ABA modulates the degradation of phosphoenolpyruvate carboxylase kinase in sorghum leaves

Salt stresses strongly enhance the phosphoenolpyruvate carboxylase kinase (PEPC-k) activity of sorghum leaves. This work shows that (1) abscisic acid (ABA) increased the rise in kinase activity in illuminated leaf disks of the non-stressed plant, (2) ABA decreased the disappearance of PEPC-k activity in the dark, (3) two PEPC-k genes expressed in sorghum leaves, PPCK1 and PPCK2, were not up-regulated by the phytohormone and, (4) ABA effects were mimicked by MG132, a powerful inhibitor of the ubiquitin-proteasome pathway. Collectively these data support a role for the ubiquitin-proteasome pathway in the rapid turnover of PEPC-k. The negative control by ABA on this pathway might account for the increase of kinase activity observed in salt-treated plants.     

pH and carbon supply control the expression of phosphoenolpyruvate carboxylase kinase genes in Arabidopsis thaliana

Phosphoenolpyruvate carboxylase (PEPC) is thought to play many roles in C(3) plants including the provision of biosynthetic precursors and control of pH during N assimilation. Its activity is controlled via phosphorylation catalysed by PEPC kinases, which are encoded by PPCK genes. We examined PPCK expression in response to changes in the supply of N or C, and to changes in intracellular pH, using cultured Arabidopsis cells and seedlings. The results show that expression of both PPCK1 and PPCK2 is increased by C availability, but does not respond to N availability. Expression of the two PPCK genes and the phosphorylation state of PEPC are increased in response to increasing intracellular pH. Elevated pH also reduces the repression of PPCK gene expression by P(i). Expression of phosphoenolpyruvate carboxykinase (PEPCK), which catalyses the decarboxylation of oxaloacetate, is decreased in response to increasing intracellular pH. pH homeostasis may be mediated at least partly by reciprocal changes in the expression of PPCK genes and PEPCK.     

A conserved 19-amino acid synthetic peptide from the carboxy terminus of phosphoenolpyruvate carboxylase inhibits the in vitro phosphorylation of the enzyme by the calcium-independent phosphoenolpyruvate carboxylase kinase

Higher plant phosphoenolpyruvate carboxylase (PEPC) is subject to in vivo phosphorylation of a regulatory serine located in the N-terminal domain of the protein. Studies using synthetic peptide substrates and mutated phosphorylation domain photosynthetic PEPC (C4 PEPC) suggested that the interaction of phosphoenolpyruvate carboxylase kinase (PEPCk) with its target was not restricted to this domain. However, no further information was available as to where PEPCk-C4 PEPC interactions take place. In this work, we have studied the possible interaction of the conserved 19-amino acid C-terminal sequence of sorghum (Sorghum vulgare Pers cv Tamaran) C4 PEPC with PEPCk. In reconstituted assays, a C-terminal synthetic peptide containing this sequence (peptide C19) was found to inhibit the phosphorylation reaction by the partially purified Ca2+-independent PEPCk (50% inhibition of initial activity = 230 microm). This effect was highly specific because peptide C19 did not alter C4 PEPC phosphorylation by either a partially purified sorghum leaf Ca2+-dependent protein kinase or the catalytic subunit of mammalian protein kinase A. In addition, the Ca2+-independent PEPCk was partially but significantly retained in affinity chromatography using a peptide C19 agarose column. Because peptide C15 (peptide C19 lacking the last four amino acids, QNTG) also inhibited C4 PEPC phosphorylation, it was concluded that the amino acid sequence downstream from the QNTG motif was responsible for the inhibitory effect. Specific antibodies raised against peptide C19 revealed that native C4 PEPC could be in two different conformational states. The results are discussed in relation with the reported crystal structure of the bacterial (Escherichia coli) and plant (maize [Zea mays]) enzymes.     

