Crystallization of the globular domain of histone H5

Interaction of chromatin with a histone H1 containing swapped N- and C-terminal domains

The present study was to understand whether the globular or C-terminal linker histone domain is more important for its binding to chromatin. Using histone H1, with swapped domain orientation, we found that both domains are equally important for nucleosome binding.

Although the details of the structural involvement of histone H1 in the organization of the nucleosome are quite well understood, the sequential events involved in the recognition of its binding site are not as well known. We have used a recombinant human histone H1 (H1.1) in which the N- and C-terminal domains (NTD/CTD) have been swapped and we have reconstituted it on to a 208-bp nucleosome. We have shown that the swapped version of the protein is still able to bind to nucleosomes through its structurally folded wing helix domain (WHD); however, analytical ultracentrifuge analysis demonstrates its ability to properly fold the chromatin fibre is impaired. Furthermore, FRAP analysis shows that the highly dynamic binding association of histone H1 with the chromatin fibre is altered, with a severely decreased half time of residence. All of this suggests that proper binding of histone H1 to chromatin is determined by the simultaneous and synergistic binding of its WHD–CTD to the nucleosome.

Multifunctionality of the linker histones: an emerging role for protein-protein interactions

Linker histones, e.g., H1, are best known for their ability to bind to nucleosomes and stabilize both nucleosome structure and condensed higher-order chromatin structures. However, over the years many investigators have reported specific interactions between linker histones and proteins involved in important cellular processes. The purpose of this review is to highlight evidence indicating an important alternative mode of action for H1, namely protein-protein interactions. We first review key aspects of the traditional view of linker histone action, including the importance of the H1 C-terminal domain. We then discuss the current state of knowledge of linker histone interactions with other proteins, and, where possible, highlight the mechanism of linker histone-mediated protein-protein interactions. Taken together, the data suggest a combinatorial role for the linker histones, functioning both as primary chromatin architectural proteins and simultaneously as recruitment hubs for proteins involved in accessing and modifying the chromatin fiber.

The histone H1 family: specific members, specific functions?

The linker histone H1 binds to the DNA entering and exiting the nucleosomal core particle and has an important role in establishing and maintaining higher order chromatin structures. H1 forms a complex family of related proteins with distinct species, tissue and developmental specificity. In higher eukaryotes all H1 variants have the same general structure, consisting of a central conserved globular domain and less conserved N-terminal and C-terminal tails. These tails are moderately conserved among species, but differ among variants, suggesting a specific function for each H1 variant. Due to compensatory mechanisms and to the lack of proper tools, it has been very difficult to study the biological role of individual variants in chromatin-mediated processes. Our knowledge about H1 variants is indeed limited, and in vitro and in vivo observations have often been contradictory. Therefore, H1 variants were considered to be functionally redundant. However, recent knockout studies and biochemical analyses in different organisms have revealed exciting new insights into the specificity and mechanisms of actions of the H1 family members. Here, we collect and compare the available literature about H1 variants and discuss possible specific roles that challenge the concept of H1 being a mere structural component of chromatin and a general repressor of transcription.

Binding of antitumor antibiotic daunomycin to histones in chromatin and in solution

Daunomycin is an anticancer drug that is well-known to interact with DNA in chromatin. Using a compositionally defined chicken erythrocyte chromatin fraction, we have obtained conclusive evidence that the drug is also able to interact with chromatin-bound linker histones without any noticeable binding to core histones. The drug can interact in an equal fashion with both histone H1 and H5 and to a greater extent with core histones H3/H4 and H2A/H2B as free proteins in solution. Thus, the binding of daunomycin to linker histones in the chromatin fiber is most likely due to the well-known higher accessibility of these histones to the surrounding environment of the fiber. Binding of daunomycin to linker histones appears to primarily involve the trypsin-resistant (winged-helix) domain of these proteins. The studies described here reveal the occurrence of a previously undisclosed mechanism for the antitumor activity of anthracycline drugs at the chromatin level.

