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Plant Physiol, July 2000, Vol. 123, pp. 1153-1162
Biochemical Evidence for Two Novel Enzymes in the Biosynthesis of
3-Dimethylsulfoniopropionate in Spartina
alterniflora1
Michael G.
Kocsis and
Andrew D.
Hanson*
Horticultural Sciences Department, University of Florida,
Gainesville, Florida 32611
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ABSTRACT |
3-Dimethylsulfoniopropionate (DMSP) is an osmoprotectant
accumulated by the cordgrass Spartina alterniflora and
other salt-tolerant plants. Previous in vivo isotope tracer and
metabolic modeling studies demonstrated that S.
alterniflora synthesizes DMSP via the route
S-methyl-Met  3-dimethylsulfoniopropylamine
(DMSP-amine) 3-dimethylsulfoniopropionaldehyde DMSP and
indicated that the first reaction requires a far higher substrate
concentration than the second to attain one-half-maximal rate. As
neither of these reactions is known from other organisms, two novel
enzymes are predicted. Two corresponding activities were identified in S. alterniflora leaf extracts using specific
radioassays. The first, S-methyl-Met decarboxylase
(SDC), strongly prefers the L-enantiomer of
S-methyl-Met, is pyridoxal 5'-phosphate-dependent, generates equimolar amounts of CO2 and DMSP-amine, and has
a high apparent Km (approximately 18 mM) for its substrate. The second enzyme, DMSP-amine
oxidase (DOX), requires O2 for activity, shows an apparent
Km for DMSP-amine of 1.8 mM, and
is not accompanied by DMSP-amine dehydrogenase or transaminase
activity. Very little SDC or DOX activity was found in grasses lacking
DMSP. These data indicate that SDC and DOX are the predicted novel
enzymes of DMSP synthesis.
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INTRODUCTION |
The tertiary sulfonium compound
3-dimethylsulfoniopropionate (DMSP) is accumulated by certain
salt-tolerant angiosperms and many marine algae (Malin and Kirst, 1997 ;
McNeil et al., 1999). DMSP is structurally analogous to a betaine and
like betaines, functions as a cytoplasmic compatible solute or
osmoprotectant and contributes to adaptation to osmotic and freezing
stresses (Rhodes and Hanson, 1993; Karsten et al., 1996; Vianney et
al., 1998). DMSP differs from betaines in that it contains sulfur
instead of nitrogen and, in DMSP-accumulating plants, appears to act as a substitute for betaines when nitrogen is scarce (Colmer et al., 1996;
Cooper and Hanson, 1998). Engineering accumulation of betaines or other
osmoprotectants can improve osmotic or freezing stress resistance
(Holmberg and Bülow, 1998; Nuccio et al., 1999). Since nitrogen
often limits crop growth, and DMSP accumulation does not require
nitrogen, DMSP synthesis is an attractive target for the engineering of
stress resistance in low-nitrogen environments (McNeil et al.,
1999).
DMSP biosynthesis is also environmentally important because DMSP is the
main biogenic precursor of dimethylsulfide (DMS) released to the
atmosphere from the oceans (Malin and Kirst, 1997) and is a likely
precursor of DMS coming from land (Dacey et al., 1987; Paquet et al.,
1994). Biogenic DMS plays a pivotal role in the global sulfur cycle,
affects the pH of precipitation, and is believed to contribute to the
regulation of global climate (Malin, 1996).
In vivo isotope labeling and modeling studies (Kocsis et al., 1998)
demonstrated that DMSP biosynthesis in the saltmarsh cordgrass Spartina alterniflora proceeds from
L-Met via S-methyl-Met (SMM), 3-dimethylsulfoniopropylamine (DMSP-amine) and
3-dimethylsulfoniopropionaldehyde (DMSP-ald; Fig.
1). The first and last steps in this
pathway are the same as in the dicot Wollastonia biflora,
but the central part is not. In W. biflora, SMM is converted
directly to DMSP-ald without formation of DMSP-amine, most likely via a
transamination/decarboxylation mechanism (Hanson et al., 1994; James et
al., 1995; Rhodes et al., 1997). All angiosperms appear to produce SMM
(Mudd and Datko, 1990; Bourgis et al., 1999), and to have enzymes that
can catalyze the conversion of DMSP-ald to DMSP (Trossat et al., 1997;
Vojt chová et al., 1997). It is thus the conversion of SMM
to DMSP-ald that is unique to DMSP synthesis, and S. alterniflora appears to have evolved specific enzymes that mediate
this conversion. Besides predicting the existence of novel enzymes in
S. alterniflora that convert SMM to DMSP-amine, and
DMSP-amine to DMSP-ald, the in vivo tracer and modeling studies
predicted that, of these enzymes, the first has a much higher
Km for its sulfonium substrate than the
second (Kocsis et al., 1998).
