Crystal structure of the chromodomain helicase DNA-binding protein 1 (Chd1) DNA-binding domain in complex with DNA

Chromatin remodelers are ATP-dependent machines that dynamically alter the chromatin packaging of eukaryotic genomes by assembling, sliding, and displacing nucleosomes. The Chd1 chromatin remodeler possesses a C-terminal DNA-binding domain that is required for efficient nucleosome sliding and believed to be essential for sensing the length of DNA flanking the nucleosome core. The structure of the Chd1 DNA-binding domain was recently shown to consist of a SANT and SLIDE domain, analogous to the DNA-binding domain of the ISWI family, yet the details of how Chd1 recognized DNA were not known. Here we present the crystal structure of the Saccharomyces cerevisiae Chd1 DNA-binding domain in complex with a DNA duplex. The bound DNA duplex is straight, consistent with the preference exhibited by the Chd1 DNA-binding domain for extranucleosomal DNA. Comparison of this structure with the recently solved ISW1a DNA-binding domain bound to DNA reveals that DNA lays across each protein at a distinct angle, yet contacts similar surfaces on the SANT and SLIDE domains. In contrast to the minor groove binding seen for Isw1 and predicted for Chd1, the SLIDE domain of the Chd1 DNA-binding domain contacts the DNA major groove. The majority of direct contacts with the phosphate backbone occur only on one DNA strand, suggesting that Chd1 may not strongly discriminate between major and minor grooves.     

No need for a power stroke in ISWI‐mediated nucleosome sliding

Nucleosome remodelling enzymes of the ISWI family reposition nucleosomes in eukaryotes. ISWI contains an ATPase and a HAND‐SANT‐SLIDE (HSS) domain. Conformational changes between these domains have been proposed to be critical for nucleosome repositioning by pulling flanking DNA into the nucleosome. We inserted flexible linkers at strategic sites in ISWI to disrupt this putative power stroke and assess its functional importance by quantitative biochemical assays. Notably, the flexible linkers did not disrupt catalysis. Instead of engaging in a power stroke, the HSS module might therefore assist DNA to ratchet into the nucleosome. Our results clarify the roles had by the domains and suggest that the HSS domain evolved to optimize a rudimentary remodelling engine.     

SLIDE, the Protein Interacting Domain of Imitation Switch Remodelers, Binds DDT-Domain Proteins of Different Subfamilies in Chromatin Remodeling Complexes

The Imitation Switch (ISWI) type adenosine triphosphate (ATP)-dependent chromatin remodeling factors are conserved proteins in eukaryotes, and some of them are known to form stable remodeling complexes...     

Crystal structure and functional analysis of a nucleosome recognition module of the remodeling factor ISWI

Energy-dependent nucleosome remodeling emerges as a key process endowing chromatin with dynamic properties. However, the principles by which remodeling ATPases interact with their nucleosome substrate to alter histone-DNA interactions are only poorly understood. We have identified a substrate recognition domain in the C-terminal half of the remodeling ATPase ISWI and determined its structure by X-ray crystallography. The structure comprises three domains, a four-helix domain with a novel fold and two alpha-helical domains related to the modules of c-Myb, SANT and SLIDE, which are linked by a long helix. An integrated structural and functional analysis of these domains provides insight into how ISWI interacts with the nucleosomal substrate.     

1H, 13C and 15N resonance assignments of an N-terminal domain of CHD4

Chromatin-remodeling proteins have a pivotal role in normal cell function and development, catalyzing conformational changes in DNA that ultimately result in changes in gene expression patterns. Chromodomain helicase DNA-binding protein 4 (CHD4), the defining subunit of the nucleosome remodeling and deacetylase (NuRD) complex, is a nucleosome-remodeling protein of the SNF2/ISWI2 family, members of which contain two chromo domains and an ATP-dependent helicase module. CHD3, CHD4 and CHD5 also contain two contiguous PHD domains and have an extended N-terminal region that has not previously been characterized. We have identified a stable domain in the N-terminal region of CHD4 and report here the backbone and side chain resonance assignments for this domain at pH 7.5 and 25 °C (BMRB No. 18906).     

