Mechanism of carbamoyl phosphate synthetase from Escherichia coli--binding of the ATP molecules used in the reaction and sequestration by the enzyme of the ATP molecule that yields carbamoyl phosphate.

The conflicting data on the binding of the two molecules of ATP that are involved in the overall reaction catalyzed by carbamoyl-phosphate synthetase (CPS) of Escherichia coli, and a mechanism recently proposed for this reaction, has led us to reexamine ATP binding using pulse/chase techniques. With [gamma-32P]ATP and bicarbonate in the pulse solution, there is a positive intercept at zero time of approximately 1 mol Pi/mol CPS in the plot of 32Pi formation against time, irrespective of whether the incubation is terminated by the addition of acid or by addition of a chase solution containing glutamine, excess unlabeled ATP and bicarbonate. The intercept is decreased to about 50% if the excess unlabeled ATP is added prior to the addition of the glutamine. These are the expected results if the intercept reflects the reversible formation of enzyme-bound ADP and carboxyphosphate. Approximately 0.6 mol carbamoyl [32P]phosphate/mol enzyme is formed in these experiments when the pulse step is terminated by addition to the chase solution. The ATP molecule that provides the phosphoryl group of carbamoyl phosphate, therefore, also binds to the enzyme in the absence of ammonia or glutamine and reacts in the chase to give carbamoyl phosphate before it can dissociate from the enzyme. At 1 mM ATP, the binding of both ATP molecules is essentially complete at 2.5 s, but the dissociation of the ATP that yields carbamoyl phosphate is extremely slow (t(1/2) of about 6 min at 22 degrees C; HCO3-, 40 mM), although it is faster in the absence of bicarbonate. The extreme sequestration from the aqueous environment of this ATP allows the enzyme-ATP complex to be separated from the surrounding ATP by centrifugal gel filtration. After two successive steps of gel filtration through Sephadex G-50 equilibrated with unlabeled ATP and bicarbonate, the majority of the radioactivity remaining in the solution is bound to the enzyme and is released as [gamma-32P]ATP if acid is added, or is converted to carbamoyl [32P]phosphate by addition to chase solution, without concomitant release of 32Pi. K+ is necessary in the pulse solution, but not in the chase solution, to demonstrate this binding. These findings and other confirmatory experiments demonstrate conclusively that, in the presence of K+, both ATP molecules bind to the enzyme in the absence of ammonia or glutamine. The bound ATP that yields Pi in the overall reaction is replaced relatively rapidly by exchange and by hydrolysis in the bicarbonate-dependent ATPase activity of the enzyme, whereas the bound ATP that provides the phosphoryl group of carbamoyl phosphate is replaced very slowly. The temporal pattern of carbamoyl [32P]phosphate formation from [gamma-32P]ATP, in pulse/chase experiments in which a small concentration of ammonia is added to the pulse solution, shows that, in the normal enzyme reaction, this last ATP molecule binds to the enzyme before ammonia. These findings exclude a recently proposed mechanism [Kothe, M., Eroglu, B., Mazza, H., Samudera, H. & Powers-Lee, S. (1997) Proc. Natl Acad. Sci. USA 94, 12348-12353] in which a single molecule of ATP bound at the catalytic center phosphorylates bicarbonate and provides the phosphoryl group of carbamoyl phosphate. A mechanism in which a single ATP molecule binds, followed by the binding of bicarbonate and ammonia (from glutamine) and the release of Pi before the second molecule of ATP is bound is also excluded. We have previously reported very similar findings for carbamoyl-phosphate synthetase (ammonia), strongly suggesting that the different types of CPS share a common mechanism. The virtual sequestration of the ATP that provides the phosphoryl group of carbamoyl phosphate is consistent with a palmate-binding site, with the nucleotide bound within a beta-sheet sandwich, and a loop closure mechanism triggered by the binding of bicarbonate or the formation of carboxyphosphate.

Isomerization of the free enzyme versus induced fit: effects of steps involving induced fit that bypass enzyme isomerization on flux ratios and countertransport.

