Weak base amines can inhibit class I MHC-restricted antigen presentation

This report describes the effects of NH4Cl, CH3NH2, and chloroquine on class I and II MHC-restricted Ag presentation. OVA-specific T-T hybridomas were used to detect processed OVA in association with class I, H-2Kb, and class II, I-Ad/b, molecules on a B lymphoblastoid APC. OVA, internalized by APC under hypertonic conditions, was presented in association with class I and II MHC molecules. Treating the APC with NH4Cl or CH3NH2 inhibited class I- and II-restricted Ag presentation. In contrast, chloroquine markedly inhibited class II, but not class I-restricted Ag presentation. Controls indicated that drug-treated APC were fully competent to interact with T cells and present processing-independent antigenic peptides in association with both class I and II MHC molecules. NH4Cl and CH3NH2 did not inhibit the uptake of radiolabeled Ag by the APC. After the proteolytic removal of H-2Kb from the surface of APC, NH4Cl and CH3NH2-treated and control APC regenerated identical amounts of surface H-2Kb and this regeneration required de novo protein synthesis. These latter results indicate that NH4Cl and CH3NH2 can inhibit Ag presentation without affecting the synthesis, transport, or surface expression of H-2Kb. Also, NH4Cl did not affect the transport of H-2Db to the surface of mutant RMA-S cells that were cultured with exogenous peptides. Taken together these results strongly suggest that NH4Cl and CH3NH2 but not chloroquine can inhibit a critical and early intracellular step in class I-restricted Ag presentation while simultaneously inhibiting class II-restricted Ag presentation.     

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.     

Antigen form influences induction and frequency of influenza-specific class I and class II MHC-restricted cytolytic T lymphocytes

The induction of class I and class II MHC-restricted CTL in response to different forms of A/JAP/57 influenza virus was compared. Splenocytes removed from influenza-immune BALB/c mice and stimulated in vitro with infected syngeneic splenocytes are mainly CD8+ (Lyt-2+) and specifically lyse infected Ia- and Ia+ target cells. To a lesser extent they also lyse non-infectious virus-pulsed Ia+ but not Ia- target cells. In contrast, syngeneic stimulators pulsed with non-infectious virus (exogenous Ag) induce effector T cells that specifically lyse both infected and non-infectious virus-pulsed Ia+ target cells. The cells present in this heterogeneous culture predominantly express the CD4 (L3T4) cell surface marker. Frequency analysis by limiting dilution of splenocytes derived directly from influenza-immune mice revealed a similar pattern of precursor induction: In vitro stimulation with infected splenocytes yielded primarily class I MHC-restricted CTL, whereas stimulation with non-infectious virus reciprocally induced primarily class II MHC-restricted CTL. Thus, the Ag form and consequently the intracellular route of viral Ag presentation profoundly influence the MHC restriction of CTL precursors induced.     

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.     

MHC class I-restricted presentation of exogenous antigen by thymic antigen-presenting cells in vitro and in vivo.

We have used a T-T hybridoma, RF33.70, to detect the MHC class I-restricted presentation of exogenous native OVA by thymic APC in vitro. Presentation of OVA with class I molecules by thymic APC requires intracellular processing. Phenotypic analyses indicated that low bouyant density, MHC class II+, FcR+ cells are capable of using this presentation pathway. In order to determine whether thymic APC have this function in vivo, thymic APC were isolated from mice after i.v. injection of native OVA. We find that OVA is presented in association with MHC class I, but not class II, molecules in the thymus. This is in contrast to splenic APC, which present exogenous OVA with both class I and class II molecules under these conditions. Our findings have implications for the repertoire of self-peptides that might be presented by thymic APC to developing T lymphocytes.     

Formation of complexes between self-peptides and MHC class II molecules in cells defective for presentation of exogenous protein antigens.

A vertebrate immune response is initiated by the presentation of foreign protein Ag to MHC class II-restricted T lymphocytes by specialized APC. Presentation of self-peptides in association with MHC class II molecules is also necessary for the induction of T cell tolerance. It is important to understand whether functionally divergent APC are responsible for delivering these distinct signals to class II-restricted T cells. Here we examine the ability of I-Ad surface molecules expressed in diverse cell types to stimulate I-Ad-restricted T cells. Recipients included J558L myeloma cells and EL4 lymphoma cells expressing barely detectable or undetectable levels of Ii chain mRNA. This allowed us to examine the influence of Ii expression on the presentation of intracellular Ag and thus test the hypothesis that Ii chain is necessary to prevent access of self-peptides to newly synthesized class II molecules. Ii chain expression did not restore the ability of transformants to process and present soluble protein Ag. A striking result was the finding that cells showing a defect in the exogenous class II presentation pathway were capable of functioning as stimulators when they expressed intracellular secreted but not signal-less V-CH3b Ag. Thus, so-called professional APC that can capture and process exogenous protein Ag may express a specialized set of proteins not required for the presentation of self-peptides.     

