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Plant Physiol. (1998) 116: 329-335
Regulation of Leaf Senescence by Cytokinin, Sugars, and
Light
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ABSTRACT |
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Top
Abstract
Introduction
Methods
Results
Discussion
References
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The aim of this study was to investigate the interactions between cytokinin, sugar repression, and light in the senescence-related decline in photosynthetic enzymes of leaves. In transgenic tobacco (Nicotiana tabacum) plants that induce the production of cytokinin in senescing tissue, the age-dependent decline in NADH-dependent hydroxypyruvate reductase (HPR), ribulose-1,5-bisphosphate carboxylase/oxygenase, and other enzymes involved in photosynthetic metabolism was delayed but not prevented. Glucose (Glc) and fructose contents increased with leaf age in wild-type tobacco and, to a greater extent, in transgenic tobacco. To study whether sugar accumulation in senescing leaves can counteract the effect of cytokinin on senescence, discs of wild-type leaves were incubated with Glc and cytokinin solutions. The photorespiratory enzyme HPR declined rapidly in the presence of 20 mm Glc, especially at very low photon flux density. Although HPR protein was increased in the presence of cytokinin, cytokinin did not prevent the Glc-dependent decline. Illumination at moderate photon flux density resulted in the rapid synthesis of HPR and partially prevented the negative effect of Glc. Similar results were obtained for the photosynthetic enzyme ribulose-1,5-bisphosphate carboxylase/oxygenase. It is concluded that sugars, cytokinin, and light interact during senescence by influencing the decline in proteins involved in photosynthetic metabolism.
During the process of leaf senescence, chlorophyll and
photosynthetic proteins are degraded (Humbeck et al., 1996 Whereas the plant growth regulators ABA and ethylene accelerate the
symptoms of senescence (Smart, 1994 Low light intensities or darkness results in the reduced expression of
light-dependent genes and the disappearance of photosynthetic proteins
and chlorophyll (Thomas, 1978 In nonsenescent leaves sugar accumulation can lead to a decline in
chlorophyll and photosynthetic proteins (Stitt et al., 1990 In this paper we have studied the interactions of cytokinins, light,
and sugars during senescence in transgenic tobacco (Nicotiana tabacum L.) plants with autoregulated synthesis of cytokinin (Gan and Amasino, 1995 Wild-type tobacco (Nicotiana tabacum L. cv Wisconsin)
and transgenic tobacco homozygous for the chimeric gene
PSAG12-IPT (TTI) (Gan and Amasino,
1995 Gas Exchange
INTRODUCTION
Top
Abstract
Introduction
Methods
Results
Discussion
References
). There are
several factors that can accelerate or delay this breakdown of the
photosynthetic apparatus.
), exogenous application of
cytokinins inhibits the degradation of chlorophyll and photosynthetic proteins (Richmond and Lang, 1957; Badenoch-Jones et al., 1996). Senescence is also delayed in transgenic plants producing cytokinin by
expression of a bacterial gene encoding IPT, the enzyme catalyzing the
first step of cytokinin synthesis (Smart et al., 1991; Gan and Amasino,
1995).
). Since phytochrome acts as the light
receptor for the expression of many photosynthetic genes, a lower
red/far-red ratio reaching the lower leaves of a plant can also
accelerate the senescence of these leaves (Rousscaux et al., 1996).
; von
Schaewen et al., 1990; Krapp et al., 1991; Krapp and Stitt, 1994). Glc
and Suc repress the transcription of photosynthetic genes (Sheen,
1990), probably acting via hexokinase as a sugar sensor (Jang and
Sheen, 1994; Jang et al., 1997). The involvement of sugar-mediated
repression of genes in the regulation of natural senescence is less
clear (Feller and Fischer, 1994). The concentration of leaf sugars can
increase during leaf senescence (Crafts-Brandner et al., 1984), and
accumulation of sugars, induced by removal of sinks or phloem
interruption, can both accelerate and delay senescence (e.g.
Crafts-Brandner et al., 1984; Fröhlich and Feller, 1991). The
response of leaves to the accumulation of sugars must therefore also
depend on other factors, such as the C:N status of the leaf (Paul and
Driscoll, 1997), light (Dijkwel et al., 1997) and plant growth
regulators (Koch, 1996). For example, it has been suggested that
cytokinin, in addition to delaying senescence, could block some of the
responses to sugars (Jang et al., 1997).
