Peritrophic membrane structure and secretion in European corn borer larvae (Ostrinia nubilalis)

Peritrophic membrane (PM) secretion and formation occur primarily in the anterior region of the mesenteron in the European corn borer (Ostrinia nubilalis) as determined by light and electron microscopy. Nascent PM first became visible as fibrous linear chitin-containing structures stained with gold-labeled wheat germ agglutinin between and at the tips of the microvilli. No formed PM was visible at the foregut-midgut junction, but a thin single PM appeared first in the lumen between the stomodeal valves and the midgut epithelium. Just posterior to the stomodeal valves, multiple PMs were observed that became progressively thicker and more numerous in the mid and posterior regions of the mesenteron. The PM consists of an orthogonal chitin meshwork with openings slightly larger than the diameters of the microvilli. As it delaminates from the microvilli, the meshwork becomes embedded in proteinaceous matrix that greatly reduces the pore size of the PM.     

Spatial arrangement of fish gill secondary lamellar cells in intact and dissociated tissues from rainbow trout (Oncorhynchus mykiss) and Atlantic salmon (Salmo salar)

Gill structure of rainbow trout and Atlantic salmon was investigated using cell disaggregation and dry fracture techniques for scanning electron microscopy (SEM), allowing new interpreta-tions of the structure of the secondary lamella. The basement membrane underlying the lamellar epithelium (secondary epithelium) was shown to be a tough sheet with numerous depressions corresponding to underlying pillar cells. This membrane is probably the most important structural element of the secondary lamella, capable of withstanding considerable mechanical stress. For the first time the structure of the apical surface of the secondary lamella was shown by SEM to consist of an outer microridged coat overlying a fibrous coat which appears continuous with the extracellular matrix surrounding the rest of the cell. When cells were detached they rounded up and the external microridged coat became more vesicle like, indicating the labile nature of this coat. In cell suspension preparations, epithelial, mucus and chloride cells are present as well as many blood derived cells such as erythrocytes, presumptive leucocytes and thrombocytes.     

Lepidopteran peritrophic membranes and effects of dietary wheat germ agglutinin on their formation and structure

Peritrophic membrane (PM) structure and the effects of dietary wheat germ agglutinin (WGA) on PM formation were studied in larvae of the European corn borer (ECB), Ostrinia nubilalis, and the tobacco hornworm (THW), Manduca sexta. Growth of ECB was strongly inhibited by low amounts of WGA in the diet (0.05%), whereas THW was not affected by amounts of up to 2%. In ECB larvae, chitin microfibrils were secreted to form an orthogonal network within the apical region of the anterior midgut microvilli. The network then moved to the tips of the microvilli where proteinacious matrix was added prior to delamination of a single PM into the lumen to enclose the food bolus. Multiple PMs rapidly appeared as the food moved posteriorly and some of these became greatly thickened in the middle and posterior regions of the midgut. WGA in the diet caused hypersecretion of unorganized PM in the anterior midgut lumen, disintegration of microvilli, and cessation of feeding. It was also shown to bind to both the chitinous network and to several PM proteins, perhaps causing voids in the PM and sparse matrix material. This allowed the passage of food particles through a defective PM into the ectoperitrophic space and penetration into the microvillar brush border. Stimulation of PM secretion and cessation of feeding may have been a response to damage to the brush border. Unlike ECB, the chitinous network of THW is a randomly organized felt-like structure embedded in a proteinaceous matrix. This PM is secreted as a thin multilayered structure in the anterior region of the midgut, but multiple and thickened PMs occur in the middle and posterior lumens of the midgut. THW tolerated high amounts of WGA in its diet with no disruption of PM formation or inhibition of growth. WGA did accumulate as large masses embedded in the PM, but caused no voids that would allow the penetration of food particles and subsequent damage to the brush border. Therefore, differences in PM formation and structure between ECB and THW appeared to affect how WGA interacts with chitinous and proteinaceous components of the PM and subsequent effects on larval feeding and growth.     

