Nucleotide sequence-directed mapping of the nucleosomes of SV40 chromatin

Molecular biology, epidemiology, and pathogenesis of progressive multifocal leukoencephalopathy, the JC virus-induced demyelinating disease of the human brain

Progressive multifocal leukoencephalopathy (PML) is a debilitating and frequently fatal central nervous system (CNS) demyelinating disease caused by JC virus (JCV), for which there is currently no effective treatment. Lytic infection of oligodendrocytes in the brain leads to their eventual destruction and progressive demyelination, resulting in multiple foci of lesions in the white matter of the brain. Before the mid-1980s, PML was a relatively rare disease, reported to occur primarily in those with underlying neoplastic conditions affecting immune function and, more rarely, in allograft recipients receiving immunosuppressive drugs. However, with the onset of the AIDS pandemic, the incidence of PML has increased dramatically. Approximately 3 to 5% of HIV-infected individuals will develop PML, which is classified as an AIDS-defining illness. In addition, the recent advent of humanized monoclonal antibody therapy for the treatment of autoimmune inflammatory diseases such as multiple sclerosis (MS) and Crohn's disease has also led to an increased risk of PML as a side effect of immunotherapy. Thus, the study of JCV and the elucidation of the underlying causes of PML are important and active areas of research that may lead to new insights into immune function and host antiviral defense, as well as to potential new therapies.

Sequence signatures of nucleosome positioning in Caenorhabditis elegans

Our recent investigation in the protist Trichomonas vaginalis suggested a DNA sequence periodicity with a unit length of 120.9 nt, which represents a sequence signature for nucleosome positioning. We now extended our observation in higher eukaryotes and identified a similar periodicity of 175 nt in length in Caenorhabditis elegans. In the process of defining the sequence compositional characteristics, we found that the 10.5-nt periodicity, the sequence signature of DNA double helix, may not be sufficient for cross-nucleosome positioning but provides essential guiding rails to facilitate positioning. We further dissected nucleosome-protected sequences and identified a strong positive purine (AG) gradient from the 5′-end to the 3′-end, and also learnt that the nucleosome-enriched regions are GC-rich as compared to the nucleosome-free sequences as purine content is positively correlated with GC content. Sequence characterization allowed us to develop a hidden Markov model (HMM) algorithm for decoding nucleosome positioning computationally, and based on a set of training data from the fifth chromosome of C. elegans, our algorithm predicted 60%-70% of the well-positioned nucleosomes, which is 15%-20% higher than random positioning. We concluded that nucleosomes are not randomly positioned on DNA sequences and yet bind to different genome regions with variable stability, well-positioned nucleosomes leave sequence signatures on DNA, and statistical positioning of nucleosomes across genome can be decoded computationally based on these sequence signatures.

Construction of nucleosome cores from defined sequence DNA of viral origin

The de novo construction of defined nucleosomes from two DNA fragments of simian virus SV40 is described. One fragment spans the region containing the origin of replication of the virus from base -16 to base 161, a region which is nucleosome-free during virus replication. The other fragment, of 142 bp (1352 to 1493), is within the region coding for viral proteins VP2 and VP3, and serves for comparison. Both fragments form nucleosomes with similar efficiency when combined with histone cores as well as when exchanged with existing core particles. The DNase I digestion pattern and exonuclease III analysis both indicate that true nucleosome cores are formed, and that a prolonged tail is not protruding from the constructs. The efficient formation of a nucleosome core particle from the origin region of DNA implies that the absence of nucleosomes from this region during viral infection is not prescribed by the specific base sequence of origin DNA, and is therefore likely to be determined by non-histone nuclear factors associated with the SV40 replication process.

Preferred positions of AA and TT dinucleotides in aligned nucleosomal DNA sequences

Multiple alignment of 118 nucleosomal DNA sequences by maximizing simultaneously match of AA dinucleotides and match of TT dinucleotides results in a pattern of the dinucleotide distributions which is characteristic of the nucleosomal DNA sequences. The AA dinucleotides are found to be distributed symmetrically relative to the TT dinucleotide distribution, around the middle point of the nucleosomal DNA sequence. The distances between major peaks of the distributions are multiples of about 10.4 bases. The peaks of the TT distribution are shifted by 6 bases downstream from the peaks of the AA distribution.

