Identification of seven new humanMHC class I region genes around theHLA-F locus

Using cDNA hybridization selection techniques, we identified seven new genes in a 280 kilobase YAC coveting theHLA-F locus. The new genes were mapped back to the YAC by a combination of optical restriction mapping and pulse field gel electrophoresis. Northern analysis of individual clones demonstrated the presence of either different mRNA sizes or different expression patterns. Two of the cDNA clones were expressed only in lymphoid cell lines: one in Jurkat cells (T cell) and another in JY cells (B cell). All the genes lacked sequence similarity to any known classical and non-classical major histocompatibility complex (MHC) class I genes, indicating that theMHC class I region has more functions than anticipated. Of the seven new genes, one is highly similar (97%) to mouse 60S ribosomal protein, and another is homologous to diubiquitin proteins. Of the two G-coupled receptor-like cDNAs, one was fully sequenced and found to be an olfactory receptor-like gene. The study strengthens evidence that theMHC complex not only plays a key role in the immune system, but also contributes to non-immunological functions. The nucleotide sequence data reported in this paper have been submitted to the Genbank nucleotide sequence database and have been assigned the accession numbers U37229 (IB2), U37230 (IC4), U37231 (IF12), U37232 (IH9), U37233 (2D8), U37234 (2H6), and L35475 (IA8)     

Alterations of class I HLA genes in human colon cancers

Summary Alterations of HLA class I genes were found in 3 of 12 human colon cancers. Rearrangements in HLA class I genes were observed in 2 cancers and amplification of HLA-coding genes was observed in 1 cancer. All 3 cancers were at an advanced stage. No examples of amplification or rearrangement in the HLA genes were found in 10 other tumours of diverse types. No alterations in the ₂-microgubulin gene were observed in 22 human solid tumours included in this study. The association between alterations in HLA genes and proto-oncogenes in these tumours is discussed.     

Expression of class I HLA genes by trophoblast cells. Analysis by in situ hybridization

Evaluation of trophoblast cells by immunohistology has shown that subpopulations of trophoblast cells express class I HLA differently from one another and differently from embryonic and adult cells. Placental syncytial trophoblast does not express detectable levels of class I HLA; chorion membrane cytotrophoblasts bind one mAb to monomorphic determinants of class I Ag, W6/32, but not a second, 61D2. In the present study, sections of normal term placentae and matching extraplacental membranes were evaluated by in situ hybridization procedures for cells containing class I HLA mRNA using pHLA1.1, which is complementary to HLA-B. Class I Ag expression was identified by immunohistology using two mAb to class I HLA (W6/32, 61D2) and the mAb 4E to identify HLA-B. Placental syncytial trophoblast contained low to undetectable levels of class I mRNA and failed to bind all three mAb. Chorion membrane cytotrophoblast cells contained moderate levels of class I HLA mRNA and were positive with the mAb W6/32 but were negative with 61D2 and 4E. In adjacent tissues, fetal mesenchymal cells and maternal decidual cells contained high levels of class I mRNA and were positive with all three mAb. The results suggest that syncytial trophoblast may not express class I HLA because of low steady-state levels of class I HLA mRNA. In contrast, chorionic cytotrophoblast cells may express truncated versions of class I HLA or nonclassical HLA-A,B,C-like Ag. Regulation of the expression of class I HLA gene products may be essential to the development of a satisfactory immunologic relationship between the mother and her semiallogeneic fetus during pregnancy.     

KIR genes and HLA class I ligands in Gaucher disease

Gaucher disease (GD) is caused by reduced activity of the lysosomal enzyme glucocerebrosidase, which leads to a buildup of glucocerebroside within the cells and chronic stimulation of the immune system. GD is associated with clinical variability even in the same family, which suggests the influence of modifier genes. Natural killer (NK) cells play an important role in the immune response, and their number is decreased in GD. Killer-cell immunoglobulin-like receptors (KIR) regulate the activity of NK cells through an interaction with specific human leukocyte antigen (HLA) class I molecules on target cells.     

