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Plant Physiol. (1998) 118: 1317-1326
Comparison of Binding Properties and Early Biological Effects of
Elicitins in Tobacco Cells1
Stéphane Bourque,
Michel Ponchet,
Marie-Noëlle Binet,
Pierre Ricci,
Alain Pugin, and
Angela Lebrun-Garcia*
Unité Associée Institut National de la Recherche
Agronomique-Université de Bourgogne no. 692, Laboratoire de
Phytopharmacie et Biochimie des Interactions Cellulaires, BV 1540, 21 034 Dijon cedex, France (S.B., M.-N.B., A.P., A.L.-G.); and Station de
Botanique et de Pathologie Végétale, Institut National de
la Recherche Agronomique, Villa Thuret, BP 2078, 06 606 Antibes cedex,
France (M.P., P.R.)
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ABSTRACT |
Elicitins are a family of small
proteins secreted by Phytophthora species that have a
high degree of homology and elicit defense reactions in tobacco
(Nicotiana tabacum). They display acidic or basic
characteristics, the acidic elicitins being less efficient in inducing
plant necrosis. In this study we compared the binding properties of
four elicitins (two basic and two acidic) and early-induced signal
transduction events (Ca2+ influx, extracellular medium
alkalinization, and active oxygen species production). The affinity for
tobacco plasma membrane-binding sites and the number of binding sites
were similar for all four elicitins. Furthermore, elicitins compete
with one another for binding sites, suggesting that they interact with
the same receptor. The four elicitins induced Ca2+ influx,
extracellular medium alkalinization, and the production of active
oxygen species in tobacco cell suspensions, but the intensity and
kinetics of these effects were different from one elicitin to another.
As a general observation the concentrations that induce similar levels
of biological activities were lower for basic elicitins (with the
exception of cinnamomin-induced Ca2+ uptake). The
qualitative similarity of early events induced by elicitins indicates a
common transduction scheme, whereas fine signal transduction tuning is
different in each elicitin.
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INTRODUCTION |
Elicitins are a family of proteins excreted by
Phytophthora spp., a group of widespread and highly damaging
pathogenic fungi (Ricci et al., 1993 ; Yu, 1995). These proteins have
the property to elicit defense responses in tobacco (Nicotiana
tabacum), triggering a hypersensitive response and systemic
resistance to further inoculation (Bonnet et al., 1996; Keller et al.,
1996). These 98 amino acid proteins show more than 60% sequence
identity with each other. They are devoid of posttranslational
modifications and possess six invariant Cys residues that account for
three disulfide bridges, which were first established in capsicein, an
elicitin secreted by Phytophthora capsici (Bouaziz et al.,
1994).
Circular dichroism experiments performed on four elicitins, cryptogein,
cinnamomin, parasiticein, and capsicein, together with capsicein
structure analysis by NMR, led to the conclusion that the elicitin
folding was mainly  -helical (Nespoulous et al., 1992; Bouaziz et
al., 1994). A recent study (Boissy et al., 1996) determined the crystal
structure of cryptogein, confirming the existence of three disulfide
bridges. These authors proposed a globular structure composed of six
-helices and a beak-like motif built from invariant residues,
forming an antiparallel, two-stranded  -sheet and an  -loop.
However, beyond these general structural features, elicitins have long
been classified into two groups according to their differences in net
charge, the acidic or -elicitins (pI between 3 and 5) and the basic
or -elicitins (pI between 7 and 9).
This classification correlates with the biological properties of
elicitins in tobacco plants. The amount of basic elicitins required to
induce leaf necrosis or protection against Phytophthora parasitica var nicotianae is 50- to 100-fold lower than
for acidic elicitins (Ricci et al., 1989; Nespoulous et al., 1992;
Pernollet et al., 1993; Bonnet et al., 1996). Necrotic activity was not the result of different migration rates or elicitin accumulation, since
125I-labeled elicitins (the basic cryptogein and
the acidic capsicein) showed the same distribution within the plant
(Devergne et al., 1992; Zanetti et al., 1992). Instead, this activity
should depend on the high number of Lys residues present in basic
elicitins, which contributed to their net charge. Particularly the
mutation of Lys-13 resulted in a decrease in necrotic activity
(O'Donohue et al., 1995).
The difference in biological activity between - and -elicitins,
which is associated with their structural properties, might be
correlated with one or several steps of the signal transduction pathway
induced in the target cells. It is generally assumed that a putative
receptor on the plasma membrane acts as the first component of the
transduction pathway, and then secondary messengers, membrane proteins, or cytosolic proteins such as protein kinases transduce the signal to activate plant-defense responses (Staskawicz et al.,
1995). Perception of elicitins by the target cell and transduction of
this signal should direct the physiological effects observed at the
plant level, emphasizing the importance of studying the initial steps
of the transduction pathway.
