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.     

Demonstration of a pump-mediated efflux in the epithelial potassium active transport system of insect midgut.

The larval midgut epithelium of lepidopteran insects (e.g., Hyalophora cecropia and Manduca sexta) actively transports potassium from hemolymph to lumen when mounted in a chamber. The potassium active transport is rheogenic and does not require the presence of other alkali ions. The transepithelial potential difference, short-circuit current, and electromotive force of active transport are rapidly diminished by anoxia. The efflux of potassium, opposite in direction to potassium active transport, dramatically increased in anoxia, whereas the effluxes of sodium, cesium, and chloride did not increase in anoxia. The increase in efflux was found to have an alkali selectivity similar to that of potassium active transport. It is concluded that the rise of efflux in anoxia is due to the change characteristics of the epithelial potassium active transport mechanism in anoxia.     

Cell identification corresponding to microelectrode impalements in insect midgut

The-low potential-difference (LPD) cells and the high-potential-difference (HPD) cells ofManduca sexta midgut epithelium have not previously been directly linked with the two major histological cell types, goblet and columnar cells. Using ionophoretic injection of fluorescent dye into LPD and HPD impalement types, we have located the dye-filled cells with the fluorescence microscope, and directly linked the goblet cell with the LPD impalement type and the columnar cell with the HPD impalement type. Thus, for the first time in this polymorphic tissue, the impalement type responsible for active ion transport, the LPD type, has been identified as the goblet cell.Supported in part by USPHS grantr AMR-21890     

Resolution of the potassium pool size controversy in insect midgut

The isolated midgut of Lepidopteran larvae actively transports potassium from the hemolymph side to the lumen side when chamber-mountedin vitro. Active potassium transport is not affected by ouabain and is not dependent on sodium. A long controversy has existed over the fraction of the midgut cells that participate in active transport of potassium. One set of investigators demonstrated that only a small fraction of the tissue potassium was involved in the pool of potassium involved in active transport whereas a separate set of workers found that virtually all of the exchangeable potassium was thus involved. The results presented in this paper show that the insect's diet affects whether some or all the cells are in the pool, known formally as a transport pool. Leaf-reared insects are characterized by a small pool whereas diet-reared insects are characterized by a large pool. These results are shown to correlate with the pool size results of previous investigators.     

The morphology and fine structure of the larval midgut of a moth (Manduca sexta) in relation to active ion transport.

Light and electron microscopic examination of the midgut of Manduca sexta has shown that the organization of this tissue is more complex than was originally believed. The midgut can be divided into anterior, middle and posterior regions on the basis of the pattern of folding of the epithelial sheet, and variations in the structure of goblet and columnar cells which occur along its length. The columnar cells show gradual structural changes form the anterior to the posterior end of the midgut. For example, the microvilli in the anterior region form a dense, interconnecting network from which vesicles break off. This organization becomes less obvious through the middle region, until by the posterior region each microvillus is unconnected to adjacent microvilli along its entire length and vesicles are no longer produced. Two distinct types of goblet cells are found. In the anterior and middle regions the goblet cells have a large basally located cavity, but in the posterior region the cavity occupies only the apical half of the cell. In both cases the cavity is formed by invagination of the apical membrane, which is studded with small particles implicated in active ion transport. In the anterior and middle regions this membrane is closely associated with mitochondria, but not in the posterior region. The significance of the observed structural differences is discussed in relation to active ion transport.     

A vacuolar-type proton pump in a vesicle fraction enriched with potassium transporting plasma membranes from tobacco hornworm midgut

Mg-ATP dependent electrogenic proton transport, monitored with fluorescent acridine orange, 9-aminoacridine, and oxonol V, was investigated in a fraction enriched with potassium transporting goblet cell apical membranes of Manduca sexta larval midgut. Proton transport and the ATPase activity from the goblet cell apical membrane exhibited similar substrate specificity and inhibitor sensitivity. ATP and GTP were far better substrates than UTP, CTP, ADP, and AMP. Azide and vanadate did not inhibit proton transport, whereas 100 microM N,N'-dicyclohexylcarbodiimide and 30 microM N-ethylmaleimide were inhibitors. The pH gradient generated by ATP and limiting its hydrolysis was 2-3 pH units. Unlike the ATPase activity, proton transport was not stimulated by KCl. In the presence of 20 mM KCl, a proton gradient could not be developed or was dissipated. Monovalent cations counteracted the proton gradient in an order of efficacy like that for stimulation of the membrane-bound ATPase activity: K+ = Rb+ much greater than Li+ greater than Na+ greater than choline (chloride salts). Like proton transport, the generation of an ATP dependent and azide- and vanadate-insensitive membrane potential (vesicle interior positive) was prevented largely by 100 microM N,N'-dicyclohexylcarbodiimide and 30 microM N-ethylmaleimide. Unlike proton transport, the membrane potential was not affected by 20 mM KCl. In the presence of 150 mM choline chloride, the generation of a membrane potential was suppressed, whereas the pH gradient increased 40%, indicating an anion conductance in the vesicle membrane. Altogether, the results led to the following new hypothesis of electrogenic potassium transport in the lepidopteran midgut. A vacuolar-type electrogenic ATPase pumps protons across the apical membrane of the goblet cell, thus energizing electroneutral proton/potassium antiport. The result is a net active and electrogenic potassium flux.     