). The transgenic tobacco plants express the gene for
IPT under control of the senescence-specific SAG 12 promoter (Lohman et
al., 1994). This promoter is activated at the onset of senescence,
leading to the synthesis of cytokinin. Because of the inhibition of
senescence by cytokinin, the promoter is actively attenuated. This
results in an autoregulatory loop, preventing the overproduction of
cytokinin and confining expression solely to those tissues that have
initiated senescence. Apart from a delay in senescence, these plants
therefore develop normally (Gan and Amasino, 1995). To obtain more
detailed information on how sugars and cytokinin interact, we incubated
leaf discs of wild-type tobacco with Glc and cytokinin solutions. We
focused on the effect on NADH-dependent HPR, an enzyme of the
photorespiratory C cycle that catalyzes the reduction of
hydroxypyruvate to glycerate. Because recycling of C in the
photorespiratory cycle is essential for photosynthetic metabolism,
photosynthesis depends on the activity of HPR (Murray et al., 1989). In
cotyledons of curcurbits the synthesis of HPR is induced by cytokinin
(Chen and Leisner, 1985; Andersen et al., 1996) and light (Bertoni and
Becker, 1993), and the activity of HPR decreases during senescence (De
Bellis and Nishimura, 1991). In this study we show that HPR protein
declines during incubation with Glc and provide evidence that this
decline is modulated by cytokinin and light.
MATERIALS AND METHODS
Top
Abstract
Introduction
Methods
Results
Discussion
References
) were grown in high-nutrient compost (M3; Fisons, Ipswich, UK) in
a greenhouse in natural daylight supplemented with tungsten/halogen
lamps (200 µmol m
2 s1
PFD). The plants were fertilized weekly with a Hoagland solution containing 12 mm nitrate. All experiments were carried out
on leaves taken from plants that had initiated flowering.
2
s1, and leaf temperature was maintained at
25 ± 0.5°C.
Incubation of Leaf Discs
Leaf discs were floated in Petri dishes on solutions containing Glc, sorbitol, iPR, or combinations thereof. All solutions were adjusted to pH 7.0. The Petri dishes were kept in controlled conditions at 23°C and cycles of 16 h of light (20 or 250 µmol m2 s1) and 8 h of
darkness.
Quantification of Protein and Chlorophyll
Protein was extracted in 50 mm Hepes-KOH (pH 7.4), 5 mm MgCl2, 1 mm EDTA, 1 mm EGTA, 10% (v/v) glycerol, 0.1% (v/v) Triton X-100, and 5 mm DTT, and determined with the Bio-Rad protein assay, according to Bradford (1976). Chlorophyll was extracted in 80% acetone
and quantified according to Lichtenthaler and Wellburn (1983).
Quantification of Sugars
Samples for sugar determinations were harvested in the morning, between 3 and 4 h into the photoperiod. Sugars were extracted in 80% ethanol and determined enzymatically as described by Scholes et al. (1994).
Western Blotting
Proteins were extracted in 200 mm Bicine-KOH (pH 9.0), 4.5 mm DTT, and 1% (w/v) SDS. Extracts were boiled for 90 s with equal volumes of solubilization buffer (62.5 mm Tris, 20% [v/v] glycerol, 2.5% [w/v] SDS, and 5% [v/v] 2-mercaptoethanol, pH 6.8). For SDS-PAGE, equal leaf areas (3.3 mm2) were loaded and separated onto gels containing 10% acrylamide. Proteins were transferred onto a PVDF membrane (Immobilon-P, Millipore) and probed with antisera raised to NADH-dependent HPR of spinach (Spinacia oleracea L.) (Kleczkowski et al., 1990), Rubisco of pea (Pisum
sativum L.), plastidic Fru-1,6-bisphosphatase of spinach, NADP-dependent glyceraldehyde-3-phosphate dehydrogenase of spinach, NADP-dependent malate-dehydrogenase of pea, and aldolase. A
peroxidase-conjugated secondary antibody was used, and immunoreactive
bands were visualized with an enhanced chemoluminescence kit
(Amersham). For quantification of proteins, the peak volumes of bands
were determined by video imaging.
