No full-text available
To read the full-text of this research,
you can request a copy directly from the authors.
Identification of antigenic domains on the human sodium-iodide symporter which are recognized by autoantibodies from patients with autoimmune thyroid disease
Abstract
The sodium-iodide symporter (NIS) is a novel autoantigen in autoimmune thyroid disease. In the present study we have characterized the antigenic domains on the human symporter which are recognized by autoantibodies from patients with either Graves' disease (GD) or autoimmune hypothyroidism (AH). Deletion derivatives of complementary DNA (cDNA) encoding the Na(+)/I(-) symporter were constructed using polymerase chain reaction (PCR) amplification. These deletion constructs were translated in vitro with the concomitant incorporation of [(35)S]methionine into the protein products. The reactivity of seven GD and six AH sera, which were known to contain symporter-binding antibodies, to each of the radiolabelled modified symporters was then determined in immunoprecipitation experiments. Analyses of the results obtained in the radiobinding assays suggest the existence of multiple antibody binding sites on human NIS (hNIS), including regions between amino acids (aa) 1--134, 191--286, 290--411, 411--520 and 520--588. Computer prediction of the potential B cell epitopes on the symporter revealed that, apart from aa 134--191, all the epitope domains identified overlapped, at least in part, with areas predicted to be highly antigenic. Interestingly, the antigenic domains represented by aa 191--286, 290--411 and 411--520 include regions of the polypeptide which form putative extracellular domains in the secondary structure model of the rat symporter. No correlation between the recognition of specific epitopes on the human symporter and the type of autoimmune thyroid disease was demonstrated.
... Using deletion derivatives of NIS cDNA, which were in vitro translated in the presence of [ 35 S]methionine and immunoprecipitated with seven Graves' disease and six Hashimoto's thyroiditis sera, that tested positive for NIS-binding antibodies, several antibody binding sites of the hNIS protein could be identified (amino acids 1-134, 191-286, 290 -411, 411-520 and 520 -588). No correlation between specific epitopes on the hNIS protein and the type of autoimmune thyroid disease was demonstrated (Kemp et al., 2001). ...
The sodium iodide symporter (NIS) is an intrinsic plasma membrane protein that mediates the active transport of iodide in the thyroid gland and a number of extrathyroidal tissues, in particular lactating mammary gland. Because of its crucial role in the ability of thyroid follicular cells to trap iodide, cloning of NIS opened an exciting and extensive new field of thyroid-related research. Cloning and molecular characterization of NIS allowed investigation of its expression and regulation in thyroidal and nonthyroidal tissues, and its potential pathophysiological and therapeutic implications in benign and malignant thyroid disease. In addition to its key function in thyroid physiology, NIS-mediated iodide accumulation allows diagnostic thyroid scintigraphy as well as effective therapeutic application of radioiodine in benign and malignant thyroid disease. Characterization and application of NIS as a novel therapeutic gene and the presence of high native NIS expression in the majority of breast cancers further suggest a promising role of NIS in diagnosis and therapy of cancer outside the thyroid gland.
... With the exception of the main thyroid autoantigens such as thyroglobulin and thyroid peroxidase, the NIS is considered to be the next autoantigen in patients with AITD (D' Herbomez and Wemeau 2001). Multiple antibody binding sites on human NIS was recently identified ( Kemp et al. 2001). Although the clinical utility of NIS autoantibody determination is not yet proved, antibodies to NIS were found in 22-24 % of the patients with GD and AIT (Heufelder et al. 2001). ...
The aim of the study was to compare the prevalence of autoimmune thyroid diseases in three groups of women (66 with breast cancer (CaB), 68 with colorectal cancer (CaC) and 49 without oncological diseases as a control group). Serum levels of thyroid-stimulating hormone (TSH), free thyroxin (fT4), antibodies to thyroglobulin (TGB-ab) and thyroperoxidase (TPO-ab) and tumor markers CEA, CA 15-3 and CA 19-9 were investigated in all subjects by using the chemiluminiscence method. In contrast to Graves' disease (no observed case), autoimmune thyroiditis was diagnosed in 24.2 % women with CaB (4.5 % euthyroid and 19.7 % with subclinical or overt hypothyroidism), compared to 16.7 % in women with CaC (2.0 % euthyroid and 14.7 % with subclinical or overt hypothyroidism) and 16.2 % controls (4.0 % euthyroid and 12.2 % with subclinical or overt hypothyroidism). Serum levels of TGB-ab were higher in the group with breast cancer as compared to those with colorectal cancer and the control group (medians: 35.80 vs. 31.75 vs. 27.70, p<0.001). Similarly, the percentage of positive TGB-ab and TPO-ab serum levels was higher in women with breast cancer as compared to those with colorectal cancer and the control group. The results of the study support the controversial theory that there is an increased prevalence of autoimmune thyroiditis in women with breast cancer.
... Current computational predictions of B-cell epitopes should be taken with extreme caution. On the other hand, B-cell epitope mapping brings important knowledge about the pathogenesis of autoimmunity and computational approaches have been used in the study of pathogenic autoantigens such as citrate synthase [94], human desmoglein-3 [95], human sodium-iodide symporter [96], human transaldolase [97], and a panel of autoantigens implicated in autoimmune diabetes [98]. ...
Recent years have witnessed an explosive growth in available biological data pertaining to autoimmunity research. This includes a tremendous quantity of sequence data (biological structures, genetic and physical maps, pathways, etc.) generated by genome and proteome projects plus extensive clinical and epidemiological data. Autoimmunity research stands to greatly benefit from this data so long as appropriate strategies are available to enable full access to and utilization of this data. The quantity and complexity of this biological data necessitates use of advanced bioinformatics strategies for its efficient retrieval, analysis and interpretation. Major progress has been made in development of specialized tools for storage, analysis and modeling of immunological data, and this has led to development of a whole new field know as immunoinformatics. With advances in novel high-throughput immunology technologies immunoinformatics is transforming understanding of how the immune system functions. This paper reviews advances in the field of immunoinformatics pertinent to autoimmunity research including databases, tools in genomics and proteomics, tools for study of B- and T-cell epitopes, integrative approaches, and web servers.
