Destructive proteolysis by cysteine proteases in antigen presentation of ovalbumin

Most native antigens require digestion by acidic proteases in order to be recognized in the context of major histocompatibility complex class II by T helper cells (Th). We have studied the roles of three different acidic proteases, cathepsin D, cathepsin B and cathepsin L, in the processing of ovalbumin (OVA) for presentation in the context of I-A^d. We report that digestion of OVA in vitro with the aspartyl protease cathepsin D generates the epitope OVA_322–336, which is recognized by I-A^d-restricted OVA-specific Th in the presence of paraformaldehyde-fixed antigen-presenting cells (APC). In contrast, digestion of OVA with the cysteine proteases cathepsin B and L not only failed to generate an epitope, but also destroyed OVA_322–336. In the presence of fixed APC expressing I-A^d, OVA_322–336 was protected from destructive proteolysis by cathepsin L. These results illustrate the dependence of epitope selection on the intracellular proteolytic environment in APC, and suggest that mechanisms must exist for protection of epitopes from destructive proteolysis in the processing compartments.     

Generation of hen egg lysozyme-specific and major histocompatibility complex class I-restricted cytolytic T lymphocytes: recognition of cytosolic and secreted antigen expressed by transfected cells

Syngeneic cells exogenously supplied with hen egg lysozyme (HEL) or endogenously synthesizing HEL were used as antigen-presenting cells to induce major histocompatibility complex class I-restricted cytotoxic T lymphocytes (CTL). Immunization of C57BL/6 mice followed by repeated stimulation of their splenocytes in vitro with trypsinized HEL peptides led to the generation of CTL lines specific for trypsinized HEL peptides and restricted by H-2K^b. Immunization of C3H mice with a mixture of soluble native HEL and irradiated syngeneic spleen cells followed by in vitro stimulation of immune spleen cells with soluble HEL could in a few cases result in HEL-specific CTL able to kill syngeneic transfectant L cells secreting HEL (HELs) or expressing cytosol-targeted HEL (HELc). The use of HELs or HELc transfectant L cells as in vivo and in vitro immunogens was a potent way for eliciting HEL-specific polyclonal CTL. These CTL and two CD8⁺ clones were found to be H-2K^k restricted and specific for the 1-17 N-terminal HEL peptide. In addition, the anti-HEL CTL could also exhibit a significant cross-reactivity against unsensitized and HEL-untransfected targets expressing the K restriction element. This cross-reactivity was likely due to recognition of unidentified HEL mimicking peptides (self-derived ?) presented by the MHC class I (H-2K^b or H-2K^k) molecule used as the restriction element for the specific recognition of HEL. The CTL raised after immunization with HELs or HELc transfectant cells were found to recognize both the HELs and HELc transfectant cells even though HEL was not detected in the latter after a 2- or 5-min radiolabeling pulse. Recognition of both HELs and HELc transfectant cells by a given CTL clone suggests that HEL subjected to two separate processing pathways, each depending on the initial subcellular localization, can ensure the generation of similar MHC class I peptide complexes.     

Dose-dependent T cell tolerance to an immunodominant self peptide

We have previously described a model of tolerance to self peptides in a mouse transgenic (Tg) line producing secreted hen egg-white lysozyme (HEL). The HEL cDNA was placed under the control of a ubiquitous promoter expressed early in embryogenesis, so that HEL should be present in Tg mice throughout the development of the immune system. Since individual HEL Tg mice express different amounts of serum HEL, we were previously able to show that H-2^d mice with HEL blood level > 10 ng/ml are tolerant to HEL and to the immunodominant (ID) peptide 108–116. However, autoreactive T lymphocytes recognizing the HEL subdominant (SD) peptides 74–96 and 1–18 still persist and the SD-specific responses disappear at higher blood HEL concentrations. In the present work, we have studied HEL Tg H-2^d mice with HEL serum levels < 10 ng/ml (HEL-low Tg animals). We find that 50% of Tg animals with HEL blood concentration < 2 ng/ml are responsive to HEL in T cell proliferation assays, although these responses are lower than those seen in non-Tg control mice. The HEL-specific T lymphocytes react only with 15-mer overlapping peptides encompassing the single H-2^d ID region of HEL (residues 102–122); whereas the 9-mer minimal ID peptide 108–116, which strongly triggers non-Tg T cells, is unable to stimulate auto-reactive T cells in vitro from HEL-low Tg mice. Altogether, our results suggest that T lymphocytes specific for the minimal ID peptide are deleted or inactivated, while T cell clones of lower affinity and reacting with epitopes on longer peptides persist. Thus, the high affinity ID peptide-specific T cell clones can be negatively selected even in the presence of low amounts of HEL.     