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RESULTS |
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Top
Abstract
Introduction
Methods
Results
Discussion
References
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Effects of Endogenous Production of Cytokinin on the Senescence-Related Decline in Enzymes Involved in Photosynthetic Metabolism
The effect of cytokinin on the senescence-related decline in photosynthetic enzymes was studied with transgenic tobacco (TTI) expressing a bacterial gene encoding IPT under control of the senescence-specific SAG12 promoter (Gan and Amasino, 1995). As reported
previously, the transgenic plants developed normally until the early
stages of flowering; at this point the wild-type plants showed
senescence-related yellowing of the lower leaves, whereas these leaves
remained largely green in the transgenic plants. These differences were
reflected in chlorophyll and protein contents. In the wild type,
chlorophyll and protein decreased strongly as the leaves aged (Table
I). In transgenic tobacco plants this
decrease was delayed considerably, although chlorophyll and protein
still declined in older leaves. Rates of photosynthetic CO2 assimilation were similar in young leaves of
the wild type and of the transgenic tobacco plants (Fig.
1). In mature leaves (leaves four to
eight from the bottom), however, the transgenic tobacco plants
maintained considerably higher rates of photosynthesis than the wild
type.
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Effects of Exogenous Supply of Cytokinin and Glc on HPR
Inhibition of the Decline in HPR and Other Enzymes by Autoregulated
Production of Cytokinin
Involvement of Cytokinin, Sugar Repression, and Light in the
Regulation of HPR
Interaction of Cytokinin, Sugar Repression, and Light with
Senescence
Received July 25, 1997;
accepted October 13, 1997.
Abbreviations:
HPR, hydroxypyruvate reductase.
iPR, N6-[ We are grateful to R.M. Amasino (University of Wisconsin,
Madison) for providing the transgenic tobacco and to the laboratory of
R. Scheibe (University of Osnabrück) and U. Sonnewald (IPK, Gatersleben, Germany) for providing antisera. We would also like to
thank B.C. Jarvis (University of Sheffield) for advice on the application of cytokinins.
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View larger version (50K):
[in a new window]
Figure 2.
A, Western blots for NADH-dependent HPR, the large
subunit of Rubisco, plastidic Fru-1,6-bisphosphatase, plastidic
aldolase, NADP-dependent glyceraldehyde-3-phosphate dehydrogenase, and
NADP-dependent malate dehydrogenase in leaves of different age from
wild-type tobacco plants (WT) and tobacco plants with autoregulated
production of cytokinin (TTI). B, Relative content of HPR and Rubisco
as determined from western blots. Data are means ± se of
three samples.
View larger version (22K):
[in a new window]
Figure 3.
Sugar contents in leaves of different age from
wild-type tobacco (WT, 
) and tobacco with autoregulated production
of cytokinin (TTI, 
). Data are means ± se of three
samples.
2
s1). At this PFD, sugar repression by
internally accumulating sugars that could occur at higher PFDs can be
prevented (Krapp et al., 1991). Complete darkness, on the other hand,
would have caused starvation of the tissue. After 10 d of
incubation with 50 mm Glc, discs from mature and senescing
leaves showed a strong loss of chlorophyll (Table
II), whereas discs from young leaves were affected to a lesser extent. Incubation with sorbitol as a control did
not result in significantly decreased chlorophyll contents in discs
from young and mature leaves. However, sorbitol did induce the death of
discs from senescing leaves. All further experiments were performed
with mature (fully expanded) leaves.
View this table:
Table II.
Contents of chlorophyll in leaf discs from
wild-type leaves of different age
The discs were incubated for 10 d at very low PFD (20 µmol
m 2 s1) with water, 50 mm Glc,
or 50 mm sorbitol. Data are means ± se of
three to four samples. The relative contents compared with the water
controls are given in parentheses.
7 and
105 m, but decreased when the
concentration was as high as 104 m.
Despite the positive effect of iPR on HPR protein, iPR did not prevent
the Glc-dependent (20 or 50 mm Glc) decline in HPR. Similar
results were obtained with the cytokinins
N6-[
2]isopentenyladenine
and zeatin riboside (data not shown). Although cytokinin clearly did
not affect the final content of HPR in the presence of Glc, we tested
whether it may have altered the time course of the Glc-dependent
decrease. Leaf discs were harvested over a period of 10 d. In the
very low PFD necessary for this experiment, the content of HPR protein
decreased even in the absence of Glc (Fig.
5); however, incubation with 50 mm Glc clearly accelerated the drop in HPR, which occurred
before a visible loss of chlorophyll. In the absence of Glc, iPR
delayed the decline in HPR and even caused a slight increase in HPR
between d 2 and 4, but it did not delay the Glc-dependent drop in HPR.
View larger version (34K):
[in a new window]
Figure 4.
