Restrictions on the use of antigenic peptides by the immune system

The human Major Histocompatibility Complex as a paradigm in genomics research

Since its discovery more than 50 years ago, the human Major Histocompatibility Complex (MHC) on chromosome 6p21.3 has been at the forefront of human genetic research. Here, we review from a historical perspective the major advances in our understanding of the nature and consequences of genetic variation which have involved the MHC, as well as highlighting likely future directions. As a consequence of its particular genomic structure, its remarkable polymorphism and its early implication in numerous diseases, the MHC has been considered as a model region for genomics, being the first substantial region to be sequenced and establishing fundamental concepts of linkage disequilibrium, haplotypic structure and meiotic recombination. Recently, the MHC became the first genomic region to be entirely re-sequenced for common haplotypes, while studies mapping gene expression phenotypes across the genome have strongly implicated variation in the MHC. This review shows how the MHC continues to provide new insights and remains in the vanguard of contemporary research in human genomics.

Features of MHC and NK gene clusters

When comparing the immune genome to the genome in general, a higher prevalence for association with disease is the only genetic feature significant in immune genes as a group. However, some genetic features, such as marked levels of polymorphism and gene duplication, are present in subsets of immune genes, namely the Major Histocompatibility Complex (MHC) and Natural Killer (NK) cell receptor gene complexes. In this review, we discuss features of MHC and NK receptor gene clusters, their epistatic interactions, and the impact of both on association to disease.

Extensive interbreed, but minimal intrabreed, variation of DLA class II alleles and haplotypes in dogs

The DLA class II genes in the dog major histocompatibility complex are highly polymorphic. To date, 52 DLA-DRB1, 16 DLA-DQA1 and 41 DLA-DQB1 allelic sequences have been assigned. The aim of this study was to examine the intrabreed and interbreed variation of DLA allele and haplotype frequencies in dogs, and to ascertain whether conserved DLA class II haplotypes occur within and between different breeds. One thousand and 25 DNA samples from over 80 different breeds were DLA class II genotyped, the number of dogs per breed ranging from 1 to 61. DNA sequence based typing and sequence specific oligonucleotide probing were used to characterize dogs for their DLA-DRB1, DQA1 and DQB1 alleles. The high frequency of DLA class II homozygous animals (35%), allowed the assignment of many haplotypes despite the absence of family data. Four new DLA alleles were identified during the course of this study. Analysis of the data revealed considerable interbreed variation, not only in allele frequency, but also in the numbers of alleles found per breed. There was also considerable variation in the number of breeds in which particular alleles were found. These interbreed variations were found in all three DLA class II loci tested, and also applied to the three-locus haplotypes identified. Within this data set, 58 different DLA-DRB1/DQA1/DQB1 three-locus haplotypes were identified, which were all found in at least two different animals. Some of the haplotypes appeared to be characteristic of certain breeds. The high interbreed, and relatively low intrabreed, variation of MHC alleles and haplotypes found in this study could provide an explanation for reports of interbreed variation of immune responses to vaccines, viruses and other infections.

The human major histocompatability complex: lessons from the DNA sequence

The entire 3.6-MbpDNA sequence of a human major histocompatibility complex derived from a composite of DNA clones from different haplotypes, was completed in 1999, primarily through the work of four main groups. At that time, it was the longest contiguous human DNA sequence to have been determined. The sequence is of extremely high quality and accuracy. In this review, we discuss how the DNA sequence has facilitated our understanding of the biology and genetics of the major histocompatibility complex. We suggest some ways in which the sequence may be exploited in the future to explore the relationship between the extraordinary polymorphism of the region and its association with both autoimmune and infectious diseases.

Leishmaniasis: current status of vaccine development

Leishmaniae are obligatory intracellular protozoa in mononuclear phagocytes. They cause a spectrum of diseases, ranging in severity from spontaneously healing skin lesions to fatal visceral disease. Worldwide, there are 2 million new cases each year and 1/10 of the world's population is at risk of infection. To date, there are no vaccines against leishmaniasis and control measures rely on chemotherapy to alleviate disease and on vector control to reduce transmission. However, a major vaccine development program aimed initially at cutaneous leishmaniasis is under way. Studies in animal models and humans are evaluating the potential of genetically modified live attenuated vaccines, as well as a variety of recombinant antigens or the DNA encoding them. The program also focuses on new adjuvants, including cytokines, and delivery systems to target the T helper type 1 immune responses required for the elimination of this intracellular organism. The availability, in the near future, of the DNA sequences of the human and Leishmania genomes will extend the vaccine program. New vaccine candidates such as parasite virulence factors will be identified. Host susceptibility genes will be mapped to allow the vaccine to be targeted to the population most in need of protection.

