(Received for publication, December 10, 1996, and in revised form, February 11, 1997)
From the Departments of Foods and Nutrition and
¶ Medicinal Chemistry and Molecular Pharmacology, Purdue
University, West Lafayette, Indiana 47907 and § University
of Geneva, Geneva, Switzerland
Plasma membranes of plant cells are characterized
by a plant hormone (auxin)-responsive oxidation of NADH. The
latter proceeds under argon. Also, when NADH oxidation is stimulated
50% by auxin addition, oxygen consumption is reduced by 40%. These
findings are reconciled by direct assays using
5,5-dithiobis-(2nitrobenzoic acid) (DTNB) (Ellman's
reagent) that show protein disulfides to be electron acceptors for
auxin-stimulated NADH oxidation. In the presence of an external
reducing agent such as NADH, cysteine, or dithiothreitol, protein
disulfides of the membrane are reduced with a concomitant
stoichiometric increase in free thiols. In the absence of an external
reducing agent, or in the presence of oxidized glutathione,
DTNB-reactive thiols of the plasma membrane are decreased in the
presence of auxins. Several auxin-reductant combinations were
effective, but the same reductants plus chemically related and
growth-inactive auxin analogs were not. A cell surface location of the
affected thiols demonstrated with detergents and impermeant thiol
reagents suggests that the protein may have a different physiological
role than oxidation of NADH. For example, it may carry out some other
role more closely related to the function of the auxin hormones in cell
enlargement such as protein disulfide-thiol interchange.
Brightman et al. (1) described an NADH oxidative
activity of the plant plasma membrane that was stimulated by the active auxins 2,4-dichlorophenoxyacetic acid
(2,4-D),1 indole-3-acetic acid (IAA), and
-naphthaleneacetic acid (
-NAA). The activity was unaffected by
benzoic acid and the structurally related but inactive auxin analogs
2,3-dichlorophenoxyacetic acid (2,3-D) and
-naphthaleneacetic acid
(
-NAA) (2). Subsequently, the activity was correlated with plant
cell elongation using thiol reagents as inhibitors of both
auxin-induced cell elongation and the auxin-stimulated oxidation of
NADH (3). Both were inhibited by N-ethylmaleimide,
p-chloromercuribenzoate, 5,5
-dithiobis-(2-nitrobenzoic acid) (DTNB), reduced glutathione (GSH), or dithiothreitol (DTT).
In the absence of auxin, the oxidation of NADH by plasma membranes of soybean hypocotyls was accompanied by an approximately stoichiometric consumption of oxygen (ratio of NADH reduced to 0.5 O2 consumed of 1) (4). However, when oxygen consumption was measured following stimulation of NADH oxidation by 2,4-D, not only was oxygen consumption no longer stoichiometric, it was less than that measured in the absence of 2,4-D (5). Therefore, alternative electron acceptors in the membrane for the 2,4-D-stimulated activity were sought.
Preliminary indications favored disulfides of membrane proteins (5). Plasma membrane vesicles were subsequently found to catalyze a protein disulfide-thiol interchange activity that was auxin-responsive (6). Both the latter and the auxin-stimulated NADH oxidase were sensitive to inhibition by brefeldin A (7). Based on this and other evidence, it was suggested that the two activities (auxin-stimulated NADH oxidation and auxin-stimulated protein disulfide-thiol interchange) might be catalyzed by the same protein of the plasma membrane. In keeping with that suggestion, experiments were conducted to determine if auxin treatment of isolated plasma membrane vesicles would lead to net changes in the thiol or disulfide content of the isolated plasma membranes vesicles. An auxin (2,4-D or IAA)-induced increase in thiols and decrease in disulfides of the plasma membrane were observed in the presence of NADH, cysteine and DTT but less so with GSH. The changes modulated by 2,4-D in the thiols and disulfides in the presence of NADH occurred in stoichiometric proportions to the reducing equivalents coming from NADH. The results suggest that protein disulfides serve as acceptors for NADH reduction by plasma membrane vesicles. The physiologically relevant function of the activity at the cell surface, however, may be the more general catalysis of disulfide-thiol interchange among membrane proteins that occurs in the absence of NADH (6).
