Peptidic soil components are a major dietary resource for the humivorous larvae of Pachnoda spp. (Coleoptera: Scarabaeidae)

Humivorous scarab beetle larvae can thrive exclusively on soil organic matter. Feeding experiments have revealed that the larva of Pachnoda ephippiata mineralizes all major humus components except the polyphenolic fraction. High proteolytic activity in the alkaline midgut fluid and an enormous ammonia production during gut passage suggested that peptidic soil components are an important dietary resource for the larva. By comparing acid-hydrolyzable amino acids in food soil and feces, we showed that a significant fraction of the peptides in soil are removed during gut passage. This agrees well with the high concentrations of free amino acids found the midgut section. Incubation experiments revealed the presence of substantial particle-associated proteolytic activity also in the hindgut, most probably due to microbial activity. High rates of ammonia formation in hindgut homogenates and the conversion of radiolabeled amino acids to acetate and propionate indicated that microbial fermentations of soil peptides play an important role in the hindgut. This was corroborated by viable counts of amino-acid-fermenting bacteria, which formed a substantial fraction of the hindgut microbiota. A complete inventory of organic and inorganic nitrogen species before, during, and after gut passage revealed the formation of nitrite and nitrate in midgut and hindgut, and a substantial nitrogen deficit in the feces, suggesting that part of the ammonia formed by mineralization is subjected to oxidation and subsequent denitrification to N2. Together, the results strongly support the hypothesis that peptidic soil components form a major energy and nutrient source for humivorous insects, supplying the animal with microbial fermentation products and essential amino acids.     

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.     

A target protease activity of serpins in insect hemolymph

Two zymogens of the serine enzymes (prophenoloxidase activating enzyme and BAEEase, an enzyme hydrolyzing ethyl ester), which are thought to be components of prophenoloxidase cascade in silkworm (Bombyx mori) plasma, were activated through the action of microbial cell wall components. The two active enzymes of the zymogens were studied with regard to the regulation of their activities by two endogenous serpins (silkworm anti-trypsin and silkworm anti-chymotrypsin).

BAEEase activity was shown to be inactivated by silkworm antitrypsin, whereas the inactivation of prophenoloxidase activating enzyme by either of silkworm antitrypsin and silkworm antichymotrypsin could not be demonstrated under the experimental conditions.     

Research progress on the immune mechanism of the silkworm Bombyx mori

The silkworm Bombyx mori L., representing an important economic insect and one of the best models for studying insect immunity, possesses an efficient and sophisticated innate immune system against invasive microorganisms. The innate immune system basically includes humoural immunity and cellular immunity. The humoural immunity, which functions via molecules including humoural factors, lysozymes, phenoloxidase, hemolin, lectins and, in particular, antimicrobial peptides, plays a central role in eliminating the invading pathogens. The cellular immunity is primarily carried out and mediated by plasmatocytes and granular cells of haemocytes in the haemolymph, usually followed by melanization. Additionally, apoptosis, a primary viral defence for insects lacking adaptive immunity, comprises an important part of the silkworm immune system. Currently, there is still the lack of a comprehensive and systematic understanding of the molecular mechanisms of silkworm immunity. We review the latest research progress on silkworm immune mechanisms, including phenoloxidase‐dependent melanization and apoptosis, which is conducive to improving our understanding of the silkworm immune mechanism, clarifying the relationship of various immune mechanisms, and also providing a theoretical basis and reference for the future research of insect immunity.     

