Essentiality of the small subunit (B) in the catalysis of RuBP carboxylase/oxygenase is not related to substrate-binding in the large subunit (A)

The small subunit (B) of ribulose 1,5-bisphosphate (RuBP) carboxylase/oxygenase from Aphanothece halophytica is absolutely required for the catalysis, but depletion of subunit B does not significantly affect the formation of the quaternary complex-[enzyme.activator CO2.Mg.carboxyarabinitol bisphosphate] in the catalytic core. The inhibition of RuBP carboxylase activity by the reaction of the epsilon-amino group of a lysine in the RuBP-binding site with pyridoxal 5-P is the same whether subunit B is added to the catalytic core before or after the inactivating reaction. The function of subunit B is not related to the substrate binding.     

Cyanate modification of essential lysyl residues in the catalytic subunit of tobacco ribulosebisphosphate carboxylase

Crystalline ribulose-1,5-bisphosphate carboxylase (3-phospho-D-glycerate carboxy-lyase (dimerizing), EC 4.1.1.39) isolated from tobacco (Nicotiana tabacum L.) leaf homogenates is irreversibly inactivated by incubation with potassium cyanate at pH 7.4. The rate of inactivation is pseudo first-order and linearly dependent on reagent concentration. In the presence of ribulosebisphosphate or high levels of CO2 and Mg2+ the rate constant for inactivation is reduced, suggesting that chemical modification occurs in the active site region of the enzyme. In contrast, neither the effector NADPH nor the activator Mg2+ alone significantly affect the rate of inactivation by cyanate; however, NADPH markedly enhances the protective effect of CO2 and Mg2+. Incubation of the carboxylase with potassium [14C] cyanate in the absence or presence of ribulosebisphosphate revealed that the substrate specifically reduces cyanate incorporation into the large catalytic subunits of the enzyme. Analysis of acid hydrolysates of the radioactive carboxylase indicated that the reagent carbamylates both NH2-terminal groups and lysyl residues in the large and small subunits. Comparison of the substrate-protected enzyme with the inactivated carboxylase revealed that ribulosebisphosphate preferentially reduces lysyl modification within the large subunit. The data here presented indicate that inactivation of ribulosebisphosphate carboxylase by cyanate or its reactive tautomer, isocyanic acid, results from the modification of lysyl residues within the catalytic subunit, presumably at the activator and substrate CO2 binding sites on the enzyme.     

Bicarbonate is a recycling substrate for cyanase

Cyanase is an inducible enzyme in Escherichia coli that catalyzes bicarbonate-dependent decomposition of cyanate to ammonia and bicarbonate. Previous studies provided evidence that carbamate is an initial product and that the kinetic mechanism is rapid equilibrium random (bicarbonate serving as substrate as opposed to activator); the following mechanism was proposed (Anderson, P. M. (1980) Biochemistry 19, 2282-2888; Anderson, P. M., and Little, R. M. (1986) Biochemistry 25, 1621-1626). (formula; see text) Direct evidence for this mechanism was obtained in this study by 1) determining whether CO2 or HCO3- serves as substrate and is formed as product, 2) identifying the products formed from [14C]HCO3- and [14C] OCN-, 3) identifying the products formed from [13C] HCO3- and [12C]OCN- in the presence of [18O]H2O, and 4) determining whether 18O from [18O]HCO3- is incorporated into CO2 derived from OCN-. Bicarbonate (not CO2) is the substrate. Carbon dioxide (not HCO3-) is produced in stoichiometric amounts from both HCO3- and OCN-. 18O from [18O]H2O is not incorporated into CO2 formed from either HCO3- or OCN-. Oxygen-18 from [18O]HCO3- is incorporated into CO2 derived from OCN-. These results support the above mechanism, indicating that decomposition of cyanate catalyzed by cyanase is not a hydrolysis reaction and that bicarbonate functions as a recycling substrate.     

The activation of ribulose-1,5-bisphosphate carboxylase by carbon dioxide and magnesium ions. Equilibria, kinetics, a suggested mechanism, and physiological implications.

