甲硫氨酸脑啡肽对猴免疫缺陷病毒早期感染引起CEM x1 74细胞凋亡的可能作用(英文)

探讨短期甲硫氨酸脑啡肽作用对SIV感染CEMx174细胞凋亡的可能作用 .用MTS法测定甲硫氨酸脑啡肽对感染CEMx174细胞存活率的影响 ,流式细胞仪分析SIV诱导细胞凋亡及其甲硫氨酸脑啡肽的作用 ,并测定了cAMP含量、PKA活性和组蛋白磷酸化的水平 .SIV能够显著减少CEMx174细胞数 ,甲硫氨酸脑啡肽可以提高感染细胞的存活率 .AnnexinⅤ结合实验显示 ,1μmol L甲硫氨酸脑啡肽可以增加存活细胞的比率 ,减少凋亡细胞数 .甲硫氨酸脑啡肽降低正常细胞和感染细胞cAMP的含量和PKA活性 ,但是在感染组较为明显 .在感染的情况下 ,磷酸化的组蛋白增加 ,甲硫氨酸脑啡肽可以减少其含量 .甲硫氨酸脑啡肽的作用可以被纳酪酮所拮抗 .研究结果提示 ,甲硫氨酸脑啡肽对SIV感染引起早期细胞凋亡的作用涉及cAMP PKA信号传递过程     

大鼠小肠5-HT免疫活性内分泌细胞的角蛋白免疫细胞化学定位

本文作者用免疫组化双色反应,对大鼠小肠5-HT免疫活性内分泌细胞进行表皮角蛋白免疫细胞化学定位。结果表明,5-HT免疫活性内分泌细胞含有表皮角蛋白阳性颗粒,提示胃肠的正常内分泌细胞和其它粘膜上皮细胞一样含有角蛋白中间丝,它们可能也和其它粘膜上皮细胸一样共同起源于内胚层。     

大鼠胰腺嗜铬颗粒素A分布的免疫组织化学研究

本研究用ＡＢＣ免疫组织化学方法,在Ｂｏｕｉｎ液固定的常规石蜡切片上,观察了啥铬颗粒素Ａ在大鼠胰腺内分泌细胞内的定位和分布,并用相邻切片双标记法,观察了它与胰高血糖素、胰岛素、生长抑素的共存关系。结果发现,大鼠胰腺嗜铬颗粒素Ａ样免疫反应细胞主要分布于胰岛的周边部,胰腺外分泌部的导管和腺泡等处均未见ＣｇＡ祥物质存在。用相邻薄切片免疫显色技术证明,大鼠胰腺中ＣｇＡ样物质与胰高血糖素共存。结果提示,ＣｇＡ可能是胰腺内分泌细胞的一个新的标志物,在胰腺功能调节上发挥着重要作用。     

酪氨酸羟化酶在成年大鼠胰腺中的定位

目的:酪氨酸羟化酶(tyrosine hydroxylase,TH)是儿茶酚胺类递质合成的限速梅,儿茶酚胺类递质对胰腺内分泌细胞的功能具有重要的调控作用,本研究拟探讨酪氨酸羟化酶(tyrosine hydroxylase,TH)在成年大鼠整个胰腺的具体定位和表达.方法:取雄性成年大鼠胰腺,冰冻组织切片,应用免疫荧光技术观察酪氨酸羟化酶在整个胰腺中的表达分布情况,并进一步运用免疫荧光双标技术鉴定酪氨酸羟化酶是否与胰岛素、胰高血糖素、生长抑素以及胰多肽分别共定位于β细胞;α细胞;δ细胞及PP细胞,进一步确定合成酪氨酸羟化酶确切的细胞类型.结果:①在胰腺腺泡细胞胞浆中存在酪氨酸羟化酶的阳性表达颗粒.②分布于胰腺外分泌腺的神经纤维和胰岛的神经纤维中都有酪氨酸羟化酶的表达.③酪氨酸羟化酶与胰岛的四种内分泌细胞所合成的肽之间均没有共定位关系.结论:在胰腺,酪氨酸羟化酶只存在于胰腺外分泌腺的腺泡细胞胞浆内以及胰腺中的神经纤维中,而胰岛四种内分泌细胞中没有酪氨酸羟化酶,说明胰腺儿茶酚胺类神经递质一方面由胰腺外分泌部的腺泡细胞合成,另一方面来源于神经末梢的释放,而胰岛细胞不能合成儿茶酚胺类递质;该结果为进一步研究胰腺内、外分泌部之间的关系和儿茶酚胺对胰腺分泌功能的调节提供形态学证据.     

