Structural features of the integration site of foreign DNA in the transgenic mouse genome

The structure of the transgenic mouse DNA region containing an integrated transgene (fragment of pBR322 sequence) was analysed. In one of the sequences flanking the transgene, short direct and inverted overlapping repeats were revealed at a distance of 60 bp from the integration site. In the same flanking sequence, there is an extended sequence (3.5 kbp) 0.3-1 kbp away from the transgene. It repeats 100-300 times in the mouse genome and is highly conservative (the homologs of the repeat have been revealed in other mammalian, bird, fish and insect genomes). This up-to-date unknown family of highly-conserved dispersed repeats has been denoted by T1. We believe that both the revealed short inverted repeats capable of forming hairpins with loops and the T1 repeat are structures involved in the process of non-homologous insertion of foreign DNA into the region of the transgenic mouse genome.     

Chloroplast DNA rearrangements are more frequent when a large inverted repeat sequence is lost

We examined the arrangement of sequences common to seven angiosperm chloroplast genomes. The chloroplast DNAs of spinach, petunia and cucumber are essentially colinear. They share with the corn chloroplast genome a large inversion of approximately 50 kb relative to the genomes of three legumes--mung bean, pea and broad bean. There is one additional rearrangement, a second, smaller inversion within the 50 kb inversion, which is specific to the corn genome. These two changes are the only detectable rearrangements that have occurred during the evolution of the species examined (corn, spinach, petunia, cucumber and mung bean) whose chloroplast genomes contain a large inverted repeat sequence of 22-25 kb. In contrast, we find extensive sequence rearrangements in comparing the pea and broad bean genomes, both of which have deleted one entire segment of the inverted repeat, and also in comparing each of these to the mung bean genome. Thus there is a relatively stable arrangement of sequences in those genomes with the inverted repeat and a much more dynamic arrangement in those that have lost it. We discuss several explanations for this correlation, including the possibility that the inverted repeat may play a direct role in maintaining a conserved arrangement of chloroplast DNA sequences.     

Palindrome regeneration by template strand-switching mechanism at the origin of DNA replication of porcine circovirus via the rolling-circle melting-pot replication model

Palindromic sequences (inverted repeats) flanking the origin of DNA replication with the potential of forming single-stranded stem-loop cruciform structures have been reported to be essential for replication of the circular genomes of many prokaryotic and eukaryotic systems. In this study, mutant genomes of porcine circovirus with deletions in the origin-flanking palindrome and incapable of forming any cruciform structures invariably yielded progeny viruses containing longer and more stable palindromes. These results suggest that origin-flanking palindromes are essential for termination but not for initiation of DNA replication. Detection of template strand switching in the middle of an inverted repeat strand among the progeny viruses demonstrated that both the minus genome and a corresponding palindromic strand served as templates simultaneously during DNA biosynthesis and supports the recently proposed rolling-circle "melting-pot" replication model. The genome configuration presented by this model, a four-stranded tertiary structure, provides insights into the mechanisms of DNA replication, inverted repeat correction (or conversion), and illegitimate recombination of any circular DNA molecule with an origin-flanking palindrome.     

Instability of long inverted repeats within mouse transgenes.

Various sequences in the mammalian genomes are unstable. One class of sequence arrangement is long inverted repeats, which are known to be unstable in bacteria and yeast. While in mammals some evidence suggests that short inverted repeats (<10 bp long) may show instability, nothing is known about the stability of long inverted repeats. Here we describe two unrelated multicopy transgenes in the mouse (loci 109 and OX1-5), each of which contains a long inverted repeat that shows substantial mitotic instability. This instability also occurs in the germline so that mutant transgenes appear within pedigrees at a high frequency. The mutation processes acting at these two inverted repeats are complex and can involve insertion or deletion, and can result in stabilization of the transgene. At transgene 109 mutational events range from very small rearrangements at the centre of the inverted repeat to complete transgene deletion. In addition we show that the rates of mutation at the inverted repeat of transgene OX1-5 can vary between the male and female germlines and between inbred strains of mice, suggesting the possibility of a genetic analysis to identify loci that modulate inverted repeat instability.     

