Enzyme system catalyzing formation of cis-3-hexenal and n-hexanal from linolenic and linoleic acids in Japanese silver (Farfugium iaponicum Kitamura) leaves

Leaf alcohol (cis-3-hexenol) and leaf aldehyde (trans-2-hexenal)are responsible for the green odor in leaves and fruits. cis-3-Hexenal,a precursor of cis-3-hexenol and trans-2-hexenal, was producedfrom linolenic acid by a homogenate of Farfugium japonicum (Japanesesilver) leaves. n-Hexanal was produced from linoleic acid bya homogenate of the leaves. The enzyme system catalyzing formationof C₆-aldehydes from linolenic and linoleic acids was localizedin chloroplast lamellae, and required oxygen for reaction. C₁₈-unsaturatedfatty acids such as linolenic acid, linoleic acid and -linolenicacid, which have carboxyl groups and cis-1, cis-4-pentadienesystems including a double bond at C-12, acted as substrates,and C₆-aldehydes (cis-3-hexenal or n-hexanal), but not C₉-aldehydes,were produced from them. The properties of the enzyme systemin chloroplasts were as follows: optimal pH 7.0; stable at pH5 to 7; thermolabile and no activity at 50?C. These propertieswere very similar to those of tea chloroplasts. The enzyme systemcould be solubilized from chloroplasts by 2% Triton X-100, butwas very unstable in solubilized form. (Received July 9, 1976; )     

Effect of Potassium Deficiency on C3 and C4 Cereals

C₄ cereals (Zea maya L. and Sorghum bicolor L. Moench) and C₃cereals (Triticum aestivum L. and Hordeum vulgare L) were grownin nutrient solutions with constant, interrupted, or absentpotassium supply. The lack of potassium retarded shoot growthand depressed the chlorophyll accumulation in all species ina similar way. After the renewal of potassium, the differencesin the compensation for growth retardation were not correlatedwith the photosynthetic system, but with the recovery of chlorophyllaccumulation in younger leaves. As important for the compensationof shoot growth retardation was a slower senescence of old leavescompared to plants with a constant potassium supply. This wasshown by the chlorophyll content and PEP carboxylase activity.In contrast to C₃ cereals, the C₄ cereals did not react withhigher chlorophyll contents to the same extent after the renewalof the postassium supply. The PEP carboxylase activity, however,was immediately raised higher than in control leaves. Chlorophylland PEP carboxylase activity increased simultaneously only inless aged leaves.     

Stimulatory Effect of Chloride Ions on NADP Malic Enzyme from Leaves of two C4 Species of Cyperus

NADP malic enzyme (EC 1.1.1.40 [EC] ) from leaves of two C₄ speciesof Cyperus (C. rotundus and C. brevifolius var leiolepis) exihibiteda low level of activity in an assay mixture that contained lowconcentrations of Cl^–. This low level of activity wasmarkedly enhanced by increases in the concentration of NaClup to 200 mM. Since the activity of NADP malic enzyme was inhibitedby Na₂SO₄ and stimulated by relatively high concentration ofTris-HCl (50–100 mM, pH 7–8), the activation ofthe enzyme by NaCl appears to be due to Cl^–. Variationsin the concentration of Mg²⁺ affected the K_A (the concentrationof activator giving half-maximal activation) for Cl^–,which decreased from 500 mM to 80 mM with increasing concentrationsof Mg²⁺ from 0.5 mM to 7 mM. The K_m for Mg²⁺ was decreased from7.7 mM to 1.3 mM with increases in the concentration of NaClfrom zero to 200 mM, although the increase of V_max was not remarkable.NADP malic enzyme from Cyperus, being similar to that from otherC₄ species, was able to utilize Mn²⁺. The K_m for Mn²⁺ was 5mM, a value similar to that for Mg²⁺. The addition of 91 mMNaCl markedly decreased the K_m for Mn²⁺ to 20 +M. NADP malicenzyme from Setaria glauca, which contains rather less Cl^–than other C₄ species, was inactivated by concentrations ofNaCl above 20 mM, although slight activation of the enzyme wasobserved at low concentrations of NaCl at pH7.6. (Received February 20, 1989; Accepted June 12, 1989)     

