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.     

Two major metabolic factors for an efficient NADP-malic enzyme type C4 photosynthesis

Compared to the large number of studies focused on the factors controlling C₃ photosynthesis efficiency, there are relatively fewer studies of the factors controlling photosynthetic efficiency in C₄ leaves. Here, we used a dynamic systems model of C₄ photosynthesis based on maize (Zea mays) to identify features associated with high photosynthetic efficiency in NADP-malic enzyme (NADP-ME) type C₄ photosynthesis. We found that two additional factors related to coordination between C₄ shuttle metabolism and C₃ metabolism are required for efficient C₄ photosynthesis: (1) accumulating a high concentration of phosphoenolpyruvate through maintaining a large PGA concentration in the mesophyll cell chloroplast and (2) maintaining a suitable oxidized status in bundle sheath cell chloroplasts. These identified mechanisms are in line with the current cellular location of enzymes/proteins involved in the starch synthesis, the Calvin–Benson cycle and photosystem II of NADP-ME type C₄ photosynthesis. These findings suggested potential strategies for improving C₄ photosynthesis and engineering C₄ rice.

High levels of PGA and PEP in mesophyll cell chloroplasts and a suitable oxidation state in bundle sheath cell chloroplasts are the requirements for efficient C₄ photosynthesis.     

Aberrant chloroplasts in transgenic rice plants expressing a high level of maize NADP-dependent malic enzyme

 NADP-dependent malic enzyme (NADP-ME) is a major decarboxylating enzyme in NADP-ME-type C₄ species such as maize and Flaveria. In this study, chloroplastic NADP-ME was transferred to rice (Oryza sativa L.) using a chimeric gene composed of maize NADP-ME cDNA under the control of rice light-harvesting chlorophyll-a/b-binding protein (Cab) promoter. There was a 20- to 70-fold increase in the NADP-ME activity in leaves of transgenic rice compared to that in wild-type rice plants. Immunocytochemical studies by electron microscopy showed that maize NADP-ME was mostly localized in chloroplasts in transgenic rice plants, and that the chloroplasts were agranal without thylakoid stacking. Chlorophyll content and photosystem II activity were inversely correlated with the level of NADP-ME activity. These results suggest that aberrant chloroplasts in transgenic plants may be caused by excessive NADP-ME activity. Based on these results and the known fact that only bundle sheath cells of NADP-ME species, among all three C₄ subgroups, have agranal chloroplasts, we postulate that a high level of chloroplastic NADP-ME activity could strongly affect the development of chloroplasts. Received: 27 January 1999 / Accepted: 20 January 2000     

Characterization of the NADP malic enzyme gene family in the facultative,single-cell C<Subscript>4</Subscript> monocot <Emphasis Type="Italic">Hydrilla verticillata</Emphasis>

Hydrilla verticillata has a facultative single-cell system that changes from C₃ to C₄ photosynthesis. A NADP⁺-dependent malic enzyme (NADP-ME) provides a high [CO₂] for Rubisco fixation in the C₄ leaf chloroplasts. Of three NADP-ME genes identified, only hvme1 was up-regulated in the C₄ leaf, during the light period, and it possessed a putative transit peptide. Unlike obligate C₄ species, H. verticillata exhibited only one plastidic isoform that may perform housekeeping functions, but is up-regulated as the photosynthetic decarboxylase. Of the two cytosolic forms, hvme2 and hvme3, the latter exhibited the greatest expression, but was not light-regulated. The mature isoform of hvme1 had a pI of 6.0 and a molecular mass of 64 kD, as did the recombinant rHVME1m, and it formed a tetramer in the chloroplast. The recombinant photosynthetic isoform showed intermediate characteristics between isoforms in terrestrial C₃ and C₄ species. The catalytic efficiency of rHVME1m was four-fold higher than the cytosolic rHVME3 and two-fold higher than recombinant cytosolic isoforms of rice, but lower than plastidic forms of maize. The K _m (malate) of 0.6 mM for rHVME1 was higher than maize plastid isoforms, but four-fold lower than found with rice. A comprehensive phylogenetic analysis of 25 taxa suggested that chloroplastic NADP-ME isoforms arose from four duplication events, and hvme1 was derived from cytosolic hvme3. The chloroplastic eudicot sequences were a monophyletic group derived from a cytosolic clade after the eudicot and monocot lineages separated, while the monocots formed a polyphyletic group. The findings support the hypothesis that a NADP-ME isoform with specific and unusual regulatory properties facilitates the functioning of the single-cell C₄ system in H. verticillata. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Analysis of Promoter Activity for the Gene Encoding Pyruvate Orthophosphate Dikinase in Stably Transformed C4 Flaveria Species

