Photosynthesis and Activation of Ribulose Bisphosphate Carboxylase in Wheat Seedlings : Regulation by CO(2) and O(2)

Photosynthetic carbon assimilation in plants is regulated by activity of the ribulose 1,5-bisphosphate (RuBP) carboxylase/oxygenase. Although the carboxylase requires CO₂ to activate the enzyme, changes in CO₂ between 100 and 1,400 microliters per liter did not cause changes in activation of the leaf carboxylase in light. With these CO₂ levels and 21% O₂ or 1% or less O₂, the levels of ribulose bisphosphate were high and not limiting for CO₂ fixation. With high leaf ribulose bisphosphate, the K_act(CO₂) of the carboxylase must be lower than in dark, where RuBP is quite low in leaves. When leaves were illuminated in the absence of CO₂ and O₂, activation of the carboxylase dropped to zero while RuBP levels approached the binding site concentration of the carboxylase, probably by forming the inactive enzyme-RuBP complex.

The mechanism for changing activation of the RuBP carboxylase in the light involves not only Mg²⁺ and pH changes in the chloroplast stroma, but also the effects of binding RuBP to the enzyme. In light when RuBP is greater than the binding site concentration of the carboxylase, Mg²⁺ and pH most likely determine the ratio of inactive enzyme-RuBP to active enzyme-CO₂-Mg²⁺-RuBP forms. Higher irradiances favor more optimal Mg²⁺ and pH, with greater activation of the carboxylase and increased photosynthesis.

     

A novel kinetic mechanism explaining the non-hyperbolic behavior of metal activated enzymes. Case of choline kinase from rat liver

A novel kinetic mechanism that explains the non-hyperbolic kinetics of many metal- or effector-activated enzymes is proposed as an alternative to the allosteric, hysteresis and mnemonical models. In this mechanism, the non-Michaelian behavior is generated by a reversible binding of an essential metal cation or other effector to a single site, but to at least two different enzyme forms in steady state. The model is described by a higher degree rate equation since the metal binding to more than one enzyme form generates at least two steady-state catalytic pathways of different efficiencies in addition to the recycling of the metal-enzyme species in the kinetic sequence. The proposed mechanism also explains the transition from non-hyperbolic kinetics to a Michaelian rate law, as well as the dual activation and inhibition of enzymes by the metal cation or effector, according to its concentration. This kinetic behavior is generated by the participation of the metal or effector in fast and slow competing catalytic sequences or by the competitions produced by binding as a common reactant for both the forward and reverse reactions. The model can also explain some peculiar inhibition patterns observed for some transferases. This kinetic mechanism can be tested by an experimental protocol that includes the metal cation or effector as a controlled variable reactant. The model and its complete rate equation explains the non-Michaelian behavior of choline kinase. At low ligand concentrations, an effectively ordered terreactant sequential mechanism operates (Infant. & Kinsella, 1976). The steady-state addition of choline to free enzyme is followed by the rapid-equilibrium binding of MgATp^2? and the steady-state addition of Mg²⁺ last in the sequence. Initial velocity and product inhibition studies in the non-hyperbolic kinetic region, were consistent with a partially ordered release of reactants in which phosphocholine was the first product to dissociate from the central complex. The release sequence of the other two reactants was dependent on the prevailing Mg²⁺ concentration. At low Mg²⁺ levels, i.e. below 2·0 mM the metal cation is predominantly released after phosphocholine whereas MgADP^? is the last product to dissociate under rapid-equilibrium conditions. At higher levels of the metal cation, MgADP^? is predominantly released after phosphocholine leaving the Mg-enzyme complex from which Mg²⁺ may dissociate. However, a substantial fraction of the Mg-enzyme form is recycled in an alternate catalytic sequence in which the rapid-equilibrium binding MgATP^2? to the Mg-enzyme complex is followed by the steady-state addition of choline. This pathway can also be initiated by the binding of Mg²⁺ to free enzyme. A third and unique sequence, which operates at low Mg²⁺ concentrations, includes the participation of MgADP^? as an activator via a partial reversal of one of the product release sequences. In this pathway, the rapidequilibrium binding of MgADP^? to free enzyme is followed by the addition of Mg²⁺ to the resulting transitory complex. Subsequent dissociation of MgADP^? leaves the Mg-enzyme form, which is then channeled to product formation by the consecutive additions of MgATP^2? and choline.     

