The presence of essential arginine residues at the active sites of citrate lyase complex from Klebsiella aerogenes

The acyl-transferase and acyl-lyase activities of $\text{Klebsiella aerogenes}$ citrate lyase complex are inactivated by the arginine specific reagents phenylglyoxal and 2,3-butanedione, the former reagent being the more potent inhibitor. Citrate and (3$\text{S}$)-citryl-CoA protect the transferase activity, while acetyl-CoA markedly enhances the rate of the inactivation. (3$\text{S}$)-Citryl-CoA protects the lyase subunit in the complex from inactivation. The kinetics of inactivation suggest the involvement of a single arginine residue at each of the active sites of the transferase and of the lyase subunits.     

Purification and properties of citrate lyase from Escherichia coli

Citrate lyase (EC 4.1.3.6) has been purified from Escherichia coli and the homogeneity of the preparation established from the three-component subunits obtained on sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The purified enzyme has a specific activity of 120 mumol min-1 mg-1 and requires optimally 10 mM Mg2+ and a pH of 8.0 for the cleavage reaction. The native enzyme is polydispersed in the ultracentrifuge and in polyacrylamide gel electrophoresis. The enzyme complex is composed of three different polypeptide chains of 85 000, 54 000, 32 000 daltons. An estimate of subunit stoichiometry indicates that 1 mol of the largest polypeptide chain is associated with 6 mol each of the smaller ones. The polypeptide subunits have been isolated in pure state and their biological functions characterize. The 54 000-dalton subunit functions as the acyltransferase alpha subunit catalyzing the formation of citryl coenzyme A from citrate in the presence of acetyl coenzyme A and ethylenediaminetetraacetic acid. The 32 000-dalton subunit functions as the acyllyase beta subunit catalyzing the cleavage of (3S)-citryl coenzyme A to oxal-acetate and acetyl coenzyme A. The 85 000-dalton subunit, which carries exclusively the prosthetic group components, functions as the acyl-carrier protein gamma subunit in the cleavage of citrate in the presence of mg2+ and the alpha and beta subunits. The presence of a large ACP subunit and the unusual stoichiometry of the different subunits distinguish the complex from other citrate lyases. A ligase which acetylates the deacetyl[citrate lyase] in the presence of acetate and ATP has ben shown to be present in the organism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Properties of succinyl-coenzyme A:L-malate coenzyme A transferase and its role in the autotrophic 3-hydroxypropionate cycle of Chloroflexus aurantiacus

The 3-hydroxypropionate cycle has been proposed to operate as the autotrophic CO2 fixation pathway in the phototrophic bacterium Chloroflexus aurantiacus. In this pathway, acetyl coenzyme A (acetyl-CoA) and two bicarbonate molecules are converted to malate. Acetyl-CoA is regenerated from malyl-CoA by L-malyl-CoA lyase. The enzyme forming malyl-CoA, succinyl-CoA:L-malate coenzyme A transferase, was purified. Based on the N-terminal amino acid sequence of its two subunits, the corresponding genes were identified on a gene cluster which also contains the gene for L-malyl-CoA lyase, the subsequent enzyme in the pathway. Both enzymes were severalfold up-regulated under autotrophic conditions, which is in line with their proposed function in CO2 fixation. The two CoA transferase genes were cloned and heterologously expressed in Escherichia coli, and the recombinant enzyme was purified and studied. Succinyl-CoA:L-malate CoA transferase forms a large (alphabeta)n complex consisting of 46- and 44-kDa subunits and catalyzes the reversible reaction succinyl-CoA + L-malate --> succinate + L-malyl-CoA. It is specific for succinyl-CoA as the CoA donor but accepts L-citramalate instead of L-malate as the CoA acceptor; the corresponding d-stereoisomers are not accepted. The enzyme is a member of the class III of the CoA transferase family. The demonstration of the missing CoA transferase closes the last gap in the proposed 3-hydroxypropionate cycle.     

Purification and characterization of ATP:citrate lyase from Hydrogenobacter thermophilus TK-6.