Among elicitins cryptogein has been extensively studied, and early
steps of its interaction with tobacco cells have been defined. Cryptogein high-affinity binding sites characterized on tobacco plasma
membrane preparations had properties consistent with receptor sites
(Wendehenne et al., 1995). Analysis of early events induced by this
elicitin were performed on tobacco cell suspensions.
Ca2+ influx (Tavernier et al., 1995b),
modifications of ion fluxes (H+,
K+, and Cl ; Blein et al.,
1991; Pugin et al., 1997), depolarization of the plasma membrane (Pugin
et al., 1997), production of AOS (Bottin et al., 1994), protein
phosphorylation (Viard et al., 1994), cytosol acidification
(Barbier-Brygoo et al., 1997; Pugin et al., 1997), and changes in gene
expression (Suty et al., 1996; Petitot et al., 1997) were rapidly
monitored after a few minutes of cryptogein treatment. Later, changes
in lipid composition (Tavernier et al., 1995a) and the production of
phytoalexin and ethylene were measured (Milat et al., 1991).
Protein phosphorylation and Ca2+ influx were the
earliest effects monitored after cryptogein-tobacco cell interaction.
Similar early effects were reported in other elicitor-plant cell
interactions. Tomato cells treated with a yeast-extract-derived
elicitor, a fungal xylanase elicitor, or chitin fragments produced an
increase in extracellular pH and rapid changes in protein
phosphorylation (Felix et al., 1991, 1994; Baureithel et al., 1994).
Changes in the permeability of the plasma membrane to different ions
(H+, Ca2+,
K+, and Cl) were among
the earliest events detectable after treatment of parsley cells with a
42-kD glycoprotein from Phytophthora megasperma (Nürnberger et al., 1994) or after treatment of tobacco cells with Pseudomonas syringae pv syringae
(Atkinson et al., 1990). Tobacco cells incubated with
oligogalacturonides developed rapid cytoplasmic acidification and
extracellular pH alkalinization, which depend on a phosphorylation
process (Mathieu et al., 1996a, 1996b). AOS production, which is often
correlated with plant defense reactions, is triggered by elicitors from
different organisms (Medhy, 1994) and is probably coupled to ion
flux modifications (Baker et al., 1993; Tavernier et al., 1995b). In
cryptogein-treated tobacco cells, AOS production depends on
Ca2+ influx. La3+, a
Ca2+-channel blocker, inhibited extracellular
alkalinization and AOS production (Tavernier et al., 1995b). Although
the mechanisms linking ion fluxes and AOS generation to the
elicitor-recognition step are not clearly defined, there was a tight
and close connection between elicitor perception and physiological
events.
In the present work we compared the binding properties of two acidic
elicitins (capsicein and parasiticein) and two basic elicitins
(cryptogein and cinnamomin) and studied their biological effects on
tobacco cell suspensions (Ca2+ influx,
alkalinization of the extracellular medium, and AOS production). We
wanted to determine whether elicitins share different affinities for
binding sites on tobacco plasma membranes, whether they have different
activities according to their biophysical and structural properties,
and whether the binding capacities may direct intensities of the early
responses of tobacco cells involved in signal transduction after the
recognition step.
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MATERIALS AND METHODS |
Plant Materials and Elicitors
Tobacco (Nicotiana tabacum cv Xanthi) plants were grown
in a greenhouse for 60 d. Cell suspensions were cultivated in
Chandler's medium (Chandler et al., 1972) on a rotary shaker (150 rpm,
25°C) under continuous light (photon flux rate 30-40 µmol
m2 s1). Cells were
maintained in the exponential phase and subcultured 1 d prior to
utilization. Elicitins were purified according to the method of Bonnet
et al. (1996).
Plasma Membrane Preparation
Purification of the plasma membrane was as previously described by
Wendehenne et al. (1995) using the aqueous partitioning procedure of
Widell et al. (1982). Tobacco microsomal fractions obtained from leaves
(400 g) homogenized in 800 mL of grinding medium (50 mM
Tris-Mes, pH 8.0, 0.5 M Suc, 20 mM EDTA, 10 mM DTT, and 1 mM PMSF) were added to an aqueous
polymer two-phase system with final concentrations of 6.6% (w/w)
dextran (Mr 500,000) and 6.6% (w/w) PEG
(Mr 3,350) in a PSK buffer (5 mM phosphate buffer, pH 7.8, 0.3 M Suc, and 3 mM KCl). Plasma membrane-enriched fractions were suspended
in 10 mM Tris-Mes, pH 6.5, 250 mM Suc, 1 mM PMSF, 2 mM MgCl2, and
20% glycerol and stored at  80°C. Protein content was measured
according to the method of Lowry et al. (1951). The low level of
contaminants in the plasma membrane preparations was confirmed using
marker enzymes (Larsson et al., 1994).