Antigen processing by endosomal proteases determines which sites of sperm-whale myoglobin are eventually recognized by T cells.

This study reports an identification of the major processing products of an exogenous protein antigen, viz, sperm-whale myoglobin, as obtained after cell-free processing with partially purified macrophage endosomes. It is demonstrated that such a system yields fragments that are indistinguishable by high performance liquid chromatography analysis from those generated after uptake of myoglobin inside live macrophages. The concerted action of the endosomal proteases cathepsin D and cathepsin B can account for nearly all cleavages observed. Cathepsin D appears to be mainly responsible for the initial cleavage of myoglobin, while cathepsin B catalyzes the C-terminal trimming of initially released fragments. The fragments released by cathepsin D contain most, if not all, major epitopes for murine myoglobin-specific helper T cells. Interestingly, each known T cell epitope of myoglobin is located at the very N terminus of a different myoglobin fragment released upon processing. In order to explain this correspondence, noted also in several other protein antigens, a structural relationship is proposed between antigen processing by cathepsin D and antigen recognition by major histocompatibility complex (MHC) class II products. As is demonstrated here, this relationship may be used as a predictive tool for the identification of MHC-binding sequences as well as of T cell epitopes in their naturally occurring form.     

Endogenous and exogenous forms of the same antigen are processed from different pools to bind MHC class II molecules in endocytic compartments

The current studies were carried out to examine the basis for the differences in the antigenic peptides generated from exogenous and endogenous forms of hen egg white lysozyme (HEL). The role of different intracellular compartments in the generation and binding of HEL peptides derived from two endogenous forms of HEL, either secreted (sHEL) or retained in the endoplasmic reticulum (ER, KDEL HEL), presented by MHC class II molecules was examined and compared to exogenous HEL. Initially it was found that antigen-presenting cells bearing both intracellular forms of HEL generated and presented a number of IA^k-restricted HEL epitopes to T cell hybridomas, although s HEL was processed more efficiently than KDEL HEL. There were differences, however, for some determinants between endogeneous and exogenous HEL. At equivalent antigen-presenting efficiencies, endogenous HEL-bearing cells displayed a lower surface density of IA^k-bound HEL-52-61-related peptides than cells pulsed with exogenous HEL, as detected by a specific monoclonal antibody. Neither endogenous HEL degradation nor peptide binding to MHC class II molecules occurred in the ER. Processing of sHEL and KDEL HEL appears to take place either in a post-trans-Golgi network acidic compartment or in the cytosol, whereas peptide binding to MHC class II molecules occurs in endocytic compartments . Furthermore, the peptides generated were derived from an endogenous source rather than from secreted and re-endocytosed HEL. Thus, processing of endogenous HEL is from a different pool than exogenous HEL and occurs in different compartments.     

