Fluorescence of mast cell granules in paraffin sections and cell smears induced by an N-quaternary oxazole scintillator

Summary The N-quaternized derivative of dimethyl-POPOP (termed Q4) induces a bluish-green fluorescent reaction in mast cell granules from paraffin sections and cell smears, in addition to a previously described bluish-white fluorescent reaction in chromatin DNA. The chromatin reaction was abolished by staining the samples either with Mayer's Haematoxylin before Q4 treatment or by Q4 treatment at pH 1.5. The reaction in mast cell granules was absent after substrate methylation. The staining sequence Haematoxylin-Eosin-Q4 also worked well in paraffin sections, allowing the observation of the current histological image under bright-field illumination as well as double-colour emission under fluorescence microscopy. The sequence is proposed as a new diagnostic procedure for demonstrating mast cell granules.     

Investigation of Thiazin Dyes as Biological Stains II. Influence of Buffered Solutions on Staining Properties

The effect of buffer solutions of varying reaction upon staining fixed sections with thionin, azures A, B, and C, and methylene blue has been studied. The buffer solutions were employed in one of three different ways: for pre-treatment of the sections, for post-treatment, or as solvents for the dyes. Regardless of the method of employing the buffer solutions it was found that the intensity of staining increased with increasing pH-values (a fact which is generally known to be true in the case of basic dyes). It is not certain whether this effect is due to varying the H-ion concentration or to altering the salt content of the solution, or to both. It was also noticed that there was one point where the staining intensify increased most rapidly. This point was either between pH 5 and pH 6 or between pH 6 and pH 7, its position varying with the method of fixation and of applying the buffer solutions. It was further observed that between pH 5 and pH 7 there were always more pronounced metachromatic effects than with either more acid or more alkaline buffer solutions.     

Investigation of Thiazin Dyes as Biological Stains II. Influence of Buffered Solutions on Staining Properties

The effect of buffer solutions of varying reaction upon staining fixed sections with thionin, azures A, B, and C, and methylene blue has been studied. The buffer solutions were employed in one of three different ways: for pre-treatment of the sections, for post-treatment, or as solvents for the dyes. Regardless of the method of employing the buffer solutions it was found that the intensity of staining increased with increasing pH-values (a fact which is generally known to be true in the case of basic dyes). It is not certain whether this effect is due to varying the H-ion concentration or to altering the salt content of the solution, or to both. It was also noticed that there was one point where the staining intensify increased most rapidly. This point was either between pH 5 and pH 6 or between pH 6 and pH 7, its position varying with the method of fixation and of applying the buffer solutions. It was further observed that between pH 5 and pH 7 there were always more pronounced metachromatic effects than with either more acid or more alkaline buffer solutions.     

Selective staining of nucleic acids by osmium-ammine complex in thin sections from lowicryl-embedded samples

Osmium-ammine (OA)/SO2 selectively contrasted RNA- and DNA-containing structures in thin sections from Lowicryl-embedded samples. No cell structures were stained after Epon embedding. RNAse and DNAse digestion experiments demonstrated that only RNA and DNA were stained in Lowicryl thin sections. Protease digestion did not modify the staining reaction. The very fine end-reaction produced a very high resolution of the stained structures. The staining reaction was not due to the presence of SO2 but to the low pH of the solution (ranging from 1.5-2.2). OA in glycine buffer, pH 1.5, selectively contrasted nucleic acids. Electrostatic bonds between nucleic acids and OA complex were probably involved in the staining reaction. Increasing the pH value of the staining medium resulted in loss of OA specificity for nucleic acids. The high electrolyte concentration of the staining medium hindered the staining reaction.     

Effects of Ph on Post-Mortem Retention of Trypan Blue Vital Staining in Tissues of Mice

Vital staining of aortas from mice injected subcutaneously (daily for 5 days) with trypan blue was studied. In routine paraffin sections elastic membranes were observed to be well stained and other medial elements unstained following fixation in 10% formaldehyde (25% formalin) at pH 7-9. An identical pattern of vital staining was observed in specimens that had been immersed for 48 hr in saline solutions at pH 7-11. Elastic membranes were not stained, but intermembranous connective tissue was stained after the following: (1) fixation in 10% formaldehyde at pH 1-4 and in Lavdowsky's solution (ethanol, formaldehyde, water and glacial acetic acid), pH 2.3-2.8; and (2) immersion in saline for 48 hr at pH 14. Aortic elastic membranes were vitally stained after fixation by intracardiac perfusion with 10% formaldehyde (pH 7-8) but not after perhion with Lavdowsky's fixative (pH 2.3-2.8). Vital staining was limited to medial elastic membranes in sections of fresh aorta made in a cryostat or by a regular freezing microtome. The vital staining (coarse cytoplasmic granules of dye) within macrophages (Kupffer cells and others) and in cytoplasm of renal tubular epithelium was well demonstrated following use of all methods discussed above     

