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Plant Physiol. (1998) 118: 651-659
Rapid Up-Regulation of HKT1, a High-Affinity
Potassium Transporter Gene, in Roots of Barley and Wheat
following
Withdrawal of Potassium1
Tie-Bang Wang2,
Walter Gassmann3,
Francisco Rubio4,
Julian I. Schroeder, and
Anthony D.M. Glass*
Department of Botany, University of British Columbia, Vancouver,
Canada V6T 1Z4 (T.-B.W., A.D.M.G.); and Department of Biology and
Center for Molecular Genetics, University of California-San Diego,
La Jolla, California 92093-0116 (W.G., F.R., J.I.S.)
 |
ABSTRACT |
High-affinity
K+ uptake in plant roots is rapidly up-regulated when
K+ is withheld and down-regulated when K+ is
resupplied. These processes make important contributions to plant
K+ homeostasis. A cDNA coding for a high-affinity
K+ transporter, HKT1, was earlier cloned
from wheat (Triticum aestivum L.) roots and functionally
characterized. We demonstrate here that in both barley (Hordeum
vulgare L.) and wheat roots, a rapid and large up-regulation of
HKT1 mRNA levels resulted when K+ was
withdrawn from growth media. This effect was specific for K+; withholding N caused a modest reduction of
HKT1 mRNA levels. Up-regulation of HKT1
transcript levels in barley roots occurred within 4 h of removing
K+, which corresponds to the documented increase of
high-affinity K+ uptake in roots following removal of
K+. Increased expression of HKT1 mRNA was
evident before a decline in total root K+ concentration
could be detected. Resupply of 1 mM K+ was
sufficient to strongly reduce HKT1 transcript levels. In wheat root cortical cells, both membrane depolarizations in response to
100 µM K+, Cs+, and
Rb+, and high-affinity K+ uptake were enhanced
by K+ deprivation. Thus, in both plant systems the observed
physiological changes associated with manipulating external
K+ supply were correlated with levels of
HKT1 mRNA expression. Implications of these findings for
K+ sensing and regulation of the HKT1 mRNA
levels in plant roots are discussed.
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INTRODUCTION |
The absorption of K+ by plant roots is
mediated by at least two general transport systems. At low external
[K+], high-affinity transport systems, referred
to as mechanism I by Epstein et al. (1963) or HATS by Guy et al.
(1988), are saturable and have apparent Km
values for K+ uptake in the micromolar range
(Epstein et al., 1963; Glass, 1976; Kochian and Lucas, 1982). Rates of
high-affinity K+ uptake are extremely sensitive
to plant K+ status;
Vmax values for K+
(86Rb+) influx decline and
Km values increase as the
K+ content of roots increases (Glass, 1976). By
contrast, there is a rapid up-regulation of high-affinity
K+ uptake when the exogenous
K+ supply is interrupted (Glass, 1975; Kochian
and Lucas, 1982; Drew et al., 1984; Fernando et al., 1990). Under these
conditions, root K+ concentrations are rapidly
depleted by K+ translocation to the shoot and by
root growth (Hooymans, 1974; Glass, 1978; Drew and Saker, 1984; Walker
et al., 1996a). Likewise, when K+ uptake is
limited by pruning the root system (Claassen and Barber, 1977) or by
restricting the K+ supply to certain regions of
the root (Drew et al., 1984), high-affinity K+
uptake increases to compensate for the reduced absorptive surface.
The elevated rates of high-affinity K+ influx
observed in K+-deprived plants are rapidly
down-regulated when K+ is resupplied (Glass,
1976, 1978; Fernando et al., 1990). Recently, it was shown that in
addition to these changes of K+ fluxes across the
plasma membrane, adjustments in K+ fluxes across
the tonoplast and K+ transport to the xylem
contribute to K+ homeostasis (Fernando et al.,
1992; Walker et al., 1996a).
At higher external [K+] a second class of
K+ transport systems that is responsible for
low-affinity K+ transport becomes evident
(Epstein et al., 1963; Epstein and Rains, 1965; Glass and Dunlop, 1978;
Kochian and Lucas, 1982). Unlike the high-affinity transporters,
low-affinity transport systems appear to be insensitive to plant
K+ status in barley (Hordeum vulgare
L.) and ryegrass (Glass and Dunlop, 1978) and in corn (Kochian and
Lucas, 1982), whereas in sunflower (Benlloch et al., 1989) and
Arabidopsis (Maathuis and Sanders, 1995) low-affinity
K+ uptake and K+
channel activity were slightly increased by K+
starvation.
Genes that encode K+-uptake function
(AKT1 and KAT1) were identified from a higher
plant by complementing a yeast strain defective in
K+ uptake with a cDNA from Arabidopsis (Anderson
et al., 1992; Sentenac et al., 1992). Translation of the
KAT1 cRNA in Xenopus laevis oocytes conferred
functional expression of the classical properties of plant
inward-rectifying K+ channels, including the lack
of inactivation, time and voltage dependences, external
K+ dependence, K+
selectivity, and pharmacological block (Schachtman et al., 1992). In
Brassica napus high levels of the AKT1 gene
expression were evident in plants supplied with 5 mM, 0.25 mM, and <5 µM K+
(Lagarde et al., 1996), and it was concluded that withholding K+ from B. napus plants did not alter the
expression levels of AKT1. This observation indicates that
AKT1 may thus be expressed constitutively, in agreement with
the proposed constitutive expression of low-affinity K+ uptake activity in barley, ryegrass, and maize
(Glass and Dunlop, 1978; Kochian and Lucas, 1982).
By complementation of yeast mutants with cDNAs from
K+-starved roots, a cDNA encoding a high-affinity
transporter for K+ (HKT1) was
identified in wheat (Triticum aestivum L.; Schachtman and
Schroeder, 1994). HKT1 shows homology to the high-affinity K+ transporters (encoded by TRK1 and
TRK2 genes) of the yeast plasma membrane (Ko and Gaber,
1991). HKT1 expression in yeast yields saturable kinetics
with apparent Km values in the range of 3 µM for K+ uptake and 30 µM for Rb+ uptake. Patterns of in
situ RNA hybridization of wheat seedlings showed that HKT1
is expressed in root cortical cells and in cells adjacent to the
vascular tissue in leaves, indicative of a role in
K+ transport (Schachtman and Schroeder, 1994).
