Subrepeats result from regional DNA sequence conservation in tandem repeats in Chironomus telomeres

Repeat units, widespread in eukaryotic genomes, are often partially or entirely built up of subrepeats. Homogenization between whole repeat units arranged in tandem usually can best be understood as a result of unequal crossing over. Such a mechanism is less plausible for maintaining similarities between subrepeats within a repeat unit when present in a regular array. In Chironomus telomeres, large blocks of tandemly repeated approximately 350 base-pair units contain two or three pairs of subrepeats with high mutual identities, embedded in linker DNA, non-repetitive within the repeat unit. Measurements of evolutionary base changes in two closely related species, Chironomus tentans and Chironomus pallidivittatus, permit us to conclude that the subrepeat arrangement is best explained as a consequence of regional sequence conservation after an earlier duplication of an ancestral half-unit.     

The structure of Marek's disease virus DNA: amplification of repeat sequence in IRs and TRs

The structure of Marek's disease virus (MDV) DNA was investigated by using Southern blot hybridization analysis. A heterogeneous region was observed in the inverted repeats region, IRs and TRs, as well as in the TRL and IRL. The results of DNA sequencing of the heterogeneous region showed that the heterogeneity of IRS and TRS was due to amplification of a 178-bp repeat sequence. Amplification of IRS and TRS was found in viral DNA from both pathogenic and nonpathogenic strains. The structure of DNA from the latent MDV genome present in established lymphoblastic cells was also determined. Amplification of the 132-bp repeat sequence in IRL and TRL was not found in latent MDV DNA of established lymphoblastic cells, whereas amplification of the 178-bp repeat sequence in IRS and TRS was found in the same DNA.     

Structure of the 5S rRNA genes in birch (Betula papyrifera) and alder (Alnus incana).

Hybridization of a 5S rDNA probe to Southern transfers of birch (Betula papyrifera) or alder (Alnus incana) DNA digested with BamH1 reveals similar triple-band "ladder-like" patterns. The sizes of sequenced 5S repeat units from both plants ranges only from 471 to 490 base pairs, suggesting that the complexity detected by Southern analysis is not due to different size classes of 5S repeats as found in other species. Within the intercistronic spacer region, conservation of large blocks of sequence between birch and alder 5S is observed implying a close evolutionary relationship between these two species. In both species, a duplication of part of the coding sequence including a restriction site for BamH1 introduces a second BamH1 site into the repeat unit. Differential methylation of the two BamHI restriction sites can account for the observed triple-band pattern.     

The mitochondrial genomes of spontaneous orir petite mutants of yeast have rearranged repeat units organized as inverted tandem dimers

We have investigated the structure and organization of the mitochondrial genomes of two related orir (ori-rearranged) spontaneous petite mutants of Saccharomyces cerevisiae. In these mutant genomes every repeat unit contains an inverted terminal duplication harboring a second (inverted) ori sequence, and tandem pairs of repeat units alternate with tandem pairs in inverted orientation. We have shown that orir genomes are organized as the genomes with inverted repeat units of ethidium bromide (EtBr)-induced petites, and we have clarified the mechanism by which such mutant mitochondrial genomes arise.     

Amplification of a short nucleotide sequence in the repeat units of defective herpes simplex virus type 1 Angelotti DNA

It has been shown earlier that the reiterated regions TRS and IRS bracketing the Us segment of herpes simplex virus type 1 Angelotti DNA are heterogeneous in size by stepwise insertion of one to six copies of a 550-base-pair nucleotide sequence. Considerably higher amplification of this sequence was observed in defective viral DNA: up to 14 copies were detected to be inserted in the repeat units of a major class of defective herpes simplex virus type 1 Angelotti DNA, dDNA1, which originated from noncontiguous sites located in UL and the inverted repeats of the S component of the parental genome. Physical maps were established for the cleavage sites of KpnI, PstI, XhoI, and BamHI restriction endonucleases on the repeats of dDNA1. The map position of the insertion sequence was determined. It was demonstrated that the amplified inserts were not distributed at random among or within the repeats. A given total population of dDNA1 molecules consisted of different homopolymers, each of which contained a constant number of inserts in all of its repeats. Assuming that a rolling-circle mechanism is involved in the generation of full-length defective herpes simplex virus type 1 Angelotti DNA from single repeat units, these data suggest that the 550-base-pair sequence is amplified in the repeats before the replication process.     

