Identification of two new peritrophic membrane proteins from larval Trichoplusia ni: structural characteristics and their functions in the protease rich insect gut

Peritrophic membrane (PM) proteins are important determinants for the structural formation and function of the PM. We identified two new chitin binding proteins, named CBP1 and CBP2, from the PM of Trichoplusia ni larvae by cDNA cloning. The proteins contain 12 and 10 tandem chitin binding domains in CBP1 and CBP2, respectively. Chitin binding studies demonstrated the chitin binding activity of CBP1 and CBP2, and confirmed the chitin binding domain sequence predicted by sequence analysis. Both CBP1 and CBP2 were not mucin-like glycoproteins, however, they were highly resistant to proteolytic degradation by trypsin. We found that in CBP1 and CBP2, potential trypsin and chymotrypsin cleavage sites reside primarily within the chitin binding domain sequences, limiting exposure of the potential cleavage sites to the digestive proteinases. This finding suggests a proteinase-resistance mechanism for non-mucin PM proteins to function in the proteinase rich gut environment. Immunohistochemical analysis showed that CBP1 and CBP2 are specifically localized in the PM. However, intact CBP1 and CBP2 proteins were not present in the PM, indicating that their partially degraded fragments were assembled into the PM. This observation suggests that the presence of a large number of chitin binding domains in PM proteins allows the proteins to tolerate limited proteolytic degradation in the midgut without loss of their chitin binding activity with multiple chitin binding domains. Alignment of the chitin binding sequences suggested that CBP1 and CBP2 evolved by gene duplication and the tandem chitin binding domains in the proteins arose from domain duplications.     

Chitin is only a minor component of the peritrophic matrix from larvae of Lucilia cuprina

The gut of most insects is lined with a peritrophic matrix that facilitates the digestive process and protects insects from invasion by micro-organisms and parasites. It is widely accepted that the matrix is composed of chitin, proteins and proteoglycans. Here we critically re-examine the chitin content of the typical type 2 peritrophic matrix from the larvae of the fly Lucilia cuprina using a range of techniques. Many of the histochemical and biochemical techniques indicate the presence of chitin, although they are often adversely influenced by the presence of highly glycosylated proteins, a principal component of the matrix. The alkali-stable fraction, which is used as an indicator of the maximum chitin content in a biological sample, is only 7.2% of the weight of the matrix. Larvae fed on the potent chitin synthase inhibitor polyoxin D or the chitin-binding agent Calcofluor White, showed strong concentration-dependent inhibition of larval weight and survival but no discernible effects on the matrix structure. A bacterial endochitinase fed to larvae had no effect on larval growth and no observable effect in vitro on the structure of isolated peritrophic matrix. RT–PCR did not detect a chitin synthase mRNA in cardia, the tissue from which PM originates. It is concluded that chitin is a minor structural component of the type 2 peritrophic matrix of this insect.     

Chitin is only a minor component of the peritrophic matrix from larvae of Lucilia cuprina

The gut of most insects is lined with a peritrophic matrix that facilitates the digestive process and protects insects from invasion by micro-organisms and parasites. It is widely accepted that the matrix is composed of chitin, proteins and proteoglycans. Here we critically re-examine the chitin content of the typical type 2 peritrophic matrix from the larvae of the fly Lucilia cuprina using a range of techniques. Many of the histochemical and biochemical techniques indicate the presence of chitin, although they are often adversely influenced by the presence of highly glycosylated proteins, a principal component of the matrix. The alkali-stable fraction, which is used as an indicator of the maximum chitin content in a biological sample, is only 7.2% of the weight of the matrix. Larvae fed on the potent chitin synthase inhibitor polyoxin D or the chitin-binding agent Calcofluor White, showed strong concentration-dependent inhibition of larval weight and survival but no discernible effects on the matrix structure. A bacterial endochitinase fed to larvae had no effect on larval growth and no observable effect in vitro on the structure of isolated peritrophic matrix. RT–PCR did not detect a chitin synthase mRNA in cardia, the tissue from which PM originates. It is concluded that chitin is a minor structural component of the type 2 peritrophic matrix of this insect.     

