Christina Bade-Doeding

The molecular diversity of Sema7A, the semaphorin that carries the JMH blood group antigens

BACKGROUND: Semaphorin 7A (Sema7A), the protein that carries the JMH blood group antigen, is involved in immune responses and plays an important role in axon growth and guidance. Because previous serologic studies on red blood cells (RBCs) suggested a considerable diversity of Sema7A, the present study was designed to elucidate the complex picture of the molecular diversity of this protein.

Position 156 influences the peptide repertoire and tapasin dependency of human leukocyte antigen B*44 allotypes

Background Polymorphic differences between donor and recipient human leukocyte antigen class I molecules can result in graft-versus-host disease due to distinct peptide presentation. As part of the peptide-loading complex, tapasin plays an important role in selecting peptides from the pool of potential ligands. Class I polymorphisms can significantly alter the tapasin-mediated interaction with the peptide-loading complex and although most class I allotypes are highly dependent upon tapasin, some are able to load peptides independently of tapasin. Several human leukocyte antigen B*44 allotypes differ exclusively at position 156 (B*44:02156Asp, 44:03156Leu, 44:28156Arg, 44:35156Glu). From these alleles, only the high tapasin-dependency of human leukocyte antigen B*44:02 has been reported. Design and Methods We investigated the influence of position 156 polymorphisms on both the requirement of tapasin for efficient surface expression of each allotype and their peptide features. Genes encoding human leukocyte antigen B*44 variants bearing all possible substitutions at position 156 were lentivirally transduced into human leukocyte antigen class I-negative LCL 721.221 cells and the tapasin-deficient cell line LCL 721.220. Results Exclusively human leukocyte antigen B*44:28156Arg was expressed on the surface of tapasin-deficient cells, suggesting that the remaining B*44/156 variants are highly tapasin-dependent. Our computational analysis suggests that the tapasin-independence of human leukocyte antigen B*44:28156Arg is a result of stabilization of the peptide binding region and generation of a more peptide receptive state. Sequencing of peptides eluted from human leukocyte antigen B*44 molecules by liquid chromatography-electrospray ionization-mass spectrometry (LTQ-Orbitrap) demonstrated that both B*44:02 and B*44:28 share the same overall peptide motif and a certain percentage of their individual peptide repertoires in the presence and/or absence of tapasin. Conclusions Here we report for the first time the influence of position 156 on the human leukocyte antigen/tapasin association. Additionally, the results of peptide sequencing suggest that tapasin chaperoning is needed to acquire peptides of unusual length.

Amino acid 95 causes strong alteration of peptide position PΩ in HLA-B*41 variants

There have been several attempts over the years to identify positions in the peptide-binding region (PBR) of human leukocyte antigens (HLA) that influence the specificity of bound amino acids (AAs) at each position in the peptide. Originally, six pockets (A–F) were defined by calculating the surface area of the PBR on the crystal structure of HLA-A2 molecules. More recent crystallographic analyses of a variety of HLA alleles have led to broader pocket definitions. In this study, we examined the peptide-binding specificity of HLA-B*41 alleles and compared our results with the available pocket definitions. By generating recombinant HLA-B molecules and studying the eluted peptides by mass spectrometry and pool sequencing, we detected two different PΩ peptide motifs within the B*41 group: Leu vs Val/Pro. Specificity was dependent on the presence of Leu (B*4102, B*4103, and B*4104) vs Trp (B*4101, B*4105, and B*4106) at AA position 95 in the HLA molecule, whose impact on PΩ has been a subject of controversy in current pocket definitions. In contrast, the Arg97Ser mutation did not affect pocket F binding specificity in B*41 subtypes although residue 97 was previously identified as a modulator of peptide binding for several HLA class I alleles. According to most pocket definitions, this study shows that the Asn80Lys substitution in B*4105 impels the peptide’s PΩ anchor toward more promiscuity. Our sequencing results of peptides eluted from HLA-B*41 variants demonstrate the limitations of current pocket definitions and underline the need for an extended peptide motif database for improved understanding of peptide–major histocompatibility complex interactions.

A single amino-acid polymorphism in pocket A of HLA-A*6602 alters the auxiliary anchors compared with HLA-A*6601 ligands

In this study we have sequenced peptides eluted from a truncated recombinant HLA-A*6602 molecule, and compared their features with data reported for peptides presented in the A*6601 molecule. A striking change in the amino-acid binding preferences was observed at peptide position P1, which interacts with pocketxa0A of the HLA peptide-binding region. For A*6601, aspartic acid and glutamic acid, both of which possess polar acidic side-chains, have been described as auxiliary anchors. This is in marked contrast to A*6602, where we observed serine, which has a neutral polar side-chain, as auxiliary anchor at P1. Accordingly, this shift in the physico-chemical properties of the auxiliary anchor may be best explained by the HLA amino-acid polymorphism at position 163, where arginine (hydrophilic, alkaline) in A*6601 has been replaced by glutamic acid in A*6602. This amino-acid exchange results in a shift towards higher acidity in pocket A, apparently resulting in the loss of preference for acidic auxiliary anchors, and leading to the preference for the neutral amino acid serine. The change of the auxiliary anchor residue at P1 is likely to alter the spectrum of peptides presented by A*6602 compared with A*6601, which may result in allogenicity in the case of a mismatch in allogeneic stem cell transplantation.