Further studies of HKT1 expression in Saccharomyces
cerevisiae and X. laevis oocytes showed that this
transporter behaves as a
Na+-K+ symporter that is
strongly selective for the uptake of K+ and
Na+ relative to the other alkali cations,
Rb+, Li+, and
Cs+ (Rubio et al., 1995; Gassmann et al., 1996).
The finding that HKT1 functions as a
Na+-K+ symporter has led to
the suggestion that HKT1 may represent one of the multiple
molecular pathways contributing to high-affinity K+ uptake in vivo (Rubio et al., 1996). Recent
research supports this hypothesis, showing that in Arabidopsis members
of a large new gene family may contribute to high- and/or low-affinity
K+ uptake (Quintero and Blatt, 1997; Santa-Maria
et al., 1997; Fu and Luan, 1998; Kim et al., 1998).
High-affinity 86Rb+
(K+) uptake in barley and wheat has been
demonstrated to be active in the absence of Na+
(Epstein and Hagen, 1952; Maathuis et al., 1996; Walker et al., 1996b).
As a consequence, a role for HKT1 in mediating high-affinity K+ transport in higher plant roots has been
questioned (Maathuis et al., 1996; Walker et al., 1996b) and remains an
open question. In the present study we investigated the effects of
manipulating external K+ supply to roots of
barley and wheat on HKT1 mRNA transcript levels. We observed
a rapid up-regulation of HKT1 expression during the first
4 h following withdrawal of K+ from external
media, which corresponds with the documented increases of high-affinity
K+ uptake systems in barley and maize roots under
identical conditions (Glass, 1975, 1976; Kochian and Lucas, 1982;
Fernando et al., 1990). The increased expression of HKT1 in
roots preceded any detectable changes of root or shoot
[K+], providing novel insights concerning the
sensing of root or plant K+ status.
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MATERIALS AND METHODS |
Growth of Plants
Seeds of barley (Hordeum vulgare L. cvs Jackson and
Klondike) and wheat (Triticum aestivum L. cv Atlas 66) were
germinated for 4 d in a growth room maintained at 20°C on a
day/night cycle of 16-h light/8-h dark. Light was provided by
fluorescent lamps (Vita-Lite, Durotest, Fairfield, NJ), which produced
approximately 300 µmol m 2 s1 at
plant level. Seeds were surface sterilized for 15 min using a 1%
solution of commercial bleach and then subjected to at least six washes
with distilled water to remove all traces. Barley seeds were then
aerated for 24 h in distilled water before planting on plastic
mesh on Plexiglas discs in sterilized, washed sand. By d 4 seedling
roots had grown through the mesh to a length of approximately 50 mm.
Seedlings were then treated according to the described experimental
conditions. This typically involved transfer to hydroponic growth tanks
in the same growth room. The solutions used for culture were based on
Johnson's modified inorganic nutrient recipe (Epstein, 1972), diluted
to one-fifth strength. The [K+] in this
solution was 1.2 mM. At the times indicated, plants were transferred to otherwise identical solutions lacking
K+. Wheat seedlings were germinated on filter
paper wetted with distilled water for 4 d, and then transferred to
hydroponic solutions containing 1 mM
CaCl2 (K+ free) or 1 mM KCl and 1 mM NaCl for another 2 d. When
plants were 6 d old, they were used for physiological and
molecular investigations, as described below.
Isolation of RNA and Expression Analysis
All root samples for northern hybridization were cut from shoots
and immediately frozen in liquid N2. Total barley
root RNA was isolated using guanidium hydrochloride (Logemann et al.,
1987). To isolate mRNA from wheat roots, 4-d-old wheat seedlings were transferred to hydroponic solutions containing 1 mM
CaCl2 or 1 mM KCl. After 2 d,
approximately 100 mg of root tissue per sample was homogenized in
liquid N2, and total mRNA was isolated using the
QuickPrep Micro mRNA purification kit (Pharmacia). The total amount of
mRNA isolated was quantified spectroscopically.
Electrophoresis of the RNA was carried out in 1.2% agarose containing
17% formaldehyde, and RNA was blotted onto nylon membranes (Hybond
N+, Amersham). Blots were probed by a
32P-labeled HindIII-XbaI
fragment of the HKT1 clone (Schachtman and Schroeder, 1994)
at 40°C for at least 16 h in 50% formamide, 5× SSPE (0.75 M NaCl, 50 mM
NaH2PO4, and 5 mM EDTA, pH 7.4), 1% SDS, 5× Denhardt's solution (0.1%
PVP and 0.1% BSA), and 125 mg mL1
herring-sperm DNA. Membranes were washed twice at 40°C in 2× SSC
(0.3 M NaCl and 0.03 M sodium citrate, pH 7),
0.1% SDS for 10 min, twice in 0.5× SCC, 0.1 SDS for 15 min, and twice
in 0.25× SCC, 0.1 SDS for 20 min. Autoradiographs were exposed for
10 d. To generate an internal control for equivalent loading of
lanes, the membranes were reprobed using a
32P-labeled 0.97-kb BstEII fragment of
rice 28S rRNA excised from pRRbm2, which was constructed by subcloning
the 3.7-kb BamHI fragment of pRR217 into pUC19 (Takaiwa et
al., 1984). The autoradiograph was exposed for 10 to 20 min.
Quantitative analysis of HKT1 mRNA levels in the time-course
study was achieved by scanning x-ray films and measuring the relative
densities of film exposure using NIH Image 1.54 software (National
Institutes of Health, Bethesda, MD).
To determine the expression level of HKT1 mRNA in wheat
roots, the method of quantitative competitive reverse-transcription PCR
was used (Gilliland et al., 1990). For construction of the competitor
molecule, the HKT1 cDNA subcloned into the SmaI
site of the vector pGEM-HE (Liman et al., 1992) was cut with
KpnI and StuI, blunted, and religated. This
removed 783 bp from the N terminus of HKT1, including one
EcoRI site at position 777. The religated vector with the
C-terminal portion of the HKT1 cDNA contained two
EcoRI sites at positions 1026 and 1113 of the full-length HKT1-coding region and one in the polylinker of pGEM-HE at
the C-terminal end. To remove the EcoRI-EcoRI
fragment from the HKT1-coding region, the DNA was partially
digested with EcoRI. Isolation of the correct construct
missing the 87-bp EcoRI-EcoRI fragment from the
C-terminal part of the HKT1-coding region was verified by PCR. From this construct, mRNA was transcribed from the linearized plasmid using the mMESSAGE mMACHINE In Vitro Transcription Kit (Ambion,
Inc., Austin, TX).
