Mutations in the active site of Escherichia coli phosphofructokinase

The 6-phosphofructokinase reaction in Acetivibrio thermocellus is both ATP- and pyrophosphate-dependent

Acetivibrio thermocellus (formerly Clostridium thermocellum) is a potential platform for lignocellulosic ethanol production. Its industrial application is hampered by low product titres, resulting from a low thermodynamic driving force of its central metabolism. It possesses both a functional ATP- and a functional PPi-dependent 6-phosphofructokinase (PPi-Pfk), of which only the latter is held responsible for the low driving force. Here we show that, following the replacement of PPi-Pfk by cytosolic pyrophosphatase and transaldolase, the native ATP-Pfk is able to carry the full glycolytic flux. Interestingly, the barely-detectable in vitro ATP-Pfk activities are only a fraction of what would be required, indicating its contribution to glycolysis has consistently been underestimated. A kinetic model demonstrated that the strong inhibition of ATP-Pfk by PPi can prevent futile cycling that would arise when both enzymes are active simultaneously. As such, there seems to be no need for a long-sought-after PPi-generating mechanism to drive glycolysis, as PPi-Pfk can simply use whatever PPi is available, and ATP-Pfk complements the rest of the PFK-flux. Laboratory evolution of the ΔPPi-Pfk strain, unable to valorize PPi, resulted in a mutation in the GreA transcription elongation factor. This mutation likely results in reduced RNA-turnover, hinting at transcription as a significant (and underestimated) source of anabolic PPi. Together with other mutations, this resulted in an A. thermocellus strain with the hitherto highest biomass-specific cellobiose uptake rate of 2.2 g/gx/h. These findings are both relevant for fundamental insight into dual ATP/PPi Pfk-nodes, which are not uncommon in other microorganisms, as well as for further engineering of A. thermocellus for consolidated bioprocessing.

Phosphofructokinases A and B from Mycobacterium tuberculosis Display Different Catalytic Properties and Allosteric Regulation

Tuberculosis (TB) remains one of the major health concerns worldwide. Mycobacterium tuberculosis (Mtb), the causative agent of TB, can flexibly change its metabolic processes during different life stages. Regulation of key metabolic enzyme activities by intracellular conditions, allosteric inhibition or feedback control can effectively contribute to Mtb survival under different conditions. Phosphofructokinase (Pfk) is one of the key enzymes regulating glycolysis. Mtb encodes two Pfk isoenzymes, Pfk A/Rv3010c and Pfk B/Rv2029c, which are differently expressed upon transition to the hypoxia-induced non-replicating state of the bacteria. While pfkB gene and protein expression are upregulated under hypoxic conditions, Pfk A levels decrease. Here, we present biochemical characterization of both Pfk isoenzymes, revealing that Pfk A and Pfk B display different kinetic properties. Although the glycolytic activity of Pfk A is higher than that of Pfk B, it is markedly inhibited by an excess of both substrates (fructose-6-phosphate and ATP), reaction products (fructose-1,6-bisphosphate and ADP) and common metabolic allosteric regulators. In contrast, synthesis of fructose-1,6-bisphosphatase catalyzed by Pfk B is not regulated by higher levels of substrates, and metabolites. Importantly, we found that only Pfk B can catalyze the reverse gluconeogenic reaction. Pfk B thus can support glycolysis under conditions inhibiting Pfk A function.

The Planktonic Core Microbiome and Core Functions in the Cattle Rumen by Next Generation Sequencing

The cow rumen harbors a great variety of diverse microbes, which form a complex, organized community. Understanding the behavior of this multifarious network is crucial in improving ruminant nutrient use efficiency. The aim of this study was to expand our knowledge by examining 10 Holstein dairy cow rumen fluid fraction whole metagenome and transcriptome datasets. DNA and mRNA sequence data, generated by Ion Torrent, was subjected to quality control and filtering before analysis for core elements. The taxonomic core microbiome consisted of 48 genera belonging to Bacteria (47) and Archaea (1). The genus Prevotella predominated the planktonic core community. Core functional groups were identified using co-occurrence analysis and resulted in 587 genes, from which 62 could be assigned to metabolic functions. Although this was a minimal functional core, it revealed key enzymes participating in various metabolic processes. A diverse and rich collection of enzymes involved in carbohydrate metabolism and other functions were identified. Transcripts coding for enzymes active in methanogenesis made up 1% of the core functions. The genera associated with the core enzyme functions were also identified. Linking genera to functions showed that the main metabolic pathways are primarily provided by Bacteria and several genera may serve as a “back-up” team for the central functions. The key actors in most essential metabolic routes belong to the genus Prevotella. Confirming earlier studies, the genus Methanobrevibacter carries out the overwhelming majority of rumen methanogenesis and therefore methane emission mitigation seems conceivable via targeting the hydrogenotrophic methanogenesis.

