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.     

Sequence and sequence variation within the 1.688 g/cm3 satellite DNA of Drosophila melanogaster.

We have determined the complete nucleotide sequence of the monomer repeating unit of the 1.688 g/cm³ satellite DNA from Drosophila melanogaster. This satellite DNA, which makes up 4% of the Drosophila genome and is located primarily on the sex chromosomes, has a repeat unit 359 base-pairs in length. This complex sequence is unrelated to the other three major satellite DNAs present in this species, each of which contains a very short repeated sequence only 5 to 10 base-pairs long. The repeated sequence is more similar to the complex repeating units found in satellites of mammalian origin in that it contains runs of adenylate and thymidylate residues. We have determined the nature of the sequence variations in this DNA by restriction nuclease cleavage and by direct sequence determination of (1) individual monomer units cloned in hybrid plasmids, (2) mixtures of adjacent monomers from a cloned segment of this satellite DNA, (3) mixtures of monomer units isolated by restriction nuclease cleavage of total 1.688 g/cm³ satellite DNA. Both direct sequence determination and restriction nuclease cleavage indicate that certain positions in the repeat can be highly variable with up to 50% of certain restriction sites having altered recognition sequences. Despite the high degree of variation at certain sites, most positions in the sequence are highly conserved. Sequence analysis of a mixture of 15 adjacent monomer units detected only nine variable positions out of 359 base-pairs. Total satellite DNA showed only four additional positions. While some variability would have been missed due to the sequencing methods used, we conclude that the variation from one repeat to the next is not random and that most of the satellite repeat is conserved. This conservation may reflect functional aspects of the repeated DNA, since we have shown earlier that part of this sequence serves as a binding site for a sequence-specific DNA binding protein isolated from Drosophila embryos (Hsieh &; Brutlag, 1979).     

Characterization of a highly repeated satellite DNA from the cyprinid fish Notropis lutrensis

1. A highly repeated, satellite DNA family from the North American cyprinid fish, Notropis lutrensis, was identified as a fragment band following restriction endonuclease enzyme digestion and agarose gel electrophoresis of genomic DNA; evidence of a tandem arrangement of the satellite in the genome was demonstrated by the formation of "ladders" in partial restriction endonuclease digests. 2. The satellite family was estimated densitometrically to comprise 7-8% of the N. lutrensis genome; mapping experiments using isolated and purified monomer repeat units of the satellite uncovered nine sites for seven different restriction enzymes. 3. A monomeric repeat unit of the satellite was cloned and sequenced, and found to be 174 base pairs in length and to have a base composition of 47% G + C (guanine + cytosine); computer analysis of the sequence revealed 13 new restriction sites for 12 additional enzymes. 4. Computer analysis also revealed that a large degree of internal redundancy in the monomer unit exists in the form of both direct and inverted repeating units, and that the entire sequence, starting with one base in either orientation, constitutes an open reading frame. In all but the last characteristic, the N. lutrensis satellite DNA is very similar to satellite DNAs in other eukaryotes.     

