Chloroplast NADP-malate dehydrogenase: structural basis of light-dependent regulation of activity by thiol oxidation and reduction.

BACKGROUND: NADP-dependent malate dehydrogenase (EC 1.1.1.82) is a light-activated chloroplast enzyme that functions in the C4 pathway of photosynthesis. The light regulation is believed to be mediated in vivo by thioredoxin-catalyzed reduction and re-oxidation of cystine residues. The rates of reversible activation and inactivation of the enzyme are strongly influenced by the coenzyme substrates that seem to ultimately determine the steady-state extent of activation in vivo. RESULTS: The X-ray structure of the inactive, oxidized enzyme was determined at 2.8 A resolution. The core structure is homologous to AND-dependent malate dehydrogenases. Two surface-exposed and thioredoxin-accessible disulfide bonds are present, one in the N-terminal extension and the other in the C-terminal extension. The C-terminal peptide of the inactive, oxidized enzyme is constrained by its disulfide bond to fold into the active site over NADP+, hydrogen bonding to the catalytic His225 as well as obstructing access of the C4 acid substrate. Two loops flanking the active site, termed the Arg2 and Trp loops, that contain the C4 acid substrate binding residues are prevented from closing by the C-terminal extension. CONCLUSIONS: The structure explains the role of the C-terminal extension in inhibiting activity. The negative C terminus will interact more strongly with the positively charged nicotinamide of NADP+ than NADPH, explaining why the coenzyme-binding affinities of the enzyme differ so markedly from those of all other homologous alpha-hydroxy acid dehydrogenases. NADP+ may also slow dissociation of the C terminus upon reduction, providing a mechanism for the inhibition of activation by NADP+ but not NADPH.

Purification of multiple pea ferredoxins by chromatography at high ionic strength on unsubstituted Sepharose 4B.

At high concentrations of ammonium sulfate (3--4 M) pea ferredoxin (which is soluble under these conditions) can be adsorbed to Sepharose 4B, either by column chromatography or by batchwise treatment. A reverse (3 M to 1 M) ammonium sulfate gradient results in the elution of three peaks of ferredoxin. The spectral ratio A420/A280 of 0.47--0.54 indicates that each peak of ferredoxin is highly purified by this single step. A further gel filtration removes residual high molecular weight contaminants from the ferredoxin. The spectrum of the purified pea ferredoxin is typical of other plant ferredoxins in having absorbance peaks at 276 nm, 330 nm, 422 nm and 465 nm. Other chromatographic matrices are capable of adsorbing ferredoxin. Sepharose and Sephacryl wee the best adsorbents while Sephadex and cellulose adsorbed ferredoxin less tenaciously. The polyacrylamide-based resins Biogel P-4 and P-200 did not adsorb ferredoxin at high ionic strength.

NADP-Malate Dehydrogenase in the C4 Plant Flaveria bidentis (Cosense Suppression of Activity in Mesophyll and Bundle-Sheath Cells and Consequences for Photosynthesis).

Flaveria bidentis, a C4 dicot, was transformed with sorghum (a monocot) cDNA clones encoding NADP-malate dehydrogenase (NADP-MDH; EC 1.1.1.82) driven by the cauliflower mosaic virus 35S promoter. Although these constructs were designed for over-expression, many transformants contained between 5 and 50% of normal NADP-MDH activity, presumably by cosense suppression of the native gene. The activities of a range of other photosynthetic enzymes were unaffected. Rates of photosynthesis in plants with less than about 10% of normal activity were reduced at high light and at high [CO2], but were unaffected at low light or at [CO2] below about 150 [mu]L L-1. The large decrease in maximum activity of NADP-MDH was accompanied by an increase in the activation state of the enzyme. However, the activation state was unaffected in plants with 50% of normal activity. Metabolic flux control analysis of plants with a range of activities demonstrates that this enzyme is not important in regulating the steady-state flux through C4 photosynthesis in F. bidentis. Cosense suppression of gene expression was similarly effective in both the mesophyll and bundle-sheath cells. Photosynthesis of plants with very low activity of NADP-MDH in the bundle-sheath cells was only slightly inhibited, suggesting that the presence of the enzyme in this compartment is not essential for supporting maximum rates of photosynthesis.

