Plant Physiol. (1998) 118: 1265-1275
NPH4, a Conditional Modulator of Auxin-Dependent Differential
Growth Responses in Arabidopsis1
Emily L. Stowe-Evans,
Reneé M. Harper,
Andrei V. Motchoulski, and
Emmanuel Liscum*
Division of Biological Sciences, University of Missouri, Columbia,
Missouri 65211
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ABSTRACT |
Although sessile in nature, plants
are able to use a number of mechanisms to modify their morphology in
response to changing environmental conditions. Differential growth is
one such mechanism. Despite its importance in plant development, little
is known about the molecular events regulating the establishment of
differential growth. Here we report analyses of the nph4
(nonphototropic hypocotyl) mutants of Arabidopsis that suggest that the NPH4 protein plays a
central role in the modulation of auxin-dependent differential growth.
Results from physiological studies demonstrate that NPH4 activity is
conditionally required for a number of differential growth responses,
including phototropism, gravitropism, phytochrome-dependent hypocotyl
curvature, apical hook maintenance, and abaxial/adaxial leaf-blade
expansion. The nph4 mutants exhibited auxin resistance and severely impaired auxin-dependent gene expression, indicating that
the defects associated with differential growth likely arise because of
altered auxin responsiveness. Moreover, the auxin signaling events
mediating phototropism are genetically correlated with the abundance of
the NPH4 protein.
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INTRODUCTION |
Most, if not all, plant growth can be considered differential in
the sense that not all cells within a given organ are elongating equally at any given time. However, "differential growth responses" have been classically defined by the bending or movement of an organ
resulting from unequal cellular growth in one position of the organ
relative to an opposing position. As such, the generation of
differential growth represents one adaptive mechanism by which plants
are able to modify their morphology rapidly in response to changing
environmental conditions. Examples of such responses include tropisms,
modification of apical hook structures, and nastic movements of leaves
(for reviews, see Darwin and Darwin, 1896
; Firn and Digby, 1980;
Palmer, 1985). Results from physiological studies conducted during the
past 60 years have shown that auxins likely play an important role(s)
in the establishment of differential growth (for reviews, see
Trewavas, 1992; Hobbie and Estelle, 1994; Kaufman et al., 1995).
Perhaps the most well-known interpretation of such data is found in the
Cholodny-Went theory (Went and Thimann, 1937). This theory holds
that tropic curvatures develop in response to an unequal distribution
of auxin in the two sides of a curving organ, which arises as a result
of lateral auxin transport. Despite considerable effort aimed at
testing this theory (see Trewavas, 1992), very little is known about
the coordinated regulation of differential growth at the
molecular level by auxin or any other growth-promoting/ -inhibiting
substances.
In recent years the study of mutants has played an increasingly
important role in the analysis of differential growth (for reviews, see
Hobbie and Estelle, 1994; Estelle, 1996; Leyser, 1998). The
aux1, axr3, and hls1 mutants of
Arabidopsis are especially notable. These mutants exhibit altered root
gravitropic and thigmotropic responses (Maher and Martindale,
1980; Okada and Shimura, 1990; Pickett et al., 1990; Timpte et al.,
1995), altered root and hypocotyl gravitropic responses (Leyser et al.,
1996), and altered apical hook formation/maintenance (Guzman and Ecker,
1990; Hou et al., 1993; Lehman et al., 1996), respectively. The
corresponding wild-type genes have been cloned for these mutants, and
each of the encoded proteins has been hypothesized to regulate
auxin-dependent processes. Specifically, the AUX1/amino acid
permease-like protein may function in the basipetal transport of IAA
(Bennett et al., 1996; Yamamoto and Yamamoto, 1998), the AXR3/IAA17
protein may act as an auxin-responsive transcriptional regulator (Rouse
et al., 1998), and the putative HLS1/N-acetyltransferase may
modify the transport or chemical structure of IAA in planta (Lehman et
al., 1996).
Despite the intriguing nature of these gene products and their possible
roles, phenotypic analyses of mutants indicate that the proteins
encoded by these loci function in only one or a limited number of
differential growth responses. Furthermore, the hls1 and
axr3 mutants exhibit several additional defects not directly related to differential growth, including decreased hypocotyl and
primary inflorescence length and changes in apical dominance (Lehman et
al., 1996; Leyser et al., 1996). Hence, none of these proteins appears
to have functions that are common to the suite of differential growth
responses a plant possesses.
Another class of Arabidopsis mutants in which differential growth can
be studied are the nph
(nonphototropic hypocotyl) mutants (Liscum and Briggs, 1995). Of particular interest are the
nph4 mutants, which have been shown to exhibit not only
disrupted hypocotyl and root phototropism, but also impaired hypocotyl
gravitropism (Liscum and Briggs, 1996). It has been hypothesized that
the NPH4 protein might act close to, or directly on, the differential
growth response, giving rise to tropic curvatures (Liscum and Briggs, 1996). In this paper we present results from a number of physiological analyses of the nph4 mutants that implicate NPH4 as a
specific regulator of multiple auxin-dependent differential growth
responses. Genetic and molecular studies further indicate that NPH4
represents a temporally early-acting, concentration-dependent modulator
of an auxin-response pathway(s) leading to differential growth.
