Posttranslational regulation of phosphoenolpyruvate carboxylase in c(4) and crassulacean Acid metabolism plants

Control of C₄ photosynthesis and Crassulacean acid metabolism (CAM) is, in part, mediated by the diel regulation of phosphoenolpyruvate carboxylase (PEPC) activity. The nature of this regulation of PEPC in the leaf cell cytoplasm of C₄ and CAM plants is both metabolite-related and posttranslational. Specificially, the regulatory properties of the enzyme vary in accord with the physiological activity of C₄ photosynthesis and CAM: PEPC is less sensitive to feedback inhibition by l-malate under light (C₄ plants) or at night (CAM plants) than in darkness (C₄) or during the day (CAM). While the view that a light-induced change in the aggregation state of the holoenzyme is a general mechanism for the diel regulation of PEPC activity in CAM plants is currently in dispute, there is no supportive in vivo evidence for such a tetramer/dimer interconversion in C₄ plants. In contrast, a wealth of in vitro and in vivo data has accumulated in support of the view that the reversible phosphorylation of a specific, N-terminal regulatory serine residue in PEPC (e.g. Ser-15 or Ser-8 in the maize or sorghum enzymes, respectively) plays a key, if not cardinal, role in the posttranslational regulation of the carboxylase by light/dark or day/night transitions in both C₄ and CAM plants, respectively.     

Alfalfa Root Nodule Carbon Dioxide Fixation : III. Immunological Studies of Nodule Phosphoenolpyruvate Carboxylase

Antiserum was prepared in rabbits against purified alfalfa (Medicago sativa L.) nodule phosphoenolpyruvate carboxylase (PEPC). Immunotitration assays revealed that the antiserum recognized the enzyme from alfalfa nodules, uninoculated alfalfa roots, and from soybean nodules. Tandem-crossed immunoelectrophoresis showed that the PEPC protein from alfalfa roots and nodules was immunologically indistinguishable. The 101 kilodalton polypeptide subunit of alfalfa nodule PEPC was identified on Western blots. The PEPC polypeptide was detected in low quantities in young alfalfa roots and nodules but was present at increased levels in mature nodules. Senescent nodules appeared to contain a reduced amount of the PEPC polypeptide. PEPC was also detected by western blot in some plant- and bacterially-conditioned ineffective alfalfa nodules but was not detected in bacteroids isolated from effective nodules. Alfalfa nodule PEPC is constitutively expressed in low levels in roots. In nodules, expression of PEPC polypeptide increases several-fold, resulting in increased PEPC activity. Antiserum prepared against the C₄ PEPC from maize leaves recognized the PEPC enzyme in all legume nodules and roots tested, while the antiserum prepared against alfalfa nodule PEPC also recognized the leaf PEPC of several C₄ plant species. Neither antiserum reacted strongly with any C₃ leaf proteins. The molecular weight of the PEPC polypeptide from C₄ leaves and legume nodules appears to be similar.     

Molecular biology of C4 phosphoenolpyruvate carboxylase: Structure,regulation and genetic engineering