Structural Mechanics of DNA Wrapping in the Nucleosome

Experimental X-ray crystal structures and a database of calculated structural parameters of DNA octamers were used in combination to analyse the mechanics of DNA bending in the nucleosome core complex. The 1kx5 X-ray crystal structure of the nucleosome core complex was used to determine the relationship between local structure at the base-step level and the global superhelical conformation observed for nucleosome-bound DNA. The superhelix is characterised by a large curvature (597°) in one plane and very little curvature (10°) in the orthogonal plane. Analysis of the curvature at the level of 10-step segments shows that there is a uniform curvature of 30° per helical turn throughout most of the structure but that there are two sharper kinks of 50° at ± 2 helical turns from the central dyad base pair. The curvature is due almost entirely to the base-step parameter roll. There are large periodic variations in roll, which are in phase with the helical twist and account for 500° of the total curvature. Although variations in the other base-step parameters perturb the local path of the DNA, they make minimal contributions to the total curvature. This implies that DNA bending in the nucleosome is achieved using the roll-slide-twist degree of freedom previously identified as the major degree of freedom in naked DNA oligomers. The energetics of bending into a nucleosome-bound conformation were therefore analysed using a database of structural parameters that we have previously developed for naked DNA oligomers. The minimum energy roll, the roll flexibility force constant and the maximum and minimum accessible roll values were obtained for each base step in the relevant octanucleotide context to account for the effects of conformational coupling that vary with sequence context. The distribution of base-step roll values and corresponding strain energy required to bend DNA into the nucleosome-bound conformation defined by the 1kx5 structure were obtained by applying a constant bending moment. When a single bending moment was applied to the entire sequence, the local details of the calculated structure did not match the experiment. However, when local 10-step bending moments were applied separately, the calculated structure showed excellent agreement with experiment. This implies that the protein applies variable bending forces along the DNA to maintain the superhelical path required for nucleosome wrapping. In particular, the 50° kinks are constraints imposed by the protein rather than a feature of the 1kx5 DNA sequence. The kinks coincide with a relatively flexible region of the sequence, and this is probably a prerequisite for high-affinity nucleosome binding, but the bending strain energy is significantly higher at these points than for the rest of the sequence. In the most rigid regions of the sequence, a higher strain energy is also required to achieve the standard 30° curvature per helical turn. We conclude that matching of the DNA sequence to the local roll periodicity required to achieve bending, together with the increased flexibility required at the kinks, determines the sequence selectivity of DNA wrapping in the nucleosome.     

Restriction enzyme analysis of a highly diverged satellite DNA from Drosophila nasutoides

The satellite II DNA of Drosophila nasutoides is a highly diverged repetitive DNA, showing about 17% base changes between repeat units (Cordeiro-Stone and Lee, 1976). This DNA is cleaved by four different restriction enzymes to produce multimeric fragmentation patterns, indicating that their restriction sites are regularly arranged. Moreover, all four enzymes produce identical fragment lengths, the size of a monomer being 96 base pairs. Such multimeric patterns are expected for a diverged repetitive DNA, since many restriction sequences could have undergone changes during sequence divergence. Further restriction analyses of this DNA by double digestions and cloning reveal that there are three different sequences in satellite II DNA with respect to the presence and the arrangement of various restriction sites (Fig. 7). As an example, one sequence contains many EcoRI sites and fewer Hinfl sites (20% of EcoRI sites), which are arranged regularly. These observations suggest that satellite II DNA of D. nasutoides might have evolved through different modes of sequence divergence.     

A subtelomeric satellite DNA family isolated from the genome of the dioecious plant Silene latifolia.

In an ongoing effort to trace the evolution of the sex chromosomes of Silene latifolia, we have searched for the existence of repetitive sequences specific to these chromosomes in the genome of this species by direct isolation from low-melting agarose gels of satellite DNA bands generated by digestion with restriction enzymes. Five monomeric units belonging to a highly repetitive family isolated from Silene latifolia, the SacI family, have been cloned and characterized. The consensus sequence of the repetitive units is 313 bp in length (however, high variability exists for monomer length variants) and 52.9% in AT. Repeating units are tandemly arranged at the subtelomeric regions of the chromosomes in this species. The sequence does not possess direct or inverted sequences of significant length, but short direct repeats are scattered throughout the monomer sequence. Several short sequence motives resemble degenerate monomers of the telomere repeat sequence of plants (TTTAGGG), confirming a tight association between this subtelomeric satellite DNA and the telomere repeats. Our approach in this work confirms that SacI satellite DNA sequences are among the most abundant in the genome of S. latifolia and, on the other hand, that satellite DNA sequences specific of sex chromosomes are absent in this species. This agrees with a sex determination system less cytogenetically diverged from a bisexual state than the system present in other plant species, such as R. acetosa, or at least a lesser degree of differentiation between the sex chromosomes of S. latifolia and the autosomes.     

