A Cytochemical Technique for Demonstration of Lipids,Polysaccharides and Protein Bodies in Thick Resin Sections

An effective cytochemical technique for the simultaneous demonstration of lipids, polysaccharides and protein bodies in the same section from the tissue embedded in Epon 812 is described. Thick sections of peanut cotyledon are used for a typical sample according to the following procelures. Firstly, PAS reaction: (1) Oxidize sections in 0.5% periodic acid in 0.3% nitric acid for 10 min, (2) Wash in running water for 1–2 min and then pass through distilled water, (3) Stain in Schiff's reagent for 30 min, (4) Wash in sodium metabisulfite 3 times, 2 min for each time, (5) Wash in running water for 5 min and then pass through distilled water. Secondly, Sudan black B staining: (1) Rinse section in 70% ethanol for 1-2 min, (2) Stain in fresh 1% Sudan black B in 70% ethanol for 30–60 min at 40–60℃, (3)Rinse in 70% ethanol for 1 min and then in distilled water. Thirdly, Coomassie brilliant blue R staining: (1) Rinse sections in 7% acetic acid for 1–2 min, (2) Stain in I% Coomassie brilliant blue R in 7% acetic acid for 20 min at 60℃, (3) Differentiate in 0.1% acetic acid for I min, (4) Rinse in lunning water for 5 min and then pass through distilled water, (5) Dry at room temperature or in oven, 40℃. The dry sections mount in glycerin-gelatin. After the above three step staining, the three main compounds of the cell can be stained simultaneously. Starch grains and cellulose cell wall take cherry red colour, lipids appear in black, protein bodies are blue. The sealed slides can be kept permanently.     

Improvements In The Paraffin Method

Dilute hydrofluoric acid alone and in conjunction with glycerin and ethyl alcohol was employed successfully to soften various types of refractory plant materials embedded in paraffin. Serial sections were cut at 6-8 μ and no appreciable deleterious effects on cell walls, cell contents, or staining procedures occurred. “Tannins” and “phlobaphene compounds” can be removed from tissues softened by this method by treating the sections for 12-48 hours with an aqueous solution of chromic acid, potassium bichromate and glacial acetic acid prepared according to the formula given by Johansen (1940).     

A Trichrome Stain for Insect Material

Deparaffinized insect sections are brought down to water and overstained in a 0.1% solution of azocarmine G in 1% acetic acid. They are then destained in a saturated solution of orange G until the azocarmine G is removed from the endocuticle and the latter is colored pale yellow. After washing, the sections are transferred to a 5.0 % solution of phosphotungstic acid in water for 3 min. They are then rinsed in distilled water and stained in a 0.1% solution of methyl green in 1% acetic acid until the endocuticle is green. Differentiation is done in 2 changes of 95% alcohol. The sections are then dehydrated either in absolute alcohol or dioxane, cleared in a mixture of “camsal”, eucalyptol, dioxane, and paraldehyde (1:2:2:1), and mounted in Mohr and Wehrle's medium, a mountant of the Euparal type.     

The Phloem of Nelumbo nucifera Gaertn

In common with other aquatic angiosperms, Nelumbo nucifera Gaertn.has a relatively strongly developed phloem tissue. The vascularsystem consists of discrete collateral bundles in which no cambiumdevelops and the phloem and xylem are separated by a narrowlayer of parenchyma cells. The phloem consists of sieve elements,companion cells, and phloem parenchyma cells. The sieve elementshave transverse end walls with simple sieve plates. The cellsattain considerable width in the late phloem (metaphloem). Thecompanion cells are in vertical strands. In the early phloem(protophloem) of large bundles the sieve tubes and companioncells are eventually obliterated. The parenchyma cells alsoform vertical strands which may contain tannin cells. Some parenchymacells and companion cells are binucleate. The sieve elementsshow ultrastructural features common for these cells in dicotyledons.At maturity, they lack nuclei, ribosomes, and tonoplasts, butretain a plasmalemma, mitochondria, and plastids. The latterare poorly differentiated and form starch. The endoplasmic reticulumis in part stacked, in part it forms a network next to the plasmalemma.The P-protein occurs in two forms. One consists of tubules notassembled in any specific type of array. The other, possiblycomposed of much extended tubules, is assembled in crystallineaggregates which are retained as such in mature cells. The sieveplate pores are lined with callose and plasmalemma. The lateralwalls are relatively thin and the nacreous layer varies in degreeof distinctness.     

