Why peptides? Their possible role in the evolution of MHC-restricted T-cell recognition

Unbiased, High-Throughput Identification of T Cell Epitopes by ELISPOT

Recent systematic immune monitoring efforts suggest that, in humans, epitope recognition by T cells is far more complex than has been assumed based on minimalistic murine models. The increased complexity is due to the higher number of HLA loci in humans, the typical heterozygosity for these loci in the outbred population, and the high number of peptides that each HLA restriction element can bind with an affinity that suffices for antigen presentation. The sizable array of potential epitopes on any given antigen is due to each individual's unique HLA allele makeup. Of this individualized potential epitope space, chance events occurring in the course of the T cell response determine which epitopes induce dominant T cell expansions. Establishing the actually-engaged T cell repertoire in each human subject, including the individualized peptides targeted, therefore requires the systematic testing of all peptides that constitute the potential epitope space in that person. The goal of comprehensive, high-throughput epitope mapping can be readily established by the methods described in this chapter.

Discordance Between the Predicted Versus the Actually Recognized CD8+ T Cell Epitopes of HCMV pp65 Antigen and Aleatory Epitope Dominance

CD8+ T cell immune monitoring aims at measuring the size and functions of antigen-specific CD8+ T cell populations, thereby providing insights into cell-mediated immunity operational in a test subject. The selection of peptides for ex vivo CD8+ T cell detection is critical because within a complex antigen exists a multitude of potential epitopes that can be presented by HLA class I molecules. Further complicating this task, there is HLA class I polygenism and polymorphism which predisposes CD8+ T cell responses towards individualized epitope recognition profiles. In this study, we compare the actual CD8+ T cell recognition of a well-characterized model antigen, human cytomegalovirus (HCMV) pp65 protein, with its anticipated epitope coverage. Due to the abundance of experimentally defined HLA-A*02:01-restricted pp65 epitopes, and because in silico epitope predictions are most advanced for HLA-A*02:01, we elected to focus on subjects expressing this allele. In each test subject, every possible CD8+ T cell epitope was systematically covered testing 553 individual peptides that walk the sequence of pp65 in steps of single amino acids. Highly individualized CD8+ T cell response profiles with aleatory epitope recognition patterns were observed. No correlation was found between epitopes' ranking on the prediction scale and their actual immune dominance. Collectively, these data suggest that accurate CD8+ T cell immune monitoring may necessitate reliance on agnostic mega peptide pools, or brute force mapping, rather than electing individual peptides as representative epitopes for tetramer and other multimer labeling of surface antigen receptors.

Comprehensive Evaluation of the Expressed CD8+ T Cell Epitope Space Using High-Throughput Epitope Mapping

T cell immunity is traditionally assessed through functional recall assays, which detect the consequences of the T cells' antigen encounter, or via fluorescently labeled multimers that selectively bind peptide-specific T cell receptors. Using either approach, if the wrong antigen or peptide of a complex antigenic system, such as a virus, is used for immune monitoring, either false negative data will be obtained, or the magnitude of the antigen-specific T cell compartment will go largely underestimated. In this work, we show how selection of the “right” antigen or antigenic peptides is critical for successful T cell immune monitoring against human cytomegalovirus (HCMV). Specifically, we demonstrate that individual HCMV antigens, along with previously reported epitopes, frequently failed to detect CD8+ T cell immunity in test subjects. Through systematic assessment of T cell reactivity against individual nonamer peptides derived from the HCMVpp65 protein, our data clearly establish that (i) systematic testing against all potential epitopes encoded by the genome of the antigen of interest is required to reliably detect CD8+ T cell immunity, and (ii) genome-wide, large scale systematic testing of peptides has become feasible through high-throughput ELISPOT-based “brute force” epitope mapping.