ATP:citrate lyase [ATP citrate (pro-3S)-lyase; EC 4.1.3.8] was purified and characterized from the cells of Hydrogenobacter thermophilus, an aerobic, thermophilic, hydrogen-oxidizing bacterium which fixes carbon dioxide by a reductive carboxylic acid cycle. The enzyme was quite stable, even in the absence of sulfhydryl reagents. Optimum pH for reaction was 6.7 to 6.9, and optimum temperature was around 80 degrees C. The molecular weight of native enzyme was estimated to be 260,000 by gel filtration analysis, and that of a subunit was estimated to be 43,000 by sodium dodecyl sulfate-polyacrylamide gel analysis. Km values for reaction components were as follows: citrate, 6.25 mM; ATP, 650 microM; coenzyme A, 40.8 microM; and Mg2+, 8 mM. The enzyme showed citrate synthase activity in the presence of Mg2+, but the reaction rate was very low (less than 1/200 of the lyase activity).     

Synthesis and evaluation of (+) and (-)-2,2-difluorocitrate as inhibitors of rat-liver ATP-citrate lyase and porcine-heart aconitase.

The enantiomers (+) and (-)-2,2-difluorocitrate have been synthesized. Both are good inhibitors of ATP-citrate lyase, showing competitive inhibition against citrate, with Kis = 0.7 microM for (+)-2,2-difluorocitrate and 3.2 microM for (-)-2,2-difluorocitrate. The inhibition patterns with either ATP or CoA as the varied substrate were uncompetitive and mixed, respectively, but with much weaker inhibition constants. Neither isomer undergoes carbon-carbon bond cleavage as a substrate and there is no evidence of irreversible time-dependent inactivation. When ATP-citrate lyase is incubated with CoA and difluorocitrate, the maximal intrinsic ATPase rate is 10% of the citrate-induced rate for the (+)-enantiomer and 2% for the (-)-enantiomer. 19F-NMR studies confirm that only the (+)-enantiomer is chemically processed. The effects of the difluorocitrate enantiomers on the reaction catalysed by aconitase were examined. (-)-2,2-Difluorocitrate is a competitive inhibitor against citrate (Kis = 1.5 microM), whereas the (+)-enantiomer is a relatively poor mixed inhibitor (Ki greater than 300 microM). The (-)-enantiomer irreversibly inactivates aconitase at 1.1 min-1.mM-1 at 25 degrees C and pH 7.4, whereas no irreversible inhibition is seen with the (+)-enantiomer. Therefore, it would be expected that the (+)-enantiomer would slow the rate of acetyl-CoA synthesis in vivo, without inhibiting the citric acid cycle.     

Compartmentation of enzymes: ATP citrate lyase in hepatocytes from fed or fasted rats

Compared with traditional techniques of tissue homogenization, digitonin fractionation of isolated hepatocytes provides a much more rapid and, in some instances, more accurate determination of enzyme compartmentation. Results with ATP citrate lyase (EC 4.1.3.8) illustrate the information that uniquely can be obtained. Although the enzyme was previously thought to be entirely cytosolic, digitonin fractionation has shown that a portion of total cellular ATP citrate lyase is bound to mitochondria or some other structure, and the amount bound varies with the animal's nutritional state. In hepatocytes from rats that were starved for 2 days, fed NIH stock diet ab libitum, or starved for 2 days and then refed a fat-free diet for 2 days, the noncytosolic activity was, respectively, 52, 21, or 24% of total cellular lyase. However, because starvation/refeeding greatly induces lipogenic enzymes, the amount of bound lyase activity in this dietary state was 10-12 times greater than that in rats that were starved or fed ad libitum. The association of citrate lyase with a subcellular organelle is also influenced by CoA. Addition of 20 microM CoA to the digitonin fractionation medium caused all of the lyase to be released from cells like a cytosolic enzyme. Conversely, when cellular free CoA was decreased by incubating hepatocytes with the hypolipidemic agent 5-(tetradecyloxy)-2-furoic acid, the amount of bound lyase was increased. These results suggest the possibility that the noncytosolic ATP citrate lyase may have a special role in lipogenesis.     

ATP-citrate lyase from rat liver. Characterisation of the citryl-enzyme complexes.

