MHC class II-peptide complexes in dendritic cell lipid microdomains initiate the CD4 Th1 phenotype

We investigated differentiation of CD4 T cells responding to Ag presented by bone marrow-derived dendritic cells (DC) in association with MHC class II (MHC II) molecules. Peptides encapsulated in liposomes opsonized by IgG were taken up by endocytosis. MHC II-peptide-specific T cells responding to this Ag were polarized to a Th1 cytokine profile in a CD40-, CD28-, MyD88-, and IL-12-dependent manner. Th2 responses were obtained from the same transgenic T cell population exposed to the same DC on which MHC-peptide complexes had dispersed for 48 h following uptake of FcR-targeted liposomes. DC that took up the same FcR-targeted liposomes and then were exposed to methyl-beta-cyclodextrin, which chelates cholesterol and dissociates lipid microdomains, also stimulated Th2 differentiation. Incubation of T cells with DC incubated with peptides directly binding to MHC II resulted in Th2 responses, whether or not the DC were coincubated with opsonized liposomes as a maturation stimulus. CD4 Th1 polarization thus appears to depend on MHC II-peptide complex clustering in DC lipid microdomains and the time between peptide loading and T cell encounter.     

Impaired ability of MHC class II-/- dendritic cells to provide tumor protection is rescued by CD40 ligation.

The contribution of CD4+ T cells to dendritic cell (DC) activation and to the induction of CD8+ T cell responses in vivo was investigated using a model of antitumor immune responses. Immunization with peptide-loaded MHC class II-deficient (MHC class II-/-) DC induced the activation of Ag-specific CD8+ T cells and their accumulation in the lymph nodes and spleens of immunized mice. The accumulation induced by MHC class II-/- DC immunization was lower than the accumulation observed after immunization with MHC class II+/+ DC. Similarly, immunization with peptide-loaded, MHC class II-/- DC induced some degree of protection against tumor challenge, but this protection was lower than the protection achieved after immunization with MHC class II+/+ DC. Incubation with a membrane-associated form of CD40 ligand resulted in the up-regulation of costimulatory molecules on MHC class II-/- DC and fully rescued their ability to induce antitumor immunity. We conclude that CD4+ T cells play a critical role in the generation of antitumor immune responses through their capacity to induce the activation of DC via CD40/CD40 ligand interaction, and thus maximize CD8+ T cell responses.     

Immune complex-loaded dendritic cells are superior to soluble immune complexes as antitumor vaccine

Dendritic cells (DCs) play an important role in the induction of T cell responses. Fc gammaRs, expressed on DCs, facilitate the uptake of complexed Ag, resulting in efficient MHC class I and MHC class II Ag presentation and DC maturation. In the present study, we show that prophylactic immunization with DCs loaded with Ag-IgG immune complexes (ICs) leads to efficient induction of tumor protection in mice. Therapeutic vaccinations strongly delay tumor growth or even prevent tumors from growing out. By depleting CD4+ and CD8+ cell populations before tumor challenge, we identify CD8+ cells as the main effector cells involved in tumor eradication. Importantly, we show that DCs that are preloaded in vitro with ICs are at least 1000-fold more potent than ICs injected directly into mice or DCs loaded with the same amount of noncomplexed protein. The contribution of individual Fc gammaRs to Ag presentation, T cell response induction, and induction of tumor protection was assessed. We show that Fc gammaRI and Fc gammaRIII are capable of enhancing MHC class I-restricted Ag presentation to CD8+ T cells in vitro and that these activating Fc gammaRs on DCs are required for efficient priming of Ag-specific CD8+ cells in vivo and induction of tumor protection. These findings show that targeting ICs via the activating Fc gammaRs to DCs in vitro is superior to direct IC vaccination to induce protective tumor immunity in vivo.     

