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1	Purification and partial characterization of a peptide cross reacting with antibodies to gastric inhibitory polypeptide Otte, Susan Carol January 1984 (has links) Gel filtration coupled with radioimmunoassay of fractions has demonstrated the existence of an 8000 dalton immunoreactive form of GIP (glucose-dependent insulinotropic polypeptide or gastric inhibitory polypeptide), which may be a precursor in the biosynthetic pathway. A monoclonal antibody to GIP has been shown to have highly suitable characteristics for affinity purification of different species of IR-GIP. An enzyme-linked immunosorbent assay (ELISA) was developed for GIP, employing the monoclonal antibody and was used for screening fractions for peptides with the same antigenic determinant i.e. IR-foras of GIP. Classical strategy used in peptide purification may result in loss of related peptides if they are sensitive to the pH or temperature conditions used. Tissue from hog duodenal and jejunal mucosa was boiled and extracted into acetic acid. Peptides were then adsorbed to alginic acid, eluted with 200 mM HC1, precipitated with NaCl and desalted on Sephadex G-25. The desalted material was adjusted to pH 7.0 with 200mM ammonia and extracted with methanol. The methanol insoluble fraction demonstrated the highest content of IR-GIP₈₀₀₀⋅ The overall acidic charge on the larger IR-GIP oUUU moiety suggested the possibility that it might not be adsorbed to alginic acid. The monoclonal antibody to porcine GIP₅₀₀₀ was coupled to cyanogen bromide activated Sepharose -4B. The peptide fraction which was not adsorbed to alginic acid was applied to the column and the fraction which bound to the ligand was eluted with 100 mM HC1. The immunoreactive material was rotary evaporated to dryness and further purified to a monocomponent by HPLC. A µBondapak C₁₈ column and a linear gradient of acetonitrile in water containing 0.1% TFA was used for HPLC. Amino acid analyses revealed the following composition: Asx (6), Thr (2), Ser (3), Glx (3), Pro (3), Gly (4), Ala (8), Val (5), Met (1), He (0), Leu (7), Tyr (1), Phe (3), His (4), Lys (5), Arg (3), Trp (+). The N-terminal residue was identified as valine using the dansylation method. Cleavage of the molecule with trypsin and separation of the tryptic peptides on HPLC showed 2 peptides with elution times similar to tryptic peptides of GIP. Application of monocomponent IR-GIP designated IR-LGIP C, and GIP to the HPLC system confirmed the two peptides to be separate entities. Biological activity was assessed in the isolated perfused rat pancreas, a model used for measurement of the insulin releasing effect of GIP. IR-LGIP C did not demonstrate insulinotropic activity. It is unlikely that this polypeptide is a proform of GIP. It shares common immunoreactivity but lacks the necessary common core of amino acid residues. / Medicine, Faculty of / Cellular and Physiological Sciences, Department of / Graduate Gastrointestinal hormones Gastric Inhibitory Polypeptide
2	The role of glucose-dependent insulinotropic peptide in adipocyte. / CUHK electronic theses & dissertations collection January 2012 (has links) 糖尿病是一种呈现流行趋势的代谢紊乱综合症，现如今，全球大约有3.46亿糖尿病患者，这庞大的数字给各国的公共健康安全支出带来了严重的财政负担。其中，二型糖尿病（T2DM）占90%。其特点是周围组织的胰岛素抵抗以及后期损伤的胰岛β细胞的功能。在饮食后，小肠会分泌两种肠促胰岛素，葡萄糖依赖性促胰岛素多肽（GIP）和胰高血糖素样肽-1（GLP-1）。两种多肽的主要功能是促进餐后胰岛细胞中胰岛素的分泌，另外他们还可以通过其自身的G蛋白偶联受体，GIPR和GLP-1R发挥其他作用，如葡萄糖依赖性的刺激胰岛素的生成，刺激胰岛β细胞的增殖，抑制细胞的凋亡等。这些功能也使肠促胰岛素成为糖尿病治疗的一种手段，比如Exendin-4和DPP4抑制剂。然而，除了在胰岛中的作用，肠促胰岛还可能和脂质代谢相关，其中GIP和脂质代谢的报导研究的更加深入。在肥胖的状态下，血液中GIP含量高于正常水平；GIPR基因敲除老鼠和GIPR的抑制剂喂养的小鼠可以抵抗高脂饮食诱导的肥胖和2型糖尿病；GIP还可以直接调节脂肪细胞的脂肪生成和脂解。这些数据表明GIP在肥胖和糖尿病的发生过程中可能存在促进作用,这使得GIP治疗药物的开发需要谨慎的对待。 / 为了进一步研究GIP在脂肪细胞中发挥的生物学效应，在本研究中，我们利用腺病毒介导技术通过在脂肪细胞中过表达GIPR来增加GIP的活性，然后检查GIP在脂肪细胞中所起的作用。实验结果表明,GIP可以通过cAMP-PKA信号通路迅速并且长期的刺激脂肪细胞的炎症反应，增强IKKβ-NFκB信号通路和增加炎症基因的表达。更深入的机制研究表明，JNK 信号通路也参与GIP诱导的炎症反应，抑制JNK通路可以大部分恢复GIP增加的炎症因子的表达和IKKβ的磷酸化水平。由于长期的炎症反应，脂肪细胞的胰岛素信号通路受到GIP的损伤，在GIPR过表达的脂肪细胞中，胰岛素刺激的AKT磷酸化水平和葡萄糖吸收能力都被GIP降低，葡萄糖转运蛋白4（Glut-4）的表达水平也同时减少。