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Figure 1.
The DMSP biosynthesis pathway in S. alterniflora. Only the decarboxylation of SMM and conversion of
DMSP-amine to DMSP-ald are unique to DMSP biosynthesis. Enzymes able to
catalyze the other two steps are widespread in angiosperms.
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We report here the identification, initial characterization, and assay
procedures of two enzymes from S. alterniflora that catalyze
the SMM DMSP-amine and DMSP-amine DMSP-ald steps. The
first is SMM decarboxylase (SDC). The second is DMSP-amine oxidase
(DOX). Comparative biochemical data indicate that both are
specific to the DMSP pathway.
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RESULTS |
Extraction and Assay of SDC Activity
Amino acid decarboxylases can be conveniently assayed by measuring
the release of 14CO2 from
14C-carboxyl-labeled substrate. However, such
assays must first be validated by confirming that
CO2 and amine production are in a 1:1 molar ratio
because other reactions in plant extracts may lead to loss of the
carboxyl group as CO2 (Birecka et al., 1985). To
test this, L-[U-14C]SMM was used as
substrate, and [14C]DMSP-amine and
14CO2 were quantified.
[14C]DMSP-amine formation was readily detected
(Fig. 2A), and 14C
quantification indicated a CO2:DMSP-amine molar
ratio of 0.97 ± 0.01 (mean ± SE;
n = 3). SDC was therefore assayed in subsequent work by
measuring 14CO2 release
from L-[1-14C]SMM. SDC
activity showed a strong preference for the L
enantiomer of SMM.
D-[1-14C]SMM gave <4%
of the activity observed with
L-[1-14C]SMM (Fig.
2B).
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Figure 2.
Characterization of SDC activity in S. alterniflora leaf extracts. Buffers contained 0.1 mM PLP. A, Formation of
[14C]DMSP-amine from
L-[U-14C]SMM.
L-[U-14C]SMM (1.12 nmol,
10.7 kBq) was incubated with (+E) or without ( E) extract (860 µg of
protein) for 75 min. The assay mixtures were separated using TLC system
1, and 14C was detected by autoradiography. The
positions of standards and the origin (ori) are marked. B, SDC
activities assayed using D- or
L-[1-14C]SMM as
substrate. Assays contained 520 µg of protein. Data are means of
triplicates. SE values were  4% of the means.
C, Progress of 14CO2
release from L-[1-14C]SMM, plus or minus
extract (330 µg of protein). Data points are means of triplicates.
SE values were 4% of the means.
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Most amino acid decarboxylases have a pyridoxal 5'-phosphate (PLP)
coenzyme, but a few use a covalently-bound pyruvate as prosthetic group
instead (Recsei and Snell, 1984; John, 1995). We therefore tested the
effect of including PLP (0.1 or 1 mM) in the buffers used
to extract and assay SDC. Adding PLP to the assay buffer doubled
activity and adding it to both extraction and assay buffers increased
activity 18-fold. These data indicate that SDC requires PLP for
stability as well as activity. PLP (0.1 mM) was therefore
added to all SDC buffers. Progress curves showed that the rate of
14CO2 production from
L-[1-14C]SMM declined slowly with
time (Fig. 2C). This was not due to substrate depletion or product
inhibition (see below) and presumably not to abortive transamination
(and hence, inactivation) of the coenzyme because PLP was present to
replace the inactivated species (John, 1995). We therefore attribute
the activity loss to inactivation of the enzyme itself. A 75-min
incubation time was adopted for subsequent work. Using this incubation
time, 14CO2 formation was
approximately linearly related to enzyme level (not shown).
Characteristics of SDC Activity
SDC showed a broad pH optimum around 7, retaining  75% of the
maximum activity between pH 6.5 and 8. SDC activity was
one-half-maximal at about 18 mM SMM, and its
Vmax was estimated as 0.28 nmol
min 1 mg1 protein (crude
extract). Unlike some other decarboxylases (Grossfeld et al., 1984),
SDC is not highly sensitive to inhibition by the amine product. A
2-fold molar excess of DMSP-amine over SMM had no effect on activity.
SDC activity appears not to be a side reaction mediated by one of the
decarboxylases found in all plants. This was shown by assaying SDC
activity in the presence of a 20-fold molar excess of five
L-amino acids for which specific decarboxylases are known (Stevenson et al., 1990; Kumar et al., 1997), all except one
(Glu) being structural analogs of SMM (Table
I). None of these compounds caused the
drastic inhibition that would be expected were SMM a poor alternative
substrate for their respective decarboxylases. Met,
S-adenosyl-L-Met (Ado-Met), Arg, and
Glu gave 18% inhibition. Orn inhibited activity by 60%.