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MATERIALS AND METHODS |
All mutants used in these studies were of the Columbia ecotype of
Arabidopsis and have been described elsewhere: nph1-4
(Liscum and Briggs, 1995); nph1-5 (Huala et al., 1997);
nph4-1, nph4-2, and nph4-3 (Liscum and
Briggs, 1996); tir5-1 (nph4-4) (Ruegger et al.,
1997); msg1-2 (nph4-102) (Watahiki and Yamamoto,
1997); etr1-1 (Bleecker et al., 1988); hy4-101
(Liscum and Hangarter, 1991); and phyB-9 (Reed et al.,
1993).
Growth Conditions
For seedling experiments, seeds were surface-sterilized and plated
on nutrient medium solidified with 1.0% (w/v) agar, as described
previously (Liscum and Briggs, 1995). One-half-strength Murashige and
Skoog nutrient medium (Murashige and Skoog, 1962) without Suc was used
for all but the auxin-sensitivity experiments. In these latter
experiments, full-strength Murashige and Skoog medium supplemented with
2.0% (w/v) Suc was used. Cold treatment and RL exposure to induce
uniform germination were as described previously by Liscum and Briggs
(1995).
After induction of germination plates were handled in several different
ways, depending on the experiment. For phototropic assays, plates were
placed in darkness for 71.5 h and then transferred to unilateral
BL (0.1 µmol m
2 s1)
for 8 h. For assays of dark growth and apical hook structure, plates were placed in a vertical position in darkness for the indicated
times. Vertical plate orientation caused seedlings to grow along the
surface of the agar medium, thus allowing seedling images to be traced
on the back side of the plates. When seedlings were to be exposed to
ethylene, plates were placed in a desiccator to which 1 mL of pure
ethylene was added each day after purging with ambient air (daily
ethylene exposure was approximately 50 µL/L). For de-etiolation
experiments, plates were placed in darkness for 23.5 h and then
transferred to BL or RL for 96 h at the indicated fluence rates.
For assays of RL-induced hypocotyl curvature, plates were placed in
darkness for 60 h and then transferred to RL for 20 h at the
indicated fluence rates. For auxin-sensitivity experiments, plates
lacking auxin were incubated in darkness for 23.5 h and then
transferred to YL (30 ± 5 µmol m2
s1). After 48 h seedlings were transferred
to vertically oriented plates containing auxin (IAA, 2,4-D, or NAA) at
the indicated concentrations. After marking the positions of hypocotyl
and root termini, plates were returned to YL for 72 h. For assays
of gene expression, plates were placed in darkness for 23.5 h and
then transferred to WL (45 ± 4 µmol m2
s1) for 7 d before exposure to auxin.
For mature plant experiments, seeds were sown directly on Pro-Mix
(Premier Horticulture, Red Hill, PA) saturated with 0.3% (w/v)
Peter's nutrient solution (Scotts-Sierra Horticultural Products, Marysville, OH) and grown under constant WL (100-150 µmol
m2 s1). Plants were
watered twice weekly with distilled water and once every other week
with nutrient solution.
Light Sources
For the induction of germination and phytochrome-dependent
hypocotyl growth inhibition experiments, RL was obtained by filtering light from gold fluorescent bulbs (F40/GO, Sylvania) through one layer
of red acrylic (Rohm and Haas no. 2423, 3.18 mm thick; Cope Plastics,
St. Louis, MO). For phototropism experiments, BL was obtained as
described previously (Liscum and Briggs, 1995), and for
cryptochrome-dependent hypocotyl-growth-inhibition experiments, BL was
obtained by filtering light from blue fluorescent bulbs (F40B,
Sylvania) through one layer of blue acrylic (Rohm and Haas no. 2424, 3.18 mm thick; Cope Plastics). For auxin-sensitivity experiments, YL
was obtained by filtering light from cool-white fluorescent bulbs
(F40CW.RS.WM, Sylvania) through one layer of yellow acrylic (Rohm and
Haas no. 2208, 3.18 mm thick; Cope Plastics). For the growth of
seedlings for RNA experiments, WL was obtained from unfiltered,
cool-white fluorescent bulbs, and for the growth of adult plants, WL
was obtained from Trimline T8 fluorescent bulbs (F32T8SP41, General
Electric).
Genetic Analysis
Heterozygous (nph4-1/NPH4-1) F1
plants were generated by pollinating wild-type plants with pollen from
homozygous nph4-1 plants. Complementation tests were
performed using F1 seedlings from crosses between
homozygous mutants. The genetic mapping stock consisted of
nph4-1 individuals (aphototropic/agravitropic seedlings)
selected from an F2 population arising from
self-pollination of F1 plants derived from a
cross of a nph4-1/nph4-1 plant of the Columbia ecotype to a
wild-type Landsberg erecta plant. The nph4
genotype of F2 mapping individuals was verified
in the F3 generation. PCR primers for
simple-sequence-length polymorphism marker-based mapping (Bell and
Ecker, 1994) were obtained from Research Genetics (Huntsville, AL).
Linkage to the flanking markers nga106 and nga139 was determined by
examination of 250 and 290 chromosomes, respectively. Map positions are
relative to the latest recombinant-inbred map
(http://genome-www.stanford.edu/Arabidopsis/ww/Feb98Rimaps/html/chrom5.html).