Inverted repeat sequences in the drosophila genome

The properties of inverted repeat (foldback) sequences in Drosophila melanogaster DNA have been studied by HAP chromatography and electron microscope methods. Electron microscope observations show that there is a broad distribution of lengths of the duplex regions of the inverted repeats from very short to greater than 15 kb, with number and weight average values of 1.35 kb and 5.0 kb respectively. About 20% of the inverted repeats are separated by a single-strand spacer with lengths too short to observe, but the other 80% have spacers, P, with lengths ranging from 0.5 kb to greater than 30 kb. The number average and weight average spacer lengths for the total sample are 2.7 kb and 6.1 kb. With respect to the lengths of the spacers, P, between inverted repeats, the Drosophila genome differs from that of most organisms which have been studied where the spacers P are mostly too short to be measured. EM and HAP studies suggest that the average center-to-center spacing between sets of inverted repeats is 40–80 kb. The HAP studies show that there is a broad range of thermal stabilities for the duplexes formed by reassociation of inverted repeat sequences. Kinetic analysis shows that all of the frequency components of the Drosophila genome are present in the inverted repeats, the loops P, and the flanking sequences. There is a somewhat larger proportion of middle repetitive DNA in those inverted repeat duplexes which are resistant to digestion by Mung Bean Endonuclease I. These enzyme resistant duplexes comprise about 3% of the entire genome. It is estimated that there are approximately 2000–4000 inverted repeat pairs in the entire genome.     

Eucaryotic transposable genetic elements with inverted terminal repeats

DNA carrying inverted repeats was tested for transposition within the Drosophila genome. Five Bam HI segments containing related inverted repeats were isolated from D. melanogaster and analyzed by electron microscopy and restriction mapping. Southern blot experiments using single-copy flanking sequences as probes allowed the study of DNA arrangements at specific sites in the genomes of five closely related strains. We found that in some genomes the sequences with inverted repeats were present at a particular site, whereas in other genomes they were absent from this site. These results indicated that three of the sequences are transposable genetic elements. In one case we have purified the two corresponding DNA segments, with and without the sequence containing inverted repeats, thereby confirming the mobility of this sequence. These DNA elements were found to be distinct in two ways from copia and others previously described: first, they contain inverted terminal repeats, and second, they have a more heterogeneous construction.     

Characterization of a Tc1-like transposable element in zebrafish (Danio rerio)

We have characterized Tdr1, a family of Tc1-like transposable elements found in the genome of zebrafish (Danio rerio). The copy number and distribution of the sequence in the zebrafish genome have been determined, and by these criteria Tdr1 can be classified as a moderately repetitive, interspersed element. Examination of the sequences and structures of several copies of Tdr1 revealed that a particular deletion derivative, 1250 by long, of the transposon has been amplified to become the dominant form of Tdr1. The deletion in these elements encompasses sequences encoding the N-terminal portion of the putative Tdr1 transposase. Sequences corresponding to the deleted region were also detected, and thus allowed prediction of the nucleotide sequence of a hypothetical full-length element. Well conserved segments of Tc1-like transposons were found in the flanking regions of known fish genes, suggesting that these elements have a long evolutionary history in piscine genomes. Tdr1 elements have long, 208 by inverted repeats, with a short DNA motif repeated four times at the termini of the inverted repeats. Although different from that of the prototype C. elegans transposon Tc1, this inverted repeat structure is shared by transposable elements from salmonid fish species and two Drosophila species. We propose that these transposons form a subgroup within the Tc1-like family. Comparison of Tc1-like transposons supports the hypothesis that the transposase genes and their flanking sequences have been shaped by independent evolutionary constraints. Although Tc1-like sequences are present in the genomes of several strains of zebrafish and in salmonid fishes, these sequences are not conserved in the genus Danio, thus raising the possibility that these elements can be exploited for gene tagging and genome mapping.     

Characterization of a Tc1-like transposable element in zebrafish (Danio rerio)

We have characterized Tdr1, a family of Tc1-like transposable elements found in the genome of zebrafish (Danio rerio). The copy number and distribution of the sequence in the zebrafish genome have been determined, and by these criteria Tdr1 can be classified as a moderately repetitive, interspersed element. Examination of the sequences and structures of several copies of Tdr1 revealed that a particular deletion derivative, 1250 by long, of the transposon has been amplified to become the dominant form of Tdr1. The deletion in these elements encompasses sequences encoding the N-terminal portion of the putative Tdr1 transposase. Sequences corresponding to the deleted region were also detected, and thus allowed prediction of the nucleotide sequence of a hypothetical full-length element. Well conserved segments of Tc1-like transposons were found in the flanking regions of known fish genes, suggesting that these elements have a long evolutionary history in piscine genomes. Tdr1 elements have long, 208 by inverted repeats, with a short DNA motif repeated four times at the termini of the inverted repeats. Although different from that of the prototype C. elegans transposon Tc1, this inverted repeat structure is shared by transposable elements from salmonid fish species and two Drosophila species. We propose that these transposons form a subgroup within the Tc1-like family. Comparison of Tc1-like transposons supports the hypothesis that the transposase genes and their flanking sequences have been shaped by independent evolutionary constraints. Although Tc1-like sequences are present in the genomes of several strains of zebrafish and in salmonid fishes, these sequences are not conserved in the genus Danio, thus raising the possibility that these elements can be exploited for gene tagging and genome mapping.     