Isolated clusters of paired tandemly repeated sequences in the Xenopus laevis genome.

There exist in the Xenopus laevis genome clusters of tandemly repeated DNA sequences, consisting of two types of 393-base-pair repeating unit. Each such cluster contains several units of one of these paired tandem repeats (PTR-1), followed by several units of the other repeat (PTR-2). The number of repeats of each type is variable from cluster to cluster and averages about seven of each type per cluster. Every cluster has ca. 1,000 base pairs of common left flanking sequence (adjacent to the PTR-1 repeats) and 1,000 base pairs of common right flanking sequence (adjacent to the PTR-2 repeats). Beyond these common flanks, the DNA sequences are different in the eight cloned genomic fragments we have studied. Thus, the hundreds of PTR clusters in the genome are dispersed at apparently unrelated sites. Nucleotide sequences of representative PTR-1 and PTR-2 repeats are 64% homologous. These sequences do not reveal an obvious function. However, the related species X. mulleri and X. borealis have sequences homologous to PTR-1 and PTR-2, which show the same repeat lengths and genomic organization. This evolutionary conservation suggests positive selection for the clusters. Maintenance of these sequences at dispersed sites imposes constraints on possible mechanisms of concerted evolution.     

The myotonic dystrophy type 1 triplet repeat sequence induces gross deletions and inversions

The capacity of (CTG.CAG)n and (GAA.TTC)n repeat tracts in plasmids to induce mutations in DNA flanking regions was evaluated in Escherichia coli. Long repeats of these sequences are involved in the etiology of myotonic dystrophy type 1 and Friedreich's ataxia, respectively. Long (CTG.CAG)n (where n = 98 and 175) caused the deletion of most, or all, of the repeats and the flanking GFP gene. Deletions of 0.6-1.8 kbp were found as well as inversions. Shorter repeat tracts (where n = 0 or 17) were essentially inert, as observed for the (GAA.TTC)176-containing plasmid. The orientation of the triplet repeat sequence (TRS) relative to the unidirectional origin of replication had a pronounced effect, signaling the participation of replication and/or repair systems. Also, when the TRS was transcribed, the level of deletions was greatly elevated. Under certain conditions, 30-50% of the products contained gross deletions. DNA sequence analyses of the breakpoint junctions in 47 deletions revealed the presence of 1-8-bp direct or inverted homologies in all cases. Also, the presence of non-B folded conformations (i.e. slipped structures, cruciforms, or triplexes) at or near the breakpoints was predicted in all cases. This genetic behavior, which was previously unrecognized for a TRS, may provide the basis for a new type of instability of the myotonic dystrophy protein kinase (DMPK) gene in patients with a full mutation.     

Long terminal repeat of murine retroviral DNAs: sequence analysis, host-proviral junctions, and preintegration site.

The nucleotide sequence of the long terminal repeat (LTR) of three murine retroviral DNAs has been determined. The data indicate that the U5 region (sequences originating from the 5' end of the genome) of various LTRs is more conserved than the U3 region (sequences from the 3' end of the genome). The location and sequence of the control elements such as the 5' cap, "TATA-like" sequences, "CCAAT-box," and presumptive polyadenylic acid addition signal AATAAA in the various LTRs are nearly identical. Some murine retroviral DNAs contain a duplication of sequences within the LTR ranging in size from 58 to 100 base pairs. A variant of molecularly cloned Moloney murine sarcoma virus DNA in which one of the two LTRs integrated into the viral DNA was also analyzed. A 4-base-pair duplication was generated at the site of integration of LTR in the viral DNA. The host-viral junction of two molecularly cloned AKR-murine leukemia virus DNAs (clones 623 and 614) was determined. In the case of AKR-623 DNA, a 3- or 4-base-pair direct repeat of cellular sequences flanking the viral DNA was observed. However, AKR-614 DNA contained a 5-base-pair repeat of cellular sequences. The nucleotide sequence of the preintegration site of AKR-623 DNA revealed that the cellular sequences duplicated during integration are present only once. Finally, a striking homology between the sequences flanking the preintegration site and viral LTRs was observed.     

Comparative structure and evolution of goat and sheep satellite I DNAs.

