Regeneration of midgut epithelial cell in the silkworm, Bombyx mori, infected with viruses

In the larvae of the silkworm, Bombyx mori, the regeneration of midgut cells infected with a cytoplasmic polyhedrosis virus (CPV), a flacherie virus (FV), and a small DNA virus (SDV) was studied. Large numbers of newly developed cells appeared in the CPV-infected part of the midgut epithelium just before larval molt, and along with their development, the CPV-infected old columnar cells were discharged into the midgut lumen during the molt. On the other hand, in the uninfected portion of the midgut only a few cells developed, and no columnar cells were discharged. Similarly, the marked replacement of midgut epithelial cells during larval molt was also observed in larvae infected with CPV + FV. In the larvae infected with CPV + SDV, the columnar cells lost their regenerative ability, and because of the exfoliation of infected columnar cells, the midgut epithelium consisted mainly of uninfected goblet cells at a late stage of infection. The degree of epithelial regeneration varied with the silkworm strain and the dosage of the virus.     

Electron microscopic study of the anterior midgut in Cenocorixa bifida Hung. (Hemiptera: Corixidae) with reference to its secretory function

The epithelium of anterior midgut of adult Cenocorixa bifida was examined with light and electron microscopy. The folded epithelium is composed of tall columnar cells extending to the lumen, differentiating dark and light cells with interdigitating apices and regenerative basal cells in the nidi surrounded by villiform ridges that penetrate deeply into the epithelium. The columnar cells display microvilli at their luminal surface. Microvilli lined intercellular spaces and basal plasma membrane infoldings are associated with mitochondria. These ultrastructural features suggest their role in absorption of electrolytes and nutrients from the midgut lumen. The columnar cells contain large oval nuclei with prominent nucleoli. Their cytoplasm is rich in rough endoplasmic reticulum, Golgi complexes and electron-dense secretory granules indicating that they are also engaged in synthesis of digestive enzymes. The presence of secretory granules in close proximity of the apical plasma membrane suggests the release of secretion is by exocytosis. The presence of degenerating cells containing secretory granules at the luminal surface and the occurance of empty vesicles and cell fragments in the lumen are consistent with the holocrine secretion of digestive enzymes. Apical extrusions of columnar cells filled with fine granular material are most likely formed in response to the lack of food in the midgut. The presence of laminated concretions in the cytoplasm is indicative of storageexcretion of surplus minerals. The peritrophic membrane is absent from the midgut of C. bifida.     

Comparative midgut ultrastructure of unfed larvae and adult mites of Platytrombidium fasciatum (C.L. Koch, 1836) and Camerotrombidium pexatum (C.L. Koch, 1837) (Acariformes: Microtrombidiidae)

The midgut of unfed larvae and adult mites of Platytrombidium fasciatum (C.L. Koch, 1836) and Camerotrombidium pexatum (C.L. Koch, 1937) (Acariformes: Microtrombidiidae) was investigated by electron microscopy. The sac-like midgut occupies the entire body volume, ends blindly and is not divided into functionally differentiated diverticula or caeca. The midgut walls are composed of one type of digestive cell that greatly varies in shape and size. In larvae, the lumen of the midgut is poorly recognizable and its epithelium is loosely organized, although yolk granules are already utilized. In adults, the midgut forms compartments as a result of deep folds of the midgut walls, and the lumen is well distinguished. The epithelium is composed of flat, prismatic or club-like cells, which may contain nutritional vacuoles and residual bodies in various proportions that depend on digestive stages. In both larvae and adult mites, parts of cells may detach from the epithelium and float within the lumen. The cells contain a system of tubules and vesicles of a trans-Golgi network, whereas the apical surface forms microvilli as well as pinocytotic pits and vesicles. Lysosome-like bodies, lipid inclusions and some amount of glycogen particles are also present in the digestive cells. Spherites (concretions) are not found to be a constant component of the digestive cells and in adult mites occur for the most parts in the midgut lumen.     

Proteolysis, histopathological effects, and immunohistopathological localization of delta-endotoxins of Bacillus thuringiensis subsp. kurstaki in the midgut of lepidopteran olive tree pathogenic insect Prays oleae

Considering the fact that Prays oleae is one of the most pathogenic insects to the olive tree in the Mediterranean particularly in Tunisia, the mode of action of Cry insecticidal toxins of Bacillus thuringiensis kurstaki in Prays oleae midgut was investigated. The proteolysis of Bacillus thuringiensis δ-endotoxins in the midgut was a key step in determining their potency against Prays oleae. The latter's proteases activated the δ-endotoxins early, yielding stable toxins. The in vitro and in vivo binding of these toxins to Prays oleae larvae midgut was studied immunohistochemically, evidencing a midgut columnar cell vacuolization, microvilli damage, and then a pass of epithelium cell content into the larvae midgut. Moreover, Bacillus thuringiensis toxins were shown to bind to the apical microvilli of the midgut epithelial cells. The in vitro study of the interaction of Prays oleae midgut proteins with biotinylated Bacillus thuringiensis toxins allowed the prediction of four suitable receptor proteins in Prays oleae.     