Direct Detection of T- and B-Memory Lymphocytes by ImmunoSpot® Assays Reveals HCMV Exposure that Serum Antibodies Fail to Identify

It is essential to identify donors who have not been infected with human cytomegalovirus (HCMV) in order to avoid transmission of HCMV to recipients of blood transfusions or organ transplants. In the present study, we tested the reliability of seronegativity as an indicator for the lack of HCMV exposure in healthy human blood donors. Eighty-two HCMV seronegative individuals were identified, and their peripheral blood mononuclear cells (PBMC) were tested in ImmunoSpot® assays for the presence of HCMV-specific T- and B-memory lymphocytes. Eighty-two percent (67 of 82) of these HCMV seronegative individuals featured at least one memory cell that was lineage specific for HCMV, with the majority of these subjects possessing CD4+ and CD8+ T cells, as well as B cells, providing three independent lines of evidence for having developed immunity to HCMV. Only 15 of these 82 donors (18%) showed neither T- nor B-cell memory to HCMV, consistent with immunological naïveté to the virus. The data suggest that measurements of serum antibodies frequently fail to reveal HCMV exposure in humans, which may be better identified by direct detection of HCMV-specific memory lymphocytes.

How frequently are predicted peptides actually recognized by CD8 cells?

Detection of antigen-specific CD8 cells frequently relies on the use of peptides that are predicted to bind to HLA Class I molecules or have been shown to induce immune responses. There is extensive knowledge on individual HLA alleles’ peptide-binding requirements, and immunogenic peptides for many antigens have been defined. The 32 individual peptides that comprise the CEF peptide pool represent such well-defined peptide determinants for Cytomegalo-, Epstein–barr-, and Influenza virus. We tested the accuracy of these peptide recognition predictions on 42 healthy human donors that have been high-resolution HLA-typed. According to the predictions, 241 recall responses should have been detected in these donors. Actual testing showed that 36 (15 %) of the predicted CD8 cell responses occurred in the high frequency range, 41 (17 %) in mid-frequencies, and 45 (19 %) were at the detection limit. In 119 instances (49 %), the predicted peptides were not targeted by CD8 cells detectably. The individual CEF peptides were recognized in an unpredicted fashion in 57 test cases. Moreover, the frequency of CD8 cells responding to a single peptide did not reflect on the number of CD8 cells targeting other determinants on the same antigen. Thus, reliance on one or a few predicted peptides provides a rather inaccurate assessment of antigen-specific CD8 cell immunity, strongly arguing for the use of peptide pools for immune monitoring.

How much of virus-specific CD8 T cell reactivity is detected with a peptide pool when compared to individual peptides?

Immune monitoring of T cell responses increasingly relies on the use of peptide pools. Peptides, when restricted by the same HLA allele, and presented from within the same peptide pool, can compete for HLA binding sites. What impact such competition has on functional T cell stimulation, however, is not clear. Using a model peptide pool that is comprised of 32 well-defined viral epitopes from Cytomegalovirus, Epstein-Barr virus, and Influenza viruses (CEF peptide pool), we assessed peptide competition in PBMC from 42 human subjects. The magnitude of the peptide pool-elicited CD8 T cell responses was a mean 79% and a median 77% of the sum of the CD8 T cell responses elicited by the individual peptides. Therefore, while the effect of peptide competition was evident, it was of a relatively minor magnitude. By studying the dose-response curves for individual CEF peptides, we show that several of these peptides are present in the CEF-pool at concentrations that are orders of magnitude in excess of what is needed for the activation threshold of the CD8 T cells. The presence of such T cells with very high functional avidity for the viral antigens can explain why the effect of peptide competition is relatively minor within the CEF-pool.

Evolutionary origin of the immune system: a dialogue with Rod Langman

The need of a specific defence mechanism against intracellular pathogens is proposed to have arisen very early in evolution, perhaps already in protozoa, e.g. amoebae. The phagocytic machinery of amoebae lends itself as a possible starting point for the evolution of such a mechanism. The hypothetical evolutionary pathway described here has been constructed to demonstrate the feasibility of developing a defence system against pathogens in the amoeba, which bears resemblances to contemporary cell-mediated immunity, and can thus be considered as its ancestor.