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Table I.
Effect of L-amino acids on
decarboxylation of L-1-[-14C]SMM by S. alterniflora extract
Assays contained 50 µM
L-[1-14C]SMM, 1 mM unlabeled
L-amino acid, and desalted leaf extract corresponding to
520 µg of protein. The L-amino acids were neutralized
with KOH or HCl. Data are the means of duplicates. SE
values were 1% of the means.
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SDC Activity in Grasses That Do Not Accumulate DMSP
Comparative biochemistry provided further evidence that the SDC
activity is due to an enzyme specific to DMSP synthesis. SDC activity
in S. alterniflora was compared with its activity in three
other grasses, one of which is another Spartina species, that contain very little or no DMSP (Paquet et al., 1994; Kocsis et
al., 1998). The housekeeping enzymes, catalase and malate dehydrogenase (MDH), were also assayed as controls for the quality of the extracts. Their activities were fairly similar in all species (Table
II). In contrast only S. alterniflora had high SDC activity. Spartina patens showed 30- to 40-fold less activity, and neither
maize (Zea Mays) nor wheat (Triticum aestivum)
had detectable activity (Table II).
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Table II.
SDC activity in leaf extracts of various grasses
SDC activity was measured in desalted leaf extracts of S. alterniflora and three grasses that do not accumulate DMSP,
S. patens, maize, and wheat. SDC was assayed using an
L-[1-14C]SMM concentration of 36 µM and a
75-min incubation time. Catalase and MDH were assayed
spectrophotometrically. The experiment was repeated, with similar
results.
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Assay for the Conversion of DMSP-Amine to DMSP-Ald
Because DMSP-amine could, a priori, be converted to DMSP-ald by a
transaminase, dehydrogenase, or oxidase, we developed a radioassay able
to measure any of these activities. The principles of the assay are
schematized in Figure 3 and can be
briefly stated as follows: (a) [35S]DMSP-amine
is used as substrate. When [35S]DMSP-ald is
formed, it decomposes rapidly and spontaneously to give
[35S]DMS (Trossat et al., 1996); (b) the
[35S]DMS is trapped in 30%
H2O2, which oxidizes it to
non-volatile [35S]dimethyl sulfoxide (DMSO);
(c) as some of the [35S]DMSP-ald formed may be
chemically or enzymatically oxidized to
[35S]DMSP, [35S]DMSP
formation is measured at the end of the assay by fractionating the
reaction mixture or by decomposing the
[35S]DMSP to [35S]DMS
by injecting cold NaOH; and (d) catalase is added to the assay to
destroy H2O2 generated by
DOX activity, or diffusing from the DMS trap.
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Figure 3.
Assay for the enzyme-catalyzed conversion of
[35S]DMSP-amine to
[35S]DMSP-ald. The assay was carried out in
potassium-phosphate buffer, pH 8, in which
[35S]DMSP-ald decomposes spontaneously to
acrolein and [35S]DMS with a half-life of <4
min (Trossat et al., 1996). The [35S]DMS
released partitions into the gas phase and is trapped on a filter disc
soaked in 30% H2O2. The
H2O2 oxidizes
[35S]DMS to [35S]DMSO,
which is non-volatile. In certain conditions, some
[35S]DMSP-ald may be oxidized to
[35S]DMSP before it breaks down. At the end of
the assay, [35S]DMSP can be decomposed to
acrylate and [35S]DMS by treatment with NaOH.
*, 35S radiolabel.
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The assay was tested first with purified hog kidney diamine oxidase,
for which DMSP-amine is a substrate (Bardsley et al., 1971). After a
75-min incubation, not followed by NaOH treatment, 19.6% of the
[35S]DMSP-amine was converted to
[35S]DMS (in the trap), 2.1% to
[35S]DMSP, and 0.06% to
[35S]DMSO (in the reaction mixture). These data
show that [35S]DMSP formation can be
significant, and that little oxidation of
[35S]DMS to [35S]DMSO
occurs in the reaction mixture. This is important because DMSO is not
volatile and would not be transferred to the trap.
