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Plant Physiol, August 2001, Vol. 126, pp. 1716-1724
Transpiration Rate. An Important Factor Controlling the Sucrose
Content of the Guard Cell Apoplast of Broad Bean1
William H.
Outlaw Jr.* and
Xiaoyi
De Vlieghere-He
Department of Biological Science, Biology Unit I, Florida State
University, Tallahassee, Florida 32306-4370
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ABSTRACT |
Evaporation of water from the guard cell wall concentrates
apoplastic solutes. We hypothesize that this phenomenon provides two
mechanisms for responding to high transpiration rates. First, apoplastic abscisic acid is concentrated in the guard cell wall. Second, by accumulating in the guard cell wall, apoplastic sucrose (Suc) provides a direct osmotic feedback to guard cells. As a means of
testing this second hypothesized mechanism, the guard cell Suc contents
at a higher transpiration rate (60% relative humidity [RH]) were
compared with those at a lower transpiration rate (90% RH) in broad
bean (Vicia faba), an apoplastic phloem loader. In
control plants (constant 60% RH), the guard cell apoplast Suc content
increased from 97 ± 81 femtomol (fmol) guard cell pair 1 to 701 ± 142 fmol guard cell
pair1 between daybreak and midday. This increase is
equivalent to approximately 150 mM external, which is
sufficient to decrease stomatal aperture size. In plants that were
shifted to 90% RH before daybreak, the guard cell apoplast Suc content
did not increase during the day. In accordance, in plants that were
shifted to 90% RH at midday, the guard cell apoplast Suc content
declined to the daybreak value. Under all conditions, the guard cell
symplast Suc content increased during the photoperiod, but the guard
cell symplast Suc content was higher (836 ± 33 fmol guard cell
pair1) in plants that were shifted to 90% RH. These
results indicate that a high transpiration rate may result in a high
guard cell apoplast Suc concentration, which diminishes stomatal
aperture size.
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INTRODUCTION |
Potassium and its counterions are
the well-known fluctuating osmotica that cause stomatal movements
through regulation of the aqueous volume of guard cells (for review,
see Outlaw, 1983 ; Zeiger, 1983). Thus, an accumulation of potassium
causes stomatal opening and a dissipation of potassium may cause
stomatal closing. Suc has been found more recently to be an important
fluctuating osmolyte in the guard cell symplast (Tallman and Zeiger,
1988; Poffenroth et al., 1992; Talbott and Zeiger, 1993, 1996, 1998; Amodeo et al., 1996) and the guard cell apoplast (Lu et al., 1995). The
importance of Suc in stomatal aperture size regulation lies in the
difference between Suc concentrations in the guard cell symplast and
the guard cell apoplast. Therefore, it is important to know the sources
and conditions leading to changes in the Suc concentration in both
these compartments, as discussed below.
Three sources have been proposed for the elevation of guard cell
symplastic Suc in open stomata: (a) The photosynthetic carbon reduction
pathway is the first (Gotow et al., 1988; Poffenroth et al., 1992;
Talbott and Zeiger, 1993), but guard cells typically do not have
sufficient carbon flux through this pathway (Outlaw, 1989; Tarczynski
et al., 1989; Reckmann et al., 1990; Gautier et al., 1991; Lu et al.,
1997) to account for Suc accumulation. (b) Starch breakdown in guard
cells is a second potential source of Suc (Tallman and Zeiger, 1988;
Talbott and Zeiger, 1993). Although light quality (Poffenroth et al.,
1992), the availability of external chloride (Raschke and Schnabl,
1978), and osmotic stress (Kopka et al., 1997; Asai et al., 1999)
regulate carbon metabolism in guard cells, the amount of starch in
guard cells appears to be a limiting factor. (c) Import of Suc by an
H+-Suc symporter (Ritte et al., 1999) is a final
potential source of guard cell symplastic Suc. Import is consistent
with the presence of Suc in the guard cell apoplast (Lu et al., 1995)
and of Suc-metabolizing enzymes that are associated with photosynthate
sinks (Hite et al., 1993).