HIV gag mRNA transfection of dendritic cells (DC) delivers encoded antigen to MHC class I and II molecules, causes DC maturation, and induces a potent human in vitro primary immune response

Dendritic cells (DC) are the major APCs involved in naive T cell activation making them prime targets of vaccine research. We observed that mRNA was efficiently transfected, resulting in superior translation in DC compared with other professional APCs. A single stimulation of T cells by HIV gag-encoded mRNA-transfected DC in vitro resulted in primary CD4(+) and CD8(+) T cell immune responses at frequencies of Ag-specific cells (5-12.5%) similar to primary immune responses observed in vivo in murine models. Additionally, mRNA transfection also delivered a maturation signal to DC. Our results demonstrated that mRNA-mediated delivery of encoded Ag to DC induced potent primary T cell responses in vitro. mRNA transfection of DC, which mediated efficient delivery of antigenic peptides to MHC class I and II molecules, as well as delivering a maturation signal to DC, has the potential to be a potent and effective anti-HIV T cell-activating vaccine.     

Defective MHC class II presentation by dendritic cells limits CD4 T cell help for antitumor CD8 T cell responses

Cancer immunosurveillance failure is largely attributed to insufficient activation signals and dominant inhibitory stimuli for tumor Ag (TAg)-specific CD8 T cells. CD4 T cells have been shown to license dendritic cells (DC), thereby having the potential for converting CD8 T cell responses from tolerance to activation. To understand the potential cooperation of TAg-specific CD4 and CD8 T cells, we have characterized the responses of naive TCR transgenic CD8 and CD4 T cells to poorly immunogenic murine tumors. We found that whereas CD8 T cells sensed TAg and were tolerized, the CD4 T cells remained ignorant throughout tumor growth and did not provide help. This disparity in responses was due to normal TAg MHC class I cross-presentation by immature CD8alpha+ DC in the draining lymph node, but poor MHC class II presentation on all DC subsets due to selective inhibition by the tumor microenvironment. Thus, these results reveal a novel mechanism of cancer immunosubversion, in which inhibition of MHC-II TAg presentation on DC prevents CD4 T cell priming, thereby blocking any potential for licensing CD8alpha+ DC and helping tolerized CD8 T cells.     

Processing of an endogenous protein can generate MHC class II-restricted T cell determinants distinct from those derived from exogenous antigen.

Class II MHC molecules on the surface of an APC present immunogenic peptides derived mainly from exogenous proteins to CD4+ T cells. During its transport to the cell surface, class II molecules intersect the endocytic pathway where they acquire peptides derived from endocytosed proteins. However, class II-restricted presentation of endogenously derived peptides can also occur. The current studies were undertaken to examine the ability of different types of APC to generate and present four different T cell determinants derived from an endogenous, nonsecreted, truncated form of hen-egg white lysozyme (HEL[1-80]-Kk). This was compared with the ability of these APC to generate the same determinants from exogenous HEL. All the peptides derived from endogenous HEL[1-80]-Kk tested, were presented by B cells to HEL-specific T cell hybridomas with an efficiency similar to presentation of the same determinants from exogenous HEL. In contrast, an I-Ak-bearing rat fibroblast was unable to generate the HEL peptide 25-43 from exogenous HEL, but could efficiently produce it from endogenous HEL[1-80]-Kk. The results indicate first, that peptides derived from an endogenous Ag can be presented by MHC class II molecules with an efficiency comparable to that of the presentation of the exogenous Ag. Second, that Ag-presenting B cells can generate the same repertoire of antigenic peptides from endogenous Ag as those generated from the exogenous protein. And third, that in contrast to B cells, certain "nonprofessional" APC can generate, from an endogenous protein, T cell determinants distinct from those generated after endocytosis of the exogenous protein. These results suggest that processing of exogenous and endogenous Ag by different APC take place in different intracellular compartments.     