Functional ultrastructure of the midgut of the fire ant Solenopsis saevissima Forel 1904 (Formicidae: Myrmicinae)

Solenopsis saevissima has a midgut composed of columnar, regenerative, and goblet cells. The midgut epithelium was covered by a basal lamina. Outside the basal lamina, layers of inner oblique, circular, and outer longitudinal muscles were present. Columnar cells showed a basal plasma membrane containing numerous folds, mitochondria, and the nucleus. Rough endoplasmic reticulum, Golgi bodies, membrane bounded vacuoles, and spherocrystals were found in this region. The apical plasma membrane was constituted by microvilli, which were above a region rich in mitochondria. Regenerative cells were found in groups lying by the basal lamina. Goblet cells were associated with an ion-transporting mechanism between the haemolymph and the midgut epithelium. These cells were lying by the midgut lumen and large microvilli were evident, but the cytoplasmic features were similar to the columnar cells.     

Structure and formation of the peritrophic membrane in the larva of the southern corn rootworm, Diabrotica undecimpunctata

The peritrophic membrane (PM) in larvae of the southern corn rootworm Diabrotica undecimpunctata (Coleoptera:Chrysomelidae) forms along the full length of the midgut epithelium, defining D. undecimpunctata as a Type I insect with respect to PM formation. PM formation occurs in three phases: organization of a continuous lamella of matrix from material secreted into the interstices between the microvilli, maturation and apical movement of the lamella along the microvilli, and shedding of the lamella from the tips of the microvilli into the midgut lumen. Subsequent cycles of synthesis and shedding give rise to multiple, concentric lamellae which surround the food in the gut lumen. PM lamellae are 0.2 mum in profile width and consist of a core of bundles of 5 nm-diameter microfibers encased in a finely-granular homogeneous material. The microfiber bundles are arranged in an orthogonal grid-like array with dimensions consistent with formation around the microvilli. The homogeneous material separates from the PM lamellae to enclose food particles suggesting it may contain digestive enzymes. The PM, microvilli and intracellular vesicles in the midgut epithelium stain intensely with wheat germ agglutinin reflecting the presence and sites of secretion and synthesis of chitin.     

ACTIVE TRANSPORT BY THE CECROPIA MIDGUT : II. Fine Structure of the Midgut Epithelium

A morphological basis for transcellular potassium transport in the midgut of the mature fifth instar larvae of Hyalophora cecropia has been established through studies with the light and electron microscopes. The single-layered epithelium consists of two distinct cell types, the columnar cell and the goblet cell. No regenerative cells are present. Both columnar and goblet cells rest on a well developed basement lamina. The basal portion of the columnar cell is incompletely divided into compartments by deep infoldings of the plasma membrane, whereas the apical end consists of numerous cytoplasmic projections, each of which is covered with a fine fuzzy or filamentous material. The cytoplasm of this cell contains large amounts of rough endoplasmic reticulum, microtubules, and mitochondria. In the basal region of the cell the mitochondria are oriented parallel to the long axes of the folded plasma-lemma, but in the intermediate and apical portions they are randomly scattered within the cytoplasmic matrix. Compared to the columnar cell, the goblet cell has relatively little endoplasmic reticulum. On the other hand, the plications of the plasma membrane of the goblet cell greatly exceed those of the columnar cell. One can distinguish at least four characteristic types of folding: (a) basal podocytelike extensions, (b) lateral evaginations, (c) apical microvilli, and (d) specialized cytoplasmic projections which line the goblet chamber. Apically, the projections are large and branch to form villus-like units, whereas in the major portion of the cavity each projection appears to contain an elongate mitochondrion. Junctional complexes of similar kind and position appear between neighboring columnar cells and between adjacent columnar and goblet cells as follows: a zonula adherens is found near the luminal surface and is followed by one or more zonulae occludentes. The morphological data obtained in this study and the physiological information on ion transport through the midgut epithelium have encouraged us to suggest that the goblet cell may be the principal unit of active potassium transport from the hemolymph to the lumen of the midgut. We have postulated that ion accumulation by mitochondria in close association with plicated plasma membranes may play a role in the active movement of potassium across the midgut.     

