A molecular and cytogenetic survey of major repeated DNA sequences in tomato (Lycopersicon esculentum)

Summary The major families of repeated DNA sequences in the genome of tomato (Lycopersicon esculentum) were isolated from a sheared DNA library. One thousand clones, representing one million base pairs, or 0.15% of the genome, were surveyed for repeated DNA sequences by hybridization to total nuclear DNA. Four major repeat classes were identified and characterized with respect to copy number, chromosomal localization by in situ hybridization, and evolution in the family Solanaceae. The most highly repeated sequence, with approximately 77000 copies, consists of a 162 bp tandemly repeated satellite DNA. This repeat is clustered at or near the telomeres of most chromosomes and also at the centromeres and interstitial sites of a few chromosomes. Another family of tandemly repeated sequences consists of the genes coding for the 45 S ribosomal RNA. The 9.1 kb repeating unit in L. esculentum was estimated to be present in approximately 2300 copies. The single locus, previously mapped using restriction fragment length polymorphisms, was shown by in situ hybridization as a very intense signal at the end of chromosome 2. The third family of repeated sequences was interspersed throughout nearly all chromosomes with an average of 133 kb between elements. The total copy number in the genome is approximately 4200. The fourth class consists of another interspersed repeat showing clustering at or near the centromeres in several chromosomes. This repeat had a copy number of approximately 2100. Sequences homologous to the 45 S ribosomal DNA showed cross-hybridization to DNA from all solanaceous species examined including potato, Datura, Petunia, tobacco and pepper. In contrast, with the exception of one class of interspersed repeats which is present in potato, all other repetitive sequences appear to be limited to the crossing-range of tomato. These results, along with those from a companion paper (Zamir and Tanksley 1988), indicate that tomato possesses few highly repetitive DNA sequences and those that do exist are evolving at a rate higher than most other genomic sequences.     

Sequence and evolution of rhesus monkey alphoid DNA

Summary Analysis of rhesus monkey alphoid DNA suggests that it arose by tandem duplication of an ancestral monomer unit followed by independent variation within two adjacent monomers (one becoming more divergent than the other) before their amplification as a dimer unit to produce tandem arrays. The rhesus monkey alphoid DNA is a tandemly repeated, 343-bp dimer; the consensus dimer is over 98% homologous to the alphoid dimers reported for baboon and bonnet monkey, 81% homologous to the African green monkey alpha monomer, and less than 70% homologous to the more divergent human alphoid DNAs. The consensus dimer consists of two wings (I and II, 172 and 171 bp, respectively) that are only 70% homologous to each other, but share seven regions of exact homology. These same regions are highly conserved among the consensus sequences of the other cercopithecid alphoid DNAs. The three alpha-protein binding sites reported for African green monkey alpha DNA by F. Strauss and A. Varshavsky (Cell 37: 889–901, 1984) occur in wings I and II, but with one site altered in wing I. Two cloned dimer segments are 98% homologous to the consensus, each containing 8 single-base-pair differences within the 343-bp segment. Surprisingly, 37% of these differences occur in regions that are evolutionarily conserved in the alphoid consensus sequences, including the alpha-protein binding sites. Sequence variation in this highly repetitive DNA family may produce unique nucleosomal architectures for different members of an alphoid array. These unique architectures may modulate the evolution of these repetitive DNAs and may produce unique centromeric characteristics in primate chromosomes.     

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.     

A highly repeated DNA sequence in Arabidopsis thaliana

Summary Three members of a family of highly repeated DNA sequences from Arabidopsis thaliana have been cloned and characterized. The repeat unit has an average length of 180 bp and is tandemly repeated in arrays longer than 50 kb. This family represents more than one percent of the Arabidopsis genome. Sequence comparisons with tandemly repeated DNA sequences from other Cruciferae species show several regions of homology and a similar length of the repeat unit. Homologies are also found to highly repeated sequences from other plant species. When the sequence CCGG occurs in the repeated DNA, the inner cytosine is generally methylated.     

Genomic representation of the Hind II 1.9 kb repeated DNA.

The genomic representation and organization of sequences homologous to a cloned Hind III 1.9 kb repeated DNA fragment were studied. Approximately 80% of homologous repeated DNA was contained in a genomic Hind III cleavage band of 1.9 kb. Double digestion studies indicated that the genomic family, in the majority, followed the arrangement of the sequenced clone, with minor restriction cleavage variations compatible with a few base changes. Common restriction sites external to the 1.9 kb sequence were mapped, and hybridization of segments of the cloned sequence indicated the 1.9 kb DNA was itself not tandemly repeated. Kpn I bands which were homologous to the sequence contained specific regions of the repeat, and the molecular weight of these larger fragments could be simply explained. Mapping of common external restriction sites indicated that in some but not all cases the repeat could be organized in larger defined blocks of greater than or equal to 5.5 kb. In some instances, flanking regions adjacent to the repeat may contain common DNA elements such as other repeated DNA sequences, or possibly rearranged segments of the 1.9 kb sequence. It is suggested that although the 1.9 kb sequence is not strictly contiguous, at least some of these repeated sequences in the human genome are arranged in clustered or intercalary arrays. A region of the 1.9 kb sequence hybridized to a mouse repeated DNA, indicating homology beyond the primates.     

