A simple and rapid whole-mount staining method with methyl green-pyronin G applied to a molluscan brain preparation.

Subesophageal ganglia of molluscs have been stained as whole mounts with methyl green-pyronin G to display the relative location of individual neurons. Nuclei appear blue, perikarya red. Expose the ganglion cells by dissection of the connective tissue in snail Ringer. Transfer the ganglion to a fixative of 2.5% glutaraldehyde in 0.1 M Na cacodylate pH 7.1 at 4 C for 12--24 hours, and wash in distilled water for 1 1/2 hours. Stain with methyl green-pyronin G for 1/2--1 hour and differentiate in 96% ethanol using many rapid changes. Transfer the ganglion to absolute ethanol for 2 1/2 hours and clear in xylene for 3 hours before embedding in Depex in a suitable dish. When the Depex has hardened, the preparation can be stored, and is readily available for subsequent examination. The method may be applicable to other invertebrate tissues, and may be useful in preparing objects for teaching purposes.     

Red-blue staining of hydrolysed nucleic acids in paraffin sections

A previous treatment with 10% HC1 in tetrahydrofuran for 2-3 min at 37° C hydrolyses DNA while substantially preserving RNA in formol-fixed paraffin sections. If this treatment is followed by dyeing with basic fuchsin-thiazine or oxazine mixtures, the basic fuchsin stains DNA, the blue dye cytoplasmic RNA, though nucleolar RNA is not well preserved. A specimen sequence is to treat the hydrolysed section with a mixture of 1% aqueous trimethylthionin (Chroma), 15 ml; 0.1% basic fuchsin (G. T. Gurr), 4 ml; and glacial acetic acid, 1 ml. Stain for 15-30 min, dehydrate in acetone, then pass sections through xylene to polystyrene. The specificity of this stain for cytoplasmic RNA is sharper than that of methyl green-pyronin; hence the technic given can be a useful addition to the standard Unna-Pappenheim procedure.     

A Six-Dye Staining Schedule for Sections of Mesquite and Other Desert Plants

Materials are fixed in FPA (formalin, 2; propionic acid, 1; 70% ethanol, 17). Paraffin sections on slides are brought to 50% ethanol and stained as follows: (1) in Bismarck brown Y, a 0.02% solution in 0.1% aqueous phenol, 10-30 min; wash 30 sec in 0.7% acetic acid, and wash in distilled water 20-30 sec; (2) in crystal violet, 1% in 70% ethanol alkalinized with 1 drop of 1 N NaOH per 100 ml, 12-35 min; wash 30-60 sec in tap water to remove excess stain, and rinse 0.5 sec in 70% ethanol; then mordant in I₂-KI, 1% each in 70% ethanol, 40 sec, and rinse in 70% ethanol 2-5 sec; (3) in a mixture containing 0.4% acid fuchsin and 0.6% crythrosin B in 70% ethanol about 0.5 sec; rinse in 70% ethanol 5-15 sec to remove excess red; dehydrate in 70%, 95%, and absolute ethanol, 2-3 sec each; (4) in fast green FCF, 0.5% in a mixture of equal parts of methyl cellosolve, absolute ethanol, and clove oil, 5-15 sec; rinse in a mixture of clove oil, 10 ml; absolute ethanol, 100 ml; and methyl cellosolve, 10 ml, 5-7 sec; (5) in orange G, 0.75 gm in a mixture of clove oil, 40 ml; absolute ethanol, 40 ml; and methyl cellosolve, 60 ml, 5-30 sec; rinse clean in a 1:1 mixture of xylene and absolute ethanol, 5-20 sec Complete the clearing in pure xylene, 3 changes, 1.5 min in each, and apply a cover glass with synthetic resin. Slides are agitated in all steps except Bismark brown Y, crystal violet, and the xylenes. Contrast and staining intensity are adjusted by varying staining times in the dye solutions.     