The mechanism of ATP-citrate lyase has been proposed to involve a citryl-enzyme intermediate. When the enzyme is incubated with its substrates ATP and [14C]citrate, but in the absence of the final acceptor, two distinct types of citrate-containing complex can be isolated. At early time points, a highly unstable complex can be isolated by gel filtration which has a half-life of 36 s at 25 degrees C. This complex reacts rapidly with CoA, but cannot be acid-precipitated; behaviour consistent with its identification as enzyme-citryl phosphate. However, ATP-citrate lyase is also capable of undergoing a slow time-dependent covalent incorporation of radiolabel from [14C]citrate. This modification is acid-stable, non-specific, and cannot be reversed by the addition of CoA. When cytochrome is included in the reaction mixture as a heterologous acceptor, it is also citrylated. These reactions require that when ATP-citrate lyase is incubated with all its substrates except for CoA, a freely diffusible citrylating species is generated within the active site. This evidence suggests that there is no requirement for the mechanism of ATP-citrate lyase to proceed via a covalent citryl-enzyme intermediate. By analogy with succinyl-CoA synthetase, an enzyme which has a high degree of sequence similarity with ATP-citrate lyase, a simple mechanism is proposed for the enzyme in which citryl-CoA is produced by direct nucleophilic attack on citryl phosphate.     

The structure and computational analysis of Mycobacterium tuberculosis protein CitE suggest a novel enzymatic function

Fatty acid biosynthesis is essential for the survival of Mycobacterium tuberculosis and acetyl-coenzyme A (acetyl-CoA) is an essential precursor in this pathway. We have determined the 3-D crystal structure of M. tuberculosis citrate lyase beta-subunit (CitE), which as annotated should cleave protein bound citryl-CoA to oxaloacetate and a protein-bound CoA derivative. The CitE structure has the (beta/alpha)(8) TIM barrel fold with an additional alpha-helix, and is trimeric. We have determined the ternary complex bound with oxaloacetate and magnesium, revealing some of the conserved residues involved in catalysis. While the bacterial citrate lyase is a complex with three subunits, the M. tuberculosis genome does not contain the alpha and gamma subunits of this complex, implying that M. tuberculosis CitE acts differently from other bacterial CitE proteins. The analysis of gene clusters containing the CitE protein from 168 fully sequenced organisms has led us to identify a grouping of functionally related genes preserved in M. tuberculosis, Rattus norvegicus, Homo sapiens, and Mus musculus. We propose a novel enzymatic function for M. tuberculosis CitE in fatty acid biosynthesis that is analogous to bacterial citrate lyase but producing acetyl-CoA rather than a protein-bound CoA derivative.     

Purification and characterization of a cytoplasmic enzyme component of the Na+-activated malonate decarboxylase system of Malonomonas rubra: acetyl-S-acyl carrier protein: malonate acyl carrier protein-SH transferase

Malonate decarboxylation by crude extracts of Malonomonas rubra was specifically activated by Na⁺ and less efficiently by Li⁺ ions. The extracts contained an enzyme catalyzing CoA transfer from malonyl-CoA to acetate, yielding acetyl-CoA and malonate. After about a 26-fold purification of the malonyl-CoA:acetate CoA transferase, an almost pure enzyme was obtained, indicating that about 4% of the cellular protein consisted of the CoA transferase. This abundance of the transferase is in accord with its proposed role as an enzyme component of the malonate decarboxylase system, the key enzyme of energy metabolism in this organism. The apparent molecular weight of the polypeptide was 67,000 as revealed from SDS-polyacrylamide gel electrophoresis. A similar molecular weight was estimated for the native transferase by gel chromatography, indicating that the enzyme exists as a monomer. Kinetic analyses of the CoA transferase yielded the following: pH-optimum at pH 5.5, an apparent K_m for malonyl-CoA of 1.9mM, for acetate of 54mM, for acetyl-CoA of 6.9mM, and for malonate of 0.5mM. Malonate or citrate inhibited the enzyme with an apparent K_i of 0.4mM and 3.0mM, respectively. The isolated CoA transferase increased the activity of malonate decarboxylase of a crude enzyme system, in which part of the endogenous CoA transferase was inactivated by borohydride, about three-fold. These results indicate that the CoA transferase functions physiologically as a component of the malonate decarboxylase system, in which it catalyzes the transfer of acyl carrier protein from acetyl acyl carrier protein and malonate to yield malonyl acyl carrier protein and acetate. Malonate is thus activated on the enzyme by exchange for the catalytically important enzymebound acetyl thioester residues noted previously. This type of substrate activation resembles the catalytic mechanism of citrate lyase and citramalate lyase.Abbreviations DTNB 5,5 Dithiobis (2-nitrobenzoate) - MES 2-(N-Morpholino)ethanesulfonic acid - TAPS N-[Tris(hydroxymethyl)-methyl]-3-aminopropanesulfonic acid - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Inhibition of rat liver acetyl-CoA carboxylase by beta, beta'-tetramethyl-substituted hexadecanedioic acid (MEDICA 16)