In a single-substrate-single-product enzyme reaction, "counter transport', which indicates that the ratio of the forward to the reverse fluxes is less than that expected from the Independence Relationship, is regarded as strong evidence for the free enzyme existing in two states, one of which combines with the substrate and the other with the product, with a slow isomerization between the two conditions. To account for positive and negative co-operativity, found with some enzymes, additional induced-fit reactions bypassing at least part of the isomerization have been proposed. The effects of such additional steps have been examined, using two models: in one, (a), the enzyme passes through an intermediate state during its isomerization, and both substrate and product may react with this state to give rise to the binary complexes; in the other, (b), the substrate may react with the enzyme as soon as the product is released and similarly with the reverse reaction, the isomerization thereby being bypassed completely. In the presence of such additional steps, the following can be concluded. (i) The data should be analysed in terms of the flux ratios, rather than observation of the amount of countertransport. (ii) The additional bypassing steps markedly change the pattern of dependence of the flux ratio on substrate and product concentrations. At high substrate and product concentrations, the ratio remains very dependent on how far the reaction is from equilibrium, and the kinetics are asymmetric. (iii) The mechanism causing the flux ratio to be less than that given by the Independence Relationship differs from that previously described, in that, at least in part, it arises from a 1:1 exchange between substrate and product. (iv) Despite this novel mechanism, there must be two states of the enzyme, combining respectively with substrate and product, and these must not be in rapid exchange. Thus countertransport remains very strong evidence for the existence of two such states. It is no longer a requirement that the enzyme states should be linked by an isomerization step. (v) Under no conditions can the flux ratio exceed that given by the Independence Relationship. (vi) Under unusual conditions the isomerization of the enzyme in model (b) may be undetectable by steady-state kinetics. (vii) Measurements of the coefficients in the flux ratio equations enable limits to be set to certain ratios of the rate constants. In addition to these conclusions, methods are described for (viii) analysing flux ratio data for the presence of induced fit steps and (ix) determining flux ratios from induced transport curves. The derivation of steady state-velocity equations show that: (x) both models may give rise to positive and negative 'co-operativity' and sigmoid substrate-velocity curves, but that, under conditions giving rise to sigmoid curves, the deviation of the flux ratio from that required by the Independence Relationship may be difficult to demonstrate because of the asymmetry of the system. Under all conditions the fluxes at equilibrium should obey hyperbolic kinetics.

Photoaffinity labeling with UMP of lysine 992 of carbamyl phosphate synthetase from Escherichia coli allows identification of the binding site for the pyrimidine inhibitor.

UMP is a highly specific reagent for photoaffinity labeling of the allosteric inhibitor site of carbamyl phosphate synthetase (CPS) from Escherichia coli and has been found to be photoincorporated in the COOH-terminal domain of the large subunit [Rubio et al. (1991) Biochemistry 30, 1068-1075]. In the present work we identify lysine 992 as the residue that is covalently attached to UMP. This identification is based on two lines of evidence. First, [14C]UMP is found to be incorporated between residues 939 and 1006, as shown by peptide mapping and by mass estimates of [14C]UMP-peptides generated by chemical and enzymatic cleavage of CPS. Secondly, we have purified two radioactive peptides derived exclusively from those enzyme molecules (approximately 5% of the total enzyme) that had incorporated [14C]-UMP. Edman analyses show the sequences of the labeled peptides (989)LVNXVHEGRPHIQD and (989)LVNXVHE to be overlapping. Since neither a phenylthiohydantoin (Pth) derivative (in cycle 4) nor any radioactivity is released from the membrane during sequencing, we can conclude that Lys992 and [14C]-UMP form a covalent adduct that remains bound to the membrane. Formation of this adduct agrees with all of the evidence and with the finding that UMP labeling prevents trypsin cleavage at Lys992. Lysine 992 is invariant in those CPSs that are inhibited by UMP, and is located 30 residues upstream of the site whose phosphorylation in hamster CAD reduces inhibition of CAD by UTP. Multiple sequence alignment of the residues surrounding Lys992 of the E. coli enzyme and the corresponding residues of the yeast and animal enzymes supports the existence of a uridine nucleotide binding fold in this region of the protein. We conclude that sequence changes in the binding fold provide a structural basis for the different regulatory properties found among CPSs I, II, and III.