Cytochemical Staining of Sections from Plastic-Embedded Flagellates

Dinoflagellate chromosomes in sections of plastic-embedded cells were stained without removing the plastic. Azur B and Feulgen procedures were used to localise DNA. Azur B was used with Araldite or methacrylate sections by staining in 0.2% stain in 0.05 M citrate buffer at pH 4 for 1 hr at 50 C followed by rinsing in tertiary butyl alcohol to differentiate the chromosomes. Feulgen stain was used with Araldite sections by hydrolyzing in 1 N HCl at 60 C for 10 min, rinsing in water, staining for 24 hr, washing well, drying and covering. Fast green was used with methacrylate sections to stain proteins by flooding the slide with a 0.1% solution of stain in 0.06 M phosphate buffer at pH 8, allowing the stain to dry out at 40-50 C, washing well, drying and covering. Controls were carried out on material fixed in formalin and treated with nucleases or proteolytic enzymes prior to embedding, and staining.     

Does progressive nuclear staining with hemalum (alum hematoxylin) involve DNA,and what is the nature of the dye-chromatin complex?

Previous investigators have disagreed about whether hemalum stains DNA or its associated nucleoproteins. I review here the literature and describe new experiments in an attempt to resolve the controversy. Hemalum solutions, which contain aluminum ions and hematein, are routinely used to stain nuclei. A solution containing 16 Al³⁺ ions for each hematein molecule, at pH 2.0–2.5, provides selective progressive staining of chromatin without cytoplasmic or extracellular “background color.” Such solutions contain a red cationic dye-metal complex and an excess of Al³⁺ ions. The red complex is converted to an insoluble blue compound, assumed to be polymeric, but of undetermined composition, when stained sections are blued in water at pH 5.5–8.5. Staining experiments with DNA, histone and DNA + histone mixtures support the theory that DNA, not histone, is progressively colored by hemalum. Extraction of nucleic acids, by either a strong acid or nucleases at near neutral pH, prevented chromatin staining by a simple cationic dye, thionine, pH 4, and by hemalum, with pH adjustments in the range, 2.0–3.5. Staining by hemalum at pH 2.0–3.5 was not inhibited by methylation, which completely prevented staining by thionine at pH 4. Staining by hemalum and other dye-metal complexes at pH ≤ 2 may be due to the high acidity of DNA-phosphodiester (pK_a ~ 1). This argument does not explain the requirement for a much higher pH to stain DNA with those dyes and fluorochromes not used as dye-metal complexes. Sequential treatment of sections with Al₂(SO₄)₃ followed by hematein provides nuclear staining that is weaker than that attainable with hemalum. Stronger staining is seen if the pH is raised to 3.0–3.5, but there is also coloration of cytoplasm and other materials. These observations do not support the theory that Al³⁺ forms bridges between chromatin and hematein. When staining with hematein is followed by an Al₂(SO₄)₃ solution, there is no significant staining. Taken together, the results of my study indicate that the red hemalum cation is electrostatically attracted to the phosphate anion of DNA. The bulky complex cation is too large to intercalate between base pairs of DNA and is unlikely to fit into the minor groove. The short range van der Waals forces that bind planar dye cations to DNA probably do not contribute to the stability of progressive hemalum staining. The red cation is precipitated in situ as a blue compound, insoluble in water, ethanol and water-ethanol mixtures, when a stained preparation is blued at pH > 5.5.     

The effect of various fixation procedures on the digestability of sialomucins with neuraminidase

Synopsis The histochemical digestability with neuraminidase of sialomucin in mouse sublingual gland was studied in unfixed and formaldehyde vapour-fixed cryostat sections, and in sections prepared from paraffin-embedded material fixed in several alcohol- or formaldehyde-containing fixatives recommended for mucosubstances.The removal of sialic acid residues from sections treated with neuraminidase was followed histochemically with the following staining methods: Azure A pH 3.5, Alcian Blue pH 2.5, Low Iron Diamine and Alcian Blue pH 2.5 followed by periodic acid-Schiff. When Goland's methanolic cyanuric chloride was used as fixative, only a partial loss of tissue basophilia was evident after enzyme incubation, but in tissues fixed in other ways a complete loss of histochemically detectable sialic acid residues was observed.     

