Both MHC and background gene heterozygosity alter T cell receptor repertoire selection in an antigen-specific response

Loss in CD4 T-cell responses to multiple epitopes in influenza due to expression of one additional MHC class II molecule in the host

An understanding of factors controlling CD4 T-cell immunodominance is needed to pursue CD4 T-cell epitope-driven vaccine design, yet our understanding of this in humans is limited by the complexity of potential MHC class II molecule expression. In the studies described here, we took advantage of genetically restricted, well-defined mouse strains to better understand the effect of increasing MHC class II molecule diversity on the CD4 T-cell repertoire and the resulting anti-influenza immunodominance hierarchy. Interferon-γ ELISPOT assays were implemented to directly quantify CD4 T-cell responses to I-A(b) and I-A(s) restricted peptide epitopes following primary influenza virus infection in parental and F(1) hybrid strains. We found striking and asymmetric declines in the magnitude of many peptide-specific responses in F(1) animals. These declines could not be accounted for by the lower surface density of MHC class II on the cell or by antigen-presenting cells failing to stimulate T cells with lower avidity T-cell receptors. Given the large diversity of MHC class II expressed in humans, these findings have important implications for the rational design of peptide-based vaccines that are based on the premise that CD4 T-cell epitope specificity can be predicted by a simple cataloguing of an individual's MHC class II genotype.

Major histocompatibility complex heterozygosity enhances reproductive success

We investigated how heterozygosity at the major histocompatibility complex (MHC) affects fitness in wild-derived (F2) house mice (Mus musculus musculus). To compare and control for potential confounding effects from close inbreeding and genome-wide heterozygosity, we used mice that were systematically outbred. We assessed how heterozygosity at MHC and background loci (using 15 microsatellite markers on 11 different chromosomes) affects individual survival and reproductive success (RS) in large, semi-natural population enclosures. We found that overall heterozygosity significantly increased RS, and this correlation was entirely explained by heterozygosity at two MHC loci. Moreover, we found that the effects of MHC heterozygosity depend on the level of background heterozygosity, and the benefits of maximal MHC heterozygosity show a curvilinear effect with increasing background heterozygosity. The enhanced RS from MHC heterozygosity was not because of increased survival, and although MHC heterozygosity was correlated with body mass, body mass did not correlate with RS when heterozygosity is controlled. Breeders were more MHC heterozygous than nonbreeders for both sexes, indicating that MHC heterozygosity enhanced fecundity, mating success or both. Our results show that (i) MHC heterozygosity enhances fitness among wild, outbred as well as congenic laboratory mice; (ii) heterozygosity-fitness correlations can potentially be explained by a few loci, such as MHC; (iii) MHC heterozygosity can increase fitness, even without affecting survival, by increasing mating and RS; and (iv) MHC effects depend on background genes, and maximal MHC heterozygosity is most beneficial at intermediate or optimal levels of background heterozygosity.

Major histocompatibility complex heterozygosity reduces fitness in experimentally infected mice

It is often suggested that heterozygosity at major histocompatibility complex (MHC) loci confers enhanced resistance to infectious diseases (heterozygote advantage, HA, hypothesis), and overdominant selection should contribute to the evolution of these highly polymorphic genes. The evidence for the HA hypothesis is mixed and mainly from laboratory studies on inbred congenic mice, leaving the importance of MHC heterozygosity for natural populations unclear. We tested the HA hypothesis by infecting mice, produced by crossbreeding congenic C57BL/10 with wild ones, with different strains of Salmonella, both in laboratory and in large population enclosures. In the laboratory, we found that MHC influenced resistance, despite interacting wild-derived background loci. Surprisingly, resistance was mostly recessive rather than dominant, unlike in most inbred mouse strains, and it was never overdominant. In the enclosures, heterozygotes did not show better resistance, survival, or reproductive success compared to homozygotes. On the contrary, infected heterozygous females produced significantly fewer pups than homozygotes. Our results show that MHC effects are not masked on an outbred genetic background, and that MHC heterozygosity provides no immunological benefits when resistance is recessive, and can actually reduce fitness. These findings challenge the HA hypothesis and emphasize the need for studies on wild, genetically diverse species.

The course of malaria in mice: major histocompatibility complex (MHC) effects, but no general MHC heterozygote advantage in single-strain infections

A general MHC-heterozygote advantage in parasite-infected organisms is often assumed, although there is little experimental evidence for this. We tested the response of MHC-congenic mice (F2 segregants) to malaria and found the course of infection to be significantly influenced by MHC haplotype, parasite strain, and host gender. However, the MHC heterozygotes did worse than expected from the average response of the homozygotes.

