Phi bodies: peroxidatic particles that produce crystalloidal cellular inclusions.

Unique, spindle-shaped particles (phi bodies) and rods with peroxidatic activity are found in certain epithelial cells of normal mice, clofibrate-fed rats, and in leukemic leukocytes. The ellipsoidal shape of phi bodies apparently results from the deformation of spherical granules by extrusion of axial crystalloid that subsequently fragments into rods.

Wafer embedding: specimen selction in electron microscopic cytochemistry with osmiophilic polymers.

A new wafer embedding procedure is described that permits light microscopic screening of embedded tissue prior to ultrathin sectioning. It is particularly valuable when used on specimens obtained with an automatic sectioner and treated cytochemically to obtain visible intermediate or visible and electron opaque final reaction products. Aldehyde-fixed tissues are cut into sections with an automatic sectioner, incubated cytochemically osmication if required, then embedded in epoxy resin between fluorocarbon coverglasses which are supported by a platform specially designed for this purpose. The resultant wafter, less than 0.2 mm thick, is examined by light microscopy for optimal areas of cytochemical reaction and desirable structural features. Such areas are cut out and glued to blank blocks with fast curing cyanoacrylate cement for subsequent ultrathin sectioning. The usefulness of this technique is demonstrated by the location of: (1) esterase-positive lysosomes in kidney and trigeminal ganglia; (2) palatal sensory endings stained for acetylcholinesterase; and (3) phagosomes arising from the resorption of horseradish peroxidase tracer by the cuboidal parietal epithelial cells of Bowman's capsule in the male mouse.

Tissue fixation and osmium black formation with nonvolatile octavalent osmium compounds.

Several compounds of osmiumVIII, including potassium osmiamate and coordination complexes of OsO4 with ammonia and various heterocyclic nitrogen compounds, have been synthesized and characterized. They have also been evaluated as substitutes for OsO4 in postfixation of biological specimens and in light and electron microscopic cytochemical methods resulting in osmium black formation. The most useful of these osmic compounds, a molecular addition complex of hexamethylenetetramine (methenamine) with OsO4, has a negligible vapor pressure of OsO4. It has the molecular formula C6H12N4.2OsO4 and has been designated osmeth. Although it has only limited solubility, aqueous solutions of the compound (or of OsO4) can be rapidly prepared by dissolution in a minimal amount of dimethylformamide and subsequent dilution with distilled water or buffer. Although stable in the solid state, the complex in solution undergoes partial dissociation releasing OsO4, and the odor of OsO4 becomes apparent. Such solutions of osmeth are (approximately 0.25%) considerably less concentrated with respect to OsO4 than solutions (1-2%) ordinarily employed for ultrastructural preservation or in cytochemical studies. Osmeth has limited value for postosmication after glutaraldehyde fixation because the generation (release) of OsO4 appears to be slow. Adequate osmication of tissue blocks exists only at the surface, but effective osmication can be achieved throughout tissue sections. In cytochemical reactions resulting in the formation of osmium blacks, the osmeth solutions are as effective as OsO4 solutions of equivalent concentrations. Our findings indicate that OsO4 solutions of less than 1% may be satisfactorily utilized in many cytochemical studies. Osmeth is safer and more convenient to handle than OsO4 because small amounts may be solubilized as needed. It should be considered as a substitute for OsO4 in ultrastructural cytochemistry. These results suggest that the effectiveness of OsO4 as a fixative may, in part, be related to its nonpolarity. The infrared spectra indicate that the OsO4 molecule is tetrahedral, perfectly symmetrical and, therefore, as a whole nonpolar. As a consequence, it could be expected to readily penetrate charged surfaces of tissues, cells, and organelles. The spectral studies show that osmeth is much less symmetrical and, to that extent, polar; thus, it penetrates biomembranes less readily.

Catalase in salivary gland striated and excretory duct cells. II. phi body: an ellipsoidal peroxisomal organelle with crystalloid axial projections.

A new distinctive and unique peroxisomal organelle with a spindle shape has been observed in luminal epithelial cells of striated and excretory ducts of mouse salivary glands. Light microscopic studies indicate it has an ellipsoidal centre from which catalase-positive filamentous or rod-like processes protrude along its major axis; hence, it is called a phi body. A role for this specialized peroxisome in the formation of nearby free filaments and rods is suggested by the frequent observation of segmentation of its axial processes. Complementary ultrastructural studies of osmium-fixed preparations show that the deformation to an oval shape results from the pressure of the extruding crystalloid coincident with the major axis of the ellipsoidal body. The size range and conformation of phi body axial processes are comparable to those of free catalase-positive rods and filaments observed in the same cells. The periodic substructure of the crystalloid in the phi body core is identical with that of nearby cytoplasmic rods. These observations are consistent with the view that the rods and filaments observed free in the cytoplasm are formed by extrusion from the crystalloid core of the phi body. phi Bodies could also be responsible for the Aver rods of leukemic leukocytes.

Cellulose in cyanobacteria. Origin of vascular plant cellulose synthase?

