|
Plant Physiol. (1998) 116: 715-723
Effects of Short- and Long-Term Elevated CO2 on the
Expression of Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase Genes and
Carbohydrate Accumulation in Leaves of Arabidopsis
thaliana (L.) Heynh.1
Shu-Hua Cheng*,
Brandon d. Moore, and
Jeffrey R. Seemann
Department of Biochemistry, University of Nevada, Reno, Nevada
89557
 |
ABSTRACT |
To investigate the proposed molecular
characteristics of sugar-mediated repression of photosynthetic genes
during plant acclimation to elevated CO2, we examined the
relationship between the accumulation and metabolism of
nonstructural carbohydrates and changes in
ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) gene
expression in leaves of Arabidopsis thaliana exposed to
elevated CO2. Long-term growth of Arabidopsis at high
CO2 (1000 µL L 1) resulted in a 2-fold
increase in nonstructural carbohydrates, a large decrease in the
expression of Rubisco protein and in the transcript of
rbcL, the gene encoding the large subunit of Rubisco (approximately 35-40%), and an even greater decline in mRNA of rbcS, the gene encoding the small subunit (approximately
60%). This differential response of protein and mRNAs suggests that transcriptional/posttranscriptional processes and protein turnover may
determine the final amount of leaf Rubisco protein at high CO2. Analysis of mRNA levels of individual
rbcS genes indicated that reduction in total
rbcS transcripts was caused by decreased expression of
all four rbcS genes. Short-term transfer of Arabidopsis plants grown at ambient CO2 to high CO2
resulted in a decrease in total rbcS mRNA by d 6, whereas Rubisco content and rbcL mRNA decreased by d 9. Transfer to high CO2 reduced the maximum expression level
of the primary rbcS genes (1A and, particularly, 3B) by limiting their normal pattern of accumulation through the night period.
The decreased nighttime levels of rbcS mRNA were
associated with a nocturnal increase in leaf hexoses. We suggest that
prolonged nighttime hexose metabolism resulting from exposure to
elevated CO2 affects rbcS transcript
accumulation and, ultimately, the level of Rubisco protein.
| |
INTRODUCTION |
Exposure of C3 plants to elevated
CO2 frequently results in an immediate increase
in the rate of CO2 assimilation; however, a
reduction in photosynthetic capacity often occurs after prolonged periods (days to weeks) at elevated CO2 (for
reviews, see Stitt, 1991 ; Griffin and Seemann, 1996). This
down-regulation or acclimation of photosynthesis is generally
accompanied by a large increase in leaf carbohydrates. On average, leaf
soluble sugars increase by 52% and starch content increases by 160%
(Long and Drake, 1992; Webber et al., 1994). Growth at elevated
CO2 may also result in a large decline in Rubisco
protein (up to 60%; Sage et al., 1989; Besford et al., 1990;
Rowland-Bamford et al., 1991) and significant decreases in the
transcript levels of genes encoding the small (rbcS) and
large (rbcL) subunits of Rubisco (Nie et al., 1995a; Van
Oosten and Besford, 1995). However, the metabolic signals and
biochemical/molecular mechanisms underlying this acclimation to
elevated CO2 are not well understood.
Understanding the mechanisms that will ultimately determine the
response of photosynthesis to the all-but-certain doubled atmospheric
CO2 of the 21st century is a critical component
in predicting the impact of global change on the earth's terrestrial
ecosystems.
Sugars are known to influence many metabolic and cellular processes in
both prokaryotes and eukaryotes, in part through modulation of gene
expression (for reviews, see Sheen, 1994; Saier et al., 1995; Koch,
1996). To date, there is substantial evidence indicating that increased
sugar levels can trigger repression of photosynthetic gene
transcription. Using a transient expression system in maize protoplasts, Sheen (1990) showed that transcription of seven
photosynthetic genes, including rbcS, is repressed by Glc
and Fru. Furthermore, overexpression of a yeast invertase gene in the
apoplast of tobacco leaves resulted in leaf hexose accumulation,
bleached leaves, and stunted growth (von Schaewen et al., 1990). These
transgenic plants also showed an inhibition of photosynthesis
attributable to a decrease in the levels of several Calvin-cycle
enzymes, including Rubisco. When detached spinach leaves were supplied
with Glc through the transpiration stream, levels of rbcS
mRNA decreased within hours (Krapp et al., 1993), and the amount of
Rubisco protein declined 90% after 7 d (Krapp et al., 1991). Such
sugar repression of photosynthetic genes appears to be widespread; this
phenomenon has also been demonstrated to occur in an autotrophic cell
culture of Chenopodium rubrum (Krapp et al., 1993), in
photomixotrophic cultures and protoplasts of rapeseed (Harter et el.,
1993), and in intact leaves/plants of Arabidopsis thaliana,
tomato, potato, and wheat (Cheng et al., 1992; Heineke et al., 1994;
Van Oosten and Besford, 1994; Jones et al., 1996; Dijkwel et al.,
1997).
Repression of photosynthetic gene transcription by accumulated leaf
soluble sugars is an attractive hypothesis to explain the acclimation
responses of photosynthesis to elevated CO2.
However, research on plant responses to high CO2
has largely focused on growth and physiological acclimation, with only
a few studies addressing the effects of elevated
CO2 on photosynthetic gene expression (e.g. Van
Oosten et al., 1994; Van Oosten and Besford, 1995; Majeau and Coleman,
1996). Although these studies indicate that plants do modulate the
levels of photosynthetic mRNAs in parallel with leaf carbohydrate
status after exposure to high CO2, the link
between sugar repression of gene expression and control of
photosynthetic acclimation at elevated CO2
remains elusive.
All of the attributes of Arabidopsis that have made it a model
experimental organism (e.g. the existence of many mutants, the small
genome, the short generation time, and the large amount of genome
information) for addressing a myriad of important questions in plant
biology make it valuable for high-CO2 research.
In Arabidopsis and other higher plants, rbcS mRNAs are
encoded by a multigene family and their expression patterns can differ
both quantitatively and qualitatively in response to light and
development, and in different organs (for review, see Manzara and
Gruissem, 1988; Dean et al., 1989). In Arabidopsis, the rbcS
gene family consists of four members, namely 1A, 1B, 2B, and 3B
(Krebbers et al., 1988). Dedonder et al. (1993) showed that the
expression of individual Arabidopsis rbcS genes is
differentially regulated by light of different quality and quantity.
Whether other environmental factors such as elevated
CO2 exert differential effects on the expression of individual rbcS genes in any species has not yet been
determined.
Furthermore, in many species, such as Arabidopsis, grown in a
light/dark photoperiod, rbcS mRNA exhibits a diurnal pattern of expression, with peak abundance occurring soon after dawn and minimum levels at the end of the light period (Pilgrim and McClung, 1993; this paper). This diurnal oscillation of rbcS mRNA
occurs in an inverse time frame to the normal daytime accumulation and nighttime mobilization of leaf carbohydrates (e.g. Trethewey and ap
Rees, 1994; Geiger et al., 1995). The response of such diurnal patterns
after treatment of the plant with high CO2 can be
a useful approach for evaluating carbohydrate regulation of
photosynthetic gene expression (e.g. Nie et al., 1995a).