Evidence for a DOX in S. alterniflora Extracts
Desalted S. alterniflora extracts gave high rates of
DMSP-amine DMSP-ald conversion in the above assay. The activity was not stimulated by  -keto acids or PLP (Table
III), indicating that it is not due to a
transaminase. Nor was activity increased by adding flavins (Table III)
or pyridine nucleotides (Fig. 4), making a dehydrogenase unlikely. Although NAD and NADP did not increase activity, they caused a switch in the major reaction product from [35S]DMS to [35S]DMSP
(Fig. 4). This is anticipated because S. alterniflora is expected to possess NAD(P)-linked DMSP-ald dehydrogenase activity (Kocsis et al., 1998). Adding NAD(P) as well as DMSP-amine to S. alterniflora extracts therefore reconstitutes the last two steps
in the DMSP pathway (Fig. 1). The above results suggest, by
elimination, that the enzyme mediating the DMSP-amine DMSP-ald conversion is an oxidase. Direct evidence for this was obtained by
removing O2 from the assay using Glc oxidase plus
Glc (Table IV). The Glc oxidase/Glc
system reduced activity by 96% when used alone, and by 99% when
combined with a nitrogen atmosphere.
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Table III.
Effects of -keto acids, PLP, or flavins on the
conversion of [35S]DMSP-amine to
[35S]DMSP-ald by S. alterniflora leaf extract
Assays contained 1 mM [35S]DMSP-amine and
desalted extract (78 µg of protein). The concentration of -keto
acids, FMN and FAD, was 1 mM. The PLP concentration was 0.1 mM. Incubation was for 75 min. The conversion of
[35S]DMSP-amine to [35S]DMSP-ald was
estimated from total [35S]DMS production when base was
added after incubation. Values are the means of duplicate assays.
SE values were 2% of the means.
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Figure 4.
Effect of pyridine nucleotides on conversion of
[35S]DMSP-amine to
[35S]DMS and [35S]DMSP
by S. alterniflora leaf extract. After desalting twice,
extract (470-720 µg of protein per assay) was incubated for 75 min
with 25 nmol (3.7 kBq) of [35S]DMSP-amine,
minus (PN) or plus 1 mM NAD or NADP.
L-Ascorbate (5 mM) was
included in the assay buffer. Data are means of two or three
replicates, normalized to 500 µg of protein per assay.
SE values were 12% of the means. The identity
of the [35S]DMSP formed was confirmed by TLC
and autoradiography (inset).
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Table IV.
O2-Dependence of the conversion of
[35S]DMSP-amine to [35S]DMSP-ald by S. alterniflora leaf extract
Assays contained 1 mM [35S]DMSP-amine and
desalted extract (75 µg of protein) and were carried out in air
except where indicated. The final concentration of Glc was 100 mM. Glucose oxidase (GOX) was added at 500 units per assay.
Catalase was omitted so that H2O2 generated by
GOX would not be reconverted to O2. The conversion of
[35S]DMSP-amine to [35S]DMSP-ald was
estimated from total [35S]DMS production when base was
added after incubation. Subsequent fractionation of reaction mixtures
confirmed that no [35S]DMSO was formed. Values are the
means of duplicate assays. SE values were 3% of the
means.
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Characteristics of DOX Activity
Fractionation of assay mixtures showed that
[35S]DMSP became a major product as the amount
of extract increased, but that [35S]DMSO
formation was never very important (Fig.
5A). The relationship between
[35S]DMSP formation and extract concentration
is presumably due mainly to DMSP-ald dehydrogenase activity, supported
by traces of NAD(P) left after desalting (compare with Fig. 4) and by
NAD(P)H oxidase activity in the extract. Total
[35S]DMSP-ald formation, whether estimated from
the sum of labeled products after fractionation or from total
[35S]DMS production when assays were treated
with base, was almost the same and was linearly related to the amount
of protein (Fig. 5B). The base-treatment procedure, which is simpler,
was therefore adopted for routine use.
[35S]DMSP-ald formation was linear with time
for 2 h (not shown). DOX activity was maximal at pH 7.5 to 8, and
showed a Vmax of 0.37 nmol
min1 mg1 protein (crude
extract), and an apparent Km for DMSP-amine
of 1.8 mM. L-Ascorbate (5 mM) inhibited activity, but improved enzyme extraction. It was therefore routinely added to the DOX extraction buffer and removed by desalting.
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Figure 5.
Effect of S. alterniflora extract
concentration on the nature and amounts of the products formed in the
DOX assay. Assays containing 1 mM
[35S]DMSP-amine and extract equivalent to 2 to
100 µg of protein were incubated for 75 min, and then either
fractionated as described in "Materials and Methods" or treated
with 25 µL of 17% NaOH to decompose
[35S]DMSP to [35S]DMS.
