Sustained expression of osteopontin is closely associated with calcium deposits in the rat hippocampus after transient forebrain ischemia

The present study was designed to evaluate the extent and topography of osteopontin (OPN) protein expression in the rat hippocampus 4 to 12 weeks following transient forebrain ischemia, and to compare OPN expression patterns with those of calcium deposits and astroglial and microglial reactions. Two patterns of OPN staining were recognized by light microscopy: 1) a diffuse pattern of tiny granular deposits throughout the CA1 region at 4 weeks after ischemia and 2) non-diffuse ovoid to round deposits, which formed conglomerates in the CA1 pyramidal cell layer over the chronic interval of 8 to 12 weeks. Immunogold-silver electron microscopy and electron probe microanalysis demonstrated that OPN deposits were indeed diverse types of calcium deposits, which were clearly delineated by profuse silver grains indicative of OPN expression. Intracellular OPN deposits were frequently observed within reactive astrocytes and neurons 4 weeks after ischemia but rarely at later times. By contrast, extracellular OPN deposits progressively increased in size and appeared to be gradually phagocytized by microglia or brain macrophages and some astrocytes over 8 to 12 weeks. These data indicate an interaction between OPN and calcium in the hippocampus in the chronic period after ischemia, suggesting that OPN binding to calcium deposits may be involved in scavenging mechanisms.     

Ultrastructure of the proliferation of astrocytes and microglia]

Glial cell proliferation was studied during axonal reaction of hypoglossal nerve, and around stab wound in the brain cortex of the rat. The cytoplasm and chromosomes of astroglial mitoses were pale. Lipid droplets, few sparse dense bodies with heterogenous structure were present in the cytoplasm. The mitotic astrocytes had irregular outlines. The ultrastructure of "light microglial" cells was described; it was found that these cells divided and gave rise to microglial cells. The cytoplasm and the chromosomes of microglial mitoses were dense; the cytoplasm contained always groups of dense bodies and lipfuscine granules. The outlines of mitotic microglial cells were more regular.     

Metamorphosis of midgut epithelial cells in the silkworm (Bombyx Mori L.) with special regard to the calcium salt deposits in the cytoplasm. I. light microscopy

The morphological changes of the metamorphosing midgut cell in the silkworm were traced light-microscopically. The regenerative cells of the larval midgut proliferate rapidly during larval-pupal molt and finally replace the larval midgut, establishing new pupal midgut tissue composed of only one cell type. Pupal midgut cells contain numerous basophilic granules which are believed on histological grounds to be the deposits of calcium salts. Calcium seems to be transported from hemolymph to the pupal midgut cells and stored there temporarily as insoluble salts such as phosphate or carbonate, and then finally discharged into the lumen in a merocrine fashion. The midgut cells of the adult no longer contain calcium deposits.     

Unique precipitation and exocytosis of a calcium salt of myo-inositol hexakisphosphate in larval Echinococcus granulosus

The ubiquitous intracellular molecule myo-inositol hexakisphosphate (IP6) is present extracellularly in the hydatid cyst wall (HCW) of the parasitic cestode Echinococcus granulosus. This study shows that extracellular IP6 is present as its solid calcium salt, in the form of deposits that are observed, at the ultrastructural level, as naturally electron dense granules some tens of nanometers in diameter. The presence of a calcium salt of IP6 in these structures was determined by two different electron microscopy techniques: (i) the analysis of the spatial distribution of phosphorus and calcium in the outer, acellular layer of the HCW (the laminated layer, LL) through electron energy loss spectroscopy, and (ii) the observation, by transmission electron microscopy, of HCW that were selectively depleted of IP6 by treatment with EGTA or phytase, an enzyme that catalyses the dephosphorylation of IP6. The deposits of the IP6-Ca(II) salt are also observed inside membrane vesicles in cells of the germinal layer (the inner, cellular layer of the HCW), indicating that IP6 precipitates with calcium within a cellular vesicular compartment and is then secreted to the LL. Thus, much as in plants (that produce vesicular IP6 deposits), the existence of transporters for IP6 or its precursors in internal membranes is needed to explain the compound's cellular localisation in E. granulosus.     

Glial activation and TNFR-I upregulation precedes motor dysfunction in the spinal cord of mnd mice

Mice homozygous for the spontaneous motor neuron degeneration mutation (mnd) show at the age of 8 months a marked impairment of the motor function and accumulation of lipofuscin granules in the cytoplasm of almost all neurons of the central nervous system.We previously reported a significant increase in GFAP protein levels in the lumbar spinal cord homogenates by western blot analysis and upregulation of TNF, a proinflammatory cytokine, in the motor neurons of lumbar spinal cord of mnd mice, already in a presymptomatic stage (4 months of age). In the present study, using immunohistochemical analysis, we performed a time course in mnd mice (1, 4 and 9 months of age) evaluating the expression and the distribution of astroglial and microglial cells and the expression of both TNF receptors, TNFR-I and TNFR-II. We observed a marked increase in astroglial and microglial cells and in TNFR-I immunoreactivity already at the 4th month. Since motor neuron dysfunction occurs in mnd mice in the absence of evident loss of spinal motor neurons, the present results indicate that the activation of microglial cells and astrocytes is independent from neuronal degeneration. The role of TNF and TNFR-I on motor neurons is still to be demonstrated.     