Oligo(dT)-primed reverse transcription was carried out with 20 µM of total mRNA and varying amounts of competitor RNA
with the cDNA Cycle Kit (Invitrogen, San Diego, CA). The resulting single-stranded DNA was directly amplified in PCR reactions with the
primers 5 -CATGATCAATAACCCCGAGG-3 (forward, positions 900-919 of
full-length HKT1 cDNA) and 5-ATTAGCACAAACTTTCCTCC-3
(reverse, positions 1516-1535) with the following cycle parameters:
once at 94°C for 3 min; 40 times at 94°C for 1 min, 55°C
for 2 min, 72°C for 3 min; and once at 72°C for 5 min.
Amplified bands were analyzed on 2% agarose gels.
K+ Content and Uptake in Roots
At intervals after transfer to K+-free
solutions, barley root and shoot samples were rinsed briefly in fresh
K+-free solution and spun for 15 s in a
basket centrifuge to remove superficial water. Samples were then
weighed and placed in glass scintillation vials, which were ashed
overnight in a furnace at 400°C. Ashes were dissolved in distilled
water and analyzed for K+ with a flame photometer
(Instrumentation Laboratory, Lexington, MA).
Uptake by wheat roots was measured by atomic-absorption
spectrophotometry, as described by Benlloch et al. (1989). After 6 d of growth in hydroponic solutions, seedlings were rinsed in double-distilled water and for 5 min in a rinse buffer containing 10 mM Mes and 0.1 mM MgCl2,
Ca(OH)2, pH 6.0. At time 0, seedlings were
transferred to the uptake solution, which consisted of the rinse buffer
plus 10 µM RbCl. Seedlings were removed from the uptake
solution after incubations lasting up to 10 min and placed in an
ice-cold buffer containing 5 mM CaCl2
and 1 mM KCl for 5 min. Subsequently, the plant tissue was
carefully blotted on filter paper, and the roots were cut off to
determine their fresh weights and then frozen at  80°C. For
extraction of Rb+, the tissue was thawed and
soaked in 1.5 mL of 10% acetic acid for 12 h and then washed with
10 mL of boiling water. The [Rb+] of the
combined liquids was determined by atomic-absorption spectrophotometry.
Cation-Induced Depolarizations in Roots
The wheat plants from which HKT1 was isolated were used
for cortical root-cell membrane depolarization measurements. Plants were grown hydroponically in the presence of either 1 mM
CaCl2 or 1 mM KCl and 1 mM NaCl for 2 d after the 4-d germination period. Plant roots were pierced with quartz microelectrodes filled with 3 M KCl, and the membrane potentials of the cortical cells
were measured using an electrometer (model DUO 773, World Precision Instruments, Sarasota, FL). Roots were perfused with 1.8 mM
CaCl2, 6 mM
MgCl2, and 10 mM Mes, adjusted to pH
6.0. K+, Cs+, and
Rb+ were added as chloride salts to compare
cation-induced depolarizations in K+-starved
versus 1 mM K+-fed plants.
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RESULTS |
Barley plants previously grown in complete nutrient solution
containing 1.2 mM K+ and then
transferred to K+-free medium, had no significant
reduction of either root or shoot K+ at 4 h
(Fig. 1). By 12 h root
[K+] had declined from 88.6 ± 3.5 µM mol g1 at the time of transfer to
69.9 ± 3.5 µM mol g1, a reduction of
21% (Fig. 1). During the same time there was no change in shoot
[K+], which was 167 ± 2.6 µM mol g1 at the time of transfer to minus
K+ medium and remained at 168.6 ± 3 µM mol g1 12 h later (Fig. 1).
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| Figure 1.
Time course of whole-root ( ) and whole-shoot
( ) K+ concentration changes in the barley cv Klondike
following transfer of intact plants from a complete inorganic nutrient
medium containing 1.2 mM K+ to medium lacking
K+. Means and SE were determined for four
replicates of approximately 10 plants each. FW, Fresh weight.
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To investigate whether HKT1 mRNA levels are up-regulated
during K+ deprivation, expression of
HKT1 was investigated at intervals following removal of
exogenous K+. Quantitative analysis of the
northern blots presented in Figure 2
demonstrated that by 4 h after K+
withdrawal, the level of HKT1 expression had increased to
>2-fold in the barley cv Jackson and approximately 1.5-fold in cv
Klondike (Fig. 2, compare lanes 1 and 2 and 6 and 7).
HKT1 RNA levels increased in spite of the lack of detectable
changes in whole root or shoot [K+] by 4 h
after withdrawing K+ (Fig. 1). Expression of
HKT1 continued to increase until 12 h of
K+ deprivation, both in cvs Jackson and Klondike
(Fig. 2, lanes 4 and 9, respectively). Removing all sources of N
from the growth medium for 4 and 16 h caused no increase of
HKT1 expression; this treatment caused a 30% reduction of
HKT1 expression (Fig. 2, lanes 11 and 12). By 24 h of
K+ deprivation, HKT1 mRNA expression
had declined slightly in cvs Jackson and Klondike from the 12-h peak
levels (Fig. 2, lanes 5 and 10).
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| Figure 2.
Time course of HKT1 expression in
roots of cvs Jackson (lanes 1-5) and Klondike (lanes 6-12). Plants
were transferred to complete nutrient inorganic nutrient medium
containing 1.25 mM K+ on d 4. On d 7 plants
were transferred to medium lacking K+ for 0 h (lanes 1 and 6), 4 h (lane 2), 6 h (lanes 3 and 7), 8 h (lane 8),
12 h (lanes 4 and 9), and 24 h (lanes 5 and 10), or to medium
lacking N for 16 h (lanes 11 and 12). Fifteen micrograms of total
RNA was loaded into each lane. Lanes were probed with a 32P
fragment of an HKT1 cDNA clone from wheat and reprobed
with a 32P fragment of rice 28S rDNA as an internal control
for gel loading.
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Studies of K+
(86Rb+) uptake in barley
plants have commonly made use of plants grown in
CaSO4 for 4 to 6 d to generate
"low-salt" roots. These typically showed high rates of
high-affinity K+ uptake (Epstein et al., 1963).
The expression of the HKT1 gene was therefore examined in
roots of barley plants grown for 4 or 5 d in
CaSO4 without exogenous K+.