鲤、青鱼肠粘膜内分泌细胞的免疫组织化学鉴别和定位

使用过氧化物酶——抗过氧化物酶(PAP)的免疫组织化学染色技术,用10种哺乳动物激素培育出的抗血清对鲤、青鱼肠道粘膜中内分泌细胞的鉴別表明,它们的肠道粘膜上皮中存在有胃泌素、P物质、牛胰多肽、亮氨酸脑啡肽、胰高血糖素样免疫反应物、抑胃多肽等6种免疫活性內分泌细胞;而五羟色胺、胆囊收缩素和神经降压素没有免疫活性反应。在鲤的肠粘膜中存在生长抑素免疫活性内分泌细胞;青鱼中则未见到这种细胞。两种鱼的各种免疫活性內分泌细胞多数在前肠的分布密度较大;但青鱼肠粘膜中P物质和亮氨酸脑啡肽两种免疫活性内分泌细胞却在直肠中分布最多;胰高血糖素样免疫活性内分泌细胞在中肠分布最多。P物质和胃泌素免疫活性內分泌细胞大多数分布于肠褶顶部;其他各种免疫活性內分泌细胞则主要分布于肠褶的中、底部。本文比较了鲤、青鱼的肠内分泌细胞在各肠段中的分布密度,并对其形态学及分布特点进行描述和讨论。     

脂肪细胞对胰岛β细胞功能的内分泌调节作用

脂肪因子包括脂肪细胞分泌的多种活性因子,它们通过内分泌方式调节胰岛β细胞的胰岛素分泌、基因表达以及细胞凋亡等多方面的功能。本文提出脂肪因子影响胰岛β细胞功能主要通过三条相互联系的途径而实现。第一是调节β细胞内葡萄糖和脂肪的代谢;第二是影响β细胞离子通道的活性;第三是改变β细胞本身的胰岛素敏感性。脂肪细胞的内分泌功能是一个动态过程,在不同的代谢状态下,各脂肪因子的分泌发生不同变化。从正常代谢状态发展到肥胖以及2型糖尿病的过程中,脂肪因子参与了胰岛β细胞功能障碍的发生与发展。     

阿片类物质对猴免疫缺陷病毒感染的CEM×174细胞内p53合成的调节作用(英文)

已经证明阿片类物质如吗啡能够刺激猴免疫缺陷病毒 ( SIV)的复制 ,并最终加速细胞死亡 ,但是其机理却研究很少 .为探讨吗啡和甲硫氨酸脑啡肽对细胞内 p53合成的作用 ,用 SIV感染CEM× 1 74细胞 ,同时分析 SIV感染时病理过程的机理 .在 CEM× 1 74细胞感染 SIV后不同时间 ,p53含量逐渐增加 ,但 1 0 -7mol/L的吗啡仅在起始阶段对其有促进作用 .在 SIV感染组加入吗啡或甲硫氨酸脑啡肽进行时间曲线实验时 ,p53含量较低 .加入 1 0 -8～ 1 0 -6mol/L吗啡 8h,正常细胞 p53含量仅有轻微改变 .但在 SIV感染情况下 ,则呈现剂量依赖性的大量增加 .相反 ,1 0 -8- 1 0 -6mol/L甲硫氨酸脑啡肽在 8h时能增加正常细胞 p53合成达 60 % .在 SIV感染时 ,SIV本身能够促进 p53的含量 .尽管各组 p53仍然高于对照组 ,但甲硫氨酸脑啡肽对其不再起作用 .结果提示甲硫氨酸脑啡肽对正常细胞 p53含量有明显影响 ,而吗啡 8h增加 SIV感染细胞的 p53含量可能是其加速爱滋病病理过程的机理之一 .     