A Simple Histochemical Reaction for Aldehydes

A study has been made on the possibility of replacing leucofuchsin by colored basic fuchsin for the histochemical demonstration of aldehydes. Several tissues from mammals and various pertinent fixatives were used. Aldehydes were freed from carbohydrates by oxidation and from thymonucleic acid by hydrolysis.

It was found that the colored form and not necessarily the leucoform of basic fuchsin can be used histochemically in demonstrating aldehydes. The technic used is as follows: (1) Treat with 1.0-0.5% H₅IO₆ (or in 1% KIO₄ in M/1 H₂SO₄) for 5 to 10 min. and wash thoroughly. For thymonucleic acid hydrolize with N HCl 5 min. at room temperature, 10 min. at 60°C. and 5 min. at room temperature. (2) Stain for 2-3 min. with 0.05% basic fuchsin in 5% ethanol, 3% phenol. (3). Transfer immediately to 1 or 2 changes of 1% sodium bisulphite or potassium metabisulphite in 0.1-0.2 N H₂SO₄ for a total of 5 min. (4) Rinse with water and treat with M H₂SO₄ in 95% ethanol for 3-5 min. 6. Wash thoroughly in water and dehydrate, clear, and mount. For glycogen and mucin the following counterstaining solution is recommended: orange G, 0.25 g.; light green SFY, 0.10 g.; phosphotungstic acid 0.50 g.; 50% ethanol, 100 ml.; glacial acetic acid, 0.25 ml.     

The use of methyl green-pyronin staining after glutaraldehyde fixation and paraffin or araldite embedding.

Methyl green-pyronin staining has been used for localization of RNA and DNA in chick and mouse embryonic tissues and in insect larval salivary glands. Glutaraldehyde or tricholoracetic acid-lanthanum acetate (TCA-LA) was used as fixative and paraffin wax or Araldite was used as embedding medium. For good results the following are specially desirable: fixation with 2.5% glutaraldehyde, dehydration in alcohols for short time, and the use of fresh staining solutions. After TCA-LA fixation the final results are much less specific. The digestion with RNAse appears essential for the detection of RNA because pyronin does not seem to be entirely specific to RNA. The results show that glutaraldehyde a common fixative for electron microscopic work, is particularly suitable fixative for light microscopic cytochemical investigations if followed by methyl green-pyronin staining; furthermore, methyl green-pyronin staining after glutaraldehyde fixation can be carried out on Araldite sections.     

Methyl Green-Pyronin for Staining Autoradiographs of Hydroxyethyl Methacrylate-Embedded Lymphoid Tissue

Cells in the spleen in DNA-synthesis were labelled with tritiated thymidine. Tissue was fixed for 12 hr in 10% neutral formalin, washed for 4 hr in tap water and dehydrated through 70% and absolute ethanol. The tissue blocks were infiltrated overnight with a mixture consisting of glycol methacrylate, 80 ml; polyethylene glycol 400, 12 ml; and benzoyl peroxide, 0.27 gm. Specimens were cast in BEEM capsules with the final embedding medium consisting of 42 parts of the infiltration medium and 1 part of an acceleration mixture. This mixture consisted of N,N-dimethylaniline, 1 part and polyethylene glycol 400, 15 parts. The blocks hardened in 30 min and were sectioned with an ultramicrotome fitted with glass knives. Sections were coated with Ilford K5 liquid emulsion and exposed for 2 wk. Methyl green-pyronin staining of autoradiographs was carried out at pH 4.1 in acetate buffer containing 0.5% methyl green (Allied Chemicals) and 0.2% pyronin GS (Chroma). Staining was for 30-60 min, after which sections were washed for 1 min in water, blotted, allowed to dry, and mounted in Canada balsm. The procedure resulted in good quality autoradiographs in which the degree of basophilia of labelled cells could be assessed.     

