Histone octamer instability under single molecule experiment conditions

We have studied the sample concentration-dependent and external stress-dependent stability of native and reconstituted nucleosomal arrays. Whereas upon stretching a single chromatin fiber in a solution of very low chromatin concentration the statistical distribution of DNA length released upon nucleosome unfolding shows only one population centered around approximately 25 nm, in nucleosome stabilizing conditions a second population with average length of approximately 50 nm was observed. Using radioactively labeled histone H3 and H2B, we demonstrate that upon lowering the chromatin concentration to very low values, first the linker histones are released, followed by the H2A-H2B dimer, whereas the H3-H4 tetramer remains stably attached to DNA even at the lowest concentration studied. The nucleosomal arrays reconstituted on a 5 S rDNA tandem repeat exhibited similar behavior. This suggests that the 25-nm disruption length is a consequence of the histone H2A-H2B dimer dissociation from the histone octamer. In nucleosome stabilizing conditions, a full approximately 145 bp is constrained in the nucleosome. Our data demonstrate that the nucleosome stability and histone octamer integrity can be severely degraded in experiments where the sample concentration is low.     

Base excision repair of 8-oxoG in dinucleosomes

In this work we have studied the effect of chromatin structure on the base excision repair (BER) efficiency of 8-oxoG. As a model system we have used precisely positioned dinucleosomes assembled with linker histone H1. A single 8-oxoG was inserted either in the linker or the core particle DNA within the dinucleosomal template. We found that in the absence of histone H1 the glycosylase OGG1 removed 8-oxoG from the linker DNA and cleaved DNA with identical efficiency as in the naked DNA. In contrast, the presence of histone H1 resulted in close to 10-fold decrease in the efficiency of 8-oxoG initiation of repair in linker DNA independently of linker DNA length. The repair of 8-oxoG in nucleosomal DNA was very highly impeded in both absence and presence of histone H1. Chaperone-induced uptake of H1 restored the efficiency of the glycosylase induced removal of 8-oxoG from linker DNA, but not from the nucleosomal DNA. We show, however, that removal of histone H1 and nucleosome remodelling are both necessary and sufficient for an efficient removal of 8-oxoG in nucleosomal DNA. Finally, a model for BER of 8-oxoG in chromatin templates is suggested.     

Differential association of linker histones H1 and H5 with telomeric nucleosomes in chicken erythrocytes.

Rat liver telomeric DNA is organised into nucleosomes characterised by a shorter and more homogeneous average nucleosomal repeat than bulk chromatin as shown by Makarov et al. (1). The latter authors were unable to detect the association of any linker histone with the telomeric DNA. We have confirmed these observations but show that in sharp contrast chicken erythrocyte telomeric DNA is organised into nucleosomes whose spacing length and heterogeneity are indistinguishable from those of bulk chromatin. We further show that chicken erythrocyte telomeric chromatin contains chromatosomes which are preferentially associated with histone H1 relative to histone H5. This contrasts with bulk chromatin where histone H5 is the more abundant species. This observation strongly suggests that telomeric DNA condensed into nucleosome core particles has a higher affinity for H1 than H5. We discuss the origin of the discrimination of the lysine rich histones in terms of DNA sequence preferences, telomere nucleosome preferences and particular constraints of the higher order chromatin structure of telomeres.     

Nucleosome DNA repeat length and histone complement in a fungus exhibiting condensed chromatin

Fungal chromatins are reported to exhibit unusually short nucleosomal DNA repeat lengths. To test whether this is a phylogenetic feature of fungi or rather is correlated with an apparent absence of condensed chromatin in the organisms studied, we have examined the chromatin organization and the complement of basic nuclear proteins in the fungus Entomophthora, an organism which exhibits marked chromatin condensation. Micrococcal nuclease digestion of Entomophthora chromatin revealed a nucleosomal DNA repeat length of 197 +/- 1.2 base pairs (bp). This repeat length is 20-40 bp longer than that reported for any fungus. Entomophthora nucleosomes exhibited an HI-like protein which was much less basic than the HI histones reported for higher eukaryotes but which was similar in basicity to the HI histone reported for the fungus Neurospora. However, the nucleosomal DNA repeat length of Neurospora chromatin is reported to be unusually short, whereas that of Entomophthora was found to be typical of the repeat lengths observed for chromatins of higher eukaryotes. Thus, repeat length, at least in fungi, would not appear to be directly determined by the basicity of the fungal cognate of histone HI.     

