Artificial nucleosome positioning sequences tested in yeast minichromosomes: a strong rotational setting is not sufficient to position nucleosomes in vivo.

DNA sequences that support bending around the histone octamer ('rotational setting') are considered to be a major determinant of nucleosome positions. TG5 is an artificial positioning sequence containing 100 bp of an (A/T)3NN(G/C)3NN motif repeated with a 10 bp period. It provides a strong rotational setting and is superior to natural sequences in nucleosome formation in vitro [Shrader, T.E. and Crothers, D.M. (1989) Proc. Natl. Acad. Sci. USA, 86, 7418-7422]. To investigate the contribution of the rotational setting to nucleosome positioning in vivo, TG sequences were inserted in a nucleosome, at the edge of a nucleosome and in a nuclease sensitive region of yeast minichromosomes and the chromatin structures were analysed. In none of the constructs were TG sequences folded in a positioned nucleosome, demonstrating that the rotational setting played a subordinate role in the rough positioning in vivo. The rotational setting might fine tune the positions. Positioned nucleosomes were found overlapping the ends of TG, indicating that a discontinuity of the 10 bp periodicity of (A/T)3 and (G/C)3 near the centre of a nucleosome might be favourable for positioning and serve as a translational signal.     

Correlation between dinucleotide periodicities and nucleosome positioning on mouse satellite DNA

Previous studies demonstrated 16 well-defined nucleosome locations (A-P) on a tandemly repeated prototype 234 base pair (bp) mouse satellite repeat unit. We have aligned the A-P fragments to search for DNA sequence elements that might contribute to nucleosome placement at these positions. Our results demonstrate a strikingly regular, uninterrupted, periodic pattern for the AA dinucleotide occurrences along the entire length of the aligned fragments. The periodicity of the AA occurrences is about 9.7 bp. The pattern exhibits a local minimum at position 74, near the nucleosome dyad axis of symmetry. Other dinucleotides--including AC: GT, CA: TG, and CC: GG--are also placed periodically, but their patterns of occurrence are less regular and less frequent than AA. The calculated spacings between consecutive preferred nucleosome locations on mouse satellite DNA are nearly identical, corresponding to multiples of 9.7 bp. The correlation between the periodicity of dinucleotide occurrences and the average spacing of nucleosome positions suggests that the preferred nucleosome locations recur at intervals that may correspond to the DNA helical repeat in the mouse satellite nucleosomes, and that the histone octamers sample (or slip along) the duplex in steps of 9.7 bp during nucleosome formation on mouse satellite DNA.     

Attenuation of DNA charge transport by compaction into a nucleosome core particle

The nucleosome core particle (NCP) is the fundamental building block of chromatin which compacts ~146 bp of DNA around a core histone protein octamer. The effects of NCP packaging on long-range DNA charge transport reactions have not been adequately assessed to date. Here we study DNA hole transport reactions in a 157 bp DNA duplex (AQ-157TG) incorporating multiple repeats of the DNA TG-motif, a strong NCP positioning sequence and a covalently attached Anthraquinone photooxidant. Following a thorough biophysical characterization of the structure of AQ-157TG NCPs by Exonuclease III and hydroxyl radical footprinting, we compared the dynamics of DNA charge transport in ultraviolet-irradiated free and NCP-incorporated AQ-157TG. Compaction into a NCP changes the charge transport dynamics in AQ-157TG drastically. Not only is the overall yield of oxidative lesions decreased in the NCPs, but the preferred sites of oxidative damage change as well. This NCP-dependent attenuation of DNA charge transport is attributed to DNA–protein interactions involving the folded histone core since removal of the histone tails did not perturb the charge transport dynamics in AQ-157TG NCPs.     

Anatomy and dynamics of DNA replication fork movement in yeast telomeric regions

Replication initiation and replication fork movement in the subtelomeric and telomeric DNA of native Y' telomeres of yeast were analyzed using two-dimensional gel electrophoresis techniques. Replication origins (ARSs) at internal Y' elements were found to fire in early-mid-S phase, while ARSs at the terminal Y' elements were confirmed to fire late. An unfired Y' ARS, an inserted foreign (bacterial) sequence, and, as previously reported, telomeric DNA each were shown to impose a replication fork pause, and pausing is relieved by the Rrm3p helicase. The pause at telomeric sequence TG(1-3) repeats was stronger at the terminal tract than at the internal TG(1-3) sequences located between tandem Y' elements. We show that the telomeric replication fork pause associated with the terminal TG(1-3) tracts begins approximately 100 bp upstream of the telomeric repeat tract sequence. Telomeric pause strength was dependent upon telomere length per se and did not require the presence of a variety of factors implicated in telomere metabolism and/or known to cause telomere shortening. The telomeric replication fork pause was specific to yeast telomeric sequence and was independent of the Sir and Rif proteins, major known components of yeast telomeric heterochromatin.     