In this study we have examined the accumulation of leaf carbohydrates
and changes in Rubisco expression (both protein and transcripts) during
exposure of Arabidopsis to elevated CO2 (both long-term growth and short-term transfer). We have also closely examined the impact of elevated CO2 on the
diurnal expression of rbcS gene family members in relation
to leaf carbohydrate metabolism. These data provide insight into the
regulation of photosynthetic gene expression by elevated sugar levels
and on the control points of Rubisco synthesis (e.g. transcription,
mRNA stability, translation, and protein turnover) during plant
acclimation to high CO2.
| |
MATERIALS AND METHODS |
Plants of Arabidopsis thaliana (L.) Heynh. ecotype
Columbia were germinated and grown five plants per 1-L pot in growth
chambers at either 360 µL L1
CO2 (ambient conditions) or 1000 µL
L1 CO2
(high-CO2 conditions), a 10-h photoperiod, a
21/18°C thermoperiod, 80% RH, and an irradiance of 400 µmol quanta
m2 s1. To avoid
growth-chamber effects, two chambers per treatment were used in
replicate experiments. Plants were watered with one-fourth-strength Hoagland solution twice weekly.
For long-term growth experiments, plants were grown continuously for
40 d at ambient or high CO2. At this stage,
plants grown at high CO2 were 3 to 4 d
farther along developmentally than those grown at ambient
CO2, as judged by subsequent bolting. Thus,
high-CO2-grown plants on average may have been
2 d more advanced developmentally. For transfer experiments,
30-d-old ambient-CO2-grown plants were transferred to high CO2 for up to 12 d, and
no accelerated development was apparent after the transfer. Diurnal
tissue sampling of ambient control or
high-CO2-treated plants began on the 6th d after
transfer from ambient to high CO2. Five plants of
each treatment were harvested at the indicated times and leaves were
pooled for analysis. Shoots of Arabidopsis were harvested and frozen in
liquid N2. Stems and petioles were removed from
the samples before leaf analyses.
Biochemical Measurements
Leaf Rubisco content was measured by binding
[14C]2-carboxyarabinatol-1,5-bisphosphate,
followed by immunoprecipitation (Evans and Seemann, 1984). For
carbohydrate measurements, samples were extracted in hot ethanol and
processed as described by Moore et al. (1997). Starch in residual
material was autoclaved and hydrolyzed as described by Schulze et al.
(1991). All sugars were measured using high-performance anion
exchange-pulsed-amperometric detection and a CarboPac PA1 column
(Dionex, Sunnyvale, CA) under conditions described previously for
parsley (Moore et al., 1997).
RNA Isolation and Northern-Blot Analysis
Total leaf RNA was isolated as described previously (Cheng and
Seemann, 1998), except that the RNA pellet was dissolved in 10 mm Tris-HCl, pH 7.5, and 1 mm EDTA after LiCl
precipitation, and no alcohol precipitation was performed thereafter.
Carbohydrate or protein contamination of the RNA preparation was
evaluated by measuring A230,
A260, and A280, and the
A260 values were used for quantitation.
Total RNA was denatured, size fractionated by electrophoresis in a
Mops-formaldehyde-1.4% agarose gel, transferred to a nylon membrane
(Schleicher & Schuell), and cross-linked to the membrane by UV
irradiation (Stratalinker, Stratagene) (Sambrook et al., 1989).
Before hybridization, the nylon membrane was stained with methylene
blue to check RNA integrity and ensure equal loading of RNA amounts.
cDNAs used as probes were a 750-bp SalI/NotI
fragment of Arabidopsis rbcS (no. 11C1T7P) and a 1.6-kb
SalI/NotI fragment of Arabidopsis  -tubulin
(no. 32C11T7) obtained from the Arabidopsis Biological Research Center
(Ohio State University, Columbus), and a 1.2-kb plastid
BamHI/EcoRI fragment of tobacco rbcL
(Shinozaki and Sugiura, 1982). These DNA fragments were labeled with
[-32P]dCTP by random priming (Prime-a-Gene,
Promega).
Hybridization was carried out at 42°C in a buffer containing 6× SSC
buffer (1× SSC is 150 mm NaCl and 15 mm sodium
citrate, pH 7.0), 50% (v/v) formamide, 5× Denhardt's solution (1×
Denhardt's solution is 0.02% PVP, 0.02% Ficoll, and 0.02% BSA), 50 mm sodium phosphate, pH 7.0, 0.2% SDS (w/v), and 100 µg
mL1 denatured salmon-sperm DNA. After 16 h of
hybridization the blots were washed twice for 5 min at room temperature
in 2× SSC/0.1% SDS, and then twice for 10 min in 0.2× SSC/0.1% SDS
at 60°C (for rbcS mRNA) or in 0.5× SSC/0.1% SDS at
60°C (for rbcL and tubulin mRNAs). In each blot a dilution
series of an RNA sample was included to ensure that
32P-labeled probes were in excess. The
hybridizing DNA probe was removed by incubating the blots in 50 mm Tris-HCl, pH 8.0, 60% formamide, and 1% SDS at 75°C
for 1 h, and the blots were reprobed. Hybridization signals were
quantified with a phosphor imager (Bio-Rad) to determine the relative
amount of RNA present in each lane.
The expression of individual members of the Arabidopsis rbcS
gene family was determined by using gene-specific oligonucleotide probes (Dedonder et al., 1993). The sequences of the probes were 5 -TTTTGAGGTTTACACAAAAG-3 (1A), 5-CGGATAGTCAACATTGAAT-3 (1B), 5-AGAATAATCAACGCTGAATAT-3 (2B), and 5-AGATAATTCATAAGAATGTT-3 (3B). These synthetic oligonucleotides are complementary to the 3
untranslated regions of the rbcS mRNAs (Krebbers et al.,
1988). Ten micrograms of total RNA from each sample was processed as described as above, and the hybridization conditions were the same as
reported by Dedonder et al. (1993).
| |
RESULTS |
Effects of Long-Term Growth at Elevated CO2
Glc, Fru, Suc, and starch were the predominant nonstructural leaf
sugars in both ambient- and high-CO2-grown
Arabidopsis. Long-term growth of Arabidopsis at elevated
CO2 resulted in a 2-fold or greater increase in
Glc and Fru and a 3.5-fold increase in starch, whereas Suc levels
remained relatively constant (Fig. 1).
Growth of Arabidopsis at high CO2 caused an
approximately 34% reduction in Rubisco protein content and an
approximately 38% decrease in rbcL mRNA (Fig.
