CecC, a cecropin gene expressed during metamorphosis in Drosophila pupae.

Cecropins are antibacterial peptides, induced in insects in response to bacterial infections. In Drosophila, three cecropin genes have previously been characterized, CecA1, CecA2, and CecB, in a dense cluster at 99E on the third chromosome. From the same locus, we now describe a fourth member of the cecropin gene family, CecC, which is mainly expressed at the early pupal stage. In situ hybridization to immunized pupae show that CecC is induced in the anterior end of the larval hindgut and in other larval tissues that are undergoing histolysis. Within these other tissues it is often expressed in distinct foci that may correspond to hemocytes. A similar pattern of expression in the metamorphosing pupa is also observed for the CecA and CecB genes. Comparing the DNA sequences of the cecropin genes, a conserved region is observed about 30 bp upstream of the TATA box. It consists of three shorter motifs, two of which are reminiscent of a putative promoter element in immune protein genes from the cecropia moth.     

Molecular Population Genetics of Drosophila Immune System Genes

A striking aspect of many vertebrate immune system genes is the exceptionally high level of polymorphism they harbor. A convincing case can be made that this polymorphism is driven by the diversity of pathogens that face selective pressures to evade attack by the host immune system. Different organisms accomplish a defense against diverse pathogens through mechanisms that differ widely in their requirements for specific recognition. It has recently been shown that innate defense mechanisms, which use proteins with broad-spectrum bactericidal properties, are common to both primitive and advanced organisms. In this study we characterize DNA sequence variation in six pathogen defense genes of Drosophila melanogaster and D. mauritiana, including Andropin; cecropin genes CecA1, CecA2, CecB, and CecC; and Diptericin. The necessity for protection against diverse pathogens, which themselves may evolve resistance to insect defenses, motivates a population-level analysis. Estimates of variation levels show that the genes are not exceptionally polymorphic, but Andropin and Diptericin have patterns of variation that differ significantly from neutrality. Patterns of interpopulation and interspecific differentiation also reveal differences among the genes in evolutionary forces.     

Insect Cytokine Paralytic Peptide (PP) Induces Cellular and Humoral Immune Responses in the Silkworm Bombyx mori

In the blood (hemolymph) of the silkworm Bombyx mori, the insect cytokine paralytic peptide (PP) is converted from an inactive precursor to an active form in response to the cell wall components of microorganisms and contributes to silkworm resistance to infection. To investigate the molecular mechanism underlying the up-regulation of host resistance induced by PP, we performed an oligonucleotide microarray analysis on RNA of blood cells (hemocytes) and fat body tissues of silkworm larvae injected with active PP. Expression levels of a large number of immune-related genes increased rapidly within 3 h after injecting active PP, including phagocytosis-related genes such as tetraspanin E, actin A1, and ced-6 in hemocytes, and antimicrobial peptide genes cecropin A and moricin in the fat body. Active PP promoted in vitro and in vivo phagocytosis of Staphyloccocus aureus by the hemocytes. Moreover, active PP induced in vivo phosphorylation of p38 mitogen-activated protein kinase (p38 MAPK) in the fat body. Pretreatment of silkworm larvae with ML3403, a pharmacologic p38 MAPK inhibitor, suppressed the PP-dependent induction of cecropin A and moricin genes in the fat body. Injection of active PP delayed the killing of silkworm larvae by S. aureus, whereas its effect was abolished by preinjection of the p38 MAPK inhibitor, suggesting that p38 MAPK activation is required for PP-dependent defensive responses. These findings suggest that PP acts on multiple tissues in silkworm larvae and acutely activates cellular and humoral immune responses, leading to host protection against infection.     

A transgenic silkworm expressing the immune-inducible cecropin B-GFP reporter gene

To analyze cecropin B promoter (P-CecB) activity in vivo, we constructed transgenic silkworms that expressed EGFP under the control of P-CecB using the piggyBac transposable element. Genomic Southern blot analysis of the G1 and G2 generations indicated the stable insertion of EGFP in the genome. Injection of Escherichia coli cells into the larvae strongly induced EGFP expression in the fat bodies and all five hemocyte cell types. Northern blot analysis indicated that the expression kinetics of EGFP in the fat bodies following bacterial injection were correlated with that of endogenous CecB. Flow cytometric analysis of the hemocytes revealed that EGFP expression was increased by bacteria, but not by yeast. Our results indicate that the features of EGFP expression in the transgenic silkworm are equivalent to those of endogenous CecB and that P-CecB activation can be monitored by EGFP expression using transgenic silkworms.     