Identification of specific functional subdomains within the linker histone H10 C-terminal domain

Linker histone binding to nucleosomal arrays in vitro causes linker DNA to form an apposed stem motif, stabilizes extensively folded secondary chromatin structures, and promotes self-association of individual nucleosomal arrays into oligomeric tertiary chromatin structures. To determine the involvement of the linker histone C-terminal domain (CTD) in each of these functions, and to test the hypothesis that the functions of this highly basic domain are mediated by neutralization of linker DNA negative charge, four truncation mutants were created that incrementally removed stretches of 24 amino acids beginning at the extreme C terminus of the mouse H1(0) linker histone. Native and truncated H1(0) proteins were assembled onto biochemically defined nucleosomal arrays and characterized in the absence and presence of salts to probe primary, secondary, and tertiary chromatin structure. Results indicate that the ability of H1(0) to alter linker DNA conformation and stabilize condensed chromatin structures is localized to specific C-terminal subdomains, rather than being equally distributed throughout the entire CTD. We propose that the functions of the linker histone CTD in chromatin are linked to the characteristic intrinsic disorder of this domain.     

The core histone N termini function independently of linker histones during chromatin condensation

The relationships between the core histone N termini and linker histones during chromatin assembly and salt-dependent chromatin condensation were investigated using defined chromatin model systems reconstituted from tandemly repeated 5 S rDNA, histone H5, and either native "intact" core histone octamers or "tailless" histone octamers lacking their N-terminal domains. Nuclease digestion and sedimentation studies indicate that H5 binding and the resulting constraint of entering and exiting nucleosomal DNA occur to the same extent in both tailless and intact chromatin arrays. However, despite possessing a normal chromatosomal structure, tailless chromatin arrays can neither condense into extensively folded structures nor cooperatively oligomerize in MgCl(2). Tailless nucleosomal arrays lacking linker histones also are unable to either fold extensively or oligomerize, demonstrating that the core histone N termini perform the same functions during salt-dependent condensation regardless of whether linker histones are components of the array. Our results further indicate that disruption of core histone N termini function in vitro allows a linker histone-containing chromatin fiber to exist in a decondensed state under conditions that normally would promote extensive fiber condensation. These findings have key implications for both the mechanism of chromatin condensation, and the regulation of genomic function by chromatin.     

Features of the chromatin structure of erythrocytes depending on the properties of lysine-rich histones

A comparative analysis of chromatin from erythrocytes of frog, trout and hen has been performed in correlation with properties of the nucleosomal linker histones of H1 family. In the nucleosomes from frog erythrocytes the linker histone is represented by H1(0)-like variant with amino acid sequence highly homologous to that of the hen histone H5, however the arginine content in the proteins differs (3 mol% in the frog erythrocyte H1 and 12 mol% in the hen erythrocyte H5). On the other hand histone H5 from trout being significantly different in the primary structure from the hen histone H5 is at the same time rich in arginine (9 mol%). The nucleosomal repeat length, estimated by using agarose gel electrophoresis is 201, 213 and 213 b.p. in erythrocyte chromatin from frog, trout and hen, correspondingly. Chromatin packing density in fixed nuclei from erythrocytes of frog, trout and hen as determined using cytophotometric measurements is 0.144, 0.444 and 530 pg/mu 3, correspondingly. The data support the previously made suggestion that the increase in arginine content in nucleosomal linker proteins is connected with the increase of chromatin compaction in the nuclei and elongation of the linker in the nucleosome.     

Subnuclear distribution of the entire complement of linker histone variants in Arabidopsis thaliana

Linker histones (e.g. H1, H5, H1°) are thought to exert control on chromatin function by restricting nucleosomal dynamics. All higher eukaryotes possess a diverse family of linker histones, which may exhibit functional specialization. Arabidopsis thaliana apparently contains a minimal complement of linker histone structural variants and therefore is an ideal model for investigating functional differentiation among linker histones. Histones H1-1 and H1-2 are relatively similar proteins that are expressed in a wide variety of tissues and make up the majority of linker histone while H1-3 is a highly divergent minor variant protein that is induced by drought stress. We are interested in determining whether the in vivo distribution of each of these proteins also differs. To this end, we have produced subtype-specific antibodies and have localized each of the three proteins at the intranuclear and DNA sequence levels by indirect immunofluorescence and immunoprecipitation, respectively. Antibodies against linker histones H1-1 and H1-2 decorate nuclei in patterns very similar to 4’,6-diamidino-2-phenylindole (DAPI) staining, but different than the staining pattern of total histones. In contrast, antibodies made against two regions of H1-3 bind to chromatin in a diffuse pattern distinct from the DAPI-staining pattern. We also describe a technique to determine the localization of plant linker histone variants along regions of chromatin, employing in vivo chemical DNA-protein cross-linking to preserve native associations followed by immunoprecipitation with subtype-specific antibodies. We use this technique to demonstrate that, in contrast to the major linker histones, H1-3 does not bind the repetitive sequences pAL1 and 5S rDNA. In addition, we show that linker histones are bound to the compacted nucleosomal arrays at the telomere but with reduced stoichiometry. Taken together, our results suggest that plants, as has been shown for animals, possess a variant linker histone that is differentially localized. Received: 15 April 1999 / Accepted: 1 Mai 1999     

