Abstract. Gene cloning and sequencing of the HLA-Blocus split antigens B38 (B16.1) and B39 (B16.2) allowed localization of their subtypic as well as their public specificities HLA-Bw4 or -Bw6 to the c~-helical region of the c~ 1 domain flanked by the amino acid positions 74-83. Comparison of their amino acid sequences with those of other HLA-B-locus alleles established HLA-Bw6 to be distinguished by Ser at residue 77 and Asn at residue 80. In contrast, HLA-Bw4 is characterized by at least seven different patterns of amino acid exchanges at positions 77 and 80-83. Reactivity patterns of Bw4-or Bw6-specific monoclonal antibodies reveal two alloantigenic epitopes contributing to the HLA-Bw4 or -Bw6 specificity residing next to the region of highest diversity of the cr domain.
Secretion of the proinflammatory cytokine Interleukin-17A (IL-17A) is the hallmark of a unique lineage of CD4 T cells designated Th17 cells, which may play a crucial role in the pathogenesis of rheumatoid arthritis (RA) and many autoimmune diseases. Recently, IL-17-producing cells other than T cells have been described, including diverse innate immune cells. Here, we show that the cellular sources of IL-17A in RA include a significant number of non-T cells. Multicolour fluorescence analysis of IL-17-expressing peripheral blood mononuclear cells (PBMC) revealed larger proportions of IL-17+CD3- non-T cells in RA patients than in healthy controls (constitutive, 13.6% vs. 8.4%, and after stimulation with PMA/ionomycin 17.4% vs. 7.9% p < 0.001 in both cases). The source of IL-17 included CD3-CD56+ NK cells, CD3-CD14+ myeloid cells as well as the expected CD3+CD4+ Th17 cells and surprisingly a substantial number of CD3-CD19+ B cells. The presence of IL-17A-expressing B cells was confirmed by specific PCR of peripheral MACS-sorted CD19+ B cells, as well as by the analysis of different EBV-transformed B cell lines. Here we report for the first time that in addition to Th17 cells and different innate immune cells B cells also contribute to the IL-17A found in RA patients and healthy controls.
Allele-specific differences in the regulation of HLA class I genes by type I interferon (IFN) were observed after transfection of eight HLA-B, -A, or -C genes into mouse L cells. HLA-B7 and -Bw64 gene expression was significantly more inducible by type I IFN than the genes coding for HLA-B27, HLA-B51, HLA-B38, HLA-B39, HLA-Cw3, and HLA-A2 antigens. Modification of the 5' end of HLA-B7 and HLA-B27 genes revealed the presence of enhancer sequences responding to IFN treatment in the 5' untranslated region of HLA-B7, but not of HLA-B27 and suggested further, independently acting enhancer elements downstream of the transcription initiation site. Comparison of 5' enhancer region sequences in correlation with type I IFN inducibility of the different HLA class I alleles indicated that the exchange of only two nucleotides in the interferon response sequence (IRS) or enhancer A region of HLA-B7 or -Bw64 could account for nonregulated promoters in all other HLA-A, -B, or -C alleles analyzed. Thus, type I IFN stimulation of HLA class I genes in mouse L cells appears to predominantly operate in most alleles by a mechanism targeted to enhancer sequences downstream of the gene's transcription initiation site.
In this study, a new sequencing-based typing strategy for the HLA-A locus is presented which involves group-specific separate amplification of exon 2 and 3 of HLA-A alleles in a first step. Conserved HLA-A locus-specific primers of intron 1 or 3 were combined in 10 primer-mixes with group-specific primers hybridizing to the 5'- or 3'-end of exon 3 or 2 for pre-typing of the HLA-A alleles in 14 allelic groups. Maximally four overlapping short amplicons are produced under identical polymerase chain reaction (PCR) conditions with individual separate amplification of exon 2 and exon 3 of the haplotypic alleles in most heterozygous combinations. Time- and money-saving one-directional Big Dye Terminator cycle sequencing is shown to provide reliable high resolution typing of the HLA-A alleles, even in a few cases of two amplicons in one primer reaction mixture. In comparison, to other sequencing-based typing (SBT) techniques the applied typing strategy minimizes the risk of unequal amplification or of drop-outs of one of the haplotypic alleles and allows unequivocal definition of the cis/ trans linkage of polymorphic positions of the complete exon 2 and exon 3 in most heterozygous cells. This also includes detection of new alleles differing in the polymorphic template generating primer annealing sites as well as in unusual combinations of known exon 2 and 3 sequences. With 10 primer sets working under identical conditions for pre-grouping and separate amplification of the haplotypic alleles our SBT procedure also could be implemented in clinical settings of large-scale stem cell donor histocompatibility testing for fast molecular HLA-A matching.
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