Metabolite profiling and associated gene expression reveal two metabolic shifts during the seed-to-seedling transition in Arabidopsis thaliana

Metabolic and transcriptomic correlation analysis identified two distinctive profiles involved in the metabolic preparation for seed germination and seedling establishment, respectively. Transcripts were identified that may control metabolic fluxes. The transition from a quiescent metabolic state (dry seed) to the active state of a vigorous seedling is crucial in the plant's life cycle. We analysed this complex physiological trait by measuring the changes in primary metabolism that occur during the transition in order to determine which metabolic networks are operational. The transition involves several developmental stages from seed germination to seedling establishment, i.e. between imbibition of the mature dry seed and opening of the cotyledons, the final stage of seedling establishment. We hypothesized that the advancement of growth is associated with certain signature metabolite profiles. Metabolite-metabolite correlation analysis underlined two specific profiles which appear to be involved in the metabolic preparation for seed germination and efficient seedling establishment, respectively. Metabolite profiles were also compared to transcript profiles and although transcriptional changes did not always equate to a proportional metabolic response, in depth correlation analysis identified several transcripts that may directly influence the flux through metabolic pathways during the seed-to-seedling transition. This correlation analysis also pinpointed metabolic pathways which are significant for the seed-to-seedling transition, and metabolite contents that appeared to be controlled directly by transcript abundance. This global view of the transcriptional and metabolic changes during the seed-to-seedling transition in Arabidopsis opens up new perspectives for understanding the complex regulatory mechanism underlying this transition.

Evolution of the genetic code by incorporation of amino acids that improved or changed protein function

Fifty years have passed since the genetic code was deciphered, but how the genetic code came into being has not been satisfactorily addressed. It is now widely accepted that the earliest genetic code did not encode all 20 amino acids found in the universal genetic code as some amino acids have complex biosynthetic pathways and likely were not available from the environment. Therefore, the genetic code evolved as pathways for synthesis of new amino acids became available. One hypothesis proposes that early in the evolution of the genetic code four amino acids-valine, alanine, aspartic acid, and glycine-were coded by GNC codons (N = any base) with the remaining codons being nonsense codons. The other sixteen amino acids were subsequently added to the genetic code by changing nonsense codons into sense codons for these amino acids. Improvement in protein function is presumed to be the driving force behind the evolution of the code, but how improved function was achieved by adding amino acids has not been examined. Based on an analysis of amino acid function in proteins, an evolutionary mechanism for expansion of the genetic code is described in which individual coded amino acids were replaced by new amino acids that used nonsense codons differing by one base change from the sense codons previously used. The improved or altered protein function afforded by the changes in amino acid function provided the selective advantage underlying the expansion of the genetic code. Analysis of amino acid properties and functions explains why amino acids are found in their respective positions in the genetic code.

Blocking the butyrate-formation pathway impairs hydrogen production in Clostridium perfringens

Inactivating competitive pathways will improve fermentative hydrogen production by obligate anaerobes, such as those of genus Clostridium. In our previous study, the hydrogen yield of Clostridium perfringens W13 in which l-lactate dehydrogenase was inactivated increased by 44% when compared with its original strain W12. In this study, we explored whether blocking butyrate formation pathway would increase hydrogen yield. The acetyl-CoA acetyltransferase gene (atoB) encodes the first enzyme in this pathway, which ultimately forms butyrate. Clostridium perfringens W14 and W15 were constructed by inactivating atoB in W13 and W12, respectively. The hydrogen yield of W14 and W15 was 44% and 33% of those of W13 and W12, respectively. Inactivation of atoB decreased the pyruvate synthesis and its conversion to acetyl-CoA in both mutants, and increased ethanol formation in W14 and W15. Proteomic analysis revealed that the expressions of five proteins involved in butyrate formation pathway were up-regulated in W14. Our results suggest that butyrate formation deficiency improved ethanol production but not hydrogen production, indicating the importance of butyrate formation pathway for hydrogen production in C. perfringens.