Similar as well as distinct MHC class I-binding peptides are generated by exogenous and endogenous processing of hepatitis B virus surface antigen

Murine MHC class I-restricted cytotoxic T lymphocyte (CTL) responses can be primed by exogenous as well as endogenous hepatitis B surface antigen (HBsAg). Immunodominant CTL-defined epitopes of this viral envelope protein are the L^d -binding 12-mer S28 – 39 peptide IPQSLDSWWTSL in H-2 ^d mice, and the K^b -binding 8-mer S208 – 215 peptide ILSPFLPL in H-2^b mice. We tested if CTL recognizing these epitopes can be primed in vivo by HBsAg delivered as either an exogenous antigen (native HBsAg lipoprotein particles), or an endogenous antigen (plasmid DNA encoding HBsAg). Primed T cells were restimulated in vitro prior to the cytotoxicity assay with cells presenting the H-2 class I-binding epitopes generated by either exogenous or endogenous processing of HBsAg. The data indicate that the L^d -binding peptide S28 – 39 is generated during exogenous as well as endogenous processing of HBsAg. In contrast, the K^b -binding peptide S208 – 215 is generated during exogenous but not endogenous processing of HBsAg. Hence, some but not all MHC class I-binding, immunogenic peptides are generated during endogenous and exogenous processing of HBsAg but there also exists a repertoire of immunogenic peptides of viral origin that is only revealed after exogenous processing of viral proteins.     

mAb against hen egg-white lysozyme regulate its presentation to CD4(+) T cells.

Specific antibodies increase antigen uptake and presentation by antigen-presenting cells via the B cell receptor in B cells or FcgammaR in dendritic cells. To determine whether the interaction between antibody and antigen could influence the set of peptides presented by MHC II molecules, we analyzed the presentation of different CD4(+) T cell epitopes of hen egg-white lysozyme (HEL) after the capture of immune complexes formed between HEL and seven different specific mAb. The 103-117 T cell epitope (I-E(d)) was specifically and selectively up-regulated by the D1.3 and F9.13.7 mAb that binds to proximal loops in the native structure of HEL. Furthermore, Ii-independent T cell epitopes exposed on the HEL surface (116-129 and 34-45, I-A(k) restricted) which require a mild processing involving the recycling of MHC II molecules were selectively up-regulated by mAb that overlap those T cell epitopes (D1.3 and D44.1). However, F10.6.6, somatically derived from the same germ line genes as D44.1 and exhibiting an higher affinity for HEL, was without effect on the presentation of the 34-45 epitope. An Ii-dependent T cell epitope buried into the tertiary structure of HEL (45-61, I-A(k) restricted) and requiring the neosynthesis of MHC II was up-regulated by high-affinity mAb recognizing epitopes located at the N- or C-terminus of the T cell epitope. These results strongly suggest that (i) the spatial relationship linking the T cell epitope and the B cell epitope recognized by the mAb, (ii) the intrinsic processing requirements of the T cell epitope, and (iii) the antibody affinity influences the presentation of a given T cell epitope.     

The unveiling of hidden T-cell determinants of a native antigen by defined mediators of inflammation: implications for the pathogenesis of autoimmunity

A major hypothesis for the induction of autoimmunity invokes the enhanced display of previously hidden (cryptic) epitopes under inflammatory conditions leading to the activation of self-reactive T cells. However, there is meager data that directly validate the influence of specific immune mediators on the upregulation of the presentation of cryptic determinants in vivo. We tested the effect on well-defined cryptic epitopes of hen eggwhite lysozyme (HEL) of the availability locally of a cytokine (IL-2, IL-4, IL-6, IL-10, TNF-alpha or granulocyte-macrophage colony-stimulating factor) at the antigen delivery site, or of the pretreatment of the immunogen with a cathepsin (Cat B, D, L or S) prior to use in vivo. Each of the three mouse strains (H-2(b/d/k)) tested revealed a unique profile of T-cell reactivity to different cryptic epitopes of HEL in response to a particular cytokine or cathepsin. These results provide proof of principle for the reversal of crypticity of self-epitopes by immune mediators in the local milieu. Moreover, co-immunization with an antigen and a cytokine offers a simple and reliable tool for studying the role of cryptic epitopes in autoimmunity. Our results also strengthen the rationale for the use of inhibitors of cytokine/cathepsin activity in the treatment of autoimmune diseases.     

