Isoforms of the nonclassical class I MHC antigen H2-Q5 are enriched in brain and encode Qdm peptide.

Although the human nonclassical class Ib major histocompatibility complex (Mhc) locus, HLA-G, is known to act as an immune suppressor in immune-privileged sites, little is currently known regarding participation of the rodent class Ib Mhc in similar pathways. Here, we investigated the expression properties of the mouse nonclassical Mhc H2-Q5(k) gene, previously detected in tumors and tissues associated with pregnancy. We find that H2-Q5(k) is alternatively spliced into multiple novel isoforms in a wide panel of C3H tissues. Unlike other known class I MHC, it is most highly transcribed in the brain, where the classical class Ia Mhc products are scarce. The truncated isoforms are selectively enriched in sites of immune privilege and are translated into cell surface proteins in neural crest-derived transfected cells. Furthermore, we present data supporting a model whereby Q5(k) isoforms serve an immune-protective role by donating their Qdm leader peptide to Qa-1, in a pathway homologous to the HLA-G leader fragment binding HLA-E and inhibiting CD94/NKG2A-positive cytotoxic cells. In addition, we report a previously unknown homolog of H2-Q5(k) in the C57BL/6 mouse, which encodes Qdm, but is transcribed solely into noncanonical isoforms. Collectively, these studies demonstrate that H2-Q5(k), and its homologous class I-like H2(b) gene may play tissue-specific roles in regulating immune surveillance.

Sequence feature variant type (SFVT) analysis of the HLA genetic association in juvenile idiopathic arthritis.

The immune response HLA class II DRB1 gene provides the major genetic contribution to Juvenile Idiopathic Arthritis (JIA), with a hierarchy of predisposing through intermediate to protective effects. With JIA, and the many other HLA associated diseases, it is difficult to identify the combinations of biologically relevant amino acid (AA) residues directly involved in disease due to the high level of HLA polymorphism, the pattern of AA variability, including varying degrees of linkage disequilibrium (LD), and the fact that most HLA variation occurs at functionally important sites. In a subset of JIA patients with the clinical phenotype oligoarticular-persistent (OP), we have applied a recently developed novel approach to genetic association analyses with genes/proteins sub-divided into biologically relevant smaller sequence features (SFs), and their "alleles" which are called variant types (VTs). With SFVT analysis, association tests are performed on variation at biologically relevant SFs based on structural (e.g., beta-strand 1) and functional (e.g., peptide binding site) features of the protein. We have extended the SFVT analysis pipeline to additionally include pairwise comparisons of DRB1 alleles within serogroup classes, our extension of the Salamon Unique Combinations algorithm, and LD patterns of AA variability to evaluate the SFVT results; all of which contributed additional complementary information. With JIA-OP, we identified a set of single AA SFs, and SFs in which they occur, particularly pockets of the peptide binding site, that account for the major disease risk attributable to HLA DRB1. These are (in numeric order): AAs 13 (pockets 4 and 6), 37 and 57 (both pocket 9), 67 (pocket 7), 74 (pocket 4), and 86 (pocket 1), and to a lesser extent 30 (pockets 6 and 7) and 71 (pockets 4, 5, and 7).

Novel sequence feature variant type analysis of the HLA genetic association in systemic sclerosis.

We describe a novel approach to genetic association analyses with proteins sub-divided into biologically relevant smaller sequence features (SFs), and their variant types (VTs). SFVT analyses are particularly informative for study of highly polymorphic proteins such as the human leukocyte antigen (HLA), given the nature of its genetic variation: the high level of polymorphism, the pattern of amino acid variability, and that most HLA variation occurs at functionally important sites, as well as its known role in organ transplant rejection, autoimmune disease development and response to infection. Further, combinations of variable amino acid sites shared by several HLA alleles (shared epitopes) are most likely better descriptors of the actual causative genetic variants. In a cohort of systemic sclerosis patients/controls, SFVT analysis shows that a combination of SFs implicating specific amino acid residues in peptide binding pockets 4 and 7 of HLA-DRB1 explains much of the molecular determinant of risk.

The murine family of gut-restricted class Ib MHC includes alternatively spliced isoforms of the proposed HLA-G homolog, "blastocyst MHC".

The gastrointestinal tract is populated by a multitude of specialized immune cells endowed with receptors for classical (class Ia) and nonclassical (class Ib) MHC proteins. To identify class I products that engage these receptors and impact immunity/tolerance, we studied gut-transcribed class Ib loci and their polymorphism in inbred, outbred, and wild-derived mice. Intestinal tissues enriched in epithelial cells contained abundant transcripts of ubiquitously expressed and preferentially gut-restricted Q and T class I loci. The latter category included the "blastocyst Mhc" gene, H2-Bl, and its putative paralog, Tw5. Expression of H2-Bl was previously detected only at the maternal/fetal interface, where it was proposed to induce immune tolerance via interactions with CD94/NKG2A receptors. Analysis of coding region polymorphism performed here revealed two major alleles of H2-Bl with conserved residues at positions critical for class I protein folding and peptide binding. Both divergent alleles are maintained in outbred and wild mice under selection for fecundity and pathogen resistance. Surprisingly, we found that alternative splicing of H2-Bl mRNA in gut tissues is prevalent and allele-specific. It leads to strain-dependent expression of diverse repertoires of canonical and noncanonical transcripts that may give rise to distinct ligands for intestinal NK cell, T cell, and/or intraepithelial lymphocyte receptors.