Dynamic stability in random and scale-free B-lymphocyte networks

One of the most intriguing features of the immune system is regulation: a limited response when perturbed repeatedly. We propose a minimal network model for immune regulation in a lymphocyte network containing two types of elements: B lymphocytes and ligands that bind to their receptors. Effective interactions between B cells, mediated by other components of the immune system can be excitatory or inhibitory. In our model, B cell clones and ligand species are represented by nodes, and interactions by links. We expect that, as in many complex systems, the connectivity distribution is broad, motivating study of the model on a scale-free network; for comparison we study the same dynamics on a random graph. We characterize the dynamics of the model and its response to perturbations. Our model reproduces several key features of immune system dynamics: regulation (saturation of response), and more rapid response upon repeated perturbation with the same agents. Our results suggest that a scale-free network of interactions contributes to the regulation and dynamics of the immune system.

Spontaneous inflammatory disease in HLA-B27 transgenic mice does not require transporter of antigenic peptides

HLA-B27 is strongly linked with a group of human diseases called spondyloarthropathies. Even though HLA-B27 as an MHC class I molecule would be expected to present endogenously processed peptides such as cytosolic or viral proteins, many of the B27-linked diseases begin after an infection with an enterobacteria, an exogenous antigen. In our previous studies, we have described development of spontaneous inflammatory disease in HLA-B27 transgenic mice expressing beta(2)m free heavy chains on the cell surface. In order to address the role of endogenous versus exogenous antigens and a role for Tap genes in the development of spontaneous diseases, mice lacking Tap-1 (knockout) were mated to HLA-B27/human beta(2)m transgenic mice. B27(+)/human beta(2)m(+) double-transgenic mice (without mouse beta(2)m) lacking the Tap-1 gene developed spontaneous inflammatory disease similar to wild-type Tap-1 gene-expressing counterparts. Our data demonstrate that peptide transporters (Tap) were not involved in the development of spontaneous inflammatory disease in B27(+)/human beta(2)m transgenic animals.

MHC-restricted antigen presentation and recognition: constraints on gene, recombinant and peptide vaccines in humans

The target of any immunization is to activate and expand lymphocyte clones with the desired recognition specificity and the necessary effector functions. In gene, recombinant and peptide vaccines, the immunogen is a single protein or a small assembly of epitopes from antigenic proteins. Since most immune responses against protein and peptide antigens are T-cell dependent, the molecular target of such vaccines is to generate at least 50-100 complexes between MHC molecule and the antigenic peptide per antigen-presenting cell, sensitizing a T cell population of appropriate clonal size and effector characteristics. Thus, the immunobiology of antigen recognition by T cells must be taken into account when designing new generation peptide- or gene-based vaccines. Since T cell recognition is MHC-restricted, and given the wide polymorphism of the different MHC molecules, distinct epitopes may be recognized by different individuals in the population. Therefore, the issue of whether immunization will be effective in inducing a protective immune response, covering the entire target population, becomes an important question. Many pathogens have evolved molecular mechanisms to escape recognition by the immune system by variation of antigenic protein sequences. In this short review, we will discuss the several concepts related to selection of amino acid sequences to be included in DNA and peptide vaccines.

Clinical Significance of HLA-DRB1*0410 in Japanese Patients With Idiopathic Thrombocytopenic Purpura