The autoimmune thyroid diseases (AITD), Graves' disease (GD) and Hashimoto's thyroiditis (HT) are most common endocrine disorders in humans. Both disorders are characterized by lymphocytic infiltration of the thyroid gland and the production of autoantibodies (aAb) against proteins that are thyroid-specific or expressed predominantly in the thyroid. The three main autoantigens are thyroperoxidase (TPO), thyroglobulin (Tg), and thyrotropin hormone receptor. Recently, the thyroidal iodide transporters Na+/I- symporter (NIS) and pendrin have also been identified as novel antigens in AITD. TPO-aAb and Tg-aAb are hallmarks of AITD, whereas the pathological and clinical relevance of NIS and pendrin aAb are still uncertain. To gain a greater understanding of the pathogenic mechanism(s) of autoimmune thyroid diseases at the molecular level, further characterisation of the autoantigens is required in order to shed light on why and how these molecules are seen by the immune system. This review summarizes current knowledge regarding the patho-physiological function and immunogenic response to the proteins TPO, Tg, NIS, and pendrin.
There is a large and increasing number of therapeutic proteins approved for clinical use and many more undergoing preclinical studies and clinical trials in humans. Most of them are human or 'humanized' recombinant molecules. Virtually all therapeutic proteins elicit some level of antibody response, which in some cases, can lead to potentially serious side effects. Therefore, immunogenicity of therapeutic proteins is a concern for clinicians, manufacturers and regulatory agencies. In order to assess immunogenicity of these molecules, appropriate detection, quantitation and characterization of antibody responses are necessary. Immune responses to therapeutic proteins in conventional animal models has not been, except in rare cases, predictive of the response in humans. In recent years there has been a considerable progress in development of computational methods for prediction of epitopes in protein molecules that have the potential to induce an immune response in a recipient. Initial attempts to apply such tools in early development of therapeutic proteins have already been reported. It is expected that computer driven prediction followed by in vitro and/or in vivo testing of any potentially immunogenic epitopes will help in avoiding, or at least minimizing, immune responses to therapeutic proteins.
The Na(+)/I(-) symporter (NIS) is an integral plasma membrane glycoprotein that mediates active I(-) transport into the thyroid follicular cells, the first step in thyroid hormone biosynthesis. NIS-mediated thyroidal I(-) transport from the bloodstream to the colloid is a vectorial process made possible by the selective targeting of NIS to the basolateral membrane. NIS also mediates active I(-) transport in other tissues, including salivary glands, gastric mucosa, and lactating mammary gland, in which it translocates I(-) into the milk for thyroid hormone biosynthesis by the nursing newborn. NIS provides the basis for the effective diagnostic and therapeutic management of thyroid cancer and its metastases with radioiodide. NIS research has proceeded at an astounding pace after the 1996 isolation of the rat NIS cDNA, comprising the elucidation of NIS secondary structure and topology, biogenesis and posttranslational modifications, transcriptional and posttranscriptional regulation, electrophysiological analysis, isolation of the human NIS cDNA, and determination of the human NIS genomic organization. Clinically related topics include the analysis of congenital I(-) transport defect-causing NIS mutations and the role of NIS in thyroid cancer. NIS has been transduced into various kinds of cancer cells to render them susceptible to destruction with radioiodide. Most dramatically, the discovery of endogenous NIS expression in more than 80% of human breast cancer samples has raised the possibility that radioiodide may be a valuable novel tool in breast cancer diagnosis and treatment.
Graves' ophthalmopathy (GO) affects 50% to 60% of patients with Graves' hyperthyroidism, resulting in exophthalmos, periorbital edema, pain, double vision, optic neuropathy, and loss of vision. Fibroblasts are a key autoimmune target in GO and have effector functions that contribute to GO-associated pathologic conditions, including proliferation, production of excess glycosaminoglycans, and fat deposition. GO is also characterized by autoimmune inflammation of orbital connective tissue with mononuclear cell infiltration, including T cells.
To determine whether autologous T cells can drive proliferation of orbital fibroblasts and thus contribute to GO, a novel reverse autologous mixed-cell reaction (rAMCR) was performed. Fibroblasts cultured from orbital tissue of patients with GO that was removed during orbital decompression surgery were mixed with autologous T cells, and fibroblast proliferation was determined.
Autologous T cells stimulated proliferation of orbital fibroblasts. Fibroblasts derived from blepharoplasty fat of two different patients did not proliferate, demonstrating that the effect is specific to cells derived from deep orbital fat. Proliferation was dependent on cell contact and on major histocompatibility complex (MHC) class II and CD40-CD154 (CD40 ligand) signaling.
The results suggest that T cells and orbital fibroblasts participate in an antigen-dependent positive feedback loop in which presentation of autoantigens by fibroblasts via MHC class II and CD40-CD40L signaling results in T-cell activation. These activated T cells stimulate fibroblast proliferation, leading to fibroblast-associated diseases in GO. Thus, therapies that interfere with CD40-CD40L signaling, antigen expression by fibroblasts, or T-cell function may be effective in preventing progression of GO symptoms.
