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.     

Cell death in the midgut epithelium of the worker honey bee (Apis mellifem carnica) during metamorphosis

Summary The types of cell death in the midgut epithelium of the worker honey bee during the larva-to-pupa transformation were analyzed by light and electron microscopes. The metamorphosis begins with an increase in the number of autophagic vacuoles in larval epithelial cells and terminates with lytic destruction of the whole intestinal epithelium. Apoptosis seems to be independent of cell age, but important in fashioning of the new organ. Even in the cells in the regenerative nests of the larval epithelium, from which the pupal epithelium develops, apoptotic death occurs. Single apoptotic cells are eliminated gradually from the primary multilayer tissue until the monolayer pupal epithelium is formed. Some of the apoptotic cells are endocytosed by sister epithelial cells.     

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.     

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.     

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.     

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.     

Autophagy and acid phosphatase activity in the corpora allata of adult mated females of Diploptera punctata

The corpora allata exbibit cycles of synchronous cell growth and atrophy during ovarian cycles in adult females of the cockroach Diploptera punctata. In the present report, the process of synchronous autophagy of organelles which results in cellular atrophy was investigated. In general, unwanted organelles were sequentially sequestered by several different mechanisms and then targeted for destruction. Autophagy was initiated on day 4 when corpus allatum cells were largest and most actively synthesizing juvenile hormone. The first sign of the initiation of autophagy was aggregation of ribosomes in an isolation membrane. By day 5, many organelles were isolated in the autophagic vacuoles. The ribosomecontaining vacuoles were wrapped by flattened stacks of Golgi cisternae to form conspicuous whorl-like autophagosomes. This is a previously undescribed type of autophagic vacuole with the entire complex of Golgi cisternae forming part of the autophagic membranes. Smooth endoplasmic reticulum was wrapped into membranous autophagic vacuoles with concentric arrays of doubel membranes. Plasma membrane was invaginated and then isolated in a multivesicular body. These three different types of isolated vacuoles did not show acid phosphatase activity as indicated by histochemical staining with -glycerophosphate as substrate. Subsequently, these autophagosomes fused with each other and with 1° or 2° lysosomes to form giant autophagolysosomes. Some mitochondria appeared to have coalesced directly into autophagolysosomes. Golgi complexes were evident during this period; they actively participated in making lysosomal enzymes. Cytoskeletons were frequently observed in the vicinity of autophagic vacuoles and were presumably involved in the transport of the vacuoles. As a result of lysosomal degradation lipofuscins and dense bodies were frequently observed by days 9–12 indicating atrophy of corpus allatum cells. Structural parameters, especially those present early in autophagy, such as the isolation membrane, ribosome-containing vacuoles and whorl-like autophagosomes, can be used to search for potential growth regulators responsible for the induction of autophagy, of the corpora allata, and the subsequent termination in juvenile hormone synthesis.     

Lepidopteran larval midgut during prepupal instar: digestion or self-digestion?

Programmed cell death (PCD) is crucial in body restructuring during metamorphosis of holometabolous insects (those that have a pupal stage between the final larval and adult stages). Besides apoptosis, an increasing body of evidence indicates that in several insect species programmed autophagy also plays a key role in these developmental processes. We have recently characterized the midgut replacement process in Heliothis virescens larva, during the prepupal phase, responsible for the formation of a new pupal midgut. We found that the elimination of the old larval midgut epithelium is obtained by a combination of apoptotic and autophagic events. In particular, autophagic PCD completely digests decaying tissues, and provides nutrients that are rapidly absorbed by the newly formed epithelium, which is apparently functional at this early stage. The presence of both apoptosis and autophagy in the replacement of midgut cells in Lepidoptera offers the opportunity to investigate the functional peculiarities of these PCD modalities and if they share any molecular mechanism, which may account for possible cross-talk between them.     

Aedes aegypti midgut remodeling during metamorphosis

The Aedes aegypti midgut is restructured during metamorphosis; its epithelium is renewed by replacing the digestive and endocrine cells through stem or regenerative cell differentiation. Shortly after pupation (white pupae) begins, the larval digestive cells are histolized and show signs of degeneration, such as autophagic vacuoles and disintegrating microvilli. Simultaneously, differentiating cells derived from larval stem cells form an electron-dense layer that is visible 24 h after pupation begins. Forty-eight hours after pupation onset, the differentiating cells yield an electron-lucent cytoplasm rich in microvilli and organelles. Dividing stem cells were observed in the fourth instar larvae and during the first 24 h of pupation, which suggests that stem cells proliferate at the end of the larval period and during pupation. This study discusses various aspects of the changes during midgut remodeling for pupating A. aegypti.     

