Mutations in the ribonuclease H active site of HIV-RT reveal a role for this site in stabilizing enzyme-primer-template binding

The RNase H activity of HIV-RT is coordinated by a catalytic triad (E478, D443, D498) of acidic residues that bind divalent cations. We examined the effect of RNase H deficient E(478)-->Q and D(549)-->N mutations that do not alter polymerase activity on binding of enzyme to various nucleic acid substrates. Binding of the mutant and wild-type enzymes to various nucleic acid substrates was examined by determining dissociation rate constants (k(off)) by titrating both Mg(2+) and salt concentrations. In agreement with the unaltered polymerase activity of the mutant, the k(off) values for the wild-type and mutant enzymes were essentially identical using DNA-DNA templates in the presence of 6 mM Mg(2+). However, with lower concentrations of Mg(2+) and in the absence of Mg(2+), although both enzymes dissociated more rapidly, the mutant enzymes dissociated several-fold more slowly than the wild type. This was also observed on RNA-DNA templates. These results indicate that alterations in residues essential for Mg(2+) binding have a pronounced positive effect on enzyme-template stability and that the negative residues in the RNase H region of the enzyme have a negative influence on binding in the absence of Mg(2+). In this regard RT is similar to other nucleic acid cleaving enzymes that show enhanced binding upon mutation of active site residues.     

Studies on Ca(II) binding to gamma-carboxyglutamic acid. Use of thermal decarboxylation to probe metal ion/gamma-carboxyglutamic acid interactions

The thermal decarboxylation of N-benzyloxycarbonyl-L-gamma-carboxyglutamic acid alpha-methyl ester [Z)-L-Gla-OMe) has been studied. In the presence of increasing amounts of calcium or magnesium ions, lyophilized powders of (Z)-L-Gla-OMe exhibit a corresponding increase in thermal stability. Both magnesium and calcium form relatively tight, thermally stable complexes with (Z)-L-Gla-OMe at high metal ion concentrations. Differences between Ca(II) and Mg(II) binding are noted at low metal ion concentrations, where (Z)-L-Gla-OMe is in excess. Under these conditions, complex formation with Mg(II) apparently favors a 2:1 Gla-magnesium ion complex in which both Gla residues are unstable to thermal decarboxylation. Calcium ion complexes, however, are found to favor a 3:1 Gla-calcium ion complex in which 1 of the 3 Gla residues is thermally stable.     

The metal ion in the active site of the membrane glucose dehydrogenase of Escherichia coli

All pyrroloquinoline quinone (PQQ)-containing dehydrogenases whose structures are known contain Ca(2+) bonded to the PQQ at the active site. However, membrane glucose dehydrogenase (GDH) requires reconstitution with PQQ and Mg(2+) ions (but not Ca(2+)) for activity. To address the question of whether the Mg(2+) replaces the usual active site Ca(2+) in this enzyme, mutant GDHs were produced in which residues proposed to be involved in binding metal ion were modified (D354N-GDH and N355D-GDH and D354N-GDH/N355D-GDH). The most remarkable observation was that reconstitution with PQQ of the mutant enzymes was not supported by Mg(2+) ions as in the wild-type GDH, but it could be supported by Ca(2+), Sr(2+) or Ba(2+) ions. This was competitively inhibited by Mg(2+). This result, together with studies on the kinetics of the modified enzymes have led to the conclusion that, although a Ca(2+) ion is able to form part of the active site of the genetically modified GDH, as in all other PQQ-containing quinoproteins, a Mg(2+) ion surprisingly replaces Ca(2+) in the active site of the wild-type GDH.     

EcoRV restriction endonuclease: communication between DNA recognition and catalysis.