Mesophyll-derived leaf apoplastic Suc is the source of guard cell
apoplastic Suc (Lu et al., 1997) during midday in broad bean
(Vicia faba), an apoplastic phloem loader (Delrot et al., 1983; Kühn et al., 1999). Suc becomes concentrated in the guard cell apoplast because this is the distal point in the evaporative pathway. In accordance, the extent to which Suc accumulates in the
guard cell apoplast is hypothesized to be controlled by two interacting
physiological parameters: (a) the Suc concentration in the leaf
apoplast, which is a function of photosynthesis rate and the transport
rate from the leaf (Ntsika and Delrot, 1986; Lohaus et al., 1995); and
(b) the rate of transpiration. As discussed below, this second
parameter indicates that guard cell apoplast Suc concentration may be a
factor in the stomatal closing response to increasing vapor pressure
difference (VPD).
In a landmark study, Mott and Parkhurst (1991) found that the stomatal
response to humidity is consistent with sensing of the transpiration
rate rather than of relative humidity (RH) per se. A reanalysis
(Monteith, 1995) of 52 published sets of measurements and subsequent
work (Jarvis et al., 1999) support this conclusion. Therefore, Lu et
al. (1997) hypothesized that transpiration-linked accumulation of guard
cell apoplastic Suc is a mechanism by which plants respond to high
transpiration rate. The present study is a test of that hypothesis.
Broad bean plants were maintained at 60% RH (control conditions) or
shifted to 90% RH, which decreased the transpiration rate.
At various times, the guard cell apoplast Suc contents, the guard cell
symplast Suc contents, the whole-leaf Suc contents, and the
bulk-leaf apoplast Suc concentrations were determined. The results
indicate that sufficient Suc accumulates in the guard cell apoplast to
diminish stomatal aperture size at a high transpiration rate but not at
low transpiration rate.
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RESULTS |
Lowered VPD Increased Guard Cell Symplast Suc Content, Prevented an
Increase in the Guard Cell Apoplast Suc Content, and Decreased
Transpiration
The essence of this report is a comparison of the Suc contents of
the guard cell symplast and the guard cell apoplast under control
conditions (constant 60% RH) and RH shift conditions (90% RH). The
results of the control experiments (compare with Lu et al., 1995) and
the RH shift experiments will be described (Fig. 1), respectively. Then, results under the
two conditions will be compared (Table I), along with
changes in the transpiration rate.
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Figure 1.
Time course for Suc content changes in the guard
cell symplast ( ) and the guard cell apoplast ( ). Broad bean
plants were cultured at a constant 60% RH in a growth chamber (14-h
day, 20°C/25°C, 600 µmol photons m2
s1). Control plants (upper; n = 16 [two experiments]) were maintained at 60% RH (Lu et al., 1995),
whereas the RH-shifted plants (lower; n = 40 [five
experiments]) were transferred to 90% RH 8 h before the onset of
the photoperiod. Corresponding stomatal aperture sizes
(n = 48-120) are represented by the histogram. Errors
are SE.
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Table I.
Statistical comparisons of the guard cell-apoplast
Suc contents, the guard cell-symplast Suc contents, and stomatal
aperture sizes at a constant 60% RH versus cognate values obtained
when the RH was shifted to 90% 8 h prior to the onset of illumination
The compared values are derived from Figure 1, which provides other
details.
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Control experiments (upper, Fig. 1) were conducted on plants that were
maintained at 60% RH. The guard cell apoplast Suc content was low at
the onset of the photoperiod (0600 h, 97 ± 81 femtomol [fmol] guard cell pair1) and was
correlated with a small stomatal aperture size (2.0 ± 1.6 µm).
No significant changes took place in this Suc pool (P > 0.11, compared with 0600 h) or in stomatal aperture size over the next 3 h. By 1100 h, however, the
guard cell apoplast Suc content had increased (P < 0.02 for all earlier values) by 7-fold to 701 ± 142 fmol guard
cell pair1 (upper, Fig. 1). This highest value
in guard cell apoplast Suc content during the photoperiod was
correlated with the largest stomatal aperture size (7.4 ± 2.3 µm, P < 0.01). The increase in guard cell apoplast Suc
content during the photoperiod was approximately 145 mM (for conversion factors, see Ewert et al., 2000). In these experiments, the apparent decreases between 1100 h
and 1300 h in guard cell apoplast Suc content (to 504 ± 77 fmol guard cell pair1, P > 0.11) and in stomatal aperture size (to 6.2 ± 2.1 µm) were not significant.
