Permeability of the peritrophic membrane of the Douglas fir tussock moth (Orgyia pseudotsugata)

Peritrophins are involved in the defense against Bacillus thuringiensis and nucleopolyhedrovirus formulations in Spodoptera littoralis (Lepidoptera: Noctuidae)

The peritrophic matrix (or peritrophic membrane, PM) is present in most insects where it acts as a barrier to mechanical insults and pathogens, as well as a facilitator of digestive processes. The PM is formed by the binding of structural PM proteins, referred to as peritrophins, to chitin fibrils and spans the entire midgut in lepidopterans. To investigate the role of peritrophins in a highly polyphagous lepidopteran pest, namely the cotton leafworm (Spodoptera littoralis), we generated Insect Intestinal Mucin (IIM-) and non-mucin Peritrophin (PER-) mutant strains via CRISPR/Cas9 mutagenesis. Both strains exhibited deformed PMs and retarded developmental rates. Bioassays conducted with Bacillus thuringiensis (Bt) and nucleopolyhedrovirus (SpliNPV) formulations showed that both the IIM- and PER- mutant larvae were more susceptible to these bioinsecticides compared to the wild-type (WT) larvae with intact PM. Interestingly, the provision of chitin-binding agent Calcofluor (CF) in the diet lowered the toxicity of Bt formulations in both WT and IIM- larvae and the protective effect of CF was significantly lower in PER- larvae. This suggested that the interaction of CF with PER is responsible for Bt resistance mediated by CF. In contrast, the provision of CF caused increased susceptibility to SpliNPV in both mutants and WT larvae. The study showed the importance of peritrophins in the defense against pathogens in S. littoralis and revealed novel insights into CF-mediated resistance to Cry toxin.

A peritrophin mediates the peritrophic matrix permeability in the workers of the bees Melipona quadrifasciata and Apis mellifera

The permeability of the peritrophic matrix, essential for its function, depends on its chemical composition. The objective was to determine if the permeability of the peritrophic matrix varies along the midgut and in the presence of anti-peritrophin-55 antibody in Melipona quadrifasciata and Apis mellifera bees. The thickness of the peritrophic matrix in both species varies between the anterior and posterior midgut regions in workers. In A. mellifera dextran molecules with 40 kDa cross the peritrophic matrix, whereas those ≥70 kDa are retained in the endoperitrophic space. In M. quadrifasciata the peritrophic matrix permeability was for molecules <40 kDa. Bees fed on anti-peritrophin-55 antibody showed an increase in peritrophic matrix permeability, but survival was not affected. In the bees studied, the peritrophic matrices have morphological differences between midgut regions, but there is no difference in their permeability along the midgut, which is affected by peritrophin 55.

Role of the peritrophic matrix in insect-pathogen interactions

The peritrophic matrix (PM) is an acellular chitin and glycoprotein layer that lines the invertebrate midgut. The PM has long been considered a physical as well as a biochemical barrier, protecting the midgut epithelium from abrasive food particles, digestive enzymes and pathogens infectious per os. This short review will focus on the latter function, as a barrier to pathogens infectious per os. We focus on the evidence confirming the role of the PM as protective barrier against pathogenic microorganisms of insects, mainly bacteria and viruses, as well as the evolution of a variety of mechanisms used by pathogens to overcome the PM barrier.

Reaching the melting point: Degradative enzymes and protease inhibitors involved in baculovirus infection and dissemination

Baculovirus infection of a host insect involves several steps, beginning with initiation of virus infection in the midgut, followed by dissemination of infection from the midgut to other tissues in the insect, and finally culminating in "melting" or liquefaction of the host, which allows for horizontal spread of infection to other insects. While all of the viral gene products are involved in ultimately reaching this dramatic infection endpoint, this review focuses on two particular types of baculovirus-encoded proteins: degradative enzymes and protease inhibitors. Neither of these types of proteins is commonly found in other virus families, but they both play important roles in baculovirus infection. The types of degradative enzymes and protease inhibitors encoded by baculoviruses are discussed, as are the roles of these proteins in the infection process.

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.

The intestinal barrier in lepidopteran larvae: permeability of the peritrophic membrane and of the midgut epithelium to two biologically active peptides

Endogenous peptide regulators of insect physiology and development are presently being considered as potential biopesticides, but their efficacy by oral delivery cannot be easily anticipated because of the limited information on how the insect gut barrier handles these kind of molecules. We investigated, in Bombyx mori larvae, the permeability properties of the two components of the intestinal barrier, the peritrophic membrane (PM) and the midgut epithelium, separately isolated and perfused in conventional Ussing chambers. The PM discriminated compounds of different dimensions but was easily crossed by two small peptides recently proposed as bioinsecticides, the neuropeptide proctolin and Aedes aegypti Trypsin Modulating Oostatic Factor (Aea-TMOF), although their flux values indicated that the permeability was highly affected by their steric conformation. To date, there is very little functional data available on how peptides cross the insect intestinal epithelium, but it has been speculated that peptides could reach the haemocoel through the paracellular pathway. We characterized the permeability properties of this route to a number of organic molecules, showing that B. mori septate junction was highly selective to both the dimension and the charge of the permeant compound. Confocal images of whole-mount midguts incubated with rhodamine(rh)-proctolin or fluorescein isothiocyanate (FITC)-Aea-TMOF added to the mucosal side of the epithelium, revealed that rh-proctolin did not enter the cell and crossed the midgut only by the paracellular pathway, while FITC-Aea-TMOF did cross the cell apical membrane, permeating also through the transcellular route.