Dissociation between hippocampal neuronal loss, astroglial and microglial reactivity after pharmacologically induced reverse glutamate transport

The inflammatory central nervous system response that involves activated microglia and reactive astrocytes may both heal and harm neurons, as inflammatory mediators lead to neuroprotection or excitation at one dose but to injury at a different concentration. To investigate these complex cellular interactions, L-trans-pyrrolidine-2,4-dicarboxylate (PDC), a selective substrate inhibitor of glutamate transport, was infused during 14 days in the rat hippocampus at three different rates: 5, 10 and 25 nmol/h. A microglial reaction appeared at the 5 nmol/h PDC rate in absence of astroglial reaction and neuronal loss. Microgliosis and neuronal death were observed at PDC 10 nmol/h in absence of astrogliosis and calcium precipitation, whereas all four aspects were present at the highest rate. This dissociation between neuronal loss and astroglial reactivity took place in presence of a permanent microglial reaction. These data suggest a specific response of microglia to PDC whose neuronal effects may differ with the infused dose.     

The impregnation of bone and pathologic calcification by metal salts and their recognition by unoxidized hematoxylin

Summary Of 225 metal compounds tested, salts of 34 metals can enter the calcium carbonate-phosphate-protein complex of bone and calcified tissue. The soluble salts of silver and mercury (I) form black deposits by direct reaction; mercury forms black feathery or acicular crystals as well. The other metals are easily detected by the formation of colored compounds when dilute unoxidized hematoxylin is applied. Nine metals combine with the protein moiety, as their presence is still observed by color changes with hematoxylin after decalcification of the tissues with acids or sequestrene prior to metal impregnation. Because of similarity of color produced by similar metal salts, there seems to be some resemblance between the protein of the keratohyalin granules of the skin and the protein of bone and pathologic calcification.     

Modulation of [3H]-glutamate binding by serotonin in the rat hippocampus: an autoradiographic study.

Serotonin (5-HT) added in vitro (10 microM) increased [3H]-glutamate specific binding in the rat hippocampus, reaching statistical significance in layers rich in N-Methyl-D-Aspartate sensitive glutamate receptors. This effect was explained by a significant increase in the apparent affinity of [3H]-glutamate when 5-HT is added in vitro. Two days after lesion of serotonergic afferents to the hippocampus with 5,7-Dihydroxytryptamine [3H]-glutamate binding was significantly decreased in the CA3 region and stratum lacunosum moleculare of the hippocampus, this reduction being reversed by in vitro addition of 10 microM 5-HT. The decrease observed is due to a significant reduction of quisqualate-insensitive (radiatum CA3) and kainate receptors (strata oriens, radiatum, pyramidal of CA3). Five days after lesion [3H]-glutamate binding increased significantly in the CA3 region of the hippocampus but was not different from sham animals in the other hippocampal layers. Two weeks after lesion [3H]-glutamate binding to quisqualate-insensitive receptors was increased in all the hippocampal layers, while kainate and quisqualate-sensitive receptors were not affected. These data are consistent with the possibility that 5-HT is a direct positive modulator of glutamate receptor subtypes.     

Histochemical demonstration of purine nucleoside phosphorylase (PNPase) in microglial and astroglial cells of adult rat brain

The histochemical localization of enzymes associated with purine nucleoside metabolism indicates that glial cells might participate in the regulation of these compounds in the central nervous system. In the present study we examined the histochemical localization of purine nucleoside phosphorylase (PNPase) in sections from adult rat brain. Some sections were also sequentially stained immunocytochemically for astroglial or microglial cells utilizing glial fibrillary acidic protein (GFAP) or OX-42 antibodies, respectively. Our observations showed that PNPase was restricted to glial cells, whereas neurons always remained negative. Brain sections stained for both PNPase and GFAP showed that the GFAP-positive astroglial cells were always PNPase positive. Other PNPase-positive but GFAP-negative cells were also observed. These cells resembled microglial cells, and brain sections reacted for both PNPase and OX-42 confirmed this by showing that the major part of OX-42-positive microglial cells were PNPase positive. In these sections, the PNPase-positive but OX-42-negative cells present resembled astroglial cells. From our double staining experiments, we conclude that PNPase is present in both astroglial and microglial cells in normal adult brain.     

