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Biological Research

versión impresa ISSN 0716-9760

Biol. Res. v.43 n.2 Santiago  2010 

Biol Res 43: 191-195, 2010


The Role of Tyrosine 207 in the Reaction Catalyzed by Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase


Cherie Andrade, Carolina Sepulveda, Emilio Cardemil, Ana M. Jabalquinto.

Facultad de Química y Biología, Universidad de Santiago de Chile, Casilla 40, Santiago 33, Chile.

Dirección para Correspondencia


The functional signifcance of tyrosine 207 of Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase was explored by examining the kinetic properties of the Tyr207Leu mutant. The variant enzyme retained the structural characteristics of the wild-type protein as indicated by circular dichroism, intrinsic fuorescence spectroscopy, and gel-exclusion chromatography. Kinetic analyses of the mutated variant showed a 15-fold increase in Km CO2, a 32fold decrease in Vmax, and a 6-fold decrease in Km for phosphoenolpyruvate. These results suggest that the hydroxyl group of Tyr 207 may polarize CO2 and oxaloacetate, thus facilitating the carboxylation/decarboxylation steps.

Key terms: Phosphoenolpyruvate carboxykinase, Saccharomyces cerevisiae, CO2 interaction.



Enzymes have evolved different strategies to catalyze carboxylation and decarboxylation reactions, some enzymes use organic or inorganic cofactors, and others are cofactor independent (Liu & Zhang, 2005). Phosphoenolpyruvate (PEP) carboxykinases (GTP/ATP, oxaloacetate carboxy-lyase (transphosphorylating), EC catalyze the reversible GTP/ATP-dependent decarboxylation of oxaloacetate (OAA) to yield PEP, CO2 and the corresponding GDP/ADP. They have an absolute requirement for divalent cations for activity. One cation, preferentially a transition metal like Mn2+, interacts with the enzyme at metal binding site 1 to elicit activation, while the second cation (Mg2+ or Mn2+), at metal binding site 2, interacts with the nucleotide to serve as the metal-nucleotide substrate (Matte et al., 1997). Two classes of PEP carboxykinases exist in nature: ATP-dependent enzymes, which are found in plants, yeast, trypanosomatids, and some bacteria (Matte et al., 1997), and GTP-dependent PEP carboxykinases found in animals and some bacteria (Hanson & Patel, 1994; Fukuda et al., 2004). There is no signifcant overall sequence identity between the two groups of enzymes; however, active site residues are strictly conserved.

Kinetic experiments suggested that PEP carboxykinases have a binding site for CO2 (Arnelle & O'Leary, 1992; Cheng & Nowak 1989).

This proposal was confirmed by the structure of the Escherichia coli enzyme complexed with CO2-ATP-Mg2+-Mn2+, which indicates that CO2 is hydrogen bonded to Arg65 and Tyr207 (Cotelesage et al., 2007). A proposed reaction mechanism for PEP production indicates the formation of a hydrogen bond between the C4 carboxylate group of oxaloacetate and the hydroxyl group of Tyr207. Thus Tyr207 would polarize CO2 and oxaloacetate, facilitating catalysis (Cotelesage, 2007). Structural (Dunten et al., 2002) and kinetic studies (Dharmarajan et al., 2008) indicate that the equivalent Tyr 235 of human cytosolic PEP carboxykinase establishes an anion-quadrupole interaction with PEP carboxylate. A similar role has been proposed for Tyr 254 from the Mn2+-PEP complex of mitochondrial PEP carboxykinase (Holyoak & Sullivan, 2006).

In this work, we use site directed mutagenesis to evaluate the contribution of Tyr 207 to substrate affnity and catalysis of Saccharomyces cerevisiae PEP carboxykinase.


The ATP was obtained from Sigma Chemical Company, Saint Louis, USA and the OAA from Boehringer. Germany. All other reagents and auxiliary enzymes were of the highest purity commercially available, and their origin has been described before (Krautwurst et al., 2002).

