An analysis of the bovine genome by Cs2SO4-Ag density gradient centrifugation

Calf DNA preparations having molecular weights of 5 to 7 × 10⁶ have been fractionated by preparative Cs₂SO₄—Ag⁺ density gradient centrifugation into a number of components. These may be divided into three groups: (1) the main DNA component (1.697 g/cm³; all densities quoted are those determined in CsCl density gradients), the 1.704 and 1.709 g/cm³ components form about 50, 25 and 10% of the genome, respectively; they are characterized by having symmetrical CsCl bands and melting curves, both of which have standard deviations close to those of bacterial DNAs of comparable molecular weight, and by their G + C contents being equal to 39, 48 and 54%, respectively; after heat-denaturation and reannealing, their buoyant densities in CsCl are greater than native DNA by 12, 10 and 3 mg/cm³, respectively. (2) The 1.705, 1.710, 1.714 and 1.723 g/cm³ components represent 4, 1.5, 7 and 1.5% of the DNA, respectively, and exhibit the properties of “satellite” DNAs; their CsCl bands and melting curves have standard deviations lower than those of bacterial DNAs; after heat-denaturation and reannealing, their buoyant densities are identical to native DNA, except for the 1.705 g/cm³ component, which remains heavier by 5 mg/cm³; in alkaline CsCl, only the 1.714 g/cm³ component shows a strand separation. (3) A number of minor components, forming 1% of the DNA, have been recognized, but they have not been investigated in detail; two of them (1.719 and 1.699 g/cm³) might correspond to ribosomal cistrons and mitochondrial DNA, respectively.     

Isolation and characterization of satellite DNA from mustard seedlings

The DNA from mustard (Sinapis alba L.) seedlings was examined by neutral CsCl and Ag⁺/Cs₂SO₄ density gradient centrifugation. Different satellite fractions were revealed by these two methods. The satellite fractions obtained from the Ag⁺/Cs₂SO₄ density gradient could not be generally correlated with satellite DNA fractions observed in CsCl. In CsCl density gradient centrifugation, a main band at density 1,695 g/cm³ and a heavy shoulder at density 1,703 g/cm³ are found. By preparative CsCl gradient centrifugation the heavy shoulder can be enriched but not completely separated from the main band DNA.—Gradient centrifugation by complexing the DNA with Ag⁺ rf. 0.25 to DNA phosphate reveals three distinct fractions which are further characterized: The heavy satelite DNA fraction revealed by Ag⁺/Cs₂SO₄ gradient centrifugation has the same density in a CsCl gradient and the same Tm value as the main band, but differs from main band DNA in the details of its melting profile and in its renaturation kinetics. The light Ag⁺/Cs₂SO₄ satellite DNA fraction had a higher melting temperature corresponding to a GC-rich base composition. Differences between these 3 fractions are observed in thermal denaturation and renaturation profiles, hybridization in situ with ribosomal RNA, and their response to restriction endonuclease digestion. The light satellite fraction from the Ag⁺/Cs₂SO₄ gradient, rich in ribosomal cistrons corresponds to the heavy shoulder DNA of neutral CsCl gradients which also is rich in ribosomal cistrons. The heavy satellite fraction from Ag⁺/Cs₂SO₄ gradient which contains highly repetitive short nucleotide sequences could not be revealed by the classical CsCl gradient centrifugation technique.     

Sequences of the 1.672 g/cm3 satellite DNA of Drosophila melanogaster.

The 1.672 g/cm³ satellite DNA of Drosophila melanogaster was purified by successive equilibrium centrifugations in a CsCl gradient, an actinomycin $\text{D}\text{CsCl}$ gradient, and a netropsin sulfate/CsCl gradient. The resulting DNA was homogeneous by the physical criteria of thermal denaturation, renaturation kinetics and equilibrium banding in each of the gradients listed above. In addition, the complementary strands could be separated in an alkaline CsCl gradient. Despite this rigorous purification procedure, nucleotide sequence analysis indicates the presence of two different DNA species in this satellite, poly $\text{A-A-T-A-T}\text{T-T-A-T-A}$ and poly$\text{A-A-T-A-T-A-T}\text{T-T-A-T-A-T-A}$. Further physical, chemical and template properties of the isolated complementary strands demonstrate that these two repeating sequences are not interspersed with each other. This result has biological significance since sequences of this particular satellite are known to be located primarily on two different chromosomes, Y and 2. These results further suggest that the sequence heterogeneity observed in satellite DNA of higher eukaryotes may result from mixtures of very closely related but molecularly homogeneous repeated sequences each restricted to a particular chromosome or chromosomal region.     

