Interspersed repeated sequences in the African green monkey genome that are homologous to the human Alu family.

The dominant family of interspersed repetitive DNA sequences in the human genome has been termed the Alu family. We have found that more than 75% of the lambda phage in a recombinant library representing an African green monkey genome hybridize with a human Alu sequence under stringent conditions. A group of clones selected from the monkey library with probes other than the Alu sequence were analyzed for the presence and distribution of Alu family sequences. The analyses confirm the abundance of Alu sequences and demonstrate that more than one repeat unit is present in some phages. In the clones studied, the Alu units are separated by an average of 8 kilobase pairs of unrelated sequences. The nucleotide sequence of one monkey Alu sequence is reported and shown to resemble the human Alu sequences closely. Hence, the sequence, dispersion pattern, and copy number of the Alu family members are very similar in the African green monkey and human genomes. Among the clones investigated were two that contain segments of the satellite DNA term alpha-component joined to non alpha-component DNA. The experiments indicate that in the monkey genome Alu sequences can occur close to regions of alpha-component DNA.     

Analysis of LINE-1 family sequences on a single monkey chromosome.

The structure of LINE-1 (L1Ca) family members present on African green monkey chromosome CAE-19 is compared with that of the entire set of L1Ca sequences present in the monkey genome. The analysis involved annealing of cloned subsegments of monkey L1 family members to DNA-blots containing restriction endonuclease digests of either total monkey liver DNA or DNA isolated from a monkey/mouse somatic cell hybrid carrying the single monkey chromosome. In addition, L1Ca segments cloned from hybrid cell DNA were characterized by restriction endonuclease mapping and hybridization. The data indicate that, taken as a whole, the set of L1Ca sequences on CAE-19 tends to differ in characteristic ways from the set present in the total monkey genome.     

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.     

KpnI families of long, interspersed repetitive DNAs in human and other primate genomes.

KpnI restriction of DNAs from all anthropoid primates studied releases a conspicuous series of segments representing families of long, interspersed repetitive DNAs termed here the KpnI 1.2, 1.5, 1.8 and 1.9 kb families. Human KpnI 1.2 to 1.9 kb segments representative of these families were isolated and separately cloned in the KpnI site of a plasmid pBK5, specially constructed for this purpose. The KpnI clones did not cross-hybridize with cloned, primate alphoid sequences, suggesting that the KpnI families represent sequences separate and distinct from the alphoid DNAs. Secondary restriction analyses of cloned KpnI segments demonstrated microheterogeneity among individual members within the same KpnI family. Autoradiograms of capuchin monkey, AGM and human DNA cleaved with HaeIII, AluI or RsaI and hybridized to various cloned human KpnI sequences demonstrated a remarkable conservatism and relative simplicity in the organization of the KpnI families in the genomes of these widely divergent primates. The KpnI 1.2 kb and 1.5 kb families occur in high frequency (15%) among all plaques in two recombinant human genome libraries. Evidence is presented suggesting that the bulk of the KpnI families occur in the genome as clusters or congeries of higher molecular weight segments (greater than 2 kb) containing sequences homologous to the low molecular weight segments (1.2 to 1.9 kb).     

A dimer satellite sequence in bonnet monkey DNA consists of distinct monomer subunits

A family of 342 nucleotide fragments was isolated from total bonnet monkey DNA by the restriction endonuclease HaeIII and its base sequence was determined. This family was found to consist of a dimer of two related but distinct nucleotide sequences. Both sequences are closely related to previously reported sequences from African green monkey and human DNA. The two bonnet monkey sequences are unequally divergent from the African green monkey sequence, and have fewer bases in common with each other than they do with African green monkey. Restriction of the dimer with other endonucleases confirms the inequality of the two monomers.     

Nucleosome arrangement in alpha-satellite chromatin of African green monkey cells.

