Single turnover kinetics of phage T4 DNA-(N6-adenine)methyltransferase

Interaction of T4 DNA-(N6-adenine)-methyltransferase [EC 2.1.1] was studied with a variety of synthetic oligonucleotide substrates containing the native recognition site GATC or its modified variants. The data obtained in the decisecond and second intervals of the reaction course allowed for the first time the substrate methylation rates to be compared with the parameters of the steady-state reaction. It was established that the substrate reaction proceeds in two stages. Because it is shown that in steady-state conditions T4 MTase forms a dimeric structure, the following sequence of events is assumed. Upon collision of a T4 MTase monomer with an oligonucleotide duplex, an asymmetrical complex forms in which the enzyme randomly oriented relative to one of the strands of the specific recognition site catalyzes a fast transfer of the methyl group from S-adenosylmethionine to the adenosine residue (k1 = 0.21 s-1). Simultaneously, a second T4 MTase subunit is added to the complex, providing for the continuation of the reaction. In the course of a second stage, which is by an order of magnitude slower (k2 = 0.023 s-1 for duplex with the native site), the dimeric T4 MTase switches over to the second strand and the methylation of the second residue, target. The rate of the methyl group transfer from donor, S-adenosylmethionine, to DNA is much higher than the overall rate of the T4 MTase-catalyzed steady-state reaction, although this difference is considerably less than that shown for EcoRI Mtase. Substitutions of bases and deletions in the recognition site affect the substrate parameters in different fashions. When the GAT sequence is disrupted, the proportion of the initial productive enzyme-substrate complexes is usually sharply reduced. The flipping of the adenosine residue, a target for the modification in the recognition site, revealed by fluorescence titration, upon interaction with the enzyme supports the existing notions about the involvement of such a DNA deformation in reactions catalyzed by various DNA-MTases.     

DNA-(N4-Cytosine)-Methyltransferase from Bacillus amyloliquefaciens: Kinetic and Substrate-binding Properties

Interaction of DNA-(N4-cytosine)-methyltransferase from the Bacillus amyloliquefaciens (BamHI MTase, 49 kDa) with a 20-mer duplex containing a palindromic recognition site GGATCC was studied by methods of steady-state and pre-steady-state kinetics of the methyl group transfer, gel retardation, and crosslinking of the enzyme subunits with glutaraldehyde. In steady-state conditions, BamHI MTase displays a simple kinetic behavior toward the 20-mer substrate. A linear dependence was observed for the reaction rate on the enzyme concentration and a Michaelis dependence of the reaction rate on the concentration of both substrates: S-adenosyl-L-methionine (SAM), the methyl group donor, and DNA, the methyl group acceptor. In independent experiments, the concentration of the 20-mer duplex or SAM was changed, the enzyme concentration being substantially lower than the concentrations of substrates. The k _cat values determined in these conditions are in good agreement with one another and approximately equal to 0.05 s^–1. The K _M values for the duplex and SAM are 0.35 and 1.6 M, respectively. An analysis of single turnover kinetics (at limiting concentration of the 20-mer duplex) revealed the following characteristics of the BamHI MTase-dependent methylation of DNA. The value of rate constant of the DNA methylation step at the enzyme saturating concentration is on average 0.085 s^–1, which is only 1.6 times higher than the value determined in steady-state conditions. Only one of two target cytidine residues was methylated in a single turnover of the enzyme, which coincides with the earlier data on EcoRI MTase. Regardless of the order of enzyme preincubation with SAM and DNA, both curves for the single turnover methylation are comparable. These results are consistent with the model of the random order of the productive ternary enzyme–substrate complex formation. In contrast to the relatively simple kinetic behavior of BamHI MTase in the steady-state reaction are the data on the enzyme binding with DNA. In gel retardation experiments, there was no stoichiometrically simple complex with the oligonucleotide duplex even at low enzyme concentrations. The molecular mass of the complexes was so high that they did not enter 12% PAG. In experiments on crosslinking of the BamHI MTase subunits, it was shown that the enzyme in a free state exists as a dimer. Introduction of substoichiometric amounts of DNA into the reaction mixture results in pronounced multimerization of the enzyme. However, addition of SAM in saturating concentration at an excess of the oligonucleotide duplex over BamHI MTase converts most of the enzyme into a monomeric state.     

