Cold-active citrate synthase: mutagenesis of active-site residues.

A comparison of the crystal structure of the dimeric enzyme citrate synthase from the psychrophilic Arthrobacter strain DS2-3R with that of the structurally homologous enzyme from the hyperthermophilic Pyrococcus furiosus reveals a significant difference in the accessibility of their active sites to substrates. In this work, we investigated the possible role in cold activity of the greater accessibility of the Arthrobacter citrate synthase. By site-directed mutagenesis, we replaced two alanine residues at the entrance to the active site with an arginine and glutamate residue, respectively, as found in the equivalent positions of the Pyrococcus enzyme Also, we introduced a loop into the active site of the psychrophilic citrate synthase, again mimicking the situation in the hyperthermophilic enzyme. Analysis of the thermoactivity and thermostability of the mutant enzymes reveals that cold activity is not significantly compromised by the mutations, but rather the affinity for one of the substrates, acetyl-CoA, is dramatically increased. Moreover, one mutant (Loop insertion/K313L/A361R) has an increased thermostability but a reduced temperature optimum for catalytic activity. This unexpected relationship between stability and activity is discussed with respect to the nature of the dependence of catalytic activity on temperature.     

The unfolding and attempted refolding of citrate synthase from pig heart

The unfolding of the dimeric enzyme citrate synthase from pig heart in solutions of guanidinium chloride (GdnHCl) was studied. Data from fluorescence, circular dichroism (CD) and thiol group reactivity studies indicated that the enzyme was almost completely unfolded at GdnHCl concentrations greater than or equal to 4 M. On dilution of GdnHCl, essentially no reactivation of the enzyme occurred. The implications of this finding for the process of folding and assembly in vivo of this and other mitochondrial enzymes are discussed. Exposure of the enzyme to high pH (9-10) led to only a small loss of secondary structure and partial reactivation could be observed on readjustment of the pH to 8.0.     

Mutation of essential catalytic residues in pig citrate synthase.

Two amino acid residues, His274 and Asp375, were replaced singly in the active site of pig citrate synthase (PCS) with Gly274, Arg274, Gly375, Asn375, Glu375, and Gln375. The nonmutant protein and the mutant proteins were expressed in and purified from Escherichia coli, and the effects of these amino acid substitutions on the overall reaction rate and conformation of the PCS protein were studied by initial velocity and full time course kinetic analysis, behavior during affinity column chromatography, and monoclonal antibody reactivity. Native and mutant proteins purified similarly had a subunit molecular weight of 50,000 and were homologous when examined with 10 independent a-PCS monoclonal IgGs or with a polyclonal anti-PHCS serum. No activity was detected for Asn375 or Gln375. The kcats of the other purified mutant proteins, however, were decreased by about 10(3) compared to the nonmutant enzyme activity. The Km for oxalacetate was decreased 10-fold in the Glu375 protein and was reduced by half in Gly274 and Arg274 PCSs, while the Km for acetyl-CoA was decreased 2-3-fold in Gly274, Arg274, and Gln375 PCSs. A mechanism is proposed that electrostatically links His274 and Asp375.     

Probing the Sinorhizobium meliloti-alfalfa symbiosis using temperature-sensitive and impaired-function citrate synthase mutants

To study the role of the decarboxylating leg of the bacterial TCA cycle in symbiotic nitrogen fixation, we used DNA shuffling and localized random polymerase chain reaction mutagenesis to construct a series of temperature-sensitive and impaired-function mutants in the Sinorhizobium meliloti Rm104A14 citrate synthase (gltA) gene. Reducing citrate synthase (CS) activity by mutation led to a corresponding decrease in the free-living growth rate; however, alfalfa plants formed fully effective nodules when infected with mutants having CS activities as low as 7% of the wild-type strain. Mutants with approximately 3% of normal CS activity formed nodules with lower nitrogenase activity and a mutant with less than 0.5% of normal CS activity formed Fix- nodules. Two temperature-sensitive (ts) mutants grew at a permissive temperature (25 degrees C) with 3% of wild-type CS activities but were unable to grow on minimal medium at 30 degrees C. Alfalfa plants that were inoculated with the ts mutants and grown with a root temperature of 20 degrees C formed functional nodules with nitrogenase activities approximately 20% of the wild type. When the roots of plants infected with the ts mutants were transferred to 30 degrees C, the nodules lost the ability to fix nitrogen over several days. Microscopic examination of these nodules revealed the loss of bacteroids and senescence, indicating that CS activity was essential for nodule maintenance.     

