Functional mapping of MHC class II polymorphic residues. The alpha-chain controls the specificity for binding an Ad-versus an A k-restricted peptide and the beta-chain region 65-67 controls T cell recognition but not peptide binding.

MHC proteins are polymorphic cell surface glycoproteins involved in the binding of peptide Ag and their presentation to T lymphocytes. The polymorphic amino acids of MHC proteins are primarily located in the N-terminal domains and are thought to influence T cell recognition both by influencing the binding of peptide Ag and by direct contact with the T cell receptor. In order to determine the relative importance of individual polymorphic amino acids in Ag presentation, a number of groups have taken the approach of interchanging polymorphic amino acids between different alleles of MHC protein in an attempt to define which of the polymorphisms influence peptide binding and which influence T cell recognition by direct contact with the TCR. The peptide OVA323-339 has been previously shown to bind to the MHC class II protein Ad and to have a much lower affinity for Ak, whereas the peptide hen egg lysozyme 46-61 binds well to Ak and poorly to Ad. In the present report, we have analyzed the ability of purified wild-type MHC class II proteins as well as the ability of three different hybrid molecules between Ad and Ak to bind and present these peptides. We find that the alpha-chain of the MHC class II protein plays a critical role in the binding of HEL46-61 and confers the specificity for binding OVA323-339, regardless of which beta-chain is present. We also find that the beta-chain region 65-67 does not control the specificity of peptide binding to the MHC protein, but is important in T cell responses to preformed MHC-peptide complexes, suggesting a role for this region in contacting the TCR.     

Analysis of the interaction of peptide hen egg white lysozyme (34-45) with the I-Ak molecule

We examined the structural characteristics of a peptide Ag that determine its ability to interact with class II-MHC molecules and TCR. The studies reported here focused on recognition of the hen egg white lysozyme (HEL) tryptic fragment HEL(34-45) by two I-Ak-restricted T cell hybridomas. HEL(34-45) bound to I-Ak created more than one antigenic specificity. Experiments with truncated peptides and alanine-substituted peptides indicated that two T cell hybrids either recognized distinct regions of the HEL(34-45) peptide, or different determinants generated by interaction of the peptide with I-Ak. Although we identified residues of HEL(34-45) that were critical to T cell recognition, no positions in the peptide were identified as I-Ak contact sites using single alanine substitutions. This suggests that more than one site or region of the peptide contributes to the binding to I-Ak. Finally, the murine lysozyme equivalent of 34-45 did not bind to I-Ak. Substitution of the corresponding murine lysozyme (self) residue at position 41 of HEL(34-45) abrogated I-Ak binding of the peptide.     

Binding to Ia protects an immunogenic peptide from proteolytic degradation

A 34 amino acid hen egg-white lysozyme (HEL) peptide was designed and synthesized to investigate if an immunogenic peptide once bound to an Ia molecule becomes proteolytically inaccessible. The determinant recognized by T cells, HEL(52-61) was composed of L-amino acids whereas the 12 amino acid extension on each side of this core were composed of D-epimers. This peptide, HEL(40-73) was resistant to proteolysis, except in the core region, where any cleavage would destroy the determinant. Initially HEL(40-73) was shown to be able to stimulate the HEL specific T cell, 3A9, indicating that an I-Ak molecule can bind and present large peptides that extend beyond the theoretical binding groove. HEL(40-73) was then used to examine the proteolytic sensitivity of determinants recognized by T cells. If HEL(40-73) was treated with chymotrypsin before binding to I-Ak, the determinant was totally destroyed; however, if HEL(40-73) was allowed to first bind to I-Ak, then the determinant became resistant to chymotrypsin cleavage. Thus an Ia molecule can protect a determinant from proteolytic degradation, a finding that has important implications for proposed pathways of Ag processing.     

Analysis of adjuvant function by direct visualization of antigen presentation in vivo: endotoxin promotes accumulation of antigen-bearing dendritic cells in the T cell areas of lymphoid tissue.