We performed HLA-A, -B, and -C antigen and -DR DNA typing in 111 Japanese patients with idiopathic thrombocytopenic purpura (ITP). DRB1*0410 was significantly increased in ITP patients compared with healthy controls (relative risk = 9.52, P < .05), but the other DRB1*04 alleles showed no significant differences. On HLA-DR serotyping, patients with Vogt-Koyanagi-Harada disease (VKH) had a high frequency of DR4, so we compared the frequencies of DRB1*04 suballeles between ITP and VKH. The high frequency of DRB1*04 was dependent on DRB1*0405 in VKH, but on DRB1*0410 in ITP. Plasma autoantibodies were studied in 111 patients using a microtiter well assay. Thirty-six patients had anti-GPIIb/IIIa autoantibodies, and antibody positivity was associated with HLA-DR4 (29 of 36, 80.6% v 28 of 75, 37.3%) but not with DRB1*0410. When HLA-DR4 and DRB1*0410 were compared between patients with a good or poor response to prednisolone, HLA-DR4 was decreased and DRB1*0410 was significantly decreased (χ2 = 11.455, P < .01) in patients with a good response. In conclusion, this study showed that genetically determined factors influence the course of ITP. However, our findings should be considered preliminary because of possible racial differences in HLA status between Japanese and other ITP patients.

Clinical Significance of HLA-DRB1*0410 in Japanese Patients With Idiopathic Thrombocytopenic Purpura

We performed HLA-A, -B, and -C antigen and -DR DNA typing in 111 Japanese patients with idiopathic thrombocytopenic purpura (ITP). DRB1*0410 was significantly increased in ITP patients compared with healthy controls (relative risk = 9.52, P < .05), but the other DRB1*04 alleles showed no significant differences. On HLA-DR serotyping, patients with Vogt-Koyanagi-Harada disease (VKH) had a high frequency of DR4, so we compared the frequencies of DRB1*04 suballeles between ITP and VKH. The high frequency of DRB1*04 was dependent on DRB1*0405 in VKH, but on DRB1*0410 in ITP. Plasma autoantibodies were studied in 111 patients using a microtiter well assay. Thirty-six patients had anti-GPIIb/IIIa autoantibodies, and antibody positivity was associated with HLA-DR4 (29 of 36, 80.6% v 28 of 75, 37.3%) but not with DRB1*0410. When HLA-DR4 and DRB1*0410 were compared between patients with a good or poor response to prednisolone, HLA-DR4 was decreased and DRB1*0410 was significantly decreased (χ2 = 11.455, P < .01) in patients with a good response. In conclusion, this study showed that genetically determined factors influence the course of ITP. However, our findings should be considered preliminary because of possible racial differences in HLA status between Japanese and other ITP patients.

Determinant selection for T-cell tolerance in HEL-transgenic mice: dissociation between immunogenicity and tolerogenicity

The induction of T-cell tolerance to self-antigens has been extensively characterized for immunodominant (ID) regions. However, tolerance toward other minor self-determinants has received less attention. In the H-2(d) haplotype, HEL contains a single ID determinant (region 102-120) presented by I-E(d) MHC class II molecules. The present study evaluates the role of subdominant and cryptic HEL regions in maintaining tolerance. We have generated a mutated HEL antigen, HEL mu, whose ID region does not bind to I-E(d). Lymph node cells from HEL-immunized mice proliferated strongly to HEL mu in vitro. Two new stimulatory regions common to HEL and HEL mu were uncovered. They are produced during antigen processing and prime specific T lymphocytes. HEL-Tg mice were tolerant to these determinants, thus confirming their in vivo presentation. These HEL regions were as tolerogenic as the HEL ID determinant, despite their poor immunogenicity. These results demonstrate that there is not always a correlation between tolerogenicity and immunogenicity, a finding that may be critical for understanding T-cell tolerance.

Pathogen-based models favoring MHC genetic diversity

We present six models that are currently the most likely ways that pathogens might favor the evolution of MHC genetic diversity. Although each model makes one or more unique predictions, the current lack of crucial data prevents distinguishing the relative importance of each model. However, this first-time organization of these models should contribute to the design of critical experiments. This synthetic review yields at least three essentially new ideas. First, MHC-dependent immune recognition may be sufficiently redundant to render it essentially escape-proof by pathogens. Second, the four models based on pathogen escape do not work (or work weakly) for diversifying class II genes, unless class II-restricted cytotoxic T-cells are important, an idea that is controversial. Third, pathogen-escape events have traditionally been thought to result in only frequency-dependent selection but here we show that heterozygote advantage is an inevitable consequence of such pathogen evasion. Therefore, the controversy over the relative importance of these two forms of balancing selection is largely a false dichotomy.

