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.     

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.     

Calcium pathway through a mineralizing epithelium in the crustacean Orchestia in pre-molt: Ultrastructural cytochemistry and X-ray microanalysis

During the pre-exuvial period of the terrestrial crustacean Orchestia, the calcium of the old cuticle is almost entirely reabsorbed and stored as calcareous concretions in the lumen of the midgut posterior caeca. The elaboration of these concretions is due to transport by the caecal epithelium. With ultrastructural cytochemistry controlled by X-ray microanalysis, it can be demonstrated that the main sites of ionized or ionizable calcium are the apical microvilli and an extracellular (lateral and basal) network of channels. Direct precipitating cytochemical methods, using potassium pyroantimonate or pyrophosphate, potassium oxalate or oxalic acid, sodium fluoride, sodium tungstate, and indirect substitution methods, using lead acetate or nitrate and cobalt nitrate were comparatively used. The results are interpreted in favour of the hypothesis of an extracellular transport pathway for calcium through the lateral smooth septate junctions, in conjunction with a more classical apical transport through the microvilli.     

Alterations in the fine structure of cytoplasmic organelles in the hepatopancreatic cells of shell-regenerating snail,Helix pomatia L.

Summary The investigation of hepatopancreatic cells following damage to the shell revealed hypertrophic alterations of several Cytoplasmic organelles. The network of endoplasmic reticulum was extensively developed within both digestive and calcium cells. The arrangement of tubules exhibited a peculiar hexagonal pattern. It is suggested that the reticulum is of agranular type and may be engaged in the transport of lipids and calcium ions. Remarkable alterations were observed in mitochondria, apparently as the result of their hyperfunction. Mitochondria with reduced cristae, with two-layered transverse septum, and with bleb-like protrusions, occurred frequently. In the calcium cells, helically entwined fibres appeared among the fragments of disintegrated calcium spherites. The results of the investigation and the possible presence of collagen in the fibres originating from disintegrated spherites are discussed.This investigation was supported by grants from the Swedish Natural Science Research Council, which are gratefully acknowledged. The author wishes to thank Mrs. I. Rehnberg for technical assistance.     

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

Summary 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.     

Electron microscope studies of the intracellular origin and formation of calcifying granules and calcium spherites in the hepatopancreas of the snail,Helix pomatia L.

Summary It has been previously demonstrated that the hepatopancreas of the snail, Helix pomatia, produce proteinaceous particles (termed b-granules), which are involved in the process of calcification. In calcium cells of this organ calcium spherites arise from these granules. The present study retraces the intracellular development of b-granules from Golgi vesicles and from Golgi saccules encircling the cytoplasmic areas up to the formation of calcium spherites. It is suggested that the mature b-granules are well-defined cytoplasmic units with calcifying capacity. The fine structure of b-granules and calcium spherites is described. The possible function of various cell organelles in the formation of the b-granules and spherites is discussed.This investigation was supported by grants from the Swedish Natural Science Research Council. The assistance of Mrs. I. Rehnberg is gratefully acknowledged.     

The role of cell death in the midgut epithelium in Filientomon takanawanum (Protura)

Midgut epithelium in Filientomon takanawanum is composed of epithelial cells and single, sporadic regenerative cells. In 80% of analyzed specimens midgut epithelial cells, as fat body and gonads, are infected with rickettsia-like microorganism. In non-infected specimens young and completely differentiated epithelial cells are distinguished among epithelial cells. Characteristic for midgut epithelial cells regionalization in organelles distribution is not observed. Autophagy is the sporadic process, but if the cytoplasm of epithelium cells possesses numerous spherites and sporadic autophagosomes, the apoptosis begins. Necrosis is observed sporadically.In the midgut epithelium cells of about 80% of analyzed specimens rickettsia-like microorganisms are observed. The more rickettsia-like microorganisms occur in the cytoplasm, the more autophagosomes are formed, and the process of apoptosis proceeds intensively.     

Structure of the Malpighian tubule cells and annual changes in the structure and chemical composition of their spherites in the cave cricket Troglophilus neglectus Krauss, 1878 (Rhaphidophoridae,Saltatoria)

Periodical changes in the structure of spherites in the Malpighian tubule cells of the cave cricket Troglophilus neglectus were studied to elucidate their role during the cricket's life cycle in natural circumstances. Special interest was given to the dormant overwintering period when we hypothesized that the primary role of spherites is to supply minerals for basic vital processes. The investigation was carried out by light and transmission electron microscopy, energy dispersive X-ray spectroscopy, electron energy-loss spectroscopy and energy-filtering TEM. Spherites are present only in the middle Malpighian tubule segment, consisting of Type 1 cells, characterized, among other features, by a round, apically placed nucleus and numerous spherites, and a few Type 2 cells with an elongated nucleus in the centre and sparse spherites. At the beginning of dormancy in November juveniles, minerals are accumulated in spherites and then decline until March. In one-year-old May larvae, spherites are commonly rich in minerals, and from July onwards they are progressively exploited in the adults. Spherite destruction starts with apoptosis in senile October individuals. The findings suggest that the mineral supply of spherites in Malpighian tubules is crucial to supporting vital processes throughout the life cycle of T. neglectus.     

