Influence of ionic strength on the dichroism properties of polynucleosomal fibers

Lee, Keun Soo; Crothers, Donald M.

doi:10.1002/bip.360210109

Cited by 25 publications

(20 citation statements)

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“…At intermediate ionic strength (Region II) the FLO signal goes through a positive maximum, after which it decreases and eventually vanishes. The ELO signal in this region becomes slowly less negative and is usually observed to reach the zero line (30,34,41 ). At high ionic strength (Region III) the FLO signal is zero in NaCl but is found largely positive in the presence ofMg 2 + (30).…”

Section: Discrepancy Between Flow and Electric Linear Dichroismmentioning

confidence: 97%

“…LD reflects the average orientation of the light absorbing transition dipoles in a macroscopically oriented sample, and is expected to depend sensitively on the DNA arrangement in chromatin. Despite intense study, however, the interpretation of LD results on chromatin has been subject to a remaining ambiguity, since electrically oriented and flow oriented chromatin, in an intermediate range of ionic strengths, persistently show different features: flow LD (FLD) being positive (20)(21)(22)(23)(24)(25)(26)(27)(28)(29)(30) and electric LD (ELD) generally negative (11,(31)(32)(33)(34)(35)(36)(37)(38)(39)(40)(41). This incongruity has been suggested to reside in different preparation procedures, buffer conditions or in experimental artifacts (28).…”

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confidence: 93%

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Reinterpretation of Linear Dichroism of Chromatin Supports a Perpendicular Linker Orientation in the Folded State

Kubista

Hagmar

Nielsen³

et al. 1990

Journal of Biomolecular Structure and Dynamics

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We present a reinterpretation of linear dichroism data for the salt induced condensation of chromatin. A conflict between electric and flow linear dichroism data for identical chromatin samples, studied at varying degrees of Mg2+ induced folding, can be solved if the orientation in electric fields is mainly determined through the polarization of counter ions along the linker parts, whereas the orientation in flow is governed by the hydrodynamical response of the entire chromatin fiber. The orientation of a chromatin fiber in an electric field would then depend on the linker tilt angle so that at an angle larger than 55 degrees the fiber would tend to orient perpendicular to the applied field. The different orientation distributions obtained with the two methods of alignment may in this way provide extra information about the structure and folding of chromatin.

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Section: Discrepancy Between Flow and Electric Linear Dichroismmentioning

confidence: 97%

mentioning

confidence: 93%

Reinterpretation of Linear Dichroism of Chromatin Supports a Perpendicular Linker Orientation in the Folded State

Kubista

Hagmar

Nielsen³

et al. 1990

Journal of Biomolecular Structure and Dynamics

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“…Because of the requirement of low conductivity in electric field orientation, in most of the early ELD studies the chromatin was condensed by di-and multivalent cations, and under these conditions, positive dichroism of condensed chromatin was not observed. However, chromatin condensed with monovalent cations has positive dichroism under all conditions, independently of orientation technique (Lee et al 1981;Lee & Crothers, 1982;Yabuki et al 1982;Roche et al 1984;Mithieux et al 1984;Marion, 1984;Chauvin et al 1985;Marion et al 1985;Marquet et al 1990). It is not clear why positive LD is not observed in electric fields for chromatin condensed with di-and multivalent cations, but one possible explanation is as follows (Kubista et al 1990 a): if chromatin orientation in electric fields is caused by polarization of DNA counter ions, as is the case for the orientation of DNA (Fredericq & Houssier, 1973;Porschke, 1985), the orientation of chromatin in the electric field will depend on its local structure.…”

Section: Electric Linear Dichroismmentioning

confidence: 99%

Linear dichroism spectroscopy of nucleic acids

Nordén

Kubista

Kurucsev

1992

Quart. Rev. Biophys.

359

376

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This review will consider solution studies of structure and interactions of DNA and DNA complexes using linear dichroism spectroscopy, with emphasis on the technique of orientation by flow. The theoretical and experimental background to be given may serve, in addition, as a general introduction into the state of the art of linear dichroism spectroscopy, particularly as it is applied to biophysical problems.

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“…The latter two methods have been extensively used to study the structure of both isolated nucleosomes and high-molecular-weight chromatin fragments. These methods, however, suffer from two serious disadvantages : (a) limited application to high-ionic-strength solutions, due to the thermal and electrochemical processes in the Kerr's cell, and (b) the electric field used for orientation of the molecules probably induces structural distortions in the chromatin fibrils [15,27]. These limitations can be overcome by flow orientation of the chromatin fibrils [15,16].…”

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confidence: 99%

Salt‐Induced Conformational Transitions in Chromatin

Макаров¹,

Dimitrov²

1983

European Journal of Biochemistry

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The chromatin structure in solution has been studied by the flow linear dichroism method (LD) in a wide range of ionic strengths. It is found that increasing the ionic strength from 0.25 mM NaZEDTA, pH 7.0 to 100mM NaCl leads to a strong reduction of the LD amplitude of chromatin and inversion of the LD sign from negative to positive at 2 mM NaCl. Chromatin exhibits a positive LD maximum value at 10-20 mM NaC1. These data enable us to conclude that in very low ionic strength (0.25 mM Na2EDTA) the nucleosome discs are oriented with their flat faces more or less parallel to the chromatin filament axis. Increasing ionic strength up to 20mM NaCl leads to reorientation of the nucleosome discs and to formation of chromatin structures with nucleosome flat faces inclined to the fibril axis. A conformational transition of that kind is not revealed in H1 -depleted chromatin. The condensation of the chromatin filaments with increasing concentration of NaCl from 20 mM to 100 mM slightly influences the orientation of the nucleosomes.Chromatin structure and the nature of conformational transitions induced by variable parameters of the environment have recently been the subject of vigorous study in connection with the function of the cellular genetic apparatus of eukaryotes. Considerable progress in solving these problems by now is closely related to the application of modern physical methods, e.g. electron microscopy [l -61, X-ray diffraction [7-lo], neutron [ l l , 121 and light [13,14] scattering, flow linear dichroism [15-171, electric birefringence [18,19] and electric dichroism [18 -271. The latter two methods have been extensively used to study the structure of both isolated nucleosomes and high-molecular-weight chromatin fragments. These methods, however, suffer from two serious disadvantages : (a) limited application to high-ionic-strength solutions, due to the thermal and electrochemical processes in the Kerr's cell, and (b) the electric field used for orientation of the molecules probably induces structural distortions in the chromatin fibrils [15,27]. These limitations can be overcome by flow orientation of the chromatin fibrils [15,16]. This paper reports the results of flow linear dichroism measurements of calf thymus chromatin preparations in a wide range of NaCl concentrations. It is shown that at very low ionic strength (0.25 mM Na2EDTA) the nucleosome discs are oriented more or less parallel to the filament axis. Increasing the concentration of NaCl up to 20 mM caused a reorientation of the nucleosomes, resulting in a chromatin structure with nucleosomal discs inclined to the filament axis. This transition was not observed with histone HI-depleted chromatin. Further increase of the ionic strength up to 100 mM led to negligible changes in the orientation of the nucleosomes.

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Influence of ionic strength on the dichroism properties of polynucleosomal fibers

Cited by 25 publications

References 20 publications

Reinterpretation of Linear Dichroism of Chromatin Supports a Perpendicular Linker Orientation in the Folded State

Reinterpretation of Linear Dichroism of Chromatin Supports a Perpendicular Linker Orientation in the Folded State

Linear dichroism spectroscopy of nucleic acids

Salt‐Induced Conformational Transitions in Chromatin

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