A crystallographic investigation of citrate synthase from pig and chicken heart muscle

Citrate synthase (EC 4. 1. 3. 7.) from pig heart and chicken heart muscle can be crystallized from 10 mM phosphate buffer (pH 7. 0–7. 5) and 10–15% PEG4000 solution. The space group is P4₁2₁2 with one subunit/asymmetric unit for the pig heart enzyme. The chicken heart citrate synthase purified from Blue-dextran as well as ATP-Sepharose affinity chromatography both crystallize in space group P2₁2₁2 with one molecule/asymmetric unit, but they have different unit cell dimensions. The a-axis differs by about 17 Å between these two crystal forms, while b- and c-axis dimensions are virtually identical.     

Selection for citrate synthase deficiency in icd mutants of Escherichia coli.

Cultures of isocitrate dehydrogenase-deficient (icd) mutants were overgrown by double mutants (icd glt) lacking citrate synthase activity also. The icd mutants grew more slowly than wild-type cells or the double mutants because they accumulated an inhibitory metabolite (possibly citrate). Intracellular citrate levels were several hundred-fold higher in icd cells than in wild-type or icd glt cells. Final growth yields of the wild type and the icd mutant on limiting glucose were equivalent and greater than the growth yield of icd glt double mutants. The icd gene mapped between 60 and 74 min. icd mutants were resistant to nalidixic acid, but glt and icd glt mutants and wild-type cells were sensitive, indicating that resistance results from accumulation of isocitrate, citrate, or a derivative of these compounds.     

GroE-dependent expression and purification of pig heart mitochondrial citrate synthase in Escherichia coli

Citrate synthase (CS) is a dimeric, mitochondrial protein, composed of two identical subunits (M(r) 48969 each). The nuclear-encoded alpha-helical protein is imported into mitochondria post-translationally where it catalyses the first step of the citric cycle. Furthermore, the pathway of thermal unfolding as well as the folding pathway was studied extensively, making CS a well-suited substrate protein for studying chaperone function. In chaperone research the quality of the substrate proteins is essential to guaranty the reproducibility of the results. In this context, we here describe the GroE-enhanced recombinant expression and purification of CS. CS was expressed in E. coli by using an arabinose regulated T7 promotor. Under standard expression conditions only insoluble, inactive CS was detected. Interestingly, the expression of soluble and active CS was possible when GroEL/GroES was co-expressed. Furthermore, a shift to lower expression temperatures increased the amount of soluble, active CS. We describe for the first time, the purification of CS in soluble and active form by following a CiPP strategy (capture, intermediate purification, polishing). After the initial capturing step on DEAE-Sephacel the protein was further purified on a Q-Sepharose column. After these two steps of anion-exchange chromatography a final size-exclusion chromatography step on a Superdex 75-pg column yields CS with a purity over 99%. Using this expression and purification strategy 1 mg CS per g E. coli wet weight were purified.     

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.     

Isolation, nucleotide sequence, and expression of a cDNA encoding pig citrate synthase

Citrate synthase is a key enzyme of the Krebs tricarboxylic acid cycle and catalyzes the stereospecific synthesis of citrate from acetyl coenzyme A and oxalacetate. The amino acid sequence and three-dimensional structure of pig citrate synthase dimers are known, and regions of the enzyme involved in substrate binding and catalysis have been identified. A cloned complementary DNA sequence encoding pig citrate synthase has been isolated from a pig kidney lambda gt11 cDNA library after screening with a synthetic oligonucleotide probe. The complete nucleotide sequence of the 1.5-kilobase cDNA was determined. The coding region consists of 1395 base pairs and confirms the amino acid sequence of purified pig citrate synthase. The derived amino acid sequence of pig citrate synthase predicts the presence of a 27 amino acid N-terminal leader peptide whose sequence is consistent with the sequences of other mitochondrial signal peptides. A conserved amino acid sequence in the mitochondrial leader peptides of pig citrate synthase and yeast mitochondrial citrate synthase was identified. To express the pig citrate synthase cDNA in Escherichia coli, we employed the inducible T7 RNA polymerase/promoter double plasmid expression vectors pGP1-2 and pT7-7 [Tabor, S., & Richardson, C. C. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 1074-1078]. The pig citrate synthase cDNA was modified to delete the N-terminal leader sequence; then by use of a synthetic oligonucleotide linker, the modified cDNA was cloned into pT7-7 immediately following the initiator Met. A glutamate-requiring (citrate synthase deficient), recA- E. coli mutant, DEK15, was transformed with pGP1-2 and then pT7-7PCS. pT7-7PCS complemented the E. coli gltA mutation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolic characterisation of E. coli citrate synthase and phosphoenolpyruvate carboxylase mutants in aerobic cultures

E. coli is still one of the most commonly used hosts for protein production. However, when it is grown with excess glucose, acetate accumulation occurs. Elevated acetate concentrations have an inhibitory effect on growth rate and recombinant protein yield, and thus elimination of acetate formation is an important aim towards industrial production of recombinant proteins. Here we examine if over-expression of citrate synthase (gltA) or phosphoenolpyruvate carboxylase (ppc) can eliminate acetate production. Knock-out as well as over-expression mutants were constructed and characterized. Knocking out ppc or gltA decreased the maximum cell density by 14% and increased the acetate excretion by 7%, respectively decreased it by 10%. Over-expression of ppc or gltA increased the maximum cell dry weight by 91% and 23%, respectively. No acetate excretion was detected at these increased cell densities (35 and 23 g/l, respectively).     

