Structural genes adjacent to interspersed repetitive DNA sequences

The observation that repetitive and single copy sequences are interspersed in animal DNAs has suggested that repetitive sequences are adjacent to single copy structural gene sequences. To test this concept, single copy DNA sequences contiguous to interspersed repetitive sequences were prepared from sea urchin DNA by hydroxyapatite fractionation (repeat-contiguous DNA fraction). These single copy sequences included about one third of the total nonrepetitive sequence in the genome as determined by the amounts recovered during the hydroxyapatite fractionation and by reassociation kinetics. ³H-labeled mRNA from sea urchin gastrula was prepared by puromycin release from polysomes and used in DNA-driven hybridization reactions. The kinetics of mRNA hybridization reactions with excess whole DNA were carefully measured, and the rate of hybridization was found to be 3–5 times slower than the corresponding single copy DNA driver reassociation rate. The mRNA hybridized with excess repeat-contiguous DNA with similar kinetics relative to the driver DNA. At completion 80% of that mRNA hybridizable with whole DNA (approximately 65%) had reacted with the repeat-contiguous DNA fraction (50%). This result shows that 80–100% of the mRNA molecules present in sea urchin embryos are transcribed from single copy DNA sequences adjacent to interspersed repetitive sequences in the genome.     

Analysis of plant genomes. V. Comparative study of molecular properties of DNAs of seven Allium species

The genomes of seven plant species belonging to the genus Allium and exhibiting a threefold variation in their nuclear DNA content were analyzed by studying their reassociation kinetics, equilibrium centrifugation behavior in neutral CsCl gradients, and melting properties. The reassociation kinetics experiments revealed the presence of 44–65% repeated DNA sequences. A comparison between DNA contents and the proportion of repeated DNA sequences indicated that, in Allium, increase in the genome size is not exclusively due to variations in the proportions of repetitive DNA. The total DNA as well as the various repetitive DNA fractions in all the Allium species examined exhibited, in spite of a few differences, a gross similarity in their behavior in neutral CsCl gradients and in their melting properties.     

DNA sequence organization in the genome of Petroselinum sativum (Umbelliferae)

The genome of parsley was studied by DNA/DNA reassociation to reveal its spectrum of DNA reiteration frequencies and sequence organization. The reassociation of 300 nucleotide DNA fragments indicates the presence of four classes of DNA differing in repetition frequency. These classes are: highly repetitive sequences, fast intermediate repetitive sequences, slow intermediate repetitive sequences, and unique sequences. The repeated classes are reiterated on average 136,000, 3000, and 42 times respectively. A minor part of the genome is made up of palindromes. — The organization of DNA sequences in the P. sativum genome was determined by the reassociation kinetics of DNA fragments of varying length. Further information was derived from S1 nuclease resistance and from hyperchromicity measurements on DNA fragments reassociated to defined C₀t values. — The portion of the genome organized in a short period interspersion pattern amounts to 47%, with the unique sequences on an average 1000 nucleotides long, and most of the repetitive sequences about 300 nucleotides in length, whereas the weight average length may be up to 600 nucleotides. — About 5% unique DNA and 11% slow intermediate repetitive DNA consist of sequences from 10³ up to 10⁴ nucleotides long; these are interspersed with repetitive sequences of unknown length. Long repetitive sequences constitute 33% of the genome, 13% are satellite-like organized, and 20% in long stretches of intermediate repetitive DNA in which highly divergent sequences alternate with sequences that show only minimal divergence. — The results presented indicate remarkable similarities with the genomes of most animal species on which information is available. The most intriguing pecularity of the plant genome derives from its high content of repetitive DNA and the presumed organization of the latter.     

Genome size and complexity of the obligate fungal pathogen,Bremia lactucae

The size and organization of the genome of Bremia lactucae, a highly specialized fungal pathogen of lettuce, has been characterized using dot blot genomic reconstructions, reverse genomic blots, and genomic DNA reassociation kinetics. The haploid genome contains 5 × 10⁷ bp of DNA and 65% of the nuclear DNA is repeated. Low copy sequences are interspersed with repeated sequences in a short-period interspersion pattern. This pattern of genome organization is different to that described for other fungi. Although most fungi have been shown to contain some form of repetitive DNA other than the ribosomal repeat, the high percentage of repetitive DNA and the interspersion of low copy and repeated sequences are atypical of fungi characterized previously.     

Characterization of the nuclear genome of pearl millet.