Binding Experiments
Iodination of elicitins was performed as previously described
(Wendehenne et al., 1995). One hundred micrograms of elicitin was
incubated for 20 min at 20°C in 100 µL of 0.1 M
phosphate buffer, pH 7.4, with 185 MBq Na125I
(specific activity 625 MBq/µg iodine; Amersham) and Iodogen (Pierce)
as the catalyst. Nonincorporated iodine was removed by gel filtration
using a Sephadex G-25 column equilibrated with 50 mM
Tris-HCl buffer, pH 7.4. Specific activity of radiolabeled elicitin was
about 9.25 TBq/mmol. Binding experiments were carried out as previously
described (Wendehenne et al., 1995), except for the binding medium (10 mM Hepes-KOH, pH 7.0, 5 mM
MgCl2, and 0.1 M Suc). Binding of
125I-elicitins on plasma membrane preparations
(50 µg of protein) was carried out on ice for 90 min after the
addition of the appropriate concentration of radiolabeled elicitin (and
10 µM unlabeled elicitin in assays for nonspecific
binding). Binding of 125I-elicitins was monitored
by filtration under a vacuum using GF/B glass-fiber filters (Whatman).
These filters were then washed three times with ice-cold binding buffer
containing 0.1% BSA. Radioactivity remaining on the filters was
measured in 5 mL of Ready-Safe cocktail (Beckman) with a gamma counter
(model LS 600 TA, Beckman). Competition experiments were performed
using 1011 to 104
M unlabeled elicitins and 10 nM labeled
elicitins.
Elicitor Treatment
Cells were collected during the exponential growth phase and
washed by filtration in a suspension buffer containing 175 mM mannitol, 0.5 mM
CaCl2, 0.5 mM
K2SO4, and 2 mM
Hepes adjusted to pH 5.75 with KOH (Keppler and Baker, 1989). Cells
were resuspended at 0.1 g fresh weight mL1
with suspension buffer and equilibrated for 2 h on a rotary shaker (150 rpm, 24°C). Tobacco cells were then used for determination of
extracellular pH changes, Ca2+ influx
measurements, and AOS production after treatment with 5 to 500 nM elicitin in aqueous solution. Control tobacco cells were
incubated under the same conditions without elicitins.
Ca2+ Influx Measurements
Ca2+ influx measurements were performed as
previously described (Tavernier et al., 1995b). Five minutes before the
treatment with elicitins, cell suspensions were incubated with
45Ca2+ (0.033 MBq
g1 fresh weight cells; Amersham). After
different periods of treatment, duplicate 2-mL aliquots were collected
and filtered under a vacuum on GF/A glass-fiber filters, washed once
for 1 min with 10 mL of ice-cold cell-suspension buffer containing 2 mM LaCl3, and then washed twice with
5 mL of the suspension buffer for 20 s. Cells remaining on filters
were collected, dried overnight at 70°C, weighed, and placed in
scintillation vials with 10 mL of Ready-Safe cocktail. Vials were
shaken overnight before counting in a scintillation counter.
Extracellular pH Changes and AOS Production
Extracellular pH changes were measured at 10-min intervals in
tobacco cell suspensions. AOS production was determined using chemiluminescence of luminol. Aliquots (250 µL) of cell suspensions were collected and mixed with 300 µL of 10 mM Hepes
buffer, pH 6.5, 175 mM mannitol, 0.5 mM
CaCl2, 0.5 mM
K2SO4, and 50 µL of 0.3 mM luminol. Chemiluminescence measured within a 10-s period with a luminometer (EG&G Wallac, Gaithersburg, MD) was integrated and
expressed in nanomoles of
H2O2 per gram fresh weight
of cells.
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RESULTS |
Binding Characteristics
Each elicitin was labeled with 125I with a
specific activity of about 9.25 TBq/mmol, which corresponds to the
radiolabeling of 12% of the molecules. This treatment did not modify
elicitin activities such as alkalinization of the extracellular medium
or AOS production (data not shown). Moreover, these activities were
unaffected when elicitins were derivatized with a least one
nonradioactive iodine per molecule (data not shown).
Binding experiments were performed by incubating 50 µg of plasma
membrane proteins with increasing concentrations (1-30 nM) of each 125I-elicitin (Fig.