2). However, the abundance of total
rbcS transcript decreased nearly 60% at elevated
CO2 relative to that at ambient
CO2. Notably, the decrease in Rubisco protein content was consistently similar in magnitude to the decrease in
rbcL mRNA but not to that in rbcS mRNA. Although
growth at high CO2 was slightly accelerated
relative to that at ambient CO2 (see ``Materials and Methods''), the large decreases in Rubisco protein and subunit transcript levels were not attributable to accelerated development, but
primarily to the effects of high CO2 (S.-H. Cheng
and J.R. Seeman, unpublished data).
View larger version (19K):
[in this window]
[in a new window]
| Figure 1.
Effects of long-term growth at elevated
CO2 on nonstructural carbohydrate content in leaves of
Arabidopsis. Values represent means ± sd
(n = 3) for plants collected at midday. Starch is
expressed as micromoles of Glc equivalents. Total sugar amounts were
19.9 and 53.8 µmol hexose equivalents g1 fresh weight
in ambient-CO2-grown (black bars) and
high-CO2-grown (hatched bars) plants, respectively. Leaf
chlorophyll was about 1.25 mg g1 fresh weight in plants
grown under both conditions. FW, Fresh weight.
|
|
View larger version (35K):
[in this window]
[in a new window]
| Figure 2.
Effects of long-term growth at elevated
CO2 on Rubisco content and rbcS and
rbcL transcript abundance. Absolute amounts of leaf
Rubisco were 33.7 and 22.3 nmol g1 fresh weight for
ambient- and high-CO2-grown plants, respectively. One
microgram of total RNA per lane was used for northern-blot analysis.
rRNA was used as an internal control to ensure equal loading of the
lanes; 25S rRNA is shown stained with methylene blue. Relative
hybridization signals quantified by phosphor imaging were expressed as
a percentage of the values obtained from the ambient control. Values
are means ± sd from three filters each, with RNA
samples extracted from two replicate experiments. Leaves were collected
at midday.
|
|
In Arabidopsis, rbcS transcripts are encoded by four
different genes, 1A, 1B, 2B, and 3B (Krebbers et al., 1988). Although the coding regions of Arabidopsis rbcS genes have a high
degree of homology with one another, the 3 untranslated regions are sufficiently divergent to allow their use as gene-specific probes to
examine individual rbcS mRNA expression (Krebbers et al.,
1988; Dedonder et al., 1993). Under both CO2
growth conditions, the levels of 1A and 3B gene mRNA accounted for
about 75% of the total rbcS transcript pool, and the 1B and
2B genes accounted for approximately 25% of the total (Fig.
3). Although total rbcS mRNAs
decreased by approximately 60% in plants grown at elevated
CO2, individual rbcS genes were
down-regulated to somewhat different degrees. High
CO2 caused more than a 60% decrease in the
transcript abundance of 1B, 2B, and 3B genes, with a smaller reduction
(45%) in 1A mRNA levels. The internal control gene -tubulin was
relatively unaffected by the CO2 growth
conditions.
View larger version (30K):
[in this window]
[in a new window]
| Figure 3.
Effects of long-term growth at elevated
CO2 on the relative abundance of rbcS gene
members. Ten micrograms of total RNA per lane was used for
northern-blot analysis. Gene-specific probes were labeled to similar
specific activities (approximately 5 × 107 dpm
pmol1), and equal amounts of radioactivity of each probe
were used. Blots were exposed for the same length of time. The relative
amounts of individual rbcS mRNA were expressed as a
percentage of the sum of hybridizing signals from each of the
rbcS members. Relative changes attributable to
CO2 treatments were expressed using the ambient values of
each rbcS gene as 100%. One of the blots was stripped
and hybridized to an internal control gene (-tubulin [Tub]).
Numbers represent means ± sd from two filters each,
with RNA samples extracted from two replicate experiments. Leaves were collected at midday.
|
|
Effects of Short-Term Transfer from Ambient to Elevated
CO2
Rapid Down-Regulation of rbcS mRNA Relative to
Rubisco Protein
In an initial experiment, plants grown at ambient
CO2 were transferred to high
CO2 for up to 12 d, and leaves were
collected at the beginning of the light period on each indicated
sampling day for Rubisco protein and transcript measurements (Fig.
4). The time of day for sampling was
selected based on a previous finding that the level of total
rbcS mRNAs in Arabidopsis grown in a light/dark photoperiod
displays a diurnal pattern, with peak abundance occurring soon after
dawn (Pilgrim and McClung, 1993). In this experiment plants from both
CO2 conditions showed an age-dependent decline in
the levels of rbcS and rbcL mRNA and in Rubisco
protein. Nonetheless, a distinct CO2 effect was
evident. Total rbcS transcript abundance decreased
significantly by d 6 (approximately 30%), with an additional decline
thereafter. There was only a small effect of elevated
CO2 on rbcL mRNA levels (an 18%
decline by d 12). A significant CO2-induced
decrease in Rubisco protein was observed on d 9 and 12 after the
transfer to elevated CO2 (20 and 29%,
respectively; Fig. 4B).
View larger version (38K):
[in this window]
[in a new window]
| Figure 4.
Time course of relative abundance of Rubisco
protein and total rbcS and rbcL
transcripts in ambient-CO2-grown plants transferred to
elevated CO2 for 12 d. Plants were transferred at the
beginning of the light period on d 1, and leaves from 10 plants were
collected on the indicated days at the beginning of the light period.
A, Northern-blot analysis using 1 µg of total RNA as shown on the representative blot. 25S rRNA is shown stained with methylene blue. B,
Leaf Rubisco content and quantified relative amounts of
rbcS and rbcL mRNAs from
ambient-CO2-grown (black bars) and high-CO2-grown (hatched bars) plants. Values are means ± sd from three separate protein extractions or from three
replicate filters, with RNA extracted from one sample collection.
|
|
Dampening of Diurnal Oscillation of rbcS mRNA
at Elevated CO2
Because a significant decrease of rbcS transcript
abundance occurred by d 6 (Fig. 4), we chose this treatment time for a
more detailed analysis of the diurnal expression patterns of rbcS and rbcL mRNAs and total leaf carbohydrate
accumulation after high-CO2 treatments. The level
of total rbcS mRNAs oscillated from a maximum at the
beginning of the light period to a minimum at the end of the light
period, with an ongoing accumulation throughout the dark period that
reestablished the maximum early-morning level (Fig.
5). The change in transcript levels
during the day was about 3-fold more than that in ambient-grown plants.
View larger version (49K):
[in this window]
[in a new window]
| Figure 5.
Effects of transfer to elevated CO2 on
the relative abundance of rbcS and rbcL
transcripts during a light/dark cycle. Ambient-CO2-grown plants were transferred to elevated CO2 at the beginning of
d 1, and plants were collected through the 24-h period on d 6 of exposure. A, Northern-blot analysis of rbcS and
rbcL expression using 1 µg of total RNA per lane. 25S
rRNA is shown stained with methylene blue. Bars above blots and at the
bottom of the graph in B indicate the light regime (the filled area
indicates dark, the open area indicates light). B, Quantified signals
of total rbcS and rbcL transcripts from
ambient-CO2-grown (black bars) and
high-CO2-grown (hatched bars) plants. The hybridizing
signal at 7:00 am from ambient-CO2-grown plants
was defined as 100%. The diurnal transfer experiment was done twice.
