The apical plasma membrane of chitin‐synthesizing epithelia

Abstract Chitin is the second most abundant polysaccharide on earth. It is produced at the apical side of epidermal, tracheal, fore‐, and hindgut epithelial cells in insects as a central component of the protective and supporting extracellular cuticle. Chitin is also an important constituent of the midgut peritrophic matrix that encases the food supporting its digestion and protects the epithelium against invasion by possibly ingested pathogens. The enzyme producing chitin is a glycosyltransferase that resides in the apical plasma membrane forming a pore to extrude the chains of chitin into the extracellular space. The apical plasma membrane is not only a platform for chitin synthases but, probably through its shape and equipment with distinct factors, also plays an important role in orienting and organizing chitin fibers. Here, I review findings on the cellular and molecular constitution of the apical plasma membrane of chitin‐producing epithelia mainly focusing on work done in the fruit fly Drosophila melanogaster.     

A novel family of chitin-binding proteins from insect type 2 peritrophic matrix. cDNA sequences, chitin binding activity, and cellular localization

The peritrophic matrix is a prominent feature of the digestive tract of most insects, but its function, formation, and even its composition remain contentious. This matrix is a molecular sieve whose toughness and elasticity are generated by glycoproteins, proteoglycans, and chitin fibrils. We now describe a small, highly conserved protein, peritrophin-15, which is an abundant component of the larval peritrophic matrices of the Old World screwworm fly, Chrysomya bezziana, and sheep blowfly, Lucilia cuprina. Their deduced amino acid sequences code for a 8-kDa secreted protein characterized by a highly conserved and novel register of six cysteines. Two Drosophila homologues have also been identified from unannotated genomic sequences. Recombinant peritrophin-15 binds strongly and specifically to chitin; however, the stoichiometry of binding is low (1:10,000 N-acetyl glucosamine). We propose that peritrophin-15 caps the ends of the chitin polymer. Immunogold studies localized peritrophin-15 to the peritrophic matrix and specific vesicles in cells of the cardia, the small organ of the foregut responsible for peritrophic matrix synthesis. The vesicular contents are disgorged at the base of microvilli underlying the newly formed peritrophic matrix. This is the first time that the process of synthesis and integration of a peritrophic matrix protein into the nascent peritrophic matrix has been observed.     

Fine structure of the chitin-protein system in the crab cuticle

The fine structure of the organic matrix of the shore crab cuticle (Carcinus maenas L.), observed in transmission electron microscopy, reveals three different levels of organization of the chitin—protein complex. The highest level corresponds to the ‘twisted plywood’ organization described by Bouligand (1972). Horizontal microfibrils, parallel to the cuticle plane, rotate progressively from one level to another. When viewed in oblique section this structure gives superimposed series of nested arcs, visible in light microscopy or at the lowest magnifications of the electron microscope, in all the chitin-protein layers. At the highest magnifications of the electron microscope and with the best resolution, when the ultrathin sections are exactly transverse to the microfibril, a constant pattern can be observed which consists of rods transparent to electrons, which are embedded in an electron-opaque matrix. In cross-section, these rods often form more or less hexagonal arrays. We call a microfibril one rod and the adjacent opaque material, and question the usual interpretation of the microfibril molecular structure. Between these two levels of organization, there is an intermediate level, which corresponds to the grouping of microfibrils. Microfibrils form a dense structure, with few free spaces in the membranous layer, the deepest and non-calcified layer of the cuticle. In other parts of the cuticle, microfibrils are grouped into fibrils of various diameters or form a reticulate structure, the free spaces of the organic matrix being occupied by the mineral.     

The formation of the pupal cuticle by Drosophila imaginal discs in vitro

Mass-isolated imaginal discs of Drosophila melanogaster form a chitin-containing pupal procuticle In vitro. Optimal procuticle deposition occurs when the discs are incubated for 4–6 hr with 0.5–1.0 μg/ml of 20-hydroxyecdysone and then with less than 0.05 μg/ml of 20-hydroxyecdysone. The formation of the chitin-containing procuticle is demonstrated using three independent assays: with fluorescene-conjugated cuticle proteins that bind to chitin; by electron microscopy; by incorporation of [³H]glucosamine into a chitin fraction. Synthesis and deposition of pupal cuticle proteins are also demonstrated. Incorporation of [³H]glucosamine into chitin is sensitive to inhibitors of protein, RNA and chitin synthesis, but has little sensitivity to inhibitors of DNA synthesis, and dolichol-dependent glycosylation.     

