Plant Physiol. (1999) 120: 1175-1182
Cucumber Hypocotyls Respond to Cutin Monomers via Both an
Inducible and a Constitutive H2O2-Generating
System1
Heinrich Kauss*,
Markus Fauth,
Axel Merten, and
Wolfgang Jeblick
Fachbereich Biologie der Universität, Postfach 3049, D-67653
Kaiserslautern, Germany
 |
ABSTRACT |
Hypocotyls from etiolated cucumber
(Cucumis sativa L.) seedlings were gently abraded at
their surface to allow permeation of elicitors. Segments from freshly
abraded hypocotyls were only barely competent for
H2O2 elicitation with fungal elicitor or hydroxy fatty acids (classical cutin monomers). However, elicitation competence developed subsequent to abrasion, reaching an optimum after
about 4 h. This process was potentiated in seedlings displaying acquired resistance to Colletotrichum lagenarium due to
root pretreatment with 2,6-dichloroisonicotinic acid or a
benzothiadiazole. Induction of competence depended on protein synthesis
and could be effected not only by surface abrasion, but also by fungal
spore germination on the epidermal surface or by rotating the seedlings
in buffer. Inhibitor studies indicated that the inducible mechanism for
H2O2 production involves protein
phosphorylation, Ca2+ influx, and NAD(P)H oxidase. In
contrast, a novel cucumber cutin monomer, dodecan-1-ol, also elicited
H2O2 in freshly abraded hypocotyls without
previous competence induction. This finding suggests the presence of an
additional H2O2-generating system that is
constitutive. It is insensitive to inhibitors and has, in addition, a
different specificity for alkanols. Thus, dodecan-1-ol might initiate
defense before the inducible H2O2-generating
system becomes effective.
| |
INTRODUCTION |
When plant cells interact with potential pathogens, they often
produce active oxygen species. The biochemical basis for this rapid
defense response has been elucidated mainly by applying elicitors
derived from pathogens to plant cell suspension cultures. The major
source for active oxygen species appears to be an NAD(P)H-oxidase system that is associated with the plasma membrane (Baker et al., 1997
;
Lamb and Dixon, 1997; Alvarez et al., 1998; Blumwald et al., 1998).
This enzyme complex is directly linked to the elicitor signaling
cascade and reduces molecular oxygen to
O2·
, which is rapidly
dismutated to the more stable
H2O2.
To investigate whether the features elaborated with cell culture models
are of significance for the resistance of whole-plant tissues against
pathogens, we have used etiolated cucumber (Cucumis sativa
L.) seedlings that can be infected by Colletotrichum
lagenarium (Siegrist et al., 1994). SAR is induced in the
hypocotyl by root pretreatment with INA. By doing so, the SAR inducer
initially does not come into direct contact with the pathogen attacking from the epidermal surface. Salicylic acid could not be used to induce SAR via the roots of entire cucumber seedlings because the
millimolar concentrations required caused phytotoxic effects (Kästner et al., 1998).
SAR in etiolated cucumber hypocotyls is manifested as an inhibition of
fungal penetration through the outer epidermal cell wall (Siegrist et
al., 1994). Hypersensitive reactions are very rare in this tissue;
essentially all attacked epidermal cells remain alive. We have
described up to now two locally triggered defense complexes associated
with SAR in the hypocotyls. One is the formation of papillae, which
includes a very localized deposition of lignin-like phenolics into the
plant cell wall around the fungal appressoria (Siegrist et al., 1994).
Phenolic deposition is already evident prior to penetration of the
epidermal cell wall, indicating that epidermal cucumber cells
exhibiting SAR are able to perceive, at very early time points, one or
more signals derived from fungal attack. This cytological observation
has recently been confirmed at the molecular level (Kästner et
al., 1998). Systemic-resistant cucumber hypocotyls contain only low
amounts of chitinase mRNA prior to infection. However, chitinase
transcript levels are greatly enhanced upon infection with C. lagenarium. Induction of mRNA occurs before appressorium formation
and is also observed with a melanin-deficient mutant fungus that can
barely penetrate the epidermal cell walls. It has been shown with
antibodies that the apoplastic chitinase is indeed produced prior to
penetration (Kästner et al., 1998). Thus, the timely induction of
chitinase beneath the outgrowing fungal spores appears to be the second
defense response contributing to arrest of fungal penetration into the systemic-resistant epidermal cells.
Cucumber hypocotyls represent a convenient material for comparing
elicited defense responses in susceptible and systemic-resistant epidermal cells. For the application of elicitors, we had to gently abrade the cuticle to make it permeable. Segments cut from freshly abraded tissues are, however, only barely competent for rapid H2O2 elicitation with FE,
ergosterol, chitosan, or chitin oligomers (Fauth et al., 1996; Kauss
and Jeblick, 1996; Kauss et al., 1997). However, competence develops
once the abraded cut segments are rotated in buffer for a certain time
period. We refer to this procedure as "conditioning." Elicitation
competence in cucumber hypocotyls thus is not constitutive, but
requires physiological changes induced by surface abrasion. Requirement
for conditioning subsequent to surface abrasion was also shown for
etiolated hypocotyls or epicotyls from another six plant species
using partially acetylated chitosan as an universal
H2O2 elicitor (Kauss et
al., 1997).