Photosynthetic Characteristics of C3-C4 Intermediate Flaveria Species II. Kinetic Properties of Phosphoenolpyruvate Carboxylase from C3, C4 and C3-C4 Intermediate Species

The kinetic properties of phosphoenolpyruvate (PEP) carboxylasehave been studied among several Flaveria species: the C₃ speciesF. cronquistii, the C₃–C₄ species F. pubescens and F.linearis, and the C₄ species F. trinervia. At either pH 7 or8, the maximum activities (in µmol.mg Chl^–1.h^–1)for F. pubescens and linearis (187–513) were intermediateto those of the C₃ species (12–19) and the C₄ species(2,182–2,627). The response curves of velocity versusPEP concentration were hyperbolic for the C₃ and C₃–C₄species at either pH 7 or 8 while they were sigmoidal for theC₄ species at pH 7 and hyperbolic at pH 8. The K_m values forPEP determined from reciprocal plots were lowest in the C₃ species,and of intermediate value in the C₃–C₄ species comparedto the K' values of the C₄ species determined from Hill plotsat either pH 7 or 8. Glucose-6-phosphate (G6P) decreased theK_m values for PEP at both pH 7 and 8 in the C₃ and C₃–C₄species. In the C₄ species, G6P decreased the K' values at pH8 but increased the K' values at pH 7. In all cases, G6P hadits effect by influencing the activity at limiting PEP concentrationswith little or no effect on the maximum activity. At pH 8 andlimiting concentrations of PEP the degree of stimulation ofthe activity by G6P was greatest in the C₄ species, intermediatein F. linearis, a C₃–C₄ species, and lowest in the C₃species. In several respects, the PEP carboxylases of the C₃–C₄Flaveria species have properties intermediate to those of theC₃ and C₄ species. (Received April 30, 1983; Accepted August 22, 1983)     

Isoforms of NADP-Malic Enzyme from Mesembryanthemum crystallinum L. That are Involved in C3 Photosynthesis and Crassulacean Acid Metabolism

Exposure of the facultative halophyte Mesembryanthemum crystallinumL. to salt stress induces a shift from C₃ photosynthesis toCrassulacean acid metabolism (CAM). During induction of CAM,the activity of NADP-malic enzyme (EC 1.1.1.40 [EC] ) increased asmuch as 12-fold in leaves, while the enzymatic activity in rootsfell to half of the original level. These changes in the activityof the enzyme corresponded to changes in levels of the enzymeprotein. NADP-malic enzymes extracted from leaves in the C₃and CAM modes could be distinguished by differences in electrophoreticmobility during electrophoresis on a non-denaturing polyacrylamidegel. NADP-malic enzyme extracted from roots in the C₃-mode andin the CAM mode migrated as fast as the enzyme extracted fromleaves in the CAM mode on the same gel. Although the patternof peptide fragments from NADP-malic enzyme from CAM-mode leaveswas similar to that from C₃-mode leaves, as indicated by peptidemapping, both immunoprecipitation and an enzyme-linked immunosorbentassay revealed some antigenic differences between the enzymesextracted from leaves in the C₃ and the CAM modes. These resultssuggest the existence of at least two isoforms of NADPmalicenzyme that differ in their levels of expression during inductionof CAM. (Received April 21, 1994; Accepted September 5, 1994)     

Polypeptide Composition of Envelope Membranes Isolated from Chloroplasts of C3, C4, and CAM Plants

