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Applied and Environmental Microbiology, May 1999, p. 1826-1833, Vol. 65, No. 5
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Contribution of Methanotrophic and Nitrifying
Bacteria to CH4 and NH4+ Oxidation
in the Rhizosphere of Rice Plants as Determined by New Methods of
Discrimination
Paul L. E.
Bodelier* and
Peter
Frenzel
Department of Biogeochemistry, Max-Planck
Institute for Terrestrial Microbiology, Marburg, Germany
Received 11 December 1998/Accepted 23 February 1999
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ABSTRACT |
Methanotrophic and nitrifying bacteria are both able to oxidize
CH4 as well as NH4+. To date it is
not possible to estimate the relative contribution of methanotrophs to
nitrification and that of nitrifiers to CH4 oxidation and
thus to assess their roles in N and C cycling in soils and sediments.
This study presents new options for discrimination between the
activities of methanotrophs and nitrifiers, based on the competitive
inhibitor CH3F and on recovery after inhibition with
C2H2. By using rice plant soil as a model
system, it was possible to selectively inactivate methanotrophs in soil
slurries at a
CH4/CH3F/NH4+ molar
ratio of 0.1:1:18. This ratio of CH3F to
NH4+ did not affect ammonia oxidation, but
methane oxidation was inhibited completely. By using the same model
system, it could be shown that after 24 h of exposure to
C2H2 (1,000 parts per million volume), methanotrophs recovered within 24 h while nitrifiers stayed
inactive for at least 3 days. This gave an "assay window" of
48 h when only methanotrophs were active. Applying both assays to
model microcosms planted with rice plants demonstrated a major
contribution of methanotrophs to nitrification in the rhizosphere,
while the contribution of nitrifiers to CH4 oxidation was insignificant.
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INTRODUCTION |
Methane- and ammonia-oxidizing
bacteria play major roles in the global carbon and nitrogen cycles.
These bacteria convert the most reduced carbon and nitrogen compounds
(CH4 and NH4+) to oxidized forms
(CO2 and NO2
). Apart from their
primary substrates, CH4 and NH4+,
both groups of bacteria need oxygen for growth and energy generation. Hence, habitats with oxic and anoxic conditions in close proximity, such as the rhizospheres of plants in flooded soils and sediments, are
ideal for their persistence. Wetland plants supply their respiring roots with oxygen by means of an aerenchymatous tissue which also facilitates the exchange of other gases such as CH4,
N2O, and N2 among the atmosphere, shoots, and
roots (2, 7). Some of the oxygen is released by the roots
into the surrounding soil, thus creating oxic areas within an otherwise
anoxic habitat. Indeed, methanotrophs (12, 20) as well as
nitrifiers (3, 10, 18, 39) have been shown to profit from
the presence of wetland plants, with distinct impacts on nutrient
cycling. Due to oxygen release by wetland plants, a substantial part
(10 to 90%) of the CH4 potentially emitted can be oxidized
by methane-oxidizing bacteria and thus retained in the system as
biomass carbon or as CO2 (12, 13, 15, 30, 41,
44). Nevertheless, enough CH4 is still being emitted
from natural wetlands and rice paddies to make them prominent sources
of atmospheric CH4, accounting for 30% of global emission
(34, 42). Because CH4 is involved in global
warming (14), knowledge of the CH4 sinks in rice
soils and of the controlling factors and organisms involved, and thus
of methane- and ammonia-oxidizing bacteria, is essential in order to
develop mitigation strategies. This knowledge is still sparse.
Both methane- and ammonia-oxidizing bacteria can act as sinks for
CH4 in rice soils. Due to the homology of the key enzymes methane monooxygenase (MMO) and ammonia monooxygenase, methanotrophs as
well as ammonia oxidizers can oxidize both CH4 and
NH4+, as well as a variety of other substrate
analogues (5). However, direct evidence for nitrification by
methanotrophs (36, 47) and for methane oxidation by
nitrifiers (26, 45) has been given only for pure cultures.
In natural wetlands and rice plant soils this has never been studied,
while in a few other natural systems this has been demonstrated only
indirectly by means of the inhibitor-sensitive
14CH4/14CO oxidation ratio, which
is higher for methanotrophs than for nitrifiers (27). By
using this technique, CH4 oxidation was assigned to
nitrifiers in agricultural and forest soils (43), whereas
methanotrophs were found to be dominant in the thermocline of a
mesotrophic lake (6). Several inhibitors (e.g.,
C2H2, CH3F, dimethylether,
allylsulfide, allylthiourea, dicyandiamide, picolinic acid, and
difluoromethane) have been evaluated for their potential to selectively
knock out one group of bacteria without affecting the other (6,
32, 33, 37, 40). However, only allylsulfide (40) and
picolinic acid (32) showed potential for discrimination,
although neither was able to discriminate 100%.
The purpose of this study was to develop and evaluate new methods to
estimate the relative contributions of methanotrophs to
NH4+ oxidation and of nitrifiers to
CH4 oxidation in soil planted with rice plants. Two
approaches, based on a temporary inactivation of one of the two groups,
were used. Methylfluoride, being a competitive inhibitor (24,
37) of CH4 and NH4+
oxidation, will be inhibitory only in a certain concentration ratio to
CH4 or NH4+, respectively. We
assessed the possibility of finding a
CH3F/CH4/NH4+ ratio
which excludes CH4 oxidation but allows for
NH4+ oxidation. The second approach was
analogous to a method for discriminating nitrifier and denitrifier
production of NO and N2O (28), based on the
differential recovery after exposure to C2H2.
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MATERIALS AND METHODS |
Soil and field site.
The soil used in all experiments was
sampled from a rice plant field of the Istituto Sperimentale per la
Cerealicoltura in Vercelli (Italy) in the spring of 1997 and was stored
after air drying. The soil type and rice plant field management
practice have been described earlier (42). Prior to use the
soil was crushed and sieved (mesh size, 2 mm).
Effects of C2H2, CH3F, and
picolinic acid. (i) Inhibition of CH4 oxidation.
To
induce CH4 oxidation in the dried rice plant soil, slurries
were prepared by mixing 5-g amounts of soil with 20 ml of demineralized water in 150-ml flasks closed with rubber stoppers (ratio of gas volume
to liquid volume, 5:1). After the flasks were flushed with synthetic
air (21% O2 in N2) for 15 min, 2.5 ml of pure
CH4 (99.995% pure; Messer Griesheim, Siegen, Germany) was
added to give a mixing ratio of 20,000 parts per million volume (ppmv).