Class I-restricted presentation occurs without internalization or processing of exogenous antigenic peptides

Previous studies have shown that glutaraldehyde-fixed cells can present fragmented, but not native, Ag to class II-restricted T cells. This presumably occurs via direct binding of peptides to class II molecules at the cell surface. More recently, it has been shown that viable target cells can present peptides and endogenous, but not exogenous, protein Ag in association with class I MHC molecules to CTL. We have derived CTL specific for a chicken OVA peptide (OVA258-276) recognized in association with H-2Kb. These CTL recognize target cells that endogenously synthesize OVA and cells "loaded" with native OVA but fail to recognize target cells in the presence of exogenous native OVA. Thus, OVA must be intracellularly located to be processed and presented for CTL recognition. It remains unclear, however, whether exogenous peptides require internalization and further processing by target cells or are able to associate directly with class I molecules at the cell surface for CTL recognition. We provide evidence that glutaraldehyde-fixed cells can present synthetic peptides to H-2Kb- and H-2Db-restricted CTL and that such presentation does not require internalization or processing. The peptides used range in size from 16 to 48 amino acids in length. In contrast, glutaraldehyde-fixed cells are incapable of presenting Ag to CTL specific for influenza nucleoprotein and OVA if the cells are fixed within 1 h of viral influenza infection or loading with OVA. Thus, CTL recognition of antigenic peptides appears to occur via direct binding of peptides to class I molecules at the cell surface and does not require any intracellular processing events.     

Induction of cytotoxic T lymphocytes in vivo with protein antigen entrapped in membranous vehicles.

Intravenous administration of APC such as splenocytes loaded with a soluble protein Ag has been shown to prime for an Ag-specific CTL response. It is thought that the APC directly presents loaded Ag in a MHC-restricted manner. However, it is demonstrated in this study that allogeneic splenocytes, MHC-free RBC, and even synthetic lipid vesicles (liposomes) after loading with OVA can elicit an OVA-specific and MHC-restricted CTL response. Biodistribution studies of these Ag-associated vehicles showed that the liver, spleen, and lung were the major organs responsible to scavenge these carriers, suggesting that the monocyte-macrophage system was involved in the Ag presentation for CTL. Depletion of macrophages by a specific macrophage killer, Cl2MDP, containing liposomes, abolished the CTL induction by immunization with OVA Ag carried by these vehicles except the induction by syngeneic splenocytes. Thus, the syngeneic splenocytes present Ag directly to the T cells, but other membranous vehicles carry the Ag to the host APC including macrophages, which then present it to the T cells. These results indicate that formulation of an Ag in membranous/colloidal vehicles may be a way to prime for a CTL response.     

Macrophages present pinocytosed exogenous antigen via MHC class I whereas antigen ingested by receptor-mediated endocytosis is presented via MHC class II

Macrophages present exogenous Ag either via MHC class I or MHC class II molecules. We investigated whether the mode of hemagglutinin (HA) uptake influences the class of MHC molecule by which this Ag is presented. Normally, HA is ingested by receptor-mediated endocytosis, but this may be switched to macropinocytosis and pinocytosis by adding phorbol esters to the cells. This switch resulted in altered intracellular routing of ingested Ag and a transition from Ag presentation via MHC class II molecules to presentation via MHC class I molecules. Similarly, inhibition of receptor-mediated HA endocytosis, by treating the cells with the HA receptor destroying enzyme neuraminidase, abrogated Ag presentation via MHC class II molecules and induced presentation via MHC class I molecules. If, however, under these conditions, receptor-mediated uptake of HA was restored, by virtue of HA/anti-HA Ab interaction and subsequent uptake of HA via the Fc receptor, presentation via MHC class II was restored as well, whereas presentation of HA via MHC class I molecules was no longer detectable. We conclude that in macrophages the mode of Ag uptake is decisive in determining via which class of MHC molecules Ag is presented: pinocytosis and macropinocytosis produce exclusive presentation of exogenous Ag via MHC class I molecules whereas receptor-mediated endocytosis leads exclusively to presentation via class II molecules.     

Induction of MHC class I presentation of exogenous antigen by dendritic cells is controlled by CD4+ T cells engaging class II molecules in cholesterol-rich domains.