Functional analysis of birch pollen allergen Bet v 1-specific regulatory T cells

Allergen-specific immunotherapy using peptides is an efficient treatment for allergic diseases. Recent studies suggest that the induction of CD4+ regulatory T (Treg) cells might be associated with the suppression of allergic responses in patients after allergen-specific immunotherapy. Our aim was to identify MHC class II promiscuous T cell epitopes for the birch pollen allergen Bet v 1 capable of stimulating Treg cells with the purpose of inhibiting allergic responses. Ag-reactive CD4+ T cell clones were generated from patients with birch pollen allergy and healthy volunteers by in vitro vaccination of PBMC using Bet v 1 synthetic peptides. Several CD4+ T cell clones were induced by using 2 synthetic peptides (Bet v 1(141-156) and Bet v 1(51-68)). Peptide-reactive CD4+ T cells recognized recombinant Bet v 1 protein, indicating that these peptides are produced by the MHC class II Ag processing pathway. Peptide Bet v 1(141-156) appears to be a highly MHC promiscuous epitope since T cell responses restricted by numerous MHC class II molecules (DR4, DR9, DR11, DR15, and DR53) were observed. Two of these clones functioned as typical Treg cells (expressed CD25, GITR, and Foxp3 and suppressed the proliferation and IL-2 secretion of other CD4+ T cells). Notably, the suppressive activity of these Treg cells required cell-cell contact and was not mediated through soluble IL-10 or TGF-beta. The identified promiscuous MHC class II epitope capable of inducing suppressive Treg responses may have important implication for the development of peptide-based Ag-specific immunotherapy to birch pollen allergy.     

Dendritic cells cross-dressed with peptide MHC class I complexes prime CD8+ T cells

The activation of naive CD8+ T cells has been attributed to two mechanisms: cross-priming and direct priming. Cross-priming and direct priming differ in the source of Ag and in the cell that presents the Ag to the responding CD8+ T cells. In cross-priming, exogenous Ag is acquired by professional APCs, such as dendritic cells (DC), which process the Ag into peptides that are subsequently presented. In direct priming, the APCs, which may or may not be DC, synthesize and process the Ag and present it themselves to CD8+ T cells. In this study, we demonstrate that naive CD8+ T cells are activated by a third mechanism, called cross-dressing. In cross-dressing, DC directly acquire MHC class I-peptide complexes from dead, but not live, donor cells by a cell contact-mediated mechanism, and present the intact complexes to naive CD8+ T cells. Such DC are cross-dressed because they are wearing peptide-MHC complexes generated by other cells. CD8+ T cells activated by cross-dressing are restricted to the MHC class I genotype of the donor cells and are specific for peptides generated by the donor cells. In vivo studies demonstrate that optimal priming of CD8+ T cells requires both cross-priming and cross-dressing. Thus, cross-dressing may be an important mechanism by which DC prime naive CD8+ T cells and may explain how CD8+ T cells are primed to Ags that are inefficiently cross-presented.     

Simultaneous induction of CD4 T cell tolerance and CD8 T cell immunity by semimature dendritic cells

Previous studies suggested that depending on their maturation state, dendritic cells (DC) could either induce T cell tolerance (immature and semimature DC) or T cell activation (mature DC). Pretreatment of C57BL/6 mice with encephalitogenic myelin oligodendrocyte glycoprotein (MOG)(35-55) peptide-loaded semimature DC protected from MOG-induced autoimmune encephalomyelitis. This protection was mediated by IL-10-producing CD4 T cells specific for the self Ag. Here we show that semimature DC loaded with the MHC class II-restricted nonself peptide Ag (OVA) induce an identical regulatory T cell cytokine pattern. However, semimature DC loaded simultaneously with MHC class II- and MHC class I-restricted peptides, could efficiently initiate CD8 T cell responses leading to autoimmune diabetes in a TCR-transgenic adoptive transfer model. Double-peptide-loaded semimature DC also induced simultaneously in the same animal partially activated CD8 T cells with cytolytic function as well as protection from MOG-induced autoimmune encephalomyelitis. Our study suggests that the decision between tolerance and immunity not only depends on the DC, but also on the type and activation requirements of the responding T cell.     

