Rajeswari S. Edayathumangalam

Crystal Structures of Nucleosome Core Particles in Complex with Minor Groove DNA-binding Ligands

We determined the crystal structures of three nucleosome core particles in complex with site-specific DNA-binding ligands, the pyrrole-imidazole polyamides. While the structure of the histone octamer and its interaction with the DNA remain unaffected by ligand binding, nucleosomal DNA undergoes significant structural changes at the ligand-binding sites and in adjacent regions to accommodate the ligands. Our findings suggest that twist diffusion occurs over long distances through tightly bound nucleosomal DNA. This may be relevant to the mechanism of ATP-dependent and spontaneous nucleosome translocation, and to the effect of bound factors on nucleosome dynamics.

Crystal structures of histone Sin mutant nucleosomes reveal altered protein–DNA interactions

Here we describe 11 crystal structures of nucleosome core particles containing individual point mutations in the structured regions of histones H3 and H4. The mutated residues are located at the two protein–DNA interfaces flanking the nucleosomal dyad. Five of the mutations partially restore the in vivo effects of SWI/SNF inactivation in yeast. We find that even nonconservative mutations of these residues (which exhibit a distinct phenotype in vivo) have only moderate effects on global nucleosome structure. Rather, local protein–DNA interactions are disrupted and weakened in a subtle and complex manner. The number of lost protein–DNA interactions correlates directly with an increased propensity of the histone octamer to reposition with respect to the DNA, and with an overall destabilization of the nucleosome. Thus, the disruption of only two to six of the ∼120 direct histone–DNA interactions within the nucleosome has a pronounced effect on nucleosome mobility and stability. This has implications for our understanding of how these structures are made accessible to the transcription and replication machinery in vivo.

Structure and dynamic properties of nucleosome core particles

It is now widely recognized that the packaging of genomic DNA, together with core histones, linker histones, and other functional proteins into chromatin profoundly influences nuclear processes such as transcription, replication, DNA repair, and recombination. Whereas earlier structural studies portrayed nucleosomes (the basic repeating unit of chromatin) as monolithic and static macromolecular assemblies, we now know that they are highly dynamic and capable of extensive crosstalk with the cellular machinery. Histone variants have evolved to locally alter chromatin structure, whereas histone chaperones and other cellular factors promote histone exchange and chromatin fluidity. Both of these phenomena likely facilitate interconversion between different chromatin states that show varying degrees of transcriptional activity.

A Feed-Forward Repression Mechanism Anchors the Sin3/Histone Deacetylase and N-CoR/SMRT Corepressors on Chromatin

ABSTRACT Transcription in eukaryotes is governed in part by histone acetyltransferase (HAT)- and histone deacetylase (HDAC)-containing complexes that are recruited via activators and repressors, respectively. Here, we show that the Sin3/HDAC and N-CoR/SMRT corepressor complexes repress transcription from histone H3- and/or H4-acetylated nucleosomal templates in vitro. Repression of histone H3-acetylated templates was completely dependent on the histone deacetylase activity of the corepressor complexes, whereas this activity was not required to repress H4-acetylated templates. Following deacetylation, both complexes become stably anchored in a repressor-independent manner to nucleosomal templates containing hypoacetylated histone H3, but not H4, resulting in dominance of repression over activation. The observed stable anchoring of corepressor complexes casts doubt on the view of a dynamic balance between readily exchangeable HAT and HDAC activities regulating transcription and implies that pathways need to be in place to actively remove HDAC complexes from hypoacetylated promoters to switch on silent genes.

Nucleosome structure and function.

It is now widely recognized that the packaging of genomic DNA, together with core histones, linker histones, and other functional proteins into chromatin profoundly influences nuclear processes such as transcription, replication, DNA repair, and recombination. How chromatin structure modulates the expression of knowledge encoded in eukaryotic genomes, and how these processes take place within the context of a highly complex and compacted genomic chromatin environment remains a major unresolved question in biology. Here we review recent advances in nucleosome structure and dynamics.