Previous Article | Next Article 
Applied and Environmental Microbiology, November 1999, p. 5075-5081, Vol. 65, No. 11
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Metabolism of Acrylate to 
-Hydroxypropionate and
Its Role in Dimethylsulfoniopropionate Lyase Induction by a Salt Marsh
Sediment Bacterium, Alcaligenes faecalis M3A
John H.
Ansede,1
Perry J.
Pellechia,2 and
Duane C.
Yoch1,*
Department of Biological
Sciences1 and Department of Chemistry
and Biochemistry,2 University of South Carolina,
Columbia, South Carolina 29208
Received 2 July 1999/Accepted 31 August 1999
 |
ABSTRACT |
Dimethylsulfoniopropionate (DMSP) is degraded to dimethylsulfide
(DMS) and acrylate by the enzyme DMSP lyase. DMS or acrylate can serve
as a carbon source for both free-living and endophytic bacteria in the
marine environment. In this study, we report on the mechanism of
DMSP-acrylate metabolism by Alcaligenes faecalis M3A.
Suspensions of citrate-grown cells expressed a low level of DMSP lyase
activity that could be induced to much higher levels in the presence of
DMSP, acrylate, and its metabolic product, 
-hydroxypropionate. DMSP
was degraded outside the cell, resulting in an extracellular
accumulation of acrylate, which in suspensions of citrate-grown cells
was then metabolized at a low endogenous rate. The inducible nature of
acrylate metabolism was evidenced by both an increase in the rate of
its degradation over time and the ability of acrylate-grown cells to
metabolize this molecule at about an eight times higher rate than
citrate-grown cells. Therefore, acrylate induces both its production
(from DMSP) and its degradation by an acrylase enzyme. 1H
and 13C nuclear magnetic resonance analyses were used to
identify the products resulting from [1-13C]acrylate
metabolism. The results indicated that A. faecalis first
metabolized acrylate to -hydroxypropionate outside the cell, which
was followed by its intracellular accumulation and subsequent induction
of DMSP lyase activity. In summary, the mechanism of DMSP degradation
to acrylate and the subsequent degradation of acrylate to
-hydroxypropionate in the aerobic -Proteobacterium A. faecalis has been described.
| |
INTRODUCTION |
Dimethylsulfide (DMS), a potential
antigreenhouse gas, accounts for as much as 90% of all marine biogenic
sulfur emissions to the atmosphere (1) and may play an
important role in marine cloud formation and climate regulation
(6, 7, 10, 29, 32). The major precursor of DMS,
dimethylsulfoniopropionate (DMSP), is an abundant sulfonium compound in
marine environments (35, 36) and has been identified in
microbial mats, macroalgae, marine phytoplankton, phototrophic
prokaryotes, and higher plants, including the salt marsh cordgrass
Spartina alterniflora (9, 12, 23, 33, 35, 46).
DMSP appears to function as a compatible solute for osmoregulation in
marine algae (19, 20, 41) and may also have a similar
function in other marine organisms. During the senescence and decay of
phytoplankton and cordgrass (30, 38) and during zooplankton
grazing on phytoplankton (13, 47), DMSP is released into the
water column or sediment where it can be degraded by the endophytic or
free-living microbial population (13, 26, 44). The dominant
pathway of DMS production in saline environments is through the
enzymatic cleavage of DMSP to DMS and acrylate by the enzyme DMSP
lyase:
(CH3)2S+CH2CH2COO
(CH3)2S + H2C==CHCOO + H+ (8,
11, 15, 22). DMSP lyase has been purified from several microbial
isolates from the marine environment (15, 18, 42) and
macroalgal species (17, 31) and was detected in species of
smooth cordgrass ascomycetes (4). Both products of the lyase reaction have been identified as potential carbon and energy sources for marine bacteria (25, 40, 44).
The process of acrylate metabolism in marine environments has not been
studied to the extent of its precursor, DMSP. In the anaerobic marine
isolate Desulfovibrio acrylicus, acrylate generated from
DMSP cleavage during growth on lactate was used as an electron acceptor
resulting in propionate production (43). Alternatively, Clostridium propionicum isolated from freshwater sediments
cleaved DMSP with the resulting acrylate being fermented to propionate and acetate (45). Anoxic marine sediment slurries amended
with acrylate metabolized it to acetate and propionate, which were then
further degraded (25). Molybdate did not inhibit acrylate metabolism in these sediments, but it did inhibit the disappearance of
acetate and propionate, suggesting the involvement of sulfate-reducing bacteria (25).
We recently identified two distinct patterns of DMSP metabolism among
the aerobic marine isolates Pseudomonas doudoroffii and
Alcaligenes faecalis M3A (49). Although the
lyases from these two bacteria displayed similarities in their in vitro
Km for DMSP, mass, and N-terminal amino acid
sequence (16, 18), the mechanism of DMSP uptake and DMSP
lyase induction and location were found to be very different (18,
49). Acrylate served as the inducer of DMSP lyase in A. faecalis, but the metabolic fate of the acrylate resulting from
DMSP cleavage has not been determined in aerobic bacteria. In this
study, we report the mechanism of DMSP-acrylate metabolism and DMSP
lyase induction in A. faecalis M3A and have identified an
intermediate, -hydroxypropionate, which plays an important role in
this process.
| |
MATERIALS AND METHODS |
Strain identification.
The estuarine isolate used in this
study was previously identified as an Alcaligenes-like
species designated strain M3A by deSouza and Yoch (15).
Fatty acid analysis, determined by using the MIDI program, and 16S rDNA
analysis positively identified strain M3A as belonging to A. faecalis (48).
Culturing and cell suspensions.
A. faecalis M3A was
grown in 100-ml batch cultures of a basal salt medium containing 40 mM
NaCl, 5 mM (NH4)2SO4, 0.8 mM
MgSO4, 0.3 mM CaCl2, 89 µM Fe EDTA and the
following per liter: 1 ml of Ho-Le trace elements solution
(21) and 1 ml of Balch's vitamin solution (5).
The medium was supplemented with either citrate or acrylate (5 mM) as
the carbon and energy source, adjusted to pH 6.4, and autoclaved. After
cooling, the medium was buffered with 10 mM potassium phosphate from a
1 M stock (pH 6.8) to give a final pH of 7.2. After 18 h of
growth, cell suspensions were prepared by centrifuging the culture
(17,400 × g for 30 s) and resuspending the pellet
in the original volume of 50 mM phosphate buffer (pH 7.45).
