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Applied and Environmental Microbiology, March 1999, p. 1214-1221, Vol. 65, No. 3
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Dissimilatory Reduction of Fe(III) and Other
Electron Acceptors by a Thermus Isolate
T. L.
Kieft,1,*
J. K.
Fredrickson,2
T. C.
Onstott,3
Y. A.
Gorby,2
H. M.
Kostandarithes,2
T. J.
Bailey,2
D. W.
Kennedy,2
S. W.
Li,2
A. E.
Plymale,2
C. M.
Spadoni,2 and
M.
S.
Gray2
Department of Biology, New Mexico Institute
of Mining and Technology, Socorro, New Mexico
878011; Pacific Northwest National
Laboratory, Richland, Washington 993522; and
Department of Geosciences, Princeton University, Princeton,
New Jersey 085443
Received 17 September 1998/Accepted 16 December 1998
 |
ABSTRACT |
A thermophilic bacterium that can use O2,
NO3
, Fe(III), and S0 as terminal
electron acceptors for growth was isolated from groundwater sampled at
a 3.2-km depth in a South African gold mine. This organism, designated
SA-01, clustered most closely with members of the genus Thermus, as determined by 16S rRNA gene (rDNA) sequence
analysis. The 16S rDNA sequence of SA-01 was >98% similar to that of
Thermus strain NMX2 A.1, which was previously isolated by
other investigators from a thermal spring in New Mexico. Strain NMX2
A.1 was also able to reduce Fe(III) and other electron acceptors.
Neither SA-01 nor NMX2 A.1 grew fermentatively, i.e., addition of an
external electron acceptor was required for anaerobic growth.
Thermus strain SA-01 reduced soluble Fe(III) complexed with
citrate or nitrilotriacetic acid (NTA); however, it could reduce only
relatively small quantities (0.5 mM) of hydrous ferric oxide except
when the humic acid analog 2,6-anthraquinone disulfonate was added as
an electron shuttle, in which case 10 mM Fe(III) was reduced.
Fe(III)-NTA was reduced quantitatively to Fe(II); reduction of
Fe(III)-NTA was coupled to the oxidation of lactate and supported
growth through three consecutive transfers. Suspensions of
Thermus strain SA-01 cells also reduced Mn(IV),
Co(III)-EDTA, Cr(VI), and U(VI). Mn(IV)-oxide was reduced in the
presence of either lactate or H2. Both strains were also
able to mineralize NTA to CO2 and to couple its oxidation to Fe(III) reduction and growth. The optimum temperature for growth and
Fe(III) reduction by Thermus strains SA-01 and NMX2 A.1 is approximately 65°C; their optimum pH is 6.5 to 7.0. This is the first
report of a Thermus sp. being able to couple the oxidation of organic compounds to the reduction of Fe, Mn, or S.
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INTRODUCTION |
Dissimilatory iron-reducing bacteria
(DIRB) have been isolated from a variety of anoxic environments,
including the deep terrestrial subsurface, and are widely distributed
among bacteria, as evidenced by 16S rRNA gene (rDNA) sequences
(14, 22). Genera of DIRB include Geobacter
(26, 29), Shewanella (36, 47),
Pelobacter (31), Geovibrio
(8), Geospirillum (19),
Ferrimonas (44), "Geothrix"
(22), Desulfuromusa (20), and
Desulfuromonas (43). Several thermophilic DIRB
have recently been described, including Bacillus infernus
(6), Thermoterrabacterium (49),
Deferribacter thermophilus (16), and
Thermoanaerobacter spp. (21). Also, there are
several reports of enrichment cultures of thermophilic bacteria that
are capable of dissimilatory iron reduction (50, 57).
Most of the DIRB described to date are obligately anaerobic; exceptions
include Shewanella spp. (36, 47) and
Ferrimonas balearica (44). In this
paper we describe the isolation and characterization of a facultatively
anaerobic Thermus strain that is capable of dissimilatory
iron reduction as well as growth with oxygen and nitrate as terminal
electron acceptors. Although the physiology and genetics of the genus
Thermus have been studied for three decades, strains showing
this metabolic versatility have not previously been reported. Most
strains of Thermus have been described as obligate aerobes
(7), with a few being noted to reduce nitrate to nitrite
(41, 42, 48, 56).
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MATERIALS AND METHODS |
Environmental sampling, enrichment culture, and strain
isolation.
Rock and groundwater samples were collected from the
Witwatersrand Supergroup at a 3.2-km depth in a South African gold mine operated by Western Deep Levels, Inc. The Witwatersrand Supergroup is a
2.9-billion-year-old formation of low-permeability sandstone and shale
with minor volcanic units and conglomerates. The ambient temperature of
the rock is approximately 60°C. Samples were collected from a freshly
mined rock surface and from a water-producing bore hole that penetrated
121 m horizontally into the formation at a depth of 3,198 m.
