Ultrastructural localization of acid phosphatase in nonhuman primate vaginal epithelium

Summary The vagina of the rhesus monkey is lined by a stratified squamous epithelium. However, little is known regarding the cytochemical composition of its cell organelles and the substances found in the intercellular spaces. In this study we have examined the ultrastructural distribution of acid phosphatase in the vaginal epithelium. In basal and parabasal cells reaction product was found in some Golgi cisternae and vesicles and in a variety of cytoplasmic granules. Reaction product was also found in some, but not all, membrane-coating granules. In the upper layers of the epithelium, the membrane-coating granules extruded their contents and acid phosphatase was localized in the intercellular spaces. The possible roles of acid phosphatase in keratinization, desquamation, or modification of substances in the intercellular compartment are discussed.     

An electron microscope study of acid hydrolase activity in the pneumonocytes of Xenopus laevis

Synopsis Electron microscope techniques were used to study the intercellular distribution of aryl sulphatase and acid phosphatase in the pneumonocytes which line the air spaces in the lung ofXenopus laevis. Strong reactions for aryl sulphatase and acid phosphatase were present in the limiting membranes of the cytoplasmic inclusion bodies; no significant activity was found in the inclusion contents or in the membranous material present in the air spaces. Both enzymes were present in the multivesicular bodies but other organelles were unreactive. These results suggest that hydrolytic enzymes are involved in the secretion of surface-active materials in amphibian lung.     

The use of an inexpensive,general purpose microcomputer in quantitative cytochemistry

Summary The histochemical localization of alkaline phosphatase in sheep parathyroid gland was investigated using light and electron microscopy. The reaction products of enzyme activity were observed by light microscopy in pericytes. By electron microscopy they were limited to the intercellular spaces between the gland cells, being exclusively confined to the external surface of plasma membrane.     

Submicroscopic localization of acid phosphatase in the dental cyst epithelium

Summary Distribution of acid phosphatase was studied in the dental cyst epithelium. Enzyme activity was found to be localized in primary and secondary lysosomes and vacuoles of the Golgi complex. Longer incubation revealed positive reaction in the Golgi complex vesicles and cisternae, in the endoplasmic reticulum, and perinuclear' space. Acid phosphatase reaction was bound also to membranous structures occurring in the intercellular spaces. These structures originated probably from disintegrated cells. Localization of acid phosphatase reaction in the dental cyst epithelium was found to be essentially the same as in the oral cavity epithelium. Smaller differences between both types of epithelium may be conditioned by different type and arrangement of the organelles in the corresponding epithelial layers.     

Distribution of Acid Phosphatase in Chick Hensen's Node

Acid phosphatase distribution and yolk drop infrastructure in Hensen's node of chick blastoderm at Hamburger-Hamilton stages 3 and 4 are described. At stage 3 large deposits of the reaction product are localised in type-A yolk drops, where signs of intensive degradation are seen. It seems that during this degradation lipid droplets are being formed in the degrading yolk drops. Partly digested yolk drops with a vesicular appearance are extruded from the cells, especially in deeper layers of the node. The phosphatase reaction product is also distributed into intercellular spaces. At stage 4 the cells of the node are more vacuolated and contain acid phosphatase and electron-dense yolk drops in lesser amounts. The possible physiological role of acid phosphatase in Hensen's node during g'astrulation is discussed.     

Ultrastructure du tissu apical testiculaire du doryphore Leptinotarsa decemlineata Say (Coléoptère: Chrysomélidé): étude autoradiographique et cytochimique / Ultrastructure of the apical testicular tissue of the doryphore Leptinotarsa decemlineata Say (Coleopterae: Chrysomelidae): an autoradiographic and cytochemical study

Summary

The somatic ‘apical tissue’ is present in the testes of the Colorado potato beetle from the embryonic stage until the end of the reproductive life. In the vicinity of this tissue, cyst cells and primary gonia are often pycnotic. Incorporation of labelled amino acids in vivo and treatment with pronase indicate that apical cells are sites of protein synthesis. Secretions are glycosylated in the Golgi apparatus where they are also concentrated in granules. Some of them display a positive reaction to the acid phosphatase test. They are extruded by exocytosis into the intercellular spaces which they distend. We conclude that the apical secretions have a lytic activity: gonia and cyst cells are reduced to cellular residues which are accumulated in the intercellular spaces.     