T cell activation requires exposure to processed Ag and signaling by cytokines and costimulatory ligands. Adjuvants are thought to enhance immunity primarily through up-regulation of the latter signals. Here, we explore the effect of the bacterial adjuvant, endotoxin, on Ag presentation by B cells and dendritic cells (DC). Using an mAb (C4H3) specific for the hen egg lysozyme (HEL) 46-61 determinant bound to I-Ak, we analyze processed Ag expression and the tissue distribution of presenting cells following systemic administration of soluble HEL to mice. In both LPS-responsive and -hyporesponsive mice given endotoxin-containing HEL, B cells rapidly display surface 46-61/I-Ak complexes. In marked contrast, in LPS-hyporesponsive mice, splenic DC show little gain in C4H3 staining. In LPS-responsive animals, interdigitating DC in T cell areas show no staining above background at early times after HEL administration, but C4H3+ DC rapidly accumulate in the outer periarteriolar lymphoid sheaths (PALS) and in follicular areas. Within a few hours, C4H3+ DC appear in the T cell areas, concomitant with a decline in C4H3+ cells in the outer PALS, suggesting migration between these two sites. Endotoxin enhancement of C4H3 staining is seen for both CD8alpha- and CD8alpha+ DC subsets. These data suggest that a major effect of adjuvants is to promote mobilization of Ag-bearing DC to the T areas of lymphoid tissue, and possibly also to enhance Ag processing by these DC. Thus, microbial products promote T cell immunity not only through DC activation for cosignaling, but through improvement in signal 1 delivery.     

I-Ak polymorphisms define a functionally dominant region for the presentation of hen egg lysozyme peptides

The class II molecules of the MHC not only bind processed antigenic peptides but also interact with the TCR. This latter interaction is thought to be the basis for allele specific "restriction" of Ag presentation to T cells. The specificity of this interaction is likely due to amino acid differences in a small number of polymorphic or "hypervariable" regions located in the amino terminal domains of the alpha- and beta-chains. We have explored the functional significance of these polymorphic regions in an I-Ak-restricted, hen egg lysozyme specific Ag presentation system in which the measurement of IL-2 production by T cell hybridomas was used as the indicator of TCR recognition of the I-A/Ag complex. Chimeric I-A molecules, in which b allelic residues were substituted in one or more of the polymorphic regions of the A alpha k chain or in which d allelic residues were substituted in one or more of the polymorphic regions of the A beta k chain, were used to examine the contribution of each polymorphic region of the molecule to its function. The results obtained demonstrate that the regions between residues 69 to 76 of the A alpha k chain and the regions between residues 63 to 67 and 75 to 78 of the A beta k-chain exert a dominant effect on the presentation of lysozyme peptides by I-Ak to the T cell hybridomas in our panel. These observations were confirmed and extended by the analysis of Ag presentation by seven serologically selected mutants, all of which have amino acid interchanges in or around the dominant polymorphic regions. The results suggest that the serologically selected mutants fail to present Ag not because they fail to bind the peptide Ag but because the amino acid substitutions destabilize the interaction between the Ia/peptide complex and the TCR. Use of the recently published hypothetical model for class II structure to interpret the Ag presentation results suggests that the dominant polymorphic regions lie across from one another near one end of the alpha-helices that form the two walls of the proposed Ag-binding cleft located on the top surface of the class II molecule. Furthermore, the majority of the amino acids which have been changed in the serologically selected mutants have side chains which are postulated to point up toward the exterior of the molecule and would, therefore, be potential contact residues for the TCR.     

The extracellular domains of MHC class II molecules determine their processing requirements for antigen presentation

We have evaluated the relative contributions of the extracellular and cytoplasmic domains of MHC class II molecules in determining the Ag-processing requirements for class II-restricted Ag presentation to T cells. Hybrid genes were constructed to encode a heterodimeric I-Ak molecule in which the extracellular portion of the molecule resembled wild type I-Ak but where the connecting stalk, transmembrane and cytoplasmic domains of both the alpha- and beta-chain were derived from the class I molecule H-2Dd. Mutant I-Ak molecules were expressed as heterodimeric membrane glycoproteins reactive with mAb specific for wild type I-Ak. Fibroblast and B lymphoma cells expressing either wild type or mutant I-Ak molecules were able to process and present hen egg lysozyme (HEL) and conalbumin to Ag-specific, I-Ak-restricted, T cell hybridomas or clones. The mutant-expressing cells presented native and peptide Ag less efficiently than the wild type-expressing cells, suggesting that the disparity in presentation efficiency was not due to a difference in Ag processing. CD4 interaction was intact on the mutant I-Ak molecules. Presentation of native Ag by mutant and wild type-I-Ak-expressing cells was abolished by preincubation with chloroquine, or after paraformaldehyde fixation. After transfection of a cDNA encoding the gene for HEL, neither mutant nor wild type-I-Ak-expressing cells presented endogenously synthesized HEL to a specific T hybrid. Newly synthesized mutant I-Ak molecules were associated with invariant chain. These data demonstrate the ability of hybrid class II molecules to associate intracellularly with invariant chain and degraded foreign Ag in a conventional class II-restricted processing pathway indicating that the extracellular domains of class II molecules play a dominant role in controlling these Ag-processing requirements.     