Groundwater was aseptically collected into sterile serum bottles,
sealed without headspace with sterile butyl rubber closures, and then
packed in ice chests and shipped to the Pacific Northwest National
Laboratory in Richland, Wash. Sample material was used to inoculate
enrichment cultures in various media, including one with H2
as the electron donor, intended to cultivate autotrophic iron-reducing
bacteria. This enrichment medium contained 10 mM PIPES
[piperazine-N,N'-bis(2-ethanesulfonic acid)]
buffer (pH 7.0), 50 mM hydrous ferric oxide (HFO), 1.5 g of
NH4Cl liter1, 0.1 g of KCl
liter1, 0.6 g of NaH2PO4
liter1, 0.1 g of CaCl2 · 2H2O liter1, 1 g of yeast extract
(Difco) liter1, 10 ml of 10× Wolfe's vitamin solution
(4) liter1, and 10 ml of 10× Wolfe's mineral
solution (4) liter1; the headspace gas was
80% H2 and 20% CO2. The HFO was prepared as
described by Lovley and Phillips (27). The 10× Wolfe's
vitamin solution contained (per liter of deionized water) 2.0 mg of
biotin, 2.0 mg of folic acid, 10.0 mg of pyridoxine HCl, 5.0 mg of
riboflavin, 5.0 mg of thiamine, 5.0 mg of nicotinic acid, 5.0 mg of
pantothenic acid, 0.1 mg of cyanocobalamin, 5.0 mg of
p-aminobenzoic acid, and 5.0 mg of thioctic acid. The 10×
Wolfe's mineral solution contained (per liter of deionized water)
2.14 g of nitrilotriacetic acid (NTA), 0.1 g of
MnCl2 · 4H2O, 0.3 g of
FeSO4 · 7H2O, 0.17 g of
CoCl2 · H2O, 0.2 g of
ZnSO4 · 7H2O, 0.03 g of
CuCl2 · 2H2O, 5 mg of
KAl(SO4)2 · 12H2O, 5 mg of
H3BO4, 0.09 g of
Na2MoO4, 0.11 g of NiSO4
· 6H2O, and 0.02 g of
Na2WO4 · 2H2O. After
incubation at 60°C with shaking for 60 days, the
groundwater-inoculated medium showed significant Fe(III) reduction and
growth of a rod-shaped bacterium. Subculturing of dilutions resulted in
isolation of an axenic culture, designated strain SA-01. SA-01 was
shown to grow aerobically in a complex organic medium, TYG (5.0 g of
tryptone [Difco], 3.0 g of yeast extract [Difco], 1.0 g
of glucose liter of H2O1), or anaerobically
in TYG containing 10 mM KNO3. Strain SA-01 was examined for
purity by streaking it onto TYG medium solidified with 2% agar and by
obtaining isolated colonies twice in succession. Frozen stocks were
maintained in 16% glycerol at 
80°C. A defined basal medium
(formulated for cultivating Geobacter chapellii) (23) containing (per liter of deionized water) 0.42 g
of KH2PO4, 0.22 g of
K2HPO4, 0.2 g of NH4Cl,
0.38 g of KCl, 0.36 g of NaCl, 0.04 g of
CaCl2 · H2O, 0.1 g of
MgSO4 · 7H2O, 1.8 g of
NaHCO3, 0.5 g of Na2CO3, 0.19 mg of Na2SeO4, 10 ml of 10× Wolfe's trace element solution, and 15 ml of a 10× solution of Wolfe's vitamins was
used for all subsequent experiments. All solutions were made anaerobic
by purging them with O2-free N2; they were
sterilized by autoclaving or filtration. The basal medium was amended
with various electron donors and electron acceptors, as indicated
below. Cells were cultured under strictly anaerobic conditions in Balch tubes (Bellco, Vineland, N.J.) or serum vials fitted with butyl rubber
stoppers and containing a mixture of 80% N2 and 20%
CO2 in the headspace. In some cases, the basal medium was
also amended with small amounts of TYG to enhance growth, as indicated below.
Identification and phylogeny.
The phylogeny of strain SA-01
was determined by 16S rDNA sequencing. DNA was extracted by a modified
freeze-thaw procedure (38). Cells were cultured aerobically
in TYG at 60°C, centrifuged, and resuspended in extraction buffer
(2% sodium dodecyl sulfate, 0.2 M Na2HPO4 [pH
8.0]). Cells were frozen at 80°C, heat shocked for 10 min at
65°C, and then ballistically lysed with 0.1-mm-diameter glass beads
and a beadbeater (Biospec Products, Bartlesville, Okla.). The
supernatant was dialyzed against TE (10 mM Tris, 1 mM EDTA, [pH 7.8])
and ethanol precipitated. The 16S rDNA was amplified from the extracted
DNA by PCR (Perkin-Elmer) with universal bacterial primers
corresponding to Escherichia coli positions 7 to 27 and 1406 to 1392 (9). The PCR product was purified by agarose gel
electrophoresis and with a GeneClean II kit (Bio 101, La Jolla,
Calif.), and the 12-base uracil-DNA-glycosylase-generated 5' overhang
was annealed to the CloneAmp pAMP1 cloning vector (Gibco BRL). This
construct, containing the 16S rDNA PCR insert, was then transformed
into DH5
competent cells (Gibco BRL). The 16S rDNA sequences from 30 clones showed identical restriction fragment length polymorphism (RFLP)
patterns when they were digested with the restriction endonuclease
CfoI (Gibco BRL). Plasmid template DNA was prepared from one
of these 30 clones and sequenced with an ABI Dye Terminator Cycle
Sequencing Kit (Perkin-Elmer) with both plasmid and internal universal
bacterial 16S rDNA primers. Sequence homology was determined with the
BLAST program (2); phylogenetic analysis of 16S rDNA
sequences was performed by the maximum-likelihood method (Genetic Data
Environment program [32a]) with aligned E. coli positions 49 to 71, 102 to 180, 221 to 451, and 481 to 1259.
