Heterochromatin at mouse pericentromeres: a model for de novo heterochromatin formation and duplication during replication.

How a nuclear domain is formed at specific chromatin loci and maintained throughout multiple cellular divisions is a central question in the field of nuclear organization. Recent efforts have concentrated on understanding how a domain is set during development in a particular cell lineage and then how DNA replication and repair in interphase as well as chromosome dynamics in mitosis deal with chromatin states at specific loci to propagate functional organization. In the latter case, for each of these events, one must not only evaluate the impact in terms of the extent of the disruption and/or modification of chromatin but also determine how and when proper organization can be restored thereafter. Using heterochromatin at mouse pericentromeres as a model, we present how important advances have been made that open avenues for understanding mechanisms involved in de novo heterochromatin formation and its duplication during replication.

Dimerization of the largest subunit of chromatin assembly factor 1: importance in vitro and during Xenopus early development.

To date, the in vivo importance of chromatin assembly factors during development in vertebrates is unknown. Chromatin assembly factor 1 (CAF-1) represents the best biochemically characterized factor promoting chromatin assembly during DNA replication or repair in human cell-free systems. Here, we identify a Xenopus homologue of the largest subunit of CAF-1 (p150). Novel dimerization properties are found conserved in both Xenopus and human p150. A region of 36 amino acids required for p150 dimerization was identified. Deletion of this domain abolishes the ability of p150 to promote chromatin assembly in vitro. A dominant-negative interference based on these dimerization properties occurs both in vitro and in vivo. In the embryo, nuclear organization was severely affected and cell cycle progression was impaired during the rapid early cleaving stages of Xenopus development. We propose that the rapid proliferation at early developmental stages necessitates the unique properties of an assembly factor that can ensure a tight coupling between DNA replication or repair and chromatin assembly.

Direct imaging of single-molecules: from dynamics of a single DNA chain to the study of complex DNA-protein interactions.

Recent years have seen significant advances in the characterization and manipulation of individual molecules. The combination of single-molecule fluorescence and micromanipulation enables one to study physical and biological systems at new length scales, to unravel qualitative mechanisms, and to measure kinetic parameters that cannot be addressed by traditional biochemistry. DNA is one of the most studied biomolecules. Imaging single DNA molecules eliminates important limitations of classical techniques and provides a new method for testing polymer dynamics and DNA-protein interactions. Here we review some applications of this new approach to physical and biological problems, focusing on videomicroscopy observations of individual DNA chains extended in a shear flow. We will first describe data obtained on the stretching, relaxation and dynamics of a single tethered polymer in a shear flow, to demonstrate that the deformation of sheared tethered chains is partially governed by the thermally driven fluctuations of the chain transverse to the flow direction. Next, we will show how single-molecule videomicroscopy can be used to study in real time DNA folding into chromatin, a complex association of DNA and proteins responsible for the packaging of DNA in the nucleus of an eukaryotic cell.

Fast kinetics of chromatin assembly revealed by single-molecule videomicroscopy and scanning force microscopy.

Fluorescence videomicroscopy and scanning force microscopy were used to follow, in real time, chromatin assembly on individual DNA molecules immersed in cell-free systems competent for physiological chromatin assembly. Within a few seconds, molecules are already compacted into a form exhibiting strong similarities to native chromatin fibers. In these extracts, the compaction rate is more than 100 times faster than expected from standard biochemical assays. Our data provide definite information on the forces involved (a few piconewtons) and on the reaction path. DNA compaction as a function of time revealed unique features of the assembly reaction in these extracts. They imply a sequential process with at least three steps, involving DNA wrapping as the final event. An absolute and quantitative measure of the kinetic parameters of the early steps in chromatin assembly under physiological conditions could thus be obtained.

Tetracycline-regulated gene expression switch in Xenopus laevis.

Xenopus is a well-characterized model system for the investigation of biological processes at the molecular, cellular, and developmental level. The successful application of a rapid and reliable method for transgenic approaches in Xenopus has led to renewed interest in this system. We have explored the applicability of tetracycline-regulated gene expression, first described by Gossen and Bujard in 1992, to the Xenopus system. By optimizing conditions, tetracycline repressor induced expression of a luciferase reporter gene was readily and reproducibly achieved in both the Xenopus oocyte and developing embryo. This high level of expression was effectively abrogated by addition of low levels of tetracycline. The significance of this newly defined system for studies of chromatin dynamics and developmental processes is discussed.

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.

Core histones and HIRIP3, a novel histone-binding protein, directly interact with WD repeat protein HIRA.

The human HIRA gene has been named after Hir1p and Hir2p, two corepressors which together appear to act on chromatin structure to control gene transcription in Saccharomyces cerevisiae. HIRA homologs are expressed in a regulated fashion during mouse and chicken embryogenesis, and the human gene is a major candidate for the DiGeorge syndrome and related developmental disorders caused by a reduction to single dose of a fragment of chromosome 22q. Western blot analysis and double-immunofluorescence experiments using a specific antiserum revealed a primary nuclear localization of HIRA. Similar to Hir1p, HIRA contains seven amino-terminal WD repeats and probably functions as part of a multiprotein complex. HIRA and core histone H2B were found to physically interact in a yeast double-hybrid protein interaction trap, in GST pull-down assays, and in coimmunoprecipitation experiments performed from cellular extracts. In vitro, HIRA also interacted with core histone H4. H2B- and H4-binding domains were overlapping but distinguishable in the carboxy-terminal region of HIRA, and the region for HIRA interaction was mapped to the amino-terminal tail of H2B and the second alpha helix of H4. HIRIP3 (HIRA-interacting protein 3) is a novel gene product that was identified from its HIRA-binding properties in the yeast protein interaction trap. In vitro, HIRIP3 directly interacted with HIRA but also with core histones H2B and H3, suggesting that a HIRA-HIRIP3-containing complex could function in some aspects of chromatin and histone metabolism. Insufficient production of HIRA, which we report elsewhere interacts with homeodomain-containing DNA-binding factors during mammalian embryogenesis, could perturb the stoichiometric assembly of multimolecular complexes required for normal embryonic development.

