DNA nuclear satellites of the genus Brassica: variation between species.

The distribution of nuclear DNAs of nine species of the genus Brassica in CsCl density gradients was investigated. The amount of satellite DNA with buoyant density of 1.704 g - cm-minus3 varies widely between the species. The satellite component is completely absent in B. oleracea; in B. nigra its amount reaches 37%, and in the other species it occupies an intermediate position. The absence of satellite DNA in B. oleracea was demonstrated by equilibrium centrifugation using a Cs2SO4 density gradient, containing Hg2+.     

Chloroplast and nuclear DNA studies in a few members of the <Emphasis Type="Italic">Brassica oleracea</Emphasis> L. group using PCR-RFLP and ISSR-PCR markers: a population genetic analysis

A population genetic analysis of chloroplast and nuclear DNA was performed covering nine wild populations of Brassica oleracea. Three members of the n = 9 group, all close to B. oleracea, Brassica alboglabra Bailey, Brassica bourgeaui (Webb) O. Kuntze and Brassica montana Pourret, were also studied to better understand their relationship with B. oleracea. Chloroplast DNA was analysed using the PCR-RFLP (polymerase chain reaction - restriction fragment length polymorphism) method. The ISSR-PCR (inter-simple sequence repeat - polymerase chain reaction) technique was adopted to study nuclear DNA. Twelve primer pairs of chloroplast DNA showed very good amplification. The amplified product of each primer pair, digested by three restriction enzymes, revealed no variation of cpDNA among the taxa studied. This indicates they may have the same chloroplast genotype. Seven selected ISSR primers have detected genetic variation, both within and among the populations/taxa surveyed. The information obtained on the intra- and inter-populational genetic diversity of wild populations of B. oleracea neatly defined the individual plants. It could provide important guidelines for backing management and conservation strategies in this species. The study confirms a close relationship between B. alboglabra, B. bourgeaui and B. montana, which is parallel to their morphological similitude.     

Study of a haploid yeast strain with an unusually high rDNA content. II. Fractionation of the DNA in preparative Ag+-Cs2SO4 density gradients.

Yeast DNA has been fractionated in preparative Ag+-C-S2SO4 density gradients. After complexing with silver ions at a pH of about 7, the rDNA appears in a defined heavy satellite component in the gradient. For our particular strain, the satellite represents about 15% of the total nuclear DNA and has been identified as the gamma-DNA. In alkaline CsCl density gradients, the satellite DNA forms two bands, of which the light component hybridizes with ribosomal RNA.     

Amplification of nuclear DNA sequences during induced plant cell dedifferentiation

Cell dedifferentiation has been induced in Vicia faba roots by removing the whole meristem (decapitation). When centrifuged to equilibrium in CsCl density gradient, the DNA from dedifferentiating tissues forms a heavier satellite, not occurring in the DNA from differentiated tissues. Most of the radioactivity after [3H]thymidine feeding is found in the satellite DNA. Its sequences have a well defined nuclear localization, as shown by in situ hybridization experiments. These results indicate amplification of G + C-rich nuclear DNA sequences during cell dedifferentiation.     

Observations on centromeric heterochromatin and satellite DNA in salamanders of the genus Plethodon

DNA from Plethodon cinereus cinereus separates into two fractions on centrifugation to equilibrium in neutral CsCl. The smaller of these fractions has been described as a high-density satellite. It represents about 2% of nuclear DNA from this species, and it has a density of 1.728 g/cm³. It is cytologically localized near the centromeres of all 14 chromosomes of the haploid set. In P. c. cinereus the heavy satellite DNA constitutes about 1/4 of the DNA in centromeric heterochromatin. The nature of the rest of the DNA in centromeric heterochromatin is unknown. The number of heavy satellite sequences clustered around the centromeres in a chromosome from P. c. cinereus is roughly proportional to the size of the chromosome, as determined by in situ hybridization with satellite-complementary RNA, and autoradiography. Likewise the amount of contromeric heterochromatin, as identified by its differential stainability with Giemsa, shows a clear relationship to chromosome size. — The heavy satellite sequences identified in DNA from P. c. cinereus are also present in smaller amounts in other closely related forms of Plethodon. Plethodon cinereus polycentratus and P. richmondi have approximately half as many of these sequences per haploid genome as P. c. cinereus. P. hoffmani and P. nettingi shenandoah have about 1/3 as many of these sequences as P. c. cinereus. P. c. cinereus, P. c. polycentratus, and P. richmondii all have detectable heavy satellites with densities of 1.728 g/cm³. Among these forms, satellite size as determined by optical density measurements, and number of satellite sequences as determined from hybridization studies, vary co-ordinately. P. c. cinereus heavy satellite sequences are not detectable in P. nettingi, P. n. hubrichti, or P. dorsalis. The latter species has a heavy satellite with a density of 1.718 g/cm³, representing about 8% of the genomic DNA, and two light satellites whose properties have not been investigated. The heavy satellite of P. dorsalis is cytologically localized in the centromeric heterochromatin of this species. — These observations are discussed in relation to the function and evolution of highly repetitive DNA sequences in the centromeric heterochromatin of salamanders and other organisms.     

