DNA Double Helices Recognize Mutual Sequence Homology in a Protein Free Environment

Overview

Journal J Phys Chem B

Publisher American Chemical Society

Specialty Chemistry

Date 2008 Jan 10

PMID 18181611

Citations 33

Authors

Geoff S Baldwin

Nicholas J Brooks

Rebecca E Robson

Aaron Wynveen

Arach Goldar

Sergey Leikin

John M Seddon

Alexei A Kornyshev

Affiliations

Soon will be listed here.

Abstract

The structure and biological function of the DNA double helix are based on interactions recognizing sequence complementarity between two single strands of DNA. A single DNA strand can also recognize the double helix sequence by binding in its groove and forming a triplex. We now find that sequence recognition occurs between intact DNA duplexes without any single-stranded elements as well. We have imaged a mixture of two fluorescently tagged, double helical DNA molecules that have identical nucleotide composition and length (50% GC; 294 base pairs) but different sequences. In electrolytic solution at minor osmotic stress, these DNAs form discrete liquid-crystalline aggregates (spherulites). We have observed spontaneous segregation of the two kinds of DNA within each spherulite, which reveals that nucleotide sequence recognition occurs between double helices separated by water in the absence of proteins, consistent with our earlier theoretical hypothesis. We thus report experimental evidence and discuss possible mechanisms for the recognition of homologous DNAs from a distance.

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