Chromosomal Banding Patterns Produced by Methyl Green-Pyronin Staining After Trypsin Treatment

A method is described for producing banding pattern with methyl green-pyronin (MGP) stain in chromosomes of fibrosarcoma cells. 1) The stain was made by mixing equal volumes of 2% aqueous pyronin G, 2% aqueous methyl green, distilled water, and 0.1 M acetate Mer (pH 5.7). 2) Treatment with colcemide and hypotonic KCI (0.075 M) was performed u usual. 3) Metaphase chromosomes were prepared using the flame-drying technique and treated with 0.25% trypsin at 37 C for 45 to 90 seconda. Before staining, the slides were rid in PBS, in distilled water, and then were dipped in 0.05 M acetate buffer. 4) Chromosomes were stained for more than 20 minuta, rinsed in distilled water, and hot-air dried. satisfactory results were obtained in uncontracted metaphase chromosomes. MCP stain hm the advantage of permitting much longer trypsin treatment and staining time than the trypsin-Giemsa method while providing satisfactory banding pattern.     

Chromosomal banding patterns produced by methyl green-pyronin staining after trypsin treatment.

A method is described for producing banding patterns with methyl green-pyronin (MGP) stain in chromosomes of fibrosarcoma cells. 1) The stain was made by mixing equal volumes of 2% aqueous pyronin G, 2% aqueous methyl green, distilled water, and 0.1 M acetate buffer (pH 5.7). 2) Treatment with colcemide and hypotonic KCl (0.075 M) was performed as usual. 3) Metaphase chromosomes were prepared using the flame-drying technique and treated with 0.25% trypsin at 37 C for 45 to 90 seconds. Before staining, the slides were rinsed in PBS, in distilled water, and then were dipped in 0.05 M acetate buffer. 4) Chromosomes were stained for more than 20 minutes, rinsed in distilled water, and hot-air dried. Satisfactory results were obtained in uncontracted metaphase chromosomes. MGP stain has the advantage of permitting much longer trypsin treatment and staining time than the trypsin-Giemsa method while providing satisfactory banding patterns.     

Feulgen's Reaction Applied to Protozoa and Small Worms, Mounted In Toto in Venetian Turpentine

Permanent mounts of certain protozoa and small worms are obtained as follows: kill suspensions of the organisms with Feulgen's fixative (6% HgCl₂ in 2% aqu. acetic acid) for 3 to 24 hours. After pipetting off the fixative, add successively: 70% iodized alcohol; ditto, 30 minutes later; 50%, then 35% alcohol; 2 baths distilled water; normal HCl. Transfer to cold water and heat to 60°C for 4 to 5 minutes or longer. Cool under running water; and wash in distilled water.

Stain 1 to 3 hours in Feulgen's fuchsin sulfurous acid (1 g. of a suitable basic fuchsin, e. g. rosanilin hydrochloride, boiled in 200 cc. water, cooled, and allowed to stand 24 hours after adding 20 cc. normal HCl and 1 g. sodium bisulfite). Pass thru 3 baths of 200 cc. distilled water with 10 cc. normal HCl and 1 g. sodium bisulfite. Transfer to water and then to 35%, 70%, and 95% alcohols successively. Counterstain with fast green FCF, orange G or eosin Y in 95% alcohol. Pass thru two changes of absolute alcohol.

Transfer to 10% Venetian turpentine and place in a dessicator; mount after the turpentine has become concentrated.

If sections instead of total mounts are desired, the material should go from absolute alcohol, thru alcohol-xylol and xylol to paraffin (or preferably paraffin of M. P. 56°C with 3% bees-wax). The paraffin may be added to the material in the test tube, and cooled after the organisms have settled. Then break the tube, trim a block, and cut.     

Morphological and electrophysiological mapping of giant neurons in the suboesophageal ganglia of Helix pomatia

1. To reveal the morphology of the suboesophageal ganglia of Helix pomatia, the connective tissue was completely removed and the preparations stained whole-mount with methyl green-pyronin G to display the relative locations of the neurons. 2. Fifteen large cells which could be recognized as individuals in at least 75% of the preparations investigated, were morphologically identified by size, position and color. 3. The cells were electrophysiologically characterized with respect to spontaneous activity, synaptic input from peripheral nerves, and response to application of drugs (e.g. ACh, DA and 5-HT). 4. The peripheral axonal projections of eight of the major identified cells were investigated by intracellular CoCl2 injection and by cobalt backfilling of the peripheral nerves.     