Processing and reactivity of T cell epitopes containing two cysteine residues from hen egg-white lysozyme (HEL74-90)

The Ag processing and structural requirements involved in the generation of a major T cell epitope from the hen egg-white lysozyme protein (HEL74-88), containing two cysteine residues at positions 76 and 80, were investigated. Several T cell hybridomas derived from both low responder (I-Ab) and high responder (I-Ak) mice recognize this region. These hybridomas are strongly responsive to native HEL, but unresponsive to the reduced and carboxymethylated protein. Air-oxidized HEL74-88 peptide was unable to bind I-Ak molecules and failed to stimulate T cells in the absence of intracellular Ag processing. Further functional competition assays showed that alkylation of cysteine residues with bulky methyl groups interferes with the contacts for the MHC class II molecules (I-Ak) of high responder mice and the I-Ab-restricted TCR of low responder mice. Serine substitutions of the cysteine residues of HEL74-88 either enhanced or abrogated T cell stimulation by the peptides without significant alterations in the class II binding. These results suggest that the cysteine residues of peptides must be free from disulfide bonding for efficient stimulation of T cells and yet frequently used modifications of cysteine residues may not be suitable for peptide-based vaccine development.     

Co-dominant restriction by a mixed-haplotype I-A molecule (alpha k beta b) for the lysozyme peptide 52-61 in H-2k x H-2b F1 mice

Helper (CD4+) T lymphocytes recognize protein Ag as peptides associated to MHC class II molecules. The polymorphism of class II alpha- and beta-chains has a major influence on the nature of the peptides presented to CD4+ T lymphocytes. For instance, T cell responses in H-2k and H-2b mice are directed at different epitopes of the hen egg lysozyme (HEL) molecule. The current studies were undertaken with the aim of defining the role of mixed haplotype I-A (alpha k beta b and alpha b beta k) molecules in T cell responses to HEL in (H-2k x H-2b)F1 mice, as well as the nature of the immunogenic peptides of HEL recognized in the context of I-A alpha k beta b and I-A alpha b beta k. A series of HEL-reactive T cell lines and hybridomas derived from MHC class II heterozygous (C57BL/6 x C3H F1) mice were established. Their responsiveness to HEL and synthetic HEL peptides was analyzed with the use of L cells transfected with either I-A alpha k beta b or I-A alpha b beta k as APC. Out of 28 clonal T cell hybridomas tested, 13 (46%) only responded to HEL presented by I-A alpha k beta b, 11 (40%) by I-A alpha b beta k (and to a minor extent I-A alpha k beta k), only 4 (14%) were primarily restricted by I-Ak, and none by I-Ab. All the I-A alpha k beta b-restricted T cell hybridomas responded to the HEL peptide 46-61 and to its shorter fragment 52-61, even at concentrations as low as 0.3 nM. As this determinant has been previously defined as immunodominant for I-Ak but not for I-Ab mice, these results suggest a role for the I-A alpha k chain in the selection and immunodominance of HEL 52-61 in H-2k mice. The fine specificity of I-A alpha k beta b-restricted T cell hybridomas for a series of different HEL peptides around the sequence 52 to 61 suggests that peptide 52-61 binds to I-A alpha k beta b with higher affinity than to I-A alpha k beta k. The peptides recognized in the context of I-A alpha b beta k and I-A alpha k beta k were not identified.     

