Primate Mhc-E and -G alleles

HLA-G: Function, polymorphisms and pathology

HLA-G immune modulatory genes and molecules are presently being studied by a widespread number of research groups. In the present study, we do not aim to be exhaustive since the number of manuscripts published every year is overwhelming. Instead, our aim is pointing out facts about HLA-G function, polymorphism and pathology that have been confirmed by several different researchers, together with exposing aspects that may have been overlooked or not sufficiently remarked in this productive field of study. On the other hand, we question whether performing mainly studies on HLA-G and disease associations is going to give a clear answer in the future, since 40 years of study of classical HLA molecules association with disease has still given no definite answer on this issue.

Mammalian non-classical major histocompatibility complex I and its receptors: Important contexts of gene, evolution, and immunity

The evolutionary conserved, less-polymorphic, nonclassical major histocompatibility complex (MHC) class I molecules: Qa-1 and its human homologue human leukocyte antigen-E (HLA-E) along with HLA-F, G and H cross-talk with the T-cell receptors and also interact with natural killer T-cells and other lymphocytes. Moreover, these nonclassical MHC molecules are known to interact with CD94/NKG2 heterodimeric receptors to induce immune responses and immune regulations. This dual role of Qa-1/HLA-E in terms of innate and adaptive immunity makes them more interesting. This review highlights the new updates of the mammalian nonclassical MHC-I molecules in terms of their gene organization, evolutionary perspective and their role in immunity.

Insights into HLA-G Genetics Provided by Worldwide Haplotype Diversity

Human leukocyte antigen G (HLA-G) belongs to the family of non-classical HLA class I genes, located within the major histocompatibility complex (MHC). HLA-G has been the target of most recent research regarding the function of class I non-classical genes. The main features that distinguish HLA-G from classical class I genes are (a) limited protein variability, (b) alternative splicing generating several membrane bound and soluble isoforms, (c) short cytoplasmic tail, (d) modulation of immune response (immune tolerance), and (e) restricted expression to certain tissues. In the present work, we describe the HLA-G gene structure and address the HLA-G variability and haplotype diversity among several populations around the world, considering each of its major segments [promoter, coding, and 3′ untranslated region (UTR)]. For this purpose, we developed a pipeline to reevaluate the 1000Genomes data and recover miscalled or missing genotypes and haplotypes. It became clear that the overall structure of the HLA-G molecule has been maintained during the evolutionary process and that most of the variation sites found in the HLA-G coding region are either coding synonymous or intronic mutations. In addition, only a few frequent and divergent extended haplotypes are found when the promoter, coding, and 3′UTRs are evaluated together. The divergence is particularly evident for the regulatory regions. The population comparisons confirmed that most of the HLA-G variability has originated before human dispersion from Africa and that the allele and haplotype frequencies have probably been shaped by strong selective pressures.

Nomenclature report on the major histocompatibility complex genes and alleles of Great Ape, Old and New World monkey species

The major histocompatibility complex (MHC) plays a central role in the adaptive immune response. The MHC region is characterised by a high gene density, and most of these genes display considerable polymorphism. Next to humans, non-human primates (NHP) are well studied for their MHC. The present nomenclature report provides the scientific community with the latest nomenclature guidelines/rules and current implemented nomenclature revisions for Great Ape, Old and New World monkey species. All the currently published MHC data for the different Great Ape, Old and New World monkey species are archived at the Immuno Polymorphism Database (IPD)-MHC NHP database. The curators of the IPD-MHC NHP database are, in addition, responsible for providing official designations for newly detected polymorphisms.