Extensive major histocompatibility complex class I binding promiscuity for Mycobacterium tuberculosis TB10.4 peptides and immune dominance of human leucocyte antigen (HLA)‐B*0702 and HLA‐B*0801 alleles in TB10.4 CD8+ T‐cell responses

The molecular definition of major histocompatibility complex (MHC) class I‐presented CD8⁺ T‐cell epitopes from clinically relevant Mycobacterium tuberculosis (Mtb) target proteins will aid in the rational design of T‐cell‐based diagnostics of tuberculosis (TB) and the measurement of TB vaccine‐take. We used an epitope discovery system, based on recombinant MHC class I molecules that cover the most frequent Caucasian alleles [human leucocyte antigen (HLA)‐A*0101, A*0201, A*0301, A*1101, A*2402, B*0702, B*0801 and B*1501], to identify MHC class I‐binding peptides from overlapping 9‐mer peptides representing the Mtb protein TB10.4. A total of 33 MHC class I‐binding epitopes were identified, spread across the entire amino acid sequence, with some clustering at the N‐ and C‐termini of the protein. Binding of individual peptides or closely related peptide species to different MHC class I alleles was frequently observed. For instance, the common motif of xIMYNYPAMx bound to six of eight alleles. Affinity (50% effective dose) and off‐rate (half life) analysis of candidate Mtb peptides will help to define the conditions for CD8⁺ T‐cell interaction with their nominal MHC class I‐peptide ligands. Subsequent construction of tetramers allowed us to confirm the recognition of some of the epitopes by CD8⁺ T cells from patients with active pulmonary TB. HLA‐B alleles served as the dominant MHC class I restricting molecules for anti‐Mtb TB10.4‐specific CD8⁺ T‐cell responses measured in CD8⁺ T cells from patients with pulmonary TB.     

MUC1 peptide epitopes associated with five different H-2 class I molecules

We have previously described the induction of murine CD8⁺ major histocompatibility complex (MHC) class I-restricted cytotoxic T cells (CTL) recognizing the 20-amino acid repeat region of the human mucin 1 (MUC1) variable number of tandem repeats region (VNTR), a mucin greatly increased in expression in breast cancer and proposed as a target for immunotherapy. In that study, CTL could detect MUC1 peptides associated with the MHC of all nine strains examined, and we now report the different epitopes presented by five different MHC class I molecules. The epitopes were defined in CTL assays using peptide-pulsed phytohemagglutinin blasts or MHC class I-transfected L cells as targets; in addition, peptide binding assays and T cell proliferation studies were performed. Within the 20-amino acid VNTR, nine potential epitopes could be defined. The epitopes for the four MHC class I molecules [K^b (three epitopes), D^d, L^d and K^k] were closely related, all containing the amino acids PDTRPAP. For D^b, three epitopes were identified, all containing APGSTAP. Most of the epitopes did not contain a consensus motif for the particular MHC class I allele, and bound with low ‘affinity’, compared with known high-affinity peptides. CD8⁺ T cell proliferation also occurred to the same MHC class I-presented epitopes. Finally, when conventional anchor residues were introduced into the peptides, peptide binding increased, whereas CTL recognition was either retained (K^b) or lost (D^b) depending on the epitope.     

Immunodominance of cytotoxic T lymphocyte epitopes co-injected in vivo and modulation by interleukin-12

Immunodominance (ID) of T cell epitopes is a well-documented phenomenon that might have profound significance in the evolution of T cell responses to pathogens, tumors, autoantigens and vaccines. With the intention of developing vaccines composed of several cytotoxic T cell (CTL) epitopes, we injected mice with peptide mixtures containing two to five CTL epitopes and observed clear patterns of ID. In a first case, ID strictly correlated with the competitor activity of the individual peptides for H-2K^d, whereas in a second case, the absence of correlation between ID and competitor activity, binding affinity, half-life of the peptides in serum, induction of proliferation in vitro and the individual immunogenicity of the peptides, suggested to us that ID of co-injected CTL epitopes can be determined both at the peptide level (binding affinity to H-2K^d) and at the T cell level. This hypothesis is supported by our finding that interleukin-12 strongly modulates ID when it is not correlated with MHC binding.     