Extranucleosomal DNA binding directs nucleosome sliding by Chd1

Chd1- and ISWI-type chromatin remodelers can sense extranucleosomal DNA and preferentially shift nucleosomes toward longer stretches of available DNA. The DNA-binding domains of these chromatin remodelers are believed to be responsible for sensing extranucleosomal DNA and are needed for robust sliding, but it is unclear how these domains contribute to directional movement of nucleosomes. Here, we show that the DNA-binding domain of Chd1 is not essential for nucleosome sliding but is critical for centering mononucleosomes on short DNA fragments. Remarkably, nucleosome centering was achieved by replacing the native DNA-binding domain of Chd1 with foreign DNA-binding domains of Escherichia coli AraC or Drosophila melanogaster engrailed. Introducing target DNA sequences recognized by the foreign domains enabled the remodelers to rapidly shift nucleosomes toward these binding sites, demonstrating that these foreign DNA-binding domains dictated the direction of sliding. Sequence-directed sliding occluded the target DNA sequences on the nucleosome enough to promote release of the remodeler. Target DNA sequences were highly stimulatory at multiple positions flanking the nucleosome and had the strongest influence when separated from the nucleosome by 23 or fewer base pairs. These results suggest that the DNA-binding domain's affinity for extranucleosomal DNA is the key determinant for the direction that Chd1 shifts the nucleosome.     

Human CHD2 Is a Chromatin Assembly ATPase Regulated by Its Chromo- and DNA-binding Domains

Chromodomain helicase DNA-binding protein 2 (CHD2) is an ATPase and a member of the SNF2-like family of helicase-related enzymes. Although deletions of CHD2 have been linked to developmental defects in mice and epileptic disorders in humans, little is known about its biochemical and cellular activities. In this study, we investigate the ATP-dependent activity of CHD2 and show that CHD2 catalyzes the assembly of chromatin into periodic arrays. We also show that the N-terminal region of CHD2, which contains tandem chromodomains, serves an auto-inhibitory role in both the DNA-binding and ATPase activities of CHD2. While loss of the N-terminal region leads to enhanced chromatin-stimulated ATPase activity, the N-terminal region is required for ATP-dependent chromatin remodeling by CHD2. In contrast, the C-terminal region, which contains a putative DNA-binding domain, selectively senses double-stranded DNA of at least 40 base pairs in length and enhances the ATPase and chromatin remodeling activities of CHD2. Our study shows that the accessory domains of CHD2 play central roles in both regulating the ATPase domain and conferring selectivity to chromatin substrates.     

<Superscript>1</Superscript>H, <Superscript>13</Superscript>C and <Superscript>15</Superscript>N resonance assignments of a C-terminal domain of human CHD1

Chromatin remodelling proteins are an essential family of eukaryotic proteins. They harness the energy from ATP hydrolysis and apply it to alter chromatin structure in order to regulate all aspects of genome biology. Chromodomain helicase DNA-binding protein 1 (CHD1) is one such remodelling protein that has specialised nucleosome organising abilities and is conserved across eukaryotes. CHD1 possesses a pair of tandem chromodomains that directly precede the core catalytic Snf2 helicase-like domain, and a C-terminal SANT-SLIDE DNA-binding domain. We have identified an additional conserved domain in the C-terminal region of CHD1. Here, we report the backbone and side chain resonance assignments for this domain from human CHD1 at pH 6.5 and 25 °C (BMRB No. 25638).     

DNA-binding and chromatin localization properties of CHD1.