Induction of competence for the
H2O2 response is
reminiscent of observations with soybean cotyledons, which develop
competence for elicitation of glyceollin and phenolic cell wall
polymers only in cell layers close to the cut surface or adjacent to
the site of elicitor injection (Graham and Graham, 1994, 1996). In the
abraded cucumber hypocotyls, it is the conditioning process that is
enhanced by systemically supplied INA or by salicylic acid applied to
the abraded segments (Fauth et al., 1996; Kauss and Jeblick, 1996). We
and others (Mur et al., 1996; Thulke and Conrath, 1998) refer to
such an enhancement of locally triggered defense responses in cells
primed by SAR inducers as "potentiation."
Induction of elicitor competence is suppressed by the presence of
cycloheximide and puromycin during the conditioning period and, thus,
appears to require protein synthesis (Fauth et al., 1996). Taken
together, our results showed that intact plant tissues require an
additional stimulus derived from surface abrasion as a prerequisite to
develop a functional H2O2
elicitation system by a process potentiated under SAR conditions.
The early response of resistant epidermal cells to germinating fungal
spores (Kästner et al., 1998) suggested, as a working hypothesis,
that the cuticle might play a role in signaling. This idea was
sustained by the observation that alkaline hydrolysates from cutin of
either cucumber hypocotyls or leaves can elicit H2O2 production in abraded
and conditioned hypocotyl segments (Fauth et al., 1998). The cutin
hydrolysates are rich in DDO and also contain some hydroxy fatty acids,
which, due to their small amounts, have not been identified. We used
the hypocotyl segment system to screen a large collection of authentic
hydrocarbons for H2O2
elicitation. Hydroxy groups, epoxy groups, and double bonds are
important features for the
H2O2 elicitation potency of
fatty acids (Fauth et al., 1998). Short-chain alkanols, including the
novel cucumber cutin monomer DDO, are also active at
H2O2 induction. In
addition, the cucumber surface wax and certain alkanols and hydroxy
fatty acids also enhance the activity of
H2O2 elicitors of fungal
origin (FE, ergosterol, and chitosan; Fauth et al., 1998). Thus, the
epidermal cells of cucumber hypocotyls can perceive and respond to
monomers derived from their cutin and/or components of their surface
wax layer.
In the present report we show that upon conditioning of entire cucumber
seedlings after hypocotyl abrasion, induction of competence for
elicitation with FE and hydroxy fatty acids is much more rapid compared
with conditioning of cut segments. With this improved conditioning
protocol, we could show that the induction of elicitor competence
occurs not only after surface abrasion but also when fungal spores
germinate on the epidermal surface. The inducible H2O2-generating system is
potentiated under SAR conditions and exhibits properties similar to
the NAD(P)H-oxidase system characterized in detail in suspension
culture models. In addition, cucumber hypocotyls can
generate H2O2 by another pathway that is
constitutively present but only responds to the cucumber cutin monomer
DDO.
| |
MATERIALS AND METHODS |
Cucumber (Cucumis sativus) seedlings were grown in
closed plastic boxes in the dark for 4 to 5 d (Fauth et al.,
1996). The cultivar Mervita was used routinely, and the cultivars
Mepram and Bimbo were used for comparison. Abrasion of the hypocotyls was performed with a slurry of SiC (Fauth et al., 1998; Kästner et al., 1998) and the seedlings were conditioned on a rotary shaker (80 rpm) in 10 mM Mes/KOH buffer, pH 6.5. The volume
varied with the amount of seedlings. For example, for 20 to 30 seedlings, 50 mL of buffer was used in a beaker of 8.5 cm in diameter.
Under these conditions, the seedlings showed little motion even though the buffer rotated. The seedlings were briefly washed under running tap
water. Segments (3 cm) were subsequently cut from the seedlings, starting about 1 cm above the root crown. Five segments were used for
the H2O2 assay in 3.5 cm
Petri dishes containing 3 mL of the above buffer. The dishes were
rotated (140 rpm) and elicitors were added after a 45 min adaptation
period which was necessary as shortly after cutting an extra
H2O2 burst is evident
especially in INA-pretreated seedlings. This burst is generated by
segment handling. DHSA, HPA, and DDO were added from a DMSO stock
solution (final solvent concentration 0.2%, v/v). In this case, the
controls without elicitor which were run in parallel contained DMSO at the same concentration. At the indicated times, 100 µL of the buffer
was removed and H2O2 was
determined by ferricyanide-catalyzed oxidation of luminol as described
previously (Fauth et al., 1996). For determination of
H2O2 degradation, exogenous
H2O2 (10 µM) was added in the absence of the elicitor
and the initial rate of decrease in concentration was determined (Kauss
and Jeblick, 1996).
For SAR induction, the cucumber seeds were germinated on paper towels
wetted with suspensions of formulated INA or BTH at an inducer
concentration of 100 µM unless stated otherwise.
Infection experiments and scoring of penetration by C. lagenarium were performed as described by Siegrist et al. (1994).
Induction of elicitor competence with the C. lagenarium
melanin-deficient mutant was as described by Kästner et al.
(1998) for induction of chitinase mRNA. For unknown reasons, the spores
of the mutant strain in some periods formed clumps, causing uneven and
scarce germination. Such experiments were not included in this paper.
The various elicitors were bought or prepared as described by Fauth et
al. (1998). Formulated INA and BTH (under the trade name Bion) were
kindly supplied by Novartis (Basel, Switzerland). Seeds were from a
local store. Cycloheximide and anisomycin were from Sigma. The latter
was applied from a methanolic stock solution that was freshly prepared
every day because it appeared to lose its activity within a week.