Altering the fate of stem cells from midgut of Heliothis virescens:the effect of calcium ions

Cultured stem cells from larval midgut tissue of the lepidopteran Heliothis virescens respond to alterations in external calcium ion concentration (Ca(2+) (out)) by changing the rate of stem cell proliferation and by differentiating to larval or non-larval phenotypes. Decreasing the external concentration of Ca(2+) with the Ca(2+) chelating agent EGTA increased proliferation of stem cells in culture, and doubled the proportion of cells differentiating to columnar and goblet cells typical of larval midgut compared to controls. In contrast, increasing inward transport of Ca(2+) into the cells by increasing the concentration of external calcium ion concentration, or by incubation with the Ca(2+) ionophore A23187 (which tends to open inward plasma membrane Ca(2+) channels), induced dose-dependent differentiation to non-midgut cell types such as squamous and scale-like cells. However, the latter treatments did not significantly alter stem cell proliferation or differentiation to normal larval midgut epithelium.     

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.     

X-ray microanalysis of elements in frozen-hydrated sections of an electrogenic K+ transport system: The posterior midgut of tobacco hornworm (Manduca sexta) in vivo andin vitro

Summary The lepidopteran midgut is a model for the oxygendependent, electrogenic K⁺ transport found in both alimentary and sensory tissues of many economically important insects. Structural and biochemical evidence places the K⁺ pump on the portasome-studded apical plasma membrane which borders the extracellular goblet cavity. However, electrochemical evidence implies that the goblet cell K⁺ concentration is less than 50mm. We used electron probe X-ray microanalysis of frozenhydrated cryosections to measure the concentration of Na, Mg, P, S, Cl, K, Ca and H₂O in several subcellular sites in the larval midgut ofManduca sexta under several experimental regimes. Na is undetectable at any site. K is at least 100mm in the cytoplasm of all cells. Typicalin vivo values (mm) for K were: blood, 25; goblet and columnar cytoplasm, 120; goblet cavity, 190; and gut lumen, 180. The high K concentration in the apically located goblet cavity declined by 100mm under anoxia. Both cavity and gut fluid are Cl deficient, but fixed negative charges may be present in the cavity. We conclude that the K⁺ pump is sited on the goblet cell apical membrane and that K⁺ follows a nonmixing pathway via only part of the goblet cell cytoplasm. The cavity appears to be electrically isolated in alimentary tissues, as it is in sensory sensilla, thereby allowing a PD exceeding 180 mV (lumen positive) to develop across the apical plasma membrane. This PD appears to couple K⁺ pump energy to nutrient absorption and pH regulation.     

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.     

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).     

Origin of the short circuit decay profile and maintenance of the cation transport capacity of the larval lepidopteran midgut in vitro and in vivo

The larval midguts of Hyalophora cecropia and Manduca sexta contain two primary cell types: a columnar cell and a goblet cell. Employing scanning electron microscopy, goblet cells were found to contain within their cavities semi-viscous matrix plugs. Massive release or removal of goblet matrix plugs is noted following a variety of physiological insults to the tissues, including stretching, gaseous carbon dioxide anesthesia, gut evacuation, gut excision in the absence of cold anesthesia, and mounting the tissue in a chamber designed for the study of cation transport. A reduction in the capacity to actively transport cations in vitro or in vivo follows each of these treatments.When a current (short-circuit current = I_SC) is imposed across the isolated larval midgut that is equal but opposite in direction to the natural electromotive force generated by the tissue, a characteristic irreversible I_SC (and potential = P.D.) decay profile is obtained. This decay profile normally consists of three phases : a transient increase in I_SC, a rapid decay in I_SC and a slower but continuous decay in I_SC. The transient increase in I_SC is an artifact associated with anoxia. The duration of this transient increase in I_SC is related to elapsed time between mounting the midgut in a chamber designed for measuring I_SC and the time at which the hemolymph side of the tissue is bathed in oxygenated saline. The rapid decay is associated with massive release of matrix plugs, an increase in membrane K⁺ conductance and a reduced capacity to transport K⁺. The slower decay is associated with further loss of plugs coupled with cell death. Cell death is caused by inadequacies in the saline normally employed to bathe the midgut epithelium in vitro. These inadequacies promote tissue histolysis and disruption of the normal epithelial topology.     