Implications of the polymorphism of HLA-G on its function, regulation, evolution and disease association

The HLA-G gene displays several peculiarities that are distinct from those of classical HLA class I genes. The unique structure of the HLA-G molecule permits a restricted peptide presentation and allows the modulation of the cells of the immune system. Although polymorphic sites may potentially influence all biological functions of HLA-G, those present at the promoter and 3′ untranslated regions have been particularly studied in experimental and pathological conditions. The relatively low polymorphism observed in the MHC-G coding region both in humans and apes may represent a strong selective pressure for invariance, whereas, in regulatory regions several lines of evidence support the role of balancing selection. Since HLA-G has immunomodulatory properties, the understanding of gene regulation and the role of polymorphic sites on gene function may permit an individualized approach for the future use of HLA-G for therapeutic purposes.

14th International HLA and Immunogenetics Workshop: Report on non-classical class I genes

Non-classical class I genes are encoding for cell surface proteins that have largely yet unknown functions. Although some of these proteins (human leukocyte antigens E, F and G) have been shown to present peptides, their polymorphism is very restricted at the peptide-binding region. In the present Workshop, several papers were presented addressing detection, evolutive and functional issues of these proteins. The general inhibitory immunological function of these proteins is put forward.

MHC-F polymorphism and evolution

The major histocompatibility complex (MHC)-F class Ib locus shows a limited polymorphism, and the function of its mainly intracellular protein is not clear. We have identified human leukocyte antigen (HLA)-F orthologous DNA sequences in Pongidae in order to study the MHC-F gene evolution and its products' function. HLA-F orthologous complementary DNA transcripts are found in chimpanzee and in the new primate species studied (bonobo, gorilla and orangutan). Analyses of the predicted amino acid sequences and their comparison with other primate MHC-F proteins show that MHC-F may be a protein with a typical class I structure and that the key residues of the peptide-binding region are highly conserved in MHC-F in all studied primates species. Thus, MHC-F conservation along the primate evolution suggests an important role in cellular physiology. It is possible that the MHC-F protein could be involved, together with MHC-G and MHC-E, in the natural killer cell activity regulation, although rhesus macaque cannot express complete surface MHC-G orthologue molecules.

HLA-G, -E and -F: allelism, function and evolution

The major histocompatibility complex class I genes comprise a bunch of classical genes (A, B, C), non-classical genes (E, F and G), pseudogenes and truncated genes. MHC-E, -F and -G are now considered immune "tolerization" molecules, which not only interact with NK cells but with T lymphocyte subsets and other cells and have a role in fetus acceptation. A strong positive directional selection is acting for maintaining the observed low polymorphism on E, F and G loci in human and apes. Invariance must be important for this non-classical class I proteins function.

MHC-F DNA sequences in bonobo, gorilla and orangutan

The major histocompatibility complex (MHC)-F class Ib locus shows a limited polymorphism, and the function of its mainly intracellular protein is not clear. We have identified human leucocyte antigen (HLA)-F orthologous DNA sequences in Pongidae in order to study the MHC-F gene evolution and its products' function. HLA-F orthologous cDNA transcripts are found in chimpanzee and in the new primate species studied (bonobo, gorilla and orangutan). Analyses of the predicted amino acid sequences and their comparison with other primate MHC-F proteins show that MHC-F may be a protein with a typical class I structure and that the key residues of the peptide-binding region (PBR) are highly conserved in MHC-F in all studied primates species. Thus, MHC-F conservation along the primate evolution suggests an important role in cellular physiology. It is possible that the MHC-F protein could be involved, together with MHC-G and MHC-E, in the natural killer (NK) cell activity regulation, although rhesus macaque does not express MHC-G and MHC-E orthologues. The evolutionary pathway of the six-base-pair deletion at exon 2 existing in some primates is put forward.

Identification of the MHC class I B locus in cynomolgus monkeys

By determining the nucleotide sequences of more than 700 cDNA clones isolated from 16 cynomolgus monkeys, we identified 26 Mafa-B alleles. In addition, nine sequences with similarity to Mamu-I alleles were identified. Since multiple Mafa-B alleles were found in each individual, it was strongly suggested that the cynomolgus MHC class I B locus might be duplicated and that the Mafa-I locus was derived from the B locus by gene duplication, as in the case of the Mamu-I locus of rhesus monkeys.

