1998 RESEARCH
PROJECTS
Program Element 1
Biotransformation and Biodegradation
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| PROJECT: |
Biodegradation
of PuEDTA and Impacts on Pu Mobility |
| PRINCIPAL
INVESTIGATOR: |
Harvey
Bolton |
| PROGRAM
ELEMENT 1 |
Biotransformation
and Biodegradation |
OBJECTIVE:
Plutonium (Pu) contamination of sediments and groundwater at many
Department of Energy (DOE) sites is a long-term problem. Ethylenediaminetetraacetate
(EDTA) was co-disposed with Pu, formed strong PuEDTA complexes, and
enhanced Pu transport at many sites. EDTA poses a long-term problem
of potentially disseminating Pu in the subsurface environment, because
it is recalcitrant to biodegradation. Biodegradation of EDTA should
decrease Pu mobility through destruction of the PuEDTA complex and the
precipitation of insoluble PuO2. However, this biodegradation
is not well understood because of the lack of information on PuEDTA
aqueous species, microbial degradation (e.g., uptake into the cell and
enzymology of degrading enzymes), and the effect of physicochemical
factors (e.g., Pu:EDTA ratio, CO2 partial pressure, pH, and
other metals) on the rate and ability of microorganisms to degrade PuEDTA.
The objectives of this research are to determine the dominant PuEDTA
complexes and their stability, the biological and geochemical factors
influencing the rate and extent of PuEDTA biodegradation, and the resulting
impacts on Pu mobility. Research will focus on determining the dominant
PuEDTA aqueous species and their biodegradation, the uptake of Pu- and
metal-EDTA complexes into the cell, the distribution and mobility of
the Pu during and after EDTA biodegradation (e.g., extracellular, biosorbed,
or intracellularly bioaccumulated), and the enzymology and genetics
of EDTA biodegradation. This information will provide mechanistic understanding
and approaches to bioremediate PuEDTA contaminated sites, determine
the influence of PuEDTA biodegradation on Pu immobilization, and provide
information necessary for modeling the fate and transport of PuEDTA
in the environment.
| PROJECT: |
Microbial
Reduction and Immobilization of Uranium in Fe(III)- and Mn(IV)- Containing
Sediments |
| PRINCIPAL
INVESTIGATOR: |
Jim
K. Fredrickson |
| PROGRAM
ELEMENT 1 |
Biotransformation
and Biodegradation |
OBJECTIVE:
Solid and liquid wastes discharged to the ground over a 40-year
period constitute a major environmental problem at Department of Energy
(DOE) sites nationwide. Metallic and radionuclide contaminants from
DOE site wastes that have been found in groundwaters include U, Co,
Pu, As, Cd, Cr, Cu, Hg, Ni, and Pb. Uranium is the most frequently-occurring
radionuclide in soils, sediments, and groundwater at DOE sites and,
therefore, is of particular environmental concern. At many of these
sites, co-disposal of metals and radionuclides with organic ligands
has led to the formation of metal-organic complexes with enhanced mobility
in soils and groundwater.
Dissimilatory
iron-reducing bacteria (DIRB) can utilize ferric iron associated with
aqueous or solid phases as a terminal electron acceptor coupled to the
oxidation of H2 or organic substrates. DIRB are also capable
of reducing other metal ions such as Mn(IV), Cr(VI), and U(VI). The
reduction of Fe and other metals and radionuclides has a pronounced
effect on their solubility and overall geochemical behavior. It is these
changes in geochemical behavior that hold promise for using DIRB to
alter the mobility of metals and radionuclides in situ for remediation
purposes.
The focus
of this research will be on coupled microbiological-geochemical investigations
of: a) microbial transformations of U-organic (EDTA, citrate, humic
acids) complexes in the presence of reactive solid phases (synthetic
and naturally-occurring) containing Fe- and Mn-oxides and b) humic acid-accelerated
microbial growth, metabolism, and reduction of Fe (III). These processes
must be more fully understood before the in situ immobilization
of U or mobilization/solubilization of other metals and radionuclides
using microbial processes can be fully realized.