We previously reported that the spirochete Borrelia burgdorferi could trigger autoimmune thyroid diseases (AITD). Subsequently, we showed local amino acid sequence homology between all human thyroid autoantigens (human thyrotropin receptor [hTSH-R], human thyroglobulin [hTg], human thyroperoxidase [hTPO], human sodium iodide symporter [hNIS]) and Borrelia proteins (n = 6,606), and between hTSH-R and Yersinia enterocolitica (n = 1,153). We have now updated our search of homology with Borrelia (n = 11,198 proteins) and extended our search on Yersinia to the entire species (n = 40,964 proteins). We also searched the homologous human and microbial sequences for peptide-binding motifs of HLA-DR molecules, because a number of these class II major histocompatibility complex (MHC) molecules (DR3, DR4, DR5, DR8, and DR9) are associated with AITD. Significant homologies were found for only 16 Borrelia proteins (5 with hTSH-R, 2 with hTg, 3 with hTPO, and 6 with hNIS) and only 19 Yersinia proteins (4 with hTSH-R, 2 with hTg, 2 with hTPO, and 11 with hNIS). Noteworthy, segments of thyroid autoantigens homologous to these microbial proteins are known to be autoantigenic. Also, the hTSH-R homologous region of one Borrelia protein (OspA) contains an immunodominant epitope that others have found to be homologous to hLFA-1. This is of interest, as the hLFA-1/ICAM-1 ligand/receptor pair is aberrantly expressed in the follicular cells of thyroids affected by Hashimoto's thyroiditis. A computer-assisted search detected antigenic peptide binding motifs to the DR molecules implicated in AITD. In conclusion, our in silico data do not directly demonstrate that Borrelia and Yersinia proteins trigger AITD but suggest that a restricted number of them might have the potential to, at least in persons with certain HLA-DR alleles.
Monoclonal antibody (MAbs) is a powerful and essential tool to perform studies concerning antigens and antibodies at molecular level. MAbs to major thyroid specific autoantigens, thyroglobulin (Tg), thyroid peroxidase (TPO) and TSH receptor (TSHR), have been prepared and applied for a variety of investigations including the structure of antigens and antibodies, the expression of antigens, the epitopes of antibodies, the functional regions of antigens, mutated antigens in congenital diseases, and clinical applications to diagnosis of various thyroid diseases. Recently, sodium iodide symporter (NIS) was identified and became a potential thyroid autoantigen related to autoimmune thyroid disease, although few MAbs to NIS have been prepared. In this manuscript, I primarily focus on studies concerning MAbs to three major thyroid specific autoantigens, Tg, TPO and TSHR, and summarize studies using the mAbs.
The Na+/I−symporter (NIS), a 618-amino acid membrane glycoprotein that catalyzes the active accumulation of I− into thyroid cells, was identified and characterized at the molecular level in our laboratory (Dai, G., Levy, O., and Carrasco,
N. (1996) Nature 379, 458–460). Because mature NIS is highly glycosylated, it migrates in SDS-polyacrylamide gel electrophoresis as a broad
polypeptide of higher molecular mass (∼90–110 kDa) than nonglycosylated NIS (∼50 kDa). Using site-directed mutagenesis, we
substituted both separately and simultaneously the asparagine residues in all three putativeN-linked glycosylation consensus sequences of NIS with glutamine and assessed the effects of the mutations on function and
stability of NIS in COS cells. All mutants were active and displayed 50–90% of wild-type NIS activity, including the completely
nonglycosylated triple mutant. This demonstrates that to a considerable extent, function and stability of NIS are preserved
in the partial or even total absence of N-linked glycosylation. We also found that Asn225 is glycosylated, thus proving that the hydrophilic loop that contains this amino acid residue faces the extracellular milieu
rather than the cytosol as previously suggested. We demonstrated that the NH2 terminus faces extracellularly as well. A new secondary structure model consistent with these findings is proposed.
The transport of iodide into the thyroid, catalyzed by the Na+/I- symporter (NIS), is the initial and rate-limiting step in the formation of thyroid hormones. To study the basic characteristics of the human (h) NIS, we have established a Chinese hamster ovary cell line stably expressing the hNIS (CHO-NIS9). In agreement with previous work on the rat NIS, iodide uptake in these cells was initiated within 2 min of the addition of 131I, reaching a plateau after 30 min. Both perchlorate and thiocyanate inhibited iodide uptake in a dose-dependent manner, with inhibition evident at concentrations of 0.01 and 0.1 micromol/L, respectively, and reaching complete inhibition at 20 micromol/L and 500 micromol/L, respectively. Ouabain, which blocks the activity of the Na+/K+ adenosine triphosphatase, also inhibited iodide uptake in a dose-dependent manner, starting at concentrations of 100 micromol/L and reaching maximum inhibition at 1600 micromol/L, indicating that iodide uptake in these cells is sodium dependent. CHO-NIS9 cells were further used to study 88 sera from patients with Graves' disease, for iodide uptake inhibitory activity, which were compared with sera from 31 controls. Significant iodide uptake inhibition was taken as any inhibition in excess of the mean + 3 SD of the results with the control sera. On this basis, 27 (30.7%) of the Graves' sera, but none of the controls, inhibited iodide uptake in CHO-NIS9. IgGs from these patients also inhibited iodide uptake, indicating that this inhibitory activity was antibody mediated. In summary, we have established a CHO cell line stably expressing the hNIS and shown that antibodies in GD sera can inhibit iodide uptake in these cells. This further emphasizes the role of NIS as a novel autoantigen in thyroid immunity.
Melanocytes preferentially express an mRNA species, Pmel 17, whose protein product cross-reacts with anti-tyrosinase antibodies and whose expression correlates with the melanin content. We have now analyzed the deduced protein structure and mapped its chromosomal location in mouse and human. The amino acid sequence deduced from the nucleotide sequence of the Pmel 17 cDNA showed that the protein is composed of 645 amino acids with a molecular weight of 68,600. The Pmel 17 protein contains a putative leader sequence and a potential membrane anchor segment, which indicates that this may be a membrane-associated protein in melanocytes. The deduced protein contains five potential N-glycosylation sites and relatively high levels of serine and threonine. Three repeats of a 26-amino acid motif appear in the middle of the molecule. The human Pmel 17 gene, designated D12S53E, maps to chromosome 12, region 12pter-q21; and the mouse homologue, designated D12S53Eh, maps to the distal region of mouse chromosome 10, a region also known to carry the coat color locus si (silver).