Seeds of soybean (Glycine max L. Merr., cv. Williams 82) were soaked 4-6 h in deionized water, planted
in moist vermiculite, and grown 4-5 days in darkness at 20-22 °C
in foil-covered 18 cm × 23 cm × 10-cm plastic boxes or
enamel trays normally without supplemental additions of water. One- or
two-cm long segments, cut 5 mm below the cotyledons, were harvested
under low laboratory lighting (0.15 µmol of photons s1
m
2) and used for elongation measurements (1-cm long
segments) or isolation of plasma membranes (2-cm long segments).
Hypocotyl segments 2 cm long,
cut just below the cotyledon, were harvested and placed in cold water.
The segments (40 g) were chopped with razor blades in 40 ml of
homogenization buffer (0.3 M sucrose, 50 mM
Tris-Mes (pH 7.5), 10 mM KCl, 1 mM
MgCl2. The homogenate was filtered through one layer of
Miracloth (Chicopee Mills, New York, NY) and centrifuged for 10 min at
6,000 × g (HB-rotor). The supernatant was
recentrifuged at 60,000 × g (Beckman SW 28 rotor) for
30 min, and the pellets were resuspended in 0.25 M sucrose
with 5 mM potassium phosphate (pH 6.8). Plasma membrane vesicles were prepared using a 16- g aqueous two-phase
partitioning system (8). Resuspended 60,000 × g
pellets were mixed with 6.4% (w/w) polyethylene glycol 3350 (Fisher),
6.4% (w/w) dextran T500 (Pharmacia), 0.25 M sucrose, and 5 mM potassium phosphate (pH 6.8). After mixing the tubes by
40 inversions, the phases were separated by centrifugation at 750 × g for 5 min. The lower phase was repartitioned with a
fresh upper phase, and the two upper phases were repartitioned twice
with fresh lower phases. The upper phases were diluted approximately
4-fold with buffer, and the membranes were collected by centrifugation
at 100,000 × g for 30 min. The membranes were assayed
fresh (in Figs. 1 and 3 and Table I) or prepared and stored frozen at
70 °C (all other tables and figures) prior to assay. The yield was
1-2 mg of plasma membrane protein.
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The assay for the plasma membrane
NADH oxidase was in 50 mM Tris-Mes buffer (pH 7.0), 150 µM NADH in the presence of 1 mM potassium
cyanide, the latter to inhibit any mitochondrial NADH oxidases
contaminating the plasma membranes and 0.25 mg of plasma membrane
protein. The reaction was monitored by the decrease in the absorbance
at 340 nm using a Hitachi model U3210 spectrophotometer. The change of
absorbance was recorded as a function of time by a chart recorder. The
specific activity of the plasma membrane was calculated using an
absorption coefficient of 6.21 mM1
cm
1.
Assays were initiated by addition of NADH. Following the addition of NADH and for each subsequent addition, the assays were continued for 10 min with the steady state rates between 5 and 10 min being reported.
Incubation of Plasma Membrane Vesicles with 2,4-DPlasma membranes (600 µg) resuspended in 200 µl of homogenization medium were incubated with or without 1 or 10 µM 2,4-D for 0, 10, 20, or 30 min at room temperature (23-25 °C). At the times indicated, aliquots of 50 µl were removed and centrifuged immediately for 3 min at 15,000 × g (Eppendorf model 5414). The supernatants were removed, and the tube completely drained of liquid. Thiols or disulfides were determined as follows.
Determination of Thiols Using DTNB (or Ellman's Reagent)Plasma membranes (150 µg) resuspended in the
incubation medium or in water following centrifugation as described
above to recover the plasma membranes were combined with 50 µl of 10 mM DTNB and incubated 20 min at room temperature. The
membranes were then diluted with 2.5 ml of 0.1 M sodium
phosphate, pH 8.0. Absorbance was determined using a Shimadzu UV-160
(Columbia, MD) double wavelength spectrophotometer at 412 nm with
reference at 520 nm. Thiol content was estimated from a cysteine
standard curve determined in parallel for each assay. Values for
control samples without membranes were equivalent to the reagent blank.
