Wnt信号通路与前体脂肪细胞

Wnt蛋白是一类分泌型蛋白生长因子,通过自分泌和旁分泌作用调节多种细胞的发生和发育.新近研究表明,Wnt信号通路在前体脂肪细胞的增殖分化中发挥着重要作用.Wnt蛋白的配基通过与细胞膜上的特异性受体Frizzled1/2/5及辅助受体LRP5/6结合,激活经典或非经典的Wnt信号通路,影响下游靶基因产物的磷酸化作用,进而抑制C/EBPα、PPARγ等脂肪细胞关键转录因子,使细胞保持未分化状态,从而抑制脂肪的形成.本文就Wnt信号通路的研究史和主要分支、作用方式及其抑制脂肪细胞的机制方面进行了综述,并对今后的研究方向和应用作了展望.     

胰高血糖素样肽-1与受体相互作用研究进展

胰高血糖素样肽-1(GLP-1)具有促胰岛素分泌、抑制胰高血糖素分泌、刺激胰岛β细胞的增殖和分化、抑制β细胞凋亡、抑制胃排空等作用,近年来成为治疗糖尿病药物研究中的热点。GLP-1与受体的相互作用一直备受关注,我们从4个方面对GLP-1与受体相互作用的研究进行了综述:GLP-1的二级结构、GLP-1单个残基改变及残基间的相互作用、GLP-1不同残基片段对GLP-1结合并激活受体的影响和GLP-1受体的相互作用模式。     

浅析"胰岛素和胰高血糖素"

现行人教版高中生物教材必修本第一册P86～87中提到“拮抗作用是指不同激素对同一生理效应发挥相反的作用.这可以通过胰岛素和胰高血糖素对血糖含量的调节来说明.”“当血糖含量较高时,胰岛素分泌增加,胰高血糖素分泌减少……”,“当血糖含量较低时,胰岛素分泌减少,胰高血糖素分泌增加……”,此处容易给学生造成这种认识：胰岛素和胰高血糖素的生理作用相反,因而两种激素的分泌也相互抑制,即胰高血糖素含量的增加会抑制胰岛素的分泌;胰岛素含量的增加会抑制胰高血糖素的分泌.事实是否这样呢？再看现行人教版高中生物教材选修本P12中内容：“图1-7、血糖的激素调节示意图。”     

GLP-1合成与分泌的分子机制及其影响因素北大核心CSCD

肠促胰素之一的胰高血糖素样肽(GLP-1)是胰高血糖素原基因在肠道L细胞中编码的产物。研究发现GLP-1具有抑制摄食、刺激胰岛素分泌从而降低餐后血糖等重要生物学功能,而GLP-1类似物和受体激动剂等已作为糖尿病治疗主要药物用于临床。本文总结近年关于GLP-1合成与分泌的研究进展,简要介绍胰高血糖素原基因转录、翻译后修饰及其相关调控机制,并从营养物质、激素、自主神经系统、机体生理状态和病理状态等方面,介绍影响GLP-1水平的一些主要因素。     

YB-1通过激活Notch受体信号通路抑制肺鳞癌细胞凋亡研究

目的探讨肺鳞癌中YB-1是否通过激活Notch受体信号通路发挥凋亡抑制作用。方法将YB-1干扰质粒pYr-1.1-YB-1-shRNA和野生表达质粒pYr-ads-1-YB-1分别转染肺鳞癌细胞株SK-MES-1,Western blot检测YB-1、RT-PCR检测Notch受体信号通路靶基因Hes1的表达;pYr-ads-1-YB-1瞬时转染SK-MES-1细胞,DAPT抑制Notch受体信号通路,Annexin V-PI双染法检测凋亡。结果 (1)YB-1可正调控Notch受体信号通路靶基因Hes1的转录;(2)YB-1过表达可显著抑制顺铂诱导的凋亡,DAPT抑制Notch受体信号通路后解除了YB-1的凋亡抑制作用。结论 YB-1可通过激活Notch受体信号通路抑制肺鳞癌细胞凋亡。     

内分泌腺疾病(摘登)

