Banding in Human Chromosomes treated with Trypsin

THE differential staining properties of the Giemsa stain were first observed by Pardue and Gall¹. They were studying in situ hybridization between mouse satellite DNA and mouse chromosomes and observed that following certain pretreatment the centromeric regions of mouse chromosomes were more densely stained by Giemsa stain than other regions. The darkly stained regions were considered to consist of constitutive heterochromatin. Similar observations were later made on human chromosomes by Arrighi and Hsu² and Gagné et al.³. Through modifications of the original methods used in the DNA hybridization work, techniques have been developed which make each chromosome identifiable^4–6.     

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.     

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.     

THE USE OF BISMUTH AS AN ELECTRON STAIN FOR NUCLEIC ACIDS

Evidence is presented to show that bismuth combines in vitro with the phosphate of nucleic acids in a manner similar to its reaction with inorganic phosphate. When tested under similar conditions, protein exhibited no attraction for bismuth. The results of the in vitro experiments, which are of interest within themselves, may be indirectly applicable to in vivo staining. Dividing cells of onion root tips were fixed in OsO₄, stained with bismuth, and examined in the electron microscope. The electron opacity of cell structures known to contain nucleic acids was enhanced by bismuth, while organelles known to lack appreciable quantities of DNA or RNA showed little, if any, change. Bismuth is particularly effective as a stain for the chromatin material during interphase and for the chromosomes during division.     

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.     

Asynchrony of DNA replication and mitotic spiralization along heterochromatic portions of Chinese hamster chromosomes

Sequence of DNA synthesis and mitotic chromosome spiralization along heterochromatic portions of the sex (X₁X₂) and of some marker chromosomes in cultured Chinese hamster cells were studied, employing two methods: study of segmentation pattern caused in chromosomes with colcemid, and autoradiography with tritiated thymidine. The heterochromatic portions of all chromosomes studied were characterized by striking internal asynchrony of DNA replication. In particular, they had segments that replicated relatively early. The short arm of the X₂ chromosome, heterochromatic in female somatic cells, had at least three such segments. Replication patterns of the long arms of the X₁ and X₂ chromosomes were different. In X₁ this arm contains several segments showing relatively early replication. The long arm of X₂ had no similar segments. The possible significance of the data obtained is discussed with regard to the problem of genetic inertness of heterochromatin. At the terminal stage of the S period, H³-thymidine seems to be incorporated into condensed chromatin of interphase nuclei. On the basis of the data obtained, it is proposed that during replication of heterochromatin consecutive despiralization of parts of it takes place.     

Structural changes of dinoflagellate chromosomes by pronase and ribonuclease

When cells of the dinoflagellates Prorocentrum micans and Gyrodinium cohnii are exposed to the proteolytic enzyme pronase or alternatively to ribonuclease, the structure of chromosomes is markedly altered. These changes have been observed electron microscopically in thin sections and spreads. Treatment of cells with pronase removed the bulk of nonfibrillar chromosome material completely unmasking fine chromosomal DNA fibres. Pronase had similar effect also on the dense material which is in contact with chromosomes; fibrillar loops protruding from chromosomes were exposed. However, pronase had no effect on the structural integrity of chromosomes. On the contrary, treatment of cells with ribonuclease loosened the package of chromosomal fibres. Thin sections showed that the tight package of longitudinal periodic structures seen in untreated chromosome was relaxed; chromosome extended longitudinally and formed a linear array of balls. When ribonuclease-treated chromosomes were spread, they were substantially more stretched than untreated chromosomes because of uncoiling of two oppositehanded spiral chromatid bundles. The effect of ribonuclease treatment suggests that unknown RNA species have an important role in the maintenance of permanent condensation of dinoflagellate chromosomes. On the other hand, proteins removable by pronase are also present. Most probably they are not linked to the chromosome structure but represent the matrix of nuclear activity.     