Effect of wheat germ agglutinin on formation and structure of the peritrophic membrane in European corn borer (Ostrinia nubilalis) larvae

European corn borer (ECB; Ostrinia nubilalis (Hubner)) larvae (third instar) fed 0.05% w/w wheat germ agglutinin (WGA) in their diet for 72 h showed very little increase in body weight, whereas weight of control larvae increased nearly fourfold. Light and transmission electron microscopy studies showed that the morphology of the peritrophic membrane (PM) changed within 24 h after ECB larvae fed on the WGA diet. Whereas the PM in the anterior region of the midgut was a thin membranous structure in control larvae, the WGA-fed larvae secreted a multiple-layered and unorganized PM that contained embedded food particles, bacteria, and pieces of disintegrated microvilli. Gold-labeled WGA was localized specifically in the PM and microvilli. The PM of WGA-fed larvae was inundated with dark-staining amorphous structures that, when incubated with anti-WGA, showed heavy WGA localization. The antibody label indicated that most of the ingested WGA was found in the PM, with lesser amounts on the microvillar surface and the least amount within the epithelium. After 72 h, the middle portion of the mesenteron revealed a thin, compact PM in the control larvae, whereas the PM of the WGA-fed larvae was multilayered and discontinuous, which allowed plant cell-wall fragments to penetrate into the microvilli of the epithelium. Scanning electron microscopy of PMs from fifth instar ECB larvae fed the WGA diet revealed a breakdown in the chitinous meshwork by 48 h after initiation of feeding. The endo-PM surface from control larvae was smooth and intact, whereas the PM of WGA-fed larvae showed disintegration of the meshwork and a reduced proteinaceous matrix. This allowed bacteria and food particles to penetrate through the PM into the ectoperitrophic space and directly contact the microvilli. Therefore, WGA, a protein inhibitor of larval growth, interferes with the formation and integrity of the PM, which exposes the brush border to ingested material. This, in turn, appears to stimulate secretion of additional PM layers, the concomitant disintegration of the microvilli, and cessation of feeding.     

Modeling the structure of the type I peritrophic matrix: characterization of a Mamestra configurata intestinal mucin and a novel peritrophin containing 19 chitin binding domains

Twelve to fourteen integral proteins were found to reside in the Type I peritrophic matrix (PM) of Mamestra configurata (bertha armyworm) larvae. Several methods were employed, including de novo peptide sequencing, the generation of a midgut-specific EST database and immunological screening, which led to the isolation of cDNAs encoding two integral PM proteins. McPM1, the largest PM protein described to date at 202 kDa, was comprised of a concatamer of 19 chitin binding domains (CBD), 12 of which resided within a central repetitive region consisting of six iterations of a two CBD module. The protein was found to reside within the PM primarily as several lower molecular weight, presumably proteolytically processed, forms. McMUC1 was similar in structure to other insect intestinal mucins (IIM) and was highly glycosylated. The expression of both proteins was restricted to the larval midgut. Lower molecular weight proteins that may represent non- and partially glycosylated forms of McMUC1 were also recognized by an anti-McMUC1 antiserum. These were preferentially degraded upon ingestion of M. configurata multi-capsid nucleopolyhedrovirus by larvae, possibly by a viral-encoded metalloprotease. A molecular model of PM structure is presented featuring the interaction of McPM1 with chitin inter-fibril junctions and McMUC1 with the extended chains in the internodal regions. The potential for interaction between PM proteins via intermolecular disulfide bond formation and through association of CBD with N-linked glycans is discussed.     

Susceptibility/resistance of Anticarsia gemmatalis larvae to its nucleopolyhedrovirus (AgMNPV): Structural study of the peritrophic membrane

This investigation compares the peritrophic membrane (PM) morphology along the midgut of susceptible (SL) and resistant (RL) Anticarsia gemmatalis larvae to the AgMNPV. The PM increased the thickness from the anterior to the posterior midgut region in both insects strain; however, the intensity of FITC-WGA reaction of the PM in the RL were greater than in SL. The PM in RL was ultrastructurally constituted by several layers of fibrous/vesicular materials in comparison with the few ones in SL. Our results showed that the structure of PM in the RL could be one of the resistance barriers to AgMNPV.     

The Fine Structure of the Epithelial Cells of the Mouse Prostate : I. Coagulating Gland Epithelium

The fine structure of the epithelial cells of the anterior lobe, or coagulating gland, of the mouse prostate has been investigated by electron microscopy. This organ is composed of small tubules, lined by tall, simple cuboidal epithelium surrounded by connective tissue and smooth muscle. The epithelial cells are limited by a distinct plasma membrane, which covers minute projections of the cytoplasm into the lumen. The cell membranes of adjacent cells are separated by a narrow layer of structureless material of low density. The cavities of the endoplasmic reticulum are greatly dilated, and the cytoplasmic matrix is reduced to narrow strands, in which the various organelles are visible. The content of the cavities of the endoplasmic reticulum appears as structureless material of lesser density than the cytoplasmic matrix. Material which may be interpreted as secretion products can be seen in the lumina of the tubules. The possible nature of the material inside the cisternal spaces and the secretory mechanisms in these cells is discussed.     