Domain structure of the large subunit of Escherichia coli carbamoyl phosphate synthetase. Location of the binding site for the allosteric inhibitor UMP in the COOH-terminal domain.

The large subunit of Escherichia coli carbamoyl phosphate synthetase (a polypeptide of 117.7 kDa that consists of two homologous halves) is responsible for carbamoyl phosphate synthesis from NH3 and for the binding of the allosteric activators ornithine and IMP and of the inhibitor UMP. Elastase, trypsin, and chymotrypsin inactivate the enzyme and cleave the large subunit at a site approximately 15 kDa from the COOH terminus (demonstrated by NH2-terminal sequencing). UMP, IMP, and ornithine prevent this cleavage and the inactivation. Upon irradiation with ultraviolet light in the presence of [14C]UMP, the large subunit is labeled selectively and specifically. The labeling is inhibited by ornithine and IMP. Cleavage of the 15-kDa COOH-terminal region by prior treatment of the enzyme with trypsin prevents the labeling on subsequent irradiation with [14C]UMP. The [14C]UMP-labeled large subunit is resistant to proteolytic cleavage, but if it is treated with SDS the resistance is lost, indicating that UMP is cross-linked to its binding site and that the protection is due to conformational factors. In the presence of SDS, the labeled large subunit is cleaved by trypsin or by V8 staphylococcal protease at a site located 15 or 25 kDa, respectively, from the COOH terminus (shown by NH2-terminal sequencing), and only the 15- or 25-kDa fragments are labeled. Similarly, upon cleavage of the aspartyl-prolyl bonds of the [14C]UMP-labeled enzyme with 70% formic acid, labeling was found only in the 18.5-kDa fragment that contains the COOH terminus of the subunit. Thus, UMP binds to the COOH-terminal domain.(ABSTRACT TRUNCATED AT 250 WORDS)

A structure-reactivity study of the binding of acetylglutamate to carbamoyl phosphate synthetase I.

The requirements for binding at the N-acetyl-L-glutamate binding site of carbamoyl phosphate synthetase I were studied by the displacement of the activator from the central enzyme complex by analogs. Two carboxyls are essential and the acetamido group, if linked to the alpha-carbon, enhances binding 5000-fold. The subsite for the delta-carboxyl is mobile with respect to that for the alpha-carboxyl. Mixtures of complementary fragment of acetylglutamate do not bind, indicating a strong 'chelate' effect. Substituents revealed the existence of steric constraints around the delta-carboxyl, the alpha and gamma-carbons, and the whole of the acetamido group. However, phenyl substituents at the beta-carbon did not hamper binding, indicating that substituents at the beta-carbon face the solution. This is consistent with binding of acetylglutamate as the minimum-energy conformer. All analogs binding with high affinity are activators. Some analogs that bind poorly are competitive inhibitors. They appear to bind preferentially to a low-affinity conformation adopted by the site when the products dissociate and the substrates bind. The acetamido group plays no role in the binding of the inhibitors but it is crucial for the binding of the activators, and the high- and low-affinity conformations of the site differ markedly in structural selectivity.

Carbamoyl-phosphate synthetase I. Kinetics of binding and dissociation of acetylglutamate and of activation and deactivation.

