Chromatin-remodeling factors: machines that regulate?

Chromatin has shifted into the focus of attention as a key to understanding the regulation of nuclear processes such as transcription. Protein machines have been described that use the energy of ATP to render chromatin dynamic and hence active, but which may also be involved in chromatin assembly. The discovery of three different Drosophila nucleosome remodeling complexes that contain imitation switch (ISWI), an ATPase with a high degree of sequence conservation from yeast to human, points to a central function of this ATPase in chromatin dynamics.

Soft skills turned into hard facts: nucleosome remodelling at developmental switches.

Nucleosome remodelling factors are regulators of DNA accessibility in chromatin and lubricators of all major functions of eukaryotic genomes. Their action is transient and reversible, yet can be decisive for irreversible cell-fate decisions during development. In addition to the well-known local actions of nucleosome remodelling factors during transcription initiation, more global and fundamental roles for remodelling complexes in shaping the epigenome during development are emerging.

Cell-free system for assembly of transcriptionally repressed chromatin from Drosophila embryos.

We describe a cell-free system, derived from preblastoderm Drosophila embryos, for the efficient assembly of cloned DNA into chromatin. The chromatin assembly system utilizes endogenous core histones and assembly factors and yields long arrays of regularly spaced nucleosomes with a repeat length of 180 bp. The assembly system is also capable of complementary-strand DNA synthesis accompanied by rapid nucleosome formation when the starting template is single-stranded circular DNA. Chromatin assembled with the preblastoderm embryo extract is naturally deficient in histone H1, but exogenous H1 can be incorporated during nucleosome assembly in vitro. Regular spacing of nucleosomes with or without histone H1 is sufficient to maximally repress transcription from hsp70 and fushi tarazu gene promoters. The Drosophila assembly system should be particularly useful for in vitro studies of chromatin assembly during DNA synthesis and for elucidating the action of transcription factors in the context of native chromatin.

Heat shock factor increases the reinitiation rate from potentiated chromatin templates.

Transcription by RNA polymerase II is highly regulated at the level of initiation and elongation. Well-documented transcription activation mechanisms, such as the recruitment of TFIID and TFIIB, control the early phases of preinitiation complex formation. The heat shock genes provide an example for transcriptional regulation at a later step: in nuclei TFIID can be detected at the TATA box prior to heat induction. Using cell-free systems for chromatin reconstitution and transcription, we have analyzed the mechanisms by which heat shock factor (HSF) increases transcription of heat shock genes in chromatin. HSF affected transcription of naked DNA templates in multiple ways: (i) by speeding up the rate of preinitiation complex formation, (ii) by increasing the number of productive templates, and (iii) by increasing the reinitiation rate. Under the more physiological conditions of potentiated chromatin templates, HSF affected only the reinitiation rate. Activator-dependent reinitiation of transcription, obviating the slow assembly of the TFIID-TFIIA complex on a promoter, may be especially crucial for genes requiring a fast response to inducers.

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

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 their cis-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.

A CAF-1-PCNA-mediated chromatin assembly pathway triggered by sensing DNA damage.

Sensing DNA damage is crucial for the maintenance of genomic integrity and cell cycle progression. The participation of chromatin in these events is becoming of increasing interest. We show that the presence of single-strand breaks and gaps, formed either directly or during DNA damage processing, can trigger the propagation of nucleosomal arrays. This nucleosome assembly pathway involves the histone chaperone chromatin assembly factor 1 (CAF-1). The largest subunit (p150) of this factor interacts directly with proliferating cell nuclear antigen (PCNA), and critical regions for this interaction on both proteins have been mapped. To isolate proteins specifically recruited during DNA repair, damaged DNA linked to magnetic beads was used. The binding of both PCNA and CAF-1 to this damaged DNA was dependent on the number of DNA lesions and required ATP. Chromatin assembly linked to the repair of single-strand breaks was disrupted by depletion of PCNA from a cell-free system. This defect was rescued by complementation with recombinant PCNA, arguing for role of PCNA in mediating chromatin assembly linked to DNA repair. We discuss the importance of the PCNA-CAF-1 interaction in the context of DNA damage processing and checkpoint control.

Reconstitution of human beta-globin locus control region hypersensitive sites in the absence of chromatin assembly.

