Replication fork pausing at protein barriers on chromosomes.

When a cell divides prior to completion of DNA replication, serious DNA damage may occur. Thus, in addition to accuracy, the processivity of the replication forks is important. DNA synthesis at replication forks should be completed in time, and forks overcome aberrant structures on the template DNA, including damaged sites, using trans-lesion synthesis, occasionally introducing mutations. By contrast, the protein barrier built on the DNA is known to block the progression of replication forks at specific chromosomal loci. Such protein barriers avert any collision of replication and transcription machineries, or control the recombination of specific loci. The components and the mechanisms of action of protein barriers have been revealed mainly using genetic and biochemical techniques. In addition to proteins involved in replication fork pausing, the interaction of the replicative helicase and DNA polymerase is also essential for replication fork pausing. Here, we provide an overview of replication fork pausing at protein barriers.

DNA polymerase ε-dependent modulation of the pausing property of the CMG helicase at the barrier.

The proper pausing of replication forks at barriers on chromosomes is important for genome integrity. However, the detailed mechanism underlying this process has not been well elucidated. Here, we successfully reconstituted fork-pausing reactions from purified yeast proteins on templates that had binding sites for the LacI, LexA, and/or Fob1 proteins; the forks paused specifically at the protein-bound sites. Moreover, although the replicative helicase Cdc45-Mcm2-7-GINS (CMG) complex alone unwound the protein-bound templates, the unwinding of the LacI-bound site was impeded by the presence of a main leading strand DNA polymerase: polymerase ε (Polε). This suggests that Polε modulates CMG to pause at these sites.

Flexible DNA Path in the MCM Double Hexamer Loaded on DNA.

The formation of the pre-replicative complex (pre-RC) during the G1 phase, which is also called the licensing of DNA replication, is the initial and essential step of faithful DNA replication during the subsequent S phase. It is widely accepted that in the pre-RC, double-stranded DNA passes through the holes of two ring-shaped minichromosome maintenance (MCM) 2-7 hexamers; however, the spatial organization of the DNA and proteins involved in pre-RC formation is unclear. Here we reconstituted the pre-RC from purified DNA and proteins and visualized the complex using atomic force microscopy (AFM). AFM revealed that the MCM double hexamers formed elliptical particles on DNA. Analysis of the angle of binding of DNA to the MCM double hexamer suggests that the DNA does not completely pass through both holes of the MCM hexamers, possibly because the DNA exited from the gap between Mcm2 and Mcm5. A DNA loop fastened by the MCM double hexamer was detected in pre-RC samples reconstituted from purified proteins as well as those purified from yeast cells, suggesting a higher-order architecture of the loaded MCM hexamers and DNA strands.

Concerted interaction between origin recognition complex (ORC), nucleosomes and replication origin DNA ensures stable ORC-origin binding.

Chromosomal replication origins, where DNA replication is initiated, are determined in eukaryotic cells by specific binding of a six-subunit origin recognition complex (ORC). Many biochemical analyses have showed the detailed properties of the ORC-DNA interaction. However, because of the lack of in vitro analysis, the molecular architecture of the ORC-chromatin interaction is unclear. Recently, mainly from in vivo analyses, a role of chromatin in the ORC-origin interaction has been reported, including the existence of a specific pattern of nucleosome positioning around origins and of a specific interaction between chromatin-or core histones-and Orc1, a subunit of ORC. Therefore, to understand how ORC establishes its interaction with origin in vivo, it is essential to know the molecular mechanisms of the ORC-chromatin interaction. Here, we show that ORC purified from yeast binds more stably to origin-containing reconstituted chromatin than to naked DNA and forms a nucleosome-free region at origins. Molecular imaging using atomic force microscopy (AFM) shows that ORC associates with the adjacent nucleosomes and forms a larger complex. Moreover, stable binding of ORC to chromatin requires linker DNA. Thus, ORC establishes its interaction with origin by binding to both nucleosome-free origin DNA and neighboring nucleosomes.

Core histone charge and linker histone H1 effects on the chromatin structure of Schizosaccharomyces pombe.