Ribulose-1,5-bisphosphate carboxylase was activated by incubation with CO2 and Mg2++, and inactivated upon removal of CO2 and Mg2+ by gel filtration. The activation process involved CO2 rather than HCO3-. The activity of the enzyme was dependent upon the preincubation concentrations of CO2 and Mg2+ and upon the preincubation pH, indicating that activation involved the reversible formation of an equilibrium complex of enzyme-CO2-Mg. The initial rate of activation was linearly dependent upon the CO2 concentration but independent of the Mg2+ concentration. Kinetic analyses indicated that the enzyme reacted first with CO2 in a rate-determining and reversible step, followed by a rapid reaction with Mg2+ to form an active ternary complex (see eq 1 in text). The pseudo-first order rate constant, kobsd, for the activation process at constant pH was derived: kobsd=k1[CO2] + (k2k4/k3[Mg2+]). Experimentally, kobsd was shown to be linearly dependent upon the CO2 concentration and inversely dependent upon the Mg2+ concentration. The activity of the enzyme after preincubation to equilibrium at constant concentrations of CO2 and Mg2+ increased as the preincubation pH was raised, indicating that CO2 reacted with an enzyme group whose pK was distinctly alkaline. It is proposed that the activation of ribulose-1, 5-biphosphate carboxylane involves the formation of a carbamate.     

Crystal structure of activated ribulose-1,5-bisphosphate carboxylase complexed with its substrate, ribulose-1,5-bisphosphate

The three-dimensional structure of the complex of ribulose-1,5-bisphosphate carboxylase from Rhodospirillum rubrum, CO2, Mg2+, and ribulose bisphosphate has been determined with x-ray crystallographic methods to 2.6-A resolution. Ribulose-1,5-bisphosphate binds across the active site with the two phosphate groups in the two phosphate binding sites of the beta/alpha barrel. The oxygen atoms of the carbamate and the side chain of Asp-193 provide the protein ligands to the bound Mg2+ ion. The C2 and the C3 or C4 oxygen atoms of the substrate are also within the first coordination sphere of the metal ion. At the present resolution of the electron density maps, two slightly different conformations of the substrate, with the C3 hydroxyl group "cis" or "trans" to the C2 oxygen, can be built into the observed electron density. The two different conformations suggest two different mechanisms of proton abstraction in the first step of catalysis, the enolization of the ribulose 1,5-bisphosphate. Two loop regions, which are disordered in the crystals of the nonactivated enzyme, could be built into their respective electron density. A comparison with the structure of the quaternary complex of the spinach enzyme shows that despite the different conformations of loop 6, the positions of the Mg2+ ion, and most atoms of the substrate are very similar when superimposed on each other. There are, however, some significant differences at the active site, especially in the metal coordination sphere.     

The sites for catalysis and activation of ribulosebisphosphate carboxylase share a common domain

The complexation of ribulosebiphosphate carboxylase with CO2, Mg2+, and carboxyarabinitol bisphosphate (CABP) to produce the quaternary enzyme-carbamate-Mg2+-CABP complex closely mimics the formation of the catalytically competent enzyme-carbamate-Mg2+-3-keto-CABP form during enzymatic catalysis. Quaternary complexes were prepared with various metals (Mg2+, Cd2+, Mn2+, Co2+, and Ni2+) and with specifically 13C-enriched ligands. 31P and 13C NMR studies of these complexes demonstrate that the activator CO2 site (carbamate site), the metal binding site, and the substrate binding site are contiguous. It follows that both the carboxylase and oxygenase activities of this bifunctional enzyme are influenced by the structures of the catalytic and activation sites.     