Cytosolic Phosphofructokinase from Spinach Leaves : II. Affinity for Mg and Nucleoside Phosphates

Cytosolic ATP-phosphofructokinase (PFK) from spinach leaves (Spinacia oleracea L.) was inhibited by submillimolar concentrations of free Mg²⁺. The free Mg²⁺ concentration required for 50% inhibition of PFK activity was 0.22 millimolar. Inhibition by free Mg²⁺ was independent of the MgATP²⁻ concentration. Inorganic phosphate (Pi) reduces the inhibition of PFK activity by Mg²⁺. Free ATP (ATP⁴⁻) also inhibits PFK activity. For free ATP the inhibition of PFK activity was dependent on the MgATP²⁻ concentration. Fifty percent inhibition of PFK activity requires 1.2 and 3.7 millimolar free ATP at 0.1 and 0.5 millimolar MgATP²⁻, respectively. It was proposed that free ATP competes for the MgATP²⁻ binding site, whereas free Mg²⁺ does not. Pi diminished the inhibitory effect of free ATP on PFK activity. Free ATP and Pi had substantial effects on the MgATP²⁻ requirement of cytosolic PFK. For half-maximum saturation of PFK activity 3 and 76 micromolar MgATP²⁻ was required at 0.007 and 0.8 millimolar free ATP in the absence of Pi. At 5 and 25 millimolar Pi, half-maximum saturation was achieved at 9 and 14 micromolar MgATP²⁻. PFK activity was inhibited by Ca²⁺. The inhibition by Ca²⁺ depends upon the total Mg²⁺ concentration. Fifty percent inhibition of PFK activity required 22 and 32 micromolar Ca²⁺ at 0.1 and 0.2 millimolar Mg²⁺, respectively. At physiological concentrations of about 0.5 millimolar free Mg²⁺, Ca²⁺ would have little effect on cytosolic PFK activity from spinach leaves. PFK is not absolutely specific for the nucleoside 5′-triphosphate substrate. Besides MgATP²⁻, MgUTP²⁻, MgCTP²⁻, and MgGTP²⁻ could be used as a substrate. All four free nucleotides inhibit PFK activity. The physiological consequences of the regulatory properties of cytosolic PFK from spinach leaves will be discussed. A model will be introduced, in an attempt to describe the complex interaction of PFK with substrates and the effectors Mg²⁺ and Pi.     

Pyruvate carboxylase: affinity labelling of the pyruvate binding site.

The active-site-directed reagent, bromopyruvate has been used to covalently label the pyruvate binding site of pyruvate carboxylase (E.C.6.4.1.1.) isolated from sheep liver. Oxalo-acetate proved to be the most effective reaction component in protecting the enzyme against inactivation; pyruvate was less effective although its efficiency was enhanced by the presence of acetyl CoA. The other reaction components, MgATP^2? and HCO₃^? failed to protect the enzyme against inactivation. Using bromo[2¹⁴C]pyruvate, it was shown that at 100% inactivation, 1.5 pyruvyl residues were bound per mole of biotin and when the reaction was carried out in the presence of acetyl CoA, this ratio was reduced to 1.0. Analysis of pronase digests of the enzyme revealed that more than 90% of the radioactivity was present as carboxy-hydroxyethyl cysteine.     

