Plant Physiol. (1998) 117: 893-900
Autonomic Straightening after Gravitropic
Curvature of Cress
Roots1
Bratislav Stankovi
2,
Dieter Volkmann, and
Fred David Sack*
Department of Plant Biology, Ohio State University, Columbus, Ohio
43210 (B.S., F.D.S.); and Botanisches Institut, Universität
Bonn, 53115 Bonn, Germany (D.V.)
 |
ABSTRACT |
Few
studies have documented the response of gravitropically curved organs
to a withdrawal of a constant gravitational stimulus. The effects of
stimulus withdrawal on gravitropic curvature were studied by following
individual roots of cress (Lepidium
sativum L.) through reorientation and clinostat rotation. Roots
turned to the horizontal curved down 62° and 88° after 1 and 5 h, respectively. Subsequent rotation on a clinostat for 6 h
resulted in root straightening through a loss of gravitropic curvature
in older regions and through new growth becoming aligned closer to the
prestimulus vertical. However, these roots did not return completely to
the prestimulus vertical, indicating the retention of some gravitropic
response. Clinostat rotation shifted the mean root angle 
36°
closer to the prestimulus vertical, regardless of the duration of prior horizontal stimulation. Control roots (no horizontal stimulation) were
slanted at various angles after clinostat rotation. These findings
indicate that gravitropic curvature is not necessarily permanent, and
that the root retains some commitment to its equilibrium orientation
prior to gravitropic stimulation.
| |
INTRODUCTION |
The reorientation of most plant organs results in gravitropic
curvature that normally persists for the life of the organ. This
curvature is due to differential growth that at some point becomes
stabilized and long-lasting. However, before stabilization, the locus
of gravitropic curvature actually migrates in some organs (Firn and
Digby, 1979
; MacDonald et al., 1983; Tarui and Iino, 1997; for review,
see Stankovi et al., 1998). Thus, some curved regions later
straighten, and more basal regions that were straight later become
curved. Although the net result is a curved organ, loss of gravitropic
curvature (axis straightening) does occur distal to the final curve.
The local straightening described above occurs in organs that are kept
stationary with a constant g stimulus. In contrast, straightening throughout the organ seems to occur when a g
stimulus is withdrawn by placement in microgravity in spaceflight
or by rotation of the plant on a clinostat on earth (for review, see Stankovi et al., 1998). The loss of gravitropic curvature in space has been documented using oat coleoptiles and cress
(Lepidium sativum L.) roots (Chapman et al., 1994; Volkmann
and Tewinkel, 1996). Seedlings centrifuged in flight at 1g
continued gravitropic curvature when removed from the centrifuge.
Later, previously curved regions straightened in microgravity so that
the organ approached the angle it was in prior to the 1g
stimulus.
There are also relatively few descriptions of the straightening of
gravitropically curved organs resulting from the use of a clinostat in
ground-based studies. In some cases, straightening apparently only
occurred at very slow speeds of rotation (0.008-0.016 rpm), and not at
higher speeds (roots of Artemisia absinthium and cress;
Larsen, 1953, 1957). In another report, loss of gravitropic curvature
took place when roots were rotated at 2 and 4 rpm (Arabidopsis; Mirza
et al., 1984). But Larsen's studies did not continually follow the
same roots through time and none of these reports analyzed the regions
of the root responsible for straightening. Other studies on the effects
of clinostat rotation on cress roots (Hensel and Iversen, 1980; Hoson
et al., 1997) did not address the presence and extent of straightening.
Moreover, it cannot be assumed that because curved cress roots
straighten in microgravity (Volkmann and Tewinkel, 1996) they will also
do so on a clinostat, since oat coleoptiles lose gravitropic curvature
in space but not on a clinostat (Chapman et al., 1994). Obviously,
stimulus withdrawal in space and on a clinostat are qualitatively
different, since clinostat rotation results in a continuously changing
stimulation that is circumlateral (one axis of clinostat rotation) or
omnilateral (three-dimensional clinostat; Hoson et al., 1997),
whereas in microgravity, a g stimulus is essentially
eliminated.