Cat satellite DNA. Isolation using netropsin with CsCl gradients

The absence of centromeric bands in the karyotype of Felis catus is confirmed. It is also confirmed that no satellite band is visible in CsCl density gradients. However, a satellite is observed both by recentrifuging the fraction of the DNA that bands at high density in CsCl and by using netropsin to enhance the resolution of a CsCl gradient containing total F. catus DNA. The satellite, about 0.5% of total DNA, was isolated by repeated centrifugation in CsCl alone and in CsCl with netropsin. Netropsin was removed and a pure satellite DNA obtained. The reassociation kinetics (C0t1/2 less than 10(-3) M . s) show that the satellite is of the simple sequence type and hence a candidate for centromeric heterochromatin. Its cytological localisation awaits in situ hybridisation experiments.     

Separation of B and C Type Virions by Centrifugation in Gentle Density Gradients

Murine type B particles were separated from type C (Rauscher leukemia virus) by means of gentle (low-increment rate) density gradients. The best separation was obtained when the density ranged from 1.13 to 1.20 g/cm³ when sucrose was used and from 1.12 to 1.28 g/cm³ with CsCl. The buoyant densities of the B and C particle bands in sucrose were 1.18 and 1.16 g/cm³, respectively. The CsCl gradient gave a better separation with the B particles banding at a density of 1.20 g/cm³ and with the C particle density little different from its value in sucrose.     

Satellite DNA of Drosophila nasuta nasuta and D. n. albomicana: Localization in polytene and metaphase chromosomes

The DNA from the two Drosophila nasuta races, D. n. nasuta and D. n. albomicana was investigated by CsCl density gradient centrifugation. D. n. nasuta has one major AT-rich satellite DNA sequence with a density of 1.664g/cm³, while D. n. albomicana has at least three satellites with densities of 1.674g/cm³, 1.665g/cm³ and 1.661 g/cm³. The isolated satellite sequences hybridize in situ to all heterochromatic regions of all metaphase chromosomes of both races. In polytene chromosomes the satellite sequences hybridize exclusively to the chromocenter. All chromosomal regions hybridizing with the satellites show also bright quinacrine fluorescence.     

Compositional patterns in the nuclear genome of cold-blooded vertebrates

Summary DNA preparations obtained from 122 species of fishes, 5 species of amphibians, and 13 species of reptiles were investigated in their compositional properties by analytical equilibrium centrifugation in CsCl density gradients. These species represented 21 orders of Osteichthyes, 3 orders of Chondrichthyes, 2 orders of amphibians, and 3 orders of reptiles. Modal buoyant densities of fish DNAs ranged from 1.696 to 1.707 g/cm³, the vast majority of values falling, however, between 1.699 and 1.704 g/cm³, which is the range covered by the DNAs of amphibians and reptiles. In all cases, DNA bands in CsCl were only weakly asymmetrical and only very rarely were accompanied by separate satellite bands (mostly on the GC-rich side). Intermolecular compositional heterogeneities were low in the vast majority of cases, and, like CsCl band asymmetries, at least partially due to cryptic or poorly resolved satellites. The present findings indicate, therefore, that DNAs from cold-blooded vertebrates are characterized by a number of common properties, namely a very wide spectrum of modal buoyant densities, low intermolecular compositional heterogeneities, low CsCl band asymmetries, and, in most cases, small amounts of satellite DNAs. In the case of fish DNAs a negative correlation was found between the GC level and the haploid size (c value) of the genome. If polyploidization is neglected, this phenomenon appears to be mainly due to the fact that increases and decreases in GC are associated with contraction and expansion phenomena, respectively, of intergenic noncoding sequences, which are GC poor relative to coding sequences.     