The flasks were incubated at 25°C in the dark on a gyratory shaker
(100 rpm) for 3 days, after which all CH4 was consumed, as
confirmed by gas chromatographic (GC) analyses. After the preincubation
period, the flasks were flushed again with synthetic air for 15 min,
after which 1.25 ml of CH4 was added to give a final mixing
ratio of 10,000 ppmv (~10 µM). In the case of the gaseous
inhibitors C2H2 (99.6% pure; Messer Griesheim)
and CH3F (>98% pure; Fluorochem, Old Glossop, Derbyshire,
United Kingdom), triplicate flasks were supplemented with amounts
resulting in mixing ratios of 0, 0.1, 1, 10, 100, 1,000, and 10,000 ppmv. The total amounts of gas present and the concentrations of the
gases in the liquid phase were calculated by using Bunsen coefficients
at 25°C (0.03 for CH4 [16], 0.934 for
C2H2 [16], and 0.99 for
CH3F [19]) and the gas and liquid volumes
of the flasks. Before C2H2 was added, it was
purified by passage through 5 N NaOH-5 N H2SO4
(22). In the case of picolinic acid, 19 ml instead of 20 ml
of demineralized water was added to the soil. To these slurries, 1 ml
of stock solution was added to reach final concentrations of 0, 10, 100, 500, 1,000, and 10,000 µM. After addition of the inhibitor, the
flasks were incubated at 25°C in the dark on a gyratory shaker (250 rpm). CH4, C2H2, and
CH3F mixing ratios in the headspaces were monitored during 24 h. Gas samples (100 µl) were taken and injected into a GC by using pressure lock syringes (Precision Sampling Corp., Baton Rouge,
La.). CH4 oxidation rates were calculated from linear
regressions applied to the data of the first 8 h of the assay
(r2 > 0.95).
(ii) Inhibition of NH4+ oxidation.
NH4+ oxidation in the dried rice plant soil was
induced in soil slurries by preincubation for 7 days. For this purpose
20-g amounts of dry soil were transferred to 500-ml flasks equipped with septa at the bottoms for withdrawal of slurry samples. A total of
0.15 g of CaCO3 and 85 ml of assay medium containing 0.33 g of (NH4)2SO4/liter,
0.027 g of KH2PO4/liter, and 0.14 g of
K2HPO4/liter were added (ratio of gas volume to
liquid volume, 5:1). The flasks were closed with silicone septa and
incubated horizontally on a gyratory shaker (120 rpm) at 25°C. After
this preincubation period, the flasks were flushed with nitrogen for 1 h, followed by anoxic incubation for 24 h. During this time the initial amounts of NO3 and
NO2 were reduced by denitrification. After
this treatment the flasks were opened and flushed with pressurized air
for 5 min. The flasks were closed again, and the respective amounts of
the various inhibitors were added as described above. During the
subsequent oxic incubation, nitrification activity was monitored by
withdrawing 1-ml subsamples at regular intervals during 24 h. The
slurry samples were centrifuged (13,800 × g, 4°C, 15 min), and the supernatant was stored at 
20°C for later analysis of
NH4+, NO2, and
NO3. For treatments with
C2H2 or CH3F, the mixing ratios of
these gases were determined as described above. Potential
NH4+ oxidation activities were calculated from
linear regressions of the
NO3-plus-NO2
concentration during the first 24 h of incubation
(r2 > 0.95).
(iii) Recovery of CH4 and
NH4+ oxidation after 24-h exposure to
C2H2 and CH3F.
After 24 h
of incubation in the presence of the gaseous inhibitors, the flasks
were opened and shaken on a gyratory shaker for 30 min. While they were
shaken, the flasks were flushed with pressurized air. The flasks were
then closed again and shaken vigorously by hand, followed by immediate
flushing with air. This was repeated three times for each bottle, after
which new stoppers were used to seal the bottles. New stoppers were
used because the stoppers already exposed to
C2H2 or CH3F release amounts of these gases which they have absorbed during exposure. The absence of
C2H2 and CH3F was checked by GC.
When the inhibitors could no longer be detected, the flasks were
incubated again as described above. Recovery of CH4 and
NH4+ oxidation was monitored as described above.
CH4 and NH4+ oxidation in the
rice plant rhizosphere. (i) Operation of the model system and growth
conditions.
As a model system, compartmented microcosms were used
as described in detail by Bodelier et al. (9). In the center
of each of these cylindrical stainless steel microcosms (height by
diameter, 12 by 9 cm) a perforated steel cylinder (height by diameter,
12 by 4 cm), covered on the inside with nylon gauze (mesh size, 30 µm), served to separate the rooted from the nonrooted soil. The microcosms were filled with 700 g of dry rice plant soil,
subsequently flooded with demineralized water, and incubated for 1 week
in a growth chamber (Conviron CMS 3244; Controlled Environments
Limited, Winnipeg, Manitoba, Canada) at 25°C and 70% relative
humidity in the dark. After 1 week, one rice seedling (Oryza
sativa cv. Roma, type japonica), which had been germinated on wet
filter paper at 25°C in the greenhouse, was planted in the root
compartment of each microcosm. The planted microcosms were incubated in
the growth chamber for 12 weeks at 70% relative humidity and
illuminated in a cycle of 12 h of light and 12 h of dark at a
photosynthetic active radiation (PAR) of 450 microeinsteins · m2 · s1 and a temperature regimen of
20°C at night and 25°C in the day. The surface of the soil was
always covered with 2 cm of demineralized water and shaded with
aluminum foil to reduce warming of the microcosms due to illumination.
Temperatures of ambient air and temperatures in the soil (5 cm) during
the daytime varied between 25 and 28°C, as measured with thermistor
probes connected to a data logger (DL2e; Delta-T Devices Ltd.,
Cambridge, United Kingdom). The microcosms were fertilized weekly with
(NH4)HPO4 by syringe injection of 0.84 mmol of
N in 10 ml of H2O, corresponding to a total application of
260 kg of N · ha1.
(ii) Porewater sampling.
In order to monitor
CH4, NH4+,
NO3, NO2, and pH,
weekly porewater samples were taken from the root and nonroot
compartments of the microcosms by means of Rhizon soil solution
samplers (Eijkelkamp, Giesbeek, The Netherlands) as described by
Bodelier et al. (9). Evacuated Venoject blood-collecting
tubes, which had been flushed with nitrogen to remove residual methane,
were mounted on the sampling devices for sample collection. After
sampling, the pressure in the tubes was adjusted to atmospheric
pressure by addition of ambient air, after which the tubes were shaken
vigorously. Subsequently, CH4 was withdrawn from the
headspace and analyzed as described below. After the pH was measured, 1 ml of porewater was centrifuged (13,800 × g, 4°C, 15 min) and
stored at 20°C for further analysis.