Genome‐wide identification of chitin‐binding proteins and characterization of BmCBP1 in the silkworm,Bombyx mori

The insect cuticle plays important roles in numerous physiological functions to protect the body from invasion of pathogens, physical injury and dehydration. In this report, we conducted a comprehensive genome-wide search for genes encoding proteins with peritrophin A-type (ChtBD2) chitin-binding domain (CBD) in the silkworm, Bombyx mori. One of these genes, which encodes the cuticle protein BmCBP1, was additionally cloned, and its expression and location during the process of development and molting in B. mori were investigated. In total, 46 protein-coding genes were identified in the silkworm genome, including those encoding 15 cuticle proteins analogous to peritrophins with one CBD (CPAP1s), nine cuticle proteins analogous to peritrophins with three CBD (CPAP3s), 15 peritrophic membrane proteins (PMPs), four chitinases, and three chitin deacetylases, which contained at least one ChtBD2 domain. Microarray analysis indicated that CPAP-encoding genes were widely expressed in various tissues, whereas PMP genes were highly expressed in the midgut. Quantitative polymerase chain reaction and western blotting showed that the cuticle protein BmCBP1 was highly expressed in the epidermis and head, particularly during molting and metamorphosis. An immunofluorescence study revealed that chitin co-localized with BmCBP1 at the epidermal surface during molting. Additionally, BmCBP1 was notably up-regulated by 20-hydroxyecdysone treatment. These results provide a genome-level view of the chitin-binding protein in silkworm and suggest that BmCBP1 participates in the formation of the new cuticle during molting.     

Ultrastructure of Porocephalus crotali (Pentastomida) cuticle with phylogenetic implications.

The cuticle of P. crotali is pro-arthropodan, composed of an epi-, exo-, and endocuticle. The exo- and endocuticles are separated by a 600-A intermediate cuticular zone. The epicuticle is homogeneous and varies from 100 to 350 A in thickness. The exocuticle varies from 2 to eight mu in thickness and is divided into superficial and deep exocuticular zones. The endocuticle is lamellate and varies from 8 to 30 mu in thickness. Lamellae result from ordered parabolic orientations of 40-A chitin fibrils. Underlying cells lack a basement membrane. Subcuticular muscle cells insert tonofibrils directly into the adjacent endocuticle. No apodemes or apophyses occur.     

An easy,inexpensive, and sensitive method for the quantification of chitin in insect peritrophic membrane by image processing

ABSTRACT

Chitin, poly (β-(1→4)-N-acetyl-d-glucosamine), is an important biopolymer for insects that is utilized as a major component of peritrophic membrane. The chitin content in peritrophic membrane is of expedient interest from a pest control perspective, although it is hard to quantify chitin. In this study, we establish a facile method for the quantification of chitin in peritrophic membrane by image processing. In this method, chitin was indirectly quantified using chitosan–I₃^? complex, which exhibited a specific red-purple color. A calibration curve using a chitosan solution showed good linearity in a concentration range of 0.05–0.5 μg/μL. We quantified the amount of chitin in peritrophic membrane of Spodoptera litura (Lepidoptera: Noctuidae) larvae using this method. Throughout the study, only common inexpensive regents and easily attainable apparatuses were employed. This method can be easily applied to the sensitive quantification of the amounts of chitin and chitosan in materials by wide range of researchers.

Abbreviations: LOD: limit of detection; LOQ: limit of quantification; ROI: region of interest; RSD: relative standard deviation.     