The phenotype of H-2M-deficient mice is dependent on the MHC class II molecules expressed

For a broader view of the role of H-2M as an accessory molecule in antigen presentation, we investigated the degree to which different MHC class II isotypes and alleles depend on H-2M to function in vivo. We generated H-2M-deficient animals expressing E^{k / b} or A^k molecules in addition to the A^b molecules already present in the mutant strain, and compared the ability of the different MHC class II molecules to present antigen at the cell surface for recognition by T cells, and contribute to positive selection of CD4⁺ T cells in the thymus. Biochemical analyses were performed to assess MHC class II maturation, and to determine the peptide content of the molecules. In the absence of H-2M, E^{k / b} molecules containd a more heterogeneous set of class II-associated invariant chain peptides (CLIP) than A^b did, which, unlike A^b -CLIP complexes, were not SDS-stable. Unlike A^b molecules, both E^{k / b} and A^k efficiently presented exogenously added peptides to T cells in the absence of H-2M. In addition, epitopes from some proteins, especially those known to be invariant chain independent, were presented by A^k molecules in the mutant animals. To our surprise, expression of E^{k / b} overcame the positive selection defect observed in H-2M-deficient mice expressing A^b alone. In contrast, A^k expression did not augment positive selection of CD4⁺ T cells in the mutant animals. Some of these findings in vivo contrast significantly with findings from in vitro studies on murine MHC class II molecules in human DM-deficient cell lines.     

Abundance of H-2 promiscuous T cells specific for mycobacterial determinants in H-2b/d F1 hybrid mice

A majority of immunodominant epitopes of mycobacterial antigens are known to be recognized by murine T cells in the context of several H-2 haplotypes. In this study, we established the frequency of T cells able to recognize these peptides promiscuously, i.e. in the context of allogeneic antigen-presenting cells, using hybridomas from peptide-immunized H-2 homologous and heterologous mice. The degree of promiscuity in homozygous mice varied between 4–27% between different specificities and genetic backgrounds. In particular, the results showed that promiscuity between A^b and A^d in respect to a peptide from the Mycobacterium tuberculosis 38-kDa protein (residues 350–369) was displayed by 22% of BALB/c and 4% of C57BL/10-derived hybrids, but by 42% of [BALB/c x C57BL/10] F1-derived clones. This represents a significant increase (p < 0.001) of T cell promiscuity compared to the parental haplotypes. It is noteworthy that considerably lower peptide concentrations were able to stimulate the promiscuous hybridomas compared to the H-2-restricted hybrids. This finding suggests a functional advantage of promiscuous T cells which enables them to expand preferentially in the initial stages of infections with M. tuberculosis and thus enables the host to mount a rapid protective immune response.     

Vaccination with cytotoxic T lymphocyte epitope-containing peptide protects against a tumor induced by human papillomavirus type 16-transformed cells

Cytotoxic T lymphocyte (CTL) peptide epitopes can be used for immunization of mice against lethal virus infection. To study whether this approach can be successful against virus-induced tumors we generated a B6 (H-2^b) tumorigenic cell line transformed by human papillomavirus (HPV). This virus is detected in over 90% of all human cervical cancers. To identify vaccine candidates, we generated a set of 240 overlapping peptides derived from the HPV type 16 (HPV16) oncogenes E6 and E7. These peptides were tested for their ability to bind H-2K^b and H-2D^b MHC class I molecules. Binding peptides were compared with the presently known peptide-binding motifs for H-2K^b and H-2D^b and the predictive value of these motifs is shortly discussed. The high-affinity H-2D^b-binding peptide and putative CTL epitope E₇ 49-57 (RAHYNIVTF) was used in vaccination studies against HPV 16-transformed tumor cells. Immunization with peptide E₇ 49-57 rendered mice insensitive to a subsequent challenge with HPV 16-transformed tumor cells in vivo, and induced a CTL response which lysed the tumor cells in vitro.     

