Inorganic Chemistry

Research in Inorganic Chemistry spans the continuum from small molecule systems to metalloproteins, from the investigation of the reactivity properties of synthetic complexes to the use of metal-based reagents for probing protein-DNA interactions.

Associated Faculty

John Caradonna
Bioinorganic chemistry
The Caradonna lab is interested in the biological chemistry of non-heme iron. Approaches include the investigation of synthetic reactivity models, biophysical and mechanistic studies of natural metalloenzymes, and the rational design of metalloproteins.

Linda Doerrer

Synthetic inorganic chemistry

The Doerrer group specializes in synthetic inorganic chemistry and
is an equal-opportunity element utilizer. Currently it is pursuing two main
avenues of research. The first is the use of highly fluorinated
aryloxide and alkoxide ligands for the stabilization of high oxidation
states in first-row transition metals. Spectroscopic work strongly suggests
that these ligands generate a stronger field environment than chloride and
might be fluoride mimics. We have prepared many phenolate anions of the form
[M(OAr)n]m- and are investigating their reactivity with strong oxidizing
agents. The second area of research is in metallophilicity, which is the
attraction of electron rich metal centers e.g. Au(I), Pt(II), for each
other. We are investigating the use of this relatively weaker attractive
force in combination with electrostatics to form chain of metal atoms that
can be prepared with odd numbers of spins and investigated as
low-dimensional conductors.

Sean Elliott
Bioinorganic chemistry and Metallobiochemistry
Protein film voltammetry (PFV) is used in the Elliott lab as a way to explore the electron transfer pathways and redox-dependent catalytic chemistry of complex metalloproteins such as sulfite reductase and multicopper oxidases. We also are devloping proteomic tools to allow us to probe the 'metallome' -- a complete read-out of the metal-binding components of biological pathways -- such that we can develop new insight into the role of metal ions in biochemistry.

Thomas Tullius
Bioinorganic chemistry
Development and use of the hydroxyl radical (generated by the reaction of iron(II) EDTA with hydrogen peroxide) as a high-resolution chemical footprinting reagent to determine the structure of DNA and DNA-protein complexes in solution. In vivo hydroxyl radical footprinting, using gamma radiation as the source of hydroxyl radical. Mapping of DNA structure in the genome.