Jamsandekar, M.; Sangdehi, F. M.; Berg, F.; Criscitiello, M. F.; Davis, B. W.; Larsson, M.; Li, j.; Pettersson, M. E.; Andersson, L.

Major Histocompatibility Complex (MHC) genes are the most polymorphic in vertebrate genomes due to their important function of presenting a diversity of peptides from pathogens to initiate an adaptive immune response. Here, we have characterized MHC class II genes and explored their polymorphism and evolution in one of the most abundant vertebrates in the world, Atlantic herring (Clupea harengus). The vast population size and schooling behavior make Atlantic herring an attractive target for pathogens. Hence, we hypothesized that it would maintain exceptionally high MHC polymorphism. We used PacBio HiFi long-read whole genome sequencing data of 14 individuals from three different geographic regions in the Atlantic Ocean and Baltic Sea. The analysis identified nine MHC class II loci distributed across four chromosomes. We found two distinct lineages of class II genes, a highly polymorphic one denoted DA and a non-polymorphic DB lineage, arranged as alpha-beta gene pairs (DAA-DAB or DBA-DBB). The DA genes showed extremely high nucleotide diversity in exon 2, strong signatures of positive selection (dN/dS >> 1) as well as copy number variation. Structure prediction revealed that all highly polymorphic amino acid residues occurred in the predicted peptide binding cleft. Two of the most polymorphic loci showed distinct allelic groupings (supertypes), with high sequence similarity within supertypes and high sequence divergence between supertypes. Most of the haplotypes had genes from different supertypes, thus maintaining diverse class II repertoire in a single individual. There was also a highly significant nonrandom association of DAA and DAB alleles within supertypes, strongly suggesting coevolution of DAA and DAB alleles forming the peptide binding domain. This study reveals that the herring MHC class II genes are among the most, if not the most, polymorphic so far described in vertebrates. Their exceptional polymorphism surpasses that of human due to a larger gene repertoire, copy number variation, and pronounced sequence divergence among alleles. This unheralded polymorphism is most likely explained by the combined effects of the vast population size, minimizing genetic drift, and strong pathogen-driven balancing selection.