The kinetic mechanism of yeast inorganic pyrophosphatase

The kinetic mechanism of yeast inorganic pyrophosphatase (PPase) was examined by carrying out initial velocity studies. Ca2+ and Rh(H2O)4(methylenediphosphonate) (Rh(H2O)4PCP) were used as dead-end inhibitors to study the order of binding of Cr(H2O)4PP to the substrate site and Mg2+ to the "low affinity" activator site on the enzyme. Competitive inhibition was observed for Ca2+ vs Mg2+ (Kis = 0.93 +/- 0.03 mM), for Rh(H2O)4PCP vs Cr(H2O)4PP (Kis = 0.25 +/- 0.07 mM), and for RH(H2O)4PCP vs Mg2+ (Kis = 0.38 +/- 0.03 mM). Uncompetitive inhibition was observed for Ca2+ vs Cr(H2O)4PP (Kii = 0.49 +/- 0.01). On the basis of these results a rapid equilibrium ordered mechanism in which Cr(H2O)4PP binding precedes Mg2+ ion binding is proposed. The inert substrate analog, Mg(imidodiphosphate) (MgPNP) was shown to induce Mg2+ inhibition of the PPase-catalyzed hydrolysis of MgPP. The Mg2+ inhibition observed was competitive vs MgPP and partial. These results suggest that Mg2+/MgPNP release from the enzyme occurs in preferred rather than strict order and that the Mg2+/MgPP-binding steps are at steady state. Zn2+, Co2+, and Mn2+ (but not Mg2+) displayed activator inhibition of the PPase-catalyzed hydrolysis of PPi (this study) and of Cr(H2O)4PP (W.B. Knight, S. Fitts, and D. Dunaway-Mariano, (1981) Biochemistry 20, 4079). These findings suggest that cofactor release from the low affinity cofactor site on the enzyme must precede product release and that Zn2+, Mn2+, and Co2+ (but not Mg2+) have high affinities for the cofactor sites on both the PPase.M.MPP and PPase.M.M(P)2 complexes. The role of the metal cofactor in determining PPase substrate specificity was briefly explored by testing the ability of the Mg2+ complex of tripolyphosphate (PPPi) (a substrate for the Zn2+-activated enzyme but not the Mg2+-activated enzyme) to induce Mg2+ inhibition of PPase-catalyzed hydrolysis of MgPP. MgPPP was shown to be as effective as MgPNP in inducing competitive Mg2+ inhibition (vs MgPP). This result suggests that the low affinity Mg2+ cofactor-binding site present in the enzyme-MgPP complex is maintained in the enzyme-MgPPP complex. Thus, failure of Mg2+ to bind to the enzyme-MgPPP complex was ruled out as a possible explanation for the failure of the Mg2+-activated enzyme to catalyze the hydrolysis of MgPPP.     

Catalytic properties of chloroplast F1-ATPase modified at catalytic or noncatalytic sites by 2-azido adenine nucleotides

When heat-activated F1-ATPase from chloroplasts was repeatedly exposed to Mg2+ and 2-azido-ATP, followed by separation from medium nucleotides and photolysis, a total of two sites per enzyme, both catalytic and noncatalytic, were labeled. In a coupled assay with pyruvate kinase about half the activity was lost when one site per enzyme was modified. However, increased modification resulted in no further loss of activity. In contrast, methanol-sulfite activation of the enzyme showed a loss of most of the catalytic capacity when one site per enzyme was modified. Predominant labeling of either one catalytic or one noncatalytic site caused a loss of most of the activity in either assay. An indication that the enzyme modified at one site retained some catalytic activity was verified by measurement of the [18O]Pi species formed when [gamma-18O]ATP was hydrolyzed by partially derivatized enzyme. With either catalytic or noncatalytic site modification, the distributions of [18O]Pi species formed showed that the modified enzyme had different catalytic characteristics. An interpretation is that with modification by azido nucleotides at either catalytic or noncatalytic sites, capacity for rapid catalysis is largely lost but the remaining sites retain weak modified catalytic properties.     

Membrane-associated thiamin triphosphatase. II. Activation by divalent cations.

Activation of membrane-associated thiamin triphosphatase from rat brain requires a divalent cation (Mg2+, Ca2+, or Mn2+). The optimum concentration of Mg2+ necessary for maximal enzyme activity varies with substrate concentration; conversely, the maximal rate of hydrolysis attainbale by increasing thiamin triphosphate concentration is directly proportional to [Mg2+] for all levels of Mg2+ below that of the substrate. Under appropriate conditions, the Km of the thiamin triphosphatase for Mg2+ and for thiamin triphosphate are shown to be identical. Dissociation constants (Kd) for the binding of Mg2+ to thiamin triphosphate, thiamin diphosphate, and thiamin were determined; kinetic data re-expressed in terms of [Mg2+-thiamin triphosphate] conform to simple single substrate predictions, suggesting that the true enzyme substrate may be the Mg2+-thiamin triphosphate complex. Excess free Mg2+ inhibits thiamin triphosphatase activity competitively while excess free thiamin triphosphate in concentrations up to 10 times Km has no effect on the membrane-bound enzyme.     