Under control conditions, the symplast Suc pool size in guard cells
increased linearly from the onset of the photoperiod (270 ± 49 fmol guard cell pair1) to 1100 h (551 ± 88 fmol guard cell pair1, P = 0.04). The apparent decrease in the guard cell symplast Suc pool size
between 1100 h and 1300 h was not significant
(P = 0.14). Overall, the results of the control
experiments are in general qualitative agreement with those of Lu et
al. (1995).
Figure 1 (lower) shows the results for RH-shifted plants (in these
experiments, plants were transferred to 90% RH 8 h before the
onset of the photoperiod). The guard cell apoplast Suc content was
initially low (0600 h, 173 ± 48 fmol guard cell
pair1) and was correlated with a small stomatal
aperture size (0.9 ± 1.0 µm). The guard cell apoplast Suc pool
size did not change significantly over the course of the experiment.
The stomatal aperture size increased significantly (P < 0.01) by 0900 h to 6.5 ± 2.1 µm, and reached a highest
value at 1100 h (11.6 ± 2.0 µm). In these experiments, the
decrease between 1100 and 1300 h in stomatal aperture size (to
9.3 ± 1.9 µm) was significant.
Under these RH shift conditions, the symplast Suc pool size in guard
cells increased linearly from the onset of the photoperiod (383 ± 33 fmol guard cell pair1, P < 0.01). The apparent decrease in the guard cell symplast Suc pool size
between 100 h and 1300 h was not significant
(P = 0.37).
Pair-wise comparisons of the guard cell symplast Suc contents, the
guard cell apoplast Suc contents, and stomatal aperture sizes under
control and RH shift conditions are shown in Table I. At 0600 or
0700 h, altered VPD did not have a significant effect on the guard
cell apoplast Suc content, the guard cell symplast Suc content, or the
stomatal aperture size, but all three of these parameters were
significantly altered by lowered VPD at 1100 and 1300 h.
Stomatal aperture size is proportional to conductance (broad bean; see
Zhang and Outlaw, 2001b). Between 0900 and 1100 h, the average
increase in stomatal conductance for RH-shifted plants was twice that
of control plants (Fig. 1, Table I). At all times, however, the average
stomatal conductance of control plants was less than 0.5-fold that of
RH-shifted plants.
In summary, the main features that were altered by the shift to 90% RH
were exemplified at 1100 h (Fig. 1, Table I): (a) a 1.6-fold
greater stomatal aperture size, coupled with a nominal 4-fold decrease
in VPD, which led to a less than 2-fold decrease in transpiration rate;
(b) a 1.5-fold increase in the guard cell symplast Suc content; and (c)
the absence of a 7-fold increase in the guard cell apoplast Suc content.
The Changes in Guard Cell Suc Pools Caused by the Shift to 90% RH
Were Not Artifacts Resulting from External Liquid Water
At 90% RH and 25°C, the dew point is 23.2°C. This small
temperature differential raises the possibility that transient
microscopic external water droplets on the leaf surface at 90% RH
leach the contents of the guard cell apoplast. As a means of testing
this possibility, guard cell Suc was assayed in leaflets that were washed vigorously immediately before sampling. As expected, the symplast Suc content of guard cells (Fig.
2) was not affected by the washing
treatment (516 ± 66 fmol guard cell pair1
versus 541 ± 58 fmol guard cell pair1
[P = 0.21]). The apoplast Suc content of guard cells
also was not affected by the washing treatment (655 ± 68 fmol
guard cell pair1 versus 650 ± 64 fmol
guard cell pair1 [P = 0.70]).
Therefore, the diminution of guard cell apoplast Suc content in
RH-shifted plants (Fig. 1) cannot be attributed to artifactual dew
formation.
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Figure 2.
Suc content of the guard cell symplast (left pair
of columns) and of the guard cell apoplast (right pair of columns) of
control leaflets ( ) and of leaflets that were washed before sampling
( ). Samples were collected at constant 60% RH. n = 24 (three experiments). P values (t test) are for
the paired columns; other details are as in Figure 1.
