Highly repeated sequences in mammalian genomes

Satellite DNA from Xenopus laevis: comparative analysis of 745 and 1037 base pair Hind III tandem repeats

Highly repetitive Hind III restriction fragments of 0.72-0.76 KBP from total Xenopus laevis genomic DNA are organized in a tandem like arrangement. Cloning of these fragments in pBR 322 with subsequent restriction site mapping and nucleotide sequence analysis of some selected clones showed two different types of sequences. 25-30% of material represent the oocyte specific 5 S DNA repeat units, 70-75% are similar to the recently described repeat elements of satellite 1 DNA. Hybridization of a genomic DNA library to such a 745 BP monomeric repeat unit and investigation of some clones with positive autoradiographic signals revealed structural heterogeneities of repeat elements, in that the 745 BP sequence cross-hybridized with 1037 BP Hind III repeat units. Nucleotide sequence analysis demonstrated that the two types of sequences show a homology of 84.3% and that the 1037 BP sequence additionally contains duplicated elements of the 745 BP sequence as well as apparently unrelated DNA sequences.

Construction of a small Mus musculus repetitive DNA library: identification of a new satellite sequence in Mus musculus

We report the construction of a small library of recombinant plasmids containing Mus musculus repetitive DNA inserts. The repetitive cloned fraction was derived from denatured genomic DNA by reassociation to a Cot value at which repetitive, but not unique, sequences have reannealed followed by exhaustive S1 nuclease treatment to degrade single stranded DNA. Initial characterizations of this library by colony filter hybridizations have led to the identification of a previously undetected M. musculus minor satellite as well as to clones containing M. musculus major satellite sequences. This new satellite is repeated 10-20 times less than the major satellite in the M. musculus genome. It has a repeat length of 130 nucleotides compared with the M. musculus major satellite with a repeat length of 234 nucleotides. Sequence analysis of the minor satellite has shown that it has a 29 base pair region with extensive homology to one of the major satellite repeating subunits. We also show by in situ hybridization that this minor satellite sequence is located at the centromeres and possibly the arms of at least half the M musculus chromosomes. Sequences related to the minor satellite have been found in the DNA of a related Mus species, Mus spretus, and may represent the major satellite of that species.

Simple DNA sequences and dispersed repetitive elements in the vicinity of mouse immunoglobulin K light chain genes

The simple DNA sequences (T-G)20, (T-T-T-G-C)20 and (G-C-C-T-C-T)30 were found in the vicinity of mouse immunoglobulin genes and of dispersed repetitive elements as the R, B1 and B2 sequences. On the basis of sequence data, blot hybridizations with salmon and mouse DNA and with defined mouse DNA fragments, possible functional and evolutionary aspects of simple DNA sequences are discussed.

Organization of the R family and other interspersed repetitive DNA sequences in the mouse genome

Six R sequences have been described as members of a new family of dispersed repetitive DNA in the mouse genome (Gebhard et al., 1982). Several sequenced regions were extended in the 5' direction (R1, R2 and R6) and two new sequences were determined (R7 and R8). On the basis of our sequence and blot hybridization data it is concluded that the R sequence are adjacent to the so-called small Bam family (Fanning, 1982), which in turn runs into the MIF sequence part (Brown & Piechaczyk, 1983) of the large Bam sequences (Meunier-Rotival et al., 1982). In one of our clones a sequence of 1290 base-pairs comprises MIF, Bam and R sequences in a contiguous arrangement which seems to be characteristic of the long repeat unit of the mouse genome. Several repeat units were found to be truncated within their Bam or R sequence parts. Evidence is also reported for transposition events involving R sequences; for instance of one R sequence (R1) into another (R7). Two R sequences (R1 and R4) have apparently been transposed together with part of the adjacent Bam sequences. Truncation and transposition events may also explain the imbalance of copy numbers within the large repeat unit (25,000 to 50,000 for the small Bam sequences and 100,000 for the R sequences). The spreading of R sequences and other interspersed DNA sequences within the mouse genome may have occurred by transposition events on the DNA level and/or by transcription, retrotranscription and insertion processes.