The 14 bp deletion-insertion polymorphism in the 3' UT region of the HLA-G gene influences HLA-G mRNA stability

Human leukocyte antigen (HLA)-G molecules are generated by an alternative splicing of the primary transcript of the gene and display specialized function in regulating the immune response. Although HLA-G gene polymorphism is low, it may influence levels of protein expression and, in some cases, has been associated with pregnancy diseases. The HLA-G gene exhibits 14 alleles generating six proteins with minor variations and a null allele. HLA-G allelic variants may be also characterized by a 14 bp deletion-insertion polymorphism located in the 3' UT region of the HLA-G gene. The presence of the 14 bp insertion is known to generate an additional splice whereby 92 bases are removed from the start of exon 8. To analyze the effect of this deletion on the stability of HLA-G mRNAs, we performed actinomycin D treatments on both JEG-3 choriocarcinoma cell line and M8 melanoma cell line transfected with HLA-G*010102 allele. We observed that HLA-G mRNAs having the 92-base deletion are more stable than the complete mRNA forms, suggesting that this region may be involved in the mechanisms controlling post-transcriptional regulation of HLA-G molecule associated with allelic variants.

Pig-tailed macaques (Macaca nemestrina) possess six MHC-E families that are conserved among macaque species: implication for their binding to natural killer receptor variants

MHC loci encode highly polymorphic molecules involved in the presentation of self and non-self peptides to cells of the adaptive and innate immune systems. Although variable, MHC-E genes are well conserved among primates and provide signals to natural killer cells. In this study, we sequenced and analyzed MHC-E alleles of pig-tailed macaque (Macaca nemestrina), a nonhuman primate used for HIV pathogenesis and vaccine studies. Among a group of seven macaques, the characterization of eight Mane-E alleles revealed an increased number of polymorphic sites compared with human HLA-E alleles. Phylogenetic analyses of MHC-E alleles from pig-tailed macaque, rhesus monkey (Macaca mulatta) and cynomolgus macaque (Macaca fascicularis) demonstrated that the three macaque species shared six families of macaque MHC-E alleles and indicated that these families existed in the common ancestor 5.5 million years ago. Polymorphic Mane-E sites were not concentrated within the peptide-binding pockets, but were distributed throughout the entire ORF. The peptide-binding domain of Mane-E is similar to its human analogue, and peptide substrates theoretically capable of binding to Mane-E molecules were found in the leader sequence of classical Mane-A and -B molecules. Additionally, the polymorphic amino acids located in the alpha(1) and alpha(2) domains of Mane-E molecules have side chains expected to be oriented toward solvent and away from the peptide-binding groove, suggesting that some of them (positions 19, 73, 79 and 145) might be available for interaction with polymorphic receptors of natural killer cells.

Analysis of HLA-E peptide-binding specificity and contact residues in bound peptide required for recognition by CD94/NKG2

The MHC class Ib molecule HLA-E is the primary ligand for CD94/NKG2A-inhibitory receptors expressed on NK cells, and there is also evidence for TCR-mediated recognition of this molecule. HLA-E preferentially assembles with a homologous set of peptides derived from the leader sequence of class Ia molecules, but its capacity to bind and present other peptides remains to be fully explored. The peptide-binding motif of HLA-E was investigated by folding HLA-E in vitro in the presence of peptide libraries derived from a nonameric leader peptide sequence randomized at individual anchor positions. A high degree of selectivity was observed at four of five total anchor positions, with preference for amino acids present in HLA-E-binding peptides from class Ia leader sequences. Selectivity was also observed at the nonanchor P5 position, with preference for positively charged amino acids, suggesting that electrostatic interactions involving the P5 side chain may facilitate assembly of HLA-E peptide complexes. The observed HLA-E peptide-binding motif was strikingly similar to that previously identified for the murine class Ib molecule, Qa-1. Experiments with HLA-E tetramers bearing peptides substituted at nonanchor positions demonstrated that P5 and P8 are primary contact residues for interaction with CD94/NKG2 receptors. A conservative replacement of Arg for Lys at P5 completely abrogated binding to CD94/NKG2. Despite conservation of peptide-binding specificity in HLA-E and Qa-1, cross-species tetramer-staining experiments demonstrated that the interaction surfaces on CD94/NKG2 and the class Ib ligands have diverged between primates and rodents.

