Plant Physiol. (1999) 119: 17-20
Transgenically Enhanced Sorbitol Synthesis Facilitates Phloem
Boron Transport and Increases Tolerance of Tobacco to Boron
Deficiency1
Patrick H. Brown*,
Nacer Bellaloui,
Hening Hu, and
Abhaya Dandekar
Department of Pomology, University of California, Davis, California
95616
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ABSTRACT |
The mobility of elements within
plants contributes to a plant species' tolerance of nutrient
deficiencies in the soil. The genetic manipulation of within-plant
nutrient movement may therefore provide a means to enhance plant growth
under conditions of variable soil nutrient availability. In these
experiments tobacco (Nicotiana tabacum) was engineered
to synthesize sorbitol, and the resultant effect on phloem mobility of
boron (B) was determined. In contrast to wild-type tobacco, transgenic
tobacco plants containing sorbitol exhibit a marked increase in
within-plant B mobility and a resultant increase in plant growth and
yield when grown with limited or interrupted soil B supply. Growth of
transgenic tobacco could be maintained by reutilization of B present in
mature tissues or from B supplied as a foliar application to mature
leaves. In contrast, B present in mature leaves of control tobacco
lines could not be used to provide the B requirements for new plant growth. 10B-labeling experiments verified that B is phloem
mobile in transgenic tobacco but is immobile in control lines. These
results demonstrate that the transgenic enhancement of within-plant
nutrient mobility is a viable approach to improve plant tolerance of
nutrient stress.
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INTRODUCTION |
The inorganic nutrients required for plant growth can be provided
to growing tissues either in the xylem, driven by transpirational water
flow, or in the phloem, associated with the sink-driven movement of
organic solutes from source to sink tissues. The rate of supply of
inorganic nutrients to growing tissues is a primary determinant of
plant growth, and inadequate nutrient supply results in growth
impairment and the development of deficiency symptoms. The relative
contribution of phloem and xylem transport to the supply of nutrient
elements varies from species to species and differs for each element.
N, P, K, S, and Mg are readily transported in either the xylem or the
phloem (phloem-mobile nutrients), whereas Ca, and, in most species, B
have limited mobility and can only be supplied to growing tissues in
the xylem (phloem-immobile nutrients).
The relative mobility of an element within a plant has important
physiological and agricultural implications. Immobile elements present
in mature tissues cannot be retranslocated to supply the needs of
developing tissues and must therefore be available in the soil at all
times. For elements with limited within-plant mobility, the absence of
soil nutrient supply results in rapid inhibition of meristematic growth
(particularly reproductive growth). This is especially critical for
elements required in high amounts in growing tissues, of which B and Ca
are the most relevant examples. The ability of a plant species to
survive or to yield optimally during a period of nutrient stress is
therefore a consequence of both its ability to obtain nutrients from
the soil under limiting conditions and the extent to which the
nutrients can be supplied through redistribution from other plant
tissues.
B plays an important role in the formation of plant cell walls, and, as
a consequence, it is critical for plant growth (Matoh, 1997
).
Historically, B has been considered to have only limited phloem
mobility (Oertli and Richardson, 1970) and the removal of B from the
growth medium frequently results in rapid inhibition of plant growth
(Loomis and Durst, 1992). B deficiency is a widespread agricultural
problem that results in yield and quality loss in many crop species
worldwide (Shorrocks, 1997). Perhaps the most important manifestation
of B deficiency is the reduction in seed set and fruit yields that have
been observed in diverse agricultural regions (Dell and Huang, 1997).
Because B cannot readily be redistributed within the plant in most
species, even a brief disruption of soil nutrient supply results in
growth depression and yield loss, the extent of which is dependent upon
the duration of the deficiency and the stage of plant growth at which
it occurs (Dell and Huang, 1997).
Recently, it has been demonstrated that the mobility of B varies
greatly among species (Brown and Hu, 1996). The biochemical basis of
these species differences and the resulting physiological effects and
agronomic consequences are now well described (Brown and Shelp,
1997). Evidence suggests that the principal factor that confers
phloem B mobility to a plant species is the synthesis of sugar alcohols
and the subsequent transport of the B-sugar alcohol complex in the
phloem to sink tissues (Hu et al., 1997). The capacity to use B present
in mature tissues is now known to enhance species tolerance to
transient B deficiency in the growth medium (Brown and Hu, 1996). To
further demonstrate the critical role of sugar alcohols in B transport
and to determine if the capacity for within-plant B mobility could be
transferred to species in which B is normally immobile, we engineered
tobacco (Nicotiana tabacum) with the gene for sorbitol
production, S6PDH, and determined the resultant effect on sorbitol
production, B mobility, and tolerance of tobacco to B stress.