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The Changes in Guard Cell Suc Contents Caused by the Shift to
90% RH Were Not Artifacts Resulting from Limited Sample Sizes Used
for Quantitative Histochemistry
Suc content varies by as much as 2-fold within an individual broad
bean leaflet (Outlaw and Manchester, 1979), raising the possibility
that changes in Suc pools attributed to the RH shift (Fig. 1) are
sampling artifacts. As a first means of eliminating this possibility,
multiple areas of each leaflet were selected randomly for dissection of
guard cells (see "Materials and Methods"). As a second means of
eliminating this possibility, guard cell Suc contents were studied
exhaustively at 1100 h under the control and RH shift conditions
of Fig. 1. Altogether (Fig. 3), 624 guard cell pairs, individually dissected from 78 leaflets, were extracted individually and analyzed. In control plants, the guard cell apoplast Suc content was 701 ± 96 fmol guard cell
pair1 (Fig. 3), in contrast to the 205 ± 52 fmol guard cell pair1 of RH-shifted plants.
This significant decrease (P < 0.01) of 496 fmol guard
cell pair1 is equivalent to a concentration
change of 120 mM (for conversion factor, see
Ewert et al., 2000). In control plants, the guard cell symplast Suc
content was 479 ± 69 fmol guard cell
pair1, less than that of RH-shifted plants
(894 ± 27 fmol guard cell pair1). This
significant increase (P = 0.02) is 415 fmol guard cell pair1.
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Figure 3.
Suc content of the guard cell symplast () and
the guard cell apoplast () at 60% RH (left column in each pair) and
at 90% RH (right column in each pair) at 1100 h.
n = 88-224 guard cell pairs (11-28 plants) for each
column. P values (t test) are for the paired
columns; other details are as in Figure 1.
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In summary, at 1100 h, the total guard cell Suc pool at 60% RH
was 1,180 fmol guard cell pair1, of which 59%
was apoplastic, whereas the total guard cell Suc pool at 90% RH was
1,099 fmol guard cell pair1, of which 19% was apoplastic.
The Changes in Guard Cell Suc Pools Caused by the Shift to 90% RH
Were Not Consequences of Changes in the Whole-Leaf Suc Content or
the Bulk-Apoplast Suc Concentration
Both the bulk-apoplast Suc concentration and the whole-leaf Suc
content may increase during the photoperiod, raising the possibility that either or both are altered by an RH shift and, thus, account for
guard cell Suc pool changes (Figs. 1 and 3) independently of the
transpiration rate. The bulk-apoplast Suc concentration was, as
expected, higher (top, Fig. 4) at
1100 h than at 0600 h in control plants ( = 0.3 mM; P < 0.01) but not in RH-shifted plants
(app = 0.2 mm; P = 0.08).
There was also a significant difference (P < 0.01) in
the bulk-apoplast Suc concentration at 1100 h in the control (0.94 mM) and RH-shifted (0.67 mM) plants. However, the absolute difference was
much smaller than the corresponding severalfold difference in the guard
cell apoplast Suc contents (Fig. 3).
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Figure 4.
Suc concentration in the apoplastic sap (top) and
the Suc content of whole leaf (lower) at 60% RH () and at 90% RH
( ) at various times during the photoperiod. Apoplastic sap
(n = 9 [three experiments]) was obtained with the
pressure chamber. Separate extracts for Suc analysis were made of three
random fragments of each freeze-dried whole leaf used in the
experiments displayed in Figure 1, which provides additional
details.
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The whole-leaf Suc content was higher (lower, Fig. 4) at 1100 h
than at 0600 h in control (P = 0.04) and in
RH-shifted (P < 0.01) plants. The 2-fold increase,
nominally 60 mmol kgdry mass1,
occurred independently of RH.
Lowering VPD during Midday Caused an Increase in the Guard
Cell Symplast Suc Content, a Decrease in the Guard Cell Apoplast Suc
Content, and a Decrease in Transpiration
The previous sections establish that a shift from 60% RH to 90%
RH 8 h before the onset of the photoperiod results in an elevation in the guard cell symplast Suc content and prevents an increase in the
guard cell apoplast Suc content during the following day (Figs. 1 and
3). These changes were not an artifact of the high ambient humidity
(Fig. 2), and they could not be accounted for by RH-induced changes in
the whole-leaf Suc content or the bulk-leaf apoplast Suc concentration
(Fig. 4). In this section, the effects of an RH shift during the
photoperiod, when stomata are open, will be addressed. In these
experiments, all plants were maintained at 60% RH until 1100 h;
then, some plants were shifted to 90% RH (Fig.