(iii) Harvest and preparation of soil slurries.
After 12 weeks the microcosms were harvested, and the soil from the root and
nonroot compartments was treated as follows. Prior to processing of the
soil, the upper 2 to 3 cm of both compartments were removed and
excluded from further analysis, because this soil layer receives oxygen
from the overlying water and not only from the rice plant root. The
complete root compartment with roots was transferred to a beaker
containing 240 ml of demineralized water. The resulting suspension of
rhizosphere soil contained approximately 0.25 g of dry soil per
ml. The soil from the nonroot compartment was completely transferred to
a glass beaker and mixed. One hundred sixty grams of this soil was
suspended in 240 ml of demineralized water. These slurries were used to
determine potential CH4 oxidation. For potential
NH4+ oxidation, competitive exclusion, and
differential recovery assays, 150 ml of these slurries was mixed with
150 ml of a (NH4)2SO4 solution
containing 6.23 mM NH4+. This
NH4+ concentration was chosen in order to reach
a desired concentration of 2 mM in the slurry, accounting for the
endogenous ammonium already present and for the adsorption of ammonium
to the soil particles (35% of added ammonium), which was determined in
a preharvest experiment with soil from identical microcosms (data not shown).
(iv) Potential CH4 and NH4+
oxidation in soil slurries.
The potential CH4
oxidation activities of root and nonroot compartments of four replicate
microcosms were determined as described above. Seventy milliliters of
slurry was transferred to 500-ml flasks and assayed as described above
for the nitrification assays. The flasks were supplemented with 10,000 ppmv of CH4 and incubated at 25°C on a gyratory shaker
(120 rpm). For the potential NH4+ oxidation, 70 ml of slurry [supplemented with
(NH4)2SO4 as described above] was
used and incubated immediately under the conditions described for the
CH4 oxidation. Further assay procedures were as already described.
(v) Potential CH4 and NH4+
oxidation associated with rice plant roots.
The potential
CH4 oxidation activities of rice plant roots were
determined by using 5 g of fresh root material incubated in 150-ml
flasks closed with rubber stoppers. After flushing with synthetic air
for 15 min, 1.5 ml of CH4 (10,000 ppmv) was added. The
flasks were incubated statically at 25°C in the dark. The CH4 mixing ratio was monitored as already described.
Potential NH4+ oxidation activity associated
with rice plant roots was determined by incubating 5 g of fresh
root material together with 50 ml of assay medium (see "Inhibition of
NH4+ oxidation" above) in a 250-ml Erlenmeyer
flask. Flasks were incubated on a gyratory shaker (100 rpm) at 25°C
in the dark. Samples were taken at regular intervals and were processed
as described for the slurry samples from the potential
NH4+ oxidation assay.
(vi) CEA.
For the competitive exclusion assay using
CH3F (CEA), the slurries which were diluted with
(NH4)2SO4 solution were used.
Seventy milliliters of slurry from the root and nonroot compartments of four replicate microcosms was transferred to 500-ml assay flasks with
no CH4 addition or with the addition of CH4
(10,000 ppmv) alone or of CH4 (10,000 ppmv) plus
CH3F (300 ppmv). The latter treatment gives rise to a
CH4/CH3F/NH4+ dissolved
molar ratio of 0.1:1:18. In all assay bottles CH4, NH4+, NO2, and
NO3 were monitored as described above.
(vii) Differential recovery assay using
C2H2 (DRA).
Seventy-milliliter amounts of
the NH4+-supplemented slurries from the root
and nonroot compartments of four replicate microcosms were transferred
to 500-ml assay flasks, and CH4 (10,000 ppmv) was added.
The flasks were incubated as described above, and CH4 and
NH4+ oxidation was monitored for 24 h,
after which C2H2 (1,000 ppmv) was added. After
24 h of exposure the C2H2 was removed as
described above. After removal of C2H2, the
flasks were supplemented again with CH4. During the
following 2 days, the recovery of CH4 and NH4+ oxidation was monitored.
(viii) Numbers of methanotrophs.
The numbers of
methanotrophs in soil from the root and nonroot compartments, as well
as those associated with the rice plant roots, were determined by the
most probable number (MPN) method according to Gilbert and Frenzel
(20). Soil slurries and root suspensions were serially
diluted in microtiter plates containing ammonium-mineral salts medium.
The plates were incubated for 4 weeks at 25°C in gastight jars
containing 20% CH4 in air. Inoculated plates without
CH4 served as controls. Wells which were turbid were
considered positive.
Analyses. (i) Gas analyses.
In inhibitor experiments with
preincubated rice plant soil, CH4 was analyzed on an SRI GC
(SRI Instruments, Torrance, Calif.) equipped with a flame ionization
detector (FID) and a Hayesep D column (length, 2 m; 80/100 mesh).
Helium was used as the carrier gas (flow rate, 20 ml · min1), and synthetic air (250 ml · min1) and H2 (20 ml · min1) were used as burning gases. The oven temperature
was 80°C. C2H2 and CH3F in the
inhibitor experiments with preincubated soil, as well as
C2H2, CH3F, and CH4 in
the microcosm experiment and CH4 in the weekly porewater
samples, were analyzed with an SRI GC equipped with an FID and a
Porapak N column (length, 2 m; 80/400 mesh). N2 was
used as the carrier gas (20 ml · min1), and
synthetic air (222 ml · min1) and H2
(20 ml · min1) were used as burning gases. The
oven temperature was 60°C. Calibration was performed at each sampling
event by triplicate injection of 1,000 ppmv of CH4 in
N2 (Messer Griesheim). C2H2 and
CH3F standards were prepared by adding defined amounts to
serum bottles of known volumes.
(ii) Slurry and porewater analyses.
The concentrations of
NH4+, NO2, and
NO3 in the slurry samples were analyzed
colorimetrically with a Technicon Traacs 800 autoanalyzer (Technicon
Instrument Corp., Tarrytown, N.Y.). NH4+ in the
weekly porewater samples was analyzed by ion chromatography using a
high-pressure liquid chromatograph (HPLC) equipped with an LCA (Sykam,
Gilching, Germany) A14 column and ascorbic acid-oxalic acid as the
eluent. NO2 and NO3
were also analyzed by ion chromatography on an HPLC equipped with an
LCA KSP column and Na2CO3 as the eluent.