Abnormal magnesium metabolism in etiology of salt-sensitive hypertension and type 2 diabetes mellitus

A previously unknown genetic defect in magnesium metabolism (i.e., the magnesium-binding defect [MgBD]) was found to be associated with the cause of “salt-sensitive” essential hypertension in humans and rats. It inhibits the entrance of Mg²⁺ into the cell so that the intracellular concentrations of Mg²⁺ and MgATP²⁻ are decreased. Consequently, the 300 enzyme reactions in the cell, especially the 100 that either use or produce MgATP²⁻, are inhibited. Thus, because the extrusion of intracellular Na⁺ requires MgATP²⁻, hypertension results when the involved MgATP²⁻ requiring enzyme is inhibited. The MgBD is corrected by the tachykinin substance P, which occurs in normal blood plasma, and by the pentapeptide and its contained tetrapeptide, which are released from the C-terminal region of substance P by plasma aminopeptidases. In vivo, the intravenous administration of the tetrapeptide corrects the hypertension and the MgBD as well. The MgBD also occurs in type 2 diabetes mellitus and, thus, the decreased intracellular concentrations of Mg²⁺ and MgATP²⁻ ions appear to be involved also in the cause of this disease, which is reputed to be the fifth most deadly disease in the world.     

The response to ribulose bisphosphate4− (RuBP4−) and RuBP-Mg2− in catalysis by structurally divergent RuBP carboxylase/oxygenases

Free ribulose bisphosphate (RuBP^4?) rather than its magnesium complex (RuBP-Mg^2?) was the apparent substrate for spinach ribulose bisphosphate carboxylase/oxygenase. The apparent K_m for total RuBP (pH 8.0 at 30° C) increased with increasing Mg²⁺ concentrations from 11.6 μM at 13.33 mM Mg²⁺ to 32.6 μM at 40.33 mM Mg²⁺. Similarly the apparent K_m for RuBP-Mg^2? complex increased with increasing Mg²⁺ from 9.4 μM at 13.33 mM Mg²⁺ to 29.7 μM at 40.33 mM Mg²⁺. However, the K_m values for uncomplexed RuBP^4? were independent of the (saturating) concentration of Mg²⁺ (K_m=2.2 μM). The V_max did not vary with the changing concentrations of Mg²⁺. In contrast, the K_m for total RuBP remained constant with varying Mg²⁺ concentrations (K_m=59.5 μM) for the enzyme from R. rubrum. The apparent K_m for the RuBP-Mg^2? complex decreased with increasing Mg²⁺ concentrations from 16.0 μM at 7.5 mM Mg²⁺ to 5.9 μM at 27.5 mM Mg²⁺. The initial velocity for the C. vinosum enzyme was also found to be independent of the (saturating) concentration of Mg²⁺ when total RuBP was varied in the assay. Thus the response to total RuBP by these two bacterial enzymes, which markedly differ in structure, was closely similar.     

Activation of ribulose-1, 5-bisphosphate oxygenase, The role of Mg2+, CO2, and pH.

Ribulose-1,5-bisphosphate oxygenase was activated by incubation with CO₂ and Mg²⁺ and inactivated upon removal of CO₂ and Mg²⁺ by gel filtration. The activity of the enzyme was dependent upon the preincubation concentrations of CO₂ and Mg²⁺ and upon the preincubation pH. This indicated that activation involved the reversible formation of an equilibrium complex of enzyme-CO₂-Mg. The kinetics of the activation process were the same as those described by G. H. Lorimer et al. ((1976) Biochemistry15, 529–536), for ribulose bisphosphate carboxylase and are consistent with the ordered reversible reaction sequence:

The activity of the enzyme, after preincubation at constant concentrations of CO₂ and Mg²⁺, increased as the pH was raised, suggesting that CO₂ reacted with an enzyme group having an alkaline pK. Since CO₂ and O₂ interact competitively at the catalytic site, the activation of ribulose bisphosphate oxygenase by CO₂ and Mg²⁺ indicates that the CO₂ molecule which takes part in the activation process is not the same as that which becomes fixed during the carboxylase reaction. These results also indicate that the oxygenase and carboxylase functions of the catalytic site are tightly coupled rather than independent of one another.     