A nuclear microscopic study of elemental changes in the rat hippocampus after kainate-induced neuronal injury

The effect of intracerebroventricular kainate injection on the elemental composition of the hippocampus was studied in adult Wistar rats, at 1 day and 1, 2, 3, and 4 weeks postinjection, using a nuclear microscope. An increase in calcium concentration was observed on the injected side from 1 day postinjection. The increase peaked at 3 weeks postinjection, reaching a concentration of 18 times normal. Large numbers of glial cells but no neurons were observed in the lesioned CA fields at this time, suggesting that an increased calcium level was present in glial cells. This was confirmed by high-resolution elemental maps of the lesioned areas, which showed very high intracellular calcium concentrations in almost all glial cells. It is possible that the high intracellular calcium level could activate calcium-dependent enzymes, including calpain II and cytosolic phospholipase A2, shown to be expressed in reactive glial cells after kainate injections. In addition to calcium, an increase in iron content was also observed at the periphery of the glial scar at 4 weeks postinjection. Because free iron could catalyze the formation of free radicals, the late increase in iron content may be related to oxygen radical formation during neurodegeneration.     

The lipofuscin in neuroglial cells of the optic nerve of Formosan rock-monkey (Macaca cyclopis)

The ultrastructure of lipofuscin granules in neuroglial cells of the optic nerve of the Formosan Rock-Monkey was investigated by electron microscopy. In the cytoplasm of astroglial cells, numerous irregular lipofuscin granules were characterized by the presence of large lipid droplets, small electron-dense pigment granules, and some lamellar structures. The lipofuscin granules of the oligodendroglial cells were composed largely of dense, coarse pigment granules, multilinear structures, and a few small lipid droplets. The lipofuscin granules in microglial cells were characterized by numerous lipid droplets in various sizes, small electron-dense pigment granules, and prominent lamellar structures. It was reported that the lipofuscin granules are wear-and-tear materials and products from the cells in lower functional activity. However, our observations suggest that the presence of lipofuscin granules in the neuroglial cells of the optic nerve is likely a characteristic product of active phagocytosis.     

Accurate Localization in Ultrathin Sections by Direct Observation of the Block Face for Trimming

Psammoma bodies and small calcifications are frequently seen in a wide variety of tissues. These deposits of calcium salts render tissues difficult to section. Conventional decalcification alters the tissues; consequently it is not advisable to decalcify tissues containing only small calcium deposits. A simple and rapid method to remove small amounts of calcium salts using citric acid alone is described. This method does not alter the antigenic properties of the substances studied.     

A Method for Decalcification with Citric Acid

Psammoma bodies and small calcifications are frequently seen in a wide variety of tissues. These deposits of calcium salts render tissues difficult to section. Conventional decalcification alters the tissues; consequently it is not advisable to decalcify tissues containing only small calcium deposits. A simple and rapid method to remove small amounts of calcium salts using citric acid alone is described. This method does not alter the antigenic properties of the substances studied.     

Cytohistochemical techniques for calcium localization and their application to diseased plants

Lesion delimitation and resistance of old bean (Phaselous vulgaris L., cv. Red Kidney) plants to Rhizoctonia solani Kühn have been suggested to result from increased calcium pectate formation in walls. Ultrastructural histochemistry was used to determine the site of calcium in tissues adjacent to lesions and in older bean hypocotyls. Hypocotyl lesion tissue and uninoculated control tissue were treated with ammonium oxalate or potassium pyroantimonate during fixation. Treatment with potassium pyroantimonate, but not with oxalate, resulted in granular deposits in cell walls of healthy and lesion tissue. Granules also occurred on the plasma membrane of cells adjacent to lesions and in organelles of damaged cells, but wall granule density was not increased. Cell walls from healthy 24-day-old plants had a greater granule density than those for 8-day-old plants. Wall granules were removed from thin sections with ethylene glycol bis(β-aminoethyl ether)-N,N,N′,N′-tetraacetic acid. Energy dispersive analysis of x-rays also suggested that potassium pyroantimonate localized calcium. Chemical analyses showed that some calcium was retained in tissues after fixation. The results suggest that there are different mechanisms for lesion delimitation and age-induced resistance.     

Scanning electron microscopy of spherules of Physarum polycephalum

The ultrastructure of starvation-induced sclerotic and mannitol-induced spherules was studied by a scanning electron microscope (SEM). Each spherule in the berry-like sclerotium is not rounded and has lobe-like forms, whereas the separate spherules are significantly bigger and rounded. Bead-like granules were observed inside and on the spherules. Broken spherules observed in the SEM show ultrastructure of cell wall, cytoplasm, vacuoles and granules, nuclei and nucleoli.     

The local environment of metal sites in intracellular granules investigated by using X-ray-absorption spectroscopy.

