Cold stability of pyruvate,orthophosphate dikinase of Flaveria brownii

The nucleotide sequences of the complementary DNA of pyruvate, P_i dikinase (PPDK) from Flaveria bidentis, a C₄ plant which possesses a cold-sensitive form of PPDK, and Flaveria brownii, a C₄-like plant which possesses a cold-tolerant form of PPDK, were determined. PPDK was isolated from the leaves of both Flaveria species and purified and the N-terminal amino acid sequences characterised. Together with a maize PPDK cDNA, cDNA inserts which code for the mature form of PPDK of F. bidentis and of F. brownii were expressed in bacteria and the cold sensitivity of the expressed PPDK studied. The cold sensitivity of the PPDK expressed in bacteria mimics the cold sensitivity of PPDK found in vivo in all three plant species. This study indicates that the cold sensitivity of plant PPDK is controlled by the primary structure of the enzyme.     

High-Level Expression of Cold-Tolerant Pyruvate, Orthophosphate Dikinase from a Genomic Clone with Site-Directed Mutations in Transgenic Maize

Pyruvate, orthophosphate dikinase (PPDK) is a key enzyme in the C₄ photosynthetic pathway of maize. To improve the cold tolerance of the enzyme in maize, we designed two genomic sequence-based constructs in which the carboxy-terminal region of the enzyme was modified to mimic the amino acid sequence of the cold-tolerant PPDK of Flaveria brownii (Asteraceae). A large amount of PPDK was found to have accumulated in the leaves of many of the maize plants transformed with one of these constructs – that which introduced 17 amino acid substitutions without any alteration of the exon-intron structure – although there was a wide range of variation in the amount of PPDK among the separate plants. In contrast, the production was much less in maize transformed with the second construct in which a cDNA fragment for the same carboxy-terminal region was inserted. The specific activity of PPDK in the plants transformed with the gene with the amino acid substitutions was inversely correlated with the amount of enzyme in the leaves. In addition, the activity of the cold-tolerant recombinant enzyme was judged to be regulated by the PPDK regulatory protein, similar to that of the native PPDK. The cold tolerance of PPDK in crude leaf extracts was greatly improved in plants that produced a large amount of the engineered PPDK. The photosynthetic rate at 8°C increased significantly (by 23%, p<0.05), but there was no obvious effect at higher temperatures. These results support the hypothesis that PPDK is one of the limiting factors in the C₄ photosynthesis of maize under cold conditions.     

Comparative effects of growth irradiance on photosynthesis and leaf anatomy of Flaveria brownii (C4-like), Flaveria linearis (C3–C4) and their F1 hybrid

Photosynthetic rates and related anatomical characteristics of leaves developed at three levels of irradiance (1200, 300 and 80 umol · m^–2 · s^–1) were determined in the C₄-like species Flaveria brownii A.M. Powell, the C₃–C₄-intermediate species F. linearis Lag., and the F₁ hybrid between them (F. brownii × F. linearis). In the C₃–C₄ and F₁ plants, increases in photosynthetic capacity per unit leaf area were strongly correlated with changes in mesophyll area per unit leaf area. The C₄-like plant F. brownii, however, showed a much lower correlation between photosynthetic capacity and mesophyll area per unit leaf area. Plants of F. brownii developed at high irradiance showed photosynthetic rates per unit of mesophyll cell area 50% higher than those plants developed at medium irradiance. These results along with an increase in water-use efficiency are consistent with an increase of C₄ photosynthesis in high-irradiance-grown F. brownii plants, whereas in the other two genotypes such plasticity seems to be absent. Photosynthetic discrimination against ¹³C in the three genotypes was less at high than at low irradiance, with the greatest change occurring in F. brownii. Discrimination against ¹³C expressed as ¹³C was linearly correlated (r ² = 0.81; P<0.001) with the ratio of bundle-sheath volume to mesophyll cell area when all samples from the three genotypes were combined. This tissue ratio increased for F. brownii and the F₁ hybrid as growth irradiance increased, indicating a greater tendency towards Kranz anatomy. The results indicated that F. brownii had plasticity in its C₄-related anatomical and physiological characteristics as a function of growth irradiance, whereas plasticity was less evident in the F₁ hybrid and absent in F. linearis.Abbreviations A leaf surface area - A_ma, A_mn, A_lm total ma, mn or lm cell surface area - bs vascular bundle sheath - lm large spongy-mesophyll cells - ma mesophyll cells adjacent to bundle sheath - mn mesophyll cells not adjacent to bundle sheath - P_n net photosynthesis - (H, M, L) PPFD (high, medium, low) photosynthetic photon flux density - SLDW specific leaf dry wight - V_bs bs volume - V_{(ma + mn + bs)} total photosynthetic tissue volume - ¹³C ¹³C discrimination We thank Mrs. Lisa Smith for technical assistance in light microscopy and Dr. Ned Friedman (Department of Botany, University of Georgia, Athens, GA, USA) for the use of digitizing equipment. Participation of Dr. J.L. Araus in this work was supported by a grant Beca de Especialización para Doctores y Tecnólogos en el Extranjero, from Ministerio de Educatión y Ciencia, Spain.     