Initiation and bidirectional propagation of chromatin assembly from a target site for nucleotide excision repair.

To restore full genomic integrity in a eukaryotic cell, DNA repair processes have to be coordinated with the resetting of nucleosomal organization. We have established a cell-free system using Drosophila embryo extracts to investigate the mechanism linking de novo nucleosome formation to nucleotide excision repair (NER). Closed-circular DNA containing a uniquely placed cisplatin-DNA adduct was used to follow chromatin assembly specifically from a site of NER. Nucleosome formation was initiated from a target site for NER. The assembly of nucleosomes propagated bidirectionally, creating a regular nucleosomal array extending beyond the initiation site. Furthermore, this chromatin assembly was still effective when the repair synthesis step in the NER process was inhibited.

Genomic footprinting of Drosophila embryo nuclei by linker tag selection LM-PCR.

The unmatched power of Drosophila genetics revealed the complex regulatory network of gene activities that governs the development of higher eukaryotes. An understanding of gene control at the level of transcription requires insight into the protein/DNA interactions that regulate transcription in the developing embryo. Genomic footprinting allows the direct visualization of these protein/DNA interactions within intact nuclei or cells. In combination with other in vivo assays such as protein/DNA crosslinking and classical biochemistry, genomic footprinting can give valuable insight into the architecture of promoters in various states of activity. In this article we summarize our experience in analyzing Drosophila embryos by genomic footprinting and describe modifications of the ligation-mediated PCR procedure that have improved this analysis. Applications of genomic footprinting to embryos are currently limited by the fact that all target nuclei must be uniform with respect to the protein/DNA interactions at the chosen site. We discuss strategies that should allow the analysis of small numbers of cells derived from heterogeneous populations and tissues.

Solid phase technology improves coupled gel shift/footprinting analysis.

For the analysis of protein-DNA interactions by coupled gel-shift/footprinting, DNA fragments need to be extracted from polyacrylamide gels and subsequently separated on high resolution gels. Due to impurities in the extracted DNA, single nucleotide resolution is frequently not achieved. We now describe an improved experimental strategy that employs transient coupling of DNA fragments to a solid support in order to extract DNA of high purity quantitatively, rapidly and reliably. As an example, we describe the application of our protocol to the 'in-gel footprinting' by copper phenanthroline. The method should also find application to the chemical interference assays.

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 interaction of wheat germ tyrosyl-tRNA synthetase and the tRNA-like end of brome mosaic virus RNA has no effect on in vitro viral protein synthesis and on in vitro encapsidation.

The effect of aminoacylation of the tRNA-like end of brome mosaic virus RNA during in vitro protein synthesis and in vitro viral encapsidation was investigated. The components of the homologous system were: BMV RNA, wheat germ cell-free protein synthesizing system and pure tyrosyl-tRNA synthetase from wheat germ. During in vitro protein synthesis directed with tyrosylated as well as non-tyrosylated BMV RNA, no differences were observed in the amount and in the class of polypeptides formed neither in the velocity of the translation reaction. Excess active TyrRS was added during in vitro translation, without modifying the translation efficiency. BMV RNA and active TyrRS were preincubated prior to translation in order to interact without the translation system components and then subjected to translation in vitro. Similar results were obtained when BMV RNA was preincubated with inactive TyrRS or BSA. These results indicate that the aminoacylation of BMV RNA has no pronounced effect on viral protein synthesis in vitro. During BMV RNA encapsidation either tyrosylated or non-tyrosylated BMV RNA 4 could be encapsidated in a similar way.

Tyrosyl-tRNA synthetase from wheat germ.

Tyrosyl-tRNA synthetase (TyrRS) was purified 5,000-fold from wheat germ extract by ultracentrifugation, precipitation with ammonium acetate, and column chromatography. Under denaturing conditions the enzyme ran as a single band on SDS-polyacrylamide electrophoresis with an apparent Mr of 55,000. The native molecular weight determined by gel filtration was 110,000, suggesting a quaternary structure of an alpha 2 type for native TyrRS. Purified enzyme activity, based on the aminoacylation reaction, was studied in terms of Mg2+, ATP, pH, and KCl dependence. Optimum concentrations were 6 mM Mg2+, 4 mM ATP, and 200 mM KCl at pH 8. The Km values for ATP, tyrosine, and tRNA were 40, 3.3, and 1.5 microM, respectively. The instability of the TyrRS activity and the methods used for stabilizing it are discussed. In wheat germ extract we found a second tyrosylating activity that works with Escherichia coli tRNA, but not with wheat germ tRNA. We believe that this enzyme is the mitochondrial tyrosyl-tRNA synthetase of wheat germ.