Mineral congregations, “spherites” in the midgut gland ofCoelotes terrestris (Araneae): Structure,composition and function

Summary Spherites in the digestive and secretory cells of the midgut gland of the agelenid spiderCoelotes terrestris were studied by electron microscopy and histochemical methods. Spherites measured 1–6 m in diameter and were characterized by alternating layers of electron dense and electron lucent material. The main-components of spherites were calcium phosphates and calcium carbonates. Guanine and barium, as well as aminopeptidase and alkaline phosphatase were also present. The matrix consisted of proteins and carbohydrates. Numerous spherites were found together with excretory products within the excretory vacuoles of the digestive cells.Spiders fed with food containing lead, showed deposition of the metall in the spherites. It is then proposed that spherites, aside from their role in storing calcium and other ions, may function in detoxification of heavy metals.     

Hyaluronic acid production and hyaluronidase activity in the newt iris during lens regeneration

The process of lens regeneration in newts involves the dedifferentiation of pigmented iris epithelial cells and their subsequent conversion into lens fibers. In vivo this cell-type conversion is restricted to the dorsal region of the iris. We have examined the patterns of hyaluronate accumulation and endogenous hyaluronidase activity in the newt iris during the course of lens regeneration in vivo. Accumulation of newly synthesized hyaluronate was estimated from the uptake of [3H]glucosamine into cetylpyridinium chloride-precipitable material that was sensitive to Streptomyces hyaluronidase. Endogenous hyaluronidase activity was determined from the quantity of reducing N-acetylhexosamine released upon incubation of iris tissue extract with exogenous hyaluronate substrate. We found that incorporation of label into hyaluronate was consistently higher in the regeneration-activated irises of lentectomized eyes than in control irises from sham-operated eyes. Hyaluronate labeling was higher in the dorsal (lens-forming) region of the iris than in ventral (non-lens-forming) iris tissue during the regeneration process. Label accumulation into hyaluronate was maximum between 10 and 15 days after lentectomy, the period of most pronounced dedifferentiation in the dorsal iris epithelium. Both normal and regenerating irises demonstrated a high level of endogenous hyaluronidase activity with a pH optimum of 3.5-4.0. Hyaluronidase activity was 1.7 to 2 times higher in dorsal iris tissue than in ventral irises both prior to lentectomy and throughout the regeneration process. We suggest that enhanced hyaluronate accumulation may facilitate the dedifferentiation of iris epithelial cells in the dorsal iris and prevent precocious withdrawal from the cell cycle. The high level of hyaluronidase activity in the dorsal iris may promote the turnover and remodeling of extracellular matrix components required for cell-type conversion.     

Ultrastructure of the Rectum Epithelial Cells in the Mosquito Larvae, Anopheles sinensis Wiedemann

ABSTRACT The Ultrastructure of rectum epithelial cells in the mosquito larvae, Anopheles sinensis Wiedemann, was studied using electron microscope. The rectal epithelium forms rectal papillae composed of the absorptive cells and the surrounding basal cells. Moreover, rectal epithelium was covered with thin cuticular intima. Apical plasma membrane of the epithelial cells had infoldings and in between them, mitochondria developed into elongated shape were attached. In addition, the membrane infoldings reach down into the cell cytoplasm to form several layers of leaflet-like prolongations. On both sides of these prolongations were also large, well-developed mitochondria. Their formation was that mitochondria were attached to 3 μm length and 4–13 layers of membrane wrinkle lump. Many spherites, which are lamelated crystals that form an illusory structure in concentric circles inside of the cytoplasm of epithelial cell were observed. Basal plasma membrane in the epithelial cells was also wrinkled to promulgate into the cytoplasm to become basal infoldings producing canaliculi in basal labyrinth formation. There were many mitochondria scattered in these formations as well. On the bottom of the epithelial cell, basal lamina was attached and between basal lamina and muscle bundle was subepithelial space, which is connective tissue. Inside the space, tracheal and nerve cells were observed.     