The Ia.2 epitope defines a subset of lipid raft-resident MHC class II molecules crucial to effective antigen presentation

Previous work established that binding of the 11-5.2 anti-I-A(k) mAb, which recognizes the Ia.2 epitope on I-A(k) class II molecules, elicits MHC class II signaling, whereas binding of two other anti-I-A(k) mAbs that recognize the Ia.17 epitope fail to elicit signaling. Using a biochemical approach, we establish that the Ia.2 epitope recognized by the widely used 11-5.2 mAb defines a subset of cell surface I-A(k) molecules predominantly found within membrane lipid rafts. Functional studies demonstrate that the Ia.2-bearing subset of I-A(k) class II molecules is critically necessary for effective B cell-T cell interactions, especially at low Ag doses, a finding consistent with published studies on the role of raft-resident class II molecules in CD4 T cell activation. Interestingly, B cells expressing recombinant I-A(k) class II molecules possessing a β-chain-tethered hen egg lysosome peptide lack the Ia.2 epitope and fail to partition into lipid rafts. Moreover, cells expressing Ia.2(-) tethered peptide-class II molecules are severely impaired in their ability to present both tethered peptide or peptide derived from exogenous Ag to CD4 T cells. These results establish the Ia.2 epitope as defining a lipid raft-resident MHC class II conformer vital to the initiation of MHC class II-restricted B cell-T cell interactions.     

Identification and characterization of a T cell-inducing epitope of bovine ribonuclease that can be restricted by multiple class II molecules.

An immunodominant epitope of bovine RNase restricted by I-Ek molecules was identified using a T cell hybridoma recognizing RNase. This epitope was localized to the peptide RNase(90-105). Single conservative amino acid substitutions were made at each of the positions 94 through 105. It was found that only at one position, Asn-103, were conservative substitutions not allowed. This residue was shown to be the critical residue in determining T cell specificity. The ability of RNase(90-105) and the well-defined T cell epitope, HEL(46-61) to stimulate mouse strains expressing different independent H-2 haplotypes was examined using a T cell proliferation assay. The response to HEL(46-61) was completely restricted to mice expressing an I-Ak molecule. In striking contrast, 6 of 10 different mouse strains, H-2b,f,k,q,s,u, mounted vigorous T cell responses to RNase(90-105). The response was restricted to both I-A and I-E molecules, including I-Ab, I-Af, I-Ek, I-Aq, and I-As. H-2d mice were nonresponders to RNase(90-105), which was shown to be due to the failure of RNase(90-105) to bind to I-Ad molecules. A variant RNase(90-105) peptide was generated, containing an I-Ad binding motif, that could bind to I-Ad molecules. Despite its ability to bind, this variant peptide was not able to stimulate a response in H-2d mice. This result demonstrates that the ability of a peptide to bind to an Ia molecule is necessary but not always sufficient for a response to occur. Thus, in contrast to the highly restricted HEL(46-61) determinant, the RNase(90-105) determinant is permissive in its binding to Ia molecules. These results show that in the universe of T cell inducing epitopes contains both highly restricted and broadly restricted epitopes are found.     

The antigen-processing mutant T2 suggests a role for MHC-linked genes in class II antigen presentation.

.174xCEM.T2 (T2) is a human cell hybrid that has a large homozygous deletion within the MHC, including all of the functional class II genes. We have generated stable HLA-DR3 and H-2 I-Ak transfectants of T2 that express parental levels of class II molecules at the cell surface. T2.Ak transfectants fail to stimulate a hen egg lysozyme (HEL)-specific, I-Ak-restricted T cell when incubated with intact HEL. However, stimulation occurs if the appropriate HEL peptide is provided. The T2 cell line therefore has a defect in class II-restricted Ag processing. Biosynthetic studies demonstrate that the kinetics of I-Ak transport in T2.Ak are similar to the parental rates of transport, although the percentage of I-Ak molecules transported appears somewhat lower. I-Ak glycoproteins in T2.Ak associate normally with the I-chain, which appears to be proteolytically cleaved after transport through the Golgi apparatus in a similar fashion to that in the parent cell line, .174xCEM.T1 (T1). The DR alpha beta heterodimers in T2 differ from the parental phenotype in two ways. First, HLA-DR3 expressed in T2 does not have the epitope recognized by the DR3-specific mAb 16.23, although DR3 expressed in the parent does have the epitope. Second, the alpha beta subunits in the parent remain associated when exposed to SDS at room temperature, although those in T2 dissociate.     