The final methanol concentration in the sample and respective controls
was 0.1% (v/v).
| |
RESULTS |
An Inducible H2O2-Generating System
Develops after Surface Abrasion and Responds to FE and Hydroxy
Fatty Acids
Hypocotyl segments from freshly abraded cucumber seedlings cannot
respond to FE with H2O2
production (Fig. 1, 0 time point). In
contrast, when the entire hypocotyl-abraded seedlings were rotated for
some time in buffer, the subsequently cut segments responded to FE with
H2O2 generation, exhibiting
a burst maximum at 30 to 45 min after elicitor addition (Fig. 1). This
induction of competence for
H2O2 elicitation with FE
was complete within 3 to 4 h, whereas in the previously used cut
segments, at least 10 h were required for an optimal effect (Fauth
et al., 1996). Although the absolute level of
H2O2 elicitation varied
between individual experiments, the
H2O2 burst was further
elevated in all experiments performed when the seedlings were
pretreated at the roots with either INA or BTH (see legend of Fig. 1).
The induced elicitor competence was found to be transient. In the
example shown in Figure 1, elicitor competence in INA-treated seedlings remained near maximal for about 2 h, and this result was similar in a total of five experiments performed.
View larger version (20K):
[in this window]
[in a new window]
| Figure 1.
Surface abrasion and a subsequent conditioning
period are required for H2O2 elicitation by FE.
Cucumber seedlings were grown either on water (control; white symbols)
or in the presence of INA or BTH (SAR; black symbols). Their hypocotyl
surface was gently abraded and segments were either cut immediately (0 time) or after rotating the whole abraded seedlings in buffer for the
indicated time periods (conditioning). The segments were adapted for 45 min in the H2O2 elicitation assay before the
addition of 20 µg mL1 FE. The
H2O2 concentration at the burst maximum (45 min
after elicitation) was corrected against values determined in a
parallel batch of segments without elicitor. The curves ( and  )
refer to one representative experiment in which SAR was induced by root
pretreatment with INA. For the 4-h time point, means ± SD are given from 15 experiments with controls ( ) and 13 experiments with seedlings rendered systemic resistant by root
pretreatment with BTH ( ). For further notes on the variability in
the time course of elicitation competence induction, see text.
|
|
In two additional experiments the elicitor competence was maximal only
for about 1 h, and in another experiment it took 6 h to reach
the maximum (data not shown). As we routinely had to restrict
conditioning to one competence induction time (namely 4 h), it
appears possible that in individual experiments the maximum of elicitor
competence was either not yet reached or no longer evident. This fact
may at least in part explain the apparently great variability in the
level of H2O2 elicitation
between various experiments (Fig. 1). Variability between experiments
also likely relates to a further observation. The rate of degradation
of exogenous H2O2, for
unknown reasons, can differ by a factor of up to 2 between different
batches of seedlings (data not shown). As
H2O2 degradation occurs
concomitantly with H2O2
generation, the absolute level of
H2O2 concentration reached
at the burst maximum only partly reflects actual
H2O2 generation.
Hydroxy fatty acids also barely elicited
H2O2 in freshly abraded
segments, as exemplarily shown for DHSA and HPA in Figure 2. With both of these hydroxy fatty acids
as the elicitor, a 4-h conditioning period induced elicitor
competence, with a further potentiation in SAR hypocotyls (Fig.
2). As in the example shown in Figure 2, a major
H2O2 burst maximum was
reached in all experiments at 2 to 2.5 h post elicitation. In some
of the experiments we observed an additional minor peak or shoulder at
about 30 min, which was not considered further in this report. DHSA and
HPA were used throughout this report as commercially available models for classical cutin hydroxy fatty acids. From the other oxygenated fatty acids found active under previously used conditions (Fauth et
al., 1998) we confirmed
H2O2 elicitor activity
under the new conditioning protocol for 12-epoxy-linoleic acid and
13-hydroxy-9Z,11E-octadecadienoic acid (data not shown).
View larger version (26K):
[in this window]
[in a new window]
| Figure 2.
Influence of a conditioning period on the time
course of H2O2 elicitation by the hydroxy fatty
acids DHSA and HPA. Seedlings were either grown on water (controls; and  ) or on INA (SAR; ,  , and  ). Segments were cut from
hypocotyls of freshly abraded seedlings () or from seedlings
conditioned for 4 h subsequent to abrasion ( and ). DHSA
( and ) or HPA ( and ) were used as elicitors at 50 µM. In freshly abraded segments only the values from SAR
seedlings elicited with DHSA are shown (), but those from control
segments elicited with any of the two elicitors were similarly low. One
representative experiment is given. In additional experiments, the
absolute level of the H2O2 burst maximum (120 min) differed for susceptible (control) segments between 1 and 4 µM, and for systemic resistant segments between 3 and 10 µM. An increase in the elicited
H2O2 burst due to SAR induction was seen in any
individual experiment performed. For instance, upon elicitation with
DHSA in four independent experiments with INA this increase was
3.2 ± 1.2-fold, and in seven experiments with BTH it was 2.4 ± 0.8-fold. For further notes on the variability between experiments,
see text.
|
|
In the presence of cycloheximide during conditioning, subsequent
H2O2 elicitation by FE was
fully suppressed (Table I). This observation confirms our previous results with conditioning of cut
segments (Fauth et al., 1996). Full inhibition of the process leading
to competence for FE was also found for anisomycin, another inhibitor
of translational protein synthesis, and for the competence to elicit
H2O2 generation with DHSA
(Table I). These results indicate that the induction of competence for
H2O2 elicitation both by FE
and DHSA requires protein synthesis.