A genetic system was constructed for the mutagenesis of the EcoRV restriction endonuclease and for the overproduction of mutant proteins. The system was used to make two mutants of EcoRV, with Ala in place of either Asn185 or Asn188. In the crystal structure of the EcoRV-DNA complex, both Asn185 and Asn188 contact the DNA within the EcoRV recognition sequence. But neither mutation affected the ability of the protein to bind to DNA. In the absence of metal ion cofactors, the mutants bound DNA with almost the same affinity as that of the wild-type enzyme. In the presence of Mg2+, both mutants retained the ability to cleave DNA specifically at the EcoRV recognition sequence, but their activities were severely depressed relative to that of the wild-type. In contrast, with Mn2+ as the cofactor, the mutant enzymes cleaved the EcoRV recognition site with activities that were close to that of the wild-type. When bound to DNA at the EcoRV recognition site, the mutant proteins bound Mn2+ ions readily, but they had much lower affinities for Mg2+ ions than the wild-type enzyme. This was the reason for their low activities with Mg2+ as the cofactor. The arrangement of the DNA recognition functions, at one location in the EcoRV restriction enzyme, are therefore responsible for organizing the catalytic functions at a separate location in the protein.     

The crystal structure of R-specific alcohol dehydrogenase from Lactobacillus brevis suggests the structural basis of its metal dependency

The crystal structure of the apo-form of an R-specific alcohol dehydrogenase from Lactobacillus brevis (LB-RADH) was solved and refined to 1.8A resolution. LB-RADH is a member of the short-chain dehydrogenase/reductase (SDR) enyzme superfamily. It is a homotetramer with 251 amino acid residues per subunit and uses NADP(H) as co-enzyme. NADPH and the substrate acetophenone were modelled into the active site. The enantiospecificity of the enzyme can be explained on the basis of the resulting hypothetical ternary complex. In contrast to most other SDR enzymes, the catalytic activity of LB-RADH depends strongly on the binding of Mg(2+). Mg(2+) removal by EDTA inactivates the enzyme completely. In the crystal structure, the Mg(2+)-binding site is well defined. The ion has a perfect octahedral coordination sphere and occupies a special position concerning crystallographic and molecular point symmetry, meaning that each RADH tetramer contains two magnesium ions. The magnesium ion is no direct catalytic cofactor. However, it is structurally coupled to the putative C-terminal hinge of the substrate-binding loop and, via an extended hydrogen bonding network, to some side-chains forming the substrate binding region. Therefore, the presented structure of apo-RADH provides plausible explanations for the metal dependence of the enzyme.     

Purification from a yeast mutant of mitochondrial F1 with modified beta-subunit. High affinity for nucleotides and high negative cooperativity of ATPase activity

Mitochondrial F1 containing genetically modified beta-subunit was purified for the first time from a mutant of the yeast Schizosaccharomyces pombe. Precipitation by poly(ethylene glycol) allowed us to obtain a very stable and pure enzyme from either mutant or wild-type strain. In the presence of EDTA, purified F1 retained high amounts of endogenous nucleotides: 4.6 mol/mol and 3.7 mol/mol for mutant and wild-type F1, respectively. The additional nucleotide in mutant F1 was ATP; it was lost in the presence of Mg2+, which led to a total of 3.4 mol of nucleotides/mol whereas wild-type F1 retained all its nucleotides. Mutant F1 bound more exogenous ADP than wild-type F1 and the same total nucleotide amount was reached with both enzymes. Kinetics of ATPase activity revealed a much higher negative cooperativity for mutant than for wild-type F1. Bicarbonate abolished this negative cooperativity, but higher concentrations were required for mutant F1. The mutant enzyme was more sensitive than the wild-type one to azide inhibition and ADP competitive inhibition; this indicated stronger interactions between nucleotide and F1 in the mutant enzyme. The latter also showed increased sensitivity to N,N'-dicyclohexylcarbodiimide irreversible inhibition.     