Contribution of folate biosynthesis to Ralstonia solanacearum proliferation in intercellular spaces

The vigorous proliferation of Ralstonia solanacearum OE1-1 in host intercellular spaces after the invasion of host plants is necessary for the virulence of this bacterium. A folate auxotroph, RM, in which a mini-Tn5 transposon was inserted into pabB encoding para-aminobenzoate synthase component I, lost its ability to vigorously proliferate in intercellular spaces along with its systemic infectivity and virulence after inoculation into roots and infiltration into leaves of tobacco plants. Complementation of RM with the pabB gene allowed the mutant to multiply in intercellular spaces and to cause disease. In tobacco plants that were pretreated with folate, RM was able to vigorously proliferate in the intercellular spaces and cause disease. Interestingly, when it was inoculated through cut stems, the mutant multiplied in the plants and was virulent. Moreover, the mutant multiplied well in stem fluids but not in intercellular fluids, suggesting that the folate concentration within intercellular spaces may be a limiting factor for bacterial proliferation. Therefore, folate biosynthesis contributes to the vigorous proliferation of bacteria in intercellular spaces and leads to systemic infectivity resulting in virulence.     

Cryoprotectant-treated myocardium evaluation.

Whole excis ed rat hearts were treated with 5, 10, or 15% (v/v) dimethyl sulfoxide/glycerol and then some were frozen in liquid nitrogen while the balance remained unfrozen. Freezing and thawing rates were approximately 30degreesC/min. Ventricular tissue was examined for histological damage, glycogen depletion, and enzyme sites, using histological, histochemical, and electron microscopy techniques. Early signs of cellular degeneration and ischemia were observed in all unfrozen groups; depletion of glycogen reserves, fuchsinophilic staining, vacuolization and granulation of the sarcoplasm were noted. Results from frozen groups were similar, but ultrastructural damage was more severe and extensive. Alkaline phosphatase and succinic dehydrogenase sites were abundant in unfrozen specimens and absent or markedly reduced in frozen specimens which also exhibited widespread nonspecific staining throughout intercellular spaces.     

The formation of intercellular spaces in the cotyledons of developing and germinating pea seeds

Summary Electron microscopic observations have shown that the intercellular spaces in the storage parenchyma of the cotyledons of pea (Pisum sativum L.) seeds arise schizogenously. The wall segments adjoining future intercellular spaces display a triple zonation and contain regions with electron-dense material. Space formation starts at the central point of contact between several cells and spreads then further up to the electron-dense, intra-wall structures. As a result of this the electron-dense material is found again in the corners of intercellular spaces. It is proposed that the intra-wall structures may have an important function in limiting the schizogenous process. The localization of the intercellular spaces is thus predetermined. The amount of electron-dense material in their corners increases considerably during further development of the embryo. During germination wall segments between two intercellular spaces diverge resulting in a fusion of several spaces.     

Cavitation of intercellular spaces is critical to establishment of hydraulic properties of compression wood of Chamaecyparis obtusa seedlings

Background and Aims When the orientation of the stems of conifers departs from the vertical as a result of environmental influences, conifers form compression wood that results in restoration of verticality. It is well known that intercellular spaces are formed between tracheids in compression wood, but the function of these spaces remains to be clarified. In the present study, we evaluated the impact of these spaces in artificially induced compression wood in Chamaecyparis obtusa seedlings.Methods We monitored the presence or absence of liquid in the intercellular spaces of differentiating xylem by cryo-scanning electron microscopy. In addition, we analysed the relationship between intercellular spaces and the hydraulic properties of the compression wood.Key Results Initially, we detected small intercellular spaces with liquid in regions in which the profiles of tracheids were not rounded in transverse surfaces, indicating that the intercellular spaces had originally contained no gases. In the regions where tracheids had formed secondary walls, we found that some intercellular spaces had lost their liquid. Cavitation of intercellular spaces would affect hydraulic conductivity as a consequence of the induction of cavitation in neighbouring tracheids.Conclusions Our observations suggest that cavitation of intercellular spaces is the critical event that affects not only the functions of intercellular spaces but also the hydraulic properties of compression wood.     

Maintenance of air in intercellular spaces of plants

Although air-filled intercellular spaces are necessary and ubiquitous in higher plants, little attention has been paid to the possible mechanisms by which these spaces are kept from being flooded. The most likely mechanism is that the living plant cell may maintain a hydrophobic monolayer on the surfaces of adjacent intercellular spaces. The existence of `apparent free space' in cell walls and the fact that detergent solutions do not enter the intercellular spaces argue against this hypothesis. It is concluded that the mechanism by which these important air spaces are maintained is still unknown.     