Nucleosome arrangement in green monkey alpha-satellite chromatin. Superimposition of non-random and apparently random patterns

We have studied the structure of tandemly repetitive alpha-satellite chromatin (alpha-chromatin) in African green monkey cells (CV-1 line), using restriction endonucleases and staphylococcal nuclease as probes. While more than 80% of the 172-base-pair (bp) alpha-DNA repeats have a HindIII site, less than 15% of the alpha-DNA repeats have an EcoRI site, and most of the latter alpha-repeats are highly clustered within the CV-1 genome. EcoRI and HindIII solubilize approximately 8% and 2% of the alpha-chromatin, respectively, under the conditions used. EcoRI is thus approximately 30 times more effective than HindIII in solubilizing alpha-chromatin, with relation to the respective cutting frequencies of HindIII and EcoRI on alpha-DNA. EcoRI and HindIII solubilize largely non-overlapping subsets of alpha-chromatin. The DNA size distributions of both EcoRI- and HindIII-solubilized alpha-chromatin particles peak at alpha-monomers. These DNA size distributions are established early in digestion and remain strikingly constant throughout the digestion with either EcoRI or HindIII. Approximately one in every four of both EcoRI- and HindIII-solubilized alpha-chromatin particles is an alpha-monomer. Two-dimensional (deoxyribonucleoprotein leads to DNA) electrophoretic analysis of the EcoRI-solubilized, sucrose gradient-fractionated alpha-oligonucleosomes shows that they do not contain "hidden" EcoRI cuts. Moreover, although the EcoRI-solubilized alpha-oligonucleosomes contain one EcoRI site in every 172-bp alpha-DNA repeat, they are completely resistant to redigestion with EcoRI. This striking difference between the EcoRI-accessible EcoRI sites flanking an EcoRI-solubilized alpha-oligonucleosome and completely EcoRI-resistant internal EcoRI sites in the same alpha-oligonucleosome indicates either that the flanking EcoRI sites occur within a modified chromatin structure or that an altered nucleosome arrangement in the vicinity of a flanking EcoRI site is responsible for its location in the nuclease-sensitive internucleosomal (linker) region. Analogous redigestions of the EcoRI-solubilized alpha-oligonucleosomes with either HindIII, MboII or HaeIII (both before and after selective removal of histone H1 by an exchange onto tRNA) produce a self-consistent pattern of restriction site accessibilities. Taken together, these data strongly suggest a preferred nucleosome arrangement within the EcoRI-solubilized subset of alpha-oligonucleosomes, with the centers of most of the nucleosomal cores being approximately 20 bp and approximately 50 bp away from the nearest EcoRI and HindIII sites, respectively, within the 172-bp alpha-DNA repeat. However, as noted above, the clearly preferred pattern of nucleosome arrangement within the EcoRI-solubilized alpha-oligonucleosomes is invariably violated at the ends of every such alpha-oligonucleosomal particle, suggesting at least a partially statistical origin of this apparently non-random nucleosome arrangement.(ABSTRACT TRUNCATED AT 400 WORDS)

Interruption of an alpha-satellite array by a short member of the KpnI family of interspersed, highly repeated monkey DNA sequences

We describe here the interruption of a cloned African green monkey alpha-satellite array by an 829-base-pair-long nonsatellite DNA segment. Hybridization experiments indicate that the sequences within the interruption are homologous to segments frequently found in the 6-kilobase-pair-long members of the KpnI family of long, interspersed repeats. These data confirm and extend earlier results suggesting that sequences common to the KpnI family can occur independently of one another and in segments of variable lengths. The 829-base-pair-long segment, which is termed KpnI-RET, contains a terminal stretch of adenosine residues preceded by two typical but overlapping polyadenylation sites. KpnI-RET is flanked by direct repeats of a 14-base-pair-long segment of alpha-satellite that occurs only once in the satellite consensus sequence. These structural features suggest that KpnI-RET was inserted into the satellite array as a movable element.