Growth Measurements
Hypocotyl curvature responses (phototropism and RL-induced
curvatures) were determined as described previously for phototropic and
gravitropic responses of etiolated Arabidopsis seedlings (Liscum and
Briggs, 1995). For the analysis of etiolated hypocotyl growth, seedling
images traced on the back of growth plates (see above) were measured
with a ruler to the nearest millimeter. Apical hook angles were
measured as described by Liscum and Hangarter (1993a). Light-dependent
hypocotyl growth inhibition was determined as described by Young et al.
(1992). Growth of hypocotyls and roots after exposure to exogenous
hormones was determined essentially as described by Lincoln et al.
(1990).
Microscopy
Three-day-old etiolated seedlings were fixed and embedded in
butyl-methyl-methacrylate, and ultramicrotome sections were made as
described by Baskin and Wilson (1997). Sections were then stained using
a modified periodic acid-Schiff's reagent method. Sections were first
placed in acetone for 10 min to extract the embedded material, and then
transferred to 1.0% (v/v) periodic acid for 15 min. After a 9-min wash
in tap water, sections were placed in Schiff's reagent (Sigma) for 30 min, followed by a 9-min wash in tap water. Sections were finally
washed for 1 min in distilled water.
Northern-Blot Analysis
Plates containing 7-d-old WL-grown seedlings were flooded with 10 mL of 100 µM IAA or solvent (0.04% [v/v] ethanol) and
returned to WL for an additional 1 h. Seedlings were then
immediately frozen in liquid nitrogen, and total RNA was extracted as
described by Ausubel et al. (1995). RNA samples (20 µg) were
separated on a 1.0% (w/v) agarose formaldehyde/Mops gel and
transferred to a nylon membrane (Nytran, Schleicher & Schuell),
according to the method of Ausubel et al. (1995). Prehybridization,
hybridization, and washing of blots were performed as described by
Ausubel et al. (1995). Probes were labeled with
32P by random priming (Prime-a-Gene Labeling
System, Promega) and then purified from unincorporated label by
chromatography (NucTrap columns, Stratagene). Hybridized membranes were
exposed to Kodak X-Omat x-ray film.
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RESULTS |
Genetic Analysis of the nph4 Locus
It was shown previously that nph4 alleles do not
segregate as simple recessive Mendelian traits in
F2 populations (Liscum and Briggs, 1995). Here we
demonstrate that etiolated NPH4/nph4 heterozygotes
(F1 plants) exhibit phototropic curvatures that are intermediate between, and significantly different from, those of
either parental homozygote (Table I).
These results indicate that nph4 alleles are semidominant
with respect to phototropism.
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Table I.
Phototropic curvature in wild-type, heterozygous,
and homozygous nph4 mutants
Three-day-old seedlings were exposed to 7 h of continuous,
unilateral BL at a fluence rate of 0.1 µmol m2
s1, and then phototropic curvatures were determined (see
``Materials and Methods''). Data represent the mean response ± SD. Numbers of seedlings are given in parentheses.
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The nph4 locus was mapped to the proximal arm of chromosome
5 between simple-sequence-length polymorphism markers (Bell and Ecker,
1994) nga106 and nga139 at approximately position 44 centimorgans (data
not shown). A similar map position has been reported for two recently
identified Arabidopsis mutants, msg1 (Watahiki and Yamamoto,
1997) and tir5 (Ruegger et al., 1997). The msg1
mutants were identified in a screen for mutants that failed to exhibit hypocotyl curvature in response to unilaterally applied auxin, whereas
the tir5 mutants were identified by their resistance to auxin-transport inhibitors. Neither the msg1-2 nor the
tir5-1 mutant was capable of complementing the
nph4 mutants in the F1 generation, and
no wild-type seedlings have segregated in the F2
progeny from such F1 plants (data not shown).
Thus, the msg1 and tir5 mutants represent
independently identified alleles of the nph4 locus. The two
tir5 alleles (Ruegger et al., 1997) have been renamed
nph4-4 and nph4-5 (M. Estelle, unpublished data), and the msg1 mutants (Watahiki and Yamamoto, 1997) have been
given nph4 allele designations beginning with allele number
101 (K. Yamamoto, unpublished data).
Overall Morphogenesis of Dark- and Light-Grown nph4
Plants Is Normal
It was proposed previously that the NPH4 gene
product might play an essential (Watahiki and Yamamoto, 1997), if not direct (Liscum and Briggs, 1996), role in the establishment of differential growth in Arabidopsis. This hypothesis was based mainly on
data related to hypocotyl tropisms. Alternatively, it could be argued
that the observed mutant tropic phenotypes arose because of changes in
overall growth properties or cellular/tissue organization, rather than
from specific defects related directly to differential growth. In an
attempt to reconcile these opposing hypotheses, we examined a number of
morphogenic properties in both dark- and light-grown nph4
plants.
Etiolated Growth
As shown in Figure 1, hypocotyls of
etiolated wild-type and nph4 seedlings exhibit similar
straight-growth kinetics. Moreover, the overall cellular morphology and
anatomical structure are similar between hypocotyls of wild-type and
nph4 seedlings (Fig. 2). Thus,
it appears unlikely that disrupted tropic responses of etiolated
nph4 seedlings result from gross changes in hypocotyl morphogenesis.
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| Figure 1.
Time course of hypocotyl growth of wild-type and
nph4 seedlings in darkness. At the indicated times after
induction of germination, seedlings were removed and hypocotyl lengths
were measured to the nearest millimeter. Data represent the mean
response of a minimum of 60 seedlings from two replicate experiments.