1). Nonspecific binding on the plasma
membrane was similar for each elicitin, whereas when elicitins were
used at 10 nM specific 125I-elicitin
binding was between 2500 and 3500 cpm, depending on each
125I-elicitin specific activity. The saturation
curves were hyperbolic, with half-maximal binding concentrations at
about 10 nM. Scatchard plots gave straight lines,
indicating the presence of a single class of specific binding sites for
each elicitin (Fig. 1, insets). The Kd
values and the number of binding sites deduced from Scatchard plots are
shown in Table I. The
Kd of cryptogein (10.3 nM) was similar to that previously obtained in a Tris buffer
(Kd = 2 nM; Wendehenne et al.,
1995).
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| Figure 1.
Saturation curves obtained with labeled elicitins
and corresponding Scatchard plots (insets). Plasma membrane
preparations were incubated with various concentrations of
125I-cryptogein (A), 125I-cinnamomin (B),
125I-capsicein (C), or 125I-parasiticein (D).
Nonspecific binding was measured in the presence of a 10 µM concentration of the corresponding nonlabeled elicitin
and was subtracted from total binding to give the saturation curves.
Experiments were repeated at least three times. Results are means ± SD.
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Table I.
125I-elicitin binding characteristics in
tobacco plasma membranes
Specific binding was obtained by subtracting nonspecific binding from
total binding. Data were obtained from Scatchard plots deduced from
saturation curves and are the averages ± SD of three
experiments.
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The Kd for the other elicitins ranged from
5.8 to 13.5 nM, showing that the four elicitins,
independently of their acidic or basic properties, bound with the same
affinity to plasma membrane-binding sites. Furthermore, the number of
binding sites present on the plasma membrane was similar for each
elicitin (Table I). Specific binding as a function of pH and tested at
a pH range of 4.0 to 9.0 was optimum at pH 7.0 for each elicitin (Fig.
2). These results suggest that the four
elicitins bind to common sites through invariant amino acids.
Competition experiments were performed to verify this hypothesis.
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| Figure 2.
pH dependence of the specific binding of
125I-elicitins on tobacco plasma membrane preparations.
Fifty micrograms of plasma membrane proteins was incubated with 10 nM 125I-cryptogein
( ),125I-cinnamomin ( ), 125I-capsicein
( ), or 125I-parasiticein ( ) in the following buffers:
citrate-KOH (pH 4.0-6.0), Hepes-KOH (pH 6.5-8.0), and Tris-HCl
(pH > 8.0). Buffer strength was 10 mM. Specific
binding was expressed as a percentage of the maximal specific binding
measured for each elicitin. The experiment was repeated three times.
Each data point represents the average of triplicate measurements.
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Competition of Elicitins for Binding Sites
125I-cryptogein (10 nM) was
incubated with plasma membrane preparations in the presence of
increasing concentrations of unlabeled elicitins or elicitins
derivatized with nonradioactive iodine. The corresponding
IC50 values are reported in Tables
II and III. Results indicated that the four unlabeled elicitins compete with labeled cryptogein (10 nM) for specific binding sites: the
IC50 for unlabeled cryptogein, capsicein, or
parasiticein was similar. The IC50 for unlabeled
cinnamomin was 4 to 5 times higher than unlabeled cryptogein
IC50 (Table II). The reverse-competition experiments using the four labeled elicitins (10 nM each)
in competition with unlabeled cryptogein gave similar cryptogein
IC50 values whatever the elicitin, with only a
2-fold variation (Table II). In this experiment the IC50
values were comparable to those obtained when unlabeled elicitins were
competing with 125I-cryptogein.
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Table II.
Inhibition of 125I-elicitin specific
binding by noniodinated elicitins
IC50 values were determined from competition curves. Data
are the averages ± SD of three experiments.
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Table III.
Inhibition of 125I-cryptogein-specific
binding by elicitins after derivatization with nonradioactive
iodine calculated from competition curves
Data are from Figure 3 and represent the averages ± SD of three experiments.
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These results showed that elicitin-binding properties were comparable
and that elicitins were acting as competitors; however, these
IC50 values were higher than the expected values,
which should reach the Kd values. This
discrepancy could reflect different affinities of iodinated and
noniodinated elicitins for binding sites. Therefore, competition
experiments were also performed with increasing concentrations of
elicitins derivatized with nonradioactive iodine (Fig.
3; Table III). In these conditions the
IC50s for unlabeled iodinated elicitins were
similar (close to the Kd of the labeled elicitin), suggesting that iodinated elicitins were better competitors for the plasma-binding sites than noniodinated elicitin. Consequently, Kd values should better reflect the
iodinated elicitin affinities. However, all elicitins had a similar
shifted IC50 value when iodinated; therefore,
binding properties are comparable among the four elicitins, all of
which bind to the same specific binding sites with a similar affinity.
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| Figure 3.