ONTOGENY AND STRUCTURE OF THE SECONDARY PHLOEM IN EPHEDRA

The secondary phloem in Ephedra is atypical of the gymnosperms in general and exhibits several angiosperm-like characteristics. The ray system of the conducting phloem consists of parenchymatous, multiseriate rays. The axial system contains parenchyma cells, sieve cells, and unusual albuminous cells reminiscent of the specialized parenchyma cells found in some angiosperms. These cell types may intergrade with each other. P-protein in the developing sieve element appears early in the form of a single, ovoid slime body. Later, smaller slime bodies appear and quickly disperse. In the mature sieve element the single, ovoid slime body is lost, and P-protein is then evident in the form of a parietal cylinder, thread-like strands, amorphose globules, or a slime plug. Necrotic-appearing nuclei are commonly found in mature sieve cells.     

An Eosin-Fast Green-Naphthol Yellow Mixture for Differential Staining of Cytologic Components in Mammalian Permatozoa

Air-dried smears of saline suspensions of mammalian spermatozoa were stained for 10-60 min at room temperature in a mixture of eosin Y, fast green FCF, and naphthol yellow S (0.1% w/v, each dye) in 1.0% aqueous acetic acid. They were then blotted, rinsed in 1.0% acetic acid until no more dye was removed (0.5-1.5 min), blotted and allowed to dry completely, rinsed in xylene and mounted in synthetic resin. In all species examined except the rat, acrosomes were stained greenish blue to bluish green or blue depending on their thickness; in the rat, they displayed more affinity for eosin and were reddish. In all species, spermatozoan nuclei were strongly stained by naphthol yellow. In intact sperm heads, postnuclear cap had a yellowish green appearance. Midpieces of rodent spermatozoa, especially those of younger gametes, were stained bright red while those of ejaculated bull and rabbit spermatozoa were stained blue-green. Cytoplasmic droplets associated with rodent spermatozoa were consistently stained a dark green. In all species, the remainder of the flagellum generally was stained bluish to blue-black. Deductions concerning the morphology of spermatozoa derived from the staining experiments were verified by means of scanning electron microscopy. Because it provides reliable information concerning the morphology of the various components of mammalian spermatozoa, this simple staining procedure should prove applicable to a wide variety of studies involving the morphology of intact spermatozoa     

Sieve elements rapidly develop ‘nacreous walls’ following injury − a common wounding response?

Thick glistening cell walls occur in sieve tubes of all major land plant taxa. Historically, these ‘nacreous walls’ have been considered a diagnostic feature of sieve elements; they represent a conundrum, though, in the context of the widely accepted pressure–flow theory as they severely constrict sieve tubes. We employed the cucurbit Gerrardanthus macrorhizus as a model to study nacreous walls in sieve elements by standard and in situ confocal microscopy and electron microscopy, focusing on changes in functional sieve tubes that occur when prepared for microscopic observation. Over 90% of sieve elements in tissue sections processed for microscopy by standard methods exhibit nacreous walls. Sieve elements in whole, live plants that were actively transporting as shown by phloem‐mobile tracers, lacked nacreous walls and exhibited open lumina of circular cross‐sections instead, an appropriate structure for Münch‐type mass flow of the cell contents. Puncturing of transporting sieve elements with micropipettes triggered the rapid (<1 min) development of nacreous walls that occluded the cell lumen almost completely. We conclude that nacreous walls are preparation artefacts rather than structural features of transporting sieve elements. Nacreous walls in land plants resemble the reversibly swellable walls found in various algae, suggesting that they may function in turgor buffering, the amelioration of osmotic stress, wounding‐induced sieve tube occlusion, and possibly local defence responses of the phloem.     

A Simplified Nissl Stain with Thionin

Recently two articles on the use of thionin as a cell stain for neurological materials have appeared. One utilizes a solution buffered in the acid range³; the other uses a “steaming” staining solution⁴. For some time we have been using thionin as a routine stain after either formalin or alcohol fixation and our method is so simple and has given such satisfactory results with a variety of brands of thionin that it seemed to be worthy of more general use. Briefly the method consists of placing the celloidin sections in a 0.05% solution of Li₂CO₃ (the percentage of Li₂CO₃ is non-critical) for about 5 minutes and then grossly overstaining in a 0.25% solution of thionin in a 0.05% solution of Li₂CO₃ in distilled water. The overstaining is necessary if all the stain is to be removed from the background. The sections are then passed through distilled water, 70 or 80% alcohol, two changes of butyl alcohol, two changes of xylene and mounted with Clarite. For most material, split mica cover-slips are quite satisfactory. The time of differentiation may be considerably lessened by the use of the differentiator recommended by Neumann (1942) except that we find the chloroform superfluous and transfer the sections to the aniline solution from 95% alcohol. Less fading seems to occur if the aniline differentiator is followed by a saturated solution of Li₂CO₃ in 95% alcohol.     

