SPECIALIZATION OF MESOPHYLL MORPHOLOGY IN RELATION TO C4 PHOTOSYNTHESIS IN THE POACEAE

Our current understanding of the photosynthetic process in species utilizing the C₄ photosynthetic pathway suggests that photosynthetic efficiency should be enhanced by: 1) maximizing the conductance of the gas phase transport pathway from the leaf exterior to the mesophyll cell surfaces; 2) maximizing cytoplasmic connections and metabolite transport between bundle sheath and mesophyll parenchyma cells; and 3) minimizing the conductance of the gas phase transport pathway from the bundle sheath cells to the leaf exterior. In this study we have examined several species in the Poaceae with C₄ photosynthesis to determine if there is any evidence for anatomical specialization which would lead to enhanced photosynthetic efficiency by these processes. Observations with light and scanning electron microscopes revealed specializations in mesophyll cell morphology and arrangement which include branched cells forming intercellular channels. These specializations are hypothesized to contribute to photosynthetic efficiency through its influence on the above transport processes.     

C4 photosynthesis in C3 rice: a theoretical analysis of biochemical and anatomical factors

Engineering C₄ photosynthesis into rice has been considered a promising strategy to increase photosynthesis and yield. A question that remains to be answered is whether expressing a C₄ metabolic cycle into a C₃ leaf structure and without removing the C₃ background metabolism improves photosynthetic efficiency. To explore this question, we developed a 3D reaction diffusion model of bundle‐sheath and connected mesophyll cells in a C₃ rice leaf. Our results show that integrating a C₄ metabolic pathway into rice leaves with a C₃ metabolism and mesophyll structure may lead to an improved photosynthesis under current ambient CO₂ concentration. We analysed a number of physiological factors that influence the CO₂ uptake rate, which include the chloroplast surface area exposed to intercellular air space, bundle‐sheath cell wall thickness, bundle‐sheath chloroplast envelope permeability, Rubisco concentration and the energy partitioning between C₃ and C₄ cycles. Among these, partitioning of energy between C₃ and C₄ photosynthesis and the partitioning of Rubisco between mesophyll and bundle‐sheath cells are decisive factors controlling photosynthetic efficiency in an engineered C₃–C₄ leaf. The implications of the results for the sequence of C₄ evolution are also discussed.     

Metabolism of phosphoenolpyruvate in the C4 cycle during photosynthesis in the phosphoenolpyruvate-carboxykinase C4 grass Spartina anglica Hubb.

The aim of this work was to investigate the fate of phosphoenolpyruvate (PEP) produced by decarboxylation of oxaloacetate during photosynthesis in the bundle sheaths of leaves of the PEP-carboxykinase C₄ grass Spartina anglica Hubb. Mesophyll protoplasts and bundle sheath cells were separated enzymically and used to investigate activities and distributions of putative enzymes of the C₄ cycle and the photosynthetic carbon metabolism of bundle sheath cells. The results indicate that neither conversion of PEP to pyruvate nor its conversion to 3-phosphoglycerate can account for all of the carbon flux through the C₄ cycle during photosynthesis. It is likely, therefore, either that PEP moves directly from bundle sheath to mesophyll or that more than one pathway of regeneration of PEP is involved in the C₄ cycle in this plant.Abbreviations Chl chlorophyll - PEP phosphoenolpyruvate - Pi phosphate - RuBP ribulose-1,5-bisphosphate     

EXPRESSION OF THE C4 PATTERN OF PHOTOSYNTHETIC ENZYME ACCUMULATION DURING LEAF DEVELOPMENT IN ATRIPLEX ROSEA (CHENOPODIACEAE)

Immunolocalization of the bundle sheath-specific enzyme, ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPCase), and of the mesophyll-specific enzyme, phosphoenolpyruvate carboxylase (PEPCase), was used to follow development of the C₄ pattern of photosynthetic enzyme expression during leaf growth in Atriplex rosea. The leaf tissue used for this characterization was also used in a parallel ultrastructural study, so that the temporal coordination of developmental changes in enzyme expression and cell structure could be monitored. Bundle sheath-specific accumulation of RuBPCase occurs early, at the time that bundle sheath tissue is delimited from the ground meristem, and follows the order of vein initiation. PEPCase proteins were detected 2–4 days after the first appearance of RuBPCase. PEPCase accumulation is restricted to ground meristem cells that are in direct contact with bundle sheath tissue and that will become C₄ mesophyll; PEPCase was never found in more distant ground tissue. This pattern suggests that, while bundle sheath-specific accumulation of RuBPCase coincides with formation of the appropriate precursor cells, PEPCase expression is delayed until mesophyll tissue reaches a critical developmental stage. Cell-specific expression of both photosynthetic enzymes occurs well before the striking anatomical divergence of bundle sheath and mesophyll tissues, suggesting that biochemical compartmentation might serve as a developmental signal for subsequent structural differentiation.     