Stimulation of spinach (Spinacia oleracea) chloroplast fructose-1,6-bisphosphatase by mercuric ions.

Chloroplast fructose-1,6-bisphosphatase can exist in an active reduced form or a less active oxidised form. Oxidised fructose bisphosphatase from spinach (Spinacia oleracea) could be stimulated up to many hundred-fold by 0.1 mM HgCl2 whereas fructose bisphosphatases from rabbit, yeast, a non-chloroplast enzyme from spinach and the reduced chloroplast enzyme were only inhibited by HgCl2. Stimulation of the enzyme was maximal at pH 8.0 and low magnesium concentrations where the oxidised enzyme normally has little activity.

NADP-malic enzyme from the C4 plant Flaveria bidentis: nucleotide substrate specificity.

NADP-malic enzyme (NADP-ME, EC 1.1.1.40) was purified to near-homogeneity from leaves of the C4 dicot Flaveria bidentis and shown to possess intrinsic NAD-dependent malic enzyme activity. The NAD-dependent activity is optimal at pH 7.5 and in the presence of Mn2+. The Km for NAD is very high (20 mM), while the Vmax is 50% greater than the Vmax with NADP under the same conditions. The NAD-dependent activity is competitively inhibited by micromolar concentrations of NADP and NADPH (Ki approximately 2 microM). This very low Ki reflects the high affinity of malic enzyme for NADP(H) under these conditions. When utilizing NADP, the Km for NADP is 1.5 microM while the Ki for NADPH is 2 microM. Chicken liver NADP-ME also has NAD-dependent activity that is inhibited by low concentrations of NADPH. These results indicate that the NAD- and NADP-dependent activities are likely catalyzed by the same active site. The use of NAD as an alternative coenzyme revealed interactions between the binding of coenzyme and metal ions on the Km values of each of the other participants in the malic enzyme reaction. Thus, the affinity of malic enzyme for the divalent metal ions Mg2+ and particularly Mn2+ as well as the other substrate L-malate is also dependent on the nucleotide coenzyme substrate. In turn, the divalent metal ion influences the affinity of the enzyme for the coenzyme as well as L-malate. With NADP as substrate the Km for Mn2+ is 4 microM, whereas with NAD the Km is 300 microM. The relatively high affinity of the enzyme for Mn2+ and low affinity for NAD required the use of metal ion buffers when determining these values because of the substantial depletion of free Mn2+ caused by binding to NADP.

A simple procedure for purifying the major chloroplast fructose-1,6-bisphosphatase from spinach (Spinacia oleracea) and characterization of its stimulation by sub-femtomolar mercuric ions.