Relative content of NADH-dependent HPR in leaf
discs of wild-type tobacco plants after incubation for 10 d at
very low PFD (20 µmol m 2 s1) with
different concentrations of Glc and iPR.
View larger version (23K):
[in a new window]
Figure 5.
Time course of the relative content of
NADH-dependent HPR in leaf discs of wild-type tobacco plants after
incubation at very low PFD (20 µmol m 2
s1) ± 50 mm Glc and ± 30 µm
iPR. Data are means ± se of three samples. 
,
H2O; , iPR; 
, Glc; and 
, Glc plus iPR.
). Therefore, we also employed a higher PFD to
test whether sugar repression of HPR also occurs when the gene is
induced by light. In moderate PFD, approximately the PFD at which the
plants were grown (250 µmol m2
s1), HPR declined in water or in Glc solution.
iPR prevented this loss of HPR when it was included in water, but not
when Glc was present (Fig. 6A). All four
treatments led to a visible loss of chlorophyll (data not shown) and
the accumulation of sugars (Fig. 6B). Compared with d 0, the Glc
content rose 78-fold during 6 d in water. After incubation with
Glc all sugar contents were approximately twice as high as after
incubation without Glc. Apart from a slightly lower Suc content, the
presence of iPR had no effect on the accumulation of sugars. To
determine if the reduction in HPR in water was due to sugar
accumulation or general aging of the tissue, leaf discs were
transferred for 2 d into continuous, moderate light, after they
had been incubated for 6 d in the low-light conditions described
earlier. In this experiment the transfer into a higher PFD resulted in
a rapid accumulation of HPR in the absence of Glc (Fig.
7, A and B). This indicates that the leaf discs were still capable of de novo protein synthesis after 6 d of
incubation, and that the decline in HPR observed in water (Fig. 6) was
not due to aging of the tissue but to accumulation of sugars. Even in
the presence of Glc, HPR increased slightly (1.5-fold) after the
transfer into moderate PFD, whereas longer incubation in low light led
to a further decline in HPR. The large subunit of Rubisco showed a
similar response to HPR (Fig. 7A). In both low and moderate PFD, iPR
had a positive effect on the content of Rubisco protein in the absence
of Glc, but incubation with Glc resulted in a decline in Rubisco that
was not prevented by iPR.
View larger version (30K):
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Figure 6.
A, Relative content of NADH-dependent HPR in leaf
discs of wild-type tobacco plants at d 0 and after incubation for
6 d at moderate PFD (250 µmol m 2 s1) ± 50 mm Glc and ± 30 µm iPR. B, Sugar
contents in the leaf discs. Data are means ± se of three
samples.
View larger version (31K):
[in a new window]
Figure 7.
Contents of NADH-dependent HPR and the large
subunit of Rubisco in leaf discs of wild-type tobacco plants after
transfer from very low PFD (20 µmol m 2
s1) into moderate PFD (250 µmol m2
s1). A, Western blots for discs incubated for 6 d at
very low PFD (LL) or for 6 d at very low PFD plus 2 d at
continuous, moderate PFD (ML) ± 50 mm Glc and ± 30 µm iPR. B, Relative content of HPR as determined from
western blots after incubation for 6 d at very low PFD () for
8 d at very low PFD (), and for 6 d at very low PFD plus
2 d in continuous moderate PFD (). Data are means ± se of three samples.
DISCUSSION
Top
Abstract
Introduction
Methods
Results
Discussion
References
). The basis for the
maintained photosynthetic activity in old leaves (Fig. 1) is the
delayed decline in chlorophyll and in enzymes involved in
photosynthetic metabolism (Fig. 2). The production of cytokinin in
these leaves could directly influence the amount of the enzymes by a
variety of mechanisms that influence the rate of protein synthesis or
degradation. It has, for example, been demonstrated that cytokinin
treatment can increase the activities of Rubisco, Fru-1,6-bisphosphatase, NADP-dependent glyceraldehyde-3-phosphate dehydrogenase, NADP-dependent malate dehydrogenase (Harvey et al.,
1974; Feierabend and de Boer, 1978), and HPR (Chen and Leisner, 1985).