The use of a cloned bacterial gene to study mutation in mammalian cells

The recombinant DNA molecule pSV2-gpt, which contains the bacterial gene coding for xanthine-guanine phosphoribosyl transferase (XGPRT) activity, was introduced into a hamster cell line lacking the equivalent mammalian enzyme (HGPRT). Hamster cell sublines were found with stable expression of XGPRT activity and were used to study mutation of the integrated pSV2-gpt DNA sequence. Mutants were selected by their resistance to 6-thioguanine (TG) under optimal conditions which were found to be very similar to those for selection of HGPRT-deficient mutants of mammalian cells. The frequency of XGPRT-deficient mutants was increased by treatment with X-rays, ethyl methanesulphonate and ethyl nitrosourea. X-Ray induction of mutants increased approximately linearly with dose up to about 500 rad, but the frequency of mutants per rad was very much higher than that usually found for 'native' mammalian genes. However, still higher frequencies of mutation were found for the hamster HGPRT gene when it had been stably transferred into the same hamster cell line. It is suggested, therefore, that transferred DNA may integrate in sequences which are more 'reactive' than most of the genome. Cell-free extracts of 10 TG-resistant mutants of XGPRT-proficient sublines showed no measurable XGPRT activity. High molecular weight DNA from XGPRT-proficient sublines used in the mutation studies hybridized with nick-translated pSV2-gpt DNA, showing two distinct bands when cut with the restriction enzyme Eco R1. This suggests that a single copy of pSV2-gpt DNA was integrated in these sublines. DNA from most spontaneous and mutagen-induced TG-resistant mutants had lost these two hybridizing bands, but one spontaneous mutant was found with rearranged pSV2-gpt sequence.

Homology between the KpnI primate and BamH1 (M1F-1) rodent families of long interspersed repeated sequences

The KpnI and BamH1 (or M1F-1) families are the predominant sets of long interspersed repeated DNA sequences (LINEs) in primates and rodents, respectively. Recently, the sequences of several cloned subsegments from each family were determined in different laboratories. These sequences have now been compared and found to be homologous over at least 1400 bp. The data suggest that the two LINE families had a common progenitor and have been conserved in similar abundance although in divergent forms in the two mammalian orders.

Size and structure of the highly repetitive BAM HI element in mice

The BAM HI family of long interspersed DNAs in mice represent as much as 0.5% of the mouse genome. Cloned mouse DNA fragments which contain BAM HI/non-BAM HI junction sequences have been analyzed by restriction mapping and DNA sequencing. It has been found that BAM HI elements: (i) are approximately 7 kilobase pairs in size, (ii) are not bracketed by long repeated sequences analogous to the terminal repeats of proviruses and (iii) contain a poly-dA track at one end. The data strongly suggest that BAM HI elements arose by a process involving RNA intermediates. The beginning of the element, opposite the poly-dA track, contains a 22 base pair sequence exhibiting 65% homology to a ubiquitous mammalian sequence which may play a role in DNA replication (1). The poly-dA end of the element contains BAM5 and R sequences, both of which have been described previously (2,3).

Eight different highly specific nucleosome phases on alpha-satellite DNA in the African green monkey

The question of nucleosome phasing on African Green Monkey (AGM) alpha-satellite DNA has been addressed by employing a new approach. Nucleosome cores were prepared from AGM nuclei with micrococcal nuclease, exonuclease III and nuclease S1. The core DNA population derived from alpha-satellite DNA containing chromatin was purified from total core DNA by denaturation of the DNA, reassociation to a low Cot value, and hydroxyapatite chromatography to separate the renatured satellite fraction. After end-labeling the termini of the alpha-satellite containing core DNA fragments were mapped by high resolution gel electrophoresis relative to known restriction sites along the 172 bp repeat unit of the satellite DNA. The results show that nucleosomes occupy eight strictly defined positions on the alpha-satellite DNA which could be determined with an accuracy of +/- 1 base pair. Approximately 35% of all nucleosomes are organized in one of these frames while the other seven registers contribute about 10% each.

Kpn I family of long interspersed repeated DNA sequences in primates: polymorphism of family members and evidence for transcription

An approximately equal to 2-kilobase-pair-long member (Kpn I-LS1) of the African green monkey Kpn I family of repeated sequences has been cloned, subjected to sequence analysis, and compared to other family members which are over 6 kilobase pairs (Kpn I-alpha 7) and 829 base pairs (Kpn I-RET) long. Both Kpn I-LS1 and Kpn I-RET lack sequences found at the ends of the longer family member and their structures resemble those of processed genes. Kpm I-LS1 sequences are colinear with part of the long family member, Kpn I-alpha 7. However, although all sequences in Kpn I-RET are represented in Kpn I-LS1, the two are not colinear; Kpn I-RET is missing 731 base pairs found in Kpn I-LS1 and one segment flanking the deletion is inverted. The results demonstrate that Kpn I family members are not only of different lengths but may also contain scrambled arrangements of common sequences. Sequences in Kpn I-LS1 hybridize to RNA from monkey and human cells, indicating that some family members are transcribed.

