A Method for Visualizing the Acrosome by Light Microscopy

A silver staining technique applied to squash preparations of material previously fixed in 3:1 ethanol: acetic acid produces differential staining of the acrosomal region of spermatids during spermiogenesis in orthopteroid species. The method includes treatment with saline sodium citrate solution for 15 min at 60 C, and staining with 50% aqueous silver nitrate adjusted to pH 2.9 with formic acid.     

Evidence from studies on segregated nucleoli that nucleolar silver staining proteins C23 and B23 are in the fibrillar component

Several procedures for the silver staining of nucleoli have been evaluated at the electron microscopic level to determine optimal conditions for ultrastructural preservation and staining specificity. The present study shows that a brief fixation with 1% buffered formaldehyde followed by methanol: acetic acid (3 : 1) fixation yielded optimal preservation and silver staining of nucleoli. Using this procedure for electron microscopic studies of interphase nucleoli, it was found that the punctate silver grains observed by light microscopy were composed of fine silver granules, of approx. 100 Å diameter, organized in discrete clusters. In similar studies on adriamycin-induced segregated nucleoli, it was observed that the silver staining reaction was mainly limited to the fibrillar portion of the nucleolus. Accordingly, nucleolar proteins C23 and B23, found earlier to be the major silver binding proteins of the nucleolus, are mainly concentrated in the fibrillar nucleolar component.     

高碘酸-硝酸银染色法鉴定糖蛋白

对传统的糖蛋白染色方法(高碘酸-Schiff法)进行了改进。蛋白质的氧化采用高碘酸法,染色时采用硝酸银染色法。此方法灵敏度是高碘酸-Schiff法的100倍,而且比高碘酸-Schiff法节省16~18h。     

An Improved Silver Stain for Developing Nervous Tissue

A reduced silver technique using physical development to stain embryonic nervous tissue is described. Brains are fixed in Bodian's fixative. Paraffin sections are pretreated with 1% chromic acid or 5% formol. They are impregnated with 0.01% silver nitrate dissolved in 0.1 M boric acid/sodium tetraborate buffer of pH 8 or with silver proteinate. Finally they are developed in a special physical developer which contains 0.1% silver nitrate, 0.01-0.l% formol as developed agent, 25% sodium carbonate to buffer the solution at pH 10.3, 0.1% ammonium nitrate to prevent precipitation of silver hydroxide, and 5% tungstosilicic acid as a protective colloid. The development takes several minutes in this solution, thus the intensity of staining can be controlled easily. The method yields uniform, complete and reproducible staining of axons at all developmental stages of the nervous tissue and is easy to handle.     

An improved silver stain for developing nervous tissue.

A reduced silver technique using physical development to stain embryonic nervous tissue is described. Brains are fixed in Bodian's fixative. Paraffin sections are pretreated with 1% chromic acid or 5% formol. They are impregnated with 0.01% silver nitrate dissolved in 0.1 M boric acid/sodium tetraborate buffer of pH 8 or with silver proteinate. Finally they are developed in a special physical developer which contains 0.1% silver nitrate, 0.01-0.1% formol as reducing agent, 2.5% sodium carbonate to buffer the solution at pH 10.3, 0.1% ammonium nitrate to prevent precipitation of silver hydroxide, and 5% tungstosilicic acid as a protective colloid. The development takes several minutes in this solution, thus the intensity of staining can be controlled easily. The method yields uniform, complete and reproducible staining of axons at all developmental stages of the nervous tissue and is easy to handle.     

Ultrastructural localization of carbohydrates on thin sections of Staphylococcus aureus with silver methenamine and wheat germ agglutinin-gold complex.

Postembedding staining of intracellular carbohydrates on thin sections of Staphylococcus aureus was studied by the silver methenamine and the wheat germ agglutinin-gold techniques. Staining of silver grains was observed on both the cell wall and the cross wall. The staining was interpreted to be due to teichoic acid. Labeling by wheat germ agglutinin-gold particles was observed on both the cell wall and the cross wall, and the staining pattern resembled that of silver methenamine staining. Therefore, the labeling was considered to be due to N-acetylglucosamine of teichoic acid. The combination of two types of cytochemical techniques was useful to localize and characterize the carbohydrates of the bacterial cell.     

