The "open" and "closed" structures of the type-C inorganic pyrophosphatases from Bacillus subtilis and Streptococcus gordonii.

Recently, a new class of soluble inorganic pyrophosphatase (type-C PPase) has been described that is not homologous in amino acid sequence or kinetic properties to the well-studied PPases (types A and B) found in many organisms from bacteria to humans and thought to be essential to the cell. Structural studies of the type-C PPases from Streptococcus gordonii and Bacillus subtilis reveal a homodimeric structure, with each polypeptide folding into two domains joined by a flexible hinge. The active site, formed at the interface between the N and C-terminal domains, binds two manganese ions approximately 3.6 A apart in a conformation resembling binuclear metal centres found in other hydrolytic enzymes. An activated water molecule bridging the two metal ions is likely poised for nucleophilic attack of the substrate. Importantly, the S. gordonii and B. subtilis enzymes have crystallised in strikingly different conformations. In both subunits of the S. gordonii crystal structure (1.5 A resolution) the C-terminal domain is positioned such that the active site is occluded, with a sulphate ion bound in the active site. In contrast, in the B. subtilis structure (3.0 A resolution) the C-terminal domain is rotated by about 90 degrees, leaving the active site wide open and accessible for substrate binding.     

Structure of the bacteriophage lambda Ser/Thr protein phosphatase with sulfate ion bound in two coordination modes

The protein phosphatase encoded by bacteriophage lambda (lambda PP) belongs to a family of Ser/Thr phosphatases (Ser/Thr PPases) that includes the eukaryotic protein phosphatases 1 (PP1), 2A (PP2A), and 2B (calcineurin). These Ser/Thr PPases and the related purple acid phosphatases (PAPs) contain a conserved phosphoesterase sequence motif that binds a dinuclear metal center. The mechanisms of phosphoester hydrolysis by these enzymes are beginning to be unraveled. To utilize lambda PP more effectively as a model for probing the catalytic mechanism of the Ser/Thr PPases, we have determined its crystal structure to 2.15 A resolution. The overall fold resembles that of PP1 and calcineurin, including a conserved beta alpha beta alpha beta structure that comprises the phosphoesterase motif. Substrates and inhibitors probably bind in a narrow surface groove that houses the active site dinuclear Mn(II) center. The arrangement of metal ligands is similar to that in PP1, calcineurin, and PAP, and a bound sulfate ion is present in two novel coordination modes. In two of the three molecules in the crystallographic asymmetric unit, sulfate is coordinated to Mn2 in a monodentate, terminal fashion, and the two Mn(II) ions are bridged by a solvent molecule. Two additional solvent molecules are coordinated to Mn1. In the third molecule, the sulfate ion is triply coordinated to the metal center with one oxygen coordinated to both Mn(II) ions, one oxygen coordinated to Mn1, and one oxygen coordinated to Mn2. The sulfate in this coordination mode displaces the bridging ligand and one of the terminal solvent ligands. In both sulfate coordination modes, the sulfate ion is stabilized by hydrogen bonding interactions with conserved arginine residues, Arg 53 and Arg 162. The two different active site structures provide models for intermediates in phosphoester hydrolysis and suggest specific mechanistic roles for conserved residues.     

Crystal structure of Streptococcus mutans pyrophosphatase: a new fold for an old mechanism

BACKGROUND: Streptococcus mutans pyrophosphatase (Sm-PPase) is a member of a relatively uncommon but widely dispersed sequence family (family II) of inorganic pyrophosphatases. A structure will answer two main questions: is it structurally similar to the family I PPases, and is the mechanism similar? RESULTS: The first family II PPase structure, that of homodimeric Sm-PPase complexed with metal and sulfate ions, has been solved by X-ray crystallography at 2.2 A resolution. The tertiary fold of Sm-PPase consists of a 189 residue alpha/beta N-terminal domain and a 114 residue mixed beta sheet C-terminal domain and bears no resemblance to family I PPase, even though the arrangement of active site ligands and the residues that bind them shows significant similarity. The preference for Mn2+ over Mg2+ in family II PPases is explained by the histidine ligands and bidentate carboxylate coordination. The active site is located at the domain interface. The C-terminal domain is hinged to the N-terminal domain and exists in both closed and open conformations. CONCLUSIONS: The active site similiarities, including a water coordinated to two metal ions, suggest that the family II PPase mechanism is "analogous" (not "homologous") to that of family I PPases. This is a remarkable example of convergent evolution. The large change in C-terminal conformation suggests that domain closure might be the mechanism by which Sm-PPase achieves specificity for pyrophosphate over other polyphosphates.     

