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Chromatin reconstituted

The effect of the superhelical strain of the DNA template on the nucleosome structure can be investigated from the in vitro chromatin reconstitution system (for the detail of in vitro chromatin reconstitution, see sections 2.1 and 2.3). Interestingly, the efficiency of the reconstitution becomes higher as the lengths of the DNA used are longer (Hizume et al, 2004) (Fig. 3a-c). In the 3 kb reconstituted chromatin, one nucleosome could be formed in every 826 bp DNA on average, while in the 106 kb chromatin fibers, one nucleosome can be formed in every 260 bp of DNA. The chromatin reconstituted on the any length of linearized plasmid, the efficiency of the reconstitution becomes one nucleosome per 800 bp DNA. The treatment of the... [Pg.10]

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... [Pg.25]

Simpson RT, Thoma F, Brubaker JM (1985) Chromatin reconstituted from tandemly repeated cloned DNA fragments and core histones a model system for study of higher order structure. Cell 42 799-808 Sugiyama S, Yoshino T, Kanahara H, Kobori T, Ohtani T (2003) Atomic force microscopic imaging of 30 nm chromatin fiber from partially relaxed plant chromosomes. Scanning 25 132-136 Sugiyama S, Yoshino T, Kanahara H, Shichiri M, Fukushi D, Ohtani T (2004) Effects of acetic acid treatment on plant chromosome structures analyzed by atomic force microscopy. Anal Biochem 324 39 4... [Pg.28]

Duband-Goulet, I., Carol, V., Ulyanov, A.V., Douc-Rasy, S., and Prunell, A. (1992) Chromatin reconstitution on small DNA rings. IV. DNA supercoiling and nucleosome sequence preference. J. Mol. Biol. 224, 981-1001. [Pg.71]

Simpson, R.T., Thoma, F., and Brubaker, J.M. (1985) Chromatin reconstituted from tandemly repeated cloned DNA fragments and core histones. A model system for study of higher order structure. Cell 42, 799-808. [Pg.71]

The principles whereby a chain of nueleosomes can compact to form a 30 nm chromatin fiber are still not well understood. Nevertheless, important aspects of this process are becoming clear from imaging studies, employing both ECM and SFM. When isolated chicken erythrocyte chromatin or chromatin reconstituted onto six tandem 208 bp nucleosome positioning units were examined by ECM, a linker DNA stem-like architectural motif was observed at the entry-exit sites (Fig. 4) [30]. Particles consistent with an octamer are surrounded with 1.7 turns of DNA, a linker... [Pg.352]

Fig. 4. Images of unfixed and unstained chromatin in a frozen and hydrated state. All samples shown contain linker histone H5. (A) Soluble chromatin prepared from chicken erythrocyte nuclei. Arrow indicates a nucleosome with a linker histone stem conformation. (B-E) Chromatin reconstituted onto an array of the 5S rDNA nucleosome positioning sequence. En face views (B-D) of nucleosomes show the linker DNA entering and exiting the nucleosome tangentially, before interacting and remaining associated for 3-5 nm before separating (arrows). An edge-on view (E) shows the two gyres of DNA (arrow heads) and the apposed linker DNA (arrow) (from Ref. [30]). Scale bar 20 nm (A) and 10 nm (B-E). Fig. 4. Images of unfixed and unstained chromatin in a frozen and hydrated state. All samples shown contain linker histone H5. (A) Soluble chromatin prepared from chicken erythrocyte nuclei. Arrow indicates a nucleosome with a linker histone stem conformation. (B-E) Chromatin reconstituted onto an array of the 5S rDNA nucleosome positioning sequence. En face views (B-D) of nucleosomes show the linker DNA entering and exiting the nucleosome tangentially, before interacting and remaining associated for 3-5 nm before separating (arrows). An edge-on view (E) shows the two gyres of DNA (arrow heads) and the apposed linker DNA (arrow) (from Ref. [30]). Scale bar 20 nm (A) and 10 nm (B-E).
Enzymatic digestion and chromatin reconstitution experiments indicate that the globular domain of HI can interact with the core histones but the end domains of both HI and the core histones are necessary for the correct positioning of HI with respect to the nucleosome so,26,si,s2)... [Pg.207]

