Mason Lab

Deepwater Horizon oil spill

Marine microorganisms are capable of transforming their environment by, for example, rendering toxic compounds non-toxic.  Thus their actions can serve to mitigate the propagation of toxic substances up trophic levels and ultimately to humans.  Microbially mediated hydrocarbon degradation processes were essential agents of these transformations during the Deepwater Horizon oil spill .  The ecosystem service provided by resident microorganisms in consuming hydrocarbons introduced to the Gulf of Mexico during the spill was significant, but not equitable.  For example, nearly all of the methane, a potent greenhouse gas, released was consumed by microorganisms, however, other constituents, including carcinogenic PAHs detected in the sediments and in the water column were largely undegraded.  Thus microbially mediated processes determined, in part, the type and magnitude of the hydrocarbon flux at the sediment seawater interface, as well as the fate of the hydrocarbons throughout the water column and eventually in coastal environments. 

Northern Gulf of Mexico "Dead Zone"

Areas of low oxygen have spread exponentially over the past 40 years, and are cited as a key stressor on coastal ecosystems. The world's second largest coastal hypoxic (≤2 mg of O2 l−1) zone occurs annually in the northern Gulf of Mexico. The net effect of hypoxia is the diversion of energy flow away from higher trophic levels to microorganisms. This energy shunt is consequential to the overall productivity of hypoxic water masses and the ecosystem as a whole.  The Mason lab has a time series in the Gulf hypoxic zone, revealing an annual increase in abundance of Thaumarchaeota in the expansive hypoxic zone.  In particular, the abundance of ammonia-oxidizing Thaumarchaeota increases significantly in correlation with decreasing dissolved oxygen concentrations. Hypoxic archaeal hotspots might persist over time in the hypoxic area and may continue to serve as a site where energy flow is diverted away from higher trophic levels to, in this case, ammonia-oxidizing Thaumarchaeota. This population of Thaumarchaeota could carry out sustained draw down of oxygen in these water masses, as well as potentially influence the nitrogen cycle in the nGOM.  Collaborators on this project are: Nancy Rabalais and Cameron Thrash.

Microscale trophic interactions in pitcher plant leaf fluids

The aquatic communities found within the water filled leaves of the pitcher plant, Sarracenia purpurea, have a simple trophic structure providing an ideal system to study microscale interactions between protozoan predators and their bacterial prey.  Specifically, we use pitcher plant leaves to carry out experiments directed at characterizing predator (protozoa)/prey (microbes) interactions, evolution and to test ecological theory.  For example, niche partitioning has been proposed as a driver of evolution in ecology, however empirical evidence remains controversial.  Replicate inquiline microbial communities are maintained with four protozoan species (in monoculture and competitive mixtures) to determine whether different predators target specific microbial species, and if competition among the protozoa affects resource use.  This experiment’s design includes an additional study analyzing microbial community change after seven weeks of protozoan evolution to assess successional patterns in niche partitioning. These tractable microcosm experiments help to clarify patterns of microbial evolution and predator resource distribution.  Collaborators on this project are: Tom Miller (FSU).  

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