Maize recombinant C4-pyruvate,orthophosphate dikinase: Expression in Escherichia coli, partial purification, and characterization of the phosphorylatable protein

The gene for C₄-pyruvate,orthophosphate dikinase (PPDK) from maize (Zea mays) was cloned into an Escherichia coli expression vector and recombinant PPDK produced in E. coli cells. Recombinant enzyme was found to be expressed in high amounts (5.3 U purified enzyme-activity liter^-1 of induced cells) as a predominantly soluble and active protein. Biochemical analysis of partially purified recombinant PPDK showed this enzyme to be equivalent to enzyme extracted from illuminated maize leaves with respect to (i) molecular mass, (ii) specific activity, (iii) substrate requirements, and (iv) phosphorylation/inactivation by its bifunctional regulatory protein.Abbreviations DTT- dithiothreitol - FPLC- fast-protein liquid chromatography - HAP- hydroxyapatite - IPTG- isopropyl--thiogalactoside - MOPS- 3-(N-morpholino)propanesulfonic acid - PCR- polymerase chain reaction - PEP- phosphoenolpyruvate - PMSF- phenylmethylsufonyl fluoride - PPDK- pyruvate,orthophosphate dikinase - RP- regulatory protein     

Pyruvate orthophosphate dikinase of c(3) seeds and leaves as compared to the enzyme from maize

Pyruvate orthophosphate dikinase (PPDK) was found in various immature seeds of C₃ plants (wheat, pea, green bean, plum, and castor bean), in some C₃ leaves (tobacco, spinach, sunflower, and wheat), and in C₄ (maize) kernels. The enzyme in the C₃ plants cross-reacts with rabbit antiserum against maize PPDK. Based on protein blot analysis, the apparent subunit size of PPDK from wheat seeds and leaves and from sunflower leaves is about 94 kdaltons, the same as that of the enzyme from maize, but is slightly less (about 90 kdaltons) for the enzyme from spinach and tobacco leaves. The amount of this enzyme per mg of soluble protein in C₃ seeds and leaves is much less than in C₄ leaves. PPDK is present in kernels of the C₄ plant, Zea mays in amounts comparable to those in C₄ leaves.

Regulatory properties of the enzyme from C₃ tissues (wheat) are similar to those of the enzyme from C₄ leaves with respect to in vivo light activation and dark inactivation (in leaves) and in vivo cold lability (seeds and leaves).

Following incorporation of ¹⁴CO₂ by illuminated wheat pericarp and adjoining tissue for a few seconds, the labeled metabolites were predominantly products resulting from carboxylation of phosphoenolpyruvate, with lesser labeling of compounds formed by carboxylation of ribulose 1,5-bisphosphate and operation of the reductive pentose phosphate cycle of photosynthesis. PPDK may be involved in mechanisms of amino acid interconversions during seed development.

