Fine structure of the larval midgut of the fly Rhynchosciara and its physiological implications

The midgut of Rhynchosciara americana larvae consists of a cylindrical ventriculus from which protrudes two gastric caeca formed by polyhedral cells with microvilli covering their apical faces. The basal plasma membrane of these cells is infolded and displays associated mitochondria which are, nevertheless, more conspicuous in the apical cytoplasm. The anterior ventricular cells possess elaborate mitochondria-associated basal plasma membrane infoldings extending almost to the tips of the cells, and small microvilli disposed in the cell apexes. Distal posterior ventricular cells with long apical microvilli are grouped into major epithelial foldings forming multicellular crypts. In these cells the majority of the mitochondria are dispersed in the apical cytoplasm, minor amounts being associated with moderately-developed basal plasma membrane infoldings. The proximal posterior ventriculus represents a transition region between the anterior ventriculus and the distal posterior ventriculus. The resemblance between the gastric caeca and distal posterior ventricular cells is stressed by the finding that their microvilli preparations display similar alkaline phosphatase-specific activities. The results lend support to the proposal, based mainly on previous data on enzyme excretion rates, that the endo-ectoperitrophic circulation of digestive enzymes is a consequence of fluid fluxes caused by the transport of water into the first two thirds of midgut lumen, and its transference back to the haemolymph in the gastric caeca and in the distal posterior ventriculus.     

Phylogenetic Placement of Pentatomid Stink Bug Gut Symbionts

Insect bacterial symbionts are ubiquitous, however, only a few groups of host families have been well studied in relation to their associations with microbes. The determination of the phylogenetic relationships among bacteria associated with different species within an insect family can provide insights into the biology and evolution of these interactions. We studied the phylogenetic placement of vertically transmitted bacterial symbionts associated with the posterior midgut (crypt-bearing) region of pentatomid stink bugs (Hemiptera, Pentatomidae). Our results demonstrate that different host species carried one major bacterium in their midgut. Phylogenetic analyses of the 16S rRNA gene sequences obtained from the midgut of stink bugs placed all symbionts in a clade with Erwinia and Pantoea species, both plant-associated bacteria. Results indicate that symbiont monophyly occurs among recently diverged taxa (e.g., within a genus) but does not occur in the Pentatomidae. Results suggest that these vertically transmitted symbionts are occasionally replaced by other taxonomically similar bacteria over evolutionary time. Our findings highlight how the evolutionary history of hemipteran symbionts in unexplored host families may have unpredictable levels of complexity.     

Regenerative cells and the architecture of beetle midgut epithelia

The architectural ground plan of beetle and other insect midguts is represented by a monolayer of epithelial cells arranged in a cylindrical configuration. Proliferation and differentiation of regenerative cells maintain the integrity of this monolayer in the face of continual losses of individual cells through cytoplasmic budding and/or expulsion of entire epithelial cells. Peritrophic membranes have conventionally been considered universal features of insect midguts that function to protect vulnerable microvillar surfaces of the midgut epithelium from abrasion by ingested food; however, peritrophic membranes were found in only a small fraction of the adult beetle species examined in this study. In adult beetles, midgut epithelial cells are continually replaced by cells recruited from populations of mitotic regenerative cells that are interspersed among the differentiated epithelial monolayer. To remain contiguous with the other cells in the midgut monolayer, some of these proliferating populations have adopted evaginated configurations of cells that extend for varying distances from the basal surface of the monolayer. These configurations are referred to as regenerative crypts or pouches and consist of progenitor cells and stem cells. The presence, the relative densities, and the relative lengths of these regenerative pouches vary considerably among families of beetles. Placement of longitudinal muscles of the midgut relative to the proximodistal axes of these regenerative pouches also varies among species of beetles. The presence, the size, and the density of regenerative cell populations are related to 1) feeding habits of adult beetles, 2) presence of peritrophic membranes, and 3) expulsion of entire midgut epithelial cells or fragments of these epithelial cells into midgut lumens. © 2012 Wiley Periodicals, Inc.     