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MATERIALS AND METHODS |
Plant Growth and Treatment
Three tobacco (Nicotiana tabacum) lines were used: SR1,
wild-type tobacco; A4, tobacco transformed with the antisense gene construct for S6PDH; and S11, the tobacco line transformed with the
sorbitol-synthesizing sense construct (Tao et al., 1995). Lines
A4 and SR1 served as controls; lines A4 and S11 are identical in all
regards except the orientation of the S6PDH coding region with respect
to the cauliflower mosaic virus 35S promoter.
Homozygous seed of each tobacco line were germinated and then grown in
vermiculite for 4 weeks with adequate supply of all nutrients,
including 0.05 µg mL
1 B. At 4 weeks,
plants were transferred to hydroponic solution (one-half-strength
Hoagland solution [Hoagland and Arnon, 1950], minus B) and the
following treatments were imposed: (a) continual supply of 0.05 µg
mL1 B in the rooting medium; (b) 0 µg
mL1 B, received no B in the rooting medium; and
(c) "foliar"-treated plants, received biweekly foliar applications
of B to three mature leaves (described below) with no B supplied in the
root nutrient medium.
At the time of foliar B application, the three mature leaves were
immersed for 10 s in 100 µg mL1 B
solution as 10B-enriched boric acid (99.43%
10B:0.57% 11B) with 0.05%
(v/v) L-77 as surfactant. Care was taken so that contamination of B to
the stem/petiole or drip of the B solution was avoided. The foliar B
application was made three times. B analysis was performed by
inductively coupled plasma MS (Elan 5000, Perkin-Elmer SCIEX, Norwalk,
CT), as previously described (Brown and Hu, 1996). Plant
appearance was closely monitored; 8 weeks after transfer to hydroponic
solutions, plants were harvested, and growth, reproductive performance,
and tissue analysis for various parameters was performed.
There were six replicate plants in each treatment group. Sorbitol
production was determined by GC-MS (Greve and Labavitch, 1993) in
mature leaf discs of all lines, significant sorbitol concentrations
were detected in line S11 (800 ± 100 nmol
g1 fresh weight) but no
detectable sorbitol could be found in either control (SR1) or
antisense lines (A4).
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RESULTS AND DISCUSSION |
Tobacco lines that received continuous adequate B in the rooting
medium (0.05 µg mL1B) showed no sign
of B deficiency at any time during the experiment; no differences in
final dry weight, flower abortion, or seed yield were evident at
harvest among any of the tobacco lines (Table I; Fig. 1).
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Table I.
Flower abortion and plant dry weight at harvest
Three tobacco lines, S11 (sorbitol producing) and SR1 and A4 (control
lines producing no sorbitol), were grown for 28 d with complete
nutrient solution, including adequate B (0.0 µg mL1),
and then transferred to nutrient solutions supplied with 0 µg
mL1 B, no B added to the medium; foliar B, 100 µg
mL1 solutions of 10B (as boric acid with
99.43% 10B:0.57% 11B atomic composition)
applied to three mature leaves at 2-week intervals; or 0.05 µg
mL1 B supplied to the rooting medium. Percentage of
abortion was determined as the number of aborted flowers/total number
of initiated flowers × 100. Percentage of abortion and plant dry
weight were determined 8 weeks after transfer to hydroponic solution.
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| Figure 1.
Seed yield of tobacco lines (S11, SR1, and A4)
grown for 28 d with adequate B and then transferred to 0 µg
mL1 B, 0.05 µg mL1 B supplied to
the roots, or 100 µg mL1 B supplied to three mature
leaves. Seed yield was determined 56 d after transfer to treatment
solutions. Values represent means ± SE of six
replicates.