A rapid and simple staining method, using Toluidine Blue, for analysing mitotic figures in tissue sections

Summary Mitotic index is a clinically important parameter in cancer pathology. We developed a staining method using Toluidine Blue to detect efficiently and rapidly mitotic figures in sections of formalin-fixed paraffin-embedded human and rat tisues. Sections were stained at acid pH with a 0.01% Toluidine Blue solution after removal of RNA with hydrochloric acid or ribonuclease. The optimal pH of the TB staining solution was found to be 4.5 for rat tissues and 3.5 for human tissues. This procedure stained mitotic figures much more intensely than other (extra)cellular structures. A quantitative estimate of the total number of nuclei in the field where mitotic figures were counted, was obtained in an adjacent section hydrolysed in 5 N hydrochloric acid and stained by the Feulgen reaction with a Schiff-type reagent containing 0.01% Toluidine Blue. This method specifically stained interphase and mitotic nuclei and the field cellularity could be quantified by image cytometry. When these procedures were performed on two consecutive serial sections, a mitotic index could be determined accurately by relating the count of mitotic figures to the number of tumour cells.     

Romanowsky Staining with Buffered Solutions, III. Extension of the Method to Romanowsky Stains in General

Solutions at 0.3 g. per 100 cc. of equal parts of glycerin and methyl alcohol of various Wright, Giemsa, Leishman and Balch stains and similar eosinates of thiazene dyes give satisfactory wholesale staining of sections without differentiation when buffered with citric-acid and sodium-phosphate. Prestaining with alum hematoxylin adds to depth, density and permanence of nuclear staining, but decreases clarity. A satisfactory modification of Mayer's acid hemalum is described. The reaction should be pH 4.2 for neutral formalin or Orth fixation, pH 4.6 for acid formalin, pH 5.0 for Zenker formalin and pH 6.5 for ethyl or methyl alcohol or Carney fixation. Toluidine blue phloxhiate is found to be a quite desirable stain and its preparation is described. Clarite and clarite are definitely superior to neutral Canada balsam, and somewhat inferior in regard to fading compared with liquid petrolatum as mounting media for these Romanowsky stains.     

Observations on the use of diazo-I-H-tetrazole and phenylglyoxal in protein histochemistry as applied to human gingiva

Synopsis A solution of diazo-1-H-tetrazole, freshly prepared by the diazotization of 5-amino-1-H-tetrazole under conditions to avoid explosion, was adjusted to pH 8.8, diluted (11 or 19) with 0.67 M bicarbonate buffer, pH 8.8, and used immediately as a histochemical reagent for demonstrating histidine, tryptophan, and tyrosine residues in deparaffinized sections of frozen-dried human gingiva, rat abdominal skin, and mouse larynx fixed in modified Newcomer's solution. Diazo-1-H-tetrazole reacted histochemically like other diazonium coupling reagents in common use, except that in sections pretreated with bromoacetic acid at pH 7, diazo-1-H-tetrazole staining was increased, rather than decreased as expected. Pretreatment with bromoacetic acid also increased staining in gingival sections exposed to an acetic anhydride-pyridine mixture and then reacted with diazo-1-H-tetrazole. Similarly, pretreatment with bromoacetic acid increased the intensity of Millon's reaction in gingival sections. Sections of human gingiva or mouse larynx pretreated with diazo-1-H-tetrazole stained less intensely with Biebrich Scarlet used respectively at pH 2.62 and 6.50.In test-tube experiments to check the specificity of diazo-1-H-tetrazole for amino acids, only histidine, tryptophan, and tyrosine gave solutions with colours visually distinguishable from the buffer blank. In similar tests a solution of ribonuclease A gave a colour like that given by histidine and tyrosine. Whereas pyridine failed to yield a colour with undiluted diazo-1-H-tetrazole reagent in test-tube experiments, gingival sections exposed to pyridine for 24 hr stained more intensely with diazo-1-H-tetrazole, but diazo-1-H-tetrazole staining of abdominal skin sections was not altered by prior treatment with pyridine.Phenylglyoxal, used as a 1.5% w/v solution inN-ethylmorpholine-acetate buffer (0.2 M acetate) pH 8, blocked the Sakaguchi reaction in human gingival sections. Pretreatment with phenylglyoxal also led to a reduction in their staining by Biebrich Scarlet at pH 2.62, dinitrofluorobenzene, or diazo-1-H-tetrazole. In addition the dimethylaminobenzaldehyde nitrite reaction for tryptophan was reduced. Phenylglyoxal blockade of arginine residues in gingival sections was labile to 1% acetic acid containing 0.05 M choline chloride after 60 min; but in test-tube experiments extending over 320 min, di(phenylglyoxal)-l-arginine hydrochloride was more stable in this acetic acid-choline solution than in water. It is suggested that after treatment of gingival sections with bromoacetic acid at pH 7.0, additional tyrosine residues become available for reaction with diazo-1-H-tetrazole. Pyridine is thought to remove bound lipid from gingival epithelium, thereby exposing protein residues reactive with diazo-1-H-tetrazole. The use of diazo-1-H-tetrazole and phenylglyoxal for characterizing amino acid residues of gingival proteins responsible for anionic dye binding is discussed.     