胰岛素与糖尿病胰腺包括两类组织:一是分泌消化液,由管道通入十二指肠腔,属外分泌腺.二是胰腺中有许多内分泌细胞,聚集成细胞群,形成小岛,叫做胰岛,总数1—2百万个,总重量约1克,占胰重的1—2％.胰岛集中在胰头部分,包括四种不同的细胞:α细胞占20％,分泌胰高血糖素(glucagon);β细胞较α细胞小,占75％,分泌胰岛素(insulin);δ细胞占5％,可能分泌胃泌素(gastrin),生理作用尚不明;γ细胞,人、猴、兔的胰岛有之.α、β两种细胞相互靠近,只隔一狭小的空隙,α细胞所分泌的胰高血糖素可迅速作用于β细胞而促使胰岛素的分泌. 胰岛素是一种可溶性蛋白质激素,分子量5,743,等电点5.35. 胰岛素的分泌主要受血糖浓度的调节.当血糖浓度升高时,直接使β细胞分泌的胰岛素增加.因为胰岛邻近有丰富的血管,每个胰岛细胞几乎都和毛细血管直接接触;胰岛及其邻近血管均富于神经支配,交感神经与副交感神经纤维进入胰岛后直接终止于胰岛细胞.此外,中枢神经系统可通过迷走神经促进胰岛素的分泌.     

胰高血糖素样肽-1在胰腺中作用机制的研究进展

胰高血糖素样肽-1（GLP-1）是胰高血糖素原基因编码的一种激素,主要由肠道L细胞产生并分泌进入血液。GLP-1能激活胰腺、肾脏、肺、胃、心脏和脑等组织中存在的特异性G蛋白偶联受体（GPCR）。通过GLP-1受体（GLP-1R）的激活,活化腺苷酸环化酶,产生3＇,5＇-环腺苷酸,随后通过cAMP依赖性第二信使途径激活蛋白激酶A和鸟苷酸交换因子。大量围绕胰岛素产生细胞——β细胞开展的研究证明,GLP-1短期作用能够加强葡萄糖依赖性的胰岛素分泌作用,持续的GLP-1R激活也能增加胰岛素的合成,促进β细胞的增殖和新生,抑制β细胞凋亡。GLP-1在胰岛素和胰高血糖素分泌方面的独特作用引发了大量针对GLP-1受体激动剂的研究。我们对胰腺中GLP-1R激活所产生作用的机制进行简要综述。     

~(21)Ala定点突变胰高血糖素及结构与功能变化

 胰高血糖素是由 2 9个氨基酸组成的多肽激素 ,具有促糖元分解的生理功能 ,其拮抗剂有治疗糖尿病病人的潜在应用价值 .在获得重组胰高血糖素基因工程菌基础上 ,利用定点突变技术改造其第 2 1位氨基酸天冬氨酸为丙氨酸 ,并经DNA测序证明胰高血糖素基因发生了点突变 .用IPTG诱导表达后 ,经亲和层析和反相高效液相层析 ,纯化到突变型重组2 1Ala 胰高血糖素 .质谱测定分子量与理论值相符 .利用园二色谱比较重组胰高血糖素和突变的2 1Ala 胰高血糖素在TFE中的二级结构 ,发现胰高血糖素以α螺旋为主要二级结构 ,2 1Ala 胰高血糖素仍有α螺旋结构特征 ,并且含量有所增大 .利用兔升血糖试验 ,发现2 1Ala 胰高血糖素生物活性比重组胰高血糖素减少 51 % (P <0 .0 1 ) .显示天然胰高血糖素第 2 1位氨基酸天冬氨酸与形成α螺旋结构关系不大 ,但在发挥胰高血糖素的生物功能中有重要作用 ,与其可作为钙离子结合位点 ,参与胰高血糖素和受体结合的潜在功能密切相关 .     