Cecropins as a marker of Spodoptera frugiperda immunosuppression during entomopathogenic bacterial challenge

An antimicrobial peptide (AMP) of the cecropin family was isolated by HPLC from plasma of the insect pest, Spodoptera frugiperda. Its molecular mass is 3910.9 Da as determined by mass spectrometry. Thanks to the EST database Spodobase, we were able to describe 13 cDNAs encoding six different cecropins which belong to the sub-families CecA, CecB, CecC and CecD. The purified peptide identified as CecB1 was chemically synthesized (syCecB1). It was shown to be active against Gram-positive and Gram-negative bacteria as well as fungi. Two closely related entomopathogenic bacteria, Xenorhabdus nematophila F1 and Xenorhabdus mauleonii VC01(T) showed different susceptibility to syCecB1. Indeed, X. nematophila was sensitive to syCecB1 whereas X. mauleonii had a minimal inhibitory concentration (MIC) eight times higher. Interestingly, injection of live X. nematophila into insects did not induce the expression of AMPs in hemolymph. This effect was not observed when this bacterium was heat-killed before injection. On the opposite, both live and heat-killed X. mauleonii induced the expression of AMPs in the hemolymph of S. frugiperda. The same phenomenon was observed for another immune-related protein lacking antimicrobial activity. Altogether, our data suggest that Xenorhabdus strains have developed different strategies to supplant the humoral defense mechanisms of S. frugiperda, either by increasing their resistance to AMPs or by preventing their expression during such host-pathogen interaction.     

Tissue communication in a systemic immune response of Drosophila

Several signaling pathways, including the JAK/STAT and Toll pathways, are known to activate blood cells (hemocytes) in Drosophila melanogaster larvae. They are believed to regulate the immune response against infections by parasitoid wasps, such as Leptopilina boulardi, but how these pathways control the hemocytes is not well understood. Here, we discuss the recent discovery that both muscles and fat body take an active part in this response. Parasitoid wasp infection induces Upd2 and Upd3 secretion from hemocytes, leading to JAK/STAT activation mainly in hemocytes and in skeletal muscles. JAK/STAT activation in muscles, but not in hemocytes, is required for an efficient encapsulation of wasp eggs. This suggests that Upd2 and Upd3 are important cytokines, coordinating different tissues for the cellular immune response in Drosophila. In the fat body, Toll signaling initiates a systemic response in which hemocytes are mobilized and activated hemocytes (lamellocytes) are generated. However, the contribution of Toll signaling to the defense against wasps is limited, probably because the wasps inject inhibitors that prevent the activation of the Toll pathway. In conclusion, parasite infection induces a systemic response in Drosophila larvae involving major organ systems and probably the physiology of the entire organism.     

Fat body and hemocyte contribution to the antimicrobial peptide synthesis in <Emphasis Type="Italic">Calliphora vicina</Emphasis> R.-D. (Diptera: Calliphoridae) larvae

Antimicrobial peptides accumulated in the hemolymph in response to infection are a key element of insect innate immunity. The involvement of the fat body and hemocytes in the antimicrobial peptide synthesis is widely acknowledged, although release of the peptides present in the hemolymph from the immune cells was not directly verified so far. Here, we studied the presence of antimicrobial peptides in the culture medium of fat body cells and hemocytes isolated from the blue blowfly Calliphora vicina using complex of liquid chromatography, mass spectrometry, and antimicrobial activity assays. Both fat body and hemocytes are shown to synthesize and release to culture medium defensin, cecropin, diptericins, and proline-rich peptides. The spectra of peptide antibiotics released by the fat body and hemocytes partially overlap. Thus, the results suggest that insect fat body and blood cells are capable of releasing mature antimicrobial peptides to the hemolymph. It is notable that the data obtained demonstrate dramatic difference in the functioning of insect antimicrobial peptides and their mammalian counterparts localized into blood cells’ phagosomes where they exert their antibacterial activity.     