The vertical error bars represent the SE
values. Because the symbols often overlap, some individual
symbols and error bars are not visible. The dotted line represents a
regression (r2 = 0.942) calculated
for combined wild-type and nph4 data during the period
of linear growth (d 2, 3, and 4). Col, Wild-type Columbia ecotype.
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| Figure 2.
Cellular morphology of wild-type (A),
nph4-1 (B), nph4-2 (C), and
nph4-3 (D) hypocotyls. All sections were taken from a
region just below the apical hook of 3-d-old dark-grown seedlings,
where phototropism is initiated (Orbovic and Poff, 1991), stained with
periodic acid-Schiff's reagent, and viewed with bright-field optics.
Morphologies are similar to those reported previously for etiolated
Arabidopsis seedlings (Gendreau et al., 1997). Bar = 100 µm.
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Because apical hooks of etiolated seedlings are formed by the continual
differential growth of cells on the inner and outer edges of the hook
as they flow through the apical region (Silk and Erickson, 1978), we
examined the apical hooks of nph4 mutants. As illustrated in
Figure 3A, nph4 seedlings were
partially hookless, indicating that this response is disrupted by
nph4 mutations. The dark-dependent hook-opening response of
nph4 seedlings was saturated after about 2.5 to 3 d,
rather than 4 to 5 d as in the wild-type (Fig.
4; see also Liscum and Hangarter, 1993a).
Apical hooks of nph4 seedlings, however, were similar in
appearance to the wild type upon germination (data not shown). Thus, it
appears that the hookless phenotype of nph4 seedlings
resulted from an accelerated phase of opening. It is interesting that
both wild-type and nph4 seedlings exhibited an exaggerated
apical hook when grown in the presence of ethylene (Fig. 3B). This
result demonstrates that the cells within the apical hook of
nph4 seedlings are capable of exhibiting differential
growth, and indicates that the hookless phenotype of air-grown
nph4 seedlings is not a result of a general defect in apical
hook structure/maintenance. Taken together, the apical hook phenotypes
of nph4 seedlings suggest that NPH4 acts as a conditional
modulator of differential growth.
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| Figure 3.
Morphogenesis of etiolated wild-type and
nph4 seedlings grown in air (A) and 50 µL/L ethylene
(B). Photographs were taken after 4 d of growth in darkness. The
ethylene receptor mutant etr1-1 is shown as a negative
control for ethylene responsiveness. Col, Wild-type Columbia ecotype.
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| Figure 4.
Time course of apical hook opening in dark-grown
wild-type and nph4 seedlings. Seedlings were grown in
darkness on vertical plates. At the indicated times (after induction of
germination), apical hook angles were determined (see ``Materials and Methods''). Data represent the mean response of a minimum of 21 seedlings from two replicate experiments. The vertical error bars
represent the SE values. Because the symbols
often overlap, some individual symbols and error bars are not visible.
Col, Wild-type Columbia ecotype.
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De-Etiolated Growth
As was observed with etiolated seedlings (Fig. 1), hypocotyl
growth of deetiolated nph4 seedlings was
indistinguishable from that of the wild type (Fig.
5). In general, the growth and development of adult light-grown nph4 plants also appeared
normal. As shown in Table II, rosettes of
mature nph4 plants were similar to those of the wild type
with respect to size and number of leaves. The growth and development
of reproductive structures were also unaffected by nph4
mutations, such that wild-type and nph4 plants flowered with
a similar timing (data not shown) and the resultant inflorescences were
similar in size and number (Table II).
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| Figure 5.
BL-dependent (A) and RL-dependent (B)
hypocotyl growth inhibition in wild-type and nph4
seedlings. After 23 h of growth in darkness, seedlings were
transferred to continuous light at the indicated fluence rates shown
for an additional 96 h. Control seedlings were kept in darkness
for the entire growth period. Hypocotyl lengths were measured from
digitized images of seedlings (see ``Materials and Methods''). Data
represent the mean response of at least 33 seedlings from two
replicate experiments. Vertical error bars represent the combined
SE values for dark- and light-grown seedlings. Because the
symbols often overlap, some individual symbols and error bars are not
visible. The response of cry1-deficient hy4-101
seedlings is presented as a negative control. The response of
phyB-deficient phyB-9 seedlings is presented as a
negative control. Col, Wild-type Columbia ecotype.
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Table II.
Morphological features of adult wild-type and
nph4 plants
Seeds were sown directly on soil and allowed to germinate under
constant WL (120 µmol m2 s1) at 25°C.
Measurements were made at 3 weeks (number of leaves) and 6 weeks (all
other characteristics) after sowing. Data represent the mean
response ± SD of a minimum of 16 plants. Col,
Wild-type Columbia ecotype (genetic background of nph4-2).
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The only abnormal morphological feature invariably associated with
light-grown nph4 plants was the presence of epinastic or hyponastic rosette leaves (data not shown). The extent of leaf epinasty
observed in this study was similar to that observed previously for the
nph4-102 allele (see Watahiki and Yamamoto, 1997). Although hyponasty has been reported for the nph4-103 allele
(Watahiki and Yamamoto, 1997), only epinasty was observed in other
nph4 alleles (data not shown; Watahiki and Yamamoto, 1997).
