The Chinese hamster Alu-equivalent sequence: a conserved highly repetitious, interspersed deoxyribonucleic acid sequence in mammals has a structure suggestive of a transposable element.

A consensus sequence has been determined for a major interspersed deoxyribonucleic acid repeat in the genome of Chinese hamster ovary cells (CHO cells). This sequence is extensively homologous to (i) the human Alu sequence (P. L. Deininger et al., J. Mol. Biol., in press), (ii) the mouse B1 interspersed repetitious sequence (Krayev et al., Nucleic Acids Res. 8:1201-1215, 1980) (iii) an interspersed repetitious sequence from African green monkey deoxyribonucleic acid (Dhruva et al., Proc. Natl. Acad. Sci. U.S.A. 77:4514-4518, 1980) and (iv) the CHO and mouse 4.5S ribonucleic acid (this report; F. Harada and N. Kato, Nucleic Acids Res. 8:1273-1285, 1980). Because the CHO consensus sequence shows significant homology to the human Alu sequence it is termed the CHO Alu-equivalent sequence. A conserved structure surrounding CHO Alu-equivalent family members can be recognized. It is similar to that surrounding the human Alu and the mouse B1 sequences, and is represented as follows: direct repeat-CHO-Alu-A-rich sequence-direct repeat. A composite interspersed repetitious sequence has been identified. Its structure is represented as follows: direct repeat-residue 47 to 107 of CHO-Alu-non-Alu repetitious sequence-A-rich sequence-direct repeat. Because the Alu flanking sequences resemble those that flank known transposable elements, we think it likely that the Alu sequence dispersed throughout the mammalian genome by transposition.     

The Ds1 controlling element family in maize andTripsacum

Summary Hybridization experiments indicated that the maize genome contains a family of sequences closely related to the Ds1 element originally characterized from theAdh1-Fm335 allele of maize. Examples of these Ds1-related segments were cloned and sequenced. They also had the structural properties of mobile genetic elements, i.e., similar length and internal sequence homology with Ds1, 10- or 11-bp terminal inverted repeats, and characteristic duplications of flanking genomic DNA. All sequences with 11-bp terminal inverted repeats were flanked by 8-bp duplications, but the duplication flanking one sequence with 10-bp inverted repeats was only 6 bp. Similar Ds1-related sequences were cloned fromTripsacum dactyloides. They showed no more divergence from the maize sequences than the individual maize sequences showed when compared with each other. No consensus sequence was evident for the sites at which these sequences had inserted in genomic DNA.     

Interruption of a human nuclear sequence homologous to mitochondrial DNA by a member of the KpnI 1.8 kb family.

We reported that several DNA sequences homologous to mitochondrial DNA (mtDNA) are present in the human nuclear genome (Tsuzuki et al. (1983) Gene 25, 223-229). Detailed Southern blot analyses revealed that one of such sequences is interrupted by a repetitive sequence about 1.8 kb long, and that the insert is one member of the dispersed repeated DNA sequences of the KpnI 1.8 kb family. Nucleotide sequence analysis showed that the KpnI 1.8 kb DNA is flanked with imperfect 15-base pair (bp) direct repeats of mtDNA. This KpnI 1.8 kb DNA has an A-rich sequence at its 3'-end, and has a considerable homology with one of the published cDNA sequences homologous to one of the human KpnI families and also to one of the African green monkey KpnI families, KpnI-LS1. These structural features suggest that the KpnI 1.8 kb DNA is a movable element and is inserted within the mtDNA-like sequence by an RNA-mediated process.     

Fragments of LINE-1 retrotransposons flanked by inverted telomeric repeats are present in the bovine genome. Homology with human LINE-1 elements

In the bovine genome we found two intrachromosomal DNA fragments flanked by inverted telomeric repeats (GenBank Accession Nos. AF136741 and AF136742). The internal parts of the fragments are homologous exclusively to the human sequences and to the consensus sequence of the L1MC4 subfamily of LINE-1 retrotransposons which are widespread among mammalian genomes. We found that distribution of homologous human sequences within our fragments is not random, reflecting a complicated pattern of insertion mechanisms of and maintenance of retrotransposons in mammalian genomes. One of the possible explanations of the origin of LINE-1 truncated elements flanked by inverted telomeric repeats in the bovine genome is that extrachromosomal DNA fragments may be modified by telomerase and subsequently, transferred into chromosomal DNA.     

