A Selective Stain for Renal Basement Membranes

Paraffin sections from human kidneys fixed in Carnoy's fluid No. 2 were treated consecutively with periodic acid-sodium bisulfite and stained with resorcin-fuchsin. Basement membranes were colored black in cross sections, dark gray in tangential sections. Cytoplasm, nuclei, reticulin and collagen fibers remained unstained or were only lightly colored, depending on duration of fixation. Elastic fibers were colored black. In sections counterstained with Kernechtrot, the sharp black coloration of basement membranes and the pink staining of nuclei facilitated the study of glomerular lesions. After counterstaining with Van Gieson's picro-fuchsin, the black basement membranes contrasted well with the red reticulin and collagen fibers. Because this method does not require differentiation, it gave uniform results in the hands of different users. No fading was observed in section stored for 3 yr.     

Tannic Acid-Iron Alum Reaction: Stain of Choice for Macroscopic Sections of Brain to be Embedded in Plastic

As a macroscopic stain for gross brain sections to be embedded in plastic, tannic acid-iron alum is superior to the generally recommended LeMasurier's variation of the Berlin blue technique because of its greater permanency in plastic. However, as originally adopted for use with brain tissue by Mulligan, the intense black staining of gray matter is too dark for plastic embedded specimens. A modification of this method designed to overmme this difficulty is described. Staining procedure: Wash formalin-fixed brain slices overnight in running water. Wash in distilled water, 2 changes, 30 minutes each. Place slices individually in Mulligan's solution at a temperature of 60-65 C for 4 minutes. Rinse in ice water for 10 seconds. Mordant in 0.4% tannic acid in distilled water for 1 minute. Wash in running tap water for 1 minute. Develop in 0.08% ferric ammonium sulfate in distilled water until gray matter is light gray, about 10-15 seconds. Wash in lukewarm running water for 1 hour, then gently hand-rub whitish film from myelinated surfaces. Store briefly in 3% formalin or 25% glycerine if necessary depending on plastic embedding procedure to be followed.     

Tannic Acid as an Electron Microscope Tracer for Permeable Cell Membranes

To recognize damaged cells in preparations for transmission electron microscopy, high molecular weight (1700 MW) tannic acid (1-4%) has been added to glutaraldehyde fixing solutions. During fixation, the tannic acid penetrates only those cells whose plasma membranes were previously damaged. It enhances the electron density of the injured cells, which become clearly distinguishable from the undamaged ones. As a tracer tannic acid shows great advantages over either lanthanum hydroxide, ruthenium red, or horseradish peroxidase. It diffuses evenly throughout the tissue block and is not removed by preparative steps. Furthermore, it is also a good tracer at the light microscope level.     

Phosphotungstic Acid-Chromic Acid as a Selective Electron-Dense Stain for Plasma Membranes of Plant Cells

A mixture consisting of 1% phosphotungstic acid (PTA) in 10% chromic acid (CrO₃) selectively stains the plasma membrane of plant cells. Whole tissue or pelleted cell fractions are prepared for electron microscopy using conventional methods including glutaraldehyde fixation and OsO₄ postfixation, dehydration in acetone and embedding in Epon. To stain the plasma membrane, thin sections are transferred with a plastic loop to the surface of a 1% aqueous solution of periodic acid for 30 min for destaining. Following transfer through 5 distilled water rinses, the sections are exposed to the PTA-CrO₃ mixture for 5 min, rinsed and mounted on grids for viewing with the electron microscope. The selectivity of the stain is retained in homogenates and serves to identify the plant plasma membrane in cell fractions.     

The Bi-Functional Organization of Human Basement Membranes

The current basement membrane (BM) model proposes a single-layered extracellular matrix (ECM) sheet that is predominantly composed of laminins, collagen IVs and proteoglycans. The present data show that BM proteins and their domains are asymmetrically organized providing human BMs with side-specific properties: A) isolated human BMs roll up in a side-specific pattern, with the epithelial side facing outward and the stromal side inward. The rolling is independent of the curvature of the tissue from which the BMs were isolated. B) The epithelial side of BMs is twice as stiff as the stromal side, and C) epithelial cells adhere to the epithelial side of BMs only. Side-selective cell adhesion was also confirmed for BMs from mice and from chick embryos. We propose that the bi-functional organization of BMs is an inherent property of BMs and helps build the basic tissue architecture of metazoans with alternating epithelial and connective tissue layers.     