By analyzing the accessibility of restriction endonuclease sites in African green monkey alpha-satellite chromatin, we demonstrate the absence of a unique phase relationship between nucleosomes and alpha-satellite DNA. The data indicate a minimum of three different positions for nucleosome cores relative to the alpha-satellite sequence and suggest a random distribution in at least some regions. In addition, while we confirm published reports that staphylococcal nuclease cuts the alpha-satellite sequence in chromatin at a highly preferred site, two-dimensional gel electrophoresis of nuclear digests demonstrates that this site is preferentially cut by staphylococcal nuclease even when it is within the nucleosome core. These data indicate that staphylococcal nuclease is not useful for determining nucleosome positions on alpha-satellite DNA, and perhaps on other specific DNA sequences as well.     

Highly repetitive component α and related alphoid DNAs in man and monkeys

The genomes of Old-World, New-World, and prosimian primates contain members of a large class of highly repetitive DNAs that are related to one another and to component DNA of the African green monkey by their sequence homologies and restriction site periodicities. The members, of this class of highly repetitive DNAs are termed the alphoid DNAs, after the prototypical member, component of the African green monkey which was the first such DNA to be identified (Maio, 1971) and sequenced (Rosenberg et al., 1978). The alphoid DNAs appear to be uniquely primate sequences. — From the restriction enzyme cleavage patterns and Southern blot hybridizations under different stringency conditions, the alphoid DNAs comprise multiple sequence families exhibiting varying degrees of homology to component DNA. They also share common elements in their restriction site periodicities (172 · n base-pairs), in the long-range organization of their repeating units, and in their banding behavior in CsCl and Cs₂SO₄ buoyant density gradients, in which they band within the bulk DNA as cryptic repetitive components. — In the three species from the Family Cercopithecidae examined, the alphoid DNAs represent the most abundant, tandemly repetitive sequence components, comprising about 24% of the African green monkey genome and 8 to 10% of the Rhesus monkey and baboon genomes. In restriction digests, the bulk of the alphoid DNAs among the Cercopithecidae appeared quantitatively reduced to a simple series of arithmetic segments based on a 172 base-pair (bp) repeat. In contrast with these simple restriction patterns, complex patterns were observed when human alphoid DNAs were cleaved with restriction enzymes. Detailed analysis revealed that the human genome contains multiple alphoid sequence families which differ from one another both in their repeat sequence organization and in their degree of homology to the African green monkey component DNA. — The finding of alphoid sequences in other Old-World primate families, in a New-World monkey, and in a prosimian primate attests to the antiquity of these sequences in primate evolution and to the sequence conservatism of a large class of mammalian highly repetitive DNA. In addition, the relative conservatism exhibited by these sequences may distinguish the alphoid DNAs from more recently evolved highly repetitive components and satellite DNAs which have a more restricted taxonomical distribution.     

Acquisition of the sequence of a new subclass of human alpha- satellite DNA, localized in the centromere regions of two pairs of acrocentric chromosomes

The results are presented in the paper on obtaining of a clone of sub-group of alpha-satellite human DNA localized in heterochromatin regions of two pairs of acrocentric chromosomes. The obtained repeated DNA sequence is represented in a genome by some 20,000 copies. Using of the blot-hybridization method made it possible to show the polymorphic restriction variant distribution being preserved in different individuals genomes. Intergenomic structural heterogeneity in this alpha-satellite DNA sub-group has been found only by using restriction endonuclease BamHI.     

The nucleotide sequence of repetitive monkey DNA found in defective simian virus 40.

DNA fragments containing monkey DNA sequences have been isolated from defective SV40 genomes that carry host sequences in place of portions of the SV40 genome. The fragments were isolated by restriction endonuclease cleavage and contain segments homologous to sequences in both the highly repetitive and unique (or less repetitive) classes of monkey DNA. The complete nucleotide sequence of one such fragment [151 base pairs (bp)] predominantly homologous to the highly reiterated class of monkey DNA was determined using both RNA and DNA sequencing methods. The nucleotide sequence of this homogeneous DNA segment does not contain discernible multiple internal repeating units but only a few short oligonucleotide repeats. The reiteration frequency of the sequence in the monkey genome is >10⁶. Digestion of total monkey DNA (from uninfected cells) with endonuclease R Hind III produces relatively large amounts of discrete DNA fragments that contain extensive regions homologous to the fragment isolated from the defective SV40 DNA.A second fragment, also containing monkey sequences, was isolated from the same defective substituted SV40 genome. The nucleotide sequence of the 33 bp of this second fragment that are contiguous to the 151 bp fragment has also been determined.The sequences in both fragments are also present in other, independently derived, defective substituted SV40 genomes.     