The inability to process a self-peptide allows autoreactive T cells to escape tolerance

It is now clear that antigen presenting cells (APCs) do not present all the possible peptides of self-proteins to the immune system. When then, is the fate of T cells specific for those self-peptides that escape processing? In this study, the COOH-terminal peptide (residues 81-104) of self cytochrome c (cyt c) elicited strong autoimmune T cells, as well as autoantibodies specific for this immunogen. These T cells did not respond to stimulation with the whole self cyt c molecule, demonstrating that APCs cannot process and present the self 81-104 peptide. Whereas mice were unresponsive to immunization with the whole mouse cyt c molecule, the mouse 81-104 fragment together with the whole self-molecule induced and amplified the autoimmune T cell response to sites within the 1-80 peptide. T cells that never contact the relevant self-peptide are functionally ignorant. They do not become tolerized or deleted, nor do they normally participate in immune responses to the native whole self-protein, since APCs cannot present the 81-104 peptide.

Distribution of interferon-gamma receptor in human tissues

Interferon-gamma (IFN-gamma) is produced by activated T lymphocytes and plays a regulatory role in immune responses. The nature and location of cells that express the IFN-gamma receptor (R) and respond to this lymphokine are not well documented. The distribution of human IFN-gamma-R (HuIFN-gamma-R) was, therefore, investigated in situ by immunohistochemistry, using affinity-purified rabbit polyclonal antibodies directed against the extracellular domain of the receptor. In lymphoid organs, IFN-gamma-R expression is restricted to the B cell areas of lymph nodes, adult and fetal spleen, tonsils, appendix, and mucosa-associated lymphoid tissue of the small bowel. Macrophages and other reticular cells in lymphoid tissues and other organs are strongly positive for IFN-gamma-R, whereas its expression was consistently negative in the cortical and medullary thymocytes. Two-color flow cytofluorometric analysis of blood, lymph node, tonsil, spleen and thymus cells confirms that most B lymphocytes are IFN-gamma-R positive, whereas T lymphocytes are negative. However, after in vitro activation, peripheral blood T cells become IFN-gamma-R+. In non-lymphoid organs, IFN-gamma-R is expressed on endothelial cells of the medium- and small-size vessels. In epithelial tissues, high expression of IFN-gamma-R is detected on trophoblastic epithelium, glandular cells of stomach, ileum and colon, lung alveolar cells, salivary duct cells, renal tubular cells, and endometrial mucosa cells. Hepatocytes are weakly positive, while squamous epithelial cells are negative. The distribution of the HuIFN-gamma-R is discussed in view of the known functions of IFN-gamma.

Comparison between the MHC-restricted antibody repertoire to Ascaris antigens in adjuvant-assisted immunization or infection

Genetic restrictions to the immune repertoire will be an important consideration in the development of anti-nematode vaccines. It has already been established that the major histocompatibility complex (MHC) limits responsiveness to nematode antigens in infection, but little is known of whether this also applies under other routes of sensitization, such as with adjuvants. The specificity of the antibody response was, therefore, compared in infection and adjuvant-assisted immunization using secreted and somatic antigens of Ascaris suum as a model system in mice and rats. The findings were, first, that the lack of responsiveness to certain antigens in infection was not circumvented by Freund's adjuvant-based immunization, despite the fact that the latter generally elicited higher levels of response. Secondly, that adjuvant-assisted immunization could elicit responses to parasite products which were not detectable in the context of infection. Conversely, some specificities were detectable in infection but absent under adjuvant immunization. Finally, immunization with a defined parasite allergen (ABA-1) in Freund's adjuvant did not provoke an IgE response which would be anticipated if the molecule were to have an intrinsic allergenic property. These results are likely to be of general importance to the application of subunit or recombinant vaccines against nematodiases and to the hypersensitivity reactions which vaccination might engender or recall.

