Additional Schiff-Type Reagents for Use in Cytochemistry

Twenty-four new Schiff-type reagents were discovered in a survey of 140 different dyes. These dyes include acid fuchsin, acridine yellow, acriflavine hydrochloride, azure C., Bismarck brown R, Bismarck brown Y, celestine blue B, chrysoidine 3R, chrysoidine Y extra, cresyl violet, crystal violet, gentian violet, methylene blue, neutral violet, phenosafranin, phosphine GN, proflavine, toluidine blue O, and toluylene blue. Positive results obtained with crystal violet and a few samples of methylene blue are considered due to impurities. Various chemical extractions, aldehyde blocking reagents, and enzymatic treatments were used to verify the aldehyde specificity of the above dye-SO₂, reagents as well as azure A, brilliant cresyl blue, neutral red, safranin O, and thionin which have been mentioned by other workers. These reagents were tested in the Feulgen reaction for DNA and the PAS reaction for polysaccharides. Absorption curves were obtained from individual nuclei stained for DNA. The absorption peaks ranged from 450 mμ, to 630 mμ. depending on the dye studied. The Feulgen reaction could be followed by the PAS reaction or vice versa in mouse intestine using reactive dyes of complementary colors. The evidence indicates that a potential Schiff-type reagent must have at least one free NH₂ group on the dye molecule.     

Studies of Chromosome Banding with Giemsa in Vicia faba and Allium cepa

Giemsa dye is a complex mixture containing methylene blue, its oxidation products-azure Ⅰ, Ⅱ, Ⅲ, and their eosinate. The results of our experiments have demonstrated that staining with methylene blue alone can give a faint trace of banding as well as azure Ⅰ, Ⅱ. No bands are obtained with eosin. Nevertheless, good chromosome bandings can be often produced by staining with methylene blue-eosinate or azure Ⅱ-eosinate. These data indicate that eosinate has an important effect for the formation of C-banding on plant chromosomes. In our experiments, the treatments of chromosomes with trypsin or papain have also resulted in good C-banding pattern when slides are stained with Giemsa. We found that the slides untreated with proteinase showed homogeneous intense chromosome staining and, on the contrary, the slides treated with proteinase led to palestaining chromosomes and presenting bandings. It has shown that proteinase, especially trypsin, not only can remove a large amount of chromosomal protein but also can remove DNA and results in C-bandings. Treated properly with trypsin and followed by the Feulgen staining, chromosomes can also produce the C-bandings, but chromosomes treated overtime with trypsin are stained more palely in Feulgen reaction or lead to colourlessness. The above results have further proved that trypsin technique removes large amounts of chromosome DNA and removes less from the C-band regions than from the non-band regions. In this paper we mainly discussed the effects of protein on mechanism of plant chromosome banding. We consider that the production of plant C-banding is probably due to the differential accessibility of nucleoprotein between euehromatin and heteroehromatin regions. It brings about selective removal of nucleoprotein from the chromosome arms. We have compared the effect of trypsin with papain and pepsin on producing bands. Good bands are produced by Giemsa staining chromosomes with trypsin, but no bands are obtained by staining chromosomes treated with pepsin. So the results have expressed that histones are possibly playing more important role in C-bandings.     

Cytophotometric analysis of neuronal chromatin and RNA changes in oxotremorine-treated rats

Neuronal nucleic acid responses were examined within the rat striatum and sensorimotor cortex (layer V) following single intraperitoneal injections of the central cholinergic-muscarinic agonist oxotremorine (0.1, 0.7, or 1.0 mg/kg). After stoichiometric Feulgen and azure B staining of brain sections, scanning-integrating microdensitometry was used to quantify Feulgen-deoxyribonucleic acid levels, changes in the susceptibility of chromatin to Feulgen acid hydrolysis (F-DNA yield) and azure B-ribonucleic acid (RNA) content of neurons on an individual basis. Changes in neuronal nuclear and nucleolar volumes were also determined histometrically. Within the striatum and sensorimotor cortex, oxotremorine produced marked dose-dependent elevations in both F-DNA yield and RNA content. These metabolic increases were typically paralleled by elevations in nuclear and nucleolar volumes. The data demonstrate that the oxotremorine-induced central muscarinic activation is associated with dose-related enhancements in neuronal chromatin template activity, RNA content, and protein synthetic capacity.     