Bacteriophage T4Dam (DNA-(adenine-N6)-methyltransferase): evidence for two distinct stages of methylation under single turnover conditions

We compared the (pre)steady-state and single turnover methylation kinetics of bacteriophage T4Dam (DNA-(adenine-N6)-methyltransferase)-mediated methyl group transfer from S-adenosyl-l-methionine (AdoMet) to oligodeoxynucleotide duplexes containing a single recognition site (palindrome 5'-GATC/5'-GATC) or some modified variant. T4Dam-AdoMet functions as a monomer under steady-state conditions (enzyme/DNA < 1), whereas under single turnover conditions (enzyme/DNA > 1), a catalytically active complex containing two Dam-AdoMet molecules is formed initially, and two methyl groups are transferred per duplex (to produce a methylated duplex and S-adenosyl-l-homocysteine (AdoHcy)). We propose that the single turnover reaction proceeds in two stages. First, two preformed T4Dam-AdoMet complexes bind opposite strands of the unmodified target site, and one enzyme molecule catalyzes the rapid transfer of the AdoMet-methyl group (kmeth1 = 0.21 s-1); this is 2.5-fold slower than the rate observed with monomeric T4Dam-AdoMet bound under pre-steady-state conditions for burst determination. In the second stage, methyl transfer to adenine in GATC on the complementary strand occurs at a rate that is 1 order of magnitude slower (kmeth2 = 0.023 s-1). We suggest that under single turnover conditions, methylation of the second strand is rate-limited by Dam-AdoHcy dissociation or its clearance from the methylated complementary strand. The hemimethylated duplex 5'-GATC/5'-GMTC also interacts with T4Dam-AdoMet complexes in two stages under single turnover reaction conditions. The first stage (kmeth1) reflects methylation by dimeric T4Dam-AdoMet productively oriented to the strand with the adenine residue capable of methylation. The slower second stage (kmeth2) reflects methylation by enzyme molecules non-productively oriented to the GMTC chain, which then have to re-orient to the opposite productive chain. Substitutions of bases and deletions in the recognition site affect the kinetic parameters in different fashions. When the GAT portion of GATC was disrupted, the proportion of the initial productive enzyme-substrate complexes was sharply reduced.     

The Role of the Methyltransferase Domain of Bifunctional Restriction Enzyme RM.BpuSI in Cleavage Activity

Restriction enzyme (REase) RM.BpuSI can be described as a Type IIS/C/G REase for its cleavage site outside of the recognition sequence (Type IIS), bifunctional polypeptide possessing both methyltransferase (MTase) and endonuclease activities (Type IIC) and endonuclease activity stimulated by S-adenosyl-L-methionine (SAM) (Type IIG). The stimulatory effect of SAM on cleavage activity presents a major paradox: a co-factor of the MTase activity that renders the substrate unsusceptible to cleavage enhances the cleavage activity. Here we show that the RM.BpuSI MTase activity modifies both cleavage substrate and product only when they are unmethylated. The MTase activity is, however, much lower than that of M1.BpuSI and is thought not to be the major MTase for host DNA protection. SAM and sinefungin (SIN) increase the V_max of the RM.BpuSI cleavage activity with a proportional change in K_m, suggesting the presence of an energetically more favorable pathway is taken. We further showed that RM.BpuSI undergoes substantial conformational changes in the presence of Ca²⁺, SIN, cleavage substrate and/or product. Distinct conformers are inferred as the pre-cleavage/cleavage state (in the presence of Ca²⁺, substrate or both) and MTase state (in the presence of SIN and substrate, SIN and product or product alone). Interestingly, RM.BpuSI adopts a unique conformation when only SIN is present. This SIN-bound state is inferred as a branch point for cleavage and MTase activity and an intermediate to an energetically favorable pathway for cleavage, probably through increasing the binding affinity of the substrate to the enzyme under cleavage conditions. Mutation of a SAM-binding residue resulted in altered conformational changes in the presence of substrate or Ca²⁺ and eliminated cleavage activity. The present study underscores the role of the MTase domain as facilitator of efficient cleavage activity for RM.BpuSI.     