Acrylate-grown cells were resuspended in half the original volume to
compensate for the lower cell yield per mole of substrate than that of
citrate-grown cells. The cell suspensions used in these experiments had
A600s of ca. 0.52 and 0.26 and protein concentrations of 0.068 and 0.037 mg · ml1 for
citrate- and acrylate-grown cells, respectively.
DMSP and acrylate metabolism.
Cell suspensions (12-ml
aliquots in 36-ml glass serum bottles) to which DMSP or acrylate had
been added were incubated on an orbital shaker at 100 rpm at ambient
temperature. DMSP and acrylate metabolism were measured by acrylate
production (from DMSP) and acrylate disappearance from the media,
respectively. Acrylate was analyzed by removing 1-ml aliquots from the
cell suspension and pelleting the cells by centrifugation (2 min). The
supernatant (top 800 µl) was immediately frozen on dry ice and stored
at 
70°C for later high-pressure liquid chromatography (HPLC)
analysis (see below). In parallel cell suspensions, DMS production from
DMSP (resulting from DMSP lyase activity) was measured in 1-ml aliquots
of cell suspensions in 14.5-ml serum bottles that were capped with
Teflon-lined butyl rubber stoppers and crimped with aluminum caps. The
headspace gases were analyzed for DMS by gas chromatography
(15). To test the effects of the protein synthesis
inhibitor, gentamicin (200 µg · ml1) on DMSP,
and acrylate catabolism, the inhibitor was added 30 min prior to the
addition of the substrate.
To test DMSP, acrylate, and -hydroxypropionate as inducers of DMSP
lyase, cells were cultured on tryptic soy broth, harvested, resuspended
in phosphate buffer (as above), and placed in 14.5-ml bottles (4-ml
aliquots). The putative inducers were added over a concentration range
of 1 µM to 10 mM. DMSP lyase activity was then tested at 6, 12, and
24 h after the inducers were added by removing 1-ml aliquots,
pelleting the cells in a microcentrifuge for 30 s, and
resuspending the pellet in phosphate buffer along with excess substrate
(2.5 mM DMSP). The rate of DMS production by the cells removed at each
time point was assumed to be proportional to the extent of DMSP lyase
induction. Data presented in the Results section are representative of
at least two replicate experiments.
HPLC analysis.
Supernatants of cell suspensions for HPLC
analysis that had been stored at 70°C were thawed, centrifuged for
2 min, and diluted 1:5 with HPLC buffer (2.5% acetonitrile, 0.2%
phosphoric acid in double-distilled H2O). Aliquots (150 µl) were analyzed by using a Beckman isocratic liquid chromatograph
(model 330) equipped with a Waters µ Bondapack C18 column
(3.9 by 300 mm) (Millipore) which was operated at a flow rate of 0.8 ml · min1. Retention times of acrylate and
methylmercaptopropionic acid (MMPA), monitored at 214 nm, were 5.30 and
9.10 min, respectively. Acrylate concentrations were determined from
standard curves constructed with known concentrations and diluted 1:5,
similar to the unknowns. DMSP, propionate, and -hydroxypropionate
could not be identified by using these HPLC parameters and this
detection system.
Purification of endogenous DMSP lyase.
A. faecalis was
grown in 5 mM citrate-basal salt medium (10 2-liter batch cultures) on
a rotary shaker (100 rpm) at 30°C. The purification steps were the
same as those used for the inducible lyase in this organism
(15).
Western blot analysis.
Western blots were used to compare
the sizes of DMSP lyase purified from either A. faecalis
citrate-grown (i.e., endogenous lyase) or A. faecalis
acrylate-grown (i.e., induced lyase) cells. A polyclonal DMSP lyase
antiserum was raised against a protein shown to be pure by sodium
dodecyl sulfate-polyacrylamide gel electrophoresis and N-terminal amino
acid sequencing (16, 18). Samples were subjected to sodium
dodecyl sulfate-12% polyacrylamide gel electrophoresis followed by
Western blot analysis as described by Sambrook et al. (37).
13C NMR determination of acrylate metabolites.
Three 1-liter cultures of 24-h acrylate-grown cells
(A600 
0.26) were harvested by
centrifugation, resuspended in 80 ml of 50 mM phosphate buffer, and
placed in a 250-ml Erlenmeyer flask and used for 13C
nuclear magnetic resonance (NMR) analysis of acrylate metabolites. Cells were preincubated for 15 min at 100 rpm on a rotary shaker at
ambient temperature followed by the addition of 5 mM
[1-13C]acrylic acid (Cambridge Isotope Laboratories,
Andover, Mass.) from a 150 mM stock solution (pH 7). Cell aliquots (10 ml) were removed at intervals between 10 and 120 min, placed in 10 ml
of ice-cold phosphate buffer, and then centrifuged at 17,400 × g for 30 s. The supernatant (extracellular medium) was
decanted, frozen on dry ice, and stored at 70°C; these samples were
thawed and diluted 1:1 in D2O prior to 1H and
13C NMR analysis. The pellet which contained the
intracellular 13C metabolites was washed with 1 ml of
ice-cold buffer and then extracted twice for 16 h in 1.5 ml of
95% ethanol at ambient temperatures. The combined ethanol extracts
which contained the low Mr organic pool were
dried in a rotary evaporator, and the residue was solubilized in 1 ml
of D2O and analyzed by NMR.
NMR analysis.
NMR data on acrylate and its metabolic
product(s) were collected on a Varian Unity Inova 500. The
1H (500.16 MHz) spectra of the extracellular medium
(supernatant) required presaturation of the dominant water resonance.
Data were collected by using a 7-kHz window centered on the water
resonance (4.63 ppm); 256 transients were collected by using a 45°
pulse angle, a 3-s acquisition time, and a 4.5-s interpulse delay.
