Plant Physiol. (1998) 118: 1507-1515
pH-Regulated Leaf Cell Expansion in Droughted Plants Is Abscisic
Acid Dependent1
Mark A. Bacon*,
Sally Wilkinson, and
William J. Davies
Biological Sciences Department, Institute of Environmental and
Natural Sciences, Lancaster University, Bailrigg, Lancaster LA1 4YQ,
United Kingdom
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ABSTRACT |
Elongation rates of barley
(Hordeum vulgare L. cv Hanna) leaves decreased with
decreasing soil water content, whereas the pH of xylem sap increased
from 5.9 to 6.9 over 6 d as the soil dried. The reduction in
leaf-elongation rate (LER) was correlated with the increase in sap pH.
Artificial sap buffered to different pH values was fed via the subcrown
internode to derooted seedlings. Although leaves elongated at in planta
rates when fed artificial sap at a well-watered pH of 6.0, LER declined
with increasing sap pH. This effect persisted in the light and in the
dark. pH had no effect on the relative water content or the bulk
abscisic acid (ABA) concentration of the growing zone of these leaves. LERs of the ABA-deficient mutant Az34 were uniformly high over the pH
range tested, whereas those of its isogenic wild-type cultivar Steptoe
were reduced as the artificial sap pH was increased from 6.0 to 7.0. However, supplying a well-watered concentration of ABA (3 × 10
8 M) in the artificial xylem sap restored
the pH response of the Az34 mutant. The results suggest that increased
xylem sap pH acts as a drought signal to reduce LER via an
ABA-dependent mechanism.
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INTRODUCTION |
In fertile soils the growth and yield of plants is more sensitive
to water availability than to any other environmental factor (Kramer,
1974
; Boyer, 1982). The direct relationship between crop yield and the
rate of leaf production and expansion (Monteith, 1977), coupled with
the high sensitivity of the leaf growth process to drought (Hsiao,
1973), provide both academic and economic motives to further our
understanding of the mechanism by which leaf expansion is restricted
during drought.
Although the basis of leaf expansion has been subject to investigation
for many years (e.g. Hales, 1727; Sachs, 1887; Begg and Wright, 1962;
Baker et al., 1985; Palmer and Davies, 1996), substantial questions
concerning its control and regulation remain unanswered (Dale, 1988).
The mechanistic basis by which leaf expansion is restricted during
drought has received comparatively little attention. Clearly, leaf
water relations can and do play a vital role in the determination of
the rate of leaf growth, but reductions in growth during drought
frequently occur in the absence of any decline in leaf turgor
(Passioura, 1988; Gowing et al., 1990; Puliga et al., 1995). Michelena
and Boyer (1982) demonstrated that although LERs of maize growing in
drying soil were significantly reduced, sufficient solutes accumulated
in the leaf-elongation zone to maintain virtually constant turgor. This
suggests the involvement of regulatory processes aside from leaf water
relations that can control the rate of leaf expansion during drought.
Increases in xylem sap pH during soil drying and other stresses are
frequently observed (Hartung and Radin, 1989; Gollan et al., 1992;
Wilkinson and Davies, 1997; Wilkinson et al., 1998), which may give
rise to increases in the apoplastic (wall) pH of leaf tissues (Hoffmann
and Kosegarten, 1995). The importance of pH in mediating physiological
responses to stress has long been recognized (Hartung and Radin, 1989)
and more recently it was shown to form a stress signal that controls
gas exchange in leaves of plants growing in drying soil (Wilkinson and
Davies, 1997; Wilkinson et al., 1998).
An early indication that drought may control leaf growth via its
effects on apoplastic pH was given by Van Volkenburgh and Boyer (1985).
They reported that reductions in leaf growth of maize plants subjected
to a soil-drying treatment correlated with a reduced ability of the
leaf to acidify a weakly buffered droplet of solution placed on its
surface and assumed to be in contact with the apoplast. The pH of the
droplet on the leaf surface of plants growing in drying soil was
initially higher (pH 6.3) than that from well-watered plants (pH 5.9),
and plants growing in drying soil showed a reduced ability to acidify
the droplet in response to illumination. Van Volkenburgh and Boyer
(1985) demonstrated the possibility of a drought-induced increase in
apoplastic sap pH and provided the first suggestion that there is a
possible link between apoplastic pH and the rate of leaf expansion
during drought.
In intact leaves, increases in xylem sap pH cause closure of stomata
(Wilkinson and Davies, 1997). This pH response was shown to require the
presence of ABA, but only at the very low concentration found in the
xylem sap of most well-watered plants. This is a concentration that
does not affect stomatal aperture in a well-watered environment
(Wilkinson et al., 1998). Rather than having a direct effect on
stomatal guard cell turgor, increased pH mediates an accumulation of
ABA in the apoplast surrounding the guard cells (Hartung et al., 1998).
ABA receptors on the external plasma membrane of the stomatal guard
cells (Hartung, 1983) are thus stimulated to induce changes in guard
cell turgor and hence in stomatal aperture via effects on membrane ion
channels (see MacRobbie, 1991). In this paper we investigate the
possibility that high pH could induce reductions in leaf expansion via
a mechanism that involves ABA.
A role for ABA in the control of leaf expansion during water deficit
has already been suggested (e.g. Zhang and Davies, 1990a, 1990b; Dodd
and Davies, 1996). Increased concentrations of this hormone will reduce
leaf elongation in vivo and in vitro (Zhang and Davies, 1990a, 1990b).
