A study of the evolution of repeated DNA sequences in primates and the existence of a new class of repetitive sequences in primates.

A new class of lowly repetitive DNA sequences has been detected in the primate genome. The renaturation rate of this sequence class is practically indistinguishable from the renaturation rate of single-copy sequences. Consequently, this lowly repetitive sequence class has not been previously observed in DNA renaturation rate studies. This new sequence class is significant in that it might occupy a major fraction of the primate genome.Based on a study of the thermal stabilities of DNA heteroduplexes constructed from human DNA and either bonnet monkey or galago DNAs, we are able to compare the relative mutation rates of repetitive and single-copy sequences in the primate genome. We find that the mutation rate of short, interspersed repetitive sequences is either less than or approximately equal to the mutation rate of single-copy sequences. This implies that the base sequence of these repetitive sequences is important to their biological function.We also find that numerous mutations have accumulated in interspersed repeated sequences since the divergence of galago and human. These mutations are only recognizable because they occur at specific sites in the repeated sequence rather than at random sites in the sequence. Although interspersed repetitive sequences from human and galago can readily cross-hybridize, these site-specific mutations identify them as being two distinct classes. In contrast, far fewer site-specific mutations have occurred since the divergence of human and monkey.     

Genome structure of Tetrahymena pyriformiis

Reassociation kinetics of DNA from the macronucleus of the ciliate, Tetrahymena pyriformis GL, has been studied. The genome size determined by the kinetic complexity of DNA was found to be 2.0×10⁸ base pairs (or 1.2×10¹¹ daltons). About 90% of the macronuclear DNA fragments 200–300 nucleotides in length reassociate at a rate corresponding to single-copy nucleotide sequences, and 7–9% at a rate corresponding to moderate repetitive sequences; 3–4% of such DNA fragments reassociate at C₀t practically equal to zero. To investigate the linear distribution of repetitive sequences, DNA fragments of high molecular weight were reassociated and reassociation products were treated with Sl-nuclease. DNA double-stranded fragments were then fractionated by size. It has been established that in the Tetrahymena genome long regions containing more than 2000 nucleotides make up about half of the DNA repetitive sequences. Another half of the DNA repetitive sequences (short DNA regions about 200–300 nucleotides long) intersperse with single-copy sequences about 1,000 nucleotides long. Thus, no more than 15% of the Tetrahymena genome is patterned on the principle of interspersing single-copy and short repetitive sequences. Most of the so called zero time binding or foldback DNA seem to be represented by inverted self-complementary (palindromic) nucleotide sequences. The conclusion has been drawn from the analysis of this fraction isolated preparatively by chromatography. About 75% of the foldback DNA is resistant to Sl-nuclease treatment. The Sl-nuclease resistance is independent of the original DNA concentration. Heat denaturation and renaturation are reversible and show both hyper and hypochromic effects. The majority of the inverted sequences are unique and about 20% are repeated tens of times. According to the equilibrium distribution in CsCl density gradients the average nucleotide content of the palindromic fraction does not differ significantly from that of total macronuclear DNA. It was shown that the largest part of this fraction of the Tetrahymena genome are not fragments of ribosomal genes.     

A whole-genome snapshot of 454 sequences exposes the composition of the barley genome and provides evidence for parallel evolution of genome size in wheat and barley

The genomes of barley and wheat, two of the world's most important crops, are very large and complex due to their high content of repetitive DNA. In order to obtain a whole-genome sequence sample, we performed two runs of 454 (GS20) sequencing on genomic DNA of barley cv. Morex, which yielded approximately 1% of a haploid genome equivalent. Almost 60% of the sequences comprised known transposable element (TE) families, and another 9% represented novel repetitive sequences. We also discovered high amounts of low-complexity DNA and non-genic low-copy DNA. We identified almost 2300 protein coding gene sequences and more than 660 putative conserved non-coding sequences. Comparison of the 454 reads with previously published genomic sequences suggested that TE families are distributed unequally along chromosomes. This was confirmed by in situ hybridizations of selected TEs. A comparison of these data for the barley genome with a large sample of publicly available wheat sequences showed that several TE families that are highly abundant in wheat are absent from the barley genome. This finding implies that the TE composition of their genomes differs dramatically, despite their very similar genome size and their close phylogenetic relationship.     

Sequence organization of the rat genome by electron microscopy.

