Application of DNA sonication in the study of reassociation kinetics]

Single-stranded breaks arising is DNA under sonication divide the molecule in short double-stranded regions of lengths depending on sonication conditions. The reassociation rate of DNA with single-stranded breaks is considerably lowered as compared with intact DNA of the same length. For sonicated DNA the slowing of reassociation and the deflection to higher orders of C(o)t of the reaction is observed at the late stages. Further process of sonication occurs likely on single-stranded breaks and DNA fragments obtained as a result of infinite sonication are practically intact. Reassociation of DNA, degraded to a "saturation", proceeds as a second order reaction in precise accordance with the obtained fragment length.     

Improving specificity of DNA hybridization-based methods

Methods based on DNA reassociation in solution with the subsequent PCR amplification of certain hybrid molecules, such as coincidence cloning and subtractive hybridization, all suffer from a common imperfection: cross-hybridization between various types of paralogous repetitive DNA fragments. Although the situation can be slightly improved by the addition of repeat-specific competitor DNA into the hybridization mixture, the cross-hybridization outcome is a significant number of background chimeric clones in resulting DNA libraries. In order to overcome this challenge, we developed a technique called mispaired DNA rejection (MDR), which utilizes a treatment of resulting reassociated DNA with mismatch-specific nucleases. We examined the MDR efficiency using cross-hybridization of complex, whole genomic mixtures derived from human and chimpanzee genomes, digested with frequent-cutter restriction enzyme. We show here that both single-stranded DNA-specific and mismatched double-stranded DNA-specific nucleases can be used for MDR separately or in combination, reducing the background level from 60 to 4% or lower. The technique presented here is of universal usefulness and can be applied to both cDNA and genomic DNA subtractions of very complex DNA mixtures. MDR is also useful for the genome-wide recovery of highly conserved DNA sequences, as we demonstrate by comparing human and pygmy marmoset genomes.     

Reassociation kinetics of three satellite components of calf thymus DNA.

Using absorption measurements the reassociation kinetics of three satellite DNA components isolated from calf thymus was studied under various conditions. A different method using CsC1 density gradient determinations particularly suited for kinetic analysis of mixtures was also used and shown to give similar results. Reassociation rate constants were corrected for mismatching during strand reassociation using data obtained by kinetic analysis of fractions of the 1.714 g/cm-3 satellite component. The values of corrected as well as uncorrected complexities were calculated and compared with results of other methods. They were shown to be compatible with the concept of sequence repetition at various levels.     

Relationship between the study of DNA reassociation kinetics of various chromosomal forms of Ellobius and questions concerning the pathways of chromosome rearrangement during evolution

Fifteen chromosome forms of Ellobius talpinus (from 2n = 31 to 2n = 54) were found in the small area in the Pamirs. Low-chromosome karyotypes evolved from 54-chromosomal ancestral form by Robertsonia centric fusions. The DNA reassociation kinetics of 34- and 54-chromosome forms of E. talpinus have been studied. For comparison DNA of E. lutescens (2n = 17) the karyotype of which seems to have arisen from 54-chromosome ancestor by Robertsonian and other types rearrangements was examined. Reassociation profiles of Ellobius DNA suggest the existence of several repeated sequences families with different frequences of repetitions. The reassociation curves of DNA from 34- and 54-chromosome forms were identical. These data indicate absence of changes in DNA molecular organization during the evolution of E. talpinus karyotypes by Robertsonian fusions. Comparative analysis of DNA reassociation kinetics of E. talpinus and E. lutescens showed identical characteristics of highly repeated sequences and of one from the three intermediate fractions, however Cot 1/2, complexity and repetitive frequencies of two intermediate fractions of E. talpinus and E. lutescens were different. It is possible that non-robertsonian rearrangements of E. lutescens karyotype affected only intermediate repetitions. The alternative explanation of these data is a simple divergence of repeated sequences during the evolution of E. lutescens DNA.     