光增白剂M2R对草地螟中肠围食膜的影响及对Bt毒力的增效作用

以光增白剂M2R作为影响因子,探讨其对草地螟Loxostege sticticalis幼虫围食膜（peritrophic membrane, PM）的作用机理。通过环境扫描电镜观察和生化测定研究了光增白剂对草地螟幼虫围食膜结构和蛋白质种类的影响,及其对Bt毒力的增效作用。结果表明：围食膜含有多种蛋白质,经SDS-PAGE测定至少有19条带,分子量在94 kD以下,虫取食光增白剂可影响围食膜中几丁质结合蛋白（chitin binding proteins,CBPs）的含量。不同浓度的光增白剂可以对草地螟围食膜的形态结构产生明显的影响,正常的围食膜表面光滑致密、无孔洞和缝隙,增白剂处理的围食膜产生了孔缝。生测实验表明,添加光增白剂后能够显著缩短Bt的杀虫时间 降低Bt的使用浓度。可见,光增白剂可对草地螟围食膜产生损伤,进而提高了Bt的防治效果。     

Isolation and identification of insect intestinal mucin HaIIM86--the new target for Helicoverpa armigera biocontrol

There are many more glycoproteins in Helicoverpa armigera peritrophic membrane than midgut separated by SDS-PAGE analysis after Periodic acid-Schiff (PAS) and coomassie staining. The peritrophic membrane (PM) of H. armigera larvae contains about forty associated proteins. A cDNA library was constructed from H. armigera midgut mRNA to study the new target for pest biocontrol. An antiserum against Spodoptera exigua integral/total PM proteins cross reacted with several H. armigera PM proteins and was used to isolate a complete cDNA encoding an insect intestinal mucin (HaIIM86). The deduced protein sequence of the cDNA contained one potentially glycosylated, mucin-like domain, five cysteine-rich chitin-binding domains (CBDs) and two D-G rich regions. Mucin domain was lined between the first and second CBDs; the two additional D-G rich regions were proposed to internal reside at the amino terminus of the protein flanked by three cysteine-rich CBDs. HaIIM86 contains two D-G-rich tandem repeat domains flanked by cysteine-rich sequences in peritrophic membrane proteins which is not present in all the currently known PM proteins. Howerer the functions of D-G rich domains require further investigation. HaIIM86 was shown as 200 kDa protein by SDS-PAGE analysis and appeared to be associated with the PM. HaIIM86 has chitin-binding activity and can be degraded into 90 and 70 kDa by HaGV Enhancin in vivo. The finding has shown that HaIIM86 is the target substrate for enhancin and the potential target for pest control.     

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.     

In vitro and in vivo application of RNA interference for targeting genes involved in peritrophic matrix synthesis in a lepidopteran system

Abstract The midgut of most insects is lined with a semipermeable acellular tube, the peritrophic matrix (PM), composed of chitin and proteins. Although various genes encoding PM proteins have been characterized, our understanding of their roles in PM structure and function is very limited. One promising approach for obtaining functional information is RNA interference, which has been used to reduce the levels of specific mRNAs using double‐stranded RNAs administered to larvae by either injection or feeding. Although this method is well documented in dipterans and coleopterans, reports of its success in lepidopterans are varied. In the current study, the silencing midgut genes encoding PM proteins (insect intestinal mucin 1, insect intestinal mucin 4, PM protein 1) and the chitin biosynthetic or modifying enzymes (chitin synthase‐B and chitin deacetylase 1) in a noctuid lepidopteran, Mamestra configurata, was examined in vitro and in vivo. In vitro studies in primary midgut epithelial cell preparations revealed an acute and rapid silencing (by 24 h) for the gene encoding chitin deacetylase 1 and a slower rate of silencing (by 72 h) for the gene encoding PM protein 1. Genes encoding insect intestinal mucins were slightly silenced by 72 h, whereas no silencing was detected for the gene encoding chitin synthase‐B. In vivo experiments focused on chitin deacetylase 1, as the gene was silenced to the greatest extent in vitro. Continuous feeding of neonates and fourth instar larvae with double‐stranded RNA resulted in silencing of chitin deacetylase 1 by 24 and 36 h, respectively. Feeding a single dose to neonates also resulted in silencing by 24 h. The current study demonstrates that genes encoding PM proteins can be silenced and outlines conditions for RNA interference by per os feeding in lepidopterans.     