Crystal structure of the ternary complex of ribulose-1,5-bisphosphate carboxylase, Mg(II), and activator CO2 at 2.3-A resolution

The activated ternary complex, enzyme-CO2-Mg(II), of the dimeric ribulose-1,5-bisphosphate carboxylase/oxygenase from Rhodospirillum rubrum can be prepared in the same crystal form that was used for the crystallographic structure determination of the native nonactivated enzyme (Schneider, G., Br?nden, C.-I., & Lorimer, G. (1986) J. Mol. Biol. 187, 141-143). The three-dimensional structure of the activated enzyme has been determined to a nominal resolution of 2.3 A by protein crystallographic methods. The activator CO2 forms a carbamate with Lys191, located at the bottom of the funnel-shaped active site. In both subunits, this labile adduct is stabilized by a Mg(II) ion, bound to the carbamate and the side chains of Asp193 and Glu194. One solvent molecule was found within the first coordination sphere of the metal ion. The metal-binding site in ribulose-1,5-bisphosphate carboxylase consists thus of at least three protein ligands, all located on loop 2 of the beta/alpha barrel. One additional metal ligand, the side chain of the conserved Asn111, was observed close to the Mg(II) ion in the B-subunit. Other structural differences at the active site between the activated and nonactivated enzyme are limited to side-chain positions. Nevertheless, it is obvious that the hydrogen-bonding pattern in the vicinity of the activator site is completely altered.     

The orientation of substrate and reaction intermediates in the active site of ribulose-1,5-bisphosphate carboxylase

There are four possible orientations of the substrate ribulose 1,5-bisphosphate in the active site of ribulose-1,5-bisphosphate carboxylase. Distinction between these four possible orientations has been made on the basis of 31P NMR and borohydride-trapping experiments. The orientation of the reaction-intermediate analog, 2'-carboxy-D-arabinitol 1,5-bisphosphate with respect to the divalent metal ion was determined by 31P NMR studies of the quaternary complex, enzyme.CO2.Ni2+.2'-carboxyarabinitol 1,5-bisphosphate. Assignment of the phosphorus resonances of this complex was made by labeling the phosphoryl group at either C-1 or C-5 with 17O. The phosphorus atom closer to the paramagnetic metal ion, Ni2+, to which the broader of the phosphorus resonances is attributed, has been identified as that attached to C-1. When bound to the active site of carbaminated enzyme, D-ribulose 1,5-bisphosphate was reduced by sodium borohydride with absolute stereospecificity to D-arabinitol 1,5-bisphosphate. The reduction of the enzyme-bound substrate thus occurred on the Si face of the C-2 carbonyl group. These two results together establish that ribulose 1,5-bisphosphate is oriented within the active site so that 1) the phosphoryl group at C-1 is closer to the divalent metal ion than that at C-5 and 2) the Si face of the carbonyl group points to the "outside world."     

Estimation of Bundle Sheath Cell Conductance in C4 Species and O2 Insensitivity of Photosynthesis

Low conductance to CO2 of bundle sheath cells is required in C4 photosynthesis to maintain high [CO2] at the site of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco). Elevated [CO2] allows high CO2 assimilation rates by this enzyme and prevents Rubisco oxygenase activity and O2 inhibition of carboxylation. Bundle sheath conductance to CO2 was estimated by chemically inhibiting phosphoenolpyruvate carboxylase and calculating the slope of the linear response of leaf CO2 uptake to [CO2]. The inhibitor 3,3-dichloro-2-dihydroxyphosphinoylmethyl-2-propenoate was supplied to detached leaves of Panicum maximum, Panicum miliaceum, and Sorghum bicolor at 4 mM. Uptake of CO2 was measured at 210 mL L-1 O2 over the CO2 concentration range of 0.34 to 28 mL L-1. Without the inhibitor, CO2 uptake increased steeply at low [CO2] and saturated at about 1 mL L-1. After inhibition, CO2 uptake was a linear function of [CO2] over much of the range tested. The slope of this CO2 response, taken as bundle sheath conductance, was 2.35, 1.96, and 1.13 mmol m-2 s-1 for P. maximum, P. miliaceum, and S. bicolor, respectively, on a leaf area basis. Conductance based on bundle sheath area was 0.76, 0.93, and 0.54 mmol m-2 s-1, respectively. Uptake of CO2 by leaves of P. maximum supplied with the inhibitor was not affected by reduction of [O2] from 210 to 20 mL L-1 over the range of [CO2] used. Because [CO2] in bundle sheath cells of inhibited leaves is likely to be much lower than ambient, the lack of O2 sensitivity of CO2 uptake cannot be ascribed to lack of O2 reaction with ribulose bisphosphate and is probably due to the low conductance of bundle sheath cells, especially at low ambient [CO2]. The likely result of reducing [O2] from 210 to 20 mL L-1 is to stimulate carboxylation of ribulose bisphosphate, thus further reducing [CO2] in bundle sheath cells and increasing CO2 diffusion to these cells from the mesophyll. However, the increase in diffusion is greatly limited by low conductance of the bundle sheath cell walls. Calculations based on estimated bundle sheath conductance show that changes in bundle sheath [CO2] of 0.085 to 0.5 mL L-1, which might be associated with reduced [O2], would have a negligible effect on CO2 uptake.     