The relationship between diet and the size of the midgut caeca in grasshoppers (Insecta: Orthoptera: Acridoidea)

A survey of the size and form of the midgut caeca in relation to diet has been carried out on 173 species from 21 families and subfamilies of Acridoidea (grasshoppers). Although differences exist in the size of the anterior caecal arms relative to body length, these differences are not related to the type of food eaten. Assuming that the anterior arms have a key role in digestive and absorptive processes, this suggests that different foods make similar demands on these processes. The posterior caecal arms are smaller in graminivorous species than in species eating other types of plants as a whole or part of their diet. This is true across all the taxa, including those families and subfamilies that are predominantly forb-feeding. It is suggested that the posterior caecal arms have a special role in the detoxification of plant secondary compounds and that the requirement for this is reduced in graminivorous species because of the lower levels of toxic secondary compounds in grasses. A specialized pocket region is present in the posterior caecal arms of some forb-feeding species. Its occurrence across the taxa is spasmodic. It may be concerned with the removal of phenolic compounds.     

Light and electron microscopy studies of the midgut and salivary glands of second and third instars of the horse stomach bot,Gasterophilus intestinalis

A morphological study of the midgut and salivary glands of second and third instars of Gasterophilus intestinalis (De Geer) (Diptera: Oestridae) was conducted by light, scanning and transmission electron microscopy. The midgut is anteriorly delimited by a proventriculus, without caeca, and is composed of posterior foregut and anterior midgut tissue from which a double‐layered peritrophic matrix is produced. The midgut can be divided into anterior, median and posterior regions on the basis of the structural and physiological variations of the columnar cells which occur along its length. Two other types of cell were identified: regenerative cells scattered throughout the columnar cells, and, more rarely, endocrine cells of two structural types (closed and open). Different secretion mechanisms (merocrine, apocrine and microapocrine) occur along the midgut epithelium. Abundant microorganisms are observed in the endoperitrophic space of the anterior midgut. The origin and nature of these microorganisms remain unknown. No structural differences are observed between the second and third instar midguts. The salivary glands of G. intestinalis second and third instars consist of a pair of elongated tubular structures connected to efferent ducts which unite to form a single deferent duct linked dorsally to the pharynx. Several intermediate cells, without cuticle, make the junction with the salivary gland epithelium layer. Cytological characteristics of the gland epithelial cells demonstrate high cellular activity and some structural variations are noticed between the two larval stages.     

庭疾灶螽中肠及马氏管结构

【目的】本研究旨在以庭疾灶螽Tachycines asynamorus为例探索驼螽消化系统和排泄系统在结构上与其生活环境的适应关系。【方法】运用解剖学方法、石蜡切片技术、冰冻切片技术及超薄切片技术对庭疾灶螽中肠及马氏管的结构进行研究。【结果】庭疾灶螽中肠向前延伸出3个胃盲囊包围着前胃。中肠上皮由再生细胞、柱状上皮细胞和内分泌细胞构成,具有典型的再生细胞龛;闭合型内分泌细胞紧贴在再生细胞龛的外围,基底区聚集大量的分泌颗粒。柱状上皮细胞内聚集有2类大的分泌颗粒：线团状颗粒和电子密度很高的球状颗粒;中肠管腔内有明显的围食膜结构,中肠基底部由基膜和肌肉层组成。马氏管着生在中后肠的交界处,从横切面看马氏管管壁具有3~5个细胞,细胞近管腔端部具有大量长微绒毛,细胞质内分布着电子致密的同心圆球晶体,基底膜内折形成膜迷路。【结论】庭疾灶螽中肠柱状上皮细胞的线团状颗粒由微丝包裹;内分泌细胞由再生细胞龛中的细胞分化而来,产生内分泌颗粒并将其排到血腔;中肠基膜发达,包含微丝与复合糖成分,基膜通过对中肠上皮细胞的支撑作用为肠道蠕动提供保障。庭疾灶螽马氏管细胞中可见大量颗粒和大量同心圆球晶体,推测可能是一种储存排泄。     

The ultrastructural investigation of the midgut in the quill mite Syringophilopsis fringilla (Acari,Trombidiformes: Syringophilidae)