Although cytokinin accumulates in old leaves of TTI (W. Jordi, personal
communication), the senescence-related decline in these proteins could
not be prevented completely by the autoregulated production of
cytokinin. This could be due to the fact that cytokinin is only
produced in TTI when the process of senescence has already started, or
to the fact that other factors in addition to cytokinin regulate
senescence. For example, the high hexose contents in the old leaves of
TTI (Fig. 3) could have counteracted the effect of cytokinin by
repressing the genes for photosynthetic enzymes, such as Rubisco,
Fru-1,6-bisphosphatase, and NADP-dependent glyceraldehyde-3-phosphate dehydrogenase (Stitt et al., 1990; Krapp et al., 1991).
), it was important
to investigate if sugars could also repress light induction, as shown
for genes encoding plastocyanin and chlorophyll
a/b-binding protein (Dijkwel et al., 1997). In our
experiments we observed that the light-induced increase in HPR was
lower in the presence than in the absence of Glc (Fig. 7), and that the
accumulation of endogenous sugars in moderate light resulted in a
decrease in HPR protein (Fig. 6).
). In very low light Glc clearly counteracted the positive
effect of cytokinin on HPR. However, when the PFD was increased,
cytokinin could prevent the decline in HPR observed in water controls.
This decline was probably brought about by the internal accumulation of
sugars that occurred in high-light conditions (Fig. 6B). Only when the
sugar contents increased drastically in the presence of exogenously
supplied sugars did cytokinin have no effect.
View larger version (12K):
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Figure 8.
Interaction of cytokinin, sugar repression, and
light in the regulation of senescence. 
, Inhibition of senescence;
, acceleration of
senescence; 
, block of the
effect of cytokinin; and 
,
partial block of the effect of sugars.
*
Corresponding author; e-mail a.wingler{at}sheffield.ac.uk; fax
44-114-2760159.
FOOTNOTES
ABBREVIATIONS
2-isopentenyl]adenosine.
IPT, isopentenyl transferase.
PFD, photon flux density.
ACKNOWLEDGMENTS
LITERATURE CITED
Top
Abstract
Introduction
Methods
Results
Discussion
References
Copyright Clearance Center: 0032-0889/98/116/0329/07
© 1998 American Society of Plant Physiologists
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F. Calenge, V. Saliba-Colombani, S. Mahieu, O. Loudet, F. Daniel-Vedele, and A. Krapp Natural Variation for Carbohydrate Content in Arabidopsis. Interaction with Complex Traits Dissected by Quantitative Genetics Plant Physiology, August 1, 2006; 141(4): 1630 - 1643. [Abstract] [Full Text] [PDF]
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A. Wingler, S. Purdy, J. A. MacLean, and N. Pourtau The role of sugars in integrating environmental signals during the regulation of leaf senescence J. Exp. Bot., January 1, 2006; 57(2): 391 - 399. [Abstract] [Full Text] [PDF]
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A. Wingler, E. Brownhill, and N. Pourtau Mechanisms of the light-dependent induction of cell death in tobacco plants with delayed senescence J. Exp. Bot., November 1, 2005; 56(421): 2897 - 2905. [Abstract] [Full Text] [PDF]
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C. Diaz, S. Purdy, A. Christ, J.-F. Morot-Gaudry, A. Wingler, and C. Masclaux-Daubresse Characterization of Markers to Determine the Extent and Variability of Leaf Senescence in Arabidopsis. A Metabolic Profiling Approach Plant Physiology, June 1, 2005; 138(2): 898 - 908. [Abstract] [Full Text] [PDF]
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L. N. Huynh, T. VanToai, J. Streeter, and G. Banowetz Regulation of flooding tolerance of SAG12:ipt Arabidopsis plants by cytokinin J. Exp. Bot., May 1, 2005; 56(415): 1397 - 1407. [Abstract] [Full Text] [PDF]
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 I. TERASHIMA, T. ARAYA, S.-I. MIYAZAWA, K. SONE, and S. YANO Construction and Maintenance of the Optimal Photosynthetic Systems of the Leaf, Herbaceous Plant and Tree: an Eco-developmental Treatise Ann. Bot., February 1, 2005; 95(3): 507 - 519. [Abstract] [Full Text] [PDF]