The absorbance of the reagent blank (= control samples) was subtracted
for each set of determinations. Standards were unchanged over a 30-min
incubation with or without 2,4-D. Absorbance of preparations heated at
80 °C for 10 min did not change over time in response to NADH, for
example, either in the presence or absence of 2,4-D. Thiol content of
lower phase membranes depleted in plasma membrane vesicles did not
respond to 2,4-D over 20 min of incubation. Results were expressed as nanomoles of thiol/mg of protein based on a cysteine standard. For
Figs. 1 and 3, reagent and plasma membrane blanks were subtracted to
approximate absolute initial thiol levels exposed to DTNB at the cell
surface on a protein basis (5.5 ± 0.5 nmol/mg protein). On a
molar basis, the content of membrane surface disulfides approximated that of membrane thiols (i.e. 5.5 ± 0.5 nmol/mg of
protein). For the tables and figures where time-dependent
changes in thiols were measured (Figs. 2, 5, and 7-9) values at
t = 0 were subtracted to facilitate comparisons among
experiments on a protein basis. Table I was with a 1992 seed lot. Figs.
1 and 3 were with 1991 seeds. Figs. 2 and 8 and Table III were with
1994 seeds. The remaining tables and figures were with seeds from
1993.
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The procedure for disulfide determination was as outlined above with the exception that the plasma membranes (150 µg) were combined with 2.5 ml of NTSB assay solution and incubated for 25 min at room temperature according to Thannhauser et al. (9). The NTSB stock solution was prepared as follows. 0.1 g of DTNB was dissolved in 10 ml of 1 M Na2SO3 at 38 °C, and the pH was adjusted to 7.5. Oxygen was bubbled through the solution for 10 h. The assay solution was prepared by diluting the stock solution 1:100 with a solution containing 0.2 M Tris, 0.1 M Na2CO3, and 3 mM EDTA. The pH was adjusted to 9.5. Increase of absorbance upon liberation of NTSB was measured at 412 nm and expressed as nanomoles of disulfide/mg of protein. Disulfide content was estimated from a cystine standard curve determined in parallel for each assay. Values at t = 0 were subtracted.
ProteinProtein content was determined by the BCA procedure (10). Standards were prepared with bovine serum albumin.
Unlike those NADH oxidase activities where oxygen is the acceptor of electrons, the 2,4-D-stimulated oxidation of NADH by isolated vesicles of plasma membrane prepared from etiolated hypocotyls of soybean was unaffected or even stimulated by an argon or nitrogen atmosphere (Table I). A lack of inhibition by cyanide has served as an important criterion to distinguish the plasma membrane oxidase from that of mitochondria where NADH oxidation is cyanide sensitive. Purging the cuvette of oxygen or use of oxygen-purged solutions in combination with an argon or nitrogen atmosphere reduced but did not eliminate NADH oxidation as with an argon or nitrogen atmosphere alone.
Oxygen Consumption Decreased as NADH Oxidation Is IncreasedMeasurements of oxygen consumption using an oxygen electrode (11) also were indicative of some acceptor other than oxygen being responsible for the activity stimulated by auxin. While there was an approximately stoichiometric basal rate of NADH oxidation and oxygen consumption, the stoichiometry was not maintained upon auxin addition. Upon auxin addition, NADH oxidation was increased by approximately 50% whereas oxygen consumption was decreased by 40% (Table II). The activity was resistant as well to 150 µM salicylhydroxamic acid, an inhibitor of the alternate cyanide resistant pathway of NADH oxidation in plant mitochondria (12).
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Direct determinations of
thiols using DTNB (or Ellman's reagent) in response to treatment with
1 µM 2,4-D from a series of repeated measurements with
isolated plasma membrane vesicles are summarized in Table
III. After 10 min of 2,4-D treatment with plasma membranes incubated without thiol reagents, the thiol content was
reduced significantly by the 2,4-D treatment (Table III). However, if
DTT was present, the thiol content of the plasma membranes increased in
response to 2,4-D (Table III). In the presence of dithiothreitol, the
optimum concentration of 2,4-D to induce the thiol increase was found
to be in the range of 1 to 10 µM (Fig. 1).