Values are means ± sd from four filters (two filters
for each replicate).
|
|
A similar diurnal pattern of total rbcS mRNA level occurred
in plants transferred to elevated CO2 (Fig. 5),
with maximum and minimum values also observed at the beginning and end
of the light period, respectively. However, the maximum level was
reduced about 40% relative to ambient CO2
(comparable to Fig. 4). Treatment differences in rbcS mRNA
levels diminished from the beginning of the light period such that by
the end of the light period (5:00 pm), virtually no
difference in transcript abundance was found between
CO2 treatments. However, the nighttime
accumulation of rbcS mRNA at high CO2
was much less than what occurred at ambient CO2,
thereby reducing the maximum accumulation level at the beginning of the
light period. In contrast, rbcL transcript levels from both
CO2 conditions remained approximately constant
throughout the 24-h light/dark cycle, with rbcL mRNA amounts
at elevated CO2 decreasing only slightly relative
to amounts in the ambient treatment (Fig. 5).
Differential Sensitivity of rbcS Genes to Elevated
CO2 during the Diurnal Cycle
Because individual rbcS genes displayed differential
sensitivities to long-term growth at high CO2
(Fig. 3), we examined the effects of short-term elevated
CO2 on the diurnal expression of specific
rbcS genes. In ambient-CO2-grown
plants, the patterns of diurnal oscillation of mRNA with respect to the
timing of peak accumulation and the amplitude of the fluctuation were
not identical among rbcS genes (Fig.
6). Similar to the oscillation patterns observed for total rbcS mRNAs, the expression of
rbcS 1A and 3B mRNA (which constitute 75% of the total) was
maximum at the beginning of the light period and lowest at the end.
However, the relative magnitudes of these fluctuations and the rate of
recovery during the dark were different in these two rbcS
genes. 1A mRNA had a greater amplitude and slower recovery than did 3B
mRNA. In contrast, the peak transcript abundance of both the 1B and 2B
rbcS genes occurred before the beginning of the light period
(5 and 8 h into the dark, respectively). Also, the minimum levels
of mRNA accumulation occurred in the middle of the day for the 1B gene,
but at the end of the light period for the 2B gene. Evidently,
Arabidopsis rbcS gene members are expressed differently
during the diurnal cycle.
View larger version (22K):
[in this window]
[in a new window]
| Figure 6.
Effects of transfer to elevated CO2 on
the diurnal oscillation of different rbcS transcripts.
Ambient-CO2-grown plants were transferred to elevated
CO2 at the beginning of d 1, and plants were collected
through the 24-h period on d 6 of exposure. Ten micrograms of total RNA
was used for northern-blot analysis. The hybridizing signal for each
gene at 7:00 am from ambient-CO2-grown plants
was defined as 100%. Values are means ± sd from
three filters with total RNA extracted from one sample collection.
Filled symbols, Ambient-CO2-grown plants; open symbols,
high-CO2-treated plants.
|
|
Transfer to high CO2 on d 6 resulted in
differential effects on the diurnal fluctuations of individual
rbcS mRNAs (Fig. 6). Among the four rbcS
genes, the 3B gene was most affected by the high-CO2 treatment. The 3B transcript levels in
high-CO2-grown plants were as much as 60% lower
than those in ambient plants throughout the light/dark cycle. In
contrast to its normal nighttime recovery under ambient conditions, 3B
transcript levels remained low throughout the night after transfer to
high CO2. Elevated CO2 also
reduced 1A mRNA levels somewhat throughout the light/dark cycle, but
substantially less than occurred with 3B. 1A mRNA levels did increase
during the night, but at a slower rate than at ambient CO2. Transfer to high CO2
had a minimal effect on the 2B diurnal levels except for an apparent
stimulation at midday. Likewise, 1B mRNA levels were not much affected
by high CO2 except that they were lower during
the initial 5 h of darkness. After 6 d at high
CO2, the relative expression of 1A, 1B, 2B, and
3B were about 35, 12, 23, and 30%, respectively, at the beginning of
the light period (calculated from Figs. 3 and 6).
Diurnal Pattern of Leaf Sugar Accumulation
In both control plants and plants transferred to high
CO2, leaf Glc, Fru, Suc, and starch were at a
minimum at the beginning of the light period, accumulated throughout
the day, and then decreased to different extents during the night (Fig.
7). This pattern of leaf
carbohydrate accumulation was generally inverse to that for
rbcS mRNA. Overall,
high-CO2-treated plants had higher levels of all
four sugars than did ambient-CO2-grown plants
throughout the light/dark cycle. Moreover, the nighttime metabolism of
all four sugars was delayed in plants transferred to high
CO2. For example, the level of leaf hexoses was
high and relatively constant during the first 4 h of darkness in
treated plants, whereas the normal situation is that their levels have already declined to minimum values after 4 h of darkness. These data indicate that exposure to elevated CO2 not
only resulted in a 2-fold increase in total nonstructural leaf
carbohydrate content, but also caused a significant change in nighttime
carbohydrate metabolism.
View larger version (22K):
[in this window]
[in a new window]
| Figure 7.
Effects of transfer to elevated CO2 on
the diurnal accumulation of nonstructural leaf carbohydrates: A, Glc;
B, Fru; C, Suc; and D, starch. Ambient-CO2-grown plants
were transferred to elevated CO2 at the beginning of d 1, and plants were collected through the 24-h period on d 6 of exposure.
Values represent means ± sd from three extractions.
Starch is expressed as micromoles of Glc equivalents. Total maximum
sugar amounts were 55.7 and 108.1 µmol hexose equivalents
g1 fresh weight in ambient-CO2-grown and
high-CO2-transferred plants, respectively. Filled symbols,
Ambient-CO2-grown plants; open symbols, high-CO2-treated plants. FW, Fresh weight.
|
|
| |
DISCUSSION |
We report here the first detailed characterization of
photosynthetic acclimation to elevated atmospheric
CO2 in Arabidopsis at both the biochemical and
molecular levels. Growth of Arabidopsis at high
CO2 resulted in a 2-fold accumulation of
nonstructural leaf carbohydrates and a substantial decrease in Rubisco
protein content (Figs. 1 and 2), similar to that found in other species (e.g. wheat [Nie et al., 1995a, 1995b]; tomato [Van Oosten and Besford, 1995]; and pea [Majeau and Coleman, 1996]). Although such a
decrease in Rubisco protein during plant growth at high CO2 is well documented (e.g. Sage et al., 1989;
Stitt, 1991), the mechanism(s) that controls Rubisco expression at high
CO2 has yet to be identified. Control of Rubisco
synthesis is known to occur at the transcriptional, posttranscriptional
(e.g. mRNA stability), translational, and/or posttranslational levels,
depending on developmental factors and environmental stimuli (Deng and
Gruissem, 1987; Berry et al., 1988; Shirley and Meagher, 1990;
Wanner and Gruissem, 1991; Winder et al., 1992).