Crystal structure of inorganic pyrophosphatase from Thermus thermophilus.

The 3-dimensional structure of inorganic pyrophosphatase from Thermus thermophilus (T-PPase) has been determined by X-ray diffraction at 2.0 A resolution and refined to R = 15.3%. The structure consists of an antiparallel closed beta-sheet and 2 alpha-helices and resembles that of the yeast enzyme in spite of the large difference in size (174 and 286 residues, respectively), little sequence similarity beyond the active center (about 20%), and different oligomeric organization (hexameric and dimeric, respectively). The similarity of the polypeptide folding in the 2 PPases provides a very strong argument in favor of an evolutionary relationship between the yeast and bacterial enzymes. The same Greek-key topology of the 5-stranded beta-barrel was found in the OB-fold proteins, the bacteriophage gene-5 DNA-binding protein, toxic-shock syndrome toxin-1, and the major cold-shock protein of Bacillus subtilis. Moreover, all known nucleotide-binding sites in these proteins are located on the same side of the beta-barrel as the active center in T-PPase. Analysis of the active center of T-PPase revealed 17 residues of potential functional importance, 16 of which are strictly conserved in all sequences of soluble PPases. Their possible role in the catalytic mechanism is discussed on the basis of the present crystal structure and with respect to site-directed mutagenesis studies on the Escherichia coli enzyme. The observed oligomeric organization of T-PPase allows us to suggest a possible mechanism for the allosteric regulation of hexameric PPases.     

Ligand binding sites in Escherichia coli inorganic pyrophosphatase: effects of active site mutations

Type I soluble inorganic pyrophosphatases (PPases) are well characterized both structurally and mechanistically. Earlier we measured the effects of active site substitutions on pH--rate profiles for the type I PPases from both Escherichia coli (E-PPase) and Saccharomyces cerevisae (Y-PPase). Here we extend these studies by measuring the effects of such substitutions on the more discrete steps of ligand binding to E-PPase, including (a) Mg(2+) and Mn(2+) binding in the absence of added ligand; (b) Mg(2+) binding in the presence of either P(i) or hydroxymethylbisphosphonate (HMBP), a competitive inhibitor of E-PPase; and (c) P(i) binding in the presence of Mn(2+). The active site of a type I PPase has well-defined subsites for the binding of four divalent metal ions (M1--M4) and two phosphates (P1, P2). Our results, considered in light of pertinent results from crystallographic studies on both E-PPase and Y-PPase and parallel functional studies on Y-PPase, allow us to conclude the following: (a) residues E20, D65, D70, and K142 play key roles in the functional organization of the active site; (b) the major structural differences between the product and substrate complexes of E-PPase are concentrated in the lower half of the active site; (c) the M1 subsite is functionally isolated from the rest of the active site; and (d) the M4 subsite is an especially unconstrained part of the active site.     

An unusual, His-dependent family I pyrophosphatase from Mycobacterium tuberculosis