Electron donors and acceptors.
The abilities of strain SA-01
and Thermus strain NMX2 A.1 (provided by Hugh Morgan,
University of Waikato, Hamilton, New Zealand) to grow with various
combinations of electron donors and electron acceptors were tested in
the basal medium at 60°C. Lactate (30 mM) was routinely used as the
electron donor for testing nitrate, nitrite, Fe(III)-NTA, fumarate,
sulfate, and thiosulfate (each was used at 10 mM, except nitrite, which
was used at 1.0 mM) as terminal electron acceptors. Headspace gas was
80% N2 and 20% CO2. Fe(III)-NTA (100 mM) was
prepared by sequentially dissolving 1.64 g of NaHCO3,
2.56 g of trisodium NTA (Sigma, St. Louis, Mo.), and 2.7 g of
FeCl3 · H2O in water to a final volume
of 100 ml. Control cultures lacking an electron acceptor or donor were
also tested for growth and Fe(III) reduction. A zinc-acetate trap was placed in the headspace to trap H2S from media with sulfate
or thiosulfate as the terminal electron acceptor to avoid potential sulfide toxicity (33). Growth was observed visually as
turbidity in the culture tubes. Iron reduction was detected visually by color change as Fe(III) was reduced to colorless Fe(II). Uninoculated growth media served as controls. Cultures showing growth were subcultured (10% inoculum) in the same medium. Dissimilatory nitrate reduction by SA-01 and NMX2 A.1 was evaluated in anaerobic cultures grown at 60°C in TYG amended with 10 mM KNO3; nitrate and
nitrite were quantified by ion exchange liquid chromatography (Dionex, Sunnyvale, Calif.) by using a model AG4A guard and a model AS4A separator column, with a mobile phase containing 1.75 mM
NaHCO3 and 1.85 mM Na2CO3, and by
suppressed conductivity detection.
Reduction of S0 by Thermus strains SA-01 and
NMX2 A.1 was tested on an agar medium by methods described by Moser and
Nealson (33). TYG medium containing 30 mM S0, 30 mM lactate, and 20 g of agar liter1 was streaked
with inoculum (grown aerobically in TYG broth) and incubated at 60°C
anaerobically in a sealed canning jar containing 5% H2 and
95% N2. The jar also contained a trap with 0.1 M
Zn-acetate to absorb sulfide. The elemental sulfur in the medium was
added to the molten agar as polysulfide (a gift from Duane Moser,
University of Wisconsin
Milwaukee). Sulfur reduction was evidenced by
clearing of the S0 precipitate from the agar medium in the
areas surrounding colonies and by testing the Zn-acetate traps for the
presence of sulfide by the methylene blue method (3).
Proliferation of cells in colonies was confirmed by phase-contrast
microscopy. Controls consisted of uninoculated medium and medium
inoculated with killed (autoclaved) cells.
Growth and reduction of Fe(III)-NTA by
Thermus strains SA-01
and NMX2 A.1 were quantified in anaerobic basal medium containing
3 mM
sodium lactate, 15 mM Fe(III)-NTA, 50 mg of tryptone
liter
1, and 30 mg of yeast extract liter
1,
with 50 ml each in 160-ml serum vials and with N
2 and
CO
2 (80:20)
as headspace gas. The basal medium was also
amended to contain
3.7 mM NH
4Cl.
Thermus cells
were grown aerobically in TYG broth
(SA-01) or ATCC 697 medium (NMX2
A.1) and washed three times in
10 mM PIPES. Cells were resuspended in
aerobic 10 mM PIPES at
a density of 10
8 cells
ml
1 and incubated at 65°C and 100 rpm for 48 h.
Cells were then washed
once in basal medium and inoculated into nine
50-ml precultures
containing 10 mM Fe(III)-NTA, 10 mM lactate, 50 mg of
tryptone
liter
1, and 30 mg of yeast extract in basal
medium liter
1 at a density of 5 × 10
6
cells ml
1. After inoculation, cultures were purged with
filtered O
2-free
N
2. Cultures were incubated at
65°C and 60 rpm until almost all
of the Fe(III) was reduced: 4 days
for SA-01 and 5 days for NMX2
A.1. The purpose of the precultures was
to minimize intracellular
reserves of storage products prior to
inoculation into the Fe(III)-NTA
reduction experiment. Precultures were
harvested by centrifugation,
while anaerobic conditions were
maintained, and used to inoculate
the experimental cultures at initial
cell densities of 5.4 × 10
6 and 5.8 × 10
6 cells ml
1 for SA-01 and NMX2 A.1,
respectively. As controls (i) the same
growth medium but without
lactate was inoculated with the same
densities of cells and (ii) the
same growth medium with lactate
was not inoculated. Triplicate bottles
were used for each treatment.
Bottles were incubated at 65°C with
shaking (60 rpm). Two consecutive
transfers were made from the SA-01
cultures into fresh anaerobic
media. Cells from the treatment
containing Fe(III)-NTA and lactate
were transferred into fresh medium
containing Fe(III) and lactate;
cells from the medium containing
Fe(III)-NTA but not lactate were
transferred into fresh medium
containing Fe(III) but not lactate.
