ULTRASTRUCTURAL LOCALIZATION OF ARGYROPHILIC PROTEINS IN NUCLEOLI OF ZEA MAYS BY TWO SILVER STAINING TECHNIQUES

Ag staining was applied on interphasic nucleoli of Zea mays root cells 120h after germination. We applied the two-step Ag-NOR staining technique to small root fragments and the one-step technique to sections of Lowicryl-embedded tissue. The small-sized silver grains were mainly located in the dense fibrillar component (DFC). The unstained fibrillar centers (FCs) differed in their proteinic contents from the NOR (which is positively silver stained) and were not the interphasic NOR counterpart.     

Simultaneous visualization of rDNA clusters and the nucleolus by combining fluorescence in situ hybridization and silver staining

We designed two procedures to visualize simultaneously clusters of ribosomal RNA genes (rDNA) and the nucleolus in plant cells. The procedures combine fluorescence in situ hybridization (FISH) to visualize the rDNA clusters and silver staining to observe the nucleolus. When FISH is followed by silver staining, many minute FISH signals are localized in the nucleolus, and several large FISH signals are seen on the nucleolar periphery. When FISH was applied to the specimens with silver nitrate staining, large FISH signals were visualized in the nucleoplasm associated with the nucleolar periphery, but no signals were seen in the nucleoli. Thus, the two combinations of FISH and silver staining provided different details regarding the arrangement of rDNA clusters in the nucleolus of plant cells.     

Simultaneous visualization of rDNA clusters and the nucleolus by combining fluorescence in situ hybridization and silver staining

We designed two procedures to visualize simultaneously clusters of ribosomal RNA genes (rDNA) and the nucleolus in plant cells. The procedures combine fluorescence in situ hybridization (FISH) to visualize the rDNA clusters and silver staining to observe the nucleolus. When FISH is followed by silver staining, many minute FISH signals are localized in the nucleolus, and several large FISH signals are seen on the nucleolar periphery. When FISH was applied to the specimens with silver nitrate staining, large FISH signals were visualized in the nucleoplasm associated with the nucleolar periphery, but no signals were seen in the nucleoli. Thus, the two combinations of FISH and silver staining provided different details regarding the arrangement of rDNA clusters in the nucleolus of plant cells.     

Staining Plant Cells with Silver. III. The Mechanism

Silver does not stain all cytological structures with the same intensity. The chemical basis for differential silver staining is unclear, but differences in protein side groups available to react with silver are likely involved. These include amine, carboxyl, phosphate, sulfhydryl and hydroxyl moieties. Here we report an investigation of the chemical groups that could be involved in salt-nylon silver staining of onion root tip squashes. Based on the results, we conclude that SN silver staining primarily depends on the presence of tyrosine hydroxyl groups, and we propose a mechanism for staining.     

Analysis of nucleolus organizer regions (NORs) in mitotic and polytene chromosomes ofPhaseolus coccineus by silver staining and Giemsa C-banding

Chromosomes with active nucleolus organizer regions (NORs) were visualized in root tip metaphases ofPhaseolus coccineus using the silver staining technique. A mean number of 5.5 Ag-NORs per cell was observed in 54 cells from eight plants. In the endopolyploid nuclei of the suspensor the silver technique did not demonstrate the reported specificity for nucleolus organizer activity, because there was usually pale staining of nucleoli and preferential staining of heterochromatic regions in the polytene chromosomes including pericentromeric material, telomeres and NORs. The mean number of NORs per nucleolus as detected by this method was 5.8 (28 nucleoli analysed). Using a modified preparation technique, giant chromosomes stained pale, but nucleoli of suspensor cells displayed darkly silver staining internal domains, each of which originating from a nucleolus organizer.—Giemsa C-banding of endopolyploid suspensor nuclei revealed C-positive nucleolus organizers with darkly staining intranucleolar fibrils. The latter were frequently involved in inter-NOR associations. In 34 nucleoli analysed, the mean number of Giemsa C-positive NORs per nucleolus was 6.0.Dedicated to Professor Dr.Lothar Geitler on the occasion of his 80th birthday.     

A silver staining method for single-cell gel assay.

