THE BASE COMPOSITION OF NUCLEIC ACIDS IN CHROMOSOMES, PUFFS, NUCLEOLI, AND CYTOPLASM OF CHIRONOMUS SALIVARY GLAND CELLS

The base composition of RNA from individually isolated giant chromosomes, puffed chromosome segments, nucleoli, and samples of cytoplasm from Chironomus salivary gland cells was determined by microelectrophoresis. Data on the adenine: guanine quotient of the chromosomal DNA were also obtained. The results show that: 1) Chromosomal, nucleolar, and cytoplasmic RNA's differ significantly from each other in base composition. 2) Nucleolar and cytoplasmic RNA's, in spite of the difference, show great similarities with regard to the base composition and are both rich in adenine and uracil. 3) The RNA extracted from chromosome I differs significantly from the RNA's extracted from different segments of chromosome IV, and the latter differ significantly from each other. 4) The values for the RNA: DNA quotients of chromosome segments parallel the development of synthetically active genes, so-called Balbiani rings. 5) The chromosomal RNA does not show a base symmetry in any of the investigated cases, nor is the content of guanine + cytosine the same as that for DNA. The first of these two facts excludes the possibility that the chromosomal RNA is a complete copy of both strands of the chromosomal DNA. In spite of the difference in guanine + cytosine content between the two nucleic acids the RNA may still partly or completely be a single strand copy depending upon how representative the DNA values are for the synthetically active DNA.     

NUCLEOLAR-DERIVED RIBONUCLEIC ACID IN CHROMOSOMES, NUCLEAR SAP, AND CYTOPLASM OF CHIRONOMUS TENTANS SALIVARY GLAND CELLS

The distribution of monodisperse high molecular weight RNA (38, 30, 28, 23, and 18S RNA) was studied in the salivary gland cells of Chironomus tentans. RNA labeled in vitro and in vivo with tritiated cytidine and uridine was isolated from microdissected nucleoli, chromosomes, nuclear sap, and cytoplasm and analyzed by electrophoresis on agarose-acrylamide composite gels. As shown earlier, the nucleoli contain labeled 38, 30, and 23S RNA. In the chromosomes, labeled 18S RNA was found in addition to the 30 and 23S RNA previously reported. The nuclear sap contains labeled 30 and 18S RNA, and the cytoplasm labeled 28 and 18S RNA. On the basis of the present and earlier analyses, it was concluded that the chromosomal monodisperse high molecular weight RNA fractions (a) show a genuine chromosomal localization and are not due to unspecific contamination, (b) are not artefacts caused by in vitro conditions, but are present also in vivo, and (c) are very likely related to nucleolar and cytoplasmic (pre)ribosomal RNA. The 30 and 23S RNA components are likely to be precursors to 28 and 18S ribosomal RNA. The order of appearance of the monodisperse high molecular weight RNA fractions in the nucleus is in turn and order: (a) nucleolus, (b) chromosomes, and (c) nuclear sap. Since both 23 and 18S RNA are present in the chromosomes, the conversion to 18S RNA may take place there. On the other hand, 30S RNA is only found in the nucleus while 28S RNA can only be detected in the cytoplasm, suggesting that this conversion takes place in connection with the exit of the molecule from the nucleus.     

Comparison between chromosomal and nuclear sap RNA from Chironomus tentans salivary gland cells by RNA/DNA hybridization

Newly-synthesized, high molecular weight RNA from salivary gland polytene chromosomes and from the nuclear sap was investigated by RNA/DNA hybridization. Salivary glands were incubated for 90 min with radioactive nucleosides and afterwards fixed. Chromosomes and nuclear sap were subsequently isolated by microdissection. Labelled RNA, extracted from three different chromosomal fractions and from the nuclear sap, was subjected to different hybridization procedures under conditions which primarily allow repeated nucleotide sequences to interact.In one type of experiments RNA was hybridized by a microtechnique to filter-bound DNA at increasing RNA/DNA input ratios. Nuclear sap RNA saturated 0.25−0.30% of the DNA, while the chromosomal RNA fractions had not reached a plateau even after hybridization with 0.5−1% of the DNA. Thus chromosomal RNA appears to contain sequences which are absent from, or present in only low concentration in, the nuclear sap. Nuclear sap RNA hybrids also showed a higher thermal stability than chromosomal RNA hybrids, which may reflect a higher precision of base-pairing in hybrids formed by nuclear sap RNA.In a second type of experiments the time dependence of hybrid formation was investigated. The hybridization rate for nuclear sap RNA was about three times as high as the corresponding rate for chromosomal RNA. This result indicates a relative enrichment of rapidly hybridizing RNA sequences in the nuclear sap.The difference in hybridization properties between chromosomal and nuclear sap RNA may be due to a predominance in the nuclear sap of RNA from a special chromosomal puff, the Balbiani Ring 2 (BR2), which has been shown to contain highly repeated DNA sequences. A comparison between the hybridization properties of nuclear sap RNA and BR2 RNA indicated that 55–70% of nuclear sap RNA may be derived from BR2.The specific hybridization rate of chromosomal RNA points to an average multiplicity of about 30 for its complementary DNA sequences. On the basis of the present and previous results it is suggested that the repeated DNA is arranged in families of related sequences and that sequences belonging to a particular family are distributed in different chromosomes.     