A rapid procedure for the purification of the redox-regulated chloroplast fructose-1,6-bisphosphatase [EC 3.1.3.11] from spinach leaf extract to homogeneity is described. No thiol-reducing agents were present during the purification and the enzyme is > 99% in the oxidized form. A rapid procedure to reduce and activate the Fru-1,6-P2ase by dithiothreitol in the absence of thioredoxin is described. Reduction activates the enzyme up to several hundred-fold when assayed at pH 8.0 with 2 mM Mg2+. The activity of the purified oxidized enzyme is unusually sensitive to changes in Mg2+ and H+ concentration. Tenfold changes in Mg2+ or H+ concentration lead to > 100-fold increases in activity. The recoveries of fructose-1,6-bisphosphatase activity as determined by the activity of the oxidized enzyme at pH 8.0/20 mM Mg2+; pH 9.0/2 mM Mg2+; pH 8/2 mM Mg2+ plus 0.1 mM Hg(II) or of the reduced enzyme at pH 8.0/2 mM Mg2+ are similar (approximately 40%) indicating that the major proportion of these activities in a leaf extract is catalyzed by the same enzyme. Moreover, antibodies raised against the purified enzyme inhibit all of the above activities in crude leaf extracts. The kinetic properties of the purified enzyme suggest that the oxidized Mg(2+)-dependent enzyme can play no significant role in photosynthetic carbon assimilation. A survey of some kinetic properties of Fru-1,6-P2ase activity in extracts of various photosynthetic organisms reveals that all 11 species examined possess a redox- and pH/Mg(2+)-stimulated Fru-1,6-P2ase, whereas Fru-1,6-P2ase in extracts of Taxus baccata (a gymnosperm), Chlorella vulgaris (a green alga), and the cyanobacterium Nostoc muscorum were not activated by Hg(II). The heat stability that proved useful in the purification of the spinach enzyme was conserved in both angiosperms and gymnosperms. The oxidized enzyme (which normally has no thiol groups accessible to 5,5'-dithio-bis[2-nitrobenzoic acid]) but not the reduced enzyme can be stimulated many hundred-fold by addition of extraordinarily low concentrations of Hg(II) to a complete assay mixture. With the aid of EDTA as a Hg(II) buffer, half-maximal stimulation was achieved at 2 x 10(-16) M free Hg(II). Methylmercury also stimulates the enzyme many hundred-fold at very low concentrations. The concentration for half-maximal stimulation by methylmercury was determined with a cyanide buffer to be approximately 10(-16) M. This, together with the high affinity of the enzyme for Hg(II), suggests that Hg(II) stimulates the enzyme by binding to an enzyme thiol group that be comes exposed in the catalytically active enzyme, thereby stabilizing the oxidized enzyme in an active conformation. By contrast, in the absence of Fru-1,6-P2 and either Mg2+ or Ca2+, Hg(II) (even at 2 x 10(-16) M) rapidly inactivates the oxidized Fru-1,6-P2ase. This inactivation is similar to the inactivation of Fru-1,6-P2ase that occurred at high pH (> 9) and which is also prevented by Fru-1,6-P2 and either Mg2+ or Ca2+. Although the Hg(II)- and high pH-inactivated oxidized enzyme has no activity, both forms of the enzyme can be activated by reduction. The usefulness of buffers to maintain low, defined Hg(II) and organic mercurial concentrations is discussed.

An affinity label for the regulatory dithiol of ribulose-5-phosphate kinase from maize (Zea mays).

Ribulose-5-phosphate kinase from maize (Zea mays) can exist in either a reduced, active form or an oxidized, inactive form. Reduced ribulose-5-phosphate kinase is rapidly and irreversibly inactivated by the dichlorotriazine dye Reactive Red 1 (Procion Red MX-2B), but the irreversible inactivation of the oxidized form of ribulose-5-phosphate kinase occurs at only 0.05% of this rate. The rate of inactivation of the reduced enzyme by Reactive Red 1 (apparent bimolecular rate constant 10(4)M-1 X s-1 at pH 7.4 and 25 degrees C) is several orders of magnitude greater than previous estimates of the rates of dye-mediated inactivation of other enzymes. The dye-dependent inactivation of the reduced enzyme is inhibited by Hg2+ or p-mercuribenzoate (thiol reagents that reversibly inhibit ribulose-5-phosphate kinase activity), or by ATP and ADP, the nucleotide substrates of the enzyme. Hydrolysed Reactive Red 1, which does not inactivate the enzyme, is a reversible inhibitor of ribulose-5-phosphate kinase. This inhibition is competitive with respect to ATP (Ki approximately 0.5 mM). The dye appears to act as an affinity label for the ATP/ADP-binding site by preferentially arylating a thiol residue generated during the reductive activation of the enzyme that is achieved by dithiothreitol or thioredoxin in vitro or during illumination of leaves.

Cyclic adenosine 3':5'-monophosphate in axenic rye grass endosperm cell cultures.