Optical brightener M2R destroys the peritrophic membrane of Spodoptera exigua (Lepidoptera: Noctuidae) larvae

Observations under an environmental scanning electron microscope showed that the peritrophic membrane (PM) of Spodoptera exigua (Hübner) was smooth without pores, but there were many pores and slits in the PM of larvae fed with 10 g L(-1) optical brightener Calcofluor white M2R. After incubation of S. exigua PM in vitro with 10 g L(-1) M2R, a significant amount of proteins was released from the PM structure. M2R disrupted the structure of larval PM, resulting in greatly increased permeability and increased larval susceptibility to Syngrapha falcifera multiple nucleopolyhedrovirus infection. Continuous feeding of larvae on a diet treated with a 10 g L(-1) M2R solution significantly retarded larval development and resulted in high mortality. The destructive effect of M2R on PM was transient and reversible, depending on the presence of M2R within the midgut.

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.

A baculovirus enhancin alters the permeability of a mucosal midgut peritrophic matrix from lepidopteran larvae

The peritrophic matrix (PM) in lepidopterous larvae may function as a defensive barrier against ingested viral pathogens. PMs isolated from Trichoplusia ni and Pseudaletia unipuncta larvae, were treated with a baculovirus-encoded metalloprotease (enhancin) from Trichoplusia ni granulosis virus (TnGV) and their in vitro permeability to blue dextran and fluorescent-labelled Autographa californica nuclear polyhedrosis virus (AcMNPV) was determined using a dual chamber permeability apparatus. Incubation of T. ni PMs with 0.0, 0.5, 1.0, and 2.0mg/ml enhancin resulted in a blue dextran 2000 flux of 4.4, 6.3, 9.9, and 15.6&mgr;g/mm(2)/h, respectively. In addition, T. ni PMs treated with enhancin were found to be significantly more permeable to fluorescent-labelled AcMNPV than non-treated control PMs. The permeability of T. ni PMs treated with 3.0mg/ml enhancin was 0.017 cumulative percent crossing/mm(2)/h, whereas the permeability of the control PM was below the detectable limit. Similarly, enhancin treatment greatly increased the permeability of P. unipuncta PMs to AcMNPV. These results provide evidence that the PM from two lepidopteran species can block the passage of baculovirions across this matrix thus reducing the probability of larval infection. Furthermore, these results support the hypothesis that enhancin facilitates NPV infection of larvae by altering the permeability of the PM.

Observations on the presence of the peritrophic membrane in larval Trichoplusia ni and its role in limiting baculovirus infection

Light microscopical examinations of dissected and stained peritrophic membranes (PMs) were conducted to determine the presence or absence of this protective structure in larvae of Trichoplusia ni, prior to and through ecdysis. Observations of fourth- and fifth-instar larvae of T. ni from two independent rearing colonies showed that PMs were present and lined the midgut prior to, during, and immediately after ecdysis in both instars. Western blot analysis of insect intestinal mucin (IIM), a major protective protein in the T. ni PM, indicated that synthesis of IIM occurred during T. ni embryonic development, or more precisely, that IIM synthesis started approximately 4 h prior to hatching. These results demonstrated that the neonate T. ni midgut is lined with a protective mucinous layer at hatching. A baculovirus enhancin from T. ni granulosis virus (TnGV) enhanced per os viral infections of budded viruses (BVs) of Autographa californica multiple nuclear polyhedrosis virus (AcMNPV) and T. ni single nuclear polyhedrosis virus (TnSNPV) in neonate, fourth-, and fifth-instar larvae of T. ni. These results provided further evidence that the PM may serve as a partial barrier to viruses in the midgut lumen and that enhancins can facilitate the infection process.

Permeability of the Peritrophic Envelopes of Herbivorous Insects to Dextran Sulfate: a Test of the Polyanion Exclusion Hypothesis

We tested the hypothesis that the permeability of the peritrophic envelope in herbivorous insects is greatly reduced for polyanions as a result of an extensive network of anionic sites in the proteoglycans of the matrix. 14C-Dextran sulfate (polyanionic, 8000 M(w)) and fluorescein isothiocyanate-labeled (FITC) dextran (monoanionic, 9400 M(w)) were introduced together into the endoperitrophic space of the midguts of Orgyia leucostigma (Lepidoptera) larvae and Melanoplus sanguinipes (Orthoptera) adults. In all cases more of the 14C-dextran sulfate permeated the peritrophic envelope than the FITC-dextran, the opposite of the result predicted by the polyanion exclusion hypothesis. We conclude that polyanion exclusion is not a mechanism that contributes significantly to the permeability properties of the peritrophic envelopes of these two species, or that explains the failure of tannic acid to cross the peritrophic envelopes of lepidopteran larvae. Copyright 1997 Elsevier Science Ltd. All rights reserved