In some cases, however, reduced rates of leaf expansion have been
observed in plants growing in dry soil before the xylem sap (or bulk
leaf) ABA concentration was increased (Dodd and Davies, 1996), and it
has been forcibly argued that for many species, xylem sap of droughted
plants may not contain enough ABA to explain the physiological and
developmental responses to soil drying (Munns and King, 1988). The
mechanistic basis of the ABA-induced restriction of leaf growth also
remains to be discovered.
The use of ABA-deficient mutants may further our understanding of the
involvement of ABA in the control of leaf expansion (Mulholland et al.,
1996a, 1996b). Az34 is a molybdenum cofactor mutant of barley that is
isogenic to the Steptoe cultivar (Walker-Simmons et al., 1989).
Mutation-induced deficiencies in the molybdenum cofactor-requiring
enzyme aldehyde oxidase prevent oxidation of an ABA precursor, such
that plants exhibit reduced ABA concentrations under well-watered
conditions and are unable to produce as much extra ABA as the wild type
in response to soil drying.
In this paper we report a role for pH and ABA in the control of leaf
expansion during water deficit in the unrelated barley cvs Hanna and
Steptoe, and in the Az34 mutant of the latter. We have observed a
significant effect of increased xylem sap pH on leaf expansion, and we
demonstrate a fundamental requirement for ABA for this response to
occur. To our knowledge, this is the first demonstration that ABA is
required to mediate pH-regulated cell expansion in droughted plants.
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MATERIALS AND METHODS |
Plant Material
For leaf-elongation bioassays, approximately 100 seeds of barley
(Hordeum vulgare L. cv Hanna, mutant Az34, and the
isogenic wild-type cv Steptoe) were sown in large pots (170 mm
diameter, 3.0 dm3 in capacity) containing John
Innes No. 2 commercial potting compost (Keith Singleton's Seaview
Nurseries, Cumbria, UK). The potting compost provided the nutrient
requirements for all cultivars during the period of experimentation.
Nitrogen was available in the form of both nitrate and ammonium. Seeds
were deep sown 10 cm below the surface of the compost to allow the
development of a subcrown internode. Plants were raised in a
controlled-environment cabinet with a day/night temperature of
24°C/15°C, RH of 30%/55%, under a photoperiod of 12 h and a
light intensity of 400 µmol m2
s1 provided by eight 400-W tungsten halide
lamps (Powerstar HQI-T, Osram, Frankfurt, Germany). Plants were watered
daily to the drip point and were ready for use when the third main leaf
had emerged and was expanding at a constant rate (3 weeks old).
For other measurements (soil moisture, LER, and xylem sap pH), no more
than 15 seeds of cv Hanna were sown near the surface in 140-mm-diameter
plastic pots, 1.0 dm3 in capacity. Plants were
raised as described above. Experimentation was initiated soon after the
emergence of the fifth main leaf (4 weeks old).
Measurement of Soil Moisture, LER, and Xylem Sap pH during Soil
Drying
Water was withheld from half of the pots containing 15 cv Hanna
plants and the rest were watered as normal for the next 6 d. The
low plant-to-soil ratio ensured a slow soil-drying treatment. Although
not measured in this investigation, previous work has estimated that
this soil-drying treatment provides a decline in soil water potential
to circa 
1.0 MPa after 6 d of soil drying (Bacon, 1998). Three determinations of soil moisture content (v/v) within one drying and one well-watered pot were carried out every day
using a Theta soil-moisture probe (Delta-T Devices, Cambridge, UK). The
length of the expanding fifth leaf from 10 different plants in these
pots was measured at the same time every day to determine the LER (in
millimeters per hour). Xylem sap pH of 10 plants from an equivalent pot
was measured halfway through the photoperiod daily for the entire
soil-drying cycle. Measurement of xylem pH was obtained by severing the
plant through the base approximately 1 cm above the surface of the soil
(halfway through the elongation zone of the currently expanding leaf).
The cut surface was immediately wiped with absorbent tissue to remove contaminants from cut cells. Plants were allowed to stand for a short
time (5-30 min) until root pressure resulted in the appearance of
xylem sap as a droplet at the cut surface. During this time pots were
covered with aluminum foil to prevent evaporation from the droplet
forming at the cut surface. The pH was determined by placing an Orion
combination needle pH electrode (Orme Scientific, Manchester, UK)
into the droplet.
Although whole-pot or isolated root-system pressurization is commonly
used to express sap from plants, these techniques are fraught with
potential complexities that may lead to artifactual results. Whole-pot
pressurization may force soil moisture into the roots of the plants
(Salim and Pitman, 1984), which could rehydrate roots growing in drying
soil and reduce any dry-soil-induced pH changes that had developed in
the unpressurized plant. Pressurization of isolated root tissue causes
dehydration and affects xylem sap composition regardless of the initial
water status of the tissue (Hartung and Radin, 1989). For these reasons
we chose to exude sap under root pressure, as described above. Although
this takes a little longer and yields only small amounts of sap at the
cut surface of plants growing in drying soil, any concentration of the
sap constituents that might occur within 30 min is very small and is
more likely to acidify the droplet than to artifactually increase its
pH (Schurr and Schulze, 1995). These authors found that it took 9 h for the pH of the sap exuding under root pressure to be decreased by
0.5. Presumably, any changes within the 5 to 30 min after the pH of the
sap was determined would therefore be very small.
