Sequences of three closely related variants of a complex satellite DNA diverge at specific domains

Major differences among the sequences of the repeat units of a very complex satellite DNA are located in domains which are sensitive to S1 nuclease under torsional stress, indicating that the domains assume unusual secondary or tertiary structures. Repeat units of the satellite, which accounts for 3% of the DNA of a land crab, have been inserted into pBR322 and the primary sequences of three cloned variants determined. The variants selected for sequencing include 1) RU (2089 base pairs (bp) ), representative of the average size of repeat units of cellular satellite; 2) TRU (1674 bp), truncated at an extra EcoRI site; and 3) EXT (2639 bp), extended by a 5-fold amplification of a 142-bp segment, one copy of which is present in RU and TRU (Bonnewell, V., Fowler, R.F., and Skinner, D.M. (1983) Science 221, 862-865). It appears that every copy of the satellite may be different and that the variants do not arise from cloning accidents. Extensive domains, as long as approximately 560 bp, are greater than 95% homologous among RU, TRU, and EXT; these conserved domains are composed of DNA whose base composition and sequences do not have remarkable features. By contrast, the sequences that comprise the divergent domains are unusually rich in 1) tracts of (dG X dC) 13-23 and arrangements of similar but not identical repetitive oligonucleotides or 2) alternating purines and pyrimidines (pu/py).     

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

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

In vivo existence of left-handed DNA

A genetic-biochemical assay has been developed to investigate the in vivo existence and consequences of unusual DNA structures. Left-handed DNA was shown to exist in living Escherichia coli. The EcoRI methyltransferase gene (temperature-sensitive) was cloned to serve as a probe for perturbed GAATTC sites in vivo. This plasmid was cotransformed with different plasmids containing inserts that had varying capacities to form left-handed helices or cruciforms with a target EcoRI site in the center or at the ends of the inserts. Inhibition of methylation in vivo was found for the stable inserts with the longest left-handed helices. In vitro methylation with the purified M.EcoRI enzyme agreed with the in vivo results.     

Long-range organization and sequence-directed curvature of Xenopus laevis satellite 1 DNA.

We have investigated the long-range organization and the intrinsic curvature of satellite 1 DNA, an unusual tandemly-repeated DNA family of Xenopus laevis presenting sequence homologies to SINEs. PFGE was used in combination with frequent-cutter restriction enzymes not likely to cut within satellite 1 DNA and revealed that almost all the repeating units are tandemly organized to form large arrays (200 kb to 2 Mb) that are marked by restriction length polymorphism and contain intra-array domains of sequence variation. Besides that, we have analysed the secondary structure of satellite 1 DNA by computer modelling. Theoretical maps of curvature obtained from three independent models of DNA bending (the dinucleotide wedge model of Trifonov, the junction model of Crothers and the model of de Santis) showed that satellite 1 DNA is intrinsically curved and these results were confirmed experimentally by polyacrylamide gel electrophoresis. Moreover, we observed that this bending element is highly conserved among all the members of the satellite 1 DNA family that are accessible to analysis. A potential genetic role for satellite 1 DNA based on this unusual structural feature is discussed.     

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 set of synthetic oligodeoxyribonucleotide primers for DNA sequencing in the plasmid vector pBR322

Seven oligonucleotide primers complementary to the plasmid vector pBR322 at positions adjacent to five of the unique restriction endonuclease cleavage sites (EcoRI, HindIII, BamHI, SalI and PstI) have been chemically synthesized. The polarity of the primers is such that any DNA inserted at one or a combination of two of the above restriction sites may be sequenced by the chain termination method using one of the synthetic DNA primers. One of the primers for sequencing inserts at the PstI site of pBR322 is also complementary to the M13 phage vector designated bla6. This set of universal primers is useful for rapid sequence determination of DNA cloned into pBR322 or M13bla6.     

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).     

Cloning and organization of genes for 5S ribosomal RNA in the sea urchin. Lytechinus variegatus

A 1.35-kb EcoRI fragment of Lytechinus variegatus DNA containing a single 5S rRNA gene has been cloned into the plasmid vector pACYC184. Four clones from different transformation experiments contain 5S rDNA inserts of about the same size and have the same restriction enzyme digestion patterns for the enzymes HaeIII, HinfI, HhaI, and AluI. One EcoRI site near the HindIII site of the plasmid vector pACYC184 is missing in all the four clones. By DNA sequencing, the missing EcoRI ws found to be EcoRI site, d(AAATTN)d(TTTAAN) in pLu103, one of the four 5S rDNA clones. The structure of pLu103 was determined by restriction mapping and blot hybridization. Three restriction fragments, 1.0-kb HaeIII/HaeIII, 0.375-kb AluI/AluI and 0.249-kb MboII/MboII, which contain the 5S rRNA coding region, have been subcloned into the EcoRI site of the plasmid pACYC184. The organization of 5S rRNA genes in the sea urchin genome was also investigated. It was found that restriction endonuclease HaeIII has a single recognition site within each 5S rDNA repeat, and yields two fragment lengths, 1.2 and 1.3 kb. The behavior of these 5S rRNA genes when total L. variegatus DNA is partially digested with HaeIII is consistent with an arrangement of 5S rRNA genes in at least two tandemly repeated, non-interspersed families. Both the coding region and spacer region of the 5S rRNA gene in pLu103 hybridize to 1.2 and 1.3-kb rDNA families. This indicates that the cloned EcoRI fragment of 5S rDNA in pLu103 represents one single repeat of 5S rDNA in the genome.     