Nucleopolyhedrovirus interactions with their insect hosts

It is clear from this brief review that our understanding of the molecular cross-talk between insects and their baculovirus pathogens is still very limited. Studies in cell culture have taught us a great deal about the basic baculovirus molecular machinery and how it is regulated, and in many cases this information has been predictive of what occurs in infected insects. Frequently, however, studies in cell culture do not adequately predict the infection process in insect hosts, as demonstrated by viral mutants (some of which were discussed in this review) that behave identically to wild-type virus in cell culture but differ markedly in larvae. More baculovirus studies, therefore, need to be conducted in vivo if we are to improve our understanding of the complex interactions between baculoviruses and their hosts. Conducting baculovirus studies in insects (or at least in primary cell culture) also offers the opportunity to address questions that reach beyond the baculovirus community in significance. For example, almost all of our knowledge of viral fusion mechanisms comes from infection of cells in culture where the pH is neutral or acidic and the temperature is constant at 27 degrees or 37 degrees C. An answer to the question of how the ODV envelope fuses with the microvillar membrane of columnar epithelial cells in the highly alkaline midgut environment at low temperatures will not only be important for an improved understanding of baculovirus infection in the natural world, but will also constitute a new chapter on viral entry mechanisms. Similarly, the answer to the question of how baculovirus nucleocapsids move basally within microvilli promises to involve factors and/or a mechanism not yet described by cell biologists, and so will constitute a valuable contribution to both baculovirology and cell biology. There are many more such examples of biological mechanisms that can be uniquely explored within the context of baculoviruses and their insect hosts, some of which have been highlighted in this review. As more and more young investigators realize the importance of combining a knowledge of virology, molecular technology, and insect biology, however, many of the outstanding mysteries will be solved.

Peritrophic matrix structure and function

Formed of proteins, glycoproteins, and chitin microfibrils in a proteoglycan matrix, the peritrophic matrix (PM) separates the food from the midgut epithelium in most but not all insects. A PM occurs in two forms. A type I PM is delaminated from the entire midgut epithelium and, in some cases, may only be formed in response to feeding and the type of meal ingested. A type II PM is produced by a specialized region of the anterior midgut called the cardia and forms a continuous sleeve (or sleeves) that is always present. As it is positioned between food and midgut epithelium, the PM plays key roles in the intestinal biology of the insect. The PM may protect the midgut epithelium from mechanical damage and insult from pathogens and toxins; it must act as a semipermeable membrane regulating passage of molecules between the different midgut compartments; and it may separate the midgut lumen into different, physiologically significant compartments.

The peritrophic membrane: its formation, structure, chemical composition and permeability in relation to vaccination against ectoparasitic arthropods

Peritrophic membrane (PM) lines the gut of many arthropods and other animals, and thus separates ingested food from the gut epithelium. Its main functions are connected with its partitioning of the gut lumen into regions between which the transfer of large macromolecules and other particles is limited by its permeability properties. In the context of vaccinating mammalian hosts against parasitic arthropods. PM may either restrict penetration of ingested immune effector components within the parasite, or serve as a target for immunological attack. The properties of PM that are relevant to these potential roles--its site and mode of formation, structure, chemical composition and permeability--are reviewed with reference to ectoparasitic insects. Recent experiments, in which sheep were vaccinated with extracts of PM from larvae of the sheep blowfly, Lucilia cuprina, are outlined. Antibodies ingested from vaccinated sheep slowed the growth of L. cuprina larvae. These antibodies bound specifically to the PM, reducing its permeability and thereby perhaps hampering utilization of food by larvae. The potential for vaccination against parasitic arthropods using antigens from their PMs is discussed.

Alteration of a lepidopteran peritrophic membrane by baculoviruses and enhancement of viral infectivity

The peritrophic membrane (PM), which lines the midgut of many insect species, has several functions. In particular, it may serve as a mechanical barrier to invading microorganisms. The protein composition of the PM from healthy and baculovirus-treated Trichoplusia ni (cabbage looper) larvae was analyzed by polyacrylamide gel electrophoresis. A specific interaction took place between baculoviruses and the PM of susceptible T. ni larvae. A 68-kDa glycoprotein of the PM disappeared within 15 min postinoculation with occlusion bodies of either Autographa californica nuclear polyhedrosis virus (AcMNPV) or T. ni nuclear polyhedrosis virus (TnSNPV). In contrast, inoculation of larvae with a T. ni granulosis virus (TnGV) resulted in the disappearance of three distinct major glycoproteins with molecular weights of 253, 194, and 123 kDa. PMs of virus-treated larvae were very fragile compared with those of untreated controls, indicative of a physical/chemical change in their structure. T. ni larval bioassays showed that a factor, present in the TnGV granulin or AcMNPV polyhedrin, enhanced the infectivity of AcMNPV. These data showed that a factor present in the occlusion bodies of three distinct baculoviruses can cause specific biochemical and structural changes in the PM. The biological significance of these observations in relation to increased larval infection is not known at this time.