Chromosome-specific alpha satellite DNA: nucleotide sequence analysis of the 2.0 kilobasepair repeat from the human X chromosome.

The pericentromeric region of the human X chromosome is characterized by a tandemly repeated family of 2.0 kilobasepair (kb) DNA fragments, initially revealed by cleavage of human DNA with the restriction enzyme BamHI. We report here the complete nucleotide sequence of a cloned member of the repeat family and establish that this X-linked DNA family consists entirely of alpha satellite DNA. Our data indicate that the 2.0 kb repeat consists of twelve alpha satellite monomers arranged in imperfect, direct repeats. Each of the alpha X monomers is approximately 171 basepairs (bp) in length and is 60-75% identical in sequence to previously described primate alpha satellite DNAs. The twelve alpha X monomers are 65-85% identical in sequence to each other and are organized as two adjacent, related blocks of five monomers, plus an additional two monomers also related to monomers within the pentamer blocks. Partial nucleotide sequence of a second, independent copy of the 2.0 kb BamHI fragment established that the 2.0 kb repeat is, in fact, the unit of amplification on the X. Comparison of the sequences of the twelve alpha X monomers allowed derivation of a 171 bp consensus sequence for alpha satellite DNA on the human X chromosome. These sequence data, combined with the results of filter hybridization experiments of total human DNA and X chromosome DNA, using subregions within the 2.0 kb repeat as probes, provide strong support for the hypothesis that individual human chromosomes are characterized by different alpha satellite families, defined both by restriction enzyme periodicity and by chromosome-specific primary sequence.     

Patchwork structure of a bovine satellite DNA

According to a previous restriction nuclease analysis, bovine 1.706 satellite DNA (density 1.706 g/cm3 in CsCl) is organized in an unusual structure of superimposed long- and short-range repeats (Streeck and Zachau, 1978). We have now determined the nucleotide sequence of this satellite DNA in both cloned fragments and fragments from the total satellite DNA. Each long-range repeat unit (about 2350 bp) is divided into four segments. Each segment consists of different variants of a basic 23 bp sequence which is itself composed of a dodecanucleotide and a related undecanucleotide. A total of 2400 nucleotides have been sequenced. Detailed analysis of the sequence divergence reveals that both the overall extent of divergence and the frequency of base changes at individual positions of the 23 bp repeats are characteristically different in the various segments. Preferentially methylated sites and a high incidence of symmetry elements are found. In two of the four segments, 22 of 23 bp of the prototype sequence are included in six overlapping elements of dyad symmetry and in a palindrome. A scheme for the evolution of the satellite DNA from a basic dodecanucleotide is proposed which is based on the different degrees of divergence for the various repeats superimposed in this satellite DNA.     

Sequence-induced curvature of Tenebrio molitor satellite DNA

Single satellite DNA constitutes about 50% of the Tenebrio molitor genome. Electrophoresis of 142 base pair long satellite monomers on nondenaturating polyacrylamide gel shows retarded mobility, a characteristic of fragments with sequence-induced DNA curvature. Migrational analysis of circularly permuted satellite monomers revealed the existence of 2 bend centers in the monomer sequence. We calculated the trajectory of DNA helix axis according to the algorithm of De Santis et al. This model predicts that T molitor naked satellite DNA forms a solenoid structure with left-handed superhelix. One turn of the superhelix has approximately 310 base pairs and a 33 nm pitch. Point mutations found in the satellite DNA (1.8%) influence bending characteristics, but do not distort the general geometry of satellite superhelix.     