Chloroplast envelopes were isolated from chloroplasts purifiedfrom Spinacea oleracea L. (C₃), Panicum miliaceum L. (NAD-malicenzyme-type C₁), Digitaria sanguinalis (L.) Scop. (NADP-malicenzyme-type C₄), Kalanchoe daigremontiana Hamet et Perrier (constitutiveCAM), and from Mesembryanthemum crystallinum L. (inducible CAM)performing either C₃ photosynthesis or Crassulacean acid metabolism(CAM). For each species, methods were developed to isolate chloroplastenvelopes free of thylakoid contamination. The polypeptidesof ribulose bisphosphate (RuBP) carboxylase which has been consistentlyreported in envelope preparations of spinach were not foundin envelope preparations of C₄ mesophyll chloroplasts. Silverstaining of envelope polypeptides resolved electrophoreticallyon sodium dodecylsulfate polyacrylamide gradient slab gels produceda more complex profile than did Coomassie staining which haspreviously been used with C₃ envelope preparations, even thoughsilver reacted poorly with polypeptides corresponding to thesubunits of RuBP carboxylase. All of the plants examined possesseda major polypeptide of 27 to 29 kilodaltons (kD) which was previouslysuggested to be the phosphate translocator in spinach. WithC₃ M. crystallinum, the 29 kD polypeptide stained most intensely.After induction of CAM, a 32 kD polypeptide also stained intensely,giving a profile similar to that obtained with the constitutiveCAM species. A 32 kD polypeptide was also prominent in C₄ envelopepreparations, suggesting that a 32 kD polypeptide may be a translocatorprotein which is required in Crassulacean acid metabolism andC4 photosynthesis, but not in C₃ photosynthesis. (Received April 25, 1983; Accepted July 9, 1983)     

Variations in the Leaf Anatomy among some C4 Panicum Species

The Dichotomiflora group of Panicum contains NAD-malic enzyme(ME) species with centrifugal chloroplasts in Kranz cells, NAD-ME(F)species as well as NAD-ME species with centripetal chloroplastsin Kranz cells, NAD-ME (P) species. Many attributes of leafanatomy of 22 C₄ Panicum species were investigated to identifydifferences among four different C₄ subtypes, i.e. NADP-ME,NAD-ME(F), NAD-ME(P) and PEP-CK species grouped by the C₄-aciddecarboxylating enzymes and chloroplast location in Kranz cellsin combination. Differences were found in the number of Kranzcells surrounding a large vein, and the number surrounding asmall vein, the interveinal distances, the proportion of leafcross sectional area occupied by epidermis plus sclerenchyma,by mesophyll cells, by Kranz cells, and by vascular bundles.There were also differences in the ratios of the area of thedifferent cell types. The number of the characters significantlydifferent between a respective pair of C₄ subtypes was the largestbetween NAD-ME(F) and NAD-ME(P) species. In principal componentanalysis applied to 11 leaf anatomical characters, the differentC₄ subtypes clustered into small groups, although the rangeof variations of PEP-CK species and those of NAD-ME(F) speciesoverlapped. The results were discussed in relation to taxonomyand ecological adaptation of Panicum species in the differentC₄ subtypes. C₄ photosynthesis, NADP-malic enzyme, NAD-malic enzyme, Phosphoenolpyruvate carboxykinase, C₄ leaf anatomy, Panicum, Kranz, Dichotomiflora group     

Distribution of enzymes related to C3 and C4 pathway of photosynthesis between mesophyll and bundle sheath cells of Panicum hians and Panicum milioides