The size and arrangement of repetitive and inverted repeat (foldback) sequences in rat DNA were studied by visualization of hybrid and heteroduplex structures in the electron microscope. The self-reassociation of repetitive sequence-bearing DNA strands often results in the formation of four-ended "H" structures, whose duplex regions equal the repetitive sequence length and can be measured in the electron microscope. In this way, it was determined that the average size of the class of numerous short repetitive sequences is 0.40 +/- 0.15 kbp. Heteroduplex structures were prepared between long whole DNA single strands and short repeat-sequence-bearing strands. The analysis of these structures confirms that the size of the repetitive sequences in 0.4 kbp on average. Length measurements between adjacent duplexes show that the average spacing between two interspersed repeats is at least 1.5-1.8 kbp. By examining 29.4-kbp single strands after brief renaturation, the size and distribution of foldback sequences were determined. There are 1.9 X 10(5) foldback apirs per rat genome, spaced an average of 9.7 kbp apart according to our measurement. Repetitive, inverted repeat and unique sequences are interspersed with each other in at least half the genome.     

Sequence organization of the human genome

The organization of three sequence classes—single copy, repetitive, and inverted repeated sequences—within the human genome has been studied by renaturation techniques, hydroxylapatite binding methods, and DNA hyperchromism. Repetitive sequence classes are distributed throughout 80% or more of the genome. Slightly more than half of the genome consists of short single copy sequences, with a length of about 2 kb interspersed with repetitive sequences. The average length of the repetitive sequences is also small and approximates the length of these sequences found in other organisms. The sequence organization of the human genome therefore resembles the sequence organization found in Xenopus and sea urchin. The inverted repeats are essentially randomly positioned with respect to both sequence class and sequence arrangement, so that all three sequence classes are found to be mutually interspersed in a portion of the genome.     

The organization of DNA sequences in the mouse genome

Analysis of the organization of nucleotide sequences in mouse genome is carried out on total DNA at different fragment size, reannealed to intermediate value of Cot, by Ag⁺-Cs₂SO₄ density gradient centrifugation. — According to nuclease S-1 resistance and kinetic renaturation curves mouse genome appears to be made up of non-repetitive DNA (76% of total DNA), middle repetitive DNA (average repetition frequency 2×10⁴ copies, 15% of total DNA), highly repetitive DNA (8% of total DNA) and fold-back DNA (renatured density 1.701 g/ml, 1% of total DNA).— Non-repetitive sequences are intercalated with short middle repetitive sequences. One third of non-repetitive sequences is longer than 4500 nucleotides, another third is long between 1800 and 4500 nucleotides, and the remainder is shorter than 1800 nucleotides. —Middle repetitive sequences are transcribed in vivo. The majority of the transcribed repeated sequences appears to be not linked to the bulk of non-repeated sequences at a DNA size of 1800 nucleotides. — The organization of mouse genome analyzed by Ag⁺-Cs₂SO₄ density gradient of reannealed DNA appears to be substantially different than that previously observed in human genome using the same technique.     

DNA Base composition and repetitious DNA in several conifers

Coniferous DNA was analyzed by ultraoentrifugation and thermal denaturation and renaturation to determine base composition and the presence of repetitive sequences. The percent quanine plus cytosine values among species were constant and independent of DNA quantity per cell, whereas the proportion of repetitive DNA per genome was greatest in those species that had the highest DNA content.     

Repetitious DNA in some Anemone Species

The DNA from several Anemone species, which contain different amounts of heterochromatin as revealed by Giemsa staining, was analysed by ultra-centrifugation and renaturation. No satellite band was observed in any of the samples centrifuged in cesium chloride gradients. Renaturation studies showed the presence of repetitive sequences. The proportion of repetitive DNA per genome varied from 53% to 67% and did not correlate with either the DNA content per cell or the relative amount of heterochromatin.     

Small, repetitive DNAs contribute significantly to the expanded mitochondrial genome of cucumber

Closely related cucurbit species possess eightfold differences in the sizes of their mitochondrial genomes. We cloned mitochondrial DNA (mtDNA) fragments showing strong hybridization signals to cucumber mtDNA and little or no signal to watermelon mtDNA. The cucumber mtDNA clones carried short (30-53 bp), repetitive DNA motifs that were often degenerate, overlapping, and showed no homology to any sequences currently in the databases. On the basis of dot-blot hybridizations, seven repetitive DNA motifs accounted for >13% (194 kb) of the cucumber mitochondrial genome, equaling >50% of the size of the Arabidopsis mitochondrial genome. Sequence analysis of 136 kb of cucumber mtDNA revealed only 11.2% with significant homology to previously characterized mitochondrial sequences, 2.4% to chloroplast DNA, and 15% to the seven repetitive DNA motifs. The remaining 71.4% of the sequence was unique to the cucumber mitochondrial genome. There was <4% sequence colinearity surrounding the watermelon and cucumber atp9 coding regions, and the much smaller watermelon mitochondrial genome possessed no significant amounts of cucumber repetitive DNAs. Our results demonstrate that the expanded cucumber mitochondrial genome is in part due to extensive duplication of short repetitive sequences, possibly by recombination and/or replication slippage.     