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.     

Studies on the Karyotypes and Pollen Morphology of Brassica oleracea L.and B. alboglabra Bailey

The karyotypes and pollen morphology of Brassica oleracea L. and B. alboglabra Bailey were studied by preparing mitotic chromosome specimens and scanning electron microscope. The results are as follows: 1. the karyotypes of the 4 varieties in B. oleracea L. and of B. alboglabra Bailey are similar, all with the same chromosome number (2n=18) satellite number (one pair) and a type of karyotype, but different in respect to satellite position and karyotype symmetry 2. The pollengrains of 2 varieties of B. oleracea L. are 3-colporate and reticulate, distinctly different from those in B. alboglabra, which are pantoporate with smaller lumina. Based on the results we tend to regard that B. alboglabra Bailey is an independent species.     

Buoyant Density and Satellite Composition of DNA of Mouse Heterochromatin

Ten per cent of mouse DNA occurs as a satellite band with a buoyant density lighter than that of the main band¹. This satellite contains highly repetitious DNA^2,3. It has been shown that the amount of satellite is markedly increased in DNA isolated from the heterochromatin fraction of mouse nuclei⁴. Furthermore, in situ hybridization studies have shown that satellite DNA is localized to the pericentromeric heterochromatin of all the mouse chromosomes except the Y^5,6. These observations demonstrate an intimate association between mouse satellite DNA and heterochromatin and they raise the question: is all the DNA from mouse heterochromatin composed of satellite DNA or is a significant portion composed of non-satellite DNA?     

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.     

Composition and synthesis of DNA in synchronously growing cells of Chlorella pyrenoidosa

Summary The composition and synthesis of DNA in synchronous cultures of Chlorella pyrenoidosa strain 211/8b has been investigated. Analytical CsCl density gradient centrifugation gave a homogenous major DNA component with a (G+C) content of 51% and a minor component containing 28% (G+C). The (G+C) contents derived from melting profiles were 2–3% lower. A second minor component with approximately 41% (G+C) content was inferred from banding patterns of labelled DNA in preparative CsCl density gradients. ¹⁴C-uracil was readily incorporated into the pyrimidine moieties of the major (nuclear) DNA between the 10th and 18th hour after beginning of the light period, but not at any other time. ¹⁴C-uracil incorporation into the minor (satellite) component was low but continuous throughout the whole cell cycle. The incorporation is correlated with an increase in the proportion of satellite DNA from 6% up to 20% during the time when no nuclear DNA replication takes place. The results suggest that different regulatory mechanisms exist for the nuclear and for satellite DNA synthesis.     

Two highly repetitive DNA satellites of Drosophila hydei localized within the α-heterochromatin of specific chromosomes

Two major highly repetitive satellites have been isolated from nuclear DNA of Drosophila hydei by sequential centrifugations in Ag⁺/Cs₂SO₄, actinomycin D/CsCl and CsCl. Their CsCl-densities are 1.696 and 1.714 g/cm³. In diploid larval brains they comprise about 13% and 4% respectively of the DNA. Both satellites are localized and chromosome specific. The 1.696 component was shown to be derived from the X-heterochromatin by comparison of different stocks containing different amounts of X-heterochromatin and by in situ hybridization of the ¹²⁵I-labelled light single strand of this satellite. Since the amount of X-heterochromatin equals the amount of this satellite it was concluded that the 1.696 satellite is the only major DNA component of the X-heterochromatin besides minor DNA fractions (e.g. rDNA). The other highly repetitive satellite (1.714 g/cm³) hybridized in situ to all four acrocentric autosome pairs of D. hydei, but neither to the X nor to the small dot-like sixth chromosome, and not to the Y.     