As shown in Figure 3, HKT1
mRNA levels remained high after 4 d of K+
deprivation (Fig. 3, lane 1). HKT1 mRNA levels increased
even further after 5 d of growth in K+-free
medium (Fig. 3, lane 2), whereas HKT1 levels were low in 1.2 mM K+-grown controls (Figs. 2, lane
1, and 3, lane 3). Transfer of plants after d 4 to a complete medium
containing 1.2 mM K+ for 1 d
reduced the high level of HKT1 expression, but within 4 h of removing K+ (Fig. 3, lane 6) a high level of
HKT1 expression was again restored to levels typical of
5 d of growth without K+ (Fig. 3, lane 2).
Further growth without K+ (lanes 7-10) to a
maximum of 24 h caused only a small increase of HKT1
expression beyond that at 4 h.
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| Figure 3.
Effect of growth on CaSO4 solution and
subsequent provision and withdrawal of K+ on
HKT1 mRNA expression in roots of the barley cv Jackson.
Plants were grown on K+-free CaSO4 solution for
4 d (lane 1) or 5 d (lane 2). Plants were then exposed to
1.25 mM K+ for 1 d, which suppressed
HKT1 mRNA levels. K+ was then withdrawn for
0 h (lane 3), 1 h (lane 4), 2 h (lane 5), 4 h (lane
6), 6 h (lane 7), 8 h (lane 8), 12 h (lane 9), and
24 h (lane 10). Fifteen micrograms of total RNA was loaded into
each lane. Probing was as in Figure 2.
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To distinguish the effects of the duration of K+
deprivation from any age dependency of the response, plants grown for
7, 8, or 9 d in a complete nutrient solution containing 1.25 mM K+ were subjected to 4 h of
K+ deprivation, and the levels of HKT1
expression were determined by northern analysis. The rapid
up-regulation of HKT1 was analyzed by measuring RNA levels
after 4 h of K+ deprivation. Figure
4 reveals that the strongest response to K+ deprivation was at d 7. Beyond d 7, the
relative increase in the level of HKT1 expression declined,
although withholding K+ increased HKT1
mRNA expression in all cases.
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| Figure 4.
Effect of age and K+ deprivation on
very rapid induction of HKT1 mRNA in roots of cv
Jackson. RNA was extracted from 7-d (lanes 1 and 2), 8-d (lanes 3 and
4), or 9-d (lanes 5 and 6) seedlings that were either grown
continuously in a complete inorganic nutrient medium containing 1.2 mM K+ (lanes 1, 3, and 5) or transferred from
complete medium to a medium lacking K+ for 4 h before
RNA extraction (lanes 2, 4, and 6).
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Because the HKT1 cDNA was initially isolated from wheat
roots, the level of HKT1 mRNA was further analyzed in wheat
plants. Competitive reverse-transcription PCR experiments (Gilliland et al., 1990) were performed on 6-d-old wheat seedlings to allow quantitative analysis of HKT1 mRNA levels. Roots grown in
the presence of 1 mM K+ showed only
very low HKT1 levels corresponding to less than 0.1 pg RNA
(Fig. 5, lanes 1 and 2). Wheat roots
grown in the absence of K+ (in 1 mM
CaCl2) showed a strong enhancement in
HKT1 mRNA levels 10- to 50-fold higher than roots grown in 1 mM KCl, based on quantitative PCR analysis (Fig. 5, lanes
3-7). These data show that in barley and wheat
K+ deprivation leads to increased levels of
HKT1 mRNA. Furthermore, in both species exposure of roots to
only 1 to 1.2 mM extracellular K+ was
sufficient to substantially reduce HKT1 mRNA levels.
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| Figure 5.
HKT1 mRNA levels in response to K+
deprivation in intact roots of the wheat cv Atlas 66. Agarose-gel
analysis of a reverse-transcription competitive PCR experiment with
mRNA isolated from roots grown in 1 mM K+
(lanes 1 and 2) and from roots grown without K+ in 1 mM CaCl2 (lanes 3-7). The amount of competitor
RNA is given in picograms on the bottom. Expected band sizes for
HKT1 mRNA and competitor RNA are indicated by horizontal
arrows. The intermediate band most likely represents
HKT1-competitor hybrids, as suggested by PCR experiments
with purified DNA templates. Lane 8, Control experiment without added
RNA.
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The question of whether the increased expression levels of
HKT1 mRNA can be correlated with an increased high-affinity
K+ uptake in roots, as is known for barley and
maize (Glass, 1976; Kochian and Lucas, 1982; Fernando et al., 1992),
was further analyzed by examining the response of wheat seedlings to
altered K+ provision during growth. First, the
effect of growing wheat seedlings in the presence of 1 mM
extracellular K+ on high-affinity uptake was
determined. When plants were pretreated with 1 mM
K+, high-affinity Rb+
uptake in roots bathed in 10 µM Rb+
was low (Fig. 6). By contrast, plants
grown in a K+-free medium (1 mM
CaCl2 or water) showed high rates of
high-affinity K+ (Rb+)
uptake (Fig. 6). These data show that high-affinity uptake was strongly
reduced in wheat roots grown in only 1 mM
K+. The elevated rates of high-affinity
Rb+ uptake in wheat roots evoked by
K+ deprivation (Fig. 6) are similar to those
reported for barley and other species (Williams, 1961; Epstein et al.,
1963; Young and Sims, 1972; Glass and Dunlop, 1978; Kochian and Lucas,
1982; Fernando et al., 1990) and correlate with the strong level of expression of HKT1 mRNA in response to
K+ deprivation (Figs. 2 and 5).
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| Figure 6.
High-affinity K+ (Rb+)
uptake in wheat roots in response to K+ deprivation.
High-affinity uptake was suppressed in roots grown in 1 mM
KCl. In K+-depleted roots grown hydroponically in
H2O or in 1 mM CaCl2, high-affinity
Rb+ uptake was induced. Average uptake rates from 10 (CaCl2) or 3 (H2O) replicate experiments are
illustrated. The [Rb+] was 10 µM. FW, Fresh
weight.
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Another method that may be used to analyze the up-regulation of
high-affinity K+ uptake in
K+-deprived roots is to measure depolarizations
in roots in response to micromolar concentrations of extracellular
K+ (Newman et al., 1987). Furthermore, analysis
of depolarizations in wheat roots enables a comparison to be made with
published biophysical transport properties of HKT1.