Formation,properties and degradation of the peritrophic membranes of larval and adult fleshflies,Parasarcophaga argyrostoma (Insecta,Diptera)

Summary Parasarcophaga argyrostoma larvae continuously secrete a single, tube-like peritrophic membrane (PM), which has an electron-dense layer on the lumen side and a thicker chitin-containing electron-lucent part on the epithelium side. In the adult fleshfly, the secretion of PMs starts immediately after emergence. The initial part of the PMs is twisted and tight. The formation zone is folded with two separate secretory pads in which two tube-like PMs are formed continuously. The PMs are different, morphologically and with respect to their peripheral carbohydrate residues. The latter could be demonstrated with lectin gold conjugates. PM 1 consists of an electron-dense, chitin-free layer on the lumen side and a thicker part which contains chitin microfibrils in the matrix. PM 2 appears fluffy and has chitin microfibrils in its matrix, too. Chitin could be localized with WGA gold. Incubation of isolated PM 1 with lectin gold resulted in a peculiar pattern of bound lectins and gaps on the electron dense layer which otherwise appeared to be homogenous. Degradation of peritrophic membranes takes place in the hindgut. The cuticle of the anterior hindgut is studded with small teeth, which seem to be responsible for mechanical degradation of the peritrophic membranes into frayed pieces. This may be completed by the teeth on the rectal pads. From the appearance of the remnants of the peritrophic membranes it can be inferred that chemical degradation takes place in the hindgut.Supported by the Deutsche Forschungsgemeinschaft     

Chemical and ultrastructural studies of isolated cell walls of Epidermophyton floccosum: Presence of chitin inferred from X-ray diffraction analysis and electron microscopy

Cell walls of Epidermophyton floccosum were isolated in high purity after mechanical breakage in the Ribi fractionator, followed by sonication and sodium dodecyl sulfate treatment. Major carbohydrate components of cell wall hydrolsates were glucose (35.2%) and glucosamine (30.9%), with lesser amounts of mannose and galactose.After treating isolated cell walls with acid and alkali, the glucosamine polymer was isolated in the form of insoluble residues, and was shown to be compared of chitin fibers by X-ray diffraction analysis and electron microscopy. The surface architecture of isolated cell walls, observed by scanning and shadowing electron microscopy, revealed some remarkable differences in the length and thickness of the fibrils, and also in the orientation of the network, between the internal and external surfaces of the cell wall. A possible involvement of chitin in cell wall integrity is discussed.     

Electron microscopic localization of chitin using colloidal gold labelled with wheat germ agglutinin

Summary The lectin wheat germ agglutinin (WGA) has a binding site which is able to bind a sequence of three N-acetyl-glucosamine residues. Therefore, it has a very strong affinity for the polymers of this sugar, especially chitin. Colloidal gold can be labelled with WGA and used as a specific electron-dense marker for the electron-microseopic localization of chitin. The specificity of the WGA-gold binding can be checked by competitive inhibition with 5–10 mM triacetyl chitotriose. The reliability of this method was tested in three species. In the formation zone of the radula of the snail, Biomphalaria glabrata Say, chitin or chitin precursors were localized in vesicles of the odontoblasts, outside the extremely long microvilli of odontoblasts and in the newly formed teeth. The inner peritrophic envelope of the earwig, Forficula auricularia L., is characterized by an orthognal texture of bundles of microfibrils that are thought to contain chitin. The pesence of chitin was proved using the present method. In the peritrophic membranes of the blowfly, Calliphora erythrocephala Meigen, it was possible to differentiate between chitin and glycoproteins which have N-acetylglucosamine residues.     

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.     

Some mechanical properties of crossed fibrillar chitin

The sclerites of P. sinuata consist of crossed reticulate layers of chitin fibrils arranged in the preferred orientation together with protein glues. Stretched beetle whole cuticle and chitin obey Hooke's law in the elastic region. Anisotropic swelling in a sclerite ensures flexibility and prevents sliding in the plane surface. Chitin micelle orientation can be strain-induced in vitro. Although two-phase materials, neither beetle nor locust cuticle meet the requirements of plywood mechanics.     

Fungal contributions to carbon flow and nutrient cycling during decomposition of standing Typha domingensis leaves in a subtropical freshwater marsh

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Crystallographic aspects of sub-elementary cellulose fibrils occurring in the wall of rose cells culturedin vitro

Summary Quantities of disencrusted sub-elementary cellulose fibrils from the cell wall of rose cells culturedin vitro were prepared. Following an X-ray and electron diffraction analysis, these fibrils gave a cellulose diffraction pattern which presented only two strong equatorial diffraction spacings at 0.409 and 0.572 nm indicating that the fibrils have a crystalline structure resembling that of cellulose IV_I. This observation is best explained in terms of a lateral disorganization of the cellulose chains within the fibrils. This disorganization cannot be eliminated and is connected with the small width of the fibrils which contain from 12 to 25 cellulose chains only. In these fibrils, most of the cellulose chains are superficial and not locked with neighboring chains in a tight hydrogen bond system as in thicker cellulose microfibrils.     