The nuclear genome of pearl millet has been characterized with respect to its size, buoyant density in CsCl equilibrium density gradients, melting temperature, reassociation kinetics and sequence organization. The genome size is 0.22 pg. The mol percent G + C of the DNA is calculated from the buoyant density and the melting temperature to be 44.9 and 49.7%, respectively. The reassociation kinetics of fragments of DNA 300 nucleotides long reveals three components: a rapidly renaturing fraction composed of highly repeated and/or foldback DNA, middle repetitive DNA and single copy DNA. The single copy DNA consists of 17% of the genome. 80% of the repetitive sequences are at least 5000 nucleotide pairs in length. Thermal denaturation profiles of the repetitive DNA sequences show high Tm values implying a high degree of sequence homogeneity. About half of the single copy DNA is short (750--1400 nucleotide paris) and interspersed with long repetitive DNA sequences. The remainder of the single copy sequences vary in size from 1400 to 8600 nucleotide pairs.     

DNA sequence organization in the genome of Nicotiana tabacum

The genome of Nicotiana tabacum was investigated by DNA/DNA reassociation for its spectrum of DNA repetition components and pattern of DNA sequence organization. The reassociation of 300 nucleotide DNA fragments analyzed by hydroxyapatite chromatography reveals the presence of three major classes of DNA differing in reiteration frequency. Each class of DNA was isolated and characterized with respect to kinetic homogeneity and thermal properties on melting. These measurements demonstrate that the genome of N. tabacum has a 1C DNA content of 1.65 pg and that DNA sequences are represented an average of 12,400, 252, and 1 times each. — The organization of the DNA sequences in the N. tabacum genome was determined from the reassociation kinetics of long DNA fragments as well as S1 nuclease resistance and hyperchromicity measurements on DNA fragments after annealing to C₀t values at which only repetitive DNA sequences will reassociate. At least 55% of the total DNA sequences are organized in a short period interspersion pattern consisting of an alternation of single copy sequences, averaging 1400 nucleotides, with short repetitive elements approximately 300 nucleotides in length. Another 25% of the genome contains long repetitive DNA sequences having a minimal genomic length of 1500 nucleotides. These repetitive DNA sequences are much less divergent than the short interspersed DNA sequence elements. These results indicate that the pattern of DNA sequence organization in the tobacco genome bears remarkable similarity to that found in the genomes of most animal species investigated to date.     

Absence of short period interspersion of repetitive and non-repetitive sequences in the DNA of Drosophila melanogaster

A sensitive search has been made in Drosophila melanogaster DNA for short repetitive sequences interspersed with single copy sequences. Five kinds of measurements all yield the conclusion that there are few short repetitive sequences in this genome: 1) Comparison of the kinetics of reassociation of short (360 nucleotide) and long (1,830 nucleotide) fragments of DNA; 2) reassociation kinetics of long fragments (2,200 nucleotide) with an excess of short (390 short nucleotide) fragments; 3) measurement of the size of S1 nuclease resistant reassociated repeated sequences; 4) measurement of the hyperchromicity of reassociated repetitive fragments as a function of length; 5) direct assay by kinetics of reassociation of the amount of single copy sequence present on 1,200 nucleotide long fragments which also contain repetitive sequences.     

Sequence organization of porcine DNA.

The sequence organization of porcine DNA isolated from thyroid has been analyzed by hydroxylapatite (HAP) chromatography. The reassociation of 0.4 kilobase (Kb) DNA fragments shows, besides the presence of 5% inverted repeat sequences (foldback DNA), that 45% of the genome is represented by high (10%) and intermediate (35%) repetitive components, whereas the remaining 50% is unique sequences. 30% of the unique sequences consists of 1,000 nucleotide fragments interspersed with repetitive elements 400 nucleotides in length. The remaining 20% is longer unique sequences (10,000 nucleotides) apparently not linked to repetitive elements.     

Exploration of long and short repetitive sequence relationships in the sea urchin genome.

Long and short repetitive sequences of sea urchin DNA were prepared by reassociation of 2000 nucleotide long fragments to Cot 4 and digestion with the single strand specific nuclease S1. The S1 resistant duplexes were separated into long repetitive and short repetitive fractions on Agarose A50. The extent of shared sequences was studied by reassociating a labeled preparation of short repetitive DNA with an excess of unlabeled long repetitive DNA. Less than 10% of the long repetitive DNA preparation was able to reassociate with the short repetitive DNA. Thus the long and short repetitive elements appear to be principally independent sequence classes in sea urchin DNA. Precisely reassociating repetitive DNA was prepared by four successive steps of reassociation and thermal chromatography on hydroxyapatite. This fraction (3% of the genome) was reassociated by itself or with a great excess of total sea urchin DNA. The thermal stability of the products was identical in both cases (Tm=81 degrees C), indicating that precisely repeated sequences do not have many imprecise copies in sea urchin DNA.     