An electron microscopic histochemical and X-ray microprobe study of spherites in a mussel

Transmission electron microscopic, histochemical and X-ray analytical microprobe techniques were used to study the inorganic-organic relationship in the spherites (calcospherules) from the mantle, i.e. subadjacent to the outer mantle epithelium, of the fresh-water mussel Amblema. These structures were shown to contain calcium which could be chelated by the flotation of sections on solutions of either formic acid or ethylene glycol bis-(beta-amino ethyl ether)-N, N1-tetra-acetic acid (EGTA), Analysis of both non-chelated and sections revealed a significant sulfur peak. Chelated spherites were also intensely stained with acid phosphotungstic acid (PTA), Such data is indicative of the presence of an organic glycoprotein (proteoglycan) matrix which could serve to bind mineral ions, thus forming organic-inorganic aggregates for calcium transport and homeostasis. In this regard, the spherites are analogous to both calcium phosphate containing mitochondrial granules and the initial calcification sites in vertebrate mineralizing tissues.     

The kidney of a teleost, Spinachia spinachia II. Histochemical identification of sialic acid-containing glycoprotein and fine structure of mucus secreting cells

Kidney cells of the marine stickleback Spinachia have been studied with histochemical methods for the demonstration of glycoconjugates. The fine structure of epithelial cells is described. Mucus threads in the nephronic tubule of sexually mature males consist of neutral glycoprotein which corresponds with the secretory granules in proximal tubule segment II cells. Large lysosome-like inclusions, which also react with PAS, are present in many P II cells. All cells of the collecting duct epithelium differentiate into mucous cells in male Spinachia. The nature of their secretory products, which are well preserved by freeze-drying, is discussed. Sialylated glycoprotein is present in mucus granules and sulphated glycoprotein can be demonstrated at the apex of collecting duct cells. Collecting duct cell mucus can be digested with testicular hyaluronidase indicating that proteoglycans may be involved in the structure of macromolecules. The observations are compared with studies of mucus production in the urinary apparatus of several other vertebrates.     

Intestinal subepithelial myofibroblasts support in vitro and in vivo growth of human small intestinal epithelium

The intestinal crypt-niche interaction is thought to be essential to the function, maintenance, and proliferation of progenitor stem cells found at the bases of intestinal crypts. These stem cells are constantly renewing the intestinal epithelium by sending differentiated cells from the base of the crypts of Lieberkühn to the villus tips where they slough off into the intestinal lumen. The intestinal niche consists of various cell types, extracellular matrix, and growth factors and surrounds the intestinal progenitor cells. There have recently been advances in the understanding of the interactions that regulate the behavior of the intestinal epithelium and there is great interest in methods for isolating and expanding viable intestinal epithelium. However, there is no method to maintain primary human small intestinal epithelium in culture over a prolonged period of time. Similarly no method has been published that describes isolation and support of human intestinal epithelium in an in vivo model. We describe a technique to isolate and maintain human small intestinal epithelium in vitro from surgical specimens. We also describe a novel method to maintain human intestinal epithelium subcutaneously in a mouse model for a prolonged period of time. Our methods require various growth factors and the intimate interaction between intestinal sub-epithelial myofibroblasts (ISEMFs) and the intestinal epithelial cells to support the epithelial in vitro and in vivo growth. Absence of these myofibroblasts precluded successful maintenance of epithelial cell formation and proliferation beyond just a few days, even in the presence of supportive growth factors. We believe that the methods described here can be used to explore the molecular basis of human intestinal stem cell support, maintenance, and growth.     

Calcium localization in the shell-forming tissue of the freshwater snail,Biomphalaria glabrata: a comparative study of various methods for localizing calcium

Summary The routes calcium might take across the mantle to the shell have been investigated with various electron-microscopical techniques in the freshwater snailBiomphalaria glabrata (Planorbidae, Basommatophora).In chemically-fixed tissue, calcium was precipitated with a tannic acid-antimonate technique in predominantly the intercellular spaces of the outer mantle epithelium and the interstitium below it. Some vacuoles of the outer mantle epithelium and one type of mucus cell in the inner mantle epithelium also contained precipitate. The presence of calcium in the precipitates was proved by electron energy loss spectroscopy combined with electron spectroscopic imaging. Incubation with lead acetate and uranyl acetate revealed binding-sites for calcium in the intercellular spaces of the epithelia interstitium and the mucus cells of the inner mantle epithelium. Precipitates were also seen after all incubations in the calcium spherites of the connective tissue.The concentrations of calcium and other elements were analysed in freeze-dried ultrathin sections of cryofixed mantle tissue by means of energy-dispersive X-ray microanalysis. Only in mitochondria of the musculature could high amounts of calcium and phosphorous be detected.     