The dissociation of the cofactor, acetylglutamate, from the enzyme-cofactor complex formed by carbamoyl-phosphate synthetase I of rat liver in the presence of ATP, Mg2+, K+ and HCO-3 has been studied by centrifugal gel filtration. The rate of its dissociation (k, 0.13 s-1) is considerably slower than the rate of enzyme turnover (approximately equal to 6 s-1) and it is not increased by ammonia, although ammonia reduces the rate of reassociation of the cofactor. Omission of ATP, Mg2+ or K+ from the column buffer leads to virtually complete dissociation of bound acetylglutamate during passage through the column (0.5-2 min), owing to an increase in dissociation and a decrease in reassociation, but reduction of free Mg2+ alone has the opposite action. Dilution of the enzyme-cofactor complex into a large volume of buffer causes a biphasic loss of enzyme activity with a t1/2 of the first phase comparable with that of the dissociation of acetylglutamate. These findings show (a) that acetylglutamate does not dissociate with each turnover of the enzyme; (b) that there are rapid interactions between binding of acetylglutamate and ATPA (ATPA yields Pi in the overall reaction), Mg2+ and K+, suggesting that these ligands bind in close proximity; and (c) that the enzyme transiently retains considerable activity after dissociation of the cofactor.

The mechanism of rabbit muscle phosphofructokinase at pH8.

The mechanism of rabbit muscle phosphofructokinase was investigated by measurement of fluxes, isotope trapping and steady-state velocities at pH8 in triethanolamine/HCl buffer with 4 mM free Mg2+. Most observations were made at I0.2. The ratio Flux of fructose 1,6-bisphosphate----fructose 6-phosphate/Flux of fructose 1,6-bisphosphate----ATP at zero ATP concentration increased hyperbolically from unity to about 3.2 as the concentration of fructose 6-phosphate was increased. Similarly, the ratio Flux of fructose 1,6-bisphosphate----ATP/Flux of fructose 1,6-bisphosphate----fructose 6-phosphate at zero fructose 6-phosphate concentration increased from unity to about 1.4 as the concentration of ATP was increased. The addition of substrates must therefore be random, whatever the other aspects of the reaction. Further, from the plateau values of the ratios, it follows that the substrates dissociate very infrequently from the ternary complex and that at a low substrate concentration 72% of the reaction follows the pathway in which ATP adds first to the enzyme. Isotope-trapping studies with [32P]ATP confirmed that ATP can bind first to the enzyme in rate-limiting step and that dissociation of ATP from the ternary complex is slow in relation to the forward reaction. No isotope trapping of [U-14C]-fructose 6-phosphate could be demonstrated. The ratios Flux of ATP----fructose 1,6-bisphosphate/Flux of ATP----ADP measured at zero ADP concentration and the reciprocal of the ratio measured at zero fructose 1,6-bisphosphate concentration did not differ significantly from unity. Calculated values for these ratios based on the kinetics of the reverse reaction and assuming ordered dissociations of products or a ping-pong mechanism gave values very significantly greater than unity. These findings exclude an ordered dissociation or a substantial contribution from a ping-pong mechanism, and it is concluded that the reaction is sequential and that dissociation of products is random. Rate constants were calculated for the steps in the enzyme reaction. The results indicate a considerable degree of co-operativity in the binding between the two substrates. The observations on phosphofructokinase are discussed in relation to methods of measurement and interpretation of flux ratios and in relation to the mechanism of other kinase enzymes.

Mitochondrial carbamoyl phosphate synthetase activity in the absence of N-acetyl-L-glutamate. Mechanism of activation by this cofactor.

Rat liver carbamoyl-phosphate synthetase I is shown to have synthetase and ATPase activity in the absence of acetylglutamate. Km values for ATP, Mg2+ and K+ are greatly increased, the Km for HCO-3 is not changed much, and the Km for NH+4 is markedly reduced. Vmax for the synthetase reaction is less than 20% of that of the acetylglutamate-activated enzyme whereas Vmax for the ATPase activity is greater than 40% of that with acetylglutamate. Pulse-chase experiments with H14CO-3 show formation of less "active CO2" (the central intermediate) than with acetylglutamate; ATPase activity is reduced in proportion, but the synthetase activity is much smaller. Binding of one ATP molecule with high affinity (Kd = 20-30 microM) is shown in the absence of acetylglutamate. This appears to be the molecule of ATPB (ATPB provides the phosphoryl group of carbamoyl phosphate). In contrast, the affinity for ATPA (ATPA yields Pi) is much reduced. Initial velocity measurements without acetylglutamate show a time lag before reaching a constant velocity. At 50 microM acetylglutamate the lag is much longer, but at 10 mM acetylglutamate it is shorter. Activation by acetylglutamate requires ATP at concentrations sufficient to occupy the ATPA and the ATPB binding sites. Preincubation with 10 mM acetylglutamate alone shortens the activation time. From these findings we propose an allosteric model for activation of carbamoyl-phosphate synthetase in which there are two active states, R and R . AcGlu. Binding of ATPA is associated with the conversion of T to R. R . AcGlu differs from R in that transfer to carbamate of the gamma-phosphoryl group of ATPB appears to be facilitated.