Highly repeated DNA families in the rat

We have analyzed the repeated DNA fraction of the rat by characterizing approximately 500 repeat DNA-containing clones using hybridization to a variety of rodent nucleic acids. To facilitate this analysis we devised a method whereby the cloned DNA is transferred to nitrocellulose paper by blotting directly out of colonies of the bacterial clones. In addition to identifying repeated sequences of potential interest (e.g. those transcribed in a tissue-specific manner, or those that are highly conserved in non-rat genomes), we found that, in contrast to what is revealed by the reassociation of rat DNA (e.g. Pearson, W. R., Wu, J. R., and Bonner, J. (1978) Biochemistry 17, 51-59), the rat genome contains a number of different highly repeated (greater than 50,000 copies) sequences. We distinguished the different highly repeated sequences both by their hybridization to different nucleic acids as well as by DNA sequence determination. The highly repeated sequences shared three characteristics that distinguished each of them from the 100,000-member rat satellite I family: (i) they were recovered less often in the cloned repeat DNA library than expected from their copy number in the rat genome; (ii) they reannealed abnormally slowly for their copy number even though they are not significantly divergent; and (iii) they are transcribed in one or more rat tissues. The implications of these findings for the organization of repeated sequences in the rat genome are discussed.     

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.     

The 5-methylcytosine content of highly repeated sequences in human DNA.

Previously, we found much tissue- or cell-specificity in the levels of 5-methylcytosine (m5C) in the total human genome as well as in DNA fractions resolved by reassociation kinetics. We now report that there were even greater differences in the m5C content of the highly repeated, tandem EcoRI family of DNA sequences from different human organs or cell populations. The ratio of m5C levels in this DNA fraction from brain, placenta, and sperm was 2.0:1.2:1.0. At a HhaI site in this repeat family, sperm DNA was 5-10 fold less methylated than somatic DNAs. In contrast, the highly repeated Alu family, which is approximately 5% of the genome, had almost the same high m5C content in brain and placenta despite marked tissue-specific differences in m5C levels of the single copy sequences with which these repeats are interspersed. These data show that very different degrees of change in methylation levels of various highly repeated DNA sequences accompany differentiation.     

Interspersion of different repeated sequences in the wheat genome revealed by interspecies DNA/DNA hybridisation.

The repeated sequences in oats DNA have been used to study chromosomal repeated sequence organisation in wheat. Approximately 75% of the wheat genome consists of repeated sequences but only approximately 20% will form heteroduplexes with repeated sequences from oats DNA at 60 degrees C in 0.18 M Na+. The proportion of wheat DNA that forms heteroduplexes with oats DNA is shown to be independent of the wheat DNA fragment length. However, the proportion of wheat DNA that is retained with the heteroduplexes when fractionated on hydroxyapatite is very dependent upon the wheat fragment length up to 3500 nucleotides. This is because more non-renatured wheat DNA is attached to the heteroduplexes with longer fragments. The results indicate that the repeated sequences in the wheat genome homologous to repeated sequences in oats are not clustered in the chromosomes but distributed amongst other repeated and possible non-repeated sequences.     

Structure of simian virus 40 recombinants that contain both host and viral DNA sequences. II. The structure of variant 1103 and its comparison to variant CVPS/1P2 (EcoRI res).

In an effort to characterize sites of recombination between SV40 and monkey DNA, we have determined the primary sequence of a large portion of the SV40 variant, designated 1103. This virus contains DNA sequences derived both from the wild type SV40 genome and from the permissive monkey cell in which the virus was propagated. Further, the monkey sequences included in the defective genome are homologous to both highly repeated monkey DNA (alpha component) and sequences that are infrequently repeated in the monkey genome. The regions of the 1103 genome where DNA sequences were determined include 1) the segments of the variant that surround joints connecting SV40 and monkey sequences, 2) the segment that contains the joint between monkey sequences of high and low reiteration frequency, and 3) the DNA segment of the variant that is homologous to monkey alpha component DNA. Comparison of the data obtained from the sequences analysis of the SV40 variants 1103 and CVP8/1/P2 (EcoRI res) (described in Wakamiya, T., McCutchan, T., Rosenberg, M., and Singer, M. (1979) J. Biol. Chem 254, 3584-3591) reveals certain similarities between the two that may be involved in eukaryotic recombination and defective variant formation.     