生长抑素受体的生理功能及动力学特征

生长抑素受体家族(somatostatin receptors,SSTRs)是一类介导生长抑素及其类似物,具有多种生物学效应的G蛋白偶联受体家族,其生理功能和作用机制长期以来倍受关注.研究表明,这些细胞膜上存在的特定膜受体包括SSTR1、SSTR2、SSTR3、SSTR4以及SSTR5,可以通过cAMP、PTP和MAPK信号通路,在调控GH分泌、诱导细胞凋亡、抑制肿瘤细胞增生、抑制胰岛素作用和抑制细胞生长等生物学过程发挥重要的作用,同时表现出与其它G蛋白偶联受体性质相似的动力学特征.本文将SSTRs的结构、分布和生理功能、配体选择性、下游信号通路,以及该受体家族的动力学特征最新研究进展作一综述.     

胰高血糖素样肽1对胰腺β细胞的作用及其机制

胰高血糖素样肽1(GLP-1)是一种主要由肠道L细胞分泌的肠促胰素。GLP-1能通过葡萄糖依赖模式刺激胰岛素的分泌,同时有延缓胃排空、抑制胰高血糖素分泌、降低体重的作用,有利于维持体内血糖稳态。目前,基于GLP-1的药物作为新的糖尿病治疗手段已越来越受到重视。我们简要综述GLP-1对胰腺β细胞的作用及机制研究进展。     

Glucagon and the Glucagon Receptor: Merrifield Years at the Interface of Chemistry and Biology

The glucagon signaling system is a good model to investigate the chemical and structural requirements that dictate the interaction between a peptide hormone and its membrane-bound receptor and the cascade of events that lead to a physiological response. Secreted by pancreatic A cells, the primary target organ of glucagon is the liver where, together with insulin, it plays a central role in the maintenance of normal circulating glucose levels critical to the survival of the organism. The impetus for studying how glucagon interacts with its receptor is to gain insight into the mechanism of glucagon action in normal physiology as well as in diabetes mellitus. The principal approach towards this goal is to design and synthesize analogues of glucagon that will bind with high affinity to the glucagon receptor but will not activate it. These peptide analogues are expected to be potent antagonists of the hormone and will provide insight into the role of glucagon in diabetes. A second complementary approach is to investigate structure-function relationships in the glucagon receptor by site-directed mutagenesis and the biochemical and pharmacological characterization of mutant receptors. These studies will provide information about the peptide-binding site in the receptor and the residues that dictate ligand selectivity. A stable mammalian cell line that expresses human glucagon receptor at high-levels has been developed and should provide receptor protein for structural studies. An interdisciplinary approach combining chemical synthesis, molecular biology and biophysical methods is crucial for the conception of three-dimensional receptor models to be used in the rational design of glucagon antagonists for the management of diabetes. Dedicated to Bruce Merrifield.     

Modulation of Glucagon Receptor Pharmacology by Receptor Activity-modifying Protein-2 (RAMP2)

The glucagon and glucagon-like peptide-1 (GLP-1) receptors play important, opposing roles in regulating blood glucose levels. Consequently, these receptors have been identified as targets for novel diabetes treatments. However, drugs acting at the GLP-1 receptor, although having clinical efficacy, have been associated with severe adverse side-effects, and targeting of the glucagon receptor has yet to be successful. Here we use a combination of yeast reporter assays and mammalian systems to provide a more complete understanding of glucagon receptor signaling, considering the effect of multiple ligands, association with the receptor-interacting protein receptor activity-modifying protein-2 (RAMP2), and the role of individual G protein α-subunits. We demonstrate that RAMP2 alters both ligand selectivity and G protein preference of the glucagon receptor. Importantly, we also uncover novel cross-reactivity of therapeutically used GLP-1 receptor ligands at the glucagon receptor that is abolished by RAMP2 interaction. This study reveals the glucagon receptor as a previously unidentified target for GLP-1 receptor agonists and highlights a role for RAMP2 in regulating its pharmacology. Such previously unrecognized functions of RAMPs highlight the need to consider all receptor-interacting proteins in future drug development.     