Structural heterogeneity in the R173 family of rye-specific repetitive DNA sequences

The rye-specific R173 family of repeated DNA sequences consists of ca. 15 000 individual copies per diploid rye (Secale cereale) genome and is distributed over all 7 rye chromosomes in a dispersed manner. Individual R173 elements vary in size between 3 and 6 kb, are generally not arranged as tandem repeats and are flanked by both multi-copy and single-copy sequences. DNA sequence analysis of three R173 elements (R173-1, R173-2 and R173-3) demonstrated a high degree of homology in conserved domains. The structure of R173-1 was quite different from the other two elements: long direct repeats, which represent a rye-specific repetitive sequence, were found at the ends and a 600 bp long domain was replaced by an unrelated sequence of approximately equal size. R173-2 and R173-3 were extremely similar to each other with the exception of a terminal truncation of R173-2. No open reading frames for proteins >20 kDa were present and a database search failed to detect significant homologies to published protein sequences. Despite the transposon like genomic organisation of the R173 family, individual elements lacked sequence features frequently associated with transposons and retrotransposons. In contrast, two of the regions flanking R173 elements showed strong DNA homologies to a 850 bp long region of a proposed wheat retrotransposon and to a 300 bp long region downstream of the wheatGlu-D1 gene.     

A novel family of mobile genetic elements is limited to the germline genome in Tetrahymena thermophila

In the ciliated protozoan Tetrahymena thermophila, extensive DNA elimination is associated with differentiation of the somatic macronucleus from the germline micronucleus. This study describes the isolation and complete characterization of Tlr elements, a family of approximately 30 micronuclear DNA sequences that are efficiently eliminated from the developing macronucleus. The data indicate that Tlr elements are comprised of an ~22 kb internal region flanked by complex and variable termini. The Tlr internal region is highly conserved among family members and contains 15 open reading frames, some of which resemble genes encoded by transposons and viruses. The Tlr termini appear to be long inverted repeats consisting of (i) a variable region containing multiple direct repeats which differ in number and sequence from element to element and (ii) a conserved terminal 47 bp sequence. Taken together, these results suggest that Tlr elements comprise a novel family of mobile genetic elements that are confined to the Tetrahymena germline genome. Possible mechanisms of developmentally programmed Tlr elimination are discussed.     

Sequence variation in dispersed repetitive sequences in Saccharomyces cerevisiae

Two new dispersed repetitive DNA sequences related to the transposable element Tyl have been isolated from the genome of Saccharomyces cerevisiae. One sequence, designated Tyl-17, is present at about six copies per haploid genome, and one copy is located approximately 1000 base-pairs from the LEU2 locus on chromosome III. Tyl-17 is about the same size as Tyl (Cameron et al., 1979) and is flanked by δ sequences, but differs from Tyl by the presence of two large substitutions representing about 50% of the sequence. Tyl and Tyl-17 are found in a ‘head-to-head’ array in at least one cloned region of the yeast genome. Another sequence, designated Tyl-161, is situated about 9000 base-pairs from the PGK locus of chromosome III, and is structurally identical to Tyl except for the presence of a 1200 base-pair insertion near one end of the sequence element.     

A new family of widely propagated MB1-repeats in the human genome

A new family of repeats--i.e. MB1 repeats family--the number of copies of which per a human genome constitutes a few hundreds of thousands of copies has been revealed in a human gemone by computer analysis of a noncanonical similarity of nucleic acid sequences. The numbers of that family of repeats have also been revealed in the genomes of mouse and rat, they have been identified as mirror--reflected copies--in purines and pyrimidines--of B1 repeats in the genome of mouse and the Alu repeats in the human genome. The MB1 repeats tend to remain most similar at a length of 70 b.p. They are not flanked by short repeats, neither contain poly(A) region at the 3' end, by which they differ from the repeats of the SINE family. It has been assumed that the member of the Alu repeats family and the MB1 repeats family can form a so called H-form of DNA. The mirror-reflected repeat family could have been formed by replication of parallel DNA strands.     

G-repeats: a novel hamster sine family.

A fragment of a hamster repetitive element inserted into the aprt locus of a radiation-induced mutant is a member of a novel interspersed repetitive (SINE) family constituting approximately 0.3 to 0.5% of the hamster genome (30 to 50,000 family members). Since this family was first detected in a gene rearranged after exposure to gamma irradiation, we have called these G-repeats. In common with other repetitive elements, members of this family are about 300 bp in length, are highly divergent (an average of 30% from the consensus), have an A + T rich sequence flanking one side, and can be found in short polydisperse circular (SPC) DNA. In contrast to some other families, G-repeats are not flanked by short direct repeats and lack sequences corresponding to the RNA polymerase III consensus promoter.     

