Interspersion of repetitive and non-repetitive DNA sequences in the sea urchin genome

Measurements are reported which lead to the conclusion that repetitive and nonrepetitive sequences are intimately interspersed in the majority of the DNA of the sea urchin, Strongylocentrotus purpuratus. Labeled DNA was sheared to various lengths, reassociated with a great excess of 450 nucleotide-long fragments to cot 20, and the binding of the labeled DNA to hydroxyapatite was measured. Repetitive sequences measured in this way are present on about 42% of the 450 nucleotide-long fragments. As the DNA fragment length is increased, larger and larger fractions of the fragments contain repetitive sequences. Analysis of the measurements leads to the following estimate of the quantitative features of the pattern of interspersion of repetitive and nonrepetitive sequences. About 50% of the genome consists of a short-period pattern with 300–400 nucleotide average length repetitive segments interspersed with about 1000 nucleotide average length nonrepetitive segments. Another 20% or more consists of a longer period interspersed pattern. About 6% of the genome is made up of relatively long regions of repetitive sequences. The remaining 22% of the genome may be uninterrupted single copy DNA, or may have more widely spaced repeats interspersed. The similarity of these results to previous measurements with the DNA of an amphibian suggests that this interspersion pattern is of general occurrence and selective importance.     

Interspersion of repetitive sequences in rat liver DNA

In rat liver DNA, which contains only 20% repetitive sequences, a close interspersion of repetitive and unique sequences is found in about 35 % of the total DNA. The mean length of repetitive and unique alternating sequences is respectively 230 and 400 base pairs.     

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.     

Interspersion of different repeated sequences in the wheat genome revealed by interspecies DNA/DNA hybridisation.

The repeated sequences in oats DNA have been used to study chromosomal repeated sequence organisation in wheat. Approximately 75% of the wheat genome consists of repeated sequences but only approximately 20% will form heteroduplexes with repeated sequences from oats DNA at 60 degrees C in 0.18 M Na+. The proportion of wheat DNA that forms heteroduplexes with oats DNA is shown to be independent of the wheat DNA fragment length. However, the proportion of wheat DNA that is retained with the heteroduplexes when fractionated on hydroxyapatite is very dependent upon the wheat fragment length up to 3500 nucleotides. This is because more non-renatured wheat DNA is attached to the heteroduplexes with longer fragments. The results indicate that the repeated sequences in the wheat genome homologous to repeated sequences in oats are not clustered in the chromosomes but distributed amongst other repeated and possible non-repeated sequences.     

GEM, a cluster of repetitive sequences in the Drosophila subobscura genome

GEM is a new family of repetitive sequences detected in the D. subobscura genome. Two of the four described GEM elements encompass a heterogeneous central module, with no detectable ORF, flanked by two long inverted repeats. These elements are composed of a set of repetitive modules, which are inverted repeat (IR), direct repeat (DR), palindromic sequence (PS), long sequence (LS) and short sequence (SS). These five modules can be found either clustered or dispersed as single modules in the D. subobscura genome, in euchromatic and heterochromatic regions. In addition to the 3' region of Adh retrosequences, single IR and LS blocks were found associated with the promoter region of different genes, in particular, LS-like blocks have also been found associated with functional genes in D. melanogaster and D. virilis. Conversely, the DR block is highly similar to satellite DNAs from some other species of the obscura group. In addition, GEM elements share some structural features with IS elements described in different Drosophila species. It is likely that both GEM and IS sequences would be vestiges of an ancestral transposable element.     

Interspersion of highly repetitive DNA with single copy DNA in the genome of the red crab, Geryon quinquedens.