The weak auxin analog 2,3-D was without effect at 1 µM as was 1 µM of a weak acid, benzoic acid, lacking auxin
activity (Table III). The relatively high absolute thiol content
recorded in these experiments may be attributed at least in part to the use of vesicles that had been frozen and thawed. Similar results were
obtained comparing the growth-active auxin analog -NAA and the
growth-inactive auxin analog
-NAA (Table IV). Thiols
were decreased by
-NAA in the absence of reductant and increased by
-NAA in the presence of 0.1 mM NADH. In contrast,
-NAA was without effect on membrane thiols in both the presence or
absence of NADH.
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In the absence of DTT, the decrease in thiols in response to 2,4-D (10 µM) was rapid and sustained for about 20 min (Fig. 2A). In the presence of DTT, the 2,4-D
resulted in an increase in thiols that also was sustained for at least
20 min (Fig. 2B). Relative to controls (no 2,4-D), the net
increase in thiols in response to 2,4-D was 5.5 nmol/mg of protein over
20 min. Overall, membrane thiols did increase with dithiothreitol
treatment including inclusion of dithiothreitol in the incubation
medium. However, the differences were small (3 nmol/mg of protein)
and the 2,4-D response was not affected by DTT preincubation compared
with simultaneous DTT plus 2,4-D pretreatment.
The thiols appeared to be those accessible to DTNB at or near the membrane surface (Fig. 3). The increase in thiols in response to 2,4-D plus 10 µM DTT was essentially unchanged as the membranes were incrementally treated by concentrations of 0, 0.1, and 1% Triton X-100. In contrast, total thiols reactive with DTNB were incrementally increased by the treatment with detergent. Triton X-100 was determined to not interfere in the thiol assay over the range of concentrations reported in Fig. 3. The plasma membrane vesicles used in these studies were 50 to 70% right side-out based on measurements of ATP latency.
The membrane impermeant thiol reagent
p-chloromercuriphenylsulfonic acid was employed to test for
a functional involvement of cell surface thiols in 2,4-D-induced cell
enlargement (Fig. 4). The reagent was without
significant effect on the growth of soybean hypocotyl segments in the
absence of 2,4-D but preferentially inhibited the increment of growth
induced by 2,4-D (Fig. 4). These observations support the detergent
observations of Fig. 3, which, when taken together, suggest that the
thiol groups increased by 2,4-D and involved in the growth process are
located near the external surface of the plasma membrane.
Protein Disulfides Decreased by Treatment with 2,4-D and Electron Donor in Proportion to the Increase in Protein Thiols
When protein disulfides were estimated by use of NTSB according to the method of Thannhauser et al. (9), the plasma membrane levels of protein disulfides decreased linearly with NADH addition in the presence of 2,4-D (Fig. 5B) in approximate inverse proportion to the thiol content (Fig. 5A). In the presence of NADH, both the auxin-stimulated increase in protein thiols of the plasma membrane vesicles (Fig. 5A) and an auxin-stimulated decrease in protein disulfides of the plasma membrane vesicles (Fig. 5B) were proportional to time of incubation over 30 min.
With NADH present, the net increase in thiols in response to 10 µM 2,4-D in the presence of NADH was 13.4 nmol/mg of
protein over 20 min. The response due to 2,4-D in the
absence of reductant over 20 min was 13.0 nmol/mg of protein compared
with no 2,4-D (Table V). The net change in thiols in response to NADH
for the 2,4-D-treated vesicles was therefore 26.4 nmol/mg of protein/20 min or 1.32 nmol/min/mg of protein. The rate of 1.2 nmol/min/mg of
protein of Table VI was calculated in a similar manner.