Cytoplasmic localization of human repetitive DNA revealed by in situ hybridization

Previously, we showed that a human repetitive DNA sequence (Sau3A family) belonging to a satellite DNA is unstable and constantly excised from the chromosomes (R. Kiyama, H. Matsui, and M. Oishi, 1986, Proc. Natl. Acad. Sci. USA 83, 4665). The unusual property of the repetitive DNA, along with another repetitive DNA (Alu sequence), was further investigated by in situ hybridization in several different human cells including HeLa, bone marrow, and peripheral blood cells. We found that the excised repetitive DNA sequences are localized not only in nuclei, but also in cytoplasm. These results have confirmed the instability of these DNA sequences in the chromosomes and further suggest that the alpha satellite DNA and the Alu sequence which were excised from the chromosomes are released from nuclei to cytoplasm.     

Comparative analysis of three guinea pig satellite DNA's by restriction nucleases.

The structures of guinea pig satellite DNAs I, II, and III have been analyzed by digestion with seven restriction nucleases. From the cleavage patterns it is obvious that the long-range periodicities in these three satellites differ rather characteristically Satellite I is fairly resistant to six nucleases and gives only a number of weak discrete bands which do not show a simple regularity. By the restriction nuclease from Arthrobacter luteus, however, it is cleaved extensively and yields very heterogeneous breakdown products. This is consistent with the high extent of divergence previously found for this satellite, e. g. by sequence analysis. Satellite II is almost completely resistant to all nucleases, indicative of a high degree of sequence homogeneity of this satellite. Satellite III is completely broken by the restriction nuclease from Bacillus subtilis into fragments which form a novel, highly regular series of bands in gel electrophoresis. The patterns show that the satellite is composed of tandem repeats ofapproximately 215 nucleotide pairs length, each repeat unit containing two cleavage sites for this nuclease. The data are consistent with the assumption that 30--40% of all cleavage sites have been eliminated by a random process. Satellite III DNA yields weak degradation patterns of the same periodicity with a number of other restriction nucleases. Cleavage sites for these nuclease are clustered on separatesmall segments of the satellite DNA. In this respect, the satellite is similar to others, notably the mouse satellite DNA. The three guinea pig satellites are examples of more general types of satellite structures also found in othe organisms. Similarities and differences to other satellites are discussed with special consideration to theories on the evolution of this class of DNA.     

Restriction endonuclease cleavage of satellite DNA in intact bovine nuclei

We have analyzed the efficiency with which specific nucleotide sequences within nucleosomes are recognized and cleaved by DNA restriction endonucleases. A system amenable to this sort of analysis is the cleavage of the bovine genome with the restriction endonuclease EcoRI. Bovine satellite I comprises 7% of the genome and is tandemly repetitious with an EcoRI site at 1400 base pair (bp) intervals within this sequence. The ease with which this restriction fragment can be measured permits an analysis of the accessibility of this sequence when organized in a nucleosomal array.Initial studies indicated that satellite I sequences are organized in a nucleosomal structure in a manner analogous to that observed for total genomic DNA. We then examined the accessibility of the EcoRI cleavage sites in satellite to endonucleolytic cleavage in intact nuclei. We find that whereas virtually all the satellite I sequences from naked DNA are cleaved into discrete 1400 bp fragments, only 33% of the satellite I DNA is liberated as this fragment from intact nuclei. These data indicate that 57% of the EcoRI sites in nuclei are accessible to cleavage and that cleavage can occur within the core of at least half the nucleosomal subunits. Analysis of the products of digestion suggests a random distribution of nucleosomes about the EcoRI sites of satellite I DNA.Finally, the observation that satellite sequences can be cleaved from nuclei to 1400 bp length fragments with their associated proteins provides a method for the isolation of specific sequences as chromatin. Using sucrose gradient velocity centrifugation, we have isolated a 70% pure fraction of satellite I chromatin. Nuclease digestion of this chromatin fraction reveals the presence of nucleosomal subunits and indicates that specific sequences can be isolated in this manner without gross disorganization of their subunit structure.     

Bent DNA functions as a replication enhancer in Saccharomyces cerevisiae.

