Plant Physiol. (1998) 118: 733-741
Directional Guidance of Nicotiana alata
Pollen Tubes
in Vitro and on the Stigma1
W. Mary Lush*,
Franz Grieser, and
Mieke Wolters-Arts
Plant Cell Biology Research Centre, School of Botany (W.M.L.), and
School of Chemistry (F.G.), University of Melbourne, Parkville,
Victoria 3052, Australia; and University of Melbourne, Parkville,
Victoria 3052, AustraliaDepartment of Experimental Botany,
University of Nijmegen, Toernooiveld 1, 6525 Nijmegen, The Netherlands
(M.W.-A.)
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ABSTRACT |
Pollen tubes navigate the route from
stigma to ovule with great accuracy, but the cues that guide them along
this route are not known. We reproduced the environment on the stigma
of Nicotiana alata by immersing pollen in stigma exudate
or oil close to an interface with an aqueous medium. The growth of
pollen in this culture system mimicked growth on stigmas: pollen grains
hydrated and germinated, and pollen tubes grew toward the aqueous
medium. The rate-limiting step in pollen germination was the movement of water through the surrounding exudate or oil. By elimination of
other potential guidance cues, we conclude that the directional supply
of water probably determined the axis of polarity of pollen tubes and
resulted in growth toward the interface. We propose that a gradient of
water in exudate is a guidance cue for pollen tubes on the stigma and
that the composition of the exudate must be such that it is permeable
enough for pollen hydration to occur but not so permeable that the
supply of water becomes nondirectional. Pollen tube penetration of the
stigma may be the most frequently occurring hydrotropic response of
higher plants.
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INTRODUCTION |
Fertilization of the ovules of flowering plants occurs when
desiccated pollen grains on the receptive surface of the female (the
stigma) hydrate, germinate, and produce a tube that elongates directionally to penetrate the stigma (Knox, 1984
; Dickinson and Elleman, 1994; Nasrallah et al., 1994). These events occur in the
lipid-rich environment formed by the pollen coat or the stigma exudate,
which is essential for successful fertilization (Pandey, 1963; Konar
and Linskens, 1966b; Preuss et al., 1993; Goldman et al., 1994;
Wolters-Arts et al., 1998). Cells of the "wet" stigmas of
solanaceous plants release lipid droplets into the intercellular spaces
of the stigma and directly onto its surface. The droplets accumulate
and coalesce to form a transition layer of an oil-in-water emulsion
between an aqueous phase within the stigma and a lipid phase on the
surface (Konar and Linskens, 1966a; Herrero and Dickinson, 1979; Cresti
et al., 1986; Kandasamy and Kristen, 1987). Pollen on solanaceous
stigmas does not adhere to papillae but remains free within the
exudate, where it hydrates despite the negligible amount of water
present within the exudate itself (Konar and Linskens, 1966b) and the
barrier to water movement that lipids are usually assumed to impose.
Following germination the directional growth of pollen tubes (which
elongate by tip growth) into the stigma suggests that some external cue
establishes their polarity. Light, tactile, electrical, and chemical
cues have been suggested as polarizing agents in pollen tubes and other
tip-growing cells (Heslop-Harrison and Heslop-Harrison, 1986; Reger et
al., 1992; Cheung et al., 1995; Hülskamp et al., 1995; Malho and
Trewavas, 1996; Kropf, 1997); however, although potential external
guidance cues have been identified for pollen tubes, their roles in
guidance within the pistil remain unclear (Hepler, 1997; Sommer-Knudsen
et al., 1998).
By applying oils to exudate-free stigmas of transgenic Nicotiana
tabacum plants, we recently demonstrated the importance of the
chemical nature of the exudate by showing that stigma function, which
is restored by the application of exudate, can also be restored by some
triglycerides (Wolters-Arts et al., 1998). Results of the in vitro
assay carried out with N. tabacum pollen (Wolters-Arts et
al., 1998) suggest that the directional growth of pollen tubes into the
stigma is dependent on the presence of a boundary between the exudate
(or oil) and the aqueous environment of stigma cells. However, the
nature of guidance in the N. tabacum in vitro assay was
unclear because of the clustering of pollen grains and the possibility
that some of the oils used were toxic. We report here the results of
investigations of the growth of pollen tubes in an in vitro system in
which pollen is immersed in exudate (or a functional substitute) close
to an interface with an aqueous medium, thus reproducing one aspect of
the stigma environment. Pollen in our system mimics pollen behavior on
the stigma: it hydrates and germinates, and pollen tubes grow toward
the aqueous medium, probably using a gradient in the concentration of
water to set the direction of growth.