Three to four families of nuclear genes encode different isoforms of phosphoenolpyruvate (PEP) carboxylase (PEPC): C₄-specific, C₃ or etiolated, CAM and root forms. C₄ leaf PEPC is encoded by a single gene (ppc) in sorghum and maize, but multiple genes in the C₄-dicot Flaveria trinervia. Selective expression of ppc in only C₄-mesophyll cells is proposed to be due to nuclear factors, DNA methylation and a distinct gene promoter. Deduced amino acid sequences of C₄-PEPC pinpoint the phosphorylatable serine near the N-terminus, C₄-specific valine and serine residues near the C-terminus, conserved cysteine, lysine and histidine residues and PEP binding/catalytic sites. During the PEPC reaction, PEP and bicarbonate are first converted into carboxyphosphate and the enolate of pyruvate. Carboxyphosphate decomposes within the active site into Pi and CO₂, the latter combining with the enolate to form oxalacetate. Besides carboxylation, PEPC catalyzes a HCO₃ ^--dependent hydrolysis of PEP to yield pyruvate and Pi. Post-translational regulation of PEPC occurs by a phosphorylation/dephosphorylation cascade in vivo and by reversible enzyme oligomerization in vitro. The interrelation between phosphorylation and oligomerization of the enzyme is not clear. PEPC-protein kinase (PEPC-PK), the enzyme responsible for phosphorylation of PEPC, has been studied extensively while only limited information is available on the protein phosphatase 2A capable of dephosphorylating PEPC. The C₄ ppc was cloned and expressed in Escherichia coli as well as tobacco. The transformed E. coli produced a functional/phosphorylatable C₄ PEPC and the transgenic tobacco plants expressed both C₃ and C₄ isoforms. Site-directed mutagenesis of ppc indicates the importance of His¹³⁸, His⁵⁷⁹ and Arg⁵⁸⁷ in catalysis and/or substrate-binding by the E. coli enzyme, Ser⁸ in the regulation of sorghum PEPC. Important areas for further research on C₄ PEPC are: mechanism of transduction of light signal during photoactivation of PEPC-PK and PEPC in leaves, extensive use of site-directed mutagenesis to precisely identify other key amino acid residues, changes in quarternary structure of PEPC in vivo, a high-resolution crystal structure, and hormonal regulation of PEPC expression.Abbreviations OAA oxalacetate - PEP phosphoenolpyruvate - PEPC PEP carboxylase - PEPC-PK PEPC-protein kinase - PPDK pyruvate, orthophosphate dikinase - Rubisco ribulose 1,5-bis-phosphate carboxylase/oxygenase - CAM Crassulacean acid metabolism     

In vivo regulatory phosphorylation site in c(4)-leaf phosphoenolpyruvate carboxylase from maize and sorghum

Reversible seryl-phosphorylation contributes to the light/dark regulation of C₄-leaf phosphoenolpyruvate carboxylase (PEPC) activity in vivo. The specific regulatory residue that, upon in vitro phosphorylation by a maize-leaf protein-serine kinase(s), leads to an increase in catalytic activity and a decrease in malate-sensitivity of the target enzyme has been recently identified as Ser-15 in ³²P-phosphorylated/activated dark-form maize PEPC (J-A Jiao, R Chollet [1990] Arch Biochem Biophys 283: 300-305). In order to ascertain whether this N-terminal seryl residue is, indeed, the in vivo regulatory phosphorylation site, [³²P]phosphopeptides were isolated and purified from in vivo ³²P-labeled maize and sorghum leaf PEPC and subjected to automated Edman degradation analysis. The results show that purified light-form maize PEPC contains 14-fold more ³²P-radioactivity than the corresponding dark-form enzyme on an equal protein basis and, more notably, only a single N-terminal serine residue (Ser-15 in maize PEPC and its structural homolog, Ser-8, in the sorghum enzyme) was found to be ³²P-phosphorylated in the light or dark. These in vivo observations, combined with the results from our previous in vitro phosphorylation studies (J-A Jiao, R Chollet [1989] Arch Biochem Biophys 269: 526-535; [1990] Arch Biochem Biophys 283: 300-305), demonstrate that an N-terminal seryl residue in C₄ PEPC is, indeed, the regulatory site that undergoes light/dark changes in phosphorylation-status and, thus, plays a major, if not cardinal role in the light-induced changes in catalytic and regulatory properties of this cytoplasmic C₄-photosynthesis enzyme in vivo.     

