Properties of satellite DNA of Phaseolus vulgaris]

Nuclear DNA components of Ph. vulgaris were preparatively separated by equilibrium ultracentrifugation in Hg++-Cs2SO4 density gradient (buoyant density of the major component in CsCl density gradient 1.694 g/cm3., satellite component--1.703 g/cm3). The properties of individual DNA fractions were investigated. The melting curve of satellite DNA of Ph. vulgaris has biphasic character. The observed heterogeneity of satellite DNA component is of intermolecular nature. This is illustrated by the splitting of unsheared satellite DNA into two components during renaturation, as well as by its behaviour in Hg++-Cs2SO4 density gradient at high rf value. The width of satellite DNA reassociation curve covers three decades of Cot. The length of the major repeating sequences of the satellite component is close to the length of phage T2 DNA. During chromatography on MAK column satellite DNA elutes earlier than the major component due to its higher GC-content. It is suggested that one of the satellite DNA fractions of Ph. vulgaris contains rRNA genes.     

Variation in satellite DNA from some higher plants

Pure satellite DNAs were prepared as minor components after centrifugation to equilibrium on CsCl gradients. A single satellite DNA band was isolated from flax (Linum usitatissimum) DNA and two bands were resolved in cucumber (Cucumis sativus) DNA. These apparently homogeneous components of the plant genomes were further analyzed by thermal denaturation and renaturation. The flax satellite DNA appeared homogeneous on thermal denaturation but was shown to contain several components of renaturation. The two cucumber satellite DNAs were different from each other, but both showed at least two components in denaturation and renaturation analyses. Renaturation in the three satellites, particularly in flax, was inaccurate, indicating a considerable degree of sequence divergence. Although each satellite contained quite large amounts of simple repetitious sequences, a residual heterogeneous DNA fraction was always present. It is considered that this was too large a portion of the satellite DNA to be due to organelle or ribosomal DNA in cucumber. The latter possibility is precluded in flax, where the satellite is completely resolved in buoyant density from both organelle and ribosomal DNA.     

Satellite DNA in the kangaroo Macropus rufogriseus

Two distinct satellite DNAs, amounting to 25% of the total DNA, were isolated from the nuclei of the red-necked wallaby, Macropus rufogriseus. The physical properties of native, single-stranded and reassociated molecules were studied in buoyant-density gradient centrifugation. The homogeneity of each satellite fraction was examined using melting characteristics of native and reassociated DNA, and renaturation kinetics. These data suggest that sequence heterogeneity exists in both fractions. Each satellite fraction was found by in situ hybridization to be localized in heterochromatin of interphase nuclei and in the centromeric regions of metaphase chromosomes. The chromosomal distributions of the two satellite DNAs differentiate the sex chromosomes, which have sequences of only one satellite, from the autosomes which have sequences of both satellites in the centromeric heterochromatin. Giemsa C-banding techniques also showed a differentiation of the centromeric regions of sex chromosomes from those of the autosomes.     

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.     

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.     

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.     

Length dependence of the kinetic complexity of mouse satellite DNA

Treatment of renatured mouse satellite DNA with the single stranded DNA specific endonuclease Sl leads to the isolation, with no losses, of regions of length, L ≤ 56±28, from molecules containing several such regions. The rate of renaturation is observed to be an unusual function of length, extrapolating to an apparent complexity, N ≤ 36±9. The results are consistent with a model of tandem, spaced, repetitions where multiple nucleations may occur between two strands containing the complementary repetition units.     

Identification of a mutation in chloroplast DNA correlated with formation of defective chloroplasts in a variegated mutant of Nicotiana tabacum

Summary As in wild-type Nicotiana tabacum L., two satellite DNAs having densities of 1.700 and 1.705 g cm^–3 in CsCl were identified in the organelle fraction of homogenates made from variegated leaves of a cytoplasmic mutant of N. tabacum. As the proportion of white to green tissue increased a great reduction in the 1.700 chloroplast DNA occurred correlated with a concomitant reduction in the total number of defective and normal chloroplasts per cell. At the same time, there was an absolute increase in the 1.705 satellite DNA. Separation of the two satellite DNAs was achieved by one cycle of purification on NaI gradients. When the 1.700 chloroplast DNAs from white and from green tissue of variegated leaves were compared, identical properties were found by the conventional buoyant density, T _m and renaturation kinetics measurements. However, using a specially constructed difference melting system, the 1.700 DNA from defective chloroplasts was shown to have an approximately 1% higher GC composition than the DNA from normal chloroplasts. Also, by renaturation of a mixture of alkali denatured normal and defective chloroplast DNAs and subsequent spreading in formamide for electron microscopy, internal regions of mismatching were observed. The nonhomologous region corresponded to about 500–1000 base pairs. No differences in composition of the 1.705 satellite DNA derived from white or green tissues were detected either by difference melting or formation of heteroduplexes.     