Cytochemical Staining of Sections from Plastic-Embedded Flagellates

Dinoflagellate chromosomes in sections of plastic-embedded cells were stained without removing the plastic. Azur B and Feulgen procedures were used to localise DNA. Azur B was used with Araldite or methacrylate sections by staining in 0.2% stain in 0.05 M citrate buffer at pH 4 for 1 hr at 50 C followed by rinsing in tertiary butyl alcohol to differentiate the chromosomes. Feulgen stain was used with Araldite sections by hydrolyzing in 1 N HCl at 60 C for 10 min, rinsing in water, staining for 24 hr, washing well, drying and covering. Fast green was used with methacrylate sections to stain proteins by flooding the slide with a 0.1% solution of stain in 0.06 M phosphate buffer at pH 8, allowing the stain to dry out at 40-50 C, washing well, drying and covering. Controls were carried out on material fixed in formalin and treated with nucleases or proteolytic enzymes prior to embedding, and staining.     

Histochemical applications of two phenanthridinium compounds

The fluorescent compounds ethidium monoazide and ethidium bromide were found to react intensely with nucleic acids of fixed, paraffin embedded tissues of rat and mouse. For routine staining, 10(-5) M solutions of ethidium bromide and its monoazide analogue were virtually identical in their reactions. Fresh frozen sections of the tissues reacted in the same manner as fixed, paraffin embedded samples. Fluorescence of DNA and RNA in rat pancreas could be selectively abolished by taking advantage of the greater sensitivity of RNA to acid hydrolysis. Hydrolysis in aqueous solutions (1 N HCl at 55-60 C) abolished RNA fluorescence in 5 min, whereas 20 min or longer were required to destroy DNA fluorescence. DNA fluorescence was selectively abolished by 3 hr in 0.1 N HCl in anhydrous methanol while the RNA remained unaffected. Rat pancreas stained with the 10(-5) M ethidium compounds below pH 5.0 showed reduced RNA fluorescence, but the DNA continued to fluoresce brightly at pH 0.6. Reducing the pH of the staining solution to pH 1.0, therefore, was an additional method of selectively abolishing RNA fluorescence. Ethidium solutions in 5.0 M NaCl at pH 5.0 had little effect on DNA or RNA fluorescence. This new method of examining nucleic acids in fixed tissue samples opens new approaches to the histochemistry of these substances. The method also offers new possibilities for the study of mutagenic drug-DNA interactions.     

Immunocytochemical detection of sulphonylated DNA in tissue sections. An alternative to Feulgen staining of DNA

We report here on a new sensitive and highly specific DNA staining technique which we have called sulpho-DNA staining. DNA staining is based on a sulphonylation reaction of 2'-deoxycytidine or cytidine that takes place in the 6th position of cytosine with ensuing immunodetection of the sulphonylated DNA. The specificity of DNA staining is introduced by the use of an antibody recognizing only modified DNA but not modified RNA, by recourse to an additional acid hydrolysis step which destroys RNA but not DNA. We describe here the optimal conditions for the sulphonylation of DNA using O-methylhydroxylamine and metabisulphite as reactants. The new DNA stain labels all nuclei in either normal human tissue or in tumor cells. For nuclear DNA the staining signal is higher for the sulpho-DNA staining than for the Feulgen staining for nuclear DNA. This new DNA staining technique is suitable for use on tissue sections as well as on cytosmears.     