Mutagenesis and expression of recombinant wild-type and mutant enzymes

A specifc substitution was introduced at Tyr207 triplet to code for Leu (TAC to TTA) in the cloned S. cerevisiae PEP carboxykinase gene (pMV7 plasmid) by Retrogen, USA. To check the mutated site and verify that no additional mutations had been introduced, the altered gene in the recombinant plasmid was completely sequenced by the manufacturer. The mutant plasmid was transformed into the PEP carboxykinase-defcient yeast strain PUK-3B (MATa pck ura3) and the mutant PEP carboxykinase was purified as previously described (Llanos et al., 2001).

Enzyme kinetics

Enzyme activity was measured at 30 ºC in 1 mL fnal volume. The standard assay mixture in the OAA formation direction contained 100 mM MOPS buffer (pH 6.6), 0.20 mM NADH, 50 mM KHCO3, 15 mM PEP, 1.25 mM ADP, 5.0 mM MgCl2, 0.1 mM MnCl2 and 4 units malate dehydrogenase. The standard assay mixture in the PEP forming direction contained 100 mM MOPS buffer (pH 7.0), 0.20 mM NADH, 50 mM KCl, 5.0 mM MgCl2, 0.1 mM MnCl2, 1 mM ATP, 0.5 mM of OAA, and 5 units of both lactate dehydrogenase and pyruvate kinase. Activities were corrected for nonenzymatic OAA decarboxylation. Maximal velocity and apparent Km were determined by fitting initial velocities to the Michaelis-Menten equation with the Microcal OriginTM program. Ka for Mn2+ was measured as a function of free Mn2+, while keeping the concentration of components at fxed standard saturating levels.

The concentrations of free Mn2+, MnADP-, MgADP- and other species were calculated using the program COMPLEX version 6 (1986) written by Dr. Athel Cornish-Bowden. The dissociation constants were obtained from Martel and Smith (1998).

Circular dichroism and fuorescence spectroscopy

CD spectra (recorded from 200 nm to 260 nm) and fuorescence emission (lexcit 295 nm) were carried out as previously described (Castillo et al., 2009).

Electron Paramagnetic Resonance Spectroscopy

Mn2+ binding was measured by EPR spectroscopy on a Bruker EMX X-band EPR spectrometer at a frequency of 9.5 GHz. The enzyme used for the EPR experiments was frst incubated for 10 min at 2 °C in 50 mM MOPS buffer (pH 7.0) with 1.25 mM ADP, 2 mM PEP, and 2 mM MnCl2. The enzyme solution was then passed through a Bio-Gel P-6 (1.5 × 25 cm) column with a 2-cm layer of Chelex-100 on top. Without this preincubation, a tight binding, contaminating cation is not totally removed to form apoenzyme. Enzyme solutions (40 and 113 µM of enzyme subunits for wild-type, and Tyr207Leu PEP carboxykinases, respectively) were prepared in 50 mM KCl and 100 mM MOPS buffer (pH 7.0). The total Mn2+ concentration varied from 0 to 250 µM. Each sample was prepared in a 100 µL volume and [Mn2+] free was measured. The dissociation equilibrium constants (KD) were calculated by curve ftting to equation 1.

where n is the number of moles of Mn2+ bound per mole of enzyme monomer.


To better understand the importance of the invariant Tyr207 of S. cerevisiae PEP carboxykinase, this residue was changed to leucine, so as to entirely eliminate the ability to form an anion-quadrupole interaction, or an H- bond.

Cell growth, gene expression, enzyme purification, and structural characteristics of the Tyr207Leu mutant enzyme

The Tyr207Leu PEP carboxykinase plasmid was sequenced to confirm the absence of any spurious mutations in the coding region outside the area of the mutation. Expression of the mutated PEP carboxykinase was achieved in the PEP carboxykinase-defcient S. cerevisiae strain, PUK-3B, containing the pMV7 plasmid. The cells containing the Tyr207Leu mutation were unable to grow on medium containing ethanol as the primary carbon source, indicating lack of in vivo functional activity of the altered PEP carboxykinase. These cells were grown on glucose medium instead, and the medium was changed to ethanol to achieve the induction of the PEP carboxykinase gene. Eight liters of glucose medium yielded 50-60 g of cells. The enzyme was purifed using the procedure previously reported (Krautwurst et al., 1998). The fnal yield of mutated PEP carboxykinase was 6-8 mg from about 60 g of cells. The enzyme was judged to be at least 95% pure as determined by SDS-PAGE.