Identification and mutational analysis of Mg2+ binding site in EcoP15I DNA methyltransferase: involvement in target base eversion

EcoP15I DNA methyltransferase catalyzes the transfer of the methyl group of S-adenosyl-l-methionine to the N6 position of the second adenine within the double-stranded DNA sequence 5'-CAGCAG-3'. To achieve catalysis, the enzyme requires a magnesium ion. Binding of magnesium to the enzyme induces significant conformational changes as monitored by circular dichroism spectroscopy. EcoP15I DNA methyltransferase was rapidly inactivated by micromolar concentrations of ferrous sulfate in the presence of ascorbate at pH 8.0. The inactivated enzyme was cleaved into two fragments with molecular masses of 36 and 35 kDa. Using this affinity cleavage assay, we have located the magnesium binding-like motif to amino acids 355-377 of EcoP15I DNA methyltransferase. Sequence homology comparisons between EcoP15I DNA methyltransferase and other restriction endonucleases allowed us to identify a PD(X)n(D/E)XK-like sequence as the putative magnesium ion binding site. Point mutations generated in this region were analyzed for their role in methyltransferase activity, metal coordination, and substrate binding. Although the mutant methyltransferases bind DNA and S-adenosyl-l-methionine as well as the wild-type enzyme does, they are inactive primarily because of their inability to flip the target base. Collectively, these data are consistent with the fact that acidic amino acid residues of the region 355-377 in EcoP15I DNA methyltransferase are important for the critical positioning of magnesium ions for catalysis. This is the first example of metal-dependent function of a DNA methyltransferase. These findings provide impetus for exploring the role(s) of metal ions in the structure and function of DNA methyltransferases.     

Catalytic roles of divalent metal ions in phosphoryl transfer by EcoRV endonuclease.

The rate constant for the phosphoryl transfer step in site-specific DNA cleavage by EcoRV endonuclease has been determined as a function of pH and identity of the required divalent metal ion cofactor, for both wild-type and T93A mutant enzymes. These measurements show bell-shaped pH-rate curves for each enzyme in the presence of Mg2+ as a cofactor, indicating general base catalysis for the nucleophilic attack of hydroxide ion on the scissile phosphate, and general acid catalysis for protonation of the leaving 3'-O anion. The kinetic data support a model for phosphoryl transfer based on wild-type and T93A cocrystal structures, in which the ionizations of two distinct metal-ligated waters respectively generate the attacking hydroxide ion and the proton for donation to the leaving group. The model concurs with recent observations of two metal ions bound in the active sites of the type II restriction endonucleases BamHI and BglI, suggesting the possibility of a similar catalytic mechanism functioning in many or all members of this enzyme family.     

Ciprofloxacin affects conformational equilibria of DNA gyrase A in the presence of magnesium ions

The conformational equilibria of the A subunit of DNA gyrase (GyrA), of its 59 kDa N-terminal fragment (GyrA59) and of the quinolone-resistant Ser-Trp83 mutant (GyrATrp83), were investigated in the presence of mono- and divalent metal ions and ciprofloxacin, a clinically useful antibacterial quinolone. The stability of the proteins was estimated from temperature denaturation, monitoring unfolding with circular dichroism spectroscopy. Two transitions were observed in GyrA and GyrATrp83, which likely reflect unfolding of the N and C-terminal protein domains. Accordingly, one thermal transition is observed for GyrA59.The melting profile of the GyrA subunit is dramatically affected by monovalent and divalent metal ions, both transitions being shifted to lower temperature upon increasing salt concentration. This effect is much more pronounced with divalent ions (Mg(2+)) and cannot be accounted for by changes in ionic strength only. The presence of ciprofloxacin shifts the melting transitions of the wild-type subunit to higher temperatures when physiological concentrations of Mg(2+) are present. In contrast, both the mutant protein and the 59 kDa fragment do not show evidence for quinolone-driven changes. These data suggest that ciprofloxacin binds to the wild-type subunit in an interaction that involves Ser83 of GyrA and that both C and N-terminal domains may be required for effective drug-protein interactions. The bell-shaped dependence of the binding process upon Mg(2+) concentration, with a maximum centred at 3-4 mM [Mg(2+)], is consistent with a metal-ion mediated GyrA-quinolone-interaction. Affinity chromatography data fully support these findings and additionally confirm the requirement for a free carboxylate to elicit binding of the quinolone to GyrA.We infer that the Mg(2+)-GyrA interaction at physiological metal ion concentration could bear biological relevance, conferring more conformational flexibility to the active enzyme. The results obtained in the presence of ciprofloxacin additionally suggest that the Mg(2+)-mediated quinolone binding to the enzyme might be involved in the mechanism of action of this family of drugs.     