Deca-satellite: A highly polymorphic satellite that joins α-satellite in the African green monkey genome

Three different cloned segments of African green monkey DNA that contain α-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 λCharon4A that was constructed to select for junctions between α-satellite and other DNA sequences.The structure of the deca-satellite and of a junction between deca-satellite and α-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 α-satellite repeat unit occurs at a junction between the α-satellite and deca-satellite. It resembles the major baboon α-satellite more closely than it does monkey α-satellite and thereby provides evidence in favor of the “library” hypothesis for satellite evolution.     

Genomic organization of low copy number sequences that are associated with deca-satellite DNA in the monkey genome.

A previously described segment of African green monkey DNA (cloned in phage lambda MkA) contains deca-satellite linked to DNA sequences that are estimated to occur once per genome. Sequences homologous to the low copy number sequences in lambda MkA are also associated with species-specific satellite DNAs in the human and mouse genomes. A second clone, lambda Mk8, contains a monkey DNA region that is colinear and homologous to a portion of the low copy number sequences in lambda MkA, but no satellite sequences. The two cloned segments are markedly different starting at a point proximal to the satellite DNA region in lambda MkA. DNA-blotting experiments indicate that lambda Mk8 but not lambda MkA represents the typical genomic organization and that the low copy number segments occur only once per haploid genome. The data suggest that rearrangements such as deletions or inversions occurring in monkey cells account in part for the structure of lambda MkA. Additional rearrangements may have occurred during cloning in E. coli. This unique chromosomal region may be particularly susceptible to recombination.     

The KpnI family of long interspersed nucleotide sequences is present on discrete sizes of circular DNA in monkey (BSC-1) cells

Discretely sized molecules of small circular DNAs in African green monkey kidney (BSC-1) cells contain nucleotide sequences homologous to the KpnI family of long interspersed repetitive nucleotide sequences. The size distribution of these KpnI family-containing circular DNAs differs markedly from those of BSC-1 cell circular DNAs containing either the Alu family of short interspersed nucleotide sequences or the alpha-satellite family of tandemly repeated sequences. The structures of several cloned, apparently whole, KpnI family-related circular DNAs of varying sizes were analyzed and compared with a compilation of chromosomal KpnI sequences. In general, it was found that the cloned DNAs all contained only KpnI sequences, and that the recombination events given rise to them did not involve any noticeable gain of nucleotides.     

Defining the beginning and end of KpnI family segments.

Comparison of the sequences at the ends of several newly cloned and full length members of the monkey KpnI family with one another and with previously described monkey and human segments defines the nucleotide sequence at the two termini. No terminal repeats either direct or inverted are noted within full length family members which may or may not be immediately flanked by direct repeats. At the 3' terminus, several family members have polyadenylation signals followed by a d(A)-rich stretch. The genomic frequency of segments within the full length element increases markedly from the 5' to the 3' terminus, consistent with the cloning of various truncated family members. One such truncated version joined to a low copy number DNA segment is inserted in monkey alpha-satellite where the combination appears to have been amplified in conjunction with the satellite itself.     