This research
is focused on three central hypotheses:
-
Redox
Disequilibria Hypothesis. In sediments containing Mn-oxides,
U(VI)-carbonate complexes will be reduced by DIRB in preference
to Mn(IV)(s), but the resulting U(IV) will be reoxidized by Mn(IV)
oxides. Hence, U(IV) will function as an electron shuttle and accelerate
the rate and extent of reduction of Mn-oxides.
-
DIRB
U Reduction & Nucleation Hypothesis. The rate of biologic
reduction will far exceed the abiotic reduction rate at comparable
pe because of the active participation of the cell surface in both
the electron transfer reaction and the post reduction nucleation
of U(IV) solids. In the absence of strong aqueous complexants, U(IV)
will strongly sorb to cell surfaces, eventually nucleating as insoluble
uraninite.
-
Humic
Acid Electron Shuttle Hypothesis. Environmentally relevant concentrations
of humic acids (e.g., 5-20 mg C L-1) and quinones will support rates
of metabolism and cell growth significantly higher than in their
absence and will result in a more rapid and extensive reduction
of Fe- and Mn-oxides. The acceleration of oxide reduction will be
especially enhanced in porous media where cells can not readily
access solid phase Fe and Mn due to pore size or other physical
restrictions.
APPROACH:
The overall goal of this research project is to develop a fundamental
understanding of coupled microbiological-geochemical processes including:
a) microbial transformations of U-carbonate and -organic (EDTA, citrate)
complexes in the presence of reactive solid phases (synthetic and naturally-occurring)
containing Fe- and Mn-oxides and b) humic acid-accelerated microbial
growth, metabolism, and reduction of Fe (III). These processes must
be more fully understood before the in situ immobilization of
U or mobilization/solubilization of other metals and radionuclides using
microbial processes can be fully realized. The proposed research is
hypothesis-driven and will utilize a series of synthetic and natural
subsurface materials and organic co-contaminants of relevance to DOE
sites in experiments to address these hypotheses. Combined geochemical
and spectroscopic methods will be used to probe the distribution of
the metals and characteristics of the solids during microbial metal
reduction. A coupled geochemical-microbial reaction model will be used
to assess our understanding of these processes and to develop a predictive
capability. Although the research is laboratory based, it is expected
that the information from this project will be linked to related projects
in NABIR that address microbially-driven oxidation-reduction processes.
Ultimately, we expect this information and project to contribute to
NABIR field experiment(s) focusing on inorganic contaminant mobilization/immobilization
processes.
| PROJECT: |
Bioremediation
of Actinide and Transition Metal Contamination: Mechanistic Studies
|
| PRINCIPAL
INVESTIGATOR: |
Kenneth
H. Nealson |
| PROGRAM
ELEMENT 1 |
Biotransformation
and Biodegradation |
OBJECTIVE:
The long term objectives of this project are to study various facets
of uranium (U6+) and chromium (Cr6+) chemistry
and biochemistry, with the goal of understanding the mechanisms of removal
(biotic and abiotic) under both oxic and anoxic conditions. If these
mechanisms can be understood, it should be possible to plan strategies
for bioremediation that are both efficient and predictable. The immediate
objectives (for years 1 and 2) include:
-
Characterization
of abiotic (indirect) binding of U and Cr to metal oxides.
-
Characterization of U6+ and Cr6+ binding
to manganese and iron oxides as a function of T, pH, Eh, mineral
type, and concentration.
-
Characterization of release of U or Cr from metal oxides under
various conditions (see above).
-
Characterization
of U and Cr binding to biologically produced metal oxides.
-
Binding of U and Cr to biologically formed metal oxides, using
bacterial spores to synthesize Mn oxides in situ.
-
Characterization
of cell-catalyzed reduction of U and Cr, using S. putrefaciens
isolates.
-
Definition of the conditions favoring reduction of Mn, Fe, U,
and Cr.
-
Biochemical characterization of the cell free reduction system.
-
Fate of released U and Cr under various conditions.
APPROACH:
This work will be done using a three faceted approach. The first
is wet microbiology and microbial physiology and biochemistry. We will
examine both whole cells and cell extracts of oxidizing and reducing
bacteria to characterize both U and Cr uptake, release, and reduction.
We will use a series of mutants that are defective in metal reduction
as controls to separate specific cell mediated effects from general
anaerobic processes not specifically connected with metal reducing abilities.