The effect of divalent cations on aggregation of Dictyostelium discoideum.

Following the initiation of development, amoebae of Dictyostelium discoideum aggregate chemotactically toward cyclic AMP (cAMP). Adenyl cyclase, cAMP phosphodiesterase, and cAMP binding sites all increase 20--40 fold during the first few hours of development. It has been shown that addition of 1 mM EDTA and 5 mM MgCl2 accelerates the aggregation process. Likewise, the calcium ionophore, A23187, leads to precocious aggregation while 4 X 10(-5) M progesterone considerably delays it. These treatments have now been shown to result in increased accumulation of adenyl cyclase in the case of EDTA and Mg2+ or the ionophore and greatly decreased accumulation in the case of the steroid. Treatment with EDTA and Mg2+ or the ionophore has been shown not only to accelerate aggregation in wild-type amoebae but to overcome complete blocks to aggregation in certain mutant strains. We have found that addition of Mn2+ will also permit aggregation of mutant cells otherwise unable to aggregate. This divalent ion, unlike EDTA and Mg2+ or the ionophore, was shown to directly stimulate adenyl cyclase. Calcium ions were also found to affect the enzyme such that at Ca2+ concentrations found within the cells the great majority of the activity is inhibited. Manganese ions can overcome the inhibition by Ca2+. These findings show that conditions which stimulate aggregation result in increased activity of adenyl cyclase either by increased accumulation of the enzyme or by increased activity of the available enzyme, and support the proposed central role of adenyl cyclase in aggregation.     

Characterization of the ATP-phosphohydrolase activity of bovine spermatozoa flagellar extracts.

The ATP-phosphohydrolase activity of extracts prepared from bovine spermatozoa flagella (BSFE), was characterized with respect to enzyme, substrate, activator ion and salt concentration, temperature dependence and time stability. BSFE required the presence of a divalent cation for activity: Mg++ or Ca++ could function as activator; Mn++, Zn++ and Cd++ could not. EDTA, but not EGTA, was inhibitory to enzymatic activity. Ca++ inhibited the Mg++ stimulated activity. ATP was dephosphorylated more rapidly than GTP greater than CTP greater than ITP, and ADP was dephosphorylated at 40% of the rate of ATP. The magnesium activated ATPase was stimulated by potassium and inhibited by sodium ions. Activation of BSFE ATP-phosphohydrolase was maximal in the presence of Mg++ and ATP in equimolar concentrations and K+ (0.05-0.3 M) at 30 degrees C. Although the enzymatic activity of the extract was found to decrease rapidly with time, it could be maintained for up to three days by the addition of 2-beta-mercaptoethanol to the bovine spermatozoa flagellar extracts.     

Mutation of the aspartic acid residues of the GDD sequence motif of poliovirus RNA-dependent RNA polymerase results in enzymes with altered metal ion requirements for activity.