View this table:
[in this window]
[in a new window]
|
Table I.
Influence of protein synthesis inhibitors on
conditioning for subsequent elicitation of H2O2
Protein synthesis inhibitors were present during the 4-h conditioning
period of hypocotyl-abraded seedlings that were root pretreated with
BTH to induce SAR. Subsequently, hypocotyl segments were cut and
elicited with either 20 µg mL1 FE or 50 µM DHSA. The H2O2 concentrations
reached burst maxima at 45 min with FE and at 2 h with DHSA.
Means ± SD from five independent experiments are
given relative to controls (100%).
|
|
Similar to INA, root pretreatment with BTH also potentiated induction
of H2O2 elicitation
competence at the hypocotyls of cucumber seedlings (Figs. 1 and 2). It
was previously shown that this tissue becomes resistant to C. lagenarium upon root application of INA (Siegrist et al., 1994).
We investigated, therefore, whether BTH is also effective at SAR
induction in the etiolated cucumber hypocotyls. C. lagenarium penetrated the outer epidermal cell walls of
water-grown seedlings beneath 61.2% ± 11.4% of the appressoria formed, whereas in BTH-grown seedlings the penetration rate was reduced
to 1.0% ± 1.6% (n = 5). In the same experiments,
papillae were observed in water-grown controls only beneath 3.9% ± 4.0% of the appressoria, whereas in BTH-grown seedlings 55.8% ± 10.2% of the appressoria were associated with papillae. Thus,
systemically provided BTH primed the epidermal cells of cucumber
hypocotyls for successful formation of papillae. That BTH can induce
SAR is known for various other plants and pathogens (Görlach et
al., 1996; Sticher et al., 1997).
DDO Elicits H2O2 Also by a Constitutive
Mechanism
Cucumber cutin hydrolysate contains a high proportion of DDO
(Fauth et al., 1998). This novel cucumber cutin monomer elicited H2O2 in cucumber hypocotyl
segments that had been conditioned for 18 h (Fauth et al., 1998).
Figure 3 documents that this also holds
true for segments from abraded seedlings that were conditioned for
4 h according to the new protocol. In contrast to FE (Fig. 1) and
hydroxy fatty acids (Fig. 2), DDO was also active when added to freshly
abraded segments, reaching maximal
H2O2 levels after only 15 to 20 min (Fig. 3). These results indicate the existence of another
H2O2-generating system that
is constitutive and only responds to stimulation with DDO.
View larger version (19K):
[in this window]
[in a new window]
| Figure 3.
Time course for H2O2
elicitation by the novel cucumber cutin monomer DDO. Hypocotyl segments
were from either freshly abraded susceptible seedlings grown on water
() or from seedlings grown on INA and conditioned for 4 h
subsequent to abrasion (). One experiment is given as an example.
The variability between experiments is given in Table II.
|
|
The H2O2 level induced by
DDO in freshly abraded systemic-resistant seedlings (pretreated with
INA) reached only 71% ± 16% (n = 6) of the peak
maximum observed with water-grown control seedlings (data not shown).
When different cucumber cultivars were compared, the routinely used cv
Mervita reached a maximum of 1.0 ± 0.3 µM
(n = 5) whereas the cv Mepram reached 1.9 ± 0.1 µM (n = 3) and cv Bimbo came up
to 2.4 ± 0.1 µM (n = 3).
Interestingly, the latter two cultivars are F1
hybrids, claimed by the breeders to be tolerant or resistant
against several fungal pathogens. No considerable
H2O2 production was induced
by DDO in freshly abraded hypocotyl segments of squash (cv custard
white), melon (cv Bastion), bean (cv Dufix), sunflower (cv unknown), or
freshly abraded pea epicotyl segments (cv Rheinländerperle, data
not shown).
The specificity of various alkanols for
H2O2 elicitation in abraded
cucumber hypocotyls is shown in Table II.
The most interesting findings are that dodecan-1,2-diol exhibited no
activity in freshly abraded segments, whereas the
C8 and C6 mono-1-ols were
about as active as DDO. In contrast, in segments from conditioned
seedlings, dodecan-1,2-diol was about twice as active as DDO, whereas
the C8 and C6 mono-1-ols
had significantly weaker activity than DDO (Table II). Thus, the
constitutive
H2O2-generating system
differs from the inducible mechanism with respect to elicitor
specificity.
View this table:
[in this window]
[in a new window]
|
Table II.
Specificity of various fatty alcohols for
H2O2 elicitation in segments from freshly
abraded or conditioned cucumber hypocotyls
Segments cut from freshly abraded hypocotyls of water-grown seedlings
were incubated in the presence of 50 µM fatty alcohols
and the H2O2 concentration was determined after
30 min (see Fig. 3). The number of carbon atoms of the alcohols is
given in parentheses. Means ± SD from three
independent experiments are given. Ethanol had no considerable
activity. Seedlings grown on BTH were abraded at the hypocotyl and the
entire seedlings were conditioned for 4 h. Segments were
subsequently cut and treated as above. The H2O2
concentration was determined after 90 min. Means ± SD
from five independent experiments are given.
|
|
The Inducible and the Constitutive
H2O2-Generating Mechanism Differ in Inhibitor
Sensitivity
To further characterize the two
H2O2 elicitation mechanisms
in the cucumber hypocotyl physiologically, we took advantage of inhibitors with known effects in suspension culture systems. For elicitation with FE (Fig. 1) and hydroxy fatty acids (Fig. 2), the
abraded seedlings required a conditioning time of 4 h to develop a
functional H2O2-generating
system. This inducible pathway for H2O2 generation was fully
inhibited by 10 µM DPI, 1 µM K-252a, and
0.8 mM La3+ (Fig.
