Grants and Contracts Details
Description
Revised Abstract Section
Aerobic organisms exploit 02t0 extract large amounts of energy from oxidative metabolism of
food, and employ oxidative reactions for a number of important chemical transformations
involved in antibiotic biosynthesis, metabolism of xenobiotics, construction of biopolymers, and
more. In order to access this chemistry, 02 must be activated, and this is often accomplished
via Fe-containing enzymes. Free activated 02 reacts with many components of cells and the
damage that ensues contributes to many diseases including diabetes, arthritis,
neurodegenerative conditions, cancer, and the symptoms of old age. A crucial biochemical
defense against this array of ills is the enzyme superoxide dismutase (SOD), which catalyzes
conversion of the parent activated 02 species, superoxide, to 02 + H202. The current work
focuses on the Escherichia co//SOD that is evolved to use Fe as its catalytic metal ion
(FeSOD), with supporting in-vivo experiments on a homologous yeast SOD that employs Mn
instead (MnSOD&), The yeast enzyme is highly homologous to the human mitochondrial
MnSOD, and thus serves as a model for the human enzyme, while also drawing on extensive
genetic and physiological studies of yeast, which cannot be performed on humans. The major
thrusts address mechanisms by which the Fe of FeSOD (and by extension the Fe of 02-
activation enzymes) interacts with activated 02 without succumbing to it, and means by which
the active site of FeSOD tunes the reactivity of Fe (such that it will de-activate superoxide). The
efforts on yeast SOD initiate investigations of possible pathological consequences of Fe-
substitution into human SOD, via the yeast model, and test a mutation by which this pathology
could be prevented or corrected. The major thrust builds directly on past research in the
applicant's lab, using E. co/i FeSOD variants that have been shown to be trapped in one of the
two states employed by FeSOD's catalytic cycle, but to retain otherwise native-like active sites.
Because they cannot progress through the catalytic cycle, they are ideal systems in which to
generate models of enzyme-substrate and enzyme-product complexes, to learn how the FeSOD
active site binds and interacts with its substrate and products. Detailed studies by skilled
spectroscopists, as well as mechanistic and thermodynamic studies will provide an
exceptionally complete picture of models of the intermediates of SOD turnover, and insights into
how Fe enzymes handle their essential but dangerous substrate. Established enzymological
and biophysical approaches will be blended with stopped-flow and freeze-quenched methods to
extend the lab's ability to treat short-lived complexes. The yeast system will be launched. Initial
studies of the reactions between peroxide and Fe-substituted MnSOD will evaluate the potential
significance of Fe substitution into SOD, to human oxidative stress. A mutation developed in E.
co/i and characterized as part of the mechanistic work will also be tested for ability to reverse
the possible toxic effects of Fe substitution into yeast MnSOD, thus carrying translating
mechanistic insights into potential treatments.
Status | Finished |
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Effective start/end date | 7/1/09 → 6/30/12 |
Funding
- National Institute of General Medical Sciences: $511,802.00
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