黑水虻消化道形态及组织结构的观察

本文比较了不同发育阶段黑水虻Hermetia illucens消化道的形态学差异,掌握了幼虫消化系统的组织学特征。利用体视镜观察黑水虻5龄幼虫、预蛹及成虫的消化道形态,利用光学显微镜和扫描电镜观察幼虫消化道各段(前肠、中肠、后肠)的显微及超微结构。结果表明：黑水虻幼虫及预蛹的消化道均由前肠(食道和前胃)、中肠及后肠组成,从幼虫到成虫,消化道的长度不断缩短。与幼虫和预蛹相比,成虫消化道形态变化明显,前胃消失,出现了嗉囊及胃盲囊,中肠进一步缩短,后肠分化为回肠、结肠和直肠。组织学观察结果显示,幼虫的唾液腺开口于口腔,由膨大的管状腺体和腺管组成。食道由特化为角质刺突的内膜层及发达的肌层组成,其末端延伸至前胃。前胃膨大为球状,包括三层组织结构。根据上皮细胞形态的差异,中肠可分为四个区段。后肠薄,肠腔内褶丰富,肠壁可见数量较多的杆状细菌。马氏管开口于中、后肠交界处,包括4支盲管,管内壁密布微绒毛。黑水虻消化道形态随发育阶段的变化,反映了各阶段摄食及消化生理的差异。幼虫消化道各段具有各自典型的组织学特征,其前、中、后肠可能分别承担了食物接纳与初步消化、消化与吸收以及重吸收功能。本研究结果为进一步了...     

细菌感染后家蚕幼虫中肠差异表达基因的鉴定（英文）

作为遭遇各种微生物的前线, 昆虫的消化道在免疫反应中起到重要的作用。为了研究家蚕Bombyx mori肠道免疫反应, 我们利用基于ACP (annealing control primer)的反转录PCR技术, 从中肠组织中鉴定得到18个在经口器感染绿脓杆菌Pseudomonas aeruginosa 和金黄色葡萄球菌Staphylococcus aureus后的差异表达基因,并利用荧光定量PCR分析了其中4个基因在感染后24 h内的动态变化。结果表明： 肽聚糖识别蛋白-L1（PGRP-L1)和一个丝氨酸蛋白酶前体基因特异性地受绿脓杆菌感染后上调; 30kP蛋白酶A基因受绿脓杆菌和金黄色葡萄球菌2种细菌感染后上调。我们的研究鉴定了经口器感染后家蚕中肠中参与入侵细菌识别和免疫信号途径的基因, 可为对这些基因进一步的功能研究提供线索。     

昆虫肽聚糖识别蛋白研究进展

在脊椎动物和非脊椎动物中,识别非己是天生免疫反应中的第一步。肽聚糖是细菌细胞壁的必需成分,属于进化上保守的微生物表面病原相关分子模式(pathogen-associated molecular pattern, PAMP),可以被模式识别蛋白(pattern recognition proteins, PRRs)如肽聚糖识别蛋白(peptidoglycan recognition proteins, PGRPs)识别。 在昆虫的天生免疫系统中,有些PGRPs能够利用细菌独有的肽聚糖识别入侵细菌,并将细菌入侵信号传递给下游的抗菌肽(antimicrobial peptide, AMP)合成途径,启动抗菌肽基因的转录及合成;PGRPs对肽聚糖的识别也会启动酚氧化酶原途径的激活,引起黑化反应。有些具有酰胺酶活性的PGRPs可以促进吞噬作用;有些可以抑制抗菌肽合成以减弱过度免疫反应带来的损伤。还有一些PGRPs作为效应因子直接作用于细菌将细菌杀死。本文主要从昆虫PGRPs作为识别受体(recognition receptor)、调节子(regulator)和效应因子(effector) 3个方面进行了综述,并分析了目前PGRPs研究中仍不清楚的问题和未来研究的方向。     

Increase in midgut microbiota load induces an apparent immune priming and increases tolerance to Bacillus thuringiensis

The insect immune system is comprised of both humoral and cellular components that are mobilized in response to parasitic or pathogenic infections. Activation of the immune response implies a considerable expenditure of energy and that is why insects rely on inducible pathways that are activated after coming into contact with the pathogenic agent. Known as immune priming, insects can prolong the activation of the immune response and transmit their immune status to the next generation. Starting from a laboratory colony of the lepidopteran Spodoptera exigua and using the lytic zone assay as a measure of the immune status, we selected for a sub‐colony with high levels of immune activity in the absence of external challenging with bacteria. Immune‐activated insect showed characteristics that are typical reported for immune primed insects, such as increased tolerance to pathogens (Bacillus thuringiensis in our case), fitness‐cost associated to the immune status, and maternal transmission of the immune status. However, additional analysis revealed that the selection for the immune‐activated insects was based on the selection of insects carrying a higher bacterial load in the midgut. Our results suggest that activation of the immune system in S. exigua may not only occur as consequence of the immune priming but also from an increase in midgut microbiota load.     