Chitin in the peritrophic membrane of Acarus siro (Acari: Acaridae) as a target for novel acaricides

The peritrophic membrane in Acarus siro L. (Acari: Acaridae) is produced by distinct cells located in the ventriculus. In this study, the chitin inside the peritrophic membrane was detected using wheat germ-lectin conjugated with colloidal gold (10 nm). The chitin fibrils of the peritrophic membrane were a target for chitin effectors, including 1) chitinase, which hydrolyzes chitin fibers inside the peritrophic membrane; 2) calcofluor, which binds to chitin and destroys the peritrophic membrane mesh structure; and 3) diflubenzuron, which inhibits chitin synthesis. In addition, soybean trypsin protease inhibitor (STI) and cocktails of chitinase/calcofluor, diflubenzuron/calcofluor and chitinase/STI were tested. These compounds were supplemented in diets and an increase of population initiated from 50 individuals was observed after 21 d of cultivation. Final A. siro densities on experimental and control diets were compared. The chitin in the peritrophic membrane was determined to be a suitable target for novel acaricidal compounds for suppressing the population growth of A. siro. The most effective compounds were calcofluor and diflubenzuron, whereas the suppressive effects of chitinase and STI were low. The failure of chitinase could be due to its degradation by endogenous proteases. The combination of chitinase and STI suppressed A. siro population growth more effectively than when they were tested in oral admission separately. The combinations of calcofluor/chitinase or calcofluor/difluorbenzuron showed no additive effects on final A. siro density. The presence of chitin in peritrophic membrane provides a target for novel acaricidal compounds, which disrupt peritrophic membrane structure. The suitability of chitin effectors and their practical application in the management of stored product mites is discussed.     

Chitinous fibrils in the lorica of the flagellate chrysophyte Poteriochromonas stipitata (syn. Ochromonas malhamensis)

Ordered microfibrils are formed on the membrane of the cytoplasmic tail of the alga Poteriochromonas after attachment to a substrate. The ultrastructure of native and extracted stalk fibrils was studied with electron microscope methods. In addition, the structural polysaccharide was characterized by hydrolyses, separation of the monomers by thin- layer chromatography, gas-liquid chromatography and amino acid analysis, and by X-ray diffraction. The alkali-resistant fibrils yielded mostly glucosamine upon extensive hydrolysis, and showed X-ray diffraction patterns similar to those of fugal chitin. It is concluded that the resistant core of the fibrils is chitinous.     

Secondary galling: a novel feeding strategy among ‘non‐pollinating’ fig wasps from Ficus curtipes

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Distribution of a model biocontrol agent (Serenade® MAX) in apple and pear by mason bees and bumble bees

1. Biocontrol agents (BCAs) are commonly sprayed on flowering pipfruit trees to prevent them from getting infected by various pathogens. By entomovectoring, BCAs can be directly delivered onto the flowers. However, we currently lack knowledge on the distribution dynamics of BCAs by pollinators.
2. Here, managed bees, both bumble bees (Bombus terrestris) and mason bees (Osmia bicornis and Osmia cornuta), were placed in the vicinity of flowering pipfruit trees (pear -‘Conference’, and apple—‘Svatava’ and ‘Jonagold’), and this allowed us to investigate the distribution of a model BCA, namely, Serenade® MAX, from spray-inoculated flowers of a centralized tree to non-inoculated flowers of surrounding receiver trees by bees in an experimental setup in outdoor conditions.
3. One hour after inoculation, we detected an enrichment of BCA in the flowers of the receiver trees and this for each tested pipfruit.
4. The distribution of BCA from treated to untreated flowers was homogenous between the receiver trees for ‘Svatava’, while significantly different loads were detected for both ‘Conference’ and ‘Jonagold’, which might be due to differences in environmental factors, and/or bee characteristics.
5. More research is needed to understand the distribution dynamics of BCAs by pollinators in field conditions, such as in commercial orchards or crop fields, and how this could result in an efficient control.