Characterization of satellite DNA in Trypanosoma brucei and Trypanosoma cruzi

We have determined the properties of the simple-sequence satellite DNAs from two protozoa, Trypanosoma brucei and Trypanosoma cruzi. The T. brucei satellite DNA contains 29 mol% guanine plus cytosine and is made up of long tandem arrays of a 177 base-pair repeat. Sequence heterogeneity in these repeats is limited and restricted to certain positions as shown by sequence analysis, restriction enzyme digestion and two-dimensional analysis of nucleotides bordering the AluI and HhaI recognition sites in the repeat. The repeat contains two copies of a 19 base-pair sequence differing by a single base-pair substitution and several additional copies of part of this sequence. Sequence variants of the repeat are clustered in the DNA. Satellite DNA is not detectably linked to other DNA and no transcripts of this DNA are found in T. brucei. The T. cruzi satellite DNA repeat is 196 base-pairs long and contains 53 mol% guanine plus cytosine. Direct repetitions longer than eight base-pairs were not observed in the nucleotide sequence of this repeat. The nucleotide sequences of the satellites of T. brucei and T. cruzi are not related. In cell fractionation experiments, the T. brucei and T. cruzi satellite DNAs were recovered from the nuclear fraction. Micrococcal nuclease digestion of nuclear fractions yielded 193 and 197 base-pair nucleosomal oligomers in T. brucei and T. cruzi, respectively; these oligomers contained satellite DNA but not the extranuclear kinetoplast DNA. The 193 base-pair nucleosomal repeat of T. brucei is significantly different from the 177 base-pair satellite repeat. Satellite and nucleosomal repeats are, therefore, not in phase in T. brucei. These satellite DNAs are the first to be observed in protozoa, and we conclude that their properties are similar to those of satellites from animals or plants.

Interruption of an alpha-satellite array by a short member of the KpnI family of interspersed, highly repeated monkey DNA sequences

We describe here the interruption of a cloned African green monkey alpha-satellite array by an 829-base-pair-long nonsatellite DNA segment. Hybridization experiments indicate that the sequences within the interruption are homologous to segments frequently found in the 6-kilobase-pair-long members of the KpnI family of long, interspersed repeats. These data confirm and extend earlier results suggesting that sequences common to the KpnI family can occur independently of one another and in segments of variable lengths. The 829-base-pair-long segment, which is termed KpnI-RET, contains a terminal stretch of adenosine residues preceded by two typical but overlapping polyadenylation sites. KpnI-RET is flanked by direct repeats of a 14-base-pair-long segment of alpha-satellite that occurs only once in the satellite consensus sequence. These structural features suggest that KpnI-RET was inserted into the satellite array as a movable element.

Unusual domains of human alphoid satellite DNA with contiguous non-satellite sequences: sequence analysis of a junction region

The sequence organization of cloned segments of Human DNA carrying unusual domains of alphoid satellite was studied by restriction mapping, electron microscopy and base sequence analysis. In some cases restriction mapping revealed the absence of the typical 340 bp EcoR 1 dimer, although blot hybridizations showed the extensive presence of alphoid satellite. A variant monomeric construction was demonstrated by DNA sequencing. Furthermore, inverted repeats within these domains were detected by electron microscopy. In one case these were shown to be the result of interruptions in the satellite sequence by members of a family of repetitive, conserved elements.

The distribution of interspersed repeats is nonuniform and conserved in the mouse and human genomes

We investigated the genomic distribution of mouse and human repeated sequences by assessing their relative amounts in the four major components into which these genomes can be resolved by density gradient centrifugation techniques. These components are families of fragments that account for most or all of main-band DNAs, range in dG + dC content from 37% to 49%, and are derived by preparative breakage from long DNA segments (greater than 300 kb) of fairly homogeneous composition, the isochores. The results indicate that the short repeats of the B1 family of mouse and of the Alu I family of man are most frequent in the heavy components, whereas the long repeats of the BamHI family of mouse and of the Kpn I family of man are mainly present in the two light components. These results show that the genomic distribution of repeated sequences is nonuniform and conserved in two mammalian species. In addition, we observed that the base composition of two classes of repeats (60% dG + dC for short repeats; 39% dG + dC for long repeats) is correlated with the composition of the major components in which they are embedded. Finally, we obtained evidence that not only the short repeats but also the long repeats are transcribed, these transcripts having been found in mouse poly(A)+ mRNA.

