A chromosome 5-specific repetitive DNA sequence in rice (Oryza sativa L)

Repetitive DNA sequences in the rice genome comprise more than half of the nuclear DNA. The isolation and characterization of these repetitive DNA sequences should lead to a better understanding of rice chromosome structure and genome organization. We report here the characterization and chromosome localization of a chromosome 5-specific repetitive DNA sequence. This repetitive DNA sequence was estimated to have at least 900 copies. DNA sequence analysis of three genomic clones which contain the repeat unit indicated that the DNA sequences have two sub-repeat units of 37 bp and 19 bp, connected by 30-to 90-bp short sequences with high similarity. RFLP mapping and physical mapping by fluorescence in situ hybridization (FISH) indicated that almost all copies of the repetitive DNA sequence are located in the centromeric heterochromatic region of the long arm of chromosome 5. The strategy for cloning such repetitive DNA sequences and their uses in rice genome research are discussed.     

A new family of interspersed repetitive DNA sequences in the mouse genome

Repetitive DNA sequences near immunoglobulin genes in the mouse genome (Steinmetz et al., 1980a,b) were characterized by restriction mapping and hybridization. Six sequences were determined that turned out to belong to a new family of dispersed repetitive DNA. From the sequences, which are called R1 to R6, a 475 base-pair consensus sequence was derived. The R family is clearly distinct from the mouse B1 family (Krayev et al., 1980). According to saturation hybridization experiments, there are about 100,000 R sequences per haploid genome, and they are probably distributed throughout the genome. The individual R sequences have an average divergence from the consensus sequence of 12.5%, which is largely due to point mutations and, among those, to transitions. Some R sequences are severly truncated. The R sequences extend into A-rich sequences and are flanked by short direct repeats. Also, two large insertions in the R2 sequence are flanked by direct repeats. In the neighbourhood of and within R sequences, stretches of DNA have been identified that are homologous to parts of small nuclear RNA sequences. Mouse satellite DNA-like sequences and members of the B1 family were also found in close proximity to the R sequences. The dispersion of R sequences within the mouse genome may be a consequence of transposition events. The possible role of the R sequences in recombination and/or gene conversion processes is discussed.     

Coordinate replication of dispersed repetitive sequences in Physarum polycephalum

The synchronous macroplasmodial growth phase of the slime mould Physarum polycephalum was used to study the in vivo replication of large chromosomal DNA segments. Newly replicated DNA was isolated at various points in S-phase by its preferential association with the nuclear matrix. This DNA was then used to probe cosmid clones of the Physarum genome. The results indicate that certain dispersed repetitive sequences in the genome are coordinately replicated. The observed pattern of replication may be due either to the presence of a replication origin within each repetitive sequence or to the systematic arrangement of these sequences around a replication origin. The latter appears more likely since the repetitive sequences are probably not randomly scattered within the genome.     

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.     

Organization and evolution of highly repeated satellite DNA sequences in plant chromosomes

A major component of the plant nuclear genome is constituted by different classes of repetitive DNA sequences. The structural, functional and evolutionary aspects of the satellite repetitive DNA families, and their organization in the chromosomes is reviewed. The tandem satellite DNA sequences exhibit characteristic chromosomal locations, usually at subtelomeric and centromeric regions. The repetitive DNA family(ies) may be widely distributed in a taxonomic family or a genus, or may be specific for a species, genome or even a chromosome. They may acquire large-scale variations in their sequence and copy number over an evolutionary time-scale. These features have formed the basis of extensive utilization of repetitive sequences for taxonomic and phylogenetic studies. Hybrid polyploids have especially proven to be excellent models for studying the evolution of repetitive DNA sequences. Recent studies explicitly show that some repetitive DNA families localized at the telomeres and centromeres have acquired important structural and functional significance. The repetitive elements are under different evolutionary constraints as compared to the genes. Satellite DNA families are thought to arise de novo as a consequence of molecular mechanisms such as unequal crossing over, rolling circle amplification, replication slippage and mutation that constitute "molecular drive".     

Nucleotide sequences of mouse genomic loci including a gene or pseudogene for U6 (4.8S) nuclear RNA.