The kinetic mechanism of phage T4 DNA-[N6-adenine]-methyltransferase

Kinetic analysis of methyl group transfer from S-adenosyl-L-methionine (SAM) to the GATC recognition site catalyzed by the phage T4 DNA-[N6-adenine]-methyltransferase (MTase) [EC 2.1.1.72] showed that the reverse reaction is at least 500 times slower than the direct one. The overall pattern of product inhibition corresponds to an ordered steady-state mechanism following the sequence SAM decreases DNA decreases metDNA increases SAH increases (S-adenosyl-L-homocysteine). Pronounced inhibition was observed at high concentrations of the 20-meric substrate duplex, which may be attributed to formation of a dead-end complex MTase-SAH-DNA. In contrast, high SAM concentrations proportionally accelerated the reaction. Thus, the reaction may include a stage whereby the binding of SAM and the release of SAH are united into one concerted event. Computer fitting of alternative kinetic schemes to the aggregate of experimental data revealed that the most plausible mechanism involves isomerization of the enzyme.     

DNA-(N4-cytosine)-methyltransferase from Bacillus amyloliquefaciens: kinetic and substrate binding properties

Interaction of DNA-(N4-cytosine)-methyltransferase from the Bacillus amyloliquefaciens (BamHI MTase, 49 kDa) with a 20-mer oligonucleotide duplex containing the palindrome recognition site GGATCC was studied by methods of steady-state and presteady-state kinetics of the methyl group transfer, gel retardation, and crosslinking of the enzyme subunits with glutaric aldehyde. In steady-state conditions, BamHI MTase displays a simple kinetic behavior toward a 20-mer oligonucleotide substrate. A linear dependence was observed for the reaction rate on the enzyme concentration and a Michaelis dependence of the reaction rate on the concentration of both substrates: S-adenosyl-L-methionine (SAM), the methyl group donor, and DNA, the methyl group acceptor. In independent experiments, the concentration of the 20-mer duplex or SAM was changed, the enzyme concentration being substantially lower then the concentrations of substrates. The kcat values determined in these conditions are in good agreement with one another and approximately equal to 0.05 s-1. The Km values for the duplex and SAM are 0.35 and 1.6 microM, respectively. An analysis of single turnover kinetics (at limiting concentration of the 20-mer oligonucleotide duplex) revealed the following characteristics of the BamHI MTase-dependent methylation of DNA. The value of rate constant of the DNA methylation step at the enzyme saturating concentration is on average 0.085 s-1, which is only 1.6 times higher than the value determined in steady-state conditions. Only one of two target cytidine residues was methylated in the course of the enzyme single turnover, which coincides with the earlier data on EcoRI MTase. Regardless of the order of the enzyme preincubation with SAM and DNA, both curves for the single turnover methylation are comparable. These results are consistent with the model of the random order of the productive ternary enzyme-substrate complex formation. In contrast to the relatively simple kinetic behavior of BamHI MTase in the steady-state reaction are the data on the enzyme binding of DNA. In gel retardation experiments, there was no stoichiometrically simple complexes with the oligonucleotide duplex even at low enzyme concentrations. The molecular mass of the complexes was so high that they did not enter 12% PAG. In experiments on crosslinking of the BamHI MTase subunits, it was shown that the enzyme in a free state exists as a dimer. Introduction of substoichiometric amounts of DNA into the reaction mixture results in pronounced multimerization of the enzyme. However, addition of SAM in saturating concentration at an excess of the oligonucleotide duplex over BamHI MTase converts most of the enzyme into a monomeric state.     