     

Maize recombinant non-C<Subscript>4</Subscript> NADP-malic enzyme: A novel dimeric malic enzyme with high specific activity

Among the different isoforms of NADP-malic enzyme (NADP-ME) involved in a wide range of metabolic pathways in plants, the NADP-ME that participates in C₄-photosynthesis is the most studied. In the present work, the expression in E. coli of a cDNA encoding for a maize non-photosynthetic NADP-ME is presented. The recombinant NADP-ME thus obtained presents kinetic and structural properties different from the enzyme previously purified from etiolated leaves and roots. Moreover, the recombinant non-photosynthetic NADP-ME presents very high intrinsic NADP-ME activity, which is unexpected for a non-C₄ NADP-ME. Using antibodies against this recombinant enzyme, an immunoreactive band of 66 kDa is detected in different maize tissues indicating that the 66 kDa-NADP-ME is in fact a protein expressed invivo. The recombinant NADP-ME assembles as a dimer, although the results obtained indicate that a higher molecular mass oligomeric state of the enzyme is found in maize roots in vivo. In this way, maize presents at least three NADP-ME isoforms: a 72 kDa constitutive form (previously characterized); the novel non-photosynthetic 66 kDa isoform characterized in this work (which is the product of the ZmChlMe2gene and the likely precursor to the evolution of the photosynthetic C₄ NADP-ME) and the 62 kDa isoform (implicated in C₄ photosynthesis). The contribution of the present work anticipates further studies concerning the equilibrium between the oligomeric states of the NADP-ME isoforms and the evolution towards the C₄ isoenzyme in maize.     

Synthesis and uptake of cytoplasmically synthesized pyruvate, pi dikinase polypeptide by chloroplasts

Polyadenylated RNA was isolated from maize leaves and translated in vitro. In agreement with a previous report by others, we found among the translation products a 110-kilodalton pyruvate orthophosphate dikinase (PPDK) precursor that is about 16 kilodaltons larger than the polypeptide isolated from cells. This maize PPDK precursor polypeptide was taken up from the translation product mixture by intact spinach chloroplasts and yielded a mature PPDK polypeptide (94 kilodaltons). The uptake and processing support the proposal that the extra 16-kilodalton size of the polypeptide from in vitro translation of maize leaf mRNA represents a transit sequence which is cleaved after its entry into chloroplasts. Moreover, these results provide additional evidence that in vivo in maize leaf cells PPDK polypeptide is synthesized in the cytoplasm and is transported into the chloroplasts.

Location of PPDK in C₃ plant leaves was investigated by immunochemical analysis. Intact chloroplasts were isolated from leaves of spinach, wheat, and maize. A protein blot of stromal protein in each case gave rise to bands corresponding to authentic PPDK polypeptide. This result indicates that PPDK is present in chloroplasts of C₃ plant leaves as it is in the case of C₄ plants.

     

Posttranslational regulation of pyruvate, orthophosphate dikinase in developing rice (Oryza sativa) seeds

Pyruvate, orthophosphate dikinase (PPDK; E.C.2.7.9.1) is most well known as a photosynthetic enzyme in C₄ plants. The enzyme is also ubiquitous in C₃ plant tissues, although a precise non-photosynthetic C₃ function(s) is yet to be validated, owing largely to its low abundance in most C₃ organs. The single C₃ organ type where PPDK is in high abundance, and, therefore, where its function is most amenable to elucidation, are the developing seeds of graminaceous cereals. In this report, we suggest a non-photosynthetic function for C₃ PPDK by characterizing its abundance and posttranslational regulation in developing Oryza sativa (rice) seeds. Using primarily an immunoblot-based approach, we show that PPDK is a massively expressed protein during the early syncitial-endosperm/-cellularization stage of seed development. As seed development progresses from this early stage, the enzyme undergoes a rapid, posttranslational down-regulation in activity and amount via regulatory threonyl-phosphorylation (PPDK inactivation) and protein degradation. Immunoblot analysis of separated seed tissue fractions (pericarp, embryo + aleurone, seed embryo) revealed that regulatory phosphorylation of PPDK occurs in the non-green seed embryo and green outer pericarp layer, but not in the endosperm + aleurone layer. The modestly abundant pool of inactive PPDK (phosphorylated + dephosphorylated) that was found to persist in mature rice seeds was shown to remain largely unchanged (inactive) upon seed germination, suggesting that PPDK in rice seeds function in developmental rather than in post-developmental processes. These and related observations lead us to postulate a putative function for the enzyme that aligns its PEP to pyruvate-forming reaction with biosynthetic processes that are specific to early cereal seed development.     