Inhibition of 125I-cryptogein binding
to the plasma membrane by increasing concentrations of various
elicitins (competitor). Fifty micrograms of plasma membrane proteins
was incubated with 10 nM 125I-cryptogein and
increasing concentrations of cryptogein (), cinnamomin (),
capsicein (), or parasiticein (). Data are expressed as
percentages of the specific binding of 125I-cryptogein,
each point being an average of triplicate measurements.
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Extracellular Medium Alkalinization
Cell suspensions were treated with various concentrations of
elicitins (5-500 nM), and extracellular pH changes were
measured in the cell-suspension medium for 90 min (Fig.
4). The four elicitins induced an
extracellular pH increase. However, the kinetics and intensity of this
response were specific for each elicitin and depended on their
respective concentrations. For example, at a low concentration (10 nM) cryptogein induced a rapid and strong alkalinization of
the extracellular medium, reaching the half-maximum pH increase in less
than 10 min, whereas no significant or only slight pH changes were
measured during the first 10 min with the other elicitins. The
extracellular pH stabilized 40 to 60 min following elicitin treatment.
However, the pH plateau depended on the elicitin used and gradually
decreased in cinnamomin, parasiticein, and capsicein (in this order).
When the four elicitins were used at higher concentrations (100 nM) the maximal medium alkalinizations were similar after
treatment for 90 min, although initial rates for alkalinization were
0.085 pH unit min1 for cryptogein, 0.047 pH
unit min1 for capsicein and parasiticein, and
0.020 pH unit min1 for cinnamomin.
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| Figure 4.
Effects of increasing concentrations of elicitins
on extracellular pH of tobacco cell suspensions. Cells were treated
with cryptogein (A), cinnamomin (B), capsicein (C), or parasiticein
(D). Elicitin concentrations were 5 nM ( ), 10 nM (+), 25 nM ( ), 50 nM ( ), 75 nM (), 100 nM
(), 250 nM (), and 500 nM ().
Experiments were repeated three times. The figure corresponds to a
representative experiment.
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The lowest elicitin concentrations inducing the highest alkalinization
were about 10 nM for cryptogein and 50 nM for
cinnamomin, whereas those for the acidic elicitins were about 500 nM. These results show that basic elicitins were at least
10 times more efficient than acidic elicitins in inducing maximal
extracellular pH alkalinization.
Ca2+ Influx
Using 45Ca2+ as a
tracer we compared Ca2+ uptake induced by the
four elicitins at three concentrations: 10, 100, and 500 nM. These assays were performed in the incubation medium
used to monitor the alkalinization (low-buffered medium, pH 5.75). At
500 nM the four elicitins induced an uptake of
45Ca2+ (Fig.
5A). In the same experiments control
cells did not show any
45Ca2+ uptake. Cryptogein
was the most efficient elicitin, whereas the other elicitins induced a
similar but lower Ca2+ uptake. In a second
experiment Ca2+ influx was measured after
treatment for 1 h with increasing concentrations of elicitins.
Cryptogein was still the most efficient elicitin whatever the
concentration (Fig. 5B); the other elicitins were less efficient in
inducing 45Ca2+ uptake.
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| Figure 5.
Effect of various concentrations of elicitins on
45Ca2+ influx into tobacco cells. A, Time
course of 45Ca2+ uptake by tobacco cells after
treatment with 500 nM elicitins: cryptogein (),
cinnamomin (), capsicein (), and parasiticein (); control
cells () in a 2 mM Hepes low-buffered medium, pH 5.75. B, Effects of increasing concentrations of elicitins on
45Ca2+ uptake into tobacco cells after 1 h
of incubation with cryptogein (Cry), cinnamomin (Cin), capsicein (Cap),
or parasiticein (Para) in a 2 mM Hepes low-buffered medium,
pH 5.75. C, Time course of 45Ca2+ uptake by
tobacco cells after treatment with 100 nM elicitins:
cryptogein (), cinnamomin (), capsicein (), or parasiticein
(); control cells () in a 50 mM Hepes medium buffered
at pH 7.0. Each point corresponds to a duplicate assay. Results are
means ± SD. Specific activity of
45Ca2+ = 6.6 GBq/mol. FW, Fresh
weight.
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Because at pH 5.75 elicitins showed different relative specific
binding, Ca2+ uptake induced by elicitins at 100 nM was also measured in a 50 mM Hepes medium
buffered at pH 7.0, which corresponds to the optimum pH for the binding
of the four elicitins. Under these conditions we obtained results
comparable to those obtained at pH 5.75 (low-buffered medium; Fig. 5B),
with the exception of cinnamomin, which triggered a lower
Ca2+ uptake compared with the other elicitins.
Therefore, even when used at their optimum binding pH, the elicitins
triggered different Ca2+ uptakes (Fig. 5C).
AOS Production
AOS production was measured in response to increasing
concentrations of elicitins (5-500 nM). The four elicitins
induced AOS production in tobacco cell suspensions. Nevertheless, the
kinetics and the intensity of this production were specific for each
elicitin and depended on their concentration (Fig.
