昆虫体内的天然屏障——围食膜

昆虫围食膜是由昆虫中肠上皮细胞分泌的非细胞薄膜状结构,主要成份是几丁质、蛋白质和多糖,是昆虫抵御外界侵害的第一道天然屏障,能够保护中肠上皮细胞不受机械损伤并且能够抵御病毒、细菌及其他有害物质,防止化学损伤.昆虫病毒增效蛋白、荧光增白剂和几丁质酶等生物防治促进因子通过与围食膜上特异位点的结合,能够破坏围食膜结构,加速病原微生物对害虫的感染进程.就围食膜组分、结构、功能以及与害虫防治的关系等方面的研究进展进行综述,并且论述了以围食膜为害虫生物防治靶标的应用前景.     

昆虫围食膜的研究进展

围食膜是大多数昆虫中肠内的半透性薄膜 ,主要由几丁质、蛋白质构成。依据其形成的方式分 :Ⅰ型围食膜 ,由整个中肠细胞分泌形成多层管状膜 ;Ⅱ型围食膜由中肠前端特殊的细胞分泌成连续的套筒管状膜。由于位于食物与中肠上皮细胞间而在中肠生理中起重要作用 ,围食膜保护中肠上皮免于机械损伤以及病原菌、毒素的入侵 ;作为半透膜以及将中肠分为不同的区室而在营养物质的消化和吸收中具有重要作用。该文综述了有关围食膜结构、组分、功能、通透性以及与害虫防治的关系等方面的研究进展。     

昆虫几丁质酶及其在害虫防治中的应用

几丁质是昆虫重要的结构性组分,在昆虫生长发育的各个时期都需要一定量的几丁质来维持其代谢平衡.昆虫几丁质酶可以降解昆虫体壁和围食膜中的几丁质,作为一种潜在的生物杀虫剂在害虫防治方面具有广阔的应用前景.随着对昆虫几丁质酶研究的不断深入,目前已克隆到了30余种昆虫几丁质酶,并应用于转基因作物和基因工程微生物中,对害虫具有一定...     

舞毒蛾几丁质酶基因的真核表达与重组病毒的获得

几丁质是昆虫外骨骼和围食膜的重要组成部分,鉴于几丁质酶在昆虫生长发育过程中发挥着举足轻重的作用,应用昆虫几丁质酶为探索新的生物防治害虫的方法提供了途径。本文分别根据苜蓿银纹夜蛾Autographa californica核型多角体病毒多角体蛋白基因序列和编码舞毒蛾Lymantria disparⅠ型几丁质酶基因的开放阅读框设计引物,使用聚合酶链反应扩增出以上两个基因,全长分别为783 bp和1 737 bp。构建重组质粒pFastBac-LdCht和pFastBac-AcPH-LdCht,转化大肠杆菌DH10Bac后获得重组穿梭载体,通过脂质体介导转染Sf9细胞产生重组杆状病毒AcMNPV-AcPH--LdCht和AcMNPV-LdCht,分别用于表达蛋白和获得重组病毒。细胞成功表达出有活性的舞毒蛾几丁质酶,并在棉铃虫体内扩增得到重组病毒。研究为深入了解昆虫几丁质酶性质提供依据,并为应用重组病毒奠定基础。     

昆虫中肠围食膜蛋白研究进展

围食膜是大多数昆虫中肠内壁附着的一层起润滑和保护作用的半透性粘膜, 按其形成方式不同分为Ⅰ型围食膜和Ⅱ型围食膜。围食膜主要由几丁质和蛋白质构成, 其中蛋白质对于维持围食膜的致密结构至关重要, 对围食膜蛋白的破坏可能会对昆虫的正常生长发育造成干扰, 甚至会导致低龄幼虫的死亡。本文介绍了围食膜的组成与结构, 阐述了昆虫围食膜蛋白研究的新发现、并依据结构特征对它们进行了分类, 总结了以围食膜蛋白为新靶标的害虫防治的可能途径, 讨论了当前围食膜蛋白研究的不足, 最后展望了今后围食膜蛋白研究的发展方向。     

昆虫几丁质合成及其调控研究前沿

几丁质合成与降解是昆虫最重要的生理过程之一。本文根据国外和作者自己的研究,综述了昆虫几丁质合成及其调控研究进展。昆虫几丁质的生物合成通路始于海藻糖,终止于几丁质,其中共有8个酶参与。目前研究最多的为海藻糖酶和几丁质合成酶。昆虫存在2个海藻糖酶基因和2个几丁质合成酶基因。可溶性海藻糖酶基因对昆虫表皮的几丁质合成影响更大,而膜结合海藻糖酶基因则主要影响中肠的几丁质合成。几丁质合成酶A主要负责表皮和气管几丁质的合成,而几丁质合成酶B则负责中肠围食膜的几丁质合成。目前,昆虫几丁质合成的调控途径主要有两种:利用RNAi技术和几丁质合成抑制剂。     