The morphology of mature nph4 plants, like that of
seedlings, indicated that NPH4 is dispensable with respect to the
overall morphological and developmental program of the plant. However,
the epinastic/hyponastic character of nph4 rosette leaves,
which likely occurred as a result of abnormal differential growth of
adaxial and abaxial leaf surfaces (Palmer, 1985; Klee et al., 1987),
provides additional evidence that NPH4 acts as a modulator of
differential growth.
Phototropic Impairment Is a Common Feature of
nph4 Mutants
Watahiki and Yamamoto (1997) reported that
nph4-101, nph4-102, and nph4-103
seedlings exhibited normal phototropic responses in unilateral WL.
However, it has been shown previously that under conditions in which
significant phytochrome photoactivation occurs in addition to
phototropic photoreceptor activation (i.e. unilateral WL), considerable
phototropic response is observed in nph4 seedlings (Liscum
and Briggs, 1996). Therefore, we examined the phototropic response of
various nph4 mutants in unilateral BL. As shown in Table
III, nph4-102 was only about
28% as responsive as the wild type after exposure to 8 h of
unilateral BL, demonstrating that this allele is in fact
phototropically impaired. The response of nph4-102, however,
was more than twice as great as that observed in nph4-1
(Table III). nph4-4 seedlings exhibited a phototropic response that was intermediate between that of nph4-1 and
nph4-102 (Table III). Thus, it appears that NPH4 is
necessary for the generation of phototropic curvatures in unilateral
BL, and that considerable quantitative variation occurs between the
various nph4 alleles.
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Table III.
BL-dependent hypocotyl phototropism in dark-grown
wild-type and various nph4 seedlings
Three-day-old etiolated seedlings were exposed to 8 h of
unilateral BL (0.1 µmol m2 s1), and then
phototropic curvatures were determined (see ``Materials and Methods''). Data represent the mean response ± SE
from a minimum of two replicate experiments. Numbers of seedlings are
given in parentheses. Col, Wild-type Columbia ecotype.
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Etiolated nph4 Seedlings Lack RL-Induced
Hypocotyl Curvature
Although the hypocotyls of etiolated Arabidopsis seedlings
normally grow vertically upward (Mizra et al., 1984; Liscum and Hangarter, 1993b), they bend away from this orientation when exposed to
RL (Fig. 6; also see Hangarter, 1997).
This differential growth response apparently requires phytochrome B
photoconversion, since the response was virtually eliminated in a
phyB null mutant (Fig. 6). However, it does not require
functional NPH1, because a nph1 null mutant exhibited a
wild-type response (Fig. 6). This latter result, together with the
findings that the direction of RL-induced curvature was random (E. Liscum, unpublished data) and that phototropic curvatures in
Arabidopsis were not induced by exposure to unilateral RL (Steinitz et
al., 1985; Liscum and Briggs, 1996), indicates that this
phytochrome-B-dependent curvature response is not a phototropic
response. However, the nph4 mutants lack this RL-induced curvature (Fig. 6), indicating that at least one component is shared
between this response and phototropism. This result also illustrates an
additional condition in which NPH4 function is required for the
generation of differential growth.
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| Figure 6.
RL-dependent hypocotyl curvature in dark-grown
wild-type and mutant seedlings. Sixty-hour-old seedlings were exposed
to 20 h of continuous RL at the indicated fluence rates, and then
curvatures were determined (see ``Materials and Methods''). Data
represent the mean response of a minimum of 33 seedlings from two
replicate experiments. Vertical error bars represent the SE
values. Because the symbols often overlap, some individual
symbols and error bars are not visible. Col, Wild-type Columbia
ecotype.
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Auxin Responsiveness Is Disrupted in nph4
Seedlings
Auxin-Dependent Growth
The nph4 mutants have been shown to represent a unique
class of auxin-resistant mutants that are not crossresistant
to other growth regulators, and exhibit auxin resistance only in aerial organs (Watahiki and Yamamoto, 1997). Figure
7 shows the auxin resistance exhibited by
hypocotyls of the nph4-1, nph4-2, and nph4-3 mutants. Using a 50% inhibitory concentration as a
measure of resistance we found that the nph4-1,
nph4-2, and nph4-3 mutants were 15- to 20-fold
more resistant to IAA, 2,4-D, and 1-NAA than the wild type. In
comparison, the nph4-101, nph4-102, and
nph4-103 mutants were only about 5-fold more resistant to
2,4-D than the wild type (Watahiki and Yamamoto, 1997). Together, these
findings, along with those from analyses of apical hook structure and
BL-dependent phototropism in etiolated seedlings (Figs. 3-5; Watahiki
and Yamamoto, 1997), indicate that the nph4-101,
nph4-102, and nph4-103 mutants represent weak
alleles, whereas the nph4-1, nph4-2, and
nph4-3 mutants represent strong alleles.
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| Figure 7.
Dose responses of wild-type and
nph4 hypocotyls to exogenous IAA (A), 2,4-D (B), and
1-NAA (C). Three-day-old YL-grown seedlings were transferred to medium
containing various concentrations of auxins (see ``Materials and Methods''). Hypocotyl growth was measured 3 d later. Data
represent the mean response (as a percent of controls) of a minimum of
90 seedlings from at least three replicate experiments. Vertical error
bars represent the SE values. Controls were
seedlings transferred to plates containing only solvent (0.04%
ethanol). Because the symbols often overlap, some individual symbols
and error bars are not visible. Col, Wild-type Columbia ecotype.
