Cellular metabolism encompasses the fundamental processes by which organisms acquire, store, and release factors required to respond to changing needs and environmental conditions. In photosynthesizing organisms, the basis for cellular metabolism is drawn from the controlled capture and utilization of solar energy, a process which is essential for virtually all terrestrial life. Chemically, the early reactions of photosynthesis involve the absorption of incident solar light and its conversion into low potential electrons that can be used to drive a variety of metabolic processes, including carbon fixation. Regulation of the direction of electron flux towards different metabolic processes is largely controlled through the actions of the electron carrier, ferredoxin. However, the mechanism by which ferredoxin preferentially donates low potential electrons to one metabolic pathway over another is poorly understood. To this end, I propose to examine the plasticity of electron flux from ferredoxin within the cyanobacterium Synechococcus elongatus PCC7942. Specifically, I propose a series of experiments designed to redirect low potential electrons towards cellular hydrogenases, which catalyze the production of hydrogen gas as a readout of accepted electrons. Proposed experiments involve the construction of cyanobacterial strains with inducible downregulation of metabolic pathways competing for low potential electrons as well as strains with ferredoxin and hydrogenases spatially constrained together by expression of chimeric proteins or synthetic protein scaffolds. These experiments will result in the construction of strains of cyanobacteria capable of producing hydrogen gas directly from sunlight. The results of these experiments will have relevance for the understanding of photosynthetic metabolism. Furthermore, these experiments will have broad implications for the engineering of photosynthesis-driven pathways for the production of biomedical compounds and sustainable, clean biofuels.

Public Health Relevance

Proposed research entails the study of early cyanobacterial photosynthesis reactions which are involved with the conversion of captured solar energy into distinct biological metabolites. A deeper knowledge of these processes can be leveraged for the re-engineering of photosynthetic organisms to produce alternate, economically-relevant metabolites. Light-driven biological pathways can provide the basis for novel and inexpensive approaches for the production of chemical compounds, such as pharmaceuticals and/or biofuels.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Postdoctoral Individual National Research Service Award (F32)
Project #
5F32GM093516-02
Application #
8066339
Study Section
Special Emphasis Panel (ZRG1-F05-C (20))
Program Officer
Fabian, Miles
Project Start
2010-07-01
Project End
2012-12-31
Budget Start
2011-07-01
Budget End
2012-06-30
Support Year
2
Fiscal Year
2011
Total Cost
$51,326
Indirect Cost
Name
Harvard University
Department
Biology
Type
Schools of Medicine
DUNS #
047006379
City
Boston
State
MA
Country
United States
Zip Code
02115
Ducat, Daniel C; Silver, Pamela A (2012) Improving carbon fixation pathways. Curr Opin Chem Biol 16:337-44
Ducat, Daniel C; Avelar-Rivas, J Abraham; Way, Jeffrey C et al. (2012) Rerouting carbon flux to enhance photosynthetic productivity. Appl Environ Microbiol 78:2660-8
Ducat, Daniel C; Sachdeva, Gairik; Silver, Pamela A (2011) Rewiring hydrogenase-dependent redox circuits in cyanobacteria. Proc Natl Acad Sci U S A 108:3941-6
Ducat, Daniel C; Way, Jeffrey C; Silver, Pamela A (2011) Engineering cyanobacteria to generate high-value products. Trends Biotechnol 29:95-103