Daniel E. Geraghty

Nomenclature for factors of the HLA system, 2010

The WHO Nomenclature Committee for Factors of the HLA System met following the 14th International HLA and Immunogenetics Workshop in Melbourne, Australia in December 2005 and Buzios, Brazil during the 15th International HLA and Immunogenetics Workshop in September 2008. This report documents the additions and revisions to the nomenclature of HLA specificities following the principles established in previous reports (1–18).

Donor selection for natural killer cell receptor genes leads to superior survival after unrelated transplantation for acute myelogenous leukemia

Killer-cell immunoglobulin-like receptor (KIR) genes form a diverse, immunogenetic system. Group A and B KIR haplotypes have distinctive centromeric (Cen) and telomeric (Tel) gene-content motifs. Aiming to develop a donor selection strategy to improve transplant outcome, we compared the contribution of these motifs to the clinical benefit conferred by B haplotype donors. We KIR genotyped donors from 1409 unrelated transplants for acute myelogenous leukemia (AML; n = 1086) and acute lymphoblastic leukemia (ALL; n = 323). Donor KIR genotype influenced transplantation outcome for AML but not ALL. Compared with A haplotype motifs, centromeric and telomeric B motifs both contributed to relapse protection and improved survival, but Cen-B homozygosity had the strongest independent effect. With Cen-B/B homozygous donors the cumulative incidence of relapse was 15.4% compared with 36.5% for Cen-A/A donors (relative risk of relapse 0.34; 95% confidence interval 0.2-0.57; P < .001). Overall, significantly reduced relapse was achieved with donors having 2 or more B gene-content motifs (relative risk 0.64; 95% confidence interval 0.48-0.86; P = .003) for both HLA-matched and mismatched transplants. KIR genotyping of several best HLA-matched potential unrelated donors should substantially increase the frequency of transplants by using grafts with favorable KIR gene content. Adopting this practice could result in superior disease-free survival for patients with AML.

The ILT2(LIR1) and CD94/NKG2A NK cell receptors respectively recognize HLA-G1 and HLA-E molecules co-expressed on target cells.

Previous studies on NK recognition of HLA‐G1 employed as targets 721.221 transfectants (.221‐G1) that unknowingly co‐expressed the HLA‐E molecule, subsequently found to be a major ligand for the CD94/NKG2 receptors. In the present study we re‐evaluated the relative role played by CD94/NKG2 and ILT2(LIR1) molecules in recognition of HLA‐G1 by NK clones. We employed as targets .221‐G1 cells and a surface HLA‐E‐negative transfectant, .221‐G1(Eneg), generated by site‐directed mutagenesis of the HLA‐G1 leader sequence. The antagonistic effects of receptor‐ (i.e. CD94/NKG2A, ILT2) and ligand‐specific mAb (i.e. HLA‐G, HLA‐E) were assessed. In addition, binding of an ILT2‐Ig fusion protein to the .221‐AEH, expressing only HLA‐E, and the .221‐G1(Eneg) transfectants was analyzed. Our data demonstrate that NK recognition of cells expressing HLA‐G1 involves at least two non‐overlapping receptor‐ligand systems: the CD94/NKG2 interaction with HLA‐E, and the engagement of the ILT2(LIR1) receptor by HLA‐G1 molecules.

The killer cell immunoglobulin-like receptor (KIR) genomic region: gene-order, haplotypes and allelic polymorphism

Summary: Recent genetic studies have established that the killer cell immunoglobulin‐like receptor (KIR) genomic region displays extensive diversity through variation in gene content and allelic polymorphism within individual KIR genes. It is demonstrated by family segregation analysis, genomic sequencing, and gene order determination that genomic diversity by gene content alone gives rise to more than 20 different KIR haplotypes and at least 40–50 KIR genotypes. In the most reductionist format, KIR haplotypes can be accommodated within one of 10 different prototypes, each with multiple permutations. Our haplotype model considers the KIR haplotype as two separate halves: the centromeric half bordered upstream by KIR3DL3 and downstream by 2DL4, and the telomeric half bordered upstream by 2DL4 and downstream by 3DL2. There are rare KIR haplotypes that do not fit into this model. Recombination, gene duplication, and inversion can however, readily explain these haplotypes. Additional allelic polymorphism imposes extensive individual variability. Accordingly, this segment of the human genome displays a level of diversity similar to the one observed for the human major histocompatibility complex. Recent application of immunogenetic analysis of KIR genes in patient populations implicates these genes as important genetic disease susceptibility factors.

