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.     

Clustered and interspersed repetitive DNA sequences in four amphibian species with different genome size.

We have compared the amount of clustered and interspersed repetitive sequences in the genome of four Amphibia with different DNA contents per haploid nucleus: two Anura (Xenopus laevis, 3 pg and Bufo bufo, 7 pg) and two Urodela (Triturus cristatus, 23 pg and Necturus maculosus, 52 pg). High molecular weight DNA of the four species was denatured and reassociated to the same Cot in order to obtain duplex sequences with a similar reiteration frequency. Single-stranded DNA was digested off with the Aspergillus S1 nuclease. DNA was then fractionated according to the molecular weight through an agarose A-50 column. We found that the amount of long repetitive sequences is roughly proportional to the genome size in the four species, while the number of short (about 300 base pairs) repetitive sequences is increased many-fold in the species with the larger DNA content, both in Anura and in Urodela.     

The evolution of repetitive DNA sequences in sea urchins.

Molecular hybridization of nuclear DNAs has been employed to study the evolution of the repetitive DNA sequences in four species of sea urchin. The data show that relative to S. purpuratus there has been approximately 0.1% sequence divergence per million years in the repetitive DNA sequences of S. droebachiensis, S. franciscanus, and L. pictus. These results confirm that repetitive DNA sequences are strongly conserved during evolution. However, comparison of the extent of base pair mismatch in the repetitive DNA heteroduplexes formed at Cot 20 with those formed at Cot 200 during the hybridization of S. purpuratus and L. pictus DNAs reveals that highly repetitive sequences of sea urchins may diverge more rapidly than do the more moderately repetitive sequences.     

Primate evolution of a dispersed human repetitive DNA sequence

A dispersed middle repetitive DNA sequence isolated originally from human chromosome 12 did not show homology with rodent DNA under standard conditions of Southern DNA blot analysis. The evolutionary relationship of this human repetitive DNA to that of other primates was investigated using three hybridization methods: DNA dot blot, Southern DNA blot analysis, and chromosome in situ hybridization. Homology with the human repetitive DNA was found throughout the suborder Anthropoidea, in fourteen ape and New and Old World monkey species. In addition, the human pattern of hybridization to noncentromeric regions of all chromosomes was seen. No hybridization by any of the three techniques was found in five species of the suborder Prosimii. The phenomenon of marked differences in sequence homology and copy number of dispersed repetitive DNA from closely related species has been observed in protozoans (Plasmodia), Drosophila, sea urchins, mice and the great apes (Hominoidea). We report here a similar phenomenon that may have occurred at an early stage in primate evolution.     

Nuclear DNA divergence among Lathyrus species

Among diploid Lathyrus species a threefold variation in nuclear DNA amount is attributable to differences in the amount of repetitive DNA. Cross reassociation among repetitive and among non-repetitive DNA fractions from different species shows substantial divergence in DNA composition. The divergence in base composition is correlated with nuclear DNA amount. The degree of divergence is of the same order of magnitude in both the repetitive and nonrepetitive fractions.     

DNA/DNA Hybridization studies among six endemic Hawaiian Drosophila species

The nucleotide-sequence homology and divergence of six endemic Hawaiian Drosophila species have been studied by means of DNA/DNA hybridization experiments, using the fractionated unique and moderately repetitive sequences. The data indicate that the extent of homology between the nonrepetitive DNA sequences of D. crucigera, D. pilimana, D. engyochracea, D. silvarentis and D. picticornis confirms the taxonomic relationship established through cytological evidence. The average rate of divergence of nonrepetitive DNA sequences among Hawaiian Drosophila species is approximately 2.75 to 3.75% per million years. This value is much higher than that found among other species when divergence time is estimated on an absolute time base.     

The distribution and divergence during evolution of families of repetitive DNA sequences inLathyrus species

Summary Evolution and divergence among, species within the genusLathyrus have involved an approximately fivefold increase in the amounts of nuclear DNA. Most species inLathyrus are diploids with the same chromosome number, 2n=14. Significant changes in the amounts of repetitive sequences have accounted for much of the evolutionary DNA variation between species. Seven diploidLathyrus species with a twofold variation in nuclear DNA amounts between them were investigated. Using higher derivative analysis of the thermal denaturation profiles of the reassociated repetitive DNA, the reiteration frequency and divergence of repetitive families were compared. Much variation in the reiteration frequency was observed within and between species. In species with larger 2C DNA amounts repetitive families had on average greater amounts of DNA. Despite the massive differences in DNA amounts, six species were consistently similar in the number of repetitive families in their genomes, and they showed a similar pattern in base sequence divergence. In terms of base sequence relationships the repetitive families appeared to be heterogeneous. The evolutionary significance is discussed.     