Although cellulose biosynthesis among the cyanobacteria has been suggested previously, we present the first conclusive evidence, to our knowledge, of the presence of cellulose in these organisms. Based on the results of x-ray diffraction, electron microscopy of microfibrils, and cellobiohydrolase I-gold labeling, we report the occurrence of cellulose biosynthesis in nine species representing three of the five sections of cyanobacteria. Sequence analysis of the genomes of four cyanobacteria revealed the presence of multiple amino acid sequences bearing the DDD35QXXRW motif conserved in all cellulose synthases. Pairwise alignments demonstrated that CesAs from plants were more similar to putative cellulose synthases from Anabaena sp. Pasteur Culture Collection 7120 and Nostoc punctiforme American Type Culture Collection 29133 than any other cellulose synthases in the database. Multiple alignments of putative cellulose synthases from Anabaena sp. Pasteur Culture Collection 7120 and N. punctiforme American Type Culture Collection 29133 with the cellulose synthases of other prokaryotes, Arabidopsis, Gossypium hirsutum, Populus alba x Populus tremula, corn (Zea mays), and Dictyostelium discoideum showed that cyanobacteria share an insertion between conserved regions U1 and U2 found previously only in eukaryotic sequences. Furthermore, phylogenetic analysis indicates that the cyanobacterial cellulose synthases share a common branch with CesAs of vascular plants in a manner similar to the relationship observed with cyanobacterial and chloroplast 16s rRNAs, implying endosymbiotic transfer of CesA from cyanobacteria to plants and an ancient origin for cellulose synthase in eukaryotes.

The demonstration of arylsulfatases with 4-nitro-1,2-benzenediol mono(hydrogen sulfate) by the formation of osmium blacks at the sites of copper capture.

A new method is described for the direct cytochemical demonstration of lysosomal arylsulfatases utilizing a synthetic substrate, 4-nitro-1,2-benzenediol mono(hydrogen sulfate), and a copper capture reaction. A small amount of Hatchett's brown (cupric ferrocyanide, Cu2Fe(CN)6-7 H2O) formed at the subcellular sites of copper capture is then utilized as a heterogeneous catalyst to effect the oxidative polymerization of 3,3'-diaminobenzidine which results in the formation of an insoluble, highly colored osmiophilic indamine polymer at the sites of enzymatic activity. The reaction product even at this stage prior to osmication is highly visible. It is readily seen with a light microscope in 50 mum sections of fixed tissues prepared with a mechanical chopper or in 10 micron cryostat sections treated for arylsulfatase activity. Upon osmication, an electron-opaque osmium black is formed which is much less soluble than the products of either the lead or barium capture reactions currently used for the demonstration of arylsulfatase with the electron microscope. The selection of areas of plastic-embedded tissues for ultrathin sectioning is facilitated by the ready visibility of these osmium black end products on 1-2 mum plastic sections which can be studied with the light microscope. This method gives permanent specimens demonstrating arylsulfatases A or B in lysosomes and autophagic vacuoles. In addition, enzyme activity is seen occasionally in the Golgi region or lamellae of certain cells believed to be elaborating sulfated products. In these instances, it may be demonstrating sulfotransferase activity.

Catalase in salivary gland striated and excretory duct cells. I. The distribution of cytoplasmic and particulate catalase and the presence of catalase-positive rods.

Catalase-positive rods of different dimensions, which frequently appeared crystalline by light microscopy, were found to be concentrated along with microbodies and cytoplasmic enzyme in the cells of the striated and extralobular excretory ducts of mouse salivary glands. When an entire mouse submandibular gland and its ducts were excised, fixed, sectioned and incubated for catalase demonstration, the excretory ducts were intensely stained relative to the remainder of the gland. Light microscopic examination of the stained ductal cells revealed particulate catalase in the form of rods and microbodies as well as reactivity due to non-particulate cytoplasmic enzyme. The cytoplasmic enzyme activity was less intense in some ductal epithelial cells (light cells) which were interspersed in mosaic arrangement among those more intensely stained (dark cells). The rods were somewhat more common in the light cells. Although the rods lack a symmetrical definitive crystal habit, their gross conformation and periodic substructure are reminiscent of crystalline catalase. No rods and relatively few peroxisomes were observed in excretory duct cells of germ-free mice although cytoplasmic catalase was abundant. These observations suggest that the catalase in salivary gland duct cells could be related in some way to the protection of the gland or the oral cavity or both against micro-organisms. Alternatively, the enzyme could be involved in the non-thyroidal biosynthesis of iodinated tyrosine derivatives.

The synthesis of megatubes: new dimensions in carbon materials.

Extremely large carbon tubes, some exceeding 5 microm in diameter, were produced with both laser and electric arc techniques using graphite, a transition metal catalyst, and a reactive third-body gas. We have named these structures carbon megatubes. They are the first carbonaceous tubes large enough to observe using optical microscopy. We also report the synthesis of what we believe to be the first self-assembled branched nanotubes. In addition to their extreme diameters and unique morphologies, X-ray photoelectron spectroscopy has shown that these tubes also contain a significant amount of nitrogen atom incorporation into the graphite lattice. Subsequently, these nitrogen functionalities were shown to interact with rhenium pentacarbonyl bromide and serve as anchor points to tether molecules to the surface of the tubules.