Linker histone-dependent organization and dynamics of nucleosome entry/exit DNAs

A DNA sequence-dependent nucleosome structural and dynamic polymorphism was recently uncovered through topoisomerase I relaxation of mononucleosomes on two homologous approximately 350-370 bp DNA minicircle series, one originating from pBR322, the other from the 5S nucleosome positioning sequence. Whereas both pBR and 5S nucleosomes had access to the closed, negatively crossed conformation, only the pBR nucleosome had access to the positively crossed conformation. Simulation suggested this discrepancy was the result of a reorientation of entry/exit DNAs, itself proposed to be the consequence of specific DNA untwistings occurring in pBR nucleosome where H2B N-terminal tails pass between the two gyres. The present work investigates the behavior of the same two nucleosomes after binding of linker histone H5, its globular domain, GH5, and engineered H5 C-tail deletion mutants. Nucleosome access to the open uncrossed conformation was suppressed and, more surprisingly, the ability of 5S nucleosome to positively cross was largely restored. This, together with the paradoxical observation of a less extensive crossing in the negative conformation with GH5 than without, favored an asymmetrical location of the globular domain in interaction with the central gyre and only entry (or exit) DNA, and raised the possibility of the domain physical rotation as a mechanism assisting nucleosome fluctuation from one conformation to the other. Moreover, both negative and positive conformations showed a high degree of loop conformational flexibility in the presence of the full-length H5 C-tail, which the simulation suggested to reflect the unique feature of the resulting stem to bring entry/exit DNAs in contact and parallel. The results point to the stem being a fundamental structural motif directing chromatin higher order folding, as well as a major player in its dynamics.

Crystal structure of globular domain of histone H5 and its implications for nucleosome binding

The structure of GH5, the globular domain of the linker histone H5, has been solved to 2.5 A resolution by multiwavelength anomalous diffraction on crystals of the selenomethionyl protein. The structure shows a striking similarity to the DNA-binding domain of the catabolite gene activator protein CAP, thereby providing a possible model for the binding of GH5 to DNA.

Site-directed mutagenesis studies on the binding of the globular domain of linker histone H5 to the nucleosome

The globular domain of the linker histone H5 has been expressed in Escherichia coli. The purified peptide is functional as it permits chromatosome protection during micrococcal nuclease digestion of chromatin reconstituted with the peptide, indicating that it binds correctly at the dyad axis of the nucleosomal core particle. The globular domain residue lysine 64 is highly conserved within the linker histone family, and site-directed mutagenesis has been used to assess the importance of this residue in the binding of the globular domain of linker histone H5 to the nucleosome. Recombinant peptides mutated at lysine 64 are unable to elicit chromatosome protection to the same degree as the wild-type peptide, and since they appear to be fully folded, these observations confirm a major role for this residue in determining the effective interaction between the globular domain of histone H5 and the nucleosome.

Cooperative binding of the globular domains of histones H1 and H5 to DNA

In view of the likely role of H1-H1 interactions in the stabilization of chromatin higher order structure, we have asked whether interactions can occur between the globular domains of the histone molecules. We have studied the properties of the isolated globular domains of H1 and the variant H5 (GH1 and GH5) and we have shown (by sedimentation analysis, electron microscopy, chemical cross-linking and nucleoprotein gel electrophoresis) that although GH1 shows no, and GH5 little if any, tendency to self-associate in dilute solution, they bind highly cooperatively to DNA. The resulting complexes appear to contain essentially continuous arrays of globular domains bridging 'tramlines' of DNA, similar to those formed with intact H1, presumably reflecting the ability of the globular domain to bind more than one DNA segment, as it is likely to do in the nucleosome. Additional (thicker) complexes are also formed with GH5, probably resulting from association of the primary complexes, possibly with binding of additional GH5. The highly cooperative nature of the binding, in close apposition, of GH1 and GH5 to DNA is fully compatible with the involvement of interactions between the globular domains of H1 and its variants in chromatin folding.

Histone structure and function

The past year has seen major advances in our understanding of histone and nucleosome structure and function. Direct DNA mapping and thermodynamic experiments have finally provided conclusive evidence that the histones impose an altered helical pitch on the DNA as it is wrapped on the surface of the core histone octamer. Further, it is now clear that lysine acetylation in the amino-terminal domains of histones H3 and H4 can alter the topology of the DNA in chromatin and probably influence its higher-order folding. Genetic experiments reported in the past year have provided a wealth of new information on histone structure and function, including the identification of the peptide domain of histone H4 that is necessary for permanent gene repression, the confirmation that nucleosome structure is critical for centromere function, and evidence that histone acetylation plays a significant role in chromosome dynamics.

A model for histone H5-DNA interaction: simultaneous minor and major groove binding

Using the tertiary structure of the globular domain of H5 (GH5) and based on an alternative sequence homology between GH5 and DNA-binding proteins containing the helix-turn-helix motif, a model for H5-DNA interaction is proposed. From molecular graphics it follows that helix II recognizes the major groove of the DNA, as does the second helix of the helix-turn-helix motif, while helix III makes minor groove contacts, in agreement with the hypothesis of Turnell et al. (FEBS letters 232, 263-268). In the resulting model GH5 makes contact with a full turn of DNA.