Cellular cadmium distribution in the common winkle, Littorina littorea (L.) determined by X-ray microprobe analysis and histochemistry

Various tissues of common winkles, Littorina littorea (L.), experimentally exposed to cadmium (Cd) chloride were examined using light and electron microscopy and their elemental composition determined by X-ray microanalysis and histochemistry. Membrane granules in gill epithelial cells with paddle cilia contain carbonates, phosphates and sulphides associated with different cations in different types of granules. Traces of Cd have been found only in those granules containing sulphur and iron. Nephrocytes also contain small amounts of this metal in the cytoplasm of excretory cells. X-ray microanalysis reveals that concretions of basophilic cells are minor sites for Cd sequestration while BTAN-ASSG stain for unbound Cd indicates that most of the Cd is located within the lysosomes of digestive cells in association with proteins. Low amounts of the metal have been evidenced in the granules of epithelial mantle cells rich in sulphur. The results also indicate that hemocytes contain granules of calcium phosphate and iron sulphide. Cd is also associated to sulphur rather than to phosphate. These hemocytes may act as Cd carrier from gills to kidney and digestive gland. A hypothetical pathway for Cd accumulation and detoxification is suggested.     

Location of copper in larvae of Plectrocnemia conspersa (Curtis) (Trichoptera) exposed to elevated metal concentrations in a mine drainage stream

Using histological techniques together with transmission electron microscopy and X-ray microanalysis, copper-containing granules (which also contain significant amounts of sulphur) have been observed in the cells of the malpighian tubules and in the subcuticular region of larvae of Plectrocnemia conspersa. It is suggested that the granules in both these regions are primarily pigment granules, which provide a mechanism for taking potentially toxic concentrations of copper (and possibly other metals) out of circulation. This mechanism of metal tolerance may in part account for the reported occurrence of larvae of P. conspersa in waters with elevated concentrations of trace metals.     

The occurrence of cadmium in sub-cellular particles in the kidney of the marine mussel, Mytilus edulis, exposed to cadmium. The use of electron microprobe analysis

In mussels (Mytilus edulis) chronically exposed to cadmium, 85% of the Cd2+ was found to be associated with membrane-limited granular structures when elemental analyses were carried out on cryo-sectioned tissue by electron probe X-ray microanalysis. These granules also contained high concentrations of sulphur and phosphorus as well as other metalions, including Ca2+, iron and Zn2+. In contrast, after homogenisation and fractionation by differential centrifugation, the major proportion of the Cd2+ was found in the cytoplasmic fraction. However, many lysosomes were also ruptured by this treatment. Gel filtration chromatography of this fraction indicated the presence of a Cd2+-binding component of similar molecular weight to the metallothionein purified from the digestive gland of the same animals. It is therefore proposed that metallothionein may be associated with particulate structures which would thus reduce its cellular toxicity.     

Localization and fate of aluminium in the digestive gland of the freshwater snail Lymnaea stagnalis

The digestive gland of the freshwater snail Lymnaea stagnalis, exposed to water containing an elevated concentration of aluminium at neutral pH for up to 30 days, followed by a 20 day recovery period, was examined by light and electron microscopy and X-ray microanalysis. Aluminium was localized in the yellow granules present in the digestive and excretory cells and in the green and small granules present in the digestive cells. More aluminium, silicon, phosphorus and sulphur were present in all three granule types from aluminium exposed snails. The number of yellow and green granules from the digestive gland of aluminium exposed snails showed a progressive increase over the experimental period compared to controls. The number and aluminium content of the granules is likely to reflect the role of the digestive gland as a 'sink' for accumulated aluminium. We propose that intracellular monomeric silica is involved in the detoxification of aqueous aluminium which at neutral pH is largely in the form of an insoluble polyhydroxide. The increased amounts of sulphur and phosphorus in the granules are likely to be part of a broad response to metal loading but probably do not play a significant role in the storage and detoxification of aluminium.     

