Nucleosomes facilitate their own invasion

DNA wrapped in nucleosomes is sterically occluded, creating obstacles for polymerase, regulatory, remodeling, repair and recombination complexes, which require access to the wrapped DNA. How such complexes recognize and gain access to their DNA target sites is not known. Here we report the direct detection of a dynamic equilibrium conformational transition in nucleosomes that greatly increases the distance between the end of the nucleosomal DNA and the histone core. We quantified the equilibrium constant for this transition under physiological conditions. As predicted by these findings, addition of LexA protein to nucleosomes containing the LexA target site drives this conformational equilibrium toward the unwrapped, accessible state, simultaneously allowing stable LexA binding. This inherent property of nucleosomes allows any protein, whether an energy-dependent machine or a passive binder, to gain access even to buried stretches of nucleosomal DNA.     

Unfolding of nucleosome cores induced by chemical acetylation of histones

Relative accessibility of nucleosomal histones to acetic anhydride during acetylation has been studied as a function of concentration, pH and ionic strength of the solution using high-resolution gel-electrophoresis. It was shown that about 80% of lysine residues in nucleosomal histones and 100% of the same residues in histone complexes without DNA in 2 M NaCl are accessible to the modification, which is proved by the localization of the majority of lysine residues in nucleosomes near the surface of the histone octamer, by their participation in ionic interactions with DNA and, probably, in histone-histone contacts. Gel-electrophoretic experiments with nucleosomes and studies of the histone resistance to mild trypsinolysis indicated that neither nucleosomes themselves nor histone octamers are affected even though 50% of lysine residues in histones have been acetylated. The process of acetylation is accompanied by the growing tendency of histones to participate in mild trypsinolysis and by a gradual decline in electrophoretic mobility and in the value of the sedimentation constant. The circular dichroism spectra and the microscopic appearance of nucleosomes are also markedly changed. These results suggest that a gradual unfolding of nucleosomes occurs when 5 or more lysine residues in the nucleosomal histones have been acetylated.     

Electron microscopic and biochemical evidence that chromatin structure is a repeating unit

Electron microscopic and biochemical studies demonstrate that the fundamental structure of chromatin depleted of lysine-rich histones is composed of a flexible chain of spherical particles (nucleosomes), about 125 Å in diameter, connected by DNA filaments. Such a chromatin preparation can be separated by centrifugation into two fractions which differ in the spacing of the nucleosomes. In one fraction almost all of the DNA is condensed in nucleosomes, while the other fraction contains long stretches of free DNA connecting regions where the nucleosomes are closely packed. The isolated nucleosomes contain about 200 base pairs of DNA and the four histones F2a₁, F2a₂, and F2b, and F3 in an overall histone/DNA ratio of 0.97. In such a structure the DNA is compacted slightly more than five times from its extended length. The same basic structure can be visualized in chromatin spilling out of lysed nuclei. However, in this latter case the nucleosomes are very closely packed, suggesting that histone F1 is involved in the superpacking of DNA in chromosomes and nuclei. The chromatin fiber appears to be a self-assembling structure, since the nucleosomal arrangement can be reconstituted in vitro from DNA and the four histones F2a₁, F2a₂, F2b and F3 only, irrespective of their cellular origin.     

De novo methylation of nucleosomal DNA by the mammalian Dnmt1 and Dnmt3A DNA methyltransferases

In the cell, DNA is wrapped on histone octamers, which reduces its accessibility for DNA interacting enzymes. We investigated de novo methylation of nucleosomal DNA in vitro and show that the Dnmt3a and Dnmt1 DNA methyltransferases efficiently methylate nucleosomal DNA without dissociation of the histone octamer from the DNA. In contrast, the prokaryotic SssI DNA methyltransferase and the catalytic domain of Dnmt3a are strongly inhibited by nucleosomes. We also found that full-length Dnmt1 and Dnmt3a bind to nucleosomes much stronger than their isolated catalytic domains, demonstrating that the N-terminal parts of the MTases are required for the interaction with nucleosomes. Variations of the DNA sequence or the histone tails did not significantly influence the methylation activity of Dnmt3a. The observation that mammalian methyltransferases directly modify nucleosomal DNA provides an insight into the mechanisms by which histone tail and DNA methylation patterns can influence each other because the DNA methylation pattern can be established while histones remain associated to the DNA.     

Rapid spontaneous accessibility of nucleosomal DNA

DNA wrapped in nucleosomes is sterically occluded, creating obstacles for proteins that must bind it. How proteins gain access to DNA buried inside nucleosomes is not known. Here we report measurements of the rates of spontaneous nucleosome conformational changes in which a stretch of DNA transiently unwraps off the histone surface, starting from one end of the nucleosome, and then rewraps. The rates are rapid. Nucleosomal DNA remains fully wrapped for only approximately 250 ms before spontaneously unwrapping; unwrapped DNA rewraps within approximately 10-50 ms. Spontaneous unwrapping of nucleosomal DNA allows any protein rapid access even to buried stretches of the DNA. Our results explain how remodeling factors can be recruited to particular nucleosomes on a biologically relevant timescale, and they imply that the major impediment to entry of RNA polymerase into a nucleosome is rewrapping of nucleosomal DNA, not unwrapping.     

Salt-induced structural changes in nucleosomes

Ehrlich ascites tumor (EAT) nucleosomes treated with increasing NaCl concentrations were analyzed by sucrose density gradient centrifugation. Two events were found to take place in the course of the salt treatment: a) increasing amounts of nucleosomes dissociated into free DNA and protein in the interval 0.6M–1.5M NaCl, and b) the sedimentation coefficient of the nucleosomes decreased from 11S to 8S in the interval 0.6M-1M NaCl. This decrease was not caused by loss of protein and was fully reversible upon slow and gradual lowering of the ionic strength. This shows that before dissociation of the protein core from DNA, nucleosomes undergo a structural transition. The electron microscopic observations revealed that it consisted in detachment of the ends of nucleosomal DNA from the protein core. It is suggested that an arginine-rich domain in the protein core exists, which holds more tightly the central part of the nucleosomal DNA, while its ends are relatively loosely bound to lysine-rich domains.