The midgut of the females of Syringophilopsis fringilla (Fritsch) composed of anterior midgut and excretory organ (=posterior midgut) was investigated by means of light and transmission electron microscopy. The anterior midgut includes the ventriculus and two pairs of midgut caeca. These organs are lined by a similar epithelium except for the region adjacent to the coxal glands. Four cell subtypes were distinguished in the epithelium of the anterior midgut. All of them evidently represent physiological states of a single cell type. The digestive cells are most abundant. These cells are rich in rough endoplasmic reticulum and participate both in secretion and intracellular digestion. They form macropinocytotic vesicles in the apical region and a lot of secondary lysosomes in the central cytoplasm. After accumulating various residual bodies and spherites, the digestive cells transform into the excretory cells. The latter can be either extruded into the gut lumen or bud off their apical region and enter a new digestive cycle. The secretory cells were not found in all specimens examined. They are characterized by the presence of dense membrane-bounded granules, 2–4 μm in diameter, as well as by an extensive rough endoplasmic reticulum and Golgi bodies. The ventricular wall adjacent to the coxal glands demonstrates features of transporting epithelia. The cells are characterized by irregularly branched apical processes and a high concentration of mitochondria. The main function of the excretory organ (posterior midgut) is the elimination of nitrogenous waste. Formation of guanine-containing granules in the cytoplasm of the epithelial cells was shown to be associated with Golgi activity. The excretory granules are released into the gut lumen by means of eccrine or apocrine secretion. Evacuation of the fecal masses occurs periodically. Mitotic figures have been observed occasionally in the epithelial cells of the anterior midgut.     

The fine structure of the midgut of mite Myobia murismusculi

The pattern of digestion in females of Myobia murismusculi was studied with light and electron microscopy. The midgut consists of a stomach and two pairs of blind caeca. The stomach is connected dorsoposteriorly with the excretory organ, that leads externally to an anal opening via the cuticle-lined rectum. No differences were found between the stomach and its caeca. The midgut epithelial cells are of a single type. Their fine structure and gut contents greatly vary depending on different physiological conditions of the mite. Four stages of digestion can be shown with electron microscope. Pino- and phagocytose takes place in the same cells. At an active stage of digestion numerous pinocytic canals were observed in the midgut cells. At each stage of the digestive cycle groups of flat cells are present in the midgut epithelium. They do not take part in the intracellular digestion of food material. Cytoplasmic processes from the underlying cells of coxal glands project into the midgut cells through the orifices in the gut basal lamina.     

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.     

臭腹腺蝗（直翅目： 锥头蝗科）中肠内营养物-水分的流动和吸收

对臭腹腺蝗Zonocerus variegatus中肠内水分和营养物的流动和吸收进行了研究,以期确定其流动模式及在该虫对氰化氢适应方面的意义。对中肠细胞进行了组织切片观察;测定了K⁺, Na⁺和蛋白质沿中肠的浓度梯度,并观察了中肠对K⁺, Na⁺, Ca²⁺, Mg²⁺和甲基蓝的通透性。结果表明,中肠（胃和胃盲囊）组织上结构相似,均由具有纹状边缘的柱状细胞构成。营养物质在中肠不同部分的浓度不同。测试物在整个中肠中流动,中肠各段均参与了食物和水分的吸收。臭腹腺蝗肠内没有像大多数直翅目昆虫那样自后肠的液流逆向流动。肠溶物的单向流动可以防止有毒物质的积累,使臭腹腺蝗成功耐受木薯叶中的氰化氢。     

Investigations on the midgut caeca of mosquito larvae-I. Fine structure

Four types of cells can be distinguished in the epithelium of the caeca of three species of mosquito larvae. Specialized cells secreting a 160nm caecal membrane occur either near the opening of the caeca into the midgut (Aedes, Anopheles) or in the posterior half of the caeca (Culex). The presence of chitin could be demonstrated in this membrane with wheat germ agglutinin. In larvae of A. aegypti and C. pipiens the posterior part of the caeca is occupied by ion transporting cells. In larvae of A. stephensi these cells are interspersed among other cells, even in the anterior part of the caeca. The ion transporting cells resemble other insect cells involved in osmoregulation. Their microvillar membranes are studded with 14 nm portasomes and are closely associated with mitochondria. The main type of caecal cell seems to be responsible for resorption and storage of nutrients and for the secretion of enzymes. Small and undifferentiated cells were observed sporadically and seem to be imaginal cells.     

