Citrate synthase

For some enzymes, for example many metalloenzymes, a semiempirical QM/MM treatment is inadequate due to the limitations of the semiempirical methods. In such situations, a more sophisticated level of QM treatment (such as ab initio molecular orbital or density-functional theory) may well be required. An recent example of the application of ab initio QM/MM techniques to an enzyme mechanism is a study of acetyl-CoA enolization in citrate synthase 

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Fig. 5. Rigid-body analysis of citrate synthase, using two X-ray structures (after Hayward and Berendsen, Proteins 30 (1998) 144). The decomposition of the protein into two domains (dark gray and white) and two interconnecting regions (light gray) is shown, together with the hinge axis for the closing/opening motion between them.

Hayward, S., Berendsen, H.J.C. Systematic analysis of domain motions in proteins from conformational change New results on citrate synthase and T4 lysozyme. Proteins 30 (1998) 144-154. 

A block Lanczos algorithm (where one starts with more than one vector) has been used to calculate the first 120 normal modes of citrate synthase [4]. In this calculation no apparent use was made of symmetry, but it appears that to save memory a short cutoff of 7.5 A was used to create a sparse matrix. The results suggested some overlap between the low frequency normal modes and functional modes detennined from the two X-ray conformers. 

The final application considered in this chapter is chosen to illustrate the application of a QM-MM study of an enzyme reaction that employs an ab initio Hamiltonian in the quantum region [67]. Because of the computational intensity of such calculations there are currently very few examples in the literahire of QM-MM shidies that use a quanhim mechanical technique that is more sopliisticated than a semiempirical method. MuUiolland et al. [67] recently reported a study of part of the reaction catalyzed by citrate synthase (CS) in wliich the quanhim region is treated by Hartree-Fock and MP2 methods [10,51],... 

Citrate synthase catalyzes the metabolically important formation of citrate from ace-tyl-CoA and oxaloacetate [68]. Asp-375 (numbering for pig CS) has been shown to be the base for the rate-limiting deprotonation of acetyl-CoA (Fig. 5) [69]. An intennediate (which subsequently attacks the second substrate, oxaloacetate) is believed to be formed in this step the intermediate is thought to be stabilized by a hydrogen bond with His-274. It is uncertain from the experimental data whether this intermediate is the enolate or enol of acetyl-CoA related questions arise in several similar enzymatic reactions such as that catalyzed by triosephosphate isomerase. From the relative pK values of Asp-375... 

Figure 5 A suggested mechanism for the enolization of acetyl-CoA by the enzyme citrate synthase (CS). The keto, enolate, and enol forms of the substrate are shown.

The first sequence is from the enzyme citrate synthase, residues 260-270, which form a buried helix the second sequence is from the enzyme alcohol dehydrogenase, residues 355-365, which form a partially exposed helix and the third sequence is from troponin-C, residues 87-97, which form a completely exposed helix. Charged residues are colored red, polar residues ate blue, and hydrophobic residues are green. 

FIGURE 6.24 (a) The alpha helix consisting of residues 153-166 (red) in flavodoxin from Anahaena is a surface helix and is amphipathic. (b) The two helices (yellow and blue) in the interior of the citrate synthase dimer (residues 260-270 in each monomer) are mostly hydrophobic, (c) The exposed helix (residues 74-87—red) of calmodulin is entirely accessible to solvent and consists mainly of polar and charged residues. 

Less commonly, an a-helix can be completely buried in the protein interior or completely exposed to solvent. Citrate synthase is a dimeric protein in which a-helical segments form part of the subunit-subunit interface. As shown in Figure 6.24, one of these helices (residues 260 to 270) is highly hydrophobic and contains only two polar residues, as would befit a helix in the protein core. On the other hand. Figure 6.24 also shows the solvent-exposed helix (residues 74 to 87) of cahnodulln, which consists of 10 charged residues, 2 polar residues, and only 2 nonpolar residues. 

Entry into the Cycle The Citrate Synthase Reaction... 

FIGURE 20.5 Citrate is formed in the citrate synthase reaction from oxaloacetate and acetyl-CoA. The mechanism involves nncieophiiic attack by the carbanion of acetyl-CoA on the carbonyl carbon of oxaloacetate, followed by thioester hydrolysis. 

Citrate synthase in mammals is a dimer of 49-kD subunits (Table 20.1). On each subunit, oxaloacetate and acetyl-CoA bind to the active site, which lies in a cleft between two domains and is surrounded mainly by a-helical segments (Figure 20.6). Binding of oxaloacetate induces a conformational change that facilitates the binding of acetyl-CoA and closes the active site, so that the reactive carbanion of acetyl-CoA is protected from protonation by water. 

Citrate synthase is the first step in this metabolic pathway, and as stated the reaction has a large negative AG°. As might be expected, it is a highly regulated enzyme. NADH, a product of the TCA cycle, is an allosteric inhibitor of citrate synthase, as is succinyl-CoA, the product of the fifth step in the cycle (and an acetyl-CoA analog). 

