The Structure of the MHC Class I Molecule of Bony Fishes Provides Insights into the Conserved Nature of the Antigen-Presenting System

Abstract MHC molecules evolved with the descent of jawed fishes some 350–400 million years ago. However, very little is known about the structural features of primitive MHC molecules. To gain insight into these features, we focused on the MHC class I Ctid-UAA of the evolutionarily distant grass carp (Ctenopharyngodon idella). The Ctid-UAA H chain and β2-microglobulin (Ctid-β2m) were refolded in vitro in the presence of peptides from viruses that infect carp. The resulting peptide-Ctid-UAA (p/Ctid-UAA) structures revealed the classical MHC class I topology with structural variations. In comparison with known mammalian and chicken peptide-MHC class I (p/MHC I) complexes, p/Ctid-UAA structure revealed several distinct features. Notably, 1) although the peptide ligand conventionally occupied all six pockets (A–F) of the Ag-binding site, the binding mode of the P3 side chain to pocket D was not observed in other p/MHC I structures; 2) the AB loop between β strands of the α1 domain of p/Ctid-UAA complex comes into contact with Ctid-β2m, an interaction observed only in chicken p/BF2*2101-β2m complex; and 3) the CD loop of the α3 domain, which in mammals forms a contact with CD8, has a unique position in p/Ctid-UAA that does not superimpose with the structures of any known p/MHC I complexes, suggesting that the p/Ctid-UAA to Ctid-CD8 binding mode may be distinct. This demonstration of the structure of a bony fish MHC class I molecule provides a foundation for understanding the evolution of primitive class I molecules, how they present peptide Ags, and how they might control T cell responses.