The development of inexpensive and rapid DNA sequencing technology remains a major challenge of broad scientific interest. Preliminary work has shown that transmission electron microscopy (TEM) can be used to obtain ultra-fast ultra-low-cost DNA sequences. Since efficient electron scattering to a detector is highly dependent on atomic number (Z), it is possible to label single stranded DNA (ssDNA) with heavy atoms. To test the limits of this trend, we propose a multipronged approach to selectively prepared metal-DNA base pair complexes. Our effort will be synergistic, taking advantage of the experience of the Toste group in organometallic and heavy atom cluster synthesis, and the capabilities of Halcyon Molecular in manipulating DNA and performing TEM.Two general synthetic methods will be investigated in order to develop distinct labeling protocols. First, triosmium (ZOs = 76), tetrairidium (ZIr = 77) and trigold (ZAu = 79) clusters tethered to a group that selectively react with (alkylating reagents) or bind (platinum diamine complexes) purine bases will be explored. Incorporation of gold (ZAu = 79) and mercury (ZHg = 80) atoms through direct metal-metal bonds to the osmium atoms will also be explored. In this case, the labels would appear as intense spots in the TEM spectra. For the complementary pyrimidine label, osmium tetraoxide bipyridine will be the selective binding agent for thymine and cytosine. Using the bipyridine ligand as a scaffold for functionalization, additional osmium, platinum (ZPt = 78) or uranium (ZU = 92) atoms may be incorporated.Proof-of-concept experiments will be performed using nuclear magnetic resonance (NMR) spectroscopy using individual DNA bases. If successful, testing will be performed on single DNA strands and sequenced using TEM. The success of these methods will enable the base-selective labeling of DNA with metal atoms and help develop ultra-fast ultra-low-cost DNA sequencing technology.

DFG Programme Research Fellowships

International Connection USA

Host Professor F. Dean Toste