The effect of the simple repeating d(CG.GC)n, d(CA.GT)n, and d(A.T)n DNA sequences on the nucleosomal organization of SV40 minichromosomes

The effect of several simple repeating DNA sequences--d(CG.GC)5, d(CA.GT)30, and d(A.T)60--on the nucleosomal organization of the SV40 minichromosome is analyzed. These three different sequences were cloned at the Hpa II site of SV40 (position 346) which occurs at the 3' border of the nucleosome-free SV40 control region. Our results show that neither the d(A.T)60 sequence nor the d(CG.GC)5 sequence appear to have any relevant effect on the nucleosomal organization of the region of the minichromosome surrounding the inserted repeated sequence. Both sequences are hypersensitive to micrococcal nuclease cleavage in the minichromosome, indicating that they are not organized into nucleosomes. On the other hand, the d(CA.GT)30 sequence is found organized as nucleosomes and causes the delocation of nucleosomes in the minichromosomal region close to the inserted repeated sequence.

In vitro assembly of a positioned nucleosome near the hypersensitive region in simian virus 40 chromatin

Previous studies have identified a nucleosome near a potential late boundary for the nuclease-hypersensitive region in simian virus 40 chromatin. We have performed in vitro reconstitution analysis to determine whether the underlying DNA sequence encodes for the assembly of this nucleosome and applied hydroxyl radical and DNase I footprinting techniques to examine the structure of the reconstituted nucleosome. Both methods revealed the formation of a precisely positioned nucleosome in vitro, on a fragment spanning the strong in vivo nucleosome location site determined previously in the viral chromatin. The center of the positioned nucleosome maps between nucleotide 384 and 387 on simian virus 40 DNA. The corresponding nucleosome core includes the major-late transcription site (12 base-pairs within the core), the MspI site, and a segment shown previously to adopt a bent structure in the absence of proteins. The hydroxyl radical produces a strikingly well-defined cleavage pattern over the bent DNA incorporated in nucleosomes. The dominant periodicity of DNA in this nucleosome is 10.26 base-pairs per turn. The distribution of the .OH cut sites in the positioned nucleosome provides strong support for models in which the minor grooves of the A/T-rich tracts are oriented toward the histone core while the minor grooves of the G/C-rich sequences are facing outward.

Location of nucleosomes in simian virus 40 chromatin

Over the past decade, the results of numerous indirect mappings analyses have not clarified whether or not nucleosomes occupy preferred positions in simian virus 40 (SV40) chromatin. To address this question more directly, we followed a shotgun cloning approach and determined the nucleotide sequences of over 400 cloned nucleosomal DNA fragments obtained from digestion of SV40 chromatin with micrococcal nuclease. Our results demonstrate and establish that nucleosomes do not occupy unique positions in SV40 minichromosomes and thus indicate the existence of at least several types of chromatin molecules having different nucleosome organization patterns. We developed two types of statistical analysis in order to examine the cloning data in greater detail. One type, overlap analysis, revealed the distribution of the cloned fragments with respect to SV40 DNA. The distribution exhibits an oscillating pattern, dividing the genome into regions of weak or strong nucleosome density. The other analysis determined the distribution of the midpoints of the cloned fragments and revealed potential strong and weak nucleosome location sites, and an early versus late distinction in organization of nucleosomes in SV40 chromatin. The late region appears to contain more strong nucleosome location sites (8) than the early region (4). The strongest nucleosome abuts the late side of the nuclease-hypersensitive region and includes the major transcription initiation site of the late genes. Another strong site precedes this nucleosome and includes sequences implicated in controlling the expression of the SV40 early and late genes. A strong or weak nucleosome location site is not apparent near the early side of the nucleosome-hypersensitive region. Only weak and overlapping nucleosome location sites are found in the region where replication terminates in the SV40 minichromosomes.

In situ nucleoprotein structure at the SV40 major late promoter: melted and wrapped DNA flank the start site

New in situ probing methods have been developed and used to probe the nucleoprotein structures at the SV40 major late promoter in infected monkey cells. The region that contains the three proximal transcription elements was probed with DNase I and micrococcal nuclease in transcriptionally active, permeabilized cells, and with the single-strand selective reagent KMnO4 in intact cells. The downstream element is included in a region of enhanced DNase I reactivity at 10- to 11-bp intervals for approximately 140 bp, presumably because of DNA wrapping around a specifically positioned nucleosome particle. The two other proximal DNA elements appear to be mostly melted, with a protecting factor bound primarily to the template DNA strand. The protecting factor directly borders the wrapped particle. These observations provide an initial description of parts of the biological transcription machinery and suggest that the SV40 major late promoter elements are part of a higher order nucleoprotein complex that involves wrapped and melted DNA.