Elevated CO(2) induces biochemical and ultrastructural changes in leaves of the C(4) cereal sorghum

We analyzed the impact of growth at either 350 (ambient) or 700 (elevated) microL L(-1) CO(2) on key elements of the C(4) pathway (photosynthesis, carbon isotope discrimination, and leaf anatomy) using the C(4) cereal sorghum (Sorghum bicolor L. Moench.). Gas-exchange analysis of the CO(2) response of photosynthesis indicated that both carboxylation efficiency and the CO(2) saturated rate of photosynthesis were lower in plants grown at elevated relative to ambient CO(2). This was accompanied by a 49% reduction in the phosphoenolpyruvate carboxylase content of leaves (area basis) in the elevated CO(2)-grown plants, but no change in Rubisco content. Despite the lower phosphoenolpyruvate carboxylase content, there was a 3-fold increase in C isotope discrimination in leaves of plants grown at elevated CO(2) and bundle sheath leakiness was estimated to be 24% and 33%, respectively, for the ambient and elevated CO(2)-grown plants. However, we could detect no difference in quantum yield. The ratio of quantum yield of CO(2) fixation to PSII efficiency was lower in plants grown at elevated CO(2), but only when leaf internal was below 50 microL L(-1). This suggests a reduction in the efficiency of the C(4) cycle when [CO(2)] is low, and also implies increased electron transport to acceptors other than CO(2). Analysis of leaf sections using a transmission electron microscope indicated a 2-fold decrease in the thickness of the bundle sheath cell walls in plants grown at elevated relative to ambient CO(2). These results suggest that significant acclimation to increased CO(2) concentrations occurs in sorghum.     

In vivo phosphorylation of sorghum leaf phosphoenolpyruvate carboxylase

The use of immunological techniques allowed us to purify close to homogeneity phosphoenolpyruvate carboxylase (PEPc, EC 4.1.1.31) from sorghum leaf. It was thus established that: 1) this protein is phosphorylated in vivo on seryl residues; 2) in C4-type photosynthesis, the phosphorylation process mainly concerns the PEPC isozyme form G; 3) enzyme phosphorylation displays significant variations through a day-night alternation which therefore suggests light control of the process.     

C4‐type gene expression is not directly dependent on Kranz anatomy in an amphibious sedge Eleocharis vivipara Link

Eleocharis vivipara Link alters its photosynthetic mode depending on the growth environment. It utilizes C4 photosynthesis when grown under terrestrial conditions (terrestrial form) and C3 photosynthesis when grown under submerged conditions (submerged form). The photosynthetic organ (the mature internodal region of the culm) of the terrestrial form shows typical Kranz anatomy with well-developed bundle sheath cells, while the bundle sheath cells of the submerged form are not developed. In the mature internodal region of the terrestrial form, expression of the genes encoding two carboxylases, the small subunit of ribulose 1,5-bisphosphate carboxylase (RbcS) and phosphoenolpyruvate carboxylase (Ppc), occurred mainly in bundle sheath cells and in mesophyll cells, respectively, as seen in a typical C4 leaf. In the submerged form, RbcS was expressed in both bundle sheath cells and mesophyll cells, and no expression of Ppc was observed. In the immature internodal region with undeveloped bundle sheath cells, both life forms showed the same expression pattern as in C3 plants: RbcS expression was localized in mesophyll cells and no Ppc expression was observed. The C4-type expression pattern was established concomitantly with the development of bundle sheath cells during tissue maturation in the terrestrial internode. In contrast to the terrestrial form, the submerged form maintains C3-type gene expression during tissue maturation. When the terrestrial culm was submerged, a region of transition from the terrestrial form to the submerged form was established in newly sprouting culms. In this transitional region, C4-type expression of the two carboxylase genes was still maintained even though the development of bundle sheath cells was repressed. This observation suggests that the C4-type cell-specific gene expression pattern does not depend on the formation of Kranz anatomy.     