The arbuscular mycorrhizal fungus Glomus intraradices is haploid and has a small genome size in the lower limit of eukaryotes

The genome size, complexity, and ploidy of the arbuscular mycorrhizal fungus (AMF) Glomus intraradices was determined using flow cytometry, reassociation kinetics, and genomic reconstruction. Nuclei of G. intraradices from in vitro culture, were analyzed by flow cytometry. The estimated average length of DNA per nucleus was 14.07+/-3.52 Mb. Reassociation kinetics on G. intraradices DNA indicated a haploid genome size of approximately 16.54 Mb, comprising 88.36% single copy DNA, 1.59% repetitive DNA, and 10.05% fold-back DNA. To determine ploidy, the DNA content per nucleus measured by flow cytometry was compared with the genome estimate of reassociation kinetics. G. intraradices was found to have a DNA index (DNA per nucleus per haploid genome size) of approximately 0.9, indicating that it is haploid. Genomic DNA of G. intraradices was also analyzed by genomic reconstruction using four genes (Malate synthase, RecA, Rad32, and Hsp88). Because we used flow cytometry and reassociation kinetics to reveal the genome size of G. intraradices and show that it is haploid, then a similar value for genome size should be found when using genomic reconstruction as long as the genes studied are single copy. The average genome size estimate was 15.74+/-1.69 Mb indicating that these four genes are single copy per haploid genome and per nucleus of G. intraradices. Our results show that the genome size of G. intraradices is much smaller than estimates of other AMF and that the unusually high within-spore genetic variation that is seen in this fungus cannot be due to high ploidy.     

In vitro reassociation of phycobiliproteins and membranes to form functional membrane-bound phycobilisomes

A membrane-bound phycobilisome complex has been isolated from the cyanobacterium Fremyella diplosiphon grown in green light, thus containing phycoerythrin in addition to phycocyanin and allophycocyanin. The complex was dissociated by lowering the salt concentration. In the mixture obtained, no energy transfer from phycoerythrin to chlorophyll (Chl) a was observed. Reassociation of the phycobiliproteins and membrane mixture was carried out by a gradual increase of the salt concentration. The complex obtained after reassociation was characterized by polypeptide composition, absorbance and fluorescence emission spectra and electron microscopy. These analyses revealed similar composition and structure for the original and reconstituted membrane-bound phycobilisomes. Fluorescence emission spectra and measurements of Photosystem II activity demonstrated energy transfer from phycoerythrin to Chl a (Photosystem II) in the reconstituted complex. Reassociation of mixtures with varying phycoerythrin / Chl ratio showed that the phycobiliprotein concentration was critical in the reassociation process. Measurements of the amount of phycobilisomes reassociated with the photosynthetic membrane did not show saturation of binding when increasing the phycobiliprotein concentration. The ratio phycoerythrin / Chl a in the native complex was 7:1 (mg / mg). When the phycobiliprotein concentration was increased during the reassociation process, a ratio of 13–15 mg phycoerythrin / mg Chl a could be obtained. Under these conditions, only part of the phycobilisomes attached to the thylakoids was able to transfer energy to Photosystem II.     

Characteristics of reassociation of DNA in polytene chromosome preparations of malaria mosquito]

Analysis of DNA reassociation in polytene chromosome preparations of malarial mosquito is presented. It was shown that reassociation of highly repeated DNA sequences takes place during the first two hours. Then, middle repeated DNA sequences are reassociating at the third hour. Reassociation of different DNA sequences is going during the fourth and fifth hours.     

Reassociation of interspersed moderate DNA repeats

Reassociation kinetics of the fragments of DNA consisting of interspersed repetitive and non-repetitive nucleotide sequences is considered in this paper. Based on the model, suggested by Gavrilov and Mazo (Mol. biol., 11, 101 1977), which takes into account the random DNA shearing, both reassociation kinetics of the total DNA in the region corresponding to interspersed repeat reassociation and that of the isolated preparation of interspersed repetitive sequences are calculated. In both cases influence of the repeat length on the reassociation rate is demonstrated. The estimation of the repetition frequency of rare repeats from pigeon genome is specified using calculations performed.     