Leaf-Elongation Bioassays
The development of a subcrown internode on the plants as a result
of deep sowing allows the removal of the root system and access to the
transpiration stream while leaving the elongation zones of the leaves
intact and undamaged. The severed internode is a suitable means by
which to introduce solutions directly into the transpiration stream of
the plant (Munns, 1992; Dodd and Davies, 1994, 1996).
Plants at the correct developmental stage (third leaf with a constant
LER) were transferred to the dark for at least 1 h before use.
This reduced the transpiration rate and the chance of embolism on
cutting the xylem tissue. Plants were excavated in darkness and the
internode was cut under distilled water 2 cm below the crown. Each
plant was rapidly transferred to a vial containing 10 cm3 AS: 1.0 mM
KH2PO4, 1.0 mM
K2HPO4, 1.0 mM
CaCl2, 0.1 mM
MgSO4, 3.0 mM
KNO3, and 0.1 mM
MnSO4 (from Wilkinson and Davies, 1997). The AS
was adjusted to the appropriate pH with 1 M HCl or KOH, which resulted in increases in the concentrations of
K+ and Cl 1 order
of magnitude lower than those determined within the xylem sap of
growing plants (e.g. Schurr and Schulze, 1995) and total K+ and Cl concentrations
within the AS that have no effect on leaf expansion (Dodd, 1996).
The
H2PO4/HPO4
buffering system present within the AS is the same system found within
the xylem sap of sunflower seedlings (Gollan et al., 1992). No data on
the buffering system within barley were found in the literature. In
some cases ABA (Lancaster Synthesis, Morecambe, UK) was added to the AS
to give a final concentration of 0.03 µM, the approximate
concentration found in the xylem sap of a well-watered monocot (Zhang
and Davies, 1990b). The vials containing the seedlings were left in
darkness for another hour. They were then randomized and transferred
back to the controlled-environment cabinet in the light at 21°C to 24°C. For experiments with cv Hanna involving a dark period, the plants were placed in the light at a higher temperature of 28°C to
30°C to ensure rapid delivery of AS before the dark period, when sap
flow rates become much slower. Similar experiments with Az34 were
carried out over a longer period and therefore did not require this
initial increase in temperature. In all experiments the length of the
third leaf was measured immediately and thereafter every 2 h for
up to 14 h using graph paper photocopied onto acetate. LER was
calculated in millimeters per hour.
At the end of some experiments the basal 30 mm of the experimental
leaf, which constitutes the elongation zone (Palmer and Davies, 1996),
was dissected and weighed. It was then placed into a vial containing
distilled water, sealed, and kept on ice overnight to hydrate the
tissue. Storage on ice has been determined to inhibit any measurable
increase in length (Milnes et al., 1998). After reweighing, the tissue
section was freeze-dried for 48 h to obtain its dry weight.
Relative water content was calculated at the end of the bioassay as the
water content at that point relative to the fully hydrated water
content.
At the end of other experiments, the bulk ABA concentration of the leaf
bases was determined using a RIA (for method, see Quarrie et al.,
1988). Three bases were required to give enough material for one
replicate in the RIA. These were freeze-dried, ground, and incubated at
5°C overnight in tubes containing distilled water at a
tissue-to-solvent ratio of 1:20 (w/v). The tubes were centrifuged and
the supernatant was removed for RIA analysis.
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RESULTS |
Effects of Soil Water Deficit on LER and pH
As the soil dried, LER of the fifth leaf of the cv Hanna plants
declined with the water content of the soil (Fig.
1). There was a clear correlation
(r2 = 0.96) between the soil water content
(v/v) in which the plants were growing and the LER of those plants
during this time (Fig. 1). There was also a correlation
(r2 = 0.8) between the leaf xylem sap pH of
barley plants and the water content of the soil in which the plants
were growing (Fig. 2). As soil water
content declined, xylem sap pH increased. The pH of the xylem sap
correlated (r2 = 0.8) with the LER of
plants growing in drying soil (Fig. 3). After only 1 d of exposure to drying soil the leaf xylem sap pH increased by about 0.2, and the LER decreased in concert with soil
water content over the next 24 h (Fig.
4). The second series of experiments was
conducted to determine whether pH and LER were causally related.
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| Figure 1.
Correlation between LER of the fifth leaf of
barley cv Hanna and the water content of the soil in which the plants
were growing. Each point is the mean of at least 10 LER determinations
and three determinations of soil moisture content. A first-order
regression line is fitted to the data (r2 = 0.96) together with lines indicating the 95% confidence interval
(dotted lines).
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| Figure 2.
Correlation between the pH of xylem sap expressed
from the leaf bases of cv Hanna and the water content of the soil in
which the plants were growing. Each point is the mean of at least 15 pH
determinations and three determinations of soil water content ± SE. A first-order regression line is fitted to the data
(r2 = 0.80) together with lines indicating
the 95% confidence interval (dotted lines).
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| Figure 3.
Correlation between the pH of xylem sap expressed
from cv Hanna leaves and the LER of the fifth leaf. Each point is the
mean of at least 15 pH determinations and 10 determinations of LER ± SE. A first-order regression line is fitted to the data
(r2 = 0.90) together with lines indicating
the 95% confidence interval (dotted lines).
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| Figure 4.
Time course of mean LER (A), pH of expressed xylem
sap (B), and soil water content (C) in cv Hanna growing in either
well-watered ( ) or drying soil ( ) ± SE.