Domain III of Bacillus thuringiensis Cry1Ie Toxin Plays an Important Role in Binding to Peritrophic Membrane of Asian Corn Borer

The insecticidal IE648 toxin is a truncated Cry1Ie protein with increased toxicity against Asian corn borer (ACB). Cry toxins are pore-forming toxins that disrupt insect midgut cells to kill the larvae. However, the peritrophic membrane (PM) is an important barrier that Cry toxins must cross before binding to midgut cells. Previously, it was shown that Cry toxins are able to bind and accumulate in the PM of several lepidopteran insects. Binding of IE648 toxin to PM of ACB was previously reported and the goal of the current work was the identification of the binding region between Cry1Ie and the PM of ACB. Homologous competition binding assays showed that this interaction was specific. Heterologous competition binding assays performed with different fragments corresponding to domain I, domain II and domain III allowed us to identify that domain III participates in the interaction of IE648 with the PM. Specifically, peptide D3-L8 (corresponding to Cry1Ie toxin residues 607 to 616), located in an exposed loop region of domain III is probably involved in this interaction. Ligand blot assays show that IE648 interact with chitin and PM proteins with sizes of 30, 32 and 80 kDa. The fact that domain III interacts with proteins of similar molecular masses supports that this region of the toxin might be involved in PM interaction. These data provide for the first time the identification of domain III as a putative binding region between PM and 3D-Cry toxin.     

Analysis of expression and chitin‐binding activity of the wing disc cuticle protein BmWCP4 in the silkworm,Bombyx mori

The insect exoskeleton is mainly composed of chitin filaments linked by cuticle proteins. When insects molt, the cuticle of the exoskeleton is renewed by degrading the old chitin and cuticle proteins and synthesizing new ones. In this study, chitin‐binding activity of the wing disc cuticle protein BmWCP4 in Bombyx mori was studied. Sequence analysis showed that the protein had a conservative hydrophilic “R&R” chitin‐binding domain (CBD). Western blotting showed that BmWCP4 was predominately expressed in the wing disc‐containing epidermis during the late wandering and early pupal stages. The immunohistochemistry result showed that the BmWCP4 was mainly present in the wing disc tissues containing wing bud and trachea blast during day 2 of wandering stage. Recombinant full‐length BmWCP4 protein, “R&R” CBD peptide (CBD), non‐CBD peptide (BmWCP4‐CBD^?), four single site‐directed mutated peptides (M₁, M₂, M₃ and M₄) and four‐sites‐mutated peptide (M_F) were generated and purified, respectively, for in vitro chitin‐binding assay. The results indicated that both the full‐length protein and the “R&R” CBD peptide could bind with chitin, whereas the BmWCP4‐CBD^? could not bind with chitin. The single residue mutants M₁, M₂, M₃ and M₄ reduced but did not completely abolish the chitin‐binding activity, while four‐sites‐mutated protein M_F completely lost the chitin‐binding activity. These data indicate that BmWCP4 protein plays a critical role by binding to the chitin filaments in the wing during larva‐to‐pupa transformation. The conserved aromatic amino acids are critical in the interaction between chitin and the cuticle protein.     

Cloning, sequencing, and expression of the gene encoding Clostridium paraputrificum chitinase ChiB and analysis of the functions of novel cadherin-like domains and a chitin-binding domain.

The Clostridium paraputrificum chiB gene, encoding chitinase B (ChiB), consists of an open reading frame of 2,493 nucleotides and encodes 831 amino acids with a deduced molecular weight of 90,020. The deduced ChiB is a modular enzyme composed of a family 18 catalytic domain responsible for chitinase activity, two reiterated domains of unknown function, and a chitin-binding domain (CBD). The reiterated domains are similar to the repeating units of cadherin proteins but not to fibronectin type III domains, and therefore they are referred to as cadherin-like domains. ChiB was purified from the periplasm fraction of Escherichia coli harboring the chiB gene. The molecular weight of the purified ChiB (87,000) by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis, was in good agreement with the value (86,578) calculated from the deduced amino acid sequence excluding the signal peptide. ChiB was active toward chitin from crab shells, colloidal chitin, glycol chitin, and 4-methylumbelliferyl beta-D-N,N'-diacetylchitobioside [4-MU-(GlcNAc)2]. The pH and temperature optima of the enzyme were 6.0 and 45 degrees C, respectively. The Km and Vmax values for 4-MU-(GlcNAc)2 were estimated to be 6.3 microM and 46 micromol/min/mg, respectively. SDS-PAGE, zymogram, and Western blot analyses using antiserum raised against purified ChiB suggested that ChiB was one of the major chitinase species in the culture supernatant of C. paraputrificum. Deletion analysis showed clearly that the CBD of ChiB plays an important role in hydrolysis of native chitin but not processed chitin such as colloidal chitin.     