Cytochemical observations on mannose-specific binding sites for horseradish peroxidase in liver sinusoidal cells

Paraformaldehyde-fixed, frozen sections of the liver of rats were processed for the detection of mannose-specific binding sites of horseradish peroxidase (HRP) by a method reported previously, with some modifications resulting in a more intense binding reaction. Before staining for peroxidase activity, the sections were held in buffered solutions of physiological saline at different temperatures and pH's, and in the presence or absence of added Ca2+, mannose or galactose. The gradual decrease and final disappearance of the binding reaction were observed. The release of HRP from the binding sites as determined by the disappearance of the cytochemical reaction was 50-100 times faster at 22 degrees C than at 4 degrees C and was 5-10 times faster at 37 degrees C than at 22 degrees C. The release was approximately twice as fast at pH 7.0 than at pH 9.0 and 20-30 times faster at pH 6.0 than at pH 7.0. The release of HRP was 10-15 times faster in the absence of 1 mM Ca2+ in the buffer solution and was approximately 100 times faster in the presence of 0.1 M D-mannose as compared to 0.1 M D-galactose. Pretreatment of the sections with trypsin abolished the binding reaction whereas neuraminidase, phospholipases A2 and C, and chondroitinase ABC were without effect. An acidic isoenzyme of HRP, Sigma type VIII, was bound more intensely and more widely to liver sinusoidal cells than another acidic isoenzyme, Sigma type VII, a basic isoenzyme, Sigma type IX, and the routinely used preparation, Sigma type VI. The effect of the temperature on the binding reaction was re-examined with an improved procedure. In contradistinction to the previous finding, strong binding of HRP after 2-4 h incubation at 4 degrees C was observed.     

Histochemical Applications of Two Phenanthridinium Compounds

The fluorescent compounds ethidium monoazide and ethidium bromide were found to react intensely with nucleic acids of fixed, paraffin embedded tissues of rat and mouse. For routine staining, 10^-5 M solutions of ethidium bromide and its monoazide analogue were virtually identical in their reactions. Fresh frozen sections of the tissues reacted in the same manner as fixed, paraffin embedded samples. Fluorescence of DNA and RNA in rat pancreas could be selectively abolished by taking advantage of the greater sensitivity of RNA to acid hydrolysis. Hydrolysis in aqueous solutions (1 N HCl at 55-60 C) abolished RNA fluorescence in 5 min, whereas 20 min or longer were required to destroy DNA fluorescence. DNA fluorescence was selectively abolished by 3 hr in 0.1 N HCl in anhydrous methanol while the RNA remained unaffected. Rat pancreas stained with the 10^-5 M ethidium compounds below pH 5.0 showed reduced RNA fluorescence, but the DNA continued to fluoresce brightly at pH 0.6. Reducing the pH of the staining solution to pH 1.0, therefore, was an additional method of selectively abolishing RNA fluorescence. Ethidium solutions in 5.0 M NaCl at pH 5.0 had little effect on DNA or RNA fluorescence. This new method of examining nucleic acids in fixed tissue samples opens new approaches to the histochemistry of these substances. The method also offers new possibilities for the study of mutagenic drug-DNA interactions.     

Osteopontin is histochemically detected by the AgNOR acid-silver staining

Silver nitrate staining of decalcified bone sections is known to reveal osteocyte canaliculi and cement lines. Nucleolar Organising Regions (NOR) are part of the nucleolus, containing argyrophilic proteins (nucleoclin/C23, nucleophosmin/B23) that can be identified by silver staining at low pH. The aim of this study was to clarify the mechanism explaining why AgNOR staining also reveals osteocyte canaliculi. Human bone and kidney sections were processed for silver staining at light and electron microscopy with a modified method used to identify AgNOR. Sections were processed in parallel for immunohistochemistry with an antibody direct against osteopontin. Protein extraction was done in the renal cortex and decalcified bone and the proteins were separated by western blotting. Purified hOPN was also used as a control. Proteins were electro-transferred on polyvinylidene difluoride membranes and stained for AgNOR proteins. In bone, Ag staining identified AgNOR in cell nuclei, as well as in osteocyte canaliculi, cement and resting lines. In the distal convoluted tubules of the kidney, silver deposits were also observed in cytoplasmic granules on the apical side of the cells. Immunolocalization of osteopontin closely matched with all these locations in bone and kidney. Ag staining of membranes at low pH revealed bands for NOR proteins and 56 KDa (kidney), 60KDa (purified hOPN) and 75 KDa (bone) bands that corresponded to osteopontin. NOR proteins and osteopontin are proteins containing aspartic acid rich regions that can bind Ag. Staining protocols using silver nitrate at low pH can identify these proteins on histological sections or membranes.     