Amnion membrane epithelial cells express class I HLA and contain class I HLA mRNA

Amnion epithelial cells in membranes from term deliveries, which have been reported not to express histocompatibility Ag, were evaluated for HLA by using an avidin-biotin immunoperoxidase staining system and for class I HLA mRNA by Northern blotting and in situ hybridization. There were three major findings from these studies. 1) Amnion cells frequently expressed class I HLA. Three mAb to monomorphic determinants of class I HLA were used: 61D2, PA2.6, and W6/32. 61D2 identified 1 of 8 fresh amnion membranes as class I positive whereas PA2.6 identified 4/8 and W6/32 identified 5/8. 2) Amnion cells contained class I HLA mRNA. RNA extracted from amnion membranes hybridized to a class I HLA probe (pHLA1.1) in Northern blotting. In situ hybridization procedures with pHLA1.1 showed that essentially all amnion cells contained class I HLA mRNA. 3) Levels of class I HLA mRNA in amnion cells could be modulated. Exposure of amnion explants to medium containing IFN-gamma enhanced levels of class I HLA mRNA in amnion cells, whereas epidermal growth factor diminished those levels. The results suggest that amnion cells transcribe class I HLA genes and are capable of synthesizing class I H chains but that expression may be modulated by extrinsic regulatory molecules.     

The chromosome region containing the highly polymorphic HLA class I genes displays limited large scale variability in the human population

The large-scale organization and polymorphism of the HLA class I region was investigated by pulsed field gel (PFG) fractionation of DNA from various HLA-typed cell lines cleaved by different 'rare cutter' restriction enzymes, followed by hybridization with 'general' and locus-specific HLA probes. Results indicate that (i) most HLA class I sequences are contained in a 340 kb MluI DNA fragment which also carries the HLA-A gene; (ii) HLA-A, -B and -C genes are present on different fragments bounded by 'HTF islands' (CpG-rich, unmethylated DNA regions containing multiple sites for 'rare cutter' enzymes) which generally coincide with the 5' regions of expressed genes; and (iii) very little fragment size polymorphism is seen, implying that expansion/contraction events in the HLA class I region due to unequal crossing over (as documented in the mouse class I system) are infrequently found in the human population.     

HLA antibody responses in HLA class I transgenic mice

In a previous report we described how cross-immunizations of pairs of transgenic mice expressing different HLA class I antigens led to the production of antibodies directed exclusively at polymorphic epitopes. This was ascribed to self-tolerance of HLA that prevents immune responses to monomorphic epitopes and focuses responses on polymorphic ones. In the present report we extend our findings and demonstrate that immunizations of class I transgenic mice with HLA transfected mouse fibrosarcoma as well as with human lymphoblastoid cells also preferentially yield antibodies to polymorphic epitopes. This was the case whether or not immunizations were carried out across locus barriers [e.g., Tg (HLA-A *0201) or Tg (HLA-Cw*0301) transgenic mice immunized with HLA-B27 transfectants] or within the same locus [e.g., Tg (HLA-B*1302) transgenic mice immunized with HLA-B27 transfectants or B27-expressing lympho-blastoid cell]. Use of an extended immunization protocol with four or more booster injections favored antibodies of IgG isotype with affinities high enough to lyse normal peripheral blood lymphocytes (PBLs) in complement-dependent cytotoxicity assays and to immunoprecipitate HLA antigens. The specificities covered by the monoclonal antibodies (mAbs) could be either broad or narrow, depending on the genetic distance of the HLA antigens or alleles involved. For instance, a Tg(HLA-B*1302) transgenic mouse immunized with B27 produced both broad B7/B27-specific antibodies, Bw4-specific antibodies, and one antibody reacting with all B alleles except B13 and with some C alleles. On the other hand, a Tg(HLA-B*1302) transgenic mouse immunized with Bw47 transfectants responded narrowly with an antibody to Bw60 and Bw47. Thus it appears that by choosing appropriate recipient mice and closely related or more distant HLA antigens, antibodies of a programmed specificity can be generated. Address correspondence and offprint requests to: U. Hämmerling.     