Aspects of large-scale chromatin structures in mouse liver nuclei can be predicted from the DNA sequence

The large amount of non-coding DNA present in mammalian genomes suggests that some of it may play a structural or functional role. We provide evidence that it is possible to predict computationally, from the DNA sequence, loci in mouse liver nuclei that possess distinctive nucleosome arrays. We tested the hypothesis that a 100 kb region of DNA possessing a strong, in-phase, dinucleosome period oscillation in the motif period-10 non-T, A/T, G, should generate a nucleosome array with a nucleosome repeat that is one-half of the dinucleosome oscillation period value, as computed by Fourier analysis of the sequence. Ten loci with short repeats, that would be readily distinguishable from the pervasive bulk repeat, were predicted computationally and then tested experimentally. We estimated experimentally that less than 20% of the chromatin in mouse liver nuclei has a nucleosome repeat length that is 15 bp, or more, shorter than the bulk repeat value of 195 ± bp. All 10 computational predictions were confirmed experimentally with high statistical significance. Nucleosome repeats as short as 172 ± 5 bp were observed for the first time in mouse liver chromatin. These findings may be useful for identifying distinctive chromatin structures computationally from the DNA sequence.     

A new rice repetitive DNA shows sequence homology to both 5S RNA and tRNA.

Moderately repetitive DNA sequences are found in the genomes of all eucaryotes that have been examined. We now report the discovery of a novel, transcribed, moderately repetitive DNA sequence in a higher plant which is different from any of the known repetitive DNA sequences from any organism. We isolated a rice cDNA clone which hybridizes to multiple bands on genomic blot analysis. The sequence of this 352 bp cDNA contains four regions of homology to the wheat phenylalanine tRNA, including the polymerase III-type promoter. Unexpectedly, two regions of the same 352 bp sequence also show homology to the wheat 5S RNA sequence. Using the cDNA as a probe, we have isolated six genomic clones which contain long tandem repeats of 355 bp sequence, and have sequenced nine repeat units. Our findings suggest that the rice repetitive sequence may be an amplified pseudogene with sequence homology to both 5S RNA and tRNA, but organized as long tandem repeats resembling 5S RNA genes. This is the first example showing homology between the sequences of a moderately repetitive DNA with unknown function and 5S RNA.     

Construction of tandem repeats of DNA fragments by a polymerase chain reaction-based method

We describe a new application of megaprimer polymerase chain reaction (PCR) for constructing a tandemly repeated DNA sequence using the drought responsive element (DRE) from Arabidopsis thaliana as an example. The key feature in the procedure was PCR primers with partial complementarity but differing melting temperatures (T(m)). The reverse primer had a higher T(m), a 3' end complementary to the DRE sequence and a 5' region complementary to the forward primer. The initial cycles of the PCR were conducted at a lower primer annealing temperature to generate products that served as megaprimers in the later cycles conducted at a higher temperature to prevent annealing of the forward primer. The region of overlap between the megaprimers was extended for generating products with a variable copy number (one to four copies) of tandem DRE sequence repeats (71?bp). The PCR product with four tandem repeats (4× DRE) was used as a template to generate tandem repeats with higher copies (copy number large than four) or demonstrated to bind DRE-binding protein in an yeast one-hybrid assay using promotorless reporter genes (HIS and lacZ). This PCR protocol has numerous applications for generating DNA fragments of repeated sequences.     