Sequence organisation of the class II region of the human MHC

We present the genomic organisation of the extended class II region of the human MHC. This initial sequence, which is nearing completion, spans about 1.2 Mbp and is at present a composite of more than one haplotype. The sequencing of single haplotypes is planned for the future. The current sequence encompasses all of the known class II genes at the DP, DO, DM, DQ and DR loci as well as the transporter associated with antigen processing (TAP)/low molecular weight protein (LMP) antigen processing genes and the Tapasin locus, at the extended centromeric end.

Genomic analysis of the Tapasin gene, located close to the TAP loci in the MHC

The Tapasin molecule is a member of the immunoglobulin (Ig) superfamily required for the association of TAP transporters and MHC class I heterodimers in the endoplasmic reticulum. In this study, the Tapasin gene was precisely mapped in relation to the MHC. The gene was centromeric of the HLA-DP locus between the HSET and HKE1.5 genes and within 500 kbp of the TAP1 and TAP2 genes. A homologous mouse EST was mapped to a syntenic position on chromosome 17, centromeric of the H-2 K locus. Similarly, the rat Tapasin gene was shown to be in an equivalent location with respect to the RT1.A locus. The localization of Tapasin, TAP, LMP and class I genes within such a short distance of each other on the chromosome implies some regulatory or functional significance. We determined the Tapasin gene sequence for comparison of its structure to that of other Ig superfamily members, such as MHC class I genes. The IgC domain was encoded by a separate exon. However, the positions of the other introns were not characteristic of other Ig superfamily genes, indicating that Tapasin has a distinct phylogeny.

Divergent intron arrangement in the MB1/LMP7 proteasome gene pair

We sequenced the human MB1 gene from a cosmid clone mapping to chromosome 14q11.2-12. The gene spans about 6 kilobases and contains three exons and two introns. There was no evidence of an alternative leader exon, which is a characteristic of the major histocompatibility complex (MHC)-encoded LMP7 gene, the closest relative of MB1, with which it shares 67% amino acid identity. Conceptual translation of the 5' end of the gene calls for a cleaved leader sequence of 59 amino acids, consistent with western blot data. None of the MB1 gene's three exons were coincident with any of the six exons in LMP7. In contrast, in the delta-encoding gene and its counterpart, the MHC-encoded LMP2 gene (59% amino acid identity), all six exons are arranged at equivalent positions in respect to the coding frame. The unique structure of MB1 implies a separate origin or different selection pressures acting at this particular locus. DNA repeat analysis provides information on the minimum time of separation of the MB1/LMP7 pair of genes.

Effects of interferon-alpha on cytokine profile, T cell receptor repertoire and peptide reactivity of human allergen-specific T cells

A large panel of T cell clones (TCC) specific for the recombinant form of Poa pratensis allergen (rKBG7.2 or Poa p9) were established from the peripheral blood of grass pollen-sensitive donor in the absence or presence of recombinant interferon-alpha (IFN-alpha) in bulk culture and their pattern of cytokine secretion, peptide reactivity and TCR V beta repertoire was examined. The majority of allergen-specific TCC derived in absence of IFN-alpha produced high amounts of interleukin-4 (IL-4) and IL-5 but not IFN-gamma (Th2 cells), while most of TCC derived in presence of IFN-alpha produced IFN-gamma but not, or limited amounts of, IL-4 and IL-5 (Th1 or Th0 cells). Of 24 TCC established in the presence of IFN-alpha, 22 were able to recognize a single allergen peptide, p26, while none of the clones established in the absence of IFN-alpha showed a similar specificity. The majority of both clones expressed the V beta 2 element regardless of whether they were established in the presence of INF-alpha, but the presence of IFN-alpha favored the expansion of V beta 2+, V beta 17+ and V beta 22+ Poa p9-specific T cells, whereas in the absence of IFN-alpha, other TCR V beta-bearing T cells (V beta 5, and V beta 6.7, and V beta 14) were expanded in addition to V beta 2+ T cells. None of V beta 2+ clones established in the absence of IFN-alpha reacted with p26, whereas all the V beta 2+ clones established in its presence in the absence of interferon-alpha reacted with p26, whereas all the V beta 2+ clones established in its presence reacted to this peptide. IFN-alpha also shifted the TCR V beta repertoire of both Poa p9- and Lolium perenne group 1 (Lol p1)-specific T cell lines generated from the same patient and from a different grass-sensitive individual. These data demonstrate that IFN-alpha modulates the development of allergen-specific T cells in vitro, and suggest that IFN-alpha may represent a useful tool for novel immunotherapeutic approaches in allergic disorders.