HLA class I allele promiscuity revisited

The peptide repertoire presented on human leukocyte antigen (HLA) class I molecules is largely determined by the structure of the peptide binding groove. It is expected that the molecules having similar grooves (i.e., belonging to the same supertype) might present similar/overlapping peptides. However, the extent of promiscuity among HLA class I ligands remains controversial: while in many studies T cell responses are detected against epitopes presented by alternative molecules across HLA class I supertypes and loci, peptide elution studies report minute overlaps between the peptide repertoires of even related HLA molecules. To get more insight into the promiscuous peptide binding by HLA molecules, we analyzed the HLA peptide binding data from the large epitope repository, Immune Epitope Database (IEDB), and further performed in silico analysis to estimate the promiscuity at the population level. Both analyses suggest that an unexpectedly large fraction of HLA ligands (>50%) bind two or more HLA molecules, often across supertype or even loci. These results suggest that different HLA class I molecules can nevertheless present largely overlapping peptide sets, and that “functional” HLA polymorphism on individual and population level is probably much lower than previously anticipated.     

Order of class III genes relative to HLA genes determined by the haplotype method

The B18 C4A3 C4BQ0 BfF1 DR3 haplotype was found to be ideal for determining the order of C4 and Bf relative to HLA-B and DR by the haplotype method. All the copies of this haplotype are assumed to be derived from a single ancestral haplotype. Sixteen of the twenty-six BfFl-containing haplotypes carried all of the alleles from this ancestral haplotype. Most of the other BfFl-containing haplotypes could be derived from the ancestral haplotype by a single crossover event for one of the two possible gene orders. This suggests that B18 C4A3 C4BQ0 BfFl DR3 is the sole source of the BfFl allele. The uncommon C4 type on B18 C4A3 C4BQ0 BfFl DR3 facilitates recognition of the BfFl-containing products of recombination between Bf and C4. One such recombinant haplotype was found which shows that the orientation of the class III genes is as follows: C4 is closest to HLA-B and Bf is closest to HLA-DR. This gene order is supported by all the earlier unequivocal results obtained using the haplotype method (Olaisen et al. 1983, Marshall et al. 1984a). Combining these results with the information on class III genes obtained from overlapping cosmid clones (Carroll et al. 1984) and earlier mapping studies (Robson and Lamm 1984) shows that HLA-B is telomeric to 21B. C4B, 21A, C4A, Bf and C2 then follow 21B in that order covering 120 kb. HLA-DR is located further toward the centromere.     

Regulation of HLA class I expression by non-coding gene variations

The Human Leukocyte Antigen (HLA) is a critical genetic system for different outcomes after solid organ and hematopoietic cell transplantation. Its polymorphism is usually determined by molecular technologies at the DNA level. A potential role of HLA allelic expression remains under investigation in the context of the allogenic immune response between donors and recipients. In this study, we quantified the allelic expression of all three HLA class I loci (HLA-A, B and C) by RNA sequencing and conducted an analysis of expression quantitative traits loci (eQTL) to investigate whether HLA expression regulation could be associated with non-coding gene variations. HLA-B alleles exhibited the highest expression levels followed by HLA-C and HLA-A alleles. The max fold expression variation was observed for HLA-C alleles. The expression of HLA class I loci of distinct individuals demonstrated a coordinated and paired expression of both alleles of the same locus. Expression of conserved HLA-A~B~C haplotypes differed in distinct PBMC’s suggesting an individual regulated expression of both HLA class I alleles and haplotypes. Cytokines TNFα /IFNβ, which induced a very similar upregulation of HLA class I RNA and cell surface expression across alleles did not modify the individually coordinated expression at the three HLA class I loci. By identifying cis eQTLs for the HLA class I genes, we show that the non-coding eQTLs explain 29%, 13%, and 31% of the respective HLA-A, B, C expression variance in unstimulated cells, and 9%, 23%, and 50% of the variance in cytokine-stimulated cells. The eQTLs have significantly higher effect sizes in stimulated cells compared to unstimulated cells for HLA-B and HLA-C genes expression. Our data also suggest that the identified eQTLs are independent from the coding variation which defines HLA alleles and thus may be influential on intra-allele expression variability although they might not represent the causal eQTLs.     