6). For example, 100 nM
cryptogein induced a rapid, strong burst of AOS after a 10-min treatment (about 1200 nmol
H2O2
g1 fresh weight cells), and then the production
of H2O2 decreased slowly.
When the other elicitins were used at 100 nM, the AOS production reached a similar maximal value, which was delayed (30-40
min) and did not decrease significantly in the following 1 h. When
lower concentrations of elicitins were used (10 nM) the
production of AOS induced by cryptogein reached almost the same maximum
value (1000 nmol H2O2
g1 fresh weight cells) after 10 min (Fig. 6).
The oxidative burst induced by 10 nM cinnamomin appeared
later (after 20 min) and had a lower intensity, whereas no significant
burst was measured with 10 nM capsicein and parasiticein.
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| Figure 6.
AOS production in tobacco cell suspensions (nmol
H2O2 g1 fresh weight cells)
treated with increasing concentrations of elicitins: 5 nM
(), 10 nM (+), 25 nM (), 50 nM (), 75 nM (), 100 nM
(), 250 nM (), and 500 nM (). Cells
were treated with cryptogein (A), cinnamomin (B), capsicein (C), or
parasiticein (D). The experiment was repeated three times. The figure
corresponds to a representative experiment. FW, Fresh weight.
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As previously observed with regard to the extracellular medium
alkalinization or the Ca2+ influx, cryptogein was
the most efficient elicitin: the highest AOS production was achieved
with 25 nM cryptogein, whereas 50 nM cinnamomin
or greater than 500 nM acidic elicitins were necessary to
obtain a maximal AOS production. AOS production was also measured to
verify whether competition between acidic and basic elicitins led to a
decrease of the effects of the most efficient basic elicitin. In vivo
competition experiments on tobacco cells were performed using 25 nM cryptogein and various concentrations of capsicein (Fig.
7). AOS production due to the cryptogein
treatment in the competition assay was scored by subtracting the AOS
production contributed by capsicein alone from the total AOS
production, at the concentration corresponding to that of the
competition experiment. Cryptogein-induced AOS production was decreased
by 40% when tobacco cells were simultaneously treated with 50 nM capsicein. With higher capsicein concentrations (100 and
250 nM) the AOS production induced by cryptogein was
reduced by about 80% to 90%, showing effective in vivo competition.
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| Figure 7.
In vivo competition experiment using 25 nM cryptogein and increasing capsicein concentrations. The
AOS production induced by 25 nM cryptogein was referred to
as 100%. AOS production due to cryptogein in competition experiments
was deduced by subtracting from the total AOS production the AOS
contribution of capsicein alone used at the concentration corresponding
to that used in the competition experiment. The AOS production was
measured after treatment for 15 min with elicitins.
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DISCUSSION |
In this study we compared the binding properties of four different
elicitins on tobacco plasma membrane preparations and their effects on
tobacco cells. The four elicitins produced by Phytophthora have a high degree of sequence conservation (74%) and should therefore have a similar structure (Bouaziz et al., 1994; Boissy et al., 1996).
Nevertheless, they are classified into acidic and basic elicitins based
on their pI. An elicitin necrotic index was established that correlated
with pI, and basic elicitins had high necrotic activity (Pernollet et
al., 1993). The different level of activities of elicitins should not
depend on their stability: elicitin uptake experiments in tobacco with
labeled cryptogein demonstrated high elicitin stability in vivo,
because the protein could be recovered in a nondegradated form 8 d
after the onset of treatment (Keller et al., 1996). Furthermore, the in
vitro stability of elicitins is a general property of these proteins
(resistance to boiling and to trypsin treatment; data not shown),
probably because of their similar structure.
Using two basic elicitins (cryptogein and cinnamomin) and two acidic
elicitins (capsicein and parasiticein), we examined several aspects of
their structure-function relationship. We first looked at
binding-affinity constants and found that all four
125I-labeled elicitins had a similar
Kd, ranging from 5.8 to 13.5 nM, and that the number of binding sites on the plasma
membrane was between 234 and 403 fmol/mg plasma membrane proteins
(Table I). These binding constants were very close to those previously determined by Wendehenne et al. (1995) using tobacco plasma membrane preparations and 125I-labeled cryptogein: a
Kd of 2 nM and 220 fmol/mg
binding sites on plasma membrane proteins. Differences were expected
because we used a different binding buffer suitable for cross-linking experiments. In the present study the data based on Scatchard plots
suggest that elicitin-binding properties are equivalent. This
assumption is further supported by experiments showing that the
specific binding of each elicitin was optimal at pH 7.0, regardless of
its acidic or basic nature (Fig. 2).