Romanowsky dyes and the Romanowsky-Giemsa effect. 3. Microspectrophotometric studies of Romanowsky-Giemsa staining. Spectroscopic evidence of a DNA-azure B-eosin Y complex producing the Romanowsky-Giemsa effect

The Romanowsky-Giemsa staining (RG staining) has been studied by means of microspectrophotometry using various staining conditions. As cell material we employed in our model experiments mouse fibroblasts, LM cells. They show a distinct Romanowsky-Giemsa staining pattern. The RG staining was performed with the chemical pure dye stuffs azure B and eosin Y. In addition we stained the cells separately with azure B or eosin Y. Staining parameters were pH value, dye concentration, staining time etc. Besides normal LM cells we also studied cells after RNA or DNA digestion. The spectra of the various cell species were measured with a self constructed microspectrophotometer by photon counting technique. The optical ray pass and the diagramm of electronics are briefly discussed. The nucleus of RG stained LM cells, pH congruent to 7, is purple, the cytoplasm blue. After DNA or RNA digestion the purple respectively blue coloration in the nucleus or the cytoplasm completely disappeares. Therefore DNA and RNA are the preferentially stained biological substrates. In the spectrum of RG stained nuclei, pH congruent to 7, three absorption bands are distinguishable: They are A1 (15400 cm-1, 649 nm), A2 (16800 cm-1, 595 nm) the absorption bands of DNA-bound monomers and dimers of azure B and RB (18100 cm-1, 552 nm) the distinct intense Romanowsky band. Our extensive experimental material shows clearly that RB is produced by a complex of DNA, higher polymers of azure B (degree of association p greater than 2) and eosin Y. The complex is primarily held together by electrostatic interaction: inding of polymer azure B cations to the polyanion DNA generates positively charged binding sites in the DNA-azure B complex which are subsequently occupied by eosin Y anions. It can be spectroscopically shown that the electronic states of the azure B polymers and the attached eosin Y interact. By this interaction the absorption of eosin Y is red shifted and of the azure B polymers blue shifted. The absorption bands of both molecular species overlap and generate the Romanowsky band. Its strong maximum at 18100 cm-1 is due to the eosin Y part of the DNA-azure B-eosin Y complex. The discussed red shift of the eosin Y absorption is the main reason for the purple coloration of RG stained nuclei. Using a special technique it was possible to prepare an artificial DNA-azure B-eosin Y complex with calf thymus DNA as a model nucleic acid and the two dye stuffs azure B and eosin Y.(ABSTRACT TRUNCATED AT 400 WORDS)     

Tritium labelling and cytochemistry of extra DNA in Acheta

Females of Acheta domesticus were injected with H³-thymidine and H³-uridine at various stages of development in order to study DNA and RNA synthesis in the DNA body present in the oocytes. Staining with alkaline fast green, azure B and the Feulgen reaction were employed as cytochemical tests. The following main results were obtained.