Pyrimidine dimer formation as a probe of nucleosome core and linker structure in situ

The photoinduced dimerization of adjacent pyrimidines in DNA is influenced in predictable ways by DNA conformation. A method is described for determining patterns of pyrimidine dimer formation under conditions in which the chromatin is minimally perturbed. The relation of such patterns to the conformation of nucleosomal core DNA and linker DNA, as well as the interaction of histone H1 with nucleosomal DNA, is presented. Such data indicate that sharp bends in the path of DNA seen in crystals of isolated nucleosome core particles are also present in intact chromatin. They also indicate that most of the linker has very little curvature except for a small bend at its junction with the nucleosome core. The linker path inferred from such experiments supports models in which the chromatin fiber consists of a zigzag chain of nucleosomes.     

A nuclear protein-modifying enzyme is responsive to ordered chromatin structure.

Poly (ADP-ribose) polymerase, a nuclear protein-modifying enzyme, binds to the internucleosomal linker region of chromatin, although it modifies certain core nucleosomal histones in addition to histone H1. The activity per unit of DNA chromatin changes with the nucleosome repeat number. It reaches a maximum on chromatin of 8-10 nucleosomes in length. As the complexity of chromatin with respect to nucleosome repeat number and compactness increases, a decline and stabilization of specific activity is noted. The difference in specific activity is maintained through resedimentation and dialysis of particles. It does not appear due to differences in polymer chain length or differential degradation of poly (ADP-ribose). The data suggest a relationship between ADP-ribosylation and chromatin organization and vice versa.     

Linker histone subtypes differ in their effect on nucleosomal spacing in vivo

Linker histone H1 is located on the surface of the nucleosome where it interacts with the linker DNA region and stabilizes the 30-nm chromatin fiber. Vertebrates have several different, relatively conserved subtypes of H1; however, the functional reason for this is unclear. We have previously shown that H1 can be reconstituted in Xenopus oocytes, cells that lack somatic H1, by cytosolic mRNA injection and incorporated into in vivo assembled chromatin. Using this assay, we have expressed individual H1 subtypes in the oocytes to study their effect on chromatin structure using nucleosomal repeat length (NRL) as readout. We have compared chicken differentiation-specific histone H5, Xenopus differentiation-specific xH1(0) and the somatic variant xH1A as well as the ubiquitously expressed human somatic subtypes hH1.2, hH1.3, hH1.4 and hH1.5. This shows that all subtypes, except for human H1.5, result in a saturable increase in NRL. hH1.4 results in an increase of approximately 13-20 bp as does xH1(0) and xH1A. chH5 gives rise to the same or slightly longer increase compared to hH1.4. Interestingly, both hH1.2 and hH1.3 show a less extensive increase of only 4.5-7 bp in the NRL, thus yielding the shortest increase of the studied subtypes. We show for the first time in an in vivo system lacking H1 background that ubiquitously expressed and redundant H1 subtypes that coexist in most types of cells of higher eukaryotes differ in their effects on the nucleosomal spacing in vivo. This suggests that H1 subtypes have different roles in the organization and functioning of the chromatin fiber.     

A Mechanism for Histone Chaperoning Activity of Nucleoplasmin: Thermodynamic and Structural Models

Nucleoplasmin (NP), a histone chaperone, acts as a reservoir for histones H2A-H2B in Xenopus laevis eggs and can displace sperm nuclear basic proteins and linker histones from the chromatin fiber of sperm and quiescent somatic nuclei. NP has been proposed to mediate the dynamic exchange of histones during the expression of certain genes and assists the assembly of nucleosomes by modulating the interaction between histones and DNA. Here, solution structural models of full-length NP and NP complexes with the functionally distinct nucleosomal core and linker histones are presented for the first time, providing a picture of the physical interactions between the nucleosomal and linker histones with NP core and tail domains. Small-angle X-ray scattering and isothermal titration calorimetry reveal that NP pentamer can accommodate five histones, either H2A-H2B dimers or H5, and that NP core and tail domains are intimately involved in the association with histones. The analysis of the binding events, employing a site-specific cooperative model, reveals a negative cooperativity-based regulatory mechanism for the linker histone/nucleosomal histone exchange. The two histone types bind with drastically different intrinsic affinity, and the strongest affinity is observed for the NP variant that mimicks the hyperphosphorylated active protein. The different “affinity windows” for H5 and H2A-H2B might allow NP to fulfill its histone chaperone role, simultaneously acting as a reservoir for the core histones and a chromatin decondensing factor. Our data are compatible with the previously proposed model where NP facilitates nucleosome assembly by removing the linker histones and depositing H2A-H2B dimers onto DNA.     