Electrophysiological studies of HKT1 expressed in X. laevis oocytes have shown that the alkali cations
K+, Rb+, and
Cs+ can each cause depolarization (Rubio et al.,
1996). This relatively low specificity among cations in triggering
depolarizations via HKT1 was shown to be due to the
characteristic reduction of HKT1-mediated outward currents
by low concentrations of alkali cations and/or to cation uptake
(Schachtman and Schroeder, 1994; Gassmann et al., 1996). Therefore,
experiments were pursued to determine whether depolarizations in planta
were also less specific among cations and whether these depolarizations
were enhanced by K+ deprivation.
Depolarizations triggered by extracellular perfusion of roots with 100 µM K+, Cs+,
or Rb+ were measured in wheat root cortical cells
from plants grown in the absence and in the presence of 1 mM K+. In
K+-depleted plants, exposure to 100 µM K+, Cs+,
or Rb+ in the external solution caused large
membrane depolarizations (Fig. 7A) that
were substantially greater in magnitude than the depolarizations
observed in 1 mM K+-grown plants
under the same conditions (Fig. 7, B and C). These data show that
alkali cation-induced depolarizations are enhanced by
K+ starvation.
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| Figure 7.
Membrane potentials and depolarizations of wheat
root cortical cells in response to alkali cations for plants grown in
the presence or absence of K+. A, Membrane potential of
root cortical cells of plants grown without K+ when the
root was externally perfused with 100 µM
Tris+ (open bars) and 100 µM K+,
Cs+, or Rb+ (solid bars). B, Membrane potential
of root cortical cells of plants grown in 1 mM
K+ when the root was externally perfused with 100 µM Tris+ (open bars) and 100 µM
K+, Cs+, or Rb+ (solid bars). C,
Membrane depolarizations induced by 100 µM
K+, Cs+, or Rb+ in
K+-deprived plants (striped bars) and
K+-supplied (1 mM) plants (solid bars). In
K+-deprived plants 100 µM K+,
Cs+, and Rb+ depolarized the membrane by
66.4 ± 9 mV (n = 13), 32 ± 8.8 mV
(n = 4), and 60.5 ± 9 mV
(n = 4), respectively. Corresponding values for 1 mM K+-grown plants were 26.4 ± 9 mV
(n = 7), 8.3 ± 1.9 mV (n = 6), and 25 ± 6.8 mV (n = 7),
respectively.
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| |
DISCUSSION |
Our data show that HKT1 expression is rapidly
up-regulated at the transcript level in roots of barley and wheat
following withdrawal of extracellular K+.
Down-regulation of HKT1 expression, by contrast, results
from exposure of the roots to only 1 to 1.2 mM
K+. Extensive earlier studies demonstrated the
relative rapidity of increased or decreased plasma membrane
K+ influx, respectively, in response to
withholding or resupplying K+ to barley roots
(Glass 1978; Fernando et al., 1990). In barley increased or
decreased K+ fluxes were detected by 1 h
after external [K+] was altered (Glass, 1978;
Fernando et al., 1990). Furthermore, increases in both
K+ uptake in roots and depolarizations by low
alkali cation concentrations are elicited by withholding
K+ and reduced by growth in 1 mM
K+, which shows a correlation with previously
described biophysical depolarization properties of HKT1. The
correlations between patterns of high-affinity K+
influx in roots of barley and wheat and HKT1 expression are
consistent with a contribution of HKT1 to the high-affinity
K+-uptake systems described in classical uptake
studies (Epstein et al., 1963; Glass, 1978; Kochian and Lucas, 1982).
The data presented in this report do not exclude contributions to
(cation-induced) depolarizations and to measured high-affinity K+ uptake in plants from additional transporters,
as pointed out previously (Schachtman and Schroeder, 1994; Maathuis et
al., 1996; Rubio et al., 1996). Recently, a new gene family of plant
K+-uptake transporters, named ATKT,
HAK1, or AtKUP, was identified in Arabidopsis and
barley (Quintero and Blatt, 1997; Santa-Maria et al., 1997; Fu and
Luan, 1998; Kim et al., 1998). The barley HAK1 cDNA
expressed in yeast and the AtKUP1 gene expressed in Arabidopsis were shown to mediate high-affinity
Rb+ uptake (Santa-Maria, 1997; Kim et al., 1998).
Additionally, AtKUP1 mediates a low-affinity
K+ or Rb+ uptake at a high
external K+ or Rb+
concentrations (Fu and Luan, 1998; Kim et al., 1998). The finding that
HAK1 and AtKUP3 mRNA levels are also increased by
withholding K+ supply (Santa-Maria et al., 1997;
Kim et al., 1998) indicates that these specific members of this gene
family may contribute to increased K+ influx
associated with K+ deprivation. Time courses of
expression and the transport mechanisms have not yet been determined
for these HAK/KUP genes. Furthermore, the apparent
complexity of high-affinity K+ uptake at the
molecular level highlights the necessity for characterizing the time
course of induction of individual components of transport to determine
the relative importance of particular genes at different times and
stages of development.
Regulation of HKT1 Expression by Root
[K+]
The present findings provide experimental evidence for the
hypothesis that the up-regulation of high-affinity
K+ uptake in roots can occur rapidly via events
affecting mRNA levels of K+ transporters. This
need not preclude additional posttranslational regulation of
K+-transport proteins. The age-dependence study
of HKT1 expression in CaSO4-grown
barley plants revealed that by d 4 the transcript level was already
highly expressed in these K+-depleted plants
compared with 1 mM K+-grown plants
(Fig. 3). By d 5, HKT1 mRNA levels had increased further.
Mechanistically, this gradual increase in HKT1 mRNA levels in CaSO4-grown plants over time may not be
different from the rapid increase of HKT1 mRNA levels
associated with the transfer of rapidly growing
K+-replete plants to solutions lacking
K+ (Fig. 2). Even without an exogenous source of
K+, seeds are initially well supplied with
K+ from seed reserves. Because these are diluted
by growth without exogenous K+, influx increases
over a period of approximately 8 d, after which time influx begins
to decline (Fernando et al., 1990). Thus, the pattern of
HKT1 expression and high-affinity K+
influx in barley were also correlated in this age-dependent manner. With increasing age the response to K+
deprivation declined (Fig. 4) so that by d 8 and 9 removal of K+ in K+-grown plants
evoked a smaller enhancement in HKT1 mRNA expression levels.