The C₄ enzyme pyruvate orthophosphate dikinase is encoded by a single gene, Pdk, in the C₄ plant Flaveria trinervia. This gene also encodes enzyme isoforms located in the chloroplast and in the cytosol that do not have a function in C₄ photosynthesis. Our goal is to identify cis-acting DNA sequences that regulate the expression of the gene that is active in the C₄ cycle. We fused 1.5 kb of a 5′ flanking region from the Pdk gene, including the entire 5′ untranslated region, to the uidA reporter gene and stably transformed the closely related C₄ species Flaveria bidentis. β-Glucuronidase (GUS) activity was detected at high levels in leaf mesophyll cells. GUS activity was detected at lower levels in bundle-sheath cells and stems and at very low levels in roots. This lower-level GUS expression was similar to the distribution of mRNA encoding the nonphotosynthetic form of the enzyme. We conclude that cis-acting DNA sequences controlling the expression of the C₄ form in mesophyll cells and the chloroplast form in other cells and organs are co-located within the same 5′ region of the Pdk gene.     

Evidence for a C4 NADP-ME photosynthetic pathway in Vetiveria zizanioides Stapf

ABSTRACT

Leaf anatomy (light and transmission electron microscopy), immunogold localization of Rubisco, photosynthetic enzyme activities, CO₂ assimilation and stomatal conductance were studied in Vetiveria zizanioides Stapf., a graminaceous plant native to tropical and subtropical areas, and cultivated in temperate climates (Northwestern Italy). Leaves possess a NADP-ME Kranz anatomy with bundle sheath cells containing chloroplasts located in a centrifugal position. Dimorphic chloroplasts were also observed; they are agranal and starchy in the bundle sheath and granal starchless in the mesophyll cells. Rubisco immunolocalization studies indicate that this enzyme occurs solely in the bundle sheath chloroplasts. Pyruvate-orthophosphate dikinase, NADP-dependent malate dehydrogenase (NADP-MDH), NADP-dependent malic enzyme (NADP-ME), PEP-carboxykinase and NAD-dependent malic enzyme (NAD-ME) activities were determined. Enzyme activity and some kinetic properties of NADP-ME and NADP-MDH as well as CO₂ compensation point and stomatal conductance values were calculated indicating a NADP-ME C₄ photosynthetic pathway. Biochemical and structural results indicate that V. zizanioides belongs to the C₄ NADP-ME variant. This plant appears to be well adapted to the varying environmental conditions typical of temperate climates, by retaining high enzyme activities and a low CO₂ compensation point.     

Assessing photosystem I and II distribution in leaves from C4 plants using confocal laser scanning microscopy

Images of chlorophyll fluorescence emitted at wavelengths above and below 700 nm were recorded from leaf sections of C₄ species using confocal laser scanning microscopy (LSM). We investigated species exhibiting both NAD-malic enzyme (NAD-ME) C₄ photosynthesis and NADP-malic enzyme (NADP-ME) C₄ photosynthesis. Comparing LSM fluorescence of leaf sections with flow-cytometrically determined fluorescence from individual chloroplasts revealed that LSM fluorescence was distorted by the optical properties of leaf sections. Leaf section fluorescence, when corrected by transmission data derived from light transmission images, agreed with flow cytometry data. The corrected LSM fluorescence yielded information on the distribution of the individual photosystems in the C₄ leaf sections: PSII concentrations in bundle sheath cells were elevated in NAD-ME species but diminished in most of the NADP-ME species investigated. The NADP-ME species, Arundinella hirta, however, showed normal PSII and increased PSI concentration in bundle sheath chloroplasts. Finally, a gradient of PSI was observed within the bundle sheath cells from Euphorbia maculata.     