Independence of Cell Division and DNA Replication in <Emphasis Type="Italic">Bacillus subtilis</Emphasis>

IN Escherichia coli the completion of a round of chromosome replication is necessary before cell division can take place^1,2. A normal cell is therefore unable to divide unless it has at least two chromosomes. If DNA synthesis is specifically inhibited, cell division will continue only until each cell contains a single chromosome. Division then ceases but growth continues so that long filamentous cells are formed³. We describe here the consequences of blocking DNA synthesis in Bacillus subtilis. In this case division of the growing cells continues in spite of the inhibition of DNA replication. Eventually, not only are all pre-existing chromosomes segregated into separate cells but large numbers of cells are formed which contain no DNA.     

DNS-Gehalt und Chromosomenstruktur bei Amphibien

Comparative karyotype analysis and cytophotometric DNA measurements on further amphibian species (Hyla arborea, Bombina variegata, B. bombina, Triturus vulgaris, T. alpestris, and Salamandra salamandra) were carried out. The relative DNA values of the genomes determined for these species and other amphibians investigated earlier (Ullerich, 1966, 1967), already do nearly exclude the hypothesis that the interspecific differences in DNA content in frogs, toads, and salamanders are caused by differential polynemy of their chromosomes. Electron microscopic investigations on the DNA axes of lampbrush chromosomes of Bufo calamita, B. viridis, B. bufo, Rana esculenta, Bombina variegata, and Triturus alpestris treated with trypsin and ribonuclease confirm that the chromosomes of these species are not polynemic; in all species analysed the lampbrush chromosomes consist of the same number of DNA strands. The double-strandedness observed regularly in several segments of the chromatid axes in the loops as well as in the interchromomeric regions of all species suggest that the chromatids possibly are divided into half-chromatids. The minimum diameter of these two deoxyribonuclease-sensitive fibrills is 20–35 Å, whereas the chromatid axes in those segments which do not show double-strandedness mostly measure 40–65 Å. The high DNA amounts and interspecific differences in DNA content in the amphibian species analysed, probably in all amphibians, therefore must be caused during evolutionary processes by local increase (perhaps in a smaller extent also by-local decrease) in DNA in the chromosomes.     

tRNA2Lys gene clusters in Drosophila

We have isolated segments of Drosophila melanogaster DNA that contain two clusters of tRNA₂^Lys genes. In one segment, pPW511, there is a cluster of three of these genes surrounded by other tRNA genes. Two other segments, pPW516 and pPW541. share a 3 × 10³ base-pair region that has a cluster of four tRNA₂^Lys genes. This cluster is flanked by 20 × 10³ base-pairs of DNA that does not appear to have other tRNA genes. The tRNA genes in both clusters are irregularly spaced and are intermingled with moderately repetitive DNA. Each cluster is present once or perhaps twice in the haploid genome and has the same arrangement of restriction endonuclease sites in the genomic DNA as in the isolated, cloned DNA. In situ hybridization to polytene chromosomes localized the pPW511 cluster to the 42A region and the pPW516/541 cluster to the 42E region. Another region, 50B, also contains tRNA₂^Lys genes. In sum, these cloned tRNA₂^Lys genes account for most of this gene family and are irregularly spaced in two clusters.     

THE DNA BASE COMPOSITION OF INDIVIDUAL CHROMOSOMES AND CHROMOSOME SEGMENTS FROM CHIRONOMUS TENTANS

The base composition of DNA was determined for individual chromosomes from the dipteran Chironomus tentans and for each one of six different segments of one of the chromosomes. The isolations were carried out by micromanipulation and the DNA purines were first extracted from the isolated components and afterwards separated by means of microelectrophoresis on a cellulose fiber. It was found that DNA from this material has an unusual composition corresponding to a guanine + cytosine content of about 30%. This composition was not a function of the polytenic condition but was also found for DNA from testis tissue. Furthermore Drosophila has a more traditional base composition for the bulk of DNA. Statistically significant variations in base data were found between whole chromosomes as well as between the segments from one of the chromosomes.     

Chromosome segregation in an asymmetrically dividing bacterium,Caulobacter crescentus

The mode of chromosome segregation in an asymmetrically dividing bacterium, Caulobacter crescentus, was studied by examining the fate of labeled DNA strands. Swarmer cells (one type of Caulobacter daughter cell), in which single strands of DNA had been labeled with [³H]thymidine during the previous round of chromosome replication, were grown synchronously in a non-radioactive medium for two generations. The distribution of radioactivity among the cells was visualized by autoradiography under a phase-contrast microscope. The labeled DNA strands in each cell were found to consist of two conserved units. From this, we propose a model in which the swarmer cell has two identical chromosomes, which are segregated into the progeny swarmer cell and the progeny stalked cell after chromosome replication.     