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

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

Reassociation of human lymphoblastoid cell DNA repair replicated following methyl methanesulfonate treatment

The reassociation rates of repair replicated DNA of two human lymphoblastoid cell lines, the WIL₂-A3 ‘normal’ line and the RAJI line of Burkitt's lymphoma, were examined using the DNA/DNA ‘C₀t’ hybridization technique. The cells were treated with methyl methanesulfonate (MMS), an alkylating agent and mutagen, to induce the repair.The incorporated repair replication radioactivity in highly repetitive sequences of WIL₂-A3 cell DNA reassociates as expected for a randomly distributed incorporation. The reassociation of repair radioactivity in sequences of fewer numbers of copies, however, is less than expected for a random distribution. It is less than that occurring for semiconservatively synthesized DNA of WIL₂-A3 cells co-incubated with the repair labeled DNA as an internal control.The observed difference could be due to an over-representation of repair replication radioactivity in DNA sequences with fewer copies. It is unlikely to be due to residual alkali labile damage resulting from MMS treatment, since a similar difference was not observed when semiconservatively labeled DNA from cells which had been treated with MMS for the same time and at the same concentration as in the repair experiments was substituted for repair replicated DNA in the reassociation reactions. Other possible causes of the apparent difference in the reassociation rates observed are discussed.     

The organization of the main component DNA of a crustacean genome with a paucity of middle repetitive sequences

The frequency classes and organization of the main component (mc) DNA of a crustacean, the land crab, Gecarcinus lateralis, have been characterized. The reassociation kinetics of 380 nucleotide long mcDNA fragments show that approximately 50% contain sequences repeated more than 800 times. Present in few, if any, copies are sequences repeated from 2 to 800 times. The remainder of the DNA reassociates as single copy sequences with a rate constant consistent with the organism's genome size. The reassociation kinetics of highly sheared DNA fragments of every true crab studied (Vaughn, 1975; Christie et al., 1976) are similar to each other and different from those of other invertebrate DNAs (Goldberg et al., 1975). Each of these genomes has a paucity of sequences repeated from 10 to 800 times and an abundance of highly repeated sequences. To determine if sequences repeated more than 800 times are interspersed with single copy sequences, we examined the arrangement of repetitive and non-repetitive sequences in mcDNA. The reassociation and melting properties of partially duplex mcDNA fragments of increasing lengths show that at least 75% of the DNA is organized in an interspersed pattern. In this pattern, single copy sequences with an average length of 800–900 nucleotides are interspersed with repetitive sequences. S1 nuclease digestion of reassociated 3100 nucleotide fragments indicates that 44% of the mcDNA is repetitive and that one-third of the repetitive sequences (average length=285 nucleotides) are interspersed with single copy sequences. We conclude that repetitive sequencies are interspersed with most of the single copy sequences in an interspersion pattern similar to that of Xenopus rahter than to that of another arthropod, Drosophila.Operated by Union Carbide Corporation for the Energy Research and Development Administration     

An alternative view of mammalian DNA sequence organization: I. Repetitive sequence interspersion in Syrian hamster DNA: A model system

The biochemical and biophysical techniques originally introduced by Davidson et al. (1973) and Graham et al. (1974) for the determination of the general organization and length of repetitive and non-repetitive sequences in eukaryotic DNA have been extended and modified. Improvements in the experimental methods employed in these pioneering works have led to novel interpretations and conclusions about mammalian DNA sequence organization. In what is commonly referred to as an interspersion experiment, the average spacing of repetitive DNA regions is inferred from the length dependence of hydroxyapatite binding of radio-labeled tracer DNAs reassociated with an excess of short 200 nucleotide repetitive sequence driver DNA. Studies on Syrian hamster DNA, using an improved procedure for conducting interspersion experiments, suggest that either a frequent cluster in the distribution of non-repetitive DNA sequence lengths occurs at 7200 (±2000) nucleotides or that repetitive sequences are randomly spaced on a number average basis. In contrast, measurements obtained using the traditional methods suggest that a frequent cluster in the distribution of non-repetitive DNA sequence lengths occurs at approximately 1000 nucleotides. When reassociations were conducted at elevated temperatures, to allow only well-matched repetitive sequences to hybridize, the amount of DNA operationally observed as “repetitive” was reduced. Interspersion experiments conducted with Syrian hamster DNA at a reassociation temperature of 75 °C yielded data similar to those obtained by Manning et al. (1975) for Drosophila melanogaster DNA reassociated at 60 °C.     