Cyclic adenosine 3':5'-monophosphate (cAMP) was extensively purified from rye grass (Lolium multiflorum) endosperm cells grown in axenic suspension culture. The cAMP was purified by neutral alumina and anion and cation exchange chromatography. The cAMP was quantitated by means of a radiochemical saturation assay using a beef heart cAMP-binding protein and also by an assay involving activation of beef heart protein kinase. The cAMP levels found (corrected for recovery of tracer cyclic 3',5'-[8-(3)H]AMP included from the point of sample extraction) ranged from 2 to 12 pmol/g fresh weight. The material purified from rye grass cultures was indistinguishable from authentic cAMP with respect to chromatography in two cellulose thin layer systems, behavior on dilution in both the saturation and protein kinase activation assays, and rates of degradation by a mammalian cAMP phosphodiesterase. The cAMP from rye grass cultures was completely degraded by a mammalian cAMP phosphodiesterase, and 1-methyl-3-isobutylxanthine inhibited such degradation. The protein kinase activation and saturation assays gave essentially the same values for the cAMP content of axenic rye grass culture extracts. Material satisfying the above criteria for identity with cAMP was also isolated from the culture medium. The increase observed in medium cAMP levels during culture growth provides evidence for the synthesis and secretion of cAMP by rye grass endosperm cells in suspension culture.

A novel procedure for the rapid purification of plastocyanin from pea (Pisum sativum) leaves.

Plastocyanin is soluble at high concentrations (greater than 3 M) of (NH4)2SO4 but under these conditions will adsorb tightly to unsubstituted Sepharose beads. This observation was utilized to purify plastocyanin from pea (Pisum sativum) in two chromatographic steps. Sepharose-bound plastocyanin was eluted with low-ionic-strength buffer and subsequently purified to homogeneity by DEAE-cellulose chromatography.

Higher-plant cyclic nucleotide phosphodiesterases. Resolution, partial purification and properties of three phosphodiesterases from potato tuber.

1. Three phosphodiesterases that are capable of hydrolysing 3':5'-cyclic nucleotides were purified from potato tubers. 2. The phosphodiesterases were fractionated by (NH4)2SO4 precipitation and CM-cellulose chromatography. The phosphodiesterases were resolved from each other and further purified by gel filtration in high- and low-ionic-strength conditions. 3. All three enzymes lacked significant nucleotidase activity. 4. Enzymes I and II had mol. wts. 240,000 and 80,000 respectively, determined by gel filtration, whereas enzyme III showed anomalous behaviour on gel filtration, behaving as a high- or low-molecular-weight protein in high- or low-ionic-strength buffers respectively. 5. All enzymes hydrolysed 2':3'-cyclic nucleotides as well as 3':5'-cyclic nucleotides. The enzymes also had nucleotide pyrophosphatase activity, hydrolysing NAD+ and UDP-glucose to various extents. Enzymes I and II hydrolyse cyclic nucleotides at a greater rate than NAD+, whereas enzyme III hydrolyses NAD+ at a much greater rate than cyclic nucleotides. All three enzymes hydrolysed the artificial substrate bis-(p-nitro-phenyl) phosphate. 6. The enzymes do not require the addition of bivalent cations for activity. 7. Both enzymes I and II have optimum activity at pH6 with 3':5'-cyclic AMP and bis-(p-nitrophenyl) phosphate as substrates. The products of 3':5'-cyclic AMP hydrolysis were 3'-AMP and 5'-AMP, the ratio of the two products being different for each enzyme and varying with pH. 8. Theophylline inhibits enzymes I and II slightly, but other methyl xanthines have little effect. Enzymes I and II were competitively inhibited by many nucleotides containing phosphomonoester and phosphodiester bonds, as well as by Pi. 9. The possible significance of these phosphodiesterases in cyclic nucleotide metabolism in higher plants is discussed.

Regulation of C4 photosynthesis: physical and kinetic properties of active (dithiol) and inactive (disulfide) NADP-malate dehydrogenase from Zea mays.