4). In contrast,
H2O2 elicitation by DDO in
freshly abraded segments was not affected by these inhibitors (Fig. 4),
indicating that the constitutive system consists of enzymes that are
not involved in the inducible
H2O2 system.
View larger version (31K):
[in this window]
[in a new window]
| Figure 4.
H2O2 elicitation with
DHSA, DDO, and FE is differently inhibited in freshly abraded and
conditioned hypocotyls. Segments from either freshly abraded control
hypocotyls or from systemic-resistant (INA) abraded seedlings that had
been conditioned for 4 h were used. DPI (10 µM),
K-252a (1 µM), or La3+ (0.8 mM)
were applied 15 min prior to elicitation in assays performed as for
Figures 1-3. With freshly cut segments, H2O2
elicitation was determined 20 min after DDO addition. In conditioned
seedlings, H2O2 elicitation was determined 2.5, 2, or 1 h after addition of DHSA, DDO, or FE, respectively. The
number (n) of individual experiments performed is given in the top.
Negative values indicate that in addition to a full inhibition of the
elicited H2O2 production, the slight
non-elicited H2O2 production was also affected
by the respective inhibitor.
|
|
The level of H2O2 generated
with DDO in freshly abraded segments was increased by
NaN3 and KCN (Table
III). These compounds inhibited the
degradation of exogenously supplied H2O2, indicating the participation of peroxidase and/or catalase in
H2O2 degradation. Thus, the
increase in the level of
H2O2 due to the presence of KCN and NaN3 likely results from the inhibition
of H2O2 degradation, which
occurs concomitantly with
H2O2 production.
View this table:
[in this window]
[in a new window]
|
Table III.
Influence of KCN and NaN3 on the
generation of H2O2 with DDO and on the
degradation of exogenously supplied H2O2 in
freshly abraded segments from water-grown seedlings
Segments were incubated for 30 min with 50 µM DDO (see
Fig. 3). The inhibitors were added 15 min prior to DDO. Means from five
independent experiments ± SD are given in relation to
controls. In absence of DDO, 10 µM
H2O2 was added into the assay and the
H2O2 concentration determined in 1 min
intervals.
|
|
In conditioned segments, the action of DDO was only partly inhibited by
DPI and La3+ (Fig. 4). These inhibitors fully
suppress the inducible mechanism, which is evident from their effect on
elicitation with FE and DHSA. Thus, the observation that a part
of DDO-elicited H2O2 is resistant to DPI and La3+ indicates that in
conditioned segments both the inducible and the constitutive pathway
contribute to H2O2
production by DDO. Interestingly,
H2O2 generation by DDO in
conditioned segments was fully suppressed by the protein kinase
inhibitor K-252a, whereas in fresh segments this inhibitor was inactive
(Fig. 4). Thus, conditioned hypocotyls differ from freshly abraded
segments in their sensitivity to K-252a.
Induction of Elicitor Competence by Germinating Fungal Spores
With the new conditioning protocol, the competence for elicitation
of H2O2 with FE and DHSA
was induced within about 4 h of conditioning in entire
SAR cucumber seedlings abraded at their hypocotyls (Fig. 1). Within the
same time period, outgrowing spores of a melanin-deficient
mutant strain of C. lagenarium induces expression of
chitinase in systemic-resistant epidermal cells, indicating an early
plant/microbe interaction (Kästner et al., 1998). We therefore
determined whether germinating spores might also induce
H2O2 elicitor competence in
nonabraded seedlings. Figure 5 shows
that, indeed, within 4 h after spore application the competence
for H2O2 elicitation with
FE and DHSA was significantly higher than in controls without spores.
It is especially noteworthy that in these controls, in which the
nonabraded seedlings were rotated in buffer only, the
H2O2 elicitor competence
was also significantly higher compared with freshly abraded seedlings
taken directly from the growth box (legend of Fig. 5).
View larger version (39K):
[in this window]
[in a new window]
| Figure 5.
Germinating spores of a melanin-deficient
C. lagenarium mutant and rotating the seedlings in
buffer can partially replace surface abrasion with regard to the
stimulus needed for induction of elicitor competence. SAR was induced
in the seedlings by root pretreatment with either 100 µM
INA (A) or 40 µM BTH (B). As in Figure 1, the hypocotyls
of one batch of seedlings were abraded and the seedlings conditioned
for 4 h. The other part of the seedlings was rotated in a
suspension of spores that adhere to the surface and germinate during
the 4-h period. A third part of seedlings (controls) was rotated for
4 h in buffer only. Both the samples with spores and the controls
were abraded after rotating for 4 h. Segments from all three
batches were then cut and elicited with either FE (20 µg
mL1) or DHSA (100 µM). Means ± SD from three (A) or five (B) independent experiments are
given. Note that in contrast to the freshly abraded segments used in
Figures 1 and 2, the controls also exhibited considerable elicitor
competence. In four independent experiments similar to B, we confirmed
6 months later that the stress presumably caused by rotating the
nonabraded seedlings in buffer can indeed induce some elicitor
competence. In these experiments, freshly abraded hypocotyls directly
from the growth box exhibited 1.0% ± 0.7%, whereas the
buffer-treated hypocotyls had 8.7% ± 3.2% competence for elicitation
with FE compared with abraded and conditioned seedlings (100%).
|
|
| |
DISCUSSION |
When cucumber hypocotyls were abraded at their surface to allow
permeation of elicitors, freshly cut segments barely exhibited H2O2 generation with FE
(Fig. 1) and hydroxy fatty acids (Fig. 2). Elicitor competence rapidly
developed subsequent to abrasion in a time-dependent process that was
fully suppressed by established inhibitors of translational protein
synthesis (Table I). These results indicate that the induction of
H2O2 elicitor competence involves synthesis of as yet unknown proteins that are rate-limiting in
native epidermal cells.