Histones are highly conserved proteins among eukaryotes. However, yeast histones are more divergent in their sequences. In particular, the histone tail regions of the fission yeast, Schizosaccharomyces pombe, have fewer lysine residues, making their charges less positive than those of higher eukaryotes. In addition, the S. pombe chromatin lacks linker histones. How these factors affected yeast chromatin folding was analysed by biochemical reconstitution in combination with atomic force microscopy. Reconstitution of a nucleosome array showed that S. pombe chromatin has a more open structure similar to reconstituted human acetylated chromatin. The S. pombe nucleosomal array formed thinner fibers than those of the human nucleosomal array in the presence of mammalian linker histone H1. Such S. pombe fibers were more comparable to human acetylated fibers. These findings suggest that the core histone charges would determine the intrinsic characteristics of S. pombe chromatin and affect inter-nucleosomal interactions.

Lamin B receptor recognizes specific modifications of histone H4 in heterochromatin formation.

Inner nuclear membrane proteins provide a structural framework for chromatin, modulating transcription beneath the nuclear envelope. Lamin B receptor (LBR) is a classical inner nuclear membrane protein that associates with heterochromatin, and its mutations are known to cause Pelger-Huët anomaly in humans. However, the mechanisms by which LBR organizes heterochromatin remain to be elucidated. Here, we show that LBR represses transcription by binding to chromatin regions that are marked by specific histone modifications. The tudor domain (residues 1-62) of LBR primarily recognizes histone H4 lysine 20 dimethylation and is essential for chromatin compaction, whereas the whole nucleoplasmic region (residues 1-211) is required for transcriptional repression. We propose a model in which the nucleoplasmic domain of LBR tethers epigenetically marked chromatin to the nuclear envelope and transcriptional repressors are loaded onto the chromatin through their interaction with LBR.

Molecular dynamics of DNA and nucleosomes in solution studied by fast-scanning atomic force microscopy.

Nucleosome is a fundamental structural unit of chromatin, and the exposure from or occlusion into chromatin of genomic DNA is closely related to the regulation of gene expression. In this study, we analyzed the molecular dynamics of poly-nucleosomal arrays in solution by fast-scanning atomic force microscopy (AFM) to obtain a visual glimpse of nucleosome dynamics on chromatin fiber at single molecule level. The influence of the high-speed scanning probe on nucleosome dynamics can be neglected since bending elastic energy of DNA molecule showed similar probability distributions at different scan rates. In the sequential images of poly-nucleosomal arrays, the sliding of the nucleosome core particle and the dissociation of histone particle were visualized. The sliding showed limited fluctuation within approximately 50nm along the DNA strand. The histone dissociation occurs by at least two distinct ways: a dissociation of histone octamer or sequential dissociations of tetramers. These observations help us to develop the molecular mechanisms of nucleosome dynamics and also demonstrate the ability of fast-scanning AFM for the analysis of dynamic protein-DNA interaction in sub-seconds time scale.

Nano-scale analyses of the chromatin decompaction induced by histone acetylation.

The acetylation of histone tails is a key factor in the maintenance of chromatin dynamics and cellular homeostasis. The hallmark of active chromatin is the hyper-acetylation of histones, which appears to result in a more open chromatin structure. Although short nucleosomal arrays have been studied, the structural dynamics of relatively long acetylated chromatin remain unclear. We have analyzed in detail the structure of long hyper-acetylated chromatin fibers using atomic force microscopy (AFM). Hyper-acetylated chromatin fibers isolated from nuclei that had been treated with Trichostatin A (TSA), an inhibitor of histone deacetylase, were found to be thinner than those from untreated nuclei. The acetylated chromatin fibers were more easily spread out of nuclei by high-salt treatment, implying that hyper-acetylation facilitates the release of chromatin fibers from compact heterochromatin regions. Chromatin fibers reconstituted in vitro from core histones and linker histone H1 became thinner upon acetylation. AFM imaging indicated that the gyration radius of the nucleosomal fiber increased after acetylation and that the hyper-acetylated nucleosomes did not aggregate at high salt concentrations, in contrast to the behavior of non-acetylated nucleosomal arrays, suggesting that acetylation increases long-range repulsions between nucleosomes. Based on these data, we considered a simple coarse grained model, which underlines the effect of remaining electric charges inside the chromatin fiber.

Removal of histone tails from nucleosome dissects the physical mechanisms of salt-induced aggregation, linker histone H1-induced compaction, and 30-nm fiber formation of the nucleosome array.