Polymorphic sequence in the D-loop region of equine mitochondrial DNA

The D-loop regions in equine mitochondrial DNA were cloned from three thoroughbred horses by polymerase chain reaction (PCR). The total number of bases in the D-loop region were 1114bp, 1115bp and 1146bp. The equine D-loop region is A/T rich like many other mammalian D-loops. The large central conserved sequence block and small conserved sequence blocks 1, 2 and 3, that are common to other mammals, were observed. Between conserved sequence blocks 1 and 2 there were tandem repeats of an 8bp equine-specific sequence TGTGCACC, and the number of tandem repeats differed among individual horses. The base composition in the unit of these repeats is G/C rich as are the short repeats in the D-loops of rabbit and pig. Comparing DNA sequences between horse and other mammals, the difference in the D-loop region length is mostly due to the difference in the number of DNA sequences at both extremities. The similarities of the DNA sequences are in the middle part of the D-loop. In comparison of the sequences among three thoroughbred horses, it was determined that the region between tRNA^Pro and the large central conserved sequence block was the richest in variation. PCR primers in the D-loop region were designed and the expected maternal inheritance was confirmed by PCR-RFLP (restriction fragment length polymorphism).     

The highly variable pentameric repeats of the AT-rich germline limited DNA in Parascaris univalens are the telomeric repeats of somatic chromosomes.

We have characterized the organization of the germline limited DNA of P. univalens by means of sequence analysis. The repeat unit of this satellite DNA is the pentanucleotide 5'TTGCA, although there is a high degree of sequence variation. Repeat variants are not arranged in tandem but in a disperse, nonrandom manner. In the somatic genome which arises from the germline genome through extensive genomic rearrangement early in development, copies of these pentamers represent the telomeric repeats, indicated by their sensitivity to Bal 31 and their presence in a somatic endlibrary. Unlike telomeric sequences from other species the P. univalens telomeres do not display consecutive guanines and no strand bias for that base, recently suggested as universal features of eukaryotic telomeres. Investigation of fragments that carry pentameric repeats along with sequences of different type identifies a 5 bp consensus sequence at the junction point. We suggest a model in which pentameric repeats originate via amplification by a terminal transferase (telomerase) in both the germline and the somatic genome.     

Both DNA and histone fold sequences contribute to archaeal nucleosome stability.

The roles and interdependence of DNA sequence and archaeal histone fold structure in determining archaeal nucleosome stability and positioning have been determined and quantitated. The presence of four tandem copies of TTTAAAGCCG in the polylinker region of pLITMUS28 resulted in a DNA molecule with increased affinity (DeltaDeltaG of approximately 700 cal mol(-1)) for the archaeal histone HMfB relative to the polylinker sequence, and the dominant, quantitative contribution of the helical repeats of the dinucleotide TA to this increased affinity has been established. The rotational and translational positioning of archaeal nucleosomes assembled on the (TTTAAAGCCG)(4) sequence and on DNA molecules selectively incorporated into archaeal nucleosomes by HMfB have been determined. Alternating A/T- and G/C-rich regions were located where the minor and major grooves, respectively, sequentially faced the archaeal nucleosome core, and identical positioning results were obtained using HMfA, a closely related archaeal histone also from Methanothermus fervidus. However, HMfA did not have similarly high affinities for the HMfB-selected DNA molecules, and domain-swap experiments have shown that this difference in affinity is determined by residue differences in the C-terminal region of alpha-helix 3 of the histone fold, a region that is not expected to directly interact with DNA. Rather this region is thought to participate in forming the histone dimer:dimer interface at the center of an archaeal nucleosome histone tetramer core. If differences in this interface do result in archaeal histone cores with different sequence preferences, then the assembly of alternative archaeal nucleosome tetramer cores could provide an unanticipated and novel structural mechanism to regulate gene expression.     

Atomic force microscopy sees nucleosome positioning and histone H1-induced compaction in reconstituted chromatin.

We addressed the question of how nuclear histones and DNA interact and form a nucleosome structure by applying atomic force microscopy to an in vitro reconstituted chromatin system. The molecular images obtained by atomic force microscopy demonstrated that oligonucleosomes reconstituted with purified core histones and DNA yielded a 'beads on a string' structure with each nucleosome trapping 158 +/- 27 bp DNA. When dinucleosomes were assembled on a DNA fragment containing two tandem repeats of the positioning sequence of the Xenopus 5S RNA gene, two nucleosomes were located around each positioning sequence. The spacing of the nucleosomes fluctuated in the absence of salt and the nucleosomes were stabilized around the range of the positioning signals in the presence of 50 mM NaCl. An addition of histone H1 to the system resulted in a tight compaction of the dinucleosomal structure.     