Structural basis for immune recognition of lysozymes. II. Reactive but non-immunogenic epitopes

Certain epitopes on protein molecules are reactive with antibody but are not immunogenic. Rabbit antiserum prepared against hen egg-white lysozyme (HEL) reacted poorly or not at all with peptides LH_II (a. a. 13-105) and LH_III (a. a. 106-129) derived from the action of CNBr on reduced HEL (HEL (CB)). In sharp contrast, antiserum raised (a) to the derivative HEL (CB) with two peptide chain cleavages at methionines 12 and 105, or (b) to bob-white lysozyme (BEL), reacted with peptides LH_II and LH_III. These peptides were able to compete directly with HEL in a ¹²⁵I-HEL-anti-HEL(CB) system, or an ¹²⁵I-HEL-anti-BEL system, but could not inhibit the ¹²⁵I-HEL-anti-HEL reaction. The results demonstrate that some epitopes on HEL(CB) or BEL are reactive and immunogenic, while the same or related epitopes on HEL, although reactive with antibodies directed against them, are not immunogenic. Such epitopes are referred to as heterotopes (epitopes definable by their reactivity on a related, heterologous protein). The usage of a chemical derivative of HEL allowed the localization of another heterotope region close to tryptophan 62. The existence of heterotopes was discussed in terms of current models of cellular cooperation. The view was advaced that the activation of a particular antibody-producing precursor cell is dependent on a special steric relationship of carrier to haptenic epitopes.     

PREDNOD,a prediction server for peptide binding to the H-2g7 haplotype of the non-obese diabetic mouse

The non-obese diabetic (NOD) mouse is a widely used animal model for study of autoimmune diseases, in particular human type 1 diabetes mellitus (T1DM). Identification of the subset of peptides that bind MHC molecules comprising the H-2^g7 haplotype of NOD mouse and thereby representing potential NOD T-cell epitopes is important for research into the pathogenesis and immunotherapy of T1DM. The H-2^g7 haplotype comprises the MHC class-I molecules K^d and D^b and a single class-II molecule I-A^g7. We have developed a prediction system, PRED^NOD, for accurate identification of peptides that bind the MHC molecules constituting the H-2^g7 haplotype. PRED^NOD is accessible at http://antigen.i2r.a-star.edu.sg/Ag7.     

Permissive recognition during positive selection

In the periphery αβ T lymphocytes recognize antigens in conjunction with major histocompatibility complex (MHC) molecules. In the thymus immature T cells are positively selected on MHC molecules in the apparent absence of cognate peptides. Thus, at different developmental stages a T cell responds to different epitopes, yet uses the identical αβ T cell antigen receptor (TcR). To explain this paradox it has been hypothesized that during positive selection immature T cells see peptides/ligands unique to the thymus, are selected by specific antagonists related to their cognate peptides, or are driven by lowered affinity thresholds of their TcR. Though different in detail, these theories rely on defined peptides uniquely matched to select certain TcR. However, we find that in a TcR-transgenic (TcR_trans⁺) mouse severely limiting the diversity of peptides does not impair positive selection. We show that many unrelated peptides, including some naturally occurring on the cell surface, induce maturation of CD4^?CD8⁺TcR^high thymocytes. The same peptides when presented in conjunction with the selecting MHC molecule, are not recognized by peripheral T cells expressing the same TcR_trans. Therefore, these findings point to a promiscuous rather than discriminate recognition mode used by immature T cells.     