5). At 1100 h in control plants, the
guard cell apoplast Suc content was 743 ± 107 fmol guard cell
pair1; the stomatal aperture size, 7.4 ± 1.6 µm; and the guard cell symplast Suc content, 441 ± 71 fmol
guard cell pair1 (Fig. 5). These values were
not significantly different from those at 1100 h in plants that
were later shifted to 90% RH or from those in control plants at
1300 h. Shifting to 90% RH during the photoperiod corresponded to
a decrease in the guard cell apoplast Suc content to 96 ± 120 fmol guard cell pair1 (P < 0.01), an increase in stomatal aperture size to 9.0 ± 1.8 µm
(P < 0.01), and an increase in the guard cell symplast
Suc content to 832 ± 92 fmol guard cell
pair1 (P < 0.01). Thus, the RH
shift resulted in a decrease of the Suc concentration of 155 mM in the guard cell apoplast.
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Figure 5.
The Suc content in the guard cell symplast ()
and in the guard cell apoplast () at 1100 h and at 1300 h.
The control plants (left) were maintained at constant 60% RH (Fig. 1;
Lu et al., 1995). RH-shifted plants (right) were shifted from 60% RH
at 1100 h to 90% RH, which required approximately 10 min. The
experiments were conducted in duplicate; five leaflets were sampled in
each experiment for each datum (n = 80 guard cells per
column). Corresponding stomatal aperture sizes (n > 180)
are represented by triangles (, plants at 60% RH;  , plants at
90% RH). Data labeled by identical alphabetic characters are not
significantly different (P > 0.05). Other details are
as in Figure 1.
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DISCUSSION |
The Physiological Relevance of Changes in Guard Cell Suc
Contents
The guard cell Suc apoplast concentration varied by 7-fold,
depending on conditions and time of day (Figs. 1 and 5; Table I). The
difference that coincided with lowering the transpiration rate was 620 fmol guard cell pair1 (right, Fig. 5). The
aqueous cell wall volume of a pair of broad bean guard cells is 4.2 pL
(Ewert et al., 2000), indicating that the Suc concentration in the
guard cell apoplast changed by approximately 0.16 molal, equivalent to
a  s = 0.4 MPa (Michel, 1972). Similar calculations for the guard cell symplast, yielding
s  0.2 MPa, are imprecise because the
volume of the guard cell symplast increases with stomatal aperture
size. (That is, part of the increase in Suc content of the guard cell
symplast simply maintains the concentration there as the volume
increases.) There are various estimates for s (guard cell)
µm1 (stomatal aperture) for broad bean. Hsiao
(1976) cites a range of 0.12 to 0.2 MPa µm1
from four studies, and Poffenroth et al. (Table III, 1992) use a range
of 0.05 to 0.16 MPa µm1, derived from three
different studies, in model calculations. Use of the midpoint of these
values, 0.125 MPa µm1, provides a perspective
on the importance of Suc fluctuations on stomatal aperture size. Thus,
the change in guard cell apoplast Suc concentration predicts a change
in aperture size of about 3 µm. In summary, the most important
conclusion is that decreasing the transpiration rate coincides with
reciprocal changes in the guard cell Suc pools that are sufficient to
increase stomatal aperture size.
