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. 1974 Nov;1(11):1601–1618. doi: 10.1093/nar/1.11.1601

A conformation change of single stranded polyriboadenylate induced by an electric field

Dietmar Pörschke 1
PMCID: PMC343439  PMID: 10793715

Abstract

Absorbance measurements performed with high molecular weight poly A at pH 8 show that the degree of single strand stacking present at high ionic strength is reduced at low ionic strengths. The salt dependence of the poly A conformation is assigned to an electrostatic repulsion between subsequent turns of the single strand “helix” structure. - Electric fields of 5 to 80 kV/cm induce an increase in the poly A absorbance consistent with a decrease in the ion concentration in the environment of the polymer. The increase of the absorbance is a linear function of the field strength suggesting that the conformation change is caused by a dissociation field effect. At increasing ionic strength, threshold values of the electric field strength have to be exceeded in order to induce measurable absorbance changes. - The time required for the conformation change decreases from about 2 μsec at 10−4 M ionic strength to about 0.3 μsec at high ionic strengths. At low ionic strengths the ion equilibration may influence the rate limiting step, whereas the arrangement of the nucleotide residues into the ordered structure is rate limiting at high ionic strengths.

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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