A simple method for fixation and microdissection of frozen fresh tissue sections for molecular cytogenetic analysis of cancers.

Microdissection has been widely used for procuring DNA from specific microscopic regions of formalin fixed, paraffin embedded tissue sections. We have developed a method for fixation and microdissection of frozen fresh biopsy tissue sections. Five micrometer frozen fresh tissue sections were fixed with ethanol and stored at room temperature. Well defined regions from hematoxylin and eosin (H & E) stained or unstained sections were briefly steamed and microdissected using a needle. The dissected tissue was digested with proteinase K and DNA was isolated. Whole genome amplifications were obtained by degenerate oligonucleotide primed polymerase chain reaction (DOP-PCR) from these samples. The reliability of this technique was demonstrated by comparing conventional comparative genomic hybridization (CGH) with DOP-PCR-CGH. The advantages of this method are that frozen fresh sections can be fixed easily and stored for more than 4 years, it is easy to microdissect and pick-up very minute regions (0.1 mm(2)), and it is rapid; microdissection and purification can be accomplished within 3 h. Using DNA from microdissected sections, DOP-PCR-CGH revealed genetic abnormalities more accurately than conventional CGH. Although this novel method was demonstrated using DOP-PCR-CGH, we believe that it will be useful for other genetic analyses of specific small regions and cell populations. We also observed whether storage time, H & E staining and crude DNA extracts affected the quality of amplified DNA. DNA integrity was maintained for at least 49 months in ethanol fixed sections that were stored at room temperature, but DNA was gradually degraded after one month if the ethanol fixed sections had been H & E stained and stored. When crude DNA extracts from H & E stained sections were used, the size of the DOP-PCR product was reduced. Our study suggests that ethanol fixed tissue sections may be stored at room temperature for at least 4 years without DNA degradation, the H & E stains may not affect the quality of amplified DNA, but H & E or other components in the staining process may reduce the size of DOP-PCR product, which is critical for the quality of CGH hybridization.     

Cytochemical Method to Localize Acidic Nuclear Proteins

Fast green FCF was used to localize acidic nuclear proteins in sections of young flower buds of Limnophyton obtusifolium (L.) Miq. After extracting nucleic acids, the slides were stained at hydrogen ion concentrations ranging from pH 2.6 to 9.0. At pH 5.0 and 8.0 staining is confined to the nucleus with no cytoplasmic reaction. Staining intensity is greater at pH 5.0 than at pH 8.0. The proteins responding to fast green at pH 8.0 are basic proteins. The positive reaction at pH 5.0 is attributed to acidic nuclear proteins. These findings are confirmed by control preparations. Acetylated slides and slides treated with 0.25 N HCl were unstained at pH 8.0 but staining at pH 5.0 was undisturbed. Dilute alkali (0.003 N NaOH) reduced staining intensity at pH 5.0 but had no effect at pH 8.0. Methylated slides did not stain at pH 5.0, but at pH 8.0 staining was unaffected. Deamination blocked staining at both pH's. It is concluded that fast green at pH 5.0 specifically binds with acidic nuclear proteins.     

The staining behavior of oocyte cytoplasm with the alcoholic Feulgen variant and with methyl green

Summary A variant of the Feulgen reaction which has been proposed as a method for demonstrating cytoplasmic DNA in oocytes has been tested on ovarian material from a variety of species. While Schiff positive staining was developed, this was not removable by pretreatment with DNase and could be reproduced by using oxidants used in the pseudoplasmal reaction. This method was not considered useful for demonstrating cytoplasmic DNA.When chloroform extracted solutions of methyl green were used to stain ovaries, cytoplasmic staining identical in pattern to that obtained with other basic dyes was observed. The cytoplasmic staining was prevented by pretreatment of sections with RNase, but was not affected by DNase pretreatment. In somatic cells with high concentrations of cytoplasmic RNA, only nuclear staining was observed. This nuclear staining was labile to DNase but not to RNase.This work was supported by U.S. Public Health Service grants GM-10003-03 and K-3-6176-03.Contribution number 376 of the Bermuda Biological Station.