Digestive enzyme compartmentalization and recycling and sites of absorption and secretion along the midgut of Dermestes maculatus (Coleoptera) larvae

Bostrichiformia is the less known major series of Coleoptera regarding digestive physiology. The midgut of Dermestes maculatus has a cylindrical ventriculus with anterior caeca. There is no cell differentiation along the ventriculus, except for the predominance of cells undergoing apocrine secretion in the anterior region. Apocrine secretion affects a larger extension and a greater number of cells in caeca than in ventriculus. Ventricular cells putatively secrete digestive enzymes, whereas caecal cells are supposed to secrete peritrophic gel (PG) glycoproteins. Feeding larvae with dyes showed that caeca are water-absorbing, whereas the posterior ventriculus is water-secreting. Midgut dissection revealed a PG and a peritrophic membrane (PM) covering the contents in anterior and posterior ventriculus, respectively. This was confirmed by in situ chitin detection with FITC-WGA conjugates. Ion-exchange chromatography of midgut homogenates, associated with enzymatic assays with natural and synthetic substrates and specific inhibitors, showed that trypsin and chymotrypsin are the major proteinases, cysteine proteinase is absent, and aspartic proteinase probably is negligible. Amylase and trypsin occur in contents and decrease along the ventriculus; the contrary is true for cell-membrane-bound aminopeptidase. Maltase is cell-membrane-bound and predominates in anterior and middle midgut. Digestive enzyme activities in hindgut are negligible. This, together with dye data, indicates that enzymes are recovered from inside PM by a posterior-anterior flux of fluid outside PM before being excreted. The combined results suggest that protein digestion starts in anterior midgut and ends in the surface of posterior midgut cells. All glycogen digestion takes place in anterior midgut.     

The alimentary canal of <Emphasis Type="Italic">Blomia tropicalis</Emphasis> (Acari: Astigmata: Echymopodidae): the application of three-dimensional reconstruction technology

The domestic mite species Blomia tropicalis is an important indoor allergen source related to asthma and other allergic diseases in tropical and subtropical regions. Here, we describe the alimentary canal of B. tropicalis with the particular application of three-dimensional reconstruction technology. The alimentary canal of B. tropicalis resembles the typical acarid form consisting of the cuticle-lined foregut and hindgut separated by a cuticle-free midgut. The foregut is divided into a muscular pharynx and an esophagus. The midgut is composed of a central ventriculus, two lateral caeca, a globular colon and a postcolon with two tubiform postcolonic diverticula. The most common cells forming the epithelium of ventriculus and caeca are squamous and cuboidal. The globular cells contain a big central vacuole in the posterior region of the caeca. The epithelium of the colon and postcolon has significantly longer microvilli. The anal atrium is a simple tube with flattened epithelial cells. The spatial measurements of the three-dimensional model suggest that the paired caeca and central ventriculus occupy 55.1 and 34.6%, respectively, of the total volume of the alimentary canal and may play the key role in food digestion. J. Wu and F. Yang contributed equally.     

Ultrastructural changes in the midgut epithelium of the first larva of Allacma fusca (Insecta, Collembola, Symphypleona)

Abstract. In the newly hatched larva in Allacma fusca , the midgut epithelium was fully developed and formed by flattened epithelial cells surrounding the yolk mass in the midgut lumen. Immediately after hatching, the first larva began to feed; the migut lumen was filled with the yolk mass and food (mainly algae). Regenerative cells typical of the developing midgut epithelium of many insects were not observed. Initially, midgut cells of the larva were cuboidal but became columnar in shape with distinct regionalization in the distribution of cell organelles. Furthermore, urospherites appeared in the midgut cell cytoplasm, i.e., structures characteristic for the midgut epithelium of insects having no Malpighian tubules. As a result, cells with the capacity for digestion, absorption, and excretion were observed to be completely formed in the first larval stage.     

昆虫中肠Bt晶体蛋白受体的研究进展

苏云金芽孢杆菌Ｂａｃｉｌｌｕｓｔｈｕｒｉｎｇｉｅｎｓｉｓ杀虫作用的主要成份是胞内产生的伴孢晶体,晶体蛋白经昆虫吞食,在肠道降解为激活的毒性肽。普遍认为毒性肽的作用机制主要有两个步骤：１）与中肠表面的受体专一结合;２）在细胞膜上形成跨膜通道。杀虫晶体蛋白的专一性与中肠细胞膜表面的受体蛋白紧密相连,晶体蛋白的杀虫作用是通过昆虫中肠细胞的专一性受体而起作用。本文通过说明受体蛋白的生物学特性、分子本质及与昆虫抗性的关系,概述了近年来中肠受体蛋白的研究进展。１　昆虫中肠受体蛋白的生物学特性１１　受体蛋白…     