Conjugates of Chitinase with Fluorescein Isothiocyanate or Lissamine Rhodamine as Specific Stains for Chitin In Sztu

The fluorescent chitinase technique is based on the specific affinity of the enzyme for its substrate and applicable when an enzyme can be coupled with a fluorescent dye. Fluorescent chitinase specifically stained chitinous structures in several fungi and an insect, but failed to stain other polysaccharides in bacterial and algal cell walls. Freezing-microtome sections of Drosophila and fungal mycelia 6 μ thick were fixed in acetone for 5 min, then stained and mounted in fluorescent chitinase. Staining of smears of unsectioned fungal material required 5 min in absolute acetone, 5 min in 95% ethanol-1 N aqueous acetic acid (1:1), 10 min in 0.2 M phosphate buffer, PH 5.7, 1 sec in enzyme-dye conjugate, and 10 min in carbonate-bicarbonate buffer (0.2 M, pH 10.7, for chitinase-FITC; pH 7.6, for chitinase-LRBC). Preparations are viewed microscopically with ultraviolet light.     

Differentiated Staining of Osmium Tetroxide-Fixed, Vestopal-w-Embedded Tissue in thin Sections

Tissues were fixed at 20° C for 1 hr in 1% OsO₄, buffered at pH 7.4 with veronal-acetate (Palade's fixative), soaked 5 min in the same buffer without OsO₄, then dehydrated in buffer-acetone mixtures of 30, 50, 75 and 90% acetone content, and finally in anhydrous acetone. Infiltration was accomplished through Vestopal-W-acetone mixtures of 1:3, 1:1, 3:1 to undiluted Vestopal. After polymerisation at 60° C for 24 hr, 1-2 μ sections were cut, dried on slides without adhesive, and stained by any of the following methods. (1) Mayer's acid hemalum: Flood the slides with the staining solution and allow to stand at 20°C for 2-3 hr while the water of the solution evaporates; wash in distilled water, 2 min; differentiate in 1% HCl; rinse 1-2 sec in 10% NH,OH. (2) Iron-trioxyhematein (of Hansen): Apply the staining solution as in method 1; wash 3-5 min in 5% acetic acid; restain for 1-12 hr by flooding with a mixture consisting of staining solution, 2 parts, and 1 part of a 1:1 mixture of 2% acetic acid and 2% H₂SO₄ (observe under microscope for staining intensity); wash 2 min in distilled water and 1 hr in tap water. (3) Iron-hematoxylin (Heidenhain): Mordant 6 hr in 2.5% iron-alum solution; wash 1 min in distilled water; stain in 1% or 0.5% ripened hematoxylin for 3-12 br; differentiate 8 min in 2.5%, and 15 min in 1% iron-alum solution; wash 1 hr in tap water. (4) Aceto-carmine (Schneider): Stain 12-24 hr; wash 0.5-1.0 min in distilled water. (5) Picrofuchsin: Stain 24-48 hr in 1% acid fuchsin dissolved in saturated aqueous picric acid; differentiate for only 1-2 sec in 96% ethanol. (6) Modified Giemsa: Mix 640 ml of a solution of 9.08 gm KH₂PO₄ in 1000 ml of distilled water and 360 ml of a solution of 11.88 gm Na₂HPO₄-2H₂O in 1000 ml of distilled water. Soak sections in this buffer, 12 hr. Dissolve 1.0 gm of azur I in 125 ml of boiling distilled water; add 0.5 gm of methylene blue; filter and add hot distilled water until a volume of 250 ml is reached (solution “AM”). Dissolve 1.5 gm of eosin, yellowish, in 250 ml of hot distilled water; filter (solution “E”). Mix 1.5 ml of “AM” in 100 ml of buffer with 3 ml of “E” in 100 ml of buffer. Stain 12-24 hr. Differentiate 3 sec in 25 ml methyl benzoate in 75 ml dioxane; 3 sec in 35 ml methyl benzoate in 65 ml acetone; 3 sec in 30 ml acetone in 70 ml methyl benzoate; and 3 sec in 5 ml acetone in 95 ml methyl benzoate. Dehydrated sections may be covered in a neutral synthetic resin (Caedax was used).     

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 sections 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 9:1 methanol:acetic acid, rinsed in 9:1 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.     