The single-cell gel assay (comet assay) is a very useful microelectrophoretic technique for evaluation of DNA damage and repair in individual cells. Usually, the comets are visualized and evaluated with fluorescent DNA stains. This staining requires specific equipment (e.g., a high-quality fluorescence microscope), the slides must be analyzed immediately, and they cannot be stored for long periods of time. Here we describe, using human lymphocytes, some modifications of the silver staining for comets that significantly increase the sensitivity/reproducibility of the assay. This silver staining was compared with fluorescence staining and commercial silver stains. (J Histochem Cytochem 49:1183-1186, 2001)     

Microwave irradiation improvements in the silver staining of the nucleolar organizer (Ag-NOR) technique

The well-know technique of silver staining of the nucleolar organizer (Ag-NOR) is improved in contrast, selectivity and speed when performed with microwave irradiation. The Ag-NOR technique is a very useful tool for studies on the functional morphology and molecular architecture of the nucleolus, and is reputed to be one of the best techniques for diagnosis and prognosis of cancer lesions. To test the generality of the enhancing effects. our study has involved the use of both mammalian and plant cells. Two steps in the process are improved quantitatively by microwave irradiation: fixation and staining itself. Fixation with the ethanol-based reagent, Kryofix, for 3 min in the microwave oven, resulted in good structural preservation at the optical level, and enhanced the contrast and selectivity of silver staining. On the contrary, we found that neither glutaraldehyde fixation, nor a treatment of sections with Carnoy's solution, improved Ag-NOR staining. After an analysis of the effects of the different substances involved in sample preparation, we conclude that ethanol is an essential factor for fixation for nucleolar staining, particularly if aldehydes are eliminated from fixative solutions. The process of staining was performed with a drop of staining solution on a semithin section of plastic-embedded tissue intthe microwave oven for 1 min. Staining under these conditions always improved the visualization of nucleoli, regardless of the fixation procedure. Therefore, microwave irradiation at both steps is recommended for giving the best results. Microwave irradiation probably enhances fixation by controlled heat, whereas the increase in reactivity of the staining solution is a direct effect by the microwaves on the silver ions themselves. We used this method to study nucleolar materials during mitosis in proliferating plant cells. Current applications of Ag-NOR staining can be improved with this technical modification.     

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.     

A Method for Silver Impregnation of Mammary Myoepithelia

Histochemical methods for microscopic visualization of nummary myoepithelial cells all yielded considerable variation in completeness of myoepithelial cell staining. Although extremely variable, silver impregnation occasionally gave tissue sections containing myoepithelia having excellent microanatomical detail and contrast with other tissue elements. Consequently, sources of variation in the silver technique were considered. Composition of the tissue fixative and pH of the silver impregnating solution were most critical. A final method is presented which gives consistent, complete silver impregnation of myoepithelia, where both the cell body and cell processes are clearly evident. The staining procedure is not light sensitive, nor is acid cleaning of glassware necessary. Tissue sections from lactating mouse, rat, hamster and goat are presented; tissue from other species should stain as well. The procedure should greatly facilitate the study of the function of myoepithelial cells and the visualization of these cells in mammary pathology.     

A method for silver impregnation of mammary myoepithelia

Histochemical methods for microscopic visualization of mammary myoepithelial cells all yielded considerable variation in completeness of myoepithelial cell staining. Although extremely variable, silver impregnation occasionally gave tissue sections containing myoepithelia having excellent microanatomical detail and contrast with other tissue elements. Consequently, sources of variation in the silver technique were considered. Composition of the tissue fixative and pH of the silver impregnating solution were most critical. A final method is presented which gives consistent, complete silver impregnation of myoepithelia, where both the cell body and cell processes are clearly evident. The staining procedure is not light sensitive, nor is acid cleaning of glassware necessary. Tissue sections from lactating mouse, rat, hamster and goat are presented; tissue from other species should stain as well. The procedure should greatly facilitate the study of the function of myoepithelial cells and the visualization of these cells in mammary pathology.     

Distribution of rDNA in the nucleus of Giardia lamblia: detection by Ag-I silver stain

Previous investigations have proved that diplomonads have primitive cell nuclei and lack a nucleolus. We determined the distribution of ribosomal DNA (rDNA) in diplomonad nuclei that lacked a nucleolus. Giardia lamblia was used as the experimental organism with Euglena gracilis as the control. The distribution of rDNA was demonstrated indirectly by the modified Ag-I silver technique that can indicate specifically the nucleolus organizing region (NOR) by both light and electron microscopy. In ultrathin sections of silver stained Euglena cells, all silver grains were concentrated in the fibrosa of the nucleolus, while no silver grains were found in the cytoplasm, nucleoplasm, condensed chromosomes or pars granulosa of the nucleus. In the silver stained Giardia cells, no nucleolus was found, but a few silver grains were scattered in the nucleus. This suggests that the rDNA of Giardia does not form an NOR-like structure and that its nucleus is in a primitive state.     

A new, rapid, microwave-stimulated method of staining melanocytic lesions

A new and sensitive method of staining melanocytic lesions is described. Tissue sections covered by a solution of colloidal silver nitrate are exposed to microwaves for 45 sec in a domestic oven to produce clean, crisp staining of melanocytes and melanoma cells, often showing long delicate dendritic cell processes. The staining technique does not stain other pigments or argyrophilic tissues and is shown to be more sensitive than the standard Masson-Fontana procedure.     