Over-expression of phosphoenolpyruvate carboxylase cDNA from C4 millet (Seteria italica) increase rice photosynthesis and yield under upland condition but not in wetland fields

Phosphoenolpyruvate carboxylase (PEPC) catalyzes the initial fixation of CO₂ in C₄ plants. Under the control of the rice Rubisco small subunit promoter, cDNA of a C₄ SiPPC gene cloned from Seteria italica was introduced into Japonica rice by Agrobacterium-mediated transformation. Integration of the gene was confirmed by PCR analysis. RT-PCR showed expression of the gene at the RNA level in transgenic plants, and enzyme activity measurements confirmed the increase in PEPC protein. The transformants showed improvements in both photosynthesis rate and yield only under upland field cultivation. The possible function of PEPC in rice stress tolerance is discussed.     

Photocontrol of sorghum leaf phosphoenolpyruvate carboxylase : characterization of messenger RNA and of photoreceptor

The mechanism underlying the light effect on phosphoenolpyruvate carboxylase (PEPC) from the C₄ plant sorghum (Sorghum vulgare Pers., var Tamaran) leaves was investigated. Following exposure to light a new isozyme of PEPC, specific for the green leaf and responsible for primary CO₂ fixation in photosynthesis, was established. Northern blot experiments revealed the presence of PEPC mRNA showing a molecular weight of 3.4 kilobases. During the greening process, concomitant to enzyme activity, PEPC protein and PEPC messenger RNA amounts increased considerably. This photoresponse was shown to be under phytochrome control.     

Comparative studies of phosphoenolpyruvate carboxylase from c(3) and c(4) plants

Phosphoenolpyruvate carboxylase (PEPC) from several C₃ plants was compared to maize PEPC by immunoblotting using an antibody against maize PEPC and by peptide mapping. In C₃ gramineous plants, PEPCs of slightly different monomeric sizes were detected as two bands for wheat and barley leaves, as three bands for etiolated maize leaves and as four bands for rice leaves by SDS-polyacrylamide gel electrophoresis and immunoblotting, whereas only one PEPC band was detected for maize leaves, a C₄ plant, or tobacco leaves, a dicotyledonous C₃ plant. The peptide fragment patterns of the lower molecular weight PEPC (major band in immunoblotting) in wheat leaves was similar to that of maize PEPC in peptide mapping by protein staining or by immunological detection, but the upper one (minor band) had a different pattern from the lower one in peptide mapping by immunological detection and few peptide fragments from this were recognized by the anti-(maize) PEPC antibody. These results suggest that there are multiple forms of PEPC subunits in the gramineous plants tested, and the major PEPC has a primary structure similar to that of maize PEPC. To obtain information about the expression of PEPCs in C₃ plants, changes in the amount of PEPC protein were investigated during the greening of rice and wheat seedlings. Judging from the regulation by light, there were two types of PEPCs in greening rice seedlings, one induced by light and the other reduced by it. Greening wheat seedlings also show a PEPC band induced by light. These findings indicate that some PEPCs in C₃ gramineous plants not only have structures similar to that of maize PEPC, but also are regulated by light in a similar manner.     

Stimulation by abscisic acid of the activity of phosphoenolpyruvate carboxylase in leaf disks of <Emphasis Type="Italic">Amaranthus hypochondriacus</Emphasis> L., C<Subscript>4</Subscript> plant: role of pH and protein levels

