HLA-DQA1 and HLA-DQB1 Alleles, Conferring Susceptibility to Celiac Disease and Type 1 Diabetes, are More Expressed Than Non-Predisposing Alleles and are Coordinately Regulated.

HLA DQA1*05 and DQB1*02 alleles encoding the DQ2.5 molecule and HLA DQA1*03 and DQB1*03 alleles encoding DQ8 molecules are strongly associated with celiac disease (CD) and type 1 diabetes (T1D), two common autoimmune diseases (AD). We previously demonstrated that DQ2.5 genes showed a higher expression with respect to non-CD associated alleles in heterozygous DQ2.5 positive (HLA DR1/DR3) antigen presenting cells (APC) of CD patients. This differential expression affected the level of the encoded DQ2.5 molecules on the APC surface and established the strength of gluten-specific CD4+ T cells response. Here, we expanded the expression analysis of risk alleles in patients affected by T1D or by T1D and CD comorbidity. In agreement with previous findings, we found that DQ2.5 and DQ8 risk alleles are more expressed than non-associated alleles also in T1D patients and favor the self-antigen presentation. To investigate the mechanism causing the high expression of risk alleles, we focused on HLA DQA1*05 and DQB1*02 alleles and, by ectopic expression of a single mRNA, we modified the quantitative equilibrium among the two transcripts. After transfection of DR7/DR14 B-LCL with HLA-DQA1*05 cDNA, we observed an overexpression of the endogenous DQB1*02 allele. The DQ2.5 heterodimer synthesized was functional and able to present gluten antigens to cognate CD4+ T cells. Our results indicated that the high expression of alpha and beta transcripts, encoding for the DQ2.5 heterodimeric molecules, was strictly coordinated by a mechanism acting at a transcriptional level. These findings suggested that, in addition to the predisposing HLA-DQ genotype, also the expression of risk alleles contributed to the establishment of autoimmunity.

Effects of some endocrine disruptors on cell cycle progression and murine dendritic cell differentiation.

Endocrine disruptor chemicals (EDCs), which are predominantly present in the environment, are able to mimic or antagonise the biological activity of hormones primarily through the interaction with specific receptors. The main consequences are adverse effects on the growth and development of reproductive organs, the induction of cancer and effects on neuronal differentiation. In this study, we investigated the ability of certain EDCs, Bisphenol A (BPA), Bisphenol B (BPB), Bisphenol F (BPF), 4-n Nonylphenol (NP) and Octylphenol (OP), belonging to a homogeneous group of phenol origin, to interfere with specific cellular processes, namely, proliferation, by using MCF-7 breast carcinoma cells, and differentiation, by using murine bone marrow dendritic cells. We correlated the data on cell growth with the stimulation of cell cycle progression, which could become a step in the development of cancer, and we established a proliferation ranking between the tested EDCs: NP>BPA>OP>BPB>BPF. In addition, we investigated the ability of NP, BPA and OP to induce the differentiation of dendritic cells, the powerful antigen-presenting cells of the immune system. The differentiation and activation of these cells could affect a well-regulated immune response and determine an allergic sensitisation. We found that BPA and NP were active in determining differentiation.

Effect of bisphenol A with or without enzyme treatment on the proliferation and viability of MCF-7 cells.

Recently, aqueous solutions polluted by BPA have been bioremediated by us using laccase immobilized on hydrophobic membranes in non-isothermal bioreactors. BPA degradation was checked using analytical methods. To assess in vitro the occurred bioremediation, the proliferation and viability indexes of MCF-7 cells incubated in the presence of aqueous solutions of BPA, or of enzyme-treated BPA solutions, have been measured as a function of the initial BPA concentration. The results demonstrated that: i) at each initial BPA concentration used, both the proliferation and viability indexes are a function of the duration of enzyme treatment; ii) proliferation and viability are uncoupled biological processes with respect to BPA enzyme treatment. Non-isothermal bioreactors are a useful tool for the bioremediation of aqueous solutions polluted by BPA, which is an example of an endocrine disruptor that belongs to the alkyl phenol family.

Modulation of TCR recognition of MHC class II/peptide by processed remote N- and C-terminal epitope extensions.