Separation of Epstein-Barr Virus DNA from Large Chromosomal DNA in Non-virus-producing Cells

AT least four established human lymphocyte cell lines, one that originates from a Burkitt's lymphoma and the others from normal persons, contain Epstein-Barr virus (EBV) genome¹. These cells show no viral antigens by immunofluorescence tests nor do they produce virus particles. We are examining one of the four cell lines, Raji (cells from a Burkitt's lymphoma), in more detail. The DNA isolated from purified Raji chromosomes contains as much virus genome as the DNA extracted from whole cells (65 genome equivalents per cell)¹. The viral DNA therefore seems to be in the chromosomes. This result, however, does not necessarily indicate that the viral DNA is physically integrated into chromosomal DNA. The following experiments suggest that the EBV DNA in Raji cells is not covalently linked to the large chromosomal DNA, although the number of viral genomes per cell remains constant during passage. The results do not, however, exclude the possibility that small fragments of cell DNA are bonded to the viral DNA. The data also indicate that EBV DNA in Raji cells exists in strands of complete or nearly complete size.     

Sequence organisation in nuclear DNA from Physarum polycephalum: Arrangement of highly-repeated sequences

Recombinant plasmids containing highly repetitive Physarum DNA segments were identified by colony hybridisation using a radioactively-labelled total Physarum DNA probe. A large number of these clones also hybridised to a foldback DNA probe purified from Physarum nuclear DNA. The foldback DNA probe was characterised by reassociation kinetic analysis. About one-half of this component was shown to consist of highly repeated sequences with a kinetic complexity of 1100 bp and an average repetition frequency of 5200. Direct screening of 67 recombinant plasmids for foldback sequences using the electron microscope revealed that about one-half were located in segments of DNA containing highly repetitive sequences; the remainder were present in clones containing low-copy number repeated elements. Analysis of two DNA clones showed that they contained repetitive elements located in over half of all DNA segments containing highly repetitive DNA and that the foci containing these highly repetitive sequences had different sequence arrangements. The results are consistent with the hypothesis that the most highly repeated DNA sequence families in the Physarum genome are few in number and are clustered together in different arrangements in about one-sixth of the genome. Over one-half of the foldback DNA complement in the Physarum genome is derived from these segments of DNA.     

DNA-Replikation und Chromosomenstruktur von Mesostoma (Turbellaria)

During meiosis in M. ehrenbergi (2n=10) and M. lingua (2n=8) male certain chromosomes never pair completely. In these bivalents only terminal pairing appears, crossing over could not be proved by ³H-thymidine autoradiography. DNA amounts of the M. ehrenbergi and M. lingua genomes are in a proportion of 10∶1. The mitotic S-phase of spermatogonia in M. ehrenbergi is twice as long as in M. lingua. In metaphase of spermatogonia a differentiated DNA replication pattern can be identified in M. ehrenbergi as late-pulse-replicating segments. After incorporation of ³H-thymidine X₂-metaphase chromosomes can be found, which show single chromatid labeling, terminal and intercalary isolabeling as well as kinds of chromosome labeling, which can only result from sister strand exchange. After treating the chromosomes with low temperature, colchicine or by hydrolysis (60° C) substructures of the chromatin become visible in both spezies which however are evaluated as artefacts. — Formation of the different isolabeling types is discussed on the basis of a two-strand model of the chromosome fibril. A hypothesis is formulated that the surplusage of DNA in M. ehrenbergi is distributed over all the length of the chromatids as small parts of heterochromatin. This hypothesis is supported by investigations of the DNA replication and the contractility of the chromosomes. Furthermore, a pattern of small DNA particles can be demonstrated after partial destruction of the DNA in metaphase chromosomes of M. ehrenbergi, which could represent this intercalary heterochromatin.     