The poliovirus RNA-dependent RNA polymerase, 3Dpol, is known to share a region of sequence homology with all RNA polymerases centered at the GDD amino acid motif. The two aspartic acids have been postulated to be involved in the catalytic activity and metal ion coordination of the enzyme. To test this hypothesis, we have utilized oligonucleotide site-directed mutagenesis to generate defined mutations in the aspartic acids of the GDD motif of the 3Dpol gene. The codon for the first aspartate (3D-D-328 [D refers to the single amino acid change, and the number refers to its position in the polymerase]) was changed to that for glutamic acid, histidine, asparagine, or glutamine; the codons for both aspartic acids were simultaneously changed to those for glutamic acids; and the codon for the second aspartic acid (3D-D-329) was changed to that for glutamic acid or asparagine. The mutant enzymes were expressed in Escherichia coli, and the in vitro poly(U) polymerase activity was characterized. All of the mutant 3Dpol enzymes were enzymatically inactive in vitro when tested over a range of Mg2+ concentrations. However, when Mn2+ was substituted for Mg2+ in the in vitro assays, the mutant that substituted the second aspartic acid for asparagine (3D-N-329) was active. To further substantiate this finding, a series of different transition metal ions were substituted for Mg2+ in the poly(U) polymerase assay. The wild-type enzyme was active with all metals except Ca2+, while the 3D-N-329 mutant was active only when FeC6H7O5 was used in the reaction. To determine the effects of the mutations on poliovirus replication, the mutant 3Dpol genes were subcloned into an infectious cDNA of poliovirus. The cDNAs containing the mutant 3Dpol genes did not produce infectious virus when transfected into tissue culture cells under standard conditions. Because of the activity of the 3D-N-329 mutant in the presence of Fe2+ and Mn2+, transfections were also performed in the presence of the different metal ions. Surprisingly, the transfection of the cDNA containing the 3D-N-329 mutation resulted in the production of virus at a low frequency in the presence of FeSO4 or CoCl2. The virus derived from transfection in the presence of FeSO4 grew slowly, while the viruses recovered from transfection in CoCl2 grew at a rate which was similar to that of the wild-type poliovirus.(ABSTRACT TRUNCATED AT 400 WORDS)     

Reversing Evolution: Re-establishing Obligate Metal Ion Dependence in a Metal-independent KDO8P Synthase

Two distinct groups of 3-deoxy-d-manno-octulosonate 8-phosphate synthase (KDO8PS), a key enzyme of cell-wall biosynthesis, differ by their requirement for a divalent metal ion for enzymatic activity. The unique difference between these groups is the replacement of the metal-binding Cys by Asn. Substitution of just this Asn for a Cys in metal-independent KDO8PS does not create the obligate metal-ion dependency of natural metal-dependent enzymes. We describe how three or four mutations of the metal-independent KDO8PS from Neisseria meningitidis produce a fully functional, obligately metal-dependent KDO8PS. For the substitutions Asn23Cys, Asp247Glu (this Asp binds to the metal ion in all metal-dependent KDO8PS) and Pro249Ala, and for double and triple combinations, mutant enzymes that contained Cys in place of Asn showed an increase in activity in the presence of divalent metal ions. However, combining these mutations with substitution by Ser of the Cys residue in the conserved ²⁴⁶CysAspGlyPro²⁴⁹ motif of metal-independent KDO8PS created enzymes with obligate metal dependency. The quadruple mutant (Asn23Cys/Cys246Ser/Asp247Glu/Pro249Ala) showed comparable activity to wild-type enzymes only in the presence of metal ions, with maximum activity with Cd²⁺, the metal ion that is strongly inhibitory at micromolar concentrations for the wild-type enzyme. In the absence of metal ions, activity was barely detectable for this quadruple mutant or for triple mutants bearing both Cys246Ser and Asn23Cys mutations. The structures of NmeKDO8PS and its Asn23Cys/Asp247Glu/Pro249Ala and quadruple mutants at pH 4.6 were characterized at resolutions better than 1.85 Å. Aged crystals of the Asn23Cys/Asp247Glu/Pro249Ala mutant featured a Cys23-Cys246 disulfide linkage, explaining the spectral bleaching observed when this mutant was incubated with Cu²⁺. Such bleaching was not observed for the quadruple mutant. Reverse evolution to a fully functional obligately metal-dependent KDO8PS has been achieved with just three directed mutations for enzymes that have, at best, 47% identity between metal-dependent and metal-independent pairs.     