Intracellular distribution of low molecular weight RNA in Chironomus tentans

Low molecular weight RNA species are described in isolated nuclear components and cytoplasm of salivary gland cells of Chironomus tentans. In addition to 4S and 5S RNA and RNA in the 4–5S range previously described, at least three other components in the range below 16S are present. RNA, the molecular weight of which was estimated to 2.3 x 10⁵ and designed 10S RNA, can be observed only in nucleoli; other RNA, the molecular weight of which was estimated to 1.3 x 10⁵ and designed 8S RNA, was detected in the chromosomes, the nuclear sap, and the cytoplasm but not in the nucleoli; and a third type of RNA, the molecular weight of which was estimated to 8.5 x 10⁴ and designed 7S RNA, was present in nucleoli, chromosomes, nuclear sap, and cytoplasm. The substituted benzimidazole, 5,6-dichloro-1 (β-D-ribofuranosyl)benzimidazole (DRB), which gives a differential inhibition of the labeling of heterodisperse, mainly high molecular weight RNA in the chromosomes, does not inhibit the labeling of 8S RNA. The relative amounts of label in 8S RNA and 4–5S RNA (including 4S RNA and 5S RNA) in different isolated chromosomes, are distributed in proportion to the chromosomal DNA contents. The 8S RNA as well as the 7S RNA show a relative accumulation in chromosomes and nuclear sap with prolonged incubation time and are in this respect similar to intranuclear low molecular weight RNA species described by previous workers. Our data suggest, however, that these two types of RNA may differ in an important aspect from the previously described types since they are also present in the cytoplasm.     

Effects of -amanitin on in vitro labeling of RNA from defined nuclear components in salivary gland cells from Chironomus tentans

The effect of α-amanitin on nucleoside labeling of RNA in nucleoli, chromosomes, nuclear sap, and cytoplasm from Chironomus tentans salivary gland cells was investigated by radioautography and gel electrophoresis. Preribosomal RNA formation and processing in the nucleolus was not measurably influenced by the drug, and both 28 S and 18 S ribosomal RNA were transferred to the cytoplasm. In the chromosomes the heterogeneous RNA labeling was completely inhibited for the large size range (above 45–50 S) and partially for the low range. The labeling of 4–5 S chromosomal RNA was only moderately reduced. Most of the chromosomes showed radioautographically a disappearance of the normal band pattern, but some retained a pattern of weakly labeled bands. The electrophoretic results for the nuclear sap paralleled those for the chromosomes. The effect of α-amanitin on RNA labeling in these cells is similar but not identical to that of the substituted benzimidazole 5,6-dichloro-1(β-D-ribofuranosyl) benzimidazole (DRB).     

IN SITU DEMONSTRATION OF DNA HYBRIDIZING WITH CHROMOSOMAL AND NUCLEAR SAP RNA IN CHIRONOMUS TENTANS

Cytological hybridization combined with microdissection of Chironomus tentans salivary gland cells was used to locate DNA complementary to newly synthesized RNA from chromosomes and nuclear sap and from a single chromosomal puff, the Balbiani ring 2 (BR 2). Salivary glands were incubated with tritiated nucleosides. The labeled RNA was extracted from microdissected nuclei and hybridized to denatured squash preparations of salivary gland cells under conditions which primarily allow repeated sequences to interact. The bound RNA, resistant to ribonuclease treatment, was detected radioautographically. It was found that BR 2 RNA hybridizes specifically with the BR 2 region of chromosome IV. Nuclear sap RNA was fractionated into high and low molecular-weight RNA; the former hybridizes with the BR 2 region of chromosome IV, the latter in a diffuse distribution over the whole chromosome set. RNA from chromosome I hybridizes diffusely with all chromosomes. Nucleolar RNA hybridizes specifically with the nucleolar organizers, contained in chromosomes II and III. It is concluded that the BR 2 region of chromosome IV contains repeated DNA sequences and that nuclear sap contains BR 2 RNA.     