H2-O influence on antigen presentation in H2-E-expressing mice

MHC class II molecules sample peptides generated in the endosomal/lysosomal system for cell surface presentation to CD4+ T cells. Peptide loading requires the endosomal/lysosomal resident HLA-DM (DM; H2-DM, mouse), but in B cells, DM is tightly associated with HLA-DO (DO; H2-O, mouse). We have previously shown that H2-O differentially modulates the processing and presentation of different antigenic epitopes on H2-Ab molecules. Using H2-Ead-transgenic mice, we here show that presentation of different epitopes by H2-Ed/b molecules is similarly influenced by H2-O after membrane immunoglobulin-mediated uptake of antigen. In addition, B cells from H2-Ead-transgenic mice (which co-express H2-Ab and H2-Ed/b molecules) show an altered pattern of presentation of H2-Ab-restricted epitopes. In H2-Ead-transgenic, H2-O-deficient mice, further changes in the peptide repertoire were observed. Thus, H2-Ed/b expression influences the epitopes presented by H2-Ab, and this effect is further altered by expression of H2-O.     

Immune response in mouse and malaria-exposed humans to peptides derived from Pfl1-1, a highly repetitive megadalton protein of Plasmodium falciparum

We have investigated the immune response against the Plasmodium falciparum gametocyte-specific antigen Pf11-1. This megadalton parasite molecule has been implicated in the process of erythrocyte rupture during gametogenesis. The molecule is composed in great part of degenerated nonapeptide motifs which are tandemly repeated several hundred times. A computer algorithm searching for T sites predicted that the entire repeat region of the Pf11-1 represents potential T cell antigenic major histocompatibility complex class II-binding sites. To test this hypothesis, synthetic peptides corresponding to two nonamer subtype repeats, differing only at two amino acid positions, were used to immunize congenic mouse strains. Both peptides were shown to contain both B and T cell epitopes. The immune response is restricted to the H-2^d andH-2^khaplotypes. The T cell response against the peptides appeared to be highly specific, clearly discriminating between the two similar nonamer repeat sequences, whereas the humoral response produced cross-reacting antibodies. We also investigated the humoral and T cell reactivities of P. falciparum-primed individuals in West Africa against the synthetic Pf11-1 peptides. Among 51 individuals 35 had antibodies to at least one of the two peptides and a majority of them (28) had antibodies reacting with both peptides. The cellular response was analyzed by [³H] thymidine incorporation or interferon-y release. There was considerable variation in the response to the two peptides. Among the human samples 36% responded to one repeat subtype, while only 13% responded to the second subtype. Interestingly, in individual donors the T cell response to both peptides are associated, suggesting that, as shown for mice, the response is restricted by a genetic element. The data obtained on the two subtypes of the nonamer repeat region suggest that the entire Pfll-1 molecule might induce an unusually heterogenous B and T cell response during natural infection in man.     

Destructive potential of the aspartyl protease cathepsin D in MHC class II-restricted antigen processing

Whether specific proteases influence MHC class II antigen presentation is still not clearly defined. Cathepsin D, one of the most abundant lysosomal proteases, is thought to be dispensable for MHC class II antigen presentation, yet in vitro digestions of antigen substrates with endosomes/lysosomes from antigen-presenting cells sometimes reveal a dominant role for pepstatin-sensitive aspartyl proteases of which cathepsin D is the major representative. We tested whether the aspartyl protease substrate myoglobin requires cathepsin D activity for presentation to T cells. Surprisingly, in dendritic cells (DC) lacking cathepsin D, presentation of two different myoglobin T cell epitopes was enhanced rather than hindered. This paradox is resolved by the finding that pepstatin-sensitive myoglobin processing activity persists in lysosomes from cathepsin D-null DC and that this reduced activity, most likely due to cathepsin E, is closer to the optimum level required for myoglobin antigen presentation. Our results indicate redundancy among lysosomal aspartyl proteases and show that while processing activities can be productive for MHC class II T cell epitope generation at one level, they can become destructive above an optimal level.