Fig. 1. Electron microscopic visualization of reconstituted poly(ADP-ribosyl)ated Hl-depleted chromatin. Hl-depleted polynucleosomes were incubated at 30 C with I purified poly(ADP-ribose) in the presence of 200 NAD. The reaction was stopped by adding 1 mM 3-AB and nucleosomes were reconstituted by adding histone HI slowly at a ratio (Hl/nucleosome 1/1). Samples were diluted and treated for electron microscopy as described by Poirier et al. (5) (a and c) represent control and poly(ADP-ribosyl)-ated Hl-depleted chromatin reconstituted with histone HI. Fig. 1. Electron microscopic visualization of reconstituted poly(ADP-ribosyl)ated Hl-depleted chromatin. Hl-depleted polynucleosomes were incubated at 30 C with I purified poly(ADP-ribose) in the presence of 200 NAD. The reaction was stopped by adding 1 mM 3-AB and nucleosomes were reconstituted by adding histone HI slowly at a ratio (Hl/nucleosome 1/1). Samples were diluted and treated for electron microscopy as described by Poirier et al. (5) (a and c) represent control and poly(ADP-ribosyl)-ated Hl-depleted chromatin reconstituted with histone HI.
When the histone octamer is mixed with purified, double-stranded DNA, the same x-ray diffraction pattern is formed as that observed in freshly isolated chromatin. Electron microscopic studies confirm the existence of reconstituted nucleosomes. Furthermore, the reconsti-mtion of nucleosomes from DNA and histones H2A, H2B, H3, and H4 is independent of the organismal or cellular origin of the various components. The histone HI and the nonhistone proteins are not necessary for the reconstitution of the nucleosome core. [Pg.315]

Similar results were obtained from reconstitution experiments with DNA and a non-cross-linked octamer (Thomas and Butler, 1978). Nucleosome-like particles were observed in the EM and a pattern of histone cross-linking comparable to that of native chromatin was obtained. However, only 140-base-pair repeats were obtained upon micrococcal nuclease digestion instead of 200-base-pair repeats obtained for native rat liver chromatin (Noll and Komberg, 1977). This indicates that, in the absence of HI, only core particles can be reconstituted. Nevertheless, these studies with both cross-linked and reassembled un-cross-linked histones demonstrate that the octamer is a complete biological functional unit retaining the information for folding the DNA around the histone core. [Pg.15]

Since 1974, evidence has accumulated in the literature which indicates that chromatin itself may be considered as an assembly system. It is true that chromatin is more complex than assembly systems analyzed to date, both with respect to the size of the nucleic acid involved and therefore the amount (and variety) of protein complexed with it and with respect to the dynamic aspect of the multilevel higher order structure. Nevertheless, at least at the lower levels of organization, the interpretation of chromatin as an assembly system may be valid. Evidence for this derives from three basic lines of research described in previous sections (1) the reconstitution of the nucleosome, (2) the self-assembly of the octamer, and (3) the putative self-organization of nucleosomes into higher order structures. [Pg.36]

Figure 3. The stability of the nucleosome is affected by the length and the superhelicity of DNA. (a-b) The chromatin fibers were reconstituted from the purified plasmids and the histone octamers by a salt-dialysis method and observed under AFM. The 3 kb (a) or 106 kb (e) supercoiled circular plasmid was used as a template, (c) Relationship between the plasmid length and the frequency of nucleosome formation in the reconstitution process. The nucleosome frequency is represented as the number of base pairs per nucleosome and plotted against the length of the template DNA in supercoiled (filled circle) and linear (open circle) forms, (d) AFM image of the chromatin fiber reconstituted on the topoisomerase 1-treated plasmid, (e) Chromatin fiber reconstituted with Drosophila embryo extract. The chromatin fiber was reconstituted from plasmid DNA of 10kband the embryo extract of Drosophila, and was observed by AFM... Figure 3. The stability of the nucleosome is affected by the length and the superhelicity of DNA. (a-b) The chromatin fibers were reconstituted from the purified plasmids and the histone octamers by a salt-dialysis method and observed under AFM. The 3 kb (a) or 106 kb (e) supercoiled circular plasmid was used as a template, (c) Relationship between the plasmid length and the frequency of nucleosome formation in the reconstitution process. The nucleosome frequency is represented as the number of base pairs per nucleosome and plotted against the length of the template DNA in supercoiled (filled circle) and linear (open circle) forms, (d) AFM image of the chromatin fiber reconstituted on the topoisomerase 1-treated plasmid, (e) Chromatin fiber reconstituted with Drosophila embryo extract. The chromatin fiber was reconstituted from plasmid DNA of 10kband the embryo extract of Drosophila, and was observed by AFM...
In order to investigate the structural and functional characteristics of the chromatin fiber, several methods for in vitro nucleosome reconstitution have been developed (Lusser and Kadonga, 2004). Among them, the salt-dialysis method is the simplest... [Pg.12]