The satellite I DNAs of domestic goat (Capra hircus) and domestic sheep (Ovis aries) have been studied using molecular hybridisation and restriction enzyme analysis. Both satellite DNAs are composed of repeat units of 820 base pairs in length, but their restriction maps, although similar, differ in certain respects. Thus the majority of sheep satellite I repeat units have two EcoRI sites and one AluI site, whereas the majority of goat satellite I repeat units have one EcoRI site and two AluI sites. The sheep satellite I repeat units with the two EcoRI sites are much more homogeneous than the repeats forming the remainder of the satellite, as judged by the difference in the melting temperatures of native and reassociated molecules. DNAs from species of wild sheep and goats were screened for the presence of these repeat units, and they appear to have been amplified during the radiation of the Ovis genus. Goat satellite I is composed of a single sequence type which has changed through base substitution until the sequence now shows considerable heterogeneity. It is proposed that the major sequence types of these two satellite DNAs were amplified by different saltatory replication events at different times in the evolution of the group.     

Structure of simian virus 40 recombinants that contain both host and viral DNA sequences. I. The structure of variant CVPS/1/P2 (EcoRI res).

The entire nucleotide sequence (1210-base-pair repeating units) of a defective variant of simian virus 40 is presented. Within this variant there are deletions of large portions of the wild type genome and an inversion within the remaining wild type viral sequences. In addition, the defective variant contains DNA sequences derived from the permissive monkey cells in which the virus was propagated. The monkey sequences include a portion that is homologous to sequences within highly repeated monkey DNA (alpha component) as well as portions derived from sequences that are infrequently repeated in the monkey genome. One out of every three to four of the tandem 1210-base-pair repeat units contains in addition, a duplication of a part of the monkey sequences. The sequence information defines the structures of a number of recombinational joints which result from deletions, inversions, duplications, and insertions of host sequences into the viral genome. The data demonstrate that the various recombinational events that resulted in the formation of this defective variant did not depend on extensive homology between recombining segments.     

Isolation of novel herpes simplex virus type 1 derivatives with tandem duplications of DNA sequences encoding immediate-early mRNA-5 and an origin of replication.

Two naturally occurring variations of herpes simplex virus type 1 (Patton strain) with novel tandem DNA sequence duplications in the S component were isolated, and the DNA was characterized. These variants were identified among a number of plaque isolates by the appearance of new restriction enzyme fragments that hybridized with radiolabeled DNA from the BamHI Z fragment (map coordinates 0.936 to 0.949) located in the unique S region. One isolate, SP26-3, carried a 3.1-kilobase-pair duplication defined by recombination between a site in the BamHI Z fragment and a site near the origin of replication in the inverted repeat sequence of the S component carried by the EcoRI H fragment. The other isolate, SP22-4, carried a 3.5-kilobase-pair duplication defined by a recombination event between a tandem repeat array in the BamHI Z fragment and a site near the amino terminus of the Vmw175 gene in the S-region inverted repeat sequence contained in the EcoRI K fragment. Both duplicated segments contained the entire immediate early mRNA-5 coding region as well as the origin of replication located in the inverted repeat sequence of the S component. The DNA sequence of each duplication joint was determined.     

Novel insertion mutation in Caenorhabditis elegans.

The mutation e1662 is an allele of the Caenorhabditis elegans unc-54 gene induced with the difunctional alkylating agent 1,2,7,8-diepoxyoctane. unc-54 encodes the major myosin heavy chain isozyme of body wall muscle cells. Filter-transfer hybridization and DNA sequence analysis show that e1662 is an insertion of 288 base pairs of DNA within unc-54. The inserted DNA is identical to a 288-base pair region of unc-54 located ca. 600 base pairs from the insertion site. Thus, e1662 is a displaced duplication. A 14-base pair sequence located at one end of the duplicated segment is found adjacent to the site of insertion. These homologous sequences are juxtaposed head-to-tail by the insertion event. e1662 thus contains a tandem direct repeat extending across one of its junctions.     

Twelve 43-base-pair repeats map in a cis-acting region essential for partition of plasmid mini-F.

The nucleotide sequence of the DNA region involved in partitioning of plasmid mini-F has been determined. The sequence consists of 12 direct tandemly arranged repeats of 43 base pairs (the two flanking repeats, 43 plus 1 base pairs) with extensive homology to each other. Each repeat contains an additional inverted repeat of 7 base pairs.     