Isolation of a D-genome specific repeated DNA sequence fromAegilops squarrosa

Three repeated sequence clones, pAS1(1.0 Kb), pAS2(1.8 Kb) and pAS12(2.5 Kb), were isolated fromAegilops squarrosa (Triticum tauschii). The inserts of the three clones did not hybridize to each other. Two of the clones, pAS2 and pAS12, contain repeated sequences which were distributed throughout the genome. The clone pAS1 sequence was more restricted and was located in specific areas on telomeres and certain interstitial sites along the chromosome length. This cloned sequence was also found to be restricted to the D genome at the level ofin situ hybridization. The pAS1 sequence will be useful in chromosomal identification and phylogenetic analysis. All three clones will allow assessment of genome plasticity inAegilops squarrosa. Nuclear DNA content varies over a range of 10,000 fold among all organisms (Nagl et al., 1983). Among angiosperms, at least a 65-fold range in genome size occurs in diploid species (Sparrow, Price and Underbrink, 1972; Bennett, Smith and Heslop-Harrison, 1982). This DNA variation has been reported within families, genera, and species (Rothfels et al., 1966; Rees and Jones, 1967; Miksche, 1968; Price, Chambers and Bachmann, 1981). Much of the interspecific variation in genome size among angiosperms appears to be due to amplification and/or deletion of DNA within chromosomes. The variation in genome size does not appear to result in changes in the number of coding genes (Nagl et al., 1983). While the number of coding genes, with the exception of rDNA in specific examples, appears to remain constant, the remaining non-coding regions are quite flexible. This non-coding DNA encompasses over 99% of the plant genome and consists of sequences that exist as multiple copies throughout the genome and are identified as repeated DNA sequences (Flavell et al., 1974). Flavell et al. (1974) have reported that increasing genome size in higher plants is associated with increasing repetitive DNA amounts. Subsequent reports have substantiated this correlation (Bachmann and Price, 1977; Narayan, 1982). In various cereals, heterochromatin, which has been demonstrated to be correlated with the location of specific repeated DNA sequences, has been positively correlated with genome size (Bennett, Gustafson and Smith, 1977; Rayburn et al., 1985). Furuta, Nishikawa and Makino (1975) found significant DNA content variation among different accessions ofAegilops squarrosa L. This species contains the D genome, a pivotal genome in several polyploid species and also found in hexaploid wheat (AABBDD). The importance of this genome to the study of bread wheat genomes makes the mechanism(s) of this genomic plasticity of particular interest. In order to determine which sequences are varying, one must first have a way to identify specific types of chromatin and/or DNA. Specific types of chromosome banding such as C- and N-banding have been used to identity types of chromatin in previous studies. C-banding of the D genome results in very lightly staining bands whose pattern is somewhat indistinct. N-banding alternatively has been shown to be useful in identifying certain chromosomes of hexaploid wheat but is limited by the lack of major bands in the D genome (Endo and Gill, 1984). Specific DNA sequences have been isolated fromTriticum aestivum cultivar “Chinese Spring” (hexaploid wheat). However, these sequences are representatives of the A and/or B genomes of hexaploid wheat and are not found in significant quantities in the D genome (Hutchinson and Lonsdale, 1982). Various other repeated DNA sequences have been successfully isolated from rye (Bedbrook et al., 1980) and identified on rye chromosomes (Appels et al., 1981; Jones and Flavell, 1982). Certain of these sequences are found in wheat genomes, but the sequences are representative of only a minor fraction of the D genome (Bedbrook et al., 1980; Rayburn and Gill, 1985). The purpose of this report is to describe three distinct repeated DNA sequences isolated fromA. squarrosa (D genome). Two clones appear to be distributed throughout the total genome, and the third clone is restricted to specific sites along the chromosomes. This latter clone will prove useful in cytologically defining the D genome chromosomes. These sequences appear representative of two types of repeated DNA genome organization: 1) sequences distributed throughout the genome and 2) specific arrays of repeated sequences. The availability of such repeated DNA sequence clones along with the known intraspecific DNA content variation inA. squarrosa will allow the study of genomic plasticity of this species.     

Human transposon-like elements insert at a preferred target site: evidence for a retrovirally mediated process.

Members of the human transposon-like family of repetitive sequences (called THE 1 repeats) like many other repetitive DNA sequences are flanked by short direct repeats. Comparison of the base sequences of twelve examples of these flanking direct repeats indicates that THE 1 repeats insert into a preferred genomic target site. In one case, we have identified the sequence of an empty site into which a THE 1 element inserted. The sequence of this empty site and sequences of truncated THE 1 LTRs are consistent with a retroviral mechanism for the insertion of THE 1 elements. Truncated transposon structures illustrate for the first time that intermediate structures of retrotransposition may also be integrated into the genome.