Nitrogen metabolism in the sheep fetus. Observations on the liver and placenta.

Ammonium ions added in large quantity disappear rapidly from the reservoir of the sheep placenta perfused in situ through the umbilical vessels. Ammonium ions are removed from the reservoir of perfused sheep fetal livers of 108-141 days of conceptual age at a rate of at least 1 mumol/min/g liver. The majority appears as urea. There is little or no change in glutamine concentration. Hepatic carbamoylphosphate synthetase I, ornithine transcarbamylase, argininosuccinate synthetase, argininosuccinase and arginase are present, even at 97 days of conceptual age, in adequate amounts to account for the observed urea production. With the exception of arginase, all levels rise with fetal age. The levels in the maternal liver are comparable with those at 106 days of conceptual age. Arginase is high in the younger fetuses, falls progressively with fetal age and is very low in the mother. It is concluded that (a) the perfused placenta is permeable to ammonia and the placenta may be able to clear ammonia from the fetal circulation at a rate comparable with that of fetal liver; (b) the fetal liver converts ammonia to urea at a rate comparable with the urea production of the fetus; (c) there is virtually no glutamine production by the fetal liver; (d) adequate amounts of the enzymes of urea synthesis are present even in the immature fetal liver to account for the total urea production of the fetus, and (e) the anomalously low arginase level in the maternal liver may conserve maternal arginine, and the high levels in the younger fetuses may be related to fetal polyamine production from maternally derived arginine.

An evaluation of the tissue pH electrode for fetal monitoring using the fetal sheep as an experimental model.

The performance of the Roche tissue pH electrode has been assessed by comparison of values recorded by the the electrode with the pH of arterial blood, in fetal sheep. Observations were made under controlled conditions when the fetal pH was steady, during hypoxia, and after hypoxia. The results showed a highly significant correlation of the values recorded by the electrodes with the pH of arterial blood (r = 0.89, p less than 0.001 during control; and r = 0.86, p less than 0.001 during hypoxia and recovery). However, in about 10% of cases the insertion proved to be unsatisfactory, and in one half of the successful insertions there was a rapid initial drift which lasted up to 45 min. After stabilization, tissue pH values were symmetrically distributed about the atrial pH, with a SD of 0.07 unit. Multiple electrodes in the same fetus gave the same scatter. Movements of the electrode caused significant artefacts. During hypoxia (produced by compression of the cord or administration of gas mixtures low in O2), the electrodes lagged behind the changes in arterial pH by up to 10 min. The conclusion is that the inherent variability of the tissue pH electrode makes it unsuitable as an absolute indicator of fetal well-being, and that it cannot be used alone as an indication for operative intervention. Nevertheless, because of the limitations of conventional techniques, it should be valuable as an adjunct and, in particular, it should help in the interpretation of equivocal fetal heart rate tracings, thereby reducing the risk of fetal death.

Mechanism of activation of bicarbonate ion by mitochondrial carbamoyl-phosphate synthetase: formation of enzyme-bound adenosine diphosphate from the adenosine triphosphate that yields inorganic phosphate.