Photosynthetic and photorespiratory characteristics of flaveria species

The genus Flaveria shows evidence of evolution in the mechanism of photosynthesis as its 21 species include C₃, C₃-C₄, C₄-like, and C₄ plants. In this study, several physiological and biochemical parameters of photosynthesis and photorespiration were measured in 18 Flaveria species representing all the photosynthetic types. The 10 species classified as C₃-C₄ intermediates showed an inverse continuum in level of photorespiration and development of the C₄ syndrome. This ranges from F. sonorensis with relatively high apparent photorespiration and lacking C₄ photosynthesis to F. Among the intermediates, the photosynthetic CO₂ compensation points at 30°C and 1150 micromoles quanta per square meter per second varied from 9 to 29 microbars. The values for the three C₄-like species varied from 3 to 6 microbars, similar to those measured for the C₄ species. The activities of the photorespiratory enzymes glycolate oxidase, hydroxypyruvate reductase, and serine hydroxymethyltransferase decreased progressively from C₃ to C₃-C₄ to C₄-like and C₄ species. On the other hand, most intermediates had higher levels of phosphenolpyruvate carboxylase and NADP-malic enzyme than C₃ species, but generally lower activities compared to C₄-like and C₄ species. The levels of these C₄ enzymes are correlated with the degree of C₄ photosynthesis, based on the initial products of photosynthesis. Another indication of development of the C₄ syndrome in C₃-C₄ Flaveria species was their intermediate chlorophyll a/b ratios. The chlorophyll a/b ratios of the various Flaveria species are highly correlated with the degree of C₄ photosynthesis suggesting that the photochemical machinery is progressively altered during evolution in order to meet the specific energy requirements for operating the C₄ pathway. In the progression from C₃ to C₄ species in Flaveria, the CO₂ compensation point decreased more rapidly than did the decrease in O₂ inhibition of photosynthesis or the increase in the degree of C₄ photosynthesis. These results suggest that the reduction in photorespiration during evolution occurred initially by refixation of photorespired CO₂ and prior to substantive reduction in O₂ inhibition and development of the C₄ syndrome. However, further reduction in O₂ inhibition in some intermediates and C₄-like species is considered primarily due to the development of the C₄ syndrome. Thus, the evolution of C₃-C₄ intermediate photosynthesis likely occurred in response to environmental conditions which limit the intercellular CO₂ concentration first via refixation of photorespired CO₂, followed by development of the C₄ syndrome.     

Evolution of C4 Photosynthesis in the Genus Flaveria: Establishment of a Photorespiratory CO2 Pump

C₄ photosynthesis is nature’s most efficient answer to the dual activity of ribulose-1,5-bisphosphate carboxylase/oxygenase and the resulting loss of CO₂ by photorespiration. Gly decarboxylase (GDC) is the key component of photorespiratory CO₂ release in plants and is active in all photosynthetic tissues of C₃ plants, but only in the bundle sheath cells of C₄ plants. The restriction of GDC to the bundle sheath is assumed to be an essential and early step in the evolution of C₄ photosynthesis, leading to a photorespiratory CO₂ concentrating mechanism. In this study, we analyzed how the P-protein of GDC (GLDP) became restricted to the bundle sheath during the transition from C₃ to C₄ photosynthesis in the genus Flaveria. We found that C₃ Flaveria species already contain a bundle sheath–expressed GLDP gene in addition to a ubiquitously expressed second gene, which became a pseudogene in C₄ Flaveria species. Analyses of C₃-C₄ intermediate Flaveria species revealed that the photorespiratory CO₂ pump was not established in one single step, but gradually. The knowledge gained by this study sheds light on the early steps in C₄ evolution.     

Photosynthetic Characteristics of C(3)-C(4) Intermediate Flaveria Species : I. Leaf Anatomy, Photosynthetic Responses to O(2) and CO(2), and Activities of Key Enzymes in the C(3) and C(4) Pathways

Four species of the genus Flaveria, namely F. anomala, F. linearis, F. pubescens, and F. ramosissima, were identified as intermediate C₃-C₄ plants based on leaf anatomy, photosynthetic CO₂ compensation point, O₂ inhibition of photosynthesis, and activities of C₄ enzymes. F. anomala and F. ramosissima exhibit a distinct Kranz-like leaf anatomy, similar to that of the C₄ species F. trinervia, while the other C₃-C₄ intermediate Flaveria species possess a less differentiated Kranz-like leaf anatomy. Photosynthetic CO₂ compensation points of these intermediates at 30°C were very low relative to those of C₃ plants, ranging from 7 to 14 microliters per liter. In contrast to C₃ plants, net photosynthesis by the intermediates was not sensitive to O₂ concentrations below 5% and decreased relatively slowly with increasing O₂ concentration. Under similar conditions, the percentage inhibition of photosynthesis by 21% O₂ varied from 20% to 25% in the intermediates compared with 28% in Lycopersicon esculentum, a typical C₃ species. The inhibition of carboxylation efficiency by 21% O₂ varied from 17% for F. ramosissima to 46% for F. anomala and were intermediate between the C₄ (2% for F. trinervia) and C₃ (53% for L. esculentum) values. The intermediate Flaveria species, especially F. ramosissima, have substantial activities of the C₄ enzymes, phosphoenolpyruvate carboxylase, pyruvate, orthophosphate dikinase, NADP-malic enzyme, and NADP-malate dehydrogenase, indicating potential for C₄ photosynthesis. It appears that these Flaveria species may be true biochemical C₃-C₄ intermediates.     