1. The DNA body appears in the oogonia at interphase as a Feulgen positive spherical structure 2 microns in diameter and is seen in subsequent mitotic divisions as a slightly smaller structure of variable shape. H³-thymidine autoradiography discloses that the DNA present in this body is synthesised at a different time from the chromosomal DNA.
2. At interphase and during the early prophase of meiosis the DNA body increases in size becoming a large Feulgen positive sphere 6 microns in diameter. Small nucleoli are present within this body. The DNA of the body is complexed with histone as revealed by alkaline fast green staining. H³-thymidine labelling discloses that it is at these stages that the bulk of the DNA synthesis takes place in the body.
3. Every oocyte contains a DNA body, and no body of comparable size or shape seems to be present in the male meiotic prophase.
4. At pachytene and diplotene the DNA body acquires the appearance of a “puff”. Two zones can be distinguished inside the DNA body: (1) an inner core of DNA and an outer shell of RNA. The inner core is Feulgen positive and stains light green with azure B, the outer shell is Feulgen negative and stains purple-violet with azure B, as does the cytoplasm. From the inner DNA core many Feulgen positive fibrils radiate into the outer RNA shell. These fibrils appear unstained or slightly greenish with Azure B, forming a transparent network in a purple-violet background. This gives the body the typical appearance of a “puff”. H³-uridine incorporation reveals that the RNA synthesis occurs in the outer RNA shell of the body and in the chromosomes. RNase treatment removes the H³-uridine incorporated into these regions.
5. At the end of diplotene the DNA body starts to disintegrate. The DNA core breaks up into minor components and the outer RNA zone also begins to disintegrate. By late diplotene the whole body has vanished, releasing DNA, histone and RNA into the nucleus. Subsequently the nuclear envelope disintegrates as it regularly does at the end of prophase of meiosis.
6. The simplest interpretation of the above results is that the DNA body represents hundreds of copies of the genes of the nucleolar organizing region.

     

Feulgen Reaction for Thymonucleic Acid

The importance of thymonucleic acid in tissues is discussed briefly. The technic of the Feulgen reaction which has been employed in photometric histochemical observations in tumors is described. The evidence for the specificity of the Feulgen reaction is reviewed and additional experimental observations are reported. The staining of tissues by the Feulgen reaction is compared with that of hematoxylin, basic fuchsia, and fuchsin-sulfurous-acid reagent in which the color had been developed by the addition of formaldehyde. The stains were compared with respect to (1) the selective staining of the cytologic components of the tissues, (2) the staining of tissues following varying intervals of acid hydrolysis and (3) the photometric determination of the fading of the stained tissue by a carbon arc light. The photometric apparatus employed is suitable for the study of many problems on the staining of tissues. Staining by the Feulgen reaction is different from that of both the basic fuchsin from which the fuchsin-sulfurous-acid was prepared and from that of the product of the fuchsin-sulfurous-acid which had reacted with an aldehyde. Under carefully controlled conditions, the Feulgen technic is a relatively specific histochemical reaction for thymonucleic acid.     

Some Evidence for the Specificity of the Feulgen Reaction

Carr has attacked the specificity of the Feulgen reaction on three grounds: that the chromosomes are adsorbents capable of regenerating the color of the Schiff reagent; that selectivity for the nucleus depends on destruction of cytoplasm by acid hydrolysis preceding staining; and that the reaction is not blocked by SO₂ water, as he says it should be if staining occurs by a chemical reaction. The first point was tested by staining chromosomes treated with nuclease. They were Feulgen negative, but their protein basis remained intact. The second point was tested by hydrolyzing fixed tissues, washing off solutes, drying, and comparing weight loss with controls. As differences were negligible, the fixed cytoplasm must not have been made soluble by hydrolysis. Carr's third point was not tested experimentally. It is concluded that these objections to specificity of the Feulgen reaction are not valid.     

Feulgen hydrolysis and chromosome banding in Chilocorus (Coleoptera: Coccinellidae).

Prolonged Feulgen hydrolysis of chromosomes of Chilocorus orbus Csy. and C. stigma Say produces banding patterns that are the reverse of those revealed with quinacrine; brightly fluorescing regions are unstained, but nonfluorescent regions remain relatively darkly stained. This differential reactivity at hydrolysis times that otherwise yield intense Feulgen staining confirms the need for caution in the determination of DNA values with the Feulgen reaction in material with well-defined quinacrine bands. The coincidence of DNA-specific Feulgen bands with Q-, G-, and C-bands supports the view that, in Chilocorus at least, bands reflect differences in DNA composition along the chromosome.     