The Kinetic Mechanism of Phage T4 DNA-[N6-Adenine]-Methyltransferase

Kinetic analysis of methyl group transfer from S-adenosyl-L-methionine (SAM) to the GATC recognition site catalyzed by the phage T4 DNA-[N6-adenine]-methyltransferase (MTase) [EC 2.1.1.72] showed that the reverse reaction is at least 500 times slower than the direct one. The overall pattern of product inhibition corresponds to an ordered steady-state mechanism following the sequence SAMDNAmetDNASAH (S-adenosyl-L-homocysteine). Pronounced inhibition was observed at high concentrations of the 20-meric substrate duplex, which may be attributed to formation of a dead-end complex MTase–SAH–DNA. In contrast, high SAM concentrations proportionally accelerated the reaction. Thus, the reaction may include a stage whereby the binding of SAM and the release of SAH are united into one concerted event. Computer fitting of alternative kinetic schemes to the aggregate of experimental data revealed that the most plausible mechanism involves isomerization of the enzyme.     

DNA (cytosine-N4-)- and -(adenine-N6-)-methyltransferases have different kinetic mechanisms but the same reaction route. A comparison of M.BamHI and T4 Dam

We studied the kinetics of methyl group transfer by the BamHI DNA-(cytosine-N(4)-)-methyltransferase (MTase) from Bacillus amyloliquefaciens to a 20-mer oligodeoxynucleotide duplex containing the palindromic recognition site GGATCC. Under steady state conditions the BamHI MTase displayed a simple kinetic behavior toward the 20-mer duplex. There was no apparent substrate inhibition at concentrations much higher than the K(m) for either DNA (100-fold higher) or S-adenosyl-l-methionine (AdoMet) (20-fold higher); this indicates that dead-end complexes did not form in the course of the methylation reaction. The DNA methylation rate was analyzed as a function of both substrate and product concentrations. It was found to exhibit product inhibition patterns consistent with a steady state random bi-bi mechanism in which the dominant order of substrate binding and product release (methylated DNA, DNA(Me), and S-adenosyl-l-homocysteine, AdoHcy) was Ado-Met DNA DNA(Me) AdoHcy. The M.BamHI kinetic scheme was compared with that for the T4 Dam (adenine-N(6)-)-MTase. The two differed with respect to an effector action of substrates and in the rate-limiting step of the reaction (product inhibition patterns are the same for the both MTases). From this we conclude that the common chemical step in the methylation reaction, methyl transfer from AdoMet to a free exocyclic amino group, is not sufficient to dictate a common kinetic scheme even though both MTases follow the same reaction route.     

Highly conserved glycine 86 and arginine 87 residues contribute differently to the structure and activity of the mature HIV‐1 protease

The structural and functional role of conserved residue G86 in HIV‐1 protease (PR) was investigated by NMR and crystallographic analyses of substitution mutations of glycine to alanine and serine (PR_G86A and PR_G86S). While PR_G86S had undetectable catalytic activity, PR_G86A exhibited ～6000‐fold lower catalytic activity than PR. ¹H‐¹⁵N NMR correlation spectra revealed that PR_G86A and PR_G86S are dimeric, exhibiting dimer dissociation constants (K_d) of ～0.5 and ～3.2 μM, respectively, which are significantly lower than that seen for PR with R87K mutation (K_d > 1 mM). Thus, the G86 mutants, despite being partially dimeric under the assay conditions, are defective in catalyzing substrate hydrolysis. NMR spectra revealed no changes in the chemical shifts even in the presence of excess substrate, indicating very poor binding of the substrate. Both NMR chemical shift data and crystal structures of PR_G86A and PR_G86S in the presence of active‐site inhibitors indicated high structural similarity to previously described PR/inhibitor complexes, except for specific perturbations within the active site loop and around the mutation site. The crystal structures in the presence of the inhibitor showed that the region around residue 86 was connected to the active site by a conserved network of hydrogen bonds, and the two regions moved further apart in the mutants. Overall, in contrast to the role of R87 in contributing significantly to the dimer stability of PR, G86 is likely to play an important role in maintaining the correct geometry of the active site loop in the PR dimer for substrate binding and hydrolysis. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