Involvement of MicroRNAs in Infection of Silkworm with Bombyx mori Cytoplasmic Polyhedrosis Virus (BmCPV)

Bombyx mori cytoplasmic polyhedrosis virus (BmCPV) is one of the most important pathogens of silkworm. MicroRNAs (miRNAs) have been demonstrated to play key roles in regulating host-pathogen interaction. However, there are limited reports on the miRNAs expression profiles during insect pathogen challenges. In this study, four small RNA libraries from BmCPV-infected midgut of silkworm at 72 h post-inoculation and 96 h post-inoculation and their corresponding control midguts were constructed and deep sequenced. A total of 316 known miRNAs (including miRNA*) and 90 novel miRNAs were identified. Fifty-eight miRNAs displayed significant differential expression between the infected and normal midgut (P value < = 0.01 and fold change > = 2.0 or < = 0.5), among which ten differentially expressed miRNA were validated by qRT-PCR method. Further bioinformatics analysis of predicted target genes of differentially expressed miRNAs showed that the miRNA targets were involved in stimulus and immune system process in silkworm.     

The larval alimentary canal of the Antarctic insect, Belgica antarctica

On the Antarctica continent the wingless midge, Belgica antarctica (Diptera, Chironomidae) occurs further south than any other insect. The digestive tract of the larval stage of Belgica that inhabits this extreme environment and feeds in detritus of penguin rookeries has been described for the first time. Ingested food passes through a foregut lumen and into a stomodeal valve representing an intussusception of the foregut into the midgut. A sharp discontinuity in microvillar length occurs at an interface separating relatively long microvilli of the stomodeal midgut region, the site where peritrophic membrane originates, from the midgut epithelium lying posterior to this stomodeal region. Although shapes of cells along the length of this non-stomodeal midgut epithelium are similar, the lengths of their microvilli increase over two orders of magnitude from anterior midgut to posterior midgut. Infoldings of the basal membranes also account for a greatly expanded interface between midgut cells and the hemocoel. The epithelial cells of the hindgut seem to be specialized for exchange of water with their environment, with the anterior two-thirds of the hindgut showing highly convoluted luminal membranes and the posterior third having a highly convoluted basal surface. The lumen of the middle third of the hindgut has a dense population of resident bacteria. Regenerative cells are scattered throughout the larval midgut epithelium. These presumably represent stem cells for the adult midgut, while a ring of cells, marked by a discontinuity in nuclear size at the midgut-hindgut interface, presumably represents stem cells for the adult hindgut.     

Bacterial infection of a model insect: Photorhabdus luminescens and Manduca sexta

Invertebrates, including insects, are being developed as model systems for the study of bacterial virulence. However, we understand little of the interaction between bacteria and specific invertebrate tissues or the immune system. To establish an infection model for Photorhabdus, which is released directly into the insect blood system by its nematode symbiont, we document the number and location of recoverable bacteria found during infection of Manduca sexta. After injection into the insect larva, P. luminescens multiplies in both the midgut and haemolymph, only later colonizing the fat body and the remaining tissues of the cadaver. Bacteria persist by suppressing haemocyte-mediated phagocytosis and culture supernatants grown in vitro, as well as plasma from infected insects, suppress phagocytosis of P. luminescens. Using GFP-labelled bacteria, we show that colonization of the gut begins at the anterior of the midgut and proceeds posteriorly. Within the midgut, P. luminescens occupies a specific niche between the extracellular matrix and basal membrane (lamina) of the folded midgut epithelium. Here, the bacteria express the gut-active Toxin complex A (Tca) and an RTX-like metalloprotease PrtA. This close association of the bacteria with the gut, and the production of toxins and protease, triggers a massive programmed cell death of the midgut epithelium.     