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.     

An Evaluation of Some Parameters Required for the Enzymatic Isolation of Cells and Protoplasts with CO2 Fixation Capacity from C3 and C4 Grasses

Variable factors affecting the enzymatic isolation of mesophyll protoplasts from Triticum aestivum (wheat), a C₃ gras, and mesophyll protoplasts and bundle sheath strands from Digitaria sanguinalis (crabgrass), a C₄ grass, have been examined with respect to yields and also photosynthetic capacity after isolation. Preparations with high yields and high photosynthetic capacity were obtained when small transverse leaf segments were incubated in enzyme medium in the light at 30°C, without mechanical shaking and without prior vacuum infiltration. Best results were obtained with an enzyme medium that included 0.5 M sorbitol, 1 mM MgCl₂, 1 mM KH₂PO₄, 2% cellulase and 0.1% pectinase at pH 5.5. In gerneral, leaf age and leaf segment size were important factors, with highest yields and photosynthetic capacities obtained from young leaves cut into segments less than 0.8 mm. To facilitate the cutting of such small segments, a mechanical leaf cutter is described that uniformly (± 0.05 mm) cuts leaf tissue into transverse segments of variable size (0.4–2 mm). Isolations that required more than roughly 4 h gave poor yields with reduced photosynthetic capacity; however, using the optimum conditions described, functional preparations could be roughly 2 h. High rates of light dependent CO₂ fixation by the C₄ mesophyll protoplasts required the addition of pyruvate and low levels of oxalacetate, while isolated bundle sheath strands and C₃ mesophyll protoplasts supported CO₂ fixation without added substrates. Rates of CO₂ fixation by isolated wheat protoplasts generally exceeded the reported rates of whole leaf photosynthesis. Wheat mesophyll protoplasts and crabgrass bundle sheath strands were stable when stored at 4°C while C₄ mesophyll protoplasts were stable when stored at 25°C.     

Photosynthesis in Flaveria brownii, a C(4)-Like Species: Leaf Anatomy, Characteristics of CO(2) Exchange, Compartmentation of Photosynthetic Enzymes, and Metabolism of CO(2)

Light microscopic examination of leaf cross-sections showed that Flaveria brownii A. M. Powell exhibits Kranz anatomy, in which distinct, chloroplast-containing bundle sheath cells are surrounded by two types of mesophyll cells. Smaller mesophyll cells containing many chloroplasts are arranged around the bundle sheath cells. Larger, spongy mesophyll cells, having fewer chloroplasts, are located between the smaller mesophyll cells and the epidermis. F. brownii has very low CO₂ compensation points at different O₂ levels, which is typical of C₄ plants, yet it does show about 4% inhibition of net photosynthesis by 21% O₂ at 30°C. Protoplasts of the three photosynthetic leaf cell types were isolated according to relative differences in their buoyant densities. On a chlorophyll basis, the activities of phosphoenolpyruvate carboxylase and pyruvate, Pi dikinase (carboxylation phase of C₄ pathway) were highest in the larger mesophyll protoplasts, intermediate in the smaller mesophyll protoplasts, and lowest, but still present, in the bundle sheath protoplasts. In contrast, activities of ribulose 1,5-bisphosphate carboxylase, other C₃ cycle enzymes, and NADP-malic enzyme showed a reverse gradation, although there were significant activities of these enzymes in mesophyll cells. As indicated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the banding pattern of certain polypeptides of the total soluble proteins from the three cell types also supported the distribution pattern obtained by activity assays of these enzymes. Analysis of initial ¹⁴C products in whole leaves and extrapolation of pulse-labeling curves to zero time indicated that about 80% of the CO₂ is fixed into C₄ acids (malate and aspartate), whereas about 20% of the CO₂ directly enters the C₃ cycle. This is consistent with the high activity of enzymes for CO₂ fixation by the C₄ pathway and the substantial activity of enzymes of the C₃ cycle in the mesophyll cells. Therefore, F. brownii appears to have some capacity for C₃ photosynthesis in the mesophyll cells and should be considered a C₄-like species.     