NADP-malate dehydrogenase was purified from leaves of Zea mays in the absence of thiol-reducing agents by (NH4)2SO4, polyethylene glycol, and pH fractionation followed by dye-ligand affinity chromatography and gel filtration. The purified enzyme is completely inactive (no activity detected between pH 6 and 9) but can be reactivated by thiol-reducing agents including dithiothreitol and thioredoxin. The active enzyme shows distinctly alkaline pH optima when assayed in either direction; Km values at pH 8.5 are oxaloacetate, 18 microM; malate, 24 mM; NADPH, 50 microM; and NADP, 45 microM. The reduction of oxaloacetate is inhibited by NADP (competitive with respect to NADPH, Ki = 50 microM). The molecular weight of the native inactive or active enzyme is 150,000 with subunits of Mr 38,000. Active enzyme is much more sensitive (greater than 50-fold) to heat denaturation than is the inactive enzyme and is irreversibly inactivated by N-ethylmaleimide whereas the inactive enzyme is insensitive to this reagent. The active and inactive forms of NADP-malate dehydrogenase are assumed to correspond to dithiol and disulfide forms of the enzyme, respectively. The relative coenzyme-binding affinities of inactive NADP-malate dehydrogenase differ by a factor of 10(2) from the binding affinities for active NADP-malate dehydrogenase and 10(4) for non-thiol-regulated NAD-specific malate dehydrogenase. It is proposed that the 100-fold change in differential binding of NADP and NADPH upon conversion of NADP-malate dehydrogenase to the disulfide form may sufficiently alter the equilibrium of the central enzyme-substrate complexes, and hence the catalytic efficiency of the enzyme, to explain the associated loss of activity.

Regulation of C4 photosynthesis: regulation of activation and inactivation of NADP-malate dehydrogenase by NADP and NADPH.

Inactive NADP-malate dehydrogenase (disulfide form) from chloroplasts of Zea mays is activated by reduced thioredoxin while the active enzyme (dithiol form) is inactivated by incubation with oxidized thioredoxin. This reductive activation of NADP-malate dehydrogenase is inhibited by over 95% in the presence of NADP and the Kd for this interaction of NADP with the inactive enzyme is about 3 microM. Other substrates of the enzyme (malate, oxaloacetate, or NADPH) do not effect the rate of enzyme activation but NADPH can reverse the inhibitory effect of NADP. It appears that NADPH (Kd = 250 microM) and NADP (Kd = 3 microM) compete for the same site, presumably the coenzyme-binding site at the active centre. Apparently the enzyme . NADP binary complex cannot be reduced by thioredoxin whereas the enzyme . NADPH complex is reduced at the same rate as is the free enzyme. Similarly the oxidative inactivation of reduced NADP-malate dehydrogenase is inhibited by up to 85% by NADP and NADPH completely reverses this inhibition. The Kd values of the active-reduced enzyme for NADP and NADPH were both estimated to be 30 microM. From these data a model was constructed which predicts how changing NADPH/NADP levels in the chloroplast might change the steady-state level of NADP-malate dehydrogenase activity. The model indicates that at any fixed ratio of reduced to oxidized thioredoxin high proportions of active NADP-malate dehydrogenase and, hence, high rates of oxaloacetate reduction, can only occur with very high NADPH/NADP ratios.

Regulation of C4 photosynthesis: regulation of pyruvate, Pi dikinase by ADP-dependent phosphorylation and dephosphorylation.

Pyruvate, Pi dikinase in extracts of chloroplasts from mesophyll cells of Zea mays is inactivated by incubation with ADP plus ATP. This inactivation was associated with phosphorylation of a threonine residue on a 100 kDa polypeptide, the major polypeptide of the mesophyll chloroplast stroma, which was identified as the subunit of pyruvate, Pi dikinase. The phosphate originated from the beta-position of ADP as indicated by the labelling of the enzyme during inactivation in the presence of [beta-32P]ADP. During inactivation of the enzyme up to 1 mole of phosphate was incorporated per mole of pyruvate, Pi dikinase subunit inactivated. 32P label was lost from the protein during the Pi-dependent reactivation of pyruvate, Pi dikinase.

The specific interaction of cibacron and related dyes with cyclic nucleotide phosphodiesterase and lactate dehydrogenase.