因此，本研究结果表明GIP可能在肥胖的发展过程中，通过诱导脂肪细胞的炎症反应来损伤胰岛素敏感性而最终导致2型糖尿病的发生。 / Diabetes mellitus is a type of metabolic syndrome that has prevailed all over the world with the development of economic and over-nutrient lifestyle. It is estimated to 346 million diabetes patients in the worldwide most recently. The huge population put a major burden on the cost of public health care to all the countries. Among the types of diabetes, type 2 diabetes (T2DM) makes up 90% of recorded cases. The characteristics of T2DM are insulin resistance of peripheral tissues and impaired pancreatic cell function and mass. Two major incretins GIP (glucose-dependent insulinotropic peptide) and GLP-1 (glucagon-like peptide 1) are secreted from gut in response to food ingestion. The prominent role of GIP and GLP-1 is to stimulate glucose-dependent insulin release in pancreatic β cell. In addition, they both exert multiple biological effects via their relative G-protein coupled receptors, GIPR and GLP-1R, including glucose-stimulated insulin production, cell proliferation and anti-apoptosis in pancreatic β cells. The beneficent effects of incretins potentiate them as targets for the treatment of diabetes. GLP-1 analog, exendin-4 and DDP4 (dipeptidyl peptidase-4) inhibitors (to prevent GIP and GLP-1 from degradation) have been already used in clinical research. However, in addition to their effects on pancreatic β cell, both peptides are also related to lipid metabolism. The role of GIP has been studied more extensively. In obese state, the circulating level of GIP is elevated. GIPR knockout (KO) mice are resistant to high fat diet (HFD) induced obesity, a similar phenotype is found in GIPR antagonist administrated HFD-mice. Moreover, GIP also directly promotes lipogenesis and lipolysis in adipocytes. The rising evidence suggests a potential role of GIP in adipocyte biology and lipid metabolism, which diminishes the enthusiasm of GIP as a candidate therapeutic reagent for T2DM. / In order to further understand the biological effects of GIP in adipocytes, here, we over-expressed GIPR in 3T3-L1 CAR adipocytes via adenovirus-mediated gene transfer technology to enhance the activity of GIP. The results demonstrate that GIP impairs the physiological functions of adipocytes as a consequence of increasing the production of inflammatory cytokines, chemokines, and phosphorylation of IkB kinase (IKK) β through activation of the cyclic AMP-protein kinase A (cAMP-PKA) pathway. Activation of Jun N-terminal Kinase (JNK) pathway is also observed in GIP-induced inflammatory responses in adipocytes. An inhibitor of JNK blocks GIP-stimulated secretion of inflammatory cytokines and chemokines, as well as phosphorylation of IKKβ. The chronic inflammatory response eventually impairs insulin signaling in adipocytes, as demonstrated by reduction of protein kinase B (PKB/AKT) phosphorylation. The subsequently physiological analysis also indicates that GIP inhibits insulin-stimulated glucose uptake, and gene expression analysis reveals a decrease of glucose transporter 4 (Glut-4) in the meanwhile. The results suggest that GIP may be one of stimuli attributable to obesity induced insulin resistance via induction of adipocyte inflammation. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Nie, Yaohui. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2012. / Includes bibliographical references (leaves 95-111). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese. / Abstract --- p.i / 摘要 --- p.iii / Acknowledgements --- p.v / INTRODUCTION --- p.1 / Chapter Part 1 --- Obesity and Type 2 diabetes --- p.1 / Chapter 1.1 --- Introduction to diabetes --- p.1 / Chapter 1.1.2 --- Physiology of adipocyte --- p.4 / Chapter 1.1.3 --- Mechanism of obesity induced diabetes --- p.10 / Chapter Part 2 --- Incretins and T2DM --- p.12 / Chapter 2.1 --- History of incretins --- p.12 / Chapter 2.2 --- Physiological actions of incretins --- p.14 / Chapter 2.3 --- Molecular mechanism of incretin actions in pancreas --- p.16 / Chapter 2.4 --- Incretins and T2DM --- p.19 / Chapter Part 3 --- Incretins and lipid metabolism --- p.23 / Objective --- p.26 / Methods and materials --- p.28 / Chapter 1 --- Cell culture --- p.28 / Chapter 1.1 --- 3T3-L1 culture and differentiation --- p.28 / Chapter 1.2 --- 3T3-L1 CAR culture and differentiation --- p.29 / Chapter 2 --- Cloning and recombinant adenovirus construction --- p.30 / Chapter 2.1 --- Plasmid construct --- p.30 / Chapter 2.2 --- Construct of recombinant adenoviruses --- p.30 / Chapter 2.3 --- Generation and infection of the adenoviruses --- p.31 / Chapter 3 --- Physiological and morphological assays --- p.32 / Chapter 3.1 --- Lipolysis assay --- p.32 / Chapter 3.2 --- TUNEL assay --- p.32 / Chapter 3.3 --- Glucose uptake --- p.33 / Chapter 3.4 --- Glut-4 localization --- p.33 / Chapter 4 --- Gene expression analysis --- p.35 / Chapter 4.1 --- Quantitative real-time PCR --- p.35 / Chapter 4.2 --- Immunoblot analysis --- p.35 / Chapter 4.3 --- ELISA assay --- p.36 / Chapter 5 --- Isolation of primary adipocytes --- p.37 / Results --- p.38 / Chapter Part 1 --- Role of GIP in 3T3-L1 cells --- p.38 / Chapter 1.1 --- Differentiation of 3T3-L1 adipocytes --- p.38 / Chapter 1.2 --- GIP slightly stimulates phosphorylation of p-CREB and lipolysis in 3T3-L1 cells. --- p.40 / Chapter 1.3 --- Analysis of gene expression in GIP-treated adipocytes --- p.42 / Chapter 1.4 --- Discussion --- p.44 / Chapter Part 2 --- Role of GIP in GIPR over-expressing 3T3-L1 CAR adipocytes --- p.46 / Chapter 2.1 --- Differentiation of 3T3-L1 CAR adipocytes --- p.46 / Chapter 2.2 --- Functional tests in GIPR over-expressing 3T3-L1 CAR adipocytes. --- p.48 / Chapter 2.3 --- Effect of GIP on cell viability --- p.50 / Chapter 2.4 --- Analysis of gene expression in GIP-treated adipocytes --- p.52 / Chapter 2.5 --- GIP activates inflammatory responses in GIPR over-expressing adipocytes --- p.54 / Chapter 2.6 --- Inhibition of IKKb pathway restores GIP-induced inflammatory responses --- p.56 / Chapter 2.7 --- Effects of GIP on adipocytes are partially dependent on the cAMP-PKA pathway --- p.58 / Chapter 2.8 --- Activation of cAMP-PKA pathway induces adipocyte inflammation. --- p.60 / Chapter 2.9 --- cAMP-Epac pathway is not involved in GIP-induced inflammation --- p.62 / Chapter 2.10 --- GIP stimulates cell stress activated kinases --- p.64 / Chapter 2.11 --- JNK partially mediates GIP-induced adipocyte inflammation --- p.65 / Chapter 2.12 --- Inhibition of JNK pathway partially restores GIP-induced inflammatory responses --- p.67 / Chapter 2.13 --- GIP impairs insulin signaling in GIPR over-expressing 3T3-L1 CAR adipocytes via inducing inflammatory response --- p.69 / Chapter 2.14 --- GIP enhances basal glucose uptake but impairs insulin stimulated glucose uptake in 3T3-L1 CAR GIPR over-expressing adipocytes --- p.71 / Chapter 2.15 --- Discussion --- p.73 / Chapter Part 3 --- Role of GIP in primary adipocytes --- p.78 / Chapter 3.1 --- GIPR expression level in primary adipocytes --- p.78 / Chapter 3.2 --- Analysis of gene expression in primary adipocytes after GIP treatment --- p.80 / Chapter 3.3 --- Discussion --- p.81 / SUMMARY --- p.82 / Chapter Future investigation --- p.83 / Chapter Appendix 1: --- Abbreviations --- p.86 / Chapter Appendix 2: --- Protocols --- p.90 / Preparation of competent cells --- p.90 / Outlines of recombinant adenovirus preparation --- p.91 / Virus titering (TCID50) --- p.92 / Primers for real-time PCR --- p.93 / Chapter Publications and Scientfic activities --- p.94 / Thesis related publication: --- p.94 / Other pubiliations: --- p.94 / Scientific activities: --- p.94 / References --- p.95 Gastrointestinal hormones Insulin Fat cells Gastric Inhibitory Polypeptide Insulin Adipocytes
3	Intestinal peptides and ethnic differences in insulin secretion Higgins, Paul B. January 2006 (has links) (PDF) Thesis (Ph. D.)--University of Alabama at Birmingham, 2006. / Title from first page of PDF file (viewed Feb. 22, 2007). Includes bibliographical references (p. 92-107).