In order to reveal the roles of histone tails in the formation of higher-order chromatin structures, we employed atomic force microscopy (AFM), and an in vitro reconstitution system to examine the properties of reconstituted chromatin composed of tail-less histones and a long DNA (106-kb plasmid) template. The tail-less nucleosomes did not aggregate at high salt concentrations or with an excess amount of core histones, in contrast with the behavior of nucleosomal arrays composed of nucleosomes containing normal, N-terminal tails. Analysis of our nucleosome distributions reveals that the attractive interaction between tail-less nucleosomes is weakened. Addition of linker histone H1 into the tail-less nucleosomal array failed to promote the formation of 30nm chromatin fibers that are usually formed in the normal nucleosomal array. These results demonstrate that the attractive interaction between nucleosomes via histone tails plays a critical role in the formation of the uniform 30-nm chromatin fiber.

Single-molecule anatomy by atomic force microscopy and recognition imaging.

Atomic force microscopy (AFM) has been a useful technique to visualize cellular and molecular structures at single-molecule resolution. The combination of imaging and force modes has also allowed the characterization of physical properties of biological macromolecules in relation to their structures. Furthermore, recognition imaging, which is obtained under the TREC(TM) (Topography and RECognition) mode of AFM, can map a specific protein of interest within an AFM image. In this study, we first demonstrated structural properties of purified α Actinin-4 by conventional AFM. Since this molecule is an actin binding protein that cross-bridges actin filaments and anchors it to integrin via tailin-vinculin-α actinin adaptor-interaction, we investigated their structural properties using the recognition mode of AFM. For this purpose, we attached an anti-α Actinin-4 monoclonal antibody to the AFM cantilever and performed recognition imaging against α Actinin-4. We finally succeeded in mapping the epitopic region within the α Actinin-4 molecule. Thus, recognition imaging using an antibody coupled AFM cantilever will be useful for single-molecule anatomy of biological macromolecules and structures.

Nuclear architecture and chromatin dynamics revealed by atomic force microscopy in combination with biochemistry and cell biology.

The recent technical development of atomic force microscopy (AFM) has made nano-biology of the nucleus an attractive and promising field. In this paper, we will review our current understanding of nuclear architecture and dynamics from the structural point of view. Especially, special emphases will be given to: (1) How to approach the nuclear architectures by means of new techniques using AFM, (2) the importance of the physical property of DNA in the construction of the higher-order structures, (3) the significance and implication of the linker and core histones and the nuclear matrix/scaffold proteins for the chromatin dynamics, (4) the nuclear proteins that contribute to the formation of the inner nuclear architecture. Spatio-temporal analyses using AFM, in combination with biochemical and cell biological approaches, will play important roles in the nano-biology of the nucleus, as most of nuclear structures and events occur in nanometer, piconewton and millisecond order. The new applications of AFM, such as recognition imaging, fast-scanning imaging, and a variety of modified cantilevers, are expected to be powerful techniques to reveal the nanostructure of the nucleus.

Topoisomerase II, scaffold component, promotes chromatin compaction in vitro in a linker-histone H1-dependent manner.

TopoisomeraseII (Topo II) is a major component of chromosomal scaffolds and essential for mitotic chromosome condensation, but the mechanism of this action remains unknown. Here, we used an in vitro chromatin reconstitution system in combination with atomic force and fluorescence microscopic analyses to determine how Topo II affects chromosomal structure. Topo II bound to bare DNA and clamped the two DNA strands together, even in the absence of ATP. In addition, Topo II promoted chromatin compaction in a manner dependent on histone H1 but independent of ATP. Histone H1-induced 30-nm chromatin fibers were converted into a large complex by Topo II. Fluorescence microscopic analysis of the Brownian motion of chromatin stained with 4',6-diamidino-2-phenylindole showed that the reconstituted chromatin became larger following the addition of Topo II in the presence but not the absence of histone H1. Based on these findings, we propose that chromatin packing is triggered by histone H1-dependent, Topo II-mediated clamping of DNA strands.

Transcriptional coactivator PC4, a chromatin-associated protein, induces chromatin condensation.