Primary and continuous midgut cell cultures from Pseudaletia unipuncta (Lepidoptera: Noctuidae)

Midgut epithelial cells were isolated from fifth-instar Pseudaletia unipuncta larvae by collagenase treatment of midgut tissue, and cultured in TNM-FH medium. Long-term continuous culture and maintenance of midgut cells were achieved with P. unipuncta armyworm intestinal cells. Several cells lines were obtained from these P. unipuncta primary cultures, and they have been subcultured and maintained for over 24 mo. The three major midgut cell types were present in the cultures, including stem (regenerative), columnar, and goblet cells. In vitro morphogenesis and differentiation of columnar and goblet cells from stem cells were observed. There appeared to be a cycle of cell death of goblet and columnar cells followed by their replacement from stem cells every 7-8 wk. After approximately six passages, the cell density in T-flasks appeared to be somewhat constant, reaching 10(3)-10(4) cells per milliliter of medium. The columnar cells are round to rectangular in shape and possess a brush border, while the goblet cells have a classic flask-like shape with a central cavity. Peritrophic membrane-like secretions were observed in all the culture flasks. Infection of these cells with multiply embedded nucleopolyhedrovirus was confirmed, and we conclude that these midgut cells can be used as an in vitro model system to study early events in baculovirus infection.     

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.     

Goblet cell membrane differentiations in the midgut of a lepidopteran larva.

So-called goblet cells are present in the midgut of lepidopteran larvae. They are thought to be involved in the active transport of potassium out of the haemolymph and into the gut lumen. A number of plasma membrane differentiations within the goblet cell cavity has been investigated using conventional staining, lanthanum tracer and freeze-etch techniques. Of particular interest are junction-like inter- and intra-membrane differentiations found on the villus-like cytoplasmic projections present at the apical tip of the goblet cell cavities. These cytoplasmic projections appear to act as a valve; in some cases they seem to close off the top of the goblet cell cavity, so isolating it from the gut lumen, while in other cases they are spread apart leaving a wide channel from the cavity into the lumen. The junction-like structures on these cytoplasmic projections are different in structure from the septate-type junctions which seal the midgut cells together at their apical borders, and the 2 types are present on the same plasma membrane, often within one micron of each other. The need for a different type of junction may possibly be related to the fact that it occurs between 2 areas of the same plasma membrane. The morphology of this unusual junction-like structure is discussed and 2 diagrams are presented to illustrate our interpretation of its structure.     

K+ current stimulation by Cl- in the midgut epithelium of tobacco hornworm (Manduca sexta)

Goblet cells in the midgut epithelium of the tobacco hornworm (Manduca sexta larva, 5th instar) actively secrete K+. This can be measured as short-circuit current (Isc) when the tissue is mounted in an Ussing chamber and bathed in K(+)-rich standard saline containing 32 mmol K+.l-1. Isc depends strictly on basolateral (i.e. haemolymph side) K+ and is therefore termed K+ current, IK. Basolateral, but not apical, chloride, bromide and iodide stimulate IK when compared to the baseline current recorded with gluconate-, nitrate- or thiocyanate-containing salines. So-called "Cl(-)-specific" transport inhibitors (frusemide, 9-anthracene carboxylic acid, diphenylamine carboxylic acid and 4,4'-diisothiocyana-to-stilbene-2,2'-disulphonic acid) reduce IK when added to the basolateral bath, whether Cl- or gluconate is the principal ambient anion. Cl- stimulates IK according to saturation kinetics. The Michaelis-Menten-type, K+ concentration-dependent, saturation of IK is altered in a highly specific manner when gluconate is replaced by Cl-: maximal K+ current, as well as the apparent Michaelis constant, are increased by a factor of 4. Since IK develops in these conditions exclusively via basolateral, Ba(2+)-blockable K+ channels, these results can be understood if it is assumed that haemolymph Cl- interferes with the K+ channel by simultaneously lowering the binding affinity for K+ ions and increasing their subsequent transfer rate across the basolateral goblet cell membrane.     