The association of the interspersed repetitive KpnI sequences with the nuclear matrix

The KpnI sequences constitute the dominant, long, interspersed repetitive DNA families in primate genomes. These families contain related, but nonidentical sequence subsets, some of which border functional gene domains and are transcribed into RNA. To test whether these sequences perform an organizational function in the nucleus, their association with the nuclear matrix has been examined in African green monkey cells. DNase I treatment depleted the residual matrix of most of the KpnI 1.2- and 1.5-kilobase pair family sequences although significant amounts of each family remained in the loop attachment DNA fragments. Hybridization analysis of the KpnI and RsaI cleavage patterns of matrix loop attachment DNA indicate that some sequence subsets of these KpnI families are relatively less depleted than others. The nuclear matrix association of subpopulations of KpnI 1.2- and 1.5-kilobase pair families was also shown by metrizamide gradient centrifugation of nuclear matrix complexes cleaved by KpnI endonuclease. The gradients demonstrate that some KpnI segments are differentially associated with nuclear matrix proteins. Moreover, the procedures permit the preparative isolation and purification of the DNA-protein complexes containing these KpnI 1.2- and 1.5-kilobase pair sequence families. Speculations on the relationship between the matrix association of these KpnI family sequences and their possible roles in gene organization and expression are presented and discussed.     

Structural organization of alpha-satellite DNA in a single monkey chromosome

The organization of α-satellite sequences in a single monkey chromosome has been studied by restriction endonuclease analysis and molecular cloning. A somatic cell hybrid containing the monkey chromosome was isolated by cloning after fusion of the mouse L-cell line B82 (thymidine kinase minus) with primary African green monkey kidney cells and selective growth in HAT medium. Unlike the mouse cells, the hybrid cells contain DNA that hybridizes with the α-satellite DNA of the monkey. The presence of a single α-satellite containing monkey chromosome was demonstrated by Giemsa-11 staining and by the absence of both this chromosome and monkey α-satellite DNA sequences in cells after back-selection in bromodeoxyuridine. Hybridization of restriction endonuclease-digested hybrid cell DNA with a cloned segment of African green monkey α-satellite DNA showed distinctly different patterns from those observed with monkey total DNA. In particular, EcoRI and HaeIII restriction endonuclease sites are much more abundant in the satellite sequences in the thymidine kinase-carrying chromosome than they are in total satellite. A library of hybrid DNA was constructed in a λ bacteriophage. Analyses of purified recombinant phage that hybridized with α-satellite also indicated an abundance of EcoRI and HaeIII sites. Of nine phage studied in detail, no two showed identical distributions of the two restriction sites in the α-satellite sequences, suggesting the independent evolution of different domains within the single chromosome. These results indicate that the thymidine kinase-carrying chromosome contains distinct subsets (domains) of the α-satellite DNA of the whole monkey genome and further, that while the satellite sequence on the single chromosome is distinctive, it is also complex.     

Cae I: an endonuclease isolated from the African green monkey with properties indicating site-specific cleavage of homologous and heterologous mammalian DNA.

Component alpha DNA is a highly repetitive sequence that comprises nearly a quarter of the African green monkey (Cercopithecus aethiops) genome. A previous microbial restriction enzyme analysis showed that the repeat structure of component alpha DNA is based upon a monomeric unit of 176 +/- 4 base-pairs. An endonuclease, provisionally termed Case I, has been isolated from African green monkey testes that cleaves component alpha DNA into multimeric segments based upon the same repeat periodicity as that revealed by microbial restriction enzymes. The primary sites of Cae I cleavage in the component alpha sequence appear to be 120 +/- 6 base-pairs distant from the Hind III sites and 73 +/- 6 base-pairs distant from the Eco RI* sites. Cae I has been partially characterized with special reference to the effects of ATP and S-adenosylmethionine on the cleavage of component alpha DNA. Cae I may be a member of a class of similar site-specific nucleases present in mammalian cells. Cae I also cleaves mouse satellite DNA into a multimeric series of discrete segments: the periodicity of this series is shorter than that revealed by Eco RII retriction analysis of mouse satellite DNA.     