Examination of four HLA class I pseudogenes. Common events in the evolution of HLA genes and pseudogenes.

The HLA class I gene family in lymphoblastoid cell line 721 has been studied in detail and a number of sequences in addition to the classical genes have been identified. The cloning, characterization, and nucleotide sequences of four sequences, all full length HLA class I pseudogenes, are described in this report. These pseudogenes, contained within 5.4-, 5.9-, 7.0-, and 9.2-kb HindIII fragments, each have the class I exon-intron structure as well as class I homology in their 5' and 3' flanking regions. However, all four sequences have one or more substitutions that perturb the coding region, leaving little doubt that they are in fact pseudogenes. Comparisons among these sequences and the HLA class I genes revealed that their homology with the class I genes is patchwork. Thus, although some regions have diverged, other contiguous intron-exon sequences are highly conserved. Comparisons in the 5' regions indicate that the pseudogene promoters more closely resemble the classical HLA promoters than the nonclassical promoters as none of the unique structural features found in the HLA-E, -F, or -G regulatory regions are present in any of the pseudogene promoters. Further comparisons revealed that at least two putative gene conversion events, similar to those hypothesized to have occurred in the evolution of some HLA genes, may have occurred in the evolution of some of the pseudogenes. These and other hypothetical events in the evolution of the class I gene family are discussed.     

Proteome sampling by the HLA class I antigen processing pathway

The peptide repertoire that is presented by the set of HLA class I molecules of an individual is formed by the different players of the antigen processing pathway and the stringent binding environment of the HLA class I molecules. Peptide elution studies have shown that only a subset of the human proteome is sampled by the antigen processing machinery and represented on the cell surface. In our study, we quantified the role of each factor relevant in shaping the HLA class I peptide repertoire by combining peptide elution data, in silico predictions of antigen processing and presentation, and data on gene expression and protein abundance. Our results indicate that gene expression level, protein abundance, and rate of potential binding peptides per protein have a clear impact on sampling probability. Furthermore, once a protein is available for the antigen processing machinery in sufficient amounts, C-terminal processing efficiency and binding affinity to the HLA class I molecule determine the identity of the presented peptides. Having studied the impact of each of these factors separately, we subsequently combined all factors in a logistic regression model in order to quantify their relative impact. This model demonstrated the superiority of protein abundance over gene expression level in predicting sampling probability. Being able to discriminate between sampled and non-sampled proteins to a significant degree, our approach can potentially be used to predict the sampling probability of self proteins and of pathogen-derived proteins, which is of importance for the identification of autoimmune antigens and vaccination targets.     

Impact of peptides on the recognition of HLA class I molecules by human HLA antibodies

MHC class I molecules expressed on cell surfaces are composed of H chain, beta2-microglobulin and any of a vast array of peptides. The role of peptide in the recognition of HLA class I by serum HLA Abs is unknown. In this study, the solid-phase assay of a series (n = 11) of HLA-A2-reactive, pregnancy-induced, human mAbs on a panel (n = 12) of recombinant monomeric HLA-A2 molecules, each containing a single peptide, revealed peptide selectivity of the mAbs. The flow cytometry membrane staining intensities on the HLA-A2-transduced cell line K562, caused by these mAbs, correlated with the number of monomer species detected by the mAbs. Flow cytometry staining on HLA-A2-bearing cell lines of a variety of lineages was indicative of tissue selectivity of these HLA-A2 mAbs. This tissue selectivity suggests that the deleterious effect on allografts is confined to alloantibodies recognizing only HLA class I loaded with peptides that are derived from tissue-specific and household proteins. Since Abs that are only reactive with HLA loaded with irrelevant peptides are expected to be harmless toward allografts, the practice of HLA Ab determination on lymphocyte-derived HLA deserves reconsideration.