Differential staining of nerve cells and fibres for sections of paraffin-embedded material in mammalian central nervous system

A differential staining method is described of myelinated fibres and nerve cell bodies applicable to sections of mammalian, including human, central nervous system specimens embedded in paraffin wax. Experimental and human necropsy material fixed in acetic paraformaldehyde in phosphate buffer was used. Sections of 15–20 m in thickness were obtained, attached to slides, deparaffinized and hydrated. After hydration, sections are oxidized (30 s) in 2% potassium permanganate, bleached (1 min) in 5% oxalic acid and rinsed in distilled water. Staining is for 2–5 h in the following solution: 0.06% thionin, 1% formaldehyde, 10% acetic acid in distilled water. Sections are subsequently washed in distilled water, dehydrated through 96% and absolute ethanol, cleared in eucalyptol and mounted in Eukitt. Using the method described in the present paper, a differential coloration of myelin and neurons is obtained. Myelinated fibres appear red, whereas nerve cell bodies and glial nuclei are stained blue. This procedure provides a high contrast between myelin and cells suitable for observation and photography of sections. Simultaneous and differential coloration of both myelin and cells is easily and directly obtained with constant and homogeneous results.     

Quantitative Estimation of Phloem Regeneration in Coleus Internodes

Phloem regeneration in Coleus internodes, earlier wounded so that one or more phloem bundles were severed, is estimated quantitatively by microscopic examination of permanent slides prepared in the following way: The wounded internode is removed from the plant after a given regeneration period, is fixed in Craf III for 24 hr and is transferred to 85% lactic acid for 12-24 hr. While still in lactic acid, a “strip”, which is composed of the phloem and all tissues peripheral to it in the internode, is peeled from the internode, leaving only the xylem-pith cylinder. The strip is stained for 6-12 hr in 0.1% aniline blue in 85% lactic acid, then is transferred to 60% alcohol containing 0.5% HCI. While in the latter solution, the epidermis, scar tissue, and most of the cortical tissue is carefully dissected from the strip while it is observed in a dissecting microscope. The strip is restained for an hour or more and is passed through two 5-10 min changes each of acidified 60% alcohol, absolute alcohol, and xylene, and is then mounted on a glass slide in damar-xylene. Counts of regenerated, interfascicular phloem strands, governed by a counting convention, which were shown to bear a fairly constant relationship to the actual number of regenerated sieve tube members, are made while examining under low and high power magnifications. This method is presently being used to study the physiology of phloem differentiation and its regulation in Coleus.     

Staining Reticulin with Gold

This bromine-iodine-gold chloride-reduction sequence stains reticulin in formalin-fixed paraffin sections without risk of sections becoming detached. After hydration, sections are exposed to 0.2% bromine water containing 0.01% KBr for 1 hr, then rinsed and placed for 5 min in a solution consisting of KI, 2 gm; iodine crystals, 1 gm; and distilled water, 100 ml. After this the sections are well washed in distilled water, immersed for 5 min in 1% w/v aqueous solution of chloro-auric acid, again rinsed in distilled water, and the gold is reduced by placing in freshly made 3% H₂O₂ for 2-4 hr at 37 C, or in 2% oxalic acid for 1-3 hr at the same temperature.     

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.     

Lactic Acid Clearing and Fluorescent Staining for Demonstration of Sieve Tubes

Sieve tubes of the phloem in cleared plant parts can be located by means of a staining reaction specific for callose. The plant part is decolourized in 1:3 glacial acetic acid-95% ethanol and cleared in hot 85% lactic acid at 98-100 C. Callose is not dissolved by this treatment and is then stained with 0.01% analine blue in 0.07 M phosphate buffer, pH 7.5, and observed by fluorescence microscopy. A sieve tube is recognized by the bright yellow fluorescence of the callose on its sieve plates. In most tissues, a natural light yellow fluorescence of the parenchyma cells is evident after the clearing step. This intensifies upon staining with analine blue and tends to make the tissue opaque, but it can be minimized by quick-killing of the tissue before commencing the decolourization. The procedure gives best results when applied to young tissues in which interference from the natural yellow fluorescence of lignified cells such as xylem elements and phloem fibers is minimal. Callose plugs in pollen tubes were also shown in intact, cleared styles.     