Enzymes of the C₄, C₃ pathway and photorespiration have beenanalyzed for P. hians and P. milioides, which have chlorenchymatousbundle sheath cells in the leaves. On whole leaf extracts thelevels of PEP carboxylase are relatively low compared to C₄species, RuDP carboxylase is typical of C₃ species, and enzymesof photorespiratory metabolism appear somewhat intermediatebetween C₃ and C₄. Substantial levels of PEP carboxylase, RuDPcarboxylase, and photorespiratory enzymes were found in bothmesophyll and bundle sheath cells. Low levels of C₄-acid decarboxylatingenzymes may limit the capacity for C₄ photosynthesis in P. hiansand P. milioides. The results on enzyme activity and distributionbetween mesophyll and bundle sheath cells are consistent withCO₂ fixation via C₃ pathway in these two species. ¹ This research was supported by the College of Agriculturaland Life Sciences, University of Wisconsin, Madison; and bythe University of Wisconsin Research Committee with funds fromthe Wisconsin Alumni Research Foundation; and by the NationalScience Foundation Grant BMS 74-09611. (Received September 16, 1975; )     

Quantitative Determination of RuBP Carboxylase-Oxygenase Protein in Leaves of Several C3 and C4 Plants

RuBP carboxylase-oxygenase protein in three C₃ species (Nicotianatabacum L., Solanum tuberosum L., Triticum aestivum L.) andthree C₄ species (Panicum miliaceum L., Panicum texanum Buckl.,Zea mays L.) was quantitatively determined by sucrose densitygradient centrifugation and by immunochemical assay using antibodyraised to crystallized tobacco leaf RuBP carboxylase-oxygenase.The C₃ species had 3- to 6-fold higher concentrations of RuBPcarboxylase-oxygenase than the C₄ species when expressed oneither a chlorophyll or a leaf area basis. The C₃ species alsoallocated a higher fraction of their total soluble protein tothis enzyme (from 25 to 60% for the C₃ species compared to 8to 23% for the C₄ species). There was no RuBP carboxylase-oxygenaseprotein or activity in the C₄ mesophyll cells, while the enzymeconstituted from 20 to 40% of the total soluble protein in theC₄ bundle sheath cells. A close correlation (r = +0·91)was found between catalytic activity and level of the enzymeprotein in the species examined.     

Comparative Studies of NAD-Malic Enzyme from Leaves of Various C4 Plants

Using butyl-TSK-gel chromatography, we purified NAD-malic enzyme(ME) (EC 1.1.1.39 [EC] ), which is involved in C₄ photosynthesis,to electrophoretic homogeneity, from leaves of Amaran-thus tricolor.Molecular weights of the native and SDS-denatured enzyme fromA. tricolor were 490 kDa and 61 kDa, respectively. During assayof the enzyme there was a slow reaction transient in the formof a lag before a steady-state rate was reached. The durationof this lag was inversely proportional to the concentrationof each substrate and the activator, fructose- 1,6-bis-phosphate(FBP). The optimal pH of the reaction fell with decreasing concentrationsof either malate or FBP. High pH prolonged the lag in reaction. Double reciprocal plots of the enzymatic activity as a functionof the concentration of malate yielded straight lines and didnot show any cooperativity for binding of malate. The enzymefrom A. tricolor was not inhibited by either HCO^–₃ orCO₂. At different concentrations of malate, the nature of theactivating effect of FBP was compared among the purified enzymesfrom A. tricolor and the C₄ monocots Eleusine coracana and Panicumdichotomiflorum. At low levels of malate, FBP markedly stimulatedthe enzyme from each species. In contrast, at saturating levelsof malate, the response of enzymes to increasing concentrationsof FBP was different and depended on the source of enzyme. The immunochemical properties of the enzymes from the threespecies were compared using an enzyme-linked immunoadsorbentassay with antisera raised against the purified enzymes fromthe three species. Different cross-reactivities were observedamong the enzymes from different sources. The N-terminal aminoacid sequences of NAD-MEs from the three species were determinedand some differences were found among the three enzymes. ²Permanent address; Tohoku National Agricultural ExperimentStation, Morioka, 020-01 Japan. ³Permanent address; National Grassland Research Institute, Nishinasuno,Tochigi, 329-27 Japan. (Received December 12, 1988; Accepted February 17, 1989)     

Differential expression pattern of C4 bundle sheath expression genes in rice, a C3 plant