Concordance of Transpiration and Suc Fluxes in the Guard Cell
Apoplast
From the stomatal aperture sizes at 1100 h (Fig. 5) and
ambient conditions, the rate of transpiration is calculated to be 2 mmol water m2 s1, or 20 pL guard cell pair1
min1. This value is in close agreement with the
directly measured transpiration rates for broad bean under similar
conditions (1-2.5 mmol m2
s1, Ewert et al., 2000) and indicates that the
guard cell apoplast water turns over about five times each minute if
all evaporation occurs at this site. The rate of delivery of Suc to the
guard cell apoplast is the product of evaporation rate and
concentration of Suc in the transpiration stream. The concentration of
Suc in the transpiration stream near stomata is unknown (see
"Materials and Methods"), but labeling experiments indicate that
the sap expressed from the petiole provides an underestimate of the Suc concentration near the minor veins (Lu et al., 1997). Thus, use of that
sap value (approximately 1 mM, Fig. 4) to
calculate the rate of Suc delivery to the guard cell wall, 20 fmol
guard cell pair1 min1,
is similarly underestimated, but is still 5-fold the observed rate of
Suc accumulation in the guard cell apoplast (Fig. 1). In summary,
delivery of Suc via the transpiration stream can account for Suc
accumulation in the guard cell apoplast and is consistent with previous
results (Lu et al., 1997) that demonstrated that the source of guard
cell apoplastic Suc is the mesophyll. This interpretation is also
consistent with a CO2 (Internal)-independent mesophyll signal that prevents further stomatal opening when light is
increased (Muschak et al., 1999).
The decline in guard cell apoplast Suc content when the RH was shifted
to 90% was 620 fmol guard cell pair1 (Fig. 5),
as discussed above. Thus, the average net loss over this 2-h period
was 5 fmol guard cell pair1
min1, which is 10-fold less than the
unidirectional efflux rate calculated on the basis of
14C compartmentation analysis (Lu et al., 1997).
The relationship of these values is consistent and indicates the
rapidity with which conductance may be affected by VPD via an
apoplastic solute mechanism.
Suc Uptake by Guard Cells
Direct in planta measurements of
14CO2 incorporation by
guard cells (Lu et al., 1997) of broad bean plants grown identically to
those in this study showed that guard cell photosynthesis is not
sufficient as a source of the increased Suc content of guard cells
(Fig. 5). The starch content of guard cells of open stomata of broad
bean, approximately 500 fmol (anhydroglucosyl units) guard cell
pair1 (Outlaw and Manchester, 1979), is
somewhat low to account for the increased Suc content of guard cells
upon RH shift (Fig. 5), but guard cell starch measurements under
several conditions have not been made. The simplest interpretation is
the guard cell symplast Suc increase (Fig. 5) must result
from uptake from the apoplast. At 40 mM external Suc, the average
rate of 14C-Suc uptake by broad
bean guard cells was 225 fmol guard cell pair1 h1 (Outlaw,
1995). That rate is similar to the average rate of increase in the
guard cell symplast Suc content caused by shifting the RH from 60% to
90% (Fig. 5), indicating that guard cells have sufficient
Suc-transport capacity.
The increase in the guard cell symplast Suc content when plants were
shifted to 90% RH (Figs. 1 and 5) was unexpected, but may be related
to increased symplast volume with increased stomatal aperture size or
to observations (Amodeo et al., 1996; Talbott and Zeiger, 1996) that
Suc is the major guard cell osmoticum later in the day. Regardless, the
increase reveals that environmental control of stomatal aperture size
by Suc fluctuations is not simply a physical process that balances
evaporative deposition of Suc in the guard cell apoplast against
diffusion from this site of accumulation. An explanation requires
further understanding of guard cell Suc transport and metabolism, but
present evidence indicates regulation of these processes. In this
regard, it is relevant to note that Outlaw (1995) and Ritte et al.
(1999) observed large variability among experiments in Suc uptake by
guard cells, and Kopka et al. (1997) reported a water stress-induced
decrease in guard cell expression of the Suc transporter. It is also
intriguing that high Suc concentrations suppress expression of a Suc
transporter in broad bean (Weber et al., 1997), whereas high guard cell
apoplast Suc concentration coincided with reduced guard cell symplast
Suc uptake (Figs. 1 and 5). However, the coincidence of these
observations must not be overinterpreted, as Suc transporters comprise
a family with differently regulated members filling dedicated
physiological roles (Williams et al., 2000). In summary, regulation of
guard cell Suc uptake is likely to be multifaceted, involving
posttranslational (Roblin et al., 1998) or transcriptional or
posttranscriptional (Williams et al., 2000) regulation, and requires
further study.