A small family of elements with long inverted repeats is located near sites of developmentally regulated DNA rearrangement in Tetrahymena thermophila.

Extensive DNA rearrangement occurs during the development of the somatic macronucleus from the germ line micronucleus in ciliated protozoans. The micronuclear junctions and the macronuclear product of a developmentally regulated DNA rearrangement in Tetrahymena thermophila, Tlr1, have been cloned. The intrachromosomal rearrangement joins sequences that are separated by more than 13 kb in the micronucleus with the elimination of moderately repeated micronucleus-specific DNA sequences. There is a long, 825-bp, inverted repeat near the micronuclear junctions. The inverted repeat contains two different 19-bp tandem repeats. The 19-bp repeats are associated with each other and with DNA rearrangements at seven locations in the micronuclear genome. Southern blot analysis is consistent with the occurrence of the 19-bp repeats within pairs of larger repeated sequences. Another family member was isolated. The 19-mers in that clone are also in close proximity to a rearrangement junction. We propose that the 19-mers define a small family of developmentally regulated DNA rearrangements having elements with long inverted repeats near the junction sites. We discuss the possibility that transposable elements evolve by capture of molecular machinery required for essential cellular functions.     

Inverted repeated sequences in yeast nuclear DNA.

The inverted repeated sequences (foldback DNA) of yeast nuclear DNA have been examined by electron microscopy and hydroxyapatite chromatography. Of the inverted repeat structures seen in the electron microscope, 34% were hairpins and 66% had a single stranded loop at the end of a duplex stem. The number average length of the repeat was 0.3 kb and the single stranded loop was 1.6 kb. It is estimated that there are approximately 250 inverted repeats per haploid genome. A statistical analysis of the frequency of molecules containing multiple inverted repeats showed that these sequences are non-randomly distributed. The distribution of inverted repeats was also examined by measuring the fraction of total DNA in the foldback fraction that bound to hydroxyapatite as a function of single strand fragment size. This analysis also indicated that the inverted repeats are clustered. Renaturation kinetic analysis of isolated foldback and inverted repeat stem sequence DNA showed that these sequences are enriched for repetitive DNA.     

Differential distribution of simple sequence repeats in eukaryotic genome sequences.

Complete chromosome/genome sequences available from humans, Drosophila melanogaster, Caenorhabditis elegans, Arabidopsis thaliana, and Saccharomyces cerevisiae were analyzed for the occurrence of mono-, di-, tri-, and tetranucleotide repeats. In all of the genomes studied, dinucleotide repeat stretches tended to be longer than other repeats. Additionally, tetranucleotide repeats in humans and trinucleotide repeats in Drosophila also seemed to be longer. Although the trends for different repeats are similar between different chromosomes within a genome, the density of repeats may vary between different chromosomes of the same species. The abundance or rarity of various di- and trinucleotide repeats in different genomes cannot be explained by nucleotide composition of a sequence or potential of repeated motifs to form alternative DNA structures. This suggests that in addition to nucleotide composition of repeat motifs, characteristic DNA replication/repair/recombination machinery might play an important role in the genesis of repeats. Moreover, analysis of complete genome coding DNA sequences of Drosophila, C. elegans, and yeast indicated that expansions of codon repeats corresponding to small hydrophilic amino acids are tolerated more, while strong selection pressures probably eliminate codon repeats encoding hydrophobic and basic amino acids. The locations and sequences of all of the repeat loci detected in genome sequences and coding DNA sequences are available at http://www.ncl-india.org/ssr and could be useful for further studies.     