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RESULTS |
Effects of C2H2, CH3F, and
picolinic acid on CH4 and NH4+
oxidation.
From Fig. 1 it is evident
that both methanotrophs and nitrifiers were equally sensitive to
C2H2 and picolinic acid. Methanotrophs as well
as nitrifiers were completely inhibited at concentrations of 1 µM
C2H2 (~10 ppmv) or 100 µM picolinic acid.
Even at picolinic acid concentrations of 10 µM, CH4 and
NH4+ oxidation rates were still reduced by 11 and 20%, respectively.
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FIG. 1.
Effects of C2H2 (A) and
picolinic acid (B) on CH4 and NH4+
oxidation in preincubated rice plant soil slurries. Each value is the
arithmetic mean from three replicate assays ± standard deviation
(SD). The percent inhibition is relative to the activity without the
presence of the inhibitor. The control activities for CH4
oxidation were 0.85 ± 0.04 and 0.92 ± 0.02 µmol · g (dry weight)1 · h1 for
C2H2 and picolinic acid, respectively.
Corresponding NH4+ oxidation rates were
30.98 ± 9.41 and 30.27 ± 2.31 nmol of
NO3 plus NO2
· g (dry weight)1 · h1.
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CH
4 oxidation at a concentration of 10 µM (10,000 ppmv)
CH
4 was completely inhibited by the competitive inhibitor
CH
3F at
a concentration of 12 µM (~100 ppmv) (Fig.
2A). However, this
inhibition lasted for
only 7 h, due to the oxidation of CH
3F.
At a
concentration of 122 µM (~1,000 ppmv), CH
3F inhibited
CH
4 oxidation completely for at least 24 h. In the
presence of 2.78
mM NH
4+, ammonia-oxidizing
bacteria were not affected by the addition
of as much as 142 µM
CH
3F (Fig.
2B). Only the addition of 10,000
ppmv (1,555 µM) of CH
3F inhibited NH
4+
oxidation. Hence, using a
CH
4/CH
3F/NH
4+ molar
ratio of 0.1:1:18 enables the "competitive exclusion" of
methanotrophic activity while preserving the activity of
NH
4+ oxidizers. Differentiation of
CH
4 and NH
4+ oxidation by
methanotrophs and nitrifiers in this way is referred
to below as the
CEA.
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FIG. 2.
Effects of different CH3F mixing ratios on
CH4 oxidation at a concentration of 10 µM CH4
(A) and on NH4+ oxidation at a concentration of
2.68 mM NH4+ (B), in preincubated rice plant
soil slurries. Each value is the arithmetic mean from three replicate
assays. CH3F concentrations are given in the keys.
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Recovery of CH4 and NH4+
oxidation after 24-h exposure to CH3F or
C2H2.
After the removal of
CH3F, methanotrophs immediately resumed activity at the
same rate as that prior to inhibition (Fig.
3A), indicating the competitive nature
and thus the reversibility of the inhibition. The ammonia oxidizers
also resumed activity after inhibition with 10,000 ppmv of
CH3F but did not reach the initial level within the next
50 h of incubation (Fig. 3A). After inhibition with
C2H2, CH4 oxidation recovered fully
within 10 to 15 h irrespective of the level of
C2H2 (Fig. 3B). Recovery of the ammonia
oxidizers took substantially longer and depended on the
C2H2 concentration used (Fig. 3B). After
exposure to 10 ppmv (~2 µM) it took 24 h, and with 1,000 ppmv
(~197 µM) it took more than 3 days, before nitrification resumed.
Hence, the DRA provides a "window" of at least 48 h in which
to monitor CH4 and NH4+ oxidation
by methanotrophs only.
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FIG. 3.
Recovery of CH4 (solid symbols) and
NH4+ (open symbols) oxidation after 24 h
of exposure to different mixing ratios of CH3F (A) or
C2H2 (B). Each value represents the arithmetic
mean from three replicate assays. CH3F and
C2H2 concentrations are given in the keys.
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CH4 and NH4+ oxidation in
microcosms planted with rice plants. (i) Availability of
CH4 and NH4+ in the porewater.
Porewater NH4+ concentrations in the
rhizospheres of the rice plant microcosms dropped below 0.5 mM at 25 days after transplanting (Fig. 4A). In
this period the plants grew exponentially, as determined from total
leaf length and plant height (data not shown). During the remainder of
the experimental period, NH4+ levels of 100 to
200 µM were recorded. After 65 days the NH4+
concentration was at the same low level in both the root and nonroot
compartments despite regular fertilization. Porewater samples were
always taken prior to fertilizer addition. The inset in Fig. 4A shows
NH4+ dynamics in the root compartments after
one of the weekly fertilizer additions, i.e., 44 days after
transplanting. During a period of 20 h,
NH4+ availability was between 1 and 6 mM, and
it stabilized at 0.5 mM 50 h after fertilizer addition.
NO3 and NO2 were
never detected in the weekly porewater samples (detection limit, 1 to 5 µM).
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FIG. 4.
Porewater NH4+ (A) and
CH4 (B) concentrations in the root and nonroot compartments
of compartmented microcosms planted with rice plants. Each value
represents the arithmetic mean (± SD) from four replicate microcosms.
The inset in panel A depicts NH4+
concentrations in the root compartment during the first 55 h after
fertilizer was added at day 44.
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After 1 week of preincubation, the CH
4 concentrations in
the porewater of both compartments reached values of 300 to 400 µM
(Fig.
4B). Concurrently with the drop in NH
4+
and with the exponential-growth phase of the plants, the
CH
4 concentration in the root compartment decreased to 50 µM. Up to
day 44, the availability of CH
4 in the root
compartment was lower
than that in the nonroot compartment. This
difference disappeared
after 53 days, when concentrations between 150 and 300 µM were
reached. CH
4 concentrations even tended
to become higher in the
rhizosphere 75 days after
transplanting.
(ii) Potential CH4 and NH4+
oxidation rates.
CH4 oxidation in slurries from the
root compartment started after a lag of 10 h, while it took
30 h before CH4 was consumed in the assay from the
nonroot compartment. Potential activities were calculated from the
linear decrease of CH4 following the lag phase. Potential
CH4 oxidation in the rhizosphere was significantly higher
than that in the nonroot compartment (Table
1). Potential activities associated with
the rice plant roots reached a level of 3.68 ± 0.34 µmol of
CH4 · g of dry root1 · h1. Numbers of methanotrophs determined by MPN were 15 times higher in the root compartment (3.98 × 106 ± 1.96 × 106) than in the nonroot compartment
(0.26 × 106 ± 0.06 × 106) and
differed significantly (P < 0.05; n = 4; t test).