DNA of Akodon (Rodentia, Cricetidae). II. Molecular hybridization of repetitive DNA sequences

Interspecies repetitive DNA homology was studied in akodont rodents related at generic and suprageneric levels. The homology was determined by taking the species Akodon molinae as the reference species. The 3H-DNA/DNA hybridization on filters showed a closer relationship between A. molinae and A. azarae, A. dolores and A. mollis than between A. molinae and Bolomys obscurus. These data agree with the taxonomical ranking of the species. The quantity and quality of the hybrid DNAs were measured by investigating their thermal stabilities and subsequent comparison to the results obtained on the reference species. These data indicate high similitude between the repetitive DNA of A. dolores and A. molinae. Increasing differences were shown to occur in the repetitive DNA of A. mollis, B. obscurus and A. azarae, respectively. Since these results coincide with the G-banding homologies and differ slightly from the taxonomical rank, it is speculated that the divergency between the DNA of A. molinae and A. azarae is the result of a differential process of DNA amplification which is not related to the phylogenetical distance separating the two species.     

Evolutionary change in the repetition frequency of sea urchin DNA sequences

The frequency of occurrence of particular repetitive sequence families has been estimated in the DNA of the three sea urchin species Strongylocentrotus purpuratus, Strongylocentrotus franciscanus and Lytechinus pictus using individual cloned S. purpuratus repetitive sequence elements. Cloned repetitive sequence elements as described by Scheller et al. (1977a) were prepared by reassociation of S. purpuratus DNA fragments to repetitive Cot, digestion with single-strand-specific nuclease S1 and ligation of synthetic restriction sites to their ends. The sequences were cloned by insertion at the Eco RI site of plasmid RSF2124, labeled, strand-separated and reassociated with 800–900 nucleotide long unlabeled DNA. Both kinetic (genomic DNA excess) and saturation (cloned DNA excess) estimates of frequencies were made. For nine cloned fragments, the ratio of the repetition frequency in S. purpuratus DNA to that in S. franciscanus DNA ranges from about 20 to about 1. In the four cases examined, only a few copies were detected in the DNA of L. pictus. Estimates have also been made of frequency changes in many repetitive families by measuring the reassociation of labeled repetitive DNA fractions of each species with total DNA from other species. In each reciprocal comparison, the labeled repetitive sequences reassociate more slowly with DNA of other species than with DNA of the species from which they were prepared. Thus it appears that the dominant repetitive sequence families in the DNA of each species are present at lower frequencies in the DNA of closely related species. Measurements of thermal stability have been made of S. purpuratus cloned repetitive sequences reassociated with S. franciscanus DNA or S. purpuratus DNA. Most families have changed both in frequency and sequence, although some have changed little in sequence but show great changes in frequency.     

A Repetitive DNA Sequence Showing the Characteristic of Genomic DNA Differentiation in Oryza

A moderately repetitive DNA sequence from rice had been cloned by the method of DNA renaturation kinetics. Restriction site analysis, Southern hybridization and DNA sequence analysis indicated that the sequence was mainly in tandem repeat in rice genome. A lot of wild and cultivated rice species were analyzed by Southern blot. With some restriction endonucleases digestion the hybridization pattern of rice DNA showed more than 40 bands with different intensity mainly consisting of the strong and weak hybridization bands. It was found that the strong hybridization bands were specific to the BBCC genome and the weak bands showed abundent polymorphism in cultivated rice species. These results suggested that the repetitive DNA sequence might be useful for rice breeding.     