The apparent mass of the variant enzyme was the same as that of the wild-type enzyme, as determined in a calibrated (R = 0.95) Superose-12 column (results not shown). The calculated molecular mass of wild type PEP carboxykinase in this column was 251 kDa, and the molecular mass of the variant enzyme was within 10% of this value.

These results agree with the expected molecular mass of 244 kDa for the wild-type enzyme tetramer (Krautwurst et al., 1995), and are in the range of those determined by other authors for this same protein (Muller et al., 1981; Jacob et al., 1992). Circular dichroism spectra were measured for the mutant and wild-type enzymes to examine whether mutation at position 207 induced changes in the secondary structure of the protein. The CD spectrum of the variant enzyme was very similar to that of the wild-type enzyme, with a minimum at 208 nm and a shoulder at 222 nm (not shown). Alterations in the tertiary structure were analyzed through the intrinsic fuorescence spectra of the enzymes that have a total of 8 Trp residues at positions 88, 89, 101, 127, 171, 275, 446, and 508 (Krautwurst et al., 1995). No alteration in the λmax of emission (328 nm) was detected. The Tyr207Leu mutant enzyme showed a 15% increase in fuorescence intensity, suggesting that this mutation changes the microenvironment of some Trp residues. Changes in fuorescence emission of proteins can occur from even small movements of neighboring amino acid residues.

Steady-state kinetics studies on wild-type andTyr207Leu PEP carboxykinases

A summary of the resulting steady-state parameters for the PEP carboxylation reaction is listed in Table I. Vmax decreased by 32-fold for the Tyr207Leu PEP carboxykinase compared to wild-type enzyme. The Km value for CO2 and Mn2+ were increased 15-fold and fvefold compared to values measured for the wild-type enzyme. There was a 6-fold decrease in Km for PEP in the mutant enzyme, and the Km value for MgADP- was not signifcantly altered. In the variant enzyme, the absence of the hydroxyl group abolished the proposed hydrogen bond between CO2 and Tyr207, thus increasing the Km for CO2.

The kinetic parameters in the OAA decarboxylation direction (Table II) showed that mutation causes a 6-fold decrease in Vmax, a 2.8- fold increase in the Km value for MnATP2-, and a 3.5-fold increase in Km for OAA, suggesting that Tyr207 might be involved in OAA binding.

The relatively minor decrease in Vmax seen in both directions of the reaction indicates that Tyr 207 is not a catalytically essential residue for the yeast PEP carboxykinase.

A recent kinetic analysis of site-directed mutants of Tyr235 in human GTP-dependent PEP carboxykinase (Dharmarajan et al., 2008), showed some similarities and some differences with our data. Thus, as compared to the wild-enzymes, both the yeast and the human variant enzymes did not change the Km for the nucleotide, increase the Km for Mn2+, and did not greatly affect Vmax. On the other hand, the Tyr235Ala and Tyr235Ser enzymes showed a 4- to 6-fold increase in Km for PEP, thus confirming an edge-on interaction between the aromatic ring of Tyr235 and PEP carboxylate. In our studies, replacement of Tyr207 decreases the Km for PEP, which is not consistent with such an interaction between Tyr 207 and this substrate. The Tyr207Leu change abolished the H-bond that existed between Tyr and CO2 and in turn increased the Km for CO2. The replacement of Tyr235 in the human enzyme causes a 3-fold decrease in Km for CO2, suggesting no role in CO2 binding.

The kinetic results here reported and the previous studies of Dharmarajan et al. (2008) support the different roles for the invariant active site Tyr in ATP-dependent and GTP-dependent PEP carboxykinases implied from structural studies (Dunten et al., 2002; Holyoak & Sullivan., 2006; Cotelesage et al., 2007). It is worth noting that active site differences in ATP- and GTP-dependent PEP carboxykinases have been inferred before. For example, the OAA decarboxylase activity of some GTP-dependent enzymes require the presence of the nucleoside diphosphate (Sullivan and Holyoak, 2007), meanwhile the ATP-dependent enzymes from S. cerevisiae and Anaerobiospirillum succiniciproducens (Jabalquinto et al., 1999) do not.