The membrane-bound and soluble forms of HLA-G bind identical sets of endogenous peptides but differ with respect to TAP association

The class Ib antigen HLA-G is expressed as a membrane-bound protein like classical class Ia molecules (M.HLA-G) but, unlike typical class I, is also expressed as a soluble protein (S.HLA-G) with a unique C terminus. Our results show that, similar to classical class I proteins, the membrane-bound form of HLA-G associated with TAP, as evidenced by the ability to immunoprecipitate HLA-G class I heavy chain with TAP antisera. In contrast, the soluble G protein did not appear to associate with TAP in the same manner, since similar immunoprecipitation experiments failed to detect soluble G complex. A detailed analysis of peptides bound to the soluble and membrane HLA-G proteins expressed in the B lymphoblastoid cell line 721.221 showed that, like class Ia complexes, both HLA-G proteins consist of heavy and light chains complexed with nonameric peptides in a 1:1:1 ratio. The two proteins bind essentially the same set of peptides, which are derived from a variety of intracellular proteins and define a peptide motif for HLA-G. The peptides contain Leu at the C terminus and Pro or small hydrophobic amino acids in position 3 followed by Pro or Gly in position 4. The complexity of the bound peptides is lower than that found for some class Ia complexes, but is more similar to class Ia than to the limited repertoire of some murine class Ib molecules.

HLA-E-BOUND PEPTIDES INFLUENCE RECOGNITION BY INHIBITORY AND TRIGGERING CD94/NKG2 RECEPTORS : PREFERENTIAL RESPONSE TO AN HLA-G-DERIVED NONAMER

The HLA‐E class Ib molecule constitutes a major ligand for the lectin‐like CD94/NKG2 natural killer (NK) cell receptors. Specific HLA class I leader sequence‐derived nonapeptides bind to endogenous HLA‐E molecules in the HLA‐defective cell line 721.221, inducing HLA‐E surface expression, and promote CD94/NKG2A‐mediated recognition. We compared the ability of NK clones which expressed either inhibitory or activating CD94/NKG2 receptors to recognize HLA‐E molecules on the surface of 721.221 cells loaded with a panel of synthetic nonamers derived from the leader sequences of most HLA class I molecules. Our results support the notion that the primary structure of the HLA‐E‐bound peptides influences CD94/NKG2‐mediated recognition, beyond their ability to stabilize surface HLA‐E. Further, CD94/NKG2A+ NK clones appeared more sensitive to the interaction with most HLA‐E‐peptide complexes than did effector cells expressing the activating CD94/NKG2C receptor. However, a significant exception to this pattern was HLA‐E loaded with the HLA‐G‐derived nonamer. This complex triggered cytotoxicity very efficiently over a wide range of peptide concentrations, suggesting that the HLA‐E/G‐nonamer complex interacts with the CD94/NKG2 triggering receptor with a significantly higher affinity. These results raise the possibility that CD94/NKG2‐mediated recognition of HLA‐E expressed on extravillous cytotrophoblasts plays an important role in maternal‐fetal cellular interactions.

Activation of NK cells by an endocytosed receptor for soluble HLA-G.

Signaling from endosomes is emerging as a mechanism by which selected receptors provide sustained signals distinct from those generated at the plasma membrane. The activity of natural killer (NK) cells, which are important effectors of innate immunity and regulators of adaptive immunity, is controlled primarily by receptors that are at the cell surface. Here we show that cytokine secretion by resting human NK cells is induced by soluble, but not solid-phase, antibodies to the killer cell immunoglobulin-like receptor (KIR) 2DL4, a receptor for human leukocyte antigen (HLA)-G. KIR2DL4 was constitutively internalized into Rab5-positive compartments via a dynamin-dependent process. Soluble HLA-G was endocytosed into KIR2DL4–containing compartments in NK cells and in 293T cells transfected with KIR2DL4. Chemokine secretion induced by KIR2DL4 transfection into 293T cells occurred only with recombinant forms of KIR2DL4 that trafficked to endosomes. The profile of genes up-regulated by KIR2DL4 engagement on resting NK cells revealed a proinflammatory/proangiogenic response. Soluble HLA-G induced secretion of a similar set of cytokines and chemokines. This unique stimulation of resting NK cells by soluble HLA-G, which is endocytosed by KIR2DL4, implies that NK cells may provide useful functions at sites of HLA-G expression, such as promotion of vascularization in maternal decidua during early pregnancy.