Previous studies have demonstrated that bent DNA is a conserved property of Saccharomyces cerevisiae autonomously replicating sequences (ARSs). Here we showed that bending elements are contained within ARS subdomains identified by others as replication enhancers. To provide a direct test for the function of this unusual structure, we analyzed the ARS activity of plasmids that contained synthetic bent DNA substituted for the natural bending element in yeast ARS1. The results demonstrated that deletion of the natural bending locus impaired ARS activity which was restored to a near wild-type level with synthetic bent DNA. Since the only obvious common features of the natural and synthetic bending elements are the sequence patterns that give rise to DNA bending, the results suggest that the bent structure per se is crucial for ARS function.     

On the mode of evolution of alpha satellite DNA in human populations

Summary The hypothesis that highly reiterated satellite DNAs in present-day populations evolve by molecular mechanisms that create, by saltatory amplification steps, new long arrays of satellite DNA, and that such long arrays are used for homogenization purposes, has been tested both in mouse and in humans. In mouse, the data obtained are consistent with this hypothesis. This was tested in more detail on chromosomes 13 and 21 of the human genome. A Centre d'Etudes du Polymorphisme Humain family, which in some individuals exhibits strong supplementary DNA bands following TaqI restriction endonuclease digestion and conventional gel electrophoresis, was analyzed by pulse field gel electrophoresis following restriction by BamHI. The supplementary bands on chromosome 13 (18 times the basic alpha satellite DNA repeat) and on chromosome 21 (a 9.5-mer) segregated with centromeric alpha satellite DNA blocks of 5 and 5.3 megabases, respectively. These are by far the largest alpha satellite block lengths seen in all chromosome 13 and chromosome 21 centrometric sequences so far analyzed in this manner. The possibility that these supplementary alpha satellite sequences were created in single individuals by saltatory amplification steps is discussed in light of our own data and that published by others. It is proposed that deletion events and unequal cross-overs, which both occur in large satellite DNA arrays, contribute to the homogenization of size and sequence of the alpha satellite DNA on most chromosomes of humans.     

The centromeric satellite of the wedge sole (Dicologoglossa cuneata, Pleuronectiformes) is composed mainly of a sequence motif conserved in other vertebrate centromeric DNAs

Here, a new satellite-DNA family is isolated and characterized from wedge sole, Dicologoglossa cuneata Moreau, 1881 (Pleuronectiformes), a fish having a small genome. This satellite-DNA family of sequences was isolated by conventional cloning after digestion of genomic DNA with the DraI restriction enzyme. Repeat units are 171 bp in length with a high AT content (63%). Several runs of consecutive adenines and thymines were found, and concomitantly computer analyses revealed that these regions are prone to acquire stable sequence-directed curvature. Especially remarkable is that the DraI sequences are composed almost entirely of the repetition of up to fourteen 9-bp motifs (T/C)GTC(A/C)AAAA similar to other vertebrate centromeric satellite-DNA sequences. In fact, we demonstrate the origin of this satellite through duplication of this motif plus the addition of a stretch of cytosines. The centromeric location and the presence in this satellite-DNA sequence of not only different vertebrate motifs (CENP-B box, pJalpha) but also others such as the CDEIII motif of Saccharomyces cerevisiae reveal a possible role in centromere function. All these characteristics provide important information on the origin, function, and the evolution of the centromeric satellite DNAs in wedge sole.     

DNA curvature in front of the human mitochondrial L-strand replication origin with specific protein binding.

DNA bending has been suggested to play a role in the regulation of gene expression, initiation of DNA-replication, site specific recombination, and DNA packaging. In the human mitochondrial DNA we have found a DNA curvature structure within the 3'-region of ther URF2 sequence in front of the L-strand origin of replication. This structure interacts specifically with a protein factor isolated from mitochondria. Based on the localization of this DNA curvature structure and the known function of such structures the data suggest a model in which this DNA signal sequence and its specific protein binding is involved in the regulatory initiation event of L-strand replication.     