Direct detection of 13C NMR (125.894 MHz) spectra of the
intracellular metabolites was obtained by using a 30-kHz window
centered at 110 ppm. A total of 512 transients were collected by using
a 45° pulse angle, a 1-s acquisition time, and a 2.5-s interpulse
delay. Acetone (10 µl) was added to each sample to provide an
internal reference (C-1 = 214.97 ppm and C-2 = 29.80 ppm). An
indirect detection of 13C spectra was obtained by using the
standard gradient-enhanced heteronuclear multiple quantum coherence
sequence (HMQC). The magnetization transfer delay was set to 50 ms to
optimize detection of spin-spin coupling constants of 10 Hz. This
allowed for the correlation of protons that were two or three bonds
away from the labeled carbon. The 1H dimension was
collected with 1,984 complex points over a 4-kHz window that was
centered on the water resonance (4.63 ppm). The 13C
dimension was collected with 128 free induction decays (fid), over a
120-ppm window that was centered at 160 ppm. Four transients were
collected for each fid, and the equilibrium delay was set to 0.9 s. The 13C dimension was externally referenced with acetone
by using one of the intracellular metabolite samples from the directly
detected experiments. The direct detection of the 13C data
was obtained at ambient temperature, while the 1H spectra
and gradient-enhanced HMQC results were obtained with the sample
temperature regulated at 25°C.
Mass spectroscopy.
Negative ion electrospray mass
spectroscopy was used to confirm the identity of the
[13C]acrylate metabolite(s). Extracellular supernatant
fractions which contained the metabolite were lyophilized to dryness,
and the acetone-soluble, organic constituents were extracted with 5 ml
of deuterated acetone. This mixture was then centrifuged to pellet any
insoluble salts that remained in the acetone extract. To insure this
fraction contained the metabolite(s) of interest, it was first analyzed
by 1H NMR, after which the acetone was volatilized with a
stream of argon. The residue was resuspended in 100% methanol and
analyzed by negative ion electrospray mass spectroscopy as described
previously (3).
Materials.
-Hydroxypropionate (hydracrylic acid; Merck
reference 4660) was either synthesized from -hydroxypropionitrile as
described by Read (34) or purchased from Chem Service (West
Chester, Pa.). All other chemicals or reagents were purchased from
Aldrich Chemical Co. Inc., Milwaukee, Wis.
| |
RESULTS |
DMSP and acrylate catabolism.
DMSP uptake has been shown to
precede its degradation to DMS and acrylate in P. doudoroffii (49) and strain LFR (27), while
in A. faecalis M3A, DMSP cleavage appeared to be an
extracellular process (49). When DMSP (500 µM) was added
to suspensions of citrate-grown cells of strain M3A, there was no lag
prior to the appearance of DMS and acrylate in the extracellular medium
(Fig. 1A). Both products increased in
parallel for the first several hours, with acrylate reaching a maximum
concentration of ca. 300 µM in the extracellular medium at 5 h,
after which it decreased rapidly until it was depleted from the medium
at 9 h. These findings are consistent with DMSP being cleaved
outside the cell by an endogenous low level of DMSP lyase activity,
which was reported earlier (49). These data also show that
acrylate produced during DMSP cleavage first accumulates outside the
cell prior to its metabolism. When acrylate was added to a parallel
cell suspension, there was a low initial rate of acrylate metabolism
followed by a threefold increase in this rate with time (Fig. 1A).
View larger version (20K):
[in this window]
[in a new window]
|
FIG. 1.
Acrylate and DMS production (from DMSP) and acrylate
metabolism in suspensions of citrate-grown (A) and acrylate-grown (B)
cells. DMSP or acrylate (500 µM) was added to cell suspensions of
A. faecalis M3A. Symbols:  , DMS from DMSP cleavage;  ,
acrylate resulting from DMSP cleavage;  , added acrylate.
|
|
When suspensions of acrylate-grown cells were amended with DMSP (500 µM), it was completely degraded to DMS and acrylate within
10 min
(Fig.
1B). Furthermore, the rate of acrylate metabolism
was eight to
nine times higher than that in suspensions of citrate-grown
cells.
Acrylate (from either DMSP cleavage or as an acrylate amendment)
was
metabolized at a linear rate (no lag) and depleted from the
extracellular medium within 70 min. While DMSP lyase in
A. faecalis was known to be induced by growth on acrylate
(
15), these data
(Fig.
1) indicate that an enhanced rate of
acrylate metabolism
(acrylase activity) is also induced by exposure of
the microbe
to this molecule. The kinetics of DMSP lyase and the
acrylate-metabolizing
mechanism are, however, very different, with the
lyase having
an eightfold higher rate than the acrylase activity. Since
HPLC
analysis of the extracellular medium was unable to detect any
metabolites produced as a result of acrylate degradation, the
fate of
the acrylate added to cell suspensions was determined
by
1H
and
13C NMR analyses (see
below).
Acrylate metabolism by
A. faecalis was further examined by
testing the effect of its concentration (50 µM to 1.0 mM) on its
rate
of utilization by suspensions of both citrate- and acrylate-grown
cells. In citrate-grown cells, a lag of ca. 2 h preceded the
metabolism
of acrylate at all concentrations tested (Fig.
2A), while acrylate-grown
cells utilized
this compound with no apparent lag and at a much
higher rate (Fig.
2B).
The rate of acrylate metabolism (disappearance)
at each concentration
tested was similar, suggesting that the
Km for
the acrylase was below 50 µM. Although we could detect
much lower
levels of acrylate, it could not be reproducibly quantitated
below 25 µM, and therefore an accurate
Km could not be
determined.
These observations support the premise stated above that
acrylate
induces the enzyme(s) responsible for its metabolism. Finally,
the inducibility of acrylate metabolism was confirmed by showing
that
the addition of gentamicin to suspensions of citrate-grown
cells
resulted in acrylate being metabolized at a low endogenous
rate,
compared to untreated cells (data not shown).
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 2.
Effect of acrylate concentration on its rate of
metabolism. Kinetics (disappearance from solution) were measured in
suspensions of citrate-grown (A) and acrylate-grown (B) cells. The rate
of acrylate metabolism at a concentration of 2.5 mM was the same as
that at a concentration of 1.0 mM (data not shown).
|
|
MMPA, a DMSP analog that inhibits DMSP lyase activity (
16),
inhibited the metabolism of both acrylate and DMSP by suspensions
of
A. faecalis citrate-grown cells (Fig.
3). MMPA therefore competes
for enzyme
binding sites on the cell surface that are responsible
for both DMSP
and acrylate degradation. The same results were
obtained with
acrylate-grown cells (data not shown). MMPA, as
an inhibitor of
acrylate metabolism (acrylase activity), should
prove to be a useful
tool for the later study of this enzyme.
