Mooring Stone-Like Arg114 Pulls Diverse Bulged Peptides: First Insight into African Swine Fever Virus-Derived T Cell Epitopes Presented by Swine Major Histocompatibility Complex Class I.

African swine fever virus (ASFV) is the causative agent of African swine fever (ASF), which is a devastating pig disease threatening the global pork industry. However, currently, no commercial vaccines are available. During the pig immune response, major histocompatibility complex class I (MHC-I) molecules select viral peptide epitopes and present them to host cytotoxic T lymphocytes, thereby playing critical roles in eliminating viral infections. Here, we screened peptides derived from ASFV and determined the molecular basis of ASFV-derived peptides presented by the swine leukocyte antigen 1*0101 (SLA-1*0101). We found that peptide binding in SLA-1*0101 differs from the traditional mammalian binding patterns. Unlike the typical B and F pockets used by the common MHC-I molecule, SLA-1*0101 uses the D and F pockets as major peptide anchor pockets. Furthermore, the conformationally stable Arg114 residue located in the peptide-binding groove (PBG) was highly selective for the peptides. Arg114 draws negatively charged residues at positions P5 to P7 of the peptides, which led to multiple bulged conformations of different peptides binding to SLA-1*0101 and creating diversity for T cell receptor (TCR) docking. Thus, the solid Arg114 residue acts as a "mooring stone" and pulls the peptides into the PBG of SLA-1*0101. Notably, the T cell recognition and activation of p72-derived peptides were verified by SLA-1*0101 tetramer-based flow cytometry in peripheral blood mononuclear cells (PBMCs) of the donor pigs. These results refresh our understanding of MHC-I molecular anchor peptides and provide new insights into vaccine development for the prevention and control of ASF. IMPORTANCE The spread of African swine fever virus (ASFV) has caused enormous losses to the pork industry worldwide. Here, a series of ASFV-derived peptides were identified, which could bind to swine leukocyte antigen 1*0101 (SLA-1*0101), a prevalent SLA allele among Yorkshire pigs. The crystal structure of four ASFV-derived peptides and one foot-and-mouth disease virus (FMDV)-derived peptide complexed with SLA-1*0101 revealed an unusual peptide anchoring mode of SLA-1*0101 with D and F pockets as anchoring pockets. Negatively charged residues are preferred within the middle portion of SLA-1*0101-binding peptides. Notably, we determined an unexpected role of Arg114 of SLA-1*0101 as a "mooring stone" which pulls the peptide anchoring into the PBG in diverse "M"- or "n"-shaped conformation. Furthermore, T cells from donor pigs could activate through the recognition of ASFV-derived peptides. Our study sheds light on the uncommon presentation of ASFV peptides by swine MHC-I and benefits the development of ASF vaccines.

An Invariant Arginine in Common with MHC Class II Allows Extension at the C-Terminal End of Peptides Bound to Chicken MHC Class I.

MHC molecules are found in all jawed vertebrates and are known to present peptides to T lymphocytes. In mammals, peptides can hang out either end of the peptide-binding groove of classical class II molecules, whereas the N and C termini of peptides are typically tightly bound to specific pockets in classical class I molecules. The chicken MHC, like many nonmammalian vertebrates, has a single dominantly expressed classical class I molecule encoded by the BF2 locus. We determined the structures of BF2*1201 bound to two peptides and found that the C terminus of one peptide hangs outside of the groove with a conformation much like the peptides bound to class II molecules. We found that BF2*1201 binds many peptides that hang out of the groove at the C terminus, and the sequences and structures of this MHC class I allele were determined to investigate the basis for this phenomenon. The classical class I molecules of mammals have a nearly invariant Tyr (Tyr84 in humans) that coordinates the peptide C terminus, but all classical class I molecules outside of mammals have an Arg in that position in common with mammalian class II molecules. We find that this invariant Arg residue switches conformation to allow peptides to hang out of the groove of BF2*1201, suggesting that this phenomenon is common in chickens and other nonmammalian vertebrates, perhaps allowing the single dominantly expressed class I molecule to bind a larger repertoire of peptides.

Conserved peptides enhance immune efficiency of inactive vaccines against emerging avian influenza viruses in chicken.

Avian influenza viruses (AIVs) such as H5N1 and H7N9 are a great threat to poultry economics and public health. Vaccination can effectively inhibit the spread of AIV in poultry, which is also a viable strategy for controlling virus transmission from poultry to human. Adjuvants that are commonly used in current inactivated vaccines to provide stronger anti-AIV immune responses are often limited in their capacity to quantitatively induce both humoral and cellular immune responses. Herein, we assessed the levels of immune responses generated by a vaccine formulation comprising inactivated H5N1 antigen and synthetic peptides covering conserved CD4+, CD8+ T cell, and B cell epitopes. We found that the synthetic peptides enhanced the antibody responses against conserved influenza virus antigen M2e. Notably, the hemagglutination inhibition test results indicated that the peptides significantly augmented the antibody responses of inactivated H5N1 antigen even in the 1/10 or 1/5 dose group, in the identical antibody level as antigen alone used at the full dose. This indicates that the peptide can significantly reduce the use of inactivated virus, lowering the cost of the vaccine. Moreover, the peptides increased the transcript levels of interleukin-4 and interferon-γ cytokines in chicken peripheral blood mononuclear cells, which may facilitate both humoral and cellular immune responses. Our data suggest that this peptide combined with inactivated H5N1 antigen enhances both the humoral and cellular immune responses, which may benefit the prediction and design of synthetic peptide-based adjuvants for vaccines in chicken.

Diversified Anchoring Features the Peptide Presentation of DLA-88*50801: First Structural Insight into Domestic Dog MHC Class I.

Canines represent a crucial animal model for studying human diseases and organ transplantation, as well as the evolution of domestic animals. MHCs, with a central role in cellular immunity, are commonly used in the study of dog population genetics and genome evolution. However, the molecular basis for the peptide presentation of dog MHC remains largely unknown. In this study, peptide presentation by canine MHC class I DLA-88*50801 was structurally determined, revealing diversified anchoring modes of the binding peptides. Flexible and large pockets composed of both hydrophobic and hydrophilic residues can accommodate pathogen-derived peptides with diverse anchor residues, as confirmed by thermostability measurements. Furthermore, DLA-88*50801 contains an unusual α2 helix with a large coil in the TCR contact region. These results further our understanding of canine T cell immunity through peptide presentation of MHC class I and shed light on the molecular basis for vaccine development for canine infectious diseases, for example, canine distemper virus.