The second approach is that of ESEM (environmental scanning electron
microscopy) and CLSM (confocal laser scanning microscopy) in which the
cells and cell products will be directly examined under high resolution
without the need for cell fixation or cell coating. Finally, we will
utilize X-ray spectroscopy and X-ray microscopy, the latter being a
new technique under development by our group. These approaches allow
high resolution redox state determination of Mn, Fe, U and Cr, as well
as high resolution imaging of bacteria inside solid structures, such
as metal oxides.
| PROJECT: |
Acceptable
Endpoints for Metals and Radionuclides: Quantifying the Stability
of Uranium and Lead Immobilized Under Sulfate Reducing Conditions
|
| PRINCIPAL
INVESTIGATOR: |
Brent
M. Peyton |
| PROGRAM
ELEMENT 1 |
Biotransformation
and Biodegradation |
Biologically
mediated in-situ immobilization is being considered as a means to significantly
decrease transport of metallic contaminants, and hence, produce an acceptable
endpoint for treatment of a contaminant plume. The creation of sulfate-reduction
conditions to immobilize metals has a high possibility of being selected
for use at many contaminated sites because of the large number of metals
such as lead (Pb) that form stable sulfide compounds. In addition, effective
reduction and subsequent precipitation of uranium (U) and chromium (Cr)
under these conditions has been shown in the laboratory. However, as
with other possible treatments, the long-term stability of the immobilized
metals and factors that affect the immobilization/remobilization process
must be quantified to determine whether the treatment can produce an
acceptable endpoint.
The goal
of this project is to elucidate and quantify the fundamental microbiological
and chemical factors that control the formation and subsequent stability
of U and Pb precipitates formed under sulfate-reducing conditions. Tests
will be performed to assess the effect of redox-sensitive aquifer materials
[e.g., amorphous and crystalline iron (Fe) oxides and Fe-bearing clay
minerals] and redox-insensitive materials (e.g., quartz) on the immobilization/remobilization
processes that control plume stability. To meet this goal, a multi-disciplinary
team of microbiologists, geochemists, and engineers has been assembled.
In contrast to previous research, we will produce a combined data set
from both micro- and meso-scale experiments that quantifies and correlates
microbial activity, important aquifer materials, and contaminant properties
to yield an accurate determination of whether sulfate-reducing conditions
will produce an acceptable endpoint.
| PROJECT: |
Transformation
of Heavy Metal Contaminants in Sulfate-Reducing Subsurface Environments:
The Role of Thiolated Compounds and Hydrogen Sulfide |
| PRINCIPAL
INVESTIGATOR: |
Murthy
A. Vairavamurthy |
| PROGRAM
ELEMENT 1 |
Biotransformation
and Biodegradation |
OBJECTIVE:
The overall objective is to obtain a fuller understanding of the
role of the sulfur system, comprising mainly thiols and hydrogen sulfide,
on the speciation and transformation of toxic heavy metal ions in anaerobic
systems undergoing bacterial dissimilatory sulfate reduction. Specific
issues to be addressed include (1) the relative importance of thiol
complexation versus precipitation as metal sulfides for sequestering
metal ions in anoxic environments, (2) the stability and biotransformation
of thiol-metal complexes in anaerobic systems, (3) the effect of environmental
variables, such as pH, on the anaerobic production of H2S
and thiols, and (4) the production of metallothioneins or similar metal-binding
proteins by anaerobic bacteria in response to stress by toxic heavy
elements.
APPROACH:
Although hydrogen sulfide is the primary product of bacterial sulfate
reduction, thiols also are generated in sulfate-reducing systems, from
either biochemical processes or abiotic reactions involving sulfur nucleophiles
and functionalized organic molecules. They occur in a wide range of
molecular weights and hydrophilicity. Thiols form their strongest bonds
with large, easily polarizable heavy-metal ions such as Cd(II), Hg(II),
and Pb(II), and, thus, should play an important role in transforming
these metals in anaerobic environments. While low-molecular-weight thiols
form soluble complexes of the metals, high-molecular-weight ones, such
as humic thiols, can bind the metals to immobilize them. Hence, the
kinds of sedimentary thiols involved in metal complexation and the types
of metal-thiol complexes formed will be studied. In the initial phase
of our research, we will focus on transformations of cadmium in sulfate
reducing systems. Time series measurements of sulfur and metal speciation
will be conducted with added Cd(II) in model sulfate-reducing systems
similar to those of natural sub-surface sediments and soils. The use
of model systems is advantageous because the speciation and processes
can be more easily controlled and better understood than natural systems
which are complex and heterogeneous. We will use a suite of complementary
techniques, including x-ray absorption spectroscopy, NMR spectroscopy,
and liquid chromatography-mass spectrometry to characterize sulfur and
metal speciation in the anaerobic systems. We expect that this multifaceted
approach will yield new insights about transformations of heavy metal
species in sulfate-reducing systems.