Protein Expression and Peptide Binding Suggest Unique and Interacting Functional Roles for HLA-E, F, and G in Maternal-Placental Immune Recognition

In this study we focused on the structure and expression of the HLA-E, F, and G class I complexes in placental tissue. Structural analysis included an examination of the peptides bound to soluble and membrane forms of the HLA-G complex isolated directly from placenta. An important distinction was observed from HLA-G bound peptides previously isolated from transfectant cells. Thus, the number of distinct moieties bound to placental-derived proteins was substantially lower than that bound to transfectant-derived HLA-G. Indeed, a single peptide species derived from a cytokine-related protein alone accounted for 15% of the molar ratio of HLA-G bound peptide. To further examine HLA-E and its potential to bind peptide, notably that derived from HLA-G, we combined new Abs to examine expression in placental tissues for all the known forms of the nonclassical class I molecules. Whereas membrane HLA-G was found in extravillous trophoblasts, soluble HLA-G was found in all placental trophoblasts, including villous cytotrophoblasts and syncitiotrophoblasts. Further, HLA-E was found in all cells that expressed either form of HLA-G, consistent with HLA-E being complexed with the HLA-G signal sequence-derived nonamer in these cells. Finally, using new reagents specific for HLA-F, a restricted pattern of expression was observed, primarily on extravillous trophoblasts that had invaded the maternal decidua. Comparative staining indicated that HLA-F was on the surface of these cells, defining them as the first to demonstrate surface expression of this Ag and the first cell type identified to express all three nonclassical HLA class I Ags simultaneously.

Reprogramming of CTLs into natural killer-like cells in celiac disease

Celiac disease is an intestinal inflammatory disorder induced by dietary gluten in genetically susceptible individuals. The mechanisms underlying the massive expansion of interferon γ–producing intraepithelial cytotoxic T lymphocytes (CTLs) and the destruction of the epithelial cells lining the small intestine of celiac patients have remained elusive. We report massive oligoclonal expansions of intraepithelial CTLs that exhibit a profound genetic reprogramming of natural killer (NK) functions. These CTLs aberrantly expressed cytolytic NK lineage receptors, such as NKG2C, NKp44, and NKp46, which associate with adaptor molecules bearing immunoreceptor tyrosine-based activation motifs and induce ZAP-70 phosphorylation, cytokine secretion, and proliferation independently of T cell receptor signaling. This NK transformation of CTLs may underlie both the self-perpetuating, gluten-independent tissue damage and the uncontrolled CTL expansion leading to malignant lymphomas in severe forms of celiac disease. Because similar changes were detected in a subset of CTLs from cytomegalovirus-seropositive patients, we suggest that a stepwise transformation of CTLs into NK-like cells may underlie immunopathology in various chronic infectious and inflammatory diseases.

Nomenclature for factors of the HLA system, 2002

This chapter provides the nomenclature for factors of the HLA system, 2002. A number of previously described class I and II gene fragments within the HLA region are named in this system. Official designations are given to these gene fragments. The names LMP2 and LMP7 used previously for the two proteasome genes in the HLA class II region have been renamed by the Human Genome Nomenclature committee (HGNC) as PSMB9 and PSMB8, respectively. This system introduces the additional digit for synonymous variation and all allele names that are currently five digits or above are renamed accordingly. The use of an optional “N’” or “L” suffix to an allele name to indicate either “Null” or “Low” expression was introduced in previous Nomenclature Reports. Three new suffixes are introduced in this system. An “S” to denote an allele specifying a protein that is expressed as a soluble “Secreted” molecule but is not present on the cell surface; a “C” to indicate an allele product that is present in the “Cytoplasm” but not at the cell surface; an “A” to indicate “Aberrant” expression where there is some doubt as to whether a protein is expressed or not. There is evidence of differential splicing of HLA-G that leads to the production of both membrane-bound and soluble forms of the same allele. The IMGT/HLA Sequence Database contains sequences for all HLA alleles officially recognized by the WHO Nomenclature Committee for Factors of the HLA System and, provides users with online tools and facilities for their retrieval and analysis.