Mechanisms for ATP-dependent chromatin remodelling

During the past year, major advances have been made towards understanding the function of ATP-dependent chromatin-remodelling activities both in vitro and in vivo. These suggest that ATP-dependent chromatin-remodelling activities are capable of both altering the structure of individual nucleosomes and acting in concert with other forms of chromatin-modifying enzymes, to regulate the formation and decondensation of chromatin fibres.     

Histone H2A/H2B dimer exchange by ATP-dependent chromatin remodeling activities

ATP-dependent chromatin remodeling activities function to manipulate chromatin structure during gene regulation. One of the ways in which they do this is by altering the positions of nucleosomes along DNA. Here we provide support for the ability of these complexes to move nucleosomes into positions in which DNA is unraveled from one edge. This is expected to result in the loss of histone-DNA contacts that are important for retention of one H2A/H2B dimer within the nucleosome. Consistent with this we find that several chromatin remodeling complexes are capable of catalyzing the exchange of H2A/H2B dimers between chromatin fragments in an ATP-dependent reaction. This provides eukaryotes with additional means by which they may manipulate chromatin structure.     

Generation of superhelical torsion by ATP-dependent chromatin remodeling activities

ATP-dependent chromatin remodeling activities participate in the alteration of chromatin structure during gene regulation. All have DNA- or chromatin-stimulated ATPase activity and many can alter the structure of chromatin; however, the means by which they do this have remained unclear. Here we describe a novel activity for ATP-dependent chromatin remodeling activities, the ability to generate unconstrained negative superhelical torsion in DNA and chromatin. We find that the ability to distort DNA is shared by the yeast SWI/SNF complex, Xenopus Mi-2 complex, recombinant ISWI, and recombinant BRG1, suggesting that the generation of superhelical torsion represents a primary biomechanical activity shared by all Snf2p-related ATPase motors. The generation of superhelical torque provides a potent means by which ATP-dependent chromatin remodeling activities can manipulate chromatin structure.     

The in vivo functions of ATP-dependent chromatin-remodelling factors

ATP-dependent chromatin-remodelling factors regulate the accessibility of DNA to nuclear factors that are involved in cellular processes that depend on protein DNA interactions. They probably accomplish this by using the energy of ATP hydrolysis to change the positions of nucleosomes on the DNA, or to change the structure of DNA within the nucleosomes. Although their mechanisms of action have been extensively studied in vitro, many questions remain about their functions in vivo.     

Purification and nucleosome mapping analysis of native yeast plasmid chromatin

There is much evidence indicating the importance in gene regulation of the positions of nucleosomes with respect to DNA sequence. Low resolution chromatin structures have been described for many genes, but there is a dearth of detailed high resolution chromatin structures. In the cases where they are available, high resolution maps have revealed much more complex chromatin structures, with multiple alternative nucleosome positions. The discovery that ATP-dependent chromatin remodelling machines are recruited to genes, with their ability to mobilise nucleosomes on DNA and to alter nucleosomal conformation, emphasises the necessity for obtaining high resolution nucleosome maps, so that the details of these remodelling reactions can be defined in vivo. Here, we describe protocols for purifying plasmid chromatin from cells of the yeast Saccharomyces cerevisiae and for mapping nucleosome positions on the plasmid using the monomer extension mapping method. This method requires purified chromatin, but is capable of mapping relatively long stretches of chromatin in great detail. Typically, it reveals very complex chromatin structures.     

Antagonistic forces that position nucleosomes in vivo

ATP-dependent chromatin remodeling complexes are implicated in many areas of chromosome biology. However, the physiological role of many of these enzymes is still unclear. In budding yeast, the Isw2 complex slides nucleosomes along DNA. By analyzing the native chromatin structure of Isw2 targets, we have found that nucleosomes adopt default, DNA-directed positions when ISW2 is deleted. We provide evidence that Isw2 targets contain DNA sequences that are inhibitory to nucleosome formation and that these sequences facilitate the formation of nuclease-accessible open chromatin in the absence of Isw2. Our data show that the biological function of Isw2 is to position nucleosomes onto unfavorable DNA. These results reveal that antagonistic forces of Isw2 and the DNA sequence can control nucleosome positioning and genomic access in vivo.     

Chromatin remodelling in mammalian cells by ISWI-type complexes--where, when and why?

The specific location of nucleosomes on DNA has important inhibitory or activating roles in the regulation of DNA-dependent processes as it affects the DNA accessibility. Nucleosome positions depend on the ATP-coupled activity of chromatin-remodelling complexes that translocate nucleosomes or evict them from the DNA. The mammalian cell harbors numerous different remodelling complexes that possess distinct activities. These can translate a variety of signals into certain patterns of nucleosome positions with specific functions. Although chromatin remodellers have been extensively studied in vitro, much less is known about how they operate in their cellular environment. Here, we review the cellular activities of the mammalian imitation switch proteins and discuss mechanisms by which they are targeted to sites where their activity is needed.     

Functions of chromatin remodeling factors in heterochromatin formation and maintenance

Heterochromatin is characteristically more compact than euchromatin in the eukaryotic genome. The establishment of heterochromatin is mediated by special histone modifications, recruitment and propagation of heterochromatin specific proteins, as well as formation of special primary and high order structures of chromatin. Chromatin remodeling factors are ATPases that can alter the conformation and/or positioning of nucleosomes along DNA in an ATP-dependent manner. There is increasing evidence implicating chromatin remodeling activities in heterochromatin in various organisms ranging from yeasts to humans. Chromatin remodeling factors play roles in the establishment, maintenance and epigenetic inheritance of heterochromatin, but the underlying molecular mechanisms have just begun to be investigated.