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In tobacco plants deprived of all B in the medium, the control lines
SR1 and A4 rapidly developed chlorosis, demonstrated enhanced flower
abortion, and, at harvest, exhibited significantly decreased growth and
seed yield compared with plants grown with adequate B (Table I; Figs. 1
and 2). In comparison with plants continually supplied with B in the rooting medium, seed yield in lines
A4 and SR1 were reduced by 90% and 80%, respectively, whereas plant
growth was reduced by 50% in both tobacco lines. Visual symptoms of B
deficiency were first apparent 2 weeks after treatment imposition in
SR1 and A4 lines, but were not evident in the S11 line until 5 weeks
after transfer to treatment solutions. The delayed appearance of B
deficiency symptoms in the S11 line was also reflected in the 20%
greater plant weight, 10% less flower abortion, and a greater than
100% increase in seed yield over either SR1 or A4 lines grown under
the same conditions (Table I; Fig. 1). The first symptom of B
deficiency in tobacco was the development of mild chlorosis in young
leaves, and this was followed by flower abortion and incomplete
expansion of young leaves (Fig. 2).
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| Figure 2.
B deficiency symptoms in the control tobacco line
SR1 (left) and transgenic tobacco (S11), supplied with B as a foliar
application to three mature leaves. Symptoms exhibited in SR1 include
flower bud abortion, deformation, reduced elongation, and chlorosis of
young leaves. The control tobacco line A4 exhibited symptoms similar to
those observed in SR1 (not shown). No symptoms of B deficiency were
observed in growing tissues of transgenic tobacco line S11.
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When B was supplied solely as foliar applications to three mature
leaves, a marked difference in symptom expression, growth, and yield
among the tobacco lines was observed (Table I). Foliar-fed S11 showed
no signs of chlorosis in young, growing tissues, and did not exhibit
enhanced flower abortion at any time during the experiment, whereas
control (SR1 and A4) lines developed marked B deficiency symptoms
within 2 weeks of treatment imposition (Fig. 2). Growth and final seed
yield of foliar-fed A4 and SR1 lines did not differ significantly from
plants receiving 0 µg mL1 B treatment,
illustrating that foliar B supply was ineffective at supplying B for
plant growth in these lines. Growth and seed yield of the foliar-fed
line S11 line, however, was equal to the growth of plants that received
a continuous adequate supply of B, suggesting that foliar B was
effective at supplying the B requirements of this line (Table I; Fig.
1).
Flower abortion was the most pronounced symptom of B deficiency and was
observed in all tobacco lines receiving 0 µg
mL1 B (although it was delayed in S11).
Flower abortion was also prevalent in tobacco lines that do not produce
sorbitol (SR1 and A4) when foliar B was the sole B source provided.
Flower abortion occurred at all stages of flower and pod development,
and there was no clear sensitivity to any particular stage of
development (Fig. 2). A close correlation between the percentages of
flower abortion and final seed yield suggests that flower abortion was the primary determinant of yield. No difference in the total number of
flowers initiated (aborted sites plus flowers and plus pods) among any
of the lines or treatments was observed, suggesting that sufficient
localized B supplies existed to support flower initiation, but not
necessarily continued flower retention (results not shown). Pollen
viability was tested in all lines and treatments. All plants had
similar and adequate levels of pollen germination (>85%, results not
shown).
The delayed appearance of B deficiency in the sorbitol-producing
tobacco line S11, grown without root B supply, and the capacity for the
S11 tobacco line to grow optimally when supplied only with foliar B
suggests that B present in mature S11 leaves is phloem mobile and that
this mobility confers tolerance to B deprivation. To verify that B was
indeed mobile in S11 but not in the SR1 or A4 lines, movement of
foliar-applied 10B was assessed using
isotopically enriched foliar B application. If foliar-applied
10B is mobilized from leaves receiving foliar
10B and transported to supply the B needs of
growing tissues, then the relative abundance of
10B in these tissues should increase above the
natural abundance. In control tobacco (A4 and SR1) lines the
application of foliar B did not alter the
abundance of 10B in young tissues, flowers, or
seeds in comparison with untreated plants. In contrast, foliar
10B application to the S11 line resulted in a
marked increase in B abundance in both young
leaves and seeds (Table II).
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Table II.
Within-plant mobility of foliar-applied
10B
Isotopically enriched boric acid (99.43% 10B:0.57%
11B) was applied to three mature leaves of each tobacco
line. B mobility was determined as a percentage of 10B atom
excess (ratio of 10B/11B in treatment minus
ratio of 10B/11B in control × 100).
Experimental details are as described in Table I.