Structure of the nucleosome core particle at 8 A resolution

The x-ray crystallographic structure of the nucleosome core particle has been determined using 8 A resolution diffraction data. The particle has a mean diameter of 106 A and a maximum thickness of 65 A in the superhelical axis direction. The longest chord through the histone core measures 85 A and is in a non-axial direction. The 1.87 turn superhelix consists of B-DNA with about 78 base pairs or 7.6 helical repeats per superhelical turn. The mean DNA helical repeat contains 10.2 +/- 0.05 base pairs and spans 35 A, slightly more than standard B-DNA. The superhelix varies several Angstroms in radius and pitch, and has three distinct domains of curvature (with radii of curvature of 60, 45 and 51 A). These regions are separated by localized sharper bends +/- 10 and +/- 40 base pairs from the center of the particle, resulting in an overall radius of curvature about 43 A. Compression of superhelical DNA grooves on the inner surface and expansion on the outer surface can be seen throughout the DNA electron density. This density has been fit with a double helical ribbon model providing groove width estimates of 12 +/- 1 A inside vs. 19 +/- 1 A outside for the major groove, and 8 +/- 1 A inside vs. 13 +/- 1 A outside for the minor groove. The histone core is primarily contained within the bounds defined by the superhelical DNA, contacting the DNA where the phosphate backbone faces in toward the core. Possible extensions of density between the gyres have been located, but these are below the significance level of the electron density map. In cross-section, a tripartite organization of the histone octamer is apparent, with the tetramer occupying the central region and the dimers at the extremes. Several extensions of histone density are present which form contacts between nucleosomes in the crystal, perhaps representing flexible or "tail" histone regions. The radius of gyration of the histone portion of the electron density is calculated to be 30.4 A (in reasonable agreement with solution scattering values), and the histone core volume in the map is 93% of its theoretical volume.

Mapping in vivo topoisomerase I sites on simian virus 40 DNA: asymmetric distribution of sites on replicating molecules

Complexes between simian virus 40 DNA and topoisomerase I (topo I) were isolated from infected cells treated with camptothecin. The topo I break sites were precisely mapped by primer extension from defined oligonucleotides. Of the 56 sites, 40 conform to the in vitro consensus sequence previously determined for topo I. The remaining 16 sites have an unknown origin and were detectable even in the absence of camptothecin. Only 11% of the potential break sites were actually broken in vivo. In the regions mapped, the pattern of break sites was asymmetric. Most notable are the clustering of sites near the terminus for DNA replication and the confinement of sites to the strand that is the template for discontinuous DNA synthesis. These asymmetries could reflect the role of topo I in simian virus 40 DNA replication and suggest that topo I action is coordinated spatially with that of the replication complex.

Mapping in vivo topoisomerase I sites on simian virus 40 DNA: asymmetric distribution of sites on replicating molecules

Complexes between simian virus 40 DNA and topoisomerase I (topo I) were isolated from infected cells treated with camptothecin. The topo I break sites were precisely mapped by primer extension from defined oligonucleotides. Of the 56 sites, 40 conform to the in vitro consensus sequence previously determined for topo I. The remaining 16 sites have an unknown origin and were detectable even in the absence of camptothecin. Only 11% of the potential break sites were actually broken in vivo. In the regions mapped, the pattern of break sites was asymmetric. Most notable are the clustering of sites near the terminus for DNA replication and the confinement of sites to the strand that is the template for discontinuous DNA synthesis. These asymmetries could reflect the role of topo I in simian virus 40 DNA replication and suggest that topo I action is coordinated spatially with that of the replication complex.

Generation of different nucleosome spacing periodicities in vitro. Possible origin of cell type specificity

We have been able to generate ordered nucleosome arrays that span the physiological range of spacing periodicities, using an in vitro system. Our system (a refinement of the procedure previously developed) uses the synthetic polynucleotide poly[d(A-T)], poly[d(A-T)], core histones, purified H1, and polyglutamic acid, a factor that increases nucleohistone solubility and greatly promotes the formation of ordered nucleosome arrays. This system has three useful features, not found in other chromatin assembly systems. First, it allowed us to examine histones from three different cell types/species (sea urchin sperm, chicken erythrocyte, and HeLa) as homologous or heterologous combinations of core and H1 histones. Second, it allowed us to control the average packing density (core histone to polynucleotide weight ratio) of nucleosomes on the polynucleotide; histone H1 is added in a second distinct step in the procedure to induce nucleosome alignment. Third, it permitted us to study nucleosome array formation in the absence of DNA base sequence effects. We show that the value of the spacing periodicity is controlled by the value of the initial average nucleosome packing density. The full range of physiological periodicities appears to be accessible to arrays generated using chicken erythrocyte (or HeLa) core histones in combination with chicken H5. However, chromatin-like structures cannot be assembled for some nucleosome packing densities in reactions involving some histone types, thus limiting the range of periodicities that can be achieved. For example, H1 histone types differ significantly in their ability to recruit disordered nucleosomes into ordered arrays at low packing densities. Sea urchin sperm H1 is more efficient than chicken H5, which is more efficient than H1 from HeLa or chicken erythrocyte. Sea urchin sperm core histones are more efficient in this respect than the other core histone types used. These findings suggest how different repeat lengths arise in different cell types and species, and provide new insights into the problems of nucleosome linker heterogeneity and how different types of chromatin structures could be generated in the same cell.

