloroquine treatment had no effect on stimulation by A20 cells. Since PPD internalization appeared not to be required for presentation by A20 cells, we next determined if isolated A20 plasma membranes would substitute for the intact cell. We observed that the isolated plasma membranes from PPD-pulsed A20 cells stimulated the T hybridoma cells, and that this stimulation was antigen-specific and was inhibited by anti-Ia monoclonal antibodies. Taken together, the results presented here suggest that for the PPD-specific T-cell responses examined here, different APC utilize distinct pathways to present the same antigenic determinant for T-cell recognition.     

Two roles for Ia in antigen-specific T lymphocyte activation

In this study we examined the mechanism by which a PPD-specific murine T cell hybridoma, 8B2, recognized PPD associated with antigen-presenting cells (APC) in a manner genetically restricted by I-Ad. It was found that PPD-pulsed APC that were glutaraldehyde-fixed and treated with anti-Ia monoclonal antibody (abbreviated as PGM) were unable to stimulate the 8B2 T cells, as expected, due to inhibition caused by antibody binding to the Ia. However, addition of non-antigen-treated, glutaraldehyde-fixed APC (abbreviated as G) to cultures containing 8B2 T cells and PGM restored T cell activation, as determined by IL 2 production. This second non-antigen-specific function provided by the additional APC, G, was attributed to Ia and could be substituted by APC plasma membranes and by soluble membrane extracts. Genetic restriction analysis in which a variety of Ia-positive and Ia-negative cell lines and B cell blasts from different mouse strains were used as PGM or as G showed that each APC provided different Ia determinants that were specifically recognized by the T cells. PGM cells had to express I-Ad in order to present the PPD determinant, whereas the non-antigen-specific function was specific for I-Ad or I-Ab. These results suggest that the anti-Ia antibody does not interfere with the PPD/I-Ad-specific determinant bound by the antigen-specific T cell receptor, but prevents a second non-antigen-specific interaction with another region of the Ia molecule, which is provided by G. These two roles for Ia (antigen-specific and non-antigen-specific) were also found for activation of normal polyclonal PPD-specific T cell responses; thus they are not unique to the 8B2 T cell, but are generally applicable. In addition, T cell interactions with PGM and with G each provide different intracellular activation signals. This was determined by substituting the PGM or the G with either the tumor promoter phorbol 12-myristate 13-acetate (PMA) or the Ca++ ionophore, ionomycin. It was found that 8B2 T cells cultured with PGM and ionomycin, but not with PGM and PMA, were activated for IL 2 production. Neither PMA nor ionomycin in conjunction with G resulted in T cell activation. Taken together, these results indicate that 8B2 T cell activation involves APC Ia antigens in two different ways: one is to contribute to the presentation of the foreign PPD antigen, and a second is a non-antigen-specific Ia-T cell interaction necessary to provide additional intracellular activation signals.(ABSTRACT TRUNCATED AT 400 WORDS)     

Stimulation of normal inducer T cell clones with antigen presented by purified Ia molecules in planar lipid membranes: specific induction of a long-lived state of proliferative nonresponsiveness

Culture of normal inducer T cell clones with antigen and purified Ek beta:Ek alpha incorporated into planar lipid membranes resulted in specific T cell activation as determined by cell volume increase and IL 3 production. However, in contrast to results obtained with T cell hybridomas, antigen presentation by planar membranes did not induce measurable IL 2 production, and proliferative responses were not detected. Rather, recognition of only Ek beta:Ek alpha and antigen resulted in the specific induction of a long-lived state of proliferative nonresponsiveness to subsequent stimulation by conventional APC and antigen. Induction of nonresponsiveness required protein synthesis, and was not simply due to the absence of IL 2. The antigen-nonresponsive cells could respond to either PMA plus ionomycin or IL 2, and they expressed normal levels of surface antigen-receptor molecules. These results demonstrate that recognition by normal T cell clones of antigen and Ia molecules in the absence of other accessory cell molecules and signals results in a prolonged state of proliferative nonresponsiveness, possibly similar to a state of T cell tolerance in vivo.     