An alternative view of mammalian DNA sequence organization: II. Short repetitive sequences are organized into scrambled tandem clusters in Syrian hamster DNA

Hyperchromicity, S₁ nuclease digestion, and reassociation studies of Syrian hamster repetitive DNA have led to novel conclusions about repetitive sequence organization. Re-evaluation of the hyperchromicity techniques commonly used to determine the average length of genomic repetitive DNA regions indicates that both the extent of reassociation, and the possibility of non-random elution of hyperpolymers from hydroxyapatite can radically affect the observed hyperchromicity. An alternative interpretation of hyperchromicity experiments, presented here, suggests that the average length of repetitive regions in Syrian hamster DNA must be greater than 4000 nucleotides.S₁ nuclease digestion of reassociated 3200 nucleotide Syrian hamster repetitive DNA, on the other hand, yields both long (>2000 nucleotides) and short (300 nucleotides) resistant DNA duplexes. Calculations indicate that the observed mass of short nuclease-resistant duplexes (>60%) is too large to have arisen only from independent short repetitive DNA sequences alternating with non-repetitive regions. Reassociation experiments using long and short S₁ nuclease-resistant duplexes as driver DNA indicate that all repetitive sequences are present in both fractions at approximately the same concentration. Isolated long S₁ nuclease-resistant duplexes, after denaturation, renaturation, and a second S₁ nuclease digestion, again produce both long and short DNA duplexes. Reassociation experiments indicate that all repetitive DNA sequences are still present in the “recycled” long S₁ nuclease-resistant duplexes. These experiments imply that many of the short S₁ nuclease-resistant repetitive DNA duplex regions present in reassociated Syrian hamster DNA were initially present in the genome as part of longer repetitive sequence blocks. This conclusion suggests that the majority of “short” repetitive regions in Syrian hamster DNA are organized into scrambled tandem clusters rather than being individually interspersed with non-repetitive regions.     

Comparison of phenotypic diversity and DNA heterogeneity in a population of soil bacteria.

The phenotypic diversity of about 200 bacterial strains isolated from soil was compared with the genotypic diversity of the same population. The strains were phenotypically characterized by the API 20B test system. The results of these tests were subjected to cluster analysis, which revealed 41 biotypes at 80% similarity. The five dominating biotypes contained 43% of the strains. The phenotypic diversity as determined by the Shannon index, equitability, rarefaction, and cumulative differences was high, but indicated some dominant biotypes. The genetic diversity was measured by reassociation of mixtures of denatured DNA isolated from the bacterial strains (C0t plots). The observed genetic diversity was high. Reassociation of DNA from all bacterial strains together revealed that the population contained heterologous DNA equivalent to 20 totally different bacterial genomes (i.e., genomes that have no homology). This study showed that reassociation of DNA isolated from a collection of bacteria gave a good estimate of the diversity of the collection and that there was good agreement with different phenotypic diversity measures. The Shannon index in particular has features in common with the genetic diversity measure presented here.     

Comparison of phenotypic diversity and DNA heterogeneity in a population of soil bacteria

The phenotypic diversity of about 200 bacterial strains isolated from soil was compared with the genotypic diversity of the same population. The strains were phenotypically characterized by the API 20B test system. The results of these tests were subjected to cluster analysis, which revealed 41 biotypes at 80% similarity. The five dominating biotypes contained 43% of the strains. The phenotypic diversity as determined by the Shannon index, equitability, rarefaction, and cumulative differences was high, but indicated some dominant biotypes. The genetic diversity was measured by reassociation of mixtures of denatured DNA isolated from the bacterial strains (C0t plots). The observed genetic diversity was high. Reassociation of DNA from all bacterial strains together revealed that the population contained heterologous DNA equivalent to 20 totally different bacterial genomes (i.e., genomes that have no homology). This study showed that reassociation of DNA isolated from a collection of bacteria gave a good estimate of the diversity of the collection and that there was good agreement with different phenotypic diversity measures. The Shannon index in particular has features in common with the genetic diversity measure presented here.     

