In nucleosome

Heterogeneous reaction (Section 6 1) A reaction involving two or more substances present in different phases Hydro genation of alkenes is a heterogeneous reaction that takes place on the surface of an insoluble metal catalyst Heterolytic cleavage (Section 4 16) Dissociation of a two electron covalent bond in such a way that both electrons are retained by one of the initially bonded atoms Hexose (Section 25 4) A carbohydrate with six carbon atoms High density lipoprotein (HDL) (Section 26 11) A protein that carries cholesterol from the tissues to the liver where it is metabolized HDL is often called good cholesterol Histones (Section 28 9) Proteins that are associated with DNA in nucleosomes... 

Histones (Section 28.9) Proteins that are associated with DNA in nucleosomes. 

Fig. 10.2. FSPIM analysis of the interaction between maize transcriptional coactivators—GCN5 and ADA2—fused to CFP and YFP. GCN5 is a histone acetyltransferase that, in conjunction with adaptor protein ADA2, modulates transcription in diverse eukaryotes by affecting the acetylation status of the core histones in nucleosomes [63]. CFP- and YFP-tagged proteins, expressed in protoplasts, were excited by the 458 nm and the 514 nm laser lines sequentially. CFP fluorescence was selectively detected by an FIFT 458 dichroic mirror and BP 470-500 band pass emission filter while YFP fluorescence was selectively detected by using an HFT 514 dichroic mirror and...

Cocco, L., Martelli, A., Billi, A., Matteucci, A., Vitale, M., Neri, L., and Manzoli, F. (1986) Changes in nucleosome structure and histone H3 accessibility. Iodoacetamidofluorescein labeling after treatment with phosphatidylserine vesicles. Exp. Cell Res. 166, 465 174. 

I. Ashikawa, Y. Nishimura, M. Tsuboi, K. Watanabe, and K. Iso, Lifetime of tyrosine fluorescence in nucleosome core particles, J. Biochem. (Tokyo) 91, 2047-2055 (1982). 

The broad field of nucleic acid structure and dynamics has undergone remarkable development during the past decade. Especially in regard to dynamics, modem fluorescence methods have yielded some of the most important advances. This chapter concerns primarily the application of time-resolved fluorescence techniques to study the dynamics of nucleic acid/dye complexes, and the inferences regarding rotational mobilities, deformation potentials, and alternate structures of nucleic acids that follow from such experiments. Emphasis is mainly on the use of time-resolved fluorescence polarization anisotropy (FPA), although results obtained using other techniques are also noted. This chapter is devoted mainly to free DNAs and tRNAs, but DNAs in nucleosomes, chromatin, viruses, and sperm are also briefly discussed. 

Fig. 5. Schematic model of the nucleosome, with histone HI shown as stabilizing the fold of the DNA molecule around the core histones [based on results of Sperling and Sperling (1978)]. The nucleosome dimensions are derived from X-ray (Finch et al., 1977) and neutron (Baldwin et al., 1975 Pardon et al., 1977 Suauet al., 1977) scattering experiments. The histone core dimensions are derived from electron microscopic and X-ray studies (Sperling and Amos, 1977 Wachtel and Sperling, 1979 Sperling and Wachtel, 1979). The regions of the DNA molecule indicated by dashed lines indicate those base pairs which are not present in nucleosome core particles.

A low-energy in vitro form of nucleosome packing was observed in nucleosome core particle crystals (Finch et al., 1977). Two variants of these crystals occurred, (a) Wavy columns of nucleosomes stacked one on top of each other with an axial repeat of 340 A were obtained upon crystallization of nucleosomes containing proteolytically cleaved histones (Finch et al., 1977). (b) Straight columns of closely packed nucleosomes, 110 A in diameter, were obtained upon crystallization of nucleosomes with intact histones (Finch and Klug, 1978). In both these structures histone-histone contacts between nucleosomes are implied. Similar face-to-face packing of nucleosomes in arcs and helical patterns was observed in the EM by Dubochet and Noll (1978). 

There is good agreement between the overall dimensions of the histone octamer found by Klug et al. and data obtained from other types of histone fibers discussed here. Similarity of cross-linking data of histone octamer fibers, octamer free in solution, and octamer in nucleosomes makes the extrapolation from the octamer model in the fibers to the octameric core of nucleosome valid (Klug et al., 1980). This further substantiates the idea that histones are part of an assembly system, and therefore the histone core of the nucleosome can be regarded as a truncated histone fiber (see Section IV). 