Characterization of pig-tailed macaque classical MHC class I genes: implications for MHC evolution and antigen presentation in macaques

MHC-dependent CD8(+) T cell responses have been associated with control of viral replication and slower disease progression during lentiviral infections. Pig-tailed macaques (Macaca nemestrina) and rhesus monkeys (Macaca mulatta), two nonhuman primate species commonly used to model HIV infection, can exhibit distinct clinical courses after infection with different primate lentiviruses. As an initial step in assessing the role of MHC class I restricted immune responses to these infections, we have cloned and characterized classical MHC class I genes of pig-tailed macaques and have identified 19 MHC class I alleles (Mane) orthologous to rhesus macaque MHC-A, -B, and -I genes. Both Mane-A and Mane-B loci were found to be duplicated, and no MHC-C locus was detected. Pig-tailed and rhesus macaque MHC-A alleles form two groups, as defined by 14 polymorphisms affecting mainly their B peptide-binding pockets. Furthermore, an analysis of multiple pig-tailed monkeys revealed the existence of three MHC-A haplotypes. The distribution of these haplotypes in various Old World monkeys provides new insights about MHC-A evolution in nonhuman primates. An examination of B and F peptide-binding pockets in rhesus and pig-tailed macaques suggests that their MHC-B molecules present few common peptides to their respective CTLs.

HLA-G Molecules: from Maternal–Fetal Tolerance to Tissue Acceptance

Over the past few years, HLA-G, the non-classical HLA class I molecule, has been the center of investigations that have led to the description of its specific structural and functional properties. Although located in the HLA class I region of chromosome six, the HLA-G gene may be distinguished from other HLA class I genes by its low polymorphism and alternative splicing that generates seven HLA-G proteins, whose tissue-distribution is restricted to normal fetal and adult tissues that display a tolerogeneic function toward both innate and acquired immune cells. We review these points, with special emphasis on the role of HLA-G in human pathologies, such as cancer, viral infection, and inflammatory diseases, as well as in organ transplantation.

Viewpoint on the functionality of the human leukocyte antigen-G null allele at the fetal-maternal interface

The description of healthy individuals homozygous for the human leukocyte antigen-G (HLA-G) null allele raised doubts about the role of HLA-G in fetal-maternal tolerance. In light of recent results, we discuss this point by considering the potential activity of this null allele that might, indeed, produce functional truncated HLA-G molecules. In this context, we have recently described that, like the full-length HLA-G1, the HLA-G2, -G3, and -G4 truncated isoforms may be expressed at the cell surface and may modulate both innate and acquired immune responses.

KIR: diverse, rapidly evolving receptors of innate and adaptive immunity

KIR genes have evolved in primates to generate a diverse family of receptors with unique structures that enable them to recognize MHC-class I molecules with locus and allele-specificity. Their combinatorial expression creates a repertoire of NK cells that surveys the expression of almost every MHC molecule independently, thus antagonizing the spread of pathogens and tumors that subvert innate and adaptive defense by selectively downregulating certain MHC class I molecules. The genes encoding KIR that recognize classical MHC molecules have diversified rapidly in human and primates; this contrasts with conservation of immunoglobulin- and lectin-like receptors for nonclassical MHC molecules. As a result of the variable KIR-gene content in the genome and the polymorphism of the HLA system, dissimilar numbers and qualities of KIR:HLA pairs function in different humans. This diversity likely contributes variability to the function of NK cells and T-lymphocytes by modulating innate and adaptive immune responses to specific challenges.