Lymphocyte-mediated activation of cultured endothelial cells (EC). CD4+ T cells inhibit EC class II MHC expression despite secreting IFN-gamma and increasing EC class I MHC and intercellular adhesion molecule-1 expression

Endothelial cells (EC) were cocultured with allogeneic PBL, CD4+ T cells, or CD8+ T cells, and the degrees of EC activation induced examined by determining patterns of endothelial class I and class II MHC and intercellular adhesion molecule-1 (ICAM-1) expression. Coculture with PBL or CD8+ T cells uniformly increases class I MHC and ICAM-1 expression on all EC within a culture, but induces class II MHC expression on only a subpopulation(s) of EC. This heterogeneous EC response to coculture contrasts with the uniform class II expression on all EC induced by IFN-gamma in replicate wells. CD4+ T cells, when compared to equal numbers of unfractionated PBL or CD8+ T cells, are more effective at increasing class I MHC and ICAM-1 but are unable to induce class II MHC expression. The failure of CD4+ T cells to induce EC class II MHC Ag is not due to insufficient activation of the T cells, as PHA-activated CD4+ T cells also do not induce significant class II expression. In addition, conditioned media (CM) from CD4+ T cell/EC contain greater levels of immunoreactive IFN-gamma than do CM from PBL/EC cocultures. Rather, CD4+ T cells appear to actively inhibit the induction of EC class II Ag but not class I or ICAM-1 by IFN-gamma. Inhibition occurs at the time of induction, as CD4+ T cells are not capable of down-regulating previously induced class II Ag. CM from CD4+/EC (but not PBL/EC) cocultures also inhibits IFN-gamma induction of EC class II MHC expression. The inhibitory activity is generated during CD4+ T cell-EC cell contact, and is enhanced by PHA. The inhibitory activity(ies) of the CD4+/EC-CM is as yet unidentified, and is only minimally reversible by cocktails of neutralizing antibodies directed against TNF-alpha, TNF-beta (lymphotoxin), IFN-alpha and IFN-beta. In conclusion, CD4+ and CD8+ T cells are each effective activators of EC, but the patterns of activation produced by these subsets are quite distinct, largely due to generation of a soluble inhibitor(s) of class II MHC induction during coculture of CD4+ T cells with EC.     

Generation of T cell help through a MHC class I-restricted TCR

CD4+ T cells that are activated by a MHC class II/peptide encounter can induce maturation of APCs and promote cytotoxic CD8+ T cell responses. Unfortunately, the number of well-defined tumor-specific CD4+ T cell epitopes that can be exploited for adoptive immunotherapy is limited. To determine whether Th cell responses can be generated by redirecting CD4+ T cells to MHC class I ligands, we have introduced MHC class I-restricted TCRs into postthymic murine CD4+ T cells and examined CD4+ T cell activation and helper function in vitro and in vivo. These experiments indicate that Ag-specific CD4+ T cell help can be induced by the engagement of MHC class I-restricted TCRs in peripheral CD4+ T cells but that it is highly dependent on the coreceptor function of the CD8beta-chain. The ability to generate Th cell immunity by infusion of MHC class I-restricted Th cells may prove useful for the induction of tumor-specific T cell immunity in cases where MHC class II-associated epitopes are lacking.     

Partial activation of neonatal CD11c+ dendritic cells and induction of adult-like CD8+ cytotoxic T cell responses by synthetic microspheres

Neonatal cytotoxic T cell responses have only been elicited to date with immunogens or delivery systems inducing potent direct APC activation. To define the minimal activation requirements for the induction of neonatal CD8(+) cytotoxic responses, we used synthetic microspheres (MS) coated with a single CD8(+) T cell peptide from lymphocytic choriomeningitis virus (LCMV) or HIV-1. Unexpectedly, a single injection of peptide-conjugated MS without added adjuvant induced CD4-dependent Ag-specific neonatal murine cytotoxic responses with adult-like CTL precursor frequency, avidity for Ag, and frequency of IFN-gamma-secreting CD8(+) splenocytes. Neonatal CD8(+) T cell responses to MS-LCMV were elicited within 2 wk of a single immunization and, upon challenge, provided similar protection from viral replication as adult CTLs, demonstrating their in vivo competence. As previously reported, peptide-coated MS elicited no detectable activation of adult CD11c(+) dendritic cells (DC). In contrast, CTL responses were associated with a partial activation of neonatal CD11c(+) DC, reflected by the up-regulation of CD80 and CD86 expression but no concurrent changes in MHC class II or CD40 expression. However, this partial activation of neonatal DC was not sufficient to circumvent the requirement for CD4(+) T cell help. The effective induction of neonatal CD8(+) T cell responses by this minimal Ag delivery system demonstrates that neonatal CD11c(+) DC may mature sufficiently to stimulate naive CD8(+) neonatal T cells, even in the absence of strong maturation signals.     