Cytochemical properties of euchromatin and heterochromatin

Two classic cytochemical tests, the Feulgen-Schiff reaction and Toluidine Blue basophilia, have been employed for investigating the differential characteristics of heterochromatin and euchromatin. Differences have been detected in the Feulgen hydrolysis kinetics, the Feulgen absorption spectrum, the image analysis of Feulgen-stained material, and the binding of Toluidine Blue under ordinary and Mg2+ competitive staining conditions. The differences are assumed to be a function of the composition and stereo-arrangement of the DNA and DNA-protein complexes present in these chromatin types and are possibly associated with physiological activities whose whole meaning is far from being clear. Differences in optical retardations in Toluidine Blue-stained material were also found. These are interpreted as being due to chromatin packing state and selective removal of histones promoted by the acetic acid-ethanol fixative.     

The Oxidation Products of Methylene Blue

The mechanism of the oxidation of methylene blue varies with the conditions. The formation of trimethyl thionin (azure B) and of asymmetrical dimethyl thionolin (azure A) is followed under alkaline conditions by that of dimethyl thionin (methylene violet) and under acid conditions by that of monomethyl thionin (named by authors azure C).

Simple and practical methods are given for the preparation of azure A and azure C. The latter product, which has not been obtained from methylene blue hitherto, has valuable staining properties as a nuclear and bacterial stain in tissue and may also be employed satisfactorily as a substitute for azure A in the MacNeal tetrachrome formula as a blood stain or substitute for the Giemsa stain.

Azure B has no particular merit in staining.

Azure C proves to be a very valuable stain. A procedure is given for its use with eosin Y and orange II as counterstains, by which it is possible to demonstrate bacteria in tissue and at the same time the cytological elements of the tissue.     

Standardization of the Feulgen-Schiff technique. Staining characteristics of pure fuchsin dyes; a cytophotometric investigation

Four fuchsin analogues (Pararosaniline, Rosaniline. Magenta II and New Fuchsin) usually found in Basic Fuchsin have been applied as chemically pure dyes to the Feulgen-technique. Total nuclear absorption and wavelength of the absorption maximum were measured by microspectrophotometry in Feulgen stained cytological and plastic embedded histological liver samples, and in lymphocyte nuclei in human peripheral blood smears; absorption spectra of Feulgen stained DNA-polyacrylamide films were determined by spectrophotometry. The grey value distribution of tetraploid liver cell nuclei was calculated with an image analyzer. The staining characteristics of the pure dyes were compared to commercial fuchsin samples from various suppliers. Reverse phase thin layer chromatography was used for characterization and qualitative separation of commercial batches. Pure fuchsin analogues were all equally suitable for Feulgen staining: with respect of staining intensity all pure fuchsin dyes gave nearly identical results with a bathochromic shift of the absorption maximum from Pararosaniline to New Fuchsin of about 8 microns. Differences in staining results observed among the commercial dyes were due to varying dye content, contamination with an acridine-like fluorescent compound or simply mislabelling of samples. Pure Pararosaniline is recommended for a standard Feulgen technique.     

Quantitative cytochemical determination of desoxyribonucleic acid with the Feulgen nucleal reaction

The possibility of using the Feulgen nucleal reaction for a quantitative cytochemical estimation of desoxyribonucleic acid (DNA) was investigated. The intensity of the reaction in nuclei was determined by absorption measurements with the microscope. The accuracy of such measurements was tested by comparison with measurements on the same material with a Beckman spectrophotometer. The values obtained with the microscope agreed within a few per cent with those obtained with the Beckman spectrophotometer. Furthermore, the errors introduced by uneven distribution of absorbing material, by variations in the numerical aperture of the system, and by variation in the area used on the phototube were investigated empirically. The following variables were studied with regard to their effect on the intensity of the Feulgen reaction: type of fixation, time of hydrolysis after acetic acid-alcohol and formalin fixation, time of staining in leucobasic fuchsin, method of preparation of leucobasic fuchsin. The intensity of the Feulgen reaction in liver and erythrocyte nuclei of various vertebrates, fixed in acetic acid-alcohol, was then compared with the DNA content of these nuclei as determined by chemical analysis on a known number of nuclei. The intensity of the reaction was found to be proportional to the DNA content of the nuclei, if nuclei of similar structure and DNA concentration were compared. In nuclei of different structure and DNA concentration (i.e. liver and erythrocyte nuclei), fixed in acetic acid-alcohol, the intensity of the Feulgen reaction was, however, not proportional to the DNA content. This difficulty was overcome by isolating nuclei in sucrose and by fixing them in formalin. Uniform distribution of DNA and therefore uniform coloring after the Feulgen reaction were thus obtained. In such nuclei with uniform distribution of absorbing material the Feulgen reaction was found to be proportional to the DNA content of nuclei, even if they differed greatly in their DNA concentration. The Feulgen nucleal reaction is not quantitative in an absolute sense. For absolute determinations nuclei of known DNA content must be treated together with the unknown material to serve as standard. From these data it therefore appears possible to determine cytochemically relative amounts of DNA in cellular structures by measuring their absorption after treatment with the Feulgen nucleal reaction.     