Mg2+ and Mn2+ modulation of Ca2+ transport and ATPase activity in sarcoplasmic reticulum vesicles

Kinetic experimentation was used to characterize the Mg²⁺ and Mn²⁺ modulation of Ca²⁺ transport and ATPase activity in sarcoplasmic reticulum vesicles. In addition to its participation in the ATP·Mg complex as substrate for the ATPase, Mg²⁺ is an activator of phosphoenzyme progression to hydrolylic cleavage. It is shown that this activation is due to Mg²⁺ occupancy of an allosteric site easily accessible on the outer surface of the vesicles, rather than to participation in an antiport mechanism. The Mg²⁺ site is distinct from the Ca²⁺ binding sites which are involved in activation of enzyme phosphorylation by ATP, and Ca²⁺ translocation. The role of Mg²⁺ is quite specific, inasmuch as phosphoenzyme decay is much slower if the Mg²⁺ allosteric site is occupied by Ca²⁺. Conversely, competive occupancy of the Ca²⁺ sites by Mg²⁺ does not permit enzyme phosphorylation by ATP. Intermediate characteristics between Mg²⁺ and Ca²⁺ are displayed by Mn²⁺ which is well able to stimulate phosphoenzyme cleavage by occupancy of the Mg²⁺ allosteric site, and is also able (although at much slower rates) to activate enzyme phosphorylation, and undergo active transport by occupancy of the Ca²⁺ sites.     

Kinetic evidence for a dual cation role for muscle pyruvate kinase

The activation of muscle pyruvate kinase by divalent cations was studied by steady-state kinetics. Under experimental conditions the enzyme exhibits activation by Mg²⁺, Co²⁺, Mn²⁺, Ni²⁺, and Zn²⁺ in descending order of maximal velocity. Combinations of cations were also studied. A synergistic activation was observed with a fixed concentration of Mg²⁺ and varying concentrations of Mn²⁺ or of Co²⁺. This synergism indicates at least two roles for the cations for enzymatic activation and a differential specificity among the cations for the separate functions. Synergistic activation was also observed with fixed Co²⁺ and varying Mn²⁺. These results are consistent with a cation specifically required to activate the enzyme and a cation which serves as a cation-nucleotide complex which is a substrate for the reaction. The response observed suggests that Mn²⁺ is a better activator of the enzyme than is Mg²⁺, however, MgADP is a better substrate than is MnADP. The lack of a synergistic effect by Ni²⁺ or Zn²⁺ with Mg²⁺ suggests that Ni²⁺ and Zn²⁺ are poor activators either because they serve one catalytic function poorly but bind to that site tightly or they serve both catalytic functions poorly in contrast to Mg²⁺. These studies yield the first simple kinetic evidence that muscle pyruvate kinase, under catalytic conditions of the overall reaction, has a dual divalent cation requirement for activity.     

Effect of magnesium and ATP on ATPase of sugarcane vacuoles

Kinetic analysis of the Mg²⁺-dependence of tonoplast ATPase from suspension-cultured cells of sugarcane showed that the enzyme activity increased with increasing magnesium concentrations till 1–3 mM and then decreased consideably for higher concentrations. This kinetic could be explained by the assumption that MgATP^2- is the substrate of ATPase: MgATP^2- concentration increases with increasing concentration of magnesium till, at high concentrations of magnesium, Mg₂ATP is formed. No evidence for a direct role of Mg²⁺ as activator or inhibitor was found. These data corroborate previous findings that MgATP^2- is the sole substrate of the vacuolar ATPase of sugarcane (Thom and Komor 1984). High concentrations of ATP seemed to inhibit the ATPase. This result, however, could be traced back to interference of ATP with the Fiske-Subbarow method of phosphate determination. After adjustment of the test conditions, inhibition by ATP was no longer found. Reported data for ATPases of other plant materials, showing inhibition of enzyme activity with high magnesium or ATP concentrations, might be explicable in a similar way.Abbreviation Mes 2-(N-morpholino)ethane+Sulfonic acid     

Ribulose 1,5-bisphosphate carboxylase and oxygenase from Thiocapsa roseopersicina: activation and catalysis.