Liverwort genomes display extensive structural variations

PIKE, L. M., HU, A., RENZAGLIA, K. S. & MUSICH, P. R., 1992. Liverwort genomes display extensive structural variations. Analyses of the total genomic DNA of eight species of liverworts and two species of green algae by thermal denaturation and CsCl buoyant density gradient centrifugation reveal a high degree of structural complexity and interspecific heterogeneity. The hepatic taxa exhibit two or more DNA components of varying base composition. Average G4-C contents of total cellular DNA calculated from melting profiles are similarly variable, ranging from 38% to 53% G + C. The green alga Chara , a member of the ancestral line to land plants, shows similarities with liverworts in possessing multiple DNA components of comparable complexity, whereas Hydrodiciyon DNA displays a single component. Detailed hybridization analyses of individual density gradient fractions using α-tubulin, rRNA and ribulose 1,5-bisphosphate carboxylase/oxygenase large subunit (rbcL) gene probes were performed to locate the low-copy number and moderately repetitive nuclear genes, and the chloroplast chromosome, respectively. The location of each gene within the density gradient is highly variable among the organisms examined; a-tubulin occurs in fractions ranging from 44–64% G + C, rDNA in 50–64% G + C fractions, and the RbcL gene is located in fractions from 30–59% G + C. For a given species, the two nuclear genes normally overlap in their distributions within the gradient. In most instances, neither gene occurs in the major DNA components, indicating that these components may contain repetitive DNAs. The observed variation in the density of the rbcL gene implies substantial reorganization of the chloroplast genome. The overall differences in the genomic components within and between taxa provide insight into the dynamics of DNA structure that have occurred during the extended evolutionary history of these organisms.     

Cyclization of three satellite components of calf thymus DNA.

Cyclization of denatured and reannealed satellite components of calf thymus DNA was studied by electron microscopy. All three satellite DNA components studied (1.707g/cm-3, 1.714g/cm-3 and 1.721g/cm-3) form circular structures indicating that the sequences of the calf thymus satellite DNAs are arranged in a tandemly repetitious manner. Under appropriate annealing conditions the amount of circular structures is reproducible and practically no aggregates are formed. By comparison of cyclization experiments under defined conditions it is demonstrated that individual satellite components differ in the amount of circular structures formed during reassociation and in the distribution of linear and circular molecules. From the distribution of the contour lengths of circular molecules we conclude that the length of the repetitive sequence decreases with increasing buoyant density of the satellite components. The average lengths of the repetitive sequences calculated from electron microscopy measurements are in good agreement with those from renaturation kinetics.     

Mitochondrial deoxyribonucleic acid from Tetrahymena pyriformis and its kinetic complexity

1. Mitochondrial DNA from Tetrahymena pyriformis strain T has a buoyant density (rho) of 1.685 compared with rho1.688 for whole cell DNA. Mitochondrial preparations from T. pyriformis strain W show an enrichment of a light satellite (rho1.686), although this is not obtained free from nuclear DNA (rho1.692). 2. T. pyriformis mitochondrial DNA renatures rapidly and the kinetics of this process indicate a complexity of approx. 3x10(7) daltons. 3. The base-pairing in the renaturation product is of a precise nature, since the ;melting' temperature (80.5 degrees C) is indistinguishable from that of the native DNA (80.5 degrees C). 4. Centrifugation of mitochondrial DNA in an alkaline caesium chloride density gradient gives two bands, implying the separation of the complementary strands.     

