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Plant Physiol. (1999) 120: 717-726 Simultaneous Expression of NAD-Dependent Isocitrate Dehydrogenase and Other Krebs Cycle Genes after Nitrate Resupply to Short-Term Nitrogen-Starved Tobacco
Institut de Biotechnologie des Plantes, Unité Mixte de la Recherche 8618 Centre National de la Recherche Scientifique, Bât. 630, Université Paris Sud-XI, 91405 Orsay cedex, France (M.L., E.B., P.G., M.H.); and Laboratoire du Métabolisme et de la Nutrition des Plantes, Institut National de la Recherche Agronomique, Route de Saint-Cyr, 78026 Versailles cedex, France (S.F.-M., Y.R., C.M., B.H.)
Mitochondrial NAD-dependent (IDH) and cytosolic NADP-dependent isocitrate dehydrogenases have been considered as candidates for the production of 2-oxoglutarate required by the glutamine synthetase/glutamate synthase cycle. The increase in IDH transcripts in leaf and root tissues, induced by nitrate or NH4+ resupply to short-term N-starved tobacco (Nicotiana tabacum) plants, suggested that this enzyme could play such a role. The leaf and root steady-state mRNA levels of citrate synthase, acotinase, IDH, and glutamine synthetase were found to respond similarly to nitrate, whereas those for cytosolic NADP-dependent isocitrate dehydrogenase and fumarase responded differently. This apparent coordination occurred only at the mRNA level, since activity and protein levels of certain corresponding enzymes were not altered. Roots and leaves were not affected to the same extent either by N starvation or nitrate addition, the roots showing smaller changes in N metabolite levels. After nitrate resupply, these organs showed different response kinetics with respect to mRNA and N metabolite levels, suggesting that under such conditions nitrate assimilation was preferentially carried out in the roots. The differential effects appeared to reflect the C/N status after N starvation, the response kinetics being associated with the nitrate assimilatory capacity of each organ, signaled either by nitrate status or by metabolite(s) associated with its metabolism.
Nitrate and NH4+
assimilation depends on C metabolism for energy, reducing power, and C
skeletons. An important site for the production of critical organic
acids, and perhaps ATP and reductant especially in nongreen tissues, is
the mitochondria. In higher plants the major
NH4+ assimilatory pathway is
carried out in the plastids by the concerted action of GS and GOGAT.
The GS/GOGAT cycle requires the input of an organic acid in the form of
2-OG to produce Glu. However, the presence of several different
2-OG-producing enzymes, as well as their isoenzymatic forms, means that
this substrate is potentially synthesized in a number of subcellular
compartments, including mitochondria, cytosol, and plastids. This
has led to a poor understanding of how 2-OG is provided and how its
provision is regulated for NH4+
assimilation.
In the literature it is often proposed that the 2-OG for the GS/GOGAT
cycle is produced by either an isocitrate dehydrogenase (Gálvez
and Gadal, 1995 The interaction between C and N metabolisms in higher plant cells is
governed by many regulatory factors. This need to coordinate C and N
metabolisms is reflected by the complex interplay between signals
involving C metabolism, such as Suc and light, and those associated
with N metabolism, such as nitrate (Crawford, 1995 The initial aim of this work was to investigate the role of an I(C)DH
in 2-OG supply for amino acid synthesis during nitrate assimilation.
The effect of N supplies (nitrate or ammonium) on I(C)DH transcript
levels when supplied to short-term N-starved tobacco plants was carried
out. It was found that only IDH was affected by both N sources in roots
and leaves. The effect of nitrate resupply was chosen to see if the IDH
changes were coordinated, at the transcript level, with other enzymes
involved in N assimilation and 2-OG production. In this way it was
found that nitrate supply led to a differential but coordinated
response of several genes involved in N and C metabolisms in both roots
and leaves. The analysis of metabolite levels was carried out to
determine the signals involved in the observed simultaneous expression
and to explain the observed differences between roots and leaves.
Plants and Growth Conditions
Isolation of RNA and Northern Analyses Total RNA was extracted according to the method of Chirgwin et al. (1979) and Harpster et al. (1986). Northern analyses were carried out
according to the standard procedures as described previously (Sambrook
et al., 1989) using 20 µg of deveined leaf or root total RNA. DNA
probes were generated, using the DNA fragments described in Table
I, by random priming with the Nonaprimer
kit (Pharmacia) and [32P]dCTP (Amersham).
Specific 3 -noncoding region fragments were generated by PCR
using Taq polymerase (Appligene, Illkirch, France) and the
following oligonucleotide pairs:
TGTCTGGGCAGACAAGAGG/TTGTAATTACGGACCTC and
ATCCTGTAGCACAGAA/AGGATAGATACGCTA, for ICDH1 and mtICDH,
respectively. Hybridization and wash conditions were as described
previously (Gálvez et al., 1996) with final washes from 1× SSC
and 0.2% SDS to 0.2× SSC and 0.2% SDS, depending on the origin of
the probe.