一种能表现水稻基因组DNA分化特征的重复DNA顺序

用ＤＮＡ 复性动力学方法克隆到一个水稻中度重复顺序。Ｓｏｕｔｈｅｒｎ 杂交、限制性内切酶分析及序列分析资料表明,该重复顺序在水稻基因组中具有串联重复和散布状态两种存在方式。以该ＤＮＡ 片段作探针,用Ｓｏｕｔｈｅｒｎ 杂交方法分析了多种野生稻种和栽培稻品种的基因组分化特征。某些限制性内切酶消化过的水稻ＤＮＡ,其图谱呈现出多达４０ 条以上的杂交带,包括强杂交带和弱杂交带两种类型。重复实验结果证明,强杂交带表现为ＢＢＣＣ染色体组型特异而弱带则在栽培稻各品种间显示出丰富的多态性,表明该重复顺序片段在水稻理论研究和育种实践中可能具有重要意义     

DNA polymerase-catalyzed elongation of repetitive hexanucleotide sequences: application to creation of repetitive DNA libraries

We demonstrate the elongation of various hexanucleotide sequences with thermophilic DNA polymerase, under isothermal or thermal cyclic reaction conditions. We prepared 10 types of double repeat hexanucleotide duplexes with various GC compositions containing between 0 and 6 GC nucleotides per repeat and incubated these duplexes with thermophilic Taq DNA polymerase and dNTPs at various temperatures. All of the model repetitive short duplexes were elongated under the isothermal incubation conditions, although there were some differences in the elongation efficiencies derived from the GC composition in the repetitive sequences. It was also found that all of the model repetitive duplexes were extended more effectively by a 3-step thermal cyclic reaction involving denaturation, annealing, and extension. On the basis of this technique, we prepared a glutamate-encoding short repetitive duplex and created long repetitive DNAs under isothermal and thermal cyclic reaction conditions. DNA sequencing analysis of the cloned repetitive DNA revealed that well-ordered long repetitive DNAs of various chain lengths were created by this DNA polymerase-catalyzed ligation method, and these were easily cloned into vectors by the TA-cloning method. This method could be useful for obtaining DNAs encoding arbitrary long repetitive amino acid sequences more effectively than the conventional T4 ligase-catalyzed ligation method.     

小麦及其近缘种中基因组特异性DNA重复序列的研究进展

本文对小麦族植物中基因组特异性DNA重复序列的分类、基本特征、分离和鉴定方法、在小麦遗传改良中的应用以及未来研究的发展趋势进行了简述。综合已有的研究结果可以看出基因组特异性DNA重复序列是小麦族植物基因组特异性形成的重要构成部分。对基因组特异性DNA重复序列的研究是认识小麦族植物基因组的有效途径之一,基因组特异性DNA重复序列的应用将进一步促进小麦族植物分子细胞遗传学和普通小麦遗传改良研究的进展。 Advances in Studies of Genome-Specific Repetitive DNA Sequences in Wheat and Related Species BAI Jian-rong1,2,JIA Xu1,WANG Dao-wen1 1.The State Key Laboratory of Plant Cell and Chromosome Engineering,Institute of Genetics and Developmental Biology,The Chinese Academy of Sciences,Beijing 100101,China; 2.Crop Genetics Institute,Shanxi Academy of Agricultural Sciences,Taiyuan 030031,China Abstract:In this paper we review recent advances in studies of several aspects of genome specific repetitive DNA sequences in wheat and related species.The available results demonstrate that genome specific repetitive DNA sequences are important components of genome specificity in wheat and related species.Research on genome specific repetitive DNA sequences is essential to the elucidation of genome function.The application of genome specific repetitive DNA sequences will aid molecular cytogenetic studies in wheat and related species and contributes to genetic improvement of common wheat. Key words：wheat;genome specific repetitive DNA sequence;chromosome     

Chromosomes,DNA sequences,and evolution in salamanders of the genus Plethodon

Chromosomes and DNA sequence homologies have been studied in 15 species of North American salamander belonging to the genus Plethodon. These include 4 Eastern small species, 5 Eastern large species, 5 Western, and 1 New Mexican species. All species have 14 metacentric or sub-metacentric chromosomes. Their karyotypes are closely similar, but their C values range from 18–69 pg. DNA:DNA molecular hybridization studies showed that salamanders belonging to the same species group had between 60 and 90% of the observed repetitive DNA sequences in common, different groups of Eastern species had between 40 and 60% in common, and Eastern and Western groups had less than 10% in common. The slowly reassociating DNA sequences were also diverse among species, but higher levels of homology were observed than in the case of repetitive sequences. The New Mexican species was exceptional in showing little homology with other species with respect to either repetitive or slowly reassociating sequences.     