Antigen chemically coupled to the surface of liposomes are cross-presented to CD8+ T cells and induce potent antitumor immunity

We have previously demonstrated that liposomes with differential lipid components display differential adjuvant effects when Ags are chemically coupled to their surfaces. In the present study, Ag presentation of liposome-coupled OVA was investigated in vitro, and it was found that OVA coupled to liposomes made using unsaturated fatty acid was presented to both CD4+ and CD8+ T cells, whereas OVA coupled to liposomes made using saturated fatty acid was presented only to CD4+ T cells. Confocal laser scanning microscopic analysis demonstrated that a portion of the OVA coupled to liposomes made using unsaturated, but not saturated fatty acid, received processing beyond the MHC class II compartment, suggesting that the degradation of OVA might occur in the cytosol, and that the peptides generated in this manner would be presented to CD8+ T cells via MHC class I. The ability to induce cross-presentation of an Ag coupled to liposomes consisting of unsaturated fatty acid was further confirmed by in vivo induction of CTL and by the induction of tumor eradication in mice; E.G7 tumors in mice that received combined inoculation with OVA(257-264)-liposome conjugates, CpG, and anti-IL-10 mAbs were completely eradicated. In those mice, the frequency of CD8+ T cells reactive with OVA(257-264) peptides in the context of H-2K(b) was significantly increased. These results suggested that, by choosing lipid components for liposomes, surface-coupled liposomal Ags might be applicable for the development of tumor vaccines to present tumor Ags to APCs and induce antitumor responses.     

Dendritic cells capture killed tumor cells and present their antigens to elicit tumor-specific immune responses

Due to their capacity to induce primary immune responses, dendritic cells (DC) are attractive vectors for immunotherapy of cancer. Yet the targeting of tumor Ags to DC remains a challenge. Here we show that immature human monocyte-derived DC capture various killed tumor cells, including Jurkat T cell lymphoma, malignant melanoma, and prostate carcinoma. DC loaded with killed tumor cells induce MHC class I- and class II-restricted proliferation of autologous CD8+ and CD4+ T cells, demonstrating cross-presentation of tumor cell-derived Ags. Furthermore, tumor-loaded DC elicit expansion of CTL with cytotoxic activity against the tumor cells used for immunization. CTL elicited by DC loaded with the PC3 prostate carcinoma cell bodies kill another prostate carcinoma cell line, DU145, suggesting recognition of shared Ags. Finally, CTL elicited by DC loaded with killed LNCap prostate carcinoma cells, which express prostate specific Ag (PSA), are able to kill PSA peptide-pulsed T2 cells. This demonstrates that induced CTL activity is not only due to alloantigens, and that alloantigens do not prevent the activation of T cells specific for tumor-associated Ags. This approach opens the possibility of using allogeneic tumor cells as a source of tumor Ag for antitumor therapies.     

Microbial and T cell-derived stimuli regulate antigen presentation by dendritic cells in vivo

B cells and dendritic cells (DC) internalize and degrade exogenous Ags and present them as peptides bound to MHC class II molecules for scrutiny by CD4(+) T cells. Here we use an Ab specific for a processed form of the model Ag, hen egg lysozyme (HEL), to demonstrate that this protein is not efficiently presented by lymph node DC following s.c. immunization. HEL presentation by the DC can be dramatically enhanced upon coinjection of a microbial adjuvant, which appears to act by enhancing peptide loading onto MHC class II. CD40 cross-linking or the presence of a high frequency of T cells specific for HEL can similarly improve presentation by DC in vivo. For any of these activating stimuli, CD8alpha(+) DC consistently display the highest proportion of HEL-loaded MHC class II molecules. These data indicate that exogenous Ags can be displayed to T cells in lymphoid tissues by a large cohort of resident DC whose presentation is regulated by innate and adaptive stimuli. Our data further reveal the existence of a feedback mechanism that augments Ag presentation during cognate APC-T cell interactions.     