Rat liver acetyl-CoA carboxylase activity was inhibited by the free as well as the CoA monothioester of beta, beta'-methyl-substituted hexadecanedioic acid (MEDICA 16) (Bar-Tana, J., Rose-Kahn, G. and Srebnik, M. (1985) J. Biol. Chem. 260, 8404-8410 (1985). (1) The CoA monothioester of MEDICA 16 served as a dead-end inhibitor with an apparent Ki of 2 microM and 58 microM for the biotin-carboxylated and noncarboxylated enzyme forms, respectively. MEDICA 16-CoA binding was not mutually exclusive with that of citrate and did not affect the avidin-resistance of rat liver acetyl-CoA carboxylase. (2) The free dioic acid of MEDICA 16 was competitive to citrate, having an apparent Ki of about 70 microM, as compared to a Ka of 2-8 mM for the citrate activator. Inhibition of the carboxylase by the free dioic acid of MEDICA 16 was accompanied by an increase in its avidin resistance. The resultant inhibition of acetyl-CoA carboxylase by MEDICA 16 and its CoA thioester, together with the previously reported citrate-competitive inhibition of ATP-citrate lyase by MEDICA 16, may account for the observed hypolipidemic effect of MEDICA 16 under dietary conditions where liver lipogenesis constitutes a major flux of liver lipid synthesis.     

Interaction of ligands with pig heart citrate synthase: conformational changes and catalysis.

The fluorescence polarization of 8-hydroxypyrene (1,3,6)trisulfonate (HPT) increases upon interaction with pig heart citrate synthase. Titration of HPT with increasing concentrations of citrate synthase exhibits a hyperbolic saturation behavior, from which the dissociation constant of the enzyme-HPT complex (3.64 +/- 0.3 microM) was determined. The enzyme-HPT interaction is competitively inhibited by oxaloacetate (but not affected by acetyl CoA) with a Ki of 4.3 +/- 1.8 microM. This value is similar to the dissociation constant (Kd = 4.5 +/- 1.6 microM) for the enzyme-oxalocetate complex (determined in the absence of any effector ligand), as well as to the Km for oxaloacetate (3.9 +/- 0.7 microM) in a steady-state citrate synthase catalyzed reaction at a saturating concentration of acetyl CoA. However, the dissociation constant for the citrate synthase-oxaloacetate complex determined by the urea denaturation method is at least 25-fold lower than those determined by the other methods. This suggests an effector role of urea in strengthening the enzyme-oxaloacetate interaction. At low nondenaturing concentrations, urea inhibits the citrate synthase catalyzed reaction in an uncompetitive manner with respect to oxaloacetate, i.e., the Km for oxaloacetate decreases with an increase in urea concentration. This further suggests that urea stabilizes the interaction between citrate synthase and oxaloacetate. The effect of urea is specific for the substrate oxaloacetate, and not for the substrate analogue, HPT, although both these ligands bind citrate synthase with equal affinities, and protect the enzyme against thermal denaturation with equal magnitudes. The results presented herein are discussed in the light of known conformational states of the enzyme.     