Cell differentiation in the embryonic midgut of the tobacco hornworm, Manduca sexta

While the larval midgut of Manduca sexta has been intensively studied as a model for ion transport, the developmental origins of this organ are poorly understood. In our study we have used light and electron microscopy to investigate the process of midgut epithelial cell differentiation in the embryo. Our studies were confined to the period between 56 and 95 hr of embryonic development (hatching is at 101 hr at 25 degrees C), since preliminary studies indicated that all morphologically visible differentiation of the midgut epithelium occurs during this time. At 56 hr the midgut epithelium is organized into a ragged pseudostratified epithelium. Over the next 10 hr, the embryo molts and the midgut epithelium takes on a distinctive character in which the future goblet and columnar cells can be identified. With further differentiation, closed vesicles in the goblet cells expand and subsequently communicate to the outside by way of a valve. The columnar cells form numerous microvilli on their apical surfaces that extend over the goblet cells. Both cell types form basal folds from a series of plasmalemmal invaginations. Differentiation occurs concurrent with a six-fold elongation of these cells.     

Ultrastructural changes in the midguts of Hessian fly larvae feeding on resistant wheat

The focus of the present study was to compare ultrastructure in the midguts of larvae of the Hessian fly, Mayetiola destructor (Say), under different feeding regimens. Larvae were either fed on Hessian fly-resistant or -susceptible wheat, and each group was compared to starved larvae. Within 3 h of larval Hessian fly feeding on resistant wheat, midgut microvilli were disrupted, and after 6 h, microvilli were absent. The disruption in microvilli in larvae feeding on resistant wheat were similar to those reported for midgut microvilli of European corn borer, Ostrinia nubilasis (Hubner), larvae fed a diet containing wheat germ agglutinin. Results from the present ultrastructural study, coupled with previous studies documenting expression of genes encoding lectin and lectin-like proteins is rapidly up-regulated in resistant wheat to larval Hessian fly, are indications that the midgut is a target of plant resistance compounds. In addition, the midgut of the larval Hessian fly is apparently unique among other dipterans in that no peritrophic membrane was observed. Ultrastructural changes in the midgut are discussed from the prospective of their potential affects on the gut physiology of Hessian fly larvae and the mechanism of antibiosis in the resistance of wheat to Hessian fly attack.     

Fine Structure of the Midgut and Hindgut in Lepidocampa weberi (Insecta,Diplura)

The fine structure of the alimentary canal, especially the midgut and hindgut of Lepidocampa weberi (Diplura: Campodeidae) is described. The general organization of the canal is similar to that of Campodea. The midgut epithelium is composed of columnar apical microvillated cells. Each nucleus contains a single intranuclear crystal. Close to the pyloric region, the posterior midgut cells are devoid of microvilli and intranuclear crystals. There is no special pyloric chamber as in Protura or pyloric cuticular ring as in Collembola but a morphological transformation from midgut to hindgut cells. Eight globular Malpighian papillae, consisting of distal microvillated cells and flat proximal cells, open into the gut lumen via ducts formed by hindgut cells. The structure of the hindgut is complicated and can be divided into three segments. The anterior hindgut cells have an irregular shape and compact cytoplasm. A striking interdigitation between the large bottle-shaped epithelial cells and longitudinal muscle cells occurs in the middle segment of the hindgut. The thick cuticle gives rise to long spikes projecting into the gut lumen. The posterior hindgut cells possess the morphological features for water reabsorption. Some hypotheses are advanced about the function of the different regions of the gut.     

Replacement of midgut epithelium in the greater wax moth,Galleria mellonela,during larval-pupal moult

The epithelium of larval midgut of the greater wax moth, Galleria mellonela, was replaced during the larval-pupal moult. The development of this moth was tentatively divided into 11 stages, from the full-grown larva of last instar to the 4-day-old pupa. The midgut at each stage was observed for (1) overall structure, (2) the position of goblet cells, and (3) the appearance of the yellow body. Light microscopy revealed that cell death in the midgut began in a cocoon-spinning larva (stage II), when pigments in the stemmata started to migrate. Before drastic remodeling started to occur, cytoplasmic projections in the goblet cavities were transformed. The larval midgut changed markedly at stage III, when the pigments left the stemmata. The epithelium of the larval midgut dropped as a whole into the lumen, transforming into the yellow body. Simultaneously, a pupal midgut epithelium developed. Electron microscopy of the columnar cells of a stage III larva showed that microvilli and mitochondria looked normal even though the nucleus with condensed heterochromatin resembled an apoptotic nucleus of vertebrate and higher plant cells. Caspase-3-like protease activity was restricted to the larval midgut and increased in parallel with the formation of the yellow body. The results indicate that the replacement of the larval midgut is facilitated by a typical apoptotic process.     