High-Cot sequence analysis of the maize genome

Higher eukaryotic genomes, including those from plants, contain large amounts of repetitive DNA that complicate genome analysis. We have developed a technique based on DNA renaturation which normalizes repetitive DNA, and thereby allows a more efficient outcome for full genome shotgun sequencing. The data indicate that sequencing the unrenatured outcome of a Cot experiment, otherwise known as High-Cot DNA, enriches genic sequences by more than fourfold in maize, from 5% for a random library to more than 20% for a High-Cot library. Using this approach, we predict that gene discovery would be greater than 95% and that the number of sequencing runs required to sequence the full gene space in maize would be at least fourfold lower than that required for full-genome shotgun sequencing.     

The nuclear genome of Brachypodium distachyon: analysis of BAC end sequences

Due in part to its small genome (~350 Mb), Brachypodium distachyon is emerging as a model system for temperate grasses, including important crops like wheat and barley. We present the analysis of 10.9% of the Brachypodium genome based on 64,696 bacterial artificial chromosome (BAC) end sequences (BES). Analysis of repeat DNA content in BES revealed that approximately 11.0% of the genome consists of known repetitive DNA. The vast majority of the Brachypodium repetitive elements are LTR retrotransposons. While Bare-1 retrotransposons are common to wheat and barley, Brachypodium repetitive element sequence-1 (BRES-1), closely related to Bare-1, is also abundant in Brachypodium. Moreover, unique Brachypodium repetitive element sequences identified constitute approximately 7.4% of its genome. Simple sequence repeats from BES were analyzed, and flanking primer sequences for SSR detection potentially useful for genetic mapping are available at . Sequence analyses of BES indicated that approximately 21.2% of the Brachypodium genome represents coding sequence. Furthermore, Brachypodium BES have more significant matches to ESTs from wheat than rice or maize, although these species have similar sizes of EST collections. A phylogenetic analysis based on 335 sequences shared among seven grass species further revealed a closer relationship between Brachypodium and Triticeae than Brachypodium and rice or maize. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. N. Huo and G.R. Lazo contributed equally to this work.     

HpaII library indicates ‘methylation-free islands’ in wheat and barley

Summary A library of wheat genomic DNA HpaII tiny fragments (HTF), sized below 500 bp, has been constructed. Of the clones in the library 80% belong to the single/low-copy category, while 12% of the clones are nuclear repetitive sequences and 8% originate from the chloroplast and mitochondrial DNA. This result shows a substantial enrichment in the single/low-copy sequences of the wheat genome, which contains at least 80% repetitive sequences. Twenty-nine random single/lowcopy clones were analysed further for wheat chromosome location, cross-hybridisation to barley DNA and their association with rare-cutting, C-methylation-sensitive restriction sites. The results show that the HTF clones are associated more frequently than expected with NotI, MluI, NruI and PstI sites in wheat and barley genomic DNA. The 12% repetitive fraction of the clones contain both moderately and highly repetitive sequences, but no tandemly repeated sequences. The level of enrichment for single/low-copy sequences indicates that libraries of this type are a valuable source of probes for RFLP mapping. In addition, the close association of the HTF clones with rare-cutting restriction enzyme sites ensures that HTF clones will have a useful role in the construction of long-range physical maps in wheat.     

Characteristics of palindromic sequences in DNA of the sea urchin Strongylocentrotus intermedius

Some properties of the palindromic sequences in the sea urchin Strongylocentrotus intermedius nuclear DNA have been studied. It was shown that the amount of "foldback HAP bound DNA" and the S1 nuclease resistant DNA depends on renaturation temperature and Na+ concentration in solution. The authentic fraction of inverted repeats comprises 10-15% of the total DNA. The complexity of the palindromic fraction is approximately 8,2 X 10(7) nucleotide pairs and the average number of inverted repeats approximates 5 X 10(5) per haploid genome. The renaturation kinetics of inverted repeats with excess of total homologous DNA indicates that these sequences are enriched with unique DNA. The possible function of palindromic sequences is discussed.     

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.     