Murine thyroid follicular epithelial cells can be induced to express class II (Ia) gene products but fail to present antigen in vitro

To determine whether thyroid follicular epithelial cells (TFEC) might be involved in the induction of autoimmune thyroiditis, they were tested for their potential to express Ia antigens, and for their ability to present antigen in vitro. Results showed that Ia antigens, absent on normal TFEC, could be readily induced with interferon gamma, as detected by immunofluorescence. Maximal expression of Ia antigens in over 50% of TFEC was observed after 4 days of culture in the presence of IFN-gamma, and was quantitatively comparable to spleen cells by cytofluorometric analysis. Moreover, primary TFEC in culture secreted thyroglobulin (tg) and interleukin 1. However, TFEC consistently failed to stimulate various populations of T cells. These included lymph node cells sensitized to tg, a T-cell clone specific for azo-benzene-arsonate tyrosine (ABA), and a hybridoma specific for beef insulin. Likewise, Ia-positive TFEC did not stimulate T-cell hybridomas restricted to the class II alloantigen I-Ab, while stimulating a hybridoma specific for the class I alloantigen Kb. T-cell unresponsiveness could not be explained by inhibitory activity of TFEC, released either into the culture supernatant or exerted by cell contact. The data indicate that Ia-positive TFEC failed to serve as class II-restricted antigen-presenting cells (APC) in vitro and thus argue against a primary role for these cells in the inductive phase of thyroiditis.     

T cell-mediated recognition of foreign antigen and the Ia molecule observed by stopped-flow fluorometry

Th cell-mediated rapid recognition of foreign Ag and the Ia molecule was studied using azobenzenearsonate-L-tyrosine (ABA-L-tyrosine)-specific Th cells (I-Ak restricted), foreign Ag (ABA-L-tyrosine), and APC (H-2k). Initial transmembrane signals in Th cell hybridomas (2-45-12) and in Th cell lines (A24-17 or A33-7) were monitored by stopped-flow fluorometry with fluorescent probes. It was found that Th cells recognized foreign Ag within 1 s at 25 degrees C on the APC (B10.BR spleen cells or L cells into which I-Ak genes were transferred). Recognition of foreign Ag and the Ia molecule was shown to deliver the initial signals to Th cell hybridomas and T cell lines. First, Th cells had membrane fluidity increased and then calcium was transported from the external medium into the T cells. The initial transmembrane signals to Th cell hybridomas were inhibited by the addition of an anti-I-Ak mAb. None of the initial signals were observed in the absence of either specific foreign Ag or APC.     

Fc gamma receptor-mediated suppression of gamma-interferon-induced Ia antigen expression on a murine macrophage-like cell line (P338D1)

A variant (HS-1) of a murine macrophage cell line (P388D1) was obtained by cell cluster technique based on the Ia antigen expression induced by lymphokines. Receptors for both IgG2a and IgG2b but no detectable I-Ad are expressed on the surface of the majority of HS-1 cells. Exposure of HS-1 cell to concanavalin A supernatant or recombinant IFN-gamma resulted in the induction of I-Ad antigens on greater than 90% of the cells within 48 hr. The effects of lymphokines were transient and dependent on the synthesis of messenger RNA because the removal of lymphokines or the presence of actinomycin D both blocked Ia expression. The prior or simultaneous binding of monoclonal IgG2a or IgG2b antibodies complexed with sheep erythrocytes to respective cell surface Fc gamma R suppressed the Ia antigen inducing activity of lymphokines. Neither antibody nor antigen alone could suppress the effect of lymphokines. Inhibitors of phospholipase A2 or cyclooxygenase, which have been shown previously to suppress Fc gamma 2bR, but not Fc gamma 2aR, triggered activation of the adenylate cyclase system and reversed Fc gamma 2bR- but not Fc gamma 2aR-mediated suppression of IFN-gamma-induced Ia antigen expression.     