The H2O2-generating
mechanism induced in the hypocotyls during conditioning of abraded
seedlings was characterized using a pharmacological approach (Fig. 4).
H2O2 elicitation by FE and DHSA was completely inhibited by La3+, K-252a,
and DPI, indicating that influx of Ca2+ and
protein phosphorylation are involved in signal transmission and that
the plasma membrane-located NAD(P)-oxidase complex likely produced
O2· as an intermediate
for the evolving H2O2. The
above features are all hallmarks of the elicitation of reactive oxygen
species in cell suspension cultures (Hammond-Kosack and Jones, 1996;
Baker et al., 1997; Lamb and Dixon, 1997; Blumwald et al., 1998; Keller et al., 1998). Thus, the
H2O2 elicitation system
that responds to FE and hydroxy fatty acids and is induced subsequently
to surface abrasion of cucumber hypocotyls appears to be similar to the
system reported in suspension cultures.
For the H2O2-generating
system induced on conditioning, FE is active at a rather low
concentration, especially since a glucan present only in minor amounts
is the active fraction (Fauth et al., 1996). In contrast, elicitation
of H2O2 with DHSA and HPA was just evident at 2 µM and was saturated at about 25 µM (data not shown). Therefore, a hydroxy fatty acid
concentration of 50 µM that may appear quite high was
routinely used (Fig. 2). However, these compounds form micelles that
likely enter the scratches produced in the hypocotyl cuticle poorly
and/or can hardly diffuse through the apoplast. In addition, a large
amount of the lipid material is likely bound to the hydrophobic segment
surface. Thus, the nominal concentration of the lipids probably does
not reflect the actual concentration at the plasma membrane.
The induction of competence for
H2O2 elicitation during
conditioning was even further enhanced in hypocotyls containing
systemically supplied INA or BTH (Figs. 1 and 2). The inhibition of
fungal penetration of the outer epidermal cell wall of these
systemic-resistant cucumber seedlings involves formation of papillae
that contain lignin-like polymerized phenolics. Phenolic polymers are
also incorporated into the existing plant cell wall, visible as a
"halo" around the appressoria (Siegrist et al., 1994; Fauth et al.,
1996). The polymerization of cell wall phenolics likely requires the production of H2O2. In
fact, the production of reactive oxygen species beneath fungal
appressoria has recently been shown in barley (Thordal-Christensen et
al., 1997; Hückelhoven and Kogel, 1998). Thus, the physiological
relevance of the observation that INA and BTH potentiate the process
leading to H2O2 elicitation competence (Figs. 1 and 2) correlates with the potency of
systemic-resistant epidermal cells to readily react with the formation
of effective papillae.
The development of H2O2
elicitation competence in the cucumber hypocotyl is initiated by a
stimulus created upon surface abrasion (Fauth et al., 1996; Figs. 1 and
2). In the present report we have optimized the conditioning protocol
to avoid any "wounding" in the classical sense. Essentially no
epidermal cells become stainable with Evan's blue when abrasion is
gently performed (Kästner et al., 1998), indicating that no cells
have been destroyed. Nevertheless, breaching the cuticle with the
abrasive also impairs the integrity of the epidermal cells, even though
a severe damage of the protoplast does not occur. However, it appears
possible that abrasion might provide some type of mechanical
stimulation, followed by the production of as yet unknown signal
compounds. The results in Figure 5 provide a first hint that the
inductive abrasion can be replaced to a certain extent by rotating the
seedlings for 4 h in buffer. It is possible that the sheering
forces resulting from rotating the buffer constantly over the epidermal
surface might be sufficient to create some stimulus. It is of interest
in this context that a local mechanical stimulation imposed by placing
a needle to a suspension-cultured parsley cell can induce defense
responses including production of reactive oxygen species (Gus-Mayer et al., 1998).
The induction of H2O2
elicitor competence in cucumber hypocotyls was further enhanced when
spores of the melanin-deficient C. lagenarium mutant adhered
and germinated on the epidermal surface (Fig. 5). The induction
efficiency was not as pronounced as that after abrasion, likely because
only a smaller part of the cell surface was engaged compared with
abrasion, which likely disturbs a larger part of the cuticle.
Nevertheless, the adhesion of spores and the outgrowth of the germ
tubes on the surface in situ might be recognized by the attacked
epidermal cell, and thus induce competence for
H2O2 elicitation
concomitantly with the first availability of elicitors derived from
either the fungus or from degradation of the plant's cuticle by
esterases. The fact that the epidermal cells of cucumber recognize
fungal attack at this early time point is evident from the induction of
chitinase mRNA (Kästner et al., 1998). Induction of plant defense
responses in the absence of penetration has recently also been observed
with a nonpathogenic mutant of Magnaporthe grisea (Xu et
al., 1998).
In contrast to FE and hydroxy fatty acids, the novel cucumber cutin
monomer DDO elicited H2O2
synthesis in freshly abraded hypocotyl segments (Fig. 3; Table II).