CHD1 is a novel DNA-binding protein that contains both a chromatin organization modifier (chromo) domain and a helicase/ATPase domain. We show here that CHD1 preferentially binds to relatively long A.T tracts in double-stranded DNA via minor-groove interactions. Several CHD1-binding sites were found in a well-characterized nuclear-matrix attachment region, which is located adjacent to the intronic enhancer of the kappa immunoglobulin gene. The DNA-binding activity of CHD1 was localized to a 229-amino-acid segment in the C-terminal portion of the protein, which contains sequence motifs that have previously been implicated in the minor-groove binding of other proteins. We also demonstrate that CHD1 is a constituent of bulk chromatin and that it can be extracted from nuclei with 0.6 M NaCl or with 2 mM EDTA after mild digestion with micrococcal nuclease. In contrast to another chromo-domain protein, HP1, CHD1 is not preferentially located in condensed centromeric heterochromatin, even though centromeric DNA is highly enriched in (A+T)-rich tracts. Most interestingly, CHD1 is released into the cytoplasm when cells enter mitosis and is reincorporated into chromatin during telophase-cytokinesis. These observations lend credence to the idea that CHD1, like other proteins with chromo or helicase/ATPase domains, plays an important role in the determination of chromatin architecture.     

Mutation of the SNF2 family member Chd2 affects mouse development and survival

The chromodomain helicase DNA-binding domain (Chd) proteins belong to the SNF2-like family of ATPases that function in chromatin remodeling and assembly. These proteins are characterized by the presence of tandem chromodomains and are further subdivided based on the presence or absence of additional structural motifs. The Chd1-Chd2 subfamily is distinguished by the presence of a DNA-binding domain that recognizes AT-rich sequence. Currently, there are no reports addressing the function of the Chd2 family member. Embryonic stem cells containing a retroviral gene-trap inserted at the Chd2 locus were utilized to generate mice expressing a Chd2 protein lacking the DNA-binding domain. This mutation in Chd2 resulted in a general growth delay in homozygous mutants late in embryogenesis and in perinatal lethality. Animals heterozygous for the mutation showed decreased neonatal viability and increased susceptibility to non-neoplastic lesions affecting most primary organs. In particular, approximately 85% of the heterozygotes showed gross kidney abnormalities. Our results demonstrate that mutation of Chd2 dramatically affects mammalian development and long-term survival.     

ATP‐dependent looping of DNA by ISWI

Snf2 related chromatin remodelling enzymes possess an ATPase subunit similar to that of the SF‐II helicases which hydrolyzes ATP to track along DNA. Translocation and any resulting torque in the DNA could drive chromatin remodeling. To determine whether the ISWI protein can translocate and generate torque, tethered particle motion experiments and atomic force microscopy have been performed using recombinant ISWI expressed in E. coli. In the absence of ATP, ISWI bound to and wrapped DNA thereby shortening the overall contour length measured in atomic force micrographs. Although naked DNA only weakly stimulates ATP hydrolysis by ISWI, both atomic force microscopy and tethered particle motion data indicate that the protein generated loops in the presence of ATP. The duration of the looped state of the DNA measured using tethered particle motion was ATP‐dependent. Finally, ISWI relaxed positively supercoiled plasmids visualized by atomic force microscopy. While other chromatin remodeling ATPases catalyze either DNA wrapping or looping, both are catalyzed by ISWI. (© 2008 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Chromatin remodeling: a complex affair

ATP‐dependent chromatin remodelers are multi‐subunit enzymes that catalyze nucleosome dynamics essential for chromosomal functions, and their inactivation or dysregulation can lead to numerous diseases, including neuro‐degenerative disorders and cancers. Each remodeler contains a conserved ATPase “motor” whose activity or targeting can be regulated by enzyme‐specific, accessory subunits. The human ISWI subfamily of remodelers has been defined as a group of more than six different enzyme complexes where one of two related ATPase subunits (Snf2L/SMARCA1 and Snf2H/SMARCA5) is paired with one of six different accessory subunits. In this issue of EMBO Reports, Oppikofer et al 1 find that the human ISWI subfamily is even more polymorphic in nature—every known accessory subunit can interact and function with both ATPase isoforms. This raises the complexity of the human ISWI subfamily to > 12 distinct enzymes, with the possibility for much higher levels of combinatorial assemblies, and has the potential to create enzymes with novel biochemical activities, as well as novel regulatory wiring through differential interactions with locus‐specific factors or histone modifications.