N- and C-terminal extensions of naturally processed MHC class II-bound peptides may affect TCR recognition. In fact, residues immediately flanking the minimal epitope on either side can contact the MHC groove and modify the interaction with a TCR. We report now that residues much farther away from the peptide core can also modulate TCR recognition in a functional antigen presentation system. To show this, we isolated from the same donor DR5-restricted T cell clones, specific for the HIV-1 RT(248-262) sequence and differing in their ability to respond to recombinant antigens obtained by insertion of the epitope in different positions of schistosomal, human, or murine glutathione-S-transferase (GST). We found that the reactivity profile of individual clones was related to their TCR fine specificity, suggesting that processing can generate determinants focused onto the same epitope, but antigenically distinct. In addition, we analyzed the response of this panel of T-helper cell clones against GST-derived recombinant antigens in which the epitope was flanked by stretches of polyalanine or polyserine on either side. These spacers had different effects on TCR recognition suggesting that secondary structures outside the core peptide may influence MHC/epitope complex recognition over a distance of 15-30 residues from the determinant.

Phage display of peptide epitopes from HIV-1 elicits strong cytolytic responses.

Although much effort has been expended on evaluating recombinant proteins and synthetic peptides as immunogens, they have generally proved incapable of inducing an efficient cytotoxic T-cell (CTL) response. Filamentous bacteriophage fd can display multiple copies of foreign peptides in the N-terminal region of its major coat protein pVIII, 2,700 copies of which make up the virus capsid. Here we show that fd virions displaying peptide RT2 (ILKEPVHGV), corresponding to residues 309-317 of the reverse transcriptase (RTase) of HIV-1, are able to prime a CTL response specific for this HIV-1 epitope in human cell lines. Successful priming also requires a T-helper epitope, pep23 (KDSWTVNDIQKLVGK), corresponding to residues 249-263 of HIV-1 RTase. Supplying this by displaying it on either the same or a separate bacteriophage virion led to activation of antigen-specific CD4+ T cells. Likewise, HLA-A2 transgenic mice immunized with bacteriophage virions displaying peptide RT2 were shown to mount an effective, specific anti-HIV-RT2 CTL response. This unexpected ability to elicit a designated cytolytic T-cell response, in addition to a B-cell response, has important implications for access to the class I major histocompatibility complex (MHC) loading compartment and the development of recombinant vaccines.

Downstream sequence adjacent to AUG affects translation of chloramphenicol acetyl transferase in eukaryotic cells.

The CAT gene is widely used as a reporter in eukaryotic systems because of the efficient translation of its mRNA. We report here that a sequence occurring in the CAT mRNA at +15 nucleotides from CAT AUG is essential for translation. This sequence includes a stem-loop structure, which, however, exhibits a calculated stability significantly lower than that required for a hairpin to act as an enhancer of translation in vitro. Replacement of this region with the corresponding sequence from mRNAs that are normally translated in eukaryotic systems drastically reduced translation of CAT in COS cells, although the consensus sequence around the AUG, known to be required for high-level translation initiation, was conserved. These observations may be relevant for the exploitation of the CAT reporter system for analysis of the mechanisms of translation initiation by means of fusion constructs.

Recognition of HIV-derived B and T cell epitopes displayed on filamentous phages.

The amino acid sequence of HIV reverse transcriptase (RT) from residue 248 to residue 262 was expressed on the surface of filamentous phage fd, fused to the major coat protein gVIIIp. The chimeric phage was used to assess the ability of anti-RT (248-262) human T cell lines and clones to become activated by the phage-displayed peptide. The RT peptide displayed on phage was recognized by the T-cells and induced production of Abs. However, not all T cells raised against the synthetic RT (248-262) peptide could respond. Lack of recognition did not depend on differences in the ability of different APCs to present the phage, but was apparently determined by the TCR specificity. The results presented here may be relevant to the design of recombinant protein-based subunit vaccines.

Differential expression of insulin-dependent diabetes mellitus-associated HLA-DQA1 alleles in vivo.

The strong association of HLA-DQ genes with insulin-dependent diabetes mellitus (IDDM) susceptibility is persuasive evidence of their central role in the etiology of this autoimmune disease. Among other possibilities, it has been proposed that an unbalanced expression of IDDM-associated DQA, and/or DQB alleles may lead to alterations in the composition of alpha beta heterodimers and preferential expression of a particular heterodimer on the antigen-presenting cell surface, leading to self-recognition. In this report, we demonstrate the differential expression of DQA1 alleles in vivo, in particular of the two diabetogenic alleles DQA1*0301 and DQA1*0501. Family studies suggest that unequal HLA-DQA1 allele expression in heterozygous individuals is not associated in cis with the HLA-DQA1 gene, but may be affected by trans-acting determinant(s). We also discuss the segregation of this phenotype in IDDM-affected members. Furthermore, we examined historical samples of PBL from an IDDM-affected individual and an HLA-identical unaffected sibling acting in a kidney transplant program as donor and recipient, respectively. This analysis allowed us to establish that unbalanced expression of DQA1*0301 and DQA1*0501 can be induced by microenvironmental conditions. Inducible differential expression of HLA-DQA1 alleles may account for the discordance in the outcome of autoimmune disease in monozygotic twins and HLA-identical siblings.

