Catalytic strategy of citrate synthase: effects of amino acid changes in the acetyl-CoA binding site on transition-state analog inhibitor complexes

The Ubiquitin Ligase SCF(Ucc1) Acts as a Metabolic Switch for the Glyoxylate Cycle

Despite the crucial role played by the glyoxylate cycle in the virulence of pathogens, seed germination in plants, and sexual development in fungi, we still have much to learn about its regulation. Here, we show that a previously uncharacterized SCF(Ucc1) ubiquitin ligase mediates proteasomal degradation of citrate synthase in the glyoxylate cycle to maintain metabolic homeostasis in glucose-grown cells. Conversely, transcription of the F box subunit Ucc1 is downregulated in C2-compound-grown cells, which require increased metabolic flux for gluconeogenesis. Moreover, in vitro analysis demonstrates that oxaloacetate regenerated through the glyoxylate cycle induces a conformational change in citrate synthase and inhibits its recognition and ubiquitination by SCF(Ucc1), suggesting the existence of an oxaloacetate-dependent positive feedback loop that stabilizes citrate synthase. We propose that SCF(Ucc1)-mediated regulation of citrate synthase acts as a metabolic switch for the glyoxylate cycle in response to changes in carbon source, thereby ensuring metabolic versatility and flexibility.

The partial substrate dethiaacetyl-coenzyme A mimics all critical carbon acid reactions in the condensation half-reaction catalyzed by Thermoplasma acidophilum citrate synthase

Citrate synthase (CS) performs two half-reactions: the mechanistically intriguing condensation of acetyl-CoA with oxaloacetate (OAA) to form citryl-CoA and the subsequent, slower hydrolysis of citryl-CoA that generally dominates steady-state kinetics. The condensation reaction requires the abstraction of a proton from the methyl carbon of acetyl-CoA to generate a reactive enolate intermediate. The carbanion of that intermediate then attacks the OAA carbonyl to furnish citryl-CoA, the initial product. Using stopped-flow and steady-state fluorescence methods, kinetic substrate isotope effects, and mutagenesis of active site residues, we show that all of the processes that occur in the condensation half-reaction performed by Thermoplasma acidophilum citrate synthase (TpCS) with the natural thioester substrate, acetyl-CoA, also occur with the ketone inhibitor dethiaacetyl-CoA. Free energy profiles demonstrate that the nonhydrolyzable product of the condensation reaction, dethiacitryl-CoA, forms a particularly stable complex with TpCS but not pig heart CS.

Kinetic analysis of the effects of monovalent cations and divalent metals on the activity of Mycobacterium tuberculosis α-isopropylmalate synthase

Mycobacterium tuberculosis alpha-isopropylmalate synthase (MtIPMS) is a member of the family of enzymes that catalyze a Claisen-type condensation. In this work we characterized the monovalent and divalent specificity of MtIPMS using steady-state kinetics. The monovalent cation dependence of the kinetic parameters of substrates and divalent metals indicates that K+ is the likely physiological activator. K+ acts most likely as an allosteric activator, and exerts part of its effect through the catalytic divalent metal. The divalent metal specificity of MtIPMS is broad, and Mg2+ and Mn2+ are the metals that cause the highest activation. Interestingly, Zn2+, first assigned as the catalytic metal, inhibits the enzyme with submicromolar affinity. The features of monovalent cation and divalent metal activation, as well as the inhibition by Zn2+ and Cd2+, are discussed in light of the kinetic and structural information available for MtIPMS and other relevant enzymes.

Stepwise adaptations of citrate synthase to survival at life's extremes. From psychrophile to hyperthermophile

The crystal structure of citrate synthase from the thermophilic Archaeon Sulfolobus solfataricus (optimum growth temperature = 85 degrees C) has been determined, extending the number of crystal structures of citrate synthase from different organisms to a total of five that span the temperature range over which life exists (from psychrophile to hyperthermophile). Detailed structural analysis has revealed possible molecular mechanisms that determine the different stabilities of the five proteins. The key to these mechanisms is the precise structural location of the additional interactions. As one ascends the temperature ladder, the subunit interface of this dimeric enzyme and loop regions are reinforced by complex electrostatic interactions, and there is a reduced exposure of hydrophobic surface. These observations reveal a progressive pattern of stabilization through multiple additional interactions at solvent exposed, loop and interfacial regions.