Soluble inorganic pyrophosphatases (PPases) comprise two evolutionarily unrelated families (I and II). These two families have different specificities for metal cofactors, which is thought to be because of the fact that family II PPases have three active site histidines, whereas family I PPases have none. Here, we report the structural and functional characterization of a unique family I PPase from Mycobacterium tuberculosis (mtPPase) that has two His residues (His21 and His86) in the active site. The 1.3-A three-dimensional structure of mtPPase shows that His86 directly interacts with bound sulfate, which mimics the product phosphate. Otherwise, mtPPase is structurally very similar to the well studied family I hexameric PPase from Escherichia coli, although mtPPase lacks the intersubunit metal binding site found in E. coli PPase. The cofactor specificity of mtPPase resembles that of E. coli PPase in that it has high activity in the presence of Mg2+, but it differs from the E. coli enzyme and family II PPases because it has much lower activity in the presence of Mn2+ or Zn2+. Replacements of His21 and His86 in mtPPase with the residues found in the corresponding positions of E. coli PPase had either no effect on the Mg2+- and Mn2+-supported reactions (H86K) or reduced Mg2+-supported activity (H21K). However, both replacements markedly increased the Zn2+-supported activity of mtPPase (up to 11-fold). In the double mutant, Zn2+ was a 2.5-fold better cofactor than Mg2+. These results show that the His residues in mtPPase are not essential for catalysis, although they determine cofactor specificity.     

Rates of elementary catalytic steps for different metal forms of the family II pyrophosphatase from Streptococcus gordonii

Soluble inorganic pyrophosphatases (PPases) form two nonhomologous families, denoted I and II, that have similar active-site structures but different catalytic activities and metal cofactor specificities. Family II PPases, which are often found in pathogenic bacteria, are more active than family I PPases, and their best cofactor is Mn(2+) rather than Mg(2+), the preferred cofactor of family I PPases. Here, we present results of a detailed kinetic analysis of a family II PPase from Streptococcus gordonii (sgPPase), which was undertaken to elucidate the factors underlying the different properties of family I and II PPases. We measured rates of PP(i) hydrolysis, PP(i) synthesis, and P(i)/water oxygen exchange catalyzed by sgPPase with Mn(2+), Mg(2+), or Co(2+) in the high-affinity metal-binding site and Mg(2+) in the other sites, as well as the binding affinities for several active-site ligands (metal cofactors, fluoride, and P(i)). On the basis of these data, we deduced a minimal four-step kinetic scheme and evaluated microscopic rate constants for all eight relevant reaction steps. Comparison of these results with those obtained previously for the well-known family I PPase from Saccharomyces cerevisiae (Y-PPase) led to the following conclusions: (a) catalysis by sgPPase does not involve the enzyme-PP(i) complex isomerization known to occur in family I PPases; (b) the values of k(cat) for the magnesium forms of sgPPase and Y-PPase are similar because of similar rates of bound PP(i) hydrolysis and product release; (c) the marked acceleration of sgPPase catalysis in the presence of Mn(2+) and Co(2+) results from a combined effect of these ions on bound PP(i) hydrolysis and P(i) release; (d) sgPPase exhibits lower affinity for both PP(i) and P(i); and (e) sgPPase and Y-PPase exhibit similar values of k(cat)/K(m), which characterizes the PPase efficiency in vivo (i.e., at nonsaturating PP(i) concentrations).     

Bacillus subtilis inorganic pyrophosphatase: the C-terminal signature sequence is essential for enzyme activity and conformational integrity.

Bacillus subtilis inorganic pyrophosphatase is the first member of a newly identified Family II of PPases. To examine the role of a signature sequence found near the C-terminus, two truncated variants and a series of site-specific mutants were produced. A truncation of 17 residues (17AATR) but also single alanine substitutions, R295A and K296A, produced inactive enzyme. Removal of 5 nonconserved terminal residues (5AATR) markedly affected enzyme stability. Replacing S294 with A, T, C, or V decreased activity, the latter two mutations showing the greatest effect. Substitutions V299I and V300I had no or minor effects, whereas V300W and V299G/V300W significantly reduced activity. The sizes of truncated proteins and the full-length PPase were indistinguishable by gel-filtration. We conclude that the C-terminus has no role in multimerization, while both its conserved and nonconserved regions are essential for full enzyme activity. The signature sequence is required for both the conformation and composition of the active site.     

