The effects of deoxyribonucleic acid secondary structure on tertiary structure
- 1 December 1976
- journal article
- research article
- Published by Portland Press Ltd. in Biochemical Journal
- Vol. 159 (3) , 615-620
- https://doi.org/10.1042/bj1590615
Abstract
The secondary structure of supercoiled DNA was varied by changes in ionic strength. For I = 0.075-0.4 the structure remained in the previously established branched form with only minor alterations in molecular dimensions. In 4M-NaCl, which induces linear DNA to change its secondary structure to the C structure and brings about an increase in the superhelix density of the molecule, no extra branches were observed on the molecules. The limiting factors that dictate supercoil structure seem to be the number and position of potential branch points and the proximity with which the two intertwining DNA strands can approach each other on the arms of the branches. This value is close to 10nm under the conditions described, and is 14-15nm at I = 0.2. It is suggested that such values should be borne in mind when models of chromosome structure are being constructed.This publication has 27 references indexed in Scilit:
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