In Arabidopsis grown at high CO2, the levels of
Rubisco protein and rbcL mRNA were reduced about 40%,
whereas rbcS mRNA was reduced to an even greater extent
(approximately 60%; Fig. 2). There are only a few reports to date on
the influence of high- or low-CO2 growth
conditions on the expression of both Rubisco protein and subunit
transcript levels. In wheat grown at elevated CO2, both rbcS and rbcL
transcripts decreased equally, with the same level of decline also
observed in Rubisco protein (newly mature third leaves in chamber
plants [Webber et al., 1994]; flag leaves in field plants [Nie et
al., 1995b]). These results suggest that the regulation of
transcriptional and/or posttranscriptional processes (e.g. mRNA
stability) could determine the level of Rubisco protein at elevated
CO2.
In tomato transferred to elevated CO2 for 22 d, the levels of Rubisco protein and subunit transcripts decreased to
different extents relative to control plants, suggesting a different
type of posttranscriptional regulation of protein content (Van Oosten and Besford, 1995). In Chlamydomonas reinhardtii grown under
low-CO2 conditions, the steady-state levels of
both rbcS and rbcL transcripts were not affected,
but Rubisco protein content was found to decline rapidly (Winder et
al., 1992). This was not because of an increased rate of protein
degradation, but rather because of the inhibition of translation of
both rbcS and rbcL mRNAs. Growth of pea at low levels of CO2 resulted in decreased
rbcS mRNA, but had no effect on total Rubisco activity (i.e.
fully activated enzyme; Majeau and Coleman, 1996).
The nature of the control of Rubisco content in Arabidopsis grown at
high CO2 is intriguing because the coordination
between rbcS and rbcL transcript levels was
altered, as was the expression of protein content relative to subunit
transcripts. The synthesis of Rubisco requires coordinated expression
between the nucleus and the chloroplast genomes, but nuclear-encoded
photosynthetic genes are generally more readily repressed by
accumulated carbohydrates than are chloroplast-encoded genes (e.g. Van
Oosten and Besford, 1994; Van Oosten et al., 1994). A decreased level
of rbcS mRNA relative to rbcL mRNA has been
observed during leaf senescence in bean (Bate et al., 1991), during
severe water stress in tomato (Bartholomew et al., 1991), and with
high-CO2 growth conditions in tomato (Van Oosten
and Besford, 1994). Such differential transcript expression also has
been observed in tobacco rbcS antisense plants, but reduced
rbcS mRNA largely corresponded to reduced Rubisco content
(Rodermel et al., 1988). Of particular significance was the finding
that leaf rbcL mRNA in the rbcS antisense plants
was not efficiently translated (Rodermel et al., 1996), a situation that may also occur in Arabidopsis at high CO2.
During normal leaf development, Rubisco subunit transcripts and protein
content are all coordinately expressed (Jiang and Rodermel, 1995).
Growth of Arabidopsis at high CO2 may disrupt the
homeostatic control of Rubisco protein and transcript
expression.
We suggest that control of Rubisco content in Arabidopsis grown at high
CO2 may have three primary components: (a) an
inhibitory signal may repress levels of rbcS mRNA more than
rbcL mRNA by differential effects on transcriptional
activity and/or message stability. Transcription and mRNA stability are
both important mechanisms for Glc repression of -amylase in rice
(Sheu et al., 1994); (b) leaf rbcL mRNA may not be as
efficiently translated as is rbcS mRNA, or large subunit
protein may simply accumulate in excess of small subunit protein, as
apparently occurs in tomato (Van Oosten and Besford, 1995), or be
degraded (although the latter has not been shown to occur in any system
[Rodermel et al., 1996]); and (c) Rubisco protein turnover may be
altered such that protein levels are not repressed to an extent
comparable to rbcS mRNA. That Rubisco protein may be
longer-lived was also suggested in a study of wheat leaves of
intermediate age grown at high CO2 (Webber et
al., 1994).
In higher plants, rbcS mRNAs are encoded by a multigene
family (Dean et al., 1989). Pilgrim and McClung (1993) showed that the
diurnal expression of total leaf rbcS mRNAs in
Arabidopsis is under the control of a circadian clock, but
transcriptional activities are not involved in regulating the clock. We
have extended this observation by demonstrating that individual
rbcS gene members in Arabidopsis also generally show the
same diurnal expression pattern (Fig. 6) as was previously reported for
total rbcS mRNAs (Pilgrim and McClung, 1993). However, the
expression of 1B mRNA occurred out of phase relative to expression of
the other three genes. This result was not detected in the diurnal
analysis of total rbcS mRNAs (Fig. 5) (Pilgrim and McClung,
1993) because 1B mRNA normally constitutes only about 10% of the total
leaf rbcS mRNAs.
In this study we have also shown that individual rbcS genes
in Arabidopsis are expressed differently during long-term growth at
high CO2 or after a short-term transfer to high
CO2. During growth at high
CO2, the 1A gene was the least repressed, whereas the other three genes were repressed by a similarly increased magnitude
(Fig. 3). Transfer to high CO2 did not
significantly affect the diurnal expression pattern of the individual
genes, but did affect the magnitude of the expression levels of some of
the genes (Fig. 6). After transfer to high CO2,
the 3B gene mRNA was the most reduced, the 1A mRNA was moderately
affected, and the 1B and 2B mRNAs were minimally affected. Because the
1A and 3B genes contribute the largest portion of the rbcS
mRNA pool, their reduced expression at high CO2
resulted in a 40% reduction in the maximum level of total
rbcS mRNA by d 6, and ultimately resulted in a 20%
reduction in Rubisco content by d 9 (Figs. 4 and 5).
Several investigators (e.g. Krapp et al., 1993; Sheen, 1994; Van Oosten
et al., 1994) have proposed that the increased metabolism of
accumulated soluble sugars at high CO2 may
trigger a repression of photosynthetic gene transcription. This
repression is thought to be mediated by hexose metabolism via cytosolic
hexokinase (Jang and Sheen, 1994; Jang et al., 1997), but we have
limited knowledge of the suggested biochemical role of hexokinase as a
sugar sensor. For example, the presumed signal of hexokinase, hexoses,
are found to be almost exclusively located in the vacuole of leaf
mesophyll cells during the daytime in several species grown at ambient
or high CO2 (Heineke et al., 1994; Moore et al.,
1997). Although our data and those of others indicate a correlation
between increased leaf hexose levels and decreased rbcS mRNA
in plants exposed to high CO2, one possibility is
that hexokinase-mediated gene repression may occur in leaves at night
rather than during the day.