Ultrastructural study of cat zona pellucida during oocyte maturation and fertilization

The mammalian zona pellucida (ZP) is an extracellular glycoprotein structure formed around growing oocytes, ovulated eggs and preimplantation embryos. The specific functions of ZP are highly determined by its morphological structure. Studies on cat oocytes during maturation and after fertilization were undertaken, using routine transmission (TEM) and scanning electron microscopy (SEM). Two basic ZP layers – outer with rough spongy appearance and inner with smaller fenestrations and smooth fibrous network – were visible. Deposits, secreted by oviductal cells formed new layer, the so called oviductal ZP. After fertilization outer ZP showed rougher meshed network due to fusion between filaments as a consequence from sperm penetration while the inner was smoother with melted appearance. The presented data on the SEM and TEM characteristics of cat oocytes, together with our previous studies on carbohydrate distribution suggest that during oocyte maturation and fertilization ZP undergoes structural and functional rearrangements related to sperm binding and penetration.     

Biondi bodies in the choroid plexus epithelium of the human brain

Summary Scanning electron microscopy (SEM) was used to examine choroid plexuses in the brain of two human adults aged 44 and 46, respectively, and 12 older subjects from 67 to 98 years of age. It was possible to obtain a three-dimensional view of the ring-like structures (Biondi bodies) located in the cytoplasm of choroid plexus epithelial cells in the older-age group. The filaments forming the rings were clearly visible. No such structures were found between epithelial cells. The intracellular location of the Biondi bodies and their state of preservation compared to other cytoplasmic elements suggest that they may have a destructive effect on epithelial cells of choroid plexuses. The same material was examined by transmission electron microscopy (TEM); the results obtained were in full agreement with the evidence obtained with SEM.     

The fine structure of the digestive system of Daphnia pulex (Crustacea: Cladocera).

The alimentary canal of Daphnia pulex consists of a tube-shaped foregut, a midgut (mesenteron) with an anterior pair of small diverticula, and a short hindgut. The foregut and hindgut are structurally similar. Each is formed by a low cuboidal epithelium 5 mum tall and lined with a chitinous intima. The midgut wall consists of a simple epithelium resting on a thick beaded basal lamina which is surrounded by a spiraling muscularis. Anteriorly the midgut cells are columnar in shape being 30 mum in height each having a basal nucleus, anteriorly concentrated mitochondria and in apical border of long thin microvilli. Posteriorly the midgut cells become progressively shorter so that in the posteriormost region of the midgut the cells are 5 mum tall and cuboidal in shape. The microvilli concomitantly become shorter and thicker. All mesenteron cells contain the usual cytoplasmic organelles. The paired digestive diverticula are simple evaginations of the midgut. The wall of each consists of a simple epithelium of cuboidal cells 25 mum in height, each with a brushed border of long thin microvilli. Enzyme secretion appears to be holocrine in mode and not confined to any one region of the mesenteron though definitely polarized anteriorly. The thin gut muscularis encircles the entire length of the midgut and caeca. Thick and thin filaments appear to be in a 6:1 ratio.     

Matrices containing glycosaminoglycans in the developing anterior chambers of chick and Xenopus embryonic eyes.

The fibrous matrix present in the anterior chamber of the chick eye on the 4th day of development has been shown by autoradiography and histochemistry to contain chondroitin sulfate, protein, neutral polysaccharides, and possibly hyaluronic acid (HA). Its synthesis, probably by the mesenchyme of the angle of the eye, is completed by around 10 days of development. In the scanning electron microscope (SEM) it can be seen that, although the matrix thins as the eye grows, it does not disappear until the 15th day. The development of the Xenopus cornea is described; this animal has a matrix in its anterior chamber from soon after the formation of the inner cornea (stage 41) until metamorphosis 7 weeks later. In the SEM, this material appears as a dense, featureless aggregate rather than as a matrix of thick fibres; in the transmission electron microscope, it is seen to be a network of fine filaments containing small dark-staining granules. Histochemistry shows that it contains HA, protein, and neutral polysaccharides. The morphological evidence is compatible with the matrix being made by the inner cornea. The probable major role of the matrix is to separate lens from cornea in establishing the anterior chamber. In the chick embryo, at least, the matrix is also likely to help stabilise the endothelium during its formation.     