Stain Technology: Use of Tannic Acid for the Ultrastructural Visualization of Periplasm in Gram-Negative Bacteria

Tannic acid mordanting reveals the periplasm, the area between the outer membrane and the inner membrane of gram-negative bacteria, Rhizobium gp., Escherichia colt and Enterobacter aeregenes, as an electron-dense layer continuous with the inner leaflet of the outer membrane. The method involves 18 hr of tannic acid treatment after fixation in aldehyde prior to osmium tetroxide postfixation, followed by conventional electron microscopy.     

Trypan Blue as a Stain for Fungi

Trypan blue was tested for use in the study of fungi. It was found that it stained the cell wall of all fungi investigated. Two staining solutions were very satisfactory: (1) A quick-staining solution of 0.1-0.5% dye in 45% acetic acid; (2) A slow-staining solution of 0.1-0.5% dye in lactophenol. In both instances, heating the preparations quickened the action.     

A Modification of the Tannic Acid Phosphomolybdic Acid-Dye Stain for Demonstrating Myoepithelial Cells in Formalin Fixed Tissue

A modified tannic acid-phosphomolybdic acid-dye procedure is used for staining myoepithelial cells in formalin fixed surgical and autopsy material. Paraffin section are brought to water, mordanted for 1 hr in Bouin's fixative previously heated to 56 C, cooled while still in Bouin's, rinsed in tap water until sections are colorless, rinsed in distilled water, treated with 5% aqueous tannic acid 5-20 min, rinsed in distilled water 30 sec or less, treated with 1% aqueous phosphomolybdic acid 10-15 min, rinsed 30 sec in distilled water, rinsed in methanol, stained 1 hr in a saturated solution of amido black or phloxine B in 9:l methanol:acetic acid, rinsed in 9:l methanol:acetic acid, dehydrated, cleared and mounted. Myoepithelial cells of sweat, lacrimal, salivary, bronchial, and mammary glands are blue-green with amido black or pink with phloxine B. Fine processes of myoepithelial cells are well delineated. Background staining is minimal and the procedure is highly reproducible.     

Hematoxylin as a Pituitary Stain

The accurate picture of the acidophil granules of the anterior pituitary which is provided by iron hematoxylin can be combined with the differential staining of the basophils by either the periodic acid-Schiff (PAS) or combined aldehyde-fuchsin-PAS procedures. To accomplish this the two stages of the iron hematoxylin technique are separated so that mordanting in iron alum precedes and application of hematoxylin follows the basophil procedures.     

DAPI as a Useful Stain for Nuclear Quantitation

A simple-to-use fluorescent stain, 4′,6-diamidino-2-phenylindole (DAPI), visualizes nuclear DNA in both living and fixed cells. DAPI staining was used to determine the number of nuclei and to assess gross cell morphology. Following light microscopic analyses, the stained cells were processed for electron microscopy. Cells stained with DAPI showed no ultrastructural changes compared to the appearance of cells not stained with DAPI. DAPI staining allows multiple use of cells eliminating the need for duplicate samples.     

Isohematein as a Biological Stain

The possible use of isohematein as a biological stain is considered. Certain characteristics of the dye are discussed in relation to staining technic. A preliminary series of experiments is described. The stomach of the frog, skeletal muscle of the frog, and spinal cord of the cat were used as representative tissues. The dye has greater tinctorial power than hematoxylin (hematein) but it is not so selective for nuclei. The results at hand indicate that the dye may have some value as a differential stain for nerve cell bodies. Fibrillae in smooth muscle cells and cross striatums in skeletal muscle were also brought out.     