NADP-malic enzyme (NADP-ME) and phosphoenolpyruvate carboxykinase(PCK) are specifically expressed in bundle sheath cells (BSCs)in NADP-ME-type and PCK-type C₄ plants, respectively. Unlikethe high activities of these enzymes in the green leaves ofC₄ plants, their low activities have been detected in the leavesof C₃ plants. In order to elucidate the differences in the geneexpression system between C₃ and C₄ plants, we have producedchimeric constructs with the ß-glucuronidase (GUS)reporter gene under the control of the maize NADP-Me (ZmMe)or Zoysia japonica Pck (ZjPck) promoter and introduced theseconstructs into rice. In leaves of transgenic rice, the ZmMepromoter directed GUS expression not only in mesophyll cells(MCs) but also in BSCs and vascular cells, whereas the ZjPckpromoter directed GUS expression only in BSCs and vascular cells.Neither the ZjPck nor ZmMe promoters induced GUS expressiondue to light. In rice leaves, the endogenous NADP-Me (OsMe1)was expressed in MCs, BSCs and vascular cells, whereas the ricePck (OsPck1) was expressed only in BSCs and vascular cells.Taken together, the results obtained from transgenic rice demonstratethat the expression pattern of ZmMe or ZjPck in transgenic ricewas reflected by that of its counterpart gene in rice. (Received August 8, 2004; Accepted February 20, 2005 )     

Differentiation of Photorespiratory Activity between Mesophyll and Bundle Sheath Cells of C4 Plants I. Glycine Oxidation by Mitochondria

Mitochondria were isolated from mesophyll protoplasts and bundlesheath protoplasts or strands which were obtained by enzymaticdigestion of six C₄ species: Zea mays, Sorghum bicolor, Panicummiliaceum, Panicum capillare, Panicum maximum and Chloris gayana,representative of three C₄ types. Photorespiratory glycine oxidationand related enzyme activities of mesophyll and bundle sheathmitochondria were compared. Mesophyll mitochondria showed good P/O ratios with malate andsuccinate as substrate but lacked the ability to oxidize glycine.On the other hand, mitochondria isolated from bundle sheathprotoplasts of P. miliaceum and bundle sheath strands of Z.mays possessed glycine oxidation activity similar to that ofmitochondria from C₃ plant leaves. The two enzymes involvedin glycine metabolism in mitochondria, serine hydroxymethyltransferaseand glycine decarboxylase, were also assayed in the mitochondriaof the two cell types. The activities of the two enzymes inbundle sheath mitochondria were in the range found in C₃ mitochondria.In contrast, the activities in mesophyll mitochondria were eithernot detectable or far lower than those in bundle sheath mitochondriaand ascribed to contaminating bundle sheath mitochondria. The present results indicate the deficiency of a complete glycineoxidation system in mesophyll mitochondria and also a differentiationbetween mesophyll and bundle sheath cells of C₄ plants withrespect to the photorespiratory activities of the mitochondria. (Received June 8, 1983; Accepted August 29, 1983)     

NADP-malic enzyme: immunolocalization in different tissues34 plant maize and the C3 plant wheat

In situimmunolocalization and Western blot analysis of separatedcellular and subcellular fractions, were used to determine thelocalization of different isoforms of NADP-malic enzyme in bothwheat (C₃) and maize (C₄) plants. In both techniques, an affinitypurified anti-(maize 62 kDa NADP-ME) lgG from the maize greenleaf isoform also reacted with a 72 kDa protein in tissues ofC4 plants as well as C3 plants. The light- inducible 62 kDaisofomi is located in bundle sheath chioroplasts of maize leaves.In etiolated leaves and in roots of maize there is evidencefor the occurrence of a 72 kDa isoform which co-migrates on2-D (SDS and isoelectric focusing) PAGE. The 72 kDa isoformis also present in low levels in green leaves. This form mayoccur in multiple intracellular compartments; but in situ immunolocalizationexperiments and Western blot and activity assays on fractionatedprotoplasts indicate that a significant amount of this isoformoccurs in plastids. With regards to C³ plants such as wheat,a 72 kDa isoform in leaves is largely confined to the chloroplastsbased on in situ immunolocalization and Western blots and enzymeactivity assays with fractionated protoplasts. In maize, itappears that the constitutive expression pattern of a possibleC₃ ancestral gene for NADP-malic enzyme has been maintained,and a high level expression of a light-inducible isoform locatedin bundle sheath chloroplasts (62 kDa) has been acquired duringits evolution. Key words: NADP-malic enzyme, Triticum aestivum, Zea mays     