Generation of Adenovirus Vectors Devoid of All Viral Genes by Recombination between Inverted Repeats

Direct or inverse repeated sequences are important functional features of prokaryotic and eukaryotic genomes. Considering the unique mechanism, involving single-stranded genomic intermediates, by which adenovirus (Ad) replicates its genome, we investigated whether repetitive homologous sequences inserted into E1-deleted adenoviral vectors would affect replication of viral DNA. In these studies we found that inverted repeats (IRs) inserted into the E1 region could mediate predictable genomic rearrangements, resulting in vector genomes devoid of all viral genes. These genomes (termed DeltaAd.IR) contained only the transgene cassette flanked on both sides by precisely duplicated IRs, Ad packaging signals, and Ad inverted terminal repeat sequences. Generation of DeltaAd.IR genomes could also be achieved by coinfecting two viruses, each providing one inverse homology element. The formation of DeltaAd.IR genomes required Ad DNA replication and appeared to involve recombination between the homologous inverted sequences. The formation of DeltaAd. IR genomes did not depend on the sequence within or adjacent to the inverted repeat elements. The small DeltaAd.IR vector genomes were efficiently packaged into functional Ad particles. All functions for DeltaAd.IR replication and packaging were provided by the full-length genome amplified in the same cell. DeltaAd.IR vectors were produced at a yield of approximately 10(4) particles per cell, which could be separated from virions with full-length genomes based on their lighter buoyant density. DeltaAd.IR vectors infected cultured cells with the same efficiency as first-generation vectors; however, transgene expression was only transient due to the instability of deleted genomes within transduced cells. The finding that IRs present within Ad vector genomes can mediate precise genetic rearrangements has important implications for the development of new vectors for gene therapy approaches.     

Long inverted repeats in eukaryotic genomes: recombinogenic motifs determine genomic plasticity

Inverted repeats are unstable motifs in a genome, having a causal relation to fragment rearrangements and recombination events. We have investigated long inverted repeats (LIR) of > 30 bp in length in eukaryotic genomes to assess their contribution to genome stability. An algorithm was first designed for searching for LIRs with < 2 kb internal spacers and >85% identity (degree of homology between repeat copies of a LIR). There are much fewer LIRs in yeast, fruitfly, pufferfish and chicken than in Caenorhabditis elegans, zebrafish, frog and human. However, the high LIR frequencies do not necessarily imply high genome instability because of variant internal spacers and stem lengths and identities. From the collection of identified LIRs, we selected recombinogenic LIRs that had a short internal spacer and a high copy identity and were prone to induce high instability. We found that a relatively high proportion (5-9.8%) of the LIRs in C. elegans, zebrafish and frog were recombinogenic LIRs. In contrast, the proportions in human and mouse LIRs were quite low (0.4-1.1%) basically accounting for long internal spacers. We suggest that C. elegans, zebrafish and frog genomes are unstable in terms of the LIR frequency and the proportion of recombinogenic LIRs. For the other genomes, LIRs most likely have a minor impact.     

Genesis of Kirsten murine sarcoma virus: sequence analysis reveals recombination points and potential leukaemogenic determinant on parental leukaemia virus genome.

The genome of Kirsten murine sarcoma virus was formed by recombination between Kirsten murine leukaemia virus sequences, and rat sequences derived from a retrovirus-like '30S' (VL30) genetic element encompassing the Kras oncogene. Using cloned DNAs we have determined the nucleotide sequences of the long terminal repeats and adjacent regions, extending across the points of recombination on the sarcoma and leukaemia virus genomes. Our results suggest that discrete regions of homology and other cryptic sequence features, may have constituted recombinational hot-spots involved in the genesis of the Kirsten murine sarcoma virus genome. We have also compared the sequence of the Kirsten murine leukaemia virus p15 env and adjacent long terminal repeat with the corresponding regions of the AKV and Gross A murine leukaemia virus genomes. This comparison has identified a leukaemogenic determinant in the U3 domain of the long terminal repeat, possibly within a enhancer-like sequence element.     

Tnat1 and Tnat2 from Arabidopsis thaliana: novel transposable elements with tandem repeat sequences.

A computer-aided homology search of databases found that the nucleotide sequences flanking ATLN44, a non-LTR retrotransposon (LINE) from Arabidopsis thaliana, are repeated in the A. thaliana genome. These sequences are homologous to flanking sequences of 664 bp with terminal inverted repeat sequences of about 70 bp. The 664-bp sequence and most of the 14 homologues identified were flanked by direct repeat sequences of 9 bp. These findings indicate that the repeated sequence, named Tnat1, is a transposable element that duplicates a 9-bp sequence at the target site on transposition and that ATLN44 is inserted in one Tnat1 member. Interestingly, all of the Tnat1 members had tandem repeats comprised of several units of a 60-bp sequence, the number of repeats differing among Tnat1 members. Of the Tnat1 members identified, one was inserted into another sequence repeated in the A. thaliana genome: that sequence is about 770 bp long and has terminal inverted repeat sequences of about 110 bp. The sequence is flanked by direct repeats of a 9-bp sequence, indicating that it is another transposable element, named Tnat2, from A. thaliana. Moreover, Tnat2 members had a tandem repeat about 240 bp long. Tnat1 and Tnat2 with tandem repeats in their internal regions show no homology to each other or to any of the elements identified previously; therefore they appear to be novel transposable elements.     