Competition experiments were performed to verify whether elicitins
bound to the same high-affinity binding sites. Results demonstrated
that each nonradioactive iodinated elicitin was able to compete with
125I-cryptogein, and the corresponding
IC50 values were similar (between 4.8 and 20.1 nM) and close to the Kd of
cryptogein (Table III). However, an apparent better affinity of
iodinated versus noniodinated elicitins was suggested by the comparison
of the IC50 values, which were higher for
unlabeled iodinated elicitins (Tables II and III). Consequently, the
affinity of noniodinated elicitins for binding sites might be lower
than those determined for iodinated elicitins. At this stage we are
unable to explain why iodination increases affinity and why this
increase in affinity is not linked to an increase in activity.
Elicitins possess four to five Tyr residues with various degrees of
accessibility (based on the cryptogein structure; Boissy et al., 1996).
Only two conserved Tyr residues (Tyr-47 and Tyr-87) are partly
accessible to the solvent, and only one is fully accessible in basic
elicitins (Tyr-12). The iodination of one of these residues could
modify the binding properties if the residue lies within or in close
vicinity to the interacting domain.
The fact that elicitins showed similar Kd
constants and IC50 values regardless of the
treatment (iodination or absence of iodination) demonstrated that they
were able to interact with the same binding sites on plasma membranes.
Binding experiments have also indicated that nonconserved, charged
amino acids that confer acidic or basic pIs were probably not involved
in binding. Therefore, binding relies on invariant amino acid
interactions, which is in agreement with results of radiographic
crystallography of cryptogein indicating that elicitins may share a
very similar tertiary structure and a beak-like motif resulting from
the arrangement of an -loop and a -sheet essentially composed of
invariant residues. This conserved structure could be a major
recognition site for a putative receptor (Boissy et al., 1996).
Elicitors of different chemical origin have been reported to interact
with high affinity with plasma membrane components. Chemically pure
carbohydrates and glycopeptides or proteinaceous elicitors bound with
Kd values at or below the nanomolar range (Cheong and Hahn, 1991; Cosio et al., 1992; Basse et al., 1993; Shibuya
et al., 1993; Baureithel et al., 1994; Nürnberger et al., 1994;
Kooman-Gersmann et al., 1996). Evidence for high-affinity binding sites
is usually correlated with biological activities, confirming a linkage
with a cellular signal transduction chain. A strong relationship
between competitor abilities of various elicitors and plant defense
responses has been established previously (Cheong and Hahn, 1991; Basse
et al., 1993; Baureithel et al., 1994; Nürnberger et al., 1994).
A positive binding/activity correlation has also been reported using
-glucan elicitors and six species of the same plant family (Cosio et
al., 1996). However, since elicitor binding seems to be a prerequisite
for the induction of the plant-defense response, this interaction is
not sufficient for elicitor-induced plant-defense mechanisms. The
race-specific AVR9 peptide elicitor from Cladosporium fulvum
bound on plasma membrane preparations from both fungus-resistant and
fungus-susceptible tomato cultivars and from other solanaceous plants
(Kooman-Gersmann et al., 1996). It was suggested that in the
susceptible cultivar binding properties were related to the presence of
homologs of the resistance gene Cf-9, which characterized the resistant tomato cultivar. In tomato cells the same binding site
was shown to bind a glycopeptide (elicitor), inducing ethylene production and the N-linked glycans released from this
glycopeptide (Basse et al., 1993). The N-linked glycans act
as suppressors of ethylene production.
A comparison of the previously described effects of elicitors on whole
tobacco plants (see introduction) and of the elicitin-binding properties did not indicate a strict relationship between elicitin perception and plant response. Therefore, we looked at early
physiological events in tobacco cells following elicitin perception,
which would reflect a modulated signal transduction step dependent on
an elicitor complex leading to different plant defense levels. We chose
to measure the effects of the four elicitins on
Ca2+ influx (which is, to our knowledge, the
earliest event induced by cryptogein in tobacco cells after protein
phosphorylation; Tavernier et al., 1995b) and on the subsequent
Ca2+-dependent events extracellular medium
alkalinization and AOS production.
Using 45Ca2+ as a tracer we
observed that the four elicitins were able to induce
Ca2+ influx. Nevertheless, cryptogein triggered a
much more intense Ca2+ influx compared with the
other elicitins (Fig. 5). The ability of elicitins to trigger different
levels of Ca2+ influx was confirmed using pH
conditions (buffered medium, pH 7.0) that allowed similar binding with
the four elicitins (Fig. 5C). The intensity of the
Ca2+ influx was not associated with the basic or
acidic characters of elicitins, because the basic cinnamomin has an
effect on Ca2+ influx similar to those of acidic
elicitins.