Ribulose 1,5-bisphosphate carboxylase/oxygenase purified from malate-grown Thiocapsa roseopersicina required Mg²⁺ for the activation of both carboxylase and oxygenase activities. Mg²⁺ was either not required or required at very low concentrations for catalysis by both enzyme activities. EDTA and dithiothreitol had no effect on ribulose 1,5-biphosphate oxygenase. The K_0.5 values with respect to Mg²⁺ for activation of the carboxylase and oxygenase activities were 8.4 and 2 mm, respectively. Ribulose 1,5-biphosphate carboxylase and oxygenase activities revealed differential sensitivities to 6-phosphogluconate. This ligand at 1 mm inhibited the carboxylase activity 30%, whereas the oxygenase activity was inhibited by 69%.     

Effect of calcium ions on pyruvate carboxylase from pigeon liver.

Pigeon liver pyruvate carboxylase (pyruvate: CO2 ligase (ADP forming), EC 6.4.1.1) shows allosteric properties similar to those of chicken or rat liver enzyme. Kinetic methods have been used to determine the effect of Ca2+ on this enzyme. The Ca2+ activation effect is absolutely dependent on the Mg2+ concentration; in the absence of Mg2+, pyruvate carboxylase has no catalytic activity. Furthermore, Ca2+ cannot replace Mg2+ and also shows a paradoxical effect on the liver enzyme activity. It is an activator at low pyruvate or Mg2+ concentrations; at increased pyruvate concentrations, however, it becomes an inhibitor. At low levels of ATP a pronounced activation of pigeon liver pyruvate carboxylase by Ca2+ has been demonstrated. The results of this communication demonstrate pigeon liver pyruvate carboxylase to be different from pyruvate carboxylase from other sources.     

Differential effects of metabolites on the active and inactive forms of hepatic acetyl CoA carboxylase

Partially purified acetyl CoA carboxylase was converted in vitro to its predominately phosphorylated (less active, b) or dephosphorylated (active, a) form. Studies of the properties of the two forms of carboxylase indicated that the a-form had a greater V than the b-form in the presence of different concentrations of citrate, pyruvate, MgATP^2?, MnATP^2?, acetyl CoA, and palmityl CoA. The concentration required for half-maximum stimulation of the a-form was less for citrate and the same as the b-form for MgATP^2?, MnATP^2?, and acetyl CoA. The concentration required for half-maximum inhibition of the a-form was higher for palmityl CoA, avidin, and ATP. The b-form was more strongly inhibited by palmityl CoA and avidin and this inhibition was partially reversed by citrate. These studies indicate that under normal physiological concentrations of metabolites, the b-form is virtually inactive. The physiological significance of the interconversion between the two forms of acetyl CoA carboxylase thus appears to lie in their differential response to the various metabolites which regulate the enzyme activity.     

Studies on the activation of isocitrate dehydrogenase kinase/phosphatase (AceK) by Mn<Superscript>2+</Superscript> and Mg<Superscript>2+</Superscript>

Isocitrate dehydrogenase kinase/phosphatase (AceK) is a bifunctional enzyme with both kinase and phosphatase activities that are activated by Mg²⁺. We have studied the interactions of Mn²⁺and Mg²⁺ with AceK using isothermal titration calorimetry (ITC) combined with molecular docking simulations and show for the first time that Mn²⁺ also activates the enzyme activities. However, Mn²⁺ and Mg²⁺ exert their effects by different mechanisms. Although they have similar binding constants (of 1.11?×?10⁵ and 0.98?×?10⁵ M^?1, respectively) for AceK and induce conformational changes of the enzyme, they do not compete for the same binding site. Instead Mn²⁺ appears to bind to the regulatory domain of AceK, and its effect is transmitted to the active site of the enzyme by the conformational change that it induces. The information in this study should be very useful for understanding the molecular mechanism underlying the interaction between AceK and metal ions, especially Mn²⁺ and Mg²⁺.     