An RNA tertiary structure of the hepatitis delta agent contains UV-sensitive bases U-712 and U-865 and can form in a bimolecular complex.

Genomic RNA of the hepatitis delta agent has a highly conserved element of local tertiary structure. This element contains two nucleotides which become covalently crosslinked to each other upon irradiation with UV light. Using direct RNA analysis, we now identify the two nucleotides as U-712 and U-865 and show that the UV-induced crosslink can be broken by re-exposure to a 254 nm peak UV light source. In the rod-like secondary structural model of delta RNA, nucleotides U-712 and U-865 are off-set from each other by 5-6 bases, a distance too great to permit crosslinking. This model needs to be modified. Our data indicate that bases U-712 and U-865 closely approximate each other and suggest that the smooth helical contour proposed for delta RNA is interrupted by the UV-sensitive element. The nucleotide sequence shows that the UV-sensitive site does not have a particularly high density of conventional Watson-Crick base pairs compared to the rest of the genome. However, this element may have a number of non-Watson-Crick bonds which confer stability. Following UV-crosslinking and digestion with 1 mg/ml of RNase T1 at 37 degrees C for 45 min in 10 mM Tris-HCl, 1 mM EDTA (conditions expected to give complete digestion), this element can be isolated as part of a 54 nucleotide long partial digestion product containing at least 16 internal G residues. UV-crosslinking analysis shows that this unusual tertiary structural element can form in a bimolecular complex.     

Structure-based sequence alignment of type-II restriction endonucleases

The type-II restriction endonucleases generally do not share appreciable amino acid sequence homology. The crystal structures of restriction endonucleases EcoRI and BamHI have shown these enzymes to possess striking 3D-structural resemblance, i.e., they have a similar overall fold and similar active sites, though they possess <23% sequence identity. Structural superimposition of EcoRI, BamHI, EcoRV, and PvuII based on active site residues led to sequence alignments which showed nine possible sequence motifs. EcoRV and PvuII show a more similar pattern than EcoRI and BamHI suggesting that they belong to a different subgroup. The motifs are characterized by charged and/or hydrophobic residues. From other studies on the structure of these endonucleases, three of the motifs could be implicated in DNA binding, three in forming the active site and one in dimer formation. However, the motifs were not identifiable by regular sequence alignment methods. It is found that motif IX in BamHI is formed by reverse sequence order and the motif IX in PvuII is formed from the symmetry related monomer of the dimer. The inter-motif distance is also quite different in these cases. Of the nine motifs, motif III has been earlier identified as containing the PD motif involving one of the active site residues. These motifs were used in a modified profile analysis procedure to identify similar regions in eight other endonuclease sequences for which structures are not known.     

A cloned fragment of HeLa DNA containing consensus sequences of satellite II and III DNA hybridizes with the Drosophila P-element and with the 1.8 kb family of human KpnI fragments

We have cloned a repetitive EcoRI fragment from the human genome which displays weak homologies with the Drosophila melanogaster transposable P-element. This cloned DNA appeared not to be a mobile element but, instead, a divergent member of human satellite II or III DNAs. We present here the first complete nucleotide sequence of a 1.797 kilobase pair (kb) satellite-like DNA. Moreover, this EcoRI satellite monomer contains a unique sequence of 49 basepairs (bp) that is devoid of the satellite consensus repeat 5'TTCCA3'. Southern hybridization analysis revealed that the cloned insert is closely related to a highly repetitive 1.8 kb KpnI family of tandemly organized satellite DNAs. Thus, the relationships among these satellite DNA families appear to be complex and may be a factor in their copy number, position and spatial organization.     

Distribution and evolution of two satellite DNAs in the genus Beta

Summary EcoRI monomers of a highly repetitive DNA family of Beta vulgaris have been cloned. Sequence analysis revealed that the repeat length varies between 157–160 bp. The percentage of AT-residues is 62% on average. The basic repeat does not show significant homology to the BamHI sequence family of B. vulgaris that was analyzed by us earlier. Both the EcoRI and BamHI sequences are investigated and compared to each other with respect to their genomic organization in the genus Beta. Both repeats were found to be tandemly arranged in the genome of B. vulgaris in a satellite-like manner. The EcoRI satellite DNA is present in three sections (Beta, Corollinae and Nanae) of the genus, whereas the BamHI satellite DNA exists only in the section Beta. The distribution of the EcoRI and BamHI satellite families in the genus is discussed with respect to their evolution.     

