水稻螟虫神经肽PBAN及其受体序列的生物信息学分析

【目的】性信息素合成激活肽(PBAN)是控制昆虫产生性信息素的激素,本文旨在分析水稻螟虫神经肽PBAN及其受体的序列。【方法】通过t Blastn同源检索从水稻螟虫基因组和转录组数据库中鉴定水稻螟虫PBAN神经肽及其受体序列,在此基础上进行序列比对及系统发生分析。【结果】发现二化螟Chilo suppressalis、三化螟Tryporyza incertulas和大螟Sesamia inferens的PBAN成熟肽序列均含有33个氨基酸残基,其C端五肽序列完全相同,3种水稻螟虫PBAN多肽相似度为54.55%~63.64%;发现二化螟PBAN受体3个异构体全长氨基酸序列(PBANR-A、PBANR-B和PBANR-C),均含有7个跨膜区域。【结论】进化树分析发现不同昆虫PBAN神经肽及其受体存在一定的保守性和多样性,并且在进化树上的位置几乎与昆虫系统发育分类一致,推测PBAN神经肽和PBAN受体在昆虫系统进化过程中可能存在协同进化现象。本研究为水稻螟虫PBAN神经肽及其受体的结构和功能分析提供基础。     

昆虫神经肽PBAN的细胞内信号转导

昆虫性信息素多数为长链的不饱和醇、醋酸酯、醛或酮类,链长一般为10-20碳,主要在性信息素腺体内由乙酰辅酶A经过脂肪酸合成、碳链缩短、去饱和以及碳酰基的还原修饰等步骤合成的;而性信息素合成激活肽(pheromone biosynthesis activating neuropeptide,PBAN)是由昆虫食管下神经节中的部分神经细胞合成和分泌的神经肽,通常由33个氨基酸组成,在C-末端有一个相同的五肽序列,主要调控性信息素的生物合成。有关PBAN的细胞内信号转导是近几年的研究热点,研究显示 PBAN首先与性信息素腺体细胞表面的G蛋白偶联受体结合,随后依据昆虫种类的不同,其细胞内信号转导方式主要有三种:(1)以cAMP信号传导途径进行信号转导;(2)以cAMP和磷脂酰肌醇信号传导途径共同进行信号转导;(3)主要以Ca2 为第二信使进行信号传导。     

铃夜蛾属昆虫性信息素生物合成及内分泌调控

综述了铃夜蛾属Helicoverpa昆虫性信息素生物合成途径及内分泌因子的调控作用 ,包括信息素生物合成激活神经肽 (PBAN)和信息素生物合成抑制肽 (PSP)等的来源、结构和作用机制及一些种中保幼激素 (JH)和章鱼胺 (OA)对性信息素生物合成的作用 ,并展望了未来的研究方向。     

家蚕FXPRL神经肽前体基因的体外转录

昆虫滞育激素（Ｄｉａｐａｕｓｅｈｏｒｍｏｎｅ：ＤＨ）、性信息素合成激活肽（Ｐｈｅｒｏｍｏｎｅｂｉｏｓｙｎｔｈｅｓｉｓａｃｔｉｖａｔｉｎｇｎｅｕｒｏｐｅｐｔｉｄｅ：ＰＢＡＮ）是诱导昆虫滞育和性信息素（Ｓｅｘｐｈｅｒｏｍｏｎｅ）合成的两个重要神经肽［１...     

昆虫神经肽研究进展

近年来鉴定了化学结构的昆虫神经肽数目呈快速上升趋势, 家蚕滞育激素和性信息素合成激活肽被分离纯化.三种近年出现的研究方法对寻找新型昆虫神经肽起到重要作用,已经成功地鉴定了数个新型神经肽.昆虫神经肽cDNA或基因组DNA克隆显示了新的结构信息和神经肽间的相互关系.     