Enzyme Activities Plant material was initially ground to a fine powder in liquid N2 using a mortar and pestle and then further ground in the appropriate extraction buffer with respect to the enzyme activity to be measured. After centrifugation at 20,000g, the supernatant gave the crude extract, which was used for subsequent enzyme activity measurements. ICDH activity was measured spectrophotometrically as the reduction of NADP at 340 nm, as described by Gálvez et al. (1996). Total GS was measured as the
synthetase activity as described previously (O'Neal and Joy, 1973).
GOGAT (Fd/NADH) activity was measured as described previously (Suzuki
and Gadal, 1984) using Fd from spinach leaves or NADH. NR activity
measurements were carried out in the presence of 5 mM EDTA according to the method of
Ferrario-Méry et al. (1997).
Metabolite Measurements Carbohydrates and organic acids were extracted with 1 M perchloric acid and amino acids were extracted with 3% sulfosalycilic acid, both from dry matter of roots and de-veined leaves. Suc, Fru, and Glc were measured in the soluble fraction using the Boerhinger Mannheim Suc/D-Glc/D-Fru test kit, following the manufacturer's instructions. The nitrate content was measured as described by Cataldo et al. (1975), and the ammonium
content was measured as described by Rochat and Boutin (1989). Total
amino acids were quantified by the method of Rosen (1957). Separation
and analysis of amino acids were done by ion-exchange chromatography as
in Rochat and Boutin (1989). Citrate and 2-OG were assayed as described previously (Bergmeyer, 1965).
SDS-PAGE and Western Analysis Crude protein extracts (50 µg) were separated on 12% SDS-polyacrylamide gels according to the method of Laemmli (1970). For western analyses, protein transfer onto nitrocellulose membranes and
immunodetection were performed as in Gálvez et al. (1996), using
a 500-fold dilution of the 33% ammonium sulfate precipitate of the
rabbit antiserum containing IDHa polyclonal antibodies (Lancien et al.,
1998).
Effect of N Supply on Isocitrate Dehydrogenase Steady-State mRNA Levels If a specific isocitrate dehydrogenase produces the 2-OG for NH4+ assimilation, it is possible that the addition of either nitrate or NH4+ to N-starved plants could affect the steady-state mRNA level of this enzyme. Therefore, mRNA levels of IDH and ICDH, taken at various times from roots and deveined leaves after the resupply of either 10 mM nitrate or 10 mM ammonium to aeroponically grown 4-d N-starved tobacco plants, were analyzed by northern blot. Figure 1 shows the effect of the above-mentioned treatments on the mRNA levels of IDH, ICDH1, and mtICDH. To distinguish the two different ICDH mRNAs, specific 3-noncoding region probes were
used as described in ``Materials and Methods''. To investigate IDH
expression a NtIDHa probe was used, which encodes the
catalytic IDH subunit shown to be necessary for IDH activity (Lancien
et al., 1998). In the experiment shown in Figure 1, nitrate supply led
to a significant increase in IDHa mRNA steady-state levels only in the
roots (similar changes have also been reported for IDHb and IDHc
regulatory subunit mRNA; Lancien et al., 1998). This was seen in the
roots and deveined leaves when
NH4+ was given to the plants,
although the response was slower in the roots when compared with
nitrate addition. In contrast, nitrate did not affect ICDH1 and mtICDH
mRNA levels (Fig. 1), whereas the addition of
NH4+ gave rise to an increase in
ICDH1 (only in the roots) and mtICDH (only in the leaves) transcript
levels. Since only the IDH steady-state mRNA level was affected by the
addition of the two different inorganic N supplies, IDH appeared to be
a good candidate for the production of 2-OG with respect to N
assimilation.
Differential but Coordinated Expression of Some Genes Encoding Enzymes Involved in C or N Metabolisms between Roots and Leaves during Nitrate Resupply The effect of nitrate resupply to 4-d N-starved tobacco plants was investigated in roots (Fig. 2) and deveined leaves (Fig. 3) by northern analyses using DNA probes for N-assimilatory enzymes (NR and GS), certain Krebs cycle and putative organic acid pathway enzymes (IDH, CS, ACO, FUM, and ICDH1).
The Effect of N Starvation on Plant Metabolism It is interesting to note that N starvation already affected the roots and the leaves to different extents with respect to N- and C-containing metabolites. As expected, the 4-d treatment caused a drastic decrease in stored endogenous nitrate in both leaves and roots (Fig. 4), leading to undetectable levels in the leaves, whereas a small amount remained in the roots. In general, leaves showed a larger decrease in the content of measured amino acids than roots. This was particularly pronounced for Gln, Asp, Asn, and Ser (compare leaves and roots in Fig. 5). On the other hand, the roots showed a greater increase in sugar levels, especially Suc and Fru (Fig. 6). N starvation also resulted in a differential response with respect to the 2-OG pool, since it increased in the leaves but decreased in the roots (Fig. 6).