Histological Staining with Methyl-Green-Pyronin

The standard technics for methyl green-pyronin staining are found to give inconstant results, often with poor differentiation between chromatin and cytoplasm. A modified procedure is described using n butyl alcohol for differentiation after aqueous methyl green staining and counter-staining with pyronin in acetone. After 6 minutes in 0.2% aqueous methyl green (chloroform extracted), the section is blotted, differentiated in n butanol, counter-stained 30-90 seconds in acetone saturated with pyronin (less concentrated solutions may be preferred for some purposes), cleared in cedar oil and xylene and mounted. This technic retains the value of methyl green as a histochemical detector for polymerized desoxyribo-nucleic acid (DNA). The intensity of the stain, however, is considerably greater than that obtained with the procedure designed for quantitative (stoichiometric) photometric estimation of polymerized DNA. Pyronin serves primarily as a counterstain, and is not found to be a reliable indicator of ribonucleic acid either by this method or others which have been described.     

Simultaneous quantification of nucleoproteins and comparison of methyl green-pyronin Y and Feulgen staining in sections of oral squamous cell carcinoma,dysplastic lesions and normal mucosa

A fundamental difference between normal cells and tumor cells is the proliferative activity of the nucleus and nucleolus, which increases progressively from normal to oral dysplastic mucosa to oral squamous cell carcinoma (OSCC). This activity is evaluated routinely using hematoxylin and eosin (H & E) staining, but in some cases, inter-observer variability occurs among pathologists. We evaluated cellular proliferation by staining sections with the methyl green-pyronin Y procedure and the Feulgen reaction. We also compared the efficacy of methyl green-pyronin Y and Feulgen staining for studying nuclear and nucleolar features in oral dysplastic mucosa and in different grades of OSCC. Sections cut from formalin fixed, paraffin embedded blocks of five normal mucosa, 15 dysplastic mucosa, 10 well-differentiated OSCC, 10 moderately differentiated OSCC and five poorly differentiated OSCC cases were stained with Hematoxylin and Eosin, methyl green-pyronin Y and the Feulgen reaction. The mean diameters of the nuclei and number of nucleoli showed significant differences. A progressive increase in diameter of the nucleus and number of nucleoli was observed from normal mucosa through poorly differentiated OSCC. We observed that methyl green-pyronin Y stain is more useful than Feulgen and hematoxylin and eosin for simultaneous quantitative assessment of both RNA and DNA. The simplicity of this technique makes it a valuable tool even for daily routine examination.     

Nucleic acid staining with the methyl green-pyronin method. A comparison of the use of pure dyes and commercially available dyes

We compared the staining obtained using commercially available pyronin Y samples with that obtained using pure pyronin Y in a standardized methyl green-pyronin procedure. In addition, the importance of the dye content of the anhydrous dye was investigated by varying the dye content by the addition of pure pyronin Y to one of the commercially available pyronin Y samples. We found that, for routine histological work, commercially available pyronin Y samples may produce acceptable results provided the sample can be shown by spectrophotometry to contain at least 43% pyronin Y.     

Safranin and Anilin Blue with Delafield's Hematoxylin for Staining Cell Walls in Shoot Apexes