Localization of repeated DNA sequences in CsCl gradients by hybridization with complementary RNA

Single-stranded ends of mouse satellite DNA sequences exposed during the extraction of nuclear DNA, or by mechanical shear, can hybridize with highly labelled RNA, complementary to satellite DNA. In neutral CsCl gradients, the hybrid sediments as a sharp peak at the density of mouse satellite DNA (1.691 g/cm³). The possibility of exploiting this observation in locating and isolating cryptic repetitive DNAs from nuclear DNA or the DNA of heterochromatin is discussed.     

Ribosomal RNA cistrons in Euglena gracilis

Euglena gracilis chloroplasts contain about 12 fg DNA of average density 1.686 g cm^?3 and 1.7 pg RNA. The large (1.1 × 10⁶ mol. wt) and small (0.56 × 10⁶ mol. wt) ribosomal RNA components are coded for by separate cistrons, both of which band at a density of 1.696 g cm^?3 in a CsCl gradient. About 6% of the chloroplast DNA codes for rRNA indicating that there are 240 cistrons for rRNA in each chloroplast or about three to six cistrons per chloroplast genome. Similar studies with rRNA from cytoplasmic ribosomes indicate that the cistrons for cytoplasmic rRNA band at a density of 1.716 g cm^?3, denser than that of the main-band DNA, and that there are 1000 cistrons for cytoplasmic rRNA per cell. Fractionation of E. gracilis DNA on CsCl gradients and subsequent hybridization experiments, as well as melting curves of DNA-RNA hybrids, show that chloroplast rRNA does not anneal specifically with either the cistrons for cytoplasmic rRNA or any DNA in the dark-grown cell, in contrast to those results found in some higher plants.     

Properties of Light Particles Produced During Growth of Type 4 Adeno-Associated Satellite Virus

Adeno-associated satellite virus type 4, obtained by repeated undiluted passage, failed to produce distinct bands at the expected density of 1.43 g/cm³ after density gradient centrifugation in CsCl. This phenomenon occurred regardless of the hemagglutinating activity of the starting material. Sharp bands were found at a density of 1.34 to 1.35 g/cm³. These bands contained adenovirions and numerous satellite particles. These latter particles could be distinguished by electron microscopy from standard dense satellite particles by their flattened profiles and deep penetration of negative stains. Dense bands of satellite virus at 1.43 g/cm³ were constantly observed when the inoculum was comprised of highly diluted seed virus. Light satellite particles had a particle to HA ratio comparable with dense particles, but possessed low infectivity. Measurements of contour lengths of extracted deoxyribonucleic acid (DNA) indicate that light particles contain only a small amount of DNA, possibly less than 0.5 × 10⁶ daltons, compared to 1.4 × 10⁶ for the complete satellite DNA molecule.     

Equilibrium centrifugation of measles virus

Measles virus has been centrifuged on different density gradients. It sediments at densities of 1,20 g/cm³ in K-tartrate, of 1,18–1,21 g/cm³ in sucrose, 1,19–1,23 g/cm³ in CsCl and 1,19 g/cm³ in metrizamide gradients. Metrizamide reduced measles virus infectivity. In sucrose gradients sometimes more than one infectious peak was observed. Control Vero cells produced particles of the same densities as measles virus peaks. These peaks did contain actin as the major protein. The relevance of this finding in relation to the presence of actin in measles virus is discussed.     

Isolation of twelve satellite DNAs from Drosophila hydei

The genome of a Drosophila hydei genotype with a reduced amount of heterochromatin was fractionated by three cycles of preparative gradients: firstly in Ag⁺/Cs₂SO₄, secondly in actimomycin D/CsCl, and finally in neutral CsCl. Using this method, twelve highly repetitive simple-sequence satellites were isolated. Ten of them comprised only a minor amount of the genome in contrast to the two major satellites found earlier¹ (p = 1.696 and 1,714 g/cm³). These minor satellites were characterized by their banding in the gradient systems used, by their density in neutral CsCl, and by their melting point. Using these characteristics, it was found that the fractions of the Ag^?/Cs₂SO₄ gradient do not contain purified single components, because up to five different satellites band in the same position of the Ag^?/Cs₂SO₄ gradient. It was possible to isolate a high number of satellites even from a genome with a reduced amount of heterochromatin. Thus, the D hydei heterochromatin does not domain one unique highly repetitive sequence DNA, but is comprised of many different satellite sequences.     