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.     

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.     

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.     

Sequence definition and organization of a human repeated DNA

DNA sequence data for a DNA repeated sequence, found largely in centromeres of specific human chromosomes is presented. The sequence consists of two tandem 169 and 171 base-pair units that show 27% base variation with each other. In contrast the dimer is more faithfully copied in longer tandem repeats, such as the sequenced 680 base-pair tetramer. In the major sequence of the tetramer, base variation of the order of only 1%, in comparison to the complete dimer is seen. A minimum of two steps in the formation of this sequence is proposed, consisting of evolution of a tandem dimer of two 170 base-pair variant units of a related family within the human genome, and later saltation or amplification of this dimer. No evidence that these sequences contained or evolved from a simpler 6 to 20 base-pair repeat was found, and no homology with known simpler human satellites could be discerned. In reviewing and comparing the literature on repeated DNAs it appears that overall length and tandem repetition are the critical features, rather than individual unit repeat length or secondary structural potential, in defining these sequences as a class and their special centromeric functions and higher chromosome order. The possibility that such sequences arise from a reservoir of interspersed sequences that are common to at least several species is discussed.     

Heterochromatin and highly repeated DNA sequences in rye (Secale cereale)

Secale cereale DNA, of mean fragment length 500 bp, was fractionated by hydroxylapatite chromatography to allow recovery of a very rapidly renaturing fraction (C₀t 0–0.02). This DNA fraction was shown to contain several families of highly repeated sequence DNA. Two highly repeated families were purified; (1) a fraction which renatured to a density of 1.701 g/ cc and comprised 2–4% of the total genome, and (2) polypyrimidine tract DNA which comprised 0.1% of the total genome. The 1.701 g/cc DNA consisted of short sequence repeat units (5–50 bp long) tandemly repeated in blocks 30 kb long, while a portion of the polypyrimidine tract DNA behaved as part of a much larger block of tandemly repeated sequences. The chromosomal location of these sequences was determined by the in situ hybridisation of radioactive, complementary RNA to root tip mitotic chromosomes and showed the 1.701 g/cc sequences to be largely limited to the telomeric blocks of heterochromatin, accounting for 25–50% of the DNA present in these parts of the chromosomes. The polypyrimidine tracts were distributed at interstitial locations with 20–30% of the sequences at three well defined sites. The combined distributions of the 1.701 g/cc DNA sequences and polypyrimidine tracts effectively individualised each rye chromosome thus providing a sensitive means of identifying these chromosomes. The B chromosomes present in Secale cereale cv. Unevita, did not show defined locations for the sequences analysed. — The data are discussed in terms of the structure of the rye genome and the generality of the observed genomic arrangement of highly repeated sequence DNA.     

A BamHI family of highly repeated DNA sequences of Nicotiana tabacum

Summary HRS60.1, a monomer unit (184 bp) of a highly repeated nuclear DNA sequence of Nicotiana tabacum, has been cloned and sequenced. Following BamHI digestion of tobacco DNA, Southern hybridization with HRS60.1 revealed a ladder of hybridization bands corresponding to multiples of the basic monomer unit. If the tobacco DNA was digested with restriction endonucleases which have no target site in HRS60.1, the larger part of DNA homologous to HRS60.1 remained as uncleaved relic DNA. These results suggest a tandem arrangement of this DNA repeat unit. Four other clones of tobacco nuclear DNA cross-hybridized with HRS60.1, thus forming a HRS60-family. Sequencing their inserts has shown their strong mutual homology. HRS60-family comprised about 2% of the nuclear genome of N. tabacum. Computer comparisons with other tandem plant-repeated DNA sequences could not detect any other homologous sequence.     

A 2.2-kilobase repeated DNA segment is associated with DNA amplification in Streptomyces fradiae.

We have previously identified a 10.5-kilobase DNA sequence which is highly amplified and tandemly repeated in the mutant Streptomyces fradiae JS85. A library of DNA was prepared from S. fradiae T776, which does not contain amplified DNA. The library was screened by plaque hybridization to identify phage clones containing the unamplified 10.5-kilobase DNA sequence. Four phage isolates were identified which contained DNA homology to the amplified DNA sequence. This sequence was designated the amplifiable unit of DNA. None of the clones carried an entire amplifiable unit of DNA, and so overlapping regions were aligned to create a map of the entire region. Detailed restriction mapping identified a 2.2-kilobase direct repeat at the ends of the amplifiable unit of DNA. Analysis by Southern hybridization confirmed that the direct repeats were homologous to each other. The DNA of S. fradiae contained at least two additional copies of DNA that was homologous to the repeat sequence.