Expression of glucagon receptors in tetracycline-inducible HEK293S GnT1- stable cell lines: an approach toward purification of receptor protein for structural studies

Glucagon is a 29-amino acid polypeptide hormone secreted by pancreatic A cells. Together with insulin, it is an important regulator of glucose metabolism. Type 2 diabetes is characterized by reduced insulin secretion from pancreatic B cells and increased glucose output by the liver which has been attributed to abnormally elevated levels of glucagon. The glucagon receptor (GR) is a member of family B G protein-coupled receptors, ligands for which are peptides composed of 30-40 amino acids. The impetus for studying how glucagon interacts with its membrane receptor is to gain insight into the mechanism of glucagon action in normal physiology as well as in diabetes mellitus. The principal approach toward this goal is to design and synthesize antagonists of glucagon that will bind with high affinity to the GR but will not activate it. Site-directed mutagenesis of the GR has provided some insight into the interactions between glucagon and GR. The rational design of potent antagonists has been hampered by the lack of structural information on receptor-bound glucagon. To obtain adequate amounts of receptor protein for structural studies, a tetracycline-inducible HEK293S GnT1(-) cell line that stably expresses human GR at high-levels was developed. The recombinant receptor protein was characterized, solubilized, and isolated by one-step affinity chromatography. This report describes a feasible approach for the preparation of human GR and other family B GPCRs in the quantities required for structural studies.     

Effects of iodination of tyrosyl residues on the binding and action of glucagon at its receptor.

The binding and action of glucagon at its receptor in hepatic plasma membranes have been compared, as a function of pH, with that of glucagon containing iodotyrosyl residues. Iodinated glucagon, at pH 7.0 and below, binds to the receptor and activates adenylate cyclase with an affinity about threefold higher than that of native glucagon. At pH 8.5, the affinity of the receptor for native glucagon is the same as that seen at pH 7.0. However, iodinated glucagon binds with a lowered affinity with increasing pH. The decreased affinity of the iodinated hormone correlates with ionization of the iodotyrosyl phenoxy groups, which has a pKa of 8.2. It is suggested that the decreased affinity is actually due to the inability of the ionized iodoglucagon to bind to the receptor. The relative potency of native and iodoglucagon will depend, therefore, on the concentrations of ionized and un-ionized species of iodoglucagon, which in turn depend on the pH of the medium. We conclude that incorporation of iodine atoms in the tyrosyl residues of glucagon has two major effects: (i) the iodine atom increases hydrophobic interaction of the hormone with the receptor and (ii) ionization of the phenoxy groups results in the loss of biological activity possibly as the result of loss of hydrogen bonding capability. Thus, the tyrosyl residues in glucagon are critically involved in the function of the hormone.     

Glucagon-mediated internalization of serine-phosphorylated glucagon receptor and Gsalpha in rat liver

To assess glucagon receptor compartmentalization and signal transduction in liver parenchyma, we have studied the functional relationship between glucagon receptor endocytosis, phosphorylation and coupling to the adenylate cyclase system. Following administration of a saturating dose of glucagon to rats, a rapid internalization of glucagon receptor was observed coincident with its serine phosphorylation both at the plasma membrane and within endosomes. Co-incident with glucagon receptor endocytosis, a massive internalization of both the 45- and 47-kDa Gsalpha proteins was also observed. In contrast, no change in the subcellular distribution of adenylate cyclase or beta-arrestin 1 and 2 was observed. In response to des-His(1)-[Glu(9)]glucagon amide, a glucagon receptor antagonist, the extent and rate of glucagon receptor endocytosis and Gsalpha shift were markedly reduced compared with wild-type glucagon. However, while the glucagon analog exhibited a wild-type affinity for endosomal acidic glucagonase activity and was processed at low pH with similar kinetics and rates, its proteolysis at neutral pH was 3-fold lower. In response to tetraiodoglucagon, a glucagon receptor agonist of enhanced biological potency, glucagon receptor endocytosis and Gsalpha shift were of higher magnitude and of longer duration, and a marked and prolonged activation of adenylate cyclase both at the plasma membrane and in endosomes was observed. The subsequent post-endosomal fate of internalized Gsalpha was evaluated in a cell-free rat liver endosome-lysosome fusion system following glucagon injection. A sustained endo-lysosomal transfer of the two 45- and 47-kDa Gsalpha isoforms was observed. Therefore, these results reveal that within hepatic target cells and consequent to glucagon-mediated internalization of the serine-phosphorylated glucagon receptor and the Gsalpha protein, extended signal transduction may occur in vivo at the locus of the endo-lysosomal apparatus.     