Structural and biochemical characterization of a new Mg(2+) binding site near Tyr94 in the restriction endonuclease PvuII

We have determined the crystal structure of the PvuII endonuclease in the presence of Mg(2+). According to the structural data, divalent metal ion binding in the PvuII subunits is highly asymmetric. The PvuII-Mg(2+) complex has two distinct metal ion binding sites, one in each monomer. One site is formed by the catalytic residues Asp58 and Glu68, and has extensive similarities to a catalytically important site found in all structurally examined restriction endonucleases. The other binding site is located in the other monomer, in the immediate vicinity of the hydroxyl group of Tyr94; it has no analogy to metal ion binding sites found so far in restriction endonucleases. To assign the number of metal ions involved and to better understand the role of Mg(2+) binding to Tyr94 for the function of PvuII, we have exchanged Tyr94 by Phe and characterized the metal ion dependence of DNA cleavage of wild-type PvuII and the Y94F variant. Wild-type PvuII cleaves both strands of the DNA in a concerted reaction. Mg(2+) binding, as measured by the Mg(2+) dependence of DNA cleavage, occurs with a Hill coefficient of 4, meaning that at least two metal ions are bound to each subunit in a cooperative fashion upon formation of the active complex. Quenched-flow experiments show that DNA cleavage occurs about tenfold faster if Mg(2+) is pre-incubated with enzyme or DNA than if preformed enzyme-DNA complexes are mixed with Mg(2+). These results show that Mg(2+) cannot easily enter the active center of the preformed enzyme-DNA complex, but that for fast cleavage the metal ions must already be bound to the apoenzyme and carried with the enzyme into the enzyme-DNA complex. The Y94F variant, in contrast to wild-type PvuII, does not cleave DNA in a concerted manner and metal ion binding occurs with a Hill coefficient of 1. These results indicate that removal of the Mg(2+) binding site at Tyr94 completely disrupts the cooperativity in DNA cleavage. Moreover, in quenched-flow experiments Y94F cleaves DNA about ten times more slowly than wild-type PvuII, regardless of the order of mixing. From these results we conclude that wild-type PvuII cleaves DNA in a fast and concerted reaction, because the Mg(2+) required for catalysis are already bound at the enzyme, one of them at Tyr94. We suggest that this Mg(2+) is shifted to the active center during binding of a specific DNA substrate. These results, for the first time, shed light on the pathway by which metal ions as essential cofactors enter the catalytic center of restriction endonucleases.     

Surface denaturation of proteins: the thermal inactivation of beta-galactosidase (Escherichia coli) on wall-liquid surfaces.

Irreversible inactivation of dilute beta-galactosidase (Escherichia coli) at relatively low temperatures was found to occur as a result of interactions of beta-galactosidase with wall-liquid surfaces. The rate of inactivation was directly proportional to the wall-liquid surface area, but independent of the air-liquid surface area, and the rate was also dependent on the wall composition. A small portion of the beta-galactosidase molecules was found to bind strongly to the surfaces of vessels in which the beta-galactosidase was stored. Bovine serum albumin eliminated the inactivation and it also eliminated the binding of beta-galactosidase to the wall. On the other hand, EDTA eliminated the inactivation, but it did not decrease the amount of beta-galactosidase bound. The addition of some transition metals increased the rate of inactivation. Protection of beta-galactosidase from surface inactivation by EDTA is not, therefore, a result of decreased binding of the enzyme to the walls of the vessels, but is probably a result of the ability of EDTA to scavenge certain trace metal ions present in solution, which are needed for the inactivation. The content of protein in the solution did not change as a result of the inactivation and, thus, the inactive enzyme does not accumulate at the surface. Since beta-galactosidase is often stored for long periods of time and since it is used to decrease the lactose content of milk for lactose intolerant individuals, this study may have practical significance. The presence of metal chelators and extraneous proteins should improve the stability of the enzyme, especially for processes that are carried out at elevated temperatures.     

