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.     

Modeling Studies of Chromatin Fiber Structure as a Function of DNA Linker Length

Chromatin fibers encountered in various species and tissues are characterized by different nucleosome repeat lengths (NRLs) of the linker DNA connecting the nucleosomes. While single cellular organisms and rapidly growing cells with high protein production have short NRL ranging from 160 to 189 bp, mature cells usually have longer NRLs ranging between 190 and 220 bp. Recently, various experimental studies have examined the effect of NRL on the internal organization of chromatin fiber. Here, we investigate by mesoscale modeling of oligonucleosomes the folding patterns for different NRL, with and without linker histone (LH), under typical monovalent salt conditions using both one-start solenoid and two-start zigzag starting configurations. We find that short to medium NRL chromatin fibers (173 to 209 bp) with LH condense into zigzag structures and that solenoid-like features are viable only for longer NRLs (226 bp). We suggest that medium NRLs are more advantageous for packing and various levels of chromatin compaction throughout the cell cycle than their shortest and longest brethren; the former (short NRLs) fold into narrow fibers, while the latter (long NRLs) arrays do not easily lead to high packing ratios due to possible linker DNA bending. Moreover, we show that the LH has a small effect on the condensation of short-NRL arrays but has an important condensation effect on medium-NRL arrays, which have linker lengths similar to the LH lengths. Finally, we suggest that the medium-NRL species, with densely packed fiber arrangements, may be advantageous for epigenetic control because their histone tail modifications can have a greater effect compared to other fibers due to their more extensive nucleosome interaction network.     

Chromatin reorganization during emergence of malignant Friend tumors: early changes in H2A and H2B variants and nucleosome repeat length

Serial examination of five newly derived Friend murine tumors during early subcutaneous passages showed continuing changes in chromatin composition and structure over the first 10 to 20 passages followed by a period of stabilization over the subsequent 20 passages. These changes were reflected in a decrease in two major histone variants, H2A.1 and H2B.2, with a coordinate increase in histone variants, H2A.2 and H2B.1, and a changing nucleosome repeat length (NRL). The absolute values differed among the five tumors, but all five showed the same general direction of change. There was no obvious relationship among the NRL, H2A, and H2B histone variant values. A low H2A.1/H2A.2 ratio was found in Friend tumors of high malignant potential. Cell lines derived in vitro also showed directional changes in the H2A and H2B variants similar to those of their tumor cell parents, but with different kinetics. Our findings suggest that Friend tumor establishment is accompanied by an early period of chromatin reorganization marked by changes in several parameters of chromatin structure.     

The structural organization of sperm chromatin

The structure of rabbit, fowl, and Xenopus laevis sperm chromatin was explored by study of the reaction of their decondensed nuclei with DNase 1 and micrococcal nuclease. Those of rabbit and fowl were readily digested by DNase 1, and the polyacrylamide gel electrophoresis profiles of DNAs extracted from the digests were similar, each being polydisperse with a single discrete band of DNA smaller than 72 base pairs. There were differences, however, between the sperm chromatins in the course of their digestion by micrococcal nuclease. A limit digest at about 45% acid solubility was obtained with Xenopus sperm chromatin, while 90% of fowl sperm DNA was rendered acidsoluble by the enzyme. The gel profiles of the limit digests were polydisperse, but only those of rabbit and fowl sperm chromatins possessed a discrete band of DNA smaller than 72 base pairs. Bleomycin did not react with DNA of rabbit, fowl, or Xenopus spermatozoa. Since bleomycin reacts with somatic cell chromatin, and the course of DNase 1 or micrococcal nuclease digestion of sperm chromatin was different from that found for somatic cell chromatin, it would appear that sperm chromatin does not have the repeating nucleosometype structure of somatic cell chromatin. The nuclease digestion studies further suggest that the organization of rabbit and fowl sperm chromatins is similar, and is different from that of Xenopus sperm chromatin. The dependence of the structure of sperm chromatin on the composition of its basic proteins, and a possible structure for a protamine-type sperm chromatin, are discussed.     

The N-terminal domain determines the affinity and specificity of H1 binding to chromatin

Linker histone H1, one of the most abundant nuclear proteins in multicellular eukaryotes, is a key component of the chromatin structure mainly due to its role in the formation and maintenance of the 30nm chromatin fiber. It has a three-domain structure; a central globular domain flanked by a short N-terminal domain and a long, highly basic C-terminal domain. Previous studies have shown that the binding abilities of H1 are at large determined by the properties of the C-terminal domain; much less attention has been paid to role of the N-terminal domain. We have previously shown that H1 can be reconstituted via cytoplasmic mRNA injection in Xenopus oocytes, cells that lack somatic H1. The heterologously expressed H1 proteins are incorporated into in vivo assembled chromatin at specific sites and the binding event is monitored as an increase in nucleosomal repeat length (NRL). Using this setup we have here compared the binding properties of wt-H1.4 and hH1.4 devoid of its N-terminal domain (ΔN-hH1.4). The ΔN-hH1.4 displays a drastically lower affinity for chromatin binding as compared to the wild type hH1.4. Our data also indicates that ΔN-hH1.4 is more prone to unspecific chromatin binding than the wild type. We conclude that the N-terminal domain of H1 is an important determinant of affinity and specificity of H1-chromatin interactions.     