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 3.
MMPA inhibition of DMSP and acrylate metabolism in
suspensions of citrate-grown cells. MMPA (5 mM) was added to the
suspension 30 min before the addition of the substrates (500 µM).
Symbols: , acrylate;  , acrylate plus MMPA; , acrylate from
DMSP cleavage; , acrylate from DMSP cleavage plus MMPA.
|
|
NMR analysis of [1-13C]acrylate metabolites.
1H and 13C NMR analyses were used to follow the
metabolism of acrylate in A. faecalis M3A. To have a basis
for comparing the acrylate metabolites, an acrylate standard was first
examined by using 1H and 13C NMR. The
gradient-enhanced 1H{13C} HMQC spectrum of
the [1-13C]acrylate standard showed one 13C
resonance (at 175 ppm); this 13C resonance had
1H correlations at 5.55, 5.90, and 6.05 ppm (data not
shown). Due to the low natural abundance of 13C (1.1%), it
was only possible under these conditions to detect the labeled position
(C-1) and protons, two or three bonds removed.
To monitor the time course of acrylate utilization,
[1-
13C]acrylate was added to suspensions of
acrylate-grown cells, and both
the extracellular medium (supernatant)
and intracellular metabolites
(extract from cell pellet) were examined.
The
1H NMR spectrum of each extracellular sample taken over
the 120-min
time course of the experiment is presented in Fig.
4. The first
time point (10 min) showed
resonances centered at 5.55, 5.90,
and 6.05 ppm, indicative of acrylate
protons (see above), and
two new resonances centered at 2.35 and 3.64 ppm. The decrease
in the intensity of the proton resonances of acrylate
over time
corresponded to an increase in the intensity of the
resonances
centered at 2.35 and 3.64 ppm, which reached a maximum
intensity
at 40 min and then decreased rapidly. The
1H NMR
spectrum of the last time point (120 min) showed no peaks
(data not
shown).
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 4.
1H NMR analysis of the extracellular medium
following the addition of [1-13C]acrylate to a
concentrated cell suspension. Samples were taken at the indicated time
intervals; the cells were removed by centrifugation, and the
supernatant was assayed directly. The NMR spectra were acquired by
using the same conditions and number of scans for each sample so that
the peak intensity would represent an approximate concentration of each
metabolite relative to each sample. 1H resonances at 5.55, 5.90, and 6.05 ppm and at 2.35 and 3.64 ppm were identified as those
belonging to acrylate and -hydroxypropionate, respectively.
|
|
To aid in the identification of the unknown metabolite (resonances
centered at 2.35 and 3.64 ppm), a gradient-enhanced
1H{
13C} HMQC spectrum of the extracellular
medium was obtained after
a 40-min exposure of the cell suspension to
[1-
13C]acrylate (Fig.
5).
The spectrum showed two
13C resonances at 175 and 180 ppm
that have correlations to
1H resonances at 5.55, 5.80, and
6.05 ppm and at 2.30 and 3.67
ppm, respectively. This indicates that
the product of acrylate
metabolism consisted of two methylene groups
(based on the
1H chemical shifts with similar integral
intensities) and a carbonyl
group (based on the
13C
chemical shift of the C-1 carbon). To help identify the unknown
metabolite, several three-carbon molecules, including lactate,
propionate, and
-hydroxypropionate, were analyzed by NMR. The
-hydroxypropionate standard had
1H and
13C
resonances identical to that of the unknown metabolite (data
not
shown). The identity of the unknown metabolite in the extracellular
medium was confirmed by adding 10 mM
-hydroxypropionate to the
40-min sample, which resulted in an increase in the intensity
of the
1H resonances at 2.30 and 3.67 ppm and the
13C
resonance at 180 ppm (data not shown). The identity of the unknown
metabolite,
-hydroxypropionate, in the extracellular medium was
confirmed by using negative ion electrospray mass spectroscopy.
The
acetone-soluble metabolite extracted from the 40-min lyophilized
sample
had an
m/z of 90. This
m/z was the exact
molecular weight
calculated for
-hydroxypropionate with a
13C-labeled carbonyl group (the
-hydroxypropionate
standard that
was not
13C labeled gave an
m/z of
89). Based on these analyses, the product
of acrylate metabolism by
strain M3A in the extracellular medium
was definitively identified as
-hydroxypropionate. Based on the
integral intensity of its NMR
signal,
-hydroxypropionate in the
extracellular medium was maximum
at 40 min and was approximated
at a concentration of 3 mM.
View larger version (16K):
[in this window]
[in a new window]
|
FIG. 5.
The gradient-enhanced
1H{13C} HMQC spectrum of the extracellular
medium taken 40 min after the addition of 5 mM
[1-13C]acrylate to a suspension of A. faecalis
cells. The spectrum shows elements of both acrylate and its metabolite,
-hydroxypropionate.
|
|
To determine if any of the [1-
13C]acrylate or products
derived from its metabolism could be found in the cell cytoplasm, cell
pellets were ethanol extracted and the dried residue was rehydrated
in
D
2O and examined by
1H and
13C NMR
spectroscopy. The
1H NMR spectrum obtained from each of the
cell extracts resulted
in many overlapping peaks that could not be
interpreted. However,
13C NMR analysis of the extracts
showed only one resonance at 180
ppm (Fig.
6A). It is assumed that this resonance is
from a
13C-labeled metabolite due to its great intensity.
Cell extracts
prepared over the time course (120 min) of the experiment
described
above (Fig.
4) showed an increase in the intensity of the
resonance
at 180 ppm, which reached its maximum at 20 min and
thereafter
declined (Fig.
6B). When the
-hydroxypropionate standard
was
added to these samples, the intensity of the resonance centered
at
180 ppm increased, which confirmed the identity of the intracellular
metabolite as
-hydroxypropionate. The disappearance with time
of the
resonance centered at 180 ppm and the fact that no other
resonances
could be identified indicated that the
13C-labeled carbonyl
group of
-hydroxypropionate was subsequently
decarboxylated.