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Effects of Varying the pH of Fed AS on Leaf Growth, Relative Water
Content, and Bulk [ABA] in cv Hanna Plants
Figure 5A shows that varying the pH
of AS fed to derooted seedlings of cv Hanna plants via the subcrown
internode induced differential rates of leaf expansion. LER declined
with increasing pH. Leaves fed with sap buffered to a well-watered pH
of 6.0 (see Fig. 2) expanded the most rapidly (at circa 1.1 mm
h1), whereas those fed sap buffered to a
stressed pH of 7.0 or above expanded much more slowly, at a rate 50%
lower than those fed at pH 6.0. This trend appeared within 2 to 4 h of feeding and became increasingly pronounced over the experimental
growth period. Feeding in the dark resulted in similar pH-dependent
reductions in growth, ruling out any stomatal contribution to the
observed pH dependence of leaf expansion of cv Hanna (Fig. 5B). Varying the pH of the AS fed to the leaves had no effect on the water content
or the bulk [ABA] of the leaf-elongation zone (Fig.
6, A and B).
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| Figure 5.
The effect of feeding AS buffered to different pH
values to derooted cv Hanna seedlings via the subcrown internode on the
elongation rate of the third leaf. Each point is the mean of 10 determinations of LER ± SE. A, In the light for
6 h at 21°C to 24°C. B, In the light for 4 h at 28°C to
30°C, then in the dark for another 4 h at 20°C.
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| Figure 6.
Effect of feeding AS buffered to pH values of 6.0, 6.5, 7.0, and 7.5 on the relative water content (A) and bulk ABA
concentration (nmol g1 dry weight [DW]) (B) in the
elongation zone of the third leaf of cv Hanna monitored in a
leaf-elongation bioassay.
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Effects of Varying the pH of AS on the LER of Az34, an
ABA-Deficient Mutant, and Its Wild Type (cv Steptoe)
LER declined as described above (Fig. 5) when the pH of the AS fed
to cv Steptoe was increased from a well-watered pH of 6.0 to a stressed
pH of 7.0 (Fig. 7A). However, changes in
the pH of the fed AS had no effect on the growth of Az34: leaves
continued to grow at the faster rate observed at pH 6.0 in cv Steptoe
and cv Hanna, even when xylem sap buffered to a pH of 7.0 was fed via
the subcrown internode.
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| Figure 7.
A, The effect of feeding AS buffered to pH 6.0 or
7.0 at 21°C to 24°C via the subcrown internode of barley on the
elongation rate of the third leaf of Az34 and its isogenic wild-type cv
Steptoe over 4 h. Each point is mean of 10 determinations of
LER ± SE. B, The effect of feeding AS buffered to pH
6.0 or 7.0 with (+) or without () 3 × 108
M ABA on the elongation rate of the third leaf of Az34 over
14 h in periods of both light and dark. Each point is the mean of
10 determinations of LER ± SE.
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When a low well-watered concentration of ABA (0.03 µM),
which is characteristic of the concentration found in well-watered monocot species (Zhang and Davies, 1990b), was supplied in the AS, the
ability of Az34 to respond to the more alkaline stressed pH was
restored over 14 h of feeding (Fig. 7B): pH 7.0 only reduced the
growth rate of the third leaf of Az34 seedlings when ABA was present.
This concentration of ABA was itself too low to cause a reduction in
growth when fed via the subcrown internode at a well-watered pH of 6.0 (Fig. 7B). This effect persisted in the dark.
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DISCUSSION |
It has long been known that LER decreases as soil dries and it is
now established that the pH of xylem sap expressed from plants growing
in dry soil can be more alkaline than that from plants growing in wet
soil (Hartung and Radin, 1989; Gollan et al., 1992; Wilkinson and
Davies, 1997). Conditions other than drought can also increase xylem
sap pH (flooding, Jackson et al., 1996; nitrate availability,
Dannel et al., 1995; and time of day/year, Ferguson et al., 1983;
Fromard et al., 1995; Schurr and Schulze, 1995).
The mechanism by which sap pH is increased by stresses such as drought
is still unclear (see Wilkinson et al., 1998, and refs. therein). There
is some evidence that a reduction in ATPase activity in the cells
surrounding the xylem vessels of droughted plants could influence xylem
sap pH (Hartung and Radin, 1989; Fromard et al., 1995). Other
possibilities involve changes in nitrate reductase activity in roots
and/or stems of stressed plants (Raven and Smith, 1976). Alternatively,
stress-induced changes in xylem sap ionic composition (e.g. Schurr et
al., 1992) could change the pattern of ionic exchange with walls of
cells adjacent to the xylem vessels, and hence change sap pH (Ryan et
al., 1992). Whether the mechanism proposed to account for increases in
xylem sap pH seen during drought is the same as the mechanism that
induces increased xylem sap pH in response to flooding or changes in
nitrate availability remains to be discovered (see Wilkinson, 1998).
In several experiments using the root pressure vessel, often seen as
the more desirable technique for collection of xylem sap (but see
``Materials and Methods''), substantial increases in sap pH were
reported when the soil surrounding the roots was allowed to dry (e.g.
Gollan et al., 1992). Schurr and Schulze (1995) have shown that the
method used in the present investigation to express sap will result in a reduction in the sap flow rate and the potential concentration of
substances within the forming droplet. However, such concentration of
sap constituents results in acidification of the droplet (Schurr and
Schulze, 1995). In this study, therefore, we speculate that the
difference in pH that we detected between well-watered plants and those
growing in drying soil is, if anything, smaller than that occurring in
planta.