The effect of natural selection on enzymic catalysis.

The karyotype of Drosophila nasutoides reveals a very large autosome pair at the metaphase plate. The application of the C-banding technique shows that this chromosome is almost entirely heterochromatic and an isochromosome (Cordeiro et al., 1975). Examination of the DNA isolated from purified nuclei of D. nasutoides in neutral CsCl gradients reveals four major satellites. As much as 60% of the total DNA appears as satellites in the DNA from larval brains. The buoyant densities of the four satellites, designated as I through IV in the order of descending density, are 1.687, 1.682, 1.669 and 1.665 g/cm³, respectively. All four satellites show strand separations in alkaline CsCl gradients with the least separation in satellite III. Thermal denaturation studies with purified native satellites show that satellites I and IV consist of repeats of identical sequences, whereas satellites II and III show a large sequence variation between repeating units. As much as 10 to 24% base-pair mis-matching is observed in the reassociated satellite II. The sequence complexities obtained from DNA reassociation kinetics data are 5, 103, 2.3 × 10⁶ and 46 nucleotide pairs for the satellites I, II, III and IV, respectively. The complexity of satellite III is almost as large as that of Escherichia coli, when the reassociation rate is corrected according to the amount of mis-matching in this satellite. All four satellite sequences are localized in one chromosome (dot chromosome) according to in situ hybridizations to polytene chromosomes. The large heterochromatic chromosome seen at the metaphase plate appears as the dot chromosome after polytenization. Therefore, the large heterochromatic chromosome contains all four satellite DNA components.     

The use of netropsin with CsCl gradients for the analysis of DNA and its application to restriction nuclease fragments of ribosomal DNA from Physarum polycephalum

Netropsin binds to DNA in caesium chloride density gradients and reduces the density of the DNA. The DNA is saturated at a netropsin/DNA weight ratio of about 6 and the change in density, deltarho, at saturation is given by deltarho = -109 (dA + dT content)1.87 mg/ml for the six DNAs tested covering dA + dT contents from 0.28 to 0.69. At lower netropsin/DNA ratios the observed density shifts are consistent with a two-site model for netropsin binding to DNA. Netropsin approximately doubles the resolution of Physarum polycephalum nucleolar satellite DNA from main-band DNA. The fragments of P. polycephalum nucleolar satellite DNA obtained with the restriction endonuclease HindIII do not separate on CsCl gradients, even in the presence of netropsin, which shows that the transcribed and non-transcribed sequences in this DNA have similar nucleotide compositions.     

Nuclear DNA in normal and refed Amoeba proteus

Amoeba proteus synthesizes DNA in G2 phase of the cell cycle upon feeding after starvation. The characteristics of the DNA synthesized in G2 have been studied by microscope photometry of individual Feulgen-stained nuclei and by buoyant density centrifugation of nuclear DNA in CsCl. Amoeba nuclei were found to contain 42.8 pg of DNA. This DNA bands in CsCl at a density of 1.693 g/cm³ with a satellite at 1.714 g/cm³ which makes up 24% of nuclear DNA. DNA from whole cells has an additional non-nuclear satellite at 1.726 g/cm³. When cells are starved and re-fed with food labeled with [³H]thymidine, the DNA synthesized is predominantly the 1.714 satellite. The amount of DNA synthesized in G2 is small since there is no measurable difference in Feulgen dye binding to nuclei of starved vs starved and re-fed cells. The data suggest that refeeding induces a resumption of late S phase DNA synthesis, or the preferential synthesis of specific DNA sequences such as rRNA genes.     

Properties of satellite DNA from Brassica nigra

The DNA components of B. nigra were preparatively separated by equilibrium ultracentrifugation in a CsCl density gradient, the buoyant density of the main component being 1,696 g . cm-3, that of the satellite component--1,704 g . cm-3. The properties of individual DNA fractions were investigated. Four major components could be observed on the differential melting curve of satellite DNA. Using the reassociation kinetics method it was shown that 30% of satellite DNA are presented as a fast reassociating component with a length of a repeated unit of approximately 2,5 . 10(3) nucleotide pairs. The calculated values of Tm and buoyant density suggest that the m5C content in satellite DNA is lower than that in the main component. During equilibrium ultracentrifugation in the density gradients of actinomycin D--CsCl and Hg2+--Cs2SO4 the satellite DNA is split into 4 major components.     