Evolution of ancient satellite DNAs in sturgeon genomes

This study characterizes a repetitive DNA family of sequences in sturgeon, the PstI satellite DNA. We have found a high degree of preservation for these sequences, which are present in all 13 species analyzed, including within the genera Acipenser, Huso, and Scaphirhynchus of the family Acipenseridae. This is one of the most ancient satellite DNAs found to date, because it has been estimated to be more than 100 million years old. Alternatively, to the current view that most satellite DNAs are species-specific or preserved in a few closely related species, the PstI family and other previously characterized sturgeon satellite DNA, the HindIII, represent the most fascinating exceptions to the rapid sequence change usually undergone by satellite DNAs. Here, we compare the evolutionary pattern of these two satellite DNA families, PstI and HindIII, which differ markedly in length, sequence, and nucleotide composition. We have found that, in contrast to the situation in most other living beings, a high degree of preservation, a slow sequence change rate and slowed concerted evolution, appears to be a general rule for sturgeon satellite DNAs. The possible causes for all these features are discussed in the light of the evolutionary specifics found within these ancient organisms.     

Bending and curvature calculations in B-DNA.

A simple program, BEND, has been written to calculate the magnitude of local bending and macroscopic curvature at each point along an arbitrary B-DNA sequence, using any desired bending model that specifies values of twist, roll and tilt as a function of sequence. The program has been used to evaluate six different DNA bending models in three categories. Two are bent non-A-tract models: (a) A new model based on the nucleosome positioning data of Satchwell et al 1986 (J. Mol. Biol. 191, 659-675), (b) The model of Calladine et al 1988 (J. Mol. Biol. 201, 127-137). Three are bent A-tract models: (c) The wedge model of Bolshoy et al 1991 (Proc. Natl. Acad. Sci. USA 88, 2312-2316), (d) The model of Cacchione et al 1989 (Biochem. 28, 8706-8713), (e) A reversed version of model (b). The last is a junction model: (f) The model of Koo & Crothers 1988 (Proc. Natl. Acad. Sci. USA 85, 1763-1767). Although they have widely different assumptions and values for twist, roll and tilt, all six models correctly predict experimental A-tract curvature as measured by gel retardation and cyclization kinetics, but only the new nucleosome positioning model is successful in predicting curvature in regions containing phased GGGCCC sequences. This model--showing local bending at mixed sequence DNA, strong bends at the sequence GGC, and straight, rigid A-tracts--is the only model consistent with both solution data from gel retardation and cyclization kinetics and structural data from x-ray crystallography.     

Isolation and characterization of two families of satellite DNA with repetitive units of 135 bp and 2.5 kb in the ant Monomorium subopacum (Hymenoptera, Formicidae)

Analyzing the satellite DNA in the ant species Monomorium subopacum we found two unrelated families of satellite DNA. Because these satellite DNA families were isolated using the two enzymes HaeIII and EcoRI we called the two families HaeIII and EcoRI family, respectively. The HaeIII family proved to be organized in a 135-bp basic unit repeat, the EcoRI family in a 2.5-kb basic unit repeat. The latter represents perhaps the longest satellite DNA isolated up to now in insects. The HaeIII family apparently comprises about 10% of the total genomic DNA whereas the EcoRI family represents only about 1-2%. A comparative analysis of the two satellite DNA sequences showed no homology between the two families although both sequences possessed long A and T stretches. Eight of the 34 chromosomes showed hybridization with the HaeIII family and hybridization signals are visible in six chromosomes with the EcoRI family. Analysis of the electrophoretic mobility of satellite DNA on non-denaturing polyacrylamide showed that the HaeIII family is only slightly curved. However, the unit of the EcoRI satellite DNA family has curvature, especially the first 1000 bp of the monomeric repeat, in which this DNA is AT rich and has numerous A and T stretches. There are also internal inverted subrepeats in each family. The sequences of satellite DNA families found in Monomorium subopacum are different from the sequences of other satellite DNAs cloned in insects, including other species of ants.