Human transcriptional coactivator PC4 is a highly abundant multifunctional protein which plays diverse important roles in cellular processes, including transcription, replication, and repair. It is also a unique activator of p53 function. Here we report that PC4 is a bona fide component of chromatin with distinct chromatin organization ability. PC4 is predominantly associated with the chromatin throughout the stages of cell cycle and is broadly distributed on the mitotic chromosome arms in a punctate manner except for the centromere. It selectively interacts with core histones H3 and H2B; this interaction is essential for PC4-mediated chromatin condensation, as demonstrated by micrococcal nuclease (MNase) accessibility assays, circular dichroism spectroscopy, and atomic force microscopy (AFM). The AFM images show that PC4 compacts the 100-kb reconstituted chromatin distinctly compared to the results seen with the linker histone H1. Silencing of PC4 expression in HeLa cells results in chromatin decompaction, as evidenced by the increase in MNase accessibility. Knocking down of PC4 up-regulates several genes, leading to the G2/M checkpoint arrest of cell cycle, which suggests its physiological role as a chromatin-compacting protein. These results establish PC4 as a new member of chromatin-associated protein family, which plays an important role in chromatin organization.

Comparative structural biology of the genome: nano-scale imaging of single nucleus from different kingdoms reveals the common physicochemical property of chromatin with a 40 nm structural unit.

Genome function is closely linked to the higher-order chromatin structures. To reveal a structural basis for the interphase chromatin organization, the 'on-substrate' lysis procedure was applied to nuclei isolated from human HeLa cells, chicken erythrocyte cells and yeast Schizosaccharomyces pombe, which possessed different intrinsic properties of the genomes such as histone composition and inter-nucleosomal distance. The isolated nuclei on a coverslip were successively treated with a detergent and a high-salt solution to extract the nuclear membrane and the nucleoplasm, and therefore, atomic force microscopy (AFM) visualized the structural changes in response to the lysis procedure. After the nucleoplasm was extracted, AFM clarified that chromatin fibers, approximately 40 nm in width, were partially released out of the nuclei and that the other chromatin still remaining in the nuclei was composed of granular structures with diameter of 80-100 nm. Thus, these results suggest that the approximately 40 nm fiber would be a stable structural unit and fold the 80-100 nm granules into a one-step higher unit. A common mechanism could be implied regardless of the intrinsic properties of the eukaryotic genomes.

Protective effect of vitamin C against double-strand breaks in reconstituted chromatin visualized by single-molecule observation.

Direct attack to genomic DNA by reactive oxygen species causes various types of lesions, including base modifications and strand breaks. The most significant lesion is considered to be an unrepaired double-strand break that can lead to fatal cell damage. We directly observed double-strand breaks of DNA in reconstituted chromatin stained by a fluorescent cyanine dye, YOYO (quinolinium, 1,1'-[1,3- propanediylbis[(dimethyliminio)-3,1- propanediyl]]bis[4-[(3-methyl-2(3H)-benzoxazolylidene)methyl]]-, tetraiodide), in solution, where YOYO is known to have the ability to photo-cleave DNAs by generating reactive oxygen species. Reconstituted chromatin was assembled from large circular DNA (106 kbp) with core histone proteins. We also investigated the effect of vitamin C (ascorbic acid) on preventing photo-induced double-strand breaks in a quantitative manner. We found that DNA is protected against double-strand breaks by the addition of ascorbic acid, and this protective effect is dose dependent. The effective kinetic constant of the breakage reaction in the presence of 5 mM ascorbic acid is 20 times lower than that in the absence of ascorbic acid. This protective effect of ascorbic acid in reconstituted chromatin is discussed in relation to the highly compacted polynucleosomal structure. The results highlight the fact that single-molecule observation is a useful tool for studying double-strand breaks in giant DNA and chromatin.

Linker histone H1 per se can induce three-dimensional folding of chromatin fiber.