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MATERIALS AND METHODS |
Pollen Culture
Nicotiana alata cv Link et Otto plants of the
self-incompatibility genotypes
S2S2 and
S6S6 were used as
sources of pistils, stigma exudate, and pollen. There was no difference
in the growth of S2 and
S6 pollen in exudate from
S2S2 plants, which
is consistent with the finding that the exudate has no role in the
rejection of self-pollen in N. alata (Pandey, 1963) that
occurs within the style (Lush and Clarke, 1997). Exudate was collected
from mature stigmas of emasculated flowers with a micromanipulator
(Leitz, Wetzlar, Germany) and used immediately. Oils tested as
potential substitutes for the exudate were mineral oil (catalog no.
M-5904, Sigma) and purified olive oil (Meadowlea Foods Ltd., Mascot,
NSW, Australia). Cultures were established by placing a drop of exudate or oil (0.2-1.0 µL) on a glass microscope slide and inoculating it
with freshly collected, air-dried pollen (approximately 100 grains/µL
oil). A smaller drop of an aqueous medium was injected into the center
of the oil-pollen mixture, and the culture was covered with a glass
coverslip (2 × 2 mm) to produce a two-dimensional, two-phase
culture in which a central aqueous phase was surrounded by exudate or
oil (Fig. 1).
Cultures were photographed as soon as the coverslip was in place.
Subsequent photographs were taken within 1 h and thereafter at
intervals of 1 to 2 h. The drop of aqueous medium fragmented during establishment of some of the cultures, enabling rapid hydration of pollen grains associated with satellites of the main body of aqueous
medium. Such grains were readily detected from photographs and were
excluded from all analyses. Cultures were incubated at 25°C to
30°C. Aqueous media injected into oils were based on a pollen tube
growth medium developed for N. alata (12.5% PEG 6000, 0.15 M Suc, 1.0 mM CaCl2, 1.0 mM KCl, 0.8 mM MgSO4, 1.6 mM H3BO3, 0.03% casein acid hydrolysate, and 25 mM Mes, pH 5.9). An
olive oil:medium emulsion (1:1) was made by sonication for 20 min.
The aqueous medium was modified by omission of components. To ensure
that Ca2+ was not present as a contaminant in a
buffered solution of PEG, EGTA was added to the solution at a
concentration (1 mM) just sufficient to prevent the growth
of pollen tubes within the buffered PEG. Addition of
Ca2+ to the buffered PEG containing 1 mM EGTA alleviated the inhibition of pollen tube growth.
Hydration and germination were monitored using an inverted microscope
(model IM35, Zeiss). The degree of hydration of pollen grains was
measured as the ratio of the minor axis of the grain to the major
(longitudinal) axis. Water uptake was calculated from the increase in
the volume of individual grains (Heslop-Harrison, 1987; Dickinson and
Elleman, 1994). Germination was defined as the emergence of the pollen
tube. Pollen tubes within a 150o arc centered on
the pollen grain and widening toward the aqueous medium were defined as
growing toward the aqueous medium. Distances were measured from the
interface to the closest part of the pollen grain.
All experiments were conducted at least twice. In each experiment with
exudate there was a minimum of four replicate cultures, and in
experiments with olive oil there was at least eight. Cultures established with exudate were controls for the initial experiments with
olive oil and mineral oil, and cultures with complete aqueous medium
were controls for experiments with modified media. Data were pooled for
statistical analysis (
2).
The permeability of mineral and olive oils to water was compared by
covering 1% agarose gels (in 3.5-cm-diameter Petri dishes, depth 1 mm)
with layers of oil (depth 1 mm) and monitoring evaporation by weight
(open dishes held in laboratory, four measurements within a 7.5-h
period, four replicates of each treatment). Controls were gels with no
covering layer of oil and layers of oil without any underlying gel.