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.     

Changes in amount of bacteria during gut passage of leaf litter and during coprophagy in three species of<Emphasis Type="Italic">Bibionidae (Diptera)</Emphasis> larvae

To elucidate the interaction between bacteria and saprophagous Diptera larvae, the amounts of bacteria in leaf litter, individual gut compartments, and feces of three species of Bibionidae (Bibio pomonae, Bibio marci, and Penthetria holosericea), feeding either directly on leaf litter or on fecal pellets produced from leaf litter by larvae of the same species, were assessed by determining total direct counts and viable counts on solid media at different pH. In P. holosericea, the effect of various cultivation temperatures on direct counts of bacteria in individual compartments was also demonstrated. In all species, the amount of bacteria in the anterior mesenteron was lower than in the consumed food, regardless of whether the larvae were feeding on leaf litter or feces, and increased again in the posterior part of the gut. The amount of bacteria in these compartments was generally higher in larvae feeding on feces than in those feeding on leaf litter, whereas the amount of bacteria found in the ceca varied. In B. marci, the amount of bacteria in the mesenteron sections able to grow on alkaline medium (pH 9) was higher than that of bacteria able to grow on slightly acidic medium (pH 5.5) during both the first and the second gut passage. In B. pomonae and P. holosericea, this increase was observed only during the second gut passage. The effect of gut passage in P. holosericea on changes in direct counts of bacteria was more pronounced when the larvae were fed at 5 degrees C as compared to 20 degrees C. Radiolabeled bacteria were digested in the gut and utilized as a source of energy and nutrients by the larvae; digested bacteria represented up to 10% of the material assimilated by the larvae. Lysozyme activity in whole-gut extracts of P. holosericea had a pH optimum of at pH 7, indicating a low in situ activity in the alkaline mesenteron. Proteinase activity, however, had an optimum at pH > 12, suggesting that the digestion of bacteria in the bibionid gut is caused by a combination of digestive proteinases and alkaline pH in the anterior mesenteron.     

Formation of the endothelium of the avian cornea: A study of cell movement in vivo

In the analysis of endothelial morphogenesis reported here, scanning and transmission electron microscopes and the Nomarski light microscope were used to study both untreated and manipulated eyes of chick embryos. We found that migration of the cells into the corneal area is preceded at stage 22 by a movement of macrophages between the lens and posterior surface of the corneal stroma. At stage 23, endothelial cells move out mainly from the nasal and temporal edges of the eye where they were associated with vascular (primary) mesenchyme. Initially, they migrate through a fibrous matrix which occupies the space between lens and optic lip. When the endothelial cells reach the stroma and capsule of the lens, they can use both these surfaces as substrata, even though they seem to be more adherent to the stroma. By stage 25, the endothelium is complete and covered with fibrous matrix, which now fills and may help form the anterior chamber. The cells, initially mesenchymal, now differentiate to become epithelial (a characteristic of primary mesenchyme). The migrating endothelial cells have extended lamellipodia and filopodia along their leading edges; they show no evidence of ruffling. Moreover, contact inhibition alone does not cause them to monolayer; the presence of the lens is essential to prevent multilayering of the newly formed endothelium. In the discussion, the role of extracellular matrix and tissue boundaries in directing cell migration in vivo is emphasized.     

Preparation and characterization of glutaraldehyde cross-linked O-carboxymethylchitosan microspheres for controlled delivery of pazufloxacin mesilate

O-carboxymethylchitosan (OCMC) microspheres containing an antibiotic drug pazufloxacin mesilate (PM) have been successfully prepared by emulsion cross-linking using glutaraldehyde (GA). Various manufacturing parameters, including amount of cross-linking agent and OCMC:PM ratios were altered to optimize process variables during the microspheres production. The structure and morphology were characterized by Fourier transform infrared (FT-IR), wide-angle X-ray diffraction (WXRD) and scanning electron microscopy (SEM). The swelling and releasing behaviors of the microspheres at pH 1.2 and 7.4 media were investigated. The results revealed that the microspheres had a spherical, rough morphology and with a narrow size distribution. The degree of swelling of microspheres at pH 7.4 media was higher than that at pH 1.2 media. The microspheres proved to be successful in prolonging drug release. The release of PM was found to depend upon the extent of matrix cross-linking and drug loading. The release profiles of PM from OCMC microspheres were found to be biphasic with a burst release followed by a gradual release phase, and followed the Higuchi matrix model.     