Autoreactive islet cell Abs (ICA) accompany the pathogenic destruction of pancreatic beta cells in insulin-dependent diabetes mellitus (IDDM). Human monoclonal ICA (MICA 1-6), previously derived from a DR1/DR7-positive newly diagnosed diabetic patient, recognized the islet cell autoantigen glutamate decarboxylase 65 (GAD65) and defined two distinct conformational (MICA 1/3 and MICA 4/6) and one linear (MICA 2) autoimmune epitopes in this molecule. We have isolated 4 new ICA-reactive B cell lines, one from a DR4/DR11-positive newly diagnosed IDDM patient (MICA 7) and three from a DR3 homozygous patient with both IDDM and Graves' disease (MICA 8-10). Like MICA 1-6, MICA 7-10 are specific for GAD65, suggesting that GAD65-reactive B cells dominate the ICA response in IDDM. Comparative analysis of MICA 1-6 and MICA 7-10, using GAD65 mutants and blocking experiments, showed that MICA 7-10 define three novel conformational autoimmune epitopes in GAD65. Further structural analysis of the MICA 1-10 epitopes revealed two distinct and one overlapping region of epitope clusters. Thus, the C-terminal region, defined by amino acids 450 to 570, harbors the conformational MICA1/3 and MICA 7 epitopes as well as the linear epitope of MICA 2 (amino acids 506-531). The MICA 4/6 and MICA 10 epitopes are located in the middle region of the molecule defined by amino acids 245 to 449, whereas the N-terminal region contributes only to the MICA 8/9 epitopes (encompassed in amino acids 39-585). MICA 1-6, 7, and 8-10, derived from three IDDM patients of different HLA haplotypes, define six different epitopes in GAD65 and represent tools to determine the spectrum, possible HLA association, and temporal order of epitope recognition in IDDM.
GAD65 autoantibodies (GAD65Ab) are important markers for type 1 (insulin-dependent) diabetes mellitus. Although most patients have GAD65Ab at the time of clinical diagnosis, there are also GAD65Ab-positive individuals in the population at low risk of developing type 1 diabetes. The aim of this study was to test the hypothesis that the GAD65Ab reactivity to GAD65 cloned from human, mouse, and rat in newly diagnosed type 1 diabetic patients differ from antibody-positive healthy individuals. Sera from 254 new-onset 0- to 34-yr-old type 1 diabetic patients and 270 controls were assayed for their reactivity to human, mouse, and rat GAD65. Among the type 1 diabetic patients there was a significant better binding of human GAD65 compared to either mouse (P = 0.03) or rat GAD65 (P = 0.0005). The preference for human GAD65 increased with increasing age at onset (P = 0.0002). This differentiation was not observed in 88 GAD65Ab-positive control subjects. Our data indicate that recognition of epitopes by GAD65Ab in type 1 diabetes is different from that in nontype 1 diabetes, GAD65Ab-positive individuals.
Graves' disease is characterized by the presence of autoantibodies to the thyrotropin receptor (TSHR), which are pathogenic and responsible for disease activity. It is well recognized that the autoantibodies are heterogeneous and recognize a number of different conformational dependent epitopes on the TSHR. In this study, we have extended our previous observations to study the interaction of Graves' disease autoantibodies with TSHR ectodomain produced by in vitro transcription and translation reaction. The specific activity of the translated TSHR ectodomain has been increased by a log fold by adding an efficient ribosome binding Kozak sequence before the translation initiation codon as well as double labelling with 35S-methionine and 35S-cysteine during the translation reaction. Addition of canine pancreatic microsomes to the translation mix showed that the glycosylation of TSHR ectodomain did not occur efficiently for the nascent receptor protein. In order to determine the specificity and sensitivity of the improved assay with nonglycosylated TSHR ectodomain, we have studied 331 sera from Graves' disease patients and as controls 100 sera from patients with nonthyroid autoimmune disorders as well as sera from 200 normal control subjects with no family history of thyroid autoimmunity. With this large cohort of sera from Graves' disease and control individuals, 25% of Graves' disease sera immunoprecipitated the dual labeled, in vitro transcribed and translated TSHR ectodomain, exceeding the 98th percentile of the control sera. There was no correlation between the autoantibodies that immunoprecipitate the in vitro translated TSHR ectodomain and those that inhibit iodinated TSH binding in the radioreceptor assay and those with biological activity in a bioassay. The data are consistent with the finding that a proportion of Graves' disease autoantibodies can interact directly with TSHR ectodomain produced by in vitro transcription and translation. However, in contrast to the wide use of similar translation and immunoprecipitation assays to measure other autoantibodies for the diagnosis of autoimmune disorders, such as type 1 diabetes, the TSHR immunoprecipitation on its own is unsuitable for diagnosis of Graves' disease.
The sodium iodide symporter (NIS) is a novel autoantigen in autoimmune thyroid disease (ATD). A recent study has described the development of a bioassay for human (h) NIS antibody detection, but this will not detect antibodies that bind the symporter without modulating its activity. Therefore, the establishment of a binding assay is of importance to determine the overall prevalence of hNIS antibodies in ATD patients. An in vitro transcription and translation system was used to produce [35S]-labeled hNIS. The radiolabeled ligand reacted specifically in immunoprecipitation experiments with rabbit antiserum raised against a peptide fragment of hNIS. Subsequently, the reactivity of control and ATD sera to translated [35S]hNIS was determined using RIAs.
A significant difference in the frequency of hNIS antibody-positive sera was found when patients with either Graves’ disease (GD) or autoimmune hypothyroidism (AH) were compared with normal controls (P = 0.01 and P = 0.03, respectively). Of 49 GD and 29 AH sera tested, 11 (22%) and 7 (24%), respectively, were found to contain hNIS antibodies. Differences were also significant when the antibody-binding indices of the control group of sera were compared with those of both the GD and the AH patient sera (P < 0.0001 and P = 0.001, respectively). In contrast, sera from 10 patients with Addison’s disease and 10 patients with vitiligo (without associated ATD) were all negative for antibody reactivity to the symporter. No differences were detected when the antibody binding indices of either the Addison’s disease or the vitiligo sera were compared with those of the normal sera group (P = 0.9 and P = 0.6, respectively).