Pollen Hydration and Growth on Stigmas
Growth of compatible pollen was examined by light microscopy
(Photomakroscop M400, Wild-Leitz, Wetzlar, Germany, or Zeiss inverted
microscope) and by epifluorescence microscopy (model BH2
photomicroscope, Olympus). Hydration and germination of individual pollen grains placed on stigma papillae with a micromanipulator were
monitored with the inverted microscope in flowers cut from plants and with petals partially removed but otherwise intact (total of
20 grains observed). Pollen grains (total of 10) coated with exudate
were also observed on papillae projecting from the exudate. These
grains were coated with exudate by soaking bulk pollen in exudate and
then draining excess exudate away with the tissues. Individual grains
were extracted from the mass of pollen grains and positioned with a
micromanipulator. Hydration of grains within the exudate (or a blend of
exudate and oil) was observed on stigmas flooded with a suspension of
pollen in mineral oil to overcome problems of refraction. A total of 20 grains were observed. In parallel with observations of individual
grains, pollen was removed from stigmas (two per harvest time) by
washing with mineral oil at intervals after pollination, and germinated grains were counted. Pollen tube penetration of washed stigmas was
assessed by examining the surface of stigmas and stigma squashes (Martin, 1959) stained with aniline blue (0.1%, Merck, Darmstadt, Germany).
The effect of the RH surrounding the stigma on pollen germination and
growth was studied using cut styles. The lower 17 mm of each style was
sealed in a small vial (cut end in water), and the small vial was
enclosed in a larger vial partly filled with pure water or a saturated
solution of a salt. Solutions in the large vials produced a RH around
the upper 3 mm of the style (including the stigma) ranging from 76% to
100%. Styles were incubated in the laboratory at approximately 20°C.
Styles remained competent to support pollen germination and tube growth
for more than 24 h after cutting. Treatments were replicated three
times and the experiment was repeated five times.
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RESULTS |
Hydration and Germination of Pollen Grains in Isolated Exudate and
on Stigmas
Exudate was collected from stigmas using a micromanipulator and
placed on a microscope slide. Examination of the exudate by light
microscopy showed that it was not an emulsion and that there was no
change in its volume following exposure to air in the laboratory for
24 h. Dry pollen of N. alata is hydrophobic and
dispersed readily in the isolated exudate, but pollen grains did not
hydrate. These observations are consistent with previous findings that the exudate on solanaceous stigmas is lipidic and that it is not a
reservoir of compounds required for pollen germination (Konar and
Linskens, 1966b).
A culture system was developed in which pollen grains surrounded by
exudate were supplied with a nearby source of water and other
requirements for the germination and growth of pollen tubes (Fig. 1). A
sharp interface formed between the aqueous medium and the exudate, with
pollen grains located in both phases of the culture (exudate and
aqueous) and spanning the interface between them. Following placement
of the coverslip, there was no further movement of either pollen grains
or the interface. The progressive hydration and germination of pollen
was followed by photomicroscopy (Fig. 2,
A-C). Pollen in the aqueous medium hydrated before the first
inspection of cultures, within approximately 45 s of injection of
the aqueous medium. Based on the difference in the average dimensions
of pollen grains before and after hydration, the rate of uptake of
water into grains in the aqueous phase was approximately 500 fL
s
1. Grains spanning the interface hydrated
within 3 to 4 min.
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| Figure 2.
Hydration, germination, and directional
growth of pollen tubes in exudate or olive oil close to an interface
with an aqueous medium. A to C, Progressive hydration and germination
of pollen grains in exudate 50 min, 3 h, and 4.5 h, respectively,
after injection of the aqueous medium. Pollen grains closest to the
interface hydrated and germinated first. The pollen tube emerged from
the aperture closest to the interface and grew toward the aqueous
medium. D and E, Growth of two tubes in exudate toward the interface
5 h after the injection of aqueous medium. The direction of pollen
tube growth was determined by both the position of the germinal
aperture and the axis of polarity of the tip (photographed 5 h
after establishment of the interface). F, Pollen in exudate between two
interfaces with aqueous medium showing growth of tubes toward the
nearest interface (photographed after 6 h). G and H, Pollen in
olive oil 5 min and 5 h, respectively, after injection of aqueous
medium. Pollen spanning the interface germinated first and tubes
emerged into the aqueous medium. I, Pollen in an emulsion of aqueous
medium in olive oil close to a boundary with a predominantly aqueous
phase. The pollen tube did not grow toward the boundary (photographed
after 5 h). aq, Aqueous medium; aq, predominantly
aqueous phase; ex, stigma exudate; oil, predominantly oil
phase; pg, pollen grain; pt, pollen tube. Arrowheads indicate apertures
in pollen grain; lines indicate extended short axes of pollen grains
based on photographs of partially hydrated grains. Bar in H = 50 µm and refers to the entire figure.