We have isolated four clones which hybridize with U6 (4.8S) nuclear RNA, a mammalian small nuclear RNA(nRNA), from DNA of BALB/C mouse liver. Their restriction maps are totally different from each other, indicating that they derived from different loci in the mouse genome. The nucleotide sequences around the hybridizing region in the three clones have been determined. One clone gives a gene that is co-linear with the U6 RNA. There is a sequence TATAAAT beginning 31 nucleotides upstream of the gene, which may suggest that the U6 RNA is transcribed by RNA polymerase II. The other two clones contain a pseudogene for the U6 RNA which has 7 or 9 nucleotide changes from the RNA. The pseudogenes are surrounded by radically different sequences from those surrounding the gene, and they are closely linked to a pseudogene for another snRNA, 4.5S-I RNA, or a part of highly repetitive an interspersed sequence B1.     

Coordinate replication of dispersed repetitive sequences in Physarum polycephalum

The synchronous macroplasmodial growth phase of the slime mould Physarum polycephalum was used to study the in vivo replication of large chromosomal DNA segments. Newly replicated DNA was isolated at various points in S-phase by its preferential association with the nuclear matrix. This DNA was then used to probe cosmid clones of the Physarum genome. The results indicate that certain dispersed repetitive sequences in the genome are coordinately replicated. The observed pattern of replication may be due either to the presence of a replication origin within each repetitive sequence or to the systematic arrangement of these sequences around a replication origin. The latter appears more likely since the repetitive sequences are probably not randomly scattered within the genome.     

Characterization of the genome of Arabidopsis thaliana

The small crucifer Arabidopsis thaliana has many useful features as an experimental organism for the study of plant molecular biology. It has a four-week life-cycle, only five chromosomes and a genome size less than half that of Drosophila. To characterize the DNA sequence organization of this plant, we have randomly selected 50 recombinant lambda clones containing inserts with an average length of 12,800 base-pairs and analyzed their content of repetitive and unique DNA by various genome blot, restriction digestion and RNA blot procedures. The following conclusions can be drawn. The DNA represented in this random sample is composed predominantly of single-copy sequences. This presumably reflects the organization of the Arabidopsis genome as a whole and supports prior conclusions reached on the basis of kinetics of DNA reassociation. The DNA that encodes the ribosomal RNAs constitutes the only major class of cloned nuclear repetitive DNA. It consists of approximately 570 tandem copies of a heterogeneous 9900-base-pair repeat unit. There is an average of approximately 660 copies of the chloroplast genome per cell. Therefore, the chloroplast genome constitutes the major component of the repetitive sequences found in A. thaliana DNA made from whole plants. The inner cytosine residue in the sequence C-C-G-G is methylated more often than the outer in the tandem ribosomal DNA units, whereas very few differences in the methylation state of these two cytosine residues are detected in unique sequences.     

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.     

Sequence organisation in nuclear DNA from Physarum polycephalum: Genomic organisation of DNA segments containing foldback sequences

DNA clones containing foldback sequences, derived from Physarum polycephalum nuclear DNA, can be classified according to their pattern of hydridisation to Southern blots of genomic DNA. One group of DNA clones map to unique DNA loci when used as a probe to restriction digests of Physarum nuclear DNA. These cloned segments appear to contain dispersed repetitive sequence elements located at many hundreds of sites in the genome. Similar patterns of hybridisation are generated when these cloned DNA probes are annealed to DNA restriction fragments of genomic DNA obtained from a number of different Physarum strains, indicating that no detectable alteration has occurred at these genomic loci subsequent to the divergence of the strains as a result of the introduction or deletion of mobile genetic elements. However, deletion of segments of some cloned DNA fragments occurs following their propagation in Escherichia coli. A second, distinct group of clones are shown to be derived from highly methylated segments of Physarum DNA which contain very abundant repetitive sequences with regular, though complex, arrangements of restriction sites at their various genomic locations. It is suggested that these DNA segments contain clustered repetitive sequence elements. The results lead to the conclusion that foldback elements in Physarum DNA are located in segments of the genome which display markedly different patterns of sequence organisation and degree of DNA methylation.     