DNA sequence patterns in precisely positioned nucleosomes

Several investigators have recognized the importance of non-periodic DNA sequence information in determining the translational position of precisely positioned nucleosomes. The purpose of this study is to determine the extent of such information, in addition to the character of periodic information present. This is accomplished by examining the half-nucleosome DNA sequences of a considerable number of precisely positioned nucleosomes, and determining the probability of occurrence of each dinucleotide type as a function of position from the nucleosome center to the terminus (positions 0 to 72). By the nature of this procedure, no assumptions of periodicity are made. The results show the importance of several DNA sequence periodicities including 6-7, 10, and 21 base pairs, in addition to significant nonperiodic information. The results demonstrate that each dinucleotide type is unique in terms of its positional preference in precisely positioned nucleosomes (for example AA not equal to TT). The probabilities of occurrence for the dinucleotide types can be used to predict the translational positions of a number of observed nucleosomes.

Generation of high specificity of effect through low-specificity binding of proteins to DNA

It is proposed that proteins can bind with relatively low-affinity and specificity to multiple sites, defined as sequence motifs, on polynucleotide chains, and that such binding can collectively be turned into high-affinity, high-specificity binding through cooperative effects, especially when the sequence motifs recur periodically. The selection of individual nucleotides has in general been thought to be the condition of the existence and conservation of function in most of the noncoding sequences. This condition seems unnecessary. Calculations are presented as a step in the direction of giving credibility to a model of stable gene repression.

The terminus of SV40 DNA replication and transcription contains a sharp sequence-directed curve

We have examined nucleosome positioning on two DNA segments containing sharp sequence-directed curvatures. A 223 bp DNA from Crithidia fasciculata was cloned into two sites in pBR325 separated by 28%. These sites were found to selectively reconstitute nucleosomes 5- to 7-fold more effectively than the adjoining straight DNA. The terminus of replication and termini of transcription of SV40 DNA are contained within a region of approximately 200 bp centrally located in a 1216 bp fragment. Visualization of this fragment by electron microscopy revealed a sharp curve of approximately 200 degrees in the terminal region. Reconstitution of histone protein with this fragment revealed a 2- to 5-fold higher probability of assembling nucleosomes in the terminal region over the adjacent DNA.

The SV40 termination region exhibits an altered helical DNA conformation

The DNA structure of a fragment containing the SV40 termination sequences was examined using gel mobility assays. The region is shown to contain a DNA bend as evidenced by an abnormal mobility that is progressively accentuated as the temperature is lowered. This represents the strongest example of DNA bending among the collection of SV40 fragments studied. The same fragment was shown previously to uniquely support hyper-stable nucleosome formation in vitro, suggesting a possible relationship between DNA bending and nucleosome stability.

Curved DNA

A priori considerations and the concept of the sequence-dependent local curving of the DNA axis. Experimental evidence: electric dichroism (relaxation time measurements); anomalous electrophoretic mobility and gel-filtration of some restriction fragments of DNA; one-sided binding of the nucleosomal DNA to the mica surface. Theoretical predictions concerning the nucleotide sequences of the curved DNA. Discovery of the dinucleotide periodicity in the chromatin DNA. The sequence periodicity as a tool for mapping of the nucleosomes along the sequences. Preferential binding of the histone octamers to the curved pieces of DNA--sequence analysis predictions and comparison with experiments: Theoretical and experimental estimates of the tilt and roll angles for different combinations of the neighboring base-pairs. Inherent sequence-dependent curvature and apparent persistence length of DNA.

Simian virus 40 replication pause sites map with the nucleosomes

The locations of replication pause sites in the simian virus 40 minichromosome which were determined by sizing cloned fragments of nascent DNA (Zannis-Hadjopoulos et al., J. Mol. Biol. 165:599-607, 1983) were compared with the positions of simian virus 40 nucleosomes in the genome, as obtained by sequence-directed mapping (G. Mengeritsky and E. N. Trifonov, Nucleic Acids Res. 11:3833-3851, 1983; Mengeritsky and Trifonov, Cell Biophys. 6:1-8, 1984). Clear correlation between these two maps is demonstrated, suggesting that nucleosomes hinder propagation of the replication forks.