We investigated interactions between CD4+ T cells and dendritic cells (DC) necessary for presentation of exogenous Ag by DC to CD8+ T cells. CD4+ T cells responding to their cognate Ag presented by MHC class II molecules of DC were necessary for induction of CD8+ T cell responses to MHC class I-associated Ag, but their ability to do so depended on the manner in which class II-peptide complexes were formed. DC derived from short-term mouse bone marrow culture efficiently took up Ag encapsulated in IgG FcR-targeted liposomes and stimulated CD4+ T cell responses to Ag-derived peptides associated with class II molecules. This CD4+ T cell-DC interaction resulted in expression by the DC of complexes of class I molecules and peptides from the Ag delivered in liposomes and permitted expression of the activation marker CD69 and cytotoxic responses by naive CD8+ T cells. However, while free peptides in solution loaded onto DC class II molecules could stimulate IL-2 production by CD4+ T cells as efficiently as peptides derived from endocytosed Ag, they could not stimulate induction of cytotoxic responses by CD8+ T cells to Ag delivered in liposomes into the same DC. Signals requiring class II molecules loaded with endocytosed Ag, but not free peptide, were inhibited by methyl-beta-cyclodextrin, which depletes cell membrane cholesterol. CD4+ T cell signals thus require class II molecules in cholesterol-rich domains of DC for induction of CD8+ T cell responses to exogenous Ag by inducing DC to process this Ag for class I presentation.     

Invariant chain alters the malignant phenotype of MHC class II+ tumor cells.

T lymphocytes usually recognize endogenously encoded Ag in the context of MHC class I molecules, whereas exogenous Ag is usually presented by MHC class II molecules. In vitro studies in model systems suggest that presentation of endogenous Ag by class II molecules is inhibited by the association of class II with its invariant chain (Ii). In the present study we test this hypothesis in an in vivo system in which endogenously encoded tumor peptides are presented by tumor cell MHC class II molecules. In this system, transfection of syngeneic MHC class II genes (Aak and Abk) into a highly malignant, Ii negative, mouse tumor (SaI sarcoma) produces an immunogenic tumor (SaI/Ak) that is rejected by the autologous host. The class II+ transfectants also effectively immunize autologous A/J mice against a subsequent challenge of wild-type class II- tumor cells. We have hypothesized that the SaI/Ak transfectants induce protective immunity because they function as APC for endogenously synthesized tumor peptides, and thereby stimulate tumor-specific Th cells, by-passing the need for professional APC. To test the role of Ii as an inhibitor of presentation of endogenous peptides, SaI/Ak tumor cells were supertransfected with Ii gene (SaI/Ak/Ii cells), and the tumorigenicity of the resulting cells determined. Nine SaI/Ak/Ii clones were tested, and their malignancy compared with that of SaI/Ak and SaI cells. Seven of the nine class II+/Ii+ tumor cells are more malignant than class II+/Ii- tumor cells in autologous A/J mice. Expression of Ii therefore restores the malignant phenotype, presumably by preventing presentation of endogenously synthesized tumor peptides. Ii therefore regulates Ag presentation and can be a critical parameter for in vivo tumor immunity.     

The class II MHC-restricted presentation of endogenously synthesized ovalbumin displays clonal variation, requires endosomal/lysosomal processing, and is up-regulated by heat shock.

LB27.4 cells (a B lymphoblastoid APC) were transfected with a plasmid containing an OVA cDNA. Functional analysis of six independent clones yielded three patterns of MHC-restricted presentation of the endogenously synthesized OVA. A clone displayed either: 1) strong class I and class II-restricted presentation, 2) strong class I but little or no class II-restricted presentation or, 3) only a modest class I-restricted presentation. There was no clonal variation in class II-restricted presentation of exogenous Ag or in the amount of surface class I or II molecules. Heat shock increased the presentation of endogenous but not exogenous Ag with class II. These results indicate that an endogenously synthesized Ag both constitutively and during heat shock can gain access to the class II, MHC-restricted, presentation pathway. The amount of OVA synthesized by a cell correlated with whether OVA-class II complexes were detected. However, the amount of OVA secreted into the extracellular fluid was not sufficient to sensitize APC, which suggests that endogenously synthesized OVA enters the class II pathway of Ag presentation by an intracellular route rather than by an extracellular/reuptake route. Also, the functional and quantitative analysis of the clones suggests that endogenously synthesized OVA was presented more efficiently with class I as compared to class II-MHC molecules. Leupeptin and chloroquine inhibited the class II-restricted presentation of endogenously synthesized OVA. Together these results indicate that endogenously synthesized OVA can gain access to an endosomal/lysosomal compartment via an intracellular route and be processed and presented in association with class II-MHC molecules.     