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.     

Physico-chemical properties of chromosomal RNA in Chironomus tentans polytene chromosomes

Labelled chromosomal RNA of the dipteran Chironomus tentans was studied with respect to its migration properties during electrophoresis in agarose. The RNA was isolated from polytene chromosomes which had been microdissected from fixed salivary glands and obtained free from nucleoli and nuclear sap. Labelled material migrates as 4–5 S RNA and as polydisperse material in a range where the lower limit corresponds to 10–15 S, the upper limit to 80–90 S RNA and the maximum in the distribution to 30–40 S RNA. The data indicate that the latter fractions are formed by unbroken, single-stranded RNA molecules, partly of very high molecular weights. It is shown in a number of tests that the distribution is not a consequence of formation of complexes or aggregates between RNA molecules on one hand and DNA, proteins or other RNA molecules on the other.     

STUDIES ON ISOLATED NUCLEI : II. Isolation and Chemical Characterization of Nucleolar and Nucleoplasmic Subfractions

This paper describes the subfractionation of nuclei isolated from guinea pig liver by the procedure presented in the first article of the series (8). Centrifugation in a density gradient system of nuclear fractions disrupted by sonication permits the isolation of the following subfractions: (a) a nucleolar subfraction which consists mainly of nucleoli surrounded by a variable amount of nucleolus-associated chromatin and contaminated by chromatin blocks derived primarily from von Kupffer cell nuclei; (b) and (c), two nucleoplasmic subfractions (I and II) which consist mainly of chromatin threads in a coarser (I) or finer (II) degree of fragmentation. The protein, RNA, and DNA content of these subfractions was determined, and their RNA's characterized in terms of NaCl-solubility, nucleotide composition, and in vivo nucleotide turnover, using inorganic ₃₂P as a marker. The results indicate that there are at least three types of RNA in the nucleus (one in the nucleolus and two in the nucleoplasm or chromatin), which differ from one another in NaCl-solubility, nucleotide composition, turnover, and possibly sequence. Possible relations among these RNA's and those of the cytoplasm are discussed.     

CHROMOSOMAL LOCALIZATION OF REPETITIVE DNA IN THE NEWT, TRITURUS

The repetitive DNA sequences of the newt, Triturus viridescens, have been studied by nucleic acid hybridization procedures. Complementary RNA was synthesized enzymatically from unfractionated newt DNA. This RNA hybridized strongly to the centromeric regions of both somatic and lampbrush chromosomes It also bound to other loci scattered along the lengths of the chromosomes The amplified ribosomal DNA in the multiple oocyte nucleoli was demonstrated by in situ hybridization     

Nuclear structures in the telotrophic ovarioles of nocturnal ground beetles (Tenebrionidae, Polyphaga). III. The oocyte nucleus. Electron microscopic data]

The fine structural organization of nuclei was studied in the growing oocytes of Blaps lethifera, B. mortisaga and Gnaptor spinimanus. In the beginning of diplotene the nuclei contain primary fibrillar nucleoli and numerous electron dense globules dispersed all over the nucleus; the loose chromosome material (lampbrush chromosomes) is distributed all over the nucleus. With the oocyte growth the chromosomes are spiralized and join into the karyosphere. A capsule of fibrous material forms around the karyosphere. The karyosphere nucleoli appear on the chromosomes and, then, move to the capsule region and outside its limits, to the nuclear envelope. They are fibrillar and non-active with respect to RNA synthesis. The fibrous material of the capsule is represented by strands which consist of bundles of cross-striated filaments. These latter contact directly with the chromosomes in the karyosphere and with the surface of the karyosphere nucleoli. The fibrillar-granular bodies are distributed along the strands in the capsule; they contain both RNA and DNA. The nature of extrachromosomal DNA in the karyosphere capsule and its participation in the formation of the capsule material are discussed. A suggestion is put forward on the similarity of the capsule strands with the modified central elements of synaptinemal complex.     