The human beta-globin genes are regulated by the locus control region (LCR), an element composed of multiple DNase I-hypersensitive sites (HS sites) located 5' to the genes. Various functional studies indicate that the LCR confers high-level, position-independent, and copy number-dependent expression to linked globin genes in transgenic mice. However, the structural basis for LCR function is unknown. Here we show that LCR HS sites can be reconstituted in an erythroid cell-specific manner on chromatin-assembled LCR templates in vitro. Surprisingly, HS2 and HS3 are also formed with erythroid proteins in the absence of chromatin assembly, indicating that sensitivity to nucleases is not simply a consequence of nucleosome reorganization. The generation of LCR HS sites in the absence of chromatin assembly leads to the formation of S1- and KMnO(4)-sensitive regions in HS2 and HS3. These sites are also sensitive to S1 nuclease in erythroid cells in vivo, suggesting a distorted DNA structure in the LCR core enhancer elements. Finally, we show that RNA polymerase II initiates transcription in the HS2 and HS3 core enhancer regions in vitro. Transcription in both HS2 and HS3 proceeds in a unidirectional manner. Taken together, the data suggest that erythroid proteins interact with the core enhancer elements, distort the DNA structure, and recruit polymerase II transcription complexes. These results further our understanding of the structural basis for LCR function and provide an explanation for why the LCR core regions are so extremely sensitive to nucleases in erythroid cells.

Critical role for the histone H4 N terminus in nucleosome remodeling by ISWI.

The ATPase ISWI can be considered the catalytic core of several multiprotein nucleosome remodeling machines. Alone or in the context of nucleosome remodeling factor, the chromatin accessibility complex (CHRAC), or ACF, ISWI catalyzes a number of ATP-dependent transitions of chromatin structure that are currently best explained by its ability to induce nucleosome sliding. In addition, ISWI can function as a nucleosome spacing factor during chromatin assembly, where it will trigger the ordering of newly assembled nucleosomes into regular arrays. Both nucleosome remodeling and nucleosome spacing reactions are mechanistically unexplained. As a step toward defining the interaction of ISWI with its substrate during nucleosome remodeling and chromatin assembly we generated a set of nucleosomes lacking individual histone N termini from recombinant histones. We found the conserved N termini (the N-terminal tails) of histone H4 essential to stimulate ISWI ATPase activity, in contrast to other histone tails. Remarkably, the H4 N terminus, but none of the other tails, was critical for CHRAC-induced nucleosome sliding and for the generation of regularity in nucleosomal arrays by ISWI. Direct nucleosome binding studies did not reflect a dependence on the H4 tail for ISWI-nucleosome interactions. We conclude that the H4 tail is critically required for nucleosome remodeling and spacing at a step subsequent to interaction with the substrate.

The effect of nucleosome phasing sequences and DNA topology on nucleosome spacing.

The distances between the nucleosomes in eukaryotic chromatin that define the nucleosome repeat length are not universally constant, but vary between different cell types and activity states. We have previously established in a cell-free system that nucleosome spacing is essentially governed by electrostatic principles, most likely through charge neutralisation of linker DNA by cations either free in solution or on flexible histone domains. On the basis of the tight correlation between the parameters that affect nucleosome spacing and those that influence the folding of the nucleosomal fiber into higher order structures, we suggested that there is an intimate relationship between nucleosome spacing and chromatin folding. Here we describe DNA topology as a new parameter that influences nucleosome spacing in a predictable way. The effects of topology and cation concentrations integrate to define the final repeat length. The phenomenon of "nucleosome phasing" describes nucleosomal arrays that are generated through positioning of nucleosomes by the underlying DNA sequence. To determine the relative contribution of DNA sequence and the parameters intrinsic to physiological chromatin for nucleosomal positions, we created situations where these two principles were in conflict. We found that nucleosome repeats directed by a strong positioning sequence are dominated by the cation-induced spacing as well as by the effects of topology. We conclude that the DNA sequence effects nucleosome spacing only by "fine tuning" of nucleosome positions within the framework of a repeat pattern that is established by other principles.

Electrostatic mechanism of nucleosome spacing.