Quantitation of glucagon by radioreceptorassay

Receptors for glucagon on rat liver membranes were characterized. They bound [125I] glucagon rapidly in a specific and saturable way. Addition of unlabelled glucagon displaced [125I] glucagon from the binding sites in a concentration dependent way. Concentrations from 10(-9) to 10(-8) M of glucagon caused a linear reduction of binding of labelled glucagon. This concentration interval was used for a three-point assay which fulfilled statistical requirements for validity. Individual assays normally resulted in potency estimates of high precision and statistical weight. Mean values for glucagon activity of preparations tested by receptor assay were within the fiducial limits (P = 0.95) for corresponding activity determined by the rabbit blood glucose method. The receptor assay is less time consuming and requires only part of one rat liver while the in vivo assay uses 16 rabbits. Thus, the receptor assay is less resource demanding and should serve well as a screening instrument for control of potency of glucagon preparations.     

The purification and biological properties of pancreatic big glucagon.

1. Big glucagon was present in extracts of ox, dog, rat and turkey pancreas, representing 10-15% of the glucagon immunoreactivity, and was shown to be of islet origin by its presence in extracts of isolated pigeon islets. 2. Big glucagon was homogeneous by immunoassay after polyacrylamide-gel electrophoresis and was more electronegative than little glucagon. 3. Big glucagon was purified from bovine pancreas, and its apparent molecular weight was estimated by gel filtration as 8200+/-9%. 4. Limited tryptic proteolysis of the molecule produced an immunoreactive component slightly smaller than little glucagon. 5. Linear dilution curves were obtained with mammalian big glucagons by using both enteroglucagon cross-reacting and 'little-glucagon-carboxyl-end-specific' antisera. 6. The half-times for the disappearance of the immunoreactivity of big and little glucagon that had been injected into the rat circulation were 6.9 and 3.2min respectively. 7. Big glucagon was approximately one-sixth as effective as little glucagon in displacing radioactive little glucagon from its liver membrane receptor. 8. Big glucagon was equipotent on a molar basis with little glucagon in the stimulation of the mouse islet adenylate cyclase, an indicator of insulinogenic activity. 9. On a molar basis, big glucagon inhibited basal liver adenylate cyclase activity to the same extent that little glucagon stimulated the enzyme. 10. Big glucagon was without effect on blood glucose concentration in the rat in doses up to 5mug/kg. 11. Big glucagon was equipotent, on a molar basis, with little glucagon in stimulating lipolysis in isolated chicken fat-cells.     

Insulin as a physiological modulator of glucagon secretion

Glucose homeostasis is regulated primarily by the opposing actions of insulin and glucagon, hormones that are secreted by pancreatic islets from beta-cells and alpha-cells, respectively. Insulin secretion is increased in response to elevated blood glucose to maintain normoglycemia by stimulating glucose transport in muscle and adipocytes and reducing glucose production by inhibiting gluconeogenesis in the liver. Whereas glucagon secretion is suppressed by hyperglycemia, it is stimulated during hypoglycemia, promoting hepatic glucose production and ultimately raising blood glucose levels. Diabetic hyperglycemia occurs as the result of insufficient insulin secretion from the beta-cells and/or lack of insulin action due to peripheral insulin resistance. Remarkably, excessive secretion of glucagon from the alpha-cells is also a major contributor to the development of diabetic hyperglycemia. Insulin is a physiological suppressor of glucagon secretion; however, at the cellular and molecular levels, how intraislet insulin exerts its suppressive effect on the alpha-cells is not very clear. Although the inhibitory effect of insulin on glucagon gene expression is an important means to regulate glucagon secretion, recent studies suggest that the underlying mechanisms of the intraislet insulin on suppression of glucagon secretion involve the modulation of K(ATP) channel activity and the activation of the GABA-GABA(A) receptor system. Nevertheless, regulation of glucagon secretion is multifactorial and yet to be fully understood.