In Arabidopsis we found that the normal nighttime recovery of
rbcS transcript levels was greatly reduced after transfer of the plant to high CO2 (Fig. 5). We also found
that leaf hexose levels were unusually high during the early hours of
darkness (Fig. 7). In most species, including Arabidopsis, leaf
carbohydrates accumulate during the day and are mobilized at night
(Trethewey and ap Rees, 1994; Geiger et al., 1995). We hypothesize that
elevated nighttime cytosolic hexose concentrations resulting from high CO2 are sensed by hexokinase, and trigger a
repression response that results in decreased rbcS
transcript levels. The fact that transgenic tobacco overexpressing a
yeast invertase gene had reduced photosynthetic rates and no diurnal
turnover of leaf carbohydrates is consistent with this hypothesis (von
Schaewen et al., 1990).
An alternative possibility for hexose sensing in the absence of any
detectable cytosolic hexoses at any time during the day could involve
futile cycling of Suc between the cytosol and vacuole and/or between
the cytosol and apoplast (Foyer, 1987; Huber, 1989; Stitt et al.,
1990). Exposure to elevated CO2 may result in
increased carbon flux to Suc. Under sink-limited conditions this may
result in increased hexose accumulation from vacuolar or apoplastic
hydrolysis by acid invertase (e.g. Goldschmidt and Huber, 1992). These
hexoses may then be transported to the cytosol, phosphorylated by
hexokinase, and reassimilated into Suc. Such carbohydrate cycling could
occur rapidly but with no substantial increase in cytosolic hexoses or
other cellular metabolites, which is analogous to Suc cycling through
Suc synthase (Geigenberger and Stitt, 1991). With Suc cycling under
high CO2, hexokinase then would have to function as a flux sensor. One effect of such metabolism is that species with
lower leaf acid invertase activity may be less susceptible to
down-regulation of photosynthesis when grown at high
CO2.
In summary, our results support the hypothesis that increased leaf
carbohydrates in response to elevated CO2 may
signal the down-regulation of photosynthesis through modulation of
photosynthetic genes such as rbcS, and that
hexokinase-mediated repression of gene expression may occur at night.
However, results presented in this report also suggest that
sugar-induced repression of photosynthetic gene transcription alone
cannot totally explain the decrease of Rubisco protein at elevated
CO2. Rather,
high-CO2-mediated changes in Rubisco expression
are very complex and may involve multiple controls at the levels of
transcription, mRNA stability, translation, and/or protein turnover.
Therefore, it is important to determine specific transcription,
translation, and protein turnover rates to better understand the
mechanisms controlling photosynthetic responses to elevated
CO2.
| |
FOOTNOTES |
1
This work was supported by National Science
Foundation grant no. 1940424 to J.R.S. and S.-H.C.
*
Corresponding author; e-mail scheng{at}med.unr.edu; fax
1-702-784-1650.
Received July 28, 1997;
accepted October 27, 1997.
| |
ACKNOWLEDGMENTS |
We are grateful to Shanti Rawat and Therese Charlet for their
technical assistance. We thank Dr. Steve Rodermel (Iowa State University, Ames) for kindly providing the cDNA of tobacco
rbcL. Oligonucleotides used in this report were supplied by
the Oligonucleotide Synthesis Core Facility at the University of
Nevada, Reno.
| |
LITERATURE CITED |
Bartholomew DM,
Bartley GE,
Scolnik PA
(1991)
Abscisic acid control of rbcS and cab transcription in tomato leaves.
Plant Physiol
96:
291-296
[Abstract/Free Full Text]
Bate NJ,
Rothstein SJ,
Thompson JE
(1991)
Expression of nuclear and chloroplast photosynthesis-specific genes during leaf senescence.
J Exp Bot
42:
801-811
[Abstract/Free Full Text]
Berry OJ,
Carr JP,
Klessing DF
(1988)
mRNAs encoding ribulose-1,5-bisphosphate carboxylase remain bound to polysome but are not translated in amaranth seedlings transferred to darkness.
Proc Natl Acad Sci USA
85:
4190-4194
[Abstract/Free Full Text]
Besford RT,
Ludwig LJ,
Withers AC
(1990)
The green house effect: acclimation of tomato plants growing in high CO2: photosynthesis and ribulose-1,5-bisphosphate carboxylase protein.
J Exp Bot
41:
925-931
[Abstract/Free Full Text]
Cheng C-L,
Acedo GN,
Christinsin M,
Conkling MA
(1992)
Sucrose mimics the light induction of Arabidopsis nitrate reductase gene transcription.
Proc Natl Acad Sci USA
89:
1861-1864
[Abstract/Free Full Text]
Cheng S-H, Seemann JR (1998) Extraction and purification of RNA
from plant tissue enriched in polysaccharides. In R Rapley,
DL Manning, eds, RNA Isolation and Characterization Protocols: Methods
in Molecular Biology, Vol 86. Humana Press, Totowa, NJ (in press)
Dean C,
Dunsmuir P,
Bedbrook J
(1989)
Structure, evolution, and regulation of rbcS genes in higher plants.
Annu Rev Plant Physiol Plant Mol Biol
40:
415-439
[CrossRef][Web of Science]
Dedonder A,
Rethy R,
Fredericq H,
Van Montagu M,
Krebbers E
(1993)
Arabidopsis rbcS genes are differentially regulated by light.
Plant Physiol
101:
801-808
[Abstract]
Deng X-W,
Gruissem W
(1987)
Control of plastid gene expression during development: the limited role of transcriptional regulation.
Cell
49:
379-387
[CrossRef][Web of Science][Medline]
Dijkwel PP,
Huijser,
Weisbeek PJ,
Chua N-H,
Smeekens SCM
(1997)
Sucrose control of phytochrome A signaling in Arabidopsis.
Plant Cell
9:
583-595
[Abstract]
Evans JR,
Seemann JR
(1984)
Differences between wheat genotypes in specific activity of RuBP carboxylase and the relationship to photosynthesis.
Plant Physiol
74:
759-765
[Abstract/Free Full Text]
Foyer CH
(1987)
The basis for source-sink interaction in leaves.
Plant Physiol Biochem
25:
649-657
Geigenberger P,
Stitt M
(1991)
A "futile" cycle of sucrose synthesis and degradation is involved in regulating partitioning between sucrose, starch and respiration in cotyledons of germinating Ricinus communis L. seedlings when phloem transport is inhibited.
Planta
185:
81-90
Geiger DR,
Shieh WJ,
Yu XM
(1995)
Photosynthetic carbon metabolism and translocation in wild-type and starch-deficient mutant Nicotiana sylvestris L.
Plant Physiol
107:
507-514
[Abstract]
Goldschmidt EE,
Huber SC
(1992)
Regulation of photosynthesis by end-product accumulation in leaves of plants storing starch, sucrose, and hexose sugars.
Plant Physiol
99:
1443-1448
[Abstract/Free Full Text]
Griffin KL,
Seemann JR
(1996)
Plants, CO2 and photosynthesis in the 21st century.
Chemistry and Biology
3:
245-254
[CrossRef][Web of Science][Medline]
Harter K,
Talke-Messerer C,
Barz W,
Schafer E
(1993)
Light- and sucrose-dependent gene expression in photomixotrophic cell suspension cultures and protoplasts of rape (Brassica napus L.).