Structural studies of metal ions in family II pyrophosphatases: the requirement for a Janus ion

Family II inorganic pyrophosphatases (PPases) constitute a new evolutionary group of PPases, with a different fold and mechanism than the common family I enzyme; they are related to the "DHH" family of phosphoesterases. Biochemical studies have shown that Mn(2+) and Co(2+) preferentially activate family II PPases; Mg(2+) partially activates; and Zn(2+) can either activate or inhibit (Zyryanov et al., Biochemistry, 43, 14395-14402, accompanying paper in this issue). The three solved family II PPase structures did not explain the differences between the PPase families nor the metal ion differences described above. We therefore solved three new family II PPase structures: Bacillus subtilis PPase (Bs-PPase) dimer core bound to Mn(2+) at 1.3 A resolution, and, at 2.05 A resolution, metal-free Bs-PPase and Streptococcus gordonii (Sg-PPase) containing sulfate and Zn(2+). Comparison of the new and old structures of various family II PPases demonstrates why the family II enzyme prefers Mn(2+) or Co(2+), as an activator rather than Mg(2+). Both M1 and M2 undergo significant changes upon substrate binding, changing from five-coordinate to octahedral geometry. Mn(2+) and Co(2+), which readily adopt different coordination states and geometries, are thus favored. Combining our structures with biochemical data, we identified M2 as the high-affinity metal site. Zn(2+) activates in the M1 site, where octahedral geometry is not essential for catalysis, but inhibits in the M2 site, because it is unable to assume octahedral geometry but remains trigonal bipyramidal. Finally, we propose that Lys205-Gln81-Gln80 form a hydrophilic channel to speed product release from the active site.     

A CBS domain-containing pyrophosphatase of Moorella thermoacetica is regulated by adenine nucleotides

CBS (cystathionine beta-synthase) domains are found in proteins from all kingdoms of life, and point mutations in these domains are responsible for a variety of hereditary diseases in humans; however, the functions of CBS domains are not well understood. In the present study, we cloned, expressed in Escherichia coli, and characterized a family II PPase (inorganic pyrophosphatase) from Moorella thermoacetica (mtCBS-PPase) that has a pair of tandem 60-amino-acid CBS domains within its N-terminal domain. Because mtCBS-PPase is a dimer and requires transition metal ions (Co2+ or Mn2+) for activity, it resembles common family II PPases, which lack CBS domains. The mtCBS-PPase, however, has lower activity than common family II PPases, is potently inhibited by ADP and AMP, and is activated up to 1.6-fold by ATP. Inhibition by AMP is competitive, whereas inhibition by ADP and activation by ATP are both of mixed types. The nucleotides are effective at nanomolar (ADP) or micromolar concentrations (AMP and ATP) and appear to compete for the same site on the enzyme. The nucleotide-binding affinities are thus 100-10000-fold higher than for other CBS-domain-containing proteins. Interestingly, genes encoding CBS-PPase occur most frequently in bacteria that have a membrane-bound H+-translocating PPase with a comparable PP(i)-hydrolysing activity. Our results suggest that soluble nucleotide-regulated PPases act as amplifiers of metabolism in bacteria by enhancing or suppressing ATP production and biosynthetic reactions at high and low [ATP]/([AMP]+[ADP]) ratios respectively.     

Sulfolobus acidocaldarius inorganic pyrophosphatase: structure, thermostability, and effect of metal ion in an archael pyrophosphatase.

The first crystal structure of an inorganic pyrophosphatase (S-PPase) from an archaebacterium, the thermophile Sulfolobus acidocaldarius, has been solved by molecular replacement and refined to an R-factor of 19.7% at 2.7 A. S-PPase is a D3 homohexameric protein with one Mg2+ per active site in a position similar to, but not identical with, the first activating metal in mesophilic pyrophosphatases (PPase). In mesophilic PPases, Asp65, Asp70, and Asp102 coordinate the Mg2+, while only Asp65 and Asp102 do in S-PPase, and the Mg2+ moves by 0.7 A. S-PPase may therefore be deactivated at low temperature by mispositioning a key metal ion. The monomer S-PPase structure is very similar to that of Thermus thermophilus (T-PPase) and Escherichia coli (E-PPase), root-mean-square deviations around 1 A/Calpha. But the hexamer structures of S- and T-PPase are more tightly packed and more similar to each other than they are to that of E-PPase, as shown by the increase in surface area buried upon oligomerization. In T-PPase, Arg116 creates an interlocking ionic network to both twofold and threefold related monomers; S-PPase has hydrophilic interactions to threefold related monomers absent in both E- and T-PPase. In addition, the thermostable PPases have about 7% more hydrogen bonds per monomer than E-PPase, and, especially in S-PPase, additional ionic interactions anchor the C-terminus to the rest of the protein. Thermostability in PPases is thus due to subtle improvements in both monomer and oligomer interactions.     

