The ghrelin receptor or growth hormone secretagogue receptor (GHSR) is a G-protein-coupled receptor that controls growth hormone and insulin secretion, food intake, and reward-seeking behaviors. Liver-expressed antimicrobial peptide 2 (LEAP2) was recently described as an endogenous antagonist of GHSR. Here, we present a study aimed at delineating the structural determinants required for LEAP2 activity toward GHSR. We demonstrate that the entire sequence of LEAP2 is not necessary for its actions. Indeed, the N-terminal part alone confers receptor binding and activity to LEAP2. We found that both LEAP2 and its N-terminal part behave as inverse agonists of GHSR and as competitive antagonists of ghrelin-induced inositol phosphate production and calcium mobilization. Accordingly, the N-terminal region of LEAP2 is able to inhibit ghrelin-induced food intake in mice. These data demonstrate an unexpected pharmacological activity for LEAP2 that is likely to have an important role in the control of ghrelin response under normal and pathological conditions.
Evidence is presented showing that a neuronal isoform of nitric oxide synthase (NOS) is expressed in rat pancreatic islets and INS-1 cells. Sequencing of the coding region indicated a 99.8% homology with rat neuronal NOS (nNOS) with four mutations, three of them resulting in modifications of the amino acid sequence. Doubleimmunofluorescence studies demonstrated the presence of nNOS in insulin-secreting -cells. Electron microscopy studies showed that nNOS was mainly localized in insulin secretory granules and to a lesser extent in the mitochondria and the nucleus. We also studied the mechanism involved in the dysfunction of the -cell response to arginine and glucose after nNOS blockade with N Gnitro-L-arginine methyl ester. Our data show that miconazole, an inhibitor of nNOS cytochrome c reductase activity, either alone for the experiments with arginine or combined with sodium nitroprusside for glucose, is able to restore normal secretory patterns in response to the two secretagogues. Furthermore, these results were corroborated by the demonstration of a direct enzymesubstrate interaction between nNOS and cytochrome c, which is strongly reinforced in the presence of the NOS inhibitor. Thus, we provide immunochemical and pharmacological evidence that -cell nNOS exerts, like brain nNOS, two catalytic activities: a nitric oxide production and an NOS nonoxidating reductase activity, both of which are essential for normal -cell function. In conclusion, we suggest that an imbalance between these activities might be implicated in -cell dysregulation involved in certain pathological hyperinsulinic states. T he short-lived free radical gas nitric oxide (NO) is synthesized from L-arginine by a family of enzymes known as NO synthases (NOSs). Three NOS isoenzymes, encoded by three separate genes, have been described, including the Ca 2ϩ /calmodulin-dependent and constitutively expressed neuronal NOS (nNOS) and endothelial NOS (eNOS) enzymes and a calmodulin-independent cytokine-inducible NOS (iNOS) enzyme found in various cell types (rev. in 1). The small amounts of NO, produced by the constitutive forms in response to increases in intracellular calcium, play a crucial role in a number of physiological functions, including neurotransmission (2), vascular tone (3) and platelet aggregation (4), whereas the large amounts, produced by iNOS in a calcium-independent manner over prolonged periods of time, are implicated in pathological functions, such as cytotoxicity of activated macrophages (5).Even though the inducible isoform has been cloned in insulin-producing cells after induction by cytokines (6), it is unclear whether pancreatic -cells express a constitutive NOS. Both NADPH-diaphorase (NADPH-d) histochemical staining previously shown to be specific for NOS (7) and immunohistochemical studies using various nNOS antisera yielded apparently conflicting data. Positive NADPH-d and immunoreactive nNOS stainings have been found to be colocalized in most pancreatic endocrine cells (8), a finding not confirmed in other studies...
Human anti-thyroid peroxidase (TPO) autoantibodies (aAb) are generated during autoimmune thyroid diseases (AITD). Within recent years, increasing knowledge of the TPO-specific aAb repertoire, gained mainly by the use of combinatorial library methodology, has led to the cloning and sequencing of around 180 human anti-TPO aAb. Analysis of the immunoglobulin (Ig) variable (V) genes encoding the TPO aAb in the ImMunoGeneTics database (IMGT) (http://imgt.cines.fr) reveals major features of the TPO-directed aAb repertoire during AITD. Heavy chain VH domains of TPO-specific aAb from Graves' disease patients preferentially use D proximal IGHV1 genes, whereas those from Hashimoto's thyroiditis are characterized more frequently by IGHV3 genes, mainly located in the middle of the IGH locus. A large proportion of the anti-TPO heavy chain VH domains is obtained following a VDJ recombination process that uses inverted D genes. J distal IGKV1 and IGLV1 genes are predominantly used in TPO aAb. In contrast to the numerous somatic hypermutations in the TPO-specific heavy chains, there is only limited amino acid replacement in most of the TPO-specific light chains, particularly in those encoded by J proximal IGLV or IGKV genes, suggesting that a defect in receptor editing can occur during aAb generation in AITD. Among the predominant IGHV1 or IGKV1 TPO aAb, conserved somatic mutations are the hallmark of the TPO aAb repertoire. The aim of this review is to provide new insights into aAb generation against TPO, a major autoantigen involved in AITD.
These results demonstrate that anti-TPO aAbs can damage cultured thyroid cells by ADCC and CDC mechanisms. The monocytes, via their FcgammaRI, are important effector cells in ADCC mediated by anti-TPO aAbs and may contribute with T cells to the destruction of thyroid gland in AITD.