Relatively few data exist that document the response of curved organs
to a withdrawal of a constant g stimulus. Further study of
this response is valuable both in evaluating the stability of
gravitropic curvature and in understanding how the orientation of new
growth is coordinated with that of older regions. For example, for
organ straightening to occur, curved regions must straighten and new
growth must be coordinately aligned (Fig.
1E). Such alignment is only one of
several possible fates, since in theory the growth that occurs in the
absence of a constant g stimulus could be random or could
reference persistent or past internal signal distributions (Fig. 1,
A-D).
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| Figure 1.
Theoretically possible outcomes of the direction
of root growth after gravitropically curved roots are then rotated on a
clinostat. In A to D, the root retains gravitropic curvature and
only new growth (black segments) is affected. A, Return to original
vertical. B, No change from previous direction. C, Persistence of an
internal signal gradient established by a previous constant
g stimulus. D, Random growth. E and F, Loss of
gravitropic curvature (root straightening) on clinostat and roots
either fully (E) or partially (F) return to prestimulus vertical.
|
|
To address these issues, the behavior of individual cress roots was
followed through reorientation and subsequent rotation on a clinostat.
We demonstrate that clinostat rotation results both in the loss of
gravitropic curvature and in the coordinated alignment of new growth to
produce mostly straight roots. However, these roots do not return
completely to the prestimulus vertical (Fig. 1F), and the final angle
between the root and the former vertical is positively related to the
length of prior stimulation.
| |
MATERIALS AND METHODS |
Plant Material and Experimental Procedure
Seeds of garden cress (Lepidium sativum L.) were
obtained from Chrysant (Bonn, Germany), allowed to imbibe in
double-distilled water, and then germinated on filter paper in
vertically positioned plastic Petri plates. After 24 h in darkness
at 22 ± 1.5°C, roots were approximately 5 mm long. Dishes were
then turned to the horizontal for 1 or 5 h in darkness and then,
along with vertical controls, were placed on a clinostat (Fig.
2A). The custom-made clinostat was built
with a 1 rpm synchronous instrument motor (model KS, Hurst Corp.,
Princeton, IN). Roots were rotated for 6 h either in an
"axial" configuration (the long axis of the base of the root was
parallel to the axis of clinostat rotation) or in a "somersault" configuration (root axis perpendicular to the axis of rotation).
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| Figure 2.
Diagram of experiment and angle measurement. A,
Vertically grown roots (24 h) were turned to the horizontal and then
rotated on a clinostat in two different configurations (curved arrow, bottom center). The gravity vector is toward the bottom of the diagram.
B and C, Method of angle measurement relative to the original vertical
(prestimulus) reference line (0°). Tracings from gravitropically
curved roots after 5 h of horizontal stimulation (B, gravity
vector toward left) and then after 6 h of rotation on a clinostat
(C). The boundary (arrowhead) between the hypocotyl (light shading) and
the root base is distinguished by root hairs (fine lines). The seed
coat (dark shading) is shown at the top. C, Decrease in the angle of
the apical and middle segments indicates a loss of gravitropic
curvature and root straightening. Bar in B = 0.5 cm.
|
|
Video Imaging and Data Analysis
Roots on the clinostat were continuously illuminated with
dim-green light (intensity of approximately 0.9 µmol
m
2 s1 at root level)
provided by an incandescent lamp filtered through two layers of a
Roscolux filter (no. 1090, Rosco Laboratories, Port Chester, NY) with a
peak transmission of 526 nm and a half-bandwidth of about 58 nm. This
enabled visualization of root growth and behavior using a Hi8
videocamera (model CCD-V101, Sony, Tokyo, Japan). Images were archived
at 1-h intervals using a videocassette recorder (model EV-5900, Sony)
and were subsequently digitized using a computer equipped with a video
capture card (Snappy Play, Inc., Rancho Cordova, CA). Images were
stored and processed using imaging software (Adobe Photoshop 4.0).