4	The study of humoral inhibition of gastric acid secretion Meloche, Robert Mark January 1985 (has links) Part I Inhibition of Gastric Acid Secretion Fat in the small bowel is a powerful inhibitor of gastric acid secretion. The gastric inhibitory agent(s) liberated from intestinal mucosa by the presence of fat has been named enterogastrone. Gastric inhibitory polypeptide (GIP), has been considered a candidate for enterogastrone. GIP is released into the circulation by infusion of fat into the proximal small bowel and inhibits gastric acid secretion under select experimental conditions. It has been proposed that the release of somatostatin, a potent inhibitor of acid secretion, may mediate the gastric inhibitory action of GIP. Recently, monoclonal antibodies raised to both GIP and somatostatin have been produced. The suitability of these antibodies for the study of the physiological roles proposed for their respective peptides is not known. This study examined the inhibitory action of GIP and somatostatin on gastric acid secretion in the rat and in man. GIP was found to be a weak inhibitor of meal-stimulated gastric acid secretion in man when given in supraphysiological doses. When administered at a dose which produces less than the normal maximal physiological plasma level, GIP had little effect on the acid secretory response to the meal and no effect on either plasma gastrin or plasma SLI concentrations. In the rat, infusion of GIP produced a 60% reduction of meal-stimulated acid secretion, independent of changes in serum gastrin release. Intraduodenal infusion of oleic acid in the rat reduced the gastric acid secretory response to a liver extract meal by 80% without affecting serum gastrin levels. A humoral gastric inhibitory agent, or "enterogastrone", was demonstrated in the portal blood of the rat following fat infusion. Intravenous infusion of portal serum, which had been collected during an intraduodenal infusion of fat, reduced meal-stimulated acid secretion in a second animal. A comparison of the inhibition of gastric acid secretion produced by intraduodenal infusion of either glucose or oleic acid with the release of IR-GIP in the portal serum was performed. The inhibitory effect of an intraduodenal fat infusion could not be explained by plasma IR-GIP. The release of GIP was not found to play a significant role in the mechanism for gastric inhibition by intestinal fat. Part II Monoclonal antibodies as Probes of Humoral Inhibitors of Gastric acid secretion The ability of recently produced monoclonal antibodies to block in vivo the inhibitory action of exogenous GIP and somatostatin on gastric acid secretion was examined. Anti-GIP monoclonal antibody demonstrated a high affinity for GIP when compared to the polyclonal rabbit antiserum R07 in the ELISA. When administered either as an intravenous bolus, or after incubation with GIP for 1 hour at 37°C, the antibody was unable to block the inhibitory effect of a GIP infusion on meal-stimulated gastric acid secretion in the rat. Monoclonal antibody 3.65H may not be suitable for the study of the role of endogenously released GIP. Two anti-somatostatin monoclonal antibody clones 58 and 510, when given as intravenous boluses, blocked the inhibitory action of exogenous somatostatin on meal-stimulated gastric acid secretion in the rat. The antibody clone S10 however, had no effect on the inhibitory action of exogenous GIP on gastric acid secretion. Although both monoclonal antibodies S8 and SIO effectively prevented the gastric inhibitory effect of infused somatostatin, the ability to block the physiological action of endogenously released gastric somatostatin remains to be determined. / Surgery, Department of / Medicine, Faculty of / Graduate Peptide hormones Gastric juice - Secretion Gastric Inhibitory Polypeptide Gastric Acid - secretion