FIGURE 20.6 Citrate synthase. In the monomer shown here, citrate is shown in green, and CoA is pink. 

AceCyl-CoA + oxaloacetate + HgO. CoASH + citrate 2. Citrate. isocitrate 3. Isocitrate + NAD. a-ketoglntarate + NADH + CO, + 4. a-Ketoglntarate + CoASH + NAD. snccinyl-CoA + NADH + CO, + H Citrate synthase Aconitase Isocitrate dehydrogenase u-Ketoglutarate dehydrogenase complex... 

Ketone body synthesis occurs only in the mitochondrial matrix. The reactions responsible for the formation of ketone bodies are shown in Figure 24.28. The first reaction—the condensation of two molecules of acetyl-CoA to form acetoacetyl-CoA—is catalyzed by thiolase, which is also known as acetoacetyl-CoA thiolase or acetyl-CoA acetyltransferase. This is the same enzyme that carries out the thiolase reaction in /3-oxidation, but here it runs in reverse. The second reaction adds another molecule of acetyl-CoA to give (i-hydroxy-(i-methyl-glutaryl-CoA, commonly abbreviated HMG-CoA. These two mitochondrial matrix reactions are analogous to the first two steps in cholesterol biosynthesis, a cytosolic process, as we shall see in Chapter 25. HMG-CoA is converted to acetoacetate and acetyl-CoA by the action of HMG-CoA lyase in a mixed aldol-Claisen ester cleavage reaction. This reaction is mechanistically similar to the reverse of the citrate synthase reaction in the TCA cycle. A membrane-bound enzyme, /3-hydroxybutyrate dehydrogenase, then can reduce acetoacetate to /3-hydroxybutyrate. 

Enzymes work by bringing reactant molecules together, holding them, in the orientation necessary for reaction, and providing any necessary acidic or basic sites to catalyze specific steps. As an example, let s look at citrate synthase, an enzyme that catalyzes the aldol-like addition of acetyl CoA to oxaloacetate to give citrate. The reaction is the first step in the citric acid cycle, in which acetyl groups produced by degradation of food molecules are metabolized to yield C02 and H20. We ll look at the details of the citric acid cycle in Section 29.7. 

Figure 26.9 X-ray crystal structure of citrate synthase. Part (a) is a space-filling model and part (b) is a ribbon model, which emphasizes the a-helical segments of the protein chain and indicates that the enzyme is dimeric that is, it consists of two identical chains held together by hydrogen bonds and other intermolecular attractions. Part (cl is a close-up of the active site in which oxaloacetate and an unreactive acetyl CoA mimic are bound.

Figure 26.10 MECHANISM Mechanism of the addition of acetyl CoA to oxaloacetate to give (S)-citryl CoA, catalyzed by citrate synthase.

To learn how to use the PDB, begin by running the short tutorial listed near the top of the blue sidebar on the left of the screen. After that introduction, start exploring. Let s say you want to view citrate synthase, the enzyme shown previously in Figure 26.9 that catalyzes the addition of acetyl CoA to oxaloacetate to give citrate. Type "citrate synthase" into the small... 

Figure 26.12 An image of citrate synthase, downloaded from the Protein Data Bank.

Step 1 of Figure 29.12 Addition to Oxaloacetate Acetyl CoA enters the citric acid cycle in step 1 by nucleophilic addition to the oxaloacetate carbonyl group, to give (S)-citryl CoA. The addition is an aldol reaction and is catalyzed by citrate synthase, as discussed in Section 26.11. (S)-Citryl CoA is then hydrolyzed to citrate by a typical nucleophilic acyl substitution reaction, catalyzed by the same citrate synthase enzyme. 

Acifluorfen, synthesis of, 683 Acrolein, structure of, 697 Acrylic acid, pKa of, 756 structure of. 753 Activating group (aromatic substitution), 561 acidity and, 760 explanation of, 564-565 Activation energy, 158 magnitude of, 159 reaction rate and, 158-159 Active site (enzyme), 162-163 citrate synthase and, 1046 hexokinase and, 163... 

Citrate, prochirality of, 1156 Citrate synthase, active site of, 1046 function of, 1045 mechanism of action of, 1043, 1047... 

How Do Enzymes Work Citrate Synthase 1043 Focus On... The Protein Data Bank 1048... 

Enzymes a) citrate synthase b) aconitase c) isocitrate dehydrogenase d) a-oxoglutarate dehydrogenase e) succiny CoA synthetase f) succinate dehydrogenase g) fumarase h) malate dehydrogenase i) nucleoside diphosphokinase. 

Figure 5.3 Major control points of glycolysis and the TCA cycle. Enzymes I, hexokinase II, phosphofructokinase III, pyruvate kinase IV, pyruvate dehydrogenase V, citrate synthase VI, aconitase VII, isocitrate dehydrogenase VIII, a-oxoglutarate dehydrogenase.

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