It has been a long-standing challenge to decipher the principles that enable cells to both organize their genomes into compact chromatin and ensure that the genetic information remains accessible to regulatory factors and enzymes within the confines of the nucleus. The discovery of nucleosome remodeling activities that utilize the energy of ATP to render nucleosomal DNA accessible has been a great leap forward. In vitro, these enzymes weaken the tight wrapping of DNA around the histone octamers, thereby facilitating the sliding of histone octamers to neighboring DNA segments, their displacement to unlinked DNA, and the accumulation of patches of accessible DNA on the surface of nucleosomes. It is presumed that the collective action of these enzymes endows chromatin with dynamic properties that govern all nuclear functions dealing with chromatin as a substrate. The diverse set of ATPases that qualify as the molecular motors of the nucleosome remodeling process have a common history and are part of a superfamily. The physiological context of their remodeling action builds on the association with a wide range of other proteins to form distinct complexes for nucleosome remodeling. This review summarizes the recent progress in our understanding of the mechanisms underlying the nucleosome remodeling reaction, the targeting of remodeling machines to selected sites in chromatin, and their integration into complex regulatory schemes.
We have analyzed the histone modification status of the PHO5 promoter from yeast by the ChIP technology and have focused on changes occurring upon activation. Using various acetylation-specific antibodies, we found a dramatic loss of the acetylation signal upon induction of the promoter. This turned out to be due, however, to the progressive loss of histones altogether. The fully remodeled promoter appears to be devoid of histones as judged by ChIP analyses. Local histone hyperacetylation does indeed occur, however, prior to remodeling. This can explain the delay in chromatin remodeling in the absence of histone acetyltransferase activity of the SAGA complex that was previously documented for the PHO5 promoter. Our findings shed new light on the nucleosomal structure of fully remodeled chromatin. At the same time, they point out the need for novel controls when the ChIP technique is used to study histone modifications in the context of chromatin remodeling in vivo.
The chromatin fine structure in the promoter region of PHO5, the structural gene for a strongly regulated acid phosphatase in yeast, was analyzed. An upstream activating sequence 367 bp away from the start of the coding sequence that is essential for gene induction was found to reside in the center of a hypersensitive region under conditions of PHO5 repression. Under these conditions three related elements at positions ‐469, ‐245 and ‐185 are contained within precisely positioned nucleosomes located on both sides of the hypersensitive region. Upon PHO5 induction the chromatin structure of the promoter undergoes a defined transition, in the course of which two nucleosomes upstream and two nucleosomes downstream of the hypersensitive site are selectively removed. In this way approximately 600 bp upstream of the PHO5 coding sequence become highly accessible and all four elements are free to interact with putative regulatory proteins. These findings suggest a mechanism by which the chromatin structure participates in the functioning of a regulated promoter.
No abstract
Micrococcal nuclease is shown to cleave DNA under conditions of partial digestion in a specific manner. Sequences of the type 5'CATA and 5'CTA are attacked preferentially, followed by exonucleolytic degradation at the newly generated DNA termini. GC-rich flanking sequences further increase the probability of initial attack. Unexpectedly, long stretches containing only A and T are spared by the nuclease. These results, which were obtained with spared by the nuclease. These results, which were obtained with mouse satellite DNA and two fragments from the plasmid pBR22, do not support the previous contention that it is the regions of high At-content which are initially cleaved by micrococcal nuclease. This specificity of micrococcal nuclease complicates its use in experiments intended to monitor the nucleoprotein structure of a DNA sequence in chromatin.
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