Native bulk chromatin is characterized by regular arrays of nucleosomes with defined internucleosomal distances. The nucleosome repeat length is not a constant but varies between species and cell-types, during differentiation and during gene activation. Previous studies have highlighted the importance of linker histones as a major determinant of nucleosome repeat length in vivo. We used a physiological reconstitution system derived from Drosophila embryos to study nucleosome spacing. In these extracts, histone H1 incorporation increases the apparent linker length in a gradual way. Manipulation of the chromatin assembly conditions in vitro allowed us to define additional parameters that modulate nucleosomal distances, such as protein phosphorylation events and the precise ionic conditions during the reconstitution. Interestingly, moderate changes in the concentrations of mono-, di-, and multivalent cations affect the precise distances between nucleosome cores remarkably. These changes in the ionic environment are unlikely to affect the association of linker proteins but are known to influence the folding of the nucleosomal fiber by modulation of electrostatic forces. Our results suggest electrostatic interactions in chromatin units as major determinants of nucleosome spacing. Nucleosome spacing and the folding of the nucleosomal fiber can therefore be explained by common principles, most notably the neutralization of charges in linker DNA.

The architecture of the heat-inducible Drosophila hsp27 promoter in nuclei.

Transcriptional activation of the Drosophila hsp27 gene in response to heat shock critically relies on binding sites for heat shock factor (HSF) about 300 bp upstream of the transcription start site. In contrast to the well-characterised heat-inducible hsp70 and hsp26 promoters, no other transcription factor binding sites have been identified closer to the TATA box. In order to understand the structural requirements for activation from a distance we studied the protein-DNA interactions at the hsp27 promoter in Drosophila embryos and tissue culture cells before and after heat induction. Genomic footprinting with nucleases and a chemical probe, the 1,10-phenanthroline cuprous complex (OP-Cu), suggests that the DNA between the TATA box and the heat shock elements (HSEs) is constitutively organised by a positioned nucleosome, effectively shortening the distance between the distal HSEs and the TATA box. Protection of the TATA element from nuclease attack and the OP-Cu reactivity pattern around the start site of transcription is consistent with the constitutive presence of TFIID and the "poised polymerase", a transcription machinery blocked in an early phase of elongation. The general transcription factors at the TATA box and the positioned nucleosome are separated by a stable structure, presumably a protein bound to a palindromic sequence. These constitutive features define the "preset" architecture of the promoter within which the induced binding of HSF in vivo is observed. Our study highlights the importance of positioned nucleosomes as architectural elements within promoters and identifies a new regulatory sequence that may function either to direct a nucleosome boundary or to mediate signals of distant activator proteins.

The bifunctional protein DCoH modulates interactions of the homeodomain transcription factor HNF1 with nucleic acids.

The hepatocyte nuclear factor-1 (HNF1) is a homeodomain transcription factor that binds DNA as a dimer. HNF1 dimers associate with two molecules of DCoH, a bifunctional protein that also has an enzymatic function in the tetrahydrobiopterin regeneration, to form stable heterotetramers also capable of DNA binding. Employing purified, recombinant HNF1, HNF1/DCoH heterotetramers and DCoH homotetramers we investigated whether DCoH affects interactions of HNF1 with nucleic acids. Although we detected no direct binding of DCoH to DNA or RNA, DCoH stabilized HNF1/DNA complexes and promoted interactions with sub-optimal DNA target sequences such as the human alpha1-antitrypsin TATA box region. Importantly, we also observed interactions of HNF1 with RNA, but these interactions were completely abolished when HNF1 was complexed with DCoH. Interestingly, DCoH retains its enzymatic activity while complexed with HNF1. Our results document intermolecular regulation of HNF1 binding to nucleic acids by DCoH.

The glutamine-rich domain of the Drosophila GAGA factor is necessary for amyloid fibre formation in vitro, but not for chromatin remodelling.

The Drosophila GAGA factor binds specifically to the sequence GAGAG, and synergises with nucleosome remodelling factor to remodel chromatin in vitro. It consists of an N-terminal domain (POZ/BTB) which mediates protein-protein interactions, a central region which contains the DNA-binding domain, and a C-terminal glutamine-rich region. It is shown that the glutamine-rich region is responsible for the formation of fibres in vitro which, on the basis of their tinctorial properties and CD spectra, may be classified as amyloid fibres. A large structural change, probably resulting in beta-sheet structure, is observed upon fibre formation. Mutants containing the central region, either alone or together with the glutamine-rich region, are largely lacking in secondary structure but they bind specifically to the cognate DNA and are able to remodel chromatin in vitro. Consequently, neither the N-terminal domain nor the C-terminal glutamine-rich regions of the GAGA factor are necessary for chromatin remodelling in vitro.