Expression of a C3 plant Rubisco SSU gene in regenerated C4 Flaveria plants

We report the successful transformation, via Agrobacterium tumefaciens infection, and regeneration of two species of the genus Flaveria: F. brownii and F. palmeri. We document the expression of a C₃ plant gene, an abundantly expressed ribulose 1,5-bisphosphate carboxylase/oxygenase small subunit gene isolated from petunia, in these C₄ plants. The organ-specific expression of this petunia gene in Flaveria brownii is qualitatively identical to its endogenous pattern of expression.     

Effects of temperature on the regulation of photosynthetic carbon assimilation in leaves of maize and barley

The aim of this work was to examine the effect of temperature in the range 5 to 30 ° C upon the regulation of photosynthetic carbon assimilation in leaves of the C₄ plant maize (Zea mays L.) and the C₃ plant barley (Hordeum vulgare L.). Measurements of the CO₂-assimilation rate in relation to the temperature were made at high (735 bar) and low (143 bar) intercellular CO₂ pressure in barley and in air in maize. The results show that, as the temperature was decreased, (i) in barley, pools of phosphorylated metabolites, particularly hexose-phosphate, ribulose 1,5-bisphosphate and fructose 1,6-bisphosphate, increased in high and low CO₂; (ii) in maize, pools of glycerate 3-phosphate, triose-phosphate, pyruvate and phosphoenolpyruvate decreased, reflecting their role in, and dependence on, intercellular transport processes, while pools of hexose-phosphate, ribulose 1,5-bis phosphate and fructose 1,6-bisphosphate remained approximately constant; (iii) the redox state of the primary electron acceptor of photosystem II (Q_A) increased slightly in barley, but rose abruptly below 12° C in maize. Non-photochemical quenching of chlorophyll fluorescence increased slightly in barley and increased to high values below 20 ° C in maize. The data from barley are consistent with the development of a limitation by phosphate status at low temperatures in high CO₂, and indicate an increasing regulatory importance for regeneration of ribulose 1,5-bisphosphate within the Calvin cycle at low temperatures in low CO₂. The data from maize do not show that any steps of the C₄ cycle are particularly cold-sensitive, but do indicate that a restriction in electron transport occurs at low temperature. In both plants the data indicate that regulation of product synthesis results in the maintenance of pools of Calvin-cycle intermediates at low temperatures.Abbreviations Glc6P glucose-6-phosphate - Fru6P fructase-6-phosphate - Frul,6bisP fructose-1,6-bisphosphate - PGA glycerate-3-phosphate - p _i intercellular partial pressure of CO₂ - RuBP ribulose-1,5-bisphosphate - triose-P sum of glyceraldehyde-3-phosphate and dihydroxyacetone phosphate We thank the Agricultural and Food Research Council, UK (Research grant PG50/67) and the Science and Engineering Research Council, UK for financial support. C.A.L. was supported by the British Council, by the Conselho Nacional de Desenvolvimento Cientiflco e Tecnologico (CNPq), Brazil and by an Overseas Research Student Award. We also thank Mark Stitt (Bayreuth, FRG) and Debbie Rees for helpful discussions.     