Increased antigen presentation efficiency by coupling antigens to MHC class I trafficking signals

Genetic modification of vaccines by linking the Ag to lysosomal or endosomal targeting signals has been used to route Ags into MHC class II processing compartments for improvement of CD4+ T cell responses. We report in this study that combining an N-terminal leader peptide with an MHC class I trafficking signal (MITD) attached to the C terminus of the Ag strongly improves the presentation of MHC class I and class II epitopes in human and murine dendritic cells (DCs). Such chimeric fusion proteins display a maturation state-dependent subcellular distribution pattern in immature and mature DCs, mimicking the dynamic trafficking properties of MHC molecules. T cell response analysis in vitro and in mice immunized with DCs transfected with Ag-encoding RNA showed that MITD fusion proteins have a profoundly higher stimulatory capacity than wild-type controls. This results in efficient expansion of Ag-specific CD8+ and CD4+ T cells and improved effector functions. We used CMVpp65 and NY-ESO-1 Ags to study preformed immune responses in CMV-seropositive individuals and cancer patients. We show that linking these Ags to the MITD trafficking signal allows simultaneous, polyepitopic expansion of CD8+ and CD4+ T cells, resulting in distinct CD8+ T cell specificities and a surprisingly broad and variable Ag-specific CD4+ repertoire in different individuals.     

Archaeosomes induce long-term CD8+ cytotoxic T cell response to entrapped soluble protein by the exogenous cytosolic pathway, in the absence of CD4+ T cell help

The unique ether glycerolipids of ARCHAEA: can be formulated into vesicles (archaeosomes) with strong adjuvant activity for MHC class II presentation. Herein, we assess the ability of archaeosomes to facilitate MHC class I presentation of entrapped protein Ag. Immunization of mice with OVA entrapped in archaeosomes resulted in a potent Ag-specific CD8(+) T cell response, as measured by IFN-gamma production and cytolytic activity toward the immunodominant CTL epitope OVA(257-264). In contrast, administration of OVA with aluminum hydroxide or entrapped in conventional ester-phospholipid liposomes failed to evoke significant CTL response. The archaeosome-mediated CD8(+) T cell response was primarily perforin dependent because CTL activity was undetectable in perforin-deficient mice. Interestingly, a long-term CTL response was generated with a low Ag dose even in CD4(+) T cell deficient mice, indicating that the archaeosomes could mediate a potent T helper cell-independent CD8(+) T cell response. Macrophages incubated in vitro with OVA archaeosomes strongly stimulated cytokine production by OVA-specific CD8(+) T cells, indicating that archaeosomes efficiently delivered entrapped protein for MHC class I presentation. This processing of Ag was Brefeldin A sensitive, suggesting that the peptides were transported through the endoplasmic reticulum and presented by the cytosolic MHC class I pathway. Finally, archaeosomes induced a potent memory CTL response to OVA even 154 days after immunization. This correlated to strong Ag-specific up-regulation of CD44 on splenic CD8(+) T cells. Thus, delivery of proteins in self-adjuvanting archaeosomes represents a novel strategy for targeting exogenous Ags to the MHC class I pathway for induction of CTL response.     

Disruption of MHC class II-restricted antigen presentation by vaccinia virus

Vaccinia virus (VV), currently used in humans as a live vaccine for smallpox, can interfere with host immunity via several discrete mechanisms. In this study, the effect of VV on MHC class II-mediated Ag presentation was investigated. Following VV infection, the ability of professional and nonprofessional APC to present Ag and peptides to CD4+ T cells was impaired. Viral inhibition of class II Ag presentation could be detected within 1 h, with diminished T cell responses dependent upon the duration of APC infection and virus titer. Exposure of APC to replication-deficient virus also diminished class II Ag presentation. Virus infection of APC perturbed Ag presentation by newly synthesized and recycling class II molecules, with disruptions in both exogenous and cytoplasmic Ag presentation. Virus-driven expression of an endogenous Ag, failed to restore T cell responsiveness specific for this Ag in the context of MHC class II molecules. Yet, both class II protein steady-state and cell surface expression were not altered by VV. Biochemical and functional analysis revealed that VV infection directly interfered with ligand binding to class II molecules. Together, these observations suggest that disruption of MHC class II-mediated Ag presentation may be one of multiple strategies VV has evolved to escape host immune surveillance.     