Sub-nuclear fractionation. I. Procedure and characterization of fractions

A procedure for fractionation of nuclei from rat liver, Xenopus liver and Xenopus erythrocytes is described. It is based on mild sonication of isolated nuclei for 7–12 sec in a nearly isotonic medium, separation of nuclear sap and centrifugation on a discontinuous sucrose density gradient containing Na and K citrate. Nuclei are thus separated in a single operation into 8 fractions representing nucleoplasm, euchromatin, nucleoli, heterochromatin and nuclear membranes. The sub-nuclear fractions were characterized by chemical composition (DNA, protein, RNA and phospholipid), electron microscopy, thermal denaturation properties of chromatin, relative binding of ${}^3\text{H-actinomycin D}$, polyacrylamide gel electrophoresis of nuclear proteins and titration of membranes against Triton X-100. Approx. 10% of total DNA was recovered as heterochromatin associated with membranes but the bulk of nuclear membranes co-sedimented with the major euchromatin zones. Subnuclear fractions prepared in this way retain virtually all the RNA polymerase activity bound to chromatin [41].     

The chemical composition of nuclei and chromosomes isolated by the Langmuir trough technique

The pattern of staining for DNA, histone, and nonhistone protein has been studied in whole cells and in nuclei and chromosomes isolated by surface spreading. In whole interphase cells from bovine kidney tissue culture, nuclear staining for DNA and histones reveals numerous small, intensely stained clumps, surrounded by more diffusely stained material. Nuclei in whole cells stained for nonhistone proteins also contain intensely stained regions surrounded by diffuse stain. These intensely stained regions also stain for RNA, indicating that the regions contain nucleolar material. Electron microscopy of kidney cells confirms that multiple nucleoli are present. Kidney nuclei isolated by surface spreading show an even distribution of stain for DNA, histones, and nonhistone proteins, indicating that the surface forces disperse both condensed chromatin and nucleoli. DNA and protein staining was also studied in metaphase chromosomes from testes of the milkweed bug, Oncopeltus fasciatus. Staining for DNA and histones in metaphase chromosomes is essentially the same in sections of fixed and embedded testes as in preparations isolated by surface spreading. However, striking differences are noted in the distribution of nonhistone proteins. In sections, nonhistone stain is concentrated in extrachromosomal areas; metaphase chromosomes do not stain for nonhistone proteins. Chromosomes isolated by surface spreading, however, stain intensely for nonhistone proteins. This suggests that nonhistone proteins are bound to the chromosomes as a contaminant during the isolation procedure. The relationship of these findings to current work with chromosomes isolated for electron microscopy is discussed.     

Localization of 5 S RNA genes in Chironomus tentans

The genes for 5 S RNA in Chironomus tentans have been located to region 2A of chromosome II by cytological hybridization. RNA from individual chromosomes, nuclear sap and nucleoli of salivary gland cells hybridized with the identified 5 S RNA genes in region 2A of chromosome II. The results suggest a common origin of 5 S RNA in these different nuclear compartments.     

THE ORGANIZATION OF THE NUCLEOLUS IN MERISTEMATIC PLANT CELLS : A Cytochemical Study

The architecture of the nucleolus in Allium porum and Triticum vulgare meristematic cells has been investigated by means of digestions with various enzymes. After staining with azure B at pH4, plant nucleoli exhibit lighter regions which, under electron microscopy, correspond to the fibrillar zones characterizing these organelles. Evidence is presented indicating that these latter zones contain coarse convoluted filaments quite similar to the loops first demonstrated by La Cour (24) and which are assumed to originate from the nucleolar-organizing chromosomes. These coarse, 0.2µ wide filaments are remarkably resistant to the action of deoxyribonuclease, ribonuclease, pepsin, trypsin, or of various combinations of these enzymes and, moreover, they show insignificant incorporation of labeled thymidine even after long exposure to this DNA precursor. The clearing action of pepsin on different regions of the nucleolus lends support to the hypothesis that an amorphous material or matrix pervades the mass of this organelle. This effect is particularly striking within the particulate nucleolar zones themselves. Both ribonuclease and trypsin disorganize the RNP (ribonucleoprotein) nucleolar particles. The effect of the latter enzyme on the RNP particles is taken to indicate that they contain proteins particularly susceptible to trypsin which are essential for maintenance of their morphological integrity. Trypsin also interferes with azure B-staining of the nucleolar mass as a whole and, according to radioautographic data, extracts RNA throughout this organelle. Accordingly, the hypothesis is considered that RNA is complexed with proteins not only within the particulate nucleolar portions, as is already well known, but also in the fibrillar zones.     