Kinetic analysis of the reassociation of 420 nucleotide (NT) long fragments has shown that essentially all of the repetitive sequences of the DNA of the red crab Geryon quinquedens are highly repetitive. There are negligible amounts of low and intermediate repetitive DNAs. Though atypical of most eukaryotes, this pattern has been observed in all other brachyurans (true crabs) studied (1,2). The major repetitive component is subdivided into short runs of 300 NT and longer runs of greater than 1200 NT while the minor component has an average sequence length of 400 NT. Both components reassociate at rates commonly observed for satellite DNAs. Unique among eukaryotes the organization of the genome includes single copy DNA contiguous to short runs (approximately 300 NT) of both repetitive components. Although patent satellites are not present, subsets of the repetitive DNA have been isolated by either restriction endonuclease digestion or by centrifugation in Ag+ or Hg2+/Cs2SO4 density gradients.     

The distribution of interspersed repetitive DNA sequences in the human genome

The distribution of interspersed repetitive DNA sequences in the human genome has been investigated, using a combination of biochemical, cytological, computational, and recombinant DNA approaches. "Low-resolution" biochemical experiments indicate that the general distribution of repetitive sequences in human DNA can be adequately described by models that assume a random spacing, with an average distance of 3 kb. A detailed "high-resolution" map of the repetitive sequence organization along 400 kb of cloned human DNA, including 150 kb of DNA fragments isolated for this study, is consistent with this general distribution pattern. However, a higher frequency of spacing distances greater than 9.5 kb was observed in this genomic DNA sample. While the overall repetitive sequence distribution is best described by models that assume a random distribution, an analysis of the distribution of Alu repetitive sequences appearing in the GenBank sequence database indicates that there are local domains with varying Alu placement densities. In situ hybridization to human metaphase chromosomes indicates that local density domains for Alu placement can be observed cytologically. Centric heterochromatin regions, in particular, are at least 50-fold underrepresented in Alu sequences. The observed distribution for repetitive sequences in human DNA is the expected result for sequences that transpose throughout the genome, with local regions of "preference" or "exclusion" for integration.     

A repetitive DNA element,associated with telomeric sequences in Drosophila melanogaster,contains open reading frames

He-T sequences are a complex repetitive family of DNA sequences in Drosophila that are associated with telomeric regions, pericentromeric heterochromatin, and the Y chromosome. A component of the He-T family containing open reading frames (ORFs) is described. These ORF-containing elements within the He-T family are designated T-elements, since hybridization in situ with the polytene salivary gland chromosomes results in detectable signal exclusively at the chromosome tips. One T-element that has been sequenced includes ORFs of 1,428 and 1,614 bp. The ORFs are overlapping but one nucleotide out of frame with respect to each other. The longer ORF contains cysteine-histidine motifs strongly resembling nucleic acid binding domains of gag-like proteins, and the overall organization of the T-element ORFs is reminiscent of LINE elements. The T-elements are transcribed and appear to be conserved in Drosophila species related to D. melanogaster. The results suggest that T-elements may play a role in the structure and/or function of telomeres.by W. Hennig     

Mariner-like sequences are present in the genome of the fruitfly,Drosophila melanogaster

No mariner-like elements (MLEs) have been described until now in the genome of Drosophila melanogaster despite many experiments using molecular methods. However, analyses of sequence data from the Berkeley Drosophila Genome Project show that there are DNA sequences corresponding to pieces of MLE in the genome of D. melanogaster. The sequences of these elements have diverged considerably (about 40%) from any other sequences observed elsewhere. Moreover, the putative amino acid sequences encoded by the best conserved regions reveal that these sequences are clearly homologous to MLEs transposase.     

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.     

Recurrent insertion and duplication generate networks of transposable element sequences in the Drosophila melanogaster genome

Background  

The recent availability of genome sequences has provided unparalleled insights into the broad-scale patterns of transposable element (TE) sequences in eukaryotic genomes. Nevertheless, the difficulties that TEs pose for genome assembly and annotation have prevented detailed, quantitative inferences about the contribution of TEs to genomes sequences.     

