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Microbial CommunityDynamics in the Presenceof Pu(VI) and U(VI)
None
Date:
April 17, 2004
Creator:
Kuske, Cheryl & Neu, Mary
System:
The UNT Digital Library
New Insights into the Mechanism of Bacterial Metal Respiration
This project goal is to identify genes and gene products required for microbial metal reduction: reductive dissolution of iron; reductive dissolution of manganese; reductive precipitation of selenium; reductive precipitation of uranium; and reductive precipitation of technetium.
Date:
April 17, 2004
Creator:
DiChristina, Thomas J.
System:
The UNT Digital Library
Protein Expression in Shewanella oneidensis MR-1
None
Date:
April 17, 2004
Creator:
Giometti, Carol S.
System:
The UNT Digital Library
Virtual Institute of Microbial Stress and Survival: Deduction of Stress Response Pathways in Metal and Radionuclide Reducing Microorganisms
The projects application goals are to: (1) To understand bacterial stress-response to the unique stressors in metal/radionuclide contamination sites; (2) To turn this understanding into a quantitative, data-driven model for exploring policies for natural and biostimulatory bioremediation; (3) To implement proposed policies in the field and compare results to model predictions; and (4) Close the experimental/computation cycle by using discrepancies between models and predictions to drive new measurements and construction of new models. The projects science goals are to: (1) Compare physiological and molecular response of three target microorganisms to environmental perturbation; (2) Deduce the underlying regulatory pathways that control these responses through analysis of phenotype, functional genomic, and molecular interaction data; (3) Use differences in the cellular responses among the target organisms to understand niche specific adaptations of the stress and metal reduction pathways; (4) From this analysis derive an understanding of the mechanisms of pathway evolution in the environment; and (5) Ultimately, derive dynamical models for the control of these pathways to predict how natural stimulation can optimize growth and metal reduction efficiency at field sites.
Date:
April 17, 2004
Creator:
unknown
System:
The UNT Digital Library