DNA loop domain organization in nucleoids from cells of different types.

The loop domain organization of chromatin plays an important role in transcription regulation and thus may be assumed to vary in cells of different types. We investigated the kinetics of DNA loop migration during single cell gel electrophoresis (the comet assay) for nucleoids obtained from human lymphocytes, lymphoblasts and glioblastoma T98G cells. The results confirm our previous observation that there are three parts of DNA in nucleoids: DNA on the nucleoid surface, loops up to ∼150 kb inside the nucleoid, and larger loops that cannot migrate. However, the relative amounts of the three parts were found to be very different for different cell types. The distributions of the loop length up to 150 kb were shown to be exponential, with the distribution parameter, the loop density, to be dependent on the cell type.

Single nucleus versus single-cell gel electrophoresis: kinetics of DNA track formation.

Single-cell gel electrophoresis, or the comet assay, is usually performed with nucleoids prepared after a lysis of either whole cells (more often) or isolated cell nuclei (rarely). Electrophoretic properties of the second type of nucleoids have never been investigated carefully. We measured the kinetics of the DNA exit from nuclei-derived nucleoids in comparison with cell-derived nucleoids. The results show that general organization of the nuclei-derived nucleoids is not changed very much in comparison with nucleoids commonly obtained from whole cells. At the same time, in contrast to the cell-derived nucleoids, for which the exit is stepwise and cooperative, the DNA exit from the nuclei-derived nucleoids can be described by a simple monomolecular kinetics. This difference is probably due to agarose penetration into nuclei (but not into cells) before polymerization of the agarose gel. We suggest that single-nucleus gel electrophoresis may be a way for the comet assay standardization.

DNA loop domain organization as revealed by single-cell gel electrophoresis.

At higher order levels chromatin is organized into loops. This looping, which plays an important role in transcription regulation and other processes, remains poorly understood. We investigated the kinetics of DNA loop migration during single cell gel electrophoresis (the comet assay). The migration of a part of the loops was shown to be reversible after switching off electrophoresis and to be sensitive to intercalation-induced changes in supercoiling. Another group of the loops migrates rapidly, the rate being insensitive to the supercoiling level. The largest part of the loops cannot migrate at all, presumably because of their large size. The loop ends can be detached in the presence of high concentrations of intercalators or protein denaturants, thus increasing the fraction of DNA that cannot migrate in the gel. The distribution of the loop length up to 100kilobases appears to be consistent with the fractal globule organization.

Kinetics of comet formation in single-cell gel electrophoresis: loops and fragments.

We investigated the mechanisms of DNA exit during single-cell gel electrophoresis (the comet assay) by measuring the kinetics of the comet tail formation. In the neutral comet assay, the rate of DNA exit was found to be dependent on the topological state of DNA, which was influenced by either ethidium bromide or a low radiation dose. The results clearly show that the comet tail is formed by extended DNA loops: the loop extension, being reversible when the DNA torsional constraint remains in the loops, is favored when the constraint is relaxed. The kinetics of the comet formation in the case of a high radiation dose points out that accumulation of the single-strand breaks causes DNA fragmentation. In contrast to the neutral comet assay, the alkaline comet assay is not related to the chromatin loops. Our results imply that the alkaline treatment induces detachment of the loops from the nuclear matrix, and the comet tail is formed by ssDNA fragments, the ends of which are pulled out from the comet head by electric force. We suggest that the kinetic approach can be considered as an important improvement of the comet assay.

CENP-A-containing nucleosomes: easier disassembly versus exclusive centromeric localization.

CENP-A is a histone variant that replaces conventional H3 in nucleosomes of functional centromeres. We report here, from reconstitutions of CENP-A- and H3-containing nucleosomes on linear DNA fragments and the comparison of their electrophoretic mobility, that CENP-A induces some positioning of its own and some unwrapping at the entry-exit relative to canonical nucleosomes on both 5 S DNA and the alpha-satellite sequence on which it is normally loaded. This steady-state unwrapping was quantified to 7(+/-2) bp by nucleosome reconstitutions on a series of DNA minicircles, followed by their relaxation with topoisomerase I. The unwrapping was found to ease nucleosome invasion by exonuclease III, to hinder the binding of a linker histone, and to promote the release of an H2A-H2B dimer by nucleosome assembly protein 1 (NAP-1). The (CENP-A-H4)2 tetramer was also more readily destabilized with heparin than the (H3-H4)2 tetramer, suggesting that CENP-A has evolved to confer its nucleosome a specific ability to disassemble. This dual relative instability is proposed to facilitate the progressive clearance of CENP-A nucleosomes that assemble promiscuously in euchromatin, especially as is seen following CENP-A transient over-expression.