To measure curvature, roots were divided into three segments (Fig. 2, B
and C): the tipmost 2 mm, the next 4 mm (middle or subapical segment),
and the entire remaining basal segment. The basal segment extended to
the base of the hypocotyl, which could be distinguished from the root
by the absence of root hairs on the hypocotyl and by the larger
diameter and the lighter color of the root. Even though the basal
segment varied in length from 2 to 7 mm (depending upon the overall
length and age of the root), initial experiments indicated that it
showed enough uniformity in the distribution of curvature that it could
be quantified as a single segment. To test methods of delimiting root
segments, root-straightening data were compared for the same sample of
10 roots divided either into three segments as above or into 2-mm segments throughout the length of each root. Since all trends were
comparable using both methods for individual roots and for pooled data
(data not shown), the simpler three-segment method was adopted. The
angle measured was between the tangent of each of the three segments
and the original vertical reference line designated as 0° (Fig. 2B).
| |
RESULTS |
Cress roots turned to the horizontal for 1 h curved down
gravitropically at a mean of 62 ± 5° (± SE). When
such roots were subsequently placed on a clinostat and rotated for
6 h, some gravitropic curvature was lost and the roots mostly
straightened (Fig. 3, A and C). This
straightening on the clinostat occurred in part in regions of the root
that previously had curved gravitropically (Fig. 3, A, C, and E). Loss
of gravitropic curvature of the root was observed regardless of whether
the direction of rotation of the clinostat was around the root axis
(axial configuration, Fig. 3A) or perpendicular to the root axis
("somersault" configuration, Fig. 3C). Vertically grown (control)
roots grew in a more or less straight direction on a clinostat,
although frequently these roots slanted or curved spontaneously
away from their original direction of growth (Fig. 3, B and D).
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| Figure 3.
Images of the same roots through time
showing the loss of gravitropic curvature (after 1 h of horizontal
stimulation) during rotation on a clinostat (A, C, and E). Control
roots were kept vertical prior to placement on a clinostat (B and D).
The numbers indicate the time elapsed (hours) following placement on a
clinostat. Each figure (A-D) shows a different sample of six roots
with each root depicted three times. The positions of the roots are
different in A and B versus C and D to reflect the orientation of
clinostat rotation that was either in a "somersault" configuration
(A and B) or in an axial configuration (C and D). The circular arrow at
the right indicates the direction of rotation of the clinostat. The
original gravity vector was toward the bottom of the figure for A, B,
and E. Arrowheads indicate the transition zone between the root and the
hypocotyl. Bar = 1 cm for A to D. E, Tracings from a single root
kept horizontal for 1 h and then rotated on a clinostat for 6 h. The white and gray images show the root at the time labeled and at
the previous time point, respectively. The horizontal line indicates
the transition zone between the root and the hypocotyl. The double
arrow (6 h) shows the length of the root at 0 h for a
comparison.
|
|
The behavior of the three regions of the roots was approximated by
measuring segment angles (Fig. 2, B and C) through time to determine
the location, timing, and extent of straightening (Fig.
4). Many roots that were kept in a
horizontal orientation for 1 h contained part of the zone of
gravitropic curvature in their tips (distal 2 mm). The tip angle
remained unchanged during the 1st h of rotation on the clinostat (Fig.
4, A and C). The tip angle subsequently decreased 25 to 30° over the
next 5 h of clinostat rotation. This decrease resulted from the
former zone of gravitropic curvature becoming located farther from the
tip due to new root growth. Also, growth at the tip became oriented closer to the original vertical. The middle and basal segments continued curving toward the last constant gravity vector during the
first 2 to 4 h of clinostat rotation, i.e. some gravitropic curvature continued to be expressed in these segments. By 5 to 6 h
of rotation, the values for the angles of each of the three root
segments converged, indicating a significant amount of root straightening. The same pattern and timing of root straightening occurred in both the axial and somersault configurations of root rotation (Fig. 4, A and C). In control roots the mean angles for all
three segments were comparable throughout the period of clinostat rotation, indicating that on average these roots showed no preferred direction of root growth and/or that many roots were more or less straight. Thus, the straightening of gravitropically curved roots results in part from the loss of gravitropic curvature in older regions
and in part from the angle of new root growth on the clinostat moving
closer to the original vertical (prior to horizontal stimulation). These processes appear coordinated so that the angles of both regions
become roughly aligned.