Cloning of cDNAs for Cecropins A and B,and Expression of the Genes in the Silkworm,Bombyx mori

cDNA clones coding cecropins A and B were isolated from a cDNA library constructed from the fat body of immunized Bombyx mori larvae. The cloned cDNAs had an open reading frame of 63 amino acids, indicating the primary translated peptides were processed to form mature cecropins of 35 amino acid residues. The homology in the coding regions of cecropins A and B was 73%.

In immunized fat body, the expression of both cecropin A and B genes reached the maximal level 5 h after the injection of soluble peptidoglycan, and the high level was maintained until 9 h after immunization. The cecropin A and B genes were expressed at high levels in fat body and hemocytes, at lower but significant levels in malpighian tube, slightly in midgut, and none in silk gland.     

一个调控抗菌肽表达的小菜蛾肽聚糖识别蛋白(PxPGRP-SA)

【目的】肽聚糖识别蛋白(peptidoglycan recognition proteins,PGRPs)是昆虫免疫系统中一类重要的模式识别蛋白。本研究旨在阐明经苏云金芽孢杆菌Bacillus thuringiensis侵染后,小菜蛾Plutella xylostella PGRP-SA基因(命名为Px PGRP-SA)在体内的表达模式和对抗菌肽基因的表达调控。【方法】本研究利用实时荧光定量PCR(qRT-PCR)技术分析B.thuringiensis侵染小菜蛾幼虫后Px PGRP-SA的转录模式,通过RNAi技术结合抗血清封闭实验检测Px PGRP-SA对小菜蛾抗菌肽基因的表达调控作用。【结果】qRT-PCR检测表明,小菜蛾4龄幼虫在注射具有活性的B.thuringiensis 6 h后,Px PGRP-SA在脂肪体和血细胞中表达量迅速上升,其中脂肪体中的表达量在注射24 h后达到高峰,而在血细胞中的表达量在18 h后达到高峰。RNAi沉默小菜蛾4龄幼虫Px PGRP-SA的转录后,可显著降低小菜蛾脂肪体中cecropin,moricin-2,lysozyme和defensin 4个抗菌肽基因及Dorsal和Sptzle基因的mRNA转录水平;注射anti-Px PGRP-SA封闭小菜蛾体内Px PGRP-SA的活性后,也可降低小菜蛾脂肪体中4个抗菌肽基因的mRNA转录水平;Px PGRP-SA转录沉默后,同时导致添食B.thuringiensis的小菜蛾幼虫的存活率明显降低。【结论】Px PGRP-SA参与了小菜蛾体内抗菌肽cecropin,moricin-2,lysozyme和defensin基因的表达调控,并在免疫防御B.thuringiensis的侵染过程中起了重要的作用。     

A model of bacterial intestinal infections in Drosophila melanogaster

Serratia marcescens is an entomopathogenic bacterium that opportunistically infects a wide range of hosts, including humans. In a model of septic injury, if directly introduced into the body cavity of Drosophila, this pathogen is insensitive to the host's systemic immune response and kills flies in a day. We find that S. marcescens resistance to the Drosophila immune deficiency (imd)-mediated humoral response requires the bacterial lipopolysaccharide O-antigen. If ingested by Drosophila, bacteria cross the gut and penetrate the body cavity. During this passage, the bacteria can be observed within the cells of the intestinal epithelium. In such an oral infection model, the flies succumb to infection only after 6 days. We demonstrate that two complementary host defense mechanisms act together against such food-borne infection: an antimicrobial response in the intestine that is regulated by the imd pathway and phagocytosis by hemocytes of bacteria that have escaped into the hemolymph. Interestingly, bacteria present in the hemolymph elicit a systemic immune response only when phagocytosis is blocked. Our observations support a model wherein peptidoglycan fragments released during bacterial growth activate the imd pathway and do not back a proposed role for phagocytosis in the immune activation of the fat body. Thanks to the genetic tools available in both host and pathogen, the molecular dissection of the interactions between S. marcescens and Drosophila will provide a useful paradigm for deciphering intestinal pathogenesis.     