Experimental studies of mechanisms involved in methods demonstrating axonal and terminal degeneration

Factors influencing the consistency and specificity of the staining of neuronal degeneration products were studied in brain sections by varying systematically the composition of solutions used in the steps which are common to the degeneration methods. The formation of nuclei of metallic silver was determined either by physical development of 110Ag, after dissolving reducible silver by acetic acid. In degenerating axons metallic silver nucleic are formed by their own reducing groups in the first (acid) and in the second (alkaline) impregnating bath. The first impregnation turned out to be sufficient to produce complete staining of degenerating axons. The reducing capacity of normal axons and myelin can be suppressed by oxidation or by lowering the pH of the impregnating solution. Degenerating axon terminals are not able to reduce silver ions in either of the impregnating baths. Rather, the metallic silver nuclei initiating their staining are formed in the Nauta reducer by interaction of its reducing agent (formol) with silver ions which had been trapped in the tissue during the impregnation. Thus the nuclei are enlarged to microscopic visibility by a nonstandardized physical developer coming about from the Nauta reducer and the silver ions transferred with the sections. In this reaction catalytic sites in degenerating terminals as well as ammonium ions and the alkali reserve of the tissue play an important role. On the basis of the present results it was possible to stabilize the conditions for staining degenerating axons and degenerating axons terminals in two separate staining procedures detailed in following papers.     

Cytochemistry of the chromatin replication band in hypotrichous ciliated protozoa staining with silver and thiol-specific coumarin maleimide

A modification of the silver-staining techniques for nucleolar organizing regions (NORs) was used to stain selectively the macronuclear replication bands (RBs) and nucleoli in hypotrichous ciliated protozoa (Euplotes, Stylonychia, and Oxytricha). Silver staining of both types of structures was trypsin-sensitive and DNase I-insensitive, suggesting the involvement of proteins. Silver-staining proteins in the RB were differentially extracted with acid, without any decrease in nucleolar staining. Triton-acid-urea gel electrophoresis of an acid extract of Euplotes macronuclei revealed enhanced silver reaction with a single protein upon selective silver staining. An abundance of thiol groups was also demonstrated in the RBs and nucleoli by the fluorochrome 3-(4-maleimidylphenyl)-7-diethylamino-4-methyl coumarin (coumarin maleimide). Histochemical studies, including blocking thiols with N-ethyl maleimide (NEM), indicated that thiols were not necessary for silver staining, and that proteins in the RBs and nucleoli reacting with coumarin maleimide were not acid extractable.     

A cytochemical investigation of the host-parasite interface inPisum sativum infected by the downy mildew fungusPeronospora pisi

Summary A cytochemical study involving enzymic digestions, chemical extractions and specific staining methods was made of the host-parasite interface in downy mildew infected pea plants. Enzymic hydrolysis revealed both the penetration and extrahaustorial matrices to have a proteinaceous component, possibly glycoprotein, while the extrahaustorial matrix had cellulose as an additional constituent. Intense silver proteinate staining of both matrices following a prolonged incubation in thiocarbohydrazide indicated the presence of complex carbohydrates. Carbohydrates were confirmed as constituents of both matrices following the complete suppression of silver staining using the aldehyde blocking agents dimedone and sodium borohydride. Both matrices also exhibited a marked affinity for phosphotungstic acid. Following acetylation a complete elimination of phosphotungstate staining resulted, again indicating carbohydrate as a constituent of both matrices. Digestion of the fungal cell wall using an enzyme which hydrolyses -1,3-glucans showed that these carbohydrates are important in its construction. However such enzyme treatment did not affect the structural integrity of either the penetration or extrahaustorial matrix. The extrahaustorial membrane exhibited negligible staining with phosphotungstic-chromic acid treatment, while the host plasmalemma showed a positive but variable staining reaction. A very intense staining reaction characterized the fungal plasmalemma after staining with either phosphotungstic-chromic acid, phosphotungstic acid or silver proteinate.     

The Bielschowsky Staining Technic a Study of the Factors Influencing Its Specificity for Nerve FIBERS

By comparing results obtained with adult mammalian tissue from introducing variables into each separate step in block-staining by the Bielschowsky silver method, the following conclusions were reached:

1. No specific means for inhibiting the staining of connective tissue and still permitting complete staining of nerve fibers was found, but the avoidance of overstaining was very helpful toward such differentiation.
2. Overstaining could be corrected by reducing the concentration of the silver nitrate bath or by adding an excess of ammonia to the ammoniated silver bath.
3. Staining of fine fibers was favored by adding acetic acid to the formaldehyde used for fixation or by adding pyridin to the silver nitrate bath.
4. Addition of protein-precipitating organic acids (trichloracetic or sulfosalicylic) to the fixative was disadvantageous.
5. Prolonged fixation favored an increase in intensity of the stain. Four days' time was sufficient.
6. Extraction of lipids with ammoniated alcohol gave results similar to those obtained after extraction with pyridin, but the stain was lighter.
7. Ammoniated silver carbonate without excess ammonia had an action similar to ammoniated silver hydroxide with excess ammonia.
8. An excess of ammonia in the ammoniated silver solution (Ag 0.1 N) was tolerated, without apparent impairment of nerve-fiber staining, up to 6 M NH₃, altho the use of more than 3 M excess (2 cc. concentrated ammonia water added to 100 cc. of balanced ammoniated silver hydroxide solution) seemed unnecessary.
9. Impregnation with 1.7% (0.1 N) silver nitrate solution was quite satisfactory and variations in the concentrations of this bath suggested that the practical limits of concentrations that would be generally satisfactory lay between 0.3 and 3.0%.
10. The writers' experiences agreed with Agduhr's relative to the advantage of washing in 2.5% acetic acid between the ammoniated silver bath and formaldehyde reduction.