Eight of the 11 (73%) GD and 3 of the 7 (43%) AH sera, which were positive for hNIS antibodies in the immunoprecipitation assay, were also found to inhibit iodide uptake in hNIS-transfected CHO-K1 cells, suggesting the existence of antibodies in some serum samples that bind to the symporter without modulating its function. Overall, a significant correlation was found between the iodide uptake inhibition and the binding assays for hNIS antibody detection (r = 0.49, P < 0.0001).
In summary, we have developed a specific and quantitative assay for the detection of hNIS binding antibodies in sera of patients with ATD. This system offers the advantage of studying antibody reactivity against conformational epitopes and will be useful in understanding the role of NIS autoreactivity in the pathogenesis of ATD.
A protein determination method which involves the binding of Coomassie Brilliant Blue G-250 to protein is described. The binding of the dye to protein causes a shift in the absorption maximum of the dye from 465 to 595 nm, and it is the increase in absorption at 595 nm which is monitored. This assay is very reproducible and rapid with the dye binding process virtually complete in approximately 2 min with good color stability for 1 hr. There is little or no interference from cations such as sodium or potassium nor from carbohydrates such as sucrose. A small amount of color is developed in the presence of strongly alkaline buffering agents, but the assay may be run accurately by the use of proper buffer controls. The only components found to give excessive interfering color in the assay are relatively large amounts of detergents such as sodium dodecyl sulfate, Triton X-100, and commercial glassware detergents. Interference by small amounts of detergent may be eliminated by the use of proper controls.
The iodide concentrating activity of the thyroid gland is essential to the production of thyroid hormone and also provides a mechanism for the treatment of thyroid cancer by radioiodine ablation. We report here the nucleotide and amino acid sequence of the human sodium iodide symporter (hNIS), which mediates the iodide uptake activity in the thyroid gland. An open reading frame of 1929 nucleotides encodes a protein of 643 amino acids with 84% identity to the rat NIS (rNIS). Transient expression of the hNIS cDNA conferred perchlorate-sensitive iodide uptake to a nonthyroid cell line, COS-7. The expression of hNIS was detected at variable levels in papillary thyroid carcinoma tissues but not in any of the thyroid carcinoma cell lines that have lost the iodide uptake activity.
Iodide is concentrated to a much lesser extent by papillary thyroid carcinoma as compared with the normal gland. The Na+/I- symporter (NIS) is primarily responsible for the uptake of iodide into thyroid cells. Our objective was to compare NIS mRNA and protein expression in papillary carcinomas with those in specimens with normal thyroid. Northern blot analysis revealed a 2.8-fold increase in the level of NIS mRNA in specimens with papillary carcinoma versus specimens with normal thyroid. Immunoblot analysis using anti-human NIS antibody that was produced with a glutathione S-transferase fusion protein containing NIS protein (amino acids 466-522) showed the NIS protein at 77 kD. The NIS protein level was elevated in 7 of 17 cases of papillary carcinoma but was not elevated in the normal thyroid. Immunohistochemical staining revealed abundant NIS in 8 of 12 carcinomas, whereas NIS protein was barely detected in specimens with normal thyroid. Although considerable patient-to-patient variation was observed, our results indicate that NIS mRNA is elevated, and its protein tends to be more abundant, in a subset of papillary thyroid carcinomas than in normal thyroid tissue.
A protein determination method which involves the binding of Coomassie Brilliant Blue G-250 to protein is described. The binding of the dye to protein causes a shift in the absorption maximum of the dye from 465 to 595 nm, and it is the increase in absorption at 595 nm which is monitored. This assay is very reproducible and rapid with the dye binding process virtually complete in approximately 2 min with good color stability for 1 hr. There is little or no interference from cations such as sodium or potassium nor from carbohydrates such as sucrose. A small amount of color is developed in the presence of strongly alkaline buffering agents, but the assay may be run accurately by the use of proper buffer controls. The only components found to give excessive interfering color in the assay are relatively large amounts of detergents such as sodium dodecyl sulfate, Triton X-100, and commercial glassware detergents. Interference by small amounts of detergent may be eliminated by the use of proper controls.
Microsomal antigen is often recognized by the sera from patients with autoimmune thyroid disease (AITD). Human thyroid peroxidase (hTPO) is the main component of this antigen. In a previous study, we expressed hTPO cDNA as fusion proteins in prokaryotic vector; we thereby defined seven antigenic peptides by using two rabbit polyclonal anti-hTPO antibodies. In the present study we used the seven epitopes and three widened peptides to define the reactivity pattern of 61 sera from patients with AITD. Thirty-eight of them reacted against at least one of the seven hTPO-restricted epitopes; 14 were negative against the seven determinants but recognized one or two of the extended peptides. Thus, the antibody response against hTPO appeared to be highly heterogeneous in AITD patient sera. Moreover, we demonstrated that the immunodetection of the hTPO on Western blotting with deoxycholate solubilized microsomes can be perfectly correlated with the recognition of one of the epitopes in the region 554-735.
Five synthetic peptides corresponding to the N-, the C- and a central domain in 60-kD SSA/Ro protein were prepared and tested with sera from 112 patients with systemic lupus erythematosus (SLE), 55 with primary Sjögren's syndrome (pSS) and 29 with rheumatoid arthritis. Among these five fragments, one representing residues 21-41, was recognized by antibodies in 57% of pSS patients. Interestingly, this peptide was recognized by only a few (less than or equal to 7%) of SLE sera, while 63% of pSS sera and 46% of SLE sera tested in parallel possessed antibodies reacting in ELISA with purified 60-kD SSA protein. The ELISA results were compared with the pattern of reactivity obtained in immunodiffusion and immunoblotting. The results indicate that the sensitivity of ELISA using peptide 21-41 and pSS sera was in the same range as immunoblotting and higher than immunodiffusion. Thus the peptide 21-41 proved useful for the detection of anti-SSA antibodies in the sera of patients with pSS. Furthermore, a positive ELISA using peptide 21-41 could be of potential use to discriminate pSS with systemic features from SLE. The fact that peptide 21-41 is recognized by antibodies in pSS but only by very few SLE sera implies that different mechanisms are involved in the anti-SSA immune response in these two autoimmune diseases.