View larger version (27K):
[in this window]
[in a new window]
|
FIG. 6.
13C NMR spectrum of intracellular
[1-13C]acrylate metabolites showing the full spectrum
after 20 min (A) and a time course representing the peak intensity
centered at 180 ppm, identified as the [13C]carboxyl
group of -hydroxypropionate (B).
|
|
DMSP lyase induction.
Previous reports have provided evidence
that acrylate is the inducer of DMSP lyase in A. faecalis
M3A (15, 49); however, since acrylate does not enter the
cell (as shown here), the mechanism of DMSP lyase induction remained
unknown. Because -hydroxypropionate was shown to be a product of
acrylate metabolism, DMSP, acrylate, and -hydroxypropionate were
compared as inducers of DMSP lyase in strain M3A over a concentration
range of 100 µM to 10 mM, and all served equally well (Table
1). This strongly suggests that -hydroxypropionate or a molecule derived from its metabolism was the
inducer of DMSP lyase.
Since acrylate is metabolized to
-hydroxypropionate and is either
directly or indirectly the inducer of the lyase in strain
M3A, the
question arises as to how DMSP is first metabolized to
acrylate in
cells not induced for DMSP lyase. Figure
7 shows the
time course of DMSP
degradation (to DMS) in suspensions of uninduced
cells. When DMSP was
added at time zero, it served as both substrate
and inducer of DMSP
lyase. The initial low rate of DMS production
suggested the presence of
an endogenous lyase activity, which
was followed by much higher rates
(Fig.
7); this biphasic rate
suggested that induction of additional
DMSP lyase was occurring.
The addition of gentamicin (a protein
synthesis inhibitor) along
with DMSP had no effect on the initial rate
of DMS production,
confirming the presence of an endogenous lyase
activity in this
organism (Fig.
7). The initial rate continued until
all of the
DMSP was consumed. Finally, in comparable experiments with
P. doudoroffii and strain JA6 (two marine
-Proteobacteria
that synthesize
DMSP lyase), no DMS was produced in the presence of
gentamicin,
indicating that constitutive DMSP lyase expression is not
present
in all marine bacterial isolates (
2).
View larger version (20K):
[in this window]
[in a new window]
|
FIG. 7.
Endogenous DMSP lyase activity in noninduced cell
suspensions (i.e., grown in tryptic soy broth) of A. faecalis M3A. Cells (1 ml) were pretreated for 30 min with 200 µg · ml1 of gentamicin (Gm). DMSP (2.5 mM) was
added to treated and untreated cells, and the headspace gas was assayed
for DMS by gas chromatography.
|
|
While the endogenous rate of lyase activity may appear high (Fig.
7),
it represented less than 10% of what the fully induced
cell is capable
of synthesizing (
2,
15). When the endogenous
DMSP lyase from
A. faecalis was purified, Western blot analysis
showed that
it comigrated with the enzyme purified from acrylate-grown
cells (i.e.,
fully induced cells), indicating that the molecular
masses (ca. 48 kDa)
were indistinguishable. This was also true
of their kinetic properties
(
2). The purification of the endogenous
lyase resulted in
yields too low to permit N-terminal amino acid
sequencing, which could
have provided a more definitive
comparison.
| |
DISCUSSION |
While there is some information about acrylate metabolism in
anaerobic bacterial isolates and natural populations in anoxic environments, there are no reports documenting its metabolic fate in
aerobic bacteria. This work describes the metabolism of DMSP to
-hydroxypropionate and its subsequent utilization by the cell in a
reaction that proceeds as follows:
(CH3)2S+CH2CH2CO2
(CH3)2S + CH2==CHCO2 + H+
HOCH2CH2CO2 CO2 + X (X represents an unknown metabolite). While
there appear to be no previous reports of bacterial metabolism of
acrylate to -hydroxypropionate until this one, there are several
reports of this reaction occurring in fungi. -Hydroxypropionate was
produced by the fungus Byssochlamys sp. when grown on media
containing high concentrations of acrylate (39). Acrylate
was also -hydroxylated to -hydroxypropionate by the fungal
isolates Geotrichum sp. and Trichoderma sp. from
a petrochemical effluent treatment plant (14).
Previous reports have shown DMSP uptake to precede its degradation to
DMS and acrylate in both natural populations in oceanic waters
(28) and pure cultures of the aerobic marine bacterial isolates, P. doudoroffii and strain LFR (27, 49).
These organisms accumulate DMSP intracellularly at concentrations in
excess of 70 mM prior to its degradation to DMS and acrylate by
internal DMSP lyases (27, 47). In contrast, A. faecalis does not take up or accumulate DMSP in measurable
quantities; instead, it metabolizes DMSP to DMS and acrylate outside of
the cell by an extracellular DMSP lyase (49). In support of
those earlier observations, it was shown that as DMSP was metabolized
by a low constitutively expressed level of lyase (indistinguishable
from the inducible lyase), acrylate accumulated in the extracellular
medium (Fig. 8).
View larger version (24K):
[in this window]
[in a new window]
|
FIG. 8.
A model of DMSP metabolism in A. faecalis
M3A. Abbreviations: DL*, endogenous DMSP lyase; Ac*, endogenous
acrylate metabolizing enzyme (acrylase); DL and Ac, inducible DMSP
lyase and inducible acrylase, respectively; BP, -hydroxypropionate
uptake or binding protein; X, unidentified product of
-hydroxypropionate metabolism; Gm, gentamicin. The dashed line
indicates the possibility that the unidentified -hydroxypropionate
metabolite (X) could conceivably be the inducer of DMSP lyase and the
acrylate-metabolizing enzyme.
|
|
NMR analysis has determined that acrylate, like DMSP, is also
metabolized outside the cell by an extracellular enzyme, tentatively called acrylase. This is supported by data that showed the accumulation of -hydroxypropionate in the supernatant, as acrylate was being metabolized and then disappeared from the external medium (Fig. 4). As
-hydroxypropionate accumulated in the extracellular medium, the
13C resonance at 180 ppm (identified as
-hydroxypropionate) also increased in the cell cytoplasm. Therefore
acrylate does not enter the cell, but the product of its metabolism,
-hydroxypropionate, is taken up and accumulates in the cytoplasm, at
least transiently (Fig. 6).