Hizume K, Yoshimura SH, Maruyama H, Kim J, Wada H, Takeyasu K (2002) Chromatin reconstitution development of a salt-dialysis method monitored by nano-technology. Arch Histol Cytol 65 405 13 Hizume K, Yoshimura SH, Takeyasu K (2004) Atomic force microscopy demonstrates a critical role of DNA superhelicity in nucleosome dynamics. Cell Biochem Biophys 40 249—262 Hizume K, Yoshimura SH, Takeyasu K (2005) Linker histone HI per se can induce three-dimensional folding of chromatin fiber. Biochemistry 44 12978-12989 Hofmann WA, de Lanerolle P (2006) Nuclear actin to polymerize or not to polymerize. J Cell Biol 172 495-496... 

Tomschik M, Zheng H, van Holde K, Zlatanova J, Leuba SH (2005) Fast, long-range, reversible conformational fluctuations in nucleosomes revealed by single-pair fluorescence resonance energy transfer. Proc Natl Acad Sci USA 102 3278-3283... 

Yoda K, Ando S, Morishita S, Houmura K, Hashimoto K, Takeyasu K, Okazaki T (2000) Human centromere protein A (CENP-A) can replace histone H3 in nucleosome reconstitution in vitro. Proc Natl Acad Sci U S A 97 7266-7271... 

Ito T (2003) Nucleosome assembly and remodehng. Curr Top Microbiol Immunol 274 1-22 Ito T, Tyler JK, Kadonaga JT (1997) Chromatin assembly factors a dual function in nucleosome formation and mobilization Genes Cells 2(10) 593-600 Ivanovska I, Khandan T, Ito T, Orr-Weaver TL (2005) A histone code in meiosis the histone kinase, NHK-1, is required for proper chromosomal architecture in Drosophila oocytes. Genes Dev 19(21) 2571-2582... 

The phenylselenocysteine has also been used successfully to chemically append analogues of methyl- or acetyl-lysine, important histone modifications that can contribute to chromatin structure and accessibility of transcriptional machinery in eukaryotes. By introducing phenylselenocysteine into the Xenopus histone H3, both acetyl-lysine and mono-, di-, and trimethyl-lysine analogues were appended to the purified unnatural amino acid-containing FI 3 protein (Figure 10). " Additionally, the H3 protein with a modification mimicking acetylation of lysine 9 can be deactylated by a histone deacetylation complex and is also a substrate for phosphorylation by Aurora B kinase. Such purified and chemically labeled histones are likely functional in nucleosomes, and preparation of specifically modified histones for comprehensive analysis of chromatin structure and accessibility is particularly suited to this chemical labeling technique. 

Even in 1978, it was realized the assembly of nucleosomes in vivo was likely to be a facilitated process. In fact, Laskey et al. [33] had discovered a factor, nucleo-plasmin that assisted in this assembly. Very recently. X-ray diffraction studies have revealed much about this protein, and its probable role in nucleosome assembly [34] or disassembly [35]. At the same time, single-molecule studies (see Zlatanova and Leuba, this volume, p. 369) have provided an insight into the dynamics and energetics of nucleosome formation. This appears likely to be an area in which rapid progress is possible. 

Polymerase-induced positive supercoiling and linker positive crossing in nucleosomes... 

Stein, A. (1980) DNA wrapping in nucleosomes. The linking number problem re-examined. Nucl. Acids Res. 8, 4803 820. 

In addition to a potential role of HMGB proteins in nucleosome assembly, it has recently become apparent that many chromatin remodeling complexes either contain, or can associate with, a polypeptide containing an HMG-box homologous to the HMGBl B domain (Table 2). Examples of such complexes include the BAF (a mammalian SWI/SNF related complex [106]) and the Drosophila BRM (brahma)... 

Several lines of evidence indicate that CENP-A replaces conventional H3 in the nucleosome. Biochemical studies showed that CENP-A co-sediments with nucleo-some core particles [7] and a genetic analysis indicates an interaction between Cse4p, the CENP-A of Saccharomyces cerevisiae, and H4 [16,17]. A recent study with CENP-A purified from HeLa cells or expressed in bacteria showed that it can substitute for conventional H3 in nucleosome reconstitution [18]. Reconstituted CENP-A-containing nucleosomes appear to contain the other core histones in appropriate stoichiometry. However, they did not strongly protect 146 bp of core DNA from micrococcal nuclease, suggesting that CENP-A may significantly alter some aspects of the core nucleosome structure. 

Kleinschmidt, J.A. and Steinbeisser, H. (1991) DNA-dependent phosphorylation of histone H2A.X during nucleosome assembly in Xenopus laevis oocytes involvement of protein phosphorylation in nucleosome spacing. EMBO J. 10, 3043-3050. 

Fig. 1. Core histone modifications. Human histone N-terminal and in some cases C-terminal amino acid sequences are shown. The modifications include methylation (M), acetylation (Ac), phosphorylation (P), ubiquitination (U), and ADP ribosylation (step ladder). The sites of trypsin digestion of histones in nucleosomes are indicated (T).

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