臭腹腺蝗（直翅目：锥头蝗科）消化道对食物储存、消化和吸收相适应的显微结构

显微观察发现臭腹腺蝗Zonocerus variegatus（直翅目：锥头蝗科）嗉囊、中肠和后肠的肠壁结构有所不同。嗉囊为空时纵向折叠。中肠上皮层的厚度随龄期有明显变化,1龄和2龄时明显大于3龄、4龄和5龄。后肠具有帮助消化和吸收的功能。     

The functional morphology of the alimentary tract of barnacles (Cirripedia: Thoracica)

The alimentary tract of barnacles is made up of cuticle-lined foregut and hindgut with an intervening U-shaped midgut associated anteriorly with a pair of pancreatic glands and perhaps midgut caeca. Epithelial salivary glands secrete acid mucopolysaccharide, glycoprotein or both. Cells of all the midgut regions are capable of absorption which is carried out mainly by the anterior midgut and caeca. Midgut cells of Balanus balanoides (L.) show a seasonal variation in the distribution of intracellular lipid droplets. Midgut cells rest on an elastic basal lamina and secrete a peritrophic membrane which contains mucopolysaccharide and protein. Cells of the stratum perintestinale connect with the midgut epithelial cells via cell processes which probably translocate absorbed materials. Glycoprotein globules and lipid droplets accumulate in the body parenchyma of B. balanoides and are transported to the ovaries to form yolk (glycolipovitellin). The pancreatic gland cells of all barnacles are active secretory cells secreting proteinaceous material (probably digestive enzymes).     

Carbonic anhydrase activity in a calcium-mobilizing epithelium of the crustacean Orchestia cavimana during molting

We investigated the involvement of the enzyme, carbonic anhydrase, in the calcification-decalcification processes occurring in the posterior caeca of the midgut of the terrestrial crustacean, Orchestia cavimana, before and after exuviation. This enzyme was ultrahistochemically localized throughout the membranes of the caecal epithelium as well as extracellularly, i.e., within pre-exuvial calcareous concretions and postexuvial calcified spherules. During the molt cycle, the pattern of carbonic anhydrase activity in the posterior caeca was correlated with the calcium content at this level. Acetazolamide treatment in vivo inhibited about 50% of the calcium uptake during both pre-exuvial secretion and postexuvial reabsorption. The role of carbonic anhydrase in this mineralizing-demineralizing epithelium is discussed and compared with that of other mechanisms involved in this calcium turnover.     

The ability of an epithelium to survive removal of the basal lamina by enzymes: fine structure and content of sodium and potassium of the midgut epithelium of the larva of Tenebrio molitor after withdrawal of the basal lamina by elastase--a short note

A method is described to separate the epithelial cells of the posterior part of the mealworm midgut from their thick basal lamina using elastase. After removal of the basal lamina the naked epithelial cells remain connected with each other, still forming a midgut tube. The ultrastructural changes observed are enlargement of the lateral spaces between the cells and simultaneous destruction of junctional structures other than desmosomes and tight junctions. This enlargement is most probably due to shrinkage of the epithelial cells as a consequence of osmotic stress, which the cells normally seem to be protected against by the basal lamina. The content of sodium and potassium in the epithelium is not influenced by the elastase treatment, indicating that the midgut tube stays alive with intact plasma membranes.     

Pole Cell Migration through the Gut Wall of the Drosophila Embryo: Analysis of Cell Interactions

Early in development the precursors of germ cells in Drosophila migrate at the posterior pole of the embryo and translocate to the bottom of the developing posterior midgut primordium. At the end of germ band elongation the pole cells cross the gut wall to enter in association with the gonadal mesoderm. We used laser scanning confocal microscopy on whole-mount Rh-phalloidin-stained embryos and transmission electron microscopy to investigate how pole cells cross the epithelial wall of the posterior midgut primordium. Our results suggest that pole cells leave the midgut sac by traveling through the intercellular spaces of the epithelium. During this process the epithelial cells at the bottom of the posterior midgut primordium are greatly deformed, but their junctional complexes do not completely release, avoiding breaks in the epithelial wall.