Mutations affecting antigen processing impair class II-restricted allorecognition

Both exogenously derived and endogenously derived Ag generally require processing for their optimal binding and presentation by class I and class II major histocompatibility proteins. It is not known whether steps involved in Ag processing also affect the recognition of alloreactive T cells. We have recently described B cell mutants which have general defects in the processing and presentation of a variety of exogenous Ag to class II restricted T cells. In this report we have studied the ability of these processing mutants to stimulate a set of anti-DR3-specific alloreactive T cells clones. These processing/presentation mutants express normal MHC class II molecules, both in terms of primary sequence and cell surface abundance, but they appear unable to generate effective peptide-MHC complexes. When tested for their ability to stimulate MHC class II alloreactive T cell clones, only one of four T cell clones was stimulated by these mutants; the other three alloreactive T cell clones were not stimulated by either of two different mutants. Both of these mutants express normal levels of the accessory molecules, LFA-3 and ICAM-1. The inability of these mutants to stimulate three of four alloreactive clones indicates that the capacity to be recognized by many alloreactive T cells is linked to the Ag processing capacity of a stimulator cell.     

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.     

Generation of class I MHC-restricted T-T hybridomas

In this report we describe a system for the generation of functional, class I MHC-restricted, T-T hybridomas. The BW5147 cell line was transfected with the CD8 gene. BW5147 transfectants were obtained that stably expressed CD8 and this expression was maintained after somatic cell hybridization with activated T lymphocytes. To determine whether the stable expression of CD8 would facilitate the generation of class I MHC-specific T-T hybridomas, the transfected cells were fused with alloreactive T cells and the resultant hybrids were screened for their ability to produce lymphokines in response to antigenic stimulation. Somatic cell hybridizations with BW5147-CD8 transfectants give rise to a much higher frequency of class I MHC-specific T-T hybridomas relative to parallel fusions with BW5147. To determine whether the BW5147-CD8 transfectants would also support the generation of Ag-specific, class I MHC-restricted T-T hybridomas, they were fused with OVA-specific CTL. Several T-T hybrid clones were identified that produced lymphokines after stimulation with a transfected APC that was synthesizing OVA, or with a tryptic digest of OVA in the presence of syngeneic APC. The stimulation by Ag was MHC-restricted and mapped to the Kb molecule. An anti-CD8 mAb inhibited the stimulation of these hybridomas by Ag plus APC, whereas their stimulation by mitogen was unaffected. Cytolytic activity was not detected when several of the OVA-specific or alloreactive hybridomas were tested for their ability to kill target cells bearing the appropriate Ag. These results demonstrate that the BW5147-CD8 transfectants allow the generation of class I MHC-restricted T-T hybridomas. The potential utility of this system is discussed.     

Antigen-presenting cell-T cell interaction in the chicken is MHC class II antigen restricted

The involvement of the MHC in the recognition of Ag by avian T lymphocytes was analyzed. PBL from chickens primed with keyhole limpet hemocyanin in vivo were induced to synthesize DNA in an in vitro response to specific Ag. Responding cells were T cells as judged by immunofluorescence staining. In vivo Ag-primed PBL were stimulated in vitro with specific Ag and further propagated in the presence of IL-2. Subsequent Ag-specific T cell proliferation required the presence of Ag-pulsed peripheral blood adherent cells (APC). T cell responses were restricted by the MHC of the APC; Ag presented by allogeneic APC did not support T cell proliferation. By using MHC-recombinant chicken lines, the gene products controlled by MHC class II loci were shown to restrict the T cell-APC interaction. This conclusion was substantiated by the inhibition of the Ag-specific T cell response by a mAb against chicken MHC class II gene products but not by a mAb against chicken MHC class I gene products.     

Macrophages as accessory cells for class I MHC-restricted immune responses.

Ag do not elicit T lymphocyte responses unless they are presented in conjunction with MHC molecules on the surface of an appropriate APC. In the case of CD4+ T lymphocytes dendritic cells can deliver all signals required for complete induction as can macrophages and (activated) B cells. The function of CTL also depends on the presence of specialized accessory cells. Here we show that these accessory cells can behave like scavenger cells. They use foreign Ag in the form of cellular debris as immunogen. They are also crucial for CTL induction because in vivo depletion of phagocytotic cells completely inhibits CTL responses. In these animals CTL activity could be restored by transfer of macrophages. All of the reappearing CTL used MHC restriction elements expressed by the infused macrophages. These experiments suggest that a cognate interaction between macrophages and CTL precursors initiates class I MHC-restricted immune responses.     

The HSC73 molecular chaperone: involvement in MHC class II antigen presentation.

