Jeffrey J. Hayes

A positive role for histone acetylation in transcription factor access to nucleosomal DNA

Acetylation of the N-terminal tails of the core histones directly facilitates the recognition by TFIIIA of the 5S RNA gene within model chromatin templates. This effect is independent of a reduction in the extent of histone-DNA interactions or a change in DNA helical repeat; it is also independent of whether a histone tetramer or octamer inhibits TFIIIA binding. Removal of the N-terminal tails from the core histones also facilitates the association of TFIIIA with nucleosomal templates. We suggest that the histone tails have a major role in restricting transcription factor access to DNA and that their acetylation releases this restriction by directing dissociation of the tails from DNA and/or inducing a change in DNA configuration on the histone core to allow transcription factor binding. Acetylation of core histones might be expected to exert a major influence on the accessibility of chromatin to regulatory molecules.

Identification of additional genes belonging to the LexA regulon in Escherichia coli

Exposure of Escherichia coli to a variety of DNA‐damaging agents results in the induction of the global ‘SOS response’. Expression of many of the genes in the SOS regulon are controlled by the LexA protein. LexA acts as a transcriptional repressor of these unlinked genes by binding to specific sequences (LexA boxes) located within the promoter region of each LexA‐regulated gene. Alignment of 20 LexA binding sites found in the E. coli chromosome reveals a consensus of 5′‐TACTG(TA)5CAGTA‐3′. DNA sequences that exhibit a close match to the consensus are said to have a low heterology index and bind LexA tightly, whereas those that are more diverged have a high heterology index and are not expected to bind LexA. By using this heterology index, together with other search criteria, such as the location of the putative LexA box relative to a gene or to promoter elements, we have performed computational searches of the entire E. coli genome to identify novel LexA‐regulated genes. These searches identified a total of 69 potential LexA‐regulated genes/operons with a heterology index of < 15 and included all previously characterized LexA‐regulated genes. Probes were made to the remaining genes, and these were screened by Northern analysis for damage‐inducible gene expression in a wild‐type lexA+ cell, constitutive expression in a lexA(Def) cell and basal expression in a non‐inducible lexA(Ind−) cell. These experiments have allowed us to identify seven new LexA‐regulated genes, thus bringing the present number of genes in the E. coli LexA regulon to 31. The potential function of each newly identified LexA‐regulated gene is discussed.

Hydroxyl radical footprinting.

Publisher Summary This chapter provides an overview on hydroxyl radical footprinting. Hydroxyl radical footprinting of DNA has evolved over the last several years into a facile and powerful technique for studying DNA structure and complexes of DNA with other molecules. The chapter describes the chemistry and history behind these techniques. In a footprinting experiment, a strand of DNA is subjected to cleavage by some reagent, both in the presence and absence of a DNA-binding ligand. Comparison of the cleavage patterns yields information on the structure of the DNA-ligand complex. Footprinting can also be used to obtain thermodynamic information on DNA-ligand complexes through footprint titration experiments.

(CAG) n -hairpin DNA binds to Msh2–Msh3 and changes properties of mismatch recognition

Cells have evolved sophisticated DNA repair systems to correct damaged DNA. However, the human DNA mismatch repair protein Msh2–Msh3 is involved in the process of trinucleotide (CNG) DNA expansion rather than repair. Using purified protein and synthetic DNA substrates, we show that Msh2–Msh3 binds to CAG-hairpin DNA, a prime candidate for an expansion intermediate. CAG-hairpin binding inhibits the ATPase activity of Msh2–Msh3 and alters both nucleotide (ADP and ATP) affinity and binding interfaces between protein and DNA. These changes in Msh2–Msh3 function depend on the presence of A·A mispaired bases in the stem of the hairpin and on the hairpin DNA structure per se. These studies identify critical functional defects in the Msh2–Msh3–CAG hairpin complex that could misdirect the DNA repair process.

A positive role for nucleosome mobility in the transcriptional activity of chromatin templates: restriction by linker histones.

Nucleosome mobility facilitates the transcription of chromatin templates containing only histone octamers. Inclusion of linker histones in chromatin inhibits nucleosome mobility, directs nucleosome positioning and represses transcription. Transcriptional repression by linker histone occurs preferentially on templates associated with histone octamers relative to naked DNA. Mobile nucleosomes and the restriction of mobility by linker histones might be expected to exert a major influence on the accessibility of chromatin to regulatory molecules.