大鼠胰腺γ-氨基丁酸免疫组织化学定位

本文用ABC—GDN免疫组织化学方法,研究了γ-氨基丁酸(Gamma—Aminobutyric Acid,GABA)在大鼠胰腺的定位和分布,并用相邻切片法,观察它与胰岛素的共存关系。结果发现GABA免疫反应阳性细胞主要分布于胰腺内分泌部(胰岛)。在外分泌部亦有少许分布。大部分胰岛细胞呈GABA免疫反应阳性,集中位于胰岛的中央部。相邻连续切片免疫染色证实GABA与胰岛素共存于胰岛B细胞中。外分泌部胰腺GABA免疫反应阳性细胞,呈零散分布于腺泡和导管上皮间。本文为进一步探讨GABA在胰腺的生理作用提供了形态学依据。     

新生SD大鼠岛源性胰岛祖细胞的分离培养与诱导分化

目的：分离培养新生大鼠岛源性胰岛祖细胞,观察GLP-1（7-36）NH2诱导其向成熟细胞分化作用。方法：分离与纯化胰岛,在含20μg／LEGF和20μg／LbFGF的RPMI1640培养基中分离和扩增胰岛祖细胞．用20nmol／LGLP-1（7-36）NH2诱导分化。用原位杂交、免疫细胞化学染色、二硫腙（DTZ）染色和放射免疫分析等方法对的胰岛祖细胞分化前后细胞特征进行初步鉴定。结果：胰岛祖细胞表达Nestin,不表达PDX-1、InsulinmRNA、Insulin、Somatostatin。以GLP-1（7-36）NH2诱导分化后,部分细胞表达PDX-1、胰岛素mRNA、胰岛素、生长抑素,胰岛样细胞团（Ic＆）形成,其周边细胞DTZ着色。分化3周后培养基中胰岛素释放明显增加。结论：在新生SD大鼠胰岛存在有一类胰岛祖细胞,可以被分离并在体外不断扩增。GLP-1（7-36）NH2可以诱导胰岛祖细胞形成有胰岛素分泌功能的胰岛样细胞团。     

基础内分泌学讲座(Ⅲ)

一、胰岛 1869年兰格汉斯(Langerhans)首先发现,在胰腺中有一小簇具有丰富血管支配的细胞,这些细胞不同于分泌胰液的腺泡,没有分泌导管,称作Langerhans氏小岛或胰岛。人的胰腺含有200百万个胰岛,广泛地散布在胰腺组织内,直径为20—30微米,全部胰岛组织只占胰腺重量的1—2％。胰岛是胰腺的内分泌组织,它包含3种内分泌细胞,各自分泌不同激素。α     

Histochemistry of the pancreatic islets in golden hamsterMesocricetus auratus waterhouse 1839

Summary The histological picuture of the Langerhans' islets in hamster pancreas is quite similar to that in white rat pancreas, i.e. the B-cells are located in the middle of the islet, while the A-cells in its periphery. Very often the argyrophil cells (D-cells) are located between the A- and B-cells forming a peculiar “barrier”. The histochemical studies reveal differences between the endocrine tissue and exocrine parenchyma. In general, the islet cells are richer in enzymes, as compared with the acini. The histochemical characteristic of hamster pancreas is closest to that of white rat pancreas. Like in rat, alkaline phosphomonoesterase reaction is very strong in the A-cells, while G-6-P reaction is negative. But, concerning zinc localization, there are differences between hamster and rat. Zinc reaction is very strong in the peripheral A-cells in white rat pancreas, while in hamster this reaction is much stronger in the B-cells (the reaction is negative in the A-cells). The D-cells can not be differentiated from the other endocrine pancreatic cells by means of hystochemical studies. But these studies permit certain conclusion on the possible role of the enzymes and substances investigated in cytophysiology of the islet cells.     

Insulin secretion and islet endocrine cell content at onset and during the early stages of diabetes in the BB rat: effect of the level of glycemic control.