This result may have been due to the fact that by 8 and 9 d plants
are larger and have accumulated sufficient K+
such that a short period of K+ deprivation (4 h)
fails to perturb the K+ status as much as in
younger plants.
Figures 1 and 2 indicate that following the removal of exogenous
K+, increased levels of HKT1
expression were observed before a significant reduction in either
whole-root or whole-shoot [K+] was apparent.
Even after 24 h had elapsed, shoot [K+]
was still at a level that was 93% of that before the
K+ supply was interrupted (Fig. 1). However, by
this time root [K+] had declined to 44% of its
original value. In the analyses of gross tissue
[K+] as presented here, it is largely vacuolar
K+ that is being determined. Clearly, if the initiation of
increased HKT1 transcription was evident after 4 h of
K+ removal, before it was possible to detect
changes in root [K+], it is likely that the
signal responsible for regulating transcription is determined not by
information from the vacuole, which is little changed by this stage,
but by another pool, such as the extracellular space or cytosolic
[K+].
It is now well established that cytoplasmic
[K+] remains essentially constant when the
K+ supply is perturbed (Memon et al., 1985;
Walker et al., 1996a). If this is the case, then it is difficult to
invoke cytoplasmic K+ as the
K+ pool responsible for regulating
HKT1 expression. Nevertheless, Hooymans (1974) observed that
when exogenous K+ was withdrawn from barley
roots, translocation of K+ to the shoot continued
until root [K+] was reduced to the level of
CaSO4-grown roots. This involved mobilization of
vacuolar K+ for transport to the xylem via the
cytoplasm. Therefore, the possibility exists that, in switching to
vacuolar K+ as the source of
K+ for xylem translocation, there may be a
temporary perturbation of cytoplasmic K+
responsible for initiating the transcriptional events leading to
elevated levels of HKT1 expression. Alternatively, the net flux of K+ from the vacuole to the cytoplasm may
represent the responsible signal. During K+
translocation to the xylem, K+ is thought to be
loaded from the cytoplasmic phase of xylem parenchyma cells (Lauchli,
1972; Drew et al., 1990). Using electron probe x-ray microanalysis,
Drew et al. (1990) were able to demonstrate that the cytoplasmic
[K+] of outer cortical cells was statistically
lower than that of inner cortical cells in split-root experiments.
Thus, although it is generally true that K+
homeostasis operates to maintain the constancy of cytoplasmic K+ as a first priority, perturbations of plant
K+ resulting from modifying
K+ supply to the roots may nevertheless cause
some temporary perturbation of cytoplasmic
[K+].
An alternative hypothesis is that induction of HKT1 is
controlled by a K+ sensor located on the external
surface of the plasma membrane of root cells that is capable of rapidly
responding to altered concentrations of K+ in the
extracellular space. However, this hypothesis appears insufficient to
explain all of the observations, because in split-root experiments
(Claassen and Barber, 1977; Drew et al., 1984), withdrawal of external
K+ from one region of the root caused increased
K+ influx into the
K+-supplied roots as well as into the
K+-deprived roots. Thus, up-regulation of
K+ influx occurred in the
K+-supplied roots despite a constant external
[K+]. These results appear to signify a
response to internal rather than external signals.
High-Affinity K+ Uptake and Depolarization in Roots
In addition to the above-discussed molecular and physiological
events, exposure of maize roots to micromolar extracellular K+ concentrations results in immediate
depolarizations (Newman et al., 1987). It is interesting that in wheat
roots micromolar concentrations of the alkali cations
K+, Rb+, and
Cs+ all caused enhanced depolarizations in plants
grown in K+-free medium (Fig. 7, A and C).
Biophysical studies of HKT1 expressed in X. laevis oocytes have shown a low specificity for cation-induced depolarizations, which was attributed to inhibition of
HKT1-mediated outward currents by low-permeability cations
and/or by inward currents, depending on the cation and the conditions
(Gassmann et al., 1996; Rubio et al., 1996). These analyses emphasize
the fact that cation-induced depolarizations can occur through two simple mechanisms: inhibition of cation efflux or stimulation of cation
influx. The assumption that membrane depolarization originates from an
increased inward current through K+ transporters
(Maathuis et al., 1996) is therefore not universally valid, and
depolarizations cannot be used to unequivocally determine transport
mechanisms of individual components. Nevertheless, the present
observation that cation-induced depolarizations are strongly enhanced
by K+ deprivation (Fig. 7) is consistent with the
hypothesis that these depolarizations are directly linked to
high-affinity K+-transport mechanisms, as
originally revealed by Newman et al. (1987).
Multiple High-Affinity K+-Uptake Transporters
Despite the observed correlations between HKT1
expression levels and high-affinity K+-influx and
membrane depolarizations in the present study, the finding that
high-affinity K+ uptake via HKT1 is
mediated by a Na+-K+
symport (Rubio et al., 1995; Gassman et al., 1996) has led to the
suggestion that additional Na+-independent
K+ transporters should exist in plants (Epstein
et al.,1963; Rubio et al., 1995, 1996; Maathuis et al., 1996; Walker et
al., 1996b). Na+-coupled high-affinity
K+ uptake has been shown in charophyte algae
(Smith and Walker, 1989), in root cells of Egeria and
Elodea, and in leaves of Vallisneria (Maathuis et
al., 1996). Whereas these studies demonstrate the presence of a
Na+-coupled high-affinity
K+-uptake mechanism in plants analogous to that
of HKT1, the apparent absence of
Na+-dependent uptake when using
Rb+ as a tracer in barley, wheat, and Arabidopsis
(Epstein and Hagen, 1952; Maathuis et al., 1996; Walker et al., 1996b)
suggests that additional types of high-affinity
K+ transporters exist in plants, as discussed
previously (Rubio et al., 1996). Thus, the relative role of
HKT1 expression, although correlated with high-affinity
K+ influx, remains to be determined under
different growth conditions and at different developmental stages.