Non xenopus-like DNA sequence organization in the Chironomus tentans genome

Summary We have examined the sequence organization of Chironomus tentans DNA by means of optical and hydroxyapatite renaturation kinetics of total DNA fragment sizes of 0.36, 2.6 and 13.5 kilobases (kb) as well as isolated middle repeat DNA at sizes of 0.36 and 13.5 kb. 90% of the DNA renatured as unique sequences of a genome of 0.20 pg with the balance of DNA renaturing as middle repetitive sequences present on average 90 times per haploid genome. At a DNA fragment length of 13.5 kb, 35% of the DNA was trapped on the hydroxyapatite as middle repetitive fraction. We concluded C. tentans DNA to have a mean repeat length of about 4.3 kb distributed through out at least 35% of the genome with an inter repeat spacing of at least 13.5 kb but possibly being distributed throughout the whole genome with an inter repeat spacing of 36 kb. This shows C. tentans DNA organization not to follow the almost ubiquitous Xenopus model but to be similar to the organization of Drosophila melanogaster DNA.     

Kinetic determination of the genome size of the pea

Renaturation of pea (Pisum sativum) DNA has been used to estimate the size of the pea genome and the fraction of pea DNA containing repeated DNA sequences. Pea DNA renaturation and single copy tracer renaturation indicate that the size of the pea genome is 0.5 picograms. More than 70% of pea DNA sequences are repeated from 100 to 5,000 times.     

Repetitive DNA in Yeasts

BETWEEN 10% and 70% of the nuclear DNA of all higher organisms consists of repeating sequences^1,2 (in some organisms only 6–13 base pairs long³) which comprise families of identical or similar base sequences repeated from several hundred to more than a million times. Much of this is not transcribed⁴ and the most repetitive sequences are located in the centromeric heterochromatin⁵. If repetitive DNA occurs in all eukaryotic cells, however, it is surprising that in renaturation studies it has not been found in yeast^2,6. In Saccharomyces cerevisiae,a large number of the AT base pairs of the mitochondrial DNA probably occur in poly AT sequences^7,8. This may result in unusual renaturation kinetics.     

一些水稻的重复DNA顺序在稻属和其它禾本科植物中的多态性

重复DNA顺序是真核生物基因组的特征,很多重复DNA顺序已从小麦、拟南芥菜、燕麦、水稻、玉米等植物的基因组中克隆出来,还发现有一些重复DNA顺序具有基因组特异性,用它们作探针可以分析同属或同科物种的起源和亲缘关系,并建立系统进化树。小卫星DNA或微小卫星DNA所产生的指纹图谱可作为一种遗传学标志来研究系统进化、染色体的精细结构和物种的鉴定。一些中度重复DNA序列还可以作为组织培养株系和细胞杂交筛选的分子标志。稻属已发现并定名的有22个种,根据杂交亲和性、细胞遗传学和生理生化等将它分为6个二倍体组型(AA、BB、CC、DD、EE和FF)和2个四倍体组型(BBCC和CCDD)。现多把禾本科分作5个亚科:竹亚科、稻亚科、早熟禾亚科、画眉草亚科和     

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.     

The genome of Zea mays,its organization and homology to related grasses

The pattern of genome organization of Zea mays has been analyzed, and the relationship of maize to possible progenitor species assessed by DNADNA hybridization. Reassociation of 470 and 1,350 bp fragments of maize DNA to various C₀t values demonstrates that the genome is composed of 3 major kinetic classes: highly repetitive, mid-repetitive, and unique. Mini-C₀t curves of the repetitive sequences at short fragment length indicate that the highly repetitive sequence class is 20% of the genome and is present at an average reiteration frequency of 800,000 copies; the mid-repetitive sequence class is 40% of the genome and is present at an average reiteration frequency of 1,000 copies. Thermal denaturation studies show that the highly repetitive sequences are 12% divergent and mid-repetitive sequences are 6% divergent. Most of the genome is organized in two interspersion patterns. One, approximately one-third of the genome, is composed of unique sequences of average length 2,100 bp interspersed with mid-repetitive sequences; the other, also one-third of the genome, is mid-repetitive sequences interspersed with highly repetitive sequences. The repetitive sequences are 500 to 1,000 bp by electron microscopic measurement. The remaining third of the genome is unique sequences farther than 5,000 bp from a palindromic or repetitive sequence. Hybridization of maize DNA from Midwestern Dent to popcorn and related grasses indicates that both the unique and repetitive sequence elements have diverged. Teosinte and popcorn are approximately equally divergent from Midwestern Dent whereas Tripsacum is much more divergent. The divergence times calculated from the depression of T_m in heterologous duplexes indicate that the divergence within Zea mays and between maize and near relatives is at least an order of magnitude greater than expected. This high degree of divergence may reflect the pressures of domestication of maize.