SMALL GRANULES IN THE AMPHIBIAN OOCYTE NUCLEUS AND THEIR RELATIONSHIP TO RNA

Small particles (100 to 300 A in diameter) are seen in sections of nucleoli, the loops of the amphibian lampbrush chromosomes, and the Balbiani-ring regions of dipteran salivary-gland chromosomes. All of these structures contain cytochemically demonstrable RNA. Furthermore, the annuli seen on the nuclear envelope are composed of small particles which are similar to or identical with those commonly associated with the endoplasmic reticulum. It seems likely that ribonucleoproteins are organized as small particulates in the nucleus as well as in the cytoplasm.     

Molecular cloning of microdissected lampbrush loop DNA sequences of Drosophila hydei

We microdissected a Y chromosomal lampbrush loop pair from primary spermatocyte nuclei of Drosophila hydei and cloned the DNA directly at the microscale. Four of the 12 recombinant DNA clones recovered display in situ hybridization to mitotic metaphase Y chromosomes, preferentially in the chromosomal region identified as the origin of the lampbrush loop pair. All clones, however, also hybridize to autosomal and X chromosomal loci in polytene chromosomes. Y chromosomal DNA sequences of D. hydei again prove to be members of different families of repeated sequences distributed throughout the genome. These microcloning experiments, which were carried out under very unfavourable experimental conditions (low DNA content of the lampbrush loops in the presence of large amounts of RNA) prove that almost any chromosomal structure detected by light microscopy is directly accessible to molecular cloning experiments by micromethods.     

SYNTHETIC CAPACITIES OF CHROMOSOME FRAGMENTS CORRELATED WITH THEIR ABILITY TO MAINTAIN NUCLEOLAR MATERIAL

Onion (Allium cepa) and bean (Vicia faba) root tip cells containing many micronuclei, derived from x-ray-induced chromosome fragments, were exposed to H³-thymidine and H³-cytidine to determine the ability of such fragments to undergo DNA and RNA synthesis. Only a few micronuclei in onion and many in bean roots synthesize nucleic acid simultaneously with their main nuclei. A few micronuclei labeled with H³-thymidine undergo mitotic chromosome condensation along with the main nuclei, while the unlabeled ones never do so. The onset of nucleic acid synthesis as well as mitosis in micronuclei appears to be under generalized cellular control. Although all chromosomes and chromosome fragments at telophase give a positive reaction for a silver stainable nucleolar fraction, in the subsequent interphase only some micronuclei, derived from such chromosome fragments, are found to maintain nucleoli; others lose them with time. Those micronuclei which maintain nucleoli, perhaps due to the presence of specific chromosomal regions, are also active in DNA and RNA synthesis. These results are compatible with the concept that nucleoli and associated chromosome regions play an important role in the primary biosynthetic processes of the cell.     

The chemical composition of nuclei and chromosomes isolated by the Langmuir trough technique

The pattern of staining for DNA, histone, and nonhistone protein has been studied in whole cells and in nuclei and chromosomes isolated by surface spreading. In whole interphase cells from bovine kidney tissue culture, nuclear staining for DNA and histones reveals numerous small, intensely stained clumps, surrounded by more diffusely stained material. Nuclei in whole cells stained for nonhistone proteins also contain intensely stained regions surrounded by diffuse stain. These intensely stained regions also stain for RNA, indicating that the regions contain nucleolar material. Electron microscopy of kidney cells confirms that multiple nucleoli are present. Kidney nuclei isolated by surface spreading show an even distribution of stain for DNA, histones, and nonhistone proteins, indicating that the surface forces disperse both condensed chromatin and nucleoli. DNA and protein staining was also studied in metaphase chromosomes from testes of the milkweed bug, Oncopeltus fasciatus. Staining for DNA and histones in metaphase chromosomes is essentially the same in sections of fixed and embedded testes as in preparations isolated by surface spreading. However, striking differences are noted in the distribution of nonhistone proteins. In sections, nonhistone stain is concentrated in extrachromosomal areas; metaphase chromosomes do not stain for nonhistone proteins. Chromosomes isolated by surface spreading, however, stain intensely for nonhistone proteins. This suggests that nonhistone proteins are bound to the chromosomes as a contaminant during the isolation procedure. The relationship of these findings to current work with chromosomes isolated for electron microscopy is discussed.