Remodeling of sperm chromatin following fertilization: nucleosome repeat length and histone variant transitions in the absence of DNA synthesis

Within the first cell cycle following fertilization the average nucleosomal repeat length of sea urchin male pronuclear chromatin declines by 30-40 base pairs to a value typical of that found in the embryo. This decline occurs after a lag of about 30 min postfertilization, and is accompanied by replication of the male chromatin and accumulation of cleavage-stage (CS) core histone variants. When replication is inhibited by greater than 95% with aphidicolin, the decline in repeat length still occurs, although it is slightly retarded. The decline in repeat length also occurs when protein synthesis is blocked by greater than 98% and DNA synthesis by 60-70% with emetine. The adjustment of nucleosome repeat length therefore can occur in vivo without extensive movement of replication forks across the length of the chromatin, or normal progression of the cell cycle, and appears to require no proteins synthesized postfertilization. Blocking of DNA synthesis or protein synthesis also does not prevent the normal histone variant transitions involved in male pronuclear chromatin remodeling. Although their accumulation is slowed, CS core variants eventually become the predominant male pronuclear histones in their classes when replication is inhibited. Since a shortening of the average nucleosomal repeat length of approximately 10-20% is not sufficient to account for this large acquisition of CS variants, some of the sperm (Sp) core histones are probably displaced from the replication-blocked pronucleus. Therefore, accumulation of CS H2A and CS H2B are temporally correlated with the repeat length transition, whereas replication, normal progression of the cell cycle, and the early histone transitions involving SpH1 and SpH2B are not.     

Partial purification, from Xenopus laevis oocytes, of an ATP-dependent activity required for nucleosome spacing in vitro.

A critical feature of chromatin with regard to structure and function is the regular spacing of nucleosomes. In vivo, spacing of nucleosomes occurs in at least two steps, but the mechanism is not understood. In this report, we have mimicked the two-step process in vitro. A novel spacing activity has been partially purified from Xenopus laevis ovaries. When this activity is added, either at the beginning or at the end of a nucleosomal assembly reaction, it can convert a DNA template consisting of irregularly spaced nucleosomes into a chromatin structure made up of regularly spaced nucleosomes with a repeat length of about 165 base pairs. The reaction requires ATP. Histone H1 is able to increase the nucleosomal repeat from 165 to 190 base pairs. This two-step increase in nucleosomal repeat length suggests that both the spacing activity and histone H1 contribute to generating repeat lengths of greater than 165 base pairs and that their contributions may be additive. Alternatively, the critical step in the spacing reaction may not be the formation of the 165-base pair repeat but may be the sliding of nucleosomes or the reorganization of the octamer structure induced by the spacing activity.     

The basic linker of macroH2A stabilizes DNA at the entry/exit site of the nucleosome

MacroH2A is a histone H2A variant that is typically found in heterochromatic regions of the genome. A positively charged linker that connects the histone-fold with the macro-domain was suggested to have DNA-binding properties, and has been shown to promote oligomerization of chromatin fibers. Here we examine the influence of this basic linker on DNA of mononucleosomes. We find that the macro-linker reduces accessibility to extranucleosomal DNA, and appears to increase compaction of the nucleosome. These properties arise from interactions between the H1-like basic linker region and DNA around the entry/exit site, which increases protection of nucleosomal DNA from exonuclease III digestion by ∼10 bp. By stabilizing the wrapping of DNA around the histone core, this basic linker of macroH2A may alter the distribution of nucleosome-associated factors, and potentially contribute to the more compacted nature of heterochromatin.     

Local geometry and elasticity in compact chromatin structure

The hierarchical packaging of DNA into chromatin within a eukaryotic nucleus plays a pivotal role in both the accessibility of genomic information and the dynamics of replication. Our work addresses the role of nanoscale physical and geometric properties in determining the structure of chromatin at the mesoscale level. We study the packaging of DNA in chromatin fibers by optimization of regular helical morphologies, considering the elasticity of the linker DNA as well as steric packing of the nucleosomes and linkers. Our model predicts a broad range of preferred helix structures for a fixed linker length of DNA; changing the linker length alters the predicted ensemble. Specifically, we find that the twist registry of the nucleosomes, as set by the internucleosome repeat length, determines the preferred angle between the nucleosomes and the fiber axis. For moderate to long linker lengths, we find a number of energetically comparable configurations with different nucleosome-nucleosome interaction patterns, indicating a potential role for kinetic trapping in chromatin fiber formation. Our results highlight the key role played by DNA elasticity and local geometry in regulating the hierarchical packaging of the genome.