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Auxin-Dependent Gene Expression
A number of genes have been identified in higher plants that are
transcriptionally activated within 5 to 60 min of exposure to auxin
(for review, see Abel and Theologis, 1996). In an attempt to determine
how early in the auxin-response pathway(s) NPH4 functions, the
steady-state mRNA levels of a number of these rapid primary-response genes were examined. As shown in Figure
8, expression of such genes was severely
impaired in the nph4 mutant background. In particular,
mRNAs of SAUR-AC1 and IAA12 were undetectable, and GH3, IAA4, and IAA6 mRNAs were
detectable only after extended autoradiographic exposures (data not
shown). IAA2, IAA5, and IAA13 mRNAs,
however, were clearly detectable in total RNAs from nph4-1 and nph4-2, but were reduced in level relative to the wild
type. The basal levels of expression (i.e. expression that was
dependent on endogenous auxin) of all of the primary-response genes
examined were also reduced. However, in some cases the effects were
much smaller than those observed with respect to induction by exogenous auxin. For example, although a dramatic reduction in the abundance of
IAA2 and IAA5 mRNAs was observed in auxin-treated
nph4 seedlings, the basal level of expression of these genes
was only slightly reduced relative to the wild type (Fig. 8).
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| Figure 8.
Expression of auxin-induced genes in wild-type and
nph4 seedlings. Total RNA was isolated from 7-d-old
WL-grown seedlings that had been exposed to 100 µM IAA
(+) or solvent (0.04% ethanol;  ) for 1 h. Samples (20 µg
each) were separated on a 1.0% agarose formaldehyde/Mops gel and then
blotted to nylon. The blot was then hybridized with
32P-labeled gene-specific probes against various
auxin-induced genes: SAUR-AC1 (Gil et al., 1994);
GH3 (Hagen et al., 1984); and IAA2,
IAA4, IAA5, IAA6,
IAA12, and IAA13 (Abel et al., 1995). The
blot was also hybridized with a labeled actin probe
(ACT7; McDowell et al., 1996) as a loading control. RNA
from nph1-4 seedlings was used as an additional positive
control. Similar overall results were observed in replicate experiments
with both WL- and dark-grown seedlings (data not shown). The blot was
rehybridized with multiple probes between strippings; thus,
artificially flat upper and/or lower edges were generated on the
IAA5, IAA6, and IAA13
transcripts when individual panels for these genes were cropped from
the entire blot for photographs. Col, Wild-type Columbia ecotype;
SAUR, SAUR-AC1.
|
|
In contrast to the nph4 mutants, no differences in mRNA
abundances of the auxin primary-response genes were observed in the nph1-4 mutant (Fig. 8). Although this finding was not
unexpected, given the proposed role of NPH1 as an early step in the
signaling pathway controlling phototropism (Liscum and Briggs,
1995; Huala et al., 1997), it does indicate that the molecular
phenotypes of the nph4 mutants were not simply a consequence
of their aphototropic physiology (Liscum and Briggs, 1996). It remains
to be determined if any of the early-response genes examined are
actually necessary for the establishment of differential growth.
| |
DISCUSSION |
NPH4 Acts as a Conditional Modulator of Multiple Differential
Growth Responses
Previous studies have shown that in addition to altered hypocotyl
and root phototropism (Liscum and Briggs, 1996), nph4 mutant seedlings exhibit impaired hypocotyl gravitropism (Liscum and Briggs,
1996; Watahiki and Yamamoto, 1997). In this study we demonstrate that
apical hook and phytochrome-dependent hypocotyl curvatures of etiolated
seedlings are also disrupted by nph4 mutations. Furthermore, adaxial/abaxial leaf-surface expansion is altered in adult
nph4 plants, such that rosette leaves are either epinastic
or hyponastic in appearance (Watahiki and Yamamoto, 1997; this paper).
Under laboratory conditions all of these nph4-dependent
alterations occur in the absence of any obvious changes in general
growth or development. One interpretation of these results might be
that differential growth responses are dispensable with respect to the
overall morphological and developmental program of Arabidopsis. However, the conditional nature of the nph4 phenotypes (i.e.
aphototropism in BL versus considerable phototropism in WL, and a
hookless phenotype in air versus a normal exaggerated hook in ethylene)
indicate that redundant mechanisms exist to regulate differential
growth. Hence, progression of a normal developmental program in the
nph4 background probably reflects the function of these
redundant differential growth pathways, rather than a "noneffect"
of the nph4 mutations and dispensability of differential
growth. Because NPH4 acts as a conditional modulator of differential
growth, it represents an attractive molecule for future studies of
differential growth regulation in the absence of potentially
confounding pleiotropic effects, as occurs with many of the other
apparent regulators of differential growth. Furthermore, the
conditional nature of NPH4 action should allow us to genetically
identify redundant modulators that are functioning under other
conditions.