Kinetic characterization of the pyruvate and oxoglutarate dehydrogenase complexes from human heart

The Michaelis constant values for the highly purified pyruvate dehydrogenase complex (PDC) from human heart are 25, 13 and 50 microM for pyruvate, CoA and NAD, respectively. Acetyl-CoA produces a competitive inhibition of PDC (Ki = 35 microM) with respect to CoA, whereas NADH produces the same type of inhibition with respect to NAD (Ki = 36 microM). The oxoglutarate dehydrogenase complex (OGDC) from human heart has active sites with two different affinities for 2-oxoglutarate ([S]0.5 of 30 and 120 microM). ADP (1 mM) decreases the [S]0.5 values by a half. The inhibition of OGDC (Ki = 81 microM) by succinyl-CoA is of a competitive type with respect to CoA (Km = 2.5 microM), whereas that of NADH (Ki = 25 microM) is of a mixed type with respect to NAD (Km = 170 microM).     

Molecular biology of cytosolic acetyl-CoA generation

ATP citrate lyase (ACL) catalyses the ATP-dependent reaction between citrate and CoA to form oxaloacetate and acetyl-CoA. Our molecular characterizations of the cDNAs and genes coding for the Arabidopsis ACL indicate that the plant enzyme is heteromeric, consisting of two dissimilar subunits. The A subunit is homologous to the N-terminal third of the animal ACL, and the B subunit is homologous to C-terminal two-thirds of the animal ACL. Using both ACL-A- and ACL-B-specific antibodies and activity assays we have shown that ACL is located in the cytosol, and is not detectable in the plastids, mitochondria or peroxisomes. During seed development, ACL-A and ACL-B mRNA accumulation is co-ordinated with the accumulation of the cytosolic homomeric acetyl-CoA carboxylase mRNA. Antisense Arabidopsis plants reduced in ATP citrate lyase activity show a complex phenotype, with miniaturized organs, small cell size, aberrant plastid morphology and reduced cuticular wax. Our results indicate that ACL generates the cytosolic pool of acetyl-CoA, which is the substrate required for the biosynthesis of a variety of phytochemicals, including cuticular waxes and flavonoids.     

Energy-dependent inactivation of citrate lyase in Enterobacter aerogenes.

Enterobacter aerogenes was grown in continous culture with ammonia as the growth-limiting substrate, and changes in citrate lyase and citrate synthase activities were monitored after growth shifts from anaerobic growth on citrate to aerobic growth on citrate, aerobic growth on glucose, anaerobic growth on glucose, and anaerobic growth on glucose plus nitrate. Citrate lyase was inactivated during aerobic growth on glucose and during anaerobic growth with glucose plus nitrate. Inactivation did not occur during anaerobic growth on glucose, and as a result of the simultaneous presence of citrate lyase and citrate synthase, growth difficulties were observed. Citrate lyase inactivation consisted of deacetylation of the enzyme. The corresponding deacetylase could not be demonstrated in cell extracts, and it is concluded that, as in a number of other inactivations, electron transport to oxygen or nitrate was required for inactivation.     

Substrate specificity of citrate lyase deacetylase of Rhodopseudomonas gelatinosa and Rhodopseudomonas palustris.

Citrate lyase (EC 4.1.3.6) isolated from Rhodopseudomonas palustris was investigated with regard to its kinetic properties and its subunit composition. This enzyme was inactivated by citrate lyase deacetylase (EC 3.1.2.-) of Rhodopseudomonas gelatinosa. A corresponding cross-reaction was measured with partially purified deacetylase of R. palustris and citrate lyase of R. gelatinosa. The three different subunit types (alpha, beta, and gamma) of citrate lyase from R. gelatinosa wee purified to homogeneity, and antibodies were prepared against each of the three subunits and against the native enzyme complex. In corresondence with the enzymatic interactions, immunological cross-reactions were found between anti-enzyme and anti-large subunit antibodies and citrate lyase from R. palustris. On the other hand, no immunological cross-reactions were detectable among each of the antibodies and citrate lyases from Enterobacter aerogenes, Streptococcus diacetilactis, and Clostridium sphenoides. Antibodies against the large subunit of citrate lyase inhibited the deacetylase, but antibodies against the middle and small subunits did not, indicating that the large subunits of citrate lyase are involved in binding the deacetylase.     