The RH-linked change in guard cell Suc contents (Figs. 1 and 5)
reconciles reported quantitative differences in broad bean guard cell
symplast Suc contents. Thus, Lu et al. (1995) grew plants on a 16-h
day, 20°C/25°C, and 60% RH regimen and reported an increase in
guard cell symplast Suc contents from 140 to 350 fmol Suc guard cell
pair1 over the day. Talbott and Zeiger (1996)
grew plants on a 12-h day, 25°C/15°C, and an 85% RH regimen but in
a growth cabinet of similar design and light intensity. They reported a
larger increase, from 400 to 1,200 fmol Suc guard cell
pair1, in guard cell symplast Suc contents over
the day. The present data (Figs. 1, 3, and 5) imply that transpiration
rate is a factor in the above-reported differences. As a further
reconciliation, the absence of leaf photosynthesis probably accounts
for the small, but significant, changes in guard cell Suc content
during light and  CO2-induced stomatal opening
(Outlaw and Manchester, 1979) because mesophyll photosynthesis is the
source of guard cell Suc (Lu et al., 1997). Altogether, the reported
differences in guard cell Suc quantitation appear to reflect different
physiological states, suggesting avenues for further investigation.
Other Consequences of a High-Suc Environment
The Suc concentration in the guard cell apoplast, approximately
150 mM (Figs. 1 and 5), of plants grown at 60% RH is consistent with a
role of sugars in guard cell gene expression (Koch, 1996; Pego et al.,
2000). In particular, enzymes involved in photosynthetic carbon
metabolism are repressed by sugar (Pego et al., 2000). This repression
is an explanation for low or undetectable levels for markers of
photosynthetic carbon metabolism such as mRNA for Rubisco and plastidic
fruP2ase (Kopka et al., 1997), Rubisco protein (Tarczynski et al., 1989), light-induced P-Gly concentration increase (Outlaw and Tarczynski, 1984), and
14CO2 incorporation (Lu et
al., 1997). Although most quantitative studies support the conclusion
that photosynthetic carbon metabolism is very limited in guard cells
(Outlaw, 1989; see also Vaughn and Vaughan, 1988), there are
exceptions. As discussed earlier (Outlaw, 1989), the most significant
exception is that of Shimazaki and Zeiger (1987), who reported rates of
broad bean guard cell CO2 uptake that are typical
of mesophyll cells on a chlorophyll basis (but only 2%-4% as
much as mesophyll cells on a cell basis because of the low chlorophyll
content of guard cells). It is notable that growth conditions in the
Shimazaki and Zeiger study were at a higher RH and lower temperature,
both of which lower VPD. Therefore, we hypothesize that transpiration
rate is an indirect factor in guard cell carbon metabolism. Minimum
Rubisco-specific fluorescence in all C3 and
C4 guard cells studied and considerable Rubisco-specific fluorescence in many crassulacean acid
metabolism guard cells (Madhavan and Smith, 1982) might also be
explained by differences in transpiration and, hence, sugar repression. Confidence in an interpretation of the role of Suc in guard cell gene
expression requires further investigation, which will be complicated
because phosphate (which is high in guard cells; Outlaw et al., 1984)
modulates sugar-inducible genes (Sadka et al., 1994) and because the
ABA and Suc signal transduction networks overlap (Huijser et al.,
2000).
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MATERIALS AND METHODS |
Plant Growth and Treatments
Broad bean (Vicia faba L. cv Longpod) plants were
grown in a growth chamber in Fafard No. 2 soil-less potting medium at a density of two plants per 1-L pot. In brief, culture conditions were a
16-h day with a constant 60% RH and a 25°C/20°C day/night temperature regime. Illumination (photosynthetic photon flux density 600 µmol m2 s1) was supplied by a
combination of fluorescent and incandescent lamps. Full details of the
ramping program for the temperature and light transitions in the growth
chamber are given in Lu et al. (1997). The second fully expanded
bifoliate of 3-week-old plants was used in all experiments.
As a means of assessing the long-term and short-term effects of lowered
transpiration rate on the symplastic and apoplastic pools of guard cell
Suc, ambient RH was shifted to 90% RH: (a) at 2000 h the day
before sampling, which provided a night of acclimation and stomatal
opening under the higher humidity; and (b) at 1100 h on the day of
sampling, which provided otherwise steady-state conditions during the
RH shift.