The nph4 Mutants Comprise a Phenotypically Variable
Allele Series
Although the nph4 mutants were first identified
by their ability to disrupt hypocotyl phototropism in etiolated
seedlings (Liscum and Briggs, 1995, 1996), complementation studies
presented here demonstrate that several additional nph4
alleles have recently been identified in screens for seedlings
exhibiting reduced auxin-induced hypocotyl curvature (Watahiki and
Yamamoto, 1997) or sensitivity to auxin-transport inhibitors (Ruegger
et al., 1997). Analyses of the different nph4 mutants
indicate that considerable phenotypic variation exists within this
allele series. For instance, seedlings homozygous for the
nph4-102 allele (previously designated msg1-2) exhibit hypocotyl phototropism and apical hook closure that is considerably more like the wild type (Watahiki and Yamamoto, 1997) than
the mutants homozygous for any of the originally identified nph4 alleles, such as nph4-1. Furthermore,
whereas "weak" nph4 alleles (i.e. nph4-102)
are more resistant to exogenously applied auxin than the wild type,
they retain auxin sensitivity that is three to four times greater than
that observed with "strong" nph4 alleles (i.e.
nph4-1). Such differences in auxin sensitivity are probably
causal determinants of the aforementioned phenotypic differences
between these alleles.
Allelic variation within the nph4 allele series should not
be surprising considering how the different mutant alleles were generated. The nph4-1, nph4-2, and
nph4-3 mutants were generated by fast-neutron bombardment
(Liscum and Briggs, 1995, 1996), whereas the
nph4-4, nph4-5, nph4-101,
nph4-102, and nph4-103 mutants were generated by
EMS mutagenesis (Ruegger et al., 1997; Watahiki and Yamamoto,
1997). Fast neutrons usually induce deletions and/or large chromosomal
rearrangements (Rédei and Koncz, 1992; Bruggemann et al., 1996),
which result in the severe dysfunction or lack of the protein encoded
by the mutated gene. As expected, all of the fast-neutron-generated
nph4 mutants are phenotypically strong mutants. In contrast,
EMS usually causes G:C to A:T base substitutions that result in either
missense or nonsense mutations (DuBridge and Calos, 1987). As would be
predicted, both weak (i.e. nph4-102) and strong (i.e.
nph4-4) alleles have been identified within the collection
of EMS-generated nph4 mutants.
Strong nph4 Alleles Define a Threshold Step in the
Phototropic Signal-Response Pathway
It was concluded from earlier studies that NPH4 likely functions
as a signal transduction/response element acting downstream of the
photoperception event(s) mediating phototropism (Liscum and Briggs,
1995, 1996). Because nph4 mutants exhibit alterations in
multiple differential growth responses, it is probable that NPH4 acts
late in the phototropic signal-response pathway. The semidominant
inheritance exhibited by the fast-neutron-generated nph4
alleles indicates that the phototropic response is sensitive to the
gene dosage of NPH4, and further implies that the
magnitude of phototropic curvature is directly related to the abundance of the NPH4 protein. Therefore, we hypothesize that NPH4 is a concentration-dependent modulator of differential growth that functions
late in the signal-response process(es) leading to phototropic curvatures. Previous photophysiological studies of phototropism in
Arabidopsis (Steinitz and Poff, 1986; Janoudi and Poff, 1991; Janoudi
et al., 1992) and other species such as maize (Iino, 1987, 1990) have
shown that the magnitude of phototropic curvature is kinetically
limited by a postphotoperception component in the signal transduction
chain. It is possible that NPH4 represents, or regulates the activity
of, this previously predicted but unidentified gene product.
It is interesting to note that although the fast-neutron-generated
nph4 alleles exhibited semidominant inheritance, the
EMS-generated alleles have been reported to segregate as simple
recessive loci (Ruegger et al., 1997; Watahiki and Yamamoto, 1997). Of
several plausible explanations for these apparently contradictory data, one in which allele strength determines the pattern of inheritance seems most likely. For example, heterozygotes carrying a weak nph4 allele (i.e. nph4-102) could make enough
active NPH4 protein to exceed a threshold level required for the
establishment of a wild-type phototropic response, whereas
heterozygotes having a strong nph4 allele (i.e.
nph4-1) would not and thus would appear partially mutant.
Alternatively, the segregation of nph4 alleles could be
dependent on the physiological response being examined. As an example,
all alleles might segregate as semidominant loci with respect to
phototropism. A second alternative is that all nph4 alleles
are semidominant, independent of response, but that the "mutant"
and "wild-type" classifications used in the initial genetic
characterizations of the EMS-generated nph4 mutations (Ruegger et al., 1997; Watahiki and Yamamoto, 1997) were too broad to
clearly distinguish between recessive and semidominant inheritance. To
test these latter possibilities we are currently generating a
population that is heterozygous for the nph4-102 allele (an apparent recessive allele), and will examine the dominance of this weak
allele relative to phototropic response, for which semidominance has been observed.
Changes in Auxin Sensitivity of the nph4 Mutants
Likely Account for the Alterations in Differential Growth
Although most of the previously identified auxin-response mutants
are disrupted with respect to at least one differential growth response
(for reviews, see Hobbie and Estelle, 1994; Estelle, 1996; Leyser,
1998), nearly all are highly pleiotropic and exhibit multiple defects
in addition to altered differential growth. Moreover, many apparently
secondary effects of nonauxin growth regulators are observed in these
mutants. In contrast, the nph4 mutants represent a
class of auxin-response mutants that can be used to assess the
potential role(s) of auxin in the generation of differential growth in
the absence of confounding phenotypic effects.
In addition to being resistant to exogenously applied auxin, the
nph4 mutants exhibit alterations in multiple differential growth responses. Moreover, changes in hormone responsiveness of the
nph4 mutants are limited to auxins, and among the phenotypes examined to date, most morphological defects appear to be confined to
differential growth responses. The finding that auxin primary-response genes are expressed at dramatically reduced (or undetectable) steady-state levels in the nph4 background indicates that
NPH4 functions temporally early in an auxin-response pathway(s).