A method of equalizing the level of DNA sequences of varying amount in a heterogeneous DNA mixture]

A method for the equalization of double-stranded DNA concentrations in the mixture which may be used for equalizing double-stranded cDNA concentrations involves thermal denaturation of the double-stranded DNA mixture followed by reassociation. The initial reassociation rate is Vi = Ki.(single-stranded DNA)2, and by the end of the process the concentrations of the unreassociated molecules for different DNAs should be approximately equal. Using hydroxylapatite chromatography one can separate single-stranded DNAs from double-stranded DNAs and carry out complete single-stranded DNAs reassociation. The new ratio of different double-stranded DNA concentrations would be almost 1.     

DNA reassociation kinetics and genome complexity of a fish (Psetta maxima: Teleostei) and its gut parasite (Bothriocephalus gregarius: Cestoda).

1. The genomic structure of a fish (Psetta maxima) and of a Tapeworm (Bothriocephalus), who form a close host-parasite association, was determined by reassociation kinetics experiments. 2. Spectrophotometric readings of single-stranded versus double-stranded DNA separated on hydroxylapatite columns after reassociation at Cot values ranging from 0.0001 to 10(5) allowed the drawing of the reassociation curves of both genomes. 3. Different fractions according to their degree of repetitivity were evidenced, and the relative amounts of repetitive versus single-copy sequences, as well as their complexity, were calculated. 4. It appears that the amount of non-repetitive DNA is lower in the Tapeworm than in its vertebrate host, although the complexity of these single-copy sequences is the same.     

Use of DNA reassociation in bacterial classification

The reassociation properties of DNA provide invaluable taxonomic tools. Different methods may give different reassociation values. However, the thermal stability of reassociated DNA strands (a measurement that seems independent of method) is useful in delineating genomic species. Although many phenotypically defined species have been confirmed by DNA reassociation, some medically important genomic species previously had been split into several nomenspecies on the basis of a few characteristics whereas some environmental genomic species had been lumped into unidentifiable aggregates. It might take some time before the nomenclature can be adapted to new taxonomic findings.     

Factors affecting the kinetics of DNA reassociation in phenol–water emulsion at high DNA concentrations

DNA reassociation kinetics using the phenol emulsion reassociation technique (PERT) [Kohne, D. E., Levison, S. A. & Byers, M. J. (1977) Biochemistry 16 , 5329–5341] has been investigated at high DNA concentrations using an endonuclease S1 assay of reaction progress. Apparent second-order rate constants fall on two intersecting straight lines when presented as a function of DNA concentrations on a log–log plot. In the low DNA concentration range, the rate constants drop about 10-fold when concentration increases 1000-fold. In the high DNA concentration range, the rate constants drop more than 10-fold when concentration increases 10-fold. The slopes of these lines are the same in different solvents and at different temperatures. The intersection between the lines occurs when the available catalytic surface is saturated. At high DNA concentrations, high-complexity heterologous denatured DNA apparently competes 2–4 times better for the surface than homologous DNA because it does not participate in a reassociation reaction. Native and partially native DNA molecules cannot compete with single-stranded DNA for a saturated surface. At high DNA concentrations, reactions using PERT become dependent on the single-strand DNA length. Increasing length lowers reassociation rates.     

Propidium iodide and S1 nuclease: tools for studying DNA reassociation kinetics

A method for the determination of the amount of double-stranded DNA in a reassociation mixture is described. Reassociated DNA resistant to S1 nuclease digestion is measured fluorometrically using propidium iodide. A direct comparison is made between this method and an established method in which radiolabeled Escherichia coli DNA resistant to S1 digestion is measured by scintillation counting after separation of nucleotides by Sephadex G-100 chromatography. Reassociation curves determined for calf thymus and E. coli DNA are presented.     

DNA contained by two densonucleosis viruses.

The DNA contained by particles of densonucleosis viruses 1 and 2 were analyzed within the particle, and properties of DNA extracted from these particles were determined. The DNA appears to exist as a single-stranded molecule with limited secondary structure within particles, as assessed by spectral changes induced by formaldehyde, melting profiles, and circular dichroism studies. The single-stranded DNA had an apparent molecular weight of 1.9 X 10(6) to 2.2 X 10(6) as assessed by differences in the molecular weight of virus particles and top component and percentage of nucleic acid. DNA extracted from virus particles in low-salt buffers possessed properties typical of a single-stranded molecule. Double-stranded DNA could be extracted from virus particles under appropriate high salt and elevated temperature. The linear double-stranded DNA extracted from both viruses had a molecular weight of about 3.9 X 10(6) to 4.1 ZX 10(6) determined by neutral sedimentation and electron microscopy and an equivalent genome size determined by reassociation kinetics. About 87% of the DNA was homologous between the two viruses.     