Substitutions of Glycine Residues Gly100 and Gly147 in Conservative Loops Decrease Rates of Conformational Rearrangements of <Emphasis Type="Italic">Escherichia coli</Emphasis> Inorganic Pyrophosphatase

Escherichia coli inorganic pyrophosphatase (PPase) is a one-domain globular enzyme characterized by its ability to easily undergo minor structure rearrangements involving flexible segments of the polypeptide chain. To elucidate a possible role of these segments in catalysis, catalytic properties of mutant variants of E. coli PPase Gly100Ala and Gly147Val with substitutions in the conservative loops II and III have been studied. The main result of the mutations was a sharp decrease in the rates of conformational changes required for binding of activating Mg2+ ions, whereas affinity of the enzyme for Mg2+ was not affected. The pH-independent parameters of MgPP(i) hydrolysis, kcat and kcat/Km, have been determined for the mutant PPases. The values of kcat for Gly100Ala and Gly147Val variants were 4 and 25%, respectively, of the value for the native enzyme. Parameter kcat/Km for both mutants was two orders of magnitude lower. Mutation Gly147Val increased pH-independent Km value about tenfold. The study of synthesis of pyrophosphate in the active sites of the mutant PPases has shown that the maximal level of synthesized pyrophosphate was in the case of Gly100Ala twofold, and in the case of Gly147Val fivefold, higher than for the native enzyme. The results reported in this paper demonstrate that the flexibility of the loops where the residues Gly100 and Gly147 are located is necessary at the stages of substrate binding and product release. In the case of Gly100Ala PPase, significant impairment of affinity of enzyme effector site for PP(i) was also found.     

The role of Asp42 in Escherichia coli inorganic pyrophosphatase functioning.

Excess of Mg2+ ions is known to inhibit the soluble inorganic pyrophosphatases (PPases). In contrast, the mutant Escherichia coli inorganic pyrophosphatase Asp42-->Asn is three times more active than native and retains its activity at high Mg2+ concentration. In this paper, another two mutant variants with Asp42 replaced by Ala or Glu were investigated to characterize the role of Asp42 in catalysis. pH-independent kinetic parameters of MgPPi hydrolysis and the dissociation constants for the activating and inhibitory Mg2+ ions were calculated. It was shown that Mg2+ inhibition of MgPPi hydrolysis by native PPase exhibited uncompetitive kinetics under the saturating substrate concentration. All three substitutions of Asp42 lead to a sharp decrease of inhibitory Mg2+ affinity to the enzyme. These findings allow determination of the sites of inhibitory and substrate Mg2+ ions binding to PPase. Common features of these mutants allow the conclusion that the function of Asp42 is to accurately coordinate the residues implicated in the substrate and the inhibitory Mg2+ ion binding to PPase active site. Structural analysis of PPase complexed with Mg2+ compared with PPase complexed with Mn2+ and reaction products confirms this supposition.     

Effects of active site mutations on the metal binding affinity, catalytic competence, and stability of the family II pyrophosphatase from Bacillus subtilis