Artificial evolution of an enzyme active site: structural studies of three highly active mutants of Escherichia coli alkaline phosphatase

The crystal structure of three mutants of Escherichia coli alkaline phosphatase with catalytic activity (k(cat)) enhancement as compare to the wild-type enzyme is described in different states. The biological aspects of this study have been reported elsewhere. The structure of the first mutant, D330N, which is threefold more active than the wild-type enzyme, was determined with phosphate in the active site, or with aluminium fluoride, which mimics the transition state. These structures reveal, in particular, that this first mutation does not alter the active site. The second mutant, D153H-D330N, is 17-fold more active than the wild-type enzyme and activated by magnesium, but its activity drops after few days. The structure of this mutant was solved under four different conditions. The phosphate-free enzyme was studied in an inactivated form with zinc at site M3, or after activation by magnesium. The comparison of these two forms free of phosphate illustrates the mechanism of the magnesium activation of the catalytic serine residue. In the presence of magnesium, the structure was determined with phosphate, or aluminium fluoride. The drop in activity of the mutant D153H-D330N could be explained by the instability of the metal ion at M3. The analysis of this mutant helped in the design of the third mutant, D153G-D330N. This mutant is up to 40-fold more active than the wild-type enzyme, with a restored robustness of the enzyme stability. The structure is presented here with covalently bound phosphate in the active site, representing the first phosphoseryl intermediate of a highly active alkaline phosphatase. This study shows how structural analysis may help to progress in the improvement of an enzyme catalytic activity (k(cat)), and explains the structural events associated with this artificial evolution.     

The PD...(D/E)XK motif in restriction enzymes: a link between function and conformation

The active sites of Mg(II)-dependent nucleases feature a cluster of conserved charged residues which includes both acidic (Asp and Glu) and basic (Lys) side chains. In restriction enzymes, these side chains are part of the conserved PD...(D/E)XK functional sequence motif which has been implicated as being important in metal ion binding and catalytic steps. Recent work revealing the unusual behavior of the active site variant D58A of the representative PvuII endonuclease prompted speculation that the array of charged groups in the nuclease active site may also be linked to conformational behavior [Dupureur, C. M., and Conlan, L. H. (2000) Biochemistry 39, 10921-10927]. To address this issue, we analyzed the conformational behavior of active site variants of PvuII endonuclease using both NMR spectroscopic and thermodynamic methods. NMR spectroscopic analysis via (19)F and (1)H-(15)N HSQC experiments indicates that a number of side chain and backbone amide groups are perturbed upon Ala substitution at conserved active site residues Asp58, Glu68, and Lys70. Spectral changes are particularly pronounced for the lowest-activity mutants (D58A and K70A). These changes are accompanied by perturbations in conformational stability. Ala substitution at each of these positions results in 2-5 kcal/mol of stabilization over the wild-type enzyme at pH 7.7, changes which constitute increases in DeltaG(d)(H2O) of 20-50%. The pH dependencies of mutant enzyme stabilities are distinct from those of the wild type, results which confirm that these ionizable groups strongly influence stability. Wild-type enzyme stability is correlated with the ionization of groups shown to be important to metal ion binding and orientation. Correlations between spectral changes and conformational stability indicate that the latter measurements may prove useful in the evaluation of site-directed mutant restriction enzymes. More importantly, these results indicate that structure-function relationships in restriction enzyme active sites can be complex, and that the ensemble of conserved charged residues which mediate DNA hydrolysis in Mg(II)-dependent nucleases constitutes a critical link between function and conformation.     