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| Figure 4.
Angles of root segments through time showing the
development of gravitropic curvature and subsequent straightening on a
clinostat. Negative and positive values on abscissa indicate times for
both horizontal and on clinostat, respectively. A and C, Roots
horizontal for 1 h. B and D, Control (vertical) roots. All roots
were rotated for 6 h either in a somersault (A and B) or an axial
configuration (C and D). Mean angles (± SE) for each
segment (tip [ ], middle [ ], and base [ ]) were obtained
from 60 to 80 plants for each treatment.
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|
Although these roots mostly straightened, they were still slanted
25 ± 3° away from the original vertical (Fig. 4, A and C) in a
direction that indicated the retention of some gravitropic reaction.
However, this angle was reduced by 37° compared with the previous
angle of gravitropic curvature (62° after 1 h in a horizontal
orientation).
Roots rotated on the clinostat extended in length at the same rate,
approximately 0.75 mm h1, as that of
horizontally and vertically grown stationary roots. Neither prior root
orientation nor the configuration of rotation affected this growth
rate. During the 6 h on a clinostat, the roots grew about 4.5 mm.
To determine whether an extended period of horizontal stimulation would
preclude root straightening after withdrawal of the directional g
stimulus, roots were horizontally stimulated for 5 h. The
horizontal, stationary roots reached maximal gravitropic curvature
within 2 h of reorientation from the vertical, and after 5 h
of horizontal stimulation the mean curvature was 88 ± 3°. After
these roots were rotated on a clinostat for 6 h, the majority lost
gravitropic curvature and were essentially straight regardless of the
direction of clinostat rotation (Fig. 5,
A and C). A small fraction of roots lost no or only some gravitropic
curvature and were still curved after clinostat rotation.
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| Figure 5.
Images of roots on a clinostat as in Figure 3
except that roots in A and C were horizontal for 5 h before
placement on the clinostat. A and C, Despite variability most
roots exhibited partial loss of gravitropic curvature (roots marked
with *) and root straightening after 6 h on the clinostat. B and
D, Control roots mostly resembled those in Figure 3, B and D. Bar = 1 cm.
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Measurement of the angles of subsections of roots that were
horizontally stimulated for 5 h yielded results (Fig.
6, A and C) comparable to roots that were
horizontal for 1 h. The tip segment started to move closer to the
original vertical within 1 h of clinostat rotation. By 6 h,
new root growth was oriented 20 to 30° away from the angle that the
tip had occupied at the start of rotation (Fig. 6, A and C).
Gravitropic curvature continued to be expressed at a rate of about 2 to
5° h1 in the middle and basal regions during
the first 3 to 4 h of clinostat rotation. The reciprocal loss of
tip curvature and the increase in the angles of the middle and basal
segments resulted in a convergence of all three angles, indicating an
alignment or straightening of much of the root axis. Roots that were
fully curved gravitropically (after 5 h of horizontal stimulation)
straightened on average about 35° on a clinostat, essentially the
same value obtained for roots stimulated for only 1 h. But since
the 5-h roots were more curved to start with, they retained more of the graviresponse at the end of clinostat rotation; i.e. the mean angle of
the entire root (also equal to the convergence angle of the three
segments) was 53 ± 5° for roots stimulated for 5 h
compared with 25° for roots that were horizontal for 1 h.
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| Figure 6.
Angles of root segments as in Figure 4, except
that roots were horizontal for 5 h before placement on the
clinostat. n = 40 to 60 plants for each treatment.
A and C, Note that angles converge at 50 to 60°, indicating the
retention of more of a graviresponse than in roots horizontal for
1 h. Symbols are the same as those for Figure 4.