Extracellular pH changes were also monitored in response to the four
elicitins. The comparison of the effects of either 10 or 100 nM elicitin indicated that cryptogein was always the most efficient. At low concentrations all elicitins except cryptogein showed
a lag phase of at least 10 min before the pH of the extracellular medium increased (Fig. 4). At higher concentrations the lag phase was
shortened and the maximal pH variation was reached after 60 min of
treatment with the four elicitins, although with different initial
rates. The lowest concentrations necessary to achieve maximal pH
increase with the highest rates were 10 and 50 nM for cryptogein and cinnamomin, respectively, and about 500 nM
for capsicein and parasiticein. Basic elicitins appeared at least 10 times more efficient than acidic elicitins in inducing extracellular pH
changes. The same conclusions were drawn when measuring the AOS
production induced by the four elicitins (Fig. 6). The concentrations necessary to induce maximal AOS production were similar to those necessary to induce the maximal extracellular pH increase (25 and 50 nM for cryptogein and cinnamomin, respectively, and about 500 nM for the two acidic elicitins). The AOS burst
increased concurrently with extracellular pH and was delayed for
cinnamomin, capsicein, and parasiticein compared with cryptogein.
However, at a high elicitin concentration (100 nM) AOS
production reached the same level (approximately 1200 nmol
H2O2
g1 fresh weight cells) with the four elicitins,
although with different kinetics.
Because the four elicitins bind to the same sites with the same
affinity, one would expect that when mixed together an elicitin with
low efficiency (acidic) would decrease the effects of a highly efficient (basic) elicitin. These competition assays required 20 nM basic elicitin and 10 to 50 times more acidic elicitin
(200 nM to 1 µM). The acidic elicitin
contributions at these concentrations were high and differences were
particularly slight for extracellular pH measurements. Therefore, in
vivo competition experiments were performed by measuring only the AOS
production induced by cryptogein in competition with capsicein. Results
showed that capsicein was also a competitor in vivo: 100 nM
capsicein induced a 90% inhibition of the 25 nM
cryptogein-induced AOS production, which supports an in vivo
competition process.
Even when elicitins were tested on tobacco cell suspensions,
differences in the intensity of the early effects of elicitin arose and
could reflect the elicitin properties that were correlated with the
electric charge of the elicitins. One explanation for the different
biological activities of elicitin would be that the whole elicitin
charge might restrict the acidic elicitin diffusion at the 5.8 physiological pH in the negatively charged cell wall, resulting in
lower amounts of acidic elicitins interacting with binding sites.
Alternatively, following binding between the elicitin conserved domain
and the receptor, the amino acid electric charges that characterized
the unconserved domain could trigger different conformational changes
in the receptor, leading to variations in the intensities and kinetics
of responses at the cellular level.
Conversely, the formation of various oligomeric forms of the receptor
could be induced by elicitins, as has been reported for animal
polypeptide hormones, cytokines, and growth factors (Heldin, 1995). For
example, the different isoforms of platelet-derived growth
factor induced different dimeric forms of receptors (homodimeric and heterodimeric forms), resulting in not only modulated response intensities but also additional signal transduction molecule
interactions. Such mechanisms could also explain the behavior of the
different elicitins at the cellular level. In addition to the beak-like motif, elicitins contain two other regions around residues 13 and 87 whose charge distribution could be correlated with the level of
biological activity of elicitin (Boissy et al., 1996). These regions
could modulate the intensity of tobacco cell responses after binding on
the receptor. Presently, experiments are in progress to identify the
receptor of elicitins. After this receptor has been identified, the
interactions between ligand and receptor will be studied at the
molecular level.
In conclusion, fine regulation of signal transduction is a topic of
major interest, although many aspects remain obscure because of a lack
of information about the many processes involved. Only recently was a
-glucan elicitor-binding site characterized at the molecular level
(Umemoto et al., 1997). An integrated view of the transduction pathway
includes the analysis of the environment of the receptor and knowledge
of the molecules recruited to transduce signals such as protein
kinases, protein phosphatases, or specific ion channels.
| |
FOOTNOTES |
1
This work was supported by the Institut National
de la Recherche Agronomique and by the Conseil Regional de Bourgogne.
S.B. was supported by a grant from the Ministère de
l'Enseignement Supérieur et de la Recherche.
*
Corresponding author; e-mail lebrun{at}epoisses.inra.fr; fax
33-3-80-63-3178.
Received May 6, 1998;
accepted August 21, 1998.
| |
ABBREVIATIONS |
Abbreviations:
AOS, active oxygen species.
IC50, half-maximal inhibitor concentration.
| |
ACKNOWLEDGMENT |
We wish to thank Annick Chiltz for excellent technical
assistance.
| |
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Abstract
Introduction