新的生长激素释放激素类似肽Pro-hGHRH(1-44)-Gly-Gly-Cys的重组和比较活性*

目的:为了寻找高活性和长半衰期生的GHRH类似肽。方法:通过使用独特的酸敏感水解位点Asp-Pro的原核表达系统,构建了新的Pro-hGHRH(1-44)-Gly-Gly-Cys类似肽。通过重组细菌裂解、包含体洗涤、乙醇分级沉淀、酸水解、SP-Sephadex C-25和Sephadex G-10柱层析等技术,纯化了高纯度的Pro-hGHRH(1-44)-Gly-Gly-Cys肽。通过使用SDS-PAGE、离子化质谱、雌大鼠垂体和人流产胎儿垂体,测定了多肽的纯度、分子量、生长激素释放活性。结果:Pro-hGHRH(1-44)-Gly-Gly-Cys肽分子量5373Da与实际值吻合,0.1~10 μg/ml的肽剂量不论是对人垂体还是大鼠垂体都增加了垂体生长激素的释放,大鼠垂体生长激素的释放具有剂量依赖性。与标准的hGHRH(1-40)肽比较,新的类似肽有较高的GH释放活性。结果也显示了,Pro-GHRH(1-44)-Gly-Gly-Cys与Pro-hGHRH(1-44)肽的GH释放活性无统计学差异。结论：新的类似肽有较好的生长激素释放活性、功能选择性和种属特异性。     

鲑鱼生长激素基因分泌型表达质粒的构建

生长激素(GH)是动物垂体前叶分泌的一种多肽类激素.应用分子重组及PCR等技术,构建了一种鲑鱼生长激素基因分泌型表达质粒pOsGH153,使编码鲑鱼生长激素成熟肽的序列克隆在大肠杆菌分泌型表达载体PIN-Ⅲ-ompA内,直接位于编码大肠杆菌外膜蛋白A信号肽序列的下游,在Lpp-Lac杂合启动子控制下,经IPTG诱导,分子量约23 000的鲑鱼生长激素在大肠杆菌中获得高效表达,该产物具有天然鲑鱼生长激素的免疫活性,直接分泌到细胞周质,而信号肽被自动剪除.     

生长激素和生长激素受体的多样性

生长激素及其受体对动物生长发育起着重要的作用。转录过程选择性剪接和存在多种降解途径可能是GH或GHR产生多样性的原因。随着GH结构形态的改变,其功能也在发生变化。GH基因的多样性对鸡的抗病选择性反应与产蛋性能有相关,GH和GHR基因的多样性会影响奶牛的产奶生产性能。GHR的分子多样性可能导致动物生长发育模式的变异,例如动物的矮小病。     

生长激素促释放剂受体配体的研究进展

生长激素促释放剂是一种合成的小分子化合物,它通过生长激素促释放剂受体而起作用,该受体是一种新的G蛋白偶联受体。以前曾认为生长激素促释放剂受体是一种孤儿受体,直到近年来从人和鼠的胃中鉴定到Ghrelin的存在,而改变了这种看法。Ghrelin是包含28个氨基酸残基的肽,在3号位的丝氨酸位点有辛酰化基团。该肽是在X／A样细胞分泌颗粒中发现的,Ghrelin的发现表明促垂体分泌生长激素可能不止受到来自下丘脑的生长激素释放激素的调节,同时还可能受到来自胃和下丘脑的Ghrelin的调节。     

斜带石斑鱼生长激素/催乳素家族基因cDNAs的分子克隆及其进化意义

从斜带石斑鱼垂体提取总。RNA,再取其50ng合成SMART cDNA。从所构建的垂体SMART cDNA质粒文库中筛选到生长激素／催乳素基因家族的2个成员的全长cDNA片段：生长激素(GH)基因全长为938bp,编码204个氨基酸;催乳素基因(PRI．)全长为1429bp,编码212个氨基酸。采用计算机软件Mega 2和CLUSTAL W1．64b对9种鱼的生长激素／催乳素基因家族的3个成员(GH、PRL和生长催乳素SL)的氨基酸序列进行系统分析,构建NJ分支系统树,对于序列中的插入／缺失位点则采用Pairaise Deletion,1000次自展(Bootstrap)分析计算各节点支持率。根据3个基因的氨基酸序列构建的系统树表明,石斑鱼与金头鲷、金鲈和牙鲆聚成一类,虹鳟与大马哈鱼聚成一类,鲫鱼与鲶鱼聚成一类,鳗鲡成另外一类。根据石斑鱼全长cDNA推断的氨基酸序列比较表明,SL相对GH和PRL有较高的保守性。石斑鱼的GH、PRL和SL的氨基酸同源性在24％～31％,但其C-端的氨基酸同源性较高,尤其是C-端的3个Cys是严格保守的。其中SL与GH的同源性(30．8％)高于与PRL的同源性(25．6％),GH和PRL的同源性最低(24．1％)。     