Posttranslational Modification of Maize Chloroplast Pyruvate Orthophosphate Dikinase Reveals the Precise Regulatory Mechanism of Its Enzymatic Activity

In C₄ plants, pyruvate orthophosphate dikinase (PPDK) activity is tightly dark/light regulated by reversible phosphorylation of an active-site threonine (Thr) residue; this process is catalyzed by PPDK regulatory protein (PDRP). Phosphorylation and dephosphorylation of PPDK lead to its inactivation and activation, respectively. Here, we show that light intensity rather than the light/dark transition regulates PPDK activity by modulating the reversible phosphorylation at Thr-527 (previously termed Thr-456) of PPDK in maize (Zea mays). The amount of PPDK (unphosphorylated) involved in C₄ photosynthesis is indeed strictly controlled by light intensity, despite the high levels of PPDK protein that accumulate in mesophyll chloroplasts. In addition, we identified a transit peptide cleavage site, uncovered partial amino-terminal acetylation, and detected phosphorylation at four serine (Ser)/Thr residues, two of which were previously unknown in maize. In vitro experiments indicated that Thr-527 and Ser-528, but not Thr-309 and Ser-506, are targets of PDRP. Modeling suggests that the two hydrogen bonds between the highly conserved residues Ser-528 and glycine-525 are required for PDRP-mediated phosphorylation of the active-site Thr-527 of PPDK. Taken together, our results suggest that the regulation of maize plastid PPDK isoform (C₄PPDK) activity is much more complex than previously reported. These diverse regulatory pathways may work alone or in combination to fine-tune C₄PPDK activity in response to changes in lighting.Pyruvate orthophosphate dikinase (PPDK) is an abundant mesophyll-chloroplast enzyme involved in C₄ photosynthesis. It plays an essential role in regenerating phosphoenolpyruvate (PEP), the primary cellular CO₂ acceptor molecule. PPDK activity strongly correlates (r = 0.96) with the photosynthetic rate (Edwards et al., 1985). Therefore, PPDK may limit the rate of CO₂ assimilation in the C₄ cycle (Hatch, 1987). PPDK regulatory protein (PDRP), a unique bifunctional enzyme, catalyzes this light-dependent regulation by reversible phosphorylation of an active-site Thr in PPDK (Thr-527 in maize [Zea mays] in full amino acid sequence [http://www.maizegdb.org]; previously termed Thr-456; Ashton and Hatch, 1983; Burnell and Hatch, 1985; Roeske and Chollet, 1987; Ashton et al., 1990; Burnell, 1990; Chastain et al., 2000, 2011). PDRP is an unusual regulatory protein for three reasons (Chastain et al., 1997, 2008; Burnell and Chastain, 2006; Astley et al., 2011): (1) it is bifunctional, catalyzing both PPDK activation/dephosphorylation and PPDK inactivation/phosphorylation; (2) it uses ADP instead of ATP as the phosphoryl donor; and (3) it employs an inorganic phosphate-dependent, inorganic pyrophosphate-forming dephosphorylation mechanism as opposed to the simple hydrolysis mechanism common to most protein phosphatases.The functional properties of PDRP have been examined by selective substitutions at His-458 and active-site Thr-456 in the maize plastid PPDK isoform (C₄PPDK; Ashton and Hatch, 1983; Burnell and Hatch, 1984, 1985). These studies confirmed that PDRP is a Ser/Thr kinase that requires a phosphorylated His in the target enzyme (Burnell and Hatch, 1986). This regulatory threonyl phosphorylation of PPDK is a monocyclic cascade (Stadtman and Chock, 1977) in which the covalent modification system is assumed to be a continuous process that allows the extent of PPDK activation to be attuned to the metabolic needs (Roeske and Chollet, 1989). Therefore, PDRP can alter the activation state of its target enzyme, PPDK, according to the concentrations of metabolites (e.g. ADP, inorganic phosphate, pyruvate, and PEP) involved in the regulatory cycle. In addition, PPDK activity also can be modulated by Mg²⁺ and temperature (Hatch