C₄ plants can more efficiently fix carbon in drought, high temperatures, and limitations of nitrogen or CO₂. Primary carboxylation is mediated by phosphoenolpyruvate carboxylase (PEPC, 4.1.1.31) in mesophyll cytosol of C₄ plants. Studies on hormonal regulation of C₄ PEPC have been quite limited. We have examined the activity/regulation of PEPC by abscisic acid (ABA), a plant hormone, in the leaves of Amaranthus hypochondriacus. PEPC activity was enhanced upon 1-h incubation with 20 μM ABA by about 30% in dark and more than 2-fold in light. Glucose-6-phosphate activation of PEPC was enhanced, and sensitivity to l-malate was decreased after ABA treatment. Butyric acid (a weak acid) decreased PEPC activity and restricted the stimulation by ABA. In contrast, methylamine (an alkalinizing agent) increased the PEPC activity and enhanced the effect of ABA. ABA increased the levels of PEPC protein as well as its mRNA. Butyric acid/methylamine modulated the changes induced by ABA of PEPC protein and mRNA levels, indicating that acidification/alkalinization of leaf disks was very important. Our results emphasize the marked modulation of PEPC in C₄ plants, by ABA. Such modulation by ABA could be significant when C₄ plants are under water stress, when ABA is known to accumulate. When present, cycloheximide decreased the PEPC protein levels and restricted the extent of activation by ABA. We conclude that the enhancement by ABA of PEPC activity depends on cellular alkalinization as well as elevated PEPC protein levels.     

Physiological and metabolic enzymes activity changes in transgenic rice plants with increased phosphoenolpyruvate carboxylase activity during the flowering stage

To compare the differences in physiology and metabolism between phosphoenolpyruvate carboxylase (PEPC) transgenic rice and its control, untransformed wild rice, dry matter accumulation, soluble sugar, starch and protein contents and enzyme activities were determined in different plant parts during flowering. Results revealed that PEPC transgenic rice had higher dry weights for leaf, stem and sheath as well as panicle than the untransformed wild rice did, with the largest increase in the panicle. Soluble sugar and protein content in the grains of PEPC transgenic rice were significantly enhanced while starch content changed less. PEPC transgenic rice exhibited high levels of PEPC activity, manifesting in high net photosynthetic rates during flowering. Moreover, transgenic rice with high PEPC expression levels also had elevated levels of the enzymes such as sucrose-p-synthase and sucrose synthase, which may confer a higher capacity to assimilate CO₂ into sucrose. Little increase in grain starch content was observed in transgenic plants due to the stable activities of starch synthase and Q enzyme. However, the PEPC transgenic rice plant induced the activities of nitrate reductase, glutamate oxaloacetate transaminase, glutamate pyruvate transaminase, glutamine synthetase, and asparagine synthase to high levels, as compared with the untransformed rice plant. PEPC activity was correlated with protein content in grains and the enzymes of nitrogen metabolism, suggesting that high PEPC activity in transgenic rice might be able to redirect carbon and nitrogen flow by regulating some enzymes related to carbon or nitrogen metabolisms. These results may help to understand how the C₃ plants possessing a C₄-like photosynthesis pathway worked by expression of PEPC.     

Changes in Properties of Phosphoenolpyruvate Carboxylase with Induction of Crassulacean Acid Metabolism (CAM) in the C4 Plant Portulaca Oleracea

Aiming at understanding the odd case of CAM expression by a C₄ plant, some properties of phosphoenolpyruvate carboxylase (PEPC, EC 4.1.1.31, orthophosphate: oxaloacetate carboxylyase, phosphorylating) were comparatively studied in leaves of CAM-expressing and non-expressing Portulaca oleracea L. plants. CAM expression was induced by growing plants under an 8-h photoperiod and under water-stress. CAM induction in leaves of these plants (designated as CAM) is indicated by the nocturnal acidification and by the clear diurnal oscillation pattern and amplitude of acidity, malic acid, and PEPC activity characteristic of CAM plants. Treatment of the other plant group (designated as C₄) by growth under a 16-h photoperiod and well-watered conditions did not induce expression of the tested criteria of CAM in plants. In these C₄ plants, the mentioned CAM criteria were undetectable. PEPC from CAM and C₄ Portulaca responded differently to any of the studied assay conditions or effectors. For example, extent and timing of sensitivity of PEPC to pH change, inhibition by malate, activation by glucose-6-phosphate or inorganic phosphate, and the enzyme affinity to the substrate PEP were reversed with induction of CAM from the C₄-P. oleracea. These contrasting responses indicate distinct kinetic and regulatory properties of PEPC of the two modes. Thus by shifting to CAM in the C₄ Portulaca a new PEPC isoform may be synthesised to meet CAM requirements. Simultaneous occurrence of both C₄ and CAM is suggested in P. oleracea when challenged with growth under stress. This revised version was published online in August 2006 with corrections to the Cover Date.     