两个人生长激素基因在SV40病毒重组体感染的猴细胞中的表达

我们已经建造了带有两个不同的人生长激素(hGH)基因的SV40重组体。用这些重组体感染的猴肾细胞能合成、加工并分泌人生长激素。有着与克隆的人生长激素互补DNA(eDNA)同样编码序列的基因1,共产物从几个标准来看,与垂体hGH没有什么区别。预定编码一个变异蛋白质的基因2,其产物比垂体hGH的免疫反应活性要小,但能有效地与hGH细胞表面受体结合。这些结果表明,基因2有可能表达而产生我们以前未辨别的hGH形式。这些结果显示了在真核细胞中,用基因转移的方法产生成熟的激素是可能的。这些结果也证明了SV40—猴细胞系统可以用于生产和鉴定动物细胞分泌的蛋白质。     

达氏鲟生长激素基因cDNA克隆、表达及免疫荧光定位研究

为研究达氏鲟(Acipenser dabryanus)生长激素(Growth Hormone, GH)基因的功能, 合成了达氏鲟垂体SMART cDNA, 克隆得到GH全长cDNA序列。达氏鲟GH全长cDNA序列为1008 bp, 由52 bp的5'端非编码区(Untranslated region, UTR)、编码214个氨基酸的645 bp开放阅读框(Open reading frame, ORF)和311 bp的3'UTR构成。运用GH氨基酸序列构建进化树分析发现, 达氏鲟与两栖类、爬行类和哺乳类的一致性要高于真骨鱼类。实时荧光定量PCR结果表明, 达氏鲟GH mRNA主要在垂体和下丘脑中表达, 且垂体中GH的表达量约为下丘脑的110倍; Western-blot研究结果与qRT-PCR一致, 仅在垂体和下丘脑中检测到生长激素蛋白, 且垂体中GH的表达量远高于下丘脑。免疫荧光定位结果显示, GH主要定位于垂体中部, 下丘脑中也有少量荧光信号; 苏木精-伊红组织切片染色研究表明, GH主要是由嗜酸性的生长激素分泌细胞分泌。研究为深入研究脊椎动物生长激素基因的进化和人工养殖达氏鲟的生长调控提供了基础。       

榕江香猪生长激素基因的鉴定及功能分析

生长激素是调节动物生长的主要激素.本研究应用聚合酶链式反应技术从榕江香猪的基因组文库中分离出1.903kb生长激素基因.克隆的生长激素基因由五个外显子和四个内含子组成.榕江香猪生长激素基因的碱基序列与已知四个国外猪种和9个中国地方猪种之间的同源性为97%～99%,其间的差异主要集中在内含子2和4.通过限制性内切酶（DdeI,NarI,BsmNI）分析,鉴定出榕江香猪生长激素基因的五个多态性位点,分别位于5＇-侧翼区274（T/C）位点,外显子2的622（G/A）和631（G/A）位点,内含子2中的841（T/C）以及外显子4中的1 358（A/G）位点.同时,1 358（A/G）位的碱基改变导致榕江香猪生长激素成熟肽第108位异亮氨酸替换,三维结构分析表明,异亮氨酸的存在可能导致生长激素与受体间亲合力降低.     

生长激素分泌促进剂及构效关系研究进展

生长激素分泌促进剂是一类作用于垂体和下丘脑的具有专一性促生长激素释放作用的寡肽及其类似物.由于其分子质量小、活性高、可口服、作用专一而有可能成为新的生长激素治疗药物.目前已经发展了很多具有此类活性的多种结构的化合物,如肽、环肽、肽醇及非肽类似物等.尽管这类化合物的作用机制尚未完全明确,但已有证据表明存在新的调节生长激素分泌的途径和新的调节因子.     

青鱼生长激素的重组表达及其多克隆抗体的制备

以含有的青鱼生长激素编码区cDNA的重组质粒pbcGHc为模板,高保真PCR扩增青鱼生长激素（GH）成熟肽cDNA序列,定向插入原核表达载体pET-28a,构建青鱼GH原核表达质粒pET-bcGH。将pET-bcGH转化大肠杆菌BL21(DE3),IPTG诱导青鱼GH基因在大肠杆菌中的融合表达,SDS-PAGE凝胶电泳结果显示一条23 kDa的诱导表达重组青鱼GH带。以草鱼GH多克隆抗体为一抗,Western Blot证明,该重组青鱼GH具有免疫学活性。将经过亲和层析、透析纯化后的重组青鱼GH作为抗原,采用改进的方法对家兔进行皮下免疫注射,获得青鱼GH多克隆抗血清。以该多抗为一抗,Western Blot 可以检测出4 ng的抗原量;并且在青鱼垂体组织抽提液中和血清中检测到一种能与该抗血清作用的大小为21 kDa的蛋白质。这些结果表明本研究得到的青鱼GH多克隆抗血清具有较好的免疫特性。     