Studies of DNA dumbbells. IV. Preparation and melting of a DNA dumbbell with the 16 base-pair sequence 5′G-T-A-T-C-C-C-T-C-T-G-G-A-T-A-C3′ linked on the ends by dodecyl chains

The preparation and melting of a 16 base-pair duplex DNA linked on both ends by C¹²H²⁴ (dodecyl) chains is described. Absorbance vs temperature curves (optical melting curves) were measured for the dodecyl-linked molecule and the same duplex molecule linked on the ends instead by T₄ loops. Optical melting curves of both molecules were measured in 25, 55, and 85 mM Na⁺ and revealed, regardless of [Na ⁺], the duplex linked by dodecyl loops is more stable by at least 6°C than the same duplex linked by T₄ loops. Experimental curves in each salt environment were analyzed in terms of the two-state and multistate theoretical models. In the two-state, or van't Hoff analysis, the melting transition is assumed to occur in an all-or-none manner. Thus, the only possible states accessible to the molecule throughout the melting transition are the completely intact duplex and the completely melted duplex or minicircle. In the multistate analysis no assumptions regarding the melting transition are required and the statistical occurrence of every possible partially melted state of the duplex is explicitly considered. Results of the analysis revealed the melting transitions of both the dodecyl-linked molecule and the dumbbell with T₄ end loops are essentially two state in 25 and 55 mM Na⁺. In contrast, significant deviations from two-state behavior were observed in 85 m MNa⁺. From our previously published melting data of DNA dumbbells with T_n end loops where n = 2, 3, 4, 6, 8, 10, 14 [T. M. Paner, M. Amaratunga, and A. S. Benight, (1992) Biopolymers, Vol. 32, pp. 881–892] and the dumbbell with T₄ end loops of this study, a plot of d(T_m)/d ln [Na⁺] was constructed. Extrapolation of this data to n = 1 intersects with the value of d (T_m)/d ln [Na⁺] obtained for the alkyl-linked dumbbell, suggesting the salt-dependent stability of the alkyl-linked molecule behaves as though the duplex of this molecule were linked by end loops comprised of a single T residue. © 1993 John Wiley & Sons, Inc.     

DNA Duplexes Containing Altered Sugar Residues as Probes of EcoRII and MvaI Endonuclease Interactions with Sugar-Phosphate Backbone

Abstract

Oligonucleotides containing 1-(β-D-2′-deoxy-threo-pentofuranosyl)cytosine (dCx) and/or 1-(β-D-2′-deoxy-threo-pentofuranosyl)thymine (dT_x) in place of dC and dT residues in the EcoRII and MvaI recognition site CC^A/_TGG were synthesized in order to investigate specific recognition of the DNA sugar-phosphate backbone by EcoRII and MvaI restriction endonucleases. In 2′-deoxyxylosyl moieties of dC_x and dT_x, 3′-hydroxyl groups were inverted, which perturbs the related individual phosphates. Introduction of a single 2′-deoxyxylo-syl moiety into a dC·dG pair resulted in a minor destabilization of double-stranded DNA structure. In the case of a dA·dT pair the effect of a 2′-deoxyxylose incorporation was much more pronounced. Multiple dC_x modifications and their combination with dT_x did not enhance the destabilization effect. Hydrolysis of dC_x-containing DNA duplexes by EcoRII endonuclease was blocked and binding affinity was strongly depended on the location of an altered sugar. A DNA duplex containing a dT_x residue was cleaved by the enzyme, but k_cat/K_M was slightly reduced. In contrast, MvaI endonuclease efficiently cleaved both types of sugar-altered substrate analogs. However it did not cleave conformationally perturbed scissile bonds, when the corresponding unmodified bonds were perfectly hydrolyzed in the same DNA duplexes. Based on these data the possible contributions of individual phosphates in the recognition site to substrate recognition and catalysis by EcoRII were proposed. We observed strikingly non-equivalent inputs for different phosphates with respect to their effect on EcoRII-DNA complex formation.     