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We were most interested in pollen grains that hydrated and germinated
when surrounded by exudate. We used the photographic record of each
pollen grain to exclude the possibilities that the grain hydrated when
in transient contact with the aqueous medium during establishment of
the culture or in a small satellite of aqueous medium produced by
fragmentation of the main body of medium. Part of one such time series
of photographs is shown in Figure 2, A to C. Only grains that were
observed to hydrate progressively when surrounded by exudate are
included in the following results.
Pollen in exudate hydrated more slowly than pollen in direct contact
with the aqueous medium. There was some variation between grains, but
in general the closer grains were to the interface with the aqueous
medium the more rapidly they hydrated (Figs. 2 and
3A). The flux of water into pollen grains
was estimated for a subset of grains photographed at higher
magnification (×25). The flux into grains 10 µm from the
interface was approximately 1.5 fL
s1 (Fig. 3B). Grains between two interfaces
hydrated more rapidly than grains a similar distance from a single
interface (Fig. 2); these were excluded from our analyses. Some small,
irregularly shaped grains did not hydrate (Fig. 2).
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| Figure 3.
Hydration of pollen grains surrounded by exudate
or mineral oil but close to an interface with an aqueous medium. Each
point represents a pollen grain. A, The degree of hydration of pollen
grains in exudate or mineral oil 3 h after the establishment of
the interface with the aqueous medium. B, Variation in the flux of
water through exudate to pollen grains with distance from the interface
(estimated during the first 90 min of pollen hydration).
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The cytoplasm of cultured pollen grains started to stream at about the
time grains became fully rounded. Germination of grains within the
aqueous medium or spanning the interface started 30 min after injection
of the aqueous medium. Germination of grains within the exudate started
later and was more delayed the farther the grains were from the
interface (Fig. 2, B and C). In one experiment, for example, the
germination rate of pollen 3 h after injection of the aqueous
medium was 80% for grains between 1 and 20 µm from the interface,
30% for grains between 20 and 40 µm, and 0% for grains farther than
40 µm. Grains up to 60 µm from the interface usually germinated
within 6 h, but grains farther away, although they progressively
hydrated, rarely germinated. The pollen tube emerged from the pore
closest to the interface (Fig. 2, A and C, grain on extreme right) in
more than 95% of grains.
When two pores were approximately equidistant from the interface, the
tube was equally likely to emerge from either pore. The position of
tube emergence from most grains ensured that the tubes would reach the
interface if they grew approximately radially outward from grains.
However, except for pollen tubes in which the germinal pore was
immediately adjacent to the aqueous medium (Fig. 2C, extreme right),
tubes grew more directly toward the interface than would be expected
from radial growth (Fig. 2, C-E). Tubes then passed into the aqueous
medium. The accumulated results of seven experiments with exudate and
the complete aqueous medium are summarized in the first row of Table
I and show that the directional
growth of pollen tubes toward the aqueous medium was highly
reproducible.
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Table I.
Direction of growth of pollen tubes emerging from
grains immersed in lipid near an interface with an aqueous medium of
varying composition
Numbers in parentheses show total number of tubes (pooled for all
experiments) emerging within 6 h of the establishment of an
interface between the lipid and the aqueous medium. In all treatments
the direction of pollen tube growth was statistically different (P < 0.005) from random growth. Growth in the absence of PEG was
statistically different (P < 0.005) from all other treatments.
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All tubes from grains spanning the interface of the aqueous medium and
the exudate emerged into the aqueous medium (total of 49 tubes
observed). Pollen tubes from grains within the aqueous medium had no
consistent directional orientation (data not shown). Pollen between two
aqueous interfaces produced tubes that grew toward the nearest
interface (Fig. 2F). Emulsion-sized droplets of an aqueous solution
were observed within the exudate 1 to 2 h after cultures were
established and became more common as experiments proceeded. The
droplets were confined to localized regions of the exudate and usually
derived from burst grains or tubes. The growth of pollen tubes emerging
in regions of emulsion was not directional. The observations that
follow are restricted to events occurring within 6 h of the
introduction of the aqueous medium and to regions of the exudate (or
substitute) in which emulsion-sized droplets were absent.
