We demonstrate the detection of nanometer-scale conformational changes of single DNA oligomers through a micromechanical technique. The quantity monitored is the displacement of a micrometer-size bead tethered to a surface by the probe molecule undergoing the conformational change. This technique allows probing of conformational changes within distances beyond the range of fluorescence resonance energy transfer. We apply the method to detect single hybridization events of label-free target oligomers. Hybridization of the target is detected through the conformational change of the probe. W e describe measurements of nanometer-scale conformational changes of single DNA oligonucleotides, 40-90 bases long. The experiments are based on a micromechanical technique, which we have introduced previously (1). By measuring the contour length shortening of a single-probe molecule on formation of the double-stranded (ds) structure, we apply the method to detect hybridization of single unlabeled target oligomers. There are two interesting aspects to this approach. First, the ability to monitor directly certain conformational changes of DNA and RNA provides a tool for investigating processes such as (protein-induced) bending and looping, which have regulatory roles in transcription and splicing. The most detailed information on static conformations is provided by labor-intensive structural studies. At the other end, simple gel-shift assays provide a partial characterization, such as a bending angle. Single-molecule methods, in principle, offer a direct way of studying conformational changes, including dynamics. Recently, the conformational change involved in the catalytic activity of a ribozyme has been studied in detail by single-molecule fluorescence resonance energy transfer (FRET) (2). However, FRET is limited to distances Ͻ10 nm, whereas many interesting structures formed by DNA, such as bends and loops, involve larger (10-to 30-nm) scales (10 nm is the contour length of a dsDNA 30 mer). With the method described here, we can detect nanometer-scale conformational changes of single DNA oligomers of length 30-90 bases, thus extending the range covered by FRET.A second aspect is the possibility of developing sensitive assays based on single-molecule detection. DNA hybridization assays are ubiquitous in genomic analysis, gene expression studies, and, increasingly, diagnostics. The sensitivity and throughput of the assays have recently been improved through the introduction of DNA arrays and the development of several new sensitive detection techniques. These include molecular beacons (3-6), nanoparticle composites (7-10), surface plasmon resonance (11, 12), fiber-optic arrays (13-16), and conductivity͞capacitance measurements (17, 18). The most widely used detection methods rely on labeling target DNA, usually by fluorescent dyes. However, the resulting sensitivity limits the range of applications, specifically for DNA arrays where small populations of cells are to be analyzed. Thus improved sensitivity would be valuable.With...