Kinetic characterization of barley root plasma membrane-bound Ca2+- and Mg2+-dependent adenosine triphosphatase activities

A plasma membrane-rich microsome fraction isolated from barley (Hordeum vulgare L. cv. Conquest) roots contained considerable divalent cation-dependent ATPase activity when assayed at 16°C. The maximal divalent cation-stimulation of the apparent basal ATPase activity varied as Ca²⁺ > Mg²⁺ > Mn²⁺= Zn²⁺ > Co²⁺ > Ni²⁺, with all other divalent cations tested being inhibitory. Double reciprocal plots of the Ca²⁺- and Mg²⁺-dependent ATPase velocities as a function of substance concentration were nonlinear, suggesting the presence of multiple catalytic sites. Both MgATP^2- and CaATP^2- served as the true substrates and apparently bind to the same catalytic sites. Free ATP and Ca²⁺ could inhibitit the Ca²⁺- and Mg²⁺-dependent ATPase. Increasing free Mg²⁺ levels enhanced the affinity of the Mg²⁺-dependent ATPase for MgATP^2-, while slightly inhibiting the V_max values. Other divalent cation-nucleoside triphosphate complexes produced maximal enzyme velocities equal to or greater than those generated by CaATP^2- and MgATP^2-. However, the ATPase had significantly higher affinities for CaATP^2- and MgATP^2-, than for the alternative substrates. The high and low affinity components of the Ca²⁺- and Mg²⁺-dependent ATPase exhibited optimal V_max values at pH 5 and 6, respectively. Analysis of the pH-dependence of the enzyme K_m values indicated enzyme-substrate binding with charge neutralization at neutral and alkaline pH's. Nonlinear double reciprocal plots were obtained at all assay temperatures. However, the complexity of the enzyme kinetics became less apparent at the higher assay temperatures. The kinetics of the barley root divalent cation-dependent ATPase activities are discussed in terms of the kinetics of ATPases from other plants and the methods used to obtain them, and compared to the kinetics of ion transport ATPases from animal membranes.     

Differences in the cation sensitivity of adenylate cyclase from heart and skeletal muscle: modification by guanyl nucleotides and isoproterenol