Synthesis of citrate from phosphoenolpyruvate and acetylcarnitine by mitochondria from rabbit, pigeon and rat liver: Implications for lipogenesis

Rabbit, pigeon and rat liver mitochondria convert exogenous phosphoenolpyruvate and acetylcarnitine to citrate at rates of 14, 74 and 8 nmol/15 min/mg protein. Citrate formation is dependent on exogenous HCO3, is increased consistently by exogenous nucleotides (GDP, IDP, GTP, ADP, ATP) and inhibited strongly by 3-mercaptopicolinate and 1,2,3-benzenetricar☐ylate. Citrate is not made from pyruvate alone or combined with acetylcarnitine. Pigeon and rat liver mitochondria make large amounts of citrate from exogenous succinate, suggesting the presence of an endogenous source of acetyl units or a means of converting oxalacetate to acetyl units. Citrate synthesis from succinate by pigeon and rabbit mitochondria is increased significantly by exogenous acetylcarnitine. Pigeon and rat liver contain 80 and 15 times, respectively, more ATP:citrate lyase activity than does rabbit liver. Data suggest that mitochondrial phosphoenolpyruvate car☐ykinasein vivo could convert glycolysis-derived phosphoenolpyruvate to oxalacetate that, with acetyl CoA, could form citrate for export to support cytosolic lipogenesis as an activator of acetyl CoA car☐ylase, a carbon source via ATP:citrate lyase and NADPH via NADP: malate dehydrogenase or NADP: isocitrate dehydrogenase.     

Distribution in brain and retina of four enzymes of acetyl CoA synthesis in relation to choline acetyl transferase and acetylcholine esterase

Eleven regions of mouse brain and twelve layers of monkey retina were assayed for choline acetyl transferase (ChAT), acetylcholine esterase (AChE), and 4 enzymes that synthesize acetyl CoA. The purpose was to seek evidence concerning the source of acetyl CoA for acetylcholine generation. In brain ATP citrate lyase was strongly correlated with ChAT as well as AChE (r=0.914 in both cases). Weak, but statistically significant correlation, was observed between ChAT and both cytoplasmic and mitochondrial thiolase, whereas there was a significant negative correlation between ChAT and acetyl thiokinase. In retina ChAT was essentially limited to the inner plexiform and ganglion cell layers, whereas substantial AChE activity extended as well into inner nuclear, outer plexiform and fiber layers, but no further. ATP citrate lyase activity was also highest in the inner four retinal layers, but was not strongly correlated with either ChAT or AChE (r=0.724 and 0.761, respectively). Correlation between ChAT and acetyl thiokinase was at least as strong (r=0.757), and in the six inner layers of retina, the correlation between ChAT and acetylthiokinase was very strong (r=0.932).Special issue dedicated to Dr. Lawrence Austin     

Activity of enzymes involved in lignin biosynthesis in swede root disks

The activity of nine enzymes involved in the biosynthesis of lignin precursors has been studied during the ageing of swede root disks in the presence and absence of ethylene. Peroxidase, aromatic alcohol dehydrogenase and phenylalanine transaminase show very little change in activity during ageing under either ageing condition. O-methyl transferase, shikimate dehydrogenase and ferulyl CoA reductase show only a 2–3 fold increase on ageing and are relatively insensitive to ethylene treatment. A third group (comprising phenylalanine ammonia lyase, cinnamic acid-4-hydroxylase and hydroxycinnamate CoA ligase) show 20–30 fold increase on ageing and are most sensitive to ethylene treatment. Phenylalanine ammonia lyase and cinnamic acid-4-hydroxylase behave very similarly in respect of their time course of ageing and in their responses to metabolic inhibitors such as cycloheximide, puromycin and actinomycin D. In addition the properties of the O-methyl transferase of swede root tissue are described.     