Physical organization of the major duplication on Brassica oleracea chromosome O6 revealed through fluorescence in situ hybridization with Arabidopsis and Brassica BAC probes.

The close relationship between Brassica oleracea and Arabidopsis thaliana has been used to explore the genetic and physical collinearity of the two species, focusing on an inverted segmental chromosome duplication within linkage group O6 of B. oleracea. Genetic evidence suggests that these segments share a common origin with a region of Arabidopsis chromosome 1. Brassica oleracea and Arabidopsis bacterial artificial chromosome probes have been used for fluorescence in situ hybridization analysis of B. oleracea pachytene chromosomes to further characterize the inverted duplication. This has been highly effective in increasing the local resolution of the cytogenetic map. We have shown that the physical order of corresponding genetic markers is highly conserved between the duplicated regions in B. oleracea and the physical lengths of the regions at pachytene are similar, while the genetic distances are considerably different. The physical marker order is also well conserved between Arabidopsis and B. oleracea, with only one short inversion identified. Furthermore, the relative physical distances between the markers in one segment of B. oleracea and Arabidopsis have stayed approximately the same. The efficacy of using fluorescence in situ hybridization, together with other forms of physical and genetic mapping, for elucidating such issues relating to synteny is discussed.     

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.     

Association of DNA with the nuclear lamina in Ehrlich ascites tumor cells

We have studied in vitro binding of DNA to nuclear lamina structures isolated from Ehrlich ascites tumor cells. At low ionic strength in the presence of Mg++, they bind considerable amounts of mouse and bacterial DNA, forming complexes stable in 2 M NaCl. Single-stranded DNA and pulse-labeled DNA show higher binding efficiencies than native uniformly labeled DNA. When mixing occurs in 2 M NaCl, complex formation is inhibited. When nuclei are digested with DNAse I under conditions that favor chromatin condensation, DNA associated with matrices subsequently prepared from such nuclei is markedly enriched in satellite DNA. If digestion is carried out with DNAse II while nuclei are decondensed in EDTA, no enrichment in satellite DNA is observed. Preparations of purified, high-molecular weight, double-stranded DNA contain variable amounts of fast-sedimenting aggregates, which are insoluble in 2 M NaCl but are dispersed by DNA fragmentation or denaturation. These results point at some artifacts inherent in studies of DNA bound to residual nuclear structures in vivo and suggest conditions expected to avoid these artifacts. Further, using controlled digestion with DNAse II, we have studied the in vivo association of DNA with nuclear lamina isolated from Ehrlich ascites tumor cells. In the course of DNA fragmentation from above 50 kbp to about 20 kbp average size, the following events were observed. The DNA of high molecular weight (much longer than 50 kbp) behaved as if tightly bound to the nuclear lamina, as judged by sedimentation in sucrose and metrizamide density gradients, electron microscopy, and retention on glass fiber filters. As the size of DNA decreased, it was progressively detached from the nuclear lamina, and at about 20 kbp average length practically all DNA was released. The last 1-4% of DNA, although cosedimenting with the nuclear lamina in sucrose gradients, behaved as free DNA, banding at 1.14 g/cm3 in metrizamide density gradients and showing less than 4% retention on filters. At no stage of digestion did the DNA cosedimenting with nuclear lamina show changes in satellite DNA content relative to that of total DNA or enrichment in newly replicated DNA. It was shown, however, that digestion of nuclear lamina-DNA complex with EcoRI or Hae III led to the formation of DNA-protein aggregates, which banded at 1.35 g/cm3 in high salt containing metrizamide density gradients and which were strongly enriched in satellite DNA.(ABSTRACT TRUNCATED AT 400 WORDS)     

Analysis of plastid DNA-like sequences within the nuclear genomes of higher plants

A wide-ranging examination of plastid (pt)DNA sequence homologies within higher plant nuclear genomes (promiscuous DNA) was undertaken. Digestion with methylation-sensitive restriction enzymes and Southern analysis was used to distinguish plastid and nuclear DNA in order to assess the extent of variability of promiscuous sequences within and between plant species. Some species, such as Gossypium hirsutum (cotton), Nicotiana tabacum (tobacco), and Chenopodium quinoa, showed homogenity of these sequences, while intraspecific sequence variation was observed among different cultivars of Pisum sativum (pea), Hordeum vulgare (barley), and Triticum aestivum (wheat). Hypervariability of plastid sequence homologies was identified in the nuclear genomes of Spinacea oleracea (spinach) and Beta vulgaris (beet), in which individual plants were shown to possess a unique spectrum of nuclear sequences with ptDNA homology. This hypervariability apparently extended to somatic variation in B. vulgaris. No sequences with ptDNA homology were identified by this method in the nuclear genome of Arabidopsis thaliana.      