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。     

Identification and characterization of two chitin-binding proteins from the peritrophic membrane of the silkworm, Bombyx mori L

The peritrophic membrane (PM) is a semi‐permeable lining of the insect midgut, broadly analogous to the mucous lining of vertebrate gut. The PM proteins are important achievements for the function of the PM. In this study, two chitin‐binding proteins (BmPM‐P43 and BmPM‐P41) from the PM of the silkworm, Bombyx mori, were identified and cloned. These proteins showed the molecular mass of 43 and 41 kDa, respectively. The deduced amino acid sequences codes for a protein of 381 amino acid residues and 364 amino acid residues, containing 12 and 14 cysteine residues followed by similar domain, both of them have 5 cysteine residues in similar position in the C‐terminal. The confirmation of these proteins was performed by western blot analysis of recombinant BmPM‐P43 and BmPM‐P41. The chitin‐binding activity analysis showed that the BmPM‐P43 and BmPM‐P41 could bind to chitin strongly. It is concluded that BmPM‐P43 and BmPM‐P41 contains a polysaccharide deacetylase domain instead of peritrophin domain, indicated that these two proteins may belong to a new chitin‐binding protein family. © 2010 Wiley Periodicals, Inc.     

Peritrophic membrane structure and formation in the larva of a moth, Heliothis

The peritrophic membrane (PM) in tobacco budworm larvae (Heliothis virescens, Lepidoptera: Noctuidae), is a continuous sac which encloses the food bolus in the midgut and hindgut. The PM is a single-walled structure 3-5 mum thick which is comprised of two main layers or laminae. The laminae may be fused into a single structure or remain separated by a space which may contain additional thin strands of matrix. Staining with an anti-PM antibody and wheat germ agglutinin (WGA) illustrate the laminar nature of the PM and suggest that protein and chitin have co-incident spatial distributions within the matrix. By transmission electron microscopy, the PM is composed of a loose network of fibrils and small granules, the only structural difference among laminae being a compaction of the matrix along the edges of the two limiting laminae facing the endoperitrophic and ectoperitrophic spaces. By scanning electron microscopy, the PM surface has a wrinkled, felt-like texture without pores or slits. Contrary to the classical view that lepidopterans are Type I insects with respect to PM formation in which the PM forms along the full length of the midgut, the PM in the tobacco budworm forms primarily from secretions of specialized midgut epithelial cells at the junction of the foregut and midgut. The secretory cells, their secretions and the nascent PM stain intensely with the anti-PM antibody but not with WGA suggesting that chitin is added more posteriorly. The PM may be supplemented by the addition of minor amounts of matrix material along the length of the midgut. PM synthesis begins during embryogenesis prior to the initiation of feeding. The PM in neonates is only about 0.1 mum thick but otherwise is structurally similar to that in older larvae.     

Analysis of chitin-binding proteins from Manduca sexta provides new insights into evolution of peritrophin A-type chitin-binding domains in insects

In insects, chitin is a major structural component of the cuticle and the peritrophic membrane (PM). In nature, chitin is always associated with proteins among which chitin-binding proteins (CBPs) are the most important for forming, maintaining and regulating the functions of these extracellular structures. In this study, a genome-wide search for genes encoding proteins with ChtBD2-type (peritrophin A-type) chitin-binding domains (CBDs) was conducted. A total of 53 genes encoding 56 CBPs were identified, including 15 CPAP1s (cuticular proteins analogous to peritrophins with 1 CBD), 11 CPAP3s (CPAPs with 3 CBDs) and 17 PMPs (PM proteins) with a variable number of CBDs, which are structural components of cuticle or of the PM. CBDs were also identified in enzymes of chitin metabolism including 6 chitinases and 7 chitin deacetylases encoded by 6 and 5 genes, respectively. RNA-seq analysis confirmed that PMP and CPAP genes have differential spatial expression patterns. The expression of PMP genes is midgut-specific, while CPAP genes are widely expressed in different cuticle forming tissues. Phylogenetic analysis of CBDs of proteins in insects belonging to different orders revealed that CPAP1s from different species constitute a separate family with 16 different groups, including 6 new groups identified in this study. The CPAP3s are clustered into a separate family of 7 groups present in all insect orders. Altogether, they reveal that duplication events of CBDs in CPAP1s and CPAP3s occurred prior to the evolutionary radiation of insect species. In contrast to the CPAPs, all CBDs from individual PMPs are generally clustered and distinct from other PMPs in the same species in phylogenetic analyses, indicating that the duplication of CBDs in each of these PMPs occurred after divergence of insect species. Phylogenetic analysis of these three CBP families showed that the CBDs in CPAP1s form a clearly separate family, while those found in PMPs and CPAP3s were clustered together in the phylogenetic tree. For chitinases and chitin deacetylases, most of phylogenetic analysis performed with the CBD sequences resulted in similar clustering to the one obtained by using catalytic domain sequences alone, suggesting that CBDs were incorporated into these enzymes and evolved in tandem with the catalytic domains before the diversification of different insect orders. Based on these results, the evolution of CBDs in insect CBPs is discussed to provide a new insight into the CBD sequence structure and diversity, and their evolution and expression in insects.     