A, Proportions of [35S]DMS,
[35S]DMSP, and
[35S]DMSO formed as a function of the amount of
protein per assay. B, Relationship between the amount of protein per
assay and either the summed 35S-products obtained
by fractionation ([35S]DMS + [35S]DMSP + [35S]DMSO)
(left) or the total amount of [35S]DMS formed
when assays were treated with base (right). Data are means of two to
five replicates. The sum of the labeled reaction products, plus
remaining [35S]DMSP-amine, equaled the amount
of [35S]DMSP-amine substrate added to the
assay.
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Because DMSP-amine is structurally similar to diamines and polyamines,
the selectivity of DOX was investigated by adding a 5- or 20-fold molar
excess of unlabeled di- and polyamines to DOX assays (Fig.
6). The polyamines, spermidine and
spermine, had little effect, but the diamines, 1,3-diaminopropane,
putrescine, and cadaverine reduced DOX activity by 90% to 98% when
present in 20-fold excess. This shows that DOX is not highly selective for DMSP-amine and suggests that it may be related to diamine oxidases.
Because these are copper-containing enzymes (Smith, 1985), we attempted
to remove enzyme-bound copper using 10 mM diethyldithiocarbamate or 200 mM EDTA. These treatments
gave preparations that were stimulated 20% to 30% by 1 mM
CuSO4, which was not the case for untreated
controls. As copper is hard to strip out of some amine oxidases
(Hysmith and Boor, 1988), this result is not inconsistent with a copper
requirement.
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Figure 6.
Effect of diamines and polyamines on DOX activity
in S. alterniflora leaf extract. Assays contained 1 mM [35S]DMSP-amine, and
either 5 or 20 mM unlabeled amine or an
equivalent quantity of KCl (controls). The reaction mixtures were
treated with NaOH to convert [35S]DMSP to
[35S]DMS. Data are means of duplicate assays.
SE values were 2% of the means. DAP,
1,3-Diaminopropane; Put, putrescine; Cad, cadaverine; Spd, spermidine;
Spm, spermine.
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DOX Activity in Grasses That Do Not Accumulate DMSP
The activities of DOX, catalase, and MDH were measured in S. alterniflora and in the non-DMSP-accumulating species S. patens, maize, and wheat (Table V).
DOX activity in S. alterniflora was about 100-fold higher
than in the other plants, whereas catalase and MDH activities were
quite similar in all species. These data indicate that the DOX activity
in S. alterniflora is due principally to an enzyme specific
to DMSP synthesis and not to an oxidase of widespread occurrence.
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Table V.
DOX activity in leaf extracts of various grasses
DOX activity was measured in extracts of S. alterniflora and
three grasses that do not accumulate DMSP. DOX was assayed with a
[35S]DMSP-amine concentration of 1 mM and a 75-min
incubation time using total [35S]DMS production when base
was added after incubation. Catalase and MDH were assayed
spectrophotometrically. Data are means of duplicates. SE
values were 12% of the means.
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DISCUSSION |
We have identified novel enzyme activities in S. alterniflora that catalyze the two steps unique to DMSP synthesis
in this species, namely the decarboxylation of SMM and the oxidation of DMSP-amine to DMSP-ald. These enzymes are SDC and DOX. We also devised
convenient radioassays for SDC and DOX and improved the procedure for
synthesizing the [35S]DMSP-amine substrate for
the DOX assay. SDC and DOX activities were shown to be robust inasmuch
as they withstand freeze-thaw treatment, desalting, and concentration.
Together, these advances open the way for future work to purify and
characterize SDC and DOX, and to clone their cDNAs.
The in vivo flux through the pathway SMM DMSP-amine DMSP-ald
DMSP was estimated from computer modeling of radiotracer data to be
1.6 ± 0.7 nmol min1
g1 fresh weight (Kocsis et al., 1998). The
Vmax values for SDC and DOX activities in
S. alterniflora extracts (0.28 and 0.37 min1 mg1 protein,
respectively) are adequate to account for this flux because leaf
protein content in S. alterniflora is about 10 mg g1 fresh weight. Modeling of the in vivo
labeling data also predicted that the Km
for SMM decarboxylation would be an order of magnitude higher than that
for DMSP-amine oxidation (310 versus 5.8 nmol g1 fresh weight, each value being subject to an
error of about ± 50%; Kocsis et al., 1998). This prediction
agrees well with the 10-fold difference between the apparent
Km values that we estimated for substrates
of SDC (about 18 mM) and DOX (1.8 mM).