Supramolecular organization of double-stranded DNA molecules in the columnar hexagonal liquid crystalline phase. An electron microscopic analysis using freeze-fracture methods

I present an electron microscopical analysis of the columnar hexagonal liquid crystalline phase of DNA. Freeze-fracture methods reveal that this phase is a lamellar structure, each layer (30 to 40 A thick) composed of DNA molecules aligned in parallel. Numerous defects can be seen in the structure, and their nature is determined. I show that they are mainly screw dislocations of both handedness. By this method it is possible to follow individual double-stranded DNA molecules in this highly packed structure. I show, moreover, that there is a local twist between DNA molecules along the screw dislocation lines and that this twist can be either right-handed or left-handed. The interest of such ultrastructural analysis is discussed in relation to the understanding of chromatin structure.     

Reading sequence-directed computational nucleosome maps

Recently developed latest version of the sequence-directed single-base resolution nucleosome mapping reveals existence of strong nucleosomes and chromatin columnar structures (columns). Broad application of this simple technique for further studies of chromatin and chromosome structure requires some basic understanding as to how it works and what information it affords. The paper provides such an introduction to the method. The oscillating maps of singular nucleosomes, of short and long oligonucleosome columns, are explained, as well as maps of chromatin on satellite DNA and occurrences of counter-phase (antiparallel) nucleosome neighbors.     

Incorporation of DUF/FACT into chromatin enhances the accessibility of nucleosomal DNA

DNA unwinding factor (DUF) was discovered as an essential DNA replication factor in Xenopus egg extracts. DUF consists of an HMG protein and a homolog of Cdc68p/Spt16p, and has the capability of unwinding dsDNA. Here we have examined the interaction of DUF with chromatin. DUF was incorporated into chromatin assembled from sperm heads and from plasmid DNA in egg extracts. It was revealed that the chromatin assembled in egg extracts immunodepleted of DUF is less sensitive to micrococcal nuclease (NNase) digestion than that assembled in control extracts, indicating that chromatin containing DUF has more decompact structure than that without DUF. Also we found that DUF has a high affinity for core histones in vitro. We suggest that the function of DUF may be to make the chromatin structure accessible to replication factors.     

Unconventional metabolites in chromatin regulation

Chromatin, the complex of DNA and histone proteins, serves as a main integrator of cellular signals. Increasing evidence links cellular functional to chromatin state. Indeed, different metabolites are emerging as modulators of chromatin function and structure. Alterations in chromatin state are decisive for regulating all aspects of genome function and ultimately have the potential to produce phenotypic changes. Several metabolites such as acetyl-CoA, S-adenosylmethionine (SAM) or adenosine triphosphate (ATP) have now been well characterized as main substrates or cofactors of chromatin-modifying enzymes. However, there are other metabolites that can directly interact with chromatin influencing its state or that modulate the properties of chromatin regulatory factors. Also, there is a growing list of atypical enzymatic and nonenzymatic chromatin modifications that originate from different cellular pathways that have not been in the limelight of chromatin research. Here, we summarize different properties and functions of uncommon regulatory molecules originating from intermediate metabolism of lipids, carbohydrates and amino acids. Based on the various modes of action on chromatin and the plethora of putative, so far not described chromatin-regulating metabolites, we propose that there are more links between cellular functional state and chromatin regulation to be discovered. We hypothesize that these connections could provide interesting starting points for interfering with cellular epigenetic states at a molecular level.     

Preserving genome integrity and function: the DNA damage response and histone modifications

Modulation of chromatin templates in response to cellular cues, including DNA damage, relies heavily on the post-translation modification of histones. Numerous types of histone modifications including phosphorylation, methylation, acetylation, and ubiquitylation occur on specific histone residues in response to DNA damage. These histone marks regulate both the structure and function of chromatin, allowing for the transition between chromatin states that function in undamaged condition to those that occur in the presence of DNA damage. Histone modifications play well-recognized roles in sensing, processing, and repairing damaged DNA to ensure the integrity of genetic information and cellular homeostasis. This review highlights our current understanding of histone modifications as they relate to DNA damage responses (DDRs) and their involvement in genome maintenance, including the potential targeting of histone modification regulators in cancer, a disease that exhibits both epigenetic dysregulation and intrinsic DNA damage.     

正常及白血病小鼠白细胞染色质和DNA的酶切分析

 本文应用的核酸酶为DNaseⅡ、微球菌核酸酶与限制性内切核酸酶BstNI、EcoRⅡ、HpaⅡ和MspⅠ,将它们作用于正常小鼠615和可移植性白血病小鼠L7712脾脏白细胞染包质及其DNA,根据酶切电泳谱及水解动力学分析表明:1.白血病小鼠染色质相对正常小鼠染色质易被DNaseⅡ微球菌核酸酶水解;2.白血病小鼠染色质比正常小鼠者易被MspⅠ水解,但其DNA的MspⅠ酶切电泳谱无明显差别;3.白血病小鼠染色质及其DNA较正常小鼠染色质及其DNA易被EcoRⅡ水解。这些观察说明,白血病小鼠脾脏白细胞染色质有较活跃的构象状态;其染色质DNA的CCATGC区段内有较低的甲基化程度。