A simple and rapid technique for identification of large numbers of individual mosquitoes using DNA hybridization

A general method for obtaining species-specific repetitive DNA sequences is described. The method is based on the detection of recombinant DNA clones containing repetitive sequences using labeled total genomic DNA. These repetitive DNA sequences can be used to identify individual mosquito adults, pupae, and larvae squashed on filter membranes (squash blots). This technique was used to distinguish individuals of the four sibling species of the Anopheles quadrimaculatus complex. Repetitive DNA sequences and squash blots can be of use for rapid identification of other insect species in field collections.     

Molecular and cytological characterization of repetitive DNA sequences in Brassica

Summary We isolated three different repetitive DNA sequences from B. campestris and determined their nucleotide sequences. In order to analyze organization of these repetitive sequences in Brassica, Southern blot hybridization and in situ hybridization with metaphase chromosomes were performed. The sequence cloned in the plasmid pCS1 represented a middle repetitive sequence present only in B. campestris and not detected in closely related B. Oleracea. This sequence was localized at centromeric regions of six specific chromosomes of B. campestris. The second plasmid, pBT4, contained a part of the 25S ribosomal RNA gene, and its copy number was estimated to be 1,590 and 1,300 per haploid genome for B. campestris and B. oleracea, respectively. In situ hybridization with this sequence showed a clear signal at the NOR region found in the second largest chromosome of B. Campestris. The third plasmid, pBT11, contained a 175-bp insert that belongs to a major family of tandem repeats found in all the Brassica species. This sequence was detected at centromeric regions of all the B. campestris chromosomes. Our study indicates that in situ hybridization with various types of repetitive sequences should give important information on the evolution of repetitive DNA in Brassica species.     

Localisation of foldback DNA sequences in nuclei chromosomes of Scilla, Secale, and of mouse.

Foldback DNA, prepared from mouse and Scilla sibirica main band DNA, and from rye (Secale cereale) total DNA, was characterised by denaturation, renaturation, and electron microscopy. 3H-cRNA of this DNA was hybridised in situ to nuclei and chromosomes of the respective species. There is no universal labelling pattern among the three species. In mouse, highly repetitive foldback DNA is present in the whole chromatin including the satellite DNA-containing regions. In Scilla sibirica, on the contrary, the highly repetitive foldback sequences are excluded form the satellite DNA loci and are arranged in clusters in the remaining chromatin. In rye, there is a clear preferential labelling of the chromocenters in the interphase nuclei as well as metaphase chromosomes, indicating that highly repetitive foldback DNA is preferentially located among other highly repetitive sequences.     

DNA sequences repaired at pachytene exhibit strong homology among distantly related higher plants

Moderately repetitive DNA sequences in Lilium (cv Enchantment) which undergo a meiotic-specific repair synthesis during pachytene (P-DNA) were previously shown to exist as families of very low internal sequence divergence. The present study concerns P-DNA sequence preservation among higher plants. The relative abundance of these sequences in a variety of plant species and their divergence relative to Enchantment P-DNA was determined through C₀t analysis and thermal denaturation of hybrid duplexes. Nearly all of the P-DNA sequence families of Enchantment were found to be present in the genomes of a number of monocot species and the dicot Vicia faba. Sequence content is highly conserved, with less than 6% divergence between Lilium and distantly related species such as Zea mays and Secale cereale. However, the number of repeats per P-DNA family varies considerably in different species, being particularly low among the Poales. P-DNA differs from most high thermal stability (HTS) sequence families of Enchantment which, although exhibiting a high degree of internal homology, are not present as repetitive DNA in the genomes of the other species examined. For most HTS families, the lack of internal divergence probably reflects their fairly recent introduction into the moderately repetitive DNA class, while P-DNA sequences represent evolutionarily ancient families which are the products of strong selective pressure for an indispensable meiotic function.     

Changes in DNA composition in the evolution of Vicia species

Summary The composition of nuclear DNA in 3 Vicia species are compared. The species V. eriocarpa, V. johannis and V. melanops are from three separate subgeneric sections of Vicia and show a fourfold variation in their amounts of nuclear DNA. DNA melting experiments, buoyant density gradient analysis and Cot reassociation experiments show that the quantitiative change in nuclear DNA between the three species is achieved by changes in the amounts of both repetitive and nonrepetitive DNA sequences. It is suggested that while the increase in the repetitive fraction is achieved by the proliferation of repetitive base sequences the increase in the nonrepetitive fraction is due to the steady accretion of highly diverged base sequences resulting from mutations, deletions, insertions and base sequence rearrangements among families of repetitive sequences.