Functional analysis of cloned macrophage hybridomas. IV. Induction and inhibition of mixed lymphocyte responses

A series of macrophage (M phi) hybridomas were generated by fusion of drug-marked P388D1 (H-2d) tumor cells with CKB (H-2k) splenic adherent cells. The ability of this panel of cloned M phi hybridomas expressing various levels of surface Ia antigens to induce allogeneic mixed lymphocytes responses (MLR) was examined. All MLR stimulatory M phi hybridomas expressed surface Ia antigens. However, some Ia+ and all Ia- M phi hybridomas were unable to induce vigorous MLR responses. Furthermore, even after induction of surface Ia antigen expression with Con A supernatants (Con A Sn) or purified interferon-gamma, the nonstimulatory M phi hybridomas remained ineffective at inducing strong MLR proliferative responses. Furthermore, addition of the latter M phi hybridoma clones (both with and without Con A Sn treatment) to conventional MLR cultures resulted in inhibition of MLR responses. The series of inhibitory M phi hybridomas secreted normal levels of IL 1 upon stimulation with lipopolysaccharide. After surface Ia induction with Con A Sn, the inhibitory M phi hybridomas could stimulate secretion of IL 2 and expression of IL 2 receptors. Moreover, although they inhibited conventional MLR responses, IL 2 production and IL 2 receptor expression were not significantly inhibited. Addition of these M phi hybridomas 24 to 48 hr after initiation of MLR response also inhibited MLR proliferation. The results indicated that the group of inhibitory M phi hybridomas can inhibit MLR responses after IL 2 secretion and acquisition of IL 2 receptors. Finally, this inhibitory activity has been maintained during 1 yr of continuous in vitro culture, and the hybridomas represent a stable "homogeneous" subpopulation of inhibitory macrophages. Thus, the inhibitory phenotype appears to reflect arrest at a distinct differentiation stage.     

Production of hapten-specific T cell hybridomas and their use to study the effect of ultraviolet B irradiation on the development of contact hypersensitivity

We produced a series of T cell hybridomas that produce IL-2 when cultured with syngeneic APC coupled to FITC or TNP. These hybridomas are hapten specific and Ia restricted. The hybridomas were used to detect hapten-bearing APC in draining lymph nodes of mice sensitized with trinitrochlorobenzene or FITC in vivo. Hapten-bearing APC capable of stimulating the hybridomas were detectable in draining lymph nodes of hapten-painted mice within 3 h after sensitization. The ability of lymph node APC to stimulate the hybridomas peaked at 24 h and declined by 48 h. The dendritic cell subpopulation was the subpopulation of cells that were found in the regional lymph nodes of hapten-painted animals that were capable of stimulating the hybridomas to produce IL-2. Prior treatment of the skin with low dose UVB irradiation before epicutaneous application of contact sensitizers significantly reduced the capacity of hapten-bearing APC to stimulate the hybridomas. This observation was corroborated by results obtained from flow microfluorometry analysis of lymph node cells from FITC-sensitized mice. Lymph node dendritic cells obtained from FITC-painted mice contain a brightly staining group of cells by flow microfluorometry analysis. Lymph node dendritic cells from FITC-painted, UVB-irradiated mice did not contain this brightly staining population. These results indicate that low dose, local UVB irradiation may affect APC migration and/or function. We believe that these hybridomas will prove to be useful tools in the study of the development and regulation of contact hypersensitivity.     