哺乳动物肠上皮屏障中非编码RNAs的调控作用

哺乳动物肠上皮是一种拥有快速自我更新能力的组织,在维持机体免疫稳态与肠道应激后的损伤修复中发挥重要作用。源于隐窝底部的多能肠干细胞不断进行增殖、迁移与分化,并沿隐窝 绒毛轴向上移动,从而维持肠上皮完整性。该过程受严格而复杂的基因调控网络参与。越来越多的数据表明,肠上皮完整性受到广泛的非编码RNA的调控,主要包括肠黏膜再生、保护与上皮屏障功能等方面。本文重点讨论了两类非编码RNA(包括microRNAs和lncRNAs)转录后调控肠上皮屏障功能的研究进展。其中,miR-503、miR-146和lnc-uc.173、lnc-SPRY4-IT1、lnc-plncRNA1、lnc-Gata6等,能够促进肠黏膜的更新,增强上皮屏障功能;相反,miR-222、miR-29b、miR-195和lnc-H19与lnc-BC012900等,抑制肠上皮再生并破坏肠上皮屏障功能。miRNAs、mRNAs与lncRNAs间构成复杂的分子网络,共同调控肠上皮稳态。深入研究与肠上皮相关的miRNAs和IncRNAs分子及其作用机制,探寻引起肠黏膜炎症的关键分子靶标,为肠道炎症临床诊治提供新方向与新方法。     

哺乳动物肠上皮屏障中非编码RNAs的调控作用

哺乳动物肠上皮是一种拥有快速自我更新能力的组织,在维持机体免疫稳态与肠道应激后的损伤修复中发挥重要作用。源于隐窝底部的多能肠干细胞不断进行增殖、迁移与分化,并沿隐窝 绒毛轴向上移动,从而维持肠上皮完整性。该过程受严格而复杂的基因调控网络参与。越来越多的数据表明,肠上皮完整性受到广泛的非编码RNA的调控,主要包括肠黏膜再生、保护与上皮屏障功能等方面。本文重点讨论了两类非编码RNA(包括microRNAs和lncRNAs)转录后调控肠上皮屏障功能的研究进展。其中,miR-503、miR-146和lnc-uc.173、lnc-SPRY4-IT1、lnc-plncRNA1、lnc-Gata6等,能够促进肠黏膜的更新,增强上皮屏障功能;相反,miR-222、miR-29b、miR-195和lnc-H19与lnc-BC012900等,抑制肠上皮再生并破坏肠上皮屏障功能。miRNAs、mRNAs与lncRNAs间构成复杂的分子网络,共同调控肠上皮稳态。深入研究与肠上皮相关的miRNAs和IncRNAs分子及其作用机制,探寻引起肠黏膜炎症的关键分子靶标,为肠道炎症临床诊治提供新方向与新方法。     

Spicule Formation in the Invertebrates with Special Reference to the Gorgonian Leptogorgia virgulata

Many of the invertebrates possess calcium carbonate spicules.This paper is a review of the formation of these structuresin the Porifera, Coelenterata, Platyhelminthes, Mollusca, Echinodermataand Ascidiacea. Mature spicules appear to be extracellular structures.Sponge spicules initiate intercellularly then become extracellular.Alcyonarian, turbellarian, echinoid and ascidian spicule depositionbegins intracellularly and then becomes extracellular. The continuationof growth in the extracellular environment has not been documentedexcept for the echinoids. Placophoran spicules initiate andremain as extracellular structures. Early spicule growth seemsto occur from or within a single cell. However, cell aggregationand/or neighboring cells appear to be important to the processof spicule formation. The spicule forming cells, in general,are found in a collagenous medium which may be associated withspicule growth. The organic matrix from the spicules of the gorgonian Leptogorgiavirgulata is a glycoprotein. Autoradiography reveals that thismatrix is apparently synthesized in the rough endoplasmic reticulumand Golgi complexes and then transported to the spicule formingvacuole via Golgi vesicles. To gain information about the entryand transport of calcium ions, the effects of ouabain and vanadateon calcium uptake were examined. Ouabain had no effect on calciumuptake. Vanadate treatment increased the uptake of calcium inscleroblasts and epithelial tissue and decreased its uptakein spicules. This may suggest that vanadate sensitive ATPasesare involved in the pumping of calcium out of scleroblasts,out of epithelial cells into the mesoglea, and into scleroblastorganelles. Autoradiography using ⁴⁵Ca indicates that the majorityof these ions initially accumulate in the branch axis. The labelmoves through the axial epithelium to the mesoglea and reachesthe spiculeforming vacuoles in the scleroblasts via dense bodies