Lysozyme in the midgut of Manduca sexta during metamorphosis.

Low levels of lysozyme were found in the midgut epithelium of the tobacco hornworm, Manduca sexta, during the early part of the fifth larval stadium. This was observed in control insects as well as in bacterially challenged insects. No lysozyme was detected in the gut contents of either group of insects which were actively eating or in the early stages of metamorphosis. However, high levels of lysozyme activity were detected in homogenates of midgut tissue collected from insects later in the stadium. Immunocytochemical studies demonstrated that lysozyme accumulates in large apical vacuoles in regenerative cells of the midgut during the larval-pupal molt. These cells, initially scattered basally throughout the larval midgut epithelium, multiply and form a continuous cell layer underneath the larval midgut cells. At the larval/pupal ecdysis the larval midgut epithelium is sloughed off and the regenerative cells, now forming the single cell layer of the midgut, release the contents of their vacuoles into the midgut lumen. This release results in high lysozyme activity in the lumen of the pupal midgut and is thought to confer protection from bacterial infection. This is the first indication that the lysozyme gene may be developmentally regulated in a specific tissue in the absence of a bacterial infection.     

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.     

Significance of electron dense microbodies in trap cells of the nematophagous fungus Arthrobotrys oligospora

We have studied the fate of electron dense microbodies in nematode-trapping organs (traps) of the fungus A. oligospora during the initial hours following nematode capture. The interaction studies were performed with isolated traps which had captured a nematode under conditions where the fungal cells had no access to external energy sources. Video enhanced contrast microscopy showed that under these conditions the number of dense bodies present in the trap cell that formed the penetration tube, rapidly decreased. During subsequent penetration and development of the infection bulb this decrease continued while at this time common cell organelles such as mitochondria and vacuoles were formed. This was confirmed by electron microscopy which also revealed that the dense bodies were degraded by means of an autophagic process. The organelles were degraded individually and finally turned into compartments which, based on ultrastructural criteria, were considered vacuoles. Fusion of such vacuoles into larger organelles frequently occurred. The degradation process was initiated early in the interaction since initial stages were already evident within 15 min after capture. Generally it took 1–2 h before the infection bulb had fully developed and trophic hyphae formation started. During this time the original trap cell, characterized by numerous dense bodies, was transformed into an active vegetative hyphal cell containing typical cell organelles such as nuclei, mitochondria, a strongly proliferated endoplasmic reticulum, vacuoles and normal microbodies but lacked dense bodies. This disappearance of dense bodies was confined to the cell that penetrated the nematode and—less frequently—its two neighbouring cells in the hyphal loop. In the other cells, constituting the trap, the dense bodies remained unaffected. As will be discussed, the present results support our current view that traps of A. oligospora contribute to the survival of the organism in its natural environment.     

香鱼消化道及肝脏的形态结构特征

采用解剖及石蜡切片显微技术观察了香鱼消化道及肝脏的组织学结构。香鱼消化道由口咽腔、食道、胃及肠构成。口咽腔大且狭长,其底壁前部有一对粘膜褶,两颌边缘着生宽扁梳状齿,腭骨及舌骨具齿,犁骨无齿;舌由基舌骨突出部分覆盖粘膜构成,舌粘膜上皮为复层扁平上皮,含有较多的杯状细胞和味蕾。食道、胃及肠均由粘膜层、粘膜下层、肌层及外膜构成。食道粘膜层上皮为复层扁平上皮,杯状细胞发达。胃呈V形,由贲门部、胃体部及幽门部组成,胃壁粘膜上皮为单层柱状上皮,贲门部与胃体部的固有层中有胃腺。肠较短,由前、中、后肠构成,肠壁粘膜上皮为单层柱状上皮,其游离面具微绒毛;上皮细胞间有杯状细胞。幽门盲囊有350～400条,其组织学结构与肠相同。肝脏单叶,外被浆膜;肝细胞形态不规则,肝小叶界限不明显。     