Developmental and Environmental Effects on the Expression of the C3-C4 Intermediate Phenotype in Moricandia arvensis

Cellular anatomy and expression of glycine decarboxylase (GDC) protein were studied during leaf development of the C₃-C₄ intermediate species Moricandia arvensis. Leaf anatomy was initially C₃-like and the number and profile area of mitochondria in the bundle-sheath cells were the same as those in adjacent mesophyll cells. Between a leaf length of 6 and 12 mm there was a bundle-sheath-specific, 4-fold increase in the number of mitochondrial profiles, followed by a doubling of their individual profile areas as the leaves expanded further. Subunits of GDC were present in whole-leaf extracts before the anatomical development of bundle-sheath cells. Whereas the GDC H-protein content of leaves increased steadily throughout development, the increase in GDC P-protein was synchronous with the development of mitochondria in the bundle sheath. The P-protein was confined to bundle-sheath mitochondria throughout leaf development, and its content in individual mitochondria increased before the anatomical development of the bundle sheath. Anatomical and biochemical attributes of the C₃-C₄ character were present in the cotyledons and sepals but not in other photosynthetic organs/tissues. In leaves and cotyledons that developed in the dark, the expression of the P-protein and the organellar development were reduced but the bundle-sheath cell specificity was retained.     

Significant involvement of PEP-CK in carbon assimilation of C4 eudicots

Background and Aims

C₄ eudicot species are classified into biochemical sub-types of C₄ photosynthesis based on the principal decarboxylating enzyme. Two sub-types are known, NADP-malic enzyme (ME) and NAD-ME; however, evidence for the occurrence or involvement of the third sub-type (phosphoenolpyruvate carboxykinase; PEP-CK) is emerging. In this study, the presence and activity of PEP-CK in C₄ eudicot species of Trianthema and Zaleya (Sesuvioideae, Aizoaceae) is clarified through analysis of key anatomical features and C₄ photosynthetic enzymes.

Methods

Three C₄ species (T. portulacastrum, T. sheilae and Z. pentandra) were examined with light and transmission electron microscopy for leaf structural properties. Activities and immunolocalizations of C₄ enzymes were measured for biochemical characteristics.

Key Results

Leaves of each species possess atriplicoid-type Kranz anatomy, but differ in ultrastructural features. Bundle sheath organelles are centripetal in T. portulacastrum and Z. pentandra, and centrifugal in T. sheilae. Bundle sheath chloroplasts in T. portulacastrum are almost agranal, whereas mesophyll counterparts have grana. Both T. sheilae and Z. pentandra are similar, where bundle sheath chloroplasts contain well-developed grana while mesophyll chloroplasts are grana deficient. Cell wall thickness is significantly greater in T. sheilae than in the other species. Biochemically, T. portulacastrum is NADP-ME, while T. sheilae and Z. pentandra are NAD-ME. Both T. portulacastrum and Z. pentandra exhibit considerable PEP-CK activity, and immunolocalization studies show dense and specific compartmentation of PEP-CK in these species, consistent with high PEP-CK enzyme activity.

Conclusions

Involvement of PEP-CK in C₄ NADP-ME T. portulacastrum and NAD-ME Z. petandra occurs irrespective of biochemical sub-type, or the position of bundle sheath chloroplasts. Ultrastructural traits, including numbers of bundle sheath peroxisomes and mesophyll chloroplasts, and degree of grana development in bundle sheath chloroplasts, coincide more directly with PEP-CK recruitment. Discovery of high PEP-CK activity in C₄ Sesuvioideae species offers a unique opportunity for evaluating PEP-CK expression and suggests the possibility that PEP-CK recruitment may exist elsewhere in C₄ eudicots.     