The hydration of pollen grains and growth of pollen tubes in the
culture system were compared with growth on N. alata
stigmas. Germination of pollen on stigmas was monitored by
examining grains removed by washing the stigma in mineral oil and
staining for the presence of pollen tubes within the stigma.
Germination was first detected in grains removed from the stigma 30 min
after pollination. The first tubes within the stigma were also detected after 30 min, but the main period of penetration into the stigma occurred between 2 and 4 h after pollination. The majority
(>90%) of pollen tubes grew directly into the stigma. Hydration and
germination of individual grains on the stigma were also observed. Some
mature stigma papillae projected above the surface of the exudate, but pollen grains placed on these papillae never hydrated, even if the
grains were first coated thinly with exudate (Fig.
4, A-D). Grains within the exudate could
not be directly observed because of light refraction, but hydration and
germination of pollen on the stigma were observed in stigmas gently
flooded with a suspension of pollen in mineral oil. Grains within the
exudate/oil and close to the stigma (Fig. 4, E and F), including those
not in direct contact with papillae, hydrated. Pollen tubes grew toward
the stigma (data not shown).
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| Figure 4.
Hydration of pollen grains and growth of pollen
tubes on stigmas. A to D, Pollen on stigma papillae projecting through
the exudate into air at the RH prevailing in the laboratory. Dry pollen
(A and B) and pollen presoaked in exudate and drained (C and D) did not
hydrate. Photographs were taken 1 h (A and C) and 18 h (B and
D) after pollination. E and F, Pollen on stigma flooded with mineral
oil at the start of the experiment and photographed 30 min and 4 h
after pollination did hydrate. G and H, Growth of pollen tubes on
stigmas held at controlled RH, photographed 16 h after
pollination. G, Stigma at 88% RH. Only stigma papillae are visible
above the exudate. H, Stigma at 100% RH. Pollen tubes have grown from
the stigma into the surrounding air. pap, Papillar cell; pg, pollen
grain; pt, pollen tube. Scale bar in A = 50 µm and refers to A
through F; scale bar in G = 50 µm and refers to G and H.
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Oil, Water, and PEG Are the Only Requirements for Directional
Growth in Culture
Our results show that the presence of an immiscible, aqueous
medium within isolated stigma exudate establishes the conditions needed
for the guidance of pollen tubes toward the aqueous medium. To
investigate the role of components of the culture system in directing
pollen tube growth toward the aqueous medium, we tested potential
substitutes for the exudate (olive oil and mineral oil) and omitted
components of the aqueous medium.
The time course of hydration and germination in olive oil was the same
as in the exudate. The first grains to hydrate were those closest to
the interface with the aqueous medium, and their tubes grew toward the
aqueous medium (Fig. 2, G and H). These results were highly
reproducible, as shown by the summary of results presented in Table I.
All of the more than 800 tubes observed emerging from grains spanning
the interface grew directly into the aqueous medium (Fig. 2H). Growth
of tubes in the absence of a directional supply of aqueous medium was
investigated by replacing olive oil with a 1:1 emulsion of olive oil
and medium and establishing cultures as described above. These cultures
had a predominantly oil phase and a predominantly aqueous phase, but
the boundary between the phases was less distinct and stable than in
the usual cultures. Pollen in the predominantly oil phase of these
cultures often produced tubes that did not grow toward the boundary
between phases (Fig. 2I), but the results were not quantified because of the instability of the boundary. The predominantly water phase was
opaque (Fig. 2I), precluding observations.
When mineral oil was substituted for exudate, only grains that were
located in the aqueous medium or that spanned the interface became
fully hydrated, even after prolonged incubation (Fig. 3A). All of the
grains spanning the interface (35 were observed) produced tubes that
grew directly into the aqueous medium. A possible explanation for the
failure of pollen to hydrate and germinate in mineral oil is that this
oil is less permeable to water than olive oil. The permeability of the
two oils was assessed by measuring the effectiveness of a covering
layer (1 mm deep) of each oil in reducing evaporation from gels. After
7.5 h, the mass of gels exposed to air had decreased by 457 ± 3 mg (± SE), whereas the mass of gels covered by olive
oil or mineral oil had decreased by 4.6 ± 0.01 and 0.75 ± 0.06 mg, respectively. There was no change in the mass of the pure
oils.