Structure and function of major histocompatibility complex (MHC) class I specific receptors expressed on human natural killer (NK) cells

Natural killer (NK) cells express receptors that are specific for MHC class I molecules. These receptors play a crucial role in regulating the lytic and cytokine expression capabilities of NK cells. In humans, three distinct families of genes have been defined that encode for receptors of HLA class I molecules. The first family identified consists of type I transmembrane molecules belonging to the immunoglobulin (Ig) superfamily and are called killer cell Ig-like receptors (KIR). A second group of receptors belonging to the Ig superfamily, named ILT (for immunoglobulin like transcripts), has more recently been described. ILTs are expressed mainly on B, T and myeloid cells, but some members of this group are also expressed on NK cells. They are also referred to as LIRs (for leukocyte Ig-like receptor) and MIRs (for macrophage Ig-like receptor). The ligands for the KIR and some of the ILT receptors include classical (class Ia) HLA class I molecules, as well as the nonclassical (class Ib) HLA-G molecule. The third family of HLA class I receptors are C-type lectin family members and are composed of heterodimers of CD94 covalently associated with a member of the NKG2 family of molecules. The ligand for most members is the nonclassical class I molecule HLA-E. NKG2D, a member of the NKG2 family, is expressed as a homodimer, along with the adaptor molecule DAP10. The ligands of NKG2D include the human class I like molecules MICA and MICB, and the recently described ULBPs. Each of these three families of receptors has individual members that can recognize identical or similar ligands yet signal for activation or inhibition of cellular functions. This dichotomy correlates with particular structural features present in the transmembrane and intracytoplasmic portions of these molecules. In this review we will discuss the molecular structure, specificity, cellular expression patterns, and function of these HLA class I receptors, as well as the chromosomal location and genetic organization.

A novel, nonclassical MHC class I molecule specific to the common chimpanzee

All expressed human MHC class I genes (HLA-A, -B, -C, -E, -F, and -G) have functional orthologues in the MHC of the common chimpanzee (Pan troglodytes). In contrast, a nonclassical MHC class I gene discovered in the chimpanzee is not present in humans or the other African ape species. In exons and more so in introns, this Patr-AL gene is similar to the expressed A locus in the orangutan, Popy-A, suggesting they are orthologous. Patr-AL/Popy-A last shared a common ancestor with the classical MHC-A locus >20 million years ago. Population analysis revealed little Patr-AL polymorphism: just three allotypes differing only at residues 52 and 91. Patr-AL is expressed in PBMC and B cell lines, but at low level compared with classical MHC class I. The Patr-AL polypeptide is unusually basic, but its glycosylation, association with beta(2)-microglobulin, and antigenicity at the cell surface are like other MHC class I. No Patr-AL-mediated inhibition of polyclonal chimpanzee NK cells was detected. The Patr-AL gene is present in 50% of chimpanzee MHC haplotypes, correlating with presence of a 9.8-kb band in Southern blots. The flanking regions of Patr-AL contain repetitive/retroviral elements not flanking other class I genes. In sequenced HLA class I haplotypes, a similar element is present in the A*2901 haplotype but not the A*0201 or A*0301 haplotypes. This element, 6 kb downstream of A*2901, appears to be the relic of a human gene related to Patr-AL. Patr-AL has characteristics of a class I molecule of innate immunity with potential to provide common chimpanzees with responses unavailable to humans.

HLA-G: a shield against inflammatory aggression

Recent developments in the field of HLA-G research have revealed that, besides its involvement during pregnancy, HLA-G is expressed in peripheral tissues during pathological processes, such as viral infections, malignancies and organ transplantation. Here, we discuss recent findings regarding the influence of HLA-G on the T helper (Th) cytokine balance (favoring Th2-type responses), and the expression of HLA-G during chronic, cutaneous inflammatory diseases, such as psoriasis and atopic dermatitis. We propose a novel role for HLA-G as a tissue-protective molecule in inflammatory responses.