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.     

Protein expression during parasite redirection of host (Trichoplusia ni) biochemistry

Expression of proteins during normal egg and larval development of Trichoplusia ni was compared with that occurring in hosts stung as eggs by the parasitic wasp Chelonus sp. near curvimaculatus. Those stung hosts which produced a parasite (truly parasitized), precociously expressed proteins associated with larval-pupal metamorphosis, as did those stung hosts which did not contain a developing endoparasite (pseudoparasitized). No highly abundant, low-intermediate molecular weight hemolymph proteins were observed in truly or pseudoparasitized larvae which did not also occur at some point in the development of normal larvae. A low abundance, high molecular mass (160,000 Da) protein was observed in the hemolymph of truly parasitized larvae, but not of normal or pseudoparasitized larvae. The protein is glycosylated and very acidic (pI near 4.5). The data show that any parasitization proteins injected or induced by the ovipositing female parasite are in low abundance, in contrast to situations reported for parasitic wasps which sting hosts as larvae.     

Binding of Vigna unguiculata vicilins to the peritrophic membrane of Tenebrio molitor affects larval development

We investigated the effects of vicilins (7S storage proteins) from Vigna unguiculata (L.) Walp. (Fabaceae), cultivars EPACE‐10 [genotype susceptible to the cowpea weevil, Callosobruchus maculatus (Fabricius)] and IT81D‐1045 [cowpea weevil‐resistant genotype], seeds on Tenebrio molitor L. (Coleoptera: Tenebrionidae) larval development. Toxicity of vicilins was investigated through the incorporation of these proteins in artificial diet offered to the larvae. Binding tests of vicilins to the peritrophic membranes (PM) were carried out by in vitro incubation of PM with solutions of vicilins. Bound proteins were desorbed from PM with 100 mm HCl. Desorbed vicilins were analyzed by sodium dodecyl sulfate–polyacrylamide gel electrophoresis followed by immunoprobing on Western blotting using an anti‐vicilin cv. EPACE‐10 antibody. The chitin content of the T. molitor PM was evaluated by the Von Wisselingh color test and presence of chitin in the larval PM was confirmed. Bioassays showed that both vicilins from EPACE‐10 and IT81D‐1045 genotypes were toxic to T. molitor larvae, and in vitro binding assays showed that these seed‐storage proteins were capable of binding to the larval PM.     

Chitin is a necessary component to maintain the barrier function of the peritrophic matrix in the insect midgut

In most insects, the peritrophic matrix (PM) partitions the midgut into different digestive compartments, and functions as a protective barrier against abrasive particles and microbial infections. In a previous study we demonstrated that certain PM proteins are essential in maintaining the PM's barrier function and establishing a gradient of PM permeability from the anterior to the posterior part of the midgut which facilitates digestion (Agrawal et al., 2014). In this study, we focused on the effects of a reduction in chitin content on PM permeability in larvae of the red flour beetle, Tribolium castaneum. Oral administration of the chitin synthesis inhibitor diflubenzuron (DFB) only partially reduced chitin content of the larval PM even at high concentrations. We observed no nutritional effects, as larval growth was unaffected and neutral lipids were not depleted from the fat body. However, the metamorphic molt was disrupted and the insects died at the pharate pupal stage, presumably due to DFB's effect on cuticle formation. RNAi to knock-down expression of the gene encoding chitin synthase 2 in T. castaneum (TcCHS-2) caused a complete loss of chitin in the PM. Larval growth was significantly reduced, and the fat body was depleted of neutral lipids. In situ PM permeability assays monitoring the distribution of FITC dextrans after DFB exposure or RNAi for TcCHS-2 revealed that PM permeability was increased in both cases. RNAi for TcCHS-2, however, led to a higher permeation of the PM by FITC dextrans than DFB treatment even at high doses. Similar effects were observed when the chitin content was reduced by feeding DFB to adult yellow fever mosquitos, Aedes aegypti. We demonstrate that the presence of chitin is necessary for maintaining the PM's barrier function in insects. It seems that the insecticidal effects of DFB are mediated by the disruption of cuticle synthesis during the metamorphic molt rather than by interfering with larval nutrition. However, as DFB clearly affects PM permeability, it may be suitable to increase the efficiency of pesticides targeting the midgut.