Reductions in LER correlate with increases in xylem sap pH in plants
growing in dry soil (Fig. 3) in a manner similar to that reported by
Van Volkenburgh and Boyer (1985), who found that the reduced ability of
the apoplast to acidify a weakly buffered droplet of solution placed on
the surface of the leaf-elongation zone correlated with reductions in
LER in maize plants growing in drying soil. In subsequent experiments
(Fig. 5) we have been able to demonstrate that the relationship between
xylem sap pH and LER (Fig. 3) is indeed causal and not just
correlative.
Several possibilities exist for the mechanism by which high pH might
reduce leaf growth. We know that increased xylem sap pH is a signal
that closes stomata in the leaves of plants in drying soil (Wilkinson
and Davies, 1997; Wilkinson et al., 1998). To determine if such an
effect on stomatal aperture had any effect on growth (i.e. via changes
in the flux of water and solutes into the growing cells), it was
demonstrated that leaf growth limitation by more alkaline pH continued
in the dark when stomata were closed (Fig. 5B). Alternatively,
increased pH itself could change the water status of the
leaf-elongation zone. However, Figure 6A shows that pH had no effect on
the relative water content of the leaf bases. Because it has been
demonstrated that ABA can reduce growth, it was also necessary to rule
out the possibility that the introduction of AS buffered to a high pH
somehow increased the ABA content of the base of the third leaf of the
barley seedlings. This might have occurred if, for example, high pH
inhibited ABA metabolism or prevented its transport out of the
elongation zone. Figure 6B shows that the pH of the AS had no effect on
the ABA concentration of fed leaves.
The reduction in leaf expansion by high pH observed in this
investigation may have been caused by a shift in the pH of the solution
around the walls of growing leaf cells out of the range suggested for
auxin-stimulated growth (e.g. Cleland, 1991). Auxin is believed to
cause acidification of the wall and activation of so-called "cell
wall-loosening factors," which mediate expansion of the cell wall.
Expansins, a recently discovered set of cell wall proteins with acidic
pH optima (circa 4.5-5.5; see McQueen-Mason, 1995), may be mediators
of auxin-induced elongation because they exhibit reduced activity at
the more alkaline pH values administered in this investigation
(McQueen-Mason, 1995). However, the fact that high pH did not reduce
growth in Az34 unless ABA was provided (Fig. 7) suggests that a direct
effect of pH on cell expansion cannot account for the observed growth
reductions.
Recently, Wilkinson and Davies (1997) demonstrated that high pH reduces
stomatal aperture in leaves of plants containing only low well-watered
concentrations of ABA, via an accumulation of this ABA in the apoplast
adjacent to the stomatal guard cells. Experiments reported here would
suggest that such a mechanism might also account for the influence of
increased xylem sap pH on expanding cells within the elongation zone.
We are already well aware of the ability of ABA to reduce the rate of
leaf expansion (Zhang and Davies, 1990b; Munns and Sharp, 1993; Dodd
and Davies, 1994, 1996); now, as a result of the present investigation,
we suggest that high apoplastic pH may cause an accumulation of ABA in
this compartment to a high-enough concentration to inhibit growth. In
Commelina communis L. leaves ABA accumulated in the apoplast
as a result of the reduced ability of both mesophyll and epidermal
cells to remove the ABA from the passing transpiration stream
(Wilkinson and Davies, 1997). This was a consequence of the imposed
reduction in the pH gradient across the plasma membrane of these cells.
We were able to demonstrate that ABA is required for high pH buffers to
reduce LER (Fig. 7). There is a direct parallel here with the
requirement for ABA for high pH to close the stomata of tomato leaves
(Wilkinson et al., 1998). Whereas pH 7.0 reduced the LER of the barley
cv Steptoe in a manner similar to its effects in cv Hanna, LERs of the
Az34 mutant of cv Steptoe were equally high at both pH 6.0 and pH 7.0 (Fig. 7). One difference between cv Steptoe and Az34 is that the latter
contains a much lower endogenous concentration of ABA (Walker-Simmons
et al., 1989). When levels of ABA in Az34 were artificially increased
by supplying a concentration of ABA in the transpiration stream
equivalent to that presumably found in the xylem sap of the
well-watered wild-type cultivar (3 × 108
M), pH 7.0 was able to reduce the rate of growth (Fig. 7B).
In the mechanism that we propose to be operating, as the sap pH
increases, symplastic uptake into the cells within the growing zone is
reduced and ABA accumulates around the actively expanding cells. The
putative increase in apoplastic ABA concentration is not detectable as an increase in bulk leaf base ABA concentration (Fig. 6B), because the
ABA that would have been taken up by the leaf cells is simply left in
the apoplast such that the reduction in the symplastic ABA
concentration compensates for the apoplastic increase. The experiments with Az34 determined that a high apoplastic wall pH alone
cannot reduce leaf growth and confirmed that we are not dealing with a
direct effect of pH on the wall or its enzymatic complement.
We are assuming that the buffered solution (or the xylem sap moving
from roots of plants in dry soil; Figs. 2 and 3) is carried acropetally
with the transpiration stream so that it reaches the leaf-elongation
zone to impose a new wall pH around the expanding cells. In
broad-leaved species this concept is easier to accept because root and
shoot have a continuous xylem connection. Sap travels directly from the
root to the shoot and eventually to the apoplast (Canny, 1990).