It is important to remember that the merits of the different approaches to epitope mapping should be judged against the purpose of the study. A peptide specifically recognized by nearly all sera containing a certain autoimmune specificity [20, 21, 26], would most likely be selected for the detection of the anti-linear/continuous epitope fraction among those autoantibodies and could be highly useful for diagnostic purposes. This is true even if a majority of the antibodies were directed against conformational/discontinuous protein epitopes. If the purpose is to study the induction or maintenance of the autoimmune response, one would also have to look at and account for the conformation-dependent autoantibodies. There is also the possibility that some pathogenic autoantibodies could constitute a small fraction requiring the complete nucleic acid-protein complex as an antigen. In that case, the ‘pathogenic’ epitope would not be identified nor mapped using the techniques discussed in this review.
A new set of hydrophilicity high-performance liquid chromatography (HPLC) parameters is presented. These parameters were derived from the retention times of 20 model synthetic peptides, Ac-Gly-X-X-(Leu)3-(Lys)2-amide, where X was substituted with the 20 amino acids found in proteins. Since hydrophilicity parameters have been used extensively in algorithms to predict which amino acid residues are antigenic, we have compared the profiles generated by our new set of hydrophilic HPLC parameters on the same scale as nine other sets of parameters. Generally, it was found that the HPLC parameters obtained in this study correlated best with antigenicity. In addition, it was shown that a combination of the three best parameters for predicting antigenicity further improved the predictions. These predicted surface sites or, in other words, the hydrophilic, accessible, or mobile regions were then correlated to the known antigenic sites from immunological studies and accessible sites determined by X-ray crystallographic data for several proteins.
The revolution in molecular techniques has allowed dissection of the autoimmune response in a way impossible to imagine 10 yr ago. There have been spectacular advances in our understanding of self-tolerance mechanisms and how these may fail, combined with a detailed comprehension of antigen presentation, functional T cell subsets, and TCR utilization in autoimmunity, albeit usually in animal models that resemble, but do not exactly duplicate, human diseases. More gradually, these findings are being translated to thyroid autoimmunity, where the major achievement of the last decade has been the molecular characterization of the three main thyroid autoantigens. This in turn has allowed epitope identification, although again the only clear data so far have come from animal models of EAT. Another advance has been the recognition that the thyrocyte is not a helpless target of autoaggression, being capable of expressing a wide array of immunologically active molecules, which may exacerbate or diminish the autoimmune response. In 1983, there was considerable excitement at the discovery of the first of these phenomena, namely MHC class II expression, but its possible role in autoantigen presentation remains to be defined. By analogy with pancreatic beta-cells, and based on our own data, we believe that class II-expressing thyrocytes have little, if any, such role and suspect that instead this may be a mechanism for inducing peripheral tolerance. Defining the contribution of thyrocytes to the intrathyroidal autoimmune response, whether from released cytokines or surface-bound molecules, will be crucial to our future understanding, as well as holding the promise that these thyroid-derived products might be therapeutic targets. Despite molecular developments in HLA analysis, there have been no really major improvements in our understanding of the immunogenetics of thyroid autoimmunity, equivalent to those made in type 1 diabetes mellitus. The available data suggest strongly that non-MHC genes play an important role in susceptibility, and novel approaches will be required to identify these. On the other hand, we know more about the importance of environmental and endogenous (most probably hormonal) factors in thyroid autoimmunity. Understanding the basic immunological changes in the postpartum period is still poor, however, as most studies to date have concentrated on epidemiology and clinical delineation. As PPTD undergoes spontaneous remission, elucidation of these mechanisms has clear implications for treatment.(ABSTRACT TRUNCATED AT 400 WORDS)
Human steroid 21-hydroxylase (21-OH) expressed in an in vitro translation system was found to react specifically with adrenal autoantibodies from patients with Addison's disease. The epitopes on 21-OH which reacted with autoantibodies were studied by incorporating a series of terminal and internal deletions into the 21-OH gene and analysing the expressed proteins by Western blotting. N-Terminal deletions up to amino acid 280 had no effect on autoantibody binding whereas a series of C-terminal deletions and truncations (amino acids 281-494) showed marked effects. Our results indicate that a central segment (281-379) and a C-terminal segment (380-494) of 21-OH interact to form at least one major autoantibody binding site.
Glutamic acid decarboxylase (GAD) is an autoantigen in two autoimmune diseases, insulin-dependent diabetes mellitus (IDDM) and stiff-man syndrome (SMS). However, most individuals with one of these diseases do not have the other disease. Prior studies have suggested that the natures of the GAD Abs associated with each of these diseases are different, which may have implications for the autoimmune pathogenesis. We have compared the GAD autoantibody profile and have mapped GAD protein epitope regions in the two diseases using an immunoprecipitation assay with recombinant GAD 65 and GAD 67 proteins, GAD protein fragments, and synthetic GAD peptides, as well as chimeric GAD proteins. Our results indicate that individuals with SMS have GAD Abs in 100- to 500-fold higher titer than individuals with IDDM. The population of GAD Abs in SMS sera is quite complex and includes those that recognize at least three GAD 65 epitope regions located between amino acids 1-16, 188-442, and 442-563. These types of GAD Abs are not found in IDDM sera. All SMS sera also had Ab specificity that binds GAD 67 in a region highly homologous to amino acids 188-442 of GAD 65. In contrast to prior studies that used immunoblotting to measure GAD Abs, we find GAD Abs in SMS sera also target two conformation-dependent regions of GAD 65, one located in the middle and one near the C-terminus of the protein. These two regions of the GAD 65 protein are similar to regions targeted by GAD 65-specific Abs found in individuals with IDDM. These results indicate that although disease-specific epitopes may exist, there is also overlap in the humoral response between the two diseases.