Purification and some properties of the citrate synthase from a marine Pseudomonas.

Citrate synthase (citrate-oxaloacetate lyase (CoA acetylating), EC 4.1.3.7) has been purified to electrophoretic homogeneity from a marine Pseudomonas. The enzyme was made up of identical subunits, with a molecular wieght of about 53 000, as determined by sodium dodecyl sulphate - polyacrylamide gel electrophoresis. The native enzyme (citrate synthase II, CS II) could be dissociated by dialysis against 20 mM phosphate (Pi), pH 7; the enzyme thus obtained (citrate synthase I, CS I) was still active, but presented different molecular weight and kinetic and regulatory properties. CS II was activated by adenosine monophosphate (AMP), Pi, and KCl, and inhibited by reduced nicotinamide adenine dinucleotide (NADH), being apparently insensitive to adenosine triphosphate (ATP) and adenosine diphosphate (ADP). The inhibition by NADH was completely counteracted by 0.1 mM AMP, but not by 50 mM Pi or 0.1 M KCl. The activation by KCl and Pi, or by KCl and AMP was nearly additive, whereas that by AMP and Pi was not. The activators acted essentially by increasing Vmax, although they also caused a decrease in the Km values. CS I was inhibited by ATP, ADP, AMP, and KCl, and was insensitive to NADH. CS I could be reassociated after elimination of Pi by dialysis, regaining the higher molecular weight and the activation by AMP characteristic of CS II.     

Suppression of metabolic defects of yeast isocitrate dehydrogenase and aconitase mutants by loss of citrate synthase

Yeast mutants lacking mitochondrial NAD⁺-specific isocitrate dehydrogenase (idhΔ) or aconitase (aco1Δ) were found to share several growth phenotypes as well as patterns of specific protein expression that differed from the parental strain. These shared properties of idhΔ and aco1Δ strains were eliminated or moderated by co-disruption of the CIT1 gene encoding mitochondrial citrate synthase. Gas chromatography/mass spectrometry analyses indicated a particularly dramatic increase in cellular citrate levels in idhΔ and aco1Δ strains, whereas citrate levels were substantially lower in idhΔcit1Δ and aco1Δcit1Δ strains. Exogenous addition of citrate to parental strain cultures partially recapitulated effects of high endogenous levels of citrate in idhΔ and aco1Δ strains. Finally, effects of elevated cellular citrate in idhΔ and aco1Δ mutant strains were partially alleviated by addition of iron or by an increase in pH of the growth medium, suggesting that detrimental effects of citrate are due to elevated levels of the ionized form of this metabolite.     

Site-directed mutagenesis of citrate synthase; the role of the active-site aspartate in the binding of acetyl-CoA but not oxaloacetate

Asp-362, a potential key catalytic residue of Escherichia coli citrate synthase (citrate oxaloacetate-lyase [pro-3S)-CH2COO- ----acetyl-CoA), EC 4.1.3.7) has been converted to Gly-362 by oligonucleotide-directed mutagenesis. The mutant gene was completely sequenced, using a series of synthetic oligodeoxynucleotides spanning the structural gene to confirm that no additional mutations had occurred during genetic manipulation. The mutant gene was expressed in M13 bacteriophage and produced a protein which migrated in an identical manner to wild-type E. coli citrate synthase on SDS-polyacrylamide gels and which cross-reacted with E. coli citrate synthase antiserum. The mutant gene was subsequently recloned into pBR322 for large scale purification of the protein, and the resulting plasmid, pCS31, used to transform the citrate synthase deletion strain, W620. The mutant enzyme purified in an analogous manner to wild-type E. coli citrate synthase and expressed less than 2% of wild-type enzyme activity. The activity of the partial reactions catalysed by citrate synthase was similarly affected suggesting that this residual activity may be due to contaminating wild-type enzyme activity. The mutant citrate synthase retains a high-affinity NADH-binding site consistent with the protein preserving its overall structural integrity. Oxaloacetate binding to the protein is unaffected by the Asp-362 to Gly-362 mutation. Binding of the acetyl-CoA analogue, carboxymethyl-CoA, could not be detected in the mutant protein indicating that the lack of catalytic competence is due primarily to the inability of the protein to bind the second substrate, acetyl-CoA.