However, understanding the precise nature of xylem transport through
grass leaf-elongation zones is a long-standing problem (Esau, 1943)
that continues to be addressed (e.g. Paolillo, 1995). No permanent
xylem vessel can supply an actively expanding elongation zone. Living
protoxylem with very different properties than mature vessels allow
transport to and through the elongation zone of an actively expanding
grass leaf (Evert et al., 1996). As the leaf nears the end of its
expansion period, true metaxylem vessels mature basipetally. Only when
leaf expansion is complete does a continuous xylem connection between root and shoot exist.
The precise physical nature of the apoplast/xylem connection in the
elongation zone remains unknown. However, this investigation demonstrates that both the pH signal and the ABA required for any pH
response to operate must in some way reach those cells that are
actively expanding. We may therefore predict with some confidence that,
in general, the xylem vessel supply and the apoplastic connection to
such vessels do not differ functionally from those present in the fully
expanded leaf. If a symplastic pathway were operating, the implication
is that applied buffers would arrive at the site of action with a
completely different composition. Because it is obvious that applied
buffers do affect growing cells at a site distant from their
application (Figs. 5 and 7), we must assume that they travel with the
transpiration stream to the walls of actively expanding cells in the
leaf-elongation zone via an apoplastic pathway.
It is interesting that the most alkaline pH measured in the sap of
plants growing in drying soil (pH 6.6-6.8) did not have as significant
an effect on LER when applied as AS to freshly detached leaves. It is
possible that an effect of drought on leaf water potential may have
increased the sensitivity of the growth process to either ABA or pH.
Clearly, several factors may contribute to a restriction in leaf
expansion during drought. The drought treatment may be expected to
increase the amount of ABA within the leaf-elongation zone. Such
relatively higher apoplastic concentrations of ABA in droughted plants,
together with an increase in xylem pH, may explain the magnitude of the
LER response seen in plants growing in drying soil relative to that
observed in the bioassay system.
Although we are aware of a reduced level of nitrate reductase activity
in the Az34 mutant (Walker-Simmons et al., 1989), nitrogen was supplied
to seedlings in the form of both nitrate and ammonium. Although nitrate
reductase may also have a role in controlling the pH of the xylem under
stress conditions (Wilkinson, 1998), the observation that added ABA
restores the ability of high pH to reduce leaf expansion suggests that
the nitrate reductase deficiency does not contribute to the lack of
pH-regulated cell expansion normally exhibited by Az34.
Although we propose that the pH-induced reduction in leaf expansion is
the result of increased apoplastic accumulation of ABA in the
elongation zone, we must address the question of how the local wall ABA
concentration is detected and consequently results in the restriction
of cell expansion. We do not yet know the position of any specific
ABA-binding sites in the leaf other than in stomatal guard cells
(Hartung, 1983). Binding sites of growing cells could exist in the
wall, in the plasma membrane oriented externally or internally, or in
an inner membrane. In stomatal guard cells, functional receptors may
reside externally in the outer plasma membrane and/or inside the cell
(Hartung, 1983; Hetherington and Quatrano, 1991; Allan and Trewavas,
1994). In light of recent work on the stomatal response to increased xylem sap pH (Wilkinson and Davies, 1997; Wilkinson et al., 1998), which demonstrated that apoplastic accumulation of ABA was responsible for the observed responses, we would question the relevance of internal
receptors for responses to signals from the transpiration stream.
| |
CONCLUSIONS |
We have shown that drying soil increases the pH of barley xylem
sap from about 6.0 to 7.0. We suggest that this pH increase persists as
the transpiration stream carries the sap acropetally to the apoplast
surrounding the growing cells of the barley leaf-elongation zone. This
pH increase may cause an accumulation of ABA present in the
transpiration stream within the apoplast surrounding the cells of the
elongation zone. We speculate that in well-watered plants ABA arriving
in this vicinity is taken up by the leaf cells of the growing zone when
the pH gradient between the symplast and the apoplast is high, at a
well-watered sap pH of 6.0. The increased ABA concentration in the
apoplast that results from the increased pH of this compartment in the
droughted plant reduces the rate of cell expansion by reducing cell
wall extensibility and/or the turgor of these cells.
We propose that increased xylem sap pH is a measure of soil water
status developed in the grass roots in contact with drying soil. This
pH signal mediates an ABA-dependent restriction in leaf cell expansion,
which together with pH- and/or ABA-induced stomatal closure limits the
plant's evaporative water loss during drought. It is important to note
that although the pH-induced reduction in stomatal aperture and leaf
expansion are ABA dependent, no extra ABA (only that concentration
present in the well-watered plant) is required for this mechanism to
operate. This suggests that the plant always has enough ABA to explain
the ABA-induced restriction in stomatal opening and leaf expansion,
although synthesis in response to drought will strengthen the drought
signal. In some species, xylem sap pH may not be sensitive to soil
drying (e.g. Ricinus communis; Schurr and Shulze, 1995). We
would predict that in these circumstances, even when endogenous ABA
concentrations also increase in response to drought, stomata and leaf
expansion may be relatively insensitive to this change. The observation that leaves of the ABA-deficient mutant Az34 elongate rapidly at
alkaline pH levels shows that, in itself, pH may not be a primary factor in regulating cell expansion.
| |
FOOTNOTES |
1
This work was supported by the Biotechnology and
Biological Sciences Research Council.
*
Corresponding author; e-mail baconm{at}msmail.lancs.ac.uk; fax
44-1524-843854.
Received May 11, 1998;
accepted September 22, 1998.
| |
ABBREVIATIONS |
Abbreviations:
AS, artificial xylem sap.
LER, leaf-elongation
rate.