This H2O2 production was not inhibited by DPI, K-252a, or La3+ (Fig. 4),
indicating a constitutive mechanism that clearly differs from the
NAD(P)H-oxidase pathway requiring induction by conditioning. The
enhanced level of H2O2
generated with DDO in the presence of KCN and
NaN3 is to be expected because of the inhibition
of H2O2 degradation under
the same conditions (Table III), and argues against the participation
of peroxidase in H2O2
generation from DDO, one of the most discussed possibilities distinct
from the NAD(P)-oxidase system (Hammond-Kosack and Jones, 1996).
The inducible mechanism responded to dodecan-1,2-diol, whereas this
alkanol was inactive in freshly abraded hypocotyls (Table II). Thus,
the additional hydroxyl group added at the second C atom of DDO fully
prevents H2O2 production by
the constitutive mechanism, suggesting that DDO may directly serve as a
substrate for a
H2O2-producing enzyme. The
wax storage vacuoles in jojoba beans contain a fatty acid ester of DDO,
as well as an enzyme that can use O2 and DDO to
produce the respective aldehyde with a stoichiometry that suggests that
the other product of the reaction may be
H2O2 (Moreau and Huang,
1979). If a similar enzyme were responsible for
H2O2 production from DDO in
cucumber, in the conditioned seedlings it must have the remarkable
property of being under regulation by
Ca2+-independent protein phosphorylation. This
can be concluded from the full inhibition by K-252a but not by
La3+ of the DPI-resistant part of the
H2O2 elicited by DDO in
conditioned hypocotyls (Fig. 5). The fate of further products
eventually arising from DDO remains unclear. Nevertheless, the
constitutive
H2O2-generating system may
operate in attacked epidermal cells of cucumber before the inducible
mechanism discussed above becomes functional. The H2O2 produced from the
cucumber cutin monomer DDO may act as a systemic signal, as is
increasingly discussed for other systems (e.g. Alvarez et al., 1998;
Chamnongpol et al., 1998). Additional pathways for
H2O2 production distinct
from the NAD(P)H-oxidase system have also been discussed as possibly
playing a role in plant/microbe interactions, e.g. the apoplastic
oxalate oxidase (Lane, 1994), peroxidase (Hammond-Kosack and Jones,
1996), and amine oxidase (Rea et al., 1998; Tipping and McPherson,
1995).
Taken together, our results show that the mechanism of
H2O2 elicitation in plant
tissues is more complex than was hitherto assumed from studies with
suspension cultures. A further stimulus is required to render the
NAD(P)H-oxidase system functional by a type of short-term developmental
process potentiated under SAR conditions. The successful
defense of pathogens obviously requires coordination of rather complex
and diverse responses. In cucumber these events may involve an
additional constitutive system for H2O2 production from the
cutin monomer DDO, which possibly represents an early product from the
plant/pathogen interface and may cover the time range before the
inducible H2O2 generation
system becomes functional.
| |
FOOTNOTES |
1
This work was supported by the Deutsche
Forschungsgemeinschaft and by the Fonds der Chemischen Industrie.
*
Corresponding author; e-mail kauss{at}rhrk.uni-kl.de; fax
49-631-205-2600.
Received March 8, 1999;
accepted May 6, 1999.
| |
ABBREVIATIONS |
Abbreviations:
BTH, benzo-(1,2,3)-thiadiazole-7-carbothioic
acid S-methyl ester.
DDO, dodecan-1-ol.
DHSA, threo-9,10-dihydroxystearic acid.
DPI, diphenylene iodonium.
FE, fungal
elicitor preparation from cell walls of Phytophthora
sojae.
HPA, 16-hydroxypalmitic acid.
INA, 2,6-dichloroisonicotinic acid.
SAR, systemic acquired resistance.
| |
ACKNOWLEDGMENTS |
We would like to thank R. Tenhaken and U. Conrath from our
laboratory for stimulating discussions and R. Eising
(Botanisches Institut der Universität, Münster,
Germany) for drawing our attention to the jojoba bean enzyme.
| |
LITERATURE CITED |
Alvarez ME,
Pennell RI,
Meijer P-J,
Ishikawa A,
Dixon RA,
Lamb C
(1998)
Reactive oxygen intermediates mediate a systemic signal network in the establishment of plant immunity.
Cell
92:
773-784
[CrossRef][Web of Science][Medline]
Baker B,
Zambryski P,
Staskawicz B,
Dinesh-Kumar SP
(1997)
Signaling in plant-microbe interactions.
Science
276:
726-733
[Abstract/Free Full Text]
Blumwald E,
Aharon GS,
Lam BC-H
(1998)
Early signal transduction pathways in plant-pathogen interactions.
Trends Plant Sci
3:
342-346
[CrossRef]
Chamnongpol S,
Willekens H,
Moeder W,
Langebartels C,
Sandermann H Jr,
Van Montagu M,
Inzé D,
van Camp W
(1998)
Defense activation and enhanced pathogen tolerance induced by H2O2 in transgenic tobacco.
Proc Natl Acad Sci USA
95:
5818-5823
[Abstract/Free Full Text]
Fauth M,
Merten A,
Hahn MG,
Jeblick W,
Kauss H
(1996)
Competence for elicitation of H2O2 in hypocotyls of cucumber is induced by breaching the cuticle and is enhanced by salicylic acid.
Plant Physiol
110:
347-354
[Abstract]
Fauth M,
Schweizer P,
Buchala A,
Markstädter C,
Riederer M,
Kato T,
Kauss H
(1998)
Cutin monomers and surface wax constituents elicit H2O2 in conditioned cucumber hypocotyl segments and enhance the activity of other H2O2 elicitors.