Physical principles and new applications of comet assay.

The comet assay is a sensitive method to assess DNA damages in single cells. The approach consists of an analysis of electrophoretic migration of DNA from nucleoids obtained after cell lysis in a thin layer of agarose. Although the method is widely used the physical mechanisms of DNA track formation remained to be rather elusive for a long time. This review is devoted to our recent results pertaining to this subject, using an original approach based on the kinetic measurements of the comet formation. We argue that linear DNA fragments give an essential contribution into the tail formation in the alkaline conditions and, at neutral pH, when the level of DNA damages is very high. On the other hand, in the neutral comet assay at low levels of DNA damages (and also in the case of undamaged cells) the tail is formed by extended DNA loops. These loops are about the same as chromatin loops in the cell nuclei. Kinetic measurements in the comet assay give an opportunity to investigate the topology of the loops and large-scale features of the loop domain organization (and re-organization) in nucleoids obtained from different cell types.

Linker histone-dependent organization and dynamics of nucleosome entry/exit DNAs.

A DNA sequence-dependent nucleosome structural and dynamic polymorphism was recently uncovered through topoisomerase I relaxation of mononucleosomes on two homologous approximately 350-370 bp DNA minicircle series, one originating from pBR322, the other from the 5S nucleosome positioning sequence. Whereas both pBR and 5S nucleosomes had access to the closed, negatively crossed conformation, only the pBR nucleosome had access to the positively crossed conformation. Simulation suggested this discrepancy was the result of a reorientation of entry/exit DNAs, itself proposed to be the consequence of specific DNA untwistings occurring in pBR nucleosome where H2B N-terminal tails pass between the two gyres. The present work investigates the behavior of the same two nucleosomes after binding of linker histone H5, its globular domain, GH5, and engineered H5 C-tail deletion mutants. Nucleosome access to the open uncrossed conformation was suppressed and, more surprisingly, the ability of 5S nucleosome to positively cross was largely restored. This, together with the paradoxical observation of a less extensive crossing in the negative conformation with GH5 than without, favored an asymmetrical location of the globular domain in interaction with the central gyre and only entry (or exit) DNA, and raised the possibility of the domain physical rotation as a mechanism assisting nucleosome fluctuation from one conformation to the other. Moreover, both negative and positive conformations showed a high degree of loop conformational flexibility in the presence of the full-length H5 C-tail, which the simulation suggested to reflect the unique feature of the resulting stem to bring entry/exit DNAs in contact and parallel. The results point to the stem being a fundamental structural motif directing chromatin higher order folding, as well as a major player in its dynamics.

Sequence-dependent nucleosome structural and dynamic polymorphism. Potential involvement of histone H2B N-terminal tail proximal domain.

Relaxation of nucleosomes on an homologous series (pBR) of ca 350-370 bp DNA minicircles originating from plasmid pBR322 was recently used as a tool to study their structure and dynamics. These nucleosomes thermally fluctuated between three distinct DNA conformations within a histone N-terminal tail-modulated equilibrium: one conformation was canonical, with 1.75 turn wrapping and negatively crossed entering and exiting DNAs; another was also "closed", but with these DNAs positively crossed; and the third was "open", with a lower than 1.5 turn wrapping and uncrossed DNAs. In this work, a new minicircle series (5S) of similar size was used, which contained the 5S nucleosome positioning sequence. Results showed that DNA in pBR nucleosomes was untwisted by approximately 0.2 turn relative to 5S nucleosomes, which DNase I footprinting confirmed in revealing a approximately 1 bp untwisting at each of the two dyad-distal sites where H2B N-terminal tails pass between the two gyres. In contrast, both nucleosomes showed untwistings at the dyad-proximal sites, i.e. on the other gyre, which were also observed in the high-resolution crystal structure. 5S nucleosomes also differ with respect to their dynamics: they hardly accessed the positively crossed conformation, but had an easier access to the negatively crossed conformation. Simulation showed that such reverse effects on the conformational free energies could be simply achieved by slightly altering the trajectories of entering and exiting DNAs. We propose that this is accomplished by H2B tail untwisting at the distal sites through action at a distance ( approximately 20 bp) on H3-tail interactions with the small groove at the nucleosome entry-exit. These results may help to gain a first glimpse into the two perhaps most intriguing features of the high-resolution structure: the alignment of the grooves on the two gyres and the passage of H2B and H3 N-terminal tails between them.