In situ localization and characterization of different classes of chromosomal DNA: acridine orange and quinacrine mustard fluorescence

In situ denaturation of metaphase chromosomes with alkali results in a shift from green to yellow, orange, brown and red fluorescence with acridine orange, indicating increasing denaturation of chromosomal DNA. The kinetics and characteristics of denaturation are described. Mouse and Microtus agrestis chromosomes denature uniformly but human cells show sequential denaturation. With increasing concentrations of alkali, the secondary constrictions in chromosomes 1, 9 and 16 are the first, and the distal half of the Y chromosome the last, to become denatured. — Reassociation of chromosomal DNA occurs within seconds after the start of incubation in salt solution. Areas containing repetitious DNA, e.g. mouse centromeres, fluoresce much more strongly than other regions with acridine orange after prolonged reassociation. Since human and Microtus centromeric regions behave similarly, it is proposed that they, too, contain repetitious DNA. — Reassociation treatment leads to enhancement of bright quinacrine mustard fluorescence in regions already bright before treatment. Furthermore, regions containing repetitious DNA, e.g. the secondary constrictions in human chromosomes 1, 9 and 16, whose fluorescence is dull before treatment, turn bright after reassociation. — The methods of fluorescence analysis of mammalian chromosomes with acridine orange and quinacrine mustard permit the localization and study of different classes of chromosomal DNA.     

Differences in DNA composition along mammalian metaphase chromosomes

Denaturation of chromosomal DNA in situ can be achieved without disruption of chromosomal morphology by heating slides at 25–90° C in 10–95% formamide in SSC. The extent of denaturation is proportional to formamide concentration and temperature. Reassociation of denatured DNA is prevented with formaldehyde. — The DNA in the paracentromeric constrictions in human chromosomes 1, 9 and 16 denatures earlier than in any other regions, as shown by the red colour with acridine orange. When the temperature or formamide concentration is raised a red and green banding pattern emerges in which regions known to stain brightly with quinacrine mustard are red whereas other regions are green. The last regions to turn red are the short arms of some acrocentric chromosomes. Since A+T-rich DNA denatures before G+C-rich DNA, it is inferred that QM-bright areas are rich in A+T. Similar results are obtained with mouse and Microtus agrestis cells. — Reassociation of chromosomal DNA denatured by heat and formamide occurs if no formaldehyde is used. In human cells, kinetic studies on reassociation indicate that the highest degree of repetition is in the DNA of the distal half of the Y chromosome. Next in degree of repetition are the paracentromeric constrictions, the short arm regions of some of the acrocentric chromosomes, and all the centromeric regions. Highly repetitious DNA is found in all mouse centromeric regions except that of the Y chromosome. Constitutively heterochromatic segments of X and Y and the autosomal centromeric regions of Microtus agrestis also contain repetitious DNA. — It is proposed that differential base content and susceptibility to denaturation of DNA contribute to or at least accompany Q-, G- and R-banding. The degree of C-banding is related to repetitious DNA. The human Y chromosomal DNA is probably A+T-rich and exceptionally repetitious, exhibiting spontaneous reassociation under many experimental conditions.     

DNA reassociation kinetic analysis of the brine shrimp, Artemia salina

DNA reassociation kinetics have been partly elucidated for the brine shrimp $\text{Artemia salina}$, using calf thymus DNA as a standard. The $\text{Artemia}$ single-copy DNA sequences comprise 45% of the genome; sequences having a repetition frequency of about 2–90 are not detectable. The average repetition frequency of the intermediately redundant DNA component is about 5,000 copies. Reassociation kinetic data are consistent with a unit genome size of 1.5 pg.