Although it is agreed that autoimmune destruction of pancreatic islets in diabetic BB rats is rapid, reports of endocrine cell content of islets from BB diabetic rats at the time of onset of diabetes vary considerably. Because of the rapid onset of the disease (hours) and the attendant changes in islet morphology and insulin secretion, it was the aim of this study to compare islet beta-cell numbers to other islet endocrine cells as close to the time of onset of hyperglycemia as possible (within 12 h). As it has been reported that hyperglycemia renders the beta cell insensitive to glucose, the early effects of different levels of insulin therapy (well-controlled vs. poorly controlled glycemia) on islet morphology and insulin secretion were examined. When measured within 12 h of onset, insulin content of BB diabetic islets, measured by morphometric analysis or pancreatic extraction, was 60% of insulin content of control islets. Despite significant amounts of insulin remaining in the pancreas, 1-day diabetic rats exhibited fasting hyperglycemia and were glucose intolerant. The insulin response from the isolated perfused pancreas to glucose and the glucose-dependent insulinotropic hormone, gastric inhibitory polypeptide (GIP), was reduced by 95%. Islet content of other endocrine peptides, glucagon, somatostatin, and pancreatic polypeptide, was normal at onset and at 2 weeks post onset. A group of diabetic animals, maintained in a hyperglycemic state for 7 days with low doses of insulin, were compared with a group kept normoglycemic by appropriate insulin therapy. No insulin could be detected in islets of poorly controlled diabetics, while well-controlled animals had 30% of the normal islet insulin content.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic analysis of early endocrine pancreas formation in zebrafish

Endocrine pancreas of zebrafish consist of at least four different cell types that function similarly to mammalian pancreatic islet. No mutants specifically affecting formation of the endocrine pancreas have been identified during the previous large-scale mutagenesis screens in zebrafish due to invisibility of a pancreatic islet. We combined in situ hybridization method to visualize pancreatic islet with an ethyl-nitroso-urea mutagenesis screen to identify novel genes involved in pancreatic islet formation in zebrafish. We screened 900 genomes and identified 11 mutations belonging to nine different complementation groups. These mutants fall into three major phenotypic classes displaying severely reduced insulin expression, reduced insulin expression with abnormal islet morphology, or abnormal islet morphology with relatively normal number of insulin expressing cells. Seven of these mutants do not have any other visible phenotypes associated. These mutations affect different processes in pancreatic islet development. Additional analysis on glucagon and somatostatin cell specification revealed that somatostatin cells are specified at a separate domain from insulin cells whereas glucagon cells are specified adjacent to insulin cells. Furthermore, glucagon cells and somatostatin cells are always associated with insulin cells in mutants that have scattered insulin expression. These data indicate that there are separate mechanisms regulating endocrine cell migration, proliferation, and differentiation. Further study on these mutants will reveal important information on novel genes involved in pancreatic islet cell specification and morphogenesis.     

Development of endocrine pancreatic islets in embryos of the grass snake Natrix natrix (Lepidosauria,Serpentes)

Differentiation of the pancreatic islets in grass snake Natrix natrix embryos, was analyzed using light, transmission electron microscopy, and immuno-gold labeling. The study focuses on the origin of islets, mode of islet formation, and cell arrangement within islets. Two waves of pancreatic islet formation in grass snake embryos were described. The first wave begins just after egg laying when precursors of endocrine cells located within large cell agglomerates in the dorsal pancreatic bud differentiate. The large cell agglomerates were divided by mesenchymal cells thus forming the first islets. This mode of islet formation is described as fission. During the second wave of pancreatic islet formation which is related to the formation of the duct mantle, we observed four phases of islet formation: (a) differentiation of individual endocrine cells from the progenitor layer of duct walls (budding) and their incomplete delamination; (b) formation of two types of small groups of endocrine cells (A/D and B) in the wall of pancreatic ducts; (c) joining groups of cells emerging from neighboring ducts (fusion) and rearrangement of cells within islets; (d) differentiated pancreatic islets with characteristic arrangement of endocrine cells. Mature pancreatic islets of the grass snake contained mainly A endocrine cells. Single B and D or PP–cells were present at the periphery of the islets. This arrangement of endocrine cells within pancreatic islets of the grass snake differs from that reported from most others vertebrate species. Endocrine cells in the pancreas of grass snake embryos were also present in the walls of intralobular and intercalated ducts. At hatching, some endocrine cells were in contact with the lumen of the pancreatic ducts.     