X-ray micronalysis of copper and sulphur-containing granules in the fat body cells of homopteran insects

Regions of the fat body of larvae of Chaetophyes compacta and Pectinariophyes sp. (Machaerotidae, Homoptera) which are closely associated with mycetomes have been analysed by electron probe X-ray microanalysis. It is shown that cells in these regions contain electron probe X-ray microanalysis. It is shown that cells in these regions contain electron dense granules which are rich in copper and sulphur. These two elements occur in the atomic ratio of 3:2 respectively. It is conjectured that copper may be bound to a sulphur containing metallothionein and that the granules represent either the end products of copper detoxification or serve as copper stores for synthesis of enzymes and macromolecules by the mycetomal symbionts.     

The localization of inorganic elements,particularly vanadium and sulphur,in haemolymph from the ascidians Ascidia mentula (Müller) and Ascidiella aspersa (Müller)

Vanadium and sulphur were found by X-ray microanalysis in three different cell types, morula cells, signet-ring cells, and granular amoebocytes, from each of the ascidians Ascidia mentula (Müller) and Ascidiella aspersa (Müller). In addition to the cells containing vanadium and sulphur a few vacuolar cells containing high concentrations of iron, magnesium and calcium were also found. After fixation in the presence of strontium or barium chlorides another cell type containing large amounts of precipitated sulphur was also found, confirming our previous findings that many haemolymph cells in these species contain large amounts of sulphate only. The presence of these various cell types is discussed in relation to the question of the acidity of ascidian blood cells.     

The distribution of zinc, cadmium, lead and copper within the hepatopancreas of a woodlouse

The distribution of metals within the hepatopancreas of Oniscus asellus (Crustacea, Isopoda) from two uncontaminated sites, and two sites contaminated with zinc, cadmium and lead, has been studied by atomic absorption spectrophotometry, light microscopy, transmission and scanning electron microscopy and X-ray microanalysis. The hepatopancreas contains two types of intracellular granule. The first type, in the S cells, are spherical granules which contain copper, sulphur and calcium. In woodlice from contaminated sites, these ‘copper’ granules, also contain zinc, cadmium and lead. The second type, in the B cells, are flocculent deposits which contain iron. In woodlice from contaminated sites, these ‘iron’ granules also contain zinc and lead. Moribund woodlice from contaminated sites have large numbers of ‘copper’ and ‘iron’ granules in the hepatopancreas and a fine deposit of zinc and lead on the membranes of the cells. There are numerous microorganisms in close association with the microvillous border of the hepatopancreas of woodlice from all four sites. Within the microorganisms of Oniscus asellus from contaminated sites, there are deposits of material which contain zinc, lead, calcium and phosphorus ‘Copper’ and ‘iron’ granules could have evolved as storage sites for essential metals to be utilized when demand from the body exceeds uptake from the food. Woodlice in contaminated sites may be able to ‘detoxify’ potentially harmful amounts of essential and non-essential metals by storing them in a relatively insoluble form within these granules.     

DISTRIBUTION OF METALS IN THE DIGESTIVE GLAND -- GONAD COMPLEX OF THE MARINE GASTROPOD NUCELLA LAPILLUS

The amounts of phosphate, zinc, copper and calcium in gonadmaterial from Nucella lapillus (L.) was higher in males comparedwith females. Water insoluble extracts from the digestive glandwere found to contain granules high in concentrations of phosphate,magnesium, zinc, copper and calcium when compared with watersoluble extracts and both types of extract from gonad tissueof male and female dog whelks. Male N. lapillus contained thehighest amounts of zinc and copper in isolated digestive glandgranules. Intracellular granules containing metal were locatedhistochemically in cells of the digestive gland and visceralhaemocoelic spaces (Received 5 December 1978;     

A microprobe analysis of Gomori-positive glial cells in the rat arcuate nucleus.