Biochemical reconstitution of the 30 nm fiber has recently been succeeded by using a salt-dialysis procedure with a long DNA template (>100 kb) (Hizume et al, 2005). AFM imaging of the reconstituted chromatin has shown that the beads-on-a-string structure of the nucleosomes ( 400 nucleosomes on 100 kb DNA) are converted to a thicker fiber in the presence of histone HI. The thickness of the fiber changes reversibly between 20 nm and 30 nm, depending on the salt environment (in 50 mM and 100 mM NaCl, respectively) (Fig. 4) namely, the linker histone directly promotes a thicker fiber formation in a salt-dependent manner. [Pg.15]

Figure 4. In vitro reconstituted 30 nm chromatin fiber. Dynamic structural changes in the chromatin fiber in the absence (top) or presence (bottom) of linker histone HI with different NaCl concentration were observed by AFM. Nucleosomes were reconstituted on the 106 kb plasmid and then fixed in the buffer containing 50 mM (top left) or 100 mM NaCl (top right). Nucleosomes were well-spread in 50 mM NaCl but attached each other and partially aggregated in 100 mM NaCl. After the addition of histone HI, the thicker fibers were formed. The width of the fibers is 20nm in 50mM NaCl (bottom left) or 30 nm in lOOmM NaCl (bottom right)... Figure 4. In vitro reconstituted 30 nm chromatin fiber. Dynamic structural changes in the chromatin fiber in the absence (top) or presence (bottom) of linker histone HI with different NaCl concentration were observed by AFM. Nucleosomes were reconstituted on the 106 kb plasmid and then fixed in the buffer containing 50 mM (top left) or 100 mM NaCl (top right). Nucleosomes were well-spread in 50 mM NaCl but attached each other and partially aggregated in 100 mM NaCl. After the addition of histone HI, the thicker fibers were formed. The width of the fibers is 20nm in 50mM NaCl (bottom left) or 30 nm in lOOmM NaCl (bottom right)...
Lu W, Peterson R, Dasgupta A, Scovell WM (2000) Influence of HMG-1 and adenovirus oncoprotein ElA on early stages of transcriptional preinitiation complex assembly. J Biol Chem 275 35006-35012 Luger K, Mader AW, Richmond RK, Sargent DF, Richmond TJ (1997) Crystal structure of the nucle-osome core particle at 2.8 A resolution. Nature 389 251—260 Lusser A, Kadonaga JT (2004) Strategies for the reconstitution of chromatin. Nat Methods 1 19-26 Maeshima K, Laemmli UK (2003) A two-step scaffolding model for mitotic chromosome assembly. Dev Cell 4 467-480... [Pg.26]

Sato MH, Ura K, Hohmura KI, Tokuimsu F, Yoshimura SH, Hanaoka F, Takeyasu K (1999) Atomic force microscopy sees nucleosome positioning and histone Hl-induced compaction in reconstituted chromatin. FEES Lett 452 267—271... [Pg.28]

Tatchell K, Van Holde KE (1977) Reconstitution of chromatin core particles. Biochemistry... [Pg.28]

There have been two basic approaches. First one involves isolation of the chromatin and nucleosome from the healthy and diseased cell line. The second approach is the reconstitution of the model target such as nucleosome followed by the association with the drug(s). The second approach has been extensively employed to identify the binding site in the protein-nucleic acid complex. A pre-knowledge about the components and their arrangements in the reconstituted system sometime makes it the preferred approach. Different biophysical, biochemical and genetic techniques have been employed to understand the mode of association and the effect of the drugs upon chromatin/nucleosome structure and function. [Pg.150]

Two approaches are usually taken to study the effect of the association of DNA binding anticancer drugs upon the structure of chromatin and nucleosome. The first one is reconstitution of the model nucleosome in the presence of the drugs. This has been reported earlier in the case of mithramycin (Fox and Cons, 1993 Carpenter et al., 1993). In our laboratory, so far we have taken the second approach of comparing the association of the anticancer drugs with isolated chromatin at various levels. [Pg.157]

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See also in sourсe #XX -- [ Pg.373 , Pg.374 , Pg.378 , Pg.379 ]



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Reconstitution

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