A monoclonal antibody against HSV type 1 ribonucleotide reductase cross-reacts with the P0 protein of peripheral nerve myelin

An epitope on peripheral nerve myelin was detected by the use of a mouse monoclonal antibody directed against the 38 kDa subunit of herpes simplex virus (HSV) type 1 ribonucleotide reductase. Immunohistochemistry showed reactivity solely in PNS myelin. In nerve roots there was a sharp border in transitional zones to the negative CNS myelin. The immunoreactivity was found in rat, guinea pig, bovine and human peripheral nerves. Western blot analysis of peripheral nerve myelin as well as purified P0 revealed a distinctly stained band corresponding to a molecular weight of approximately 29 kDa. The present finding of a shared antigenic determinant between HSV ribonucleotide reductase and peripheral nerve P0 may be of pathogenetic relevance in virus induced demyelinating diseases in the peripheral nervous system.

Cell-surface molecules in the regulation of immune responsiveness

This paper reviews current knowledge genetics, structure and function on three categories of cell-surface molecules that affect immune responsiveness. It is focused on human molecules, but some references to murine analogues are made. First, the Major Histocompatibility Complex (MHC) molecules are discussed from the point of view of the associative recognition of antigenic peptides. The multiplicity, polymorphism and heterozygosity of MHC genes is correlated with the fine structure and the function of the molecules encoded by these genes. Second, selected CD molecules that are involved in cell-cell interaction and transduction of signals are discussed and correlated with discrete subsets of T cells, finally, some cell-surface receptors, antigen-specific and interleukin-specific, are analyzes, the effect of various molecules on immune responsiveness is illustrated by the actual experimental data. A minimal or parsimonious of triggering an immune response in which the discussed molecules are involved is described as a starting point for further discussion.

Evolution of the major histocompatibility complex: molecular cloning of major histocompatibility complex class I from the amphibian Xenopus

Class I major histocompatibility complex (MHC) cDNA clones have been isolated from an expression library derived from mRNA of an MHC homozygous Xenopus laevis. The nucleotide and predicted amino acid sequences show definite similarity to MHC class I molecules of higher vertebrates. The immunoglobulin-like alpha-3 domain is more similar to the immunoglobulin-like domains of mammalian class II beta chains than to those of mammalian class I molecules, and a tree based on nucleotide sequences of representative MHC genes is presented.

The immune recognition of malaria antigens

Owing to the demonstration that the immune response of inbred mice to some defined malaria antigens is influenced by the major histocompatibility complex (MHC), and the finding that only a minority of individuals living in malaria-endemic areas appear to recognize such antigens, there are fears that synthetic subunit malaria vaccines will be poorly immunogenic in a substantial proportion of the target population. Such fears have been reinforced by the results of the first two human malaria vaccine trials. In this review Eleanor Riley, Olle Olerup and Marita Troye-Blomberg summarize the experimental evidence for MHC-related genetic restriction of malaria immunity and discuss some alternative explanations for nonresponsiveness in populations living in malaria-endemic areas.

Adoptive transfer of experimental allergic encephalomyelitis and localization of the encephalitogenic epitope in the SWR mouse

Adoptively-transferred experimental allergic encephalomyelitis (EAE) was induced in the SWR (H-2q) strain of mouse using lymph node cells, spleen cells, or cell lines sensitized to whole myelin basic protein (MBP). With the aid of synthetic peptides, the minimal encephalitogenic epitope of MBP for the SWR strain was localized to amino acids 87-99 of the MBP molecule. The 87-99 sequence is also encephalitogenic for the SJL strain of mouse and the Lewis rat. EAE was induced with a protocol similar to that for the induction of EAE in the SJL strain with the exception that sublethal irradiation of recipients was necessary. Mice developed typical clinical and pathological EAE 6-14 days post-transfer of cells sensitized to either whole MBP or peptide 87-99, after which they remitted. No relapses were observed. Thus, adoptively transferred EAE can be induced in irradiated H-2q mice for which the encephalitogenic epitope is one of the nested encephalitogenic epitopes for SJL (H-2s) mice, namely residues 87-99.