RIA, radioimmunoassay.
| |
ACKNOWLEDGMENTS |
We thank Professor R.L. Warner (Washington State University) and
Dr J. Roberts (Nottingham University, UK) for supplying barley seed,
and we are also grateful to Dr. S.A. Quarrie (John Innes Institute,
Norwich, UK) for the MAC252 ABA antibody used in the RIA.
| |
LITERATURE CITED |
Allan AC,
Trewavas AJ
(1994)
Abscisic acid and gibberellin perception: inside or out?
Plant Physiol
104:
1107-1108
[Medline]
Bacon MA (1998) Control of leaf expansion in Lolium
temulentum L. and Hordeum vulgare L. growing in drying
soil. PhD thesis. University of Lancaster, UK
Baker NR, Davies WJ, Ong CK, eds (1985) Control of Leaf Growth.
Society for Experimental Biology Seminar Series 27. Cambridge
University Press, Cambridge, UK
Begg JE,
Wright MJ
(1962)
Growth and development of leaves from intercalary meristems in Phalaris arunidaceae L.
Nature
194:
1097-1098
Boyer JS
(1982)
Plant productivity and the environment.
Science
218:
443-448
[Abstract/Free Full Text]
Canny MJ
(1990)
What becomes of the transpiration stream?
New Phytol
114:
341-368
Cleland RE
(1991)
Auxin-induced growth of Avena coleoptiles involves two mechanisms with different pH optima.
Plant Physiol
99:
1556-1561
Dale JE
(1988)
The control of leaf expansion.
Annu Rev Plant Physiol Plant Mol Biol
39:
267-295
[CrossRef][ISI]
Dannel F,
Pfeffer H,
Marscher H
(1995)
Isolation of apoplasmic fluid from sunflower leaves and its use for studies on influence of nitrogen supply on apoplasmic pH.
J Plant Physiol
146:
273-278
Dodd I,
Davies WJ
(1994)
Leaf growth responses to ABA are temperature dependent.
J Exp Bot
45:
903-907
[Abstract/Free Full Text]
Dodd IC (1996) Sensitivity of gramineous leaf growth to abscisic
acid. PhD thesis. University of Lancaster, UK
Dodd IC,
Davies WJ
(1996)
The relationship between leaf growth and ABA accumulation in the grass leaf elongation zone.
Plant Cell Environ
19:
1047-1056
[CrossRef]
Esau K
(1943)
Ontogeny of the vascular bundle in Zea mays.
Hilgardia
15:
327-368
Evert RF,
Russin WA,
Bosabalidid AM
(1996)
Anatomical and ultrastructural changes associated with sink-to-source transition in developing maize leaves.
Int J Plant Sci
157:
247-261
[CrossRef]
Ferguson AR,
Eiseman JA,
Leonard JA
(1983)
Ann Bot
51:
823-833
[Abstract/Free Full Text]
Fromard L,
Babin V,
Fleurat-Lessard P,
Fromont J-C,
Serrano R,
Bonnemain J-L
(1995)
Control of vascular sap pH by the vessel-associated cells in woody species.
Plant Physiol
108:
913-918
[Abstract]
Gollan T,
Schurr U,
Shulze E-D
(1992)
Stomatal response to drying soil in relation to changes in the xylem sap concentration of Helianthus annuus 1. The concentration of cations, anions, amino acids in, and pH of, the xylem sap.
Plant Cell Environ
15:
551-559
[CrossRef]
Gowing DJG,
Davies WJ,
Jones HG
(1990)
A positive root-sourced signal as an indicator of soil drying in apple, Malus × domestica Borkh.
J Exp Bot
41:
1535-1540
[Abstract/Free Full Text]
Hales S (1727) Vegetable Staticks. W and J Inneys, London.
Reprint, 1961
Hartung W
(1983)
The site of action of abscisic acid at the guard cell plasmalemma of Valerianella locusta.
Plant Cell Environ
6:
427-428
[CrossRef]
Hartung W,
Radin JW
(1989)
Abscisic acid in the mesophyll apoplast and in the root xylem sap of water-stressed plants: the significance of pH gradients.
Curr Top Plant Biochem Physiol
8:
110-124
Hartung W,
Wilkinson S,
Davies WJ
(1998)
Factors that regulate abscisic acid concentrations at the primary site of action at the guard cell.
J Exp Bot
51:
361-367
Hetherington AM,
Quatrano RS
(1991)
Mechanisms of action of abscisic acid at the cellular level.
New Phytol
119:
9-32
[CrossRef]
Hoffmann B,
Kosergarten H
(1995)
FITC-dextran for measuring apoplastic pH and apoplastic pH gradients between various cell types in sunflower leaves.
Physiol Plant
95:
327-335
[CrossRef]
Hsiao TC
(1973)
Plant responses to water stress.
Annu Rev Plant Physiol
24:
519-570
[ISI]
Jackson MB,
Davies WJ,
Else MA
(1996)
Pressure-flow relationships, xylem solutes and root hydraulic conductance in flooded tomato plants.
Ann Bot
77:
17-24
[Abstract/Free Full Text]
Kramer PJ
(1974)
Fifty years of progress in water relations research.
Plant Physiol
54:
463-471
[Abstract/Free Full Text]
MacRobbie EAC (1991) Effect of ABA on ion transport and stomatal
regulation. In WJ Davies, HG Jones, eds, Abscisic Acid:
Physiology and Biochemistry. Environmental Plant Biology Series. BIOS
Scientific Publishers, Oxford, UK, pp 153-167
McQueen-Mason SJ
(1995)
Expansins and cell wall expansion.