DMSP lyase appears to be an inducible enzyme in all species that
metabolize DMSP via the cleavage pathway (2). This
observation has not been extended to natural populations, however,
because extremely low levels of DMSP have been shown to be cleaved with no apparent lag (or induction) period (24, 28). Data from previous reports suggested that acrylate was the inducer of DMSP lyase
in A. faecalis. This was supported by the observation that acrylate and its analogs (acrylamide and methacrylate) were also capable of DMSP lyase induction, while DMSP analogs (glycine betaine, dimethylseleniopropionate, and dimethyl glycine) would not induce the
lyase (16, 49). When DMSP, acrylate, and
-hydroxypropionate were compared as lyase inducers, all served
equally well (Table 1), but acrylate could not be detected within the
cell by NMR analysis. Therefore, it is concluded that
-hydroxypropionate is the inducer of DMSP lyase in A. faecalis (Fig. 8 and see below).
An earlier report (16) that dimethylsulfoxide (DMSO) and
dimethyldisulfide (DMDS) were inducers of DMSP lyase in A. faecalis has not been reproducible. DMSO reductase yields DMS as
one of its reaction products, and it has been determined that DMSO in the interstitial space in the cell pellet released DMS by this reaction, which was mistaken for DMSP cleavage in cell suspensions. Furthermore, we were unaware at that time of the endogenous DMSP lyase
activity that also contributed to the immediate release of DMS, leading
us to believe that DMSO had induced the lyase. DMDS trapped in the
interstitial space of the cell pellet resulted in its release into the
gas phase, and because it has nearly the same retention time as that of
DMS on our gas chromatograph, it was apparently mistaken for DMS. Using
washed cell pellets, the results clearly indicate that neither DMSO nor
DMDS are inducers of the lyase in A. faecalis
(2).
Figure 8 outlines the mechanism of DMSP-acrylate metabolism, DMSP lyase
induction, and -hydroxypropionate production and metabolism in
A. faecalis. The endogenous DMSP lyase in the periplasm of
this gram-negative organism is responsible for the initial degradation
of DMSP to DMS and acrylate in noninduced cells. Subsequently, an
endogenous acrylate-metabolizing enzyme, i.e., acrylase, also external
to the cytoplasmic membrane, converts acrylate to
-hydroxypropionate, which is taken up by the cell and metabolized to
an unidentified product and CO2. -Hydroxypropionate
serves as the inducer of both additional DMSP lyase and acrylase, but
we cannot say at this time if it or a product of its metabolism is the
actual inducer. Two potential products of -hydroxypropionate
metabolism are propionate and acetate, but neither of these induce DMSP
lyase activity in this organism (2, 16). The production of
CO2 from intracellular -hydroxypropionate metabolism is
assumed to account for the loss of the intracellular 13C
signal, as the label was in the C-1 position (Fig. 6).
It is possible that the endogenous and inducible DMSP lyases are both
the products of the same gene, with the former simply resulting from
constitutive readthrough expression; the same is true for the
endogenous and inducible acrylase activities.
This report describes a unique mechanism of DMSP-acrylate metabolism in
an aerobic gram-negative -Proteobacterium, which involves a
metabolite, -hydroxypropionate, apparently not yet documented in
bacterial metabolism. The ecological significance of this finding has
yet to be determined; however, one may speculate on how this influences
the overall carbon cycle within the marine microbial loop. Since these
reactions take place exterior to the cell membrane, the metabolism of
DMSP in natural systems by microbes of this kind may be beneficial even
to those microbes not capable of cleaving DMSP. Therefore, microbes
that are in close proximity to A. faecalis-like
DMSP-cleaving strains may benefit from the acrylate and
-hydroxypropionate released from their DMSP metabolism. This would
be significant to those microbes in phytoplankton blooms where DMSP may
be found in significant concentrations as the bloom crashes or is
heavily grazed by zooplankton (47). Although that scenario
is speculative, this report clearly documents a rather complex
extracellular mechanism of DMSP metabolism in one DMS-producing salt
marsh isolate.
| |
ACKNOWLEDGMENTS |
This work was supported in part by grants from the SC Sea Grant
Consortium (R-MX-8) and DOE/SCUREF.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biological Sciences, University of South Carolina, Columbia, SC 29208. Phone: (803) 777-2322. Fax: (803) 777-4002. E-mail:
yoch{at}biol.sc.edu.
| |
REFERENCES |
| 1.
|
Andreae, M. O.
1985.
The emission of sulfur to the remote atmosphere, p. 5-25.
In
J. N. Galoway, R. J. Charlson, M. O. Andreae, and H. Rode (ed.), The biogeochemical cycling of sulfur and nitrogen in the remote atmosphere. D. Redial Publishing Co., Boston, Mass
|
| 2.
| Ansede, J. H., and D. C. Yoch.
Unpublished data.
|
| 3.
|
Ansede, J. H.,
P. J. Pellechia, and D. C. Yoch.
1999.
Selenium biotransformation salt marsh cordgrass Spartina alterniflora: evidence for dimethylselenoniopropionate formation.
Environ. Sci. Technol.
33:2064-2069.
|
| 4.
|
Bacic, M. K.,
S. Y. Newell, and D. C. Yoch.
1998.
Release of dimethylsulfide from dimethylsulfoniopropionate by plant-associated salt marsh fungi.
Appl. Environ. Microbiol.
64:1484-1489[Abstract/Free Full Text].
|
| 5.
|
Balch, W. E.,
G. E. Fox,
L. J. Magrum,
C. R. Woese, and R. S. Wolfe.
1979.
Methanogens: reevaluation of a unique biological group.
Microbiol. Rev.
43:260-296[Free Full Text].
|
| 6.
|
Bates, T. S.,
R. J. Charlson, and R. H. Gammon.
1987.
Evidence for the climatic role of marine biogenic sulfur.
Nature
329:319-321.
|
| 7.
|
Bates, T. S., and J. D. Cline.
1985.
The role of the ocean in a regional sulfur cycle.
J. Geophys. Res.
90:9168-9172.
|
| 8.
|
Cantoni, G. L., and D. G. Anderson.
1956.
Enzymatic cleavage of dimethylthetin by Polysiphonia lanosa.