家蚕滞育激素-性信息素合成激活肽基因表达的调节

滞育激素和性信息素合成激活肽是两个重要的昆虫神经肽,这两个神经肽由一个基因编码．利用分子杂交和ＲＴ－ＰＣＲ技术,确定了滞育激素－性信息素合成激活肽基因表达的调节不属于转录后的调节,推定为翻译后形成一个大的前体多肽再剪接为几个成熟的神经肽分子．     

PBAN及其对昆虫性外激素的调控

本文综述了性外激素生物合成激活神经肽 (PBAN)及其对昆虫尤其是鳞翅目昆虫性外激素产生的调控 ,包括PBAN的结构、产生、转运、作用方式及保幼激素和蜕皮激素对性外激素合成的作用 ,并展望了未来的研究方向。     

家蚕神经肽及其受体的功能和信号转导机制研究进展

神经肽是一类由神经分泌细胞分泌、用于调节生物胞间信号传递的信号分子,其信号分子的膜定位、相应胞内信使的激活以及一系列级联反应的引发,是由存在于细胞表面的特异性受体分子来完成的。神经肽及其受体能够调控昆虫的几乎所有生命活动,在昆虫生长发育中起着关键作用。家蚕Bombyx mori作为鳞翅目昆虫的模式物种,是昆虫生长发育与生理学研究的重要模型。特别是家蚕基因组测序完成后,越来越多的家蚕神经肽及其受体被鉴定,并发现其在家蚕的生长发育、取食消化、蜕皮、滞育、繁殖、吐丝结茧等各种生理活动中都发挥了重要的调节作用。本文综述了家蚕重要神经肽的种类及其对家蚕取食消化、蜕皮变态、生殖发育等的调控作用,探讨了神经肽通过结合特异性受体而激活细胞内ERK、TOR等下游信号通路的分子作用机制,以期为昆虫神经肽及其受体研究提供借鉴和参考,并以此推进家蚕功能基因的研究,促进蚕丝产业的发展。     

烟夜蛾雄蛾性附腺因子对雌蛾性信 息素合成的抑制作用

烟夜蛾Helicoverpa assulta处女蛾在交配后1 h,其性信息素滴度即显著降低,72 h内未见恢复。生测结果表明,烟夜蛾性信息素合成抑制因子主要来源于雄蛾性附腺。不同日龄雄蛾性附腺提取物的抑制活性无显著差异。光暗期对其活性具显著影响,暗期中雄蛾的性附腺物质对雌蛾性信息素合成具有较强抑制作用,而光期中雄蛾的性附腺物质不具抑制活性。在暗期的不同时间处理,对处女蛾性信息素合成的抑制作用无显著差异。雄蛾性附腺提取物对雌蛾性信息素合成的抑制作用与注射剂量有明显的相关性,0.2 ME（雄蛾当量）是产生显著抑制作用的最小剂量。对交配雌蛾注射性信息素生物合成激活神经肽（PBAN）提取物后,其性信息素合成又可恢复,这说明雌蛾交配后,性信息素滴度降低的原因是由于缺少了PBAN的调控。     

家蚕滞育的分子机理2.蛹期滞育激素基因的表达与滞育决定

滞育激素是由食道下神经节分泌的重要昆虫神经肽,诱导昆虫的滞育。选择具有ＲＮＡ聚合酶能够识别的启动子的质粒载体,将滞育激素ｃＤＮＡ克隆进去,在体外大量合成单一的滞育激素ｃＲＮＡ为参照,测定食道下神经节分泌滞育激素ｍＲＮＡ量来确定滞育激素的分泌量。结果证明食道下神经节分泌的滞育激素的数量决定昆虫的滞育。     

An FXPRLamide neuropeptide induces seasonal reproductive polyphenism underlying a life-history tradeoff in the tussock moth