Ia-specific mixed leukocyte reactive T cell hybridomas: analysis of their specificity by using purified class II MHC molecules in synthetic membrane system

This study was undertaken to determine the nature of the antigens recognized in allogeneic and syngeneic mixed leukocyte reactions (MLR). Specifically, we wished to determine whether Ia antigens alone were recognized by MLR-reactive T cells, or whether the specificity was determined by the corecognition of non-MHC antigens together with syngeneic or allogeneic Ia. To do this we used 11 T cell hybrids that were characterized as being specific for Iad and were tested their capacity to respond to isolated I-Ad or I-Ed that had been incorporated into liposomes and had bound to the surface of glass beads. Of nine alloreactive T cell hybrids (five I-Ad-and four I-Ed-specific), seven were shown to be responsive to the relevant isolated Ia antigen on glass beads. Also, two of two syngeneic I-Ad-specific T cell hybrids responded to I-Ad on the glass beads. One of the two alloreactive T cell hybrids that failed to respond to the relevant Ia antigen on glass beads was shown to be specific for an antigen in fetal calf serum (FCS) that was recognized in the context of the allo-Ia antigen (I-Ed), because when intact accessory cells were used, a response by this hybrid was only observed when FCS was present in the assay culture medium or when the accessory cells were pre-pulsed with FCS. The possible involvement of FCS antigens and non-Ia accessory cell antigens in the stimulation of the nine T cell hybrids that responded to isolated Ia on glass beads was evaluated. T cell hybrids that were grown and were tested in serum free medium were still capable of reacting to Ia on beads. The isolated Ia preparations used were greater than 90% pure, and their capacity to stimulate the T cell hybrids did not correlate with the degree of contamination with non-Ia proteins. We conclude from these studies that the majority of T cells that respond to allogeneic or syngeneic Ia bearing stimulator cells are specific for the Ia antigens themselves, and do not require the co-recognition of other non-Ia antigens; nor is there any requirement for Ia antigen processing for this recognition.     

Inducer T-cell-mediated killing of antigen-presenting cells

L3T4+ inducer/helper T-cell clones, once activated by antigen-presenting cells (APC) expressing the appropriate Ia allele and antigen, autonomously kill their target APC. All 13 L3T4+ inducer T-cell clones tested demonstrated this cytolytic activity. In addition, 11 different target cells representing the three major APC types, namely, macrophages, B cells, and dendritic cells, were all sensitive to this cytolytic activity. Moreover, normal macrophages which were treated with interferon-gamma to increase Ia expression were also killed. These observations convincingly demonstrate that the cytolytic activity of L3T4+ inducer T-cell clones is a general phenomenon. In contrast to other reports, lysis of target APC could not be detected following 4-6 hr of incubation. Marginal lysis was observed after 9 hr and a 20-hr incubation period was required to achieve maximal killing. The kinetics of killing paralleled other parameters of T-cell activation such as IL-2 release and cell proliferation. Activation of T cells for cytolysis of APC requires the interaction of T-cell receptors with Ia and antigen. Monoclonal antibody to Ia, L3T4 and the T-cell receptor inhibited the cytolysis of APC. The ability to mediate nonspecific bystander killing was variable depending on both the T-cell clone and the target. The implications of these findings to immune regulation and autoimmunity are discussed.     

Probing the structure of processed antigen by using biotin and avidin. MHC-dependent inhibition of responses to selected biotinyl-insulin derivatives

Current models suggest that Ag undergoes proteolytic cleavage in APC and that resultant peptide fragments associate with class II histocompatibility glycoproteins before recognition by helper T cells. Little direct information is available concerning the physical structure and membrane association of Ag processed under physiologic conditions. A model system, employing a series of biotinylated insulin derivatives, was used to examine the domains of Ag that are presented by APC. We reasoned that avidin should block the response of T cells to a given derivative only if biotin is retained on the functionally relevant form of Ag after processing. By utilizing derivatives modified at selected sites one should be able to determine whether specific sites remain after processing. By using F1 APC pulsed with biotinyl-insulin derivatives modified through the free amino groups of the A1, B1, or B29 amino acids, and T cell hybridomas restricted to I-Ad or I-Ab, we found that avidin inhibited the I-Ad-restricted response to A1, but not B1 or B29 derivatives. By contrast, specific inhibition of the I-Ab-restricted response was observed by using all three derivatives. These results suggest that the processed form of insulin recognized in association with I-Ab is largely intact and includes residues from both chains (A1, B1, and B29). The differential inhibition observed by using T cells restricted to different class II alleles demonstrates that processed Ag associated with I-Ab differs in conformation or structure from that associated with I-Ad. This experimental approach should prove valuable in characterizing the actual structure of processed Ag recognized by T cells.     