5	Medium-chain triglyceride diet stimulates less GIP secretion and suppresses body weight and fat mass gain compared with long-chain triglyceride diet / 中鎖脂肪酸トリグリセリド食は長鎖脂肪酸トリグリセリド食と比較してGIP分泌刺激が少なく体重や体脂肪量の増加を抑制する Murata, Yuki 23 March 2020 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22321号 / 医博第4562号 / 新制\|\|医\|\|1041(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授川上浩司, 教授浅野雅秀, 教授岩田想 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM Medium-chain trglyceride Long-chain triglyceride Incretin Gastric inhibitory polypeptide Obesity 490
6	Estudo da expressão dos receptores do peptídeo insulinotrópico dependente de glicose (GIPR) e do hormônio luteinizante (LHCGR) em tumores e hiperplasias do córtex adrenal / Expression Study of Glucose-dependent insulinotropic peptide receptor (GIPR) and luteinizing hormone receptor (LHCGR) in adrenocortical tumors and hyperplasia Costa, Marcia Helena Soares 16 July 2007 (has links) Introdução: Os receptores do peptídeo insulinotrópico dependente de glicose (GIPR) e do hormônio luteinizante (LHCGR) são receptores acoplados à proteína G com amplo padrão de expressão tecidual. A expressão anômala destes receptores tem sido descrita em casos de hiperplasia adrenal macronodular independente de ACTH (AIMAH) e em alguns adenomas, resultando em aumento da secreção hormonal (cortisol, andrógenos e aldosterona) pelo cortex adrenal. O papel destes receptores em outras formas de hiperplasia, como a doença adrenocortical nodular pigmentosa primária (PPNAD), aumento da adrenal associado à neoplasia endócrina múltipla tipo 1 (MEN1), e em carcinoma do córtex adrenal tem sido pouco investigado; sendo assim, considera-se relevante estudar a expressão destes receptores nos pacientes com tumores adrenocorticais esporádicos, nos pacientes com AIMAH, PPNAD e aumento adrenal associado à MEN1. Objetivos: 1) Caracterização molecular dos casos de neoplasia endócrina múltipla tipo 1 e PPNAD: pesquisa de mutações dos genes MEN1 e PRKAR1A e análise da perda de heterozigose (LOH) destes genes no tecido adrenal destes pacientes. 2) Quantificar a expressão do GIPR e do LHCGR em tecido adrenocortical normal, tumoral, hiperplásico e correlacionar a expressão destes com a classificação histológica dos tumores adrenocorticais. Pacientes: 55 pacientes (30 adultos) com tumores adrenocorticais (37 adenomas e 18 carcinomas); 7 pacientes com AIMAH, 4 com MEN1, 1 com PPNAD e tecidos controles (adrenal; testículo e pâncreas). Métodos: extração de DNA genômico, RNA e síntese de DNA complementar (cDNA); amplificação por PCR das regiões codificadoras dos genes MEN1 e PRKAR1A seguida por seqüenciamento automático. Pesquisa de LOH pela amplificação de microssatélites por PCR e análise pelo programa GeneScan. Quantificação da expressão do GIPR e do LHCGR por PCR em tempo real pelo método TaqMan e estudo de imunohistoquímica para GIPR nos tumores adrenocorticais. Resultados: identificação de 3 mutações (893+ 1G>A, W183X e A68fsX118) e dois polimorfirmos (S145S e D418D) no gene MEN1 e uma mutação (Y21X) no PRKAR1A. Ausência de LOH nos tecidos adrenais estudados. A expressão do GIPR e do LHCGR foi identificada em tecidos adrenais normais, tumorais e hiperplásicos. O nível de expressão do GIPR foi mais elevado nos tumores adrenocorticais malignos que nos benignos tanto no grupo pediátrico (mediana= 18,1 e 4,6, respectivamente; p <0,05), quanto no grupo adulto (mediana = 4,8 e 1,3 respectivamente; p <0,001). O nível de expressão do LHCGR, no grupo pediátrico, foi elevado tanto nos tumores benignos quanto nos malignos (mediana= 6,4 e 4,3, respectivamente). No grupo adulto os níveis de expressão deste receptor foram extremamente baixos nos tumores malignos em relação aos benignos (mediana= 0,06 e 2,3, respectivamente; p <0,001). A imunohistoquímica para o GIPR foi variável e não correlacionada à expressão do gene GIPR. Não houve diferença nos níveis de expressão do GIPR e do LHCGR nas hiperplasias do córtex adrenal. Conclusões: a presença de LOH e mutação em heterozigose composta do gene MEN1 e do PRKAR1A foram afastadas como mecanismos responsáveis pelo