The data presented show that stigma-specific compounds within the
exudate are not required for tube growth toward an interface with an
aqueous medium. Directional growth of pollen tubes also occurred in
cultures incubated in the dark (Table I), showing that any changes in
the direction or wavelength of light caused by the presence of the
interface were not the signal for directional growth. Water itself and
any of the compounds dissolved in the aqueous medium are potential
sources of a chemical guidance cue within the oil. To identify this
cue, we modified the composition of the aqueous medium. No observations
were possible when pure water was substituted for the usual medium
because most of the pollen grains burst before germinating. The
released cell contents formed an emulsion around any grains that
remained intact in the oil.
Directional growth of pollen tubes in exudate persisted when the
aqueous medium was simplified to a buffered solution of PEG and Suc;
growth of tubes in olive oil persisted when the aqueous medium was a
buffered solution of PEG (Table I). Although
Ca2+, a potential guidance cue, was not added to
the simple media used in these experiments, its presence as a
contaminant was not precluded. To minimize the possibility that
Ca2+ was responsible for guidance, EGTA was added
to a buffered solution of PEG at a concentration just sufficient to
prevent the germination of pollen added directly to the medium. Some
grains within the oil germinated and these tubes grew toward the
EGTA-containing medium (Table I), where they burst. Tubes also grew
toward a pure solution of PEG and toward an aqueous medium containing
all components except PEG (but at a lower frequency, Table I). The incidence of pollen grain and tube bursting was higher in all of the
modified media than in the complete medium; pollen grains in regions of
emulsion created by this bursting were not included in the results.
Disruption of Normal Water Gradients at the Stigma Alters the
Direction of Pollen Tube Growth
Results with pollen in culture suggested that a gradient of water
within the exudate could direct pollen tubes into the stigma. To
investigate the role of water gradients at the stigma, pollinated stigmas were enclosed in a RH from 76% to 100%. At a RH 
88%, most
pollen tubes grew directly into the stigma; at a RH > 88%, the
incidence of tubes projecting through the exudate and into the
surrounding air increased with increasing RH (Fig. 4, G and H).
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DISCUSSION |
The Directional Growth of Pollen Tubes on Stigmas Is Reproduced in
Culture
The cues that guide pollen tubes into and through the style
function by establishing an axis of polarity. Attempts have been made
to identify chemical guidance cues by observing the responses of pollen
tubes growing in gelled media to additives diffused into the gels. The
additives tested include defined compounds such as sources of
Ca2+, undefined compounds from tissue slices and
pistil extracts, and purified components of the pistil (Brink, 1924;
Tsao, 1949; Rosen, 1971; Heslop-Harrison and Heslop-Harrison, 1986;
Mascarenhas, 1993; Cheung et al., 1995).
The present culture system represents a departure from most previous
assays because it reproduces a key element of the environment on
solanaceous stigmas. Pollen was immersed in natural exudate or a
functional substitute, where it hydrated only when a source of water
and other requirements for germination and growth were introduced to
the system as a physically distinct aqueous phase. The low density of
pollen ensured that the pathway of water to pollen was through oil and
not from grain to grain. Hydrated pollen germinated and tubes grew
directionally toward the aqueous phase. The conclusion that growth is
directional is based on observations of individual tubes and thus
avoids a problem present in many assays for directional growth: that
differential growth at high and low concentrations of the test compound
is difficult to distinguish from attraction or repulsion of pollen
tubes (Rosen, 1971; Heslop-Harrison and Heslop-Harrison, 1986). The
growth of a small number of N. alata tubes parallel to or
away from the aqueous interface (Table I) showed that pollen tubes can
extend into the oil phase; therefore, some form of guidance must
operate to direct the majority of tubes to the interface. Another
common problem in experiments on directional growth is that the results
are not quantified; our quantification of the directional growth of
N. alata pollen tubes showed that it was highly reproducible
(Table I).
There are other studies of pollen growing in oil. Maize pollen tubes
supplied directly with water while immersed in mineral oil were
observed to grow toward an aqueous phase (Kranz and Lörz, 1990).
However, this work was a study of in vitro fertilization in maize and
observations of directional growth were not investigated in depth. We
reported that Nicotiana tabacum pollen tubes in some triglycerides appear to grow toward an aqueous phase (Wolters-Arts et
al., 1998). Our interpretation of the N. tabacum assay is
consistent with the general findings of that study, but the assay
itself is open to other interpretations because water uptake may have been facilitated by direct transfer of water between the clustered grains. In addition, the direction of chemical gradients of charged or
polar molecules in oil are not clearly defined if grains are clustered.