One additional set of cultures
identical to the treatment cultures,
except lacking Fe(III)-NTA, was
inoculated with cells from the
first transfer of the treatment cultures
to control for growth
without Fe(III) reduction. Fe(II) was quantified
by the ferrozine
assay (
28). Lactate and possible organic
products (e.g., acetate)
were quantified in filtered culture samples
with a DX 500 ion
chromatography system equipped with an Ion Pac AS 11 analytical
column and a model CD 20 conductivity detector (Dionex). The
eluent
gradient was programmed to result in a 0.2 mM NaOH solution
during
equilibration and analysis and in a 35 mM NaOH solution during
column regeneration. The flow rate was 1 ml min
1, and the
injection volume was 50 µl. Cells were preserved in
3.5%
formaldehyde and quantified by filtration, staining with
acridine
orange, and epifluorescence
microscopy.
Oxidation of lactate to CO
2 was also quantified in
conjunction with the reduction of Fe(III)-NTA and, in cultures lacking
Fe(III)-NTA, by using uniformly labeled Na [
14C]lactic
acid (99% radiopure; American Radiolabeled Chemicals,
Inc., St. Louis,
Mo.). Ethanol was removed from the radiolabeled
lactate by purging with
N
2. The purged lactate solution was mixed
with anaerobic
sterile water and diluted in anaerobic basal medium
prior to its
addition to the cultures. Cultures used for measuring
the oxidation of
lactate to CO
2 were 10 ml each and contained
4.6 × 10
7 cells ml
1, 3 mM Na-lactate (Sigma), and
approximately 0.7 nM (0.4 µCi)
14C-labeled lactate in
basal medium. Fe(III)-NTA (11 mM) also was
present in the treatment
cultures. The inoculum was grown aerobically
in TYG broth and washed
three times in anaerobic basal medium.
Cultures were contained in 30-ml
serum bottles with N
2-CO
2 (80:20)
headspace gas
and incubated at 65°C without shaking. An open,
empty 2-ml cryovial
(Nalgene) was placed inside the serum bottle
to serve later as a trap.
Duplicate cultures were sacrificed at
each sampling time by adding 1.0 ml of 5.5 N HCl to each culture
and 1.0 ml of 1 N KOH to the trap. One
milliliter of 1.0 N KOH
was calculated to be sufficient for trapping
all of the CO
2 in
the headspace, all of the CO
2
derived from acidification of the
bicarbonate buffer, plus nearly all
of the carbon in the [
14C]lactate if it was all oxidized
to
14CO
2. Experimentally, it was determined
that 1.0 ml of 1 N KOH
could trap 87% of the C in the system when it
was all released
as CO
2. Following acidification of the
culture, 950 µl of the
KOH was transferred to Opti-fluor
scintillation fluid (Packard
Instrument, Downers Grove, Ill.) for
counting. These cultures
were also analyzed for
Fe(II).
Growth on and reduction of HFO by
Thermus SA-01 were
quantified with anaerobic basal medium containing 10 mM sodium lactate,
10 mM HFO, 50 mg of tryptone liter
1 and 30 mg of yeast
extract liter
1, with 50 ml each in 100-ml serum vials and
with N
2-CO
2 (80:20)
headspace gas. A second
treatment contained these components plus
0.1 mM 2,6-anthraquinone
disulfonate (AQDS) (Aldrich, Milwaukee,
Wis.). The inoculum was grown
aerobically in TYG broth and washed
three times in anaerobic 30 mM
bicarbonate buffer (pH 7); cells
were injected to obtain an initial
density of 2.5 × 10
6 cells ml
1.
Controls consisted of (i) growth medium to which the same density
of
killed (autoclaved) cells was added and (ii) uninoculated medium.
Duplicate vials were used for each treatment. Vials were incubated
at
60°C with shaking. Fe(II) and cell density were quantified
as
described
above.
Reduction of the following electron acceptors by suspensions of
Thermus strain SA-01 cells under nongrowth conditions was
tested: 1 mM Fe(III)-NTA, 10 mM Fe(III)-citrate, 10 mM HFO, 125
µM
Co(III)-EDTA, 125 µM Cr(VI), 125 µM U(VI), and 10 mM Mn(IV)-oxide.
Cells were cultured either aerobically in TYG or anaerobically
in TYG
containing 10 mM KNO
3. Cells were washed three times in
anaerobic 30 mM bicarbonate buffer (pH 7.0) and resuspended in
10 ml of
anaerobic 30 mM bicarbonate buffer (pH 7.0) in Balch
tubes containing
one or more electron donors, as described below.
The headspace gas was
80% N
2 and 20% CO
2. For HFO, Fe(III)-citrate,
and Fe(III)-NTA reduction assays, the cells were grown anaerobically
and the potential electron donors were 1 mM acetate, 10 mM lactate,
and
10 ml of H
2 injected into the Balch tubes. For the
Co(III)-EDTA,
Cr(VI), U(VI), and Mn(IV)-oxide reduction assays, the
cells were
cultured aerobically, harvested by centrifugation, and then
purged
with O
2-free N
2. The electron donor for
the Co(III)-EDTA, Cr(VI),
and U(VI) assays was 10 mM lactate. For the
Mn(IV) reduction assay,
the bicarbonate buffer was adjusted to pH 7.4 by decreasing the
percent CO
2 in the headspace to 8%. The
electron donors were 2
mM lactate and H
2 (10 ml of
H
2 injected into the headspace in
a separate treatment from
lactate), and the electron acceptor
was 10 mM MnO
2,
prepared as described by Lovley and Phillips (
29).