A New, Rapid, Microwave-Stimulated Method of Staining Melanocytic Lesions

A new and sensitive method of staining melanocyte lesions is described. Tissue sections covered by a solution of colloidal silver nitrate are exposed to microwaves for 45 sec in a domestic oven to produce clean, crisp staining of melanocytes and melanoma cells, often showing long delicate dendritic cell processes. The staining technique does not stain other pigments or argyrophilic tissues and is shown to be more sensitive than the standard Masson-Fontana procedure.     

The Modified Steiner Stain: a New Use for an Old Stain? Staining Cytomegalovirus-infected Cells in Gastrointestinal Biopsies

The modified Steiner stain is a non-specific silver stain for identifying bacteria in formalin-fixed, paraffin-embedded tissues. The principle behind its use is that bacteria are first sensitized using uranyl nitrate solution, making them able to precipitate silver from a silver nitrate solution. It is used routinely for staining gastric biopsies to identify Helicobacter pylori. Upon staining a gastric biopsy from a patient with acquired immunodeficiency syndrome (AIDS) and cytomegalovirus gastritis, we recognized that this technique also stains the viral inclusions of cytomegalovirus-infected cells. We then proceeded to stain 43 consecutive cytomegalovirus-positive gastrointestinal biopsies from 33 immunocompromised patients based on positive cytomegalovirus immunohistochemistry (DAKO-cytomegalovirus monoclonal antibody, clones DDG9 and CCH2). We also stained eight cytomegalovirus-infected, non-gastrointestinal tissue s, including lung, adrenal gland, ovary, skin and neural tissue, to ensure that the stain was staining the cytomegalovirus-infected cells and not argyrophilic or argentaffin neuroendocrine cells of the gastrointestinal tract. In 40 of the 43 cytomegalovirus-infected gastrointestinal biopsies, we saw positive staining with the modified Steiner stain (93% sensitivity). The cytomegalovirus-infected, non-gastrointestinal tissues all stained positively with the modified Steiner stain. Because the modified Steiner stain is frequently used to identify Helicobacter pylori in gastric biopsies, we propose that it be studied further for possible use either as a screen or as a confirmatory tool, or both, for cytomegalovirus inclusions in gastrointestinal biopsies.     

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.     

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.     

Argyrophilic nucleolar organizer regions

Silver staining techniques developed to demonstrate argyrophilic nucleolar organizer regions (Ag-NORs) have been widely applied in a variety of cell kinetic studies, using the mean number of AgNORs in tumour cells as a marker for malignancy of certain types of neoplasms. However, the AgNOR techniques currently available are not entirely satisfactory, as unspecific silver precipitates readily form in the sections. On the other hand, the contrast staining, may be so weak as to render identification of the AgNORs difficult. In the present study, some of the key factors influencing the outcome of AgNOR staining were evaluated in a more systematic way. A modified AgNOR staining procedure is now proposed, giving highly contrasting AgNORs with minimal unspecific silver precipitation, thus facilitating both manual and computerized counting. The new technique involves the use of microwave irradiation in order to shorten the processing time, the use of gelatin as a protective colloid, and a Farmer's solution to optimize the specificity of the technique.     

A silver carbonate method for cell counts of neurons and glial elements on paraffin embedded brain tissue.

A modification of the Del Rio-Hortega method for the demonstration of central nervous system elements is presented. This silver impregnation technique is particularly useful for the classification of cell types for quantitative differential cell counts. Formalin fixed paraffin sections are immersed in formol-ammonium bromide for 1 1/2 hours; this solution is an excellent mordant for various silver nitrate stains. The samples are stained for 20 to 60 minutes in a silver carbonate solution (25 ml of 25% silver nitrate combined with 200 ml of 5% sodium carbonate) and then reduced in a 1% formaldehyde solution to which 20 drops of acetic acid have been added. Finally, the slides are fixed in sodium thiosulfate, rinsed in tap water, dehydrated, cleared, and mounted. This procedure will enable this investigator to identify neurons, oligodendroglia, and astrocytes on the basis of their nuclear staining as well as to demonstrate the laminae of brain tissue since the method allows differentiation of cell layers and fiber tracts.     

Modified pyrogallol-initiated immunogold-silver enhancement technique applicable to prokaryotes

A modified immunogold-silver enhancement technique that was designed to reduce the nonspecific granular background staining, particularly for application on prokaryotic organisms, is reported. Aerial oxidation of pyrogallol contained in the commercial silver enhancer solution was effectively controlled during storage and in the reaction mixture. A combination of strategies such as storing the reagent under argon, modifying it using 0.5% (w/v) anhydrous sodium sulfite, reducing the concentration of silver ions in the reaction mixture and limiting the length of the silver enhancement reaction considerably reduced the granular background staining. The modified technique was demonstrated on the bacterium Xanthomonas campestris pv. malvacearum (Smith) Dye. A 7-min silver enhancement step produced little background staining, while optimal silver intensification of the bacterium pre-treated with the immunogold label was achieved.