Edgar Bonte

Chromatin-remodelling factor CHRAC contains the ATPases ISWI and topoisomerase II.

Repressive chromatin structures need to be unravelled to allow DNA-binding proteins access to their target sequences. This de-repression constitutes an important point at which transcription and presumably other nuclear processes can be regulated,. Energy-consuming enzyme complexes that facilitate the interaction of transcription factors with chromatin by modifying nucleosome structure are involved in this regulation. One such factor, nucleosome-remodelling factor (NURF), has been isolated from Drosophila embryo extracts,,. We have now identified a chromatin-accessibility complex (CHRAC) which uses energy to increase the general accessibility of DNA in chromatin. However, unlike other known chromatin remodelling factors, CHRAC can also function during chromatin assembly: it uses ATP to convert irregular chromatin into a regular array of nucleosomes with even spacing. CHRAC combines enzymes that modulate nucleosome structure and DNA topology. Using mass spectrometry, we identified two of the five CHRAC subunits as the ATPase ISWI, which is also part of NURF,, and topoisomerase II. The presence of ISWI in different contexts suggests that chromatin remodelling machines have a modular nature and that ISWI has a central role in different chromatin remodelling reactions.

Nucleosome Movement by CHRAC and ISWI without Disruption or trans-Displacement of the Histone Octamer

The chromatin accessibility complex (CHRAC) belongs to the class of nucleosome remodeling factors that increase the accessibility of nucleosomal DNA in an ATP-dependent manner. We found that CHRAC induces movements of intact histone octamers to neighboring DNA segments without facilitating their displacement to competing DNA or histone chaperones in trans. CHRAC-induced energy-dependent nucleosome sliding may, in principle, explain nucleosome remodeling, nucleosome positioning, and nucleosome spacing reactions known to be catalyzed by CHRAC. The catalytic core of CHRAC, the ATPase ISWI, also mobilized nucleosomes at the expense of energy. However, the directionality of the CHRAC- and ISWI-induced nucleosome movements differed drastically, indicating that the geometry of the native complex modulates the activity of its catalytic core.

ATP-Dependent Chromatin Remodeling by the Cockayne Syndrome B DNA Repair-Transcription-Coupling Factor

ABSTRACT The Cockayne syndrome B protein (CSB) is required for coupling DNA excision repair to transcription in a process known as transcription-coupled repair (TCR). Cockayne syndrome patients show UV sensitivity and severe neurodevelopmental abnormalities. CSB is a DNA-dependent ATPase of the SWI2/SNF2 family. SWI2/SNF2-like proteins are implicated in chromatin remodeling during transcription. Since chromatin structure also affects DNA repair efficiency, chromatin remodeling activities within repair are expected. Here we used purified recombinant CSB protein to investigate whether it can remodel chromatin in vitro. We show that binding of CSB to DNA results in an alteration of the DNA double-helix conformation. In addition, we find that CSB is able to remodel chromatin structure at the expense of ATP hydrolysis. Specifically, CSB can alter DNase I accessibility to reconstituted mononucleosome cores and disarrange an array of nucleosomes regularly spaced on plasmid DNA. In addition, we show that CSB interacts not only with double-stranded DNA but also directly with core histones. Finally, intact histone tails play an important role in CSB remodeling. CSB is the first repair protein found to play a direct role in modulating nucleosome structure. The relevance of this finding to the interplay between transcription and repair is discussed.

ISWI Is an ATP-Dependent Nucleosome Remodeling Factor

The ATPase ISWI is a subunit of several distinct nucleosome remodeling complexes that increase the accessibility of DNA in chromatin. We found that the isolated ISWI protein itself was able to carry out nucleosome remodeling, nucleosome rearrangement, and chromatin assembly reactions. The ATPase activity of ISWI was stimulated by nucleosomes but not by free DNA or free histones, indicating that ISWI recognizes a specific structural feature of nucleosomes. Nucleosome remodeling, therefore, does not require a functional interaction between ISWI and the other subunits of ISWI complexes. The role of proteins associated with ISWI may be to regulate the activity of the remodeling engine or to define the physiological context within which a nucleosome remodeling reaction occurs.