Deca-satellite: a highly polymorphic satellite that joins alpha-satellite in the African green monkey genome

Three different cloned segments of African green monkey DNA that contain alpha-satellite sequences linked to a previously undescribed, distinct monkey satellite (called deca-satellite) are described here. The cloned segments were derived from a monkey DNA library in lambda Charon 4A that was constructed to select for junctions between alpha-satellite and other DNA sequences. The structure of the deca-satellite and of a junction between deca-satellite and alpha-satellite were studied by subcloning appropriate fragments of the original cloned segments and by sequence analysis. Deca-satellite has a ten base-pair repeat unit; the consensus sequence of the repeat units is 5' A-A-A-C-C-G-G-N-T-C. Sequences homologous to the deca-satellite are in the middle repeated class of genomic DNA. Analysis of the organization of deca-satellite sequences by digestion of total DNA with various restriction endonucleases and hybridization with a cloned deca-satellite probe revealed extensive polymorphism in the genomes of different individual monkeys but not among the tissues of one organism. These observations indicate that the arrangement of deca-satellite sequences is continually changing. An unusual alpha-satellite repeat unit occurs at a junction between the alpha-satellite and deca-satellite. It resembles the major baboon alpha-satellite more closely than it does monkey alpha-satellite and thereby provides evidence in favor of the "library" hypothesis for satellite evolution.

Relationships among DNA sequences of the 1.3 kb EcoRI family of mouse DNA

The genome of the mouse (Mus musculus) contains a family of repeated DNA sequences defined by a 1.3 kb EcoRI fragment. Restriction maps of ten cloned fragments from this family have been determined. The fragments were of seven different types, based on the patterns of digestion obtained with AvaII, HindIII, and TaqI restriction enzymes. These seven unique sets of sequences fell into two classes, as defined by the position of a single HindIII site. Portions of fragments from each of the two classes were sequenced. Although certain regions of the repeat were highly conserved between classes, there was more intraspecific sequence divergence among the sequenced regions than has been observed for the short interspersed Alu family of repeated sequences in mammals. Sequences of both HindIII classes were found to be present within the mouse X chromosome; we can conclude that both classes must also be present on other mouse chromosomes.

The independent evolution of two closely related satellite DNA elements in rats (Rattus)

We have identified and determined the sequence and organization of a new rat satellite DNA in Rattus rattus, the roof rat. This satellite DNA, which we call R. rattus satellite I', consists of tandem arrays of a 185 base pair (bp) repeat unit that we call a'. a' is 86% homologous to a 185 bp portion of the 370 bp repeat unit of the previously described rat satellite [Pech et al. (1979) Nucleic Acids Res. 7, 417-432] present in the common laboratory rat species, R. norvegicus. We can thereby distinguish two 185 bp portions of the satellite I 370 bp repeat unit: "a" (homologous to a') and "b". Satellite I has the structure (a,b)n, and satellite I' has the structure (a')n. Like a, a' is only about 60% homologous to b and fails to hybridize to b. Although R. norvegicus and R. rattus contain about the same total concentration of satellite sequences, R. norvegicus contains essentially only the a,b type (satellite I), whereas R. rattus contains a' type (satellite I') and lesser amounts of the a,b type (satellite I). The a,b type (satellite I) in R. rattus is very similar to that in R. norvegicus as judged both by hybridization and by the presence of all but one of the major restriction enzyme sites that characterize the R. norvegicus satellite I. In R. rattus the a' and a,b repeat units are not detectably present in the same tandem array. All of the sequence differences between a' (R. rattus) and a (R. norvegicus) can be accounted for by simple base substitutions, and the implication of this and other features of rat satellite DNA structure for satellite DNA evolution are discussed.