The following technic is suggested for staining cell walls in shoot apexes: After the usual preliminary steps through 50% ethyl alcohol, stain in 1 % safranin 0 for 24 hours. Rinse in tap water and place in 2% aqueous tannic acid for 2 minutes. After rinsing in tap water, stain for 2 minutes in 1 part Delafield's hematoxylin to 2 parts distilled water and rinse in tap water. Remove excess hematoxylin with acidified water (1 drop cone. HC1 in 200 ml. water), then place slides in 0.5% lithium carbonate for 5 minutes. Dehydrate through an ethyl alcohol series, then transfer from absolute alcohol to a saturated solution of anilin blue in “methyl cellosolve” for 5-10 minutes. Wash in absolute alcohol, rinse in a solution of 25% methyl salicylate, 33% xylene, 42% absolute ethyl alcohol and clear for 10 minutes in a solution of 2 parts methyl salicylate, 1 part xylene, 1 part absolute ethyl alcohol. Transfer through two changes of xylene and mount in “clarite” or suitable alternate. The resulting preparations will have clearly defined, dark-staining cell walls and will photograph well when “Super Panchro-Press, Type B” film (Eastman Kodak Co.) is used in conjunction with suitable Wratten filters.     

一种快速、有效、经济的提取酵母质粒的方法

目的：建立一种经济有效、快速简便、稳定的提取酵母质粒的方法。方法：用葡糖苷酸酶消化酵母细胞壁以获取原生质体,然后采用碱裂解法裂解原生质体以获得质粒。结果：与采用商品化离心柱法试剂盒所提取的质粒相比,用该法获取的酵母质粒在PCR分析及转化效果方面没有差异。结论：建立了一种经济有效、快速简便、稳定的提取酵母质粒的方法。     

Counterstaining Golgi-Cox Impregnations with Luxol Fast Blue as a Myelin Stain

Immerse pieces of brain tissue 4 wk in solutions A and B, mixed just before use: A. K₂Cr₂O₇, 1 gm; HgCl₂, 1 gm; boiling distilled water, 85 ml. Boil A for 15 min, cool to 2 C and add: B. K₂CrO₄, 0.8 gm; Na₂WO₄, 0.5 gm; distilled water, 20 ml. Rinse in water and immerse 24 hr in LiOH, 0.5 gm; KNO₃, 15 gm; distilled water, 100 ml. Wash 24 hr in several changes of 0.2% acetic acid and then for 2 hr in tap water. Dehydrate and embed in celloidin. Process a 60 μ section through 70 and 95% ethanol, a 3:1 mixture of absolute ethanol and chloroform, and toluene. Immerse it for 5 min in a solution containing methyl benzoate, 25 ml; benzyl alcohol, 100 ml; chloroform, 75 ml. Orient the section on a chemically clean slide and let air-dry 5-10 min. Process through toluene, 3:1 ethanol-chloroform and 95% ethanol. Place the section for 5-60 min at 60 C in a solution made up of: Luxol fast blue G (Matheson, Coleman and Bell), 1 gm; 95% ethanol, 1000 ml; 10% acetic acid, 5 ml. Hydrate to water and immerse in 0.05% Li₂CO₃ for 3-4 min. Differentiate in 70% ethanol and place in water. Immerse for 5-15 min in a mixture of two solutions: A. cresylechtviolet (Otto C. Watzka, Montreal), 2 gm; 1 M acetic acid, 185 ml; B. 1 M sodium acetate, 15 ml; distilled water, 400 ml; absolute ethanol, 200 ml. Dehydrate to 3:1 ethanol-chloroform. Clear in toluene and apply a coverslip. The technique produces fast Golgi-Cox impregnated neurons against a background of counterstained myelinated fibers. Patterns of the myelinated fibers can be used to localize impregnated neurons.     

A Cytochemical Study of DNA, RNA, and Protein in the Developing Maize Anther: I. Methods

Methods are described for staining acetic-alcohol fixed, sectionedmaize anther material for DNA (Feulgen), RNA (methyl green-pyronin),and protein (naphthol yellow S) in a quantitative manner formicrodensitometry using the Barr and Stroud Integrating MicrodensitometerModel GN₂.     