棉铃虫围食膜肠粘蛋白基因HM72的克隆、表达及其蛋白组织定位

围食膜是昆虫中肠上皮细胞分泌形成一层特有的非细胞性半透膜, 肠粘蛋白是其重要的组成成分。本研究利用棉铃虫Helicoverpa armigera围食膜蛋白多克隆抗体免疫筛选棉铃虫中肠cDNA表达文库,共获得385个阳性克隆, 经DNA测序和序列对比, 确认其中之一为编码棉铃虫中肠围食膜肠粘蛋白的cDNA克隆HM72。序列分析显示,该cDNA全长为2 888 bp (GenBank登录号： HM017910), 其中ORF长2 469 bp, 编码823个氨基酸, 包含起始密码子ATG和终止密码子TAA,在poly A 末端上游19 bp处有一个多聚腺苷酸信号序列AATTAA。氨基酸序列分析表明, 其N-端含有16个氨基酸的信号肽, 预测分子量为84.2 kDa,等电点3.63,为酸性蛋白质。结构域分析表明,该蛋白具有5个几丁质结合功能域,一个粘蛋白结构域和两个甘氨酸-天冬氨酸富集区,该基因成功表达100 kDa的目的蛋白。Western blot分析表明,HM72蛋白存在于棉铃虫中肠、围食膜、粪便及蜕中,并由整个中肠分泌,而在棉铃虫脂肪体、体壁、马氏管、唾腺、消化液、血淋巴中没有检测到HM72蛋白。本研究为棉铃虫生物防治相关功能基因的深入研究以及完善昆虫围食膜理论等提供了依据。     

棉铃虫围食膜的蛋白质组鉴定

【目的】围食膜(peritrophic membrane, PM)是昆虫抵御随食物摄入的病原微生物入侵的第一道天然屏障。本研究旨在鉴定出农业重大害虫棉铃虫Helicoverpa armigera围食膜的总蛋白成分,为进一步揭示昆虫围食膜的形成机制及研发新颖的害虫控制策略奠定基础。【方法】剥离棉铃虫5龄幼虫PM,用三氟甲磺酸(trifluoromethane sulfonic acid, TFMS)处理,采用液质联用技术(LC-MS/MS)鉴定围食膜蛋白质组,然后对鉴定结果进行生物信息学分析。【结果】本研究共鉴定出棉铃虫幼虫围食膜蛋白质169个,是目前鉴定最多的棉铃虫围食膜蛋白。通过GO分析,可以将这些鉴定的蛋白分为细胞组分、分子功能和生物学过程三大类;KEGG富集结果显示,鉴定蛋白可以富集在12条代谢通路中;蛋白互作分析(protein protein interaction, PPI)结果表明,以ACC和CG3011等蛋白为核心可以形成蛋白互作网络。【结论】本研究鉴定了169个棉铃虫幼虫围食膜蛋白质,并对其进行了GO, KEGG和PPI分析,结果有助于人们全面理解昆虫围食膜的分子结构和功能。     

昆虫几丁质酶基因的分子特性概述

昆虫几丁质酶是分解昆虫体壁和中肠围食膜几丁质的重要酶类。已从烟草天蛾、家蚕等多种昆虫中分离到几丁质酶的cDNA和DNA序列。昆虫几丁质酶基因有着相似的分子特性,这些特性可为构建杀虫工程菌及转几丁质酶基因植物奠定基础。作者结合自己在该领域的工作,着重就昆虫几丁质酶基因结构特点,基因的拷贝数,基因在体内的时空表达以及异源表达及活性测定等多个方面的研究方法和研究进展进行了较为全面地介绍。     

昆虫病原真菌紫外线诱变育种研究进展

昆虫病原真菌是控制害虫发生与危害的重要生物防治因子之一,优良的菌种是生物防治的关键。紫外线诱变育种是昆虫病原真菌菌种选育中最常用的方法之一,具有易操作、效果好、作用时间长等优点。本文以白僵菌、绿僵菌、玫烟色棒束孢等三种常用的昆虫病原真菌为例,从诱变育种的材料、方法和应用等方面综述了昆虫病原真菌紫外线诱变育种的研究现状,以期为昆虫病原真菌的生物防治研究提供参考。     

Calcofluor disrupts the midgut defense system in insects

The insect midgut is generally lined with a unique protective chitin/protein structure, the peritrophic membrane (PM). We demonstrated that in Trichoplusia ni larvae, the majority of PM proteins were assembled with chitin as a consequence of their chitin binding properties. These proteins could be dissociated from the PM in vitro by Calcofluor, a well-known chemical with chitin binding properties. The chitin binding characteristics of PM proteins were confirmed by their high affinity binding in vitro to regenerated chitin. In vivo assays demonstrated that Calcofluor could inhibit PM formation in five lepidopteran insects tested. The inhibition of T. ni PM formation by Calcofluor, was accompanied by increased larval susceptibility to baculovirus infection. Continuous inhibition of PM formation by Calcofluor resulted in retarded larval development and mortality. The destructive effect of Calcofluor on PM formation was demonstrated to be transient and reversible depending on the presence of Calcofluor within the midgut. In addition, degradation of the insect intestinal mucin was observed concurrently with the inhibition of PM formation by Calcofluor. Our studies revealed a potential novel approach to develop strategies for insect control by utilizing chitin binding molecules to specifically target PM formation in a broad range of insect pest species.     