The Directional Supply of Water Is the Most Likely Guidance Cue
The directional growth of N. alata pollen tubes in our
assay was not a response to touch because there were no directional surfaces in the culture system; nor was it a response to gravity, because it was always at right angles to the major axis of pollen tube
growth or to light, which was not required for the response (Table I).
The elimination of touch, gravity, and light as cues implies that the
cue is a chemical one. The putative chemical cue is not a
style-specific molecule, because pollen tubes surrounded by olive oil
grew toward the aqueous medium, which was chemically defined. When the
supply of water and nutrients provided by the aqueous medium was not
directional, as in emulsions, growth was also not directional (Fig.
2I).
Chemical gradients, even those operating over the short distances (up
to 60 µm or about 1.5 pollen grain diameters) reported here, are
problematic as guidance cues. The rapidity of diffusion in liquids
means that, for the gradient to be maintained, there must be both a
continuously active source and a continuously active sink for the
guidance molecule. Pollen grains are active sources of
CO2 and sinks for O2.
CO2 is more soluble in organic solvents, including oil, by a factor of 2 to 3 (Stephen and Stephen, 1963; Meyer
and Canny, 1975). O2 is about 10 times more
soluble in hydrocarbons than in water (Battino et al., 1983). Thus,
gradients in the concentration of these gases in the oil surrounding
pollen grains will be the same in all directions. Conversely,
directional chemical gradients in the exudate (or oil) will be formed
by charged or polar molecules for which the aqueous medium (or stigma)
is the source and the pollen grains are the sinks. Such molecules
include Ca2+ and sugars, both of which have been
proposed as external cues for pollen tube guidance (Reger et al., 1992;
Mascarenhas, 1993). However, cultured pollen tubes grew preferentially
toward aqueous solutions that contained neither
Ca2+ nor added sugars (Table I). Directional
growth persisted when the aqueous medium was a solution of PEG in
water, suggesting that a gradient within the oil in water or PEG was
the cue.
The question of which molecule, water or PEG, was effective in guiding
pollen tubes is difficult to resolve. In an ideal system, the response
to a signal of varying strengths would be studied using pollen
competent to respond to that signal. However, varying the availability
of water alters the competence of pollen to respond, and varying the
availability of PEG may also affect competence. Thus, in the absence of
water or in the presence of pure water, N. alata pollen
grains do not germinate. The addition of PEG to media for growing
pollen tubes increases germination frequency and results in
faster-growing tubes with morphologies more like those of tubes growing
in styles (Jahnen et al., 1989; Read et al., 1993).
The reasons for the growth-promotory effects of PEG are not known but
do not appear to be related to its effect on the osmotic potential of
the growth medium (Jahnen et al., 1989). PEG may be a substitute for a
compound(s) normally supplied by the style. When PEG was omitted from
the aqueous medium, pollen tubes grew toward the interface with reduced
fidelity (Table I). We interpret this reduction in fidelity as the
consequence of a reduction in the competence of pollen tubes to respond
to water as a signal. The probability that water was the guidance cue
is supported by the presence of a gradient in the availability of water
to pollen within the oil phase, as shown by the more rapid hydration of grains close to the interface (Fig. 3). Furthermore, pollen tubes on
stigmas grew toward a water-saturated atmosphere (Fig. 4, G and H). The
directional growth of pollen tubes into stigmas of other species is
also disrupted in very humid atmospheres (Knox, 1984; Preuss et al.,
1993; Dickinson and Elleman, 1994).
The timing of N. alata germination on the stigma was similar
to that of pollen in culture, thus enabling a reconstruction of events
on the stigma to be drawn. The flux of water into the first grains to
germinate (after 30 min) on the stigma must, by analogy with grains in
culture, be approximately 500 fL s1. These
rapid germinants will be in direct contact with the stigma's sources
of water, the walls of the papilla cells and the fluid in intercellular
spaces. The germination of most grains, however, is delayed until
several hours after pollination, suggesting that fluxes of 1 to 2 fL
s1 are probably more typical on the stigma and
that most grains are surrounded by exudate. The exudate thus acts as a
throttle that reduces the rate of water uptake. Restricting the rate of water uptake by N. alata pollen does not appear to be of
importance in itself, because there is no evidence that pollen that
imbibed rapidly was functionally impaired either in vivo or in vitro. The biological significance of the low permeability of the exudate probably lies in the creation of an environment in which the supply of
water is directional, thus establishing a cue for the guidance of
hydrotropic pollen tubes toward the stigma, and in reducing water loss
from the stigma and hydrating pollen (Konar and Linskens, 1966b).