The absence or very low level of SDC activity in grasses that do not
accumulate DMSP indicates that SDC is an enzyme specific to the DMSP
pathway. The relative insensitivity of SDC to inhibition by
L-amino acids reinforces this inference by showing that SDC activity is unlikely to be a side-reaction mediated by the ubiquitous decarboxylases whose physiological substrates are Met, Ado-Met, Arg,
Orn, or Glu. The lack of Ado-Met inhibition also suggests that SDC is
not closely related to Ado-Met decarboxylase, even though SMM is very
similar in structure to Ado-Met. Additional evidence that SDC and
Ado-Met decarboxylase are unrelated is that SDC requires PLP, whereas
Ado-Met decarboxylase belongs to the small group of enzymes that use a
catalytic pyruvoyl residue, not PLP (Xiong et al., 1997). On the other
hand, the modest inhibition of SDC by L-Orn suggests a
possible relationship to Orn decarboxylase. Inasmuch as eukaryotic Orn
decarboxylases and other basic amino acid decarboxylases share amino
acid sequence homology (Sandmeier et al., 1994), such a relationship
could offer an indirect approach to the cDNA cloning of SDC.
The very low DOX activities in grasses that lack DMSP imply that DOX is
an enzyme associated specifically with DMSP synthesis. The trace of
activity found in these species may be because plant diamine oxidases
have some activity toward DMSP-amine, as has been demonstrated for the
porcine kidney enzyme (Bardsley et al., 1971). Whatever the nature of
the slight DOX activity in species that do not accumulate DMSP, this
activity is consistent with the finding that such species have a low
capacity to oxidize exogenously supplied DMSP-amine (Kocsis et al.,
1998). Assuming DOX to be a specific enzyme, it might a priori be
related to diamine oxidases or to polyamine oxidases because both types
of enzymes occur in grasses (Smith, 1985; Suzuki and Hagiwara, 1993),
and DMSP-amine can be considered to be a diamine or polyamine analog.
Diamine oxidases and polyamine oxidases are quite different, the former being copper enzymes with a covalently bound topa quinone cofactor and
the latter being flavin-containing enzymes (Smith, 1985; Klinman, 1996). That DOX is far more sensitive to inhibition by diamines than
polyamines, and modestly stimulated by copper after chelation treatment, suggests that it is more likely to be a member of the copper
amine oxidase family. The substantial sequence identity among the
members of this family (Padiglia et al., 1998) may, as for SDC, permit
the cDNA cloning of DOX by a homology-based approach.
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MATERIALS AND METHODS |
Plants
Spartina alterniflora Loisel. and Spartina
patens (Ait.) Muhl. were collected from Crescent Beach, Florida
and grown in un-drained pots in a naturally-lit greenhouse at 15°C to
35°C. S. alterniflora was grown in a 10:1 (w/w)
mixture of sand:potting soil. S. patens (Fafard mix 3-B,
Conrad Fafard, Agawam, MA) was grown in soil from the collection site.
Maize (Zea mays L. cv NK 508) was grown in potting soil
in the same greenhouse conditions. Wheat (Triticum aestivum L. cv Florida 310 or cv Bob White) was grown in
potting soil in a chamber with a 12-h photoperiod (200-300 µE
m2 s1; 25°C day/22°C night). Plants
were watered as required and fertilized weekly with Peters soluble
fertilizer (20-20-20, NPK, Scotts-Sierra Horticultural Products,
Marysville, OH).
Chemicals and Radiochemicals
L-[35S]Met (43.5 MBq
nmol1), L-[U-14C]Met (9.56 kBq
nmol1), and [14C]formate (1.79 kBq
nmol1) were obtained from NEN Life Science Products
(Boston), D-[1-14C]Met (2.07 kBq
nmol1) was from Moravek Biochemicals (Brea, CA), and
L-[1-14C]Met (2.03 kBq nmol1)
was from American Radiolabeled Chemicals (St. Louis). Specific radioactivities were adjusted with unlabeled compounds.
3-Methylthiopropylamine (MTP-amine) from Chem Service (West Chester,
PA) was used to prepare DMSP-amine as described (Kocsis et al., 1998).
DMSP was from Research Plus (Bayonne, NJ). L-SMM iodide was
converted to the hydrochloride form by ion-exchange (Kocsis et al.,
1998). Ion-exchange resins were purchased from Bio-Rad Laboratories
(Hercules, CA).
Radiochemical Syntheses
D- and L-[1-14C]SMM (2.07 and 2.03 kBq nmol1, respectively) were synthesized from
D- and L-[1-14C]Met using
methanol as the methylating agent (Gage et al., 1997). L-[35S]SMM (370 kBq nmol1) was
made from L-[35S]Met in the same way.