Plant Physiol
117:
1373-1380
[Abstract/Free Full Text]
Görlach J,
Volrath S,
Knauf-Beiter G,
Hengy G,
Beckhove U,
Kogel K-H,
Oostendorp M,
Staub T,
Ward E,
Kessmann H
(1996)
Benzothiadiazole, a novel class of inducers of systemic acquired resistance, activates gene expression and disease resistance in wheat.
Plant Cell
8:
629-643
[Abstract]
Graham MY,
Graham TL
(1994)
Wound-associated competency factors are required for the proximal cell responses of soybean to the Phytophthora sojae wall glucan elicitor.
Plant Physiol
105:
571-578
[Abstract]
Graham TL,
Graham MY
(1996)
Signaling in soybean phenylpropanoid responses: dissection of primary, secondary and conditioning effects of light, wounding and elicitor treatments.
Plant Physiol
110:
1123-1133
[Abstract]
Gus-Mayer S,
Naton B,
Hahlbrock K,
Schmelzer E
(1998)
Local mechanical stimulation induces components of the pathogen defense response in parsley.
Proc Natl Acad Sci USA
95:
8398-8403
[Abstract/Free Full Text]
Hammond-Kosack KE,
Jones JDG
(1996)
Resistance gene-dependent plant defense responses.
Plant Cell
8:
1773-1791
[CrossRef][Web of Science][Medline]
Hückelhoven R,
Kogel K-H
(1998)
Tissue-specific superoxide generation at interaction sites in resistant and susceptible near-isogenic barley lines attacked by the powdery mildew fungus (Erysiphe graminis f. sp. hordei).
Mol Plant-Microbe Interact
11:
292-300
Kästner B,
Tenhaken R,
Kauss H
(1998)
Chitinase in cucumber hypocotyls is induced by germinating fungal spores and by fungal elicitor in synergism with inducers of acquired resistance.
Plant J
13:
447-454
[CrossRef]
Kauss H,
Jeblick W
(1996)
Influence of salicylic acid on the induction of competence for H2O2 elicitation: comparison of ergosterol with other elicitors.
Plant Physiol
111:
755-763
[Abstract]
Kauss H, Jeblick W, Domard A, Siegrist J (1997) Partial
acetylation of chitosan and a conditioning period are essential for
elicitation of H2O2 in
surface-abraded tissues from various plants. In A Domard,
GAF Roberts, KM Vårum, eds, Advances in Chitin Science II. J. André Publisher, Lyon, France, pp 94-101
Keller T,
Damude HG,
Werner D,
Doerner P,
Dixon RA,
Lamb C
(1998)
A plant homolog of the neutrophil NADPH oxidase gp91phox subunit gene encodes a plasma membrane protein with Ca2+ binding motifs.
Plant Cell
10:
255-266
[Abstract/Free Full Text]
Lamb C,
Dixon RA
(1997)
The oxidative burst in plant disease resistance.
Annu Rev Plant Physiol Plant Mol Biol
48:
251-275
[CrossRef][Web of Science]
Lane BG
(1994)
Oxalate, germin, and the extracellular matrix of higher plants.
FASEB J
8:
294-301
[Abstract]
Moreau R,
Huang AHC
(1979)
Oxidation of fatty alcohol in the cotyledons of jojoba seedlings.
Arch Biochem Biophys
194:
422-430
[CrossRef][Medline]
Mur LAJ,
Naylor G,
Warner SA,
Sugars JM,
White RE,
Draper J
(1996)
Salicylic acid potentiates defence gene expression in tissue exhibiting acquired resistance to pathogen attack.
Plant J
9:
559-571
[CrossRef]
Rea G,
Laurenzi M,
Tranquilli E,
D'Ovidio R,
Federico R,
Angelini R
(1998)
Developmentally and wound-regulated expression of the gene encoding a cell wall copper amino oxidase in chickpea seedlings.
FEBS Lett
437:
177-182
[CrossRef][Web of Science][Medline]
Siegrist J,
Jeblick W,
Kauss H
(1994)
Defense responses in infected and elicited cucumber (Cucumis sativus L.) hypocotyl segments exhibiting acquired resistance.
Plant Physiol
105:
1365-1374
[Abstract]
Sticher L,
Mauch-Mani B,
Métraux JP
(1997)
Systemic acquired resistance.
Annu Rev Phytopahol
35:
235-270
[CrossRef][Web of Science][Medline]
Thordal-Christensen H,
Zhank Z,
Wei Y,
Collinge DB
(1997)
Subcellular localization of H2O2 in plants: H2O2 accumulation in papillae and hypersensitive response during the barley-powdery mildew interaction.
Plant J
11:
1187-1194
[CrossRef][Web of Science]
Thulke O,
Conrath U
(1998)
Salicylic acid has a dual role in the activation of defence-related genes in parsley.
Plant J
14:
35-43
Tipping AJ,
McPherson MJ
(1995)
Cloning and molecular analysis of the pea seedling copper amine oxidase.
J Biol Chem
270:
16939-16946
[Abstract/Free Full Text]
Xu J-R,
Staiger CJ,
Hamer JE
(1998)
Inactivation of the mitogen-activated protein kinase Mps1 from the rice blast fungus prevents penetration of host cells but allows activation of plant defense responses.
Proc Natl Acad Sci USA
95:
12713-12718
[Abstract/Free Full Text]
Top
Abstract
Introduction