Transcription factor-mediated chromatin remodelling: mechanisms and models.

The association of DNA with nucleosomes in chromatin severely restricts the access of the regulatory factors that bring about transcription. In vivo active promoters are characterised by altered, almost transparent chromatin structures that allow the interaction of the transcriptional machinery. Recently, enzymatic activities have been discovered that facilitate the binding of transcription factors to chromatin by modifying nucleosomal structures in a process that requires energy. The mechanisms by which chromatin is remodelled may involve nucleosome movements, their transient unfolding, their partial or even complete disassembly. The dynamic properties of chromatin that underlie these structural changes are fundamental to the process of regulated gene expression.

Nonradioactive, solid-phase DNase I footprints analyzed on an A.L.F. DNA Sequencer.

Solid-phase DNase I footprinting provides a powerful tool for analyzing the sequence-specific interactions of DNA binding proteins. Classically this type of assay requires radioactively labeled DNA molecules. Substitution of the isotope by fluorescein labeling of the DNA fragments enables the analysis of footprint patterns on a standard automated laser fluorescent (A.L.F.) DNA Sequencer. The combination of solid-phase footprinting technology and fluorescence-based nonradioactive detection of fragments has unique advantages over established footprinting technologies.

Patterns and significance of exhaled-breath biomarkers in lung transplant recipients with acute allograft rejection.

BACKGROUND: Obliterative bronchiolitis (OB) remains one of the leading causes of death in lung transplant recipients after 2 years, and acute rejection (AR) of lung allograft is a major risk factor for OB. Treatment of AR may reduce the incidence of OB, although diagnosis of AR often requires bronchoscopic lung biopsy. In this study, we evaluated the utility of exhaled-breath biomarkers for the non-invasive diagnosis of AR. METHODS: We obtained breath samples from 44 consecutive lung transplant recipients who attended ambulatory follow-up visits for the Johns Hopkins Lung Transplant Program. Bronchoscopy within 7 days of their breath samples showed histopathology in 21 of these patients, and we included them in our analysis. We measured hydrocarbon markers of pro-oxidant events (ethane and 1-pentane), isoprene, acetone, and sulfur-containing compounds (hydrogen sulfide and carbonyl sulfide) in exhaled breath and compared their levels to the lung histopathology, graded as stable (non-rejection) or AR. None of the study subjects were diagnosed with OB or infection at the time of the clinical bronchoscopy. RESULTS: We found no significant difference in exhaled levels of hydrocarbons, acetone, or hydrogen sulfide between the stable and AR groups. However, we did find significant increase in exhaled carbonyl sulfide (COS) levels in AR subjects compared with stable subjects. We also observed a trend in 7 of 8 patients who had serial sets of breath and histopathology data that supported a role for COS as a breath biomarker of AR. CONCLUSIONS: This study demonstrated elevations in exhaled COS levels in subjects with AR compared with stable subjects, suggesting a diagnostic role for this non-invasive biomarker. Further exploration of breath analysis in lung transplant recipients is warranted to complement fiberoptic bronchoscopy and obviate the need for this procedure in some patients.

Modifications of the histone N-terminal domains. Evidence for an "epigenetic code"?

A multicellular organism is made up of a variety of different cell types and tissues. This organization is accomplished by a well-concerted action of different regulatory molecules, which--in a very hierarchical manner--influence the expression of certain cell-specific genes. Many of those regulators are transcription factors, which directly influence the expression of the controlled gene by binding to a specific DNA sequence within its promoter or enhancer region. This binding then leads to an enhancement or a decrease in the rate of transcription of that particular gene and eventually regulates the production of the corresponding polypeptide. One major obstacle to the binding of these transcription factors is the fact that DNA is not readily accessible in the eukaryotic nucleus. It is associated with a class of very basic proteins called histones. This complex of histones and DNA is called chromatin.