aumento adrenal tanto nos pacientes com MEN1 como no paciente com PPNAD. A hiperexpressão de GIPR está associada a malignidade nos tumores adrenocorticais nos grupos adulto e pediátrico e a baixa expressão de LHCGR está associada a malignidade nos tumores adrenocorticais somente no grupo adulto. / Introduction: The glucose- dependent insulinotropic peptide receptor (GIPR) and luteinizing hormone receptor (LHCGR) are G-protein coupled receptors with a wide tissue expression pattern. The aberrant expression of these receptors has been described in cases of ACTH-independent macronodular adrenal hyperplasia (AIMAH) and in some adenomas, resulting in the increase of adrenal cortex hormonal secretion (cortisol, androgens and aldosterone). The role of these receptors in other forms of adrenocortical hyperplasia, such as primary pigmented nodular adrenocortical disease (PPNAD), adrenal enlargement associated with multiple endocrine neoplasia type 1 (MEN1), and adrenocortical carcinoma has been scarcely investigated. Thus, the study of the expression of these receptors in patients with sporadical adrenocortical tumors, AIMAH, PPNAD and adrenal enlargement associated to MEN1 was considered important. Objectives: 1) Molecular study in patients with multiple endocrine neoplasia type 1 and PPNAD: mutation screening of MEN1 and PRKAR1A genes and analysis of the loss of heterozygosis (LOH) of these genes in the adrenal lesions of these patients. 2) To quantify the GIPR and LHCGR expression, in normal, tumor and hyperplasic tissue and to correlate the expression of these receptors with the adrenocortical tumor histology. Patients: 55 patients (30 adults) with adrenocortical tumors (37 adenomas and 18 carcinomas); 7 patients with AIMAH, 4 with MEN1, 1 with PPNAD and control tissue (adrenal, testis and pancreas). Methods: Extraction of genomic DNA, RNA and synthesis of complementary DNA (cDNA); PCR-amplification of the coding regions of MEN1 and PRKAR1A, followed by direct sequencing. LOH study using polymorphic marker amplification by PCR and GeneScan software analysis. Quantification of GIPR and LHCGR expression using realtime PCR -TaqMan method and GIPR immunohistochemistry study in adrenocortical tumors. Results: Identification of 3 mutations (893+ 1G>A, W183X and A68fsX118) and two polymorphic alterations (S145S and D418D) in MEN1 and a mutation (Y21X) in the PRKAR1A gene; LOH was not identified in adrenal tissue. The GIPR and LHCGR expression was identified in normal, tumor and hyperplasic adrenal tissues; the GIPR expression level was more elevated in malignant tumors compared to benign tumors in pediatric (median = 18.1 and 4.6, respectively; p <0.05) and adult patients (median = 4.8 and 1.3 respectively; p <0.001). The LHCGR expression in pediatric patients was elevated in benign as well as in malignant tumors (median = 6.4 and 4.3, respectively). In the adult group, the expression level of these receptors was extremely low in malignant tumors in relation to benign ones (median = 0.06 and 2.3, respectively; p <0.001). The GIPR immunohistochemistry was variable and did not correlate with GIPR gene expression. No difference between GIPR and LHCGR expression levels was observed in the different forms of hyperplasia. Conclusions: The presence of LOH and mutations in compound heterozygosis of MEN1 and PRKAR1A genes were ruled out as the mechanisms responsible for the adrenal enlargement in patients with multiple endocrine neoplasia type 1. GIPR overexpression is associated with malignant adrenocortical tumors in the adult and pediatric patients and low LHCGR expression is associated with malignant adrenocortical tumors only in the adult patients. Adrenal cortex neoplasms Adrenocortical hyperfunction Expressão gênica Gastric inhibitory polypeptide Gene expression Genetic mutation Hiperfunção adrenocortical Immunohistochemistry. Imunohistoquímica. LH receptor Loss of heterozygosity Multiple endocrine neoplasia Mutação gênica Neoplasia endócrina múltipla Neoplasias do córtex supra-renal Peptide receptors Perda de heterozigosidade Polipeptídeo inibidor gástrico Polymerase chain reaction Reação de polimerização em cadeia Receptores de peptídeo Receptores do LH