No stimulating effect of rice plants on NH4+
oxidation rates was observed (Table 1). The nitrification rates in root
and nonroot compartments did not differ, and nitrification activity
associated with rice plant roots was not detected (data not shown). The
nitrogen conversion rates in the rhizosphere per gram of dry soil were
3 orders of magnitude lower than the carbon conversion rates of
methanotrophs.
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TABLE 1.
Potential CH4 and
NH4+ oxidation rates and the contribution of
methanotrophs to nitrification in soil slurries from the root and
nonroot compartments of rice microcosms
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(iii) Contribution of methanotrophs and nitrifiers to
CH4 and NH4+ oxidation.
The
results of the CEA are displayed in Fig.
5. When CH4 was added to the
assay flasks, the oxidation of NH4+ was
stimulated and mirrored the CH4 depletion curves for both the root (Fig. 5A and B) and nonroot compartments (Fig. 5D and E). In
parallel assays with CH3F, the NH4+
oxidation rates were lower than those in the control (Table 1; Fig. 5C
and F). No CH4 was consumed in these flasks. From these data the contribution of methanotrophs to nitrification was calculated by assuming that the rate in the presence of CH3F was the
result of nitrifier activity exclusively (Table 1). When no
CH4 was added, methanotrophs contributed about 50% to
NH4+ oxidation; when CH4 was
present, their contributions were 85 and 62% in the root and nonroot
compartments, respectively.
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FIG. 5.
CEAs using CH3F applied to
NH4+ (2 mM)-supplemented slurries from the root
(A through C) and nonroot (D through F) compartments of four
compartmented microcosms planted with rice plants. The scatter diagram
depicts the assay values of all four microcosms. (A and D)
NH4+ oxidation in the absence of
CH4 and CH3F, putatively caused by the
activities of both methanotrophs and nitrifiers. (B and E) Oxidation of
CH4 (solid circles) and NH4+ (open
circles) in the presence of CH4 (10,000 ppmv), putatively
caused by both methanotrophs and nitrifiers. (C and F) Oxidation of
CH4 (solid circles) and NH4+ (open
circles) in the presence of CH4 (10,000 ppmv) and
CH3F (300 ppmv), putatively allowing for activity of
nitrifiers only. The respective conversion rates are displayed in Table
1.
|
|
The DRA allows the measurement of CH
4 and
NH
4+ oxidation exclusively associated with
methanotrophs in the 48-h period after
the removal of
C
2H
2 (see Fig.
3B). In this period
methanotrophic
nitrification in slurries from rhizosphere soil started
immediately
after CH
4 oxidation had recovered (Fig.
6B). Recovery took place
only when the
inhibitor was added after the lag phase of the methanotrophs.
When
C
2H
2 was added at the start of the assay, no
recovery, and
hence no CH
4 or NH
4+
oxidation, took place (Fig.
6A) during the incubation period
of 90 h.
View larger version (30K):
[in this window]
[in a new window]
|
FIG. 6.
Differential recovery of CH4 (solid symbols;
left axis) and NH4+ (open symbols; right axis)
oxidation after 24-h exposure to C2H2 applied
to slurries from the root compartments of four replicate microcosms
planted with rice plants. (A) C2H2 was added at
the start of the incubation period. (B) C2H2
was added 24 h after the start of the incubation period.
|
|
| |
DISCUSSION |
Evaluation of inhibitor-based discrimination.
Despite the
ecological and biogeochemical impacts of methane and ammonia oxidation,
especially in agricultural and other wetland soils, the knowledge about
both processes and the organisms involved is still far from sufficient.
The contributions of methanotrophs to nitrification and of nitrifiers
to methane oxidation in these systems have never been assessed
properly. To address this matter in various ecosystems, the main
approach up to now was to find possible discriminating substances
(5). Inhibitors like methylfluoride and dimethylether
(37), allylthiourea, dicyandiamide, and allylsulfide (40), monoterpenes (1), and difluoromethane
(33) were evaluated. Of all these substances, only picolinic
acid and allylsulfide seemed to have a potential for discrimination. We
therefore evaluated picolinic acid in our rice plant soil. However, our
results were in contrast to those of Megraw and Knowles
(32), who found nitrifiers to be less sensitive for this
compound. In the rice plant soil, methane and ammonia oxidation were
equally sensitive to picolinic acid, with complete inhibition at 100 µM. The contrasting results can be explained only by assuming the
presence of more-sensitive bacteria in the rice plant soils or of
physicochemical soil parameters which make picolinic acid more
effective. Our results suggest that this inhibitor should be
reevaluated for every soil type and situation. When using picolinic
acid, one should also consider the time course of the experiments,
since inhibition with concentrations of <1 mM did not last for more
than 20 h, demonstrating the rapid degradation of this compound.
However, as much as 10 mM picolinic acid did not affect methanogenesis
(unpublished data), demonstrating the potential for use of this
compound in flux studies where CH4 oxidation has to be
eliminated without affecting methanogenesis. We did not test
allylsulfide, which is apparently less inhibitory to methanotrophs than
to nitrifiers (40), because 100% discrimination was not
possible. Moreover, this compound is insoluble in water, which poses
practical problems for its application in field and microcosm studies.
We looked for other options, mainly based on temporary inactivation of
one or both groups of bacteria. The CEA is based on
the competitive
nature of the inhibition by CH
3F, which was clearly
affirmed by the immediate recovery after removal (Fig.
3A). The
inherently different substrate concentrations in potential methane
(10 µM CH
4) and NH
4+ (1 to 5 mM
NH
4+) oxidation assays allow for selective
inactivation of methanotrophs
with the same inhibitor concentration.
The advantage of this technique
is that it is only concentration
dependent and will thus work
with different methanotrophic and
nitrifying species as well as
with samples from any environment. It
will also work with other
competitive inhibitors, for instance,
difluoromethane (
33).
However, one has to take care that the
CH
3F concentration is high
enough to be effective during
the entire assay period, because
CH
3F can be oxidized by
both methanotrophs (
37) and nitrifiers
(
24). From
our experiments with rice plant soil it could be
concluded that
CH
3F did not inhibit methane oxidation at a
CH
4/CH
3F
molar ratio of <2:1 (data not shown).
With ammonia oxidizers an
18:1 ratio of NH
4+ to
CH
3F did not inhibit ammonia oxidation at all, while a
ratio
of <2:1 inhibited it 95% (Fig.