Iodide (I-) is an essential constituent of the thyroid hormones T3 and T4, and is accumulated by the thyroid. The transport of iodide, the first step in thyroid hormogenesis, is catalysed by the Na+/I- symporter, an intrinsic membrane protein that is crucial for the evaluation, diagnosis and treatment of thyroid disorders. Although several other important thyroid proteins involved in hormogenesis have been characterized, the Na+/I- symporter has not. Here we report the isolation of a complementary DNA clone that encodes this symporter, as a result of functional screening of a cDNA library from a rat thyroid-derived cell line (FRTL-5) in Xenopus laevis oocytes. Oocyte microinjection of an RNA transcript made in vitro from this cDNA clone elicited a more than 700-fold increase in perchlorate-sensitive Na+/I- symport activity over background. To our knowledge, this is the first iodide-transporting molecule to have its cDNA cloned, providing a missing link in the thyroid hormone biosynthetic pathway.
Using recombinant rat Na+/I- symporter (NaIS) protein, we have immunochemically searched for the autoantibody in the sera from patients with autoimmune thyroid disease. We found that 22 out of 26 sera (84%) from patients with Graves' disease and 3 out of 20 sera (15%) from patients with Hashimoto's thyroiditis recognized it. By Western blot, these IgGs reacted with 80 kDa protein in FRTL-5 cell membrane, which co-migrated with the band stained by rabbit antibody toward NaIS. These results indicate that autoantibody against NaIS, newly identified antibody, frequently exists in patients with autoimmune thyroid disease, especially in Graves' disease.
Recently we have newly identified an autoantibody against thyroid iodide transporter (TIT) in the sera from patients with autoimmune thyroid disease. In order to study the function of these autoantibodies, we established CHO-KI cells stably expressing recombinant rat TIT (CHO-TIT cells), and the effect of IgGs from the patients with Hashimoto's thyroiditis on iodide uptake activity of CHO-TIT cells was investigated. We found that 4 out of 34 sera from patients with Hashimoto's thyroiditis strongly recognized TIT by Western blot analysis. These 4 IgGs, purified by protein A column chromatography, caused 14 to 62% inhibition of I- accumulation in CHO-TIT cells. Next, using synthetic peptides, we determined the recognition site of the autoantibody on the TIT molecule. The autoantibody reacted with the synthetic peptide corresponding to the 6th extracellular loop of the TIT molecule. These results suggest that autoantibody against TIT in the sera from patients with Hashimoto's thyroiditis binds to the 6th extracellular loop of TIT protein and inhibits I- transport into the thyrocytes. Anti-TIT autoantibody might participate in the pathogenesis of Hashimoto's thyroiditis and modulate thyroid function of patients with the disease.
The ability to transport and concentrate iodide, a fundamental property of normally functioning thyroid epithelial cells, represents a key step in the production of the iodine-containing thyroid hormones. Iodide uptake across the basolateral membrane of thyroid follicular cells is made possible by the Na˛/Iπ symporter (NIS), an active co-transport mechanism that is driven by an inwardly directed Na˛ gradient. In addition to providing a mechanism for several diagnostically useful tests such as the thyroidal radioiodine uptake test and the perchlorate discharge test, NIS-mediated active Iπ- accumulation by thyroid tissue is a crucial requirement for the success of radioactive iodine therapy. As highlighted earlier (1), cloning of the rat NIS from an FRTL-5 cell-derived cDNA library by Carrasco's group has revealed an open reading frame of 1854 nucleotides that encodes a 618 amino acid intrinsic membrane protein with 12 putative membrane-span- ning domains. This discovery has set the stage for Smanik et al. (2), who subsequently cloned the human homologue of NIS from a human thyroid cDNA library. An open reading frame (nucleotides 348-2276) of human NIS (hNIS) encodes a protein of 643 amino acids that shares 84% amino acid identity with recombinant NIS (rNIS) and has a predicted molecular mass of 68·7 kDa. Assignment of the 12 transmem- brane domains in hNIS has been based on the proposed transmembrane domains of the rNIS, in which the two protein sequences are highly conserved. Transient transfection of COS-7 cells with the hNIS cDNA clone resulted in perchlorate-sensitive iodide uptake, confirm- ing expression of functionally intact hNIS. Using reverse transcriptase-polymerase chain reaction, the authors detected hNIS expression at variable levels in papillary thyroid carcinoma tissues, but not in any of the thyroid carcinoma cell lines that lack iodide uptake activity, suggesting that loss of iodide-concentrating activity in thyroid carcinomas may be due to a loss of hNIS expression. Shortly after cloning of hNIS, Kosugi et al. (3) succeeded in establishing stable expression of recombi- nant rNIS in a Chinese hamster ovary (CHO) cell line. Subsequent analysis of its basic biochemical and electrophysiological properties, including time course, Na˛-dependency, kinetics and competitive inhibition by perchlorate and thiocynate, revealed characteristics
The recent cloning of the rat sodium-iodide symporter (rNIS) from FRTL-5 cells makes possible studies of the role of this thyroid-specific protein as an antigen in autoimmune diseases of the thyroid (AITD). We generated 21 synthetic peptides replicating the entire sequence of the extramembranous domains (ExMD) of rNIS. Each was synthesized by automated chemistry, purified by high-pressure liquid chromatography (HPLC), and characterized by mass spectroscopy. Immunoglobulins were purified using protein A from serum of 27 patients with Graves' disease (GD), 27 patients with autoimmune hypothyroidism (HT), and 20 normal controls. Binding of IgG from patients and controls to each of the rNIS peptides was measured by enzyme-linked immunosorbent assay (ELISA). Binding of patient IgG significantly greater than control was observed with six peptides: peptide 262-280 (representing ExMD 8 between transmembrane [TM] domains VII and VIII), peptide 437-444 (ExMD 11), peptides 468-487, 483-602, and 498-517 from ExMD 12, and peptides 560-579 from the proximal portion of the carboxyl terminus (ExMD 13). 63% of GD patients and 26% of HT patients immunoglobulin G (IgG) bound peptide 498-517 compared to zero controls. Similarly, 59% of GD were positive against peptide 468-487 versus zero controls. Peptide 262-280 bound IgG from 44% of GD patients, 15% of HT patients, and none of the controls. The remaining peptides showed little or no binding of patient IgG. These data indicate that patients with GD and HT possess antibodies that recognize rNIS significantly greater than do normal individuals, suggesting that the iodide transporter represents an important autoantigen in AITD. They further suggest that the incidence of the antibodies is higher in GD than HT, and that the antigenic epitopes involve ExMD 8, 11, 12, and 13.