Role of Endoplasmic Reticulum in the Formation of Peribacteroid Membranes

The relation between the endoplasmic reticulum and peribacteroid membranes during the development of infected cells of Chinese soybean (Glycine max L. cv. Harvest 11) root nodules by transmission electron microscopy was observed. After the host cells are infected by bacteria, the ultrastructures of the infected cells appear to have many changes, such as that their cytoplasm becomes thicker, the vacuoles decrease in size and organelles rapidly increase in number, among these organelle changes are more obvious than the others. However, changes of endoplasmic reticulum is mostly striking. It is not only increases greatly in number but often swells and forms wider inter-spaces. The swelling of endoplasmic reticulum is especially conspicuous at its ends and often form various vesicles. Sometimes, the front part of the endoplasmic reticulum also forms a gourd-shaped structure, which together with the vesicles usually contain fibrillar material. After they are released from the endoplasmic reticulum to the host cytoplasm, they continuously move towards neighbouring bacteria and close to the peribacteroid membranes. The gourd-shaped structures always locate near but never fuse with the peribacteroid membranes. However, the vesicles can do that and form a kind of papillae, often containing fibrillar material, on the peri bacteroid membranes. These papillae and their fibrillar material gradually disappear whilst the membrane of the vesicle derived from endoplasmic reticulum becomes one part of the peribacteroid membrane by way of fusing with the latter to form a papilla on it.     

DAPI as a Useful Stain for Nuclear Quantitation

A simple-to-use fluorescent stain, 4',6-diamidino-2-phenylindole (DAPI), visualizes nuclear DNA in both living and fixed cells. DAPI staining was used to determine the number of nuclei and to assess gross cell morphology. Following light microscopic analyses, the stained cells were processed for electron microscopy. Cells stained with DAPI showed no ultrastructural changes compared to the appearance of cells not stained with DAPI. DAPI staining allows multiple use of cells eliminating the need for duplicate samples.     

Chlorazol Black E as a Stain for Tension Wood

Sections containing gelatinous fibers were cut at 15 μ from material both fixed and stored in formalin-acetic-alcohol, 5:5:90 (of 70%). These sections were stained 5 min in a 1% aqueous solution of lignin pink (G. T. Gurr), differentiated quickly in water, soaked 5 min in 95% ethyl alcohol, dehydrated in absolute ethyl alcohol and counter stained 5 min with a 1% solution of chlorazol black E (G. T. Gurr) in methyl cellosolve, followed by dehydration in absolute ethyl alcohol, clearing in xylene and mounting in Canada balsam. The gelatinous layer was sharply defined as a dense black zone whilst the remainder of the cell wall stained light pink. The specificity of the technique was superior to that of safranin and light green, and was not easily obscured by overstaining. The technique is particularly useful for locating small zones of gelatinous fibres, and for photomicrographical work.     

Reduced Methylene Blue as a Stain for Crustacean Nerves

Effective in situ staining of crustacean nerves was achieved with leuco methylene blue reduced with either ascorbic acid or sodium hydrosulfite (Na₂S₂O₄). A stock solution of methylene blue, 0.4% (ca. 0.001 M), and the reductants, ascorbic acid or sodium hydrosulfite (0.01 M), were prepared in van Harreveld's crayfish physiological solution. Methylene blue stock solution was mixed with either of the reductants in the approximate ratio of 1:10, v/v, and titrated to the end point. Ascorbic acid reduction is light catalyzed and requires intense illumination during titration. The cleared or leucomethylene blue stock solution is suitable for immediate use as a working nerve stain. With either reductant, the working solution oxidizes on standing in air, but can be titrated repeatedly without loss of staining properties. Dissected nerve trunks or tissue were immersed in the working stain for 20 min at room temperature and the staining process observed until suitable contrast developed. Excess dye was decanted and the tissues flooded with crayfish physiological solution. Contrast could sometimes be enhanced by flooding the stained area with 1% hydrogen peroxide in van Harreveld's solution. When permanent mounts were prepared, tissues were dehydrated with tertiary butyl alcohol in preference to ethyl alcohol series. For anatomical and neurophysiological studies of nerve distribution in crustaceans, the alternative use of either ascorbic acid or sodium hydrosulfite, as reductants for methylene blue, was preferable to the more complicated rongalit-technique and characterization of neural elements was fully as satisfactory.