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The greater 10B atom percentage enrichment in the
seeds of line S11 compared with the young leaves of S11 demonstrates
that the seeds received a greater proportion of their B requirement from the foliar treatment than did the leaves. This is probably a
consequence of the later development of the seeds, which did not occur
until much of the B originally present in the plant had been depleted.
As the level of retranslocatable B declines in tobacco tissues, the
dependence on foliar 10B supply increases,
resulting in proportionally greater 10B
enrichment in the seeds.
These results clearly demonstrate that the introduction of the gene for
sorbitol production confers B mobility to tobacco. These results, in
combination with previous evidence of B mobility in
sugar-alcohol-producing species and the isolation of the B-sorbitol complexes from the phloem sap of peach, conclusively prove that sorbitol facilitates B mobility in higher plants (Brown and Hu, 1996).
The genetically enhanced B mobility in transgenic tobacco demonstrated
here clearly facilitated the maintenance of plant growth in the absence
of B in the rooting medium. Apparently, the metabolic disruption
imposed by the production of sorbitol in transgenic tobacco was
insufficient to negatively affect plant performance. This is in
contrast to recent reports suggesting that higher levels of mannitol
production in tobacco can result in significant negative effects on
plant growth and development (Sheveleva et al., 1997). The level
of sorbitol produced in these current experiments is significantly
lower than those reported elsewhere, suggesting that maintaining a low
level of gene expression is critically important to ensure optimal B
mobility while avoiding disruptive changes to cellular
metabolism.
This research has practical relevance to production agriculture and to
understanding the role of B in plant growth and reproduction. Here we
have demonstrated the critical importance of B for reproduction in
plants (Dell and Huang, 1997) and illustrated how a temporary reduction
in soil B availability can have profound effects on yield, particularly
when the deficiency occurs during flowering. This is in agreement with
previous research in many agricultural regions of temperate and
subtropical Asia, where reproductive B deficiency is recognized as a
primary cause of seed set failure in wheat, rice, and canola (Dell and
Huang, 1997; Rerkasem and Jamjod, 1997).
This reproductive failure is most prevalent during times of drought,
cool temperatures, and high humidity that often occur at the time of
flowering, and is probably the result of interrupted B supply from the
soil to the developing reproductive tissues. Because B is immobile in
these species, B present in mature leaves is not available to support
reproductive growth, and soil fertilizer applications are ineffective.
In these species the introduction of the gene for sorbitol production
would provide the ability to use the B present in mature tissues and
may be sufficient to overcome short-term B deficiencies and prevent
yield loss. Fertilization strategies would also be markedly simplified,
because B fertilization early in plant development could provide the B
requirements at flowering. The results presented here for tobacco
clearly suggest that this is feasible.
It is provocative that the introduction of the single gene for sorbitol
production is sufficient to facilitate not only the production of
sorbitol but also its phloem loading, transport, and the utilization of
the transported B by reproductive tissues. The mechanism by which the
B-sorbitol complex is transported is unknown. These results imply,
however, that tobacco has retained an evolutionary capacity to
transport and metabolize sorbitol, that transmembrane B-sorbitol
transport occurs by purely passive mechanisms, or that there is a
symplastic pathway from mature leaf cells to the phloem that allows for
the movement of the B-sorbitol complex without the requirement for
transmembrane passage. Each of these suggestions has intriguing
physiological and evolutionary implications.
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CONCLUSION |
Plant tolerance of nutrient deficiencies is an active area of
research that has largely focused on identifying the molecular mechanisms involved in obtaining nutrients from nutrient-poor soils.
Although identifying the mechanisms of nutrient uptake is clearly
essential to our understanding of plant physiology, the role of
within-plant nutrient mobility in plant tolerance to nutrient
deficiencies has received scant attention. The results presented here
address this subject and represent a novel approach to enhancing plant
tolerance to B deficiency. This approach may be applicable to a wide
range of elements with limited within-plant mobility.
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FOOTNOTES |
1
This work was supported by the U.S. Department
of Agriculture (grant no. CSRS 9801010).
*
Corresponding author; e-mail phbrown{at}ucdavis.edu; fax
1-530-752-8502.
Received August 10, 1998;
accepted September 8, 1998.
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ABBREVIATIONS |
Abbreviation:
S6PDH, sorbitol-6-phosphate dehydrogenase.
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ACKNOWLEDGMENTS |
We thank Meiru Wu, Agnes Nyomora, and Sandy Uratsu for their
assistance.
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