The existence of multiple high-affinity transport systems for the
acquisition of a single ion, e.g. the multiple high-affinity NO3 transporters of the
crnA family (Trueman et al., 1996; Quesada et al., 1997),
indicates that this pattern may be the norm. Recent studies have led to
the identification of a novel class of K+
transporters in plants, with some members showing high-affinity Rb+ uptake in yeast
(Santa-Maria et al., 1997) and in transgenic Arabidopsis cells (Kim et
al., 1998). The demonstration that gene families with multiple members
may also contribute to high-affinity K+ uptake
indicates that we cannot at present determine the relative contributions of individual genes, including HKT1 or
HAK/KUP, to high-affinity K+ uptake
without the use of molecular genetic disruption ("knock out") of
individual genes. Nevertheless, although the precise role of the HKT1
system remains to be determined in vivo, it is interesting that its
expression is so well correlated with patterns of high-affinity
K+ influx and membrane depolarization in barley
and wheat. Therefore, it is premature to presume that this system is of
no significance (Walker et al., 1996b). The rapid up-regulation of
HKT1 mRNA levels in response to K+
withdrawal provides a potent tool to further investigate the functional
and molecular basis of K+ sensing in plants.
| |
FOOTNOTES |
1
This research was supported by a Natural
Sciences and Engineering Research Council of Canada grant to A.D.M.G.
and by a U.S. Department of Agriculture grant to J.I.S.
2
Present address: Department of Botany,
University of Toronto, Ontario, Canada M5S 3B2.
3
Present address: Department of Plant Biology,
Koshland Hall, University of California, Berkeley, CA 94720-3102.
4
Present address: Escuela Tecnica Superior de
Ingenieros Agronomos. Universidad Politecnica de Madrid, 28040 Madrid, Spain.
*
Corresponding author; e-mail aglass{at}unixg.ubc.ca; fax
1-604-822-6089.
Received March 9, 1998;
accepted July 20, 1998.
| |
LITERATURE CITED |
Anderson JA,
Huprikar SS,
Kochian LV,
Lucas WJ,
Gaber RF
(1992)
Functional expression of a probable Arabidopsis thaliana potassium channel in Saccharomyces cerevisiae.
Proc Natl Acad Sci USA
89:
3736-3740
[Abstract/Free Full Text]
Benlloch M,
Moreno I,
Rodriguez-Navarro A
(1989)
Two modes of rubidium uptake in sunflower plants.
Plant Physiol
90:
939-942
[Abstract/Free Full Text]
Claassen N,
Barber SA
(1977)
Potassium influx characteristics of corn roots and interaction with N, P, Ca and Mg influx.
Agron J
69:
860-864
[Abstract/Free Full Text]
Drew MC,
Saker LR
(1984)
Uptake and long-distance transport of phosphate, potassium and chloride in relation to internal ion concentration in barley: evidence of non-allosteric regulation.
Planta
160:
500-507
[CrossRef][Web of Science]
Drew MC,
Saker LR,
Barber SA,
Jenkins W
(1984)
Changes in the kinetics of phosphate and potassium absorption in nutrient-deficient barley roots measured by a solution-depletion technique.
Planta
160:
490-499
[CrossRef][Web of Science]
Drew MC,
Webb J,
Saker LR
(1990)
Regulation of K+ uptake and transport to the xylem in barley roots; K+ distribution determined by electron probe x-ray microanalysis of frozen hydrated cells.
J Exp Bot
41:
815-826
[Abstract/Free Full Text]
Epstein E (1972) Mineral Nutrition of Plants: Principles and
Perspectives. John Wiley, New York
Epstein E,
Hagen CE
(1952)
A kinetic study of the absorption of alkali cations by barley roots.
Plant Physiol
27:
457-474
[Free Full Text]
Epstein E,
Rains DW
(1965)
Carrier-mediated cation transport in barley roots: kinetic evidence for a spectrum of active sites.
Proc Natl Acad Sci USA
53:
1320-1324
[Free Full Text]
Epstein E,
Rains DW,
Elzam OE
(1963)
Resolution of dual mechanisms of potassium absorption by barley roots.
Proc Natl Acad Sci USA
49:
684-692
[Free Full Text]
Fernando M,
Kulpa J,
Siddiqi MY,
Glass ADM
(1990)
Potassium-dependent changes in the expression of membrane-associated proteins in barley roots. 1. Correlations with K+ (86Rb+) influx and root K+ concentration.
Plant Physiol
92:
1128-1132
[Abstract/Free Full Text]
Fernando M,
Mehroke J,
Glass ADM
(1992)
De novo synthesis of plasma membrane and tonoplast polypeptides of barley roots during short-term K+ deprivation. In search of the high-affinity K+ transport system.
Plant Physiol
100:
1269-1276
[Abstract/Free Full Text]
Fu H-H,
Luan S
(1998)
AtKUP1: A dual-affinity K+ transporter from Arabidopsis.
Plant Cell
10:
63-73
[Abstract/Free Full Text]
Gassmann W,
Rubio F,
Schroeder JI
(1996)
Alkali cation selectivity of the wheat root high-affinity potassium transporter HKT1.
Plant J
10:
869-882
[CrossRef][Web of Science][Medline]
Gilliland G,
Perrin S,
Bunn HF
(1990)
Competitive PCR for quantitation of mRNA.
In
MA Innis,
DH Gelfand,
JJ Sninsky,
TJ White,
eds, PCR Protocols: A Guide to Methods and Applications.
Academic Press, San Diego, CA, pp 60-69
Glass ADM
(1975)
The regulation of potassium absorption in barley roots.
Plant Physiol
56:
377-380
[Abstract/Free Full Text]
Glass ADM
(1976)
The regulation of potassium absorption in barley roots: an allosteric model.
Plant Physiol
58:
33-37
[Abstract/Free Full Text]
Glass ADM
(1978)
The regulation of K+ influx into intact roots of barley (Hordeum vulgare (L) cv. Conquest) by internal K+.
Can J Bot
56:
1759-1764
[CrossRef]
Glass ADM,
Dunlop J
(1978)
The influence of potassium content on the kinetics of potassium influx into excised ryegrass and barley roots.
Planta
141:
117-119
[CrossRef]
Guy M,
Zabala G,
Filner P
(1988)
The kinetics of chlorate uptake by XD tobacco cells.
Plant Physiol
86:
817-821
[Abstract/Free Full Text]
Hooymans JJM
(1974)
Role of cell compartments in the redistribution of K and Na ions absorbed by the roots of intact barley plants.
Z Pflanzenphysiol
73:
234-242
Kim EJ,
Kwak JM,
Uozumi N,
Schroeder JI
(1998)
AtKUP1: An Arabidopsis gene encoding high-affinity potassium transport activity.
Plant Cell
10:
51-62
[Abstract/Free Full Text]
Ko CH,
Gaber RF
(1991)
TRK1 and TRK2 encode structurally related K+ transporters in Saccharomyces cerevisiae.