Mismatches outside exons 2 and 3 do not alter the peptide motif of the allele group B*44:02P

Sequence variations outside exons 2 and 3 do not appear to affect the function of human leukocyte antigen (HLA) class I alleles. HLA-B*44:02:01:01 and -B*44:27 are considered functionally identical because they differ by a single amino acid substitution of Val > Ala at position 199, which is located in the α3 domain. To validate that HLA-B*44:02:01:01 and -B*44:27 represent functionally identical alleles that might reflect a permissive mismatch in hematopoetic stem cell transplantation (HSCT), we determined their peptide-binding features. B-lymphoblastic cells were lentivirally transduced with B*44:02 and B*44:27 constructs and soluble recombinant molecules were purified by affinity chromatography. Peptides were isolated and sequencing of single peptides was performed using liquid chromatography-electrospray ionization-tandem mass spectrometry (LTQ-Orbitrap) technology. We demonstrate that the peptide motif of B*44:02(199Val) and B*44:27(199Ala) is identical. Both variants feature E at P2 and Y, F, or W at PΩ in their ligands. Most of the identified peptides are 9 to 11 amino acids in length and approximately 20% of these ligands are shared between the alleles. Our results lead to the conclusion that B*44:02:01:01 and B*44:27 might have the same immune function, validating a theory that is now being used in deciding which donors to select in HSCT when there is no identical donor available.

A weak blood group A phenotype caused by a translation-initiator mutation in the ABO gene

BACKGROUND:u2002 Weak blood groupu2003A and B phenotypes are correlated with ABO glycosyltransferases exhibiting single‐amino‐acid changes and/or C‐terminal modifications.

Weak blood group B phenotypes may be caused by variations in the CCAAT-binding factor/NF-Y enhancer region of the ABO gene.

BACKGROUND: Binding of CCAAT‐binding factor NF‐Y (CBF/NF‐Y) to a 43‐bp repeat unit in the minisatellite region in the 5′ region of the ABO gene (CBF/NF‐Y enhancer region) plays an important role in regulating the transcription of ABO genes. The common ABO alleles were found to have CBF/NF‐Y enhancer regions with specific numbers of 43‐bp minisatellite repeats.

Pocketcheck: updating the HLA class I peptide specificity roadmap.

The structural determination of peptide:HLA (human leucocyte antigen) class I complexes by X-ray crystallography has provided valuable information for understanding how peptides bind to individual HLA class I molecules and how this may influence the immune response. We compared 101 crystal structures of 9-mer peptide:HLA class I complexes available in the protein data bank (PDB) by performing a contact analysis using the Contact Map Analysis webserver http://ligin.weizmann.ac.il/cma. An InterSystems Caché post-relational database containing residue position, amino acid (AA) and buried surface that contact a particular peptide position was then created allowing data comparison for all the structures (Pocketcheck). The analysis illustrates that the HLA class I residues 24, 45, 63 and 67 show high contact frequencies to both the p1 and/or p2 position of bound peptides, indicating that they might influence the nature of a peptide anchor. To determine the influence of these residues we utilized soluble HLA technology and mass spectrometry to analyze peptides derived from HLA-B*44:06 since it differs from the previously described allele B*44:02 by seven AA exchanges located in the alpha 1 domain (residues 24, 32, 41, 45, 63, 67 and 80). HLA-B*44:06 features an anchor motif of P or A at p2 and Y or W at the C-terminal. Additionally B*44:06-derived peptides feature an auxiliary anchor motif at p1, comprising D or E. Our results illustrate that structural analysis can provide valuable information to understand allogenicity and provides a further step towards intelligent HLA mismatching.

Position 45 influences the peptide binding motif of HLA-B*44:08.

Position 45 represents a highly polymorphic residue within HLA class I alleles, which contacts the p2 position of bound peptides in 85% of the peptide–HLA structures analyzed, while the neighboring residues 41 and 46 are not involved in peptide binding. To investigate the influence of residue 45 at the functional level, we sequenced peptides eluted from recombinant HLA-B*44:0841Ala/45Met/46Ala molecules and compared their features with known peptides from B*44:0241Thr/45Lys/46Glu. While HLA-B*44:02 has an anchor motif of E at the p2 anchor position, HLA-B*44:08 exhibits Q and L as anchor motif. The 45Met/Lys polymorphism contributes to the alteration in the peptide-binding motif and provides further evidence that mismatches at position 45 should be considered as nonpermissive in a transplantation setting.

HLA-E: A Novel Player for Histocompatibility

The classical class I human leukocyte antigens (HLA-A, -B, and -C) present allele-specific self- or pathogenic peptides originated by intracellular processing to CD8+ immune effector cells. Even a single mismatch in the heavy chain (hc) of an HLA class I molecule can impact on the peptide binding profile. Since HLA class I molecules are highly polymorphic and most of their polymorphisms affect the peptide binding region (PBR), it becomes obvious that systematic HLA matching is crucial in determining the outcome of transplantation. The opposite holds true for the nonclassical HLA class I molecule HLA-E. HLA-E polymorphism is restricted to two functional versions and is thought to present a limited set of highly conserved peptides derived from class I leader sequences. However, HLA-E appears to be a ligand for the innate and adaptive immune system, where the immunological response to peptide-HLA-E complexes is dictated through the sequence of the bound peptide. Structural investigations clearly demonstrate how subtle amino acid differences impact the strength and response of the cognate CD94/NKG2 or T cell receptor.