Sequence arrangement in satellite DNA from the muskmelon

Two fractions of a satellite DNA from the muskmelon (Cucumis melo L.) isolated as a unimodal peak from CsCl gradients, differ in melting properties and complexity as estimated by reassociation kinetics. At 49.8 C, all of the low melting fraction was denatured and all of the high melting fraction was native. There were almost no partially denatured molecules detected in the electron microscope at this temperature. This observation provides direct evidence that the two fractions are not closely linked. We conclude that satellite I, the high t_m, low complexity fraction, exists as a 600-nucleotide sequence in blocks of at least 67 tandem repeats. Since the complexity of the low melting fraction, satellite II, is greater than the size of the molecules in our assay, we can only say that the minimum size of each unit of satellite II is 2.5 × 10⁷ daltons. It is unlikely that any spacer sequences are interspersed with either satellite.     

Attempted separation of transcriptively active and inactive chromatin by hydroxylapatite thermal chromatography

Chromatin and purified DNA were fractionated by hydroxylapatite thermal chromatography. Fractions of varying thermal stability were tested for the proportions of transcribed sequences and repetitive sequences relative to the unfractionated genome. The first 80--85% of either total chromatin or purified DNA eluted from hydroxylapatite contained the same proportion of hybridizable sequences as total DNA. The remaining 15--20% of chromatin eluting at the highest temperatures was depleted of transcribed sequences. Analysis of the 20% highest melting fraction of purified DNA showed that, while the first two-thirds of this fraction contained the same proportion of transcribed sequences as unfractionated DNA, the last third, comprising about 6% of total DNA, was depleted of active sequences. Although no major differences were detected in nonrepetitive sequence complexity of chromatin fractions, there was a correlation between relative thermal stability and repetitive sequence content in fractions of both chromatin and DNA separated by thermal chromatography. Fragments eluting at higher temperatures contained a greater proportion of repetitive sequences, as indicated by a rapidly renaturing component. Most likely, the latest eluting fractions from both chromatin and purified DNA were enriched for a nontranscribed, highly reiterated, G+C rich satellite component of the chicken genome.     

Molecular hybridization between rat liver deoxyribonucleic acid and complementary ribonucleic acid

RNA (cRNA) was synthesized in vitro on a template of rat liver DNA and its hybridization with rat liver DNA was studied by using the nitrocellulose-filter method. Sonication of the DNA diminished its apparent capacity to hybridize with RNA by about 50%. This is not due to cross-linkage of DNA molecules, because it could be shown that less than 2% of the sonicated DNA was cross-linked. The effect is due instead to the small size of the sonicated DNA molecules. Below a single-stranded molecular weight of 5×10⁵ the DNA showed a progressive loss of capacity to hybridize with decrease in molecular weight. Evidence is presented suggesting that the apparently diminished capacity of the DNA to hybridize is due to loss of hybridized DNA from the membrane filters. When cRNA at concentrations of up to 25μg/ml is annealed with sonicated total DNA, an apparent hybridization saturation value is found at which about 2.5% of the DNA is hybridized with RNA. Increasing the cRNA concentration tenfold brought about the hybridization of a second component of the DNA approximately equal in amount to the first. The renaturation of rat liver DNA was studied by measuring the fall in the extinction at 260nm and two different components of renaturation were observed within the reiterated fraction of DNA. By hybridizing cRNA with different fractions of rat DNA the two components of the hybridization curve are shown to correspond to the two components of the renaturation curve. The conclusion is drawn that at a cRNA concentration of 250μg/ml most of the reiterated fraction of rat liver DNA is hybridized after annealing for 16h under standard conditions (0.30m-sodium chloride–30mm-sodium citrate at 65°C). Even with such a high cRNA concentration little or no hybridization of the slowly renaturing DNA fraction occurs. It is suggested that the most highly reiterated DNA component is poorly transcribed in vitro.     

Characterization of the genome of the small free-living amoeba Acanthamoeba castellanii.

The cellular DNAs of Acanthamoeba castellanii have been characterized by their behaviour in CsC1 density gradients, by their thermal denaturation and by their renaturation kinetics. Whole-cell DNA exhibits, on CsC1 density gradients, a major peak with a density of 1.717 g/cm3 (major component) and a minor peak with a density of 1.692 g/cm3 (minor component). The major component is nuclear and the minor component is of cytoplasmic origin. The latter contains mitochondrial DNA as well as an extramitochondrial DNA fraction. Reiterated sequences make up approximately 14% of the total and are mainly cytoplasmic. They are characterized by three families of nucleotide sequences. The mitochondrial DNA exhibits a complex renaturation pattern. The fast renaturing component has a calculated complexity of 4.107 daltons. The slower renaturing component has a kinetic complexity tentatively estimated as 1.1010 daltons. The melting profile of mitochondrial DNA suggests heterogeneity in base composition.     