Effect of pH on the Steady State Kinetics of Bovine Heart NADH: Coenzyme Q Oxidoreductase

Complete initial steady state kinetics of NADH-decylubiquinone (DQ) oxidoreductase reaction between pH 6.5 and 9.0 show an ordered sequential mechanism in which the order of substrate bindings and product releases is NADH-DQ–DQH₂-NAD⁺. NADH binding to the free enzyme is accelerated by protonation of an amino acid (possibly a histidine) residue. The NADH release is negligibly slow under the turnover conditions. The rate of DQ binding to the NADH-bound enzyme and the maximal rate at the saturating concentrations of the two substrates, which is determined by the rates of DQH₂ formation in the active site and releases of DQH₂ and NAD⁺ from the enzyme, are insensitive to pH, in contrast to clear pH dependencies of the maximal rates of cytochrome c oxidase and cytochrome bc ₁ complex. Physiological significances of these results are discussed.     

Structural features promoting dioxygen production by Dechloromonas aromatica chlorite dismutase

Chlorite dismutase (Cld) is a heme enzyme capable of rapidly and selectively decomposing chlorite (ClO₂ ⁻) to Cl⁻ and O₂. The ability of Cld to promote O₂ formation from ClO₂ ⁻ is unusual. Heme enzymes generally utilize ClO₂ ⁻ as an oxidant for reactions such as oxygen atom transfer to, or halogenation of, a second substrate. The X-ray crystal structure of Dechloromonas aromatica Cld co-crystallized with the substrate analogue nitrite (NO₂ ⁻) was determined to investigate features responsible for this novel reactivity. The enzyme active site contains a single b-type heme coordinated by a proximal histidine residue. Structural analysis identified a glutamate residue hydrogen-bonded to the heme proximal histidine that may stabilize reactive heme species. A solvent-exposed arginine residue likely gates substrate entry to a tightly confined distal pocket. On the basis of the proposed mechanism of Cld, initial reaction of ClO₂ ⁻ within the distal pocket generates hypochlorite (ClO⁻) and a compound I intermediate. The sterically restrictive distal pocket probably facilitates the rapid rebound of ClO⁻ with compound I forming the Cl⁻ and O₂ products. Common to other heme enzymes, Cld is inactivated after a finite number of turnovers, potentially via the observed formation of an off-pathway tryptophanyl radical species through electron migration to compound I. Three tryptophan residues of Cld have been identified as candidates for this off-pathway radical. Finally, a juxtaposition of hydrophobic residues between the distal pocket and the enzyme surface suggests O₂ may have a preferential direction for exiting the active site.     

Active site analysis of fructosyl amine oxidase using homology modeling and site-directed mutagenesis

A three-dimensional structural model of fructosyl amine oxidase from the marine yeast Pichia N1-1 was generated using the crystal structure of monomeric sarcosine oxidase from Bacillus sp. B-0618 as template. The putative active site region was investigated by site-directed mutagenesis, identifying several amino acid residues likely playing important roles in the enzyme reaction. Asn354 was identified as a residue that plays an important role in substrate recognition and that can be substituted in order to change substrate specificity while maintaining high catalytic activity. While the Asn354Ala substitution had no effect on the V _max K _m⁻¹ value for fructosyl valine, the V _max K _m⁻¹ value for fructosyl-^ε N-lysine was decreased 3-fold, thus resulting in a 3-fold improvement in specificity for fructosyl valine over fructosyl-^ε N-lysine.     