The white spotted tussock moth, Orgyia thyellina, is a typical insect that exhibits seasonal polyphenisms in morphological, physiological, and behavioral traits, including a life-history tradeoff known as oogenesis-flight syndrome. However, the developmental processes and molecular mechanisms that mediate developmental plasticity, including life-history tradeoff, remain largely unknown. To analyze the molecular mechanisms involved in reproductive polyphenism, including the diapause induction, we first cloned and characterized the diapause hormone-pheromone biosynthesis activating neuropeptide (DH-PBAN) cDNA encoding the five Phe-X-Pro-Arg-Leu-NH(2) (FXPRLa) neuropeptides: DH, PBAN, and α-, β-, and γ-SGNPs (subesophageal ganglion neuropeptides). This gene is expressed in neurosecretory cells within the subesophageal ganglion whose axonal projections reach the neurohemal organ, the corpus cardiacum, suggesting that the DH neuroendocrine system is conserved in Lepidoptera. By injection of chemically synthetic DH and anti-FXPRLa antibody into female pupae, we revealed that not only does the Orgyia DH induce embryonic diapause, but also that this neuropeptide induces seasonal polyphenism, participating in the hypertrophy of follicles and ovaries. In addition, the other four FXPRLa also induced embryonic diapause in O. thyellina, but not in Bombyx mori. This is the first study showing that a neuropeptide has a pleiotropic effect in seasonal reproductive polyphenism to accomplish seasonal adaptation. We also show that a novel factor (i.e., the DH neuropeptide) acts as an important inducer of seasonal polyphenism underlying a life-history tradeoff. Furthermore, we speculate that there must be evolutionary conservation and diversification in the neuroendocrine systems of two lepidopteran genera, Orgyia and Bombyx, in order to facilitate the evolution of coregulated life-history traits and tradeoffs.     

The diapause hormone-pheromone biosynthesis activating neuropeptide gene of Helicoverpa armigera encodes multiple peptides that break, rather than induce, diapause

FXPRLamide peptides encoded by the DH-PBAN (diapause hormone-pheromone biosynthesis activating neuropeptide) gene induce embryonic diapause in Bombyx mori, but terminate pupal diapause in Helicoverpa armigera (Har). Here, we explore the mechanisms of terminating pupal diapause by the FXPRLamide peptides. Using quantitative RT-PCR, we observed that expression of Har-DH-PBAN mRNA in the SG of nondiapause-type pupae was significantly higher than in diapause-type pupae. Immunocytochemical results indicated that the level of FXPRLamide peptides and axonal release are related to the diapause decision. Ecdysteroidogenesis in prothoracic glands (PGs) was stimulated by synthetic Har-DH in vivo and in vitro, and labeled Har-DH bound to the membrane of the PG, thus suggesting that DH breaks diapause by activating the PG to synthesize ecdysone. Furthermore, the response of DH in terminating diapause was temperature dependent. Decerebration experiments showed that the brain can control pupal development through the regulation of DH, and DH can terminate diapause and promote development without the brain. This result suggests a possible mechanism of response for the signals of DH and other FXPRLamide peptides in H. armigera.     

Physiological differentiation of DH-PBAN-producing neurosecretory cells in the silkworm embryo

Embryonic diapause of the silkworm, Bombyx mori, is induced by a neuropeptide hormone, the diapause hormone (DH), which is secreted from a limited number of neurosecretory cells in the subesophageal ganglion (SG) at the maternal generation. We examined the developmental fate of the hormone-producing cell (DH-pheromone biosynthesis activating neuropeptide [PBAN]-producing cell) in the embryonic stage at the level of gene expression and cell biology. The DH-PBAN gene expression started at the histogenesis stage and gradually increased toward hatching. DH is an amidated peptide belonging to FXPRLamide family. The immunoreactive somata against anti FXPRLamide antiserum were found in the SG from blastokinesis. Immunoreactive neural processes with varicosites were also found on the corpus cardiacum and the corpus allatum. The implantation of a part of a developing embryo including the SG into the pupae with the SG removed induced diapause eggs in the progeny. These results were obtained from eggs incubated under diapause-averting conditions as well as diapause-inducing conditions. Thus, a neurosecretory system responsible for biosynthesis of FXPRLamide neuropeptides is established as early as histogenesis, although the system to regulate the secretion of neuropeptide hormones has not been fully formed by that time.     