Distribution pattern and enzymic hypermethylation of inverted repetitive DNA sequences in P815 mastocytoma cells.

A specific class of DNA sequences, the inverted repetitive sequences, forms a double-stranded structure within a single linear polynucleotide chain in denatured DNA. The reassociation process is unimolecular and occurs very fast. Quantitative analyses have shown that in mouse P815 cells these sequences comprise about 4% of the nuclear DNA and are interspersed within sequences of other degrees of repetitiveness. After labeling the cells with L-[Me-3H]methionine and [14C]deoxycytidine, relative rates of enzymic DNA methylation were computed on the basis of radioactivities found in pyrimidine residues of the nuclear DNA. The results indicate that in P815 cells, DNA of inverted repetitive sequences is methylated to a level about 50% higher than the normal repetitive DNA sequences and to about 300% higher than the unique and intermediary intermediatry sequences. The biological function of the inverted repetitive sequences, as well as of the role of enzymic methylation of DNA remains unknown.     

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.     

Homology of single copy and repeated sequences in chicken, duck, Japanese quail, and ostrich DNA.

The extent of reassociation of 3H-labeled repetitive or single copy DNA sequences from the chicken with excess unlabeled DNA from the duck, the Japanese quail, and the ostrich, respectively, was measured by hydroxylapatite chromatography. Chicken repetitive DNA reassociated to an equal or greater extent than chicken single copy DNA with the DNA of each of the other birds. Using an isolated subfraction of chicken repetitive DNA representing those DNA sequences common to the chicken and ostrich genomes, we determined that many repetitive DNA sequences that occur at high repetition frequency in the chicken genome have a much lower repetition frequency in ostrich DNA. The data indicate that there has been a striking change in the number of copies of many repetitive DNA sequences during avian evolution.     

Sequence organization of the soybean genome

The total complexity of one constituent soybean (Glycine max) genome is estimated to be 1.29 . 10(9) nucleotide pairs, as determined by analysis of the reassociation kinetics of sheared (0.47 kilobase) DNA. Single copy sequences are estimated to represent from 53 to 64% of the genome by analysis of hydroxyapatite binding of repetitive DNA as a function of fragment length. From 65 to 70% of these single copy sequences have a short period interspersion with 1.11--1.36 kilobase lengths alternating with 0.3--0.4 kilobase repetitive sequence elements. The repetitive sequences of soybean DNA are interspersed both among themselves and among single copy regions of the genome.     

Association of double-stranded DNA fragments into multistranded DNA structures.

We have previously observed that double-stranded DNA fragments containing a tract of the tandemly repeated sequence poly(CA). poly(TG) can associate in vitro to form stable complexes of low electrophoretic mobility, which are recognized with high specificity by proteins HMG1 and HMG2. The formation of such complexes has since been observed to depend on interactions of DNA with polypropylene surfaces, with the suggestion that the formation of low mobility complexes might be the result of strand dissociation followed by misaligned reassociation of the repetitive sequences. The data presented here show that at high ionic strength the interactions of DNA with polypropylene are sufficiently strong for DNA to remain bound to the polypropylene surface, which suggests that DNA might also be involved in interactions with hydrophobic molecules in vivo. Under such conditions, low-mobility complexes are found only in the material adsorbed to the polypropylene surface, and all DNA fragments are able to form low-mobility structures, whether or not they contain repetitive sequences. Preventing the separation of strands by ligating hairpin loop oligonucleotides at both ends of the fragments does not prevent the formation of low-mobility complexes. Our results suggest two different pathways for the formation of complexes. In the first, dissociation is followed by misaligned reassociation of repetitive sequences, yielding duplexes with single-stranded end regions that associate to form multimeric complexes. In the second, repetitive as well as nonrepetitive DNA molecules bound to polypropylene adopt a conformation with locally unwound regions, which allows interactions between neighboring duplexes adsorbed on the surface, resulting in the formation of low-mobility complexes.     

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.     

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.