Photosynthetic Characteristics of Cassava (Manihot esculenta Crantz), a C3 Species with Chlorenchymatous Bundle Sheath Cells

Cultivars of cassava, Manihot esculenta Crantz, were studiedto determine the mechanism of photosynthetic carbon assimilationin this species. The results, contrary to recent reports, indicatethat cassava is a C₃ plant based on a number of physiologicaland biochemical photosynthetic characteristics. The CO₂ compensationpoints among 10 cassava cultivars ranged from 55 to 62 µlliter^–1, which was typical for C₃ plants including castorbean, a member of the same family (Euphorbiaceae). The initialproducts of photosynthesis in cassava are C₃-like; the activitiesof several key C₄ enzymes in cassava are low and similar tothose of C₃ plants. Data on the rates of photosynthesis perunit of leaf area and the photosynthetic response of cassavato CO₂ is also consistent with C₃ photosynthesis. Cassava hasa distinctive chlorenchymatous vascular bundle sheath locatedbelow a single layer of palisade cells. Unlike C₃-C₄ intermediatesand C₄ species, the bundle sheaths of cassava are not surroundedby mesophyll cells. The bundle sheath cells which occur at highfrequency in cassava may function in both photosynthesis andtransport of photosynthates in the leaf. (Received July 31, 1990; Accepted September 25, 1990)     

Activation of NADP-Malate Dehydrogenase, Pyruvate,Pi Dikinase, and Fructose 1,6-Bisphosphatase in Relation to Photosynthetic Rate in Maize

The activity and extent of light activation of three photosynthetic enzymes, pyruvate,Pi dikinase, NADP-malate dehydrogenase (NADP-MDH), and fructose 1,6-bisphosphatase (FBPase), were examined in maize (Zea mays var Royal Crest) leaves relative to the rate of photosynthesis during induction and under varying light intensities. There was a strong light activation of NADP-MDH and pyruvate,Pi dikinase, and light also activated FBPase 2- to 4-fold. During the induction period for whole leaf photosynthesis at 30°C under high light, the time required to reach half-maximum activation for all three enzymes was only 1 minute or less. After 2.5 minutes of illumination the enzymes were fully activated, while the photosynthetic rate was only at half-maximum activity, indicating that factors other than enzyme activation limit photosynthesis during the induction period in C₄ plants.

Under steady state conditions, the light intensity required to reach half-maximum activation of the three enzymes was similar (300-400 microEinsteins per square meter per second), while the light intensity required for half-maximum rates of photosynthesis was about 550 microEinsteins per square meter per second. The light activated levels of NADP-MDH and FBPase were well in excess of the in vivo activities which would be required during photosynthesis, while maximum activities of pyruvate,Pi dikinase were generally just sufficient to accommodate photosynthesis, suggesting the latter may be a rate limiting enzyme.

There was a large (5-fold) light activation of FBPase in isolated bundle sheath strands of maize, whereas there was little light activation of the enzyme in isolated mesophyll protoplasts. In mesophyll protoplasts the enzyme was largely located in the cytoplasm, although there was a low amount of light-activated enzyme in the mesophyll chloroplasts. The results suggest the chloroplastic FBPase in maize is primarily located in the bundle sheath cells.

     

Characterization of C4 Type Leaf Anatomy in Grasses (Poaceae). Mesophyll: Bundle Sheath Area Ratios

The cross-sectional area of ‘primary carbon assimilation’(PCA) (or mesophyll) tissue and of ‘photosynthetic carbonreduction’ (PCR) (or parenchymatous bundle sheath, PBS)tissue associated with each vein has been measured in transversesections of leaf blades of 124 grass species (Poaceae). Thespecies sample is representative of all major grass taxa, andof all photosynthetic types found in this family, viz. C₃, C₃/C₄intermediate, C₄ NADP-malic enzyme type (NADP-ME), C₄ NAD-malicenzyme type (NAD-ME) and PEP carboxykinase type (PCK). MeanPCA (or mesophyll) area per vein varies between photosynthetictypes in the order C₃ > NAD-ME > PCK = NADP-ME, mean PCR(or PBS) area per vein in the order NAD-ME > PCK = C₃ >NADP-ME, and mean PCA/PCR (or mesophyll/PBS) area ratio in theorder C₃ > NADP-ME > NAD-ME > PCK. Since grass leaveshave parallel venation, tissue areas and area ratios are directlyproportional to tissue volumes and volume ratios. Regressionanalyses of plots of PCA (or mesophyll) area per vein againstPCR (or PBS) area per vein yield characteristic slopes for photosynthetictypes. Differences between types in all these parameters arenearly always statistically significant, even within high leveltaxonomic groups (Eupanicoids and Chloridoids). However, differencesbetween major taxa (Eupanicoids, Andropogonoids, Chloridoids),within a photosynthetic type, are frequently not significant.This histometric characterization of photosynthetic types isdiscussed in relation to the co-operation of PCA and PCR tissuesin C₄ photosynthesis, to possible differences between C₄ typesin PCR spatial requirements and to the developmental originof PCR tissue. Grasses, Poaceae, C₄ photosynthesis, C₄ leaf blade anatomy, ‘Kranz’, NADP-malic enzyme, NAD-malic enzyme, PEP carboxykinase, PCA tissue, PCR tissue, taxonomy     