Physical and kinetic properties of photosynthetic phosphoenolpyruvate carboxylase in developing apple fruit

Phosphoenolpyruvate carboxylase (PEPC) was partially purified from young developing apple fruit, cultivars Golden Delicious and Cox's Orange Pippin. Freeze-drying of tissue reduced the yield of PEPC activity compared to samples stored at 4°. Activities measured by H¹⁴CO₃⁻ incorporation exceeded the spectrophotometric assay for the enzyme with coupled NADH-malate dehydrogenase (MDH) by up to 60%. The enzyme could be stored at −16° with glycerol and bovine serum albumin for several months without loss of activity. Thermal inactivation of PEPC occurred after heating to 75° for 3 min when MDH was still slightly active. Inhibition of PEPC activity by endogenous phenolics could be prevented by grinding in liquid nitrogen in the presence of polyvinylpyrrolidine and dithiothreitol. Apparent K_m (PEP) and V_max values compared more favourably with those obtained from a C₃-species (spinach) than from a C₄-species (maize). l-Malate (5 mM) inhibited fruit PEPC by 22%; this was decreased to 12% by addition of glucose-6-phosphate (2 mM). From kinetic and effector experiments PEPC in the apple fruit is concluded to be a non-C₄ photosynthetic enzyme.     

Direct and selective small-molecule inhibition of photosynthetic PEP carboxylase: New approach to combat C4 weeds in arable crops

Phosphoenolpyruvate carboxylase (PEPC) is a key enzyme of C₄ photosynthesis. Besides, non-photosynthetic isoforms of PEPC are found in bacteria and all types of plants, although not in animals or fungi. A single residue in the allosteric feedback inhibitor site of PEPC was shown to adjust the affinity of the photosynthetic and non-photosynthetic isoforms for feedback inhibition by metabolites of the C₄ pathway. Here, we applied computational screening and biochemical analyses to identify molecules that selectively inhibit C₄ PEPC, but have no effect on the activity of non-photosynthetic PEPCs. We found two types of selective inhibitors, catechins and quinoxalines. Binding constants in the lower μM range and a strong preference for C₄ PEPC qualify the quinoxaline compounds as potential selective herbicides to combat C₄ weeds.     

Evolution of the C<Subscript>4</Subscript> phosphoenolpyruvate carboxylase promoter of the C<Subscript>4</Subscript> species <Emphasis Type="Italic">Flaveria trinervia</Emphasis>: the role of the proximal promoter region

Background  

The key enzymes of photosynthetic carbon assimilation in C₄ plants have evolved independently several times from C₃ isoforms that were present in the C₃ ancestral species. The C₄ isoform of phosphoenolpyruvate carboxylase (PEPC), the primary CO₂-fixing enzyme of the C₄ cycle, is specifically expressed at high levels in mesophyll cells of the leaves of C₄ species. We are interested in understanding the molecular changes that are responsible for the evolution of this C₄-characteristic PEPC expression pattern, and we are using the genus Flaveria (Asteraceae) as a model system. It is known that cis-regulatory sequences for mesophyll-specific expression of the ppcA1 gene of F. trinervia (C₄) are located within a distal promoter region (DR).     