A study of the concentrically laminated concretions, 'spherites' in the regenerative cells of the midgut of Lepidopterous larvae

Concentrically laminated granules, spherites, are sometimes found in the regenerative cells of midgut of some species of lepidopterous larvae. The spherites are formed in cytoplasmic vesicles just before ecdysis and disappear during the differentiation of the regenerative cells to columnar and goblet cells. They function as intracellular stores of compounds used in the growth of the cell. Phosphates of magnesium and perhaps calcium are probable constituents. Spherites are sometimes also found in the degenerating columnar cells where they are excreted into the lumen with the exfoliating epithelium. The phenomenon of periodic precipitation which is the physical-chemical basis of the formation of spherites is discussed.     

Effect of sublethal Bacillus thuringiensis crystal endotoxin treatment on the larval midgut of a moth, Manduca: SEM study

The effect of a single, sublethal dose of B. thuringiensis crystal endotoxin on the midgut of the moth Manduca sexta larvae was monitored during acute and recovery stages. Initially both goblet and columnar cells swelled. Many columnar cells produced membrane extrusions. In some cases the affected cells ruptured, extruding cellular debris into the midgut lumen. Following the acute stage, the midgut tissue recovered, the damaged cells being extruded into the midgut lumen apparently as newly regenerated cells rose to take their place. The insects appeared to recover completely and continue normal development.     

The midgut of Tomocerus minor lubbock (Insecta,Collembola): Ultrastructure,cytochemistry, ageing and renewal during a moulting cycle

The midgut cells of Tomocerus minor (Insecta, Collembola) were examined with the electron microscope and cytochemically. The midgut epithelium consists of a series of cells characterised by numerous mineral concretions scattered throughout the cytoplasm. Mitochondria are abundant; microvilli are well developed at the apical surface of the cell. A zonula continua (continuous junction) characterises the apical contact region of these cells. Polysaccharides, glycoproteins and carbohydrate components have been demonstrated on the surface of microvilli. Peritrophic membranes surround the food bolus and preserve midgut cells from mechanical abrasion. Lysosomes are present during the alimentary period and show strong acid phosphatase activity. During an intermoulting cycle, two stages can be observed: (1) the postexuvial feeding period during which cytoplasmic extrusions appear at the apical part of the cell: lysosomes increase in number and autophagic vacuoles appear. (2) The preexuvial fasting period; a new epithelium grows beneath the old one and pushes it into the lumen. Degeneration processes can be observed in the old epithelium. This excretory reactivity of the midgut epithelium has been compared to the cycle of the cuticle.     

Formation and structure of the surface coat in the midgut of a waterstrider,Gerris najas deg. (Heteroptera : Gerridae)

The midgut epithelium of Gerris najas (Heteroptera : Gerridae) consists of a single cell type in different differentiating and functioning states. Cells elongate from nests of regenerative cells, forming together with their differentiating neighbours an interepithelial cavity, which contains coat material of membrane-like structure, and aggregations of cubic crystals visible only at this stage. Having reached a fold, the contents of the cavity are discharged into the lumen, and the young cells join the columnar cells. Exocytosis of coat material continues, while the cells gradually change to typical digestive columnar cells. The membrane-like material spreads from the folds into the lumen in whorls without forming a continuous cover of the luminal surface. Therefore, a peritrophic membrane does not exist in Gerris.     

Morphometry of the midgut epithelium of Diatraea saccharalis Fabricius, 1794 (Lepidoptera) parasitized by Cotesia flavipes Cameron, 1891 (Hymenoptera)

The morphometric study of the midgut in Diatraea saccharalis (Lepidoptera) larvae parasitized by the Cotesia flavipes (Hymenoptera) showed that there was significant increase in the columnar, goblet and regenerative cells and their nuclei; the midgut lumen diameter and the epithelial height were also increased in the parasitized larvae. The multivariate analysis showed that parasitism affected the columnar cell only in the posterior region, and the goblet cells along the midgut length (anterior and posterior regions).     