The promoters of two carboxylases in a C4 plant (maize) direct cell-specific, light-regulated expression in a C3 plant (rice)

C₄ plants have two carboxylases which function in photosynthesis. One, phosphoenolpyruvate carboxylase (PEPC) is localized in mesophyll cells, and the other, ribulose bisphosphate carboxylase (RuBPC) is found in bundle sheath cells. In contrast, C₃ plants have only one photosynthetic carboxylase, RuBPC, which is localized in mesophyll cells. The expression of PEPC in C₃ mesophyll cells is quite low relative to PEPC expression in C₄ mesophyll cells. Two chimeric genes have been constructed consisting of the structural gene encoding β-glucuronidase (GUS) controlled by two promoters from C₄ (maize) photosynthetic genes: (i) the PEPC gene (pepc) and (ii) the small subunit of RuBPC (rbcS). These constructs were introduced into a C₃ cereal, rice. Both chimeric genes were expressed almost exclusively in mesophyll cells in the leaf blades and leaf sheaths at high levels, and no or very little activity was observed in other cells. The expression of both genes was also regulated by light. These observations indicate that the regulation systems which direct cell-specific and light-inducible expression of pepc and rbcS in C₄ plants are also present in C₃ plants. Nevertheless, expression of endogenous pepc in C₃ plants is very low in C₃ mesophyll cells, and the cell specificity of rbcS expression in C₃ plants differs from that in C₄ plants. Rice nuclear extracts were assayed for DNA-binding protein(s) which interact with a cis-regulatory element in the pepc promoter. Gel-retardation assays indicate that a nuclear protein with similar DNA-binding specificity to a maize nuclear protein is present in rice. The possibility that differences in pepc expression in a C₃ plant (rice) and C₄ plant (maize) may be the result of changes in cis-acting elements between pepc in rice and maize is discussed. It also appears that differences in the cellular localization of rbcS expression are probably due to changes in a trans-acting factor(s) required for rbcS expression.     

Environmental regulation of photosynthetic metabolism in the amphibious sedge Eleocharis baldwinii and comparisons with related species

The amphibious leafless sedge, Eleocharis baldwinii, expresses C₄ characteristics in the terrestrial form and intermediate characteristics between C₃ and C₄ photosynthesis in the submerged form. This study examined the immunocytochemical localization of C₃ and C₄ enzymes in culms of the two forms to elucidate the regulatory mechanism of photosynthetic metabolism and compared the activities and amounts of C₃ and C₄ enzymes with those in other Eleocharis species, E. vivipara and E. retroflexa, which show C₄ characteristics on land but C₃ and C₄ characteristics under water. The terrestrial form of E. baldwinii exhibited a C₄‐like pattern of enzyme localization. The submerged form exhibited a modified anatomy with well‐developed mesophyll cells and small Kranz cells. The C₄ enzyme levels declined conspicuously in outer mesophyll cells adjacent to the epidermis, whereas Rubisco levels increased throughout the mesophyll in the submerged form. These results suggest that intermediate photosynthesis between C₃ and C₄ photosynthesis in the submerged form results from the predominant operation of the C₃ pathway in the outer mesophyll cells and the C₄ pathway in both the inner mesophyll and Kranz cells. Differences in the degree of C₄ expression in terrestrial forms of Eleocharis species may cause the differences in the expression of photosynthetic modes under water.     