For all
assays, controls consisted of tubes containing the same
media without
cells. Final cell densities were approximately 10
9 cells
ml
1. Cell suspensions were incubated at 60°C with
shaking. Fe(II)
production was monitored by the ferrozine assay;
Co(III)-EDTA
was quantified by ion chromatography (
15);
Cr(VI) was quantified
by reacting it with symdiphenylcarbazide reagent
(0.25% in acetone)
and measuring absorbance at 540 nm (
51);
and U(VI) was quantified
with a kinetic phosphorescence analyzer
(
30). The Mn(II) product
of MnO
2 reduction was
extracted in 0.5 N HCl for 15 min and filtered
through a
0.2-µm-pore-size filter according to the method of Lovley
and
Phillips (
29). The extracted Mn(II) was then reacted with
10 parts of a formaldoxamine-ammonium hydroxide solution and quantified
spectrophotometrically at 450 nm, as described by Gorby et al.
(
15). All experiments were performed in
triplicate.
Temperature and pH responses.
The effects of temperature on
growth and Fe(III) reduction by SA-01 and NMX2 A.1 were quantified with
basal medium containing 10 mM lactate, 10 mM Fe(III)-NTA, 5 mg of
tryptone liter1, 3 mg of yeast extract
liter1, and 1 mg of glucose liter1.
Cultures were incubated in serum vials with shaking at various temperatures. Growth and iron reduction rates were measured at various
pHs in basal medium containing 10 mM lactate and 10 mM Fe(III)-NTA as
described above, except that the medium was buffered with 50 mM sodium
acetate at pH 5.0, 50 mM PIPES buffer at pH 6.0 and 6.5, 50 mM
N-tris(hydroxymethyl)methyl-2-aminoethanesulfonic acid (TES)
buffer at pH 7 and 7.5, 50 mM 1,3-bis-Tris-propane buffer at pH 8.0 and
9.0, and 50 mM 3-(cyclohexylamino)propanesulfonic acid (CAPS) buffer at
pH 10.0. Cultures were incubated at 60°C with shaking. Growth and
Fe(II) were quantified as described above.
NTA biodegradation.
The abilities of strains SA-01 and NMX2
A.1 to mineralize NTA to CO2 were tested because it was
noted that cells reduced Fe(III)-NTA to Fe(II), even when lactate or
other potential electron acceptors were absent, albeit more slowly and
to a lesser degree. A modification of the radiorespirometry method of
Bolton and Girvin (5) was used for these experiments.
Biodegradation was tested with cells suspended in a 10 mM HEPES (pH
7.0) buffer. Buffer solution (2.0 ml in each Balch tube) contained a
5.0 µM solution of [U-14C]Fe(III)-NTA (98% radiopure,
16.7 Bq ml1). Cells were grown anaerobically in TYG
containing 10 mM nitrate and then washed and resuspended in anaerobic
HEPES buffer. Washed cells were added to the NTA-containing buffer
solution to a final density of 2.5 × 107 cells
ml1 (SA-01) and 4.0 × 107 cells
ml1 (NMX2 A.1). Control tubes were not inoculated. The
headspace gas was N2. The tubes were incubated without
shaking at 60°C. An alkaline trap containing 0.2 ml of 0.6 N KOH (an
amount more than adequate to trap all of the C within the tube as
CO2) was attached to the underside of each rubber Balch
tube stopper. Duplicate tubes were sacrificed after 5 and 12 days, at
which times, the cultures were acidified with 0.4 ml of 1.0 N
HNO3. After 24 to 48 h, the traps were removed and the
radioactivity of subsamples (0.1 to 0.18 ml) was measured by liquid
scintillation counting. Initial cell densities were 1.3 × 106 cells ml1 for SA-01 and 3.6 × 106 cells ml1 for NMX2 A.1. After 5 and 12 days of incubation, the cultures were acidified for 24 to 48 h and
the label remaining in the culture fluid was quantified by liquid
scintillation counting. Also, after 12 days of incubation, an alkaline
trap was added to each tube immediately before acidification; the
14CO2 captured in the trap was measured by
liquid scintillation counting to corroborate the data from the solution assay.
Nucleotide sequence accession number.
The 16S rDNA sequence
of strain SA-01 has been deposited in GenBank under accession no.
AF020205.
| |
RESULTS |
Identification and phylogeny.
Comparison of the 16S rDNA
sequence of strain SA-01 with gene sequences in GenBank, with BLAST
(2), showed that this bacterium had >98% homology with the
16S rDNA sequence of Thermus strain NMX2 A.1
(45). Phylogenetic analysis of 16S rDNA sequences by the
maximum-likelihood method showed SA-01 to be a member of the genus
Thermus, closely related to strains NMX2 A.1 and Vi7
(55) (Fig. 1). After strain
SA-01 had been subcultured several times in basal medium containing (i)
lactate as the electron donor and nitrate as the electron acceptor,
(ii) lactate as the electron donor and Fe(III)-NTA as the electron
acceptor, and (iii) H2 as the electron donor and
Fe(III)-NTA as the electron acceptor, the identities of these
subcultures were confirmed to be the same as that of the original
isolate by amplification of 16S rDNA, cloning, and comparison of RFLP
patterns after digestion with CfoI (Gibco BRL). The
restriction patterns of four clones from each of the subcultures
matched the RFLP of the original isolate. Strain SA-01 also showed a
filamentous morphology that is consistent with its placement within the
genus Thermus.