Low concentrations of Mn²⁺ supported the basal adenylate cyclase activity in crude and purified sarcolemmal membranes from cardiac muscle more effectively than did relatively high concentrations of Mg²⁺; at saturating concentrations the cyclase activities obtained with Mg²⁺ or Mn²⁺ were similar. In contrast, Mg²⁺ supported the basal cyclase activities of crude membrane fractions and purified sarcolemmal membranes from skeletal muscle far more effectively than did Mn²⁺; at saturating concentrations of either metal ion the Mg²⁺-supported cyclase activities were 5- to 10-fold greater than Mn²⁺-supported activities. Further, compared to Mg²⁺, Mn²⁺ supported the cyclase activities very poorly in all the primary subcellular fractions of skeletal muscle, whereas this cation was at least as effective as Mg²⁺ in all fractions of cardiac muscle. The apparent affinities of the cyclase for Mn²⁺ in heart as well as skeletal muscle appeared to be greater compared to those for Mg²⁺. The skeletal muscle cyclase displayed greater apparent affinity for MnATP^2? (app. K_m 0.10 mm) compared to MgATP^2? (app. K_m 0.32 mm) whereas the heart enzyme displayed greater apparent affinity for MgATP^2? (app. K_m 0.07 mm) compared to MnATP^2? (app. K_m 0.19 mm). Following preactivation with guanyl-5′-yl imidodiphosphate and isoproterenol, Mn²⁺ (0.15 to 2 mm) supported the cyclase activity of skeletal muscle even more effectively than did optimally effective concentrations of Mg²⁺. With the heart enzyme the relatively greater potency of Mn²⁺ persisted following preactivation. Significant enhancement in the Mn²⁺-sensitivity of skeletal muscle cyclase was also observed when assayed in the presence of GTP and isoproterenol or in the presence of NaF. Preactivation of both heart and skeletal muscle cyclases caused selective enhancement in the enzyme's apparent affinity for free Me²⁺ (Mg²⁺ or Mn²⁺) without influencing the apparent K_m for MeATP^2? (MgATP^2? or MnATP^2?). Evidences were obtained to show that the poor effectiveness of Mn²⁺ in supporting the basal activity of skeletal muscle cyclase is not related to (a) potentiation by Mn²⁺ of adenosine-mediated inhibition of the cyclase, (b) Mn²⁺-induced lability of the cyclase, (c) indirect effects of Mn²⁺ on ATP-regenerating system, or (d) the presence of different cation-specific molecular forms of the cyclase. It is also shown that the onset of enhanced Mn²⁺ sensitivity of the skeletal muscle enzyme following preactivation is not accompanied by a general loss of cation specificity of the cyclase. These results suggest that cations support the catalytic activity of adenylate cyclase by interacting with an enzymeregulatory free metal binding site and that the differential cation sensitivity of nonactivated (basal) cyclases from heart and skeletal muscle is likely due to differences in the properties of such an allosteric metal site. Furthermore, the metal site appears to undergo a conformational change following interaction of the cyclase system with the guanyl nucleotide and isoproterenol since the cation sensitivity of the cyclase and the relative potency of cations depend on the conformational status of the enzyme.     

Status of the substrate binding sites of ribulose bisphosphate carboxylase as determined with 2-C-carboxyarabinitol 1,5-bisphosphate

The properties of the tight and specific binding of 2-C-carboxy-d-arabinitol 1,5-bisphosphate (CABP), which occurs only to reaction sites of ribulose 1,5-bisphosphate carboxylase (Rubisco) that are activated by CO₂ and Mg²⁺, were studied. With fully active purified spinach (Spinacia oleracea) Rubisco the rate of tight binding of [¹⁴C]CABP fit a multiple exponential rate equation with half of the sites binding with a rate constant of 40 per minute and the second half of the sites binding at 3.2 per minute. This suggests that after CABP binds to one site of a dimer of Rubisco large subunits, binding to the second site is considerably slower, indicating negative cooperativity as previously reported (S Johal, BE Partridge, R Chollet [1985] J Biol Chem 260: 9894-9904). The rate of CABP binding to partially activated Rubisco was complete within 2 to 5 minutes, with slower binding to inactive sites as they formed the carbamate and bound Mg²⁺. Addition of [¹⁴C]CABP and EDTA stopped binding of Mg²⁺ and allowed tight binding of the radiolabel only to sites which were CO₂/Mg²⁺-activated at that moment. This approach estimated the amount of CO₂/Mg²⁺-activated sites in the presence of inactive sites and carbamylated sites lacking Mg²⁺. The rate of CO₂ fixation was proportional to the CO₂/Mg²⁺-activated sites. During light-dependent CO₂ fixation with isolated spinach chloroplasts, the amount of carbamylation was proportional to Rubisco activity either initially upon lysis of the plastids or following total activation with Mg²⁺ and CO₂. Lysis of chloroplasts in media with [¹⁴C]CABP plus EDTA estimated those carbamylated sites having Mg²⁺. The loss of Rubisco activation during illumination was partially due to the lack of Mg²⁺ to stabilize the carbamylated sites.     