In the present study we describe the detection of TRP-2 antibodies in vitiligo patients using in vitro 35S-labelled human TRP-2 in a radioimmunoassay. Of 53 vitiligo sera examined in the assay, three (5 9%) were found to be positive for TRP-2 antibodies. In contrast, 20 control sera, sera from 10 patients with Hashimoto's thyroiditis and sera from 10 patients with Graves' disease were all negative. All three patients positive for TRP-2 antibodies (mean age 54 years, age range 50-63 years) had had vitiligo of the symmetrical type for more than 1 year and all of them also had an associated autoimmune disorder: Graves' disease in one and autoimmune hypothyroidism in two. In addition, antibodies to the melanogenic enzyme tyrosinase were present in their serum. To examine any immunological cross-reactivity between TRP-2 and tyrosinase, the three vitiligo sera positive for TRP-2 antibodies were preabsorbed with COS-7 cell extract containing either expressed TRP-2 or tyrosinase, and subsequently used in the radioimmunoassay. These absorption studies indicated that preincubation with both proteins inhibited the immunoreactivity of the positive sera in the immunoassay using in vitro translated 35S-TRP-2. This antibody cross-reactivity suggests the humoral response to the two melanogenic enzymes in these patients may not be entirely independent.
In the present study we describe the in vitro transcription-translation of human melanocyte-specific protein Pmel17 cDNA and subsequent use of the resulting 35S-labelled Pmel17 in an RIA to analyse vitiligo sera for the presence of Pmel17 antibodies. Of 53 vitiligo sera examined in the assay, three (5.9%) were found to be positive for Pmel17 antibodies. In contrast, sera from 20 healthy controls, 10 patients with Hashimoto's thyroiditis and 10 patients with Graves' disease (GD) were all negative for Pmel17 antibodies. All three patients positive for Pmel17 antibodies (aged 50-63 years) had had vitiligo of the symmetrical type for > 1 year and all of them also had an associated autoimmune disorder: GD in one and autoimmune hypothyroidism in two. In addition, all three patients had antibodies to the melanogenic enzymes tyrosinase, tyrosinase-related protein-1 (TRP-1) and tyrosinase-related protein-2 (TRP-2) in their serum. Absorption studies indicated that preincubation with COS-7 cell extract containing expressed Pmel17 absorbed out the immunoreactivity of the three sera positive in the RIA, confirming the anti-Pmel17 reactivity of the sera from these patients. In contrast, COS-7 cell extracts containing either expressed tyrosinase, TRP-1 or TRP-2 did not remove the anti-Pmel17 reactivity of the three sera in the RIA. This lack of cross-reactivity suggests that the humoral response to Pmel17 in these patients is specific and independent of the antibody reactivity to tyrosinase, TRP-1 and TRP-2.
The identification of tyrosinase autoantibodies in some patients with vitiligo has previously been reported. In this study we have determined the B cell epitopes on tyrosinase which are recognized by these autoantibodies. Deletion derivatives of tyrosinase cDNA were constructed and then translated in vitro with the concomitant incorporation of [35S]methionine into the protein products. The 35S-labeled tyrosinase derivatives were subsequently used in radioimmunoassays to investigate the reactivity of sera from five vitiligo patients. The epitope regions identified were: three in a central region of tyrosinase (amino acids 240-255, 289-294, and 295-300) and two others towards the C-terminal end of the protein (amino acids 435-447 and 461-479). Computer analysis of the potential B cell epitopes on tyrosinase revealed that the epitope regions recognized by the vitiligo sera were located in areas predicted to be highly antigenic. In addition, the centrally located antigenic regions (amino acids 289-294 and 295-300) had amino acid sequence homology to both tyrosinase-related protein-1 and -2. Thus, the epitopes on tyrosinase recognized by vitiligo patient sera are heterogeneous and include a region with homology to two related proteins which may explain the cross-reactivity previously noted between these antigens.
Binding of IgG from patients with autoimmune thyroid disease to human sodium iodide symporter peptides: Interspecies variability in the autoimmune response to NIS
- Morris J
- Bergert E
- Bryant W
Identification of epitopes on tyrosinase which are recognised by autoantibodies from patients with vitiligo
- Eh Kemp
- Ea Waterman
- Dj Gawkrodger
- Pf Watson
- Ap Weetman
Kemp EH, Waterman EA, Gawkrodger DJ, Watson PF, Weetman AP.
Identification of epitopes on tyrosinase which are recognised by
autoantibodies from patients with vitiligo. J Invest Dermatol 1999;
113:101±5.
Cloning and characterization of the thyroid iodide transporter
- Dai
Binding of IgG from patients with autoimmune thyroid disease to human sodium iodide symporter peptides: Interspecies variability in the autoimmune response to NIS
- Morris
Identification of epitopes on tyrosinase which are recognised by autoantibodies from patients with vitiligo
- Kemp