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FIG. 1.
16S rDNA-based molecular phylogeny (maximum-likelihood
method) of various Thermus strains, including metal-reducing
SA-01 and NMX2 A.1 and also various non-Thermus outgroup
species. The phylogeny was constructed with sequences corresponding to
E. coli positions 49 to 71, 102 to 180, 221 to 451, and 481 to 1259. The tree shows the close phylogenetic relationship of these
metal-reducing strains within the genus Thermus. The scale
bar shows the expected number of changes per sequence position.
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Electron donors and electron acceptors.
Thermus strains
SA-01 and NMX2 A.1 grew in basal medium amended with lactate and any of
the following terminal electron acceptors: O2, nitrate, and
Fe(III)-NTA. Growth continued with repeated subculturing, regardless of
the electron acceptor. Neither organism grew in the absence of an
electron acceptor or with fumarate, nitrite, SO42, or
S2O32 as the terminal electron
acceptor. Thermus strains SA-01 and NMX2 A1 were able to
reduce Fe(III)-NTA coupled to lactate oxidation and growth (Fig.
2). Production of Fe(II) was concomitant
with the disappearance of lactate and growth of cells. Other organic acids, such as acetate, were not detected in the medium by ion chromatography. Reduction of Fe(III)-NTA and cell reproduction also
occurred in cultures that did not contain lactate; however, levels of
iron reduction and cell growth in the absence of lactate were
significantly lower than in the presence of lactate. When cells were
transferred from this experiment into fresh medium twice, sequentially,
reduction of Fe(III)-NTA to Fe(II) and growth of cells proceeded
without diminution of the amount of iron reduced or the cell yield
(Fig. 3). Iron reduction and cell growth
proceeded through successive transfers in treatments with and without
lactate; however, the levels of Fe(II) produced and the cell yields
were again significantly lower in the treatments without lactate. When cells were transferred into medium containing lactate but without Fe(III)-NTA or another electron acceptor (second transfer), lactate utilization and cell growth were negligible (Fig. 3b and c).
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FIG. 2.
Reduction of Fe(III)-NTA coupled to lactate oxidation
and growth by Thermus strain SA-01. Fe(II) concentration
(a), lactate concentration (b), and cell density (c) versus time are
shown. Error bars show 1 standard deviation (n = 3).
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|
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FIG. 3.
Fe(II) concentrations (a) and cell densities (b) of
Thermus strain SA-01 during repeated transfers into fresh
basal medium. Error bars show 1 standard deviation (n = 3).
|
|
Oxidation of
14C-labeled lactate to
14CO
2 occurred concomitantly with the reduction
of Fe(III)-NTA to Fe(II) by
Thermus strain
SA-01; oxidation
of [
14C]lactate in the absence of Fe(III)-NTA was minimal
(Fig.
4).
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|
FIG. 4.
Mineralization of 14C-labeled lactate to
14CO2 by Thermus strain SA-01 in the
presence and absence of Fe(III)-NTA (a) and concomitant reduction of
Fe(III)-NTA to Fe(II) in the presence of lactate (b). Error bars show 1 standard deviation (n = 2).
|
|
Thermus strain SA-01 reduced HFO to Fe(II); however, the
rate of reduction was extremely low (Fig.
5). Rates of growth and
HFO reduction
were greatly accelerated in cultures containing
a low concentration of
the humic acid analog AQDS (Fig.
5b). Iron
reduction was negligible in
vials injected with dead cells and
in uninoculated vials, regardless of
whether AQDS was present.
A black solid, presumably magnetite, was
generated as a product
of HFO reduction. The production of magnetite
was indicated by
the strong attraction of black particulates to a
magnet after
several days of incubation. The original HFO was reddish
brown
and was only weakly magnetic. Likewise, controls that were not
inoculated or that were injected with killed cells did not form
a black
magnetic precipitate. Suspensions of
Thermus strain SA-01
cells reduced Fe(III)-NTA, Fe(III)-citrate, and HFO (Fig.
6a to
c); the cells also reduced Co(III)-EDTA,
Cr(VI), and U(VI) (Fig.
6d to f). Strain SA-01 reduced Mn(IV) in the
presence of either
lactate or H
2 (Fig.
6g and h). Lactate
reduced MnO
2 in the absence
of cells, but the rate and
level of Mn reduction were significantly
lower than in the sample
treated with cells.
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FIG. 5.
Reduction of HFO and growth by Thermus strain
SA-01 with lactate as the electron donor. Fe(II) concentrations without
AQDS (a) and in the presence of 0.1 mM AQDS (b) and cell density (c)
versus time are shown. Error bars show 1 standard deviation
(n = 2).
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|
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FIG. 6.