Dimensions and distribution of intercellular spaces in cryo-planed soybean nodules

The ability of legume nodules to regulate their permeability to gas diffusion has been attributed to physiological control over the size and distribution of gas-filed intercellular spaces within the nodule cortex. To examine the size and distribution of intercellular spaces and to determine whether they were filled with gas (high diffusion permeability) or liquid (low diffusion permeability), whole nodules were frozen in liquid nitrogen slush (-210°C), and then either cryo-fractured or cryo-planed before being examined by cold-stage scanning electron microscopy (SEM). The cryo-planed tissue was found to have many advantages over cryo-fractured nodules in providing images which were easier to interpret and quantify. Intercellular spaces throughout the nodule were examined in both tangential and medial planed faces. Since no differences were observed between views in either the size or shape of the open intercellular spaces, it was concluded that the intercellular spaces of nodules were not radially oriented as assumed in many mathematical models of gas diffusion. The inner cortex region in the nodules had the smallest intercellular spaces compared to other zones, and less than 10% of the intercellular spaces were occluded with any type of material in the central zone regions. Vacuum infiltration of nodules with salt solutions and subsequent cryo-planing for SEM examination showed that open and water-filled intercellular spaces could be differentiated. The potential is discussed for using this method to study the mechanism of diffusion barrier regulation in legume nodules.     

Intercellular protuberances in the ground tissue ofCocos nucifera L.

Summary Prolific filamentous intercellular protuberances have been observed in the intercellular spaces of the ground parenchyma tissue in the stems ofCocos nucifera. They are visually similar to some intercellular material reported in several other plant tissues but their chemical composition is unknown. Tests for lignin, cellulose, callose, suberin and waxes have proved negative and those for pectin inconclusive. The amount of intercellular material is closely related to the thickness of the parenchyma cell wall and the protuberances appear to be produced continuously by an active cytoplasm.     

Contribution of Folate Biosynthesis to Ralstonia solanacearum Proliferation in Intercellular Spaces

The vigorous proliferation of Ralstonia solanacearum OE1-1 in host intercellular spaces after the invasion of host plants is necessary for the virulence of this bacterium. A folate auxotroph, RM, in which a mini-Tn5 transposon was inserted into pabB encoding para-aminobenzoate synthase component I, lost its ability to vigorously proliferate in intercellular spaces along with its systemic infectivity and virulence after inoculation into roots and infiltration into leaves of tobacco plants. Complementation of RM with the pabB gene allowed the mutant to multiply in intercellular spaces and to cause disease. In tobacco plants that were pretreated with folate, RM was able to vigorously proliferate in the intercellular spaces and cause disease. Interestingly, when it was inoculated through cut stems, the mutant multiplied in the plants and was virulent. Moreover, the mutant multiplied well in stem fluids but not in intercellular fluids, suggesting that the folate concentration within intercellular spaces may be a limiting factor for bacterial proliferation. Therefore, folate biosynthesis contributes to the vigorous proliferation of bacteria in intercellular spaces and leads to systemic infectivity resulting in virulence.     

Electron microscopic investigation of water occlusions in intercellular spaces in the inner cortex of lucerne nodules.

It is unclear to what extent oxygen diffusion pathways through the cortex of the nitrogen-fixing zone of indeterminate nodules are liquid filled and whether a blockage of these pathways is involved in varying nodule oxygen permeability to control nitrogenase activity. We examined the proportion of water-filled intercellular spaces of lucerne (Medicago sativa L.) nodules with cryo-scanning electron microscopy. This technique allows for direct observation of water accumulation. Thirty percent of all intercellular spaces in the inner cortex of lucerne nodules were liquid filled. Decreasing the nodule oxygen permeability by detopping of the plant or by increasing the rhizospheric oxygen partial pressure to 80 kPa had no statistically significant effect on the water distribution in the intercellular spaces. Therefore, the hypothesis of a continuous aqueous diffusion barrier in the inner cortex could not be supported. The abundance of glycoproteins in intercellular spaces of the inner cortex was investigated with immunoelectron microscopy. No alteration due to detopping or after increase of the rhizospheric oxygen partial pressure was observed. Therefore, our results do not support the hypothesis of a short-term regulation of oxygen permeability by blockage of diffusion pathways through morphological changes in the cortex region of the nitrogen-fixing zone of lucerne nodules.     