Toward a molecular paleontology of primate genomes

KpnI restriction of anthropoid primate DNAs, from a New World monkey to man, releases a series of segments that are remarkable among all of the alphoid DNAs in the constancy of their relative amounts in the various primate genomes, in their long-range organization, and in their internal sequence structure. These segments are labeled the KpnI A, B, C and D segments. Cross-hybridization analysis by Southern filter-transfer hybridization indicates that the KpnI segments represent separate and distinct families of alphoid DNAs. These families are termed the KpnI A, B, C and D families of alphoid sequences, of which only the KpnI A and B families were studied in detail here. - Evidence is presented suggesting that the KpnI segments do not exist as long, tandemly repeated sequences in the primate genome: rather, they may occur interspersed among other, perhaps nonalphoid sequences. From the stained gel patterns and from Southern filter-transfer hybridization experiments, the KpnI families appear to be absent from the genomes of the two prosimians studied - the galago and the black lemur. The KpnI A and B families are found among all of the anthropoid primates, including the New World capuchin monkey. The KpnI C family was detected in the genomes of the Old World anthropoid primates whereas the KpnI D family was detected only among the great apes and man. - The results are in accord with the observation (Musich et al., 1980) that with the continued evolutionary development of the primate Order, there has been a parallel trend toward an increased number and variety of alphoid DNA sequences. The properties of the KpnI families suggest that these sequences, unique among the alphoid DNAs, have been conservatively maintained throughout primate phylogeny and that they are among the most ancient of all primate DNAs.     

Recurring defective variants of simian virus 40 containing monkey DNA segments.

Four independently and newly isolated defective variants of simian virus 40 have been characterized. All four are very similar, if not identical, to two previously and independently isolated variants (Wakamiya et al., J. Biol. Chem. 254:3584-3591, 1979; J. Papamatheakis, E. Kuff, E. Winocour, and M. F. Singer, J. Biol. Chem. 255:8919-8927, 1980). The documented similarities include restriction endonuclease maps and the presence of the same monkey DNA segments covalently linked to simian virus 40 DNA sequences. Each of the newly described variants was first detected upon serial passaging of wild-type simian virus 40 at a high multiplicity of infection at 33 degrees C as recently described (M. F. Singer and R. E. Thayer, J. Virol. 35:141-149, 1980). A variety of experiments support the idea that the various isolates were independent and do not reflect inadvertent cross-contamination. Two of the new isolates arose during passage of wild-type strain 777 virus in BSC-1 cells, one during passage of strain 776 in BSC-1 cells, and one during passage of strain 776 in primary African green monkey kidney cells. The two variants obtained after passage of strain 776 were shown to contain a particular recognition site for restriction endonuclease MboII within their simian virus 40 DNA segments, as do the two previous isolates. This site is not present in wild-type strain 776 DNA but is shown here to be present in wild-type strain 777 DNA. The surprising recurrence of closely related variants and particularly the unexpected presence of the endo R.MboII site in variants derived from passaging strain 776 suggest that these variants may arise by mechanisms other than recombination between the initial infecting viral genome and the host DNA.     

Isolation of low-copy-number sequences that neighbor satellite DNA in mammals

To investigate the role of satellite DNA in eukaryotic genomes, we isolated from an African green monkey (Cercopithecus aethiops) genomic library cloned segments containing the previously described deca-satellite linked to low-copy-number genomic sequences. Three such clones were obtained. The low-copy-number sequences in the three clones do not cross-hybridize suggesting that they derive from different genomic loci. The structure of one of the clones, λAMkA, is described in detail. Subcloned segments containing the low-copy-number sequences from λAMkA anneal to monkey, human and mouse genomic DNA. The subcloned probes were used to select clones containing homologous sequences from a second, independent monkey library as well as from human and mouse genomic libraries. Several of the newly isolated monkey clones hybridized to probes containing the species-specific deca- and -satellites, confirming the genomic association of the low-copy-number sequence in λAMkA with satellite DNA. Moreover, several of the human and mouse clones hybridized to species-specific human and mouse satellite DNAs, respectively. These experiments indicate that the low-copy-number sequence in λMkA and its association with satellite DNA is conserved in primates and rodents.