| PROJECT: |
Environmental
Actinide Mobility: Plutonium and Uranium Interactions with Exopolysaccharides
and Siderophores of Aerobic Soil Microbes |
| PRINCIPAL
INVESTIGATOR: |
Laura
Vanderberg-Twary |
| PROGRAM
ELEMENT 1 |
Biotransformation
and Biodegradation |
OBJECTIVE:
Our overall goal is to understand fundamental interactions of actinides
and aerobic soil microbes which can affect the mobility of these actinides
in the environment. To achieve this goal we will :
Determine
the binding and immobiliztion of actinides to cellular surfaces of aerobic
soil microbes with focus on: 1) the glutamic acid capsule of Bacillus
lichenformis with known metal-binding ability and 2) the partially
characterized exopolymer of Rhodococcus erythropolis .
Determine
the siderophore-mediated uptake of actinides as a result of cellular
translocation by 1) using a well-characterized siderophore (dessferrioxamine)
produced by the soil microbe, Streptomyces pilosus and 2) by first isolating
and characterizing the siderophore produced by the soil isolate, Rhodococcus
rhodochrous strain OFS. Determine the oxidation state, speciation
and localization of actinides that are translocated by siderophore-mediated
processes.
APPROACH:
We will study the interactions which are most likely to affect actinide
environmental mobility, binding by extracellular polymers and siderophore
complexation and uptake, using proven microbiological and biochemical
techniques and a multimethod actinide speciation approach. Understanding
these interactions will help to lay the basis for the development of
successful in situ bioremediation schemes. The environmentally
relevant forms of actinides to be used in our experiments are: uranyl
carbonate, UO2(CO3)22- as
a representative of hexavalent actinides, the hydrated plutonium(V)
ion, PuO2+(H2O)5 as a representative
of pentavalent actinides, colloidal Pu(IV) hydroxide and Pu(IV)EDTA
as representatives of tetravalent actinides. By considering the lower
(III and IV) and higher (V and VI) oxidation states we will study actinide
ions with different effective charges, redox properties, and hydrolysis
and complexation constants, as well as structural and coordination number
differences--spherical, bound by 8-10 ligand donors vs. linear, dioxo,
bound equatorially by 5-6 ligand donors. We will take a multimethod
approach to determine the speciation and location of the actinides associated
with biomolecules and obtain detailed structural and mechanistic information.
B.
lichenformis and R. erythropolis will be grown under optimal
conditions for exopolymer production. The metal binding capacity of
the R. erythropolis capsule will be characterized. Whole cell
and purified polymer studies using both microbes will be undertaken
to determine actinide binding. Specifically, we can use the different
components of the multimethod analytical approach to determine total
actinide uptake, to determine if, and to what extent the actinides are
reduced upon binding by the exopolymer, to determine the coordination
geometry about the actinide associated with the capsular material, and
to determine detailed structural information about the actinide-polymer
interactions. We will also investigate the effect of pH on the reversibility
of actinide exopolymer immobilization.
The siderophore
of R. rhodochrous strain OFS will be produced, purified and characterized
with respect to its structural type (i.e., hydroxamate, catecholate),
molecular weight and functionality prior to initiation of actinide binding
experiments. Desferrioxamine for siderophore experiments will be purchased
commercially. For both siderophores and each actinide oxidation state
(IV, V, VI), we will determine if translocation occurs. We determine
if the interaction involves metal reduction. If actinides are translocated
by siderophore mediated processes, the actinide is essentially immobilized
within the cell. If translocation does not occur, or if the actinide-siderophore
complex is found partially translocated, the composition and structure
of the complex will be determined. In addition, experiments will be
performed to determine how the relevant actinides might compete with
iron in the environment for siderophore binding.
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