Cutting edge: dueling TCRs: peptide antagonism of CD4+ T cells with dual antigen specificities.

T cells expressing two different TCRs were generated by interbreeding 3A9 and AND CD4+ TCR transgenic mice specific for the hen egg lysozyme (HEL) peptide 48-62:I-Ak and moth cytochrome c (MCC) peptide 88-103:I-Ek peptide:MHC ligands, respectively. Peripheral T cells in the offspring express two TCR V beta-chains and respond to HEL and MCC. We observed minimal or no additive effects upon simultaneous suboptimal stimulation with both agonist peptides; however, an antagonist peptide for the 3A9 TCR was able to inhibit the response of the dual receptor T cells to MCC, the AND TCR agonist. This HEL antagonist peptide did not affect AND single transgenic T cells, indicating that the antagonism observed in the dual TCR cells is dependent on the presence of the HEL-specific 3A9 TCR. In contrast, anti-TCR Abs mediate receptor-specific antagonism. These results demonstrate that peptide antagonism exerts a dominant effect.     

Fine specificity of murine class II-restricted T cell clones for synthetic peptides of influenza virus hemagglutinin. Heterogeneity of antigen interaction with the T cell and the Ia molecule

We have previously demonstrated diversity in the specificity of murine, H-2k class II-restricted, T cell clones for the hemagglutinin (HA) molecule of H3N2 influenza viruses and have mapped two T cell determinants, defined by synthetic peptides, to residues 48-68 and 118-138 of HA1. In this study we examine the nature of the determinant recognized by six distinct P48-68-specific T cell clones by using a panel of truncated synthetic peptides and substituted peptide analogs. From the peptides tested, the shortest recognized were the decapeptides, P53-62 and P54-63, which suggests that the determinant was formed from the 9 amino acids within the sequence 54-62. Asn54 was critical for recognition since P49-68 (54S) was not recognized by the T cell clones. Furthermore this peptide analog was capable of competing with P48-68 for Ag presentation, thereby suggesting that residue 54 is not involved in Ia interaction and may therefore be important for TCR interaction. Residue substitutions at position 63 also affected T cell recognition, but in a more heterogeneous fashion. Peptide analogs or mutant viruses with a single amino acid substitution at position 63 (Asp to Asn or Tyr) reduced the responses of the T cell clones to variable extents, suggesting that Asp63 may form part of overlapping T cell determinants. However since the truncated peptide P53-62 was weakly recognized, then Asp63 may not form part of the TCR or Ia interaction site, but may affect recognition through a steric or charge effect when substituted by Asn or Tyr. Ag competition experiments with the two unrelated HA peptides, P48-68 and P118-138, recognized by distinct T cell clones in the context of the same restriction element (I-Ak), showed that the peptides did not compete for Ag presentation to the relevant T cell clones, whereas a structural analog of P48-68 was a potent inhibitor. This finding is discussed in relation to the nature of the binding site for peptide Ag on the class II molecule.     

Functional studies on the role of I-A molecules expressed by the antigen-specific T suppressor cell clone HF1

The antigen-specific T suppressor (Ts) cell clone HF1 (Thy-1.2+, I-Ak+, I-Ek+) was isolated from a CBA/J mouse tolerized to low doses of bovine serum albumin (BSA), and a subclone was adapted to grow in the absence of antigen-presenting cells. The functional role of the I-Ak molecules endogenously expressed by HF1 Ts cells was analyzed by using anti-I-Ak monoclonal antibodies (mAb) in attempts to block the antigen-induced proliferation of these cells. Among a panel of anti-I-Ak mAb tested, only the H118-49 mAb directed against the private determinant Ia.m1 blocked BSA-induced proliferation. The data presented here suggest a selective regulatory role of membrane-bound I-Ak molecules in the antigen-induced signal transmission.     

