抑前胸腺肽在家蚕体内的活性作用

家蚕Bombyx mori抑前胸腺肽是昆虫脑神经肽的一种,体外实验表明它能抑制处于活动时期的家蚕前胸腺合成蜕皮激素,因此抑前胸腺肽可能对昆虫的变态起着重要的作用。将抑前胸腺肽以不同的浓度分单一注射和加强注射导入家蚕体内,不同的时间间隔取样,利用蜕皮激素放射免疫分析方法,观察到了抑前胸腺肽在家蚕体内的活性作用以及引起家蚕体内血淋巴中蜕皮激素浓度的动态变化,首次证明了抑前胸腺肽在体内对家蚕前胸腺合成蜕皮激素有强烈的抑制作用。     

家蚕抑前胸腺肽类似物的活性鉴定和结构分析

以家蚕Bombyx mori抑前胸腺肽的氨基酸序列作为基础,通过氨基酸残基的添加、减少和置换,人工合成了一组与家蚕抑前胸腺肽结构类似的多肽。利用家蚕前胸腺体外培养技术,结合蜕皮激素放射免疫分析方法,鉴定了与抑前胸腺肽结构类似的多肽的生理活性,并对它们的活性特征、化学参数、结构和功能、信号传导途径进行了综合的比较和分析。类似物899808的生物学功能与抑前胸腺肽的相同而且活性近似;类似物899805和899809对家蚕前胸腺蜕皮激素的生物合成表现出随浓度增加而增加的促进作用,而低浓度下几乎不促进;899803、899804、899806和899807类似物对家蚕前胸腺蜕皮激素的生物合成的促进和抑制作用与它们的浓度有着依赖关系。实验结果表明,对抑前胸腺肽的氨基酸序列作任何改变,都导致其生理活性的下降、丧失甚至相反的活性。     

昆虫蜕皮激素生物合成及其神经肽调控

蜕皮激素是对节肢动物体内类固醇激素的统称,昆虫的蜕皮激素主要由内分泌器官前胸腺合成,具有诱发幼虫周期性蜕皮以及最终变态蜕皮的生理功能。近期的研究工作阐明了前胸腺中原先被称为"黑箱"的一系列酶促反应步骤,此外促前胸腺激素受体的成功鉴定使人们对PTTH信号转导通路调控前胸腺蜕皮激素合成有了更深入的理解。     

Insect ecdysteroids biosynthesis and its regulation by neuropeptides

蜕皮激素是对节肢动物体内类固醇激素的统称,昆虫的蜕皮激素主要由内分泌器官前胸腺合成,具有诱发幼虫周期性蜕皮以及最终变态蜕皮的生理功能.近期的研究工作阐明了前胸腺中原先被称为“黑箱”的一系列酶促反应步骤,此外促前胸腺激素受体的成功鉴定使人们对PTTH信号转导通路调控前胸腺蜕皮激素合成有了更深入的理解.     

蜕皮激素及其对蟹虾养殖业的影响

一、蜕皮激素概况昆虫和甲壳动物蜕皮激素的研究是本世纪四十年代开始的。当时日本学者福田等人曾对家蚕进行结扎、断头及器官移植等试验,发现蚕的前胸腺的分泌活动与蜕皮及变态有着内在的密切联系。1954-1956年,德国卡尔森等从蚕蛹中分离到微量天然蜕皮激素(50mg/1000kg),仅使用0.0075μg就可以使结扎的丽蝇腹部化蛹。1965年,由美国霍夫迈斯特等鉴定了α-蜕皮激素的化学结构,证明它是一种广泛存在于昆虫及甲壳类动物体内的甾族化合物(即类固醇)。后     

RNA干扰对家蚕丝腺蜕皮激素相关基因表达的影响

昆虫变态发育过程中,蜕皮激素通过一系列的激素相关转录因子进行信号的转导和放大,从而完成对生长变态发育的调控,其中蜕皮激素受体(EcR)及转录因子BR-C和E74A可能作为早期因子发挥作用.为了研究这3个早期转录因子在鳞翅目昆虫中的功能,本研究采用体外合成dsRNA的方法,将合成的dsRNA分别注射熟蚕期的家蚕Bomby...     