The regulation mechanism of HLA class II gene expression at the level of mRNA stability.

The number of major histocompatibility complex (MHC) class II antigens may be regulated at different levels. Although transcriptional regulation has been studied most intensely, evidence for control mechanisms acting on the stability of MHC class II mRNAs has been reported. We have previously shown, in fact, that the half-life of MHC class II mRNA rapidly decreases in Raji cells upon inhibition of translation by cycloheximide; further data indicated that this effect was not correlated with the inhibition of the synthesis of trans-acting protein(s) required for mRNA stability. In the present work, we developed an in vitro mRNA decay assay system to measure HLA-DRA mRNA stability and used inhibitors of protein synthesis affecting different steps of the process of translation in order to discriminate among possible mechanisms determining controlled MHC class II mRNA hydrolysis. We found that HLA-DRA mRNA associated with polysomes derived from cells treated with either puromycin (which causes dispersion of polysomes and accumulation of monosomes) or cycloheximide (which slows down translation causing ribosome stalling) is more rapidly degraded than in the absence of protein synthesis inhibitors. On the basis of our findings, we suggest that arrest of protein synthesis per se exposes the HLA-DRA mRNA molecules to degradative activities co-sedimenting with the polysomal fraction.

Control of nucleo-cytoplasmic HLA-DRA mRNA partitioning by interaction of a retention signal with compartmentalized proteins.

Transport of mRNA from the nucleus to the cytoplasm is still a poorly understood process in which RNA signal sequences and cognate RNA-binding proteins may be involved. We have analysed the transport of the mRNA encoded by HLA-DRA, a member of the immunologically important MHC class II multigene family. We report that, in transient transfection experiments, HLA-DRA mRNA molecules encompassing a signal situated in the 3' untranslated region predominantly accumulate in the nucleus. We also show that the RNA sequence involved interacts with compartmentalized proteins of either nuclear or cytoplasmic origin. Deletion of the mRNA region encompassing this retention site results both in the abrogation of protein binding and in the release of HLA-DRA mRNA into the cytoplasm. In addition, we have found that the distribution of these HLA-DRA mRNA binding proteins is different in different cell types; in particular, their pattern of expression in Ntera-2, a human teratocarcinoma cell line, is distinct from that observed in Raji, a human B-lymphoma cell line, and is modulated by growth in retinoic acid. We conclude that recognition of a mRNA retention signal by proteins located in different compartments on either side of the nuclear membrane may regulate the nucleo-cytoplasmic partitioning of HLA-DRA transcripts and, perhaps, of MHC class II mRNA in general.

Recognition of distinct HLA-DQA1 promoter elements by a single nuclear factor containing Jun and Fos or antigenically related proteins.

The activity of MHC class II promoters depends upon conserved regulatory signals one of which, the extended X-box, contains in its X2 subregion a sequence related to the cAMP response element, CRE and to the TPA response element, TRE. Accordingly, X2 is recognized by the AP-1 factor and by other c-Jun or c-Fos containing heterodimers. We report that the X-box dependent promoter activity of the HLA-DQA1 gene is down-modulated by an array of DNA elements each of which represented twice either in an invertedly or directly repeated orientation. In this frame, we describe a nuclear binding factor, namely DBF, promiscuously interacting with two of these additional signals, delta and sigma, and with a portion of the X-box, namely the X-core, devoid of X2. The presence of a single factor recognizing divergent DNA sequences was indicated by the finding that these activities were co-eluted from a heparin-Sepharose column and from DNA affinity columns carrying different DNA binding sites as ligands. Competition experiments made with oligonucleotides representing wild type and mutant DNA elements showed that each DNA element specifically inhibited the binding of the others, supporting the contention that DBF is involved in recognition of different targets. Furthermore, we found that DBF also exhibits CRE/TRE binding activity and that this activity can be competed out by addition of an excess of sigma, delta and X-core oligonucleotides. Anti-Jun peptide and anti-Fos peptide antibodies blocked not only the binding activity of DBF, but also its X-core and sigma binding; this blockade was removed by the addition of the Jun or Fos peptides against which the antibodies had been raised. In vitro synthesized Jun/Fos was able to bind to all these boxes, albeit with seemingly different affinities. The cooperativity of DBF interactions may explain the modulation of the X-box dependent promoter activity mediated by the accessory DNA elements described here.