Allelic variations of human TCR V gene products

A central problem confronting the immune system is how to discriminate among vast numbers of antigens. Novel genetic ploys that aid the discriminative process, including complex gene rearrangements (in antibody and T-cell receptor (TCR) genes) and extensive allelic polymorphism (in major histocompatibility complex (MHC) genes), have been described. Recent evidence has suggested a further level of diversity; TCR V gene allelic variation. In this article David Posnett summarizes evidence in favour of this possibility and speculates on the possible functional consequences of TCR allelism.

Lymphokine-activated killer (LAK) cells discriminate between Epstein-Barr virus (EBV)-positive Burkitt's lymphoma cells

We have generated in vitro lymphokine-activated killer (LAK) cells from healthy donors by stimulating their mononuclear leukocytes with recombinant interleukin-2 (rIL-2) (100 U/ml). After 6 days in culture, the lytic properties of the LAK cells were analyzed in the 51Cr-release assay by utilizing a target panel of 6 paired lines consisting of an Epstein-Barr virus (EBV)-positive Burkitt's lymphoma (BL) cell line and an EBV-transformed lymphoblastoid cell line (LCL) from the same donor, the Raji BL line and the natural killer (NK) cell-sensitive K562 line. The patterns of lysis showed that the LAK cells discriminated between two categories of BL cell lines. Group I/II BL tumor cells which expressed the common acute lymphoblastic leukemia antigen (CALLA), the BL-associated glycolipid antigen (BLA) and phenotypically resembled biopsy cells were strongly lysed whereas group III BL cells which had assumed an LCL-like phenotype during culture and lacked the CALLA and BLA surface markers were only poorly lysed. The LCL targets were generally resistant to lysis but the K562 cell line was particularly sensitive. The outcome of cell depletion and monoclonal antibody (MAb) studies indicated that the LAK cell populations were phenotypically and functionally heterogeneous and consisted of at least 2 subpopulations of effector cells; a tumor-specific component and an NK-cell-mediated component.

The relationship between bovine major histocompatibility complex class II polymorphism and disease studied by use of bull breeding values

The predictive value of class II DQ and DYA polymorphisms of the bovine major histocompatibility (MHC) complex (BoLA) for the incidence of disease in dairy cattle was estimated in a sample of 196 progeny-tested AI bulls of the Swedish Red and White breed. The BoLA DQ and DYA types of the bulls were determined by analysing restriction fragment length polymorphisms (RFLPs). Breeding values of bulls for clinical mastitis, all diseases including clinical mastitis and diseases other than clinical mastitis were used as measures of disease resistance or susceptibility. The relationship between MHC polymorphism and bull breeding values for disease resistance was evaluated statistically by linear regression analysis. A significant association between the haplotype DQ1A and susceptibility to clinical mastitis was revealed. No other DQ haplotype nor the DYA locus has a significant effect on any of the disease traits studied.

Limit of T cell tolerance to self proteins by peptide presentation

Cytotoxic T lymphocytes (CTLs) recognize foreign peptides bound to major histocompatibility complex (MHC) class I molecules. MHC molecules can also bind endogenous self peptides, to which T cells are tolerant. Normal mice contained CTLs specific for self peptides that were from proteins of ubiquitous or tissue-restricted expression. In vivo, these endogenous self peptides are not naturally presented in sufficient density by somatic cells expressing MHC class I molecules. They can, however, be presented if added exogenously. Thus, our data imply that CTLs are only tolerant of those endogenous self peptide sequences that are presented by MHC class I-positive cells in a physiological manner.

The role of ligand-receptor interactions in disease

Ligand-receptor interactions play a determining role in many cell biological interactions. Mutations of ligands or receptors can both cause a disturbance in these interactions. In this paper an example will be given of these types of defects. Finally it will be speculated which role receptor mechanisms may play in the field of dermatology.

