Cryo-electron microscopy structure of the H3-H4 octasome without histones H2A and H2B

The canonical nucleosome, which represents the predominant packaging unit in eukaryotic chromatin, has an octameric core made up of two histone H2A-H2B and H3-H4 dimers with ~147 base-pair (bp) DNA wrapping around it. Non-nucleosome particles with alterative histone stoichiometries and DNA wrapping configurations have been found, and they could profoundly influence genome architecture and function. Here we solved the structure of the H3-H4 octasome, which is a nucleosome-like particle with a core made up of four H3-H4 dimers. Two conformations, open and closed, are determined at 3.9 angstrom and 3.6 angstrom resolutions by cryo-electron microscopy, respectively. The H3-H4 octasome, made up of a di-tetrameric core, is wrapped by ~120 bp DNA in 1.5 negative superhelical turns. The symmetrical halves are connected by a unique H4-H4' interface along the dyad axis. In vivo crosslinking of cysteine probes placed at another unique H3-H3' interface demonstrated the existence of the H3-H4 octasome in cells.

Modulated control of DNA supercoiling balance by the DNA-wrapping domain of bacterial gyrase

Negative supercoiling by DNA gyrase is essential for maintaining chromosomal compaction, transcriptional programming, and genetic integrity in bacteria. Questions remain as to how gyrases from different species have evolved profound differences in their kinetics, efficiency, and extent of negative supercoiling. To explore this issue, we analyzed homology-directed mutations in the C-terminal, DNA-wrapping domain of the GyrA subunit of Escherichia coli gyrase (the ‘CTD’). The addition or removal of select, conserved basic residues markedly impacts both nucleotide-dependent DNA wrapping and supercoiling by the enzyme. Weakening CTD–DNA interactions slows supercoiling, impairs DNA-dependent ATP hydrolysis, and limits the extent of DNA supercoiling, while simultaneously enhancing decatenation and supercoil relaxation. Conversely, strengthening DNA wrapping does not result in a more extensively supercoiled DNA product, but partially uncouples ATP turnover from strand passage, manifesting in futile cycling. Our findings indicate that the catalytic cycle of E. coli gyrase operates at high thermodynamic efficiency, and that the stability of DNA wrapping by the CTD provides one limit to DNA supercoil introduction, beyond which strand passage competes with ATP-dependent supercoil relaxation. These results highlight a means by which gyrase can evolve distinct homeostatic supercoiling setpoints in a species-specific manner.

CENP-C unwraps the CENP-A nucleosome through the H2A C-terminal tail

Centromeres are defined epigenetically by nucleosomes containing the histone H3 variant CENP-A, upon which the constitutive centromere-associated network of proteins (CCAN) is built. CENP-C, is considered to be a central organizer of the CCAN. We provide new molecular insights into the structure of CENP-A nucleosomes, in isolation and in complex with the CENP-C central region (CENP-CCR), the main CENP-A binding module of CENP-C. We establish that the short αN-helix of CENP-A promotes DNA flexibility at the nucleosome ends, independently of the sequence it wraps.Furthermore, we show that, in vitro, two regions of CENP-C (CENP-CCR and CENP-Cmotif) both bind exclusively to the CENP-A nucleosome. We find CENP-CCR to bind with high affinity due to an extended hydrophobic area made up of CENP-AV532 and CENP-AV533. Importantly, we identify two key conformational changes within the CENP-A nucleosome upon CENP-C binding. First, the loose DNA wrapping of CENP-A nucleosomes is further exacerbated, through destabilization of the H2A N-terminal tail. Second, CENP-CCR rigidifies the N-terminal tail of H4 in the conformation favoring H4K20 monomethylation, essential for a functional centromere.SynopsisCENP-A nucleosomes have a short αN helix incompatible with complete DNA wrapping, independently of DNA sequence. CENP-C binds exclusively to CENP-A nucleosomes and this binding induces conformational changes that further differentiate CENP-A-containing from canonical nucleosomes.CENP-C binds CENP-A nucleosomes specificallyDNA ends of the CENP-A nucleosome are further unwrapped in the CENP-A/CENP-C complex, due to flexible H2A C-terminal tailsThe N-terminal tail of H4 adopts a conformation favored for centromere specific H4K20 monomethylation when CENP-C is bound

Tuning the Photoluminescence of DNA-Wrapped Carbon Nanotubes by pH

These findings contribute in several ways to our understanding of DNA wrapping structure on the encased SWCNT and provide a basis for design of nanotube-based sensors for detecting local pH gradients in restricted environments, such as in living cells and microfluidic channels.

Tuning the Photoluminescence of DNA-Wrapped Carbon Nanotubes by pH

These findings contribute in several ways to our understanding of DNA wrapping structure on the encased SWCNT and provide a basis for design of nanotube-based sensors for detecting local pH gradients in restricted environments, such as in living cells and microfluidic channels.

DNA sequence is a major determinant of tetrasome dynamics

ABSTRACTEukaryotic genomes are hierarchically organized into protein-DNA assemblies for compaction into the nucleus. Nucleosomes, with the (H3-H4)2 tetrasome as a likely intermediate, are highly dynamic in nature by way of several different mechanisms. We have recently shown that tetrasomes spontaneously change the direction of their DNA wrapping between left- and right-handed conformations, which may prevent torque build-up in chromatin during active transcription or replication. DNA sequence has been shown to strongly affect nucleosome positioning throughout chromatin. It is not known, however, whether DNA sequence also impacts the dynamic properties of tetrasomes. To address this question, we examined tetrasomes assembled on a high-affinity DNA sequence using freely orbiting magnetic tweezers. In this context, we also studied the effects of mono- and divalent salts on the flipping dynamics. We found that neither DNA sequence nor altered buffer conditions affect overall tetrasome structure. In contrast, tetrasomes bound to high-affinity DNA sequences showed significantly altered flipping kinetics, predominantly via a reduction in the lifetime of the canonical state of left-handed wrapping. Increased mono- and divalent salt concentrations counteracted this behaviour. Thus, our study indicates that high-affinity DNA sequences impact not only the positioning of the nucleosome, but that they also endow the subnucleosomal tetrasome with enhanced conformational plasticity. This may provide a means to prevent histone loss upon exposure to torsional stress, thereby contributing to the integrity of chromatin at high-affinity sites.STATEMENT OF SIGNIFICANCECanonical (H3-H4)2 tetrasomes possess high conformational flexibility, as evidenced by their spontaneous flipping between states of left- and right-handed DNA wrapping. Here, we show that these conformational dynamics of tetrasomes cannot be described by a fixed set of rates over all conditions. Instead, an accurate description of their behavior must take into account details of their loading, in particular the underlying DNA sequence. In vivo, differences in tetrasome flexibility could be regulated by modifications of the histone core or the tetrasomal DNA, and as such constitute an intriguing, potentially adjustable mechanism for chromatin to accommodate the torsional stress generated by processes such as transcription and replication.