Base sequence homology and renaturation studies of the deoxyribonucleic acid of extremely halophilic bacteria

The genetic relatedness among various strains of halophilic bacteria has been assessed by deoxyribonucleic acid-deoxyribonucleic acid (DNA-DNA) duplex formation and ribosomal ribonucleic acid (RNA) hybridization. All of the strains of extremely halophilic rods are closely related, and the extent of divergence of base sequence is similar for the major and minor DNA components. Parallel experiments with ribosomal RNA revealed a relationship between the extremely halophilic rods and cocci and a more distant relationship to moderate halophiles and to a photosynthetic extreme halophile. Renaturation studies of halophile DNA exclude the possibility that the satellite DNA represents multiple copies of a small episomal element. The kinetics of DNA renaturation show that the genome size of the extreme and moderate halophiles is similar to that of Escherichia coli.     

Characterization of cytoplasmic and nuclear genomes in the colorless alga Polytoma

DNA isolated from purified nuclei of Polytoma obtusum has a buoyant density of 1.711 g/ml in CsCl, a Tm of 91.3° C in SSC, and a G + C content of 52.5% as determined by base composition analysis. Thermal dissociation and reassociation studies indicated that this nuclear DNA contains a considerable amount of heterogeneity. Under appropriate reannealing conditions for denatured DNA, about 15% of the DNA reannealed to form a satellite peak at a density of 1.711 g/ml within one hour. Native DNA fractions of different average buoyant densities, ranging from 1.723 to 1.708 g/ml were also obtained in a preparative CsCl gradient, indicating the presence of intermolecular heterogeneity at a molecular size of 8.5×10⁶ daltons. The nuclear DNA reassociated as three distinct classes. The very fast species constituted about 20 % of the total hyperchromicity, the class of intermediate rate comprised roughly 10% of the nuclear DNA, while the remaining 70% consisted of unique sequences. The haploid genome set was estimated by renaturation kinetics studies to contain 5.0×10¹⁰ daltons of DNA or 7.5×10⁷ nucleotide pairs. The analytical complexity of the total nuclear genome was found to be 9.35×10¹⁰ daltons, thus indicating that vegetative cells of P. obtusum are diploid.     

Characterization of DNA components from some colorless algae

The DNA components of five colorless algae were characterized by their buoyant densities in cesium chloride. Two DNA components were detected in Polytoma obtusum and Polytoma uvella. Upon renaturation of the thermally denatured DNA the minor and approx. 15% of the major DNA component returned to their native densities. The buoyant densities of the major and minor DNA of P. obtusum and P. uvella are different from that of the morphologically and biochemically similar green alga Chlamydomonas reinhardtii. A major and a minor DNA component with the same buoyant densities as that of the green alga Euglena were also found in Astasia longa, which is morphologically similar to Euglena. The renaturation of the minor but not the major component was readily detectable by the change in buoyant density. Only one DNA component was detected in Polytomella agilis and Polytomella caeca. After thermal denaturation approx. 5% of each of these DNA components were renatured readily. Based on these data, the possible evolutionary origin of these colorless algae is discussed.     

A critical examination of possible fractionations of human DNA according to base composition.

Human DNA has been fractionated according to base composition by sedimentation equilibrium in an HgCl2/Cs2SO4 density gradient, followed by sedimentation equilibrium in an actinomycin/cesium formate density gradient. The fractions of different base composition resulting from this procedure were subsequently analyzed by sedimentation equilibrium in CsCl, DNA renaturation kinetics, and electron microscopy. All fractions contain similar kinetic classes of repeated DNA sequences as judged by renaturation studies. Short (300 nucleotides) interspersed repeated sequences are found in all fractions with no noticeable enrichment for these sequences in any fraction. Repeated sequences from fractions of different base composition are partially able to cross-hybridize, demonstrating that nearly identical repeated sequences occur in molecules of different base composition. These findings are critically compared to reports of successful density gradient fractionations of different human DNA sequence classes.