Oxygen Requirement and Inhibition of C4 Photosynthesis : An Analysis of C4 Plants Deficient in the C3 and C4 Cycles

The basis for O₂ sensitivity of C₄ photosynthesis was evaluated using a C₄-cycle-limited mutant of Amaranthus edulis (a phosphoenolpyruvate carboxylase-deficient mutant), and a C₃-cycle-limited transformant of Flaveria bidentis (an antisense ribulose-1,5-bisphosphate carboxylase/oxygenase [Rubisco] small subunit transformant). Data obtained with the C₄-cycle-limited mutant showed that atmospheric levels of O₂ (20 kPa) caused increased inhibition of photosynthesis as a result of higher levels of photorespiration. The optimal O₂ partial pressure for photosynthesis was reduced from approximately 5 kPa O₂ to 1 to 2 kPa O₂, becoming similar to that of C₃ plants. Therefore, the higher O₂ requirement for optimal C₄ photosynthesis is specifically associated with the C₄ function. With the Rubisco-limited F. bidentis, there was less inhibition of photosynthesis by supraoptimal levels of O₂ than in the wild type. When CO₂ fixation by Rubisco is limited, an increase in the CO₂ concentration in bundle-sheath cells via the C₄ cycle may further reduce the oxygenase activity of Rubisco and decrease the inhibition of photosynthesis by high partial pressures of O₂ while increasing CO₂ leakage and overcycling of the C₄ pathway. These results indicate that in C₄ plants the investment in the C₃ and C₄ cycles must be balanced for maximum efficiency.     

Differences in drought sensitivities and photosynthetic limitations between co-occurring C3 and C4 (NADP-ME) Panicoid grasses

Background and Aims

The success of C₄ plants lies in their ability to attain greater efficiencies of light, water and nitrogen use under high temperature, providing an advantage in arid, hot environments. However, C₄ grasses are not necessarily less sensitive to drought than C₃ grasses and are proposed to respond with greater metabolic limitations, while the C₃ response is predominantly stomatal. The aims of this study were to compare the drought and recovery responses of co-occurring C₃ and C₄ NADP-ME grasses from the subfamily Panicoideae and to determine stomatal and metabolic contributions to the observed response.

Methods

Six species of locally co-occurring grasses, C₃ species Alloteropsis semialata subsp. eckloniana, Panicum aequinerve and Panicum ecklonii, and C₄ (NADP-ME) species Heteropogon contortus, Themeda triandra and Tristachya leucothrix, were established in pots then subjected to a controlled drought followed by re-watering. Water potentials, leaf gas exchange and the response of photosynthetic rate to internal CO₂ concentrations were determined on selected occasions during the drought and re-watering treatments and compared between species and photosynthetic types.

Key Results

Leaves of C₄ species of grasses maintained their photosynthetic advantage until water deficits became severe, but lost their water-use advantage even under conditions of mild drought. Declining C₄ photosynthesis with water deficit was mainly a consequence of metabolic limitations to CO₂ assimilation, whereas, in the C₃ species, stomatal limitations had a prevailing role in the drought-induced decrease in photosynthesis. The drought-sensitive metabolism of the C₄ plants could explain the observed slower recovery of photosynthesis on re-watering, in comparison with C₃ plants which recovered a greater proportion of photosynthesis through increased stomatal conductance.

Conclusions

Within the Panicoid grasses, C₄ (NADP-ME) species are metabolically more sensitive to drought than C₃ species and recover more slowly from drought.     

Structural and biochemical bases of photorespiration in C<Subscript>4</Subscript> plants: quantification of organelles and glycine decarboxylase

In C₄ plants, photorespiration is decreased relative to C₃ plants. However, it remains unclear how much photorespiratory capacity C₄ leaf tissues actually have. We thoroughly investigated the quantitative distribution of photorespiratory organelles and the immunogold localization of the P protein of glycine decarboxylase (GDC) in mesophyll (M) and bundle sheath (BS) cells of various C₄ grass species. Specific differences occurred in the proportions of mitochondria and peroxisomes in the BS cells (relative to the M cells) in photosynthetic tissues surrounding a vein: lower in the NADP-malic enzyme (NADP-ME) species having poorly formed grana in the BS chloroplasts, and higher in the NAD-malic enzyme (NAD-ME) and phosphoenolpyruvate carboxykinase (PCK) species having well developed grana. In all C₄ species, GDC was localized mainly in the BS mitochondria. When the total amounts of GDC in the BS mitochondria per unit leaf width were estimated from the immunogold labeling density and the quantity of mitochondria, the BSs of NADP-ME species contained less GDC than those of NAD-ME or PCK species. This trend was also verified by immunoblot analysis of leaf soluble protein. There was a high positive correlation between the degree of granal development (granal index) in the BS chloroplasts and the total amount of GDC in the BS mitochondria. The variations in the structural and biochemical features involved in photorespiration found among C₄ species might reflect differences in the O₂/CO₂ partial pressure and in the potential photorespiratory capacity of the BS cells.Abbreviations BS Bundle sheath - GDC Glycine decarboxylase - M Mesophyll - NAD-ME NAD-malic enzyme - NADP-ME NADP-malic enzyme - PCK Phosphoenolpyruvate carboxykinase