The sites in the I-Ak histocompatibility molecule photoaffinity labeled by an immunogenic lysozyme peptide

The class II histocompatibilty molecule I-Ak was photoaffinity labeled by NH2- and COOH-terminal photoreactive conjugates of an immunogenic hen egg white lysozyme (HEL) peptide. The labeled alpha and beta chains were digested with protease from Staphylococcus aureus strain V-8 (protease V-8) and/or trypsin, and the proteolytic fragments were separated by high performance liquid chromatography (HPLC) (peptide mapping). Reproducible peptide maps containing a major labeled component were obtained from the three conjugates reported here whose photoreactive group was attached via short spacers of limited flexibility. The COOH-terminal conjugate N-acetyl HEL-(49-61)-iodo-4-azidosalicyloyl thioester (compound 1) labeled hydrophilic tryptic digest fragments on both chains of I-Ak. The labeled digest fragments were homogeneous in reverse-phase and anion-exchange HPLC, indicating that the photoaffinity labeling was site-specific. Conversely, the NH2-terminal conjugate iodo-4-azidosalicyloyl HEL-(46-61) (compound 2: IASA-(46-61)) labeled exceptionally hydrophobic sequences on both chains of I-Ak. The labeling was also site-specific because reverse-phase HPLC of primary digests with protease V-8 and secondary digests with trypsin showed single major labeled components. The labeling of I-Ak by IASA-(46-61) was fully inhibitible by HEL-(46-61). In contrast, IASA attached to the smallest immunogenic peptide 52-61 (compound 3) labeled a distinctly different hydrophilic tryptic fragment. The site of the I-Ak molecule that was photoaffinity labeled by IASA-(46-61) (compound 2) was determined. IASA-(46-61) labeled selectively at Pro-118 of a primary alpha chain fragment most likely encompassing residues 115-134. It labeled Thr-121 of a primary beta chain fragment most likely encompassing residues 109-138. We also obtained evidence that IASA-(46-61) occupied the antigen-specific site; the conjugate stimulated a T-cell hybridoma that recognizes the sequence 52-61 and also competed for the binding of this smaller peptide to I-Ak. Thus, peptides that bind to the allele-specific binding site and are long enough to extend beyond it can interact with a hydrophobic area of class II molecules. This area is formed by sequences of the first halves of the second domain of both alpha and beta chains.     

Presentation of antigens internalized through the B cell receptor requires newly synthesized MHC class II molecules

Exogenous Ags taken up from the fluid phase can be presented by both newly synthesized and recycling MHC class II molecules. However, the presentation of Ags internalized through the B cell receptor (BCR) has not been characterized with respect to whether the class II molecules with which they become associated are newly synthesized or recycling. We show that the presentation of Ag taken up by the BCR requires protein synthesis in splenic B cells and in B lymphoma cells. Using B cells transfected with full-length I-Ak molecules or molecules truncated in cytoplasmic domains of their alpha- or beta-chains, we further show that when an Ag is internalized by the BCR, the cytoplasmic tails of class II molecules differentially control the presentation of antigenic peptides to specific T cells depending upon the importance of proteolytic processing in the production of that peptide. Integrity of the cytoplasmic tail of the I-Ak beta-chain is required for the presentation of the hen egg lysozyme determinant (46-61) following BCR internalization, but that dependence is not seen for the (34-45) determinant derived from the same protein. The tail of the beta-chain is also of importance for the dissociation of invariant chain fragments from class II molecules. Our results demonstrate that Ags internalized through the BCR are targeted to compartments containing newly synthesized class II molecules and that the tails of class II beta-chains control the loading of determinants produced after extensive Ag processing.     

Conformational restriction of the Tyr53 side-chain in the decapeptide HE.