Deletion analysis of a DNA sequence that positions itself precisely on the nucleosome core

Exonuclease III digests DNA sequentially from the 3' end. This enzyme is used to analyse the location of nucleosomes on DNA fragments containing a particular 145 base-pair (bp) sequence. When one of these fragments is assembled into chromatin and digested with exonuclease, a strong and persistent pause in digestion is detected at a single location. That this pause is due to the enzyme encountering a nucleosome is suggested, firstly, by its absence from digests of free DNA and, secondly, by the detection of a corresponding pause on the other strand. The two pauses, 146 bp apart, specify the location of a single precisely positioned nucleosome on the DNA fragment. This position corresponds exactly to one of two possible positions of the 145 bp sequence identified previously. A fragment containing only about 80 bp of the original 145 bp continues to position itself in the nucleosome like the parent sequence. Therefore, some of the sequence can be replaced with different DNA without affecting nucleosome positioning. Further exonuclease III analysis of an extensive set of deletions demonstrates that a central region of about 40 bp is essential for positioning the 145 bp sequence. When deletions advance into this region from either side, only a very small proportion of the DNA remains in the original position on the nucleosome. Therefore, the two short lengths of DNA at the edges of the region must each contain all or part of an essential nucleosome-positioning signal. These two critical sequences are symmetrically located across the nucleosome dyad and interact with the same region of histone H3. The sequence TGC occurs at the same place in both sequences; otherwise they are dissimilar.     

Alpha satellite DNA in neotropical primates (Platyrrhini)

The alpha satellite DNA of Old World (catarhine) primates usually consists of similar, but not identical, ca. 170 bp sequences repeated tandemly hundreds to thousands of times. The 170 bp monomeric repeats are components of higher-order repeats, many of which are chromosome specific. Alpha satellites are found exclusively in centromeric regions where they appear to play a role in centromere function. We have found that alpha satellite DNA in neotropical (New World; platyrrhine) primates is very similar to its Old World counterpart: it consists of divergent ca. 170 bp subsequences that are arranged in tandem arrays with a ca. 340 bp periodicity. New and Old World alpha satellites share about 64% sequence identity overall, and contain several short sequence motifs that appear to be highly conserved. One exception to the tandemly arrayed 340 bp motif has been found: the major alpha satellite array in Chiropotes satanas (black bearded saki) has a 539 bp repeat unit that consists of a 338 bp dimer together with a duplication of 33 bp of the first monomeric unit and 168 bp of the second monomeric unit.     

Analysis of the sequence of repeats in divergent regions of maxi-circular DNA from kinetoplasts of Crithidia oncopelti

The nucleotide sequence of direct clustered repeats from the divergent region of the maxicircle kinetoplast (mitochondrial) DNA from the protozoan Crithidia oncopelti was analysed. 10 kbp long divergent region contains 3 clusters composed of 18-23 tandem repeats of 82-83 bp (Sau-repeats) and a single cluster of five 417 bp repeats (EcoRI-repeats). The clusters are interspersed between the regions of nonrepetitive DNA. The details of the structural organization of repeats and their clusters were considered on the nucleotide sequence level. The possible ways of origin of the clusters are discussed.     

Comparative analysis of tandem repeats from hundreds of species reveals unique insights into centromere evolution

Background

Centromeres are essential for chromosome segregation, yet their DNA sequences evolve rapidly. In most animals and plants that have been studied, centromeres contain megabase-scale arrays of tandem repeats. Despite their importance, very little is known about the degree to which centromere tandem repeats share common properties between different species across different phyla. We used bioinformatic methods to identify high-copy tandem repeats from 282 species using publicly available genomic sequence and our own data.

Results

Our methods are compatible with all current sequencing technologies. Long Pacific Biosciences sequence reads allowed us to find tandem repeat monomers up to 1,419 bp. We assumed that the most abundant tandem repeat is the centromere DNA, which was true for most species whose centromeres have been previously characterized, suggesting this is a general property of genomes. High-copy centromere tandem repeats were found in almost all animal and plant genomes, but repeat monomers were highly variable in sequence composition and length. Furthermore, phylogenetic analysis of sequence homology showed little evidence of sequence conservation beyond approximately 50 million years of divergence. We find that despite an overall lack of sequence conservation, centromere tandem repeats from diverse species showed similar modes of evolution.