Because many of the genes that were examined are normally
transcriptionally activated within 5 min of exposure to auxin (for
review, see Abel and Theologis, 1996), and the lag period between
tropic stimulation and measurable curvature of hypocotyls and roots in
Arabidopsis is approximately 5 to 20 min (Kiss et al., 1989; Orbovic
and Poff, 1991), NPH4 activity is apparently required before, or
concomitant with, cellular changes that actually drive differential
growth. These observations, together with those gathered from analyses of other auxin-response mutants (for reviews, see Hobbie and Estelle, 1994; Estelle, 1996; Leyser, 1998), provide clear genetic evidence that
auxin plays a critical role in the generation of differential growth
patterns. Our results suggest further that the magnitude of
differential growth is related directly to the auxin responsiveness of
the plant, which can be modulated by NPH4. These conclusions are
consistent with a broad interpretation of the Cholodny-Went theory (see
Trewavas, 1992).
Whereas a definitive biochemical function for NPH4 awaits cloning of
the NPH4 locus, two obvious possible functions can be proposed based on the data accumulated to date: (a) NPH4 regulates lateral auxin transport (influx and/or efflux) or (b) NPH4 modulates auxin sensitivity at some step after the establishment of an auxin gradient. In terms of auxin influx, previous studies have shown that
IAA and 2,4-D enter cells through an active influx carrier, whereas NAA
enters via passive diffusion (Delbarre et al., 1996). Thus, if NPH4
regulates auxin influx, the nph4 mutants would be expected
to exhibit greater sensitivity to NAA than either IAA or 2,4-D.
However, all of the nph4 mutants examined were found to
exhibit equivalent levels of resistance to IAA, 2,4-D, and NAA. With
respect to auxin efflux, loss-of-function mutations affecting either
the efflux carrier itself or some positively acting regulatory protein
would be expected to cause increases in intracellular auxin
concentration (see Lomax et al., 1995), thereby promoting dramatic
changes in morphology. Increases in both hypocotyl elongation and
apical dominance have been observed in light-grown Arabidopsis plants
that overproduce IAA (Romano et al., 1995). However, no such
morphological changes were observed in the strong nph4
mutants. Moreover, to achieve the reduced basal levels of expression of
the IAA4 and IAA6 genes observed in the nph4 mutants, intracellular auxin concentrations might need
to increase as much as 4.5 orders of magnitude (see Abel et al., 1995),
which seems improbable. Therefore, it is unlikely that either auxin
influx or efflux is dependent on NPH4 activity; therefore, we
hypothesize that NPH4 plays a role in the modulation of auxin sensitivity. Such an activity could arise through direct binding of
auxin or at some step removed from auxin binding (i.e. regulation of
intracellular auxin signaling or auxin-dependent gene expression). These types of activities are consistent with the observed genetic and
physiological phenotypes of the nph4 mutants. We are
currently in the midst of a chromosome walk to clone the
NPH4 locus, and in the near future would like to address
these possibilities at the molecular level.
In conclusion, the results presented here demonstrate that the
NPH4 locus encodes an important conditional modulator of
auxin-dependent differential growth. Further analysis of this locus and
the encoded protein will certainly provide insight into the basic
regulation of these adaptive growth responses, and lead to a more
comprehensive understanding of the coordinated regulation of cellular
growth by auxins.
| |
FOOTNOTES |
1
This work was supported by grants from the
National Science Foundation (NSF) (no. MCB-9723124), the U.S.
Department of Agriculture (USDA)-National Research Initiative
Competitive Grants Program (no. 9602628), and the University of
Missouri Research Board (no. RB96-055) to E.L. E.L.S.-E. was
supported by a predoctoral fellowship from the University of Missouri
Maize Biology Training Program, a unit of the Department of
Energy/NSF/USDA Collaborative Research in Plant Biology Program. R.M.H.
was partially supported by the University of Missouri Food for the 21st
Century Program.
*
Corresponding author; e-mail mliscum{at}biosci.mbp.missouri.edu;
fax 1-573-882-0123.
Received July 14, 1998;
accepted September 1, 1998.
| |
ABBREVIATIONS |
Abbreviations:
BL, blue light.
EMS, ethyl methanesulfonate.
RL, red light.
WL, white light.
YL, yellow light.
| |
ACKNOWLEDGMENTS |
We are grateful to Ms. Jan Wilson and Dr. Tobias Baskin for
tissue embedding/sectioning/staining and for help with microscopy. We
are also grateful to those who contributed materials for these studies:
Dr. Mark Estelle for seed of tir5-1 (nph4-4); Dr.
Kotaro Yamamoto for seed of msg1-2 (nph4-102);
Dr. Pam Green for the SAUR-AC1 clone; Dr. Gretchen Hagen for
the GH3 clone; Dr. Sakis Theologis for the various
IAA clones; and Dr. Julie Stone for the ACT7
clone. We thank Ms. Lelia Flagg, Ms. Jamie Sommer, and Ms. Carrie
Vaughn for plant care and other technical assistance. We also thank
Drs. Tobias I. Baskin, Winslow R. Briggs, James A. Birchler, Tom J. Guilfoyle, Gretchen Hagen, Jane Murfett, John C. Walker, and Mr. Kevin
Lease for critical reading of the manuscript.
| |
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Abstract
Introduction