7	Estudo da expressão dos receptores do peptídeo insulinotrópico dependente de glicose (GIPR) e do hormônio luteinizante (LHCGR) em tumores e hiperplasias do córtex adrenal / Expression Study of Glucose-dependent insulinotropic peptide receptor (GIPR) and luteinizing hormone receptor (LHCGR) in adrenocortical tumors and hyperplasia Marcia Helena Soares Costa 16 July 2007 (has links) Introdução: Os receptores do peptídeo insulinotrópico dependente de glicose (GIPR) e do hormônio luteinizante (LHCGR) são receptores acoplados à proteína G com amplo padrão de expressão tecidual. A expressão anômala destes receptores tem sido descrita em casos de hiperplasia adrenal macronodular independente de ACTH (AIMAH) e em alguns adenomas, resultando em aumento da secreção hormonal (cortisol, andrógenos e aldosterona) pelo cortex adrenal. O papel destes receptores em outras formas de hiperplasia, como a doença adrenocortical nodular pigmentosa primária (PPNAD), aumento da adrenal associado à neoplasia endócrina múltipla tipo 1 (MEN1), e em carcinoma do córtex adrenal tem sido pouco investigado; sendo assim, considera-se relevante estudar a expressão destes receptores nos pacientes com tumores adrenocorticais esporádicos, nos pacientes com AIMAH, PPNAD e aumento adrenal associado à MEN1. Objetivos: 1) Caracterização molecular dos casos de neoplasia endócrina múltipla tipo 1 e PPNAD: pesquisa de mutações dos genes MEN1 e PRKAR1A e análise da perda de heterozigose (LOH) destes genes no tecido adrenal destes pacientes. 2) Quantificar a expressão do GIPR e do LHCGR em tecido adrenocortical normal, tumoral, hiperplásico e correlacionar a expressão destes com a classificação histológica dos tumores adrenocorticais. Pacientes: 55 pacientes (30 adultos) com tumores adrenocorticais (37 adenomas e 18 carcinomas); 7 pacientes com AIMAH, 4 com MEN1, 1 com PPNAD e tecidos controles (adrenal; testículo e pâncreas). Métodos: extração de DNA genômico, RNA e síntese de DNA complementar (cDNA); amplificação por PCR das regiões codificadoras dos genes MEN1 e PRKAR1A seguida por seqüenciamento automático. Pesquisa de LOH pela amplificação de microssatélites por PCR e análise pelo programa GeneScan. Quantificação da expressão do GIPR e do LHCGR por PCR em tempo real pelo método TaqMan e estudo de imunohistoquímica para GIPR nos tumores adrenocorticais. Resultados: identificação de 3 mutações (893+ 1G>A, W183X e A68fsX118) e dois polimorfirmos (S145S e D418D) no gene MEN1 e uma mutação (Y21X) no PRKAR1A. Ausência de LOH nos tecidos adrenais estudados. A expressão do GIPR e do LHCGR foi identificada em tecidos adrenais normais, tumorais e hiperplásicos. O nível de expressão do GIPR foi mais elevado nos tumores adrenocorticais malignos que nos benignos tanto no grupo pediátrico (mediana= 18,1 e 4,6, respectivamente; p <0,05), quanto no grupo adulto (mediana = 4,8 e 1,3 respectivamente; p <0,001). O nível de expressão do LHCGR, no grupo pediátrico, foi elevado tanto nos tumores benignos quanto nos malignos (mediana= 6,4 e 4,3, respectivamente). No grupo adulto os níveis de expressão deste receptor foram extremamente baixos nos tumores malignos em relação aos benignos (mediana= 0,06 e 2,3, respectivamente; p <0,001). A imunohistoquímica para o GIPR foi variável e não correlacionada à expressão do gene GIPR. Não houve diferença nos níveis de expressão do GIPR e do LHCGR nas hiperplasias do córtex adrenal. Conclusões: a presença de LOH e mutação em heterozigose composta do gene MEN1 e do PRKAR1A foram afastadas como mecanismos responsáveis pelo aumento adrenal tanto nos pacientes com MEN1 como no paciente com PPNAD. A hiperexpressão de GIPR está associada a malignidade nos tumores adrenocorticais nos grupos adulto e pediátrico e a baixa expressão de LHCGR está associada a malignidade nos tumores