The Specificity of the Feulgen Reaction for Thymonucleic Acid

The results of experiments on the specificity of the Feulgen reaction for thymonucleic acid do not substantiate the observations of Carr. The staining is not localized in the nucleus because of the destruction of cytoplasmic constituents following acid hydrolysis or because of the absorbing power of chromatin, since the cytoplasm and nucleolus can still be stained by numerous dyes. The effects of factors such as the acid hydrolysis and sulfurous acid washing baths upon the cytologic distribution of dye were studied on tissues stained with (1) fuchsin-sulfurous-acid (Feulgen) reagent, (2) fuchsin-sulfurous-acid reagent colorized by the addition of formaldehyde, (3) basic fuchsin in one-tenth normal HCl, and (4) basic fuchsin in distilled water. Under comparable conditions, important differences between these stains were found in the effects of preliminary hydrolysis; rapidity of staining and destaining; extractability of dye from tissues by water, alcohol, and sulfurous acid solution; rate of fading from exposure to light; localization of stain in tissues; and differences in hue. After treating tissues with desoxyribonuclease, an enzyme which acts only upon thymonucleic acid, cells do not stain with the Feulgen technic. Following removal of nucleic acid from chromatin by hydrolysis, attempts to demonstrate an absorption of thymonucleic acid upon the residual nuclear protein were unsuccessful.

The evidence for and against the specificity is discussed. In agreement with most other investigators, on the basis of the evidence in the literature as well as these experiments, it is concluded that when properly controlled the Feulgen reaction is relatively specific for thymonucleic acid.     

Feulgen Densitometry: Importance of a Stringent Hydrolysis Regime

Abstract: Feulgen densitometry is still a widely used method for DNA content measurements, but experimental procedures and results are often controversial. The present note is concerned with a recent report in the literature that optimum Feulgen staining required a remarkably longer hydrolysis time with 5 M HCI in Dactylis glomerata L. than in Hordeum vulgare L. (i.e., 62 min versus 20 min at 25 C). As this result is prone to question the usual practice of maintaining unified hydrolysis times for test material and internal standard, we established hydrolysis curves for D. glomerata, H. vulgare, Pisum sativum L. and Allium cepa L. at 20 C and 25C for 0 to 100 min. No striking differences between the species and, in particular, between Doctylis and Hordeum were found. Optimum staining occurred after 60 min with hydrolysis at 20 C and after 25 min at 25 C. It is strongly recommended to conduct the quantitative Feulgen reaction at a precisely controlled temperature instead of an inexact room temperature. The broader plateau of optimum staining at 20 C makes this regime preferable.     