Modification of aldehyde dehydrogenase with dicyclohexylcarbodiimide: Separation of dehydrogenase from esterase activity

Dehydrogenase activity of the cytoplasmic (E1) isozyme of human liver aldehyde dehydrogenase (EC 1.2.1.3) was almost totally abolished (3% activity remaining) by preincubation with dicyclohexylcarbodiimide (DCC), while esterase activity with p-nitrophenyl acetate as substrate remained intact. The esterase reaction of the modified enzyme exhibited a hysteretic burst prior to achieving steady-state velocity; addition of NAD⁺ abolished the burst. TheK _m for p-nitrophenyl acetate was increased, but physicochemical properties remained unchanged. The selective inactivation of dehydrogenase activity was the result of covalent bond formation. Protection by NAD⁺ and chloral, saturation kinetics, and the stoichiometry and specificity of interaction indicated that the reaction of DCC occurred at the active site of the E1 isozyme. The results suggested that some amino acid other than aspartate or glutamate, possibly a cysteine residue, located on a large tryptic peptide of the E1 enzyme, may have reacted with DCC.     

Structural and functional insights into the molecular mechanism of rRNA m6A methyltransferase RlmJ

RlmJ catalyzes the m⁶A2030 methylation of 23S rRNA during ribosome biogenesis in Escherichia coli. Here, we present crystal structures of RlmJ in apo form, in complex with the cofactor S-adenosyl-methionine and in complex with S-adenosyl-homocysteine plus the substrate analogue adenosine monophosphate (AMP). RlmJ displays a variant of the Rossmann-like methyltransferase (MTase) fold with an inserted helical subdomain. Binding of cofactor and substrate induces a large shift of the N-terminal motif X tail to make it cover the cofactor binding site and trigger active-site changes in motifs IV and VIII. Adenosine monophosphate binds in a partly accommodated state with the target N6 atom 7 Å away from the sulphur of AdoHcy. The active site of RlmJ with motif IV sequence ₁₆₄DPPY₁₆₇ is more similar to DNA m⁶A MTases than to RNA m⁶₂A MTases, and structural comparison suggests that RlmJ binds its substrate base similarly to DNA MTases T4Dam and M.TaqI. RlmJ methylates in vitro transcribed 23S rRNA, as well as a minimal substrate corresponding to helix 72, demonstrating independence of previous modifications and tertiary interactions in the RNA substrate. RlmJ displays specificity for adenosine, and mutagenesis experiments demonstrate the critical roles of residues Y4, H6, K18 and D164 in methyl transfer.     

Potential anti‐bacterial drug target: Structural characterization of 3,4‐dihydroxy‐2‐butanone‐4‐phosphate synthase from Salmonella typhimurium LT2

3,4‐Dihydroxy‐2‐butanone‐4‐phosphate synthase (DHBPS) encoded by ribB gene is one of the first enzymes in riboflavin biosynthesis pathway and catalyzes the conversion of ribulose‐5‐phosphate (Ru5P) to 3,4‐dihydroxy‐2‐butanone‐4‐phosphate and formate. DHBPS is an attractive target for developing anti‐bacterial drugs as this enzyme is essential for pathogens, but absent in humans. The recombinant DHBPS enzyme of Salmonella requires magnesium ion for its activity and catalyzes the formation of 3,4‐dihydroxy‐2‐butanone‐4‐phosphate from Ru5P at a rate of 199 nmol min^?1 mg^?1 with K_m value of 116 μM at 37°C. Further, we have determined the crystal structures of Salmonella DHBPS in complex with sulfate, Ru5P and sulfate‐zinc ion at a resolution of 2.80, 2.52, and 1.86 Å, respectively. Analysis of these crystal structures reveals that the acidic loop (residues 34–39) responsible for the acid‐base catalysis is disordered in the absence of substrate or metal ion at the active site. Upon binding either substrate or sulfate and metal ions, the acidic loop becomes stabilized, adopts a closed conformation and interacts with the substrate. Our structure for the first time reveals that binding of substrate Ru5P alone is sufficient for the stabilization of the acidic active site loop into a closed conformation. In addition, the Glu38 residue from the acidic active site loop undergoes a conformational change upon Ru5P binding, which helps in positioning the second metal ion that stabilizes the Ru5P and the reaction intermediates. This is the first structural report of DHBPS in complex with either substrate or metal ion from any eubacteria. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