Reduction of various electron acceptors by suspensions
of Thermus strain SA-01 cells in media containing lactate,
acetate, and/or H2 as the potential electron donor(s) (as
described in Materials and Methods). Levels of reduction of Fe(III)-NTA
(a), Fe(III)-citrate (b), HFO (c), Co(III)-EDTA (d), Cr(VI) (e), U(VI)
(f), and Mn(IV) (g and h) are shown. Electron donors for Mn reduction
were lactate (g) and H2 (h). Filled circles show results
for experimental treatments (with cells); open circles show results for
controls (no cells). Error bars show 1 standard deviation (n = 3).
|
|
Reduction of elemental sulfur by both strains SA-01 and NMX2 A.1 was
evidenced by growth under anaerobic conditions with S
0 as
the sole electron acceptor and by clearing of S
0 in TYG
agar. Significant growth and clearing of S
0 occurred within
24 h of inoculation, and sulfide was detected
in the Zn-acetate
traps. S
0 was not cleared in control plates consisting of
uninoculated
growth medium and medium streaked with killed cells, and
sulfide
was not detected. Growth did not occur on TYG agar under
anaerobic
conditions without addition of an electron acceptor such as
S
0.
When
Thermus strains SA-01 and NMX2 A.1 were grown
anaerobically in TYG medium containing 10 mM nitrate, the nitrate was
reduced
quantitatively to nitrite. Growth did not occur in anaerobic
TYG
broth unless an electron acceptor such as nitrate was
added.
Temperature and pH responses.
The optimum temperature for
growth and Fe(III) reduction was approximately 65°C for both SA-01
and NMX2 A.1; the optimum pHs for growth and Fe(III) reduction were
near neutrality for both strains (Fig.
7).
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FIG. 7.
Growth rate (µ) and Fe(III) reduction rate versus
temperature for Thermus strains SA-01 and NMX2 A.1 cultured
with lactate as the electron donor and Fe(III)-NTA as the electron
acceptor. Filled circles, µ; open circles, Fe(III)-reduction rate.
|
|
NTA biodegradation.
Both SA-01 and NMX2 A.1 mineralized
approximately 10% of radiolabeled NTA in 5 days (Fig.
8). NTA incubated in the same solution, but without cells, resulted in less than 3% mineralization to 14CO2 in the same period.
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FIG. 8.
Percent mineralization of 14C-labeled NTA by
Thermus strains SA-01 and NMX2 A.1. Error bars show 1 standard deviation (n = 2).
|
|
| |
DISCUSSION |
Reduction of Fe(III) coupled to growth by Thermus
strain SA-01 was demonstrated by (i) the disappearance of lactate as an electron donor and the production of Fe(II) from Fe(III) concomitant with cell growth, (ii) the lack of iron reduction or growth in the
absence of live cells, and (iii) the fact that rates of Fe(III) reduction were optimal in the ranges of temperature and pH that are
also optimal for growth of this and other species of
Thermus. The identity and purity of the Thermus
SA-01 strain was established by 16S rDNA cloning, sequencing, and
phylogenetic analysis, performed shortly after isolation and also after
growth and iron reduction in an iron-containing medium. Also, it was
demonstrated that Thermus strain SA-01 grew, reduced
Fe(III), and consumed lactate over three consecutive transfers into
fresh medium.
Growth and reduction of iron by SA-01 was more rapid and extensive when
Fe(III) was added in a soluble, chelated form, rather than as HFO, an
amorphous iron oxide precipitate. Although this behavior is similar to
that of some other DIRB (8, 24, 32, 37), the ability of
SA-01 to reduce HFO was particularly poor in comparison to that of
organisms such as Shewanella putrefaciens. Recent studies
demonstrate that a subsurface S. putrefaciens strain, CN-32,
could reduce approximately 40% of a 50 mM HFO suspension in
bicarbonate-buffered lactate medium (12). Thermus
strain SA-01 grew and reduced HFO at a much higher rate when a soluble humic acid analog, AQDS, was present in low concentration, as has also
been shown for Shewanella and Geobacter
(25). These findings are consistent with a model for
bacterial reduction of iron oxides in which the likely rate-limiting
step is the solubilization of Fe(III) or the transfer of electrons from
cells to the surfaces of Fe(III)-oxide particles. In this model, metal
reduction requires direct contact between cell surface-associated metal
reductases (34) (or other cell surface components). Metal
chelators can obviate the requirement for direct contact by maintaining
Fe(III) in a soluble form that can then diffuse to the cell surface
(32). Humic compounds, represented in our study by AQDS, can
shuttle electrons between DIRB and iron-oxide minerals (25).
Chelators and/or humic acids may enable some bacteria that are
otherwise unable to reduce insoluble metal oxides to couple metal
reduction to respiration. This inability to reduce iron oxides may be
due to a lack of outer membrane-associated metal reductases (35, 36) or extracellular c-type cytochromes that function
as ferric reductases, such as the one produced by Geobacter
sulfurreducens (46).
Thermus strains SA-01 and NMX2 A.1 can use lactate and/or
NTA as electron donors for growth and dissimilatory iron reduction. Because they appear to use both simultaneously when Fe(III) is chelated
with NTA, it is difficult to determine the stoichiometry of lactate
oxidation coupled to Fe(III) reduction. It appears that lactate was
completely oxidized to CO2 by SA-01 since neither acetate
nor other organic anions were detected by ion chromatography. At least
a portion of the NTA was oxidized to CO2 as well; however, intermediate oxidation products may also occur. Anaerobic
biodegradation of NTA in other genera has been reported previously
(17). Further study is needed to determine the range of
substrates that can serve as electron donors for dissimilatory iron
reduction by Thermus strain SA-01 and related metal-reducing
strains and to determine the biochemical pathways of substrate oxidation.