PHYSICAL CHEMICAL STUDIES ON THE SPECIFIC INTERACTION OF AN ACRIFLAVINE-PHOSPHOTUNGSTIC ACID COMPLEX WITH DOUBLE-STRANDED NUCLEIC ACIDS

The detailed definition of the structure of DNA in chromosomes and in interphase chromatin is important for correlating the structure of the genetic material with various states of physiological activity. A general approach to developing specific reagents for a variety of such studies in solution and in tissues is to combine a chemically specific organic cation with the electron-opaque phosphotungstic acid (PTA) molecule. The reagent described in this paper was made from the interaction of acriflavine and phosphotungstic acid. The acriflavine-PTA complex (a) displays some unique absorption and fluorescence properties, (b) binds specifically to DNA and RNA by intercalation of the acriflavine moiety, and (c) is electron opaque. In addition, it binds to double-stranded synthetic polynucleotides, but not to a variety of proteins, nucleoproteins, or polysaccharides.     

Quinacrine Fluorescence Patterns and Terminal DNA Labelling of Human <Emphasis Type="Italic">C</Emphasis> Group Chromosomes

THE human C group chromosomes have been difficult to study because they have rather similar morphology. Application of the quinacrine fluorescent staining technique developed by Caspersson et al.¹ now allows the identification of individual chromosomes and of the chromosome segments involved in translocations because the fluorescent patterns are not altered by the translocation^2–4. We have reported the value of this technique in analysing abnormalities of the D⁴ and G³ groups. We report here a variety of structural changes of C group chromosomes which have been characterized in this way, as well as the terminal DNA replication pattern of the C group chromosomes.     

5 S DNAs of Xenopus laevis and Xenopus mulleri: evolution of a gene family

The 5 S DNA which contains the genes for 5 S RNA has been purified from the frog Xenopus mulleri and compared with the 5 S DNA of Xenopus laevis. Both DNAs contain highly repetitive sequences in which the gene sequence that codes for 5 S RNA alternates with a spacer sequence. The 5 S DNAs of X. laevis and X. mulleri comprise about 0.7% of the total DNA or about 24,000 and 9000 repeating sequences, respectively. The average repeat length within native X. laevis and X. mulleri 5 S DNA is about 0.5 to 0.6 and 1.2 to 1.5 × 10⁶ daltons, respectively, each repeat of which contains a single gene sequence for 5 S RNA (0.08 × 10⁶ daltons). The two DNAs differ in the average length of their spacers and no cross homology can be detected by heterologous hybridization of the two DNAs, except within the 5 S RNA gene regions. Despite their differences, the spacer sequences of X. laevis and X. mulleri 5 S DNA resemble each other enough to conclude that they have diverged from a common ancestral sequence.The multiple repeating sequences of 5 S DNA in each species have evolved as a family of similar, but not identical sequences. It is known that 5 S DNA is located at the ends (telomeres) of the long arms of most, if not all, X. laevis chromosomes. It is proposed that multiple gene sequences located on the ends of many chromosomes can evolve together as a family if there is extensive and unequal exchange of DNA sequences between homologous and non-homologous chromosomes at their ends.     

The action of ultraviolet light on the patterns of banding induced by restriction endonucleases in human chromosomes

The irradiation of metaphase spreads of human cells with ultraviolet (UV) light blocked the chromosome banding induced by Alu I, Mbo I, Dde I, Hinf I, Hae III, and Rsa I restriction endonucleases. At 13 J/m² there was moderate inhibition of the nuclease action, which was detected as an increase in the stain intensity of chromosomes (Alu I, Mbo I, Dde I, Rsa I) or as a change in the banding pattern (Hinf I, Hae III). At 70–300 J/m² the UV-induced blockage was complete; the chromosomes showed no banding, and stain intensity was similar to that of control slides incubated with buffer. — BrdU substitution and the irradiation of BrdU-substituted chromosomes with 313 nm light at 1800–15000 J/m² did not block the action of restriction nucleases. On the other hand, UV irradiation of BrdU-substituted chromosomes inhibited the action of restriction enzymes at the same fluences that blocked the nuclease action in unsubstituted chromosomes. The data indicate that DNA-protein crosslinkage is the factor inhibiting DNA extraction and chromosome banding.