Liposome-coupled antigens are internalized by antigen-presenting cells via pinocytosis and cross-presented to CD8 T cells

We have previously demonstrated that antigens chemically coupled to the surface of liposomes consisting of unsaturated fatty acids were cross-presented by antigen-presenting cells (APCs) to CD8+ T cells, and that this process resulted in the induction of antigen-specific cytotoxic T lymphocytes. In the present study, the mechanism by which the liposome-coupled antigens were cross-presented to CD8+ T cells by APCs was investigated. Confocal laser scanning microscopic analysis demonstrated that antigens coupled to the surface of unsaturated-fatty-acid-based liposomes received processing at both MHC class I and class II compartments, while most of the antigens coupled to the surface of saturated-fatty-acid-based liposomes received processing at the class II compartment. In addition, flow cytometric analysis demonstrated that antigens coupled to the surface of unsaturated-fatty-acid-liposomes were taken up by APCs even in a 4°C environment; this was not true of saturated-fatty-acid-liposomes. When two kinds of inhibitors, dimethylamiloride (DMA) and cytochalasin B, which inhibit pinocytosis and phagocytosis by APCs, respectively, were added to the culture of APCs prior to the antigen pulse, DMA but not cytochalasin B significantly reduced uptake of liposome-coupled antigens. Further analysis of intracellular trafficking of liposomal antigens using confocal laser scanning microscopy revealed that a portion of liposome-coupled antigens taken up by APCs were delivered to the lysosome compartment. In agreement with the reduction of antigen uptake by APCs, antigen presentation by APCs was significantly inhibited by DMA, and resulted in the reduction of IFN-γ production by antigen-specific CD8+ T cells. These results suggest that antigens coupled to the surface of liposomes consisting of unsaturated fatty acids might be pinocytosed by APCs, loaded onto the class I MHC processing pathway, and presented to CD8+ T cells. Thus, these liposome-coupled antigens are expected to be applicable for the development of vaccines that induce cellular immunity.     

Some cloned murine CD4+ T cells recognize H-2Ld class I MHC determinants directly. Other cloned CD4+ T cells recognize H-2Ld class I MHC determinants in the context of class II MHC molecules.

Murine T lymphocytes recognize nominal Ag presented by class I or class II MHC molecules. Most CD8+ T cells recognize Ag presented in the context of class I molecules, whereas most CD4+ cells recognize Ag associated with class II molecules. However, it has been shown that a proportion of T cells recognizing class I alloantigens express CD4 surface molecules. Furthermore, CD4+ T cells are sufficient for the rejection of H-2Kbm10 and H-2Kbm11 class I disparate skin grafts. It has been suggested that the CD4 component of an anti-class I response can be ascribed to T cells recognizing class I determinants in the context of class II MHC products. To examine the specificity and effector functions of class I-specific HTL, CD4+ T cells were stimulated with APC that differed from them at a class I locus. Specifically, a MLC was prepared involving an allogeneic difference only at the Ld region. CD4+ clones were derived by limiting dilution of bulk MLC cells. Two clones have been studied in detail. The CD4+ clone 46.2 produced IL-2, IL-3, and IFN-gamma when stimulated with anti-CD3 mAb, whereas the CD4+ clone 93.1 secreted IL-4 in addition to IL-2, IL-3, and IFN-gamma. Cloned 46.2 cells recognized H-2Ld directly, whereas recognition of Ld by 93.1 apparently was restricted by class II MHC molecules. Furthermore, cytolysis by both clones 46.2 and 93.1 was inhibited by the anti-CD4 mAb GK1.5. These results demonstrate that CD4+ T cells can respond to a class I difference and that a proportion of CD4+ T cells can recognize class I MHC determinants directly as well as in the context of class II MHC molecules.