Iron supplementation promotes in vitro shoot induction and multiplication of <Emphasis Type="Italic">Baptisia australis</Emphasis>

C₄ plants can efficiently accumulate CO₂ in leaves and thus reduce wasteful oxygen fixation by the RuBisCO enzyme. Three C₄ enzymes, namely carbonic anhydrase (CA), phosphoenol pyruvate (PEPC) and pyruvate orthophosphate dikinase (PPDK), were over expressed in Oryza sativa L. ssp. indica var. Khitish under the control of green tissue specific promoters PD_54o, PEPC and PPDK, respectively. Integration of these genes was confirmed by Southern hybridization. The relative expression of PEPC, CA and PPDK were, respectively, 6.75, 6.57 and 3.6-fold higher in transgenic plants compared to wild type plants (control). Photosynthetic efficiency of the transgenic plants increased significantly along with a 12?% increase in grain yield compared to wild type plants. Compared to control plants, transgenic plants also showed phenotypic changes such as increased leaf blade size, root biomass, and plant height and anatomical changes such as greater leaf vein number, bundle sheath cells, and bulliform cells. Our findings indicate that the combined over expression of these three enzymes is an efficient strategy for incorporating beneficial physiological and anatomical features that will enable subsequent yield enhancement in C₃ rice plants.     

Patterns of phosphoenolpyruvate carboxylase activity and cytosolic pH during light activation and dark deactivation in C3 and C4 plants

The rate and extent of light activation of PEPC may be used as another criterion to distinguish C₃ and C₄ plants. Light stimulated phosphoenolypyruvate carboxylase (PEPC) in leaf discs of C₄ plants, the activity being three times greater than that in the dark but stimulation of PEPC was limited about 30% over the dark-control in C₃ species. The light activation of PEPC in leaves of C₃ plants was complete within 10 min, while maximum activation in C₄ plants required illumination for more than 20 min, indicating that the relative pace of PEPC activation was slower in C₄ plants than in C₃ plants. Similarly, the dark-deactivation of the enzyme was also slower in leaves of C₄ than in C₃ species. The extent of PEPC stimulation in the alkaline pH range indicated that the dark-adapted form of the C₄ enzyme is very sensitive to changes in pH. The pH of cytosol-enriched cell sap extracted from illuminated leaves of C₄ plants was more alkaline than that of dark-adapted leaves. The extent of such light-dependent alkalization of cell sap was three times higher in C₄ leaves than in C₃ plants. The course of light-induced alkalization and dark-acidification of cytosol-enriched cell sap was markedly similar to the pattern of light activation and dark-deactivation of PEPC in Alternanthera pungens, a C₄ plant. Our report provides preliminary evidence that the photoactivation of PEPC in C₄ plants may be mediated at least partially by the modulation of cytosolic pH.Abbreviations CAM Crassulacean acid metabolism - G-6-P glucose-6-phosphate - PMSF phenylmethylsulfonyl fluoride - PEPC phosphoenolpyruvate carboxylase - PEPC-PK phosphoenolpyruvate ca carboxylase-protein kinase     

Modulation in vivo by Nitrate Salts of the Activity and Properties of Phosphoenolpyruvate Carboxylase in Leaves of Alternanthera pungens (C4 plant) and A. sessilis (C3 species)

Feeding K⁺ or Na⁺ nitrate salts in vivo enhanced the activity of phosphoenolpyruvate carboxylase (PEPC) in the leaf extracts of Alternanthera pungens (C₄ plant) and A. sessilis (C₃ species). The increase was more pronounced in A. pungens than in A. sessilis. Chloride salts increased the PEPC activity only marginally. However, the sulfate salts were either not effective or inhibitory. Feeding nitrate modulated the regulatory properties of PEPC in A. pungens, resulting in increased K_I (malate) and decreased K_A (glucose-6-P). The sensitivity of PEPC to malate, which gives a measure of phosphorylation status of the enzyme, indicated that feeding leaves with NO₃ ^– enhanced the phosphorylation status of the enzyme. The reduction in PEPC activity due to cycloheximide treatment suggested that increased synthesis of PEPC protein kinase may be one of the reasons for the enhancement in PEPC activity, after the nitrate feeding. We suggest that nitrate salts could be used as a tool to modulate and analyze the properties of PEPC in C₃ and C₄ plants.     