A new enveloped helical virus from the blue crab,Callinectes sapidus

Quite different ultrastructural changes were observed in the columnar cell and the goblet cell of the silkworm midgut after administration of the crystalline toxin of Bacillus thuringiensis. Shortly after the ingestion of the toxin, the deep infoldings of the basal cell membrane of some columnar cells became very irregular in shape and the mitochondria near the basal region were transformed into a condensed form. A few goblet cells showed relatively high electron density in the cytoplasm. The earliest pathological changes were slight and located in a region lying between the first and second thirds of the midgut. With the passage of time, they spread anteriorly and posteriorly to include the entire anterior two thirds of the midgut and became more profound. The cytoplasm of columnar cells became very electron transparent. Most mitochondria were transformed into a condensed form and the endoplasmic reticulum assumed a vacuole-like configuration. The basal infoldings of the cell membrane almost disappeared. On the other hand, the cytoplasm of the goblet cells became very electron dense and granular. The clear basal infoldings of the cell membrane were enlarged making a striking contrast with the dense cytoplasm. However, the mitochondria and the endoplasmic reticulum did not show any pathological deformation.     

Electron microscopy of the tracheal ciliated mucosa in rat

Summary The structure of the tracheal epithelial cells from rat has been studied by electron microscopy on approximately 200 Å thick sections with a resolution of better than 30 Å.The epithelium is found to be of a simple columnar type composed of ciliated cells, mucus producing (goblet) cells, basal cells and a fourth kind of cell, here called brush cell. A great number of non-ciliated cells has also been encountered. It has been proved that these represent goblet cells in different stages of intracellular synthesis of mucous granules. The ciliated cells have approximately 8–9 cilia per square micron and there are about 270 cilia on each cell, the calculated surface area being 33 square microns. They are covered by a 70 Å thick membrane. The ciliary filaments are arranged in a pattern of 2 separate ones in the center and a ring of 9 peripheral ones, each divided into 2 subfilaments by a wall with same thickness as the filamentous wall itself, this being 60 Å. The peripheral filaments are continuous with the basal corpuscles. The structure of the corpuscles as compared with earlier findings is discussed. A number of 0.05 micron thick and 1 micron long filiform projections emerge from the cell surface. No cuticle is present.The cell membrane facing adjacent cells is 90 Å and separated from their cell membrane by a 105 Å wide space, this space, being expanded towards a level corresponding to the proximal parts of the cell. A structure that represents terminal bar has been encountered. The cytoplasm is loose and composed of 160 Å thick granules. Spaces enclosed by 50 Å thick membranes with attached 160 Å thick granules (-cytomembranes) are rare. The Golgi zone is analyzed and its regular composition of -cytomembranes, granules and vacuoles is confirmed. The mitochondria with a mean width of 0.23 micron differ to their inner structure from the common type in that the triple layered membranes are highly interconnected. Large opaque granules are encountered in the cytoplasm. Ring-shaped, 850 Å wide, structures are present in the nuclear membrane. The goblet cells are not as abundant as the ciliated cells, the ratio being 14. Small filiform projections covered by a 95 Å thick membrane protrude from the cell surface. This membrane is continuous with the cell membrane, the latter with the same dimensions as in the ciliated cells. Terminal bars are present. The cytoplasm is very opaque due to a dense packing of the 165 Å opaque granules, many in clusters of 4–6. The -cytomembranes have the same dimensions as mentioned above for those present in the ciliated cells. The Golgi zone is of regular composition. There is a suggestion that the Golgi vacuoles and the -cytomembranes are involved in the formation of mucus. In the stage of cellular activity with but few mucous granules, there is a great number of large opaque granules, the size varying from 0.4–1 micron. The mitochondria with a mean width of 0.23 micron have an outer triple layered membrane with a total thickness of 180 Å. The central less opaque layer is 70 Å and the opaque layer on either side is 55 Å. The inner membranes are arranged parallel to each other and have a triple layered composition where the central less opaque layer is 65 Å and the opaque layers each 60 Å. The brush cells belong to the non-ciliated cells. They are encountered singly, surrounded by goblet cells. The surface structures are shaped like brushes or clumsy protrusions which emerge from the distal end of the cell, and are covered by a 95 Å thick membrane. There have been no suggestions of the brushes being cilia in a stage of growth, nor is it probable that they represent stereocilia. They most nearly resemble the intestinal brush border extensions and thus might serve as a resorbing structure.The cytoplasm of the brush cells appears of medium opacity between the ciliated cells and goblet cells and is composed of 155 Å opaque granules. The -cytomembranes are very rare. The Golgi zone is diminutive though of regular composition. The mitochondria are abundant and small with a mean width of 0.14 micron. The outer and inner membranes are triple layered with approximately the same dimensions as reported for the mitochondria of the ciliated and goblet cells. The inner membranes are very few, often only one or two are present. Some of the large opaque granules have inside a very regular arrangement of small 60 Å thick opaque granules arranged in a crystallinic pattern. In the cytoplasm 0.5–1 micron long bundles of 30–40 Å wide fibrils are encountered. The nucleolus shows a characteristic structure of concentrically arranged thin membranes. The basal cells are believed to represent lymphocytes or white blood cells. They sometimes rest on the basement membrane, sometimes are encountered in the distal part of the intercellular spaces. They are bordered by a 110 Å thick cell membrane and have a rather opaque cytoplasm characterized by 160 Å thick opaque granules. A very small Golgi zone is present. The mitochondria, the mean width being 0.14 micron, have triple layered outer and inner membranes, where the less opaque central layer is 65–70 Å and the opaque layers 45–50 Å each. The basement membrane has a thickness of 600 Å. No inner structure has been resolved. The basement membrane is separated from adjacent parts of the ciliated, goblet, brush, and basal cells by a 250 Å wide less opaque space. Below the basement membrane is the lamina propria of the trachea, which is composed of collagen and elastin fibers together with fibroblasts, white blood cells and lymphocytes. The relationship between different types of tracheal epithelial cells in rat has been analyzed. There has been found no indication of a transformation of any type of cells observed into a different type of cell. The development of basal cells via supporting cells or intermediate cells to goblet cells or ciliated cells has not been noticed. On the contrary, all cells that in light microscopy could have been considered to be supporting or intermediate cells, we have been able to recognize as brush cells or as goblet cells to a varying degree filled with mucous granules. If the cells did not seem to reach the cell surface it has been found to be due to a diagonal direction of the sectioning. In this connection it should be emphasized that this relationship is valid only in rat where it is known that the epithelium is of a simple columnar type as distinct from the conditions in man, that epithelium being of a pseudostratified columnar type.This paper is based on a report given at the meeting of Deutsche Gesellschaft für Elektronenmikroskopie in Münster, March 28–31, 1955 and at the Scandinavian Electron Microscope Society Meeting in Stockholm, May 13, 1955.     