     

纳米金标记-逐步银染法快速检测金黄色葡萄球菌

将纳米金探针应用于目的核酸的检测,具有与PCR相当的灵敏度和特异性.本研究建立了一种可以在微孔板上快速检测金黄色葡萄球菌的纳米金标记-逐步银染法.该方法利用已包被链霉亲和素的微孔板,将PCR扩增的金黄色葡萄球菌nuc基因与生物素探针、纳米金探针形成的三明治杂交结构锚定其上,然后在低温下逐步银染显色,通过酶标仪检测放大的银染信号.这种纳米金标记-逐步银染法可以在显著降低非特异性背景信号的同时放大银染信号,检测金黄色葡萄球菌nuc基因的灵敏度为1 pmol/L,比常温一步银染法的灵敏度提高约102倍. 51例临床标本的检测结果与PCR法一致,与培养生化鉴定法的检测结果之间无显著性差异(P >0.05). 综上所述,本研究成功构建了金黄色葡萄球菌的纳米金标记-逐步银染法,在病原微生物的快速检测领域表现出广阔的发展潜力.     

Silver impregnation of Alzheimer's neurofibrillary changes counterstained for basophilic material and lipofuscin pigment

A method is described in which selective silver staining of Alzheimer's neurofibrillary changes is combined with staining of cell nuclei, Nissl material, and lipofuscin granules. Formalin fixed, paraffin embedded sections of human autopsy tissue are silver stained according to a method proposed by Gallyas. Lipofuscin is stained by crotonaldehyde fuchsin following performic acid oxidation. Nissl substance is visualized by either Darrow red or gallocyanin-chrome alum staining. Architectonic units showing the specific pathology and the neuronal types prone to develop the neurofibrillary changes can be recognized using this technique.     

Silver Impregnation of Alzheimer's Neurofibrillary Changes Counterstained for Basophilic Material and Lipofuscin Pigment

A method is described in which selective silver staining of Alzheimer's neurofibrillary changes is combined with staining of cell nuclei, Nissl material, and lipofuscin granules. Formalin fixed, paraffin embedded sections of human autopsy tissue are silver stained according to a method proposed by Gallyas. Lipofuscin is stained by crotonaldehyde fuchsin following performic acid oxidation. Nissl substance is visualized by either Darrow red or gallocyanin-chrome alum staining. Architectonic units showing the specific pathology and the neuronal types prone to develop the neurofibrillary changes can be recognized using this technique.     

A reliable method for demonstrating axonal degeneration shortly after axotomy

A method has been elaborated by which degenerating axons can be selectively impregnated with silver. Based on reconsideration of the physicochemical mechanisms of the degeneration methods it takes advantage of physical developers over the chemical ones. The staining procedure is applied to frozen sections of brains fixed with formol. It consists of 6 steps: (1) pretreatment with alkaline hydroxylamine, (2) washing in acetic acid, (3) impregnation in silver nitrate in the presence of ferric ions, (4) washing in citric acid, (5) physical development, and (6) washing in acetic acid. By electron microscopy silver precipitates by this method are almost entirely restricted to the cytoplasm of dense, degenerating axons, sparing mitochondria and myelin sheaths. No special expertise is required to achieve reproducible results. Large numbers of sections treated simultaneously, and large sections, can be stained uniformly. Light microscopic criteria are described which help diagnose the source of possible failures. Low background staining allows dark field illumination and television image analysis to be applied. The method works at survival times of only 3 to 5 days after axotomy. Hence, degenerating axons and axon terminals can be stained in alternating sections from the same brain using this method and another being described separately, which, using different conditions, demonstrates degenerating axon terminals.     

