Controlling the folding/unfolding transition of the DNA-histone H1 complex by direct optical manipulation

Yuko Yoshikawa; Shin Ichirou M. Nomura; Toshio Kanbe; Kenichi Yoshikawa

doi:10.1016/S0009-2614(00)01075-7

Controlling the folding/unfolding transition of the DNA-histone H1 complex by direct optical manipulation

Yuko Yoshikawa, Shin Ichirou M. Nomura, Toshio Kanbe, Kenichi Yoshikawa

ENG - Robotics

Research output: Contribution to journal › Article › peer-review

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Abstract

Single giant duplex DNA (T4DNA, 166 kbp) complexed with a polycationic protein, histone H1, is trapped by a continuous-wave infrared laser, without chemical modification of the DNA such as attachment to a micrometer-sized bead. When the DNA-H1 complex is transported from a low-salt solution (0.2 M NaCl) to a high-salt solution (2 M NaCl), its conformation changes from a compact to an elongated structure. With the reverse procedure, i.e., with the transportation from the high-salt to the low-salt environment, the elongated chain shrinks into a compact state. These results afford the direct evidence that histone H1 induces a salt-dependent transition in the higher-order structure of giant DNA molecules.

Original language	English
Pages (from-to)	77-82
Number of pages	6
Journal	Chemical Physics Letters
Volume	330
Issue number	1-2
DOIs	https://doi.org/10.1016/S0009-2614(00)01075-7
Publication status	Published - 2000 Nov 3

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title = "Controlling the folding/unfolding transition of the DNA-histone H1 complex by direct optical manipulation",

abstract = "Single giant duplex DNA (T4DNA, 166 kbp) complexed with a polycationic protein, histone H1, is trapped by a continuous-wave infrared laser, without chemical modification of the DNA such as attachment to a micrometer-sized bead. When the DNA-H1 complex is transported from a low-salt solution (0.2 M NaCl) to a high-salt solution (2 M NaCl), its conformation changes from a compact to an elongated structure. With the reverse procedure, i.e., with the transportation from the high-salt to the low-salt environment, the elongated chain shrinks into a compact state. These results afford the direct evidence that histone H1 induces a salt-dependent transition in the higher-order structure of giant DNA molecules.",

author = "Yuko Yoshikawa and Nomura, {Shin Ichirou M.} and Toshio Kanbe and Kenichi Yoshikawa",

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T1 - Controlling the folding/unfolding transition of the DNA-histone H1 complex by direct optical manipulation

AU - Yoshikawa, Yuko

AU - Nomura, Shin Ichirou M.

AU - Kanbe, Toshio

AU - Yoshikawa, Kenichi

N1 - Funding Information: The present work is partly supported by a Grant-in-Aid from the Ministry of Education, Science, Sports, and Culture of Japan.

PY - 2000/11/3

Y1 - 2000/11/3

N2 - Single giant duplex DNA (T4DNA, 166 kbp) complexed with a polycationic protein, histone H1, is trapped by a continuous-wave infrared laser, without chemical modification of the DNA such as attachment to a micrometer-sized bead. When the DNA-H1 complex is transported from a low-salt solution (0.2 M NaCl) to a high-salt solution (2 M NaCl), its conformation changes from a compact to an elongated structure. With the reverse procedure, i.e., with the transportation from the high-salt to the low-salt environment, the elongated chain shrinks into a compact state. These results afford the direct evidence that histone H1 induces a salt-dependent transition in the higher-order structure of giant DNA molecules.

AB - Single giant duplex DNA (T4DNA, 166 kbp) complexed with a polycationic protein, histone H1, is trapped by a continuous-wave infrared laser, without chemical modification of the DNA such as attachment to a micrometer-sized bead. When the DNA-H1 complex is transported from a low-salt solution (0.2 M NaCl) to a high-salt solution (2 M NaCl), its conformation changes from a compact to an elongated structure. With the reverse procedure, i.e., with the transportation from the high-salt to the low-salt environment, the elongated chain shrinks into a compact state. These results afford the direct evidence that histone H1 induces a salt-dependent transition in the higher-order structure of giant DNA molecules.

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JO - Chemical Physics Letters

JF - Chemical Physics Letters

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ER -

Controlling the folding/unfolding transition of the DNA-histone H1 complex by direct optical manipulation

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