1. Reactive Blue 2 (Cibacron Blue 3G-A) is a competitive inhibitor of bovine heart cyclic nucleotide phosphodiesterase (K(i) 0.3mum). The K(i) increases with increasing temperature, suggesting that hydrophobic interactions are not largely responsible for the binding of the dye. Another 25 sulphonated aromatic dyes are also competitive inhibitors of the cyclic nucleotide phosphodiesterase (K(i) values in the range of 0.06-13.6mum). 2. These dyes (covalently linked to Dextran 40) inhibit bovine heart cyclic nucleotide phosphodiesterase. Reactive Blue 2 (covalently linked to Dextran 40) is a competitive inhibitor of the phosphodiesterase (K(i) 0.4mum). 3. Bovine heart cyclic nucleotide phosphodiesterase is retained on a column of Reactive Blue 2-Sephacryl S-200 and can be eluted from the column by 3':5'-cyclic AMP. 4. A variety of the dyes (either free or covalently linked to Dextran 40) are competitive inhibitors of rabbit muscle lactate dehydrogenase. 5. The effectiveness of a wide range of structurally dissimilar dyes as competitive inhibitors of lactate dehydrogenase and cyclic nucleotide phosphodiesterase compromises proposals for the use of Reactive Blue 2 as a specific probe for the dinucleotide-binding structural domain present in many dehydrogenases and kinases. Detailed information of the various dyes used has been deposited as Supplementary Publication SUP 50089 (7 pages) at the British Library Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1978) 169, 5.

Adenosine 3':5'-cyclic monophosphate in higher plants: Isolation and characterization of adenosine 3':5'-cyclic monophosphate from Kalanchoe and Agave.

1.3':5'-Cyclic AMP was extensively purified from Kalanchoe daigremontiana and Agave americana by neutral alumina and anion- and cation-exchange column chromatography. Inclusion of 3':5'-cyclic [8-3H]AMP from the point of tissue extraction permitted calculation of yields. The purification procedure removed contaminating material that was shown to interfere with the 3':5'-cyclic AMP estimation and characterization procedures. 2. The partially purified 3':5'-cyclic AMP was quantified by means of a radiochemical saturation assay using an ox heart 3':5'-cyclic AMP-binding protein and by an assay involving activation of a mammalian protein kinase. 3. The plant 3':5'-cyclic AMP co-migrated with 3':5'-cyclic [8-3H]AMP on cellulose chromatography, poly(ethyleneimine)-cellulose chromatography and silica-gel t.l.c. developed with several solvent systems. 4. The plant 3':5'-cyclic AMP was degraded by ox heart 3':5'-cyclic nucleotide phosphodiesterase at the same rates as authentic 3':5'-cyclic AMP. 1-Methyl-3-isobutylxanthine (1 mM), a specific inhibitor of the 3':5'-cyclic nucleotide phosphodieterase, completely inhibited such degradation. 5. The concentrations of 3':5'-cyclic AMP satisfying the above criteria in Kalanchoe and Agave were 2-6 and 1 pmol/g fresh wt. respectively. Possible bacterial contribution to these analyses was estimated to be less than 0.002pmol/g fresh wt. Evidence for the occurrence of 3':5'-cyclic AMP in plants is discussed.

Molecular cloning of two different cDNAs for maize acetyl CoA carboxylase.

Acetyl CoA carboxylase (EC 6.4.1.2) in plants is a chloroplast-localized, biotin-containing enzyme that catalyses the carboxylation of acetyl CoA to malonyl CoA, the first committed step of the fatty acid biosynthesis pathway. Acetyl CoA carboxylase is the target site for the monocotyledon-specific aryloxyphenoxypropionate and cyclohexanedione groups of herbicides. We have purified a herbicide-sensitive acetyl CoA carboxylase from maize leaves to homogeneity (specific activity 7 mumol min-1 mg-1), separating it during the purification from a minor herbicide-resistant acetyl CoA carboxylase. The purified enzyme is a dimer of 230 kDa subunits. Antibodies raised to the purified acetyl CoA carboxylase detected three cross-reacting clones in a maize leaf cDNA expression library, each having an insert of 4-4.5 kb. Restriction analysis and sequencing showed that the cDNAs were derived from two different transcripts. Comparison of the deduced amino acid sequences with those of chicken and yeast acetyl CoA carboxylases confirmed that both types encoded acetyl CoA carboxylase, corresponding to the C-terminal half of the enzyme. The overall identity of the maize and chicken sequences was 37% (58% similarity) but for some shorter regions was much higher. Analysis of six other acetyl CoA carboxylase clones recovered from the maize cDNA library showed four belonged to one type and two to the other. The nucleotide sequence similarity between the two types of cDNA was approximately 95% in the coding region but considerably less in the 3'-untranslated region. Northern blot analysis of maize RNA showed a single band of 8.2-8.5 kb for acetyl CoA carboxylase mRNA. Southern blot hybridisations indicated that there are probably no more than two genes in maize for acetyl CoA carboxylase. The possible significance of two different cDNAs for acetyl CoA carboxylase is discussed.