Ribosomal DNA as a convenient probe to follow segregation and possible divergency from expected homozygosity after haploidization of an androgenetic process

Summary Restriction fragment length polymorphism of the wheat nuclear ribosomal DNA has been studied in several steps of a breeding scheme, including parental genotypes, F1 hybrid, F9 generation, and anther-derived doubled haploid lines obtained from F9. Ribosomal DNA represents a suitable molecular marker in following segregation and possible divergency from expected homozygosity after haploidization of an androgenetic process. It has been shown to undergo variations among the first cycle-doubled haploid lines in the relative amount of two different sizes of ribosomal DNA repeat units. The specificity and peculiar properties of the plant system used allowed us to assign an intrachromosomal location (short arm of the chromosomes 1B, 1R or 6B) to several ribosomal DNA repeat units that differ by the length of their nontranscribed spacer region.     

Ribosomal DNA in a nuclear satellite of tomato

A satellite DNA of buoyant density 1.704 constitutes approximately 5%–6% of nuclear DNA isolated from cherry tomato leaves. Isolated satellite DNA exhibits a multi-component melting profile. Kinetic complexity measurements indicate that 37% of the satellite consists of repeating units of 10 ⁵ daltons, and 48% of it consists of repeating units of 5.5 x 10⁶ daltons. The latter component is identified as DNA coding for ribosomal RNA on the basis of its buoyant density, kinetic complexity, and abundance in nuclear DNA, 3.2% as determined by saturation hybridization measurements. Saturation studies show that the more rapidly reassociating component of the satellite does not code for 5S RNA. The question of genetic linkage between satellite components is not resolved by this study.     

DNA of some anaerobic rumen fungi: G + C content determination

The nuclear DNAs from five species of anaerobic rumen fungi have been isolated and purified by means of two extraction methods (with and without 8 M urea). Their G + C contents have been characterized by the thermal denaturation procedure of Marmur and Doty. As has already been shown in Neocallimastix frontalis, the results obtained by the two techniques demonstrated a very low G + C content (less than 20%) and the constant presence of satellite DNA.     

Interspersion of highly repetitive DNA with single copy DNA in the genome of the red crab, Geryon quinquedens.

Kinetic analysis of the reassociation of 420 nucleotide (NT) long fragments has shown that essentially all of the repetitive sequences of the DNA of the red crab Geryon quinquedens are highly repetitive. There are negligible amounts of low and intermediate repetitive DNAs. Though atypical of most eukaryotes, this pattern has been observed in all other brachyurans (true crabs) studied (1,2). The major repetitive component is subdivided into short runs of 300 NT and longer runs of greater than 1200 NT while the minor component has an average sequence length of 400 NT. Both components reassociate at rates commonly observed for satellite DNAs. Unique among eukaryotes the organization of the genome includes single copy DNA contiguous to short runs (approximately 300 NT) of both repetitive components. Although patent satellites are not present, subsets of the repetitive DNA have been isolated by either restriction endonuclease digestion or by centrifugation in Ag+ or Hg2+/Cs2SO4 density gradients.     

Satellite DNA specific to knob heterochromatin inCucumis metuliferus (Cucurbitaceae)

Buoyant density gradient analysis of nuclear DNA of fourCucumis species showed asymmetric profiles indicating the presence of satellite DNA sequences in the nuclear genome. A highly repeated satellite DNA sequence was isolated from the nuclear genome ofC. metuliferus under neutral CsCl gradients. The satellite DNA constitutes about 4.96% of total nuclear DNA and has 48.06% guanine plus cytosine content. The kinetic complexity of satellite DNA is 150 times smaller than T₄ phage DNA and the base sequence divergence is low.³H-labeled cRNA transcribed from satellite DNA hybridized clearly to six heterochromatic knobs of pachytene chromosomes. The knob heterochromatin can be distinguished by Giemsa C-banding of pachytene chromosomes. Restriction enzyme analysis and Southern blot hybridization indicated that the satellite DNA has a tandem arrangement and predominantly formed two bands of size 210 and 151 base pairs. Absence of knob satellite DNA ofC. metuliferus in the nuclear genomes ofC. melo, C. anguria andC. sativus showed thatC. metuliferus remains isolated within the genusCucumis.