Precision of Humidity Treatments and Associated Effects
At a set point of 60% RH, an RH range of 59% to 64% was
maintained; at a set point of 90% RH, an RH range of 86% to 92% was maintained. The shift from 60% to 90% RH required approximately 10 min. Ambient temperature was maintained within 0.3°C. Leaf temperature under these conditions (and wind speed of 25 cm
s1) is approximately 1°C higher than ambient
temperature (see Gates, 1968). These data indicate that the VPD at 60%
RH was 2.9- to 4.6-fold that at 90% RH, or possibly higher if the leaf
temperature was higher at the lower transpiration rate at 90% RH. In
summary, the RH shift provided the designed decrease in the driving
force for transpiration.
Tissue Samples
Whole-Leaf and Guard Cell Samples
Four manipulations in the indicated order were made on each
bifoliate: (a) leaf conductance was measured on one side of one leaflet
with an LI-600 Steady State Porometer (LI-COR, Inc., Lincoln, NE), and
(b) a 1- × 2-cm rectangle, cut from the opposite side of this leaflet,
was frozen in liquid N2, freeze dried (35°C, <0 µm
Hg, 4 d), and stored at 20°C under vacuum. Individual guard cell pairs dissected from whole-leaf samples contained both the apoplast and symplast Suc pools. Next, (c) an abaxial epidermal peel
was taken from the sister leaflet, rinsed in water for 1 min to remove
apoplastic solutes from guard cells (Zhang and Outlaw, 2001a), and then
frozen in liquid N2. Individual guard cell pairs subsequently dissected from rinsed freeze-dried epidermal peel contained only the symplast Suc pool. Finally, (d) another peel, from
the opposite side of this leaflet, was stained with 0.03% (w/v)
aqueous neutral red and stomatal aperture sizes were determined microscopically.
Spurious conductance values were sometimes obtained at 90% RH, so
interpretations rely on stomatal aperture sizes, which are linearly
related to conductance (r2 = 0.98;
Zhang and Outlaw, 2001b; see also Weyers and Meidner, 1990).
Leaf Apoplast Sap Samples
Leaflet apoplast sap was obtained with a pressure chamber (Model
1000, PMS Instrument Co., Corvallis, OR) as detailed by Ewert et
al. (2000). Sap extruded by pressurizing the chamber to 0.5 MPa was
discarded. The pressure was increased to 1.0 MPa, which resulted in the
extrusion of approximately 5 µL sap. This sap was collected as the
bulk-leaf apoplast sample and stored at 80°C until analysis.
Altogether, the procedures required less than 3 min. It is important to
caution against overinterpretation of solute concentrations in sap
expressed by the pressure bomb (Jokhan et al., 1996, 1999).
Suc Assay
Guard Cells
Sub-microliter constriction pipettes and the oil well technique
were used for Suc analysis of guard cell pairs randomly dissected from
freeze-dried tissue (Lu et al., 1997; Outlaw and Zhang, 2001). The
guard cell apoplast Suc content was calculated by subtraction of the
Suc content of guard cells dissected out of rinsed peels from that of
guard cells dissected out of whole leaf. Standard errors for guard cell
apoplast Suc contents were calculated by a conservative routine (Rice,
1987) that incorporated the variance of the Suc contents of both types
of guard cell samples. P < 0.05 was considered significant.
Whole Leaf and Leaf Apoplast
A freeze-dried leaf fragment (approximately 150 µg) was heated
for 30 min at 95°C in 0.5 mL 0.02 N NaOH. Then, the extract was
cooled to room temperature and 0.5 mL of double-strength pH-compensated Suc-specific step reagent was added. After 30 min, the increase in
NADPH concentration was determined fluorometrically.
Apoplast sap was diluted 1,000-fold in 0.02 N NaOH and
subsequently analyzed by the oil well technique.
| |
ACKNOWLEDGEMENTS |
Ping Lu is thanked for technical assistance. T. Jiang,
Yun Kang, Fanxia Meng, Nedra Outlaw, Danielle Sherdan, and Dr. William M. Outlaw are thanked for manuscript suggestions.
| |
FOOTNOTES |
Received February 28, 2001; returned for revision May 5, 2001; accepted May 22, 2001.
1
This work was supported by the U.S. Department
of Energy (grant to W.H.O.).
*
Corresponding author; e-mail outlaw{at}bio.fsu.edu; fax
850-644-0481.
| |
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ABSTRACT
INTRODUCTION