and Slack, 1968; Wang et al., 2008).In all plants, PPDK is located in both cytoplasmic and plastid compartments (Chastain and Chollet, 2003). Regulation of the bidirectional activities of C₄PPDK has been proposed to be the consequence of light/dark-mediated changes in the stromal ADP level via its action as a potent competitive inhibitor of the PDRP phospho-PPDK dephosphorylation function (Burnell and Hatch, 1985; Chastain et al., 2011). However, GDP can serve as a substrate for the regulatory phosphorylation of the cytoplasmic PPDK isoform (Chastain et al., 2011). Two genes that encode chloroplastic (RP1) and cytosolic (RP2) isoforms of PDRP have been identified in the C₃ plant Arabidopsis (Arabidopsis thaliana). Both of them have kinase and phosphotransferase activities, although RP2 catalyzes PPDK dephosphorylation at a slower rate than does RP1 (Chastain et al., 2008; Astley et al., 2011). Bacterial genomic databases show that PDRP homologs, referred to as Domain of Unknown Function299 (DUF299) genes, are present in all PPDK-containing bacteria (Burnell, 2010). In Escherichia coli, which lacks PPDK, DUF299 regulates the on/off activity of phosphoenolpyruvate synthetase (PEPS) via reversible phosphorylation of the PEPS active-site Thr (Burnell, 2010). This specific target Thr residue for PDRP in C₄PPDK is highly conserved in all dikinases from C₃ angiosperms and prokaryotes that have been examined (Rosche et al., 1994; Fisslthaler et al., 1995; Agarie et al., 1997; Imaizumi et al., 1997; Wei et al., 2000). Taken together, these results suggest that this regulatory threonyl phosphorylation of the PPDK is a very ancient mechanism. This notion implies a common evolutionary pathway for C₄ photosynthesis facilitated by the preexistence of homologs of C₄ enzymes in C₃ plants (Edwards et al., 2001; Hibberd and Quick, 2002; Wang et al., 2009). The most significant adaptation for the enzyme to be utilized in C₄ photosynthesis may have already occurred well before the emergence of the pathway in modern angiosperms (Chastain et al., 2011).A previous empirical study showed that PPDK activity is insensitive to variations in PPDK level when a cold-tolerant ppdk is inserted into the genome of maize (Ohta et al., 2006). Enzyme activity measurements were performed on 48 strains, each with a different PPDK expression level, showing that there was only about a 20% change in the PEP formation rate despite a 5.7-fold variation in PPDK level. A similar phenomenon was also observed in transgenic rice (Oryza sativa) leaves, in which maize PPDKs accumulated at very high levels but failed to activate fully, even after 14 h of illumination and complete inactivation in darkness (Taniguchi et al., 2008). These findings suggest that the mechanism for regulating PPDK is far more complicated than previously thought. It is not known whether all or only part of the PPDK that accumulates in mesophyll chloroplasts is required for C₄ photosynthesis, because the protein level does not affect its enzyme activity. If it is only a select portion of PPDK that is required, then it is also unknown how light regulates the amount of PPDK involved in C₄ photosynthesis.To address these issues, we created a comprehensive profile of PPDK posttranslational modifications. We identified the cleavage site of the transit peptide, its N-terminal acetylated form, and four phosphorylated residues. We found that it is not the light/dark transition per se but rather a change in light intensity that regulates PPDK activity by modulating reversible phosphorylation at Thr-527. Importantly, we also partially determined the catalytic mechanism of PDRP. Taken together, these results suggest that the mechanisms via which PPDK is regulated are more complex than previously described (Ashton and Hatch, 1983; Chastain et al., 2000) and provide a foundation for studies on the molecular mechanism of PPDK regulation in the C₄ pathway.     