Morphologic changes of the basal lamina in the small intestine of Xenopus laevis during metamorphosis

Further investigations of the epithelial and mesothelial basal lamina of the duodenum of Xenopus laevis during metamorphosis were performed by means of scanning electron microscopy (SEM) and histochemical techniques using polyethyleneimine (PEI) to demonstrate anionic sites as well as light- and transmission-electron-microscopic methods involving morphometric analysis. The basal lamina of the duodenal epithelial cells was smooth, and it was occasionally curved along the processes of the epithelial cells (stages 56-59). The basal lamina became thicker by folding, and the thickness of the folded basal lamina exceeded 1 micron (stages 60-62). Subsequently, the folded basal lamina disappeared gradually and became almost smooth again and consisted of only one layer (stages 63-66). After removing the epithelium by boric acid, SEM revealed that the small ridges of the basal lamina protruded like a mesh-work into the luminal side, and the luminal surface of the basal lamina became smooth at later stages of the metamorphic climax. The electron-dense granules of PEI-positive material were localized at both sides of the lamina densa at regular intervals (80-100 nm). The basal lamina of the mesothelial cells was almost smooth at stages 56-59 and started to show occasional slight folding. This folding became continuous and deeper (stages 60-62). The folded mesothelial basal lamina disappeared except for the cell-associated basal lamina and became smooth again at later stages of the metamorphic climax (stages 63-66). These morphologic changes of the basal lamina observed in the epithelium and mesothelium may be induced by common factors. We suggest that physical changes in the small intestine involving the shortening and narrowing should be a main factor to cause these changes in the basal lamina. Furthermore, morphometric analysis proposed that the basal lamina becomes more complex by adding newly synthesized basal lamina material, especially in the epithelium.     

Capsulation of in vitro and in vivo grown Bacteroides species

By centrifugation on a four step Percoll density gradient cells of Bacteroides species could be separated according to the size of extracellular structure. The difference in size was visible by both light and electron microscopy. Two structures were observed on Bacteroides fragilis by electron microscopy, namely a fibrous network and an electron dense layer. An electron dense layer was visible on Bacteroides ovatus only when stained with ruthenium red. B. fragilis cells grown in the mouse peritoneal cavity did not produce a large fibrous network. An electron dense layer was observed on some cells in the presence of ruthenium red stain and cells possessing this layer were phagocytosed in vivo.     

Degradation of the S. frugiperda peritrophic matrix by an inducible maize cysteine protease

A unique 33-kDa cysteine protease (Mir1-CP) rapidly accumulates at the feeding site in the whorls of maize (Zea mays L.) lines that are resistant to herbivory by Spodoptera frugiperda and other lepidopteran species. When larvae were reared on resistant plants, larval growth was reduced due to impaired nutrient utilization. Scanning electron microscopy (SEM) indicated that the peritrophic matrix (PM) was damaged when larvae fed on resistant plants or transgenic maize callus expressing Mir1-CP. To directly determine the effects of Mir1-CP on the PM in vitro, dissected PMs were treated with purified, recombinant Mir1-CP and the movement of Blue Dextran 2000 across the PM was measured. Mir1-CP completely permeabilized the PM and the time required to reach full permeability was inversely proportional to the concentration of Mir1-CP. Inclusion of E64, a specific cysteine protease inhibitor prevented the damage. The lumen side of the PM was more vulnerable to Mir1-CP attack than the epithelial side. Mir1-CP damaged the PM at pH values as high as 8.5 and more actively permeabilized the PM than equivalent concentrations of the cysteine proteases papain, bromelain and ficin. The effect of Mir1-CP on the PMs of Helicoverpa zea, Danaus plexippus, Ostrinia nubilalis, Periplaneta americana and Tenebrio molitor also was tested, but the greatest effect was on the S. frugiperda PM. These results demonstrate that the insect-inducible Mir1-CP directly damages the PM in vitro and is critical to insect defense in maize.