Treatment of adjuvant arthritis in rats: vaccination potential of a synthetic nonapeptide from the 65 kDa heat shock protein of mycobacteria

Adjuvant arthritis induced by mycobacteria in rats is a widely used model of chronic arthritis. A previously described nonapeptide (Thr-Phe-Gly-Leu-Gln-Leu-Glu-Leu-Thr, amino acid sequence 180-188) from the recombinant 65 kDa heat shock protein of Mycobacterium bovis BCG, which was found to contain a T-cell epitope recognized by both arthritogenic and protective T-cell clones in vitro, has been investigated for its vaccination and therapeutic potential in adjuvant arthritis in rats. The nonapeptide was found not to be arthritogenic, although the T cells from nonapeptide immunized rats cross-react in vitro with mycobacterial antigens. Intraperitoneal administration of 0.1 mg nonapeptide in oil at day -20 or days -2, -1 and 0, resulted in a marked reduction of incidence and severity of adjuvant arthritis. The disease process and severity were also influenced by therapeutic treatment with 0.1 mg nonapeptide injected intraperitoneally at days 7 to 10. Interestingly, subplantar or intravenous application of the nonapeptide had no influence on the disease process. Deletion of the N-terminal threonine led to complete loss of in vivo activity of the nonapeptide.

Clonalism--the myth?

Two regulatory mechanisms, based on the contrasting concepts of imprinting (clonal theories and idiotypic networks) and of ongoing regulation of immune responses (by antigen and end products with specificity for antigen), give rise to different predictions and approaches to the question of autoimmunity and autoimmune disease. Both concepts have legitimacy, however, if a ranking in terms of explicative power must be given, ongoing regulation is more plausible since it accounts more fully for basic events in immune responses and in autoimmune phenomena. Many instructive findings have emerged from experiments based on this latter concept, furthermore, the approach has only received limited notice and, thus, has not yet been exhausted.

A single amino acid interchange yields reciprocal CTL specificities for HIV-1 gp160

For the IIIB isolate of human immunodeficiency virus type-1 (HIV-1), the immunodominant determinant of the envelope protein gp160 for cytotoxic T lymphocytes (CTLs) of H-2d mice is in a region of high sequence variability among HIV-1 isolates. The general requirements for CTL recognition of peptide antigens and the relation of recognition requirements to the natural variation in sequence of the HIV were investigated. For this purpose, a CTL line specific for the homologous segment of the envelope from the MN isolate of HIV-1 and restricted by the same class I major histocompatibility (MHC) molecule (Dd) as the IIIB-specific CTLs was raised from mice immunized with MN-env-recombinant vaccinia virus. The IIIB-specific and MN-specific CTLs were completely non-cross-reactive. Reciprocal exchange of a single amino acid between the two peptide sequences, which differed in 6 of 15 residues, led to a complete reversal of the specificity of the peptides in sensitizing targets, such that the IIIB-specific CTLs lysed targets exposed to the singly substituted MN peptide and vice versa. These data indicate the importance of single residues in defining peptide epitopic specificity and have implications for both the effect of immune pressure on selection of viral mutants and the design of effective vaccines.

Genetic control of the immune repertoire in nematode infections

Mammals vary considerably, both within and between species, in the way in which their innate and adaptive immune systems respond to infections. An understanding of the processes involved in such variability will not only contribute to explaining heterogeneity in susceptibility and pathology, but will also be relevant to vaccination. This will be particularly important for the new generation of vaccines that are likely to be composed of one or a few cloned or synthesized antigens. For helminth infections, this could have particular relevance to hypersensitivity responses. The adaptive immune response is fundamentally constrained by the genetic constitution of an individual, and the need to avoid reactivity to self. This will have important implications for the dynamic relationship between host defences and parasite evasion mechanisms at both physiological and evolutionary levels. In this review, Malcolm Kennedy examines the genetic control of the specificity of the immune response to nematode infections, and in particular, the role of the major histocompatibility complex.