Oxalate pretreatment and use of a physical developer render the Kossa method selective and sensitive for calcium

Summary Based on experiments on agarose gels and tissue, a procedure has been developed which greatly improves the sensitivity and the specifity of the Kossa method for demonstrating calcium in tissue. Tissue calcium is immobilized by acetonic oxalic acid, which simultaneously removes the other sorts of anions capable of precipitating silver ions (e.g. phosphate, carbonate). The resulting submicroscopic grains of calcium oxalate are converted first into silver oxalate then into metallic silver by a treatment with silver nitrate followed by an ultra-violet irradiation (Kossa reaction). These submicroscopic metallic silver grains are enlarged up to microscopic visibility by means of physical development, which makes the staining highly sensitive. Costaining of the argyrophil sites in the tissue is totally suppressed by various tricks, which render the silver staining selective for calcium.     

Acid Versus Neutral Formalin Solution as a Neurological Fixative

The fixing action of 10% formalin solution alone and with formic, acetic, propionic, butyric, lactic, monochloracetic, dichloracetic, or trichloracetic acid was studied by means of stains with silver, osmic acid and cresyl violet. The following conclusions were reached:

1. In general, better fixation and staining was obtained with acid than without.

2. Less difference was seen in comparing one acid with another than was expected before the experiments were made.

3. Propionic, butyric, and dichloracetic showed no promise of having practical value.

4. Formic and monochloracetic acids as modifiers gave superior stains with osmic acid, while silver and cresyl violet stains of the same material were about equal to those made from formalin-acetic fixed material.

5. Lactic acid caused somewhat more distortion of tissue elements than the others but was compatible with good staining.

6. Acetic acid was most effective in concentrations of 3 to 5% while the stronger acids such as formic, monochloracetic, lactic and trichloracetic were effective in concentrations of 0.5 to 1%.     

Oxalate pretreatment and use of a physical developer render the Kossa method selective and sensitive for calcium

Based on experiments on agarose gels and tissue, a procedure has been developed which greatly improves the sensitivity and the specifity of the Kossa method for demonstrating calcium in tissue. Tissue calcium is immobilized by acetonic oxalic acid, which simultaneously removes the other sorts of anions capable of precipitating silver ions (e.g. phosphate, carbonate). The resulting submicroscopic grains of calcium oxalate are converted first into silver oxalate then into metallic silver by a treatment with silver nitrate followed by an ultra-violet irradiation (Kossa reaction). These submicroscopic metallic silver grains are enlarged up to microscopic visibility by means of physical development, which makes the staining highly sensitive. Co-staining of the argyrophil sites in the tissue is totally suppressed by various tricks, which render the silver staining selective for calcium.     

Calcium oxalate and the von Kossa method with reference to the influence of citric acid.

Crystals of calcium oxalate in pathological material and artificially precipitated in the absence or presence of citric acid in gelatin models were examined by polarized light and treated with silver nitrate under a variety of conditions. It was found that the intensity of the staining reaction was largely proportional to the strength of the silver solution, and was enhanced in in vitro studies by the presence of citric acid. Staining was also influenced by the crystal form, which was itself related to the absence or presence of citric acid.     

Mass spectrometry‐compatible silver staining of histones resolved on acetic acid‐urea‐Triton PAGE

Acetic acid‐Urea‐Triton (AUT) PAGE is commonly used method to separate histone variants and their post‐translationally modified forms. Coomassie staining is the preferred method for protein visualization; however, its sensitivity is less than that of silver staining. Though silver staining of histones in AUT‐PAGE has been reported, the method is time‐consuming, dependent on prior staining by Amido black and has not been reported suitable for mass spectrometry. Here, we propose ‘SDS‐Silver’ method for rapid, sensitive and mass spectrometry‐compatible staining of histones resolved on AUT‐PAGE.     

A Reliable Method for Demonstrating Axonal Degeneration Shortly After Axotomy

A method has been elaborated by which degenerating axons can be selectively impregnated with silver. Based on a reconsideration of the physicochemical mechanisms of the degeneration methods it takes advantage of physical developers over the chemical ones. The staining procedure is applied to frozen sections of brains fixed with formol. It consists of 6 steps: (1) pretreatment with alkaline hydroxylamine, (2) washing in acetic acid, (3) impregnation in silver nitrate in the presence of ferric ions, (4) washing in citric acid, (5) physical development, and (6) washing in acetic acid. By electron microscopy silver precipitates by this method are almost entirely restricted to the cytoplasm of dense, degenerating axons, sparing mitochondria and myelin sheaths. No special expertise is required to achieve reproducible results. Large numbers of sections treated simultaneously, and large sections, can be stained uniformly. Light microscopic criteria are described which help diagnose the source of possible failures. Low background staining allows dark field illumination and television image analysis to be applied. The method works at survival times of only 3 to 5 days after axotomy. Hence, degenerating axons and axon terminals can be stained in alternating sections from the same brain using this method and another being described separately, which, using different conditions, demonstrates degenerating axon terminals.