Plant J
4:
507-516
Heineke E,
Wildenberger K,
Sonnewald U,
Willmitzer L,
Heldt HW
(1994)
Accumulation of hexoses in leaf vacuoles: studies with transgenic tobacco plants expressing yeast-derived invertase in the cytosol, vacuole or apoplasm.
Planta
194:
29-33
[Web of Science]
Huber SC
(1989)
Biochemical mechanism for regulation of sucrose accumulation in leaves during photosynthesis.
Plant Physiol
91:
656-662
[Abstract/Free Full Text]
Jang J-C,
Leon P,
Zhou L,
Sheen J
(1997)
Hexokinase as a sugar sensor in higher plants.
Plant Cell
9:
5-19
[Abstract]
Jang J-C,
Sheen J
(1994)
Sugar sensing in higher plants.
Plant Cell
6:
1665-1679
[Abstract]
Jiang C-Z,
Rodermel SR
(1995)
Regulation of photosynthesis during leaf development in rbcS antisense DNA mutants of tobacco.
Plant Physiol
107:
215-224
[Abstract]
Jones PG,
Lloyd JC,
Raines CA
(1996)
Glucose feeding of intact wheat plants repressed the expression of a number of Calvin cycle genes.
Plant Cell Environ
19:
231-236
[CrossRef]
Koch KE
(1996)
Carbohydrate-modulated gene expression in plants.
Annu Rev Plant Physiol Plant Mol Biol
47:
509-540
[CrossRef][Web of Science]
Krapp A,
Hofmann B,
Shafer C,
Stitt M
(1993)
Regulation of the expression of rbcS and other photosynthetic genes by carbohydrates: a mechanism for the `sink' regulation of photosynthesis.
Plant J
3:
817-828
Krapp A,
Quick WP,
Stitt M
(1991)
Ribulose-1,5-bisphosphate carboxylase-oxygenase, other photosynthetic enzymes and chlorophyll decrease when glucose is supplied to mature spinach leaves via the transpiration stream.
Planta
186:
58-69
Krebbers E,
Seurinck J,
Herdies L,
Cashmore AR,
Timko MP
(1988)
Four genes in two diverged subfamilies encode the ribulose-1,5-bisphosphate carboxylase small subunit polypeptides of Arabidopsis thaliana.
Plant Mol Biol
11:
745-759
[CrossRef]
Long SP,
Drake BG
(1992)
Photosynthetic CO2 assimilation and rising atmospheric CO2 concentrations.
In
NR Baker,
H Thomas,
eds, Crop Photosynthesis: Spatial and Temporal Determinants.
Elsevier, Amsterdam, pp 69-95
Majeau N,
Coleman JR
(1996)
Effects of CO2 concentration on carbonic anhydrase and ribulose-1,5-bisphosphate carboxylase/oxygenase expression in pea.
Plant Physiol
112:
569-574
[Abstract]
Manzara T,
Gruissem W
(1988)
Organization and expression of the genes encoding ribulose-1,5-bisphosphate carboxylase in higher plants.
Photosynth Res
16:
117-139
[CrossRef]
Moore Bd,
Palmquist DE,
Seemann JR
(1997)
Influence of plant growth at high CO2 concentrations on leaf content of ribulose-1,5-bisphosphate carboxylase/oxygenase and intracellular distribution of soluble carbohydrates in tobacco, snapdragon, and parsley.
Plant Physiol
115:
241-248
[Abstract]
Nie GY,
Hendrix DL,
Webber AN,
Kimball BA,
Long SP
(1995a)
Increased accumulation of carbohydrates and decreased photosynthetic gene transcript levels in wheat grown at an elevated CO2 concentration in the field.
Plant Physiol
108:
975-983
[Abstract]
Nie GY,
Long SP,
Garcia RL,
Kimball BA,
Lamorte RL,
Pinter PJ,
Wall GW,
Webber AN
(1995b)
Effects of free-air CO2 enrichment on the development of the photosynthetic apparatus in wheat, as indicated by changes in leaf proteins.
Plant Cell Environ
18:
855-864
[CrossRef]
Pilgrim ML,
McClung CR
(1993)
Differential involvement of the circadian clock in the expression of genes required for ribulose-1,5-bisphosphate carboxylase/oxygenase synthesis, assembly, and activation in Arabidopsis thaliana.
Plant Physiol
103:
553-564
[Abstract]
Rodermel S,
Abbott MS,
Bogorad L
(1988)
Nuclear-organelle interactions: nuclear antisense gene inhibits ribulose bisphosphate carboxylase enzyme levels in transformed tobacco plants.
Cell
55:
673-681
[CrossRef][Web of Science][Medline]
Rodermel S,
Haley J,
Jiang C-Z,
Tsai C-H,
Bogorad L
(1996)
A mechanism for intergenomic integration: abundance of ribulose-1,5-bisphosphate carboxylase small-subunit protein influences the translation of the large-subunit mRNA.
Proc Natl Acad Sci USA
93:
3881-3885
[Abstract/Free Full Text]
Rowland-Bamford AJ,
Baker JT,
Allen LH Jr,
Bowes G
(1991)
Acclimation of rice to changing atmospheric CO2 on growth, photosynthesis and water relations of salt marsh grass species.
Aquat Bot
39:
45-55
[CrossRef]
Sage RF,
Sharkey TD,
Seemann JR
(1989)
Acclimation of photosynthesis to elevated CO2 in five C3 species.
Plant Physiol
89:
590-596
[Abstract/Free Full Text]
Saier MH Jr,
Chauvaux S,
Deutscher J,
Reizer J,
Ye J-J
(1995)
Protein phosphorylation and regulation of carbon metabolism in Gram-negative versus Gram-positive bacteria.
Trends Biochem Sci
20:
267-271
[CrossRef][Web of Science][Medline]
Sambrook J,
Fritsch EF,
Maniatis T
(1989)
Molecular Cloning: A Laboratory Manual, Ed 2.
Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY
Schulze W,
Stitt M,
Schulze E-D,
Heuhaus HE,
Fichtner K
(1991)
A quantification of the significance of assimilatory starch for growth of Arabidopsis thaliana L. Heynh.
Plant Physiol
95:
890-895
[Abstract/Free Full Text]
Sheen J
(1990)
Metabolic repression of transcription in higher plants.
Plant Cell
2:
1027-1038
[Abstract/Free Full Text]
Sheen J
(1994)
Feedback control of gene expression.
Photosynth Res
39:
427-438
[CrossRef]
Sheu J-J,
Jan S-P,
Lee H-T,
Yu S-M
(1994)
Control of transcription and mRNA turnover as mechanisms for metabolic repression of alpha-amylase gene expression.
Plant J
5:
655-664
[CrossRef]
Shinozaki K,
Sugiura M
(1982)
The nucleotide sequence of the tobacco chloroplast gene for the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase.