2B). A disadvantage of the CEA
is that it will be difficult to apply in situ, because the
concentrations
of NH
4+ and CH
4 need
to be
manipulated.
Our second discriminating approach was based on the ability of recovery
after a discrete exposure to C
2H
2, analogous to
the
method described by Kester et al. (
28). These authors
observed
recovery of denitrifiers in soil and sediment slurries within
1 day after a 24-h exposure to 1,000 ppmv of
C
2H
2, while nitrification
activity resumed
after 6 days. We observed the same phenomenon
for methanotrophs and
nitrifiers, enabling discrimination of the
two groups in our rice plant
soil. However, because C
2H
2 is a
suicide
substrate for both nitrifiers (
25) and methanotrophs
(
38), recovery will require de novo enzyme synthesis
(
23).
This implies that the physiological status of the
bacteria at
the moment of the assay is decisive for the recovery. From
a theoretical
point of view it can be argued that methanotrophs will
have more
"reserves" for a swift recovery than the
chemolithoautotrophic
ammonia oxidizers, which spent 80% of the energy
generated from
the oxidation of NH
4+ on the
fixation and incorporation of CO
2 (
46). This
seems to
hold true for our rice plant soils, where the methanotrophs
recovered
very fast and reached the same activity as that prior to
inhibition.
However, the facts that NH
4+
oxidation in soil from barley fields recovered within 24 h after
a
15-h exposure to 100 ppmv of C
2H
2
(
11) and that methane oxidation
did not recover in soil
after inhibition with C
2H
2 (
33)
indicate
that the DRA is certainly no routine assay and has to be
evaluated
for every situation. The study of Bollmann and Conrad
(
11) points
to a better physiological status of the ammonia
oxidizers in their
oxic agricultural soils, explaining the relatively
swift recovery.
In the study of Miller et al. (
33),
methanotrophs did not recover
because the C
2H
2
was applied at the start of the assay, when,
according to the controls,
the methanotrophs were still in a lag
phase. We observed the same
phenomenon (Fig.
6). When C
2H
2 was
added after
CH
4 oxidation was induced, recovery took place. Apparently
the presence of C
2H
2 prior to the induction of
enzyme synthesis
leads to permanent inactivation. Taking into account
that C
2H
2 irreversibly inhibits the amount of
MMO that has already been
expressed, the lack of recovery must be due
to a block of the
initiation of de novo enzyme synthesis. This blockage
is relieved
when the cells metabolize CH
4 prior to
inhibition of the MMO.
Apparently, the amount of energy synthesized
during this initial
oxidation is essential for triggering enzyme
synthesis after the
inhibitor is removed. Another possible explanation
may be found
in a direct link of the active MMO to the enzyme
transcriptional
level of enzymes downstream in the CH
4
oxidizing
pathway.
CH4 and NH4+ oxidation by
methanotrophs and nitrifiers in the rhizospheres of rice plants.
It is clear that methanotrophs were able to profit from the oxygen
release from the rice plants, as reflected by the potential activities
and numbers. Gilbert and Frenzel (21) demonstrated the same
effect, using a similar compartmented-microcosm approach, with
activities and numbers in the same range. Methane oxidation rates
associated with our rice plant roots were also in the same order of
magnitude as those found with other rice plants (12, 21) and
a range of other wetland plants (29). The CH4
availability in the porewater was also comparable to that in artificial
rice systems (20, 21), natural rice paddies (35),
and natural wetlands (44) and was high enough to give the
methanotrophs the opportunity to profit from the oxygen derived from
the plants. This was obviously not the case for the nitrifiers. Due to
methodological problems, we were not able to assess the number of
nitrifiers in our microcosms. However, in comparable microcosms there
was no difference in MPN numbers of ammonia oxidizers in rhizospheres and bulk rice plant soils (4). The nitrification potentials in the rhizospheres and in the bulk soils of our microcosms were at
very low levels. It is very likely that, just as in some other studies
(3, 8, 10, 17), the ammonia oxidizers are outcompeted for
NH4+ by the plants. Indeed,
NH4+ availability in the rhizosphere in our
experiment was low despite the frequent fertilization. Low
NH4+ concentrations are common in the
rhizospheres of rice plants (21) and other wetland plants
(8, 10, 44). A stimulation of nitrate production in the
rhizospheres of rice plants was only indirectly demonstrated after
fertilization by analysis of denitrification products (see, e.g.,
references 3 and 39). However,
taking our results with the CEA and DRA into account, one can argue
about which bacteria are responsible for nitrification in the
rhizosphere. We clearly demonstrated that, at least potentially,
methanotrophs could be responsible for the nitrification in the rice
plant rhizosphere. So far, methanotrophic nitrification in soil was
reported only for humisol slurries and subsequent enrichment cultures
(31, 32). However, these slurries were enriched for
methanotrophs first by incubation with 20% CH4, thereby
making reference to the in situ situation difficult. Moreover,
discrimination between methane- and ammonia-oxidizing bacteria was
assessed by using picolinic acid, which apparently is not always 100%
discriminatory. The methanotrophic nitrification in our study was
measured in the first 24 h after harvesting of the microcosm by
using an assay which discriminates 100%, thus improving the
credibility of extrapolations to the in situ situation.
It is very unlikely that ammonia oxidizers contribute significantly to
CH
4 oxidation in our microcosms. From a theoretical
point
of view, taking the kinetic properties of CH
4 oxidation
by
pure cultures of ammonia oxidizers and the low nitrification
potential
in the microcosms into account, a prominent role of
nitrifiers in
methane oxidation in our rice plant soil is highly
unlikely.
Additionally, the CH
4 oxidation rates after recovery
of
inhibition with C
2H
2 should be lower than the
rates prior to
inhibition if nitrifiers play a significant role in
CH
4 oxidation.
The rates during the first 48 h after
recovery, due exclusively
to methanotrophs, were not different from the
rates before inhibition,
which theoretically could have been the result
of both nitrifiers
and methanotrophs. The only report so far on
involvement in methane
oxidation of nitrifiers in natural systems
originates from fertilized
forest soils (
43). Steudler et
al. (
43) used the inhibitor-sensitive
14CH
4/
14CO oxidation ratio as a
criterion for methane oxidation dominated
by methanotrophs (ratio of
>0.05) or nitrifiers (ratio of <0.05).
However, these ratios are
based on pure culture studies and are
thus also indirect evidence.
Hence, measuring the nitrifier methane
oxidation in natural systems is
still a
challenge.
Conclusions.