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Control roots exhibited a range of responses to clinostat rotation,
including curvature and slanting at various angles (Fig. 5, B and D).
Some control roots rotated in a somersault configuration slanted
slightly away from the hypocotyl hook (Figs. 5B and 6B), a direction
corresponding to the loss of gravitropic curvature (Figs. 5A and 6A).
But the degree of this slanting in controls was less than the loss of
gravitropic curvature, and these controls exhibited much more
variability (compare SEs in Fig. 6, A and B). In all other
controls, the final net angle of the root axis was zero.
To determine whether seed position affected root straightening, seeds
were positioned above or below the hypocotyl root axis in horizontal
seedlings. The position of the radicle can be determined in dry cress
seeds (Volkmann et al., 1986). In all experiments the seeds were
planted on the substrate so that the radicle emerged to the right of
the seed (Fig. 2A). For all experiments except those shown in Figure
7, vertical roots were turned
counterclockwise to the horizontal so that the cotyledons, the seed,
and the hypocotyl hook were on the lower side of the hypocotyl-root
axis (Fig. 2A). This resulted in both the hypocotyl and the
gravitropically curved root forming a "C" that was a clockwise
curve starting from the apex of the hook to the root tip (0 h in Figs.
3A and 5A). The curvature of the hypocotyl was maintained after root
straightening on a clinostat.
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| Figure 7.
Seed position does not affect root straightening.
In contrast to previous figures, the seed and the hypocotyl hook were
positioned on the upper side relative to the horizontal roots (A). Both
root straightening and retention of some gravitropic reaction occurred after 7 h of clinostat rotation, as indicated by the slanting of
most roots to the right (B), the direction of the gravity vector when
roots were previously horizontal for 1 h. Bar = 1 cm.
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|
In the experiments shown in Figure 7 vertical roots were turned
clockwise to the horizontal so that the cotyledons, seed, and hook were
on the upper side of the hypocotyl-root axis. In this case the curves
in the hypocotyl (below the hook) and in the root were in opposite
orientations so that the two formed an "S" (at 0 h). When
these seedlings were rotated on a clinostat for 7 h, the roots
straightened (Fig. 7), just as they did when the seeds were originally
positioned below the root (Figs. 3 and 5). Thus, root straightening
occurs regardless of the positions of the seed and the hypocotyl hook.
The curve in the hypocotyl (basal to the hook) was always toward the
side of the axis containing the seed regardless of orientation with
respect to gravity, indicating that the hypocotyl of 1-d-old seedlings
does not exhibit significant gravitropic curvature after 1 h of
horizontal stimulation. Also, unlike the gravitropic curvature of the
root, significant curvature of the hypocotyl was maintained throughout
clinostat rotation.
| |
DISCUSSION |
This study documents the straightening of gravitropically curved
roots following withdrawal of a constant g stimulus. Curved roots straighten on a clinostat through a combination of a loss of
gravitropic curvature and the alignment of new growth closer to the
prestimulus vertical.
Several previous reports exist of organ straightening after
g-stimulus withdrawal (Larsen, 1953, 1957; Mirza et al.,
1984; Chapman et al., 1994; Volkmann and Tewinkel, 1996; Tarui and
Iino, 1997). But even in studies in which the same organs were analyzed through time, only the tip angle was measured, and the stages of
straightening were not shown (Mirza et al., 1984; Chapman et al., 1994;
Tarui and Iino, 1997). To our knowledge, our data provide the first
visual depiction and multiregion analysis of the successive loss of
gravitropic curvature in the same organs through time following
stimulus withdrawal. These data also show that root straightening in
cress can occur at clinostat speeds of 1 rpm, whereas Larsen (1953,
1957) only found straightening at much slower speeds.
This finding of root straightening shows that gravitropic curvature, at
least complete curvature induced by 5 h of stimulation, can be
partly or fully reversed, whereas in roots that are left stationary and
that are not rotated on a clinostat, gravitropic curvature persists for
the life of the organ. This reversibility of gravitropic curvature on a
clinostat might result from active breakdown and wall
reconditioning and/or from wall elasticity in the zone of curvature.