Regulation of Hsp90 ATPase activity by the co-chaperone Cdc37p/p50cdc37

In vivo activation of client proteins by Hsp90 depends on its ATPase-coupled conformational cycle and on interaction with a variety of co-chaperone proteins. For some client proteins the co-chaperone Sti1/Hop/p60 acts as a "scaffold," recruiting Hsp70 and the bound client to Hsp90 early in the cycle and suppressing ATP turnover by Hsp90 during the loading phase. Recruitment of protein kinase clients to the Hsp90 complex appears to involve a specialized co-chaperone, Cdc37p/p50(cdc37), whose binding to Hsp90 is mutually exclusive of Sti1/Hop/p60. We now show that Cdc37p/p50(cdc37), like Sti1/Hop/p60, also suppresses ATP turnover by Hsp90 supporting the idea that client protein loading to Hsp90 requires a "relaxed" ADP-bound conformation. Like Sti1/Hop/p60, Cdc37p/p50(cdc37) binds to Hsp90 as a dimer, and the suppressed ATPase activity of Hsp90 is restored when Cdc37p/p50(cdc37) is displaced by the immunophilin co-chaperone Cpr6/Cyp40. However, unlike Sti1/Hop/p60, which can displace geldanamycin upon binding to Hsp90, Cdc37p/p50(cdc37) forms a stable complex with geldanamycin-bound Hsp90 and may be sequestered in geldanamycin-inhibited Hsp90 complexes in vivo.

Ability of single-site mutants of citrate synthase to catalyze proton transfer from the methyl group of dethiaacetyl-coenzyme A, a non-thioester substrate analog

The catalytic strategies of enzymes (such as citrate synthase) whose reactions require the abstraction of the alpha-proton of a carbon acid remain elusive. Citrate synthase readily catalyzes solvent proton exchange of the methyl protons of dethiaacetyl-coenzyme A, a sulfur-less, ketone analog of acetyl-coenzyme A, in its ternary complex with oxaloacetate. Because no further reaction occurs with this analog, it provides a uniquely simple probe of the roles of active site interactions on carbon acid proton transfer catalysis. In view of the high reactivity of the analog for proton transfer to the active site base, its failure to further condense with oxaloacetate to form a sulfur-less analog of citryl-coenzyme A was unexpected, although we offer several possible explanations. We have measured the rate constants for exchange, k(exch), at saturating concentrations of the analog for six citrate synthase mutants with single changes in active site residues. Comparisons between the values of k(exch) are straightforward in two limits. If the rate of exchange of the transferred proton with solvent protons is rapid, then k(exch) equals the forward rate constant for proton transfer, and k(exch) values for different mutants compare directly the rate constants for proton transfer. If the exchange of the transferred proton with protons in the bulk solution is the slow step and the equilibrium constant for proton transfer is unfavorable (as is likely), then k(exch) equals the product of the equilibrium constant for proton transfer and the rate constant for exchange of the transferred proton with bulk solvent. If that exchange rate with bulk solution remains constant for a series of mutant enzymes, then k(exch) values compare the equilibrium constants for proton transfer. The importance of the acetyl-CoA site residues, H274 and D375, is confirmed with D375 again implicated as the active site base. The results with the series of oxaloacetate site mutants, H320X, strongly suggest that activation of the first substrate, oxaloacetate, through carbonyl bond polarization, not just oxaloacetate binding in the active site, is required for the enzyme to efficiently catalyze proton transfer from the methyl group of the second substrate.