This study presents new methods for discerning
the interactions and overlap of C and N cycling processes, in which
different but functionally highly similar bacterial groups are
involved. The CEA and DRA are applicable to soil slurries, but similar
approaches may be useful for assessing the contributions of
methanotrophs and nitrifiers to CH4 and
NH4+ turnover in situ. For the rice plant
rhizosphere system, however, we can conclude that methanotrophs have
the potential to contribute substantially to nitrification, while
nitrifiers are probably of little importance for methane oxidation.
| |
ACKNOWLEDGMENTS |
We thank Ralf Conrad and Peter Dunfield for the critical reading
of the manuscript and Alexandra Runkel and Markus Drescher for their
technical assistance. We also appreciate the cooperation of the Centre
for Terrestrial Ecology of the Netherlands Institute of Ecology with
regard to the autoanalyzer analysis.
This project was financially supported by the EU, project BIO 4 CT
960419, and the DFG, project Fr 1054/1.
| |
FOOTNOTES |
*
Corresponding author. Mailing address:
Max-Planck-Institut für terrestrische Mikrobiologie,
Karl-von-Frischstrasse, D-35043, Marburg, Germany. Phone: 49 6421 178821. Fax: 49 6421 178809. E-mail:
bodelier{at}mailer.uni-marburg.de.
| |
REFERENCES |
| 1.
|
Amaral, J. A.,
A. Ekins,
S. R. Richards, and R. Knowles.
1998.
Effect of selected monoterpenes on methane oxidation, denitrification, and aerobic metabolism by bacteria in pure culture.
Appl. Environ. Microbiol.
64:520-525[Abstract/Free Full Text].
|
| 2.
|
Armstrong, W.,
R. Brändle, and M. B. Jackson.
1994.
Mechanisms of flood tolerance in plants.
Acta Bot. Neerl.
43:307-358.
|
| 3.
|
Arth, I.,
P. Frenzel, and R. Conrad.
1998.
Denitrification coupled to nitrification in the rhizosphere of rice.
Soil Biol. Biochem.
30:509-515.
|
| 4.
| Arth, I. 1998. Personal communication.
|
| 5.
|
Bèdard, C., and R. Knowles.
1989.
Physiology, biochemistry, and specific inhibitors of CH4, NH4+, and CO oxidation by methanotrophs and nitrifiers.
Microbiol. Rev.
53:68-84[Abstract/Free Full Text].
|
| 6.
|
Bèdard, C., and R. Knowles.
1997.
Some properties of methane oxidation in a thermally stratified lake.
Can. J. Fish. Aquat. Sci.
54:1639-1645.
|
| 7.
|
Blom, C. W. P. M., and L. A. C. J. Voesenek.
1996.
Flooding: the survival strategies of plants.
TREE
11:290-295.
|
| 8.
|
Bodelier, P. L. E.,
H. Duyts,
C. W. P. M. Blom, and H. J. Laanbroek.
1998.
Interactions between nitrifying and denitrifying bacteria in gnotobiotic microcosms planted with the emergent macrophyte Glyceria maxima.
FEMS Microbiol. Ecol.
25:63-78.
|
| 9.
|
Bodelier, P. L. E.,
A. G. Wijlhuizen,
C. W. P. M. Blom, and H. J. Laanbroek.
1997.
Effects of photoperiod on growth of and denitrification by Pseudomonas chlororaphis in the root zone of Glyceria maxima, studied in a gnotobiotic microcosm.
Plant Soil
190:91-103.
|
| 10.
|
Bodelier, P. L. E.,
J. A. Libochant,
C. W. P. M. Blom, and H. J. Laanbroek.
1996.
Dynamics of nitrification and denitrification in root-oxygenated sediments and adaptation of ammonia-oxidizing bacteria to low-oxygen or anoxic habitats.
Appl. Environ. Microbiol.
62:4100-4107[Abstract].
|
| 11.
|
Bollmann, A., and R. Conrad.
1997.
Recovery of nitrification and production of NO and N2O after exposure of soil to acetylene.
Biol. Fertil. Soils
25:41-46.
|
| 12.
|
Bosse, U., and P. Frenzel.
1997.
Activity and distribution of methane-oxidizing bacteria in flooded rice soil microcosms and in rice plants (Oryza sativa).
Appl. Environ. Microbiol.
63:1199-1207[Abstract].
|
| 13.
|
Bosse, U., and P. Frenzel.
1998.
Methane emissions from rice microcosms: the balance of production, accumulation and oxidation.
Biogeochemistry
41:199-214.
|
| 14.
|
Conrad, R.
1996.
Soil microorganisms as controllers of atmospheric trace gases (H2, CO, CH4, OCS, N2O, and NO).
Microbiol. Rev.
60:609-640[Abstract/Free Full Text].
|
| 15.
|
Denier van der Gon, H. A. C., and H. U. Neue.
1996.
Oxidation of methane in the rhizosphere of rice plants.
Biol. Fertil. Soils
22:359-366.
|
| 16.
|
Elsevier Science bv.
1976.
L'air liquide.
In
Encyclopedie des Gaz. Elsevier Science bv, Amsterdam, The Netherlands.
|
| 17.
|
Engelaar, W. H. M. G.,
P. L. E. Bodelier,
H. J. Laanbroek, and C. W. P. M. Blom.
1991.
Nitrification in the rhizosphere of a flooding-resistant and a flooding-non-resistant Rumex species under drained and waterlogged conditions.
FEMS Microbiol. Ecol.
86:33-42.
|
| 18.
|
Engelaar, W. M. H. G.,
J. C. Symens,
H. J. Laanbroek, and C. W. P. M. Blom.
1995.
Preservation of nitrifying capacity and nitrate availability in waterlogged soils by radial oxygen loss from roots of wetland plants.
Biol. Fertil. Soils
20:243-248.
|
| 19.
|
Frenzel, P., and U. Bosse.
1996.
Methyl fluoride, an inhibitor of methane oxidation and methane production.
FEMS Microbiol. Ecol.
21:25-36.
|
| 20.
|
Gilbert, B., and P. Frenzel.
1995.
Methanotrophic bacteria in the rhizosphere of rice microcosms and their effect on porewater methane concentration and methane emission.
Biol. Fertil. Soils
20:93-100.
|
| 21.
|
Gilbert, B., and P. Frenzel.
1998.
Rice roots and CH4 oxidation: the activity of bacteria, their distribution and the microenvironment.
Soil Biol. Biochem.
30:1903-1916.
|
| 22.
|
Hyman, M. R., and D. J. Arp.