Localization of the Discontinuous Immunodominant Region Recognized by Human Anti-thyroperoxidase Autoantibodies in Autoimmune Thyroid Diseases
The discontinuous immunodominant region (IDR) recognized by autoantibodies directed against the thyroperoxidase (TPO) molecule, a major autoantigen in autoimmune thyroid diseases, has not yet been completely localized. By using peptide phage-displayed technology, we identified three critical motifs, LXPEXD, QSYP, and EX(E/D)PPV, within selected mimotopes which interacted with the human recombinant anti-TPO autoantibody (aAb) T13, derived from an antibody phage-displayed library obtained from thyroid-infiltrating TPO-selected B cells of Graves' disease patients. Mimotope sequence alignment on the TPO molecule, together with the binding analysis of the T13 aAb on TPO mutants expressed by Chinese hamster ovary cells, demonstrated that regions 353-363, 377-386, and 713-720 from the myeloperoxidase-like domain and region 766 -775 from the complement control protein-like domain are a part of the IDR recognized by the recombinant aAb T13. Furthermore, we demonstrated that these regions were involved in the binding to TPO of sera containing TPO-specific autoantibodies from patients suffering from Hashimoto's and Graves' autoimmune diseases. Identification of the IDR could lead to improved diagnosis of thyroid autoimmune diseases by engineering "mini-TPO" as a target autoantigen or designing therapeutic peptides able to block undesired autoimmune responses.Human thyroid peroxidase (TPO), 1 described previously as the "thyroid microsomal antigen" (1), is a membrane-bound enzyme expressed at the apical pole of thyrocytes (2). TPO generates the functional form of thyroglobulin by iodination and coupling of tyrosine residues (3). During autoimmune thyroid diseases (AITD), TPO represents a major target for the immune system (4, 5), leading to high titer TPO-specific autoantibodies (aAbs) in the sera of patients suffering from Hashimoto's thyroiditis and Graves' disease. Besides their role as efficient and early diagnostic markers of AITD, TPO-specific aAbs also act as effector molecules either through modulating antigen presentation to T cells or by mediating thyroid destruction after complement activation or antibody-dependent cell cytotoxicity (6 -12). Alignment studies and structural homologies have shown that TPO is formed by three distinct domains: a myeloperoxidase (MPO)-like, a complement control protein (CCP)-like, and an EGF-like domain, from the N-to the Cterminal extremities (13). Although the structure of each domain has been elucidated in part by three-dimensional modeling (13-16), the full three-dimensional structure of TPO remains unknown, even though low resolution crystals have been obtained (17,18). The flexibility observed for the hinge regions probably make difficult the exact positioning of each domain in relation to the others (15).These observations denote a highly complex structure of TPO, thus explaining the reason why TPO aAbs from patients' sera preferentially recognize discontinuous epitopes on . Different approaches have been used to determine the epitopic regions recognized by anti-TPO aAbs from ...
Autoimmune thyroid diseases: genetic susceptibility of thyroid‐specific genes and thyroid autoantigens contributions
Autoimmune thyroid diseases are common polygenic multifactorial disorders with the environment contributing importantly to the emergence of the disease phenotype. Some of the disease manifestations, such as severe thyroid-associated ophthalmopathy, pretibial myxedema and thyroid antigen/antibody immune complex nephritis are unusual to rare. The spectrum of autoimmune thyroid diseases includes: Graves' disease (GD), Hashimoto's thyroiditis (HT), atrophic autoimmune thyroiditis, postpartum thyroiditis, painless thyroiditis unrelated to pregnancy and thyroid-associated ophthalmopathy. This spectrum present contrasts in terms of thyroid function, disease duration and spread to other anatomic location. The genetic basis of autoimmune thyroid disease (AITD) is complex and likely to be due to genes of both large and small effects. In GD the autoimmune process results in the production of thyroid-stimulating antibodies and lead to hyperthyroidism, whereas in HT the end result is destruction of thyroid cells and hypothyroidism. Recent studies in the field of autoimmune thyroid diseases have largely focused on (i) the genes involved in immune response and/or thyroid physiology with could influence susceptibility to disease, (ii) the delineation of B-cell autoepitopes recognized by the main autoantigens, thyroglobulin, thyroperoxidase and TSH receptor, to improve our understanding of how these molecules are seen by the immune system and (iii) the regulatory network controlling the synthesis of thyroid hormones and its dysfunction in AITD. The aim of the present review is to summarize the current knowledge regarding the relation existing between some susceptibility genes, autoantigens and dysfunction of thyroid function during AITD.
In an attempt to explore the natural variable heavy and light chain (VH/VL) pairing of autoantibodies involved in Graves’ disease, we constructed a phage-displayed Ab library obtained by in-cell PCR of thyroid-infiltrating cells. We report here the molecular cloning and characterization of human single-chain fragment variable regions (scFv) specific for thyroid peroxidase (TPO) generated from this library. On the basis of the nucleotide sequences, three different scFvs were obtained (ICA1, ICB7, and ICA5). All were encoded by genes derived from the VH1 and Vλ1 gene families. Using BIACORE for epitope mapping and kinetic analysis, we showed that these scFvs exhibited high affinity (Kd = 1 nM) for TPO and recognized three different epitopes. The biological relevance of these scFvs as compared with serum anti-TPO autoantibodies was assessed by competition studies. Sera from all the 29 Graves’ disease patients tested were able to strongly inhibit (60–100%) the binding of the 3 scFvs to TPO. These data demonstrate that the in-cell PCR library generated human anti-TPO scFvs that retained the VH/VL pairing found in vivo and that the different epitope specificities defined by these scFvs overlapped with those found in the sera of patients with autoimmune thyroid disease.
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