An Asymmetric Model for the Nucleosome: A Binding Site for Linker Histones Inside the DNA Gyres

Histone-DNA contacts within a nucleosome influence the function of trans-acting factors and the molecular machines required to activate the transcription process. The internal architecture of a positioned nucleosome has now been probed with the use of photoactivatable cross-linking reagents to determine the placement of histones along the DNA molecule. A model for the nucleosome is proposed in which the winged-helix domain of the linker histone is asymmetrically located inside the gyres of DNA that also wrap around the core histones. This domain extends the path of the protein superhelix to one side of the core particle.

Single-base resolution mapping of H1–nucleosome interactions and 3D organization of the nucleosome

Despite the key role of the linker histone H1 in chromatin structure and dynamics, its location and interactions with nucleosomal DNA have not been elucidated. In this work we have used a combination of electron cryomicroscopy, hydroxyl radical footprinting, and nanoscale modeling to analyze the structure of precisely positioned mono-, di-, and trinucleosomes containing physiologically assembled full-length histone H1 or truncated mutants of this protein. Single-base resolution •OH footprinting shows that the globular domain of histone H1 (GH1) interacts with the DNA minor groove located at the center of the nucleosome and contacts a 10-bp region of DNA localized symmetrically with respect to the nucleosomal dyad. In addition, GH1 interacts with and organizes about one helical turn of DNA in each linker region of the nucleosome. We also find that a seven amino acid residue region (121–127) in the COOH terminus of histone H1 was required for the formation of the stem structure of the linker DNA. A molecular model on the basis of these data and coarse-grain DNA mechanics provides novel insights on how the different domains of H1 interact with the nucleosome and predicts a specific H1-mediated stem structure within linker DNA.

Acetylation Mimics within Individual Core Histone Tail Domains Indicate Distinct Roles in Regulating the Stability of Higher-Order Chromatin Structure

ABSTRACT Nucleosome arrays undergo salt-dependent self-association into large oligomers in a process thought to recapitulate essential aspects of higher-order tertiary chromatin structure formation. Lysine acetylation within the core histone tail domains inhibits self-association, an effect likely related to its role in facilitating transcription. As acetylation of specific tail domains may encode distinct functions, we investigated biochemical and self-association properties of model nucleosome arrays containing combinations of native and mutant core histones with lysine-to-glutamine substitutions to mimic acetylation. Acetylation mimics within the tail domains of H2B and H4 caused the largest inhibition of array self-association, while modification of the H3 tail uniquely affected the stability of DNA wrapping within individual nucleosomes. In addition, the effect of acetylation mimics on array self-association is inconsistent with a simple charge neutralization mechanism. For example, acetylation mimics within the H2A tail can have either a positive or negative effect on self-association, dependent upon the acetylation state of the other tails and nucleosomal repeat length. Finally, we demonstrate that glutamine substitutions and lysine acetylation within the H4 tail domain have identical effects on nucleosome array self-association. Our results indicate that acetylation of specific tail domains plays distinct roles in the regulation of chromatin structure.

Nucleosomes and the chromatin fiber.

During the past year and a half, significant progress has been made in understanding the structure and dynamics of nucleosomes and the chromatin fiber, the mechanism of action of the core histone amino termini, the structure and function of histone variants, and the function of linker histones in the chromatin fiber.

The H4 Tail Domain Participates in Intra- and Internucleosome Interactions with Protein and DNA during Folding and Oligomerization of Nucleosome Arrays

ABSTRACT The condensation of nucleosome arrays into higher-order secondary and tertiary chromatin structures likely involves long-range internucleosomal interactions mediated by the core histone tail domains. We have characterized interarray interactions mediated by the H4 tail domain, known to play a predominant role in the formation of such structures. We find that the N-terminal end of the H4 tail mediates interarray contacts with DNA during self-association of oligonucleosome arrays similar to that found previously for the H3 tail domain. However, a site near the histone fold domain of H4 participates in a distinct set of interactions, contacting both DNA and H2A in condensed structures. Moreover, we also find that H4-H2A interactions occur via an intra- as well as an internucleosomal fashion, supporting an additional intranucleosomal function for the tail. Interestingly, acetylation of the H4 tail has little effect on interarray interactions by itself but overrides the strong stimulation of interarray interactions induced by linker histones. Our results indicate that the H4 tail facilitates secondary and tertiary chromatin structure formation via a complex array of potentially exclusive interactions that are distinct from those of the H3 tail domain.