J. Biol. Chem.
222:171-177[Free Full Text].
|
| 9.
|
Challenger, F., and M. I. Simpson.
1948.
Studies on biological methylation. Part XII. A precursor of the dimethyl sulfide evolved by Polysiphonia fastigata. Dimethyl-2-carboxyethyl-sulfonium hydroxide and its salts.
J. Chem. Soc.
3:1591-1597.
|
| 10.
|
Charlson, R. J.,
J. E. Lovelock,
M. O. Andreae, and S. G. Warren.
1987.
Oceanic phytoplankton, atmospheric sulfur, cloud albedo and climate.
Nature
326:655-661.
|
| 11.
|
Dacey, J. W. H., and N. V. Blough.
1987.
Hydroxide decomposition of DMSP to form DMS.
Geophys. Res. Lett.
14:1246-1249.
|
| 12.
|
Dacey, J. W. H.,
G. M. King, and S. G. Wakeham.
1987.
Factors controlling emission of dimethylsulfide from salt marshes.
Nature
330:643-645.
|
| 13.
|
Dacey, J. W. H., and S. G. Wakeham.
1986.
Oceanic dimethyl sulfide: production during zooplankton grazing on phytoplankton.
Science
233:1314-1316[Abstract/Free Full Text].
|
| 14.
|
Dave, H.,
C. Ramakrishna, and J. D. Desai.
1996.
Degradation of acrylic acid by fungi from petrochemical activated sludge.
Biotechnol. Lett.
18:963-964.
|
| 15.
|
de Souza, M. P., and D. C. Yoch.
1995.
Purification and characterization of dimethylsulfoniopropionate lyase from an Alcaligenes-like dimethyl sulfide-producing marine isolate.
Appl. Environ. Microbiol.
61:21-26[Abstract].
|
| 16.
|
de Souza, M. P., and D. C. Yoch.
1995.
Comparative physiology of dimethylsulfide production by dimethylsulfoniopropionate lyase in Pseudomonas doudoroffii and Alcaligenes sp. strain M3A.
Appl. Environ. Microbiol.
61:3986-3991[Abstract].
|
| 17.
|
de Souza, M. P.,
Y. P. Chen, and D. C. Yoch.
1996.
Dimethylsulfoniopropionate lyase from the marine macroalga Ulva curvata: purification and characterization of the enzyme.
Planta
199:433-438.
|
| 18.
|
de Souza, M. P., and D. C. Yoch.
1996.
N-terminal amino acid sequences and comparison of DMSP lyases from Pseudomonas doudoroffii and Alcaligenes strain M3A, p. 293-304.
In
R. P. Kiene, P. T. Visscher, M. D. Keller, and G. O. Kirst (ed.), Environmental and biological chemistry on dimethylsulfoniopropionate and related sulfonium compounds. Plenum Press, New York, N.Y
|
| 19.
|
Dickson, D. M.,
R. G. WynJones, and J. Davenport.
1980.
Steady state osmotic adaptation in Ulva lactuca.
Planta
150:158-165.
|
| 20.
|
Dickson, D. M. J., and G. O. Kirst.
1986.
The role of dimethylsulfoniopropionate, glycine betaine and homarine in the osmoacclimation of Platymonas subcordiformis.
Planta
167:536-543.
|
| 21.
|
Gherna, R.,
P. Pienta, and R. Cote (ed.).
1992.
1992 American Type Culture Collection Catalogue of Bacteria and Phages, 18th ed.
American Type Culture Collection, Rockville, Md
|
| 22.
|
Kadota, H., and Y. Ishida.
1972.
Production of volatile sulfur compounds by microorganisms.
Annu. Rev. Microbiol.
26:127-138[Medline].
|
| 23.
|
Keller, M. D.,
W. K. Bellows, and R. R. L. Guillard.
1989.
Dimethylsulfide sulfide production in marine phytoplankton, p. 167-182.
In
E. S. Salzman, and W. J. Cooper (ed.), Biogenic sulfur in the environment. American Chemical Society Symposium Series no. 393. American Chemical Society, Washington, D.C.
|
| 24.
|
Kiene, R. P., and S. K. Service.
1991.
Decomposition of dissolved DMSP and DMS in estuarine waters: dependence on temperature and substrate concentration.
Mar. Ecol. Prog. Ser.
76:1-11.
|
| 25.
|
Kiene, R. P., and B. F. Taylor.
1989.
Metabolism of acrylate and 3-mercaptopropionate, p. 222-230.
In
E. S. Salzman, and W. J. Cooper (ed.), Biogenic sulfur in the environment. American Chemical Society Symposium Series no. 393. American Chemical Society, Washington, D.C.
|
| 26.
|
Kiene, R. P., and P. T. Visscher.
1987.
Production and fate of methylated sulfur compounds from methionine and dimethylsulfoniopropionate in anoxic salt marsh sediments.
Appl. Environ. Microbiol.
53:2426-2434[Abstract/Free Full Text].
|
| 27.
|
Ledyard, K. M., and J. W. H. Dacey.
1994.
Dimethylsulfide production from dimethylsulfoniopropionate by a marine bacterium.
Mar. Ecol. Prog. Ser.
110:95-103.
|
| 28.
|
Ledyard, K. M., and J. W. H. Dacey.
1996.
Kinetics of DMSP-lyase activity in coastal seawater, p. 325-336.
In
R. P. Kiene, P. T. Visscher, M. D. Keller, and G. O. Kirst (ed.), Environmental and biological chemistry on dimethylsulfoniopropionate and related sulfonium compounds. Plenum Press, New York, N.Y
|
| 29.
|
Legrand, M. R.,
R. J. Delmas, and R. J. Charlson.
1988.
Climate forcing implications from Vostok ice-core sulfate data.
Nature
334:418-420.
|
| 30.
|
Matrai, P., and M. D. Keller.
1993.
DMS in a large scale coccolithophore bloom in the gulf of Maine.
Cont. Shelf Res.
13:831-843.
|
| 31.
|
Nishiguchi, M. K., and L. J. Goff.
1995.
Isolation, purification, and characterization of DMSP lyase (dimethylpropiothetin dethiomethylase (4.4.1.3)) from the red alga Polysiphonia paniculata.