Altered islet composition and disproportionate loss of large islets in patients with type 2 diabetes

Human islets exhibit distinct islet architecture with intermingled alpha- and beta-cells particularly in large islets. In this study, we quantitatively examined pathological changes of the pancreas in patients with type 2 diabetes (T2D). Specifically, we tested a hypothesis that changes in endocrine cell mass and composition are islet-size dependent. A large-scale analysis of cadaveric pancreatic sections from T2D patients (n = 12) and non-diabetic subjects (n = 14) was carried out combined with semi-automated analysis to quantify changes in islet architecture. The method provided the representative islet distribution in the whole pancreas section that allowed us to examine details of endocrine cell composition in individual islets. We observed a preferential loss of large islets (>60 µm in diameter) in T2D patients compared to non-diabetic subjects. Analysis of islet cell composition revealed that the beta-cell fraction in large islets was decreased in T2D patients. This change was accompanied by a reciprocal increase in alpha-cell fraction, however total alpha-cell area was decreased along with beta-cells in T2D. Delta-cell fraction and area remained unchanged. The computer-assisted quantification of morphological changes in islet structure minimizes sampling bias. Significant beta-cell loss was observed in large islets in T2D, in which alpha-cell ratio reciprocally increased. However, there was no alpha-cell expansion and the total alpha-cell area was also decreased. Changes in islet architecture were marked in large islets. Our method is widely applicable to various specimens using standard immunohistochemical analysis that may be particularly useful to study large animals including humans where large organ size precludes manual quantitation of organ morphology.     

The ghrelin cell: a novel developmentally regulated islet cell in the human pancreas

OBJECTIVES: Ghrelin, an endogenous ligand of the growth hormone secretagogue receptor (GHS-R), was recently identified in the stomach. Ghrelin is produced in a population of endocrine cells in the gastric mucosa, but expression in intestine, hypothalamus and testis has also been reported. Recent data indicate that ghrelin affects insulin secretion and plays a direct role in metabolic regulation and energy balance. On the basis of these findings, we decided to examine whether ghrelin is expressed in human pancreas. Specimens from fetal to adult human pancreas and stomach were studied by immunocytochemistry, for ghrelin and islet hormones, and in situ hybridisation, for ghrelin mRNA. RESULTS: We identified ghrelin expression in a separate population of islet cells in human fetal, neonatal, and adult pancreas. Pancreatic ghrelin cells were numerous from midgestation to early postnatally (10% of all endocrine cells). The cells were few, but regularly seen in adults as single cells at the islet periphery, in exocrine tissue, in ducts, and in pancreatic ganglia. Ghrelin cells did not express any of the known islet hormones. In fetuses, at midgestation, ghrelin cells in the pancreas clearly outnumbered those in the stomach. CONCLUSIONS: Ghrelin is expressed in a quite prominent endocrine cell population in human fetal pancreas, and ghrelin expression in the pancreas precedes by far that in the stomach. Pancreatic ghrelin cells remain in adult islets at lower numbers. Ghrelin is not co-expressed with any known islet hormone, and the ghrelin cells may therefore constitute a new islet cell type.     

Quantitative estimation of islet tissue of pancreas in Spinifex hopping mouse (Notomys alexis)

Pancreases from three male and three female adult Spinifex hopping mice ( Notomys alexis ) were studied. No correlation was found between pancreas weight and body weight. Estimations of islet tissue mass and of individual cell types were made on paraffin sections of Bouin-fixed tissue taken from head, neck, body and tail regions of pancreas of each animal. Islet tissue mass was assessed using a linear scanning technique on sections stained with haematoxylin and eosin, and was compared with body weight. Specific cell types were assessed using a point-intercept method, on aldehyde-fuchsin-stained sections for beta (β) cells, and on immunoperoxidase labelled sections for alpha (α) cells (glucagon) and delta (δ) cells (somatostatin). Positive regional differences noted were a greater proportion of islet tissue in the tail region, and a lower proportion of α cells in the head region. Alpha cells were peripherally situated in the islets.
These results show some elements of agreement with a previously proposed hypothesis regarding the general patterns of arrangement of the mammalian endocrine pancreas.