The mechanism of the reaction catalyzed by rat liver mitochondrial carbamoyl-phosphate synthetase has been studied by using [beta-18O2]ATP and HC18O-3, monitoring the isotopic composition of adenosine triphosphate (ATP) and inorganic phosphate (Pi) by high-resolution 31P NMR spectroscopy. In the presence of both HCO3- and acetylglutamate, the enzyme catalyzes the exchange of oxygen atoms between the beta, gamma bridging and the beta nonbridging positions of ATP. Addition of NH3 stops the exchange, Pi released by the ATPase activity of the enzyme in the absence of NH3 contains one oxygen atom from HC18O3- but there is no incorporation of 18O into ATP. There is no significant incorporation of [14C]ADP or 32Pi into ATP. It is concluded that in the enzyme-ATPA.HCO30.ATPB complex formed in the presence of ATP and HCO3- there is reversible transfer of the gamma-PO3 group of ATPA (the molecule that yields Pi) to HCO3- without dissociation of products. The beta-PO3 of the enzyme-bound ADP that is formed can rotate. Virtually all of the complex appears to be in the form in which ATPA is cleaved, but in the absence of NH3, ATP is reconstituted and dissociates from the complex on at least 75% of the occasions. On the remainder, the carbonyl phosphate is cleaved in an irreversible process that yields Pi and a low-energy form of carbonic acid (probably HCO3-). NH3 reacts rapidly and irreversibly with the complex, and at saturation the rate (greater than 10 times the rate of Pi release in the absence of NH3) is sufficient to prevent dissociation of ATPA. In the absence of HCO3- an enzyme-ATPA.ATPB complex is formed, but cleavage of the bond between beta, gamma bridging oxygen and P gamma of ATPA does not occur.

25-hydroxycholecalciferol 1 alpha-hydroxylase activity in the kidney of the fetal, neonatal and adult guinea pig.

Homogenates of fetal, newborn and maternal kidney and placenta have been compared with homogenates of non-pregnant adult kidney for their ability to hydroxylate 25-hydroxycholecalciferol. The activity in the fetal kidney near term is similar to that in the mother and 4--5 times that in the non-pregnant adult. These differences from the non-pregnant adult are significant (p less than 0.05 and 0.1 fetus and newborn, respectively). Even higher levels are present in some newborn 12--24 h after birth, but these values fall towards the non-pregnant level in the following 21 days. Significant hydroxylating activity is present in the near-term placenta.

Mechanism of carbamoyl-phosphate synthetase. Properties of the two binding sites for ATP.

Carbamoyl phosphate synthethase I synthesizes carbamoyl phosphate from ammonia, HCO3- and two molecules of ATP, one of which, ATPA, yields Pi while the other, ATPB, yields the phosphoryl group of carbamoyl phosphate. Pulse-chase experiments with [gamma-32P]ATP without added HCO3- demonstrate separate binding sites for ATPA and ATPB. Bound ATPA dissociates readily from its site (t1/2 approximately 1--2 s) and the Kd is 0.2--0.7 mM. For the ATPB binding site the t1/2 for dissociation is 5--12 s and the Kd approximately 10 mM. Kd for ATPA seems to increase with enzyme concentration whereas Kd for ATPB does not change. HClO4 releases the ATP unchanged from the enzyme . ATPB and enzyme . ATPB . ATPA complexes. In the presence of HCO3-, ATP and N-acetylglutamate, an enzyme . ATPB . HCO3- . ATPA complex is formed. Its formation by the addition of HCO3- to the enzyme . ATPB . ATPA complex appears to involve an initial bimolecular addition reaction followed by an isomerization. Treatment with HClO4 releases Pi from ATPA but ATPB is released unchanged. Spontaneous hydrolysis of ATPA is responsible for the ATPase activity of the enzyme. Thus, a covalent bond may form between HCO3- and ATPA. However, ATPA can dissociate rapidly (t1/2 less than 10 s). The Kd for ATPA is approximately 0.2 mM. ATPB appears unable to dissociate from the enzyme . ATPB . HCO3- . ATPA complex since the t1/2 for dissociation of ATPB from the enzyme is lengthened about five times in the presence of 19 mM HCO3- and at 1 mM ATP. ATPA may also hydrolyse in this complex and be replaced by another molecule of ATP in the absence of exchange of ATPB. However, the ATPA binding site must be occupied to prevent ATPB release. ATPB may be bound in a pocket which becomes inaccessible to the solution when HCO3- and ATPA also bind. In contrast, HCO3- does not inhibit the binding of ATPB to the enzyme. Various intermediate steps in the formation of the enzyme . ATPb . HCO3- . ATPA complex are discussed. Additional evidence is presented that the ATPB binding site is only periodically accessible to ATP in solution and that ATPB in the steady-state reaction binds when the products leave. Since greater than 1.3 mol ATPB and greater than 1.8 mol ATPA bind/mol enzyme dimer, the enzyme monomer may be an active species.