In vitro induction of cecropin genes--an immune response in a Drosophila blood cell line.

The Drosophila melanogaster cell line mbn-2 was explored as a model system to study insect immune responses in vitro. This cell line is of blood cell origin, derived from larval hemocytes of the mutant lethal (2) malignant blood neoplasm (1(2)mbn). The mbn-2 cells respond to microbial substances by the activation of cecropin genes, coding for bactericidal peptides. The response is stronger than that previously described for SL2 cells, and four other tested Drosophila cell lines were totally unresponsive. Bacterial lipopolysaccharide, algal laminarin (a beta-1,3-glucan), and bacterial flagellin were strong inducers, bacterial peptidoglycan fragments gave a weaker response, whereas a formyl-methionine-containing peptide had no effect. Experiments with different drugs indicate that the response may be mediated by a G protein, but not by protein kinase C or eicosanoids, and that it requires a protein factor with a high rate of turnover.     

Wound Responses in Insects

For over a century, the study of specific antipathogenic strategiesin insects has been confounded by non-specific responses tointegumental invasion. Experimental injury to diapausing Hyalophoracecropia silkmoth pupae elucidated some of the events inherentin this response—increased oxygen consumption and DNAand RNA synthesis leading to de novo synthesis of proteins,some of which are constituents of the adult protein cohort aswell as some injury-specific ones. The mechanism which enforcesdiapause is apparently released by integumental injury as wellas by normal developmental stimuli. Recent work has concentratedon purification of antipathogenic and injury-specific proteins,the possible involvement of lectins in the immune response,and localization of synthesis of these proteins in hemocytesand fat body cells. At least ten different hemolymph proteinswhich are synthesized by fat body cells in response to inoculationof lepidopteran species with bacteria currently are being isolated.The hemolymph of H. cecropia contains lectins which are synthesizedby hemocytes. Analysis of in vitro incorporation of ['H]leucineby hemocytes into proteins reveals that these lectins apparentlyare not constituents of the secreted injury response proteincomplex in fifth instar caterpillars or diapausing pupae, norare hemolymph lectin titers significantly different in healthyversus diseased or injured animals. However, intracellular lectinconcentrations may increase upon injury. Increased lectin titerand induction of bactericidal activity coincide in another holometabolousspecies, the fleshfly Sarcophaga peregrina. Pursuit of thesestudies may elaborate our knowledge of insect cellular immunity.     

Expression and purification of a recombinant antibacterial peptide, cecropin, from Escherichia coli

Insect cecropins are small basic polypeptides synthesized in fat body and hemocytes in response to bacterial infections or hypodermic injuries. To explore a new approach for high expression of soluble cecropin in Escherichia coli cells, we fused the sequence encoding Musca domestica mature cecropin (named Mdmcec) in-frame to thioredoxin (TRX) gene to construct an expression vector pTRX-6His-Mdmcec. An enterokinase cleavage site was introduced between the 6xHis-tag and Mdmcec to facilitate final release of the recombinant Mdmcec. The fusion protein TRX-6His-Mdmcec was purified successfully by HisTrap HP affinity column and a high yield of 48.0mg purified fusion protein was obtained from 1L culture. Recombinant Mdmcec was readily obtained by enterokinase cleavage of the fusion protein followed by HPLC chromatography, and 11.2mg pure active recombinant Mdmcec was obtained from 1L E. coli culture. The molecular mass of recombinant Mdmcec determined by electrospray ionization-mass spectrometry (ESI-MS) is identical to that of native cecropin. Analysis of recombinant Mdmcec by circular dichroism (CD) indicated that recombinant Mdmcec contained predominantly alpha-helix with some random coil. Antimicrobial activity assays demonstrated that recombinant Mdmcec had a broad spectrum of activity against fungi, Gram-positive and negative bacteria. The procedure described in this study will provide a reliable and simple method for production of different cationic peptides for biological studies.