A series of conformationally restricted analogs of the hen egg lysozyme (HEL) decapeptide 52-61 in which the conformationally flexible Tyr53 residue was replaced by several more constrained tyrosine and phenylalanine analogs was prepared. Among these tyrosine and phenylalanine analogs were 1,2,3,4-tetrahydro-7-hydroxyisoquinoline-3-carboxylic acid (Htc), 1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid (Tic), 4-amino- 1,2,4,5-tetrahydro-8-hydroxy-2-benzazepine-3-one (Hba), 4-amino-1,2,4,5-tetrahydro-2-benzazepine-3-one (Aba), 2-amino-6-hydroxytetralin-2-carboxylic acid (Hat) and 2-amino-5-hydroxyindan-2-carboxylic acid (Hai) in which the rotations around Calpha-Cbeta and Cbeta-Cgamma were restricted because of cyclization of the side-chain to the backbone. Synthesis of Pht-Hba-Gly-OH using a modification of the Flynn and de Laszlo procedure is described. Analogs of beta-methyltyrosine (beta-MeTyr) in which the side-chains were biased to particular side-chain torsional angles because of substitution at the beta-hydrogens were also prepared. These analogs of HEL[52-61] peptide were tested for their ability to bind to the major histocompatibility complex class II I-Ak molecule and to be recognized in this context by two T-cell hybridomas, specific for the parent peptide HEL[52-61]. The data showed that the conformation and also the configuration of the Tyr53 residue influenced both the binding of the peptide to I-Ak and the recognition of the peptide/I-Ak complex by a T-cell receptor.     

Independent selection by I-Ak molecules of two epitopes found in tandem in an extended polypeptide antigen

The protein hen egg white lysozyme (HEL) contains two segments, in tandem, from which two families of peptides are selected by the class II molecule I-Ak, during processing. These encompass peptides primarily from residues 31-47 and 48-63. Mutant HEL proteins were created with changes in residues 52 and 55, resulting in a lack of binding and selection of the 48-63 peptides to I-Ak molecules. Such mutant HEL proteins donated the same amount of 31-47 peptide as did the unmodified protein. Other mutant HEL molecules containing proline residues at residue 46, 47, or 48 resulted in extensions of the selected 31-47 or 48-62 families to their overlapping regions (in the carboxyl or amino termini, respectively). However, the amount of each family of peptide selected was not changed. We conclude that the presence or absence of the major peptide from HEL does not influence the selection of other epitopes, and that these two families are selected independently of each other.     

Recombinant Escherichia coli express a defined, cytoplasmic epitope that is efficiently processed in macrophage phagolysosomes for class II MHC presentation to T lymphocytes.

Although the processing of soluble Ag for presentation to T cells has been extensively studied in vitro, similar studies of phagocytic Ag processing have been limited. We have developed an in vitro model system to study the ability of macrophages to process recombinant Escherichia coli strain HB101 with cytoplasmic or surface expression of the well characterized T cell epitope of hen egg lysozyme (HEL) 52-61. This epitope was expressed within full length HEL or within a fusion protein containing the HEL epitope. Phagocytosis of E. coli with cytoplasmic expression of HEL or the HEL fusion protein resulted in strong presentation of HEL(52-61) to T cells. Surface-conjugated HEL was processed with even greater efficiency. Processing required viable macrophages, was inhibited by cytochalasin D, and was achieved within 20 min of bacterial contact with the macrophages. Within this time span, phagosomes containing bacteria fused with lysosomes, and the bacteria were extensively degraded. Uptake of as few as four bacteria per macrophage produced an Ag-specific T cell response. We conclude that bacterial compartmentalization of the antigenic epitope (cytoplasmic vs surface) had some effect on its processing, but that phagocytic Ag processing organelles contain extensive capacity to degrade internalized bacteria and liberate intracellular Ag epitopes for recycling and presentation, consistent with a central role for phagolysosomes. Thus, future recombinant bacterial vaccines may be effectively designed with T cell epitopes expressed either on the surface or within the bacterial cytoplasm.     

Specificity of the T cell receptor: two different determinants are generated by the same peptide and the I-Ak molecule

The determinants recognized by two I-Ak-restricted hen egg-white lysozyme-specific T cell hybridomas were differentiated with a series of truncated or substituted peptides. The 10mer 52-61 was the smallest peptide that was immunogenic for both T cells. This peptide differed by a single residue, Leu56, from the corresponding autologous lysozyme peptide, which was nonimmunogenic. The addition of amino acids to the amino terminus of 52-61 increased the immunogenicity of the peptides for 3A9 T cells and decreased the immunogenicity for 2A11 T cells. By deleting or diiodinating Tyr53, the resulting peptides were rendered totally nonimmunogenic. In contrast, the 3-NO2-Tyr derivative was fully immunogenic for the 3A9 cells but completely nonimmunogenic for the 2A11 cells. Thus, two different, but very similar, determinants were generated by the same HEL peptide and the I-Ak molecule.