We report the use of X-ray-absorption spectroscopy (x.a.s.) to study the local atomic environment of cations in intracellular granules from the hepatopancreas of Helix aspersa. Both the calcium K-edge in these concretions and the manganese K-edge in doped specimens were measured. Electron-microprobe measurements confirm that the introduced Mn2+ is concentrated in irregular growths on the surfaces of the granules. The near-edge structure (x.a.n.e.s.) of calcium is similar to that of manganese, indicating that the oxygen-co-ordination spheres of both cations share a similar symmetry. From the extended structure (e.x.a.f.s.) the metal-oxygen bond lengths of 0.230 nm (2.30A) for Ca-O and 0.218 nm (2.18A) for Mn-O [+/- 0.004 nm (0.04A)] were determined, reference being made to a variety of model compounds. The low density of the granules (2.07 g/cm3), together with the local atomic distribution, suggest an open hydrated structure for these phosphate deposits. Detailed analysis of the distribution of nearest-neighbour oxygen atoms demonstrates that this is asymmetric and considerably broader for Ca2+ than for Mn2+. Compared with the model compounds, the Ca2+ environment in the granules is similar to that observed in Ca2P2O7. I.r. spectra indicate the presence of condensed phosphate groups in the granules, with the strong possibility these are pyrophosphate (P2O7(4-) groups.     

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.     

Calcium binding by monosulfate esters of taurochenodeoxycholate

The effect of sulfate esterification of the 3 alpha- or 7 alpha-hydroxyl groups of taurochenodeoxycholate on calcium binding was studied at 0.154 M NaCl in the presence and absence of phosphatidylcholine using a calcium electrode. For comparison, similar studies were made with taurochenodeoxycholate, taurodeoxycholate, and taurocholate. No high affinity calcium binding was demonstrable for any of these bile salts in pre-micellar solutions. Taurine-conjugated bile salts have greater affinity for calcium when in a micellar form. At elevated bile salt concentrations, the calcium binding of unsulfated dihydroxy taurine conjugates was similar to that of the monosulfate esters of taurochenodeoxycholate. The presence of phosphatidylcholine decreased calcium binding of the unsulfated dihydroxy bile salts and slightly increased calcium binding by taurocholate. However, the addition of phosphatidylcholine to monosulfate esters of taurochenodeoxycholate results in large increments in calcium binding. The results indicate that increased calcium binding due to the presence of phosphatidylcholine in bile salt solutions depends, in part, on the hydrophilicity of the bile salt and that the interaction of monosulfate esters of taurochenodeoxycholate with phosphatidylcholine leads to the formation of a high affinity calcium binding site.     

Ultrastructural Localization of Calcium in the Presumptive Ectodermal Cells in Gastrulae of the Newt, Cynops pyrrhogaster, as Revealed by Cytochemistry and X-Ray Microanalysis

The ultrastructural localization of calcium in the presumptive ectodermal cells of gastrulae of the newt, Cynops pyrrhogaster , was examined by cytochemical methods and X-ray microanalysis (XMA). The cells were fixed with solutions that contained potassium oxalate, potassium ferricyanide and potassium pyroantimonate to preserve the localization of intracellular calcium in situ and for the analysis of electron density due to calcium. Electron-dense deposits associated with the localization of calcium were observed under the electron microscope. Specificially, pigment granules, round vacuoles, endoplasmic reticulum and mitochondria as well as the extracellular matrix were observed to contain calcium. In addition, XMA clearly demonstrated the localization of calcium in all of these electron-dense organelles and yolk granules.     

Contuse lesion of the rat spinal cord of moderate intensity leads to a higher time-dependent secondary neurodegeneration than severe one. An open-window for experimental neuroprotective interventions

Secondary neurodegeneration takes place in the surrounding tissue of spinal cord trauma and modifies substantially the prognosis, considering the small diameter of its transversal axis. We analyzed neuronal and glial responses in rat spinal cord after different degree of contusion promoted by the NYU Impactor. Rats were submitted to vertebrae laminectomy and received moderate or severe contusions. Control animals were sham operated. After 7 and 30 days post surgery, stereological analysis of Nissl staining cellular profiles showed a time progression of the lesion volume after moderate injury, but not after severe injury. The number of neurons was not altered cranial to injury. However, same degree of diminution was seen in the caudal cord 30 days after both severe and moderate injuries. Microdensitometric image analysis demonstrated a microglial reaction in the white matter 30 days after a moderate contusion and showed a widespread astroglial reaction in the white and gray matters 7 days after both severities. Astroglial activation lasted close to lesion and in areas related to Wallerian degeneration. Data showed a more protracted secondary degeneration in rat spinal cord after mild contusion, which offered an opportunity for neuroprotective approaches. Temporal and regional glial responses corroborated to diverse glial cell function in lesioned spinal cord.