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With NADH present, the average rate of disappearance of disulfides of the plasma membrane vesicles in response to 2,4-D was 0.6 nmol/min/mg of protein over 20 min. This rate compared closely to the rate of 2,4-D-stimulated oxidation of NADH measured in parallel (Table VI). By comparison, the rate of thiol appearance stimulated by NADH and 2,4-D (e.g. Fig. 5A) was approximately 1.2 nmol/min/mg of protein over 20 min of incubation (Table VI) above the rate with no addition (e.g. Fig. 2A).
In the presence of 0.1 mM NADH, the 2,4-D-induced increase
in protein thiols was proportional to plasma membrane protein (Fig. 6). Thiol formation over 30 min of incubation stimulated
by 2,4-D occurred as well in the presence of cysteine (Fig.
7B).
The Natural Auxin, Indole-3-acetic Acid, Like 2,4-D, Stimulates Thiol Reduction in the Presence of NADH but Not in Its Absence
As with 2,4-D, a decrease in plasma membrane thiols was observed with 10 µM of the natural auxin IAA in the absence of an external reducing agent (Fig. 8A). However, in the presence of NADH, IAA resulted in a net increase in thiols of the isolated plasma membrane vesicles compared with no IAA (Fig. 8B). The magnitude of the response to 10 µM IAA was similar to that observed for 10 µM 2,4-D. The experiments of Fig. 8 with IAA and NADH were conducted in parallel to those of Fig. 2 with 2,4-D and DTT and the results were similar.
Reduced and Oxidized Glutathione Exert Opposing EffectsIn
the presence of GSH, disulfides were decreased by 2,4-D (Fig.
9E) and accompanied by a corresponding net
increase in thiols (Fig. 9B) compared with no addition (Fig.
9A). GSSG had an opposite effect (Fig. 9, C and
F) similar to that observed in the absence of GSH (Fig. 9,
A and D). With a mixture of 0.1 mM
GSH plus 0.1 mM GSSG, neither the thiol nor the disulfide
content of the membranes was affected by 2,4-D (data not shown).
Stoichiometry of Disulfide Reduction and NADH Oxidation
The
stoichiometry of the 2,4-D-induced changes in surface membrane thiols
and disulfides on a protein basis for a 20-min incubation period
comparing all experiments is provided in Tables V and VI. With no
reductant or in the presence of GSSG, the 2,4-D-induced change was
13.3 ± 2.5 nmol/mg of protein compared with an average increase
in half disulfides of 12 nmol/mg of protein (Table V). For NADH, the
increase in thiols induced by 2,4-D was 13.4 ± 2.4 nmol/mg of
protein compared with a decrease in half disulfides of 17 nmol/mg of
protein. The increase in thiols with DTT of 7.0 ± 1.9 nmol/mg of
protein was about half that with cysteine or NADH. Within the error of
the determinations the 2,4-D-stimulated decrease in NADH accounts
quantitatively for the auxin-stimulated disappearance of disulfides of
membrane proteins and for a two-electron transfer to account for
appearance of thiols of membrane proteins (Table VI).
An NADH oxidative activity of unknown function has been observed in plasma membrane of soybeans as an activity with a 2,4-D-responsive component (1, 2). A component of the basal activity was first thought to represent an NADH-ascorbate free radical oxidoreductase (13). However, the auxin-responsive component of the activity (6 nmol/min/mg of protein out of 30 nmol/min/mg of protein in the presence of monodehydroascorbate) was observed in the absence of either added ascorbate or added dehydroascorbate (13). Thus, the auxin-responsive activity represented NADH oxidation with some constituent other than the ascorbate radical as electron acceptor. The activity was subsequently purified by Brightman et al. (1). The constitutive oxidation of NADH, but not the auxin-responsive activity, was observed to be slowed but not eliminated by an argon atmosphere free of oxygen (4). The stoichiometry of NADH reduced to 0.5 O2 consumed for the constitutive activity was near unity (4). In contrast to the constitutive activity, the 2,4-D-stimulated oxidation of NADH was subsequently shown to be unaffected by an argon atmosphere and not accompanied by a corresponding increase in oxygen consumption (5). Surprisingly, oxygen consumption was actually inhibited by auxin (5) (Table II).