Partial Reduction in Activities of Photorespiratory Enzymes in C3-C4 Intermediates of Alternanthera and Parthenium

The maximum catalytic activities of several photorespiratoryand photosynthetic enzymes were determined in leaf extractsof three C₃–C₄ intermediates (Alternanthera ficoides,A. tenella and Parthenium hysterophorus) and were compared tothose of C₃ (A. sessiles, Pisum sativum) and C₄ (A. pungens,Zea mays and Amaranthus hypochondriacus) species. The activitylevels of key photorespiratory enzymes, glycolate oxidase, catalase,NADH-hydroxypyruvate reductase and glycerate kinase were less(28 to 35% reduced) in intermediates than those of typical C₃species. Similarly, the activities of photorespiratory aminotransferasesin the C₃–C₄ intermediates were also partially reduced(23 to 37% reduction). The activities of phosphoenolpyruvatecarboxylase (PEPC), pyruvate, orthophosphate dikinase and NAD-malicenzyme were higher (2 to 7 times) in leaf extracts of the intermediatesthan those of C₃ species. But the ratios of PEPC/rubisco inthe C₃–C₄ intermediates were more like C₃ than C₄ species.We draw attention to the partial reduction in enzyme activityof photorespiratory metabolism, which could be an importantfactor for restriction of photorespiration in the C₃–C₄intermediate species, in addition to enzyme compartmentationand/or operation of a ‘C₄-like’ cycle Key words: C₃–C₄ intermediates, C₄ pathway, enzyme profile, glycolate metabolism, photorespiration, photosynthesis     

Glycolate synthesis in a C3 C4 and intermediate photosynthetic plant type

Excised leaves of a C₃-photosynthetic type, Hordeum vulgare,a C₄-type, Panicum miliaceum, and an intermediate-type, Panicummilioides, were allowed to take up through their cut ends a1 mM solution of butyl hydroxybutynoate (BHB), an irreversibleinactivator of glycolate oxidase. After 30 to 60 min in BHB,extractable glycolate oxidase activity could not be detectedin the distal quarter of the leaf blades. Following this pretreatment,recovery of ¹⁴C-glycolate from ¹⁴CO₂ incorporated in a 10 minperiod was nearly maximal for each of the three plant types.Labeled glycolate was 51% of the total ¹⁴CO₂ incorporated forthe C₃-species, 36% for the intermediate-species, and 27% forthe C₄-species Increased labeling of glycolate was compensatedfor primarily by decreased labeling of the neutral and basicfractions for the C₃ and intermediate-type species. In the C₄-type,label decreased primarily in the neutral and insoluble fractions,but increased in the basic fraction. A lower rate of glycolatesynthesis is indicative of a lower rate of photorespirationand consistent with a lower O₂/CO₂ ratio present in the bundle-sheathcells of C₄-plants. We conclude that both decreased glycolatesynthesis and the refixation of photorespiratory-released CO₂are important in maintaining a lower rate of photorespirationin C₄-plants compared to C₃ plants. Intermediate glycolate synthesisin Panicum milioldes is consistent with its intermediate levelof O₂ inhibition of photosynthesis and intermediate rate ofphotorespiration. (Received May 6, 1978; )     