J. Phycol.
31:567-574.
|
| 32.
|
Nriagu, J. O.,
D. A. Holdway, and R. D. Coker.
1987.
Biogenic sulfur and the acidity of rainfall in remote areas of Canada.
Science
237:1189-1192[Abstract/Free Full Text].
|
| 33.
|
Pakulski, J. D., and R. P. Kiene.
1992.
Foliar release of dimethylsulfoniopropionate from Spartina alterniflora.
Mar. Ecol. Prog. Ser.
81:277-287.
|
| 34.
|
Read, R. R.
1941.
-Hydroxypropionic acid, organic synthesis, 2nd ed.
, collective vol. 1, p. 321-322. John Wiley & Sons, Inc., New York, N.Y.
|
| 35.
|
Reed, R. H.
1983.
Measurement and osmotic significance of -dimethylsulfoniopropionate in marine macroalgae.
Mar. Biol. Lett.
4:173-181.
|
| 36.
|
Salzman, E. S., and W. J. Cooper (ed.).
1989.
Biogenic sulfur in the environment. American Chemical Society Symposium Series no. 393.
American Chemical Society, Washington, D.C.
|
| 37.
|
Sambrook, J.,
E. F. Fritsch, and T. Maniatis.
1989.
Molecular cloning: a laboratory manual, 2nd ed.
Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y
|
| 38.
|
Stefels, J., and W. H. M. van Boekel.
1993.
Production of DMS from dissolved DMSP in axenic cultures of the marine phytoplankton species Phaeocystis sp.
Mar. Ecol. Prog. Ser.
97:11-18.
|
| 39.
|
Takamizawa, K.,
H. Horitsu,
T. Ichikawa,
K. Kawai, and T. Suzuki.
1993.
-Hydroxypropionate acid production by Byssochlamys sp. grown on acrylic acid.
Appl. Microbiol. Biotechnol.
40:196-200.
|
| 40.
|
Taylor, B. T., and D. C. Gilchrist.
1991.
New routes for aerobic biodegradation of dimethylsulfoniopropionate.
Appl. Environ. Microbiol.
57:3581-3584[Abstract/Free Full Text].
|
| 41.
|
Vairavamurthy, A.,
M. O. Andreae, and R. L. Iversen.
1985.
Biosynthesis of dimethyl sulfide and dimethyl propiothetin by Hymenomonas carterae in relation to sulfur source and salinity variations.
Limnol. Oceanogr.
30:59-70.
|
| 42.
|
van der Maarel, M. J. E. C.,
W. Aukema, and T. A. Hansen.
1996.
Purification and characterization of a dimethylsulfoniopropionate cleaving enzyme from Desulfovibrio acrylicus.
FEMS Microbiol. Lett.
143:241-245.
|
| 43.
|
van der Maarel, M. J. E. C.,
S. van Bergeijk,
A. F. van Werkhoven,
A. M. Laverman,
W. G. Meijer,
W. T. Stam, and T. A. Hansen.
1996.
Cleavage of dimethylsulfoniopropionate and reduction of acrylate by Desulfovibrio acrylicus sp. nov.
Arch. Microbiol.
166:109-115.
|
| 44.
|
Visscher, P. T.,
M. R. Diaz, and B. F. Taylor.
1992.
Enumeration of bacteria which cleave or demethylate dimethylsulfoniopropionate in the Caribbean Sea.
Mar. Ecol. Prog. Ser.
89:293-296.
|
| 45.
|
Wagner, C., and E. R. Stadtman.
1962.
Bacterial fermentation of dimethyl--propiothetin.
Arch. Biochem. Biophys.
98:331-336.
|
| 46.
|
White, R. H.
1982.
Analysis of dimethylsulfonium compounds in marine algae.
J. Mar. Res.
40:529-536.
|
| 47.
|
Wolfe, G. V.,
E. B. Sherr, and B. F. Sherr.
1994.
Release and consumption of DMSP from Emliana huxleyi during grazing by Oxyrrhis marina.
Mar. Ecol. Prog. Ser.
111:111-119.
|
| 48.
| Yoch, D. C., J. H. Ansede, and M. P. de
Souza. Submitted for publication.
|
| 49.
|
Yoch, D. C.,
J. H. Ansede, and K. S. Rabinowitz.
1997.
Evidence for intracellular and extracellular dimethylsulfoniopropionate (DMSP) lyases and DMSP uptake sites in two species of marine bacteria.
Appl. Environ. Microbiol.
63:3182-3188[Abstract].
|
Applied and Environmental Microbiology, November 1999, p. 5075-5081, Vol. 65, No. 11
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Johnston, A. W. B., Todd, J. D., Sun, L., Nikolaidou-Katsaridou, M. N., Curson, A. R. J., Rogers, R.
(2008). Molecular diversity of bacterial production of the climate-changing gas, dimethyl sulphide, a molecule that impinges on local and global symbioses. J Exp Bot
59: 1059-1067
[Abstract]
[Full Text]
-
Wampler, D. A., Ensign, S. A.
(2005). Photoheterotrophic Metabolism of Acrylamide by a Newly Isolated Strain of Rhodopseudomonas palustris. Appl. Environ. Microbiol.
71: 5850-5857
[Abstract]
[Full Text]
-
Miller, T. R., Belas, R.
(2004). Dimethylsulfoniopropionate Metabolism by Pfiesteria-Associated Roseobacter spp.. Appl. Environ. Microbiol.
70: 3383-3391
[Abstract]
[Full Text]
-
Ansede, J. H., Pellechia, P. J., Yoch, D. C.
(2001). Nuclear Magnetic Resonance Analysis of [1-13C]Dimethylsulfoniopropionate (DMSP) and [1-13C]Acrylate Metabolism by a DMSP Lyase-Producing Marine Isolate of the {alpha}-Subclass of Proteobacteria. Appl. Environ. Microbiol.
67: 3134-3139
[Abstract]
[Full Text]
-
Ansede, J. H., Friedman, R., Yoch, D. C.
(2001). Phylogenetic Analysis of Culturable Dimethyl Sulfide-Producing Bacteria from a Spartina-Dominated Salt Marsh and Estuarine Water. Appl. Environ. Microbiol.
67: 1210-1217
[Abstract]
[Full Text]
Top
Abstract
Introduction