J Exp Bot
46:
1639-1650
[Abstract/Free Full Text]
Michelena VA,
Boyer JS
(1982)
Complete turgor maintenance at low water potentials in the elongating region of maize leaves.
Plant Physiol
69:
1145-1149
[Abstract/Free Full Text]
Milnes K, Davies WJ, Rodwell JS, Francis B (1998) The responses of
Briza media and Koleria macrantha to drought and
re-watering. Funct Ecol (in press)
Monteith JL
(1977)
Climate and the efficiency of crop production on Britain.
Philos Trans R Soc B
54:
1069-1081
Mulholland BJ,
Black CR,
Taylor IB,
Lenton JR
(1996a)
Effects of soil compaction on barley (Hordeum vulgare L.) growth. I. Possible role for ABA as a root-sourced chemical signal.
J Exp Bot
47:
539-549
Mulholland BJ,
Taylor IB,
Black CR,
Roberts JA
(1996b)
Effects of soil compaction on barley (Hordeum vulgare L.) growth. II. Are increased xylem sap ABA concentrations involved in maintaining leaf expansion in compacted soils?
J Exp Bot
47:
551-556
Munns R
(1992)
A leaf elongation bioassay detects an unknown growth inhibitor in xylem sap from wheat and barley.
Aust J Plant Physiol
19:
127-135
Munns R,
King RW
(1988)
Abscisic acid is not the only stomatal inhibitor in the transpiration stream of wheat plants.
Plant Physiol
88:
703-708
[Abstract/Free Full Text]
Munns R,
Sharp RE
(1993)
Involvement of abscisic acid in controlling plant growth in soils of low water potential.
Aust J Plant Physiol
20:
425-437
Palmer S,
Davies WJ
(1996)
An analysis of relative elemental growth rate, epidermal cell size and xyloglucan endotransglycosylase activity through the growing zone of aging maize leaves.
J Exp Bot
47:
339-347
Paolillo DJ
(1995)
Protoxylem maturation in the seedling wheat leaf.
Am J Bot
82:
337-345
[CrossRef]
Passioura JB
(1988)
Root signals control leaf expansion in wheat seedlings growing in drying soil.
Aust J Plant Physiol
15:
687-693
Puliga S,
Vassana C,
Davies WJ
(1995)
Control of leaf growth of Mediterranean forages by chemical and hydraulic influences.
J Exp Bot
47:
529-537
Quarrie S,
Whitford PN,
Appleford NEJ,
Wang TL,
Cook SK,
Henson IE,
Loveys BR
(1988)
A monoclonal antibody to (S)-abscisic acid: its characterisation and use in a radioimmunoassay for measuring abscisic acid in crude extracts of cereal and lupin leaves.
Planta
173:
330-339
[CrossRef]
Raven JA,
Smith FA
(1976)
Nitrogen assimilation and transport in vascular land plants in relation to intracellular pH regulation.
New Phytol
76:
415-431
Ryan PR,
Newman IA,
Arif I
(1992)
Rapid calcium exchange for protons and potassium in cell walls of Chara.
Plant Cell Environ
15:
675-683
[CrossRef]
Sachs J
(1887)
Lectures on the Physiology of Plants. Translated by M Ward.
Clarendon, Oxford, UK
Salim M,
Pitman MG
(1984)
Pressure-induced water and solute flow through plant roots.
J Exp Bot
35:
869-881
[Abstract/Free Full Text]
Schurr U,
Gollan T,
Schulze E-D
(1992)
Stomatal response to soil drying in relation to changes in the xylem sap composition of Helianthus annuus. 2. Stomatal sensitivity to abscisic acid imported from the xylem sap.
Plant Cell Environ
15:
561-567
[CrossRef]
Schurr U,
Schulze E-D
(1995)
The concentration of xylem sap constituents in root exudate, and in sap from intact, transpiring castor bean plants (Ricinus communis L.).
Plant Cell Environ
18:
409-420
Van Volkenburgh E,
Boyer JS
(1985)
Inhibitory effects of water deficit on maize leaf elongation.
Plant Physiol
77:
190-194
[Abstract/Free Full Text]
Walker-Simmons M,
Kudrna DA,
Warner RL
(1989)
Reduced accumulation of ABA during water stress in a molybdenum cofactor mutant of barley.
Plant Physiol
90:
728-733
[Abstract/Free Full Text]
Wilkinson S (1999) pH as a stress signal. Plant Growth Regul (in
press)
Wilkinson S,
Corlett JE,
Oger L,
Davies WJ
(1998)
Effects of xylem sap pH on transpiration from wild-type and flacca mutant tomato leaves: a vital role for abscisic acid in preventing excessive water loss from well-watered plants.
Plant Physiol
117:
703-709
[Abstract/Free Full Text]
Wilkinson S,
Davies WJ
(1997)
Xylem sap pH increase: a drought signal received at the apoplastic face of the guard cell that involves the suppression of saturable abscisic acid uptake by the epidermal symplast.
Plant Physiol
113:
559-573
[Abstract]
Zhang J,
Davies WJ
(1990a)
Changes in the concentration of ABA in the xylem sap as a function of changing soil water status can account for changes in leaf conductance and growth.
Plant Cell Environ
13:
277-285
Zhang J,
Davies WJ
(1990b)
Does ABA in the xylem control the rate of leaf growth in soil-dried maize and sunflower plants?
J Exp Bot
41:
765-772
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Abstract
Introduction