Astrocytes and microglial cells in the arcuate nucleus of the rat hypothalamus contain lipofuscin-like granules which react with chrome alum gallocyanin and exhibit endogenous peroxidase activity. These granules were assessed with energy dispersive X-ray microanalysis and compared to neuronal dense bodies and glial cytoplasm. The granules are distinguished by a consistent content of sulphur and a frequent presence of calcium. The localization of other elements such as iron, copper, potassium and chlorine is impaired by methodical difficulties. The sulphur content as well as the endogenous peroxidase activity is interpreted as indicating a special variant of lipofuscin. The presence of calcium is discussed with respect to recent concepts of glia as a regulator of the ionic environment of the CNS.     

A microprobe analysis of Gomori-positive glial cells in the rat arcuate nucleus

Summary Astrocytes and microglial cells in the arcuate nucleus of the rat hypothalamus contain lipofuscin-like granules which react with chrome alum gallocyanin and exhibit endogenous peroxidase activity. These granules were assessed with energy dispersive X-ray microanalysis and compared to neuronal dense bodies and glial cytoplasm. The granules are distinguished by a consistent content of sulphur and a frequent presence of calcium. The localization of other elements such as iron, copper, potassium and chlorine is impaired by methodical difficulties. The sulphur content as well as the endogenous peroxidase activity is interpreted as indicating a special variant of lipofuscin. The presence of calcium is discussed with respect to recent concepts of glia as a regulator of the ionic environment of the CNS.     

Scanning electron microscopy of digest cells in the midgut epithelium ofBoophilus microplus

Scanning electron microscopy showed the presence of microvilli on the digest cells, but more importantly, it showed that the gut could be everted to expose the lumen surface of the cells to molecular analysis. X-ray microanalysis demonstrated the presence of iron and sulphur in the haematin granules within spent digest cells, confirming that these granules are end products of blood digestion in adult ticks.Part of material already accepted for a Ph.D. degree, University of Queensland, Brisbane, Australia.     

The pericardial glands of the zebra mussel: Ultrastructure and implication in lead detoxication process

Summary— Ultrastructural and microanalytical investigations of the pericardial gland of the freshwater mussel, Dreissena polymorpha have been performed to investigate the possible functional role of this organ in the detoxication process of lead. The cell-type of this organ exhibits the feature characteristics of podocytes, ie the typical pedicel-basal lamina complex and the well developed lysosomalvacuolar system. X-ray microanalysis demonstrated that large electron-dense granules referred to as lysosomes are the main target organelles in these cells to accumulate and sequestrate lead where the metal was associated with phosphorus and sulphur. Consequently, the pericardial gland plays an important role in the detoxication process and allows the organism to tolerate high lead concentration without suffering severe cell injury.     

The localization of aluminium in the digestive gland of the terrestrial snail Helix aspersa

The terrestrial snail Helix aspersa was exposed to food containing elevated levels of aluminium for up to 33 days and the digestive gland examined by light and electron microscopy and X-ray microanalysis. Four types of cell are found in the digestive gland, (digestive, excretory, calcium and thin) although aluminium was only found in the excretory cells. The aluminium was localised in the 'yellow' or excretory granules that are a characteristic feature of the excretory cells. Aluminium was only found in the granules of snails fed aluminium but there was no difference in the appearance of granules from control or aluminium-fed snails. The granules were large (up to 20 mum in diameter), irregularly shaped and electron-dense. Sulphur, phosphorus and calcium were detected in granules from all snails. The presence of sulphur may indicate protein residues. The amount of aluminium and phosphorus in the granules increased over the experimental period but the number of granules did not change. Levels of aluminium in the granules decreased when the snails were given control food. The role of the excretory granules in the localisation, detoxification and excretion of aluminium is discussed.     