Mechanism of carbamoyl-phosphate synthetase. Binding of ATP by the rat-liver mitochondrial enzyme.

This paper demonstrates, by pulse-chase techniques, the binding to rat liver mitochondrial carbamoyl phosphate synthetase of the ATP molecule (ATPB) which transfers its gamma-phosphoryl group to carbamoyl phosphate. This bound APTB can react with NH3, HCO-3 and ATP (see below) to produce carbamoyl phosphate before it exchanges with free ATP. Mg2+ and N-acetylglutamate, but not NH3 or HCO-3, are required for this binding; the amount bound depends on the concentration of ATP (Kapp = 10--30 microns ATP) and the amount of enzyme. At saturation at least one ATPB molecule binds per enzyme dimer. Binding of ATPB follows a slow exponential time course (t1/2 8--16 s, 22 degrees C), independent of ATP concentration and little affected by NH3, NCO-3 or by incubation of the enzyme with unlabelled ATP prior to the pulse of [gamma-32P]ATP. Formation of carbamoyl phosphate from traces of NH3 and HCO-3 when the enzyme is incubated with ATP follows the kinetics expected if it were generated from the bound ATPB, indicating that the latter is a precursor of carbamoyl phosphate ('Cbm-P precursor') in the normal enzyme reaction. This indicates that the site for ATPB is usually inaccessible to ATP in solution but becomes accessible when the enzyme undergoes a periodical conformational change. Bound ATP becomes Cbm-P precursor when the enzyme reverts to the inaccessible conformation. Pulse-chase experiments in the absence of NH3 and HCO-3 (less than 0.2 mM) also demonstrate binding of ATPA (the molecule which yields Pi in the normal enzyme reaction), as shown by a 'burst' in 32Pi production. Therefore, (in accordance with our previous findings) both ATPA and ATPB can bind simultaneously to the enzyme and react with NH3 and HCO-3 in the chase solution before they can exchange with free ATP. However, at low ATP concentration (18 micron) in the pulse incubation, only ATPB binds since ATP is required in the chase (see above). Despite the presence of two ATP binding sites, the bifunctional inhibitor adenosine(5')pentaphospho(5')adenosine(Ap5A) fails to inhibit the enzyme significantly. A more detailed modification of the scheme previously published [Rubio, V. & Grisolia, S. (1977) Biochemistry, 16, 321--329] is proposed; it is suggested that ATPB gains access to the active centre when the products leave the enzyme and the active centre is in an accessible configuration. The transformation from accessible to inaccessible configuration appears to be part of the normal enzyme reaction and may represent to conformational change postulated by others from steady-state kinetics. The properties of the intermediates also indicate that hydrolysis of ATPA must be largely responsible for the HCO-3-dependent ATPase activity of the enzyme. The lack of inhibition of the enzyme by Ap5A indicates substantial differences between the Escherichia coli and the rat liver synthetase.

The supply of citrate to the sheep fetus.

In situ placental perfusion has been used to study the role of the sheep placenta in fetal citrate metabolism. The perfusate citrate concentrations rose steadily to values higher than in fetal plasma. This rise was not influenced by intravenous administration of citrate to the ewe. Concentration and electropotential gradients indicate that transplacental passage is unlikely and the rise is probably due to placental synthesis. However, the quantity of citrate supplied to the fetus was calculated to be small compared with the fetal metabolic rate. Comparison with the guinea pig shows close similarity in fetal plasma concentrations and the amount of citrate formed per unit weight of fetus.

