Visualizing the assembly of human Rad51 filaments on double-stranded DNA.

Rad51 is the core component of the eukaryotic homologous recombination machinery and assembles into extended nucleoprotein filaments on DNA. To study the dynamic behavior of Rad51 we have developed a single-molecule assay that relies on a combination of hydrodynamic force and microscale diffusion barriers to align individual DNA molecules on the surface of a microfluidic sample chamber that is coated with a lipid bilayer. When visualized with total internal reflection fluorescence microscopy (TIRFM), these "molecular curtains" allow for the direct visualization of hundreds of individual DNA molecules.

Visualizing the behavior of human Rad51 at the single-molecule level.

The repair of double-stranded DNA breaks by homologous recombination is essential for maintaining genome integrity. Much of what we know about this DNA repair pathway in eukaryotes has been gleaned from genetics, in vivo experiments with GFP-tagged proteins and traditional biochemical experiments with purified proteins. However, many questions have remained inaccessible to these experimental approaches.

Long-distance lateral diffusion of human Rad51 on double-stranded DNA.

Rad51 is the primary eukaryotic recombinase responsible for initiating DNA strand exchange during homologous recombination. Although the subject of intense study for over a decade, many molecular details of the reactions promoted by Rad51 and related recombinases remain unknown. Using total internal reflection fluorescence microscopy, we directly visualized the behavior of individual Rad51 complexes on double-stranded DNA (dsDNA) molecules suspended in an extended configuration above a lipid bilayer.

Organized arrays of individual DNA molecules tethered to supported lipid bilayers.

An unappreciated aspect of many single-molecule techniques is the need for an inert surface to which individual molecules can be anchored without compromising their biological integrity. Here, we present new methods for tethering large DNA molecules to the surface of a microfluidic sample chamber that has been rendered inert by the deposition of a supported lipid bilayer. These methods take advantage of the "bio-friendly" environment provided by zwitterionic lipids, but still allow the DNA molecules to be anchored at fixed positions on the surface.