A comparative analysis of the Lactuca and Helianthus (Asteraceae) plastid genomes: identification of divergent regions and categorization of shared repeats

We have sequenced two complete chloroplast genomes in the Asteraceae, Helianthus annuus (sunflower), and Lactuca sativa (lettuce), which belong to the distantly related subfamilies, Asteroideae and Cichorioideae, respectively. The Helianthus chloroplast genome is 151?104 bp and the Lactuca genome is 152?772 bp long, which is within the usual size range for chloroplast genomes in flowering plants. When compared to tobacco, both genomes have two inversions: a large 22.8-kb inversion and a smaller 3.3-kb inversion nested within it. Pairwise sequence divergence across all genes, introns, and spacers in Helianthus and Lactuca has resulted in the discovery of new, fast-evolving DNA sequences for use in species-level phylogenetics, such as the trnY-rpoB, trnL-rpl32, and ndhC-trnV spacers. Analysis and categorization of shared repeats resulted in seven classes useful for future repeat studies: double tandem repeats, three or more tandem repeats, direct repeats dispersed in the genome, repeats found in reverse complement orientation, hairpin loops, runs of A's or T's in excess of 12 bp, and gene or tRNA similarity. Results from BLAST searches of our genomic sequence against expressed sequence tag (EST) databases for both genomes produced eight likely RNA edited sites (C → U changes). These detailed analyses in Asteraceae contribute to a broader understanding of plastid evolution across flowering plants.     

Long perfect dinucleotide repeats are typical of vertebrates, show motif preferences and size convergence

Microsatellites are simple sequence repeats (SSRs) showing complex patterns of length, motif sizes, motif sequences, and repeat perfection. We studied the structure of the dinucleotide SSR population at the genome level by analyzing assembled DNA sequence across species. Three dinucleotide populations were distinguished when SSR genome frequency was analyzed as a function of repeat length and repeat perfection. A population of low-perfection SSRs was identified, which is constituted by short repeats and represents the vast majority of genomic dinucleotide SSRs across eukaryotic genomes. In turn, the highly perfect repeats are 30 to 50 times less frequent and, in addition to short repeats, also contain a long repeat population that is uniquely represented in vertebrate species. Distinctive features of this population include the modal peak in the frequency distribution of repeat length and the strong preferential usage of the repeat motifs AC and AG. These results raise the hypothesis that the ability of carrying a distinct population of long, highly perfect dinucleotide repeats in the genome is a late acquisition in chordate evolution. Our analysis also suggests that different dinucleotide repeat populations have different dynamics and are likely to be underlined by different molecular mechanisms of generation and maintenance in the genome. Thus, these observations imply that caution should be taken in extrapolating results from studies on SSR mutability and on SSR phylogenetic comparisons that do not take into account the stratification of dinucelotide populations in the eukaryotic genome.     

Machinery to support genome segment inversion exists in a herpesvirus which does not naturally contain invertible elements

In many herpesviruses, genome segments flanked by inverted repeats invert during DNA replication. It is not known whether this inversion is a consequence of an inherently recombinagenic replicative mechanism common to all herpesviruses or whether the replication enzymes of viruses with invertible segments have specifically evolved additional enzymatic activities to drive inversion. By artificially inserting a fusion of terminal sequences into the genome of a virus which normally lacks invertible elements (murine cytomegalovirus), we created a genome composed of long and short segments flanked by 1,359- and 543-bp inverted repeats. Analysis of genomic DNA from this virus revealed that inversion of both segments generates equimolar amounts of four isomers during the viral propagation necessary to produce DNA for analysis from a single viral particle. We conclude that a herpesvirus which naturally lacks invertible elements is able to support efficient segment inversion. Thus, the potential to invert is probably inherent in the replication machinery of all herpesviruses, irrespective of genome structure, and therefore genomes with invertible elements could have evolved simply by acquisition of inverted repeats and without concomitant evolution of enzymatic activities to mediate inversion. Furthermore, the recombinagenicity of herpesvirus DNA replication must have some importance independent of genome segment inversion.