Higher-order architectures of chromosomes play important roles in the regulation of genome functions. To understand the molecular mechanism of genome packing, an in vitro chromatin reconstitution method and a single-molecule imaging technique (atomic force microscopy) were combined. In 50 mM NaCl, well-stretched beads-on-a-string chromatin fiber was observed. However, in 100 mM NaCl, salt-induced interaction between nucleosomes caused partial aggregation. Addition of histone H1 promoted a further folding of the fiber into thicker fibers 20-30 nm in width. Micrococcal nuclease digestion of these thicker fibers produced an approximately 170 bp fragment of nucleosomal DNA, which was approximately 20 bp longer than in the absence of histone H1 ( approximately 150 bp), indicating that H1 is correctly placed at the linker region. The width of the fiber depended on the ionic strength. Widths of 20 nm in 50 mM NaCl became 30 nm as the ionic strength was changed to 100 mM. On the basis of these results, a flexible model of chromatin fiber formation was proposed, where the mode of the fiber compaction changes depending both on salt environment and linker histone H1. The biological significance of this property of the chromatin architecture will be apparent in the closed segments ( approximately 100 kb) between SAR/MAR regions.

Atomic force microscopy demonstrates a critical role of DNA superhelicity in nucleosome dynamics.

Nucleosome is the most basic structural unit of eukaryotic chromosome, forming an 11 nm "beads-on-a-string" fiber. The molecular mechanism of chromatin folding toward higher-order structures (30 nm and thicker fibers) is speculative; however, it is thought to be critical for the regulation of transcription, replication, and chromosome propagation. We examined the relationship between the efficiency of the nucleosome formation and the physical properties of the template DNA. A series of plasmid DNA with different lengths (3, 5, 31, 56, or 106 kb) were prepared and, together with purified histones, used for the reconstitution of chromatin fibers by a salt-dialysis method. The reconstituted chromatin fibers were visualized and analyzed by atomic force microscopy (AFM). Based on the AFM images, the efficiency of the reconstitution was dependent on the length and the negative superhelical strain of the DNA used (i.e., the longer DNA had a higher efficiency in the reconstitution, because the longer plasmids retain much higher superhelical density than the shorter ones). These results suggest that the nucleosome dynamics are tightly coupled with the DNA superhelicity. This was further supported by the fact that the linearized or topoisomerase I-treated plasmids (relaxed circular) showed very low efficiency. Namely, the negative supercoiling promoted the efficient formation of the nucleosome but the positive supercoiling strongly inhibited it.

Fundamental structural units of the Escherichia coli nucleoid revealed by atomic force microscopy.

A small container of several to a few hundred microm3 (i.e. bacterial cells and eukaryotic nuclei) contains extremely long genomic DNA (i.e. mm and m long, respectively) in a highly organized fashion. To understand how such genomic architecture could be achieved, Escherichia coli nucleoids were subjected to structural analyses under atomic force microscopy, and found to change their structure dynamically during cell growth, i.e. the nucleoid structure in the stationary phase was more tightly compacted than in the log phase. However, in both log and stationary phases, a fundamental fibrous structure with a diameter of approximately 80 nm was found. In addition to this '80 nm fiber', a thinner '40 nm fiber' and a higher order 'loop' structure were identified in the log phase nucleoid. In the later growth phases, the nucleoid turned into a 'coral reef structure' that also possessed the 80 nm fiber units, and, finally, into a 'tightly compacted nucleoid' that was stable in a mild lysis buffer. Mutant analysis demonstrated that these tight compactions of the nucleoid required a protein, Dps. From these results and previously available information, we propose a structural model of the E.coli nucleoid.

Condensin but not cohesin SMC heterodimer induces DNA reannealing through protein-protein assembly.

Condensin and cohesin are chromosomal protein complexes required for chromosome condensation and sister chromatid cohesion, respectively. They commonly contain the SMC (structural maintenance of chromosomes) subunits consisting of a long coiled-coil with the terminal globular domains and the central hinge. Condensin and cohesin holo-complexes contain three and two non-SMC subunits, respectively. In this study, DNA interaction with cohesin and condensin complexes purified from fission yeast was investigated. The DNA reannealing activity is strong for condensin SMC heterodimer but weak for holo-condensin, whereas no annealing activity is found for cohesin heterodimer SMC and Rad21-bound heterotrimer complexes. One set of globular domains of the same condensin SMC is essential for the DNA reannealing activity. In addition, the coiled-coil and hinge region of another SMC are needed. Atomic force microscopy discloses the molecular events of DNA reannealing. SMC assembly that occurs on reannealing DNA seems to be a necessary intermediary step. SMC is eliminated from the completed double-stranded DNA. The ability of heterodimeric SMC to reanneal DNA may be regulated in vivo possibly through the non-SMC heterotrimeric complex.