Conclusions

While centromere position in most eukaryotes is epigenetically determined, our results indicate that tandem repeats are highly prevalent at centromeres of both animal and plant genomes. This suggests a functional role for such repeats, perhaps in promoting concerted evolution of centromere DNA across chromosomes.     

Nucleotide sequence, genomic organization and evolution of a major repetitive DNA family in tilapia (Oreochromis mossambicus/hornorum).

A highly repetitive DNA sequence from tilapia (Oreochromis mossambicus/hornorum) has been cloned and sequenced. It is a tandemly arrayed sequence of 237 bp and constitutes 7% of the fish genome. The copy number of the repeat is approximately 3 x 10(5) per haploid genome. DNA sequence analysis of 7 cloned repeats revealed a high degree of conservation of the monomeric unit. Within the monomeric unit, a 9 bp AT rich motif is regularly spaced approximately 30 bp apart and may represent the progenitor of the amplified sequence. One cloned repeat, Ti-14, contained a 30 bp deletion at a position flanked by a 7 bp direct repeat. The Ti-14 sequence appears to have been amplified independently of the major 237 bp tandem array. A higher-order repeat unit, defined by longer-range periodicities revealed by restriction endonuclease digestion, is further imposed on the tandem array.     

Multiple Aspects of ATP-Dependent Nucleosome Translocation by RSC and Mi-2 Are Directed by the Underlying DNA Sequence

Background

Chromosome structure, DNA metabolic processes and cell type identity can all be affected by changing the positions of nucleosomes along chromosomal DNA, a reaction that is catalysed by SNF2-type ATP-driven chromatin remodelers. Recently it was suggested that in vivo, more than 50% of the nucleosome positions can be predicted simply by DNA sequence, especially within promoter regions. This seemingly contrasts with remodeler induced nucleosome mobility. The ability of remodeling enzymes to mobilise nucleosomes over short DNA distances is well documented. However, the nucleosome translocation processivity along DNA remains elusive. Furthermore, it is unknown what determines the initial direction of movement and how new nucleosome positions are adopted.

Methodology/Principal Findings

We have used AFM imaging and high resolution PAGE of mononucleosomes on 600 and 2500 bp DNA molecules to analyze ATP-dependent nucleosome repositioning by native and recombinant SNF2-type enzymes. We report that the underlying DNA sequence can control the initial direction of translocation, translocation distance, as well as the new positions adopted by nucleosomes upon enzymatic mobilization. Within a strong nucleosomal positioning sequence both recombinant Drosophila Mi-2 (CHD-type) and native RSC from yeast (SWI/SNF-type) repositioned the nucleosome at 10 bp intervals, which are intrinsic to the positioning sequence. Furthermore, RSC-catalyzed nucleosome translocation was noticeably more efficient when beyond the influence of this sequence. Interestingly, under limiting ATP conditions RSC preferred to position the nucleosome with 20 bp intervals within the positioning sequence, suggesting that native RSC preferentially translocates nucleosomes with 15 to 25 bp DNA steps.

Conclusions/Significance

Nucleosome repositioning thus appears to be influenced by both remodeler intrinsic and DNA sequence specific properties that interplay to define ATPase-catalyzed repositioning. Here we propose a successive three-step framework consisting of initiation, translocation and release steps to describe SNF2-type enzyme mediated nucleosome translocation along DNA. This conceptual framework helps resolve the apparent paradox between the high abundance of ATP-dependent remodelers per nucleus and the relative success of sequence-based predictions of nucleosome positioning in vivo.     

Circles with two tandem LTRs are precursors to integrated retrovirus DNA

Infection of susceptible cells by retroviruses results in the synthesis of linear DNA with two long terminal repeats (LTRs), circular DNA with a single LTR, and circular DNA with two tandem LTRs. To determine which of these unintegrated molecules serves as the precursor to the provirus, we inserted into a retrovirus vector a 49 bp fragment containing the junction formed by in vivo blunt-end ligation of two LTRs. Infection of chicken embryo fibroblasts with virus recovered from this vector and subsequent characterization of the proviral DNA revealed that efficient integration can occur from this introduced junction sequence. Therefore, circular DNA with two tandem LTRs is a precursor to the provirus.