A Safranin-Fast Green Stain for the Differentiation of the Nuclei of Rumen Protozoa

Mounted, deparaffinized sections of rumen ciliates were hydrolyzed in 1 N HCl for 5 min at 60 C and washed in several changes of distilled water. They were then stained in a mixture of equal volumes of 0.1% aqueous solutions of safranin O and fast green FCF. The sections were washed in 3 changes of distilled water for 2 min each, blotted, dehydrated in 2 changes of absolute alcohol of 1 min each, and mounted from xylene. Several fixatives were employed but only Zenker's gave consistent results. The micronuclei showed a densely stained basophilic “core” surrounded by a peripheral zone of acidophilia, whereas the macronuclei were completely basophilic. Similar results were obtained when RNA was extracted with cold perchloric acid. In conjunction with deoxyribonuclease treatment, the Feulgen reaction indicated that the DNA of the micronucleus is concentrated in the basophilic core while the macronucleus shows a uniform distribution of its chromatin. The safranin-fast green procedure has been used for the structural characterization of rumen protozoa and in studies concerning changes in their nuclear morphology.     

A Method for Staining Pollen Tubes in Pistil

A quadruple staining procedure has been developed for staining pollen tubes in pistil. The staining mixture is made by adding the following in the order given: lactic acid, 80 ml; 1% aqueous malachite green, 4 ml; 1% aqueous acid fuchsia, 6 ml; 1% aqueous aniline blue, 4 ml; 1 % orange G in 50% alcohol, 2 ml; and chloral hydrate, 5 g. Pistils are fixed for 6 hr in modified Carnoy's fluid (absolute alcohol:chloroform:glacial acetic acid 6:4:1), hydrated in descending alcohols, transferred to stain and held there for 24 hr at 45±2 C They were then transferred to a clearing and softening fluid containing 78 ml lactic acid, 10 g phenol, 10 g chloral hydrate and 2 ml 1% orange G. The pistils were held there for 24 hr at 45±2 C, hydrolyzed in the clearing and softening fluid at 58±1 C for SO min, then stored in lactic acid for later use or immediately mounted in a drop of medium containing equal parts of lactic acid and glycerol for examination. Pollen tubes are stained dark blue to bluish red and stylar tissue light green to light greenish blue. This stain permits pollen tubes to be traced even up to their entry into the micropyle.     

A method for staining pollen tubes in pistil

A quadruple staining procedure has been developed for staining pollen tubes in pistil. The staining mixture is made by adding the following in the order given: lactic acid, 80 ml; 1% aqueous malachite green, 4 ml; 1% aqueous acid fuchsin, 6 ml; 1% aqueous aniline blue, 4 ml; 1% orange G in 50% alcohol, 2 ml; and chloral hydrate, 5 g. Pistils are fixed for 6 hr in modified Carnoy's fluid (absolute alcohol:chloroform:glacial acetic acid 6:4:1), hydrated in descending alcohols, transferred to stain and held there for 24 hr at 45 +/- 2 C. They were then transferred to a clearing and softening fluid containing 78 ml lactic acid, 10 g phenol, 10 g chloral hydrate and 2 ml 1% orange G. The pistils were held there for 24 hr at 45 +/- 2 C, hydrolyzed in the clearing and softening fluid at 58 +/- 1 C for 30 min, then stored in lactic acid for later use or immediately mounted in a drop of medium containing equal parts of lactic acid and glycerol for examination. Pollen tubes are stained dark blue to bluish red and stylar tissue light green to light greenish blue. This stain permits pollen tubes to be traced even up to their entry into the micropyle.     

Electron Microscopic Observations of the Structure of Sieve-connexions in the Phloem of Angiosperms and Gymnosperms

The sieve elements of Pinus silvestris L., Sorbus aucupariaL., Vitis vinifera L., and Cucurbita pepo L. have been examinedelectron microscopically in ultra-thin section, and the structuresof the corresponding sieve areas or sieve plates have been describedand compared. In Pinus the sieve areas contain groups of connectingstrands which enter the wall from the lumen side as individualsbut coalesce within it in the median cavity. This cavity hasdeveloped by wall breakdown in the middle lamella and primarywall region and corresponds to the median nodule visible undera light microscope. Neither in this nor in the other speciesobserved is there any visible closing membrane. Structural differences between the four species are shown tosuggest that the major evolutionary trend in the evolution ofspecialized conducting strands has been the enlargement of theconnecting strands from groups of small separate strands toa smaller number of larger strands as the median cavity becomesenlarged to form a canal through the wall. The connecting strands appear invariably to be dense, highlyosmiophilic and continuous with the cytoplasmic surface of thecell. No signs of micropores or of other tubular structure inthe strands have been found. The structures thus revealed aremore nearly compatible with active transport of materials acrossthe sieve plate than they are with any purely physical mechanism.It is suggested that they are incompatible with any mass flowhypothesis.