This raises the question of when, if ever, curvature gets sufficiently
plastic and rigid such that it becomes irreversible. Analyses of the
responses of growing maize coleoptiles to applied tensile forces have
shown that even apparent plastic deformations can actually be a type of
reversible viscoelastic deformation or retarded elasticity (Hohl and
Schopfer, 1992; Cosgrove, 1993). Further study of this phenomenon of
loss of gravitropic curvature might prove valuable in identifying
changes in the biomechanical properties of cell walls responsible for differential tropic growth.
In addition to the loss of gravitropic curvature in regions of the root
formed before placement on the clinostat, root straightening also
involves new growth on the clinostat. Possible explanations for this
outcome are that in the absence of a constant g stimulus, that new growth follows and aligns with the straightening of older regions, or, conversely, that the loss of curvature results from coordination with new growth.
Root straightening cannot be due to the influence of hypocotyl position
or of some automorphogenetic component (Masuda et al., 1994;
Stankovi et al., 1998), since it occurs regardless of
whether the seed and hypocotyl were located above or below the
horizontally stimulated root. Similarly, it is found regardless of
whether the roots were rotated along their axis or at right angles to
their axis.
The phenomenon of organ straightening following tropistic curvature has
been referred to as "autotropism" (Pfeffer, 1906; Firn and Digby,
1979; Hart, 1990). The various usages of these terms have recently been
critically reviewed (Stankovi et al., 1998). Although the
migration of curvature during a constant g stimulus has been
termed "autotropism" (Firn and Digby, 1979; Hart, 1990; Myers et
al., 1995; Tarui and Iino, 1997), it may be more appropriate to
consider these growth adjustments to be part of the overall process of
gravitropism rather than a separate "tropism," autotropism that
only occurs during and in response to gravitropism (Stankovi et
al., 1998). In contrast, the straightening that occurs after a
withdrawal of a g stimulus is clearly not part of
gravitropism and for historical reasons might still be called
"autotropic straightening." But as this straightening is not a bona
fide tropism in the sense of a directional response of an organ to a
current environmental vector, the term autonomic straightening might be
more accurate.
Regardless of terminology, the findings that the root returns closer to
the prestimulus vertical indicates that there is some sort of inherent,
autonomic, or default tendency for disoriented organs to revert to a
previous equilibrium orientation (Fig. 1, E and F). This behavior seems
to reflect some persistent commitment to return root growth toward a
previous alignment (before it was turned on its side).
At the same time, since the final angle is still below what was the
horizontal (double arrow in Fig. 1F), some gravitropic reaction seems
to have been retained, even though the roots are no longer curved. This
apparent persistence of some gravitropic reaction might represent the
limits of autonomic straightening. This possibility is supported by the
finding that roots that were horizontally stimulated for 1 and 5 h
both moved about 36° closer to the prestimulus vertical after
clinostat rotation. Further study is required to determine whether
roots with gravitropic curvatures smaller than 36° (before clinostat
rotation) return completely to the prestimulus vertical. In any case,
the total amount of autonomic straightening is not simply limited by
properties of the zone of gravitropic curvature (e.g. wall elasticity),
but is actively and coordinately regulated in several regions of the root.
| |
FOOTNOTES |
1
This work was supported by grants
from the National Aeronautics and Space Administration (grant no.
NAG2-1023) to F.S. and by Deutsche Agentur für
Raumfahrtangelegenheiten (Bonn, Germany, grant no. 50 9429) and MWF
(Düsseldorf) to D.V.
2
Present address: Botany Department, North
Carolina State University, Raleigh, NC 27695.
*
Corresponding author; e-mail sack.1{at}osu.edu; fax
1-614- 292-6345.
Received October 16, 1997;
accepted April 6, 1998.
| |
ACKNOWLEDGMENTS |
We would like to thank K. Aram for technical assistance and
Michael Evans and several anonymous reviewers for their valuable comments on the manuscript.
| |
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Top
Abstract
Introduction