Thioredoxin-like Activity of Thylakoid Membranes: THIOREDOXIN CATALYZING THE REDUCTIVE INACTIVATION OF GLUCOSE-6-PHOSPHATE DEHYDROGENASE OCCURS IN BOTH SOLUBLE AND MEMBRANE-BOUND FORM.

The inactivation of pea leaf chloroplast glucose-6-phosphate dehydrogenase by dithiothreitol can be catalyzed by thioredoxin-like molecules that are present in chloroplasts. This thioredoxin activity occurs predominantly as a soluble species, but washed thylakoid membranes also exhibit some thioredoxin-like activity. The membrane-associated thioredoxin can be extracted by treatment with the detergent Triton X-100. The solubilized thioredoxin appears to have a molecular size similar to that of the soluble thioredoxin which catalyzes the same reaction. The thylakoid-bound activity constitutes only about 5% of the total chloroplast thioredoxin activity. The thioredoxin occurring in the membrane fraction cannot, however, be ascribed to the trapping of stroma since less than 0.1% of three stromal marker enzymes are found in the same thylakoid extract.

Regulation of C4 photosynthesis: inactivation of pyruvate, Pi dikinase by ADP-dependent phosphorylation and activation by phosphorolysis.

These studies provide information about the mechanism of the light/dark-mediated regulation of pyruvate, Pi dikinase (EC 2.7.9.1) in leaves. It is shown that inactivation is due to a phosphorylation of the enzyme from the beta-phosphate of ADP, and that activation occurs by phosphorolysis to remove the enzyme phosphate group. During ADP plus ATP-dependent inactivation of pyruvate, Pi dikinase in chloroplast extracts, 32P was incorporated into the enzyme from [beta-32P]ADP. Approximately 1 mol of phosphate was incorporated per mol of monomeric enzyme subunit inactivated. There was very little incorporation of label from ADP or ATP labeled variously in other positions with 32P or from the nucleotides labeled with 3H in the purine ring. Purified pyruvate, Pi dikinase was also labeled from [beta-32P]ADP during inactivation. In this system, phosphorylation of the enzyme required the addition of the "regulatory protein" shown previously to be essential for catalyzing inactivation and activation. During orthophosphate-dependent reactivation of pyruvate, Pi dikinase, it was shown that the enzyme loses 32P label and that pyrophosphate is produced. The significance of these findings in relation to regulation of the enzyme in vivo is discussed.

Studies on wheat acetyl CoA carboxylase and the cloning of a partial cDNA.

Wheat germ acetyl CoA carboxylase (ACCase) was purified by liquid chromatography and electroelution. During purification bovine serum albumin (BSA) was used to coat Amicon membranes used to concentrate partially pure ACCase. Despite further SDS-PAGE/electroelution and microbore HPLC steps BSA remained associated. This presented serious protein sequencing artefacts which may reflect the affinity of BSA for fatty acids bound to ACCase. To avoid these artefacts the enzyme was digested in gel with Endoproteinase LysC protease without the presence of BSA, and the resulting peptides blotted and sequenced. A partial cDNA (1.85 kb) encoding ACCase from a wheat embryo library was cloned, which hybridised to a 7.5 kb RNA species on northern blot of wheat leaf poly(A)+ RNA. The partial cDNA therefore represents about 0.25 of the full-length cDNA. The clone was authenticated by ACCase peptide sequencing and immuno cross-reactivity of the overexpressed clone. The derived amino acid sequence showed homology with both rat and yeast ACCase sequences (62%). Antibodies raised against wheat acetyl CoA carboxylase were specific for a 220 kDa protein from both wheat embryo and leaf. In addition, by using a novel quick assay for ACCase that utilised 125I-streptavidin, we showed the major biotin containing protein to be 220 kDa in both leaf and germ. This is in marked contrast to the previously published molecular mass of 75 kDa allocated to wheat leaf ACCase.