The involvement of catalytic site thiol groups in the activation of soluble guanylate cyclase by sodium nitroprusside

Sodium nitroprusside, a potent activator of soluble guanylate cyclase, potentiated mixed disulfide formation between cystine, a potent inhibitor of the cyclase, and enzyme purified from rat lung. Incubation of soluble guanylate cyclase with nitroprusside and [35S]cystine resulted in a twofold increase in protein-bound radioactivity compared to incubations in the absence of nitroprusside. Purified enzyme preincubated with nitroprusside and then gel filtered (activated enzyme) was activated 10- to 20-fold compared to guanylate cyclase preincubated in the absence of nitroprusside and similarly processed (nonactivated enzyme). This activation was completely reversed by subsequent incubation at 37 degrees C (activation-reversed enzyme). Incorporation of [35S]cystine into guanylate cyclase was increased twofold with activated enzyme, while no difference was observed with activation-reversed enzyme, compared to nonactivated enzyme. Cystine decreased the activity of nonactivated and activation-reversed enzyme about 40% while it completely inhibited activated guanylate cyclase. Mg+2- or Mn+2-GTP inhibited the incorporation of [35S]cystine into nonactivated or activated guanylate cyclase. Also, diamide, a potent thiol oxidant that converts juxtaposed sulfhydryls to disulfides, completely blocked incorporation of [35S]cystine into nonactivated or activated guanylate cyclase. These data indicate that activation of soluble guanylate cyclase by nitroprusside results in an increased availability of protein sulfhydryl groups for mixed disulfide formation with cystine. Protection against mixed disulfide formation with diamide or substrate suggests that these groups exist as two or more juxtaposed sulfhydryl groups at the active site or a site on the enzyme that regulates catalytic activity. Differential inhibition by mixed disulfide formation of nonactivated and activated enzyme suggests a mechanism for amplification of the on-off signal for soluble guanylate cyclase within cells.     

2-(4-Bromoacetamido)anilino-2-deoxypentitol 1,5-bisphosphate, a new affinity label for ribulose bisphosphate carboxylase/oxygenase from Rhodospirillum rubrum. Determination of reaction parameters and characterization of an active site peptide

A new affinity label for ribulose bisphosphate carboxylase/oxygenase from Rhodospirillum rubrum, 2-(4-bromoacetamido)anilino-2-deoxypentitol 1,5-bisphosphate, has been prepared, Reductive amination of ribulose-P2 with p-phenylenediamine in the presence of sodium cyanoborohydride yielded an epimeric mixture which was resolved by chromatography on quaternary aminoethyl-Sephadex. Subsequent bromoacetylation of the isolated amino bisphosphates gave reagents A and B (ribo and arabino epimers of 2-(4-bromoacetamido) anilino-2-deoxypentitol 1,5-bisphosphate) which were competitive inhibitors of the carboxylase with Ki values of 705 and 104 microM, respectively. Reagent A exhibited no time-dependent effects on the carboxylase in either the deactivated or activated state. Incubation of the enzyme with reagent B in the presence of the essential activators CO2 and Mg2+, however, resulted in an irreversible, time-dependent loss of activity, with a Kinact of 125 microM and a minimal half-time of 7.3 min. Covalent incorporation of [14C]reagent B was directly proportional to the loss of activity, with total inactivation correlating with an incorporation of 1.1 mol of reagent/mol of subunit. Inclusion of the competitive inhibitor 2-carboxyribitol 1,5-bisphosphate protected against inactivation with a concomitant reduction in incorporation. Neither reagent affected the activity of spinach carboxylase. Fractionation of [14C]reagent B-modified enzyme on DEAE-cellulose, subsequent to carboxymethylation and tryptic digestion, revealed two major radioactive peaks of approximately equal area. Digestion of each peak with alkaline phosphatase and rechromatography on DEAE-cellulose resulted in pure peptides I and II. The peptides were identical except in the site of labeling: peptide I contained a modified cysteinyl residue while peptide II contained a modified histidyl residue. Automated Edman degradation established the sequence as (sequence in text) which is located near the NH2 terminus of the enzyme. The lack of reactivity with the spinach enzyme is explained by the deletion of the histidyl residue and the replacement of cysteine by tryptophan in the eukaryotic species. Although the nonconservation of the modified residues argues against a functional role other than maintenance of structural integrity, the extensive homology in this region among seven different species of carboxylase is compatible with the region comprising a portion of the active site.     