Immunoreactive intensity of FXPRL amide neuropeptides in response to environmental conditions in the silkworm, Bombyx mori

In the silkworm Bombyx mori, the diapause hormone-pheromone biosynthesis activating neuropeptide gene, DH-PBAN, is a neuropeptide gene that encodes a polypeptide precursor consisting in five Phe-X-Pro-Arg-Leu-NH₂ (FXPRL) amide (FXPRLa) neuropeptides; DH (diapause hormone), PBAN (pheromone-biosynthesis-activating neuropeptide) and α-, β- and γ-SGNPs (subesophageal ganglion neuropeptides). These neuropeptides are synthesized in DH-PBAN-producing neurosecretory cells contained within three neuromeres, four mandibular cells, six maxillary cells, two labial cells (SLb) and four lateral cells of the subesophageal ganglion. DH is solely responsible, among the FXPRLa peptide family, for embryonic diapause. Functional differentiation has been previously suggested to occur at each neuromere, with the SLb cells releasing DH through brain innervation in order to induce embryonic diapause. We have investigated the immunoreactive intensity of DH in the SLb when thermal (25°C or 15°C) and light (continuous illumination or darkness) conditions are altered and following brain surgery that induces diapause or non-diapause eggs in the progeny. We have also examined the immunoreactivity of the other FXPRLa peptides by using anti-β-SGNP and anti-PBAN antibodies. Pupal SLb somata immunoreactivities seem to be affected by both thermal and light conditions during embryogenesis. Thus, we have been able to identify a close correlation between the immunoreactive intensity of neuropeptides and environmental conditions relating to the determination of embryonic diapause in B. mori.     

Roe deer on ice: Selection despite limited effective population size through the Pleistocene

Roe deer (Capreolus spp.) are a little odd. They are one of only a few placental mammals—and the only genus among even‐toed ungulates—capable of putting embryonic development “on ice”, also known as embryonic diapause (Figure 1). It would seem such an unusual trait is probably the product of natural selection, but a big question is, how does selection for important traits, such as diapause, interact with the historical demography of a species? In a ‘From the Cover’ article in this issue of Molecular Ecology, de Jong et al. (2020) demonstrate that selection is acting on genes associated with reproductive biology in roe deer, despite heightened genetic drift due to reduced effective population size through the Pleistocene.     

G protein-coupled receptor for diapause hormone, an inducer of Bombyx embryonic diapause

Bombyx diapause hormone was the first chemical substance identified as a maternal control factor that arrests offspring development. However, the molecular mechanisms by which the hormone transduces the signal to the oocyte that induces embryonic diapause immediately after mesoderm segmentation are not fully understood. Here, we describe a cDNA for a G protein-coupled diapause hormone receptor with seven transmembrane domains. Its amino-acid sequence shows a high level of similarity to the receptors of mammalian neuromedin U and insect regulatory peptide, an FXPRL-amide C-terminus. When expressed in a Xenopus oocyte system, the receptor exhibited the highest affinity (EC(50), approximately 70nM) for diapause hormone, when compared with other Bombyx FXPR/KL-amide peptides. Diapause hormone without amidation at the C-terminus, which never induces embryonic diapause in vivo, had no effect in this heterologous expression system. The mRNA is expressed in the ovaries during Bombyx pupal-adult development. These results strongly indicate that the cDNA encodes the diapause hormone receptor.     

cDNA cloning and sequence determination of the pheromone biosynthesis activating neuropeptide of the silkworm, Bombyx mori.

We have identified the cDNAs encoding pheromone biosynthesis activating neuropeptide (PBAN) using PCR technique. The nucleotide sequence showed that the PBAN gene encodes, besides PBAN, diapause hormone and three putative amidated peptides. These four peptides share with PBAN the C-terminal pentapeptide amide which is corresponding to the shortest fragment with pheromonotropic activity. The organization of the PBAN gene is characteristic of several short neuropeptides and has some degree of similarity to that of the gene for the insect neuropeptide FMRFamide. Thus, the PBAN gene products construct a family of structurally related peptides and have various biological functions.