Pyrococcus furiosus alpha-amylase is stabilized by calcium and zinc

The hyperthermophilic archeon Pyrococcus furiosus produces an extracellular alpha-amylase that belongs to glycosyl hydrolases' family 13. This enzyme is more thermostable than its bacterial and archaeal homologues (e.g., Bacillus licheniformis TAKA-term and Pyrococcus kodakaraensis KOD1 alpha-amylases, respectively) even without adding Ca(2+) ions. Unlike the TAKA-therm amylase that contains no cysteine, the P. furiosus enzyme contains five cysteines (C152, C153, C165, C387, and C430), only four of which (C152, C153, C387, and C430) are conserved in the P. kodakaraensis alpha-amylase. To test the potential function of cysteines in P. furiosus alpha-amylase stability, these five residues were substituted with Ser or Ala-either one-by-one or in sequence-to produce eight mutant enzymes. Mutation C165S dramatically destabilized P. furiosus alpha-amylase. At the same time, the quadruple mutant enzyme C152S/C153S/C387S/C430A (mutant SSCSA) was as thermostable as the wild-type enzyme. Mutant SSCSA and wild-type alpha-amylases were strongly destabilized by dithiothreitol and ethylenediaminetetraacetic acid, suggesting that metal binding can be involved in this enzyme's thermostability. Inductively coupled plasma-atomic emission spectrometry showed the presence of Ca(2+) and Zn(2+) metal ions in P. furiosus alpha-amylase. Although Ca(2+) is known to contribute to alpha-amylase's stability, the absence of two out of the three conserved Ca(2+) ligands in the P. furiosus enzyme suggests that a different set of amino acids is involved in this enzyme's Ca(2+) binding. We also provide evidence suggesting that Cys165 is involved in Zn(2+) binding and that Cys165 is essential for the stability of P. furiosus alpha-amylase at very high temperatures.     

Selective alteration of the rate-limiting step in cytosolic aldehyde dehydrogenase through random mutagenesis

Random mutagenesis followed by a filter-based screening assay has been used to identify a mutant of human class 1 aldehyde dehydrogenase (ALDH1) that was no longer inhibited by Mg(2+) ions but was activated in their presence. Several mutants possessed double, triple, and quadruple amino acid substitutions with a total of seven different residues being altered, but each had a common T244S change. This point mutation proved to be responsible for the Mg(2+) ion activation. An ALDH1 T244S mutant was recombinantly expressed and was used for mechanistic studies. Mg(2+) ions have been shown to increase the rate of deacylation. Consistent with the rate-limiting step for ALDH1 being changed from coenzyme dissociation to deacylation was finding that chloroacetaldehyde was oxidized more rapidly than acetaldehyde. Furthermore, Mg(2+) ions only in the presence of NAD(H) increased the rate of hydrolysis of p-nitrophenyl acetate showing that the metal only affects the binary complex. Though the rate-limiting step for the T244S mutant was different from that of the native enzyme, the catalytic efficiency of the mutant was just 20% that of the native enzyme. The basis for the change in the rate-limiting step appears to be related to NAD(+) binding. Using the structure of a sheep class 1 ALDH, it was possible to deduce that the interaction between the side chain of T244 and its neighboring residues with the nicotinamide ring of NAD(+) were an essential determinant in the catalytic action of ALDH1.     

Protein engineering of xylose (glucose) isomerase from Actinoplanes missouriensis. 3. Changing metal specificity and the pH profile by site-directed mutagenesis.

Aldose-ketose isomerization by xylose isomerase requires bivalent cations such as Mg2+, Mn2+, or Co2+. The active site of the enzyme from Actinoplanes missouriensis contains two metal ions that are involved in substrate binding and in catalyzing a hydride shift between the C1 and C2 substrate atoms. Glu 186 is a conserved residue located near the active site but not in contact with the substrate and not with a metal ligand. The E186D and E186Q mutant enzymes were prepared. Both are active, and their metal specificity is different from that of the wild type. The E186Q enzyme is most active with Mn2+ and has a drastically shifted pH optimum. The X-ray analysis of E186Q was performed in the presence of xylose and either Mn2+ or Mg2+. The Mn2+ structure is essentially identical to that of the wild type. In the presence of Mg2+, the carboxylate group of residue Asp 255, which is part of metal site 2 and a metal ligand, turns toward Gln 186 and hydrogen bonds to its side-chain amide. Mg2+ is not bound at metal site 2, explaining the low activity of the mutant with this cation. Movements of Asp 255 also occur in the wild-type enzyme. We propose that they play a role in the O1 to O2 proton relay accompanying the hydride shift.