昆虫成虫蜕皮激素研究进展

绝大多数成体昆虫羽化后,幼虫期间负责蜕皮激素合成的前胸腺即发生退化,但在一些内部生理及外部环境因子的调控下,某些成体组织(如生殖腺)可扮演类似前胸腺的角色合成与分泌蜕皮激素。蜕皮激素的功能发挥是经受体介导的,包括核受体(如EcR/USP)和膜受体(如DopEcR),它们广泛表达于成体许多组织,参与成虫行为、生殖、寿命、滞育及免疫应答等众多方面的调节,对维持基本的生理功能具有重要作用。就成虫蜕皮激素的产生组织及影响其滴度的因素、成虫蜕皮激素受体概述与组织分布、成虫蜕皮激素信号通路的功能发挥等研究进展方面加以综述。     

蜕皮激素及其对蟹虾养殖的影响

蜕皮激素及其对蟹虾养殖的影响房凯（四川绵阳师专生物系）（一）蜕应激素概况昆虫和甲壳动物蜕皮激素的研究是本世纪４０年代开始的。当时日本学者福田等人曾对家蚕进行结扎、断头及器官移植等试验,发现蚕的前胸腺的分泌活动与蜕皮及变态有着内在的密切联系。１９５４～...     

昆虫促前胸腺激素研究进展

昆虫促前胸腺激素研究进展李毅平龚和（中国科学院动物研究所,北京１０００８０）关键词促前胸腺激素受体信号系统促前胸腺激素（ｐｒｏｔｈｏｒａｃｉｃｏｔｒｏｐｉｃｈｏｒ－ｍｏｎｅＰＴＴＨ）因其促进前胸腺（ＰＧ）合成和分泌蜕皮激素而得名,以前也称为脑激素,因...     

桑蚕促前胸腺激素的作用与前胸腺分泌活动的某些特点

本工作以前胸腺的体外器官培养技术和蜕皮激素的放射免疫分析法(MH-RIA)相结合,研究了桑蚕(Bombyx mori)促前胸腺激素(PTTH)的作用与前胸腺分泌的某些特点。结果表明,被PTTH激活后的前胸腺,在一定的时相过程内合成并分泌脱皮甾类激素;前胸腺本体不积累蜕皮甾类激素;PTTH对前胸腺的作用是积累性的;五龄不同天数的前胸腺合成分泌脱皮甾类激素的能力不同,并有不同的剂量反应。     

Identification of a novel prothoracicostatic hormone and its receptor in the silkworm Bombyx mori

The insect brain regulates the activity of the prothoracic glands to secrete ecdysteroids, which affect growth, molting, and metamorphosis. Here we report the identification of a novel prothoracicostatic factor and its receptor in the silkworm Bombyx mori. The prothoracicostatic factor purified from pupal brains of B. mori is a decapeptide with the conserved structure of an insect myosuppressin and thus named Bommo-myosuppressin. Bommo-myosuppressin dose dependently suppressed the cAMP level and inhibited ecdysteroidogenesis in the larval prothoracic glands at much lower concentrations than the prothoracicostatic peptide, the other prothoracicostatic factor reported previously. In vitro analyses using a prothoracic gland incubation method revealed that Bommo-myosuppressin and prothoracicostatic peptide regulate the prothoracic gland activity via different receptors. In situ hybridization and immunohistochemistry revealed the existence of Bommo-myosuppressin in the brain neurosecretory cells projecting to neurohemal organs in which it is stored. We also identified and functionally characterized a specific receptor for Bommo-myosuppressin and showed its high expression in the prothoracic glands. All these results suggest that Bommo-myosuppressin functions as a prothoracicostatic hormone and plays an important role in controlling insect development.     

THE PROTHORACICOSTATIC PEPTIDE THAT INHIBITS ECDYSTEROIDOGENESIS

Abstract  The paper generalizes advances of a new insect brain neuroeptide, prothoracicostatic peptide, which plays an important role in the insect metamorphosis, and was found and identified from silkworn Bombyx mori recent years. The paper intduces its research background, primacy structure, function, mutual relationship between it and prothoracicotmpic hormone as well as the results of molecular biology research. The evaluation and expectation of this peptide are discussed.     