Family II inorganic pyrophosphatases (PPases) have been recently found in a variety of bacteria. Their primary and tertiary structures differ from those of the well-known family I PPases, although both have a binuclear metal center directly involved in catalysis. Here, we examined the effects of mutating one Glu, four His, and five Asp residues forming or close to the metal center on Mn(2+) binding affinity, catalysis, oligomeric structure, and thermostability of the family II PPase from Bacillus subtilis (bsPPase). Mutations H9Q, D13E, D15E, and D75E in two metal-binding subsites caused profound (10(4)- to 10(6)-fold) reductions in the binding affinity for Mn(2+). Most of the mutations decreased k(cat) for MgPP(i) by 2-3 orders of magnitude when measured with Mn(2+) or Mg(2+) bound to the high-affinity subsite and Mg(2+) bound to both the low-affinity subsite and pyrophosphate. In the E78D variant, the k(cat) for the Mn-bound enzyme was decreased 120-fold, converting bsPPase from an Mn-specific to an Mg-specific enzyme. K(m) values were less affected by the mutations, and, interestingly, were decreased in most cases. Mutations of His(97) and His(98) residues, which lie near the subunit interface, greatly destabilized the bsPPase dimer, whereas most other mutations stabilized it. Mn(2+), in sharp contrast to Mg(2+), conferred high thermostability to wild-type bsPPase, although this effect was reduced by all of the mutations except D203E. These results indicate that family II PPases have a more integrated active site structure than family I PPases and are consequently more sensitive to conservative mutations.     

Quaternary structure and metal ion requirement of family II pyrophosphatases from Bacillus subtilis, Streptococcus gordonii, and Streptococcus mutans

Pyrophosphatase (PPase) from Bacillus subtilis has recently been found to be the first example of a family II soluble PPase with a unique requirement for Mn2+. In the present work, we cloned and overexpressed in Escherichia coli putative genes for two more family II PPases (from Streptococcus mutans and Streptococcus gordonii), isolated the recombinant proteins, and showed them to be highly specific and active PPases (catalytic constants of 1700-3300 s(-)1 at 25 degrees C in comparison with 200-400 s(-)1 for family I). All three family II PPases were found to be dimeric manganese metalloenzymes, dissociating into much less active monomers upon removal of Mn2+. The dimers were found to have one high affinity manganese-specific site (K(d) of 0.2-3 nm for Mn2+ and 10-80 microm for Mg2+) and two or three moderate affinity sites (K(d) approximately 1 mm for both cations) per subunit. Mn2+ binding to the high affinity site, which occurs with a half-time of less than 10 s at 1.5 mm Mn2+, dramatically shifts the monomer <--> dimer equilibrium in the direction of the dimer, further activates the dimer, and allows substantial activity (60-180 s(-)1) against calcium pyrophosphate, a potent inhibitor of family I PPases.     

Crystal structure of plant asparaginase

In plants, specialized enzymes are required to catalyze the release of ammonia from asparagine, which is the main nitrogen-relocation molecule in these organisms. In addition, K+-independent plant asparaginases are also active in splitting the aberrant isoaspartyl peptide bonds, which makes these proteins important for seed viability and germination. Here, we present the crystal structure of potassium-independent L-asparaginase from yellow lupine (LlA) and confirm the classification of this group of enzymes in the family of Ntn-hydrolases. The alpha- and beta-subunits that form the mature (alphabeta)2 enzyme arise from autoproteolytic cleavage of two copies of a precursor protein. In common with other Ntn-hydrolases, the (alphabeta) heterodimer has a sandwich-like fold with two beta-sheets flanked by two layers of alpha-helices (alphabetabetaalpha). The nucleophilic Thr193 residue, which is liberated in the autocatalytic event at the N terminus of subunit beta, is part of an active site that is similar to that observed in a homologous bacterial enzyme. An unusual sodium-binding loop of the bacterial protein, necessary for proper positioning of all components of the active site, shows strictly conserved conformation and metal coordination in the plant enzyme. A chloride anion complexed in the LlA structure marks the position of the alpha-carboxylate group of the L-aspartyl substrate/product moiety. Detailed analysis of the active site suggests why the plant enzyme hydrolyzes asparagine and its beta-peptides but is inactive towards substrates accepted by similar Ntn-hydrolases, such as taspase1, an enzyme implicated in some human leukemias. Structural comparisons of LlA and taspase1 provide interesting insights into the role of small inorganic ions in the latter enzyme.     