Nucleosome chiral transition under positive torsional stress in single chromatin fibers.

Using magnetic tweezers to investigate the mechanical response of single chromatin fibers, we show that fibers submitted to large positive torsion transiently trap positive turns at a rate of one turn per nucleosome. A comparison with the response of fibers of tetrasomes (the [H3-H4](2) tetramer bound with approximately 50 bp of DNA) obtained by depletion of H2A-H2B dimers suggests that the trapping reflects a nucleosome chiral transition to a metastable form built on the previously documented right-handed tetrasome. In view of its low energy, <8 kT, we propose that this transition is physiologically relevant and serves to break the docking of the dimers on the tetramer that in the absence of other factors exerts a strong block against elongation of transcription by the main RNA polymerase.

Nucleosome conformational flexibility and implications for chromatin dynamics.

The active role of chromatin in the regulation of gene activity seems to imply a conformational flexibility of the basic chromatin structural unit, the nucleosome. This review is devoted to our recent results pertaining to this subject, using an original approach based on the topology of single particles reconstituted on DNA minicircles, combined with their theoretical simulation. Three types of chromatin particles have been studied so far: a subnucleosome, that is, the (H3-H4)(2) histone tetramer-containing particle, now known as the tetrasome; the nucleosome; and the linker histone H5/H1-bearing nucleosome (the chromatosome). All the particles were found to exist in two to three conformational states, which differ by their topological and mechanical properties. Our approach unveiled the molecular mechanisms of nucleosome conformational dynamics and will help to understand its functional relevance. A most surprising conclusion of the work was perhaps that DNA overall flexibility increases considerably upon particle formation, which might indeed be a requirement of genome function.

Kinetics and thermodynamics of the unfolding and refolding of the three-stranded alpha-helical coiled coil, Lpp-56.

Temperature-induced reversible unfolding and refolding of the three-stranded alpha-helical coiled coil, Lpp-56, were studied by kinetic and thermodynamic methods, using CD spectroscopy, dynamic light scattering, and scanning calorimetry. It was found that both unfolding and refolding reactions of this protein in neutral solution in the presence of 100 mM NaCl are characterized by unusually slow kinetics, which permits detailed investigation of the mechanism of these reactions. Kinetic analyses show that the unfolding of this coiled coil represents a single-stage first-order reaction, while the refolding represents a single-stage third-order reaction. The activation enthalpy and entropy for unfolding do not depend noticeably on temperature and are both significantly greater than those for the folding reaction, which show a significant dependence on temperature. The activation heat capacity change for the unfolding reaction is close to zero, while it is quite significant for the folding reaction. The correlation between the activation and structural parameters obtained for the Lpp-56 coiled coil suggests that interhelical van der Waals interactions are disrupted in the transition state, which is nevertheless still compact, and water has not yet penetrated into the interface; the transition from the transient state to the unfolded state results in hydration of exposed apolar groups of the interface and the disruption of helices. The low propensity for the Lpp-56 strands to fold and associate is caused by the high number of charged groups at neutral pH. On one hand, these charges give rise to considerable repulsive forces destabilizing the helical conformation of the strands. On the other hand, they align the folded helices in parallel and in register so that the apolar sides face each other, and the oppositely charged groups may form salt links, which are important for the formation of the trimeric coiled coil. A decrease in pH, which eliminates the salt links, dramatically decreases the stability of Lpp-56; its structure becomes less rigid and unfolds much faster.