Gene
20:
91-102
[CrossRef][Web of Science][Medline]
Shirley BW,
Meagher RB
(1990)
A potential role for RNA turnover in the light regulation of plant gene expression: ribulose-1,5-bisphosphate carboxylase small subunit in soybean.
Nucleic Acids Res
18:
3377-3386
[Abstract/Free Full Text]
Stitt M
(1991)
Rising CO2 levels and their potential significance for carbon flow in photosynthetic cells.
Plant Cell Environ
14:
741-762
[CrossRef]
Stitt M,
von Schaewen A,
Willmitzer L
(1990)
"Sink" regulation of photosynthetic metabolism in transgenic tobacco plants expressing yeast invertase in their cell wall involves a decrease of the Calvin-cycle enzymes and an increase of glycolytic enzymes.
Planta
183:
40-50
Trethewey RN,
ap Rees T
(1994)
The role of the hexose transporter in the chloroplasts of Arabidopsis thaliana L.
Planta
195:
168-174
Van Oosten J-J,
Besford RT
(1994)
Sugar feeding mimic effect of acclimation to high CO2 rapid down regulation of rubisco small subunit transcripts but not to the large subunit transcripts.
J Plant Physiol
143:
306-312
[Web of Science]
Van Oosten J-J,
Besford RT
(1995)
Some relationships between the gas exchange, biochemistry and molecular biology of photosynthesis during leaf development of tomato plants after transfer to different carbon dioxide concentrations.
Plant Cell Environ
18:
1253-1266
[CrossRef]
Van Oosten J-J,
Wilkins S,
Besford RT
(1994)
Regulation of the expression of photosynthetic nuclear genes by high CO2 is mimicked by carbohydrates: a mechanism for the acclimation of photosynthesis to high CO2.
Plant Cell Environ
17:
913-923
[CrossRef]
von Schaewen A,
Stitt M,
Schmidt R,
Sonnewald U,
Willmitzer L
(1990)
Expression of a yeast-derived invertase in the cell wall of tobacco and Arabidopsis plants leads to accumulation of carbohydrate and inhibition of photosynthesis and strongly influences growth and phenotype of transgenic tobacco plants.
EMBO J
9:
3033-3044
[Web of Science][Medline]
Wanner LA,
Gruissem W
(1991)
Expression dynamics of the tomato rbcS gene family during development.
Plant Cell
3:
1289-1303
[Abstract/Free Full Text]
Webber AN,
Nie GY,
Long SP
(1994)
Effects of rising CO2 concentration on expression of photosynthetic proteins.
Photosynth Res
39:
413-425
[CrossRef]
Winder TL,
Anderson JC,
Spalding MH
(1992)
Translational regulation of the large and small subunits of ribulose bisphosphate carboxylase/oxygenase during induction of the CO2 concentrating mechanism in Chlamydomonas reinhardtii.
Plant Physiol
98:
1409-1414
[Abstract/Free Full Text]
This article has been cited by other articles:
|
|
|
|
 
R. Luo, H. Wei, L. Ye, K. Wang, F. Chen, L. Luo, L. Liu, Y. Li, M. J. C. Crabbe, L. Jin, et al.
Photosynthetic metabolism of C3 plants shows highly cooperative regulation under changing environments: A systems biological analysis
PNAS,
January 20, 2009;
106(3):
847 - 852.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Patel and J. O. Berry
Rubisco gene expression in C4 plants
J. Exp. Bot.,
May 1, 2008;
59(7):
1625 - 1634.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. Tholen, T. L. Pons, L. A.C.J. Voesenek, and H. Poorter
Ethylene Insensitivity Results in Down-Regulation of Rubisco Expression and Photosynthetic Capacity in Tobacco
Plant Physiology,
July 1, 2007;
144(3):
1305 - 1315.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. A. Miklos, M. F. Alibhai, S. A. Bledig, D. C. Connor-Ward, A.-G. Gao, B. A. Holmes, K. H. Kolacz, V. T. Kabuye, T. C. MacRae, M. S. Paradise, et al.
Characterization of Soybean Exhibiting High Expression of a Synthetic Bacillus thuringiensis cry1A Transgene That Confers a High Degree of Resistance to Lepidopteran Pests
Crop Sci.,
January 22, 2007;
47(1):
148 - 157.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Patel, A. J. Siegel, and J. O. Berry
Untranslated Regions of FbRbcS1 mRNA Mediate Bundle Sheath Cell-specific Gene Expression in Leaves of a C4 Plant
J. Biol. Chem.,
September 1, 2006;
281(35):
25485 - 25491.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Araya, K. Noguchi, and I. Terashima
Effects of Carbohydrate Accumulation on Photosynthesis Differ between Sink and Source Leaves of Phaseolus vulgaris L.
Plant Cell Physiol.,
May 1, 2006;
47(5):
644 - 652.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. C. de Groot, R. van den Boogaard, L. F. M. Marcelis, J. Harbinson, and H. Lambers
Contrasting effects of N and P deprivation on the regulation of photosynthesis in tomato plants in relation to feedback limitation
J. Exp. Bot.,
August 1, 2003;
54(389):
1957 - 1967.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
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]
|
|
|
|
|
|
|
J. Sun, K. M. Gibson, O. Kiirats, T. W. Okita, and G. E. Edwards
Interactions of Nitrate and CO2 Enrichment on Growth, Carbohydrates, and Rubisco in Arabidopsis Starch Mutants. Significance of Starch and Hexose
Plant Physiology,
November 1, 2002;
130(3):
1573 - 1583.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Onizuka, H. Akiyama, S. Endo, S. Kanai, M. Hirano, S. Tanaka, and H. Miyasaka
CO2 Response Element and Corresponding trans-acting Factor of the Promoter for Ribulose-1,5-bisphosphate Carboxylase/oxygenase Genes in Synechococcus sp. PCC7002 Found by an Improved Electrophoretic Mobility Shift Assay
Plant Cell Physiol.,
June 15, 2002;
43(6):
660 - 667.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. A. Lake, F. I. Woodward, and W. P. Quick
Long-distance CO2 signalling in plants
J. Exp. Bot.,
February 1, 2002;
53(367):
183 - 193.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
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]
|
|
|
|
|
|
|
D. Jenkins Klus, S. Kalisz, P. S. Curtis, J. A. Teeri, and S. J. Tonsor
Family- and population-level responses to atmospheric CO2 concentration: gas exchange and the allocation of C, N, and biomass in Plantago lanceolata (Plantaginaceae)
Am. J. Botany,
June 1, 2001;
88(6):
1080 - 1087.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. W. Gesch, K. J. Boote, J. C.V. Vu, L. Hartwell Allen Jr, and G. Bowes
Changes in Growth CO2 Result in Rapid Adjustments of Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase Small Subunit Gene Expression in Expanding and Mature Leaves of Rice
Plant Physiology,
October 1, 1998;
118(2):
521 - 529.
[Abstract]
[Full Text]
|
|
|
|
|
Top
Abstract
Introduction