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.     

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.     

Ghrelin effect on nutritional indices, midgut and fat body of Lymantria dispar L. (Lymantriidae)

Ghrelin is a 28-amino acid peptide that has significant effects on appetite and growth in humans and animals. The aim of this study was to examine 4th instar larvae of the pest insect Lymantria dispar L. after ghrelin treatment. Parameters included changes in nutritional indices (efficiency of conversion of ingested food, efficiency of conversion of digested food, approximate digestibility); midgut and fat body mass; total proteases, trypsin and leucine aminopeptidase activities in the midgut; number, height and width of columnar and goblet cells and their nuclei in the midgut epithelium and detection of ghrelin-like immunoreactivity in the midgut tissue. Four subpicomolar injections of ghrelin (0.3pmol) or physiological saline (control) were applied every 24h. The nutritional indices were higher in the ghrelin treated than in the control group. Ghrelin treatment was also associated with elevation of midgut mass, induced digestive enzyme activities, increased fat body mass and morphometric changes in columnar and goblet cells. This is the first report of the presence of ghrelin-like hormone in endocrine cells of an insect midgut. Such information provides additional evidence for application of this relatively simple model system in the future studies of the mechanisms underlying of digestion and energy balance in more complex organisms.     

Metamorphosis of midgut epithelial cells in the silkworm (Bombyx mori L.) with special regard to the calcium salt deposits in the cytoplasm. II. Electron microscopy

The mode of formation and fate of calcium salt deposits (calcospherites) appearing in the pupal midgut cells of the silkworm Bombyx mori was followed in the electron microscope. The larval midgut absorbs calcium ions from the haemolymph primarily via the goblet cells, while in the pupal midgut this occurs throughout the entire tissue. Part of the calcium absorbed by the pupal midgut accumulates in small vesicles, probably derived from the Golgi body and these develop into the concentrically laminated calcospherites. Late in the pupal period, these are discharged into the midgut lumen in a merocrine fashion. The midgut in the adult insect retains only a few poorly defined calcospherites in the cytoplasm.