Contribution of antigen processing to the recognition of a synthetic peptide antigen by specific T cell hybridomas

Most antigens recognized by T cells require unfolding or partial degradation (processing) followed by association with Major Histocompatibility Complex (MHC) molecules. We examined the processing requirements for the presentation of antigen to two T cell hybridomas which recognize the alpha-helical synthetic polypeptide antigen Poly 18, Poly [EYK(EYA)5], in association with I-Ad. Hybridoma A.1.1 responds to EYK(EYA)4 as the minimum antigenic sequence while hybridoma B.1.1 recognizes (EYA)5 sequence. It was found that these hybridomas responded to Poly 18 and to minimum peptide sequences presented by glutaraldehyde and chloroquine treated antigen presenting cells (APC), suggesting that antigen processing is not a requirement for the activation of these cells. The reactivity pattern of hybridoma B.1.1 in the presence of glutaraldehyde fixed APC revealed that antigens containing lysine were presented with much less efficiency than antigens without lysine, suggesting an interaction of these residues with the antigen presenting cell surface. We discuss the possibility that alanine residues in the alpha-helical Poly 18 form a hydrophobic ridge which may be required for appropriate interaction between antigen, the T cell receptor, and MHC molecules.     

Antigen presentation to T cell hybridomas by a macrophage cell line: an inducible function

We have investigated the ability of an Ia-, nonantigen-presenting macrophage tumor cell line, P388D, (H-2d), to present antigen to T cell hybridomas after incubation in a lymphokine-containing preparation. P388D, cells were incubated in microtiter wells with various concentrations of Con A-stimulated spleen cell supernatants. Antigen-specific stimulation of H-2d-restricted, KLH-specific T cell hybridomas was observed by P388D1 incubated with SUP.P388D1 cells incubated for 3 days in medium or control SUP did not present antigen. In addition, no stimulation of T hybridomas was seen by P388D1 in the inhibited by the appropriate monoclonal anti-Ia reagents. These results demonstrate that a macrophage tumor cell line can be induced to present antigen and provides for large numbers of readily available, homogeneous macrophages for studying the cellular biochemical requirements for antigen processing and presentation.     

Two roles for Ia in antigen-specific T cell activation. II. Toward a Velcro model of antigen recognition

It has been previously reported that Ia Ag on APC seems to be involved in Ag-specific T cell activation in at least two different ways: one is to associate with foreign Ag to form a neoantigenic determinant (the Ag-specific Ia function), and the second is to interact with T cells in a non-Ag-specific manner. Both Ia functions are required for T cell activation. In the present study we examined whether the T cell structures responsible for the non-Ag-specific Ia interaction were separable from the Ag-specific alpha/beta TCR. Purified protein derivative of tuberculin (PPD)-specific murine hybridoma T cells and polyclonal lymph node T cells were stimulated for IL-2 production by APC pulsed with PPD, glutaraldehyde fixed, and anti-Ia antibody treated, to provide the antigenic PPD/Ia determinant, in the presence of glutaraldehyde-fixed non-Ag-pulsed APC, to provide the non-Ag-specific Ia interactions. However, in several different approaches the T cell structures or activation signals responsible for the Ag-specific recognition and non-Ag-specific Ia interactions seemed to be associated with each other in this experimental system. First, the Ag-specific and non-Ag-specific Ia interactions with T cells were both required simultaneously to initiate T cell activation, and it was not possible to activate T cells by providing either Ia signal subsequent to the other. Second, the T cell structures responsible for the non-Ag-specific Ia interactions appeared to be clonally distributed in PPD-specific lymph node T cells. Third, another T cell hybridoma specific for bovine insulin also showed dual Ia interactions, but the specificity of the non-Ag-specific Ia function was different than that for the PPD-specific T cell response. Fourth, all subclones of PPD-specific T hybridomas that had lost Ag-specific responsiveness also lost functional non-Ag-specific Ia interactions. Taken together, these observations suggest that a single species of TCR may mediate both the Ag-specific and non-Ag-specific Ia interactions. In addition, the non-Ag-specific Ia interaction with T cells augmented the Ag-specific Ia interaction for T cell activation, indicating that both types of interactions may be involved in some T cell responses. Based on these observations, a Velcromodel depicting the synergy between the two Ia functions is proposed in which a matrix of interactions consisting of higher affinity Ag binding and lower affinity Ia-TCR associations provides cooperative sets of signals necessary for cellular activation.     