Morphological regional differences of epithelial cells along the midgut in Diatraea saccharalis Fabricius (Lepidoptera: Crambidae) larvae

The sugarcane borer, Diatraea saccharalis Fabricius, is a pest to sugarcane and many other crops. This work aims to characterize morphological variability in the epithelial cells (columnar, goblet and regenerative) along the midgut of D. saccharalis larvae. Fragments of the midgut (anterior, middle and posterior regions) were fixed and processed by light and scanning electron microscopy. There are both cytochemical and ultrastructural differences in the morphology of the epithelial cells, depending on their localization along the midgut. The apical surface of columnar cells shows an increase in both number and size of the apical protrusions from the anterior to the posterior midgut regions. There is an increase in the amount of PAS-positive (Periodic Acid-Schiff Reaction) granules detected in the cytoplasm of both the columnar and regenerative cells, from the anterior to the posterior region. The goblet cell apical surface is narrow in the anterior region, and enlarged in the posterior midgut; the chamber's cytoplasm extrusion are small and thin at the apical cavity surface, being thicker, longer and more numerous at the basal portion of the cavity. Our results suggest that the sugarcane borer midgut has two morphologically different regions, the anterior and the posterior; the middle region is a transitional region.     

一种家蚕类浓核病毒的组织病理学特征

本文从家蚕病蚕中分离到一种家蚕类浓核病毒（BmDNV-Like）,对它的组织病理学研究表明:该病毒首先寄生家蚕中肠柱状细胞,继而引起其细胞核的膨大和破裂;组织原位杂交结果表明该病毒既能在家蚕中肠柱状细胞中增殖,也能在中肠的杯形细胞中增殖,甚至在感染后期能在家蚕幼虫的大部分组织细胞中感染和增殖。     

Cation-stimulated ATPase activity in purified plasma membranes from tobacco hornworm midgut

Purified goblet cell apical membranes from Manduca sexta larval midgut exhibit a specific ATPase activity approx. 20-fold higher than that in the 100 000 X g pellet of a midgut homogenate. The already substantial ATPase activity in this plasma membrane segment is doubled in the presence of 20-50 mM KCl. At ATP concentrations ranging from 0.1 to 3.0 mM, the presence of 20 mM KCl leads to a 10-fold increase in the enzyme's affinity for ATP. ATPase activity is greatest at a pH of approx. 8. In addition to ATP, GTP serves as a substrate, but CTP, ADP, AMP and p-nitrophenyl phosphate do not. Either Mg2+ or Mn2+ is required for activity and cannot be replaced by Ca2+ or Zn2+. The ATPase activity of goblet cell apical membranes is inhibited by neither the typical (Na+ + K+)-ATPase inhibitors, ouabain and orthovanadate, nor by the typical mitochondrial F1F0-ATPase inhibitors, azide and oligomycin. Although 1.5 microM DCCD is ineffective, 150 microM DCCD leads to total inhibition of ATPase activity. The ATPase activity of goblet cell apical membranes is stimulated not only by K+, but also, in order of decreasing effectiveness, by Rb+, Li+, Na+ and even Mg2+. Replacement of Cl- by Br-, F- and HCO3- has less influence than variation of the cations. However, replacement of Cl- by NO3- inhibits strongly this ATPase activity. The ATPase activity described above is characteristic of the alkali metal ion pump containing apical membranes of goblet cells and is not enhanced to a similar degree in other purified midgut epithelial cell plasma membrane segments. Its localization, its broad cation specificity and its insensitivity to ouabain all mimic properties of active ion transport by the lepidopteran midgut and suggest this ATPase as a possible key component of the lepidopteran electrogenic alkali metal ion pump.     

Isolation of separate apical,lateral and basal plasma membrane from cells of an insect epithelium. A procedure based on tissue organization and ultrastructure

The tissue used in this study was the midgut of the tobacco hornworm larva, Manduca sexta. The midgut epithelium is a single layer of cells resting on a thin basal lamina and underlying discontinuous muscle layer. The epithelial cells are of two main types, goblet and columnar cells, joined together by the septate junctions characteristic of insect epithelia. From this tissue we were able to isolate four distinct plasma membrane fractions; the lateral membranes, the columnar cell apical membrane, the goblet cell apical membrane and a preparation of basal membranes from both cell types. The lateral membranes were isolated by density gradient centrifugation following gentle homogenization of the midgut hypotonic medium, which caused the cells to rupture at their apical and basal surfaces, releasing long segments of lateral membranes still joined by their septate junctions. For isolation of apical and basal membranes the tissue was disrupted by ultrasound, based on the light microscopic observation that carefully controlled ultrasound can be used to disrupt each cell in layers starting at the apical surface. The top layer contained the columnar cell apical membrane, which consists of microvilli forming a brush border covering the lumenal surface of the epithelium. The second layer contained the goblet cell apical membrane, which is invaginated to form a cavity occupying the apical half of the cell, and the third layer contained the basal membranes. As each layer was stripped off the epithelium it was collected and the plasma membrane purified by differential or density gradient centrifugation. For all four membrane fractions, the isolation procedure was designed to preserve the original structure of the membrane as far as possible. This allowed electron microscopy to be used to follow each step in the isolation procedure, and to identify the constituents of each subcellular preparation. Although developed specifically for M. sexta midgut, these techniques could readily be modified for use on other epithelia.