中国昆虫染色体研究现状与展望

简要叙述了中国昆虫染色体研究的现状,包括研究涉及的昆虫类群、核型分析结果、研究方法和手段、染色体有丝分裂、减数分裂、染色体形态变异、结构变异和数量变异等。我国学者对昆虫染色体研究从20世纪30年代开始,迄今已对蜉蝣目、蜚蠊目、直翅目、半翅目、同翅目、鞘翅目、鳞翅目、双翅目、蚤目和膜翅目等10目481种昆虫的核型进行了研究,主要集中在蝗虫、蝽类、蚜虫、蚕类、果蝇、摇蚊及实蝇等。在染色体行为方面的研究主要有：蚕类和果蝇等有丝分裂;蜚蠊类、蝗类、蝽类和蚕类的减数分裂及性别决定机制;部分昆虫的联会复合体分析。染色体结构变异的研究主要集中在果蝇和蚊类昆虫的唾腺染色体;果蝇的B染色体;蚕类和蚊类昆虫染色体的缺失、易位和倒位等变异;蚕蛾类的数量变异。研究结果多应用于昆虫系统分类和进化的探讨,揭示昆虫遗传与变异规律。通过与国外研究成果对比,提出昆虫染色体研究的必要性,并对我国未来昆虫染色体研究进行了展望。     

Bombyx mori prothoracicostatic peptide inhibits ecdysteroidogenesis in vivo

Bombyx prothoracicostatic peptide (Bom-PTSP) is a brain neuropeptide that has recently been reported to have in vitro inhibitory activity to prothoracicotropic hormone (PTTH)-stimulated ecdysteroid biosynthesis in the prothoracic gland of the silkworm, Bombyx mori. In the present report, Bom-PTSP has been shown to significantly decrease hemolymph ecdysteroid titer in the fifth instar larvae when Bom-PTSP was injected into the fifth instar day 8 silkworm larvae, resulting in significant delay in spinning behavior. This is the first evidence that Bom-PTSP inhibits in vivo ecdysteroidogenesis in the silkworm.     

The molecular mechanisms and factors affecting the feeding habits of silkworm (Lepidoptera: Bombyxidae)

Food is critical to the survival and development of insects. Bombyx mori (Lepidoptera: Bombycidae), a Lepidoptera model insect with economic significance, is a well-known oligophagous insect that mainly feeds on mulberry leaves. The feeding characteristics of this particular species provide an excellent model for studying the food selection of insect host plants. In recent years, there has been an increasing number of studies on the factors affecting the feeding of silkworms, especially with the development of molecular technology. Many mysteries have been gradually solved. This paper summarizes and discusses the factors that affect the feeding of silkworms, with a focus on the molecular mechanisms of silkworm feeding. It is hoped that this work will be helpful for further research on artificial diets for silkworms and disease control in lepidopteran insects.     

A novel Rel protein and shortened isoform that differentially regulate antibacterial peptide genes in the silkworm Bombyx mori

Two cDNAs encoding novel Rel proteins were cloned from the silkworm, Bombyx mori. These cDNA clones (BmRelA and BmRelB) showed identical nucleotide sequences except for the 5'-region. BmRelB cDNA derived probably from an alternatively spliced mRNA lacked 241 bp nucleotides at the 5'-region of the BmRelA cDNA, resulting in a loss of the first 52 amino acids. Expression of antibacterial peptide genes was strongly inhibited upon infection with Micrococcus luteus in transgenic silkworms in which BmRel gene expression was knocked down, suggesting that these two Rel proteins are involved in activation of antibacterial peptide genes. Co-transfection experiments indicated that BmRelB activated the Attacin gene strongly and other genes to a lesser extent, whereas BmRelA activated Lebocin 4 gene strongly and Attacin and Lebocin 3 genes very weakly. The Rel homology domain of BmRelA and BmRelB was shown to bind specifically to kappaB sites of antibacterial peptide genes. Proline-rich domains of the BmRels were necessary for activation of antibacterial peptide genes. These results illustrate that a minor structural change in Rel proteins can provoke a dramatic differential activation of antibacterial peptide genes, suggesting a novel regulatory mechanism for insect antibacterial peptide gene expression.     

Identification of a prothoracicostatic peptide in the larval brain of the silkworm, Bombyx mori.