Kinetic Properties of Phosphoenolpyruvate Carboxylase in Peperomia camptotricha

Kinetic characteristics of phosphoenolpyruvate carboxylase (PEPC) from the epiphytic C₃ or C₄: CAM intermediate plant, Peperomia camptotricha, were investigated. Few day versus night differences in V_max,K_m(PEP)), or malate inhibition were observed, even in extracts from water-stressed plants which characteristically perform CAM, regardless of efforts to stabilize day/night forms. The PEPC extracted from plants during the light period remained stable, without much of an increase or decrease in activity for at least 22 hours at 0 to 4°C. Extracts from mature, fully developed leaves had slightly greater PEPC activity than from very young, developing leaves. Generally, however, the kinetic properties of PEPC extracted from mature leaves of plants grown under short day (SD), long day (LD), or 1-week water-stress conditions, as well as from young, developing leaves, were similar. The PEPC inhibitor, l-malate, decreased the V_max and increased the K_m(PEP) for all treatments. Under specific conditions, malate did not inhibit PEPC rates in the dark extracts as much as the light. The PEPC activator, glucose-6-phosphate (G-6-P), lowered the K_m(PEP) for all treatments. At saturating PEP concentrations, PEPC activity was independent of pH in the range of 7.5 to 9.0. At subsaturating PEP concentrations, the pH optimum was 7.8. The rates of PEPC activity were lower in the light period extracts than the dark, at pH 7.1, but day/night PEPC was equally active at pH 7.8. At pH 7.5 and a subsaturating PEP concentration, G-6-P significantly activated PEPC. At pH 8, however, only slight activation by G-6-P was observed. The lower pH of 7.5 combined with l-malate addition, greatly inhibited PEPC, particularly in extracts from young, developing leaves which were completely inhibited at an l-malate concentration of 1 millimolar. However, malate did not further inhibit PEPC activity in mature leaves when assayed at pH 7.1. The fairly constant day/night kinetic and regulatory properties of PEPC from P. camptotricha are unlike those of PEPC from CAM or C₄ species studied, and are consistent with the photosynthetic metabolism of this plant.     

Light modulation of maize leaf phosphoenolpyruvate carboxylase

Phosphoenolpyruvate carboxylase (PEPC) was extracted from maize (Zea mays L. cv Golden Cross Bantam T51) leaves harvested in the dark or light and was partially purified by (NH₄)₂SO₄ fractionation and gel filtration to yield preparations that were 80% homogeneous. Malate sensitivity, PEPC activity, and PEPC protein (measured immunochemically) were monitored during purification. As reported previously, PEPC from dark leaves was more sensitive to malate inhibition compared to enzyme extracted from light leaves. Extraction and purification in the presence of malate stabilized the characteristics of the two forms. During gel filtration on Sephacryl S-300, all of the PEPC activity and PEPC protein emerged in a single high molecular weight peak, indicating that no inactive dissociated forms (dimers, monomers) were present. However, there was a slight difference between the light and dark enzymes in elution volume during gel filtration. In addition, specific activity (units at pH 7/milligram PEPC protein) decreased through the peak for both enzyme samples; because the dark enzyme emerged at a slightly higher elution volume, it contained enzyme with a relatively lower specific activity. The variation in specific activity of the dark enzyme corresponded with changes in malate sensitivity. Immunoblotting of samples with different specific activity and malate sensitivity, obtained from gel filtration, revealed only a single polypeptide with a relative molecular mass of 100,000. When the enzyme was extracted and purified in the absence of malate, characteristic differences of the light and dark enzymes were lost, the enzymes eluted at the same volume during gel filtration, and specific activity was constant through the peak. We conclude that maize leaf PEPC exists in situ as a tetramer of a single polypeptide and that subtle conformation changes can affect both enzymic activity and sensitivity to malate inhibition.