The binding of propionyl-CoA and carboxymethyl-CoA to Escherichia coli citrate synthase

The interaction of propionyl-CoA and acetyl-CoA with E. coli citrate synthase has been studied in order to gain insight into the structural requirements for substrate binding by this enzyme. In contrast to the enzyme from pig heart, the E. coli enzyme was unable to catalyse significant exchange of the methylene protons of propionyl-CoA while overall activity was very low with this enzyme. Carboxymethyl-CoA is a presumptive transition state analogue of acetyl-CoA using pig heart citrate synthase. The effect of carboxymethyl-CoA on both the native enzyme from E. coli and a catalytically active aspartate mutant (D362E) was investigated. Whereas the native enzyme was inhibited by carboxymethyl-CoA, the mutant enzyme (D362E) shows either no inhibition or minimal inhibition depending on the assay conditions. The binding of acetyl-CoA is not inhibited as a result of the mutation. The results with propionyl-CoA and carboxymethyl-CoA suggest that the active site of the E. coli enzyme is more restricted as compared with the enzyme from pig heart and, in the case of propionyl-CoA, this restriction prevents the formation of a catalytically productive enzyme-substrate complex.

The crystal structure of citrate synthase from the thermophilic archaeon, Thermoplasma acidophilum

BACKGROUND

The Archaea constitute a phylogenetically distinct, evolutionary domain and comprise organisms that live under environmental extremes of temperature, salinity and/or anaerobicity. Different members of the thermophilic Archaea tolerate temperatures in the range 55-110 degrees C, and the comparison of the structures of their enzymes with the structurally homogolous enzymes of mesophilic organisms (optimum growth temperature range 15-45 degrees C) may provide important information on the structural basis of protein thermostability. We have chosen citrate synthase, the first enzyme of the citric acid cycle, as a model enzyme for such studies.

RESULTS

We have determined the crystal structure of Thermoplasma acidophilum citrate synthase to 2.5 A and have compared it with the citrate synthase from pig heart, with which it shares a high degree of structural homology, but little sequence identity (20%).

CONCLUSIONS

The three-dimensional structural comparison of thermophilic and mesophilic citrate synthases has permitted catalytic and substrate-binding residues to be tentatively assigned in the archaeal, thermophilic enzyme, and has identified structural features that may be responsible for its thermostability.

Identification of two distinct Bacillus subtilis citrate synthase genes

Two distinct Bacillus subtilis genes (citA and citZ) were found to encode citrate synthase isozymes that catalyze the first step of the Krebs cycle. The citA gene was cloned by genetic complementation of an Escherichia coli citrate synthase mutant strain (W620) and was in a monocistronic transcriptional unit. A divergently transcribed gene, citR, could encode a protein with strong similarity to the bacterial LysR family of regulatory proteins. A null mutation in citA had little effect on citrate synthase enzyme activity or sporulation. The residual citrate synthase activity was purified from a citA null mutant strain, and the partial amino acid sequence for the purified protein (CitZ) was determined. The citZ gene was cloned from B. subtilis chromosomal DNA by using a PCR-generated probe synthesized with oligonucleotide primers derived from the partial amino acid sequence of purified CitZ. The citZ gene proved to be the first gene in a tricistronic cluster that also included citC (coding for isocitrate dehydrogenase) and citH (coding for malate dehydrogenase). A mutation in citZ caused a substantial loss of citrate synthase enzyme activity, glutamate auxotrophy, and a defect in sporulation.

Does Escherichia coli possess a second citrate synthase gene?

Escherichia coli possesses a hexameric citrate synthase that exhibits allosteric kinetics and regulatory sensitivity, and for which the gene (gltA) has previously been cloned and sequenced. A citrate-synthase-deficient strain of E. coli (K114) has been mutated to generate a revertant (K114r4) that produces a dimeric citrate synthase with altered kinetic and regulatory properties. On cloning and sequencing the gltA gene from both K114 and K114r4, a single mutation was found that caused the replacement of Asp362 with Asn. Asp362 has been previously shown to be a catalytically essential residue in E. coli citrate synthase, and we demonstrate that the hexameric enzyme produced on expression of the gltA gene from K114 and K114r4 is inactive. The dimeric citrate synthase from K114r4 has been purified and shown to be immunologically distinct from the wild-type hexameric enzyme. Determination of its N-terminal amino acid sequence demonstrates that the mutant citrate synthase is encoded by a gene distinct from the E. coli gltA gene. The N-terminal sequence is compared with those of other eukaryotic, eubacterial and archaebacterial citrate synthases.