Spindles of an entomopoxvirus facilitate its infection of the host insect by disrupting the peritrophic membrane

The mode of action by which entomopoxvirus (EPV) spindles, proteinaceous crystalline bodies produced by EPVs, enhance EPV infection has not been clarified. We fed Anomala cuprea EPV (AcEPV) spindles to host insects; subsequent scanning electron microscopy revealed the disruption of the peritrophic membranes (PMs) of these insects. The PM is reportedly a barrier against the infection of some insects by viruses. Quantitative PCR of AcEPV DNA in the ectoperitrophic area revealed that PM disruption facilitated the passage of EPVs through the PM toward the initial infection site, the midgut epithelium. These results indicate that EPV spindles enhance infection by EPVs by disrupting the PM in the host insects. Fusolin is almost exclusively the constituent protein of the spindles and is the enhancing factor of the infectivity of nucleopolyhedroviruses (NPVs) and possibly that of EPVs. Spheroid is another type of proteinaceous crystalline structure produced by EPVs. Pseudaletia separata EPV (PsEPV) spheroids reportedly contain considerable amounts of fusolin and enhance NPV infection. We assessed the ability of AcEPV spheroids to enhance EPV infectivity and their effect on the PM and carried out immunological experiments; these experiments showed that AcEPV spheroids contain little or no fusolin and are biologically inactive, in contrasts to the situation in PsEPV.     

Identification of the Mamestra configurata (Lepidoptera: Noctuidae) peritrophic matrix proteins and enzymes involved in peritrophic matrix chitin metabolism

The peritrophic matrix (PM) is essential for insect digestive system physiology as it protects the midgut epithelium from damage by food particles, pathogens, and toxins. The PM is also an attractive target for development of new pest control strategies due to its per os accessibility. To understand how the PM performs these functions, the molecular architecture of the PM was examined using genomic and proteomic approaches in Mamestra configurata (Lepidoptera: Noctuidae), a major pest of cruciferous oilseed crops in North America. Liquid chromatography‐tandem mass spectrometry analyses of the PM identified 82 proteins classified as: (i) peritrophins, including a new class with a CBDIII domain; (ii) enzymes involved in chitin modification (chitin deacetylases), digestion (serine proteases, aminopeptidases, carboxypeptidases, lipases and α‐amylase) or other reactions (β‐1,3‐glucanase, alkaline phosphatase, dsRNase, astacin, pantetheinase); (iii) a heterogenous group consisting of polycalin, REPATs, serpin, C‐Type lectin and Lsti99/Lsti201 and 3 novel proteins without known orthologs. The genes encoding PM proteins were expressed predominantly in the midgut. cDNAs encoding chitin synthase‐2 (McCHS‐2), chitinase (McCHI), and β‐N‐acetylglucosaminidase (McNAG) enzymes, involved in PM chitin metabolism, were also identified. McCHS‐2 expression was specific to the midgut indicating that it is responsible for chitin synthesis in the PM, the only chitinous material in the midgut. In contrast, the genes encoding the chitinolytic enzymes were expressed in multiple tissues. McCHS‐2, McCHI, and McNAG were expressed in the midgut of feeding larvae, and NAG activity was present in the PM. This information was used to generate an updated model of the lepidopteran PM architecture.     

The origin and functions of the insect peritrophic membrane and peritrophic gel

There is a a fluid (peritrophic gel) or membranous (peritrophic membrane, PM) film surrounding the food bolus in most insects. The PM is composed of chitin and proteins, of which peritrophins are the most important. It is proposed here that, during evolution, midgut cells initially synthesized chitin and peritrophins derived from mucins by acquiring chitin-binding domains, thus permitting the formation of PM. Since PM compartmentalizes the midgut, new physiological roles were added to those of the ancestral mucus (protection against abrasion and microorganism invasion). These new roles are reviewed in the light of data on PM permeability and on enzyme compartmentalization, fluid fluxes, and ultrastructure of the midgut. The importance of the new roles in relation to those of protection is evaluated from data obtained with insects having disrupted PM. Finally, there is growing evidence suggesting that a peritrophic gel occurs when a highly permeable peritrophic structure is necessary or when chitin-binding molecules or chitinase are present in food.