黑水虻消化道形态及组织结构的观察

本文比较了不同发育阶段黑水虻Hermetia illucens消化道的形态学差异,掌握了幼虫消化系统的组织学特征。利用体视镜观察黑水虻5龄幼虫、预蛹及成虫的消化道形态,利用光学显微镜和扫描电镜观察幼虫消化道各段(前肠、中肠、后肠)的显微及超微结构。结果表明：黑水虻幼虫及预蛹的消化道均由前肠(食道和前胃)、中肠及后肠组成,从幼虫到成虫,消化道的长度不断缩短。与幼虫和预蛹相比,成虫消化道形态变化明显,前胃消失,出现了嗉囊及胃盲囊,中肠进一步缩短,后肠分化为回肠、结肠和直肠。组织学观察结果显示,幼虫的唾液腺开口于口腔,由膨大的管状腺体和腺管组成。食道由特化为角质刺突的内膜层及发达的肌层组成,其末端延伸至前胃。前胃膨大为球状,包括三层组织结构。根据上皮细胞形态的差异,中肠可分为四个区段。后肠薄,肠腔内褶丰富,肠壁可见数量较多的杆状细菌。马氏管开口于中、后肠交界处,包括4支盲管,管内壁密布微绒毛。黑水虻消化道形态随发育阶段的变化,反映了各阶段摄食及消化生理的差异。幼虫消化道各段具有各自典型的组织学特征,其前、中、后肠可能分别承担了食物接纳与初步消化、消化与吸收以及重吸收功能。本研究结果为进一步了...     

Peritrophic membrane structure and formation of larvalTrichoplusia niwith an investigation on the secretion patterns of a PM mucin

Peritrophic membrane or matrix (PM) secretion and formation patterns were examined in the cabbage looper larvae (Trichoplusia ni[Hubner]) by transmission and scanning electron microscopy (SEM). PM first became visible in the lumen between tips of the microvilli and the stomodeal valves as a single layered fibrous structure that became more compact in appearance in the middle and posterior mesenteron. In the anterior mesenteron, nascent PM was visible within the brush border as a fibrous linear structure that contained both the major PM matrix protein, invertebrate intestinal mucin (IIM) and chitin-containing structures. Even though delamination events were confined to the anterior mesenteron, IIM was secreted by columnar epithelial cells throughout the length of the mesenteron. SEM of the midgut epithelium revealed PM covering individual epithelial cells.     

Molecular interactions between Anopheles stephensi midgut cells and Plasmodium berghei: the time bomb theory of ookinete invasion of mosquitoes

We present a detailed analysis of the interactions between Anopheles stephensi midgut epithelial cells and Plasmodium berghei ookinetes during invasion of the mosquito by the parasite. In this mosquito, P. berghei ookinetes invade polarized columnar epithelial cells with microvilli, which do not express high levels of vesicular ATPase. The invaded cells are damaged, protrude towards the midgut lumen and suffer other characteristic changes, including induction of nitric oxide synthase (NOS) expression, a substantial loss of microvilli and genomic DNA fragmentation. Our results indicate that the parasite inflicts extensive damage leading to subsequent death of the invaded cell. Ookinetes were found to be remarkably plastic, to secrete a subtilisin-like serine protease and the GPI-anchored surface protein Pbs21 into the cytoplasm of invaded cells, and to be capable of extensive lateral movement between cells. The epithelial damage inflicted is repaired efficiently by an actin purse-string-mediated restitution mechanism, which allows the epithelium to 'bud off' the damaged cells without losing its integrity. A new model, the time bomb theory of ookinete invasion, is proposed and its implications are discussed.     

Growth and differentiation of the larval midgut epithelium during molting in the moth, Manduca sexta

The number of epithelial cells comprising larval midgut of the tobacco hornworm moth, Manduca sexta increases 200-fold in development from the first to the fifth instar. We have examined larvae periodically before and during molting to follow epithelial cell proliferation and differentiation. The midgut epithelium in Manduca sexta consists predominantly of columnar and goblet cells. These are arranged in a characteristic pattern with each goblet cell surrounded by a single layer of 4-6 columnar cells (Hakim et al., (1988)). While undifferentiated basal stem cells are infrequently seen in intermolt larvae, just prior to the period when external signs of molting are visible, their number increases and mitotic figures become common. Proliferation continues for several hours and then these stem cells differentiate following a pattern similar to that seen during embryogenesis (Hakim et al., (1988)). Here, however, the newly differentiating cells become intercalated among the mature differentiated cells already present in the epithelium. Since the pattern of individual goblet cells surrounded by a reticulum of columnar cells is maintained after the addition of new cells, the midgut epithelium of molting larvae appears to be a useful model for studying pattern formation in development.