A simple,single-tube radioisotopic assay for the phosphorylation/inactivation activity of the pyruvate,orthophosphate dikinase regulatory protein

A simple, single-tube radiolsotopic method has been developed to assay the relative phosphorylation (inaetivation) activity of the bifunctional regulatory protein (RP) of C₄-leaf pyruvate,orthophosphate dikinase (PPDK) in desalted leaf homogenates and partially purified preparations. RP catalyzes the inactivation of maize PPDK by phosphorylation of Thr-456, utilizing [-P]ADP as the specific phosphoryl donor. Existing spectrophotometric and radioisotopic assays for the detection of RP activity are either relatively insensitive or labor-intensive and timeconsuming. We describe a modified radioisotopic assay that couples the synthesis of [-³²P]ADP by exogenous adenylate kinase with the subsequent RP-catalyzed [-³²P]ADP-dependent phosphorylation of exogenous maize PPDK. The incorporation of [-³²P] is dependent on the initial concentrations of ATP and PPDK, as well as the presence of active RP. Desalted leaf homogenates of C₃ species fail to catalyze ³²P incorporation into exogenous maize PPDK. Conversely, heterologous systems containing the maize target enzyme and leaf homogenats of other C₄ species result in PPDK-specific ³²P-incorporation. This simple radioisotopic assay is at least 40-times more sensitive than the routine spectrophotometric assay, and qualitatively exhibits comparable sensitivity and requires significantly less time than the currently available radioisotopic RP assay. The present assay reliably generates [-³²P]ADP and as such may be useful for studies of other systems requiring -labeled ADP, which is not commercially available.Abbrevlations Ap₅A P¹, P⁵-di(adenosine-5)-pentaphosphate - Bicine N,N-bis[2-hydroxyethyl]glycine - DTT dithiothreitol - PEI poly(ethyleneimine) - PEP phosphoenolpyruvate - PEPC PEP carboxylase (E.C.4.1.1.31) - PPDK pyruvate,orthophosphate dikinase (E.C.2.7.9.1) - RP PPDK regulatory protein     

Potential mechanisms of low-temperature tolerance of C<Subscript>4</Subscript> photosynthesis in<Emphasis Type="Italic"> Miscanthus</Emphasis> ×<Emphasis Type="Italic"> giganteus</Emphasis>: an in vivo analysis

Miscanthus × giganteus (Greef & Deuter ex Hodkinson & Renvoize) is unique among C₄ species in its remarkable ability to maintain high photosynthetic productivity at low temperature, by contrast to the related C₄ NADP-malic enzyme-type species Zea mays L. In order to determine the in vivo physiological basis of this difference in photosynthesis, water vapor and CO₂ exchange and modulated chlorophyll fluorescence were simultaneously monitored on attached leaf segments from plants grown and measured at 25/20°C or 14/11°C (day/night temperature). Analysis of the response of photosynthesis to internal CO₂ concentration suggested that ribulose bisphosphate carboxylase/oxygenase (Rubisco) and/or pyruvate orthophosphate dikinase (PPDK) play a more important role in determining the response to low temperature than does phosphoenolpyruvate carboxylase (PEPc). For both species at both temperatures, the linear relationship between operating efficiency of whole-chain electron transport through photosystem II (_PSII) and the efficiency of CO₂ assimilation (_CO2) was unchanged and had a zero intercept, suggesting the absence of non-photosynthetic electron sinks. The major limitation at low temperature could not be solely at Rubisco or at any other point in the Calvin cycle, since this would have increased leakage of CO₂ to the mesophyll and increased _PSII/_CO2. This in vivo analysis suggested that maintenance of high photosynthetic rates in M. × giganteus at low temperature, in contrast to Z. mays, is most likely the result of different properties of Rubisco and/or PPDK, reduced susceptibility to photoinhibition, and the ability to maintain high levels of leaf absorptance during growth at low temperature.     