Corn leaf phosphoenolpyruvate carboxylases: The effect of divalent cations on activity

Differences in the kinetic properties of corn leaf phosphoenolpyruvate (PEP) carboxylase isoenzymes were found, depending on whether Mg²⁺ or Mn²⁺ was used as the metal cofactor of the reaction. Also, differences in kinetic constants with respect to Mg²⁺ and Mn²⁺ were noticed between the two isoenzymes which further differentiates the two proteins. The catalytic activity of the enzyme in the Mg²⁺-activated system was dependent on a PEP-Mg²⁺ complex and not on the concentration of free Mg²⁺ or free PEP. Kinetics in the presence of total Mg²⁺ and those of PEP-Mg²⁺ suggest a negative cooperative effect with respect to ligand binding with concurrent progressive substrate activation. Magnesium ions, thus, have a special regulatory role in the corn leaf PEP carboxylase reaction.     

Effect of Mg2+ on the Structure and Function of Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase

Mg²⁺ in various concentrations was added to purified Rubisco in vitro to gain insight into the mechanism of molecular interactions between Mg²⁺ and Rubisco. The enzyme activity assays showed that the reaction between Rubisco and Mg²⁺ was two order, which means that the enhancement of Rubisco activity was accelerated by low concentration of Mg²⁺ and slowed by high concentration of Mg²⁺. The kinetics constant (K _m) and V _max was 1.91 μM and 1.13 μmol CO₂ mg⁻¹ protein∙min⁻¹, respectively, at a low concentration of Mg²⁺, and 3.45 μM and 0.32 μmol CO₂∙mg⁻¹ protein∙min⁻¹, respectively, at a high concentration of Mg²⁺. By UV absorption and fluorescence spectroscopy assays, the Mg²⁺ was determined to be directly bound to Rubisco; the binding site of Mg²⁺ to Rubisco was 0.275, the binding constants (K _A) of the binding site were 6.33 × 10⁴ and 5.5 × 10⁴ l·mol⁻¹. Based on the analysis of the circular dichroism (CD) spectra, it was concluded that the binding of Mg²⁺ did not alter the secondary structure of Rubisco, suggesting that the observed enhancement of Rubisco carboxylase activity was caused by a subtle structural change in the active site through the formation of the complex with Mg²⁺.     

The response to ribulose bisphosphate4− (RuBP4−) and RuBP-Mg2− in catalysis by structurally divergent RuBP carboxylase/oxygenases

Free ribulose hisphosphate (RuBP^4?) rather than its magnesium complex (RuBP-Mg^2?) was the apparent substrate for spinach ribulose bisphosphate carboxylase/oxygenase. The apparent K_m for total RuBP (pH 8.0 at 30° C) increased with increasing Mg²⁺ concentrations from 11.6 μM at 13.33 mM Mg²⁺ to 32.6 μM at 40.33 mM Mg²⁺. Similarly the apparent K_m for RuBP-Mg^2? complex increased with increasing Mg²⁺ from 9.4 μM at 13.33 mM Mg²⁺ to 29.7 μM at 40.33 mM Mg²⁺. However, the K_m values for uncomplexed RuBP^4? were independent of the (saturating) concentration of Mg²⁺ (K_m=2.2 μM). The V_max did not vary with the changing concentrations of Mg²⁺. In contrast, the K_m for total RuBP remained constant with varying Mg²⁺ concentrations (K_m=59.5 μM) for the enzyme from R. rubrum. The apparent K_m for the RuBP-Mg^2? complex decreased with increasing Mg²⁺ concentrations from 16.0 μM at 7.5 mM Mg²⁺ to 5.9 μM at 27.5 mM Mg²⁺. The initial velocity for the C. vinosum enzyme was also found to be independent of the (saturating) concentration of Mg²⁺ when total RuBP was varied in the assay. Thus the response to total RuBP by these two bacterial enzymes, which markedly differ in structure, was closely similar.