adrenocorticais somente no grupo adulto. / Introduction: The glucose- dependent insulinotropic peptide receptor (GIPR) and luteinizing hormone receptor (LHCGR) are G-protein coupled receptors with a wide tissue expression pattern. The aberrant expression of these receptors has been described in cases of ACTH-independent macronodular adrenal hyperplasia (AIMAH) and in some adenomas, resulting in the increase of adrenal cortex hormonal secretion (cortisol, androgens and aldosterone). The role of these receptors in other forms of adrenocortical hyperplasia, such as primary pigmented nodular adrenocortical disease (PPNAD), adrenal enlargement associated with multiple endocrine neoplasia type 1 (MEN1), and adrenocortical carcinoma has been scarcely investigated. Thus, the study of the expression of these receptors in patients with sporadical adrenocortical tumors, AIMAH, PPNAD and adrenal enlargement associated to MEN1 was considered important. Objectives: 1) Molecular study in patients with multiple endocrine neoplasia type 1 and PPNAD: mutation screening of MEN1 and PRKAR1A genes and analysis of the loss of heterozygosis (LOH) of these genes in the adrenal lesions of these patients. 2) To quantify the GIPR and LHCGR expression, in normal, tumor and hyperplasic tissue and to correlate the expression of these receptors with the adrenocortical tumor histology. Patients: 55 patients (30 adults) with adrenocortical tumors (37 adenomas and 18 carcinomas); 7 patients with AIMAH, 4 with MEN1, 1 with PPNAD and control tissue (adrenal, testis and pancreas). Methods: Extraction of genomic DNA, RNA and synthesis of complementary DNA (cDNA); PCR-amplification of the coding regions of MEN1 and PRKAR1A, followed by direct sequencing. LOH study using polymorphic marker amplification by PCR and GeneScan software analysis. Quantification of GIPR and LHCGR expression using realtime PCR -TaqMan method and GIPR immunohistochemistry study in adrenocortical tumors. Results: Identification of 3 mutations (893+ 1G>A, W183X and A68fsX118) and two polymorphic alterations (S145S and D418D) in MEN1 and a mutation (Y21X) in the PRKAR1A gene; LOH was not identified in adrenal tissue. The GIPR and LHCGR expression was identified in normal, tumor and hyperplasic adrenal tissues; the GIPR expression level was more elevated in malignant tumors compared to benign tumors in pediatric (median = 18.1 and 4.6, respectively; p <0.05) and adult patients (median = 4.8 and 1.3 respectively; p <0.001). The LHCGR expression in pediatric patients was elevated in benign as well as in malignant tumors (median = 6.4 and 4.3, respectively). In the adult group, the expression level of these receptors was extremely low in malignant tumors in relation to benign ones (median = 0.06 and 2.3, respectively; p <0.001). The GIPR immunohistochemistry was variable and did not correlate with GIPR gene expression. No difference between GIPR and LHCGR expression levels was observed in the different forms of hyperplasia. Conclusions: The presence of LOH and mutations in compound heterozygosis of MEN1 and PRKAR1A genes were ruled out as the mechanisms responsible for the adrenal enlargement in patients with multiple endocrine neoplasia type 1. GIPR overexpression is associated with malignant adrenocortical tumors in the adult and pediatric patients and low LHCGR expression is associated with malignant adrenocortical tumors only in the adult patients. Expressão gênica Hiperfunção adrenocortical Imunohistoquímica. Mutação gênica Neoplasia endócrina múltipla Neoplasias do córtex supra-renal Perda de heterozigosidade Polipeptídeo inibidor gástrico Reação de polimerização em cadeia Receptores de peptídeo Receptores do LH Adrenal cortex neoplasms Adrenocortical hyperfunction Gastric inhibitory polypeptide Gene expression Genetic mutation Immunohistochemistry. LH receptor Loss of heterozygosity Multiple endocrine neoplasia Peptide receptors Polymerase chain reaction

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