A molecular phylogeny of the genus Alloteropsis (Panicoideae, Poaceae) suggests an evolutionary reversion from C4 to C3 photosynthesis

Background and Aims: The grass Alloteropsis semialata is the only plant species withboth C₃ and C₄ subspecies. It therefore offers excellent potentialas a model system for investigating the genetics, physiologyand ecological significance of the C₄ photosynthetic pathway.Here, a molecular phylogeny of the genus Alloteropsis is constructedto: (a) confirm the close relationship between the C₃ and C₄subspecies of A. semialata; and (b) infer evolutionary relationshipsbetween species within the Alloteropsis genus. Methods: The chloroplast gene ndhF was sequenced from 12 individuals,representing both subspecies of A. semialata and all four ofthe other species in the genus. ndhF sequences were added tothose previously sequenced from the Panicoideae, and used toconstruct a phylogenetic tree. Key Results: The phylogeny confirms that the two subspecies of A. semialataare among the most recently diverging lineages of C₃ and C₄taxa currently recognized within the Panicoideae. Furthermore,the position of the C₃ subspecies of A. semialata within theAlloteropsis genus is consistent with the hypothesis that itsphysiology represents a reversion from C₄ photosynthesis. Thedata point to a similar evolutionary event in the Panicum stenodes–P.caricoides–P. mertensii clade. The Alloteropsis genusis monophyletic and occurs in a clade with remarkable diversityof photosynthetic biochemistry and leaf anatomy. Conclusions: These results confirm the utility of A. semialata as a modelsystem for investigating C₃ and C₄ physiology, and provide moleculardata that are consistent with reversions from C₄ to C₃ photosynthesisin two separate clades. It is suggested that further phylogeneticand functional investigations of the Alloteropsis genus andclosely related taxa are likely to shed new light on the mechanismsand intermediate stages underlying photosynthetic pathway evolution.     

(Na+-K+)-stimulated ATPase in Leaves of C4 Plants: Possible Involvement in Active Transport of C4 Acids

Leaves of three C₄ plants, Setaria italica, Pennisetum typhoides,and Amaranthus paniculatus possessed five- to ten-fold higheractivities of a (Na⁺-K⁺)-dependent ATPase than those of twoC₃ plants, Oryza sativa and Rumex vesicarius. Na⁺-K⁺ ATPasefrom leaves of Amarathus exhibited an optimal pH of 7?5 andan optimal temperature of 35 ?C. It required 40 mM K⁺ and 80mM Na⁺ for maximal activity. Ouabain partially inhibited (Na⁺-K⁺)-dependentATPase activity in leaves of C₄ plants. Ouabain also blockedthe movement of label from initially formed C₄ acids into endproducts in leaves of only C₄ plants, Setaria and Amaranthusbut not in a C₃ plant, Rumex. We propose that Na⁺-K⁺ ATPasemay mediate transfer of energy during active transport of C₄acids from mesophyll into the bundle sheath.     

Use of inhibitors to distinguish between C4 acid decarboxylation mechanisms in bundle sheath cells of C4 plants

Both malate and aspartate were decarboxylated at the 4-carbonposition by isolated bundle sheath strands of C₄ plants butto different extents depending upon the species. In Digitariasanguinalis, an NADP-malic enzyme (NADP-ME) species, 100 µMoxalic acid blocked malate decarboxylation through NADP-ME withoutaffecting aspartate decarboxylation which apparently occursthrough NAD-ME. In several phosphoenolpyruvate carboxykinase(PEP-CK) type C₄ species, 200 µM 3-mercaptopicolinic acid(3-MPA), an inhibitor of PEP-CK, specifically inhibited themalate decarboxylation and partially inhibited aspartate decarboxylation.The aspartate decarboxylation insensitive to 3-MPA may occurthrough NAD-ME. Neither inhibitor prevented C₄ acid decarboxylationin bundle sheath cells of NAD-ME species. The inhibitors thusserved to differentiate between the decarboxylation of C₄ acidsin PEP-CK and NADP-ME type C₄ species through their major decarboxylasefrom that of their less active decarboxylation through NAD-ME. ¹ Present address: Department of Biochemistry and Microbiology,Rutgers University, New Brunswick, NJ 08903, U. S. A. (Received January 28, 1977; )     