Carbon Sink-to-Source Transition Is Coordinated with Establishment of Cell-Specific Gene Expression in a C4 Plant

Plants that use the highly efficient C4 photosynthetic pathway possess two types of specialized leaf cells, the mesophyll and bundle sheath. In mature C4 leaves, the CO2 fixation enzyme ribulose-1,5-bisphosphate carboxylase (RuBPCase) is specifically compartmentalized to the bundle sheath cells. However, in very young leaves of amaranth, a dicotyledonous C4 plant, genes encoding the large subunit and small subunit of RuBPCase are initially expressed in both photosynthetic cell types. We show here that the RuBPCase mRNAs and proteins become specifically localized to leaf bundle sheath cells during the developmental transition of the leaf from carbon sink to carbon source. Bundle sheath cell-specific expression of RuBPCase genes and the sink-to-source transition began initially at the leaf apex and progressed rapidly and coordinately toward the leaf base. These findings demonstrated that two developmental transitions, the change in photoassimilate transport status and the establishment of bundle sheath cell-specific RuBPCase gene expression, are tightly coordinated during C4 leaf development. This correlation suggests that processes associated with the accumulation and transport of photosynthetic compounds may influence patterns of photosynthetic gene expression in C4 plants.     

Metabolism of epidermal tissues, mesophyll cells, and bundle sheath strands resolved from mature nutsedge leaves

Mesophyll cells and bundle sheath strands were isolated from Cyperus rotundus L. leaf sections infiltrated with a mixture of cellulase and pectinase followed by a gentle mortar and pestle grind. The leaf suspension was filtered through a filter assembly and mesophyll cells and bundle sheath strands were collected on 20-μm and 80-μm nylon nets, respectively. For the isolation of leaf epidermal strips longer leaf cross sections were incubated with the enzymes and gently ground as above. Loosely attached epidermal strips were peeled off with forceps. The upper epidermis, which lacks stomata, could be clearly distinguished from the lower epidermis which contains stomata. Microscopic evidence for identification and assessment of purity is provided for each isolated tissue.Enzymes related to the C₄-dicarboxylic acid cycle such as phosphoenolpyruvate carboxylase, malate dehydrogenase (NADP⁺), pyruvate, P_i dikinase were found to be localized, ≥98%, in mesophyll cells. Enzymes related to operating the reductive pentose phosphate cycle such as RuDP carboxylase, phosphoribulose kinase, and malic enzyme are distributed, ≥99%, in bundle sheath strands. Other photosynthetic enzymes such as aspartate aminotransferase, pyrophosphatase, adenylate kinase, and glyceraldehyde 3-P dehydrogenase (NADP⁺) are quite active in both mesophyll and bundle sheath tissues.Enzymes involved in photorespiration such as RuDP oxygenase, catalase, glycolate oxidase, hydroxypyruvate reductase (NAD⁺), and phosphoglycolate phosphatase are preferentially localized, ≥84%, in bundle sheath strands.Nitrate and nitrite reductase can be found only in mesophyll cells, while glutamate dehydrogenase is present, ≥96%, in bundle sheath strands.Starch- and sucrose-synthesizing enzymes are about equally distributed between the mesophyll and bundle sheath tissues, except that the less active phosphorylase was found mainly in bundle sheath strands. Fructose-1,6-diP aldolase, which is a key enzyme in photosynthesis and glycolysis leading to sucrose and starch synthesis, is localized, ≥90%, in bundle sheath strands. The glycolytic enzymes, phosphoglyceromutase and enolase, have the highest activity in mesophyll cells, while the mitochondrial enzyme, cytochrome c oxidase, is more active in bundle sheath strands.The distribution of total nutsedge leaf chlorophyll, protein, and PEP carboxylase activity, using the resolved leaf components, is presented. ¹⁴CO₂ Fixation experiments with the intact nutsedge leaves and isolated mesophyll and bundle sheath tissues show that complete C₄ photosynthesis is compartmentalized into mesophyll CO₂ fixation via PEP carboxylase and bundle sheath CO₂ fixation via RuDP carboxylase. These results were used to support the proposed pathway of carbon assimilation in C₄-dicarboxylic acid photosynthesis and to discuss the individual metabolic characteristics of intact mesophyll cells, bundle sheath cells, and epidermal tissues.     