A system for mapping DNA sequences in the chromosomes of Drosophila melanogaster

Individual segments of the chromosomal DNA in D. melanogaster were isolated, and the sequences they contain were analyzed for repetition and mapped within the polytene chromosomes. Isolation was achieved by first constructing circular hybrid DNA molecules consisting of single chromosomal segments linked by poly(dA):poly(dT) joints to single molecules of the tetracycline resistance plasmid, pSC101. Tetracycline-sensitive E. coli were transformed to resistance by this heterogeneous population of hybrid molecules and homogeneous populations of different hybrids were isolated from the clones of transformants. Three hybrid plasmids (pDm 1, 2, and 4) were studied in detail. Each exhibits the structure expected from the method of construction and none exhibits internal sequence repetition detectable by reassociation kinetics. The D. melanogaster sequences in pDm2 and 4 belong to a single class defined by little or no repetition within the genome and localization to a single chromomeric region in the polytene chromosomes. The characteristics of this class, which also includes 4 of a second set of 6 hybrids, are not compatible with tandem repetition models for the chromomere. The sequences in pDm1 are repeated 90 times and are located in 15 different chromomeric regions and within the chromocentric β-heterochromatin. This distribution is of the kind predicted by certain regulatory models, for example, that of Britten and Davidson (1969).     

Identification of methylated sequences in genomic DNA of adult Drosophila melanogaster

The genome of Drosophila melanogaster contains methylated cytosines. Recent studies indicate that DNA methylation in the fruit fly depends on one DNA methyltransferase, dDNMT2. No obvious phenotype is associated with the downregulation of this DNA methyltransferase. Thus, identifying the target sequences methylated by dDNMT2 may constitute the first step towards understanding the biological functions of this enzyme. We used anti-5-methylcytosine antibodies as affinity column to identify the methylated sequences in the genome of adult flies. Our analysis demonstrates that components of retrotransposons and repetitive DNA sequences are putative substrates for dDNMT2. The methylation status of DNA encoding Gag, a protein involved in delivering the transposition template to its DNA target, was confirmed by sodium bisulfite sequencing.     

The distribution of repetitive DNA in the chromosomes of cultured cells of Drosophila melanogaster

The distribution patterns of different stains (orcein, quinacrine and Giemsa) in an established cell line of Drosophila melanogaster (GM₃ WS) were compared. Each chromosome stained both with quinacrine and with Giemsa shows up a specific banding pattern for heterochromatin. The comparison between the two patterns suggests a hypothesis concerning the significance of the fluorescence; moreover it permits the conclusion that heterochromatin in D. melanogaster mitotic chromosomes is all constitutive and that there is a correspondence between repetitive DNA and sections poor in mappable genes.This work was supported by a grant of the Consiglio Nazionale delle Ricerche Roma.     

Mitochondrial DNA in Drosophila. An analysis of genome organization and transcription in Drosophila melanogaster and Drosophila virilis

Transfer RNAs of Escherichia coli were separated by two-dimensional polyacrylamide gel electrophoresis, and the relative abundance of each of the 26 known tRNAs thus separated was measured on the basis of molecular numbers in cells. Based on this relative abundance, the distributions of cognate codons in E. coli genes (lacI, rpA, asnA, recA, lpp and four ribosomal protein genes) and in coliphage (MS2, φX174 and λ) genes were examined. A strong positive correlation between the tRNA abundance and the choice of codons, among both synonymous codons and those corresponding to different amino acids, was found for all E. coli protein genes that had been sequenced completely. However, the correlation was less significant for the phage genes. The relationship between tRNA abundance and its usage (namely anticodon usage) was examined by regression analysis. The degree of the relationship found for individual E. coli genes differed from gene to gene: those of r-protein genes and recA were higher than those of trpA, lacI and asnA. The dependent relationship of tRNA usage on its content for the first two genes seems to be greater than that expected from the proportional relationship between the two variables; i.e. these genes selectively use codons corresponding to major tRNAs but nearly avoid using those of minor tRNAs.