Mol Cell Biol
8:
4266-4273
Kochian LV,
Lucas WJ
(1982)
Potassium transport in corn roots. I. Resolution of kinetics into a saturable and linear component.
Plant Physiol
70:
1723-1731
[Abstract/Free Full Text]
Lagarde D,
Basset M,
Lepetit M,
Conejero G,
Gaymard F,
Astruc S,
Grignon C
(1996)
Tissue-specific expression of Arabidopsis AKT1 gene is consistent with a role in K+ nutrition.
Plant J
9:
195-203
[CrossRef][Web of Science][Medline]
Lauchli A
(1972)
Translocation of inorganic solutes.
Annu Rev Plant Physiol
23:
197-218
[CrossRef]
Liman ER,
Tytgat J,
Hess P
(1992)
Subunit stoichiometry of a mammalian K+ channel determined by construction of multimeric cDNAs.
Neuron
9:
861-871
[CrossRef][Web of Science][Medline]
Logemann J,
Schell J,
Willmitzer L
(1987)
Improved method for the isolation of RNA from plant tissues.
Anal Biochem
163:
16-20
[CrossRef][Web of Science][Medline]
Maathuis FJM,
Sanders D
(1995)
Contrasting roles in ion transport of two K+ channel types in root cells of Arabidopsis thaliana.
Planta
197:
456-464
[Web of Science][Medline]
Maathuis FJM,
Verlin D,
Smith FA,
Sanders D,
Fernandez JA,
Walker NA
(1996)
The physiological relevance of Na+-coupled K+ transport.
Plant Physiol
112:
1609-1616
[Abstract]
Memon AR,
Saccomani M,
Glass ADM
(1985)
Efficiency of potassium utilization by barley varieties: the role of subcellular compartments.
J Exp Bot
36:
1860-1876
[Abstract/Free Full Text]
Newman IA,
Kochian LV,
Grusak MA,
Lucas WJ
(1987)
Fluxes of H+ and K+ in corn roots. Characterization and stoichiometries using ion-selective microelectrodes.
Plant Physiol
84:
1177-1184
[Abstract/Free Full Text]
Quesada A,
Krapp A,
Trueman LJ,
Daniel-Vedele F,
Fernandez E,
Forde BG,
Caboche M
(1997)
PCR-identification of a Nicotiana plumbaginifolia cDNA homologous to the high-affinity nitrate transporters of the crnA family.
Plant Mol Biol
34:
265-274
[CrossRef][Web of Science][Medline]
Quintero F,
Blatt M
(1997)
A new family of K+ transporters from Arabidopsis that are conserved across phyla.
FEBS Lett
415:
206-211
[CrossRef][Web of Science][Medline]
Rubio F,
Gassmann W,
Schroeder JI
(1995)
Sodium-driven potassium uptake by the plant potassium transporter HKT1 and mutations conferring salt tolerance.
Science
270:
1660-1663
[Abstract/Free Full Text]
Rubio F,
Gassmann W,
Schroeder JI
(1996)
High-affinity potassium uptake in plants.
Science
273:
978-979
[Free Full Text]
Santa-Maria GE,
Rubio F,
Dubcovsky J,
Rodriguez-Navarro A
(1997)
The HAK1 gene of barley is a member of a large gene family and encodes a high-affinity potassium transporter.
Plant Cell
9:
2281-2289
[Abstract]
Schachtman D,
Schroeder JI,
Lucas WJ,
Anderson JA,
Gaber RF
(1992)
Expression of an inward-rectifying potassium channel by the Arabidopsis KAT1 cDNA.
Science
258:
1654-1658
[Abstract/Free Full Text]
Schachtman DP,
Schroeder JI
(1994)
Structure and transport mechanism of a high-affinity potassium uptake transporter from higher plants.
Nature
370:
655-658
[CrossRef][Medline]
Sentenac H,
Bonneaud N,
Minet M,
Lacroute F,
Salmon JM,
Gaymard F,
Grignon C
(1992)
Cloning and expression in yeast of a plant potassium ion transport system.
Science
256:
663-665
[Abstract/Free Full Text]
Smith FA,
Walker NA
(1989)
Transport of potassium in Chara australis. I. A symport with sodium.
J Membr Biol
108:
125-137
[CrossRef][Web of Science]
Takaiwa F,
Oono K,
Sugiura M
(1984)
The complete nucleotide sequence of a rice 17S rRNA gene.
Nucleic Acids Res
12:
5444-5448
Trueman LJ, Richardson A, and Forde BG (1996) Molecular cloning of
higher plant homologues of the high-affinity nitrate transporters of
Chlamydomonas reinhardtii and Aspergillus
nidulans. Gene 175: 223-231
Walker DJ,
Leigh RA,
Miller AJ
(1996a)
Potassium homeostasis in vacuolate plant cells.
Proc Natl Acad Sci USA
93:
10510-10514
[Abstract/Free Full Text]
Walker NA,
Sanders D,
Maathuis FJM
(1996b)
High-affinity potassium uptake in plants.
Science
273:
977-978
[CrossRef][Web of Science][Medline]
Williams DE
(1961)
The absorption of potassium as influenced by its concentration in the nutrient medium.
Plant Soil
15:
387-399
Young M,
Sims AP
(1972)
The potassium relations of Lemna minor L. I. Potassium uptake and plant growth.
J Exp Bot
23:
958-969
[Abstract/Free Full Text]
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|
|
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M. J. Chrispeels, N. M. Crawford, and J. I. Schroeder
Proteins for Transport of Water and Mineral Nutrients across the Membranes of Plant Cells
PLANT CELL,
April 1, 1999;
11(4):
661 - 676.
[Full Text]
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P. Maser, Y. Hosoo, S. Goshima, T. Horie, B. Eckelman, K. Yamada, K. Yoshida, E. P. Bakker, A. Shinmyo, S. Oiki, et al.
Glycine residues in potassium channel-like selectivity filters determine potassium selectivity in four-loop-per-subunit HKT transporters from plants
PNAS,
April 30, 2002;
99(9):
6428 - 6433.
[Abstract]
[Full Text]
[PDF]
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R. P. Elumalai, P. Nagpal, and J. W. Reed
A Mutation in the Arabidopsis KT2/KUP2 Potassium Transporter Gene Affects Shoot Cell Expansion
PLANT CELL,
January 1, 2002;
14(1):
119 - 131.
[Abstract]
[Full Text]
[PDF]
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Top
Abstract
Introduction