1987.
Quantification and removal of some contaminating gases from acetylene used to study gas-utilizing enzymes and microorganisms.
Appl. Environ. Microbiol.
53:298-303[Abstract/Free Full Text].
|
| 23.
|
Hyman, M. R., and D. J. Arp.
1992.
14C2H2- and 14CO2-labelling studies of the de novo synthesis of polypeptides by Nitrosomonas europaea during recovery from acetylene and light inactivation of ammonia monooxygenase.
J. Biol. Chem.
267:1534-1545[Abstract/Free Full Text].
|
| 24.
|
Hyman, M. R.,
C. L. Page, and D. J. Arp.
1994.
Oxidation of methylfluoride and dimethyl ether by ammonia monooxygenase in Nitrosomonas europaea.
Appl. Environ. Microbiol.
60:3033-3035[Abstract/Free Full Text].
|
| 25.
|
Hyman, M. R., and P. M. Wood.
1985.
Suicidal inactivation and labelling of ammonia monooxygenase by acetylene.
Biochem. J.
227:719-725[Medline].
|
| 26.
|
Jones, R. D., and R. Y. Morita.
1983.
Methane oxidation by Nitrosococcus oceanus and Nitrosomonas europaea.
Appl. Environ. Microbiol.
45:401-410[Abstract/Free Full Text].
|
| 27.
|
Jones, R. D.,
R. Y. Morita, and R. P. Griffiths.
1984.
Method for estimating in situ chemolithotrophic ammonium oxidation using carbon monoxide oxidation.
Mar. Ecol. Prog. Ser.
17:259-269.
|
| 28.
|
Kester, R. A.,
W. de Boer, and H. J. Laanbroek.
1996.
Short exposure to acetylene to distinguish between nitrifier and denitrifier nitrous oxide production in soil and sediment samples.
FEMS Microbiol. Ecol.
20:111-120.
|
| 29.
|
King, G. M.
1994.
Associations of methanotrophs with the roots and rhizomes of aquatic vegetation.
Appl. Environ. Microbiol.
60:3220-3227[Abstract/Free Full Text].
|
| 30.
|
King, G. M.
1996.
In situ analysis of methane oxidation associated with the roots and rhizomes of a bur reed, Sparganium eurycarpum, in a Maine wetland.
Appl. Environ. Microbiol.
62:4548-4555[Abstract].
|
| 31.
|
Megraw, S. R., and R. Knowles.
1989.
Methane-dependent nitrate production by a microbial consortium enriched from a cultivated humisol.
FEMS Microbiol. Ecol.
62:359-366.
|
| 32.
|
Megraw, S. R., and R. Knowles.
1990.
Effect of picolinic acid (2-pyridine carboxylic acid) on the oxidation of methane and ammonia in soil and in liquid culture.
Soil Biol. Biochem.
22:635-641.
|
| 33.
|
Miller, L. G.,
C. Sasson, and R. S. Oremland.
1998.
Difluoromethane, a new improved inhibitor of methanotrophy.
Appl. Environ. Microbiol.
64:4357-4362[Abstract/Free Full Text].
|
| 34.
|
Neue, H. U.
1997.
Fluxes of methane from rice fields and potential for mitigation.
Soil Use Manag.
13:258-267.
|
| 35.
|
Nouchi, I.,
T. Hosono,
K. Aoki, and K. Minami.
1994.
Seasonal variation in methane flux from rice paddies associated with methane concentration in soil water, rice biomass and temperature, and its modelling.
Plant Soil
161:195-208.
|
| 36.
|
O'Neill, J. G., and J. F. Wilkinson.
1977.
Oxidation of ammonia by methane-oxidizing bacteria and the effects of ammonia on methane oxidation.
J. Gen. Microbiol.
100:407-412.
|
| 37.
|
Oremland, R. S., and C. W. Culbertson.
1992.
Evaluation of methylfluoride and dimethylether as inhibitors of aerobic methane oxidation.
Appl. Environ. Microbiol.
58:2983-2992[Abstract/Free Full Text].
|
| 38.
|
Prior, S. D., and H. Dalton.
1985.
Acetylene as a suicide substrate and active site probe for methane monooxygenase from Methylococcus capsulatus (Bath).
FEMS Microbiol. Lett.
29:105-109.
|
| 39.
|
Reddy, K. R.,
W. H. Patrick, Jr., and C. W. Lindau.
1989.
Nitrification-denitrification at the plant root-sediment interface in wetlands.
Limnol. Oceanogr.
34:1004-1013.
|
| 40.
|
Roy, R., and R. Knowles.
1995.
Differential inhibition by allylsulfide of nitrification and methane oxidation in freshwater sediment.
Appl. Environ. Microbiol.
61:4278-4283[Abstract].
|
| 41.
|
Schipper, L. A., and K. R. Reddy.
1996.
Determination of methane oxidation in the rhizosphere of Sagittaria lancifolia using methyl fluoride.
Soil Sci. Soc. Am. J.
60:611-616.
[Abstract/Free Full Text] |
| 42.
|
Schütz, H.,
A. Holzapfel-Pschorn,
R. Conrad,
H. Rennenberg, and W. Seiler.
1989.
A 3-year continuous record on the influence of daytime, season, and fertilizer treatment on methane emission rates from an Italian rice paddy.
J. Geophys. Res.
94:16405-16416.
|
| 43.
|
Steudler, P. A.,
R. D. Jones,
M. S. Castro,
J. M. Mellilo, and D. L. Lewis.
1996.
Microbial controls of methane oxidation in temperate forest and agricultural soils.
NATO ASI Ser. Ser. I
39:69-84.
|
| 44.
|
Van der Nat, F. J. W. A.,
J. J. Middelburg,
D. van Meteren, and A. Wielemakers.
1998.
Diel methane emission patterns from Scirpus lacustris and Phragmites australis.
Biogeochemistry
42:1-22.
|
| 45.
|
Ward, B. B.
1987.
Kinetic studies on ammonia and methane oxidation by Nitrosococcus oceanus.
Arch. Microbiol.
147:126-133.
|
| 46.
|
Wood, P. M.
1986.
Nitrification as bacterial energy source.
Spec. Publ. Soc. Gen. Microbiol.
20:39-61.
|
| 47.
|
Yoshinari, T.
1984.
Nitrite and nitrous oxide production by Methylosinus trichosporium.
Can. J. Microbiol.
31:139-144.
|
Applied and Environmental Microbiology, May 1999, p. 1826-1833, Vol. 65, No. 5
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Top
Abstract
Introduction