Although it has long been proposed that roots are hydrotropic, some
apparently hydrotropic responses of roots are in fact due to greater
root proliferation in moist regions of soils; others may be due to
altered responses to gravity or other cues in roots growing in dry
soils (Leopold and LaFavre, 1989; Coutts and Nicoll, 1993; Takano et
al., 1995). In addition, the water gradients required for hydrotropic
responses may be rare in soils (Coutts and Nicoll, 1993). Little is
known about the mechanism of root hydrotropism (Takano et al., 1997).
The directional growth of pollen tubes toward aqueous media results
from the initial selection of the germinal pore for pollen tube
emergence and from continuing minor adjustments to the axis of polarity
of the growing tip (Fig. 2). The setting of and the subsequent
adjustment to the axis of polarity can be explained by turgor-driven
expansion of the cell wall of pollen tubes if the wall is weaker at
higher water contents. Turgor pressure within the pollen grain could
thus direct tube emergence from the pore closest to the source of water
by overcoming the mechanical resistance of the wall at its most
hydrated part. Growth of the tube would also be directed to the most
hydrated parts. Stretching of the wall could result in the activation
of channels in the underlying membrane (e.g. Ca2+
channels; Hepler, 1997), thus realigning the vesicle delivery system at
the tip and reinforcing the directional response. Other explanations
include the possibilities that vesicle docking at the plasma membrane
is facilitated in the more hydrated parts of the membrane and that the
vesicle delivery system is aligned as a result of a signal cascade
initiated by differential hydration of wall or membrane components.
The Role of Lipids in Pollen Hydration
It has been suggested that the effects of lipids on pollen
hydration and tube growth in species with dry stigmas are due to lipid
or lipid fragments acting as signals for hydration or penetration (Preuss et al., 1993; Pruitt, 1997). The only oils known to be functional replacements for the exudate of solanaceous plants are also
lipids (Wolters-Arts et al., 1998). Our finding that pollen of N. alata germinated when entirely surrounded by lipid (exudate or
olive oil) but not when surrounded by mineral oil is also consistent
with a specific role for lipids in germination. However, a simpler
hypothesis is that the effects of lipids on pollen germination and tube
growth are due to their physicochemical properties.
The failure of pollen surrounded by mineral oil to hydrate fully (Fig.
3) can be accounted for physicochemically if mineral oil has a lower
permeability to water, as was suggested by the greater effectiveness of
mineral oil than olive oil in reducing evaporation from an underlying
water layer. Pollen grains at the interface of mineral oil and the
aqueous medium hydrated fully, and these grains germinated to produce
tubes that grew directly into the aqueous medium, as would be expected
of pollen exposed to a very steep water gradient. The failure of other
nonlipid oils to act as substitutes for the exudate (Wolters-Arts et
al., 1998) may have been due to the physicochemical properties of these oils or to their toxicity to pollen. Pollen in vitro is notoriously sensitive to both organic and inorganic additives and rarely behaves as
a perfect osmometer. The sensitivity of pollen precludes many potentially interesting experiments.
The ability of the stigma to support pollen hydration, germination, and
tissue penetration by pollen tubes is unique in wild-type plants and in
the Solanaceae is associated with the presence of a liquid, lipid
exudate on the surface. The exudate has multiple roles in water
management. The present work shows that it must be sufficiently
permeable to water to establish hydraulic continuity between stigma and
pollen so that pollen hydrates but not so permeable that the supply of
water or a functional equivalent of PEG becomes nondirectional.
Guidance toward the stigma by a water gradient may be the first step in
a multistage process of guidance to the ovules.
| |
FOOTNOTES |
1
This work was supported by a special research
grant from the Australian Research Council to the Plant Cell
Biology Research Centre.
*
Corresponding author; e-mail w.lush{at}botany.unimelb.edu.au; fax
61-3-9347-1071.
Received March 30, 1998;
accepted July 17, 1998.
| |
ACKNOWLEDGMENTS |
We thank A. Clarke, P. Gerola, J. Golz, M. Herrero, C. Land, B. McGinness, C. Schultz, T. Schultz, and T. Spurck for their contributions to this work.
| |
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Abstract
Introduction