Identification of active site residues of the adeno-associated virus type 2 Rep endonuclease

Adeno-associated virus type 2 Rep endonuclease activity is necessary for both viral DNA replication and site-specific integration of the viral genome into human chromosome 19. The biochemical activities required for site-specific endonuclease activity (namely specific DNA binding and transesterification activity) have been mapped to the amino-terminal domain of the AAV2 Rep protein. The amino-terminal 208 amino acids are alone sufficient for site-specific endonuclease activity, and nicking by this domain is metal-dependent. To identify this metal-binding site, we have employed a cysteine mutagenesis approach that targets conserved acidic amino acids. By using this technique, we provide functional biochemical data supporting a role for glutamate 83 in the coordination of metal ions in the context of Rep endonuclease activity. In addition, our biochemical data suggest that glutamate 164, although not involved in the coordination of metal ions, is closely associated with the active site. Thus, in lieu of a crystal structure for the AAV type 2 amino-terminal domain, our data corroborate the recently published structural studies of the AAV type 5 endonuclease and suggest that although the two enzymes are not highly conserved with respect to the AAV family, their active sites are highly conserved.     

Structural and functional comparisons between vanadium haloperoxidase and acid phosphatase enzymes

The crystallographic structures of both the vanadium chloroperoxidase and bromoperoxidase enzymes have been determined with either vanadium or phosphate bound at their active site. The amino acids that are involved in phosphate binding in the acid phosphatase enzymes and those that are coordinated to vanadium in the haloperoxidases appear to be conserved between the two classes of enzyme. The detailed active site architecture for enzymes that recognize and use either vanadium or phosphate will be discussed in relation to their proposed enzymatic mechanism.     

Solution structure of the low-molecular-weight protein tyrosine phosphatase from Tritrichomonas foetus reveals a flexible phosphate binding loop

Eukaryotic low-molecular-weight protein tyrosine phosphatases (LMW PTPs) contain a conserved serine, a histidine with an elevated pKa, and an active site asparagine that together form a highly conserved hydrogen bonding network. This network stabilizes the active site phosphate binding loop for optimal substrate binding and catalysis. In the phosphatase from the bovine parasite Tritrichomonas foetus (TPTP), both the conserved serine (S37) and asparagine (N14) are present, but the conserved histidine has been replaced by a glutamine residue (Q67). Site-directed mutagenesis, kinetic, and spectroscopic experiments suggest that Q67 is located near the active site and is important for optimal catalytic activity. Kinetic experiments also suggest that S37 participates in the active site/hydrogen bonding network. Nuclear magnetic resonance spectroscopy was used to determine the three-dimensional structure of the TPTP enzyme and to further examine the roles of S37 and Q67. The backbone conformation of the TPTP phosphate binding loop is nearly superimposable with that of other tyrosine phosphatases, with N14 existing in a strained, left-handed conformation that is a hallmark of the active site hydrogen bonding network in the LMW PTPs. As expected, both S37 and Q67 are located at the active site, but in the consensus structure they are not within hydrogen bonding distance of N14. The hydrogen bond interactions that are observed in X-ray structures of LMW PTPs may in fact be transient in solution. Protein dynamics within the active site hydrogen bonding network appear to be affected by the presence of substrate or bound inhibitors such as inorganic phosphate.     

Roles of divalent metal ions in flap endonuclease-substrate interactions

Flap endonucleases (FENs) have essential roles in DNA processing. They catalyze exonucleolytic and structure-specific endonucleolytic DNA cleavage reactions. Divalent metal ions are essential cofactors in both reactions. The crystal structure of FEN shows that the protein has two conserved metal-binding sites. Mutations in site I caused complete loss of catalytic activity. Mutation of crucial aspartates in site II abolished exonuclease action, but caused enzymes to retain structure-specific (flap endonuclease) activity. Isothermal titration calorimetry revealed that site I has a 30-fold higher affinity for cofactor than site II. Structure-specific endonuclease activity requires binding of a single metal ion in the high-affinity site, whereas exonuclease activity requires that both the high- and low-affinity sites be occupied by divalent cofactor. The data suggest that a novel two-metal mechanism operates in the FEN-catalyzed exonucleolytic reaction. These results raise the possibility that local concentrations of free cofactor could influence the endo- or exonucleolytic pathway in vivo.