Molecular basis of antigen recognition by insulin specific T cell receptor

The TCR alpha/beta chains recognize antigen peptides bound to the groove of the MHC class II molecule. The crystal structure analyses of the TCR/peptide/MHC class II complexes have revealed that the Valpha chains play a significant role in antigen recognition. However, molecular details which amino acid residues of the Valpha chain are able to contribute to fine antigen specificity are not clearly understood. Previously, we have classified a panel of T hybrids specific for insulin isotypes from different species of animals into four groups based on response profiles to these antigens. In particular, the group III (pork insulin > or = beef insulin hierarchy of responsiveness) and IV (pork insulin >> beef insulin hierarchy of responsiveness) T hybrids are interesting, since these TCR alpha/beta chains with marked different antigen specificities demonstrate identical gene usages and very similar sequences. To specifically address the molecular requirements for insulin recognition by TCR, the TCR alpha and beta chain genes from these group III and IV T hybrids were transfected into 58 alpha-beta- T hybrid. The experiments suggested that CDR3alpha dictates the fine antigen specificity. Then, we have introduced a series of mutations into position 95 of CDR3alpha. The mutation experiments clearly indicated that position 95alpha determines the antigen specificity of the group III and IV T hybrids.

T cell receptor beta chain genotyping in Australian relapsing-remitting multiple sclerosis patients

This study focused on susceptibility to MS within the beta-chain of the T-cell antigen receptor (TCRB locus, 7q35) in a cohort of 122 RR-MS patients compared with 96 normal individuals using biallelic polymorphisms across the bv8s1(Vbeta8.1) to bv11s1 (Vbeta11) TCRB subregion. The markers bv6s5, bv8s1, bv10s1, bv15s1 and bv3s1 were studied for allele and genotype frequencies; haplotypes were assigned with combinations of two of these markers and stratification for HLA-DR15 was also performed. Linkage disequilibrium was found between alleles of the bv8s1, bv10s1/bv15s1 and bv3s1 loci in both patients and controls. An increase among RR-MS patients in the allele frequency of bv8s1*2 (P=0.03) and the haplotype bv8s1*2/bv3s1*1 (P=0.006) was noted and both were found to be statistically significant. In the DR15-positive group, the association between TCRB and MS was seen with the bv8s1*2 allele (Puc=0.05) and the bv8s1*2/bv10s1 haplotypes (Puc=0.048), while the haplotype associations seen among DR15-negative RR-MS patients included the bv3s1*1 allele (bv10s1*1/ bv3s1*1, Puc=0.022; bv8s1*2/bv3s1*1, Puc=0.048). These results support the involvement of the TCRB region in MS susceptibility and encourage further study of the variable gene segments in this region.

The Orientation and Nature of the Interaction Between Beef Insulin-Specific TCRs and the Insulin/Class II MHC Complex

Recent crystallographic studies suggest that TCR interact with peptide/class I MHC complexes in a single preferred orientation. Although similar studies have not been performed for class II-restricted TCR, it has been proposed that T cell recognition of peptide/class II complexes has similar orientational restrictions. This study represents a functional approach to systematic analysis of this question. Twenty-one mutant Aβd molecules were produced by alanine scanning mutagenesis and assessed for their ability to present species variants of insulin to a panel of beef insulin-specific T cell hybridomas with limited TCR α- and/or β-chain sequence differences. We demonstrate that all beef insulin-specific TCR have the same orientation on the insulin/Ad complex, such that the α-chain interacts with the carboxyl-terminal region of the Aβd α-helix, and the β-chain complementarity-determining region 3 interacts with the carboxyl-terminal portion of the peptide, consistent with that observed for crystallized TCR-peptide/class I complexes. Despite this structural constraint, even TCR that share structural similarity show remarkable heterogeneity in their responses to the panel of MHC mutants. This variability appears to result from conformational changes induced by binding of the TCR to the complex and the exquisite sensitivity of the threshold for T cell activation.

MHC-genotype of progeny influenced by parental infection

In a previous series of in vitro fertilization experiments with mice we found non-random combination of major histocompatibility complex (MHC) haplotypes in the very early embryos. Our results suggested that two selection mechanisms were operating: (i) the eggs selected specific sperm; and (ii) the second meiotic division in the eggs was influenced by the type of sperm that entered the egg. Furthermore, the proportion of MHC-heterozygous embryos varied over time, suggesting that non-random fertilization was dependent on an external factor that changed over time. As a higher frequency of heterozygous individuals correlated with an uncontrolled epidemic by MHV (mouse hepatitis virus), we suggested that MHV-infection might have influenced the outcome of fertilization. Here, we present an experiment that tests this hypothesis. We infected randomly chosen mice with MHV and sham-infected control mice five days before pairing. We recovered the two-cell embryos from the oviduct, cultured them until the blastocyst stage, and determined the genotype of each resulting blastocyst by polymerase chain reaction. We found the pattern that we expected from our previous experiments: virus-infected mice produced more MHC-heterozygous embryos than sham-infected ones. This suggests that parents are able to promote specific combinations of MHC-haplotypes during fertilization according to the presence or absence of a viral infection.