The above observations led to considerations of substrates present in the membrane other than oxygen that might serve as electron and proton acceptors for the auxin-stimulated activity. One possibility suggested by present observations is disulfides of plasma membrane proteins. Morré (14) and Spring et al. (15) had earlier observed that protein thiols increased in response to auxin but experiments with isolated plasma membrane vesicles were lacking. A role of the auxin-stimulated NADH oxidase in disulfide reduction also would be consistent with experiments where the auxin-stimulated activity was shown to be inhibited by thiol reagents (3, 16). Additionally, soybean plasma membranes were found to exhibit an auxin-stimulated restoration of activity to inactive scrambled RNase. Here, activity was restored as interchain disulfides were reformed under conditions of reduction followed by reoxidation under non-denaturing conditions (6).
Determination of thiols employed Ellman's reagent (DTNB) (17) in which a yellow color was formed in proportion to free thiols accessible to DTNB. As the plasma membrane vesicles were at least 70% right side-out based on measurement of ATP latency, only about 15% of the total membrane thiols were accessible to DTNB in the absence of Triton X-100 with freshly prepared vesicles (Fig. 3). Thus the 2,4-D-responsive thiols appeared at the cell surface in agreement with the observations of Spring et al. (15). This conclusion was further supported by observations with the membrane impermeant thiol reagent, p-chloromercuriphenylsulfonic acid, where auxin-induced growth was preferentially inhibited compared with control growth. A logarithmic dependence on concentration of auxin was obtained. The optimum auxin concentrations of 1-10 µM corresponded to the concentrations optimal for stimulation of NADH oxidation and of plant cell elongation (2).
Both GSH and GSSG were found previously to alter the NADH oxidase activity (3) and the protein disulfide-thiol interchange activity stimulated by auxin (6). In short term assays when preincubated with plasma membranes GSH inhibited, whereas GSSG did not (Fig. 3C and Fig. 5 of Ref. 6). These results were interpreted as indicating that the activity under investigation was not a classic protein disulfide isomerase as encountered in the lumen of the endoplasmic reticulum but rather a protein disulfide interchange activity perhaps unique to the plasma membrane. Thiol reductases are known for bacteria and protozoans (18) but, unlike our activity, usually drive the reduction of oxidized glutathione. The decrease in membrane thiols that occurs in response to auxin treatment in the absence of a reducing agent would presumably result from thiol use as a reductant stimulated by auxin. However, the electron acceptor for this reaction has not been identified.
The role of NADH remains problematic since it appears that the SH reagents and perhaps even auxin are affecting thiols and disulfides at the outer face of the plasma membrane. It is unlikely that a reducing agent, even ascorbate, is present in the wall space at millimolar concentrations in elongating stems. Therefore the external NADH oxidase activity is unlikely to represent a conventional NADH oxidase. If the activity does, in fact, represent a protein disulfide thiol interchange, then the use of external NADH to measure the auxin-stimulated activity need not represent a normal flow of electrons from cytoplasm to cell surface but rather a convenient method of assay as a NADH: protein disulfide reductase although we do not rule out the suggestion of Bienfait and Lüttge (19) and Møller and Crane (20), that one of the functions of their proposed plasma membrane redox chain may be to reduce thiol groups of membrane proteins.
With isolated plasma membrane vesicles, auxin-stimulated thiol formation, disulfide disappearance and NADH oxidation were stoichiometric over 20 min of auxin treatment. These relationships support the contention that the membrane acceptor for the auxin-stimulated oxidation of NADH by isolated vesicles of soybean may be disulfides of membrane proteins as indicated initially from inhibitor data (3, 16) and measurements of oxygen consumption (5). The findings do not eliminate the possibility that the electron acceptor for the constitutive basal NADH oxidase activity of soybean plasma membranes may be oxygen or some combination of oxygen and protein disulfides. In this regard, auxin might act as a switch causing the plasma membrane NADH oxidase to favor reduction of protein disulfides over oxygen (5, 16). Evidence for disulfide reduction, as one manifestation of a potentially more general role in protein disulfide-thiol interchange, may provide a mechanism to eventually help explain the physiological function of the auxin-stimulated activity in auxin-regulated plant cell enlargement.