Mn2+ Binding

To evaluate the effect of mutation in the thermodynamic interaction of Mn2+ with the enzyme, the binding of Mn2+ to wild-type and Tyr207Leu enzymes was measured by EPR spectroscopy. Binding isotherms are shown in Figure 1. Quantitative estimates of binding parameters were obtained from curve ftting to equation 1. KD values of 35 ± 3 and 157 ± 54 µM were obtained for wild-type and Tyr207Leu PEP carboxykinases, respectively. In both cases one binding site for Mn2+ per enzyme monomer was obtained. The 0.9 kcal/ mol loss in Mn2+ binding affnity of S. cerevisiae PEP carboxykinase upon mutation Tyr207Leu correlate well with the increase in Km value shown in Table 1, and also with the effect of mutation of Tyr235 of human cytosolic enzyme in Km for Mn2+ (Dharmarajan et al., 2008). For the human enzyme it was proposed that mutation of Tyr235Phe, which lowers Km for PEP, might cause a detrimental effect for the inner sphere coordination of PEP to Mn2+, thus increasing Km for Mn2+. A similar situation might also occur upon mutation Tyr207Leu in the S. cerevisiae PEP carboxykinase. It is also possible that this mutation, which introduces a non-polar residue, might perturb the general water structure of the active site, thus affecting Mn2+ binding.

In conclusion, we show that the main effect of mutation Tyr207Leu in S. cerevisiae PEP carboxykinase is to substantially alter the enzyme kinetic affinity for CO2. This suggests that the hydroxyl group of Tyr 207 is involved in CO2 binding, as also inferred from the structure of the E. coli enzyme complexed with CO2-ATP-Mg2+-Mn2+, where the hydroxyl group of Tyr 207 is at H bond distance to CO2 (Cotelesage et al., 2007). The decrease in Vmax upon mutation, although of a small magnitude, is in line with the suggestion that the hydroxyl group at position 207 may polarize CO2 and OAA, thus facilitating the carboxylation/ decarboxylation steps (Cotelesage, 2007; Cotelesage et al., 2007).


Carolina Sepúlveda is the recipient of a graduate scholarship from CONICYT-Chile. We thank Dr. Carolina Aliaga for helping with the EPR experiments.‘CD experiments were carried out at the Biophysics Instrumentation Facility of the University of Wisconsin-Madison, which was established by funding from NSF (BIR-9512577), NIH (S10RR3790), and the University of Wisconsin. This work was supported by research grants FONDECYT 1070202 and DICYT-USACH 02-0741JL.


ARNELLE DR, O'Leary MH (1992) Binding of carbon dioxide to phosphoenolpyruvate carboxykinase deduced from carbon kinetic isotope effects. Biochemistry 31: 4363-4368.        [ Links ]

CASTILLO D, SEPULVEDA C, CARDEMIL E, JABALQUINTO AM, (2009) Functional evaluation of serine 252 of Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase. Biochimie 91: 295-299.        [ Links ]

CHENG KC, NOWAK T (1989) Arginine residues at the active site of avian liver phosphoenolpyruvate carboxykinase. J Biol Chem 264: 3317-3324.        [ Links ]

COTELESAGE JJH (2007) Structural and functional studies of phosphoenolpyruvate carboxykinase. Ph. D. Thesis, University of Saskatchewan.        [ Links ]

COTELESAGE JJH, PUTTICK J, GOLDIE H, RAJABI B, NOVAKOVSKI B, DELBAERE LTJ (2007) How does an enzyme recognize CO2?. Int J Biochem Cell Biol 39: 1204-1210.        [ Links ]

DHARMARAJAN L, CASE CL, DUNTEN P , MUKHOPADHYAY B (2008) Tyr235 of human cytosolic phosphoenolpyruvate carboxykinase influences catalysis through an anion-quadrupole interaction with phosphoenolpyruvate carboxylate. FEBS J 275: 5810-5819.        [ Links ]

DUNTEN P, BELUNIS C, CROWTHER R, HOLLFELDER K, KAMMLOTT U, LEVIN W, MICHEL H, RAMSEY GB, SWAIN A, WEBER D, WERTHEIMER SJ (2002) Crystal structure of human cytosolic phosphoenolpyruvate carboxykinase reveals a new GTP-binding site. J Mol Biol 316: 257- 264.        [ Links ]