The ribosomal cistrons of the water mold Achlya bisexualis

Total DNA was extracted from vegatative mycelia of the water mold Achlya bisexualis. Fractionation of the DNA in CsCl gradients resulted in two components: a major component with a buoyant density of 1.697 g cm^?3 and a minor component with a density of 1.685 g cm^?3. The minor component has been identified as mitochondrial DNA based on extractions from isolated mitochondria and Triton X-100 washed nuclei. Detergent washing of the nuclei yielded DNA in which the mitochondrial DNA component was absent, while the isolated mitochondrial preparations contained DNA enriched in the 1.685 g cm^?3 component. Hybridization studies of A. bisexualis DNA to rRNA show that the ribosomal cistrons have a buoyant density coincident with that obtained with the nuclear DNA. In addition, preliminary evidence indicates that the mitochondrial DNA does not hybridize to the cytoplasmic RNA under the conditions used for this study. Ribosomal RNA hybridized to about 0.65% of the total DNA.     

Isolation and preliminary characterization of cryptic satellite DNA in pea

Optimum conditions have been established for isolation of ‘cryptic’ satellite DNA from the genome of pea (Pisum sativum), using gradients of CS₂SO₄ containing silver ions. At an Ag⁺ :DNA-P ratio (R) of 0.1, and at alkaline pH, four fractions are obtained: mainband (buoyant density 1.437 g cm³; 67% of total DNA), satellite I (buoyant density 1.582 g/cm³; 7% of total DNA), satellite II (buoyant density 1.520 g/cm³, 11% of total) and satellite III (buoyant density variable between 1.45 and 1.51 g/cm³; 15% of total). The reiterated DNA content of these four fractions has been investigated by reassociation experiments conducted over a Cot range of 1 × 10^?5 to 2.0. All four fractions contain at least two kinetic components; each fraction, including the mainband, consists at least partly of highly reiterated DNA. Ribosomal RNA hybridizes only to the mainband.     

Bovine galactosyl transferase. Substrate.managanese complexes and the role of manganese ions in the mechanism.

The dG+dC-rich fractions obtained by density gradient centrifugation of bovine DNA in Cs2SO4/BAMD [J. Cortadas, G. Macaya & G. Bernardi (1977) Eur. J. Biochem. 76, 13--19] were centrifuged in Cs2SO4/Ag+ density gradients. These experiments led to the preparation of the DNA components which had been detected (by analytical centrifugation in CsCl) in the Cs2SO4/BAMD fractions, and also of DNA components which had identical behaviors in Cs2SO4/BAMD gradients and identical buoyant densities in CsCl. A total of eight satellite components and 11 minor components, accounting for 23% and 4% of the bovine genome, respectively, were thus isolated and charcterized in their relative amounts and buoyant densities. The implications of these results on the interpretation of renaturation kinetic data on the bovine genome are discussed.     

Location of Satellite and Homogeneous DNA Sequences on Human Chromosomes

HUMAN DNA^1,2 contains at least two satellite fractions—satellite I (0.5% of the genome) which bands at a density of 1.687 g/cm³ in neutral CsCl and satellite II (2% of the genome) which bands at 1.693 g/cm³. The main band DNA has an average buoyant density between 1.670 and 1.720 g/cm³ and a light shoulder (constituting 15% of the genome) with a buoyant density of 1.696 g/cm³, referred to as homogeneous mainband. Satellite DNA has been observed in many higher organisms³, usually with an unknown function, notable exceptions being cistrons coding for ribosomal RNA⁴ and the DNA coding for histone messenger RNA⁵. To investigate possible functions of human repetitive DNA we have studied the annealing of complementary RNA fractions to chromosomes using in situ hybridization^6,7. We describe here preliminary observations using human satellite II and homogeneous mainband fractions.