Self-Assembling Supramolecular Complexes by Single-Stranded Extension from Plasmid DNA

M.G. SVAHN; M. HASAN; V. SIGOT; J.J. VALLE-DELGADO; M.W. RUTLAND; K.E. LUNDIN; C.I.E. SMITH

Oligonucleotides

Mary Ann Liebert, Inc

Año: 2007 p. 80 - 94

Self-assembling supramolecular complexes are of great interest for bottom-up research likenanotechnology.DNA is an inexpensive building block with sequence-specific self assemblingcapabilities through Watson–Crick and/or Hoogsteen base pairing and could beused for applications in surface chemistry, material science, nanomechanics, nanoelectronics, nanorobotics, and of course in biology. The starting point is usually single stranded DNA, which  is rather easily accessible for base pairing and duplex formation. When long stretches of double-stranded DNA are desirable, serving either as genetic codes or electrical wires, bacterial expansion of plasmids is an inexpensive approach with scale-up properties. Here, we present a method for using double-stranded DNA of any sequence for generating simple structures, such as junctions and DNA lattices. It is known that supercoiled plasmids are strand-   invaded by certain DNA analogs. Here we add to the complexity by using “Self-assembling UNiversal (SUN) anchors” formed by DNA analog oligonucleotides, synthesized with an extension, a “sticky-end” that can be used for further base pairing with single-stranded DNA. We show here how the same set of SUN anchor can be utilized for gene therapy, plasmid purification, junction for lattices, and plasmid dimerization through Watson–Crick base pairing. Using atomic force microscopy, it has been possible to characterize and quantify individual components of such supra-molecular complexes.