The C4 pathway: an efficient CO2 pump

The C₄ pathway is a complex combination of both biochemical and morphological specialisation, which provides an elevation of the CO₂ concentration at the site of Rubisco. We review the key parameters necessary to make the C₄ pathway function efficiently, focussing on the diffusion of CO₂ out of the bundle sheath compartment. Measurements of cell wall thickness show that the thickness of bundle sheath cell walls in C₄ species is similar to cell wall thickness of C₃ mesophyll cells. Furthermore, NAD-ME type C₄ species, which do not have suberin in their bundle sheath cell walls, do not appear to compensate for this with thicker bundle sheath cell walls. Uncertainties in the CO₂ diffusion properties of membranes, such as the plasmalemma, choroplast and mitochondrial membranes make it difficult to estimate bundle sheath diffusion resistance from anatomical measurements, but the cytosol itself may account for more than half of the final calculated resistance value for CO₂ leakage. We conclude that the location of the site of decarboxylation, its distance from the mesophyll interface and the physical arrangement of chloroplasts and mitochondria in the bundle sheath cell are as important to the efficiency of the process as the properties of the bundle sheath cell wall. Using a mathemathical model of C₄ photosynthesis, we also examine the relationship between bundle sheath resistance to CO₂ diffusion and the biochemical capacity of the C₄ photosynthetic pathway and conclude that bundle sheath resistance to CO₂ diffusion must vary with biochemical capacity if the efficiency of the C₄ pump is to be maintained. Finally, we construct a mathematical model of single cell C₄ photosynthesis in a C₃ mesophyll cell and examine the theoretical efficiency of such a C₄ photosynthetic CO₂ pump. This revised version was published online in August 2006 with corrections to the Cover Date.     

Research into the characteristics of C3 and C4 plants inCeratophyllum demersum L.

Summary The leaf anatomy was investigated with respect to the arrangement of cells involved in photosynthesis. The full-grown leaf has one vascular bundle consisting mainly of phioem cells. In similarity to terrestrial C₄ plants the vascular bundle is surrounded by mesophyll bundle sheath cells. However, in contrast to C₄ plants, these cells do not contain chlorophyll or starch inCeratophyllum. The early products in photosynthesis (10 seconds¹⁴C labelling) were analyzed. Although no complete separation of all radioactivity in the plant extracts was reached, it was clear that malate was the major labelled component, indicating C₄ activity in the plants. No light saturation could be proven inCeratophyllum in several stages of post-dormancy in a statistically significant way, although a tendency to light saturation was observed at intensities higher than 36 Wm^–2. The photosynthetic activity was only slightly depressed by enhancement of the O₂ concentration in the medium.     

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.     

CO2 donation by malate and aspartate reduces photorespiration in Panicum milioides,A C3C4 intermediate species

Oxygen inhibition of leaf slice photosynthesis in Panicum milioides increased from 20% to 30% at 21% O₂ in the presence of maleate, a phosphoenolpyruvate carboxylase inhibitor. The increased O₂ sensitivity was completely reversed by the addition of malate and aspartate, the stable products of the phosphoenolpyruvate carboxylase reaction. The C₄ acids, malate and aspartate, also reduced O₂ inhibition of photosynthesis by isolated bundle sheath strands, but not mesophyll protoplasts. Similarly, only bundle sheath strands exhibited an active C₄ acid-dependent O₂ evolution. Compartmentation of C₄ cycle enzymes, with pyruvate, Pi dikinase in the mesophyll and NAD-malic enzyme in the bundle sheath, was demonstrated. It is concluded that reduced photorespiration in P. milioides is due to a limited potential for C₄ photosynthesis permitting an increase in pCO₂ at the site of bundle sheath ribulosebisphosphate carboxylase.     

Distribution of Photosynthetic Enzymes between Mesophyll, Specialized Parenchyma and Bundle Sheath Cells of Arundinella hirta

Arundinella hirta L. is a C₄ plant having an unusual C₄ leaf anatomy. Besides mesophyll and bundle sheath cells, A. hirta leaves have specialized parenchyma cells which look morphologically like bundle sheath cells but which lack vascular connections and are located between veins, running parallel to them. Activities of phosphoenolpyruvate and ribulose-1,5-bisphosphate carboxylases and phosphoenolpyruvate carboxykinase, NADP-and NAD-malic enzymes were determined for whole leaf extracts and isolated mesophyll protoplasts, specialized parenchyma cells, and bundle sheath cells. The data indicate that A. hirta is a NADP-malic enzyme type C₄ species. In addition, specialized parenchyma cells and bundle sheath cells are enzymatically alike. Compartmentation of enzymes followed the C₄ pattern with phosphoenolpyruvate carboxylase being restricted to mesophyll cells while ribulose-1,5-bisphosphate carboxylase and decarboxylating enzymes were restricted to bundle sheath and specialized parenchyma cells.