Heat shock proteins (HSP) are conserved proteins, many of which share the ability for indiscriminate peptide binding and ATPase-coupled peptide release. In this paper, we show that heat shock cognate protein (HSC)73, a constitutively expressed member of the HSP70 family, could be a candidate for chaperone activity within the MHC class II presentation pathway. HSC73 expression in macrophages was shown to overlap with expression of MHC class II; overexpression of HSC73 in stable transfectants of a macrophage line markedly enhanced their presentation of exogenous Ag without affecting presentation of processing independent peptide. Ag from an exogenous source was demonstrated to associate with HSC73 in macrophages, and this association was sensitive to ATP treatment and inhibited by deoxyspergualin, an immunosuppressive agent that has previously been shown to bind specifically to HSC73. Furthermore, deoxyspergualin reduced Ag presentation by macrophages in relation to the amount of HSC73 expressed in these cells. The data are consistent with a potential role for HSC73 in binding and protecting peptides from extensive degradation and/or facilitating the kinetics of peptide transfer to MHC class II molecules.     

Role of ICAM-1 in antigen presentation demonstrated by ICAM-1 defective mutants

We report a methodology for selecting APC with mutations that have impaired their ability to present Ag to T cells. A20 B lymphoblastoid cells were mutagenized and then repeatedly cocultured with murine T-T hybridomas in the presence of specific Ag. During these cocultures, the T-T hybridomas kill the competent APC, allowing the outgrowth of inactive variants. Two variants, A20.M1 and A20.M2, were isolated and studied in detail. These variants are impaired in their ability to present multiple Ag to T cells. This defect is also observed for the presentation of processing independent peptides by fixed APC indicating that a lesion exists in a post-Ag processing step. The level of expression of MHC molecules is unaffected and the functional defect in the APC is not localized to a particular MHC molecule. In contrast, these mutants were found to have a selective decrease in the expression of the murine homolog of ICAM-1, and the residual ability of these cells to present Ag was not blocked by anti-ICAM-1 mAb. Conversely, Ag presentation by the wild-type A20 is inhibited by anti-ICAM-1 mAb. Similarly, anti-LFA-1 mAb inhibited the response of T cells to Ag presented by the wild-type A20 to a much greater degree than by the mutant cells, indicating that LFA-1 is involved in interaction of T cells with the former, but not latter, APC. In the apparent absence of a contribution of LFA-1 to the T cell-APC interaction, either as a result of mAb blocking or the disruption of the APC membrane, the mutant and wild-type APC have a similar level of Ag-presenting activity. Reconstitution of ICAM-1 expression in these mutants by transfection with murine ICAM-1 cDNA fully restores their ability to present Ag. Together these results demonstrate that a murine ICAM-1 homolog is expressed on A20 B cells, where it functions as a major cell interaction molecule. The degree of functional impairment in these mutant APC gives insight into the contribution of cell interaction molecules to efficient Ag presentation and T cell-B cell interaction. Finally, these results also demonstrate the feasibility of selecting APC with mutations affecting Ag presentation.     

Specificity, phenotype, and precursor frequency of primary cytolytic T lymphocytes specific for class II major histocompatibility antigens

Most cytolytic T lymphocytes (CTL) recognize class I rather than class II MHC determinants, and relatively little is known about those CTL that do recognize class II MHC determinants. The present study was undertaken to document the specificity, phenotype, and precursor frequency of primary class II allospecific CTL. It was found that class II-allospecific CTL could be consistently generated in vitro from unprimed spleen or thymus populations in the presence of exogenously added helper factors. The class II MHC specificity of both the precursor and CTL effectors activated in primary cultures by Ia-disparate stimulator cells was documented both by blocking experiments with anti-Ia mAb and by the use of L cell transfectants. The mechanism by which primary allospecific CTL effectors lysed their targets appeared to involve direct cell-cell contact, because they failed to lyse bystander target cells. The frequency in unprimed spleen populations of precursor CTL specific for class II alloantigens was examined by limiting dilution analysis and was found to be as high as 1/15,000 splenocytes and approximately 10% of the frequency reported for primary class I allospecific CTL. Finally, the Lyt phenotype of primary class II allospecific CTL precursors and effectors was determined. It was found that anti-class II CTL derive from at least two distinct precursor subpopulations that are either L3T4+Lyt-2- or L3T4-Lyt-2+, and that the Lyt phenotype expressed by the CTL effectors are concordant with that of their precursors. No correlation was found between the I subregion gene products recognized by CTL effectors and the Lyt phenotype they expressed in that both I-A- and I-E-specific CTL were both L3T4+Lyt-2- and L3T4-Lyt-2+.