Chloroplast DNA insertions into the nuclear genome of rice: the genes,sites and ages of insertion involved

Rice (Oryza sativa) is one of three predominant grain crops, and its nuclear and organelle genomes have been sequenced. Following genome analysis revealed many exchanges of DNA sequences between the nuclear and organelle genomes. In this study, a total of 45 chloroplast DNA insertions more than 2 kb in length were detected in rice nuclear genome. A homologous recombination mechanism is expected for those chloroplast insertions with high similarity between their flanking sequences. Only five chloroplast insertions with high sequence similarity between two flanking sequences from an insertion were found in the 45 insertions, suggesting that rice might follow the non-homologous end-joining (NHEJ) repair of double-stranded breaks mechanism, which is suggested to be common to all eukaryotes. Our studies indicate that the most chloroplast insertions occurred at a nuclear region characterized by a sharp change of repetitive sequence density. One potential explanation is that regions such as this might be susceptible target sites or “hotspots” of DNA damage. Our results also suggest that the insertion of retrotransposon elements or non-chloroplast DNA into chloroplast DNA insertions may contribute significantly to their fragmentation process. Moreover, based on chloroplast insertions in nuclear genomes of two subspecies (indica and japonica) of cultivated rice, our results strongly suggest that they diverged during 0.06–0.22 million years ago. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Studies of a novel repetitive sequence family in the genome of mice

A new middle repetitive sequence is described in the mouse genome. It has been revealed with a recombinant clone isolated from a Mus musculus BamHI gene library constructed in pBR322 and containing an insertion of 1.73 kb. When digests of genomic DNA were subjected to Southern blot hybridization, using the 1.73-kb insert as probe, we obtained a light smear and discrete bands, indicating a dispersion in the mouse genome of this sequence. This 1.73-kb sequence seems to be a part of a greater repetitive sequence at least 6 kb in length. The sizes of the bands hybridizing with the 1.73-kb insert are similar when compared between different laboratory strains but differ remarkably between the two species M. musculus and Mus caroli. We have shown also a great variation in the copy number of the sequence studied between these two species. When rat DNA is probed with the 1.73-kb insert, no hybridization is observed. Subcloning of the 1.73-kb sequence in three fragments has pointed out that the reiteration was not homogeneous along the 1.73-kb sequence. The 1.73-kb clone was sequenced and compared with other interspersed repetitive sequences, previously described in the rodent genome, and no homology was found.     

Characterization of a highly repetitive family of DNA sequences in the mouse.

A large proportion (0.5-1%) of total mouse DNA is cleaved by Bam HI into fragments whose size is about 500 base pairs. A cloned member of this repetitive family of DNA sequences (BAM5 family) was sequenced by the dideoxy chain termination procedure and shown to contain 507 base pairs. The sequence exhibited no unusual or remarkable features. Repetitive sequences complementary to the cloned BAM5 fragment were found in rat DNA, but not in feline or human DNA. Restriction mapping suggested that many BAM5 sequences were components of much larger repetitive DNAs which were scattered throughout the mouse genome. The BAM5 sequences within the larger repetitive DNAs did not appear to be arranged tandemly or as members of scrambled tandem repeats. RNA homologous to the cloned BAM5 sequence was detected in cultured mouse cells, but not in cultured rat cells.     

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.     

Structure of thymidine kinase gene introduced into mouse Ltk- cells by a new injection method

Pricking, a new injection method developed by Yamamoto et al. (1981), can be used to introduce DNA into cultured cells with high efficiency. Closed circular plasmid DNA containing the cloned HSV-TK gene (pTK-1) was introduced by this method and the structure of DNA in stable transformants was examined. In most clones, the introduced DNA was integrated into the mouse genome in a tandemly repeated form. The possibility of multiple integration via mouse middle repetitive sequences was also examined using the chimeric plasmid with TK genes and middle repetitive sequences (pMRTK-1). Digestion with restriction enzymes showed that the middle repetitive sequence used in this experiment had no effect on the efficiency of transformation, suggesting that this sequence is unable to mediate homologous recombination with mouse genomes.