A Differential Effect of Nitrate Supply on N Metabolism between
Leaves and Roots
A Differential Effect of Nitrate Supply on C Metabolism between Leaves and Roots The resupply of N-starved plants with nitrate also led to a differential response between the roots and the leaves with respect to organic acid levels and to a lesser extent with respect to sugar content (Fig. 6). After nitrate supply, the citrate content slowly increased, whereas 2-OG levels decreased in the leaf tissues, both reaching the control plant levels. However, in the roots citrate and 2-OG contents decreased to levels lower than the control plants. Nitrate addition also led to a decrease in Glc and Fru levels in both roots and leaves; in all cases the level remained higher than in the control plants. A differential effect between the roots and leaves was observed for the Suc content that stayed at the nonstarved level in the leaves but remained higher than the control level in the roots. IDH protein content (Fig. 8) and total ICDH activity (Fig. 7) were unchanged after nitrate resupply, staying at the control plant level in both leaves and roots.
2-OG Production for N Assimilation The hypothesis that cytosolic ICDH plays an important role in the production of C skeletons for NH4+ assimilation (Chen and Gadal, 1990) has recently been supported indirectly by several
observations. These include an increase in ICDH1 transcript levels and
2-OG levels by the addition of nitrate to NR tobacco mutants (Scheible
et al., 1997) and increased ICDH1 transcript levels in detached potato
leaves fed with nitrate (Fieuw et al., 1995). However, in the first
case (Scheible et al., 1997), the ICDH activity was not measured, and
in the second example, the changes in transcript levels could not be
correlated with the measured ICDH activity (Fieuw et al., 1995). In
this work the addition of 10 mM nitrate to 4-d N-starved
tobacco plants did not give rise to significant increases in leaf ICDH1
transcript levels (Figs. 1 and 2), although root ICDH1 mRNA
occasionally showed a slow increase (Fig. 2). However, in both organs
total ICDH activity did not change after nitrate resupply (Fig. 7). The
apparent contradiction with the above-mentioned works could be
explained by the different experimental models/conditions used.
Differential Response between the Roots and Leaves The experimental conditions used in this work provoked a differential response between the roots and the leaves both during the N-starvation period and after the addition of nitrate. First, the withdrawal of N supply led to less-pronounced changes in N-containing metabolite levels in the roots than in the leaves; this was seen for nitrate, NH4+, and amino acid contents (Figs. 4 and 5). It seemed that leaf N metabolism was down-regulated and export of N-containing compounds to the roots was up-regulated by the N stress. As a consequence, such changes would favor root growth under "N-limiting" conditions. It has already been shown that a moderate N deficiency stimulates root growth (Agren and Ingestad, 1987). It has been suggested that under such conditions
root growth would be selectively stimulated by a regulation of
shoot/root allocation and that roots would recruit more amino acids,
which have been shown to cycle between the leaves and the roots (Cooper
and Clarkson, 1989). Under our experimental conditions the root
contained higher sugar levels both after and during the N-starvation
period. Such changes could reflect the requirement of an increased
Krebs cycle activity to sustain cell metabolic functions, including
organic acid synthesis for N-metabolism. The decrease in the root 2-OG
level could be explained by an increased demand for C skeletons for N
assimilation. On the other hand, the increase in leaf 2-OG levels after
N starvation might reflect the observed decrease in nitrate
assimilatory capacity. Therefore, the level of 2-OG seems to reflect
the changes in N assimilatory capacity and C/N status in the different
organs. Perhaps, the 2-OG content, alone or in association with a N
compound like the Gln, allows the cell to sense the C/N status and
signal the need to regulate/coordinate C and N metabolic pathways. Such a signaling pathway is well documented in bacteria in which Gln and
2-OG levels regulate the so-called two-component system (Jiang et al.,
1997).
* Corresponding author; e-mail hodges{at}sidonie.ibp.u-psud.fr; fax 33-1-69-33-64-23. Received October 26, 1998;
accepted March 24, 1999.
Abbreviations: 2-OG, 2-oxoglutarate. ACO, aconitase. CS, citrate synthase. FUM, fumarase. GS(1/2), Gln synthetase (cytosolic/chloroplastic). ICDH(1), NADP-dependent isocitrate dehydrogenase (cytosolic). IDH, NAD-dependent isocitrate dehydrogenase. mtICDH, mitochondrial ICDH. NR, nitrate reductase.
The authors would like to thank Dr. Bernd Müller-Röber (Max-Planck-Institut für Molekulare Pflanzenphysiologie, Golm, Germany) and Dr. Christian Meyer (Institut National de la Recherche Agronomique [INRA], Versailles, France) for making available certain cDNA probes, Dr Akira Suzuki (INRA) for his help in measuring GOGAT activities, and R. Boyer (Institut de Biotechnologie des Plantes, Université Paris-Sud, Orsay, France) for his excellent photographic skills.
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Top
Abstract
Introduction
2
s
80°C.
ketoglutarate.
In HU Bergmeyer, ed, Methods of Enzymatic Analysis. Academic
Press, New York, pp 318-334