Kinetic evidence of the existence of a regulatory phosphoenolpyruvate binding site in maize leaf phosphoenolpyruvate carboxylase

Phenylphosphate, a structural analog of phosphoenolpyruvate (PEP), was found to be an activator of phosphoenolpyruvate carboxylase (PEP carboxylase) purified from maize leaves. This finding suggested the presence in the enzyme of a regulatory site, to which PEP could bind. We carried out kinetic studies on this enzyme using controlled concentrations of free PEP and of Mg-PEP complex and developed a theoretical kinetic model of the reaction. In summary, the main conclusions drawn from our results, and taken as assumptions of the model, were the following: (i) The affinity of the active site for the complex Mg-PEP is much higher than that for free PEP and Mg2+ ions, and therefore it can be considered that the preferential substrate of the PEP-catalyzed reaction is Mg-PEP. (ii) The enzyme has a regulatory site specific for free PEP, to which Mg2+ ions can not bind. (iii) The binding of free PEP, or an analog molecule, to this regulatory site yields a modified enzyme that has much lower apparent Km values and apparent Vmax values than the unmodified enzyme. So, free PEP behaves as an excellent activator of the reaction at subsaturating substrate concentrations, and as an inhibitor at saturating substrate concentrations. These findings may have important physiological implications on the regulation of the PEP carboxylase in vivo activity and, consequently, of the C4 pathway, since increased reaction rates would be obtained when the concentration of PEP rises, even at limiting Mg2+ concentrations.     

Stereochemical probes of the argininosuccinate synthetase reaction

The stereochemical course of the argininosuccinate synthetase reaction has been determined. The SP isomer of [alpha-17O,alpha-18O,alpha beta-18O]ATP is cleaved to (SP)-[16O,17O,18O]AMP by the action of argininosuccinate synthetase in the presence of citrulline and aspartate. The overall stereochemical transformation is therefore net inversion, and thus the enzyme does not catalyze the formation of an adenylylated enzyme intermediate prior to the synthesis of citrulline adenylate. The RP isomer of adenosine 5'-O-(2-thiotriphosphate) (ATP beta S) is a substrate in the presence of Mg2+, but the SP isomer is a substrate when Cd2+ is used as the activating divalent cation. Therefore, the lambda screw sense configuration of the beta,gamma-bidentate metal--ATP complex is preferred by the enzyme as the actual substrate. No significant discrimination could be detected between the RP and SP isomers of adenosine 5'-O-(1-thiotriphosphate) (ATP alpha S) when Mg2+ or Mn2+ are used as the divalent cation. Argininosuccinate synthetase has been shown to require a free divalent cation for full activity in addition to the metal ion needed to complex the ATP used in the reaction.     

Partition kinetics of ribulose-1,5-bisphosphate carboxylase from Rhodospirillum rubrum

When the enzymatically generated intermediate 2-carboxy-3-keto-D-arabinitol-1,5-bisphosphate (II) was used as a substrate with fresh enzyme, 70% reacted to produce 3-phosphoglycerate (3PGA). When a reaction mixture of enzyme plus [1-32P]ribulose 1,5-bisphosphate (RuBP) was quenched in the steady state with the tightly bound inhibitor 2-carboxyarabinitol-1,5-bisphosphate, 30% of the enzyme-bound species was released as 3PGA and 70% as RuBP. The major source for this partition was the ternary substrates Michaelis complex. The level of carboxylated intermediate in the steady state was determined to be 8% of active sites under the conditions of substrate saturation. No burst was seen in the appearance of product when 6.5 eq of [1-32P]RuBP was mixed with enzyme plus saturating CO2 and the reaction followed in the steady state. From these data plus the steady-state Vmax and Km of RuBP it is possible to derive the five bulk rate constants represented in the scheme ECO2 + RuBP in equilibrium ERuBPCO2 in equilibrium E X II----E + 2(3PGA).     