In vitro chromatin remodelling by chromatin accessibility complex (CHRAC) at the SV40 origin of DNA replication

DNA replication is initiated by binding of initiation factors to the origin of replication. Nucleosomes are known to inhibit the access of the replication machinery to origin sequences. Recently, nucleosome remodelling factors have been identified that increase the accessibility of nucleosomal DNA to transcription regulators. To test whether the initiation of DNA replication from an origin covered by nucleosomes would also benefit from the action of nucleosome remodelling factors, we reconstituted SV40 DNA into chromatin in Drosophila embryo extracts. In the presence of T‐antigen and ATP, a chromatin‐associated cofactor allowed efficient replication from a nucleosomal origin in vitro. In search of the energy‐dependent cofactor responsible we found that purified ‘chromatin accessibility complex’ (CHRAC) was able to alter the nucleosomal structure at the origin allowing the binding of T‐antigen and efficient initiation of replication. These experiments provide evidence for the involvement of a nucleosome remodelling machine in structural changes at the SV40 origin of DNA replication in vitro.

The Drosophila polycomb protein interacts with nucleosomal core particles In vitro via its repression domain.

ABSTRACT The proteins of the Polycomb group (PcG) are required for maintaining regulator genes, such as the homeotic selectors, stably and heritably repressed in appropriate developmental domains. It has been suggested that PcG proteins silence genes by creating higher-order chromatin structures at their chromosomal targets, thus preventing the interaction of components of the transcriptional machinery with theircis-regulatory elements. An unresolved issue is how higher order-structures are anchored at the chromatin base, the nucleosomal fiber. Here we show a direct biochemical interaction of a PcG protein—the Polycomb (PC) protein—with nucleosomal core particles in vitro. The main nucleosome-binding domain coincides with a region in the C-terminal part of PC previously identified as the repression domain. Our results suggest that PC, by binding to the core particle, recruits other PcG proteins to chromatin. This interaction could provide a key step in the establishment or regulation of higher-order chromatin structures.

Dual regulation of the Drosophila hsp26 promoter in vitro.

Efficient heat shock induction of Drosophila hsp26 gene transcription in vivo requires binding sites for heat shock factor (HSF) and GAGA factor (GAF) close to the TATA box (proximal elements) as well as 350 bp upstream of the start site of transcription (distal elements). We have evaluated the contribution of hsp26 promoter sequences to transcriptional activity in extracts from either heat shocked or unstressed fly embryos. Efficient transcription in either extract was governed by distinct regulatory principles. Transcription in extracts from unstressed embryos relied solely on GAGA elements which efficiently counteracted repression by abundant non-specific DNA-binding proteins. Transcription in extracts from heat shocked embryos depended only a little on GAGA elements, relying mainly on functional HSEs. Constitutively active recombinant HSF or native factor in an extract from heat shocked embryos was able to truly activate transcription essentially via proximal HSEs, but not when bound to distal sites. These two modes of regulation in vitro may correspond to the two functional states of the promoter before and after heat shock in vivo.

Preparation of chromatin assembly extracts from preblastoderm Drosophila embryos.

A rigorous biochemical analysis of chromatin structure and function requires the assembly of chromatin in vitro. A useful alternative to reconstituting nucleosomal arrays from pure or recombinant histones by salt gradient dialysis is the assembly of more complex chromatin from assembly extracts under physiological conditions. Extracts from preblastoderm embryos have proven to be particularly efficient, due to the presence of large stores of native complexes of histones, histone chaperones and ATP-dependent nucleosome spacing factors. The resulting chromatin is an excellent approximation of physiological chromatin in vivo. This chapter describes the preparation of chromatin assembly extracts and the chromatin assembly reaction.

Analysis of modulators of chromatin structure in Drosophila

Publisher Summary This chapter describes the methodology that led to the identification and preliminary characterization of one specific remodeling machine, the chromatin accessibility complex (CHRAC). CHRAC functions as an ATP-dependent nucleosome spacing factor during chromatin assembly by facilitating the relocation of nucleosomes on DNA. The chapter describes general methods required to establish a restriction enzyme accessibility assay to purify CHRAC or similar activities from other biological sources and species. The chapter describes three additional assays that may be employed to analyze remodeling complexes: a nucleosome spacing assay, an (ATPase) assay, and a strategy to assess interactions of nucleosome remodeling machines with nucleosomes, which involves single nucleosomes immobilized onto paramagnetic beads. The chapter also discusses various assays that have been used by researchers to characterize nucleosome remodeling complexes. The chapter describes nucleosome reconstitution using Drosophila embryo extracts.