L-[U-14C]SMM (9.56 kBq nmol1)
was synthesized from L-[U-14C]Met and Ado-Met
using Met S-methyltransferase (Trossat et al., 1996).
After synthesis, labeled SMM was isolated (>98% radiochemical purity)
using thin layer electrophoresis (TLE) system 2 (James et al., 1995).
[35S]DMSP (52-277 Bq nmol1) was isolated
from S. alterniflora leaf sections fed with
L-[35S]Met or
L-[35S]SMM (Kocsis et al., 1998).
[35S]DMSO was obtained by treating
[35S]DMSP with 17% (w/v) NaOH for 2 h to liberate
[35S]DMS (White, 1982; Reed, 1983), which was trapped and
converted to [35S]DMSO on a 1-cm number 3 paper disc
(Whatman, Clifton, NJ) containing 20 µL 30% (w/w)
H2O2 (Kiene and Linn, 2000). The
[35S]DMSO was then eluted with water. To prepare
[35S]DMSP-amine (370-740 kBq nmol1),
L-[35S]Met (25 nmol) was decarboxylated by
incubating (2 h, 37°C, under N2) in 0.1 mL of 0.2 M succinate-NaOH buffer, pH 5.0, containing 1 mM PLP and 11 mg of autumn fern acetone powder (Kocsis et
al., 1998). The reaction mixture was applied to 1-mL AG-1
(OH) and BioRex-70 (H+) columns arranged in
series. After washing the columns with water, [35S]MTP-amine and its sulfoxide were eluted from the
BioRex-70 column with 5 mL of 1 N HCl, and lyophilized. The
dry sample was then dissolved in 0.1 mL of water plus 4 µL of 70%
(w/w) thioglycolic acid and heated at 95°C for 3 h to reduce the
sulfoxide to [35S]MTP-amine. Excess thioglycolate was
removed by lyophilization. Methylation of [35S]MTP-amine
gave [35S]DMSP-amine, which was isolated by thin-layer
chromotography (TLC; Kocsis et al., 1998). The radiochemical yield of
[35S]DMSP-amine was 40%. Radiochemical purity was >98%
as determined by TLC and TLE. The inclusion of the thioglycolate
reduction step almost doubled the [35S]DMSP-amine yield
compared to the procedure described previously (Kocsis et al.,
1998).
Enzyme Extraction
Tissue was pulverized in liquid N2 and thawed in
extraction buffer (2 mL g1 fresh weight). Unless
otherwise stated, the extraction buffer for SDC (final pH of 7.2) was
50 mM potassium-phosphate, 5 mM dithiothreitol,
1 mM Na2EDTA, 0.1 mM PLP, and 5 mM L-ascorbic acid. The extraction buffer for
DOX was the same except that the pH was 8.0 and PLP was omitted.
Subsequent steps were at 4°C. The homogenate was centrifuged
(10,000g for 10 min) and the supernatant was desalted
using PD-10 columns (Amersham-Pharmacia Biotech, Uppsala) that were
equilibrated and eluted with extraction buffer for SDC or with
extraction buffer minus ascorbate (desalting buffer) for DOX. The
desalted extracts were clarified by centrifugation (16,000g for 5 min) and concentrated about 10-fold with
Centricon-30 units (Amicon, Beverly, MA). In some cases samples were
then frozen in liquid N2 and stored at 80°C, which did
not affect enzyme activity. Protein was estimated by the Bradford
(1976) method using bovine serum albumin as standard.
Enzyme Assays
Assays were carried out at 23°C to 25°C. Radiochemical
assays were agitated gently on a rotary shaker. No spontaneous
breakdown of labeled substrates occurred during the assays. Unless
otherwise noted, SDC was assayed in extraction buffer (pH 7.2) with 36 to 50 µM L-[1-14C]SMM using
25-µL reactions and a 75-min incubation time. Assays were carried out
in 12- × 75-mm glass tubes closed by a rubber serum stopper to which a
CO2 trap (a 1-cm Whatman number 3 paper disc containing 20 µL of 2 N KOH) was attached with a pin. Reactions were
stopped by injecting 100 µL of 10% (w/v) trichloroacetic acid, and
incubated for 1 h to maximize transfer of
14CO2 to the trap. The trapped
14CO2 was quantified by scintillation counting
after letting chemiluminescence subside. The trapping efficiency was
determined to be 98% using [14C]formate and formate
dehydrogenase (Sigma F-5632). SDC activity data were corrected
accordingly. SDC activity in potassium-phosphate buffer was twice that
in bis(2-hydroxyethyl) iminotris(hydroxymethyl) methane-HCl
(Bis-Tris-HCl), N-(2-hydroxyethyl)
piperazine-N'-(2-ethanesulfonic) acid-KOH
(HEPES-KOH), or 3-(N-morpholino) propanesulfonic acid (MOPS-KOH).