<Emphasis Type="Italic">Paracoccus denitrificans</Emphasis> proton-translocating ATPase: Kinetics of oxidative phosphorylation

The initial rates of ATP synthesis catalyzed by tightly coupled Paracoccus denitrificans plasma membrane were measured. The reaction rate was hyperbolically dependent on the substrates, ADP and inorganic phosphate (P_i). Apparent K _m values for ADP and P_i were 7–11 and 60–120 μM, respectively, at saturating concentration of the second substrate (pH 8.0, saturating Mg²⁺). These values were dependent on coupling efficiency. The substrate binding in the ATP synthesis reaction proceeds randomly: K _m value for a given substrate was independent of the concentration of the other one. A decrease of electrochemical proton gradient by the addition of malonate (when succinate served as the respiratory substrate) or by a decrease of steady-state level of NADH (when NADH served as the respiratory substrate) resulted in a proportional decrease of the maximal rates and apparent K _m values for ADP and P_i (double substitution, ping-pong mechanism). The kinetic scheme for ATP synthesis was compared with that described previously for the proton-translocating ATP hydrolysis catalyzed by the same enzyme preparation (T. V. Zharova and A. D. Vinogradov (2006) Biochemistry, 45, 14552–14558).     

An examination of structural interactions presumed to be of importance in the stabilization of phospholipase A2 dimers based upon comparative protein sequence analysis of a monomeric and dimeric enzyme from the venom ofAgkistrodon p. piscivorus

Phospholipases A₂ may exist in solution both as monomers and dimers, but enzymes that form strong dimers (K _D approximately 10^–9 M) have been found, thus far, only in venoms of the snake family Crotilidae. The complete amino acid sequences of a basic monomeric and an acidic dimeric phospholipase A₂ fromAgkistrodon piscivorus piscivorus (American cotton-mouth water moccasin) venom have been determined by protein sequencing methods as part of a search for aspects of structure contributing to formation of stable dimers. Both the monomeric and dimeric phospholipases A₂ are highly homologous to the dimeric phospholipases A₂ fromCrotalus atrox andCrotalus adamanteus venoms, and both have the seven residue carboxy-terminal extension characteristic of the crotalid and viperid enzymes. Thus, it is clear that the extension is not a prerequisite for dimerization. Studies to date have revealed two characteristic features of phosphilipases A₂ that exist in solution as strong dimers. One is the presence in the dimers of a Pro-Pro sequence at position 112 and 113 which just precedes the seven residue carboxy-terminal extension (residues 116–122). The other is a low isoelectric point; only the acidic phospholipases A₂ have been observed, thus far, to form stable dimers. These, alone or together, may be necessary, though not sufficient conditions for phospholipase A₂ dimer formation. Ideas regarding subunit interactions based upon crystallographic data are evaluated relative to the new sequence information on the monomeric and dimeric phospholipases A₂ fromA. p. piscivorus venom.     

Formation of CO2 from the carboxyl group of S-adenosylmethionine by liver membrane-associated enzymes involves the demethylation-transsulphuration pathway

The activity released from membrane fragments into the supernatant fraction of rat liver homogenate by Triton X-100 and forming ¹⁴CO₂ from carboxyl-labeled S-adenosylmethionine (1) is not a true S-adenosylmethionine decarboxylase. It did not produce decarboxylated S-adenosylmethionine but was also able to use S-adenosylhomocysteine as a substrate. The formation of CO₂ from these two substrates was absolutely dependent on the presence of cytosol proteins and low-molecular weight compounds and it accounted for 5 to 10% of the total S-adenosylmethionine degrading activity of the supernatant fraction. The reaction showed abn initial lag period and was inhibited by every intermediate of the transsulphuration pathway. It is concluded that the formation of CO₂ from S-adenosylmethionine involves the demethylation-transsulphuration route from S-adenosylmethionine to α-ketobutyric acid which is finally decarboxylated.