Standardization of the Feulgen-Schiff technique

Summary Four fuchsin analogues (Pararosaniline, Rosaniline, Magenta II and New Fuchsin) usually found in Basic Fuchsin have been applied as chemically pure dyes to the Feulgen-technique. Total nuclear absorption and wavelength of the absorption maximum were measured by microspectrophotometry in Feulgen stained cytological and plastic embedded histological liver samples, and in lymphocyte nuclei in human peripheral blood smears; absorption spectra of Feulgen stained DNA-polyacrylamide films were determined by spectrophotometry. The grey value distribution of tetraploid liver cell nuclei was calculated with an image analyzer. The staining characteristics of the pure dyes were compared to commercial fuchsin samples from various suppliers. Reverse phase thin layer chromatography was used for characterization and qualitative separation of commercial batches.Pure fuchsin analogues were all equally suitable for Feulgen staining: with respect of staining intensity all pure fuchsin dyes gave nearly identical results with a bathochromic shift of the absorption maximum from Pararosaniline to New Fuchsin of about 8 m.Differences in staining results observed among the commercial dyes were due to varying dye content, contamination with an acridine-like fluorescent compound or simply mislabelling of samples. Pure Pararosaniline is recommended for a standard Feulgen technique.     

Some observations on the mechanisms of blocking of nuclear staining by cisplatin

Summary The effect of cisplatin (cis-dichloro-diamminoplatinum II) treatment on staining of nuclei with various basic dyes and with the Feulgen reaction has been studied. Although cisplatin is reported to show negligible reaction with DNA phosphates, it has a substantial blocking effect on staining with most dyes. Short treatment with cisplatin results in binding mainly to guanine bases of DNA, causing partial blocking of the Feulgen reaction and almost complete blocking of ethidium intercalation; binding of neutral red and crystal violet is enhanced, apparently as a result of cisplatin-induced denaturation of DNA. Very prolonged cisplatin treatment does not completely block the Feulgen reaction, indicating that reaction of cisplatin with purine bases is not complete. Since attachment of cisplatin to DNA bases is unlikely to prevent binding of most basic dyes, it is suggested that the blocking of their staining may result from steric hindrance caused by formation of DNA-protein cross-links by cisplatin. Whatever the mechanism, it is incapable of producing complete blocking of staining with certain dyes. As a practical tool, it appears that rapid and almost complete blocking of staining by cisplatin may be used as an indicator of intercalative binding of dyes to DNA.     

Acid alcoholic brilliant cresyl blue stain for gastric and other mucins

Summary Some but not all samples of brilliant cresyl blue (6-methyl-7-dimethylamino-2-phenoxazin chloride) under C. I. No. 51010 in Conn's Biological Stains when dissolved at 1% level in 50–70% alcohol containing 1% concentrated (12 N) hydrochloric acid, stain (in 30 min) a wide variety of human and laboratory animal mucins blue black on an almost unstained background. The mucoprotein of the gastric surface epithelium and of the peptic gland neck cells of several species reacts strongly. A 16 hr 60° C methylation in 0.1 M methyl-sulfuric acid in methanol is required to block the staining of these gastric and some intestinal mucins, while 1–2 hr intervals suffice to prevent the staining of mast cells, cartilage and metachromatic sulfomucins generally. Saponification (1% KOH/70% alcohol, 20min) does not restore staining in either location group, indicating that sulfate mucins are probably reacting in both.Most other basic dyes fail to stain mucins from acid alcohol solutions: azure A, toluidine blue, resorcin blue, orcein, resorufin, azoresorufin brown, azolitmin, lacmoid, gallocyanin, Nile blue, methylene green, pararosanilin, crystal violet, Victoria blue R. Some staining occurred with one of three lots of Victoria blue B, with two lots of Victoria blue 4 R and with one lot each of Bernthsen's methylene violet, elastin violet PR and elastin purple PP.The stain may be preceded by the Feulgen reaction to give red nuclei, or followed by a brief collagen stain in an alcoholic acid fuchsin (0.05–0.1%), picric acid (1.5%) solution.Presented before the Symposium of the Histochemische Gesellschaft in Hamburg, 28. September 1968.Supported by National Cancer Institute Grant No. C-4816, National Institutes of Health.     