Isolation and sequence of the pyridoxal 5'-phosphate active-site peptide from Rhodospirillum rubrum ribulose-1,5-bisphosphate carboxylase/oxygenase

Ribulose-1,5-bisphosphate carboxylase/oxygenase from Rhodospirillum rubrum was modified with pyridoxal 5'-phosphate and then reduced with sodium borohydride. Both carboxylase and oxygenase activities were lost when one molecule of pyridoxal 5'-phosphate was bound per enzyme dimer. Peptide maps of modified enzyme showed one N6-(phosphopyridoxal)lysine-containing peptide. This peptide was isolated by gel filtration and cation-exchange chromatography and its sequence determined as Ala-Leu-Gly-Arg-Pro-Glu-Val-Asp-(PLP-Lys)-Gly-Thr-Leu-Val-Ile-Lys. Since activation of the enzyme with Mg2+/CO2 enhances pyridoxal 5'-phosphate modification and subsequent inactivation and the substrate ribulose bisphosphate protects against modification, the modified lysyl group is most certainly at the catalytic site and not at the activation site of the enzyme.     

Affinity labelling with a deaminatively generated carbonium ion. Kinetics and stoicheiometry of the alkylation of methionine-500 of the lacZ beta-galactosidase of Escherichia coli by beta-D-galactopyranosylmethyl-p-nitrophenyltriazene.

1. beta-D-Galactopyranosylmethyl-p-nitrophenyltriazene is an active-site-directed irreversible inhibitor of Mg2+-bound and Mg2+-free lacZ beta-galactosidase from Escherichia coli. 2. The Mg2+-enzyme binds the inhibitor more tightly but the complex then decomposes less rapidly than is the case with Mg2+-free enzyme. 3. Loss of enzyme activity is a linear function of the fraction of enzyme protomers to which are attached beta-D-galactopranosyl[14C]methyl residues: complete inactivation of fully active enzyme results in incorporation of 0.91 equivalent of carbohydrate label per enzyme protomer. 4. When the beta-galactopyranosylmethyl cation is generated in the active site of Mg2+-enzyme, it is captured essentially completely by the protein, but in the active site of Mg2+-free enzyme it is only captured with an efficiency of 25%. 5. Labelled enzyme was carboxymethylated and digested with trypsin; acidic hydrolysis of the isolated tryptic peptide, and field-desorption mass spectrometry of the isolated radioactive derivative, showed it to be 2,5-dioxo-3[2-(beta-D-galactopyranosylmethylthio)ethyl]-1,6-trimethylenepiperazine. 6. This is considered to have arisen from labelling of the sulphur atom of a methionine residue adjacent to a proline residue. 7. The complete amino acid sequence of the molecule [Fowler & Zabin (1977) Proc. Natl. Acad. Sci. U.S.A. 74, 1507-1510] enables the labelled methionine residue to be identified as either Met-421 or Met-500. 8. Sequence data [Fowler, Zabin, Sinnott & Smith (1978) J. Biol. Chem. in the press] show the site of attack to be Met-500.     

The mechanism of rat liver fructose-1,6-bisphosphate inhibition by fructose-2,6-bisphosphate

It was found that a decrease in the activating cation (Mg2+) concentration below [A]0.5 causes the disappearance of cooperativity of the fructose 1.6-bisphosphatase substrate binding sites induced by high fructose 2.6-bisphosphate concentrations without any significant alteration in the extent of the enzyme inhibition. Under these conditions, a competitive type of inhibition (with respect to the substrate) is transformed into a non-competitive type with an increase in the fructose 2.6-bisphosphate concentration. The data obtained confirm the viewpoint that fructose 2.6-bisphosphate binds to the enzyme at two distinct sites, a catalytic and an allosteric ones, differing in their affinity for the inhibitor. It is supposed that the interaction between the allosteric fructose 2.6-bisphosphate binding site and the activator site occupied by Mg2+ is necessary for the cooperative response of the enzyme to the substrate.