Safranin and Anilin Blue with Delafield's Hematoxylin for Staining Cell Walls in Shoot Apexes

The following technic is suggested for staining cell walls in shoot apexes: After the usual preliminary steps through 50% ethyl alcohol, stain in 1 % safranin 0 for 24 hours. Rinse in tap water and place in 2% aqueous tannic acid for 2 minutes. After rinsing in tap water, stain for 2 minutes in 1 part Delafield's hematoxylin to 2 parts distilled water and rinse in tap water. Remove excess hematoxylin with acidified water (1 drop cone. HC1 in 200 ml. water), then place slides in 0.5% lithium carbonate for 5 minutes. Dehydrate through an ethyl alcohol series, then transfer from absolute alcohol to a saturated solution of anilin blue in “methyl cellosolve” for 5-10 minutes. Wash in absolute alcohol, rinse in a solution of 25% methyl salicylate, 33% xylene, 42% absolute ethyl alcohol and clear for 10 minutes in a solution of 2 parts methyl salicylate, 1 part xylene, 1 part absolute ethyl alcohol. Transfer through two changes of xylene and mount in “clarite” or suitable alternate. The resulting preparations will have clearly defined, dark-staining cell walls and will photograph well when “Super Panchro-Press, Type B” film (Eastman Kodak Co.) is used in conjunction with suitable Wratten filters.     

快速诱导细胞凋亡及检测方法研究

目的：探讨Ca2＋和Na＋诱导细胞凋亡的最佳浓度及时间,并用甲基绿一派诺宁染色法检测凋亡细胞的形态变化。方法：分别用不同浓度梯度及时间梯度的Ca2＋和Na＋胁迫处理洋葱鳞茎内表皮细胞,得诱导的最佳浓度及时间;用甲基绿一派诺宁染色法检测诱导凋亡的洋葱鳞茎内表皮细胞、大蒜根尖细胞和鸡血红细胞的形态特征变化。结果：诱导处理的最佳Ca2＋和Na＋浓度为0．4mol／L,最适时间约为8h,且CaCl2的诱导效果较NaCl好;经甲基绿一派诺宁染色,洋葱鳞茎内表皮细胞、大蒜根尖细胞、鸡血红细胞凋亡细胞的细胞核均呈蓝紫色,细胞质呈红色。结论：找出了诱导细胞凋亡的最适Ca2＋和Na＋浓度和时间,并检测到细胞凋亡。     

建立小鼠膀胱肿瘤原位模型的优化方法

目的探讨硝酸银、盐酸、胰酶和乙醇预处理构建鼠膀胱肿瘤的成瘤机制。方法 24G静脉留置针插入膀胱,PBS冲洗后,将小鼠随机分为5组,每组6只:(1)乙醇作用组:22%乙醇0.1 mL保留20 min;(2)胰酶作用组:0.2%胰酶保留30 min;(3)酸碱作用组:0.1 mmol/L HCl 0.1 mL作用15 s后,PBS冲洗,0.1 mmol/L NaOH0.1 mL作用5 s,排空膀胱;(4)硝酸银作用组:0.15 mol/L硝酸银保留10 s;(5)对照组:0.1 mL生理盐水。术后1和24h随机处死每组3只小鼠,摘取膀胱,HE染色观察膀胱黏膜病理变化;戊二醛固定,电镜下观察膀胱黏膜细胞微结构变化;甲苯胺蓝染色,观察膀胱黏膜固有层肥大细胞数目变化;过碘酸-希夫(PAS)染色,观察膀胱黏膜GAG层变化。40只小鼠应用上述前四组预处理因素处理膀胱后,建立膀胱癌原位模型,计算各组成瘤率。结果胰酶和乙醇处理1h后,局部上皮伞状细胞脱落,黏膜下层暴露;酸碱和硝酸银处理组大部黏膜完整性破坏,黏膜下层暴露较多,连续性中断;对照组和实验组间炎症细胞浸润均不表现出统计学差异。24 h后,胰酶和乙醇组可见局部轻度水肿并充血,黏膜完整性恢复较好,细胞间见紧密连接;而酸碱和硝酸银组上皮黏膜薄厚不均一,仍可见部分脱落黏膜。结论利用硝酸银和酸碱预处理膀胱可作为鼠膀胱肿瘤原位模型构建的首选方法。