Use of flux ratio measurements for the determination of the order of addition of substrates and products in enzyme reactions.

1. Methods of determining the order of addition of substrates and dissociation of products by using flux ratios are investigated. Where an enzyme obeys hyperbolic steady-state velocity kinetics it is concluded that it may be particularly useful to compare the measured flux ratios with those calculated from the steady-state velocity parameters. 2. An expression is derived relating the relative contribution of the two pathways in a branched pathway to the flux ratios. 3. The relationship of equilibrium-reaction-rate measurements [Boyer & Silverstein (1963) Acta Chem. Scand. 17, Suppl. 1, S195] to the flux ratios is considered. Equilibrium-reaction rates are shown to be affected both by the addition of substrates and dissociation of products. Methods of analysing the data to distinguish between these events are discussed. 4. Methods of measurement of flux ratios are described, and it is concluded that the non-equilibrium steady-state method is preferable to measurements at chemical equilibrium. 5. The relative significance of flux ratio measurements and steady-state velocity inhibition data is discussed. It is concluded that flux ratios, when taken in conjunction with the inhibition data, provide the least ambiguous information about mechanism.

Kinetics and mechanism of action of muscle pyruvate kinase.

1. The mechanism of rabbit muscle pyruvate kinase was investigated by measurements of fluxes, isotope trapping, steady-state velocity and binding of the substrates. All measurements were made at pH8.5 in Tris/HCl buffer and at 5mm-free Mg(2+). 2. Methods of preparing [(32)P]phosphoenolpyruvate from [(32)P]P(i) in high yield and determining [(32)P]-phosphoenolpyruvate and [8-(14)C]ADP are described. 3. The ratio Flux of ATP to ADP/Flux of ATP to phosphoenolpyruvate (measured at equilibrium) increased hyperbolically with ADP concentration from unity to about 2.1 at 2mm-ADP, but was unaffected by phosphoenolpyruvate concentration. Since the ratio is greater than unity, one pathway for the addition of substrates must involve phosphoenolpyruvate adding first to the enzyme in a rate-limiting step. However, the substrates must also add in the alternative order, because of the non-linear increase in the ratio with ADP concentration and because the rate of increase is very much less than that predicted from the steady-state velocity data for an ordered addition. The lack of influence of phosphoenolpyruvate on the ratio is consistent with the rapid addition of ADP in the alternative pathway. At low ADP concentrations the alternative pathway contributes less than 33% to the total reaction. 4. Isotope trapping was observed with [(32)P]phosphoenolpyruvate, confirming that when phosphoenolpyruvate adds first to the enzyme it is in a rate-limiting step. The release of phosphoenolpyruvate from the ternary complex must also be a slow step. Trapping was not observed with [8-(14)C]ADP, hence the addition of ADP to the free enzyme must be rapid unless its dissociation constant is very large (>20mm). 5. Binding studies showed that 4mol of [(32)P]phosphoenolpyruvate binds to 1mol of the enzyme, probably unligated to Mg(2+), with a dissociation constant appropriate to the mechanism indicated above. Binding of [8-(14)C]ADP could not be detected, and hence the binding of ADP occurs by a low-affinity step. The latter is also demanded by the steady-state velocity data. 6. The ratio Flux of phosphoenolpyruvate to ATP/Flux of phosphoenolpyruvate to pyruvate (determined from the incorporation of label into phosphoenolpyruvate from [3-(14)C]-pyruvate or [gamma-(32)P]ATP during the forward reaction) did not differ significantly from unity. Steady-state velocity data predicted grossly different flux ratios for ordered dissociations of the products, and the results indicate that the dissociation must be rapid and random. The data also exclude a Ping-Pong mechanism. 7. Permissible rate constants for the above mechanism are calculated. The results indicate a high degree of cooperativity in binding, whatever the order of addition of substrate.