FUKUDA W, FUKUI T, ATOMI H, IMANAKA T (2004) First characterization of an Archaeal GTP-dependent phosphoenolpyruvate carboxykinase from the hyperthermophilic Archaeon Thermococcus kodakaraensis KOD1. J Bact 186: 4620-4627.        [ Links ]

HANSON R, PATEL Y (1994) Phosphoenolpyruvate carboxykinase (GTP): the gene and the enzyme. Adv Enzymol Relat Areas Mol Biol 69: 203-281.        [ Links ]

HOLYOAK T, SULLIVAN SM, NOWAK T (2006) Structural insights into the mechanism of PEPCK catalysis. Biochemistry 45: 8254-8263.        [ Links ]

JABALQUINTO AM, LAIVENIEKS M, ZEIKUS JG, CARDEMIL E (1999) Chraracterization of the oxaloacetate decarboxylase and pyruvate kinase-like activities of Saccharomyces cerevisiae and Anaerobiospirillum succiniciproducens phosphoenolpyruvate carboxykinases. J Prot Chem 18: 659-664        [ Links ]

JACOB LR, VOLLERT H, ROSE M, ENTIAN KD, BARTUNIK LJ, BARTUNIK H (1992) Fast high-performance liquid chromatographic purifcation of Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase, J. Chromatogr 625: 47-54.        [ Links ]

KRAUTWURST H, ENCINAS MV, MARCUS F, LATSHAW SP, KEMP RG, FREY PA, CARDEMIL E (1995) Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase: revised amino acid sequence, site-directed mutagenesis, and microenvironment characteristics of cysteines 365 and 458. Biochemistry 34: 6382-6388.        [ Links ]

KRAUTWURST H, BAZAES S, GONZÁLEZ FD, JABALQUINTO AM, FREY PA, CARDEMIL E (1998) The strongly conserved lysine 256 of Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase is essential for phosphoryl transfer. Biochemistry 37: 6295-6302.        [ Links ]

KRAUTWURST H, ROSCHZTTARDTZ H, BAZAES S, GONZÁLEZ-NILO FD, NOWAK T, CARDEMIL E (2002) Lysine 213 and histidine 233 participate in Mn(II) binding and catalysis in Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase, Biochemistry 41: 12763-12770.        [ Links ]

LIU A, ZHANG H (2006) Transition metal-catalyzed nonoxidative decarboxylation reactions. Biochemistry 45: 10407-10411.        [ Links ]

LLANOS L, BRIONES R, YÉVENES A, GONZÁLEZ-NILO FD, FREY PA, CARDEMIL E (2001) Mutation Arg336 to Lys in Saccharomyces cerevisiae phosphoenolpyruvate carboxykinase originates an enzyme with increased oxaloacetate decarboxylase activity FEBS Letters 493: 1-5.        [ Links ]

MARTEL AE, SMITH RM ( 1998) NIST Critically Selected Stability Constants of Metal Complexes. NIST Standard References Database 46 version 5.0.        [ Links ]

MATTE A, TARI LW, GOLDIE H, DELBAERE LTJ (1997) Structure and mechanism of phosphoenolpyruvate carboxykinase J Biol Chem 272: 8105-8108.        [ Links ]

MULLER M, MULLER H, HOLZER H (1981) Immunochemical studies on catabolite inactivation of phosphoenolpyruvate carboxykinase in Saccharomyces cerevisiae J Biol Chem 256: 723-727.        [ Links ]

SULLIVAN SM, HOLYOAK T (2007) Structures of rat cytosolic PEPCK: insight into the mechanism of phosphorylation and decarboxylation of oxaloacetic acid. Biochemistry 46: 10078-10088.        [ Links ]

Corresponding author: Ana M. Jabalquinto, Facultad de Química y Biología, Universidad de Santiago de Chile, Casilla 40, Santiago 33, Chile. e-mail: Telephone +56(2)718-1144; Fax +56(2)681-2108;

Received: August 17, 2009. In revised form: January 1, 2010. Accepted: March 30, 2010.

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