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U. DRUEGE, S. ZERCHE, and R. KADNER Nitrogen- and Storage-affected Carbohydrate Partitioning in High-light-adapted Pelargonium Cuttings in Relation to Survival and Adventitious Root Formation under Low Light Ann. Bot., December 1, 2004; 94(6): 831 - 842. [Abstract] [Full Text] [PDF]
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 M. E. Balibrea Lara, M.-C. Gonzalez Garcia, T. Fatima, R. Ehness, T. K. Lee, R. Proels, W. Tanner, and T. Roitsch Extracellular Invertase Is an Essential Component of Cytokinin-Mediated Delay of Senescence PLANT CELL, May 1, 2004; 16(5): 1276 - 1287. [Abstract] [Full Text] [PDF]
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H. Chang, M. L. Jones, G. M. Banowetz, and D. G. Clark Overproduction of Cytokinins in Petunia Flowers Transformed with PSAG12-IPT Delays Corolla Senescence and Decreases Sensitivity to Ethylene Plant Physiology, August 1, 2003; 132(4): 2174 - 2183. [Abstract] [Full Text] [PDF]
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M. J. Paul and T. K. Pellny Carbon metabolite feedback regulation of leaf photosynthesis and development J. Exp. Bot., January 3, 2003; 54(382): 539 - 547. [Abstract] [Full Text] [PDF]
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B. Salopek-Sondi, M. Kovac, T. Prebeg, and V. Magnus Developing fruit direct post-floral morphogenesis in Helleborus niger L. J. Exp. Bot., September 1, 2002; 53(376): 1949 - 1957. [Abstract] [Full Text] [PDF]
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 R. F. Sage How Terrestrial Organisms Sense, Signal, and Respond to Carbon Dioxide Integr. Comp. Biol., July 1, 2002; 42(3): 469 - 480. [Abstract] [Full Text] [PDF]
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F. Rolland, B. Moore, and J. Sheen Sugar Sensing and Signaling in Plants PLANT CELL, May 1, 2002; 14(90001): S185 - 205. [Full Text] [PDF]
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M. S. McCabe, L. C. Garratt, F. Schepers, W. J.R.M. Jordi, G. M. Stoopen, E. Davelaar, J. H. A. van Rhijn, J. B. Power, and M. R. Davey Effects of PSAG12-IPT Gene Expression on Development and Senescence in Transgenic Lettuce Plant Physiology, October 1, 2001; 127(2): 505 - 516. [Abstract] [Full Text] [PDF]
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M. J. Paul and C. H. Foyer Sink regulation of photosynthesis J. Exp. Bot., July 1, 2001; 52(360): 1383 - 1400. [Abstract] [Full Text] [PDF]
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 K. Yamaguchi and M. Nishimura Reduction to below Threshold Levels of Glycolate Oxidase Activities in Transgenic Tobacco Enhances Photoinhibition during Irradiation Plant Cell Physiol., December 1, 2000; 41(12): 1397 - 1406. [Abstract] [Full Text] [PDF]
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J. W.H. Yong, S. C. Wong, D. S. Letham, C. H. Hocart, and G. D. Farquhar Effects of Elevated [CO2] and Nitrogen Nutrition on Cytokinins in the Xylem Sap and Leaves of Cotton Plant Physiology, October 1, 2000; 124(2): 767 - 780. [Abstract] [Full Text]
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A. Wingler, T. Fritzius, A. Wiemken, T. Boller, and R. A. Aeschbacher Trehalose Induces the ADP-Glucose Pyrophosphorylase Gene, ApL3, and Starch Synthesis in Arabidopsis Plant Physiology, September 1, 2000; 124(1): 105 - 114. [Abstract] [Full Text]
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Z.-H. Chen, R. P. Walker, R. M. Acheson, L. I. Tecsi, A. Wingler, P. J. Lea, and R. C. Leegood Are Isocitrate Lyase and Phosphoenolpyruvate Carboxykinase Involved in Gluconeogenesis during Senescence of Barley Leaves and Cucumber Cotyledons? Plant Cell Physiol., August 1, 2000; 41(8): 960 - 967. [Abstract] [Full Text] [PDF]
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N. Dai, A. Schaffer, M. Petreikov, Y. Shahak, Y. Giller, K. Ratner, A. Levine, and D. Granot Overexpression of Arabidopsis Hexokinase in Tomato Plants Inhibits Growth, Reduces Photosynthesis, and Induces Rapid Senescence PLANT CELL, July 1, 1999; 11(7): 1253 - 1266. [Abstract] [Full Text]
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E. H. Murchie, Y.-z. Chen, S. Hubbart, S. Peng, and P. Horton Interactions between Senescence and Leaf Orientation Determine in Situ Patterns of Photosynthesis and Photoinhibition in Field-Grown Rice Plant Physiology, February 1, 1999; 119(2): 553 - 564. [Abstract] [Full Text]
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