Reversion of a transcriptionally defective MHC class II-negative human B-cell mutant.

RJ2.2.5, a mutant derived from the human B-lymphoma cell, Raji, is unable to express the MHC class II genes because of a recessive transcriptional defect attributed to the lack of an activator function. We report the isolation of a RJ2.2.5 revertant, namely AR, in which the expression of the mRNAs encoded by these genes is restored. Comparison of the binding of nuclear extracts or of partially purified nuclear preparations from the wild-type, the mutant and the revertant cells to a conserved MHC class II promoter element, the X-box, showed no alteration in the mobility of the complexes thus formed. However, in extracts from RJ2.2.5, and other MHC class II negative cell lines, such as HeLa, the amount of complex observed was significantly higher than in wild-type Raji cells. Furthermore, the binding activity exhibited by the AR revertant was lower than that of the RJ2.2.5 and higher than that of Raji. The use of specific monoclonal antibodies indicated that in all cases c-Jun and c-Fos or antigenically related proteins were required for binding. An inverse correlation between the level of DNA-protein complex formed and the level of MHC class II gene mRNA expressed in the three cell lines was apparent, suggesting that overexpression of a DNA binding factor forming complexes with class II promoter elements may cause repression of MHC class II transcription. A model which reconciles the previously ascertained recessivity of the phenotype of the mutation carried by RJ2.2.5 with the findings reported here is discussed.

DNA polymorphisms in the 5'-flanking region of the HLA-DQA1 gene.

The HLA-DQA1 gene exhibits haplotype-specific restriction fragment polymorphisms due to DNA rearrangements. We found that some of these polymorphisms extend into the 5' flanking region of the gene and are distinct from other HLA-DQA1 related DNA polymorphisms so far reported. Sequencing of genomic DNA subclones derived from the 5' flanking region of HLA-DQA1 showed the presence, in a DR4 haplotype, of two repetitive elements of the Alu family, oriented in opposite directions and bracketing an approximately 3 kilobase region immediately adjacent to the promoter of the gene. When DNAs extracted from several cell lines were analyzed by genomic hybridization using single-copy probes relative to these intervening sequences, polymorphisms were observed. No structural alterations of the gene immediately outside the DNA portion delimited by the two Alu elements were observed, thus suggesting that polymorphisms of the 5' end of HLA-DQA1 may be limited to the intervening region between the two Alu repeats. The latter includes upstream regulatory elements controlling the expression of the genes. The possibility that the structure of the DNA in this region may influence the regulation of HLA-DQA1 gene expression in different haplotypes is discussed.

Effect of the AIR-1 locus on the activation of an enhancerless HLA-DQA1 promoter.

Studies on the regulation of a major histocompatibility complex (MHC) class II gene, HLA-DQA1, in Ia-positive cells (Raji, a human B-lymphoma cell line) and in isogenic Ia-negative cells (RJ2.2.5, a mutant of Raji altered at the AIR-1 locus) are reported. As previously found, AIR-1 is required in its entirety for the activity of an enhancer factor, the absence of which abolishes transcription of MHC class II genes. In this paper, we show that HLA-DQA1 gene expression can be directed by an enhancerless promoter. The fact that this promoter is inactive in the RJ2.2.5 mutant suggests that the trans-acting element determined by the AIR-1 locus is not only an enhancer factor as previously described, but also acts at the MHC class II promoter level.

A SINE insertion provides information on the divergence of the HLA-DQA1 and HLA-DQA2 genes.

The class II region of the human major histocompatibility complex (MHC) contains a cluster of highly polymorphic genes organized into at least three subloci (DR, DQ, and DP), each encoding a subset of surface antigens participating in the modulation of the immune response. Genetic diversity in this system is brought about by two major mechanisms, hypermutation and trans-species evolution. The DQ subregion contains a pair of closely related A genes, HLA-DQA1 and HLA-DQA2, whose phylogenetic relationship is uncertain, although their generation by duplication of an ancestral A gene before or after speciation can be implied. We report here the presence of a member of the Alu repetitive family immediately 5' to the HLA-DQA1 gene. The sequence of this element indicates that it may have integrated by transposition at the time of divergence of hominoids from Old World monkeys. HLA-DQA2 carries an empty integration target site in place of the Alu, thereby suggesting that the insertion of Alu near HLA-DQA1 was preceded by the separation of the two genes.