Members of the KpnI family of long interspersed repeated sequences join and interrupt alpha-satellite in the monkey genome

Three different members of a family (KpnI-family) of interspersed repeated DNA sequences were found linked to alpha-satellite sequences in cloned segments of the African green monkey genome. In two of these segments the KpnI-family member is over 6 kbp in length and one of them is flanked by alpha-satellite on both sides indicating that it was inserted into a satellite array. Hybridization of subcloned portions of the family members to restriction endonuclease digests of monkey and human DNA and to a genomic library of African green monkey DNA indicate that 1) family members are interspersed in both the monkey and human genomes, 2) some family members may include sequences in addition to those in the three characterized here, 3) some family members may contain only parts of the sequences characterized here and 4) while the overall organization of the family is similar in the human and monkey genome the majority of the family members in each of the two genomes are distinctly identified by the variant position of certain restriction endonuclease sites. This last observation suggests that within each genome there is a tendency to maintain particular versions of the sequence. Observations 2) and 3) suggest that the KpnI family is complex and includes a variety of subfamilies.

A short interspersed repetitive element found near some mouse structural genes

We have isolated and characterized a family of interspersed repetitive elements which make up about 1% of the mouse genome. The elements represent a group of homologous but non-identical units about 400 bp in length. Individual members of the family show considerable divergence from one another. The spacial relationships between members of the family and a number of other identified mouse sequences including structural genes have been determined; these elements are found on the 5' as well as 3' sides of various genes at distances ranging from less than 1 to 7.5 kilobases (Kb). The sequences are present in the DNA of all species of Mus. Related sequences are present in the rat genome at a repetition frequency similar to that in the mouse genome. A partial sequence of one member of the family is presented.

Nucleotide sequence of satellite DNA contained in the eliminated genome of Ascaris lumbricoides

Several restriction endonuclease fragments isolated from highly repetitive satellite DNA of the chromatin eliminating nematode Ascaris lumbricoides var. suum have been cloned. Each type of restriction fragment corresponds to a different variant of the same related ancestral sequence. These variants differ by small deletions, insertions and single base substitutions. Restriction and DBM blot analyses show that members of the same variant class are tandemly linked and therefore are physically separated from other variant classes. A comparison of all the determined sequences establishes a 121 bp long and AT rich consensus sequence. There is evidence for an internal short range periodicity of 11 bp length, indicating that the Ascaris satellite initially may have evolved from an ancestral undecamer sequence. The satellite DNA sequences are mostly but not entirely eliminated from the presumptive somatic cells during chromatin diminution. We have no evidence for transcriptional activity of satellite DNA at any stage or tissue analyzed.

New orientations of ancestral, "long interspersed repeated sequences" (LINES) in human DNA

Three sets of long, interspersed repeated sequences (LINES) are described in human DNA. Each set contains two cleavage sites for the restriction endonuclease, XbaI. One set, called the Xba 850 LINES was detected only in gibbons, apes and man but is related in sequence to a more ancestral LINES family, the Kpn 1200 LINES, and in fact some Xba 850 LINES members retained the ancestral spacing of KpnI cleavage sites. The facts that the Xba 850 LINES appear as a subset of the Kpn 1200 LINES and vice versa and that the Xba 850 LINES are restricted to a smaller phylogenetic group than the Kpn 1200 LINES prompted the speculation that the Xba 850 LINES originated by a relatively recent amplification of one or a few Kpn 1200 LINES sequences.

Characterization of X-chromosome specific satellite DNA of Muntiacus muntjak vaginalis

A highly repeated DNA (designated satellite IA) was isolated from cultured cells of Muntiacus muntjak vaginalis and its organization analyzed by the use of restriction nucleases and hybridization experiments with cloned DNA-fragments. Several restriction nucleases cleave the satellite IA DNA into a series of fragments, which are multiples of a basic repeat unit of 800 bp. Sequences homologous to the satellite IA DNA were also found in a second highly repetitive DNA component of Muntiacus muntjak vaginalis (satellite IB). Its organization is more complex than the one of satellite IA and does not conform to a simple periodicity of a basic repeat unit.--Hybridization in situ revealed, that both satellites are confined in their entirety to the X-chromosome, where they are located at both arms close to the centromere. No satellite DNA was found at the Y1-chromosome, which is considered to be homologous to the long arm of the X-chromosome. These results have interesting implications for the evolution of the X-chromosome.