Is antigen presentation the primary function of HLA-G?

Human histocompatibility leukocyte antigen (HLA)-G is an antigen-presenting molecule. This review discusses the possibility that this might not be its primary function. HLA-G indeed modulates innate immunity by interacting with immunoglobulin-like receptors and by regulating HLA-E expression and its subsequent interaction with CD94/NKG2 receptors. HLA-G also down-modulates both CD8(+) and CD4(+) T-cell responsiveness.

Homozygous HLA-G*0105N healthy individuals indicate that membrane-anchored HLA-G1 molecule is not necessary for survival

HLA-G is expected to play an important role during fetal development. Recently, a healthy individual homozygous for the HLA-G*0105N allele has been described, suggesting that HLA-G expression was not essential for fetal survival. We now report studies of one family with five healthy siblings homozygous for HLA-G*0105N, who had been normally delivered; three of these siblings were females who also had normal deliveries. In addition, HLA-G*0105N cDNA has been fully sequenced, and normal G1 membrane anchored protein cannot be translated since after the codon 130 cytosine deletion (exon 3) a reading frameshift is observed leading to the existence of premature stop codon at position 189 (beginning of exon 4). Other protein isoforms (G2, G3 and G6), all containing the leader peptide and the alpha1 domain, are possible and their messenger mRNAs were found; any of these may undertake the necessary HLA-G functions. Our data show that the membrane anchored HLA-G molecule is not necessary in either mother or fetus for a normal pregnancy and survival. Also, individuals homozygous for HLA-G*0105N are healthy and with no indications of immunodeficiency or autoimmunity.

Rapid evolution of NK cell receptor systems demonstrated by comparison of chimpanzees and humans

That NK cell receptors engage fast-evolving MHC class I ligands suggests that they, too, evolve rapidly. To test this hypothesis, the structure and class I specificity of chimpanzee KIR and CD94:NKG2 receptors were determined and compared to their human counterparts. The KIR families are divergent, with only three KIR conserved between chimpanzees and humans. By contrast, CD94:NKG2 receptors are conserved. Whereas receptors for polymorphic class I are divergent, those for nonpolymorphic class I are conserved. Although chimpanzee and human NK cells exhibit identical receptor specificities for MHC-C, they are mediated by nonorthologous KIR. These results demonstrate the rapid evolution of NK cell receptor systems and imply that "catching up" with class I is not the only force driving this evolution.

Evolution of MHC-G in primates: a different kind of molecule for each group of species

When MHC-G molecules in primates (New World and Old World monkeys, Anthropoids and humans) were compared phylogenetically, very different evolutionary patterns within each species were found; their molecules did not have a straight forward and linear development throughout the postulated evolutionary pathway of primates. The earlier New World monkeys (South America) had relatively more alleles and the polymorphism was placed in the T-cell receptor (TcR), NK receptors and antigen binding sites; MHC-G probably works as a classical class I presenting molecule in these monkeys. MHC-G intron 2 from New World monkeys does not show the typical 23 bp deletion found in all other more recent primate species. Thus, it is possible that MHC-G molecules in New World monkeys belong to a different lineage than the MHC from higher primates. Another early lineage, Eurasian Old World monkeys, shows stop codons at exon 3: MHC-G proteins lacking the alpha2 domain may functionally suffice or otherwise reading-through stop-codon translational mechanisms may exist, as shown for other genes. Orangutans show lower (but significant) polymorphism than New World monkeys at NK, TcR and antigen binding regions; gorilla and chimpanzee show very low polymorphism. Humans only show three different HLA-G proteins with changes not affecting NK, TcR or antigen binding sites. It is observed that the more exposed the mother to allogeneic fetuses (polygamy), the less polymorphic HLA-G is observed within a given species. The data are concordant with the postulated immune inhibitory function for MHC-G in Old World monkeys, anthropoids and humans both at placental and inflammatory level.