Effects of different fuchsin analogs on the Feulgen reaction

The Feulgen reaction is used for cytophotometric quantitation of nuclear DNA. Schiff's reagents used in the Feulgen reaction usually are prepared from basic fuchsin, a variable mixture of four triaminotriphenylmethane analogs. The effect of the several fuchsin analogs on the quality of Schiff's staining of hydrolyzed DNA is not known. In this investigation Schiff's reagents prepared from relatively pure fuchsin analogs were used to determine whether different fuchsin analogs affect the absorbance of the Schiff's reagent-DNA complexes formed in solution. It has been determined that the complex formed by pararosaniline-Schiff's reagent and hydrolyzed DNA exhibits lower absorption than do corresponding complexes formed by Schiff's reagents prepared from magenta II or from new fuchsin.     

Hot hydrochloric acid hydrolysis and UV Feulgen staining of rat liver sections fixed in CRAF and CRAF-like fixative.

Sections of rat liver fixed in CRAF III and Nawaschin's fixative in Dutt's modification were subjected to hydrolysis in 1N HCl at 60 degrees C for different periods of time and to Schiff's staining according to the UV Feulgen technique. The study showed that Feulgen reaction intensity depends upon time of hydrolysis, optimum coloration being possible only after 10-15 min of hydrolysis. Prolongation of hydrolysis beyond this time produced decreased staining intensity which is retained for further 35 min of hydrolysis thus forming a plateau. Further prolongation of hydrolysis results in gradual deterioration of the staining intensity which culminates in utterly pale coloration of the nuclei after one hour's hydrolysis. A possible explanation for this phenomena is suggested.     

ULTRASTRUCTURE AND CYTOCHEMISTRY OF METABOLIC DNA IN TIPULA

A DNA body is present in the females of the fly Tipula oleracea and is formed in contact with the sex chromosomes in the oogonial interphases. At each oogonial mitosis, the DNA body follows the chromosomes to one anaphase group and is included in one of the telophase nuclei. The body increases appreciably in size during the interphase of meiosis. All oocytes have the body, but only a few nurse cells possess it. The DNA body synthesizes its DNA at a different time than the chromosomes, as is shown by incorporation of tritiated thymidine, and contains 59% of the DNA of the nucleus, as is disclosed by spectrophotometric measurements. At late diplotene the DNA body disintegrates, releasing its DNA into either the nucleus or the cytoplasm. When studied in the electron microscope, the DNA body appears composed of a tight mass of intertwined fibrils. Demonstration that the main mass of the body is composed of DNA is obtained from cytochemical tests which reveal that the DNA body is Feulgen positive, stains green with azure B, incorporates H³-thymidine, and after digestion with DNase is Feulgen negative. The DNA of the body is complexed with histone, like the DNA of the chromosomes, as is revealed by an intense alkaline fast green staining. Electron microscope examination of oocytes reveals that one side of the DNA body is in close contact with the nuclear envelope and that the other side possesses an outer shell composed mainly of particles 150 to 250 A in diameter. Between the outer shell and the chromosomes there is a band of low electron opacity, 4000 to 7000 A thick. In the light microscope, this light band together with the outer shell is Feulgen negative and stains violet with azure B; this is confirmation of the presence of RNA. In the oocytes the nucleoli are found inside the DNA body. These nucleoli have a nucleolonema composed mainly of particles 150 to 250 A. The nucleoli are Feulgen negative, alkaline fast green negative, stain violet with azure B, and do not stain with azure B after RNase digestion, thus confirming their RNA content. The presence of the nucleoli inside the DNA body and of a band of RNA between the body and the chromosomes is indicative of a high RNA synthetic activity. Since the DNA of the body is complexed with histone, as in the chromosomes, and the nucleoli are located inside the body, the simplest interpretation of the DNA body is that it represents hundreds of copies of the operons of the nucleolar organizing region or neighboring regions. The situation found in Tipula has several basic features in common with the polytene chromosomes of other Diptera and with the hundreds of nucleoli present in Triturus oocytes. In all three cases, genes seem to be copied hundreds of times but are kept in different types of packages. A DNA body like the one in Tipula oleracea is found in other species of Diptera and in the Coleoptera. There is no indication, from the present investigation, that the DNA body is in any way associated with a virus.