Cytological and biochemical characterization of the in situ endonuclease digestion of fixed Tenebrio molitor chromosomes

Cytological and biochemical experiments were undertaken in order to characterize the action of several restriction enzymes on fixed chromosomes of Tenebrio molitor (Coleoptera). EcoRI cuts the satellite DNA of this organism into suunit monomers of 142 bp in naked DNA and acts on fixed chromosomes cleaving and extracting these tandemly repeated sequences present in median centromeric heterochromatin. AluI, in contrast, is unable to attack the satellite sequences but does cut the main band DNA both in naked DNA and in fixed chromosomes. These enzymes therefore permit the in situ localization of satellite DNA or main band DNA in T. molitor. Other enzymes such HinfI or Sau3A do not produce longitudinal differentiation in chromosomes because of the extraction of DNA from satellite and main band DNA regions. In situ hybridization with a satellite DNA probe from T. molitor confirms that the DNA extracted from the chromosomes is the abundant and homogenous highly repeated DNA present in pericentromeric regions. These results plus the analysis of the DNA fractions retained on the slide and solubilized by the action of the restriction enzymes in situ provide evidence that: (a) as an exception to the rule EcoRI (6 bp cutter) is able to produce chromosome banding; (b) the size of the fragments produced by in situ digestion of satellite DNA with EcoRI is not a limiting factor in the extraction; (c) there is a remarkable accord between the action of EcoRI and AluI on naked DNA and on DNA in fixed chromosomes, and (d) the organization of specific chromosome regions seems to be very important in producing longitudinal differentiation on chromosomes.by E.R. Schmidt     

Alternative tertiary structure attenuates self-cleavage of the ribozyme in the satellite RNA of barley yellow dwarf virus.

A self-cleaving satellite RNA associated with barley yellow dwarf virus (sBYDV) contains a sequence predicted to form a secondary structure similar to catalytic RNA molecules (ribozymes) of the 'hammerhead' class (Miller et al., 1991, Virology 183, 711-720). However, this RNA differs from other naturally occurring hammerheads both in its very slow cleavage rate, and in some aspects of its structure. One striking structural difference is that an additional helix is predicted that may be part of an unusual pseudoknot containing three stacked helices. Nucleotide substitutions that prevent formation of the additional helix and favor the hammerhead increased the self-cleavage rate up to 400-fold. Compensatory substitutions, predicted to restore the additional helix, reduced the self-cleavage rate by an extent proportional to the calculated stability of the helix. Partial digestion of the RNA with structure-sensitive nucleases supported the existence of the proposed alternative structure in the wildtype sequence, and formation of the hammerhead in the rapidly-cleaving mutants. This tertiary interaction may serve as a molecular switch that controls the rate of self-cleavage and possibly other functions of the satellite RNA.     

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.     

Nonrandom localization of recombination events in human alpha satellite repeat unit variants: implications for higher-order structural characteristics within centromeric heterochromatin.

Tandemly repeated DNA families appear to undergo concerted evolution, such that repeat units within a species have a higher degree of sequence similarity than repeat units from even closely related species. While intraspecies homogenization of repeat units can be explained satisfactorily by repeated rounds of genetic exchange processes such as unequal crossing over and/or gene conversion, the parameters controlling these processes remain largely unknown. Alpha satellite DNA is a noncoding tandemly repeated DNA family found at the centromeres of all human and primate chromosomes. We have used sequence analysis to investigate the molecular basis of 13 variant alpha satellite repeat units, allowing comparison of multiple independent recombination events in closely related DNA sequences. The distribution of these events within the 171-bp monomer is nonrandom and clusters in a distinct 20- to 25-bp region, suggesting possible effects of primary sequence and/or chromatin structure. The position of these recombination events may be associated with the location within the higher-order repeat unit of the binding site for the centromere-specific protein CENP-B. These studies have implications for the molecular nature of genetic recombination, mechanisms of concerted evolution, and higher-order structure of centromeric heterochromatin.     

Isolation and identification of a novel tandemly repeated DNA sequence in the centromeric region of human chromosome 8

EcoRI subclones, designated as 50E1 and 50E4, were independently obtained from a cosmid clone previously mapped to the centromeric region of human chromosome 8. Southern blot hybridization analyses suggested that both subclones contain repetitive DNA sequences different from the chromosome 8 specific alphoid DNA. DNA sequence analysis of the 704 bp insert of 50E1 and the 1, 962 bp insert of 50E4 revealed that both inserts contained tandemly repeated units of 220 bp. Fluorescence in situ hybridization studies confirmed these two subclones to be specifically located on the centromeric region of chromosome 8. A 220 bp consensus sequence, derived from nine monomeric repeats, showed no significant homology to alphoid consensus sequences or to other currently known human centromeric DNA sequence. Furthermore, no significant homology was found with any other DNA sequence deposited in the EMBL or GenBank databases, indicating that this chromosome 8 specific repetitive DNA sequence is novel. From slot blot experiments it was estimated that 0.013% of the human genome comprises 1,750 of these monomeric repeats, residing on the centromeric region of chromosome 8 in tandem array(s).