The finding of dissimilatory reduction of iron and other metals by
Thermus strains was unexpected, given the long history of
study of the physiologies of organisms within this genus. However, iron
reduction in a variety of genera previously unknown to include metal-reducing species is now being reported. Examples of other such
recent findings are found in reports on Bacillus infernus (6) Rhodobacter capsulatus (10), and
Thermotoga maritima (52). However, the
metal-reducing Thermus strains of this study are distinct
from many other DIRB in that they are facultative anaerobes. The
ability of Thermus strain SA-01 to use O2,
nitrate, Fe(III), Mn(IV), and S0 as terminal electron
acceptors is analogous to that of metal-reducing Shewanella
strains, the only other organisms currently known to respire all of
these electron acceptors and to reduce Mn(IV), Co(III), Cr(VI), and
U(VI). With respect to metabolic versatility, Thermus strain
SA-01 differs from Shewanella spp. only in that it appears
not to use nitrite, sulfur oxyanions, or fumarate as terminal electron
acceptors for growth. Thermus strains SA-01 and NMX A.1
differ also from metal-reducing Shewanella strains in that
they reduce Fe(III) and other metals at lower rates.
Dissimilatory metal reduction by Thermus may be an important
biogeochemical process in some thermic deep subsurface environments. Evidence that metal-reducing Thermus strains are also
present in Witwatersrand rock was obtained by extraction,
amplification, and cloning of DNAs from rock samples that were
collected from the same mine as the groundwater from which SA-01 was
cultured (13). One such clone from these directly extracted
DNAs had a high degree of homology (>99% in its 16S rDNA) to SA-01. A
highly organic seam, termed the carbon leader, is the major source of gold in the Witwatersrand Supergroup. The carbon leader also contains high concentrations of uranium and framboidal pyrite (39).
Biological oxidation of organic matter coupled to reduction of Au(I),
Au(III), U(VI), Fe(III), or S may have been involved in the
concentrations of solid-phase elemental Au, U(IV), and pyrite within
the carbon leader. Humic-like compounds in the carbon leader may have
also served as electron acceptors and facilitated microbial reduction of solid-phase metal oxides, if present. The origin of the carbon leader has been debated, but one possibility that has been argued is
that it is the fossilized remnant of an algal mat (11). Gold in the carbon leader commonly occurs in filamentous structures that are
consistent with the sizes and morphologies of filamentous algae or
bacteria. It is interesting to note that bacteria of the genus
Thermus are commonly associated with algal-bacterial mats in
many hot springs and that these mats are believed to be an important
source of organic substrates for these organisms (1).
Dissimilatory metal-reducing strains of Thermus are not
confined to the deep subsurface of South Africa, as shown by the
related strain from New Mexico, Thermus strain NMX2 A.1,
which also has this trait. We have recently determined that a strain
isolated from Portugal, Thermus strain Vi7 (55),
which is phylogenetically closely related to SA-01 and NMX2 A.1 (Fig.
1), is also able to reduce Fe(III)-NTA (18). It remains to
be determined how widespread dissimilatory iron reduction is within the
genus Thermus.
The genus Thermus represents one of the deep branches of the
bacterial 16S rDNA phylogenetic tree (40). Other deeply
branching bacterial genera, e.g., Aquifex and
Thermotoga, are also thermophilic; however, these other
genera are strict anaerobes that respire electron acceptors such as
sulfur and Fe(III), which may have been used by the earliest forms of
life (40, 52-54). This finding raises the question of
whether early members of the genus Thermus reduced metal
and/or sulfur and whether metal reduction has subsequently been lost
from strictly aerobic species such as Thermus aquaticus. Alternatively, metal reduction may have been acquired more recently by
aerobic members of the genus Thermus. Recently, it was shown that Thermus thermophilus HB8 could grow anaerobically in
the presence of nitrate (41) and that this trait could be
transferred via conjugation to an aerobic Thermus strain
(42). Although it is currently unknown whether the factors
involved in Fe(III) reduction in Thermus strains SA-01 and
NMX2 A.1 are conjugative, their presence on a transmissible plasmid
indicates that, in addition to nitrate respiration, Fe(III) respiration
in Thermus can be horizontally transferred. Regardless of
their evolutionary histories, the metabolic versatility evinced by
these metal-reducing Thermus strains is remarkable and may
enable growth in a wide variety of thermal environments, including
those that are periodically or continuously anaerobic.
| |
ACKNOWLEDGMENTS |
This research was supported by the Subsurface Science Program,
Office of Energy Research, U.S. Department of Energy (grants DE-FG03-93ER-61683 [T.L.K.] and DE-FG02-94ER61821 [T.C.O.]).
Pacific Northwest National Laboratory is operated for the Department of Energy by the Battelle Memorial Institute under contract
DE-AC06-76RLO1830. We also acknowledge support from the Department of
Energy's Natural and Accelerated Bioremediation (NABIR) Program.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biology, New Mexico Institute of Mining and Technology, Socorro, NM
87801. Phone: (505) 835-5321. Fax: (505) 835-6329. E-mail:
tkieft{at}nmt.edu.
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Abstract
Introduction