Discordant patterns of linkage disequilibrium of the peptide-transporter loci within the HLA class II region

Disequilibrium between genetic markers is expected to decline monotonically with recombinational map distance. We present evidence from the HLA class II region that seems to violate this principle. Pairwise disequilibrium values were calculated from six loci ranging in physical separation from 15 kb to 550 kb. The histocompatibility loci DRB1, DQA1, and DQB1, located on the distal end of the class II region, behave as a single evolutionary unit within which extremely high linkage disequilibrium exists. Lower but still significant levels of disequilibrium are present between these loci and DPB1, located at the proximal edge of the HLA complex. The peptide-transporter loci TAP1 and TAP2, located in the intervening region, reveal no disequilibrium with each other and low or negligible disequilibrium with the flanking loci. The action of two genetic process is required to account for this phenomenon: a recombinational hotspot operating between TAP1 and TAP2, to eliminate disequilibrium between these loci, and at the same time selection operating on particular combinations of alleles across the DR-DP region, to create disequilibrium in the favored haplotypes. The forces producing the patterns of disequilibrium observed here have implications for the mapping of train loci and disease genes: markers of TAP1, for example, would give a false impression as to the influence of DPB1 on a trait known to be associated with DQB1.

Polymorphic peptide transporters in MHC class I monomorphic Syrian hamster

We have already shown that in species with highly polymorphic major histocompatibility complex (MHC) class I molecules (human, mouse) no functional polymorphism of the peptide transporters TAP1 and TAP2 is detectable (Lobigs and Müllbacher 1993). Investigating the antigen-presentation machinery of the class I MHC monomorphic Syrian hamster using mouse MHC class I expression via recombinant vaccinia viruses (VV) we found that six hamster cell lines fall into two phenotypic classes. four cell lines (HaK, FF, MF-2, and HT-1) showed no defect in expressing four different H2 class I molecules (Kk, Kd, Kb, Dd) and the appropriate VV peptide recognized by mouse VV-immune cytotoxic T (Tc) cells on the cell surface. Two cell lines (BHK-21 and NIL-2) expressed Dd and Kb in association with VV peptides as recognized by VV-immune, H2-restricted Tc cells but not Kk and Kd. However, Kd was expressed on the cell surface, as shown by fluorescence-activated cell sorter (FACS) analysis and alloreactive Tc-cell recognition. Kk is only surface-expressed in these two cell lines when superinfected with two VV recombinants encoding rat TAP1 (VV-mtp1) and TAP2 (VV-mtp2). Superinfection with VV-mtp1 and VV-mtp2 rendered both cell lines, after infection with either VV-Kk and VV-Kd, susceptible to lysis by either Kk- or Kd-restricted VV-immune Tc cells. Thus Syrian hamster cell lines express functionally polymorphic peptide transporters. The TAP2 gene from FF cells was cloned and sequenced; comparison with human, mouse, and rat TAP2 sequences show 78%, 88% and 87% similarity, respectively.

Linkage mapping and partial sequencing of 10 cDNA loci in the chicken

Ten cDNA clones derived from chicken spleen cell mRNA have been partially sequenced and the genes which encode the mRNAs have been located within the linkage map of the chicken genome. The sequences of five of these clones show strong homology to known mammalian genes, the remainder show little homology to sequence present in the current databases. Interestingly, one of these clones appears to be the chicken homologue of the mammalian peptide transporter gene TAP2 and is located within the major histocompatibility complex. Two other clones are homologous to genes involved in protein synthesis and these are tightly linked in chickens, as in mice. These results suggest that partial sequencing and mapping of clones from selective cDNA libraries may be an efficient way of adding candidate genes to the chicken linkage map and that on a local scale there may be some conservation of grouping of genes between chickens and mammalian species.

Peptide length and sequence specificity of the mouse TAP1/TAP2 translocator

The transporter associated with antigen processing (TAP) delivers peptides to the lumen of the endoplasmic reticulum in an adenosine triphosphate (ATP) dependent fashion for presentation by major histocompatibility complex class I molecules. We show that the mouse TAP translocator (H-2b haplotype) selects peptides based on a minimal size of nine residues, and on the presence of a hydrophobic COOH-terminal amino acid. The preponderance of COOH-terminal hydrophobic amino acids in peptides capable of binding to mouse class I molecules thus fits remarkably well with the specificity of the TAP translocator. In addition to transport in the lumenal direction, efflux of peptide in the cytosolic direction is observed in an ATP- and temperature-dependent manner. By maintaining a low peptide concentration at the site of class I assembly, this efflux mechanism may ensure that class I molecules are loaded preferentially with high affinity peptides.

Peptide translocation by variants of the transporter associated with antigen processing

Major histocompatibility complex (MHC) class I molecules associate with peptides that are delivered from the cytosol to the lumen of the endoplasmic reticulum by the transporter associated with antigen processing (TAP). Liver microsomes of SHR and Lewis rats, which express different alleles of TAP (cim(b) and cim(a), respectively), accumulate different sets of peptides. Use of MHC congenic rats assigned this difference to the MHC, independent of the class I products expressed. Both the cim(a) and cim(b) TAP complexes translocate peptides with a hydrophobic carboxyl terminus, but translocation of peptides with a carboxyl-terminal His, Lys, or Arg residue is unique to cim(a). Thus, the specificity of the TAP peptide translocator restricts the peptides available for antigen presentation.