青鱼生长激素cNDA的克隆与序列分析

从青鱼（Mylopharyngodon piceus）脑下垂体中提取总RNA,采用逆转录PCR法扩增出青鱼生长激素cDNA编码区,克隆到Pucm-T载体上。序列测定表明青鱼生长激素基因的开放阅读框架含有630bp,其中包括22个氨基酸的信号肽和188个氨基酸的成熟肽,青鱼生长激素基因的克隆成功为该基因的功能及应用研究奠定了基础。     

Thyroid-stimulating hormone and growth hormone release alterations induced by mosquito larvae proteins on pituitary cells

Mosquito larvae crude extract has shown to modulate cell proliferation of different mouse epithelial as well as human mononuclear cell populations in vivo and in vitro. A soluble fraction of the extract, with a molecular weight ranging from 12 to 80 kD, also showed an inhibitory effect on the proliferation of mouse hepatocytes. This effect disappeared after heating the extract at 90 degrees C for 60 min, suggesting that some proteinaceous molecule is involved. We report the effect of dialysed extract (MW >12 kD) on the concentration of both thyroid-stimulating hormone (TSH) and growth hormone (GH) in an incubation medium of pituitary cells from normal and oestrogenised rats. Time- and dose-dependent response of both hormones resulted in increasing TSH levels. Concentrations of GH were lower in the treated than in control pituitary cells. The time elapsed until the finding of differences suggests the presence in the mosquito extract of some protein binding the hormone. The differences were not due to lethal toxic effects since the Trypan blue viability test showed no differences between control and treated cells. Furthermore, the effect disappeared when the extract had previously been heated at 90 degrees C for 60 min. Finally, our results suggest the presence of some proteins in the mosquito Culex pipiens L. larvae, which would act as a pituitary hormone regulator.     

Effects of secretin and gastric inhibitory polypeptide on human pancreatic growth hormone-releasing factor(1-40)-stimulated growth hormone levels in the rat

Synthetic human pancreatic growth hormone-releasing factor containing 40 amino acids ([hpGRF (1-40)]-OH) significantly stimulated plasma growth hormone (GH) levels in both sodium pentobarbital and urethane anesthetized rats. Synthetic secretin, gastric inhibitory polypeptide (GIP), and glucagon significantly decreased plasma GH levels while synthetic vasoactive intestinal peptide (VIP) had no effect. Secretin and GIP also altered the in vivo plasma GH response to [hpGRF(1-40)]-OH. Whether this effect is the result of an interaction at the pituitary level or is due to an extra-pituitary effect of secretin and GIP awaits further study.     

N-glycosylated variants of growth hormone in human pituitary extracts

This study was designed to investigate the existence, in human pituitary extracts, of growth hormone (GH) variants not encoded by the hGH-N gene. Using anion exchange-fast protein liquid chromatography followed by SDS-PAGE, we isolated several basic forms of pituitary GH. Incubation of these basic forms with endoglycosidase F/N-glycosidase F revealed that two of them (about 34 and 12 kD) were N-glycosylated. In contrast, no changes were found when samples were incubated with the O-linked glycosylation-specific O-glycosidase. Since the GH-N molecule lacks consensus sequences for N-linked glycosylation, our findings suggest that GH genes other than hGH-N are expressed in the human pituitary gland.     

Melanin-concentrating hormone stimulates human growth hormone secretion: a novel effect of MCH on the hypothalamic-pituitary axis

Melanin-concentrating hormone (MCH), a 19-amino acid orexigenic (appetite-stimulating) hypothalamic peptide, is an important regulator of energy homeostasis. It is cleaved from its precursor prepro-MCH (ppMCH) along with several other neuropeptides whose roles are not fully defined. Because pituitary hormones such as growth hormone (GH), ACTH, and thyroid-stimulating hormone affect body weight and composition, appetite, insulin sensitivity, and lipoprotein metabolism, we investigated whether MCH exerts direct effects on the human pituitary to regulate energy balance using dispersed human fetal pituitaries (21-22 wk gestation) and cultured GH-secreting adenomas. We found that MCH receptor-1 (MCH-R1), but not MCH receptor-2, is expressed in both normal (fetal and adult) human pituitary tissues and in GH cell adenomas. MCH (10 nM) stimulated GH release from human fetal pituitary cultures by up to 62% during a 4-h incubation (P < 0.05). Interestingly, neuropeptide EI (10 nM), which is also cleaved from ppMCH, increased human GH secretion by up to 124% in fetal pituitaries. A milder, albeit significant, induction of GH secretion by MCH (20%) was seen in cultured GH-secreting pituitary adenomas. A comparable stimulation of GH secretion was seen when cultured mouse pituitary cells were treated with MCH. Treatment of cultured GH adenoma cells with MCH (100 nM) induced extracellular signal-regulated kinases 1 and 2 phosphorylation, suggesting activation of MCH-R1. In aggregate, these data suggest that MCH may regulate pituitary GH secretion and imply a potential cross-talk mechanism between appetite-regulating neuropeptides and pituitary hormones.