Cytosolic pyruvate,orthophosphate dikinase functions in nitrogen remobilization during leaf senescence and limits individual seed growth and nitrogen content

The protein content of seeds determines their nutritive value, downstream processing properties and market value. Up to 95% of seed protein is derived from amino acids that are exported to the seed after degradation of existing protein in leaves, but the pathways responsible for this nitrogen metabolism are poorly defined. The enzyme pyruvate,orthophosphate dikinase (PPDK) interconverts pyruvate and phosphoenolpyruvate, and is found in both plastids and the cytosol in plants. PPDK plays a cardinal role in C₄ photosynthesis, but its role in the leaves of C₃ species has remained unclear. We demonstrate that both the cytosolic and chloroplastic isoforms of PPDK are up‐regulated in naturally senescing leaves. Cytosolic PPDK accumulates preferentially in the veins, while chloroplastic PPDK also accumulates in mesophyll cells. Analysis of microarrays and labelling patterns after feeding ¹³C‐labelled pyruvate indicated that PPDK functions in a pathway that generates the transport amino acid glutamine, which is then loaded into the phloem. In Arabidopsis thaliana, over‐expression of PPDK during senescence can significantly accelerate nitrogen remobilization from leaves, and thereby increase rosette growth rate and the weight and nitrogen content of seeds. This indicates an important role for cytosolic PPDK in the leaves of C₃ plants, and allows us to propose a metabolic pathway that is responsible for production of transport amino acids during natural leaf senescence. Given that increased seed size and nitrogen content are desirable agronomic traits, and that efficient remobilization of nitrogen within the plant reduces the demand for fertiliser applications, PPDK and the pathway in which it operates are targets for crop improvement.     

Electrophoretic transfer as a technique for the detection and identification of plant amylolytic enzymes in polyacrylamide gels

Polyadenylated RNA was isolated from leaves and seeds of a C₃ plant (Triticum aestivum L. cv Cheyenne, CI 8885) and from a C₄ plant (Zea mays L. cv Golden bantam). Each polyadenylated RNA preparation was translated in vitro with micrococcal nuclease-treated reticulocyte lysate. When the in vitro translation products were probed with antibodies to pyruvate orthophosphate dikinase (PPDK) (EC 2.7.9.1), two sizes of polypeptide were identified. A 110 kilodalton polypeptide was found in the in vitro translation products of mRNA isolated exclusively from leaves of both wheat and maize. A 94 kilodalton polypeptide, similar to the PPDK polypeptide which can be extracted after in vivo synthesis in maize and wheat leaves and seeds, was found in the in vitro translation products obtained from wheat seeds and maize kernels.

These results indicate that the mRNAs for PPDK polypeptides are organ-specific in both a C₄ and a C₃ plant. Hague et al. (1983 Nucleic Acids Res 11: 4853-4865) proposed that the larger size polypeptide of the in vitro translation polypeptide from maize leaf RNA contains a `transit sequence' which permits entry into the chloroplasts of a polypeptide synthesized in vivo in maize leaf cell cytoplasm. It appears that in wheat leaves also the transit of synthesized PPDK polypeptide through an intracellular membrane may be required, while such a transit sequence seems not to be required within cells of wheat and maize seeds.

     

Cell-specific expression of pyruvate, pi dikinase : in situ mRNA hybridization and immunolocalization labeling of protein in wheat seed

Pyruvate, Pi dikinase (PPDK) is a key enzyme in the C4 photosynthetic pathway. However, its metabolic role in C3 plants remains uncertain. Northern blot analyses of PPDK mRNAs from wheat leaves and seeds probed with maize PPDK cDNA indicates the presence of organ-specific mRNAs. Immunofluorescent labeling of protein in wheat seed demonstrate that the PPDK polypeptide and the ribulose-1, 5-bisphosphate carboxylase small subunit polypeptide are localized predominantly in the aleurone layer and the chlorophyllous pericarp tissue, respectively. This differential distribution of the two polypeptides in wheat seed is paralleled by the differential localization of the their mRNAs as revealed by in situ hybridization. These results suggest a distinct role of cytoplasmic PPDK in seeds, which is different from the well established role in C4 photosynthesis.