Prothoracicotropic hormone (PTTH) stimulates ecdysteroid biosynthesis in the prothoracic gland (PG) of insects. A peptide inhibiting ecdysteroid biosynthesis in the PG was isolated from the extracts of 2,000 larval brains of the silkworm, Bombyx mori, using a protocol that included four reversed-phase high performance liquid chromatography procedures. The primary structure of this prothoracicostatic peptide (Bom-PTSP) was determined to be H-Ala-Trp-Gln-Asp-Leu-Asn-Ser-Ala-Trp-NH(2). This neuropeptide has the same sequence as Mas-MIP-I, a myoinhibitory peptide previously isolated from the ventral nerve cord of the tobacco hornworm, Manduca sexta, and is highly homologous with the N-terminal portion of vertebrate peptides of the galanin family. This peptide inhibited PTTH-stimulated ecdysteroidogenesis in the PG at both the spinning and feeding stages, which indicates that Bom-PTSP interferes with PTTH-stimulated ecdysteroidogenesis.     

Characterization of anti-CD20 monoclonal antibody produced by transgenic silkworms (Bombyx mori)

In response to the successful use of monoclonal antibodies (mAbs) in the treatment of various diseases, systems for expressing recombinant mAbs using transgenic animals or plants have been widely developed. The silkworm (Bombyx mori) is a highly domesticated insect that has recently been used for the production of recombinant proteins. Because of their cost-effective breeding and relatively easy production scale-up, transgenic silkworms show great promise as a novel production system for mAbs. In this study, we established a transgenic silkworm stably expressing a human-mouse chimeric anti-CD20 mAb having the same amino acid sequence as rituximab, and compared its characteristics with rituximab produced by Chinese hamster ovary (CHO) cells (MabThera®). The anti-CD20 mAb produced in the transgenic silkworm showed a similar antigen-binding property, but stronger antibody-dependent cell-mediated cytotoxicity (ADCC) and weaker complement-dependent cytotoxicity (CDC) compared to MabThera. Post-translational modification analysis was performed by peptide mapping using liquid chromatography/mass spectrometry. There was a significant difference in the N-glycosylation profile between the CHO? and the silkworm-derived mAbs, but not in other post-translational modifications including oxidation and deamidation. The mass spectra of the N-glycosylated peptide revealed that the observed biological properties were attributable to the characteristic N-glycan structures of the anti-CD20 mAbs produced in the transgenic silkworms, i.e., the lack of the core-fucose and galactose at the non-reducing terminal. These results suggest that the transgenic silkworm may be a promising expression system for the tumor-targeting mAbs with higher ADCC activity.     

Characterization of anti-CD20 monoclonal antibody produced by transgenic silkworms (Bombyx mori)

In response to the successful use of monoclonal antibodies (mAbs) in the treatment of various diseases, systems for expressing recombinant mAbs using transgenic animals or plants have been widely developed. The silkworm (Bombyx mori) is a highly domesticated insect that has recently been used for the production of recombinant proteins. Because of their cost-effective breeding and relatively easy production scale-up, transgenic silkworms show great promise as a novel production system for mAbs. In this study, we established a transgenic silkworm stably expressing a human-mouse chimeric anti-CD20 mAb having the same amino acid sequence as rituximab, and compared its characteristics with rituximab produced by Chinese hamster ovary (CHO) cells (MabThera®). The anti-CD20 mAb produced in the transgenic silkworm showed a similar antigen-binding property, but stronger antibody-dependent cell-mediated cytotoxicity (ADCC) and weaker complement-dependent cytotoxicity (CDC) compared to MabThera. Post-translational modification analysis was performed by peptide mapping using liquid chromatography/mass spectrometry. There was a significant difference in the N-glycosylation profile between the CHO− and the silkworm-derived mAbs, but not in other post-translational modifications including oxidation and deamidation. The mass spectra of the N-glycosylated peptide revealed that the observed biological properties were attributable to the characteristic N-glycan structures of the anti-CD20 mAbs produced in the transgenic silkworms, i.e., the lack of the core-fucose and galactose at the non-reducing terminal. These results suggest that the transgenic silkworm may be a promising expression system for the tumor-targeting mAbs with higher ADCC activity.