Exploiting the potential of insects for in vivo pathogenicity testing of microbial pathogens

Conventional assays for quantifying the virulence of microbial pathogens and mutants have traditionally relied upon the use of a range of mammalian species. A number of workers have demonstrated that insects can be used for evaluating microbial pathogenicity and provide results comparable to those that can be obtained with mammals since one component of the vertebrate immune system, the innate immune response, remains similar to that found in insects. Larvae of the Greater Wax Moth Galleria mellonella have been used to evaluate the virulence of a range of bacterial and fungal pathogens and a correlation with the virulence of these microbes in mice has been established. This review highlights the similarities of the vertebrate and insect innate immune responses to infection and identifies the potential use of insects for the in vivo evaluation of the microbial pathogenicity.     

A villin-like protein in the intestinal brush border of Calliphora vicina R.D. larvae (Diptera : Calliphoridae)

The brush border of the larval midgut and hindgut in Calliphora vicina (Diptera : Calliphoridae) shows a positive staining with a rabbit antiserum directed against pig villin. This protein has been extensively studied in chicken and in several mammals; it is known to bind together the actin filaments of the microvillar cytoskeleton. The presence of a villin-like protein in insect microvilli has never been reported. The immunodetection of villin in both hind- and midgut points out that villin exists in ectodermal tissues as well as in endodermal or mesodermal ones. Moreover, the “insect villin” seems to present the polypeptidic sequence of 13 amino acids, which has been found in both mammalian and avian villin. That may indicate that villin is a conserved molecule in several taxa.     

Immune response to bacteria induces dissemination of Ras-activated Drosophila hindgut cells

Although pathogenic bacteria are suspected contributors to colorectal cancer progression, cancer-promoting bacteria and their mode of action remain largely unknown. Here we report that sustained infection with the human intestinal colonizer Pseudomonas aeruginosa synergizes with the Ras1V12 oncogene to induce basal invasion and dissemination of hindgut cells to distant sites. Cross-talk between infection and dissemination requires sustained activation by the bacteria of the Imd-dTab2-dTak1 innate immune pathway, which converges with Ras1V12 signalling on JNK pathway activation, culminating in extracellular matrix degradation. Hindgut, but not midgut, cells are amenable to this cooperative dissemination, which is progressive and genetically and pharmacologically inhibitable. Thus, Drosophila hindgut provides a valuable system for the study of intestinal malignancies.     

The presence of conifer resin decreases the use of the immune system in wood ants

Abstract.  1. Wood ants ( Formica paralugubris ) incorporate large amounts of solidified conifer resin into their nest, which reduces the density of many bacteria and fungi and protects the ants against some detrimental micro-organisms. By inducing an environment unfavourable to pathogens, the presence of resin may allow workers to reduce the use of their immune system.
2. The present study tested the hypothesis that the presence of resin decreases the immune activity of wood ants. Specifically, three components of the humoral immune defences of workers kept in resin-rich and resin-free experimental nests (antibacterial, lytic, and prophenoloxidase activities) were compared.
3. The presence of resin was associated with reduced bacterial and fungal densities in nest material and with a small decrease in worker antibacterial and lytic activities. The prophenoloxidase activity was very low in all workers and was not affected by the presence of resin.
4. These results suggest that collective medication with resin reduces pathogen pressure, which in turn decreases the use of the inducible part of the immune system. More generally, the use of plant secondary compounds might be an efficient and economical way to fight pathogens.     

