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Biological Synthesis of Nanostructured Metal Oxide Semiconductors

Uptake and Metabolism of Trinitrotoluene by Tissue Cultures of Marine Seaweeds

Uptake and Metabolism of Polycyclic Aromatic Hydrocarbons by Tissue Cultures of Marine Seaweeds

Production of Bioactive Secondary Metabolites by Cell and Tissue Cultures of Marine Seaweeds in Bioreactor Systems

Uptake and Metabolism of Trinitrotoluene (TNT) by Tissue Cultures of Marine Seaweeds

Current Support: U.S. Office of Naval Research (ONR), Marine & Environmental Biotechnology Program (ONR Marine & Environ. Biotech. homepage)

Graduate Students: Octavio (Tavi) Cruz-Uribe (Ph.D. candidate)

Collaborators: Donald Cheney, Marine Science Center, Northeastern University, Boston, MA (Cheney Research Group homepage)

Project Description:  The presence of unexploded ordnance (UXO) and submerged mines in shallow, nearshore marine waters has the potential to release explosive compounds such as trinitrotoluene (TNT) into the marine ecosystem.  TNT and related compounds are potentially toxic to some marine organisms.  However, marine plant life may have the natural ability to bioremediate TNT-contaminated marine waters by a process similar to phytoremediation.   With this end in mind, we are studying the intrinsic capacity of marine seaweeds to tolerate, take up, and metabolize TNT from seawater.   The putative metabolism of TNT by marine seaweeds is shown below.

 

 

Present research efforts focus on three objectives:  characterize TNT uptake kinetics by microplantlets of the tropical red alga Portieria hornemannii and the cold-water red alga Acrosiphonia coalita; search for immediate products of TNT reduction (ADNTs) in aqueous phase and biomass; 3) Assess viability of microplantlets after exposure to TNT.  To facilitate these studies, axenic tissue cultures derived marine seaweeds serve as the bioremediation platform.  Development of these culture systems is described later under the research topic area titled “Production of Bioactive Secondary Metabolites by Cell and Tissue Cultures of Marine Macroalgae in Bioreactor Systems.”

 

Portieria microplantlets have a remarkable ability to take up and metabolize TNT.   TNT uptake and biotransformation kinetics are performed in aerated bubbler flasks containing microplantlets suspended in seawater containing dissolved TNT.  The specific rate of TNT uptake is over ten times faster than aquatic vascular plants such as Myriophyllum spicatum. Sample data from the TNT uptake experiments with Portieria microplantlets are provided below.

TNT Uptake Experiment

 

Collaborative efforts with Don Cheney’s research group at Northeastern University are exploring the use of genetically engineered red algae to augment the natural ability of marine seaweeds to biotransform TNT.