Photosynthesis in Panicum milioides, a Species with Reduced Photorespiration

The capacity for C₄ photosynthesis in Panicum milioides, a specieshaving reduced levels of photorespiration, was investigatedby examining the activity of certain key enzymes of the C₄ pathwayand by pulse-chase experiments with ¹⁴CO₂. The ATP$P₁ dependentactivity of pyruvate,P₁ dikinase in the species was extremelylow (0.14–0.18 µmol mg chlorophyll^–1 min^–1).Low activity of the enzyme was also found in Panicum decipiensand Panicum hians (related species with reduced photorespiration)and in Panicum laxum (a C₃ species). The antibody to pyruvate,P₁dikinase caused about 70% inhibition of the ATP$P₁ dependentactivity of the enzyme in P. milioides. The activity of NAD-malicenzyme and NADP-malic enzyme in ^P. ^milioides was equally low(approximately 0.1–0.2 µmol mg chlorophyll^–1min^–1) and similar to the activity in P. decipiens, P.hians and P. laxum. Photosynthetic pulse-chase experiments underatmospheric conditions showed a typical C₃-like pattern of carbonassimilation including the labelling of glycine and serine asexpected during photorespiration. During the pulse with ¹⁴CO₂only about 1% of the labelled products appeared in malate and2–3% in aspartate. During a chase in atmospheric levelsof CO₂ for up to 6 min there was a slight increase in labellingin the C₄ acids. The amount of label in carbon 4 of aspartatedid not change during the chase, indicating little or no turnoverof the C₄ acid via decarboxylation. The results indicate thatunder atmospheric conditions P. milioides assimilates carbondirectly through the C₃ pathway. Photorespiration as indicatedby the CO₂ compensation point may be repressed in the speciesby a more efficient recycling of photorespired CO₂. (Received June 8, 1982; Accepted July 22, 1982)     

No Light Activation and High Malate Sensitivity of Phosphoenolpyruvate Carboxylase in Guard Cell Protoplasts of Commelina communis L.

Guard cell protoplasts (GCP) were prepared from leaves of Commelinacommunis L. and phosphoenolpyruvate carboxylase (PEPc) activityrecorded after injection of the protoplasts directly into theassay medium. The GCP were lysed immediately by the presenceof Triton X-100 and a lowered osmotic concentration in the assaycuvette enabling PEPc activity to be measured with ‘nascent’enzyme. There was no light activation of the enzyme with K_mPEP (about 3.7 mol m^–3) and Vmax being similar in light-ordark-treated protoplasts. Illumination of the GCP in the presenceof CO₂-free air and KCI, a treatment which is known to swellGCP, did not change the kinetics. PEPc activity at saturating PEP was very sensitive to malateinhibition, 20 mmol m^–3 (the I₅₀ value) inhibiting activityby about 50%. Inhibition was similar in light- or dark-treatedprotoplasts. Malate inhibition was, however, much less (I₅₀= 500 mmol m^–3) if the enzyme source was a protoplastextract kept in the absence of glycerol. Inclusion of 20% glycerolin the extraction medium maintained the enzyme in the malate-sensitiveform as occurred in the in vivo assays. The high apparent K_mPEP and the high sensitivity to malate inhibition of GCP PEPcare features unlike those observed with PEPc from leaf tissuesof C₄ and CAM plants and from GCP extracts. PEPc activity increased slightly in the presence of KCI in theassay medium up to about 10 mol m^–3 and thereafter activityslowly declined as KCI concentrations increased further. Key words: Guard cell protoplasts, phosphoenolpyruvate carboxylase