Mammalian peptidoglycan recognition protein binds peptidoglycan with high affinity, is expressed in neutrophils, and inhibits bacterial growth

Peptidoglycan recognition protein (PGRP) is conserved from insects to mammals. In insects, PGRP recognizes bacterial cell wall peptidoglycan (PGN) and activates prophenoloxidase cascade, a part of the insect antimicrobial defense system. Because mammals do not have the prophenoloxidase cascade, its function in mammals is unknown. However, it was suggested that an identical protein (Tag7) was a tumor necrosis factor-like cytokine. Therefore, the aim of this study was to identify the function of PGRP in mammals. Mouse PGRP bound to PGN with fast kinetics and nanomolar affinity (K(d) = 13 nm). The binding was specific for polymeric PGN or Gram-positive bacteria with unmodified PGN, and PGRP did not bind to other cell wall components or Gram-negative bacteria. PGRP mRNA and protein were expressed in neutrophils and bone marrow cells, but not in spleen cells, mononuclear cells, T or B lymphocytes, NK cells, thymocytes, monocytes, and macrophages. PGRP was not a PGN-lytic or a bacteriolytic enzyme, but it inhibited the growth of Gram-positive but not Gram-negative bacteria. PGRP inhibited phagocytosis of Gram-positive bacteria by macrophages, induction of oxidative burst by Gram-positive bacteria in neutrophils, and induction of cytokine production by PGN in macrophages. PGRP had no tumor necrosis factor-like cytotoxicity for mammalian cells, and it was not chemotactic on its own or in combination with PGN. Therefore, mammalian PGRP binds to PGN and Gram-positive bacteria with nanomolar affinity, is expressed in neutrophils, and inhibits growth of bacteria.     

昆虫天然免疫反应分子机制研究进展

昆虫体内缺乏高等脊椎动物所具有的获得性免疫系统, 只能依赖发达的天然免疫系统抵抗细菌、 真菌、 病毒等外源病原物的侵染。本文概括了昆虫天然免疫反应发生和作用的分子机制相关进展, 重点阐述了重要免疫相关因子在昆虫天然免疫反应中的功能和作用机制。昆虫天然免疫反应分为体液免疫和细胞免疫两种, 二者共同作用完成对病原物的吞噬 (phagocytosis)、 集结 (nodulation)、 包囊 (encapsulation)、 凝结 (coagulation)和黑化（melanization）等。当昆虫受到外界病原物的侵染时, 首先通过体内的模式识别蛋白（pattern recognition proteins/receptor, PRPs）识别并结合病原物表面特有的模式分子（pathogen-associated molecular pattern, PAMPs）, 继而一系列包括丝氨酸蛋白酶和丝氨酸蛋白酶抑制剂在内的级联激活反应被激活和调控, 产生抗菌肽、 黑色素等免疫效应分子, 清除或杀灭外源物。抗菌肽是一类小分子量的阳离子肽, 具有广谱抗菌活性, 针对不同类型的病原物, 抗菌肽的产生机制也不尽相同。昆虫体内存在着两种信号转导途径调节抗菌肽的产生： 一是由真菌和大部分革兰氏阳性菌激活的Toll途径; 二是由革兰氏阴性菌激活的Imd途径（immune deficiency pathway）。这两个途径通过激活不同转录因子调控不同抗菌肽基因的表达参与昆虫体内的天然免疫反应。     

An Insect Multiligand Recognition Protein Functions as an Opsonin for the Phagocytosis of Microorganisms

We characterize a novel pathogen recognition protein obtained from the lepidopteran Galleria mellonella. This protein recognizes Escherichia coli, Micrococcus luteus, and Candida albicans via specific binding to lipopolysaccharides, lipoteichoic acid, and β-1,3-glucan, respectively. As a multiligand receptor capable of coping with a broad variety of invading pathogens, it is constitutively produced in the fat body, midgut, and integument but not in the hemocytes and is secreted into the hemolymph. The protein was confirmed to be relevant to cellular immune response and to further function as an opsonin that promotes the uptake of invading microorganisms into hemocytes. Our data reveal that the mechanism by which a multiligand receptor recognizes microorganisms contributes substantially to their phagocytosis by hemocytes. A better understanding of an opsonin with the required repertoire for detecting diverse invaders might provide us with critical insights into the mechanisms underlying insect phagocytosis.