Localization of Metals in the Gastropod Littorina saxatilis (Prosobranchia: Littorinoidea) from a Polluted Site

Organ heavy metal levels, and ultrastructural localization were examined in the marine prosobranch mollusc Littorina saxatilis from a metal-contaminated site. Copper and zinc are localized in the digestive gland, stomach and kidney. The digestive gland does not appear to be a significant site of iron accumulation. High levels of copper and zinc in the stomach may indicate significant uptake from the food. Relatively high heavy metal levels in several organs were reflected in the presence of a variety of metal-containing aggregates (granules) within the tissues. In common with other invertebrates two broad classes of granule were present. The first appears to be proteinaceous, with a high sulphur content. This type contained copper and iron and was found in the stomach, kidney, pore cells, and rectum. The second type was inorganic and mineralized, containing phosphorus. They contained calcium, zinc and manganese, and were observed in the kidney and digestive gland. Differences in the number of metals were observed between the various granule types, possibly reflecting specific pathways involved in metal sequestration.     

Hemocytes of the palaemonids Macrobrachium rosenbergiiand M. acanthurus,and of the Penaeid Penaeus paulensis

The hemocytes of two palaemonids and one penaeid were characterized using light and transmission electron microscopy (TEM). The blood cells in all three species were classified as hyaline hemocytes (HH), small granule hemocytes (SGH), and large granule hemocytes (LGH). The HH are unstable hemocytes with a characteristic high nucleo-cytoplasmic ratio. Their cytoplasm appears particularly dense and has from few to numerous granules that often exhibit a typical striated substructure. In both palaemonids, the great majority of the HH contain numerous granules, whereas in Penaeus paulensis, a small number of these cells have few or no granules. The cytoplasm of some HH of the penaeid exhibits typical electron-dense deposits. The granulocytes, LGH and SGH, contain abundant electron-dense granules that are usually smaller in the SGH. In both hemocyte types, the cytosol, but not the granules, is rich in carbohydrates (PAS positive) and numerous vesicles contain acid phosphatase (Gomori reactive). In all studied shrimps, the SGH and LGH were actively phagocytic when examined on blood cell monolayers incubated with the yeast Saccharomyces cerevisiae. A few mitotic figures (less than 1%) were observed in the granulocytes of P. paulensis, but not in the palaemonids. SGH is the main circulating blood cell type in both palaemonids, whereas HH is predominant in the penaeid. Based on morphological and functional features, it appears that the hyaline and the granular hemocytes of the three shrimp species represent different cell lineages. J. Morphol. 236:209–221, 1998. © 1998 Wiley-Liss, Inc.     

Accumulation,localisation, and toxic effects of cadmium in the liverwort Lunularia cruciata

Summary. Accumulation, tissue and intracellular localisation, and toxic effects of cadmium were investigated in the liverwort Lunularia cruciata. The results of analyses carried out by atomic absorption spectrometry on single plants showed that the cadmium accumulation was dose- and time-dependent. Cadmium localisation was assessed by X-ray scanning electron microscopy microanalysis in gemmalings and in the different tissues of the thallus and by X-ray transmission electron microscopy microanalysis at the cellular level. The metal preferentially accumulated in the hyaline parenchyma and at the base of the gemma cups. Inside the cell, cadmium accumulated in the vacuoles and the cell wall. Metal accumulation was accompanied by a concomitant increase in sulphur content within the vacuoles of stressed cells. Gel-permeation chromatography showed that most of the cadmium was associated with a low-molecular-mass fraction eluting at a ratio of elution volume to void volume corresponding to that of phytochelatins. The excess of sulphur deposited in the vacuoles may well have been caused by the stress-induced synthesis of phytochelatins. At the ultrastructural level, sublethal concentrations of cadmium caused alterations of the fine structure of the cells, inducing marked alterations of the chloroplast structure. Cadmium also induced a dose-dependent inhibition of apical thallus growth and gemma germination.Correspondence and reprints: Department of Plant Biology, University Federico 11, via Foria 223, 80132 Naples, Italy.     