Evolution of c4 phosphoenolpyruvate carboxylase. Genes and proteins: a case study with the genus Flaveria

C4 photosynthesis is characterized by a division of labour between two different photosynthetic cell types, mesophyll and bundle-sheath cells. Relying on phosphoenolpyruvate carboxylase (PEPC) as the primary carboxylase in the mesophyll cells a CO2 pump is established in C4 plants that concentrates CO2 at the site of ribulose 1,5-bisphosphate carboxylase/oxygenase in the bundle-sheath cells. The C4 photosynthetic pathway evolved polyphyletically implying that the genes encoding the C4 PEPC originated from non-photosynthetic PEPC progenitor genes that were already present in the C3 ancestral species. The dicot genus Flaveria (Asteraceae) is a unique system in which to investigate the molcular changes that had to occur in order to adapt a C3 ancestral PEPC gene to the special conditions of C4 photosynthesis. Flaveria contains not only C3 and C4 species but also a large number of C3-C4 intermediates which vary to the degree in which C4 photosynthetic traits are expressed. The C4 PEPC gene of Flaveria trinervia, which is encoded by the ppcA gene class, is highly expressed but only in mesophyll cells. The encoded PEPC protein possesses the typical kinetic and regulatory features of a C4-type PEPC. The orthologous ppcA gene of the C3 species Flaveria pringlei encodes a typical non-photosynthetic, C3-type PEPC and is weakly expressed with no apparent cell or organ specificity. PEPCs of the ppcA type have been detected also in C3-C4 intermediate Flaveria species. These orthologous PEPCs have been used to determine the molecular basis for C4 enzyme characteristics and to understand their evolution. Comparative and functional analyses of the ppcA promoters from F. trinervia and F. pringlei make it possible to identity the cis-regulatory sequences for mesophyll-specific gene expression and to search for the corresponding trans-regulatory factors.     

A Ca(2+)-dependent protein kinase phosphorylates phosphoenolpyruvate carboxylase in maize.

In C4 plants the activity of phosphoenolpyruvate carboxylase (PEPC; EC 4.1.1.31) is regulated by phosphorylation/dephosphorylation which is mediated by light/dark signals. The study using protein kinase inhibitors showed that the inhibition pattern of maize PEPC-protein kinase (PEPC-PK) is similar to that of myosin light chain kinase, a Ca(2+)-calmodulin-dependent PK. The kinase activity was also inhibited by EGTA and the inhibition was relieved by Ca2+. These results suggest that PEPC-PK is Ca(2+)-dependent in contrast with previous observations by other research groups.     

In Vivo Regulation of Wheat-Leaf Phosphoenolpyruvate Carboxylase by Reversible Phosphorylation

Regulation of C3 phosphoenolpyruvate carboxylase (PEPC) and its protein-serine/threonine kinase (PEPC-PK) was studied in wheat (Triticum aestivum) leaves that were excised from low-N-grown seedlings and subsequently illuminated and/or supplied with 40 mM KNO3. The apparent phosphorylation status of PEPC was assessed by its sensitivity to L-malate inhibition at suboptimal assay conditions, and the activity state of PEPC-PK was determined by the in vitro 32P labeling of purified maize dephospho-PEPC by [[gamma]-32P]ATP/Mg. Illumination ([plus or minus]NO3-) for 1 h led to about a 4.5-fold increase in the 50% inhibition constant for L-malate, which was reversed by placing the illuminated detached leaves in darkness (minus NO3-). A 1 -h exposure of excised leaves to light, KNO3, or both resulted in relative PEPC-PK activities of 205, 119, and 659%, respectively, of the dark/0 mM KNO3 control tissue. In contrast, almost no activity was observed when a recombinant sorghum phosphorylation-site mutant (S8D) form of PEPC was used as protein substrate in PEPC-PK assays of the light plus KNO3 leaf extracts. In vivo labeling of wheat-leaf PEPC by feeding 32P-labeled orthophosphate showed that PEPC from light plus KNO3 tissue was substantially more phosphorylated than the enzyme in the dark minus-nitrate immunoprecipitates. Immunoblot analysis indicated that no changes in relative PEPC-protein amount occurred within 1 h for any of the treatments. Thus, C3 PEPC activity in these detached wheat leaves appears to be regulated by phosphorylation of a serine residue near the protein's N terminus by a Ca2+ -independent protein kinase in response to a complex interaction in vivo between light and N.