Repetitive satellite-like sequences are present within or upstream from 3 avian protein-coding genes.

Peculiar DNA sequences made up by the tandem repetition of a 5 bp unit have been identified within or upstream from three avian protein-coding genes. One sequence is located within an intron of the chicken "ovalbumin-X" gene with 5'-TCTCC-3' as basic repeat unit (36 repeats). Another sequence made of 27 repeats of a 5'-GGAAG-3' basic unit is found 2500 base pairs upstream from the promoter of the chicken ovotransferrin (conalbumin) gene. A related but different sequence is present in the corresponding region of the ovotransferrin gene in the pheasant, with 5'-GGAAA-3' as the basic unit (55 repeats). These three satellite-like elements are thus characterized by a total assymetry in base distribution, with purines restricted to one strand, and pyrimidines to the other. Two of the basic repeat units can be derived from the third one (GGAAA) by a single base pair change. These related sequences are found repeated in three avian genomes, at degrees which vary both with the sequence type and the genome type. Evolution of tandemly repeated sequences (including satellites) is in general studied by analysing randomly picked elements. The presence of conserved protein-coding regions neighbouring satellite-like sequences allow to follow their evolution at a single locus, as exemplified by the striking comparison of the pheasant and chicken sequences upstream from the ovotransferrin gene.     

The determination of the sequences present in the shadow bands of a dinucleotide repeat PCR.

A Polymerase Chain Reaction (PCR) of a DNA sequence containing a CA repeat produces a main band but also several shadow bands that differ by 2 base pairs below the main band. In the experiments described in this paper, these shadow bands were excised from a DNA sequencing gel and directly sequenced. It was found that the sequence in the CA repeat was ambiguous. However, the sequence 5' and 3' to the CA repeat was clear and unambiguous. It is proposed that the shadow bands are generated by 2 base pair random deletions in the CA repeat region. During this process the sequence becomes 'scrambled' only in the CA repeat region. The shadow bands were shown to occur during the PCR since the genomic DNA template did not contain the shadow bands. It is probable that the shadow bands arise by slippage during the PCR. It is predicted that a thermostable DNA polymerase with a high processivity would greatly reduce the occurrence of shadow bands.     

Sequences with the Potential to Form Stem-and-Loop Structures Are Associated with Coding-Region Duplications in Animal Mitochondrial DNA

Tandem duplications of gene-encoding regions occur in the mitochondrial DNA (mt DNA) of some individuals belonging to several species of whiptail lizards (genus Cnemidophorus). All or part of the duplicated regions of the mtDNAs from five different species were sequenced. In all, the duplication endpoints were within or immediately adjacent to sequences in tRNA, rRNA or protein genes that are capable of forming energetically stable stem-and-loop structures. In two of these mtDNAs, the duplication endpoints were also associated with a direct sequence repeat of 13 bp. The consistent association of stem-and-loop structures with duplication endpoints suggests that these structures may play a role in the duplication process. These data, combined with the absence of direct or palindromic repeats at three of the pairs of duplication endpoints, also suggest the existence of a mechanism for generating de novo duplications that is qualitatively different from those previously modeled.     

Genome organization of herpesvirus aotus type 2.

Herpesvirus aotus type 2, a virus commonly found in owl monkeys without overt disease, has a similar genome structure to the oncogenic herpesviruses of nonhuman primates (herpesvirus saimiri, herpesvirus ateles). Virion DNA of herpesvirus aotus type 2 (M-DNA) has an unique 110-kilobase-pair region of low G + C content (40.2%, L-DNA), inserted between stretches of repetitive H-DNA (68.7% G + C, about 41 kilobase pairs per molecule) that are variable in length. A minority of virions contain defective genomes that consist of repetitive H-DNA only. The H-DNA is composed of various types of repeat units that are related in sequence with each other. The two dominant types of repeats (2.3 and 2.7 kilobase pairs) were cloned and compared by restriction enzyme cleavages and partial nucleotide sequencing. They are homologous in at least 1.3 kilobase pairs. The two forms of repeat units are randomly arranged and oriented in tandem. Reassociation kinetics did not allow detection of sequence homologies between H- and L-DNA of herpesvirus aotus type 2 and the respective sequences of oncogenic primate herpesviruses.