The functionality of HLA-G is emerging

In view of the recently published data, the HLA-G class Ib gene appears to be a functional locus. This is based on the following observations: 1) HLA-G is capable of presenting nonamer peptides and of exerting antigen-presenting functions; 2) HLA-G is a ligand for at least three natural killer (NK) and other cell inhibitory receptors of the immunoglobulin superfamily, namely leukocyte immunoglobulin-like receptor-1/immunoglobulin-like transcript (ILT)-2, ILT-4 and p49; 3) in addition to the extravillous cytotrophoblast cells, HLA-G proteins have been detected in endothelial cells of placental chorionic villi, as well as in amniotic fluid and in some medullary thymic epithelial cells; 4) major histocompatibility complex (MHC) class Ib genes that share the unique characteristics of HLA-G, including a high expression in placenta, have been reported in other mammalian species. In addition to the classical MHC class I roles (antigen presentation and ligation to NK receptors inducing inhibitory and/or activatory signals), HLA-G is likely to exert other, novel functions: first, HLA-G was shown to be involved in the control of HLA-E expression by furnishing the appropriate class I leader sequence nonamer peptide; second, we hypothesize that HLA-G could be a regulator of placental angiogenesis; third, soluble HLA-G isoforms may act as specific immunosuppressors during pregnancy. Such functional properties, although incompletely understood, are likely to be important in the outcome of human pregnancies but also in normal adult life.

Cell surface expression of HLA-E: interaction with human beta2-microglobulin and allelic differences

The formation of a trimeric complex composed of MHC class I heavy chain, beta2-microglobulin (beta2m) and peptide ligand is a prerequisite for its efficient transport to the cell surface. We have previously demonstrated impaired intracellular transport of the human class Ib molecule HLA-E in mouse myeloma X63 cells cotransfected with the genes for HLA-E and human beta2m (hbeta2m), which is most likely attributable to inefficient intracellular peptide loading of the HLA-E molecule. Here we demonstrate that cell surface expression of HLA-E in mouse cells strictly depends on the coexpression of hbeta2m and that soluble empty complexes of HLA-E and hbeta2m display a low degree of thermostability. Both observations imply that low affinity interaction of HLA-E with beta2m accounts to a considerable extent for the observed low degree of peptide uptake in the endoplasmic reticulum. Moreover, we show that the only allelic variation present in the caucasoid population located at amino acid position 107 (Gly or Arg) greatly affects intracellular transport and cell surface expression upon transfection of the respective alleles into mouse cells. No obvious difference was found with regard to the sequence of the peptide ligand.

Mhc-E polymorphism in Pongidae primates: the same allele is found in two different species

Mhc-E intron 1, exon 2, intron 2, and exon 3 from pygmy chimpanzee (Pan paniscus), chimpanzee (Pan troglodytes), gorilla (Gorilla gorilla) and orangutan (Pongo pygmaeus) have been sequenced; six new Mhc-E alleles have been obtained but sequence changes are only placed either in introns or in synonymous exonic bases. One pygmy chimpanzee Mhc-E DNA sequence is identical to another sequence from chimpanzee; the fact that no variation is found also at the intronic level suggests that these two species of chimpanzee may have recently separated and/or that both of them might only represent subspecies. Mhc-E phylogenetic trees separate two evolutionary groups: Pongidae, including humans, and Cercopithecinae; this is also found by studying another non-classical class I gene, Mhc-G. The Mhc-E alleles' invariance at the protein level supports that strong selective forces are operating at the Mhc-E locus, as has also been found in both Cercopithecinae and humans. These allelic and evolutionary data suggest an altogether different functionality for HLA-E (and also HLA-G) compared with classical class I proteins: i.e., sending negative (tolerogenic) signals to NK and T cells.