A study on the cytoplasmic granules of the pericardial gland cells of some bivalve molluscs

The pericardial glands of three bivalve molluscs are composed of convoluted epithelium that appears as pouches on the auricles of Mytilus and as tubules in the connective tissue at the anterior-lateral sides of the pericardial cavity of Mercenaria and Anodonta. The pericardial gland cells are attached to each other by many randomly placed desmosome-like cell junctions and gap junctions. Belt-desmosomes that are characteristic of epithelial cells were not observed. The basal membrane of these cells is invaginated producing complex interdigitating cytoplasmic processes and filtration slits. The pericardial gland cells stain for the presence of iron with Prussian blue stain. Electron-dense and electron-lucent granules of various diameters are present in the cytoplasm. Many electron-dense granules contain ferritin-like particles in which the presence of iron has been demonstrated by microanalysis. It is suggested that these particles are the iron storage protein ferritin since they contain iron, and are water soluble, heat stable, and morphologically similar to mammalian ferritin. Ferritin particles are probably both synthesized and broken down by the pericardial gland cells; thus the pericardial gland cells may be involved in iron homeostasis in these molluscs.     

Intracellular localization of lead in tissues of the mute swan

The aim of this study was to examine the ultrastructure of kidney, liver, blood and intestine of a lead-poisoned bird and compare these with tissues of a healthy bird. From these results it was hoped to reveal that any abnormalities observed were due to lead poisoning and consequently suitable sections were also selected for X-ray analysis. Renal intranuclear inclusions were present in the lead-poisoned swan. X-ray analysis clearly demonstrated that these granules consist of an amorphous mass of lead probably as lead phosphate. Large numbers of electron dense granules were observed in the liver of the lead-poisoned bird and occasionally in the healthy swans liver. X-ray analysis demonstrated that these granules contain iron. Some of the red blood cells of the lead-poisoned swan have opaque granules associated with the plasma membrane, these were not observed in the healthy swan.     

Origin,structure, composition and age-dependence of mineralized dense bodies (concretions) in the midgut epithelium of the adult housefly, Musca domestica

The epithelial cells of the midgut in 1–40 day old adult female houseflies were examined by electron microscopic, X-ray microanalytic and histochemical techniques in order to study the mode of genesis, chemical nature and age-associated distribution of dense bodies. Dense bodies contain high concentrations of phosphorus, sulphur, chlorine, calcium, iron and copper; they are therefore termed concretions. Concretionary material is initially deposited within Golgi vesicles, lamellar bodies and residual bodies. The average size of the concretion granules and the concentration of the sequestered material increases with age, while new concretions are continually formed throughout life. With advancing age, concretions accumulate in the epithelial cells and occupy a considerable proportion of the cytoplasm in old flies. It is postulated that the concretions sequester superfluous minerals and may play an important role in the excretory system of the adult housefly.     

Microbial adaptation to iron: a possible role of phosphatidylethanolamine in iron mineral deposition

Pseudomonas fluorescens multiplied in a minimal mineral medium supplemented with iron(III) (5 mm) complexed to citrate, the sole source of carbon, with no apparent diminution in cellular mass. Atomic absorption studies of different cellular fractions and supernatant at various growth intervals revealed that the trivalent metal was initially internalized. At approximately 41 h of incubation, the soluble cellular extract contained 9.5% of the iron originally found in the growth medium. However, as bacterial multiplication progressed, most of the metal was deposited as an extracellular insoluble gelatinous residue. Phosphatidylethanolamine appeared to be an important organic constituent of this precipitate. X-ray fluorescence and diffraction studies revealed that iron(III) was deposited as amorphous hydrated oxide. Scanning electron microscopy and energy dispersive X-ray microanalysis of the pellet aided in the identification of irregular shaped bodies rich in iron and oxygen that were associated with carbon-containing elongated structures. Examination of the bacterial cells by a transmission electron microscope equipped with an electron energy loss spectrometer indicated the deposition of iron within the cells.