Citrate synthase stabilizes the enethiolate of acetyldithio coenzyme A

Citrate synthase catalyzes the slow condensation of acetyldithio-CoA [Ac(= S)CoA] with oxalacetate to form thiocitrate [Wlassics, I.D., Stille, C., & Anderson, V.E. (1988) Biochim. Biophys. Acta 952, 269]. During the transient approach to steady state an observable amount of the dithioester absorbance disappears. The amplitude of the decrease in absorbance corresponds to 0.32, 0.03, and 0.02 enzyme equiv at pH 8.3, 7.5, and 6.6, respectively. The difference spectra from before and after the transient exhibit the dithioester lambda max at 306 nm. Acid quenching of a stiochiometric reaction between Ac(= S)CoA and citrate synthase following the transient quantitatively regenerates Ac(= S)CoA, indicating carbon-carbon bond formation had not yet occurred. The apparent first-order rate constant of the transient is independent of Ac(= S)CoA concentration and increases with decreasing pH, being 0.007, 0.016, and 0.04 s-1 at pH 8.3, 7.5, and 6.6, respectively. 2-Fluoroacetyldithio-CoA is a better inhibitor of citrate synthase, Ki = 300 nM, and substrate, Vmax = 2 X 10(-3) s-1, than Ac(= S)CoA. 1H NMR experiments indicate that citrate synthase catalyzes the exchange of the alpha-hydrogens of Ac(= S)CoA with turnover numbers of 0.13 and 0.54 s-1 at pD 7.9 and 7.2, respectively. Analysis of the proton and deuterium decoupled 13C NMR spectra of [2-13C]Ac(= S)CoA that has exchanged 37% of the alpha-hydrogens in the presence of citrate synthase indicates that the relative proportions of CH3, CH2D, CHD2, and CD3 were 0.29, 0.39, 0.25, and 0.07, respectively. This statistical distribution indicates each exchange event is independent. The data indicate that citrate synthase stabilizes the ionized form of Ac(= S)CoA by 5 kcal/mol relative to the un-ionized form, that the ionized dithioester is on the reaction pathway, and that below pH 8.3 the slow carbon-carbon bond forming reaction is responsible for the 10(6) decrease in Vmax caused by substituting sulfur for oxygen in the thioester carbonyl.     

Activation of acetyl-CoA carboxylase. Purification and properties of a Mn2+-dependent phosphatase

Acetyl-CoA carboxylase was isolated from rat liver by polyethylene glycol precipitation and avidin affinity chromatography. Sodium dodecyl sulfate electrophoresis of the enzyme gives one protein band (Mr 250,000). Phosphate analysis of the carboxylase showed the presence of 8.3 mol of phosphate/mol of subunit (Mr 250,000). The purified carboxylase has low activity in the absence of citrate (specific activity = 0.3 units/mg). However, addition of 10 mM citrate activates the carboxylase 10-fold, with half-maximal activation observed at 2 mM citrate, well above the physiological citrate level. Using this carboxylase as a substrate, we have isolated from rat liver a protein that activates the enzyme about 10-fold. This protein has been purified to near homogeneity (Mr 90,000). Incubation of this protein with 32P-labeled acetyl-CoA carboxylase results in a time-dependent activation of carboxylase with concomitant release of 32Pi, indicating that this protein is a phosphoprotein phosphatase. Both activation and dephosphorylation are dependent on Mn2+, but not citrate. This phosphatase does not hydrolyze p-nitrophenyl phosphate but does show high affinity for acetyl-CoA carboxylase (Km = 0.2 microM) as compared to its action on phosphorylase a (Km = 5.5 microM) and phosphohistone (Km = 20 microM). Activated acetyl-CoA carboxylase was isolated after dephosphorylation by the phosphatase. Such preparations contain about 5 mol of phosphate/mol of subunit and have specific activities of 2.6-3.0 units/mg in the absence of citrate. These activities are comparable to those of the phosphorylated carboxylase in the presence of 10 mM citrate. Thus, dephosphorylation by the Mn2+-dependent phosphatase renders the carboxylase citrate-independent, as compared to the phosphorylated form, which is citrate-dependent. To our knowledge this is the first report of a preparation of animal acetyl-CoA carboxylase that has substantial catalytic activity independent of citrate.