Functional and biochemical parameters of peptide antigen presentation

To understand the mechanism by which peptide antigens are processed and presented to T cells, we examined the T-cell response to the 13-amino-acid peptide alpha-melanocyte-stimulating hormone (alpha-MSH). To determine the fine specificity of T-cell recognition, T cells specific for alpha-MSH, and genetically restricted by I-Ab/d, were challenged with different alpha-MSH analogs and homologs. It was found that intact alpha-MSH, including the blocked amino and carboxy termini of the native molecule, was required for T-cell responsiveness. Antigen-presenting cells (APC) could be briefly pulsed with alpha-MSH and then present the alpha-MSH antigenic determinant to T cells, indicating that the relevant antigen was retained by the APC. APC stimulatory capacity was dramatically reduced by aldehyde treatment of the APC, or by pulsing the APC with alpha-MSH at low temperature. Efficient alpha-MSH pulsing was also impaired by treatment of the APC with the carboxylic ionophore, monensin, but not by the lysosomotropic agents chloroquine and methylamine. In addition, isolated APC plasma membranes added to the T cells in the presence of soluble alpha-MSH were not stimulatory. However, plasma membranes isolated from APC that had been previously pulsed with alpha-MSH retained stimulatory activity for T-cell responses. The only detectable alpha-MSH contained in these pulsed APC membranes was in an acid-stable complex of higher molecular weight than native peptide. The amount of alpha-MSH detected in the cellular membrane fraction isolated by density gradient sedimentation was also reduced by treatments that reduced the APC stimulatory capacity, such as pulsing at low temperature or in the presence of monensin. Taken together, these results suggest that processing of alpha-MSH is unlike that heretofore described for other peptide antigens and seems to involve APC handling to form the stimulatory moiety presented on the APC surface.     

Methods for nano-particle based vaccine formulation and evaluation of their immunogenicity

Nano- and microparticles have long been used for the delivery of drugs and are currently being evaluated as vaccine delivery systems. Particulates can elicit potent immune responses, either by direct immuno-stimulation of antigen presenting cells (APC) or/and by delivering antigen to specific cellular compartments and promoting antigen uptake by appropriate stimulatory cell types. Herein, we describe a detailed method for the preparation of a novel nanoparticle-based antigen delivery system which induces strong cellular and humoral immune responses in mice and sheep. This simple system is based on the use of 40 nanometer (nm) inert solid carrier beads to which antigen is covalently coupled before injection. Covalent conjugation of antigen to the nanobeads, assessment of conjugation efficiency, characterisation and measurement of in vivo immunogenicity by cytokine ELISPOT (to measure antigen-specific T-cell responses) and ELISA (to measure antibody titers), are described. Emphasis is placed on providing trouble-shooting advice to enable the reproducible production of soluble nano-size formulations that do not suffer from common problems such as aggregation, as well as understanding the causes and thus avoiding a range of prevalent technical problems that occur when using immune response detection assays, such as the cytokine ELISPOT assay and ELISA.