The intercellular canalicular system in the endocrine pancreas. A putative dynamic formation

A system of intercellular spaces in the islets of Langerhans of the rat pancreas was found after 6-hydroxydopamine treatment being absent in the control animals. Therefore, we propose that the intercellular canalicular system occurs in response to increased secretory activity of the islets.     

Ultrastractural features of the principal cell in the epididymis of the rhesus monkey

The ultrastructural features of the principal cell in the epididymal epithelium of the monkey epididymis are suggestive of the cell carrying out a dual function of absorption and secretion. Both these functions occur on the luminal surface of the cell as well as on the lateral and basal aspects of the cell which face the intercellular spaces. Transmision Electron Microscopic studies of epididymal tissues following their impregnation with lanthanum nitrate indicated that the intercellular spaces are effectively sealed-off from the luminal space by the apically situated tight junctions between adjoining principal cells. The intercellular spaces are contiguous with the perivascular spaces of the subepithelial blood capillaries. It is suggested that the absorptive and secretory functions occuring on the apical surface of cells may be related to the creation of an appropriate intraluminal milieu for the maturation of spermatozoa while the occurrence of these functions in the intercellular spaces may represent an exchange of substances between the principal cells and the subepithelial capillaries.     

Transmission Electron Microscopy of Susceptible and Resistant Tomato Leaves Following Infection with Pseudomonas syringae pv. tomato

Ultrastructural changes in tomato leaves of susceptible cv. Peto 95 and resistant cv. Ontario 7710 infected with Pseudomonas syringae pv. tomato were followed by transmission electron microscopy. Up to 48 hours from the inoculation host cells of both cultivars looked quite normal and no bacteria were visible in the intercellular spaces; bacterial cells were found only in the substomatal chambers. Afterwards, the leaf cells of cv. Peto 95 began to degenerate and bacteria invaded the intercellular spaces which seemed enlarged. After 15 days the disorganization was complete: tomato cells were plasmolyzed and the intercellular spaces were filled with bacteria. In the leaves of resistant cv. Ontario 7710 no bacteria were observed later than 48 hours and no visible modifications occurred up to 15 days after the inoculation.     

Distribution of Intercellular Material in the Apical Part of Pea Seedlings

The sections from the upper part of the third internode, counted from the seed, in etiolated pea seedlings are studied for the distribution of two types of Intercellular spaces: the transparent and the dark. The transparent spaces represent the result of the water logging of passages originally water-lined, while the dark spaces are lined with a lipid-containing substance which may be impregnated with melted paraffin and which forms a ramifying network within the tissue. The intercellular material of the dark spaces has the appearance of a tube, since it concentrically lines the intercellular space, leaving a lumen for air or gas. It is a plastic, isotropic subslance which may be cut transversely and identified in successive sections of the inlernode as belonging to the same continuous material from the intercellular space. The dark and the transparent spaces have a distinct pattern of distribution in the growing internode, and the relative quantity of dark spaces present at different levels of the internode may be measured. The dark spaces predominate in those parts of the stem with a greater potential for growth, while the transparent spaces are located in the regions where growth has ceased or subsided. Since the paraffin is infiltrated instantaneously throughout the network of dark intercellular spaces, it is possible that these may represent a channel for the translocation of substances.     

Formation of intercellular gas space in the diaphragm during the development of aerenchyma in the leaf petiole of Sagittaria trifolia

The development of aerenchyma in the petiole of Sagittaria trifolia L. was studied by means of light-microscopy, scanning electron microscope, transmission electron microscope and immunofluorescence, focusing on the formation of intercellular spaces in diaphragms and its relationship with the organization of cortical microtubule arrays. A complex and organized honeycomb-like schizogenous aerenchyma formed by cylinders and vascular diaphragms was observed in the petiole of S. trifolia at different developmental stages. Cell division was the primary factor contributing to the increased volume of air spaces at early stages, while cell enlargement became the primary factor at later stages. The cortical microtubules localize at the sites where intercellular spaces and the secondary cell walls will be formed or deposited during the formation of intercellular spaces by the separation of diaphragm cells. Cortical microtubules were observed at the boundary of diaphragm cells and the fringes of intercellular spaces at later developmental stages where cell expansion occurs rapidly. These observations support the hypothesis that reorganization of cortical microtubule arrays might be related to the formation of air spaces in diaphragms and are involved in the deposition of secondary cell walls.