Except where noted, DOX was assayed in desalting buffer (pH 8.0)
containing 1 mM [35S]DMSP-amine (2-6 kBq)
and 1 to 2 × 103 units of bovine liver catalase
(Sigma C-40) per assay. The reaction volume was 25 µL in a system
like that used for SDC assays except that the stopper was Teflon-lined
and the paper disc contained 20 µL of 30%
H2O2 to trap [35S]DMS. Routine
assays were run for 75 min, stopped by injecting 25 µL of 17% (w/v)
NaOH, and incubated for 1 h to maximize breakdown of reaction
products to [35S]DMS and transfer of
[35S]DMS to the trap. 35S was quantified by
scintillation counting. Trap efficiency was determined to be 97% using
base-mediated decomposition of [35S]DMSP as the
[35S]DMS source (White, 1982; Reed, 1983). DOX activity
data were corrected accordingly. To analyze the labeled products of the assay prior to their decomposition by NaOH, reaction mixtures were
fractionated as described below. To remove O2, 100 mM  -D-(+)-Glc plus Glc oxidase (Sigma
G-9010, 500 units per assay) were added and catalase was omitted. DOX
activity was at least as high in potassium-phosphate buffer as in other
buffers tested (the ranking was potassium-phosphate = HEPES-KOH > Bis-Tris-propane-HCl > Bis-Tris-HCl).
Catalase assays (final volume of 1 mL) contained 65 mM
potassium-phosphate, pH 7.0, 0.036% (w/v)
H2O2, and 1 µL of extract. The reaction was
monitored by the decrease in A240. MDH
assays (0.8 mL) contained 0.1 M Tris-acetate, pH 8.0, 0.2 mM NADH, 2.5 mM oxaloacetate, and 1 µL of
extract. Oxaloacetate-dependent NADH oxidation was measured by the fall
in A340.
DMSP-Amine:CO2 Stoichiometry in the SDC Assay
To measure both DMSP-amine and CO2 formation,
L-[U-14C]SMM was used as substrate,
14CO2 was trapped as above, and
[14C]DMSP-amine was isolated and quantified as follows.
After adding unlabeled DMSP-amine and SMM carriers (0.1 µmol each),
reaction mixtures were fractionated using 1-mL AG-1 (OH)
and BioRex-70 (H+) columns arranged in series. Both columns
were washed with water. DMSP-amine and SMM were then eluted from the
BioRex-70 column with 5 mL of 1 N HCl and the eluate was
lyophilized. DMSP-amine was separated from SMM using TLC system 1 (James et al., 1995), detected by autoradiography, and quantified by
scintillation counting. The recovery of DMSP-amine was determined to be
61% by spiking unlabeled reaction mixtures with
[35S]DMSP-amine. This value was used to correct
[14C]DMSP-amine data.
Analysis of Labeled Products in the DOX Assay
To analyze DMSO, DMSP, and DMSP-amine, DOX reaction mixtures
(not treated with NaOH) were mixed with DMSP, DMSO, and DMSP-amine carriers (0.2-1 µmol) and fractionated on 1-mL columns of AG-1 (OH), BioRex-70 (H+), and AG-50
(H+) arranged in series. Each column series was washed with
10 mL of water. The effluent contained DMSO. DMSP-amine was eluted from BioRex-70 with 5 mL of 1 N HCl and DMSP from AG-50 with 5 mL of 2.5 N HCl. Samples of the effluent and eluates were
counted. When only [35S]DMSP and [35S]DMS
were analyzed, a 1-mL mixed resin (AG-1 [OH]:BioRex-70
[H+], 2:1, v/v) column replaced the corresponding
separate columns. Recoveries were determined by spiking unlabeled
reactions with [35S]DMSP, [35S]DMSO, or
[35S]DMSP-amine, and experimental data were corrected
accordingly. The identity of [35S]DMSP was authenticated
using TLC system 1 and TLE system 1 of James et al. (1995).
| |
FOOTNOTES |
Received February 4, 2000; accepted April 4, 2000.
1
This work was supported by the National Science
Foundation (grant no. IBN-9816075), by an endowment from the C.V.
Griffin, Sr., Foundation, and by the Florida Agricultural Experiment
Station. This paper is journal series number R-07371.
*
Corresponding author; e-mail adha{at}gnv.ifas.ufl.edu; fax
352-392-6479.
| |
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ABSTRACT
INTRODUCTION