Crystal structures of Staphylococcus epidermidis mevalonate diphosphate decarboxylase bound to inhibitory analogs reveal new insight into substrate binding and catalysis

The polyisoprenoid compound undecaprenyl phosphate is required for biosynthesis of cell wall peptidoglycans in gram-positive bacteria, including pathogenic Enterococcus, Streptococcus, and Staphylococcus spp. In these organisms, the mevalonate pathway is used to produce the precursor isoprenoid, isopentenyl 5-diphosphate. Mevalonate diphosphate decarboxylase (MDD) catalyzes formation of isopentenyl 5-diphosphate in an ATP-dependent irreversible reaction and is therefore an attractive target for inhibitor development that could lead to new antimicrobial agents. To facilitate exploration of this possibility, we report the crystal structure of Staphylococcus epidermidis MDD (1.85 Å resolution) and, to the best of our knowledge, the first structures of liganded MDD. These structures include MDD bound to the mevalonate 5-diphosphate analogs diphosphoglycolyl proline (2.05 Å resolution) and 6-fluoromevalonate diphosphate (FMVAPP; 2.2 Å resolution). Comparison of these structures provides a physical basis for the significant differences in K(i) values observed for these inhibitors. Inspection of enzyme/inhibitor structures identified the side chain of invariant Ser(192) as making potential contributions to catalysis. Significantly, Ser → Ala substitution of this side chain decreases k(cat) by ∼10(3)-fold, even though binding interactions between FMVAPP and this mutant are similar to those observed with wild type MDD, as judged by the 2.1 Å cocrystal structure of S192A with FMVAPP. Comparison of microbial MDD structures with those of mammalian counterparts reveals potential targets at the active site periphery that may be exploited to selectively target the microbial enzymes. These studies provide a structural basis for previous observations regarding the MDD mechanism and inform future work toward rational inhibitor design.

ADP-dependent 6-phosphofructokinase from Pyrococcus horikoshii OT3: structure determination and biochemical characterization of PH1645

Some hyperthermophilic archaea use a modified glycolytic pathway that employs an ADP-dependent glucokinase (ADP-GK) and an ADP-dependent phosphofructokinase (ADP-PFK) or, in the case of Methanococcus jannaschii, a bifunctional ADP-dependent glucophosphofructokinase (ADP-GK/PFK). The crystal structures of three ADP-GKs have been determined. However, there is no structural information available for ADP-PFKs or the ADP-GK/PFK. Here, we present the first crystal structure of an ADP-PFK from Pyrococcus horikoshii OT3 (PhPFK) in both apo- and AMP-bound forms determined to 2.0-A and 1.9-A resolution, respectively, along with biochemical characterization of the enzyme. The overall structure of PhPFK maintains a similar large and small alpha/beta domain structure seen in the ADP-GK structures. A large conformational change accompanies binding of phosphoryl donor, acceptor, or both, in all members of the ribokinase superfamily characterized thus far, which is believed to be critical to enzyme function. Surprisingly, no such conformational change was observed in the AMP-bound PhPFK structure compared with the apo structure. Through comprehensive site-directed mutagenesis of the substrate binding pocket we identified residues that were critical for both substrate recognition and the phosphotransfer reaction. The catalytic residues and many of the substrate binding residues are conserved between PhPFK and ADP-GKs; however, four key residues differ in the sugar-binding pocket, which we have shown determine the sugar-binding specificity. Using these results we were able to engineer a mutant PhPFK that mimics the ADP-GK/PFK and is able to phosphorylate both fructose 6-phosphate and glucose.

The crystal structure of ATP-bound phosphofructokinase from Trypanosoma brucei reveals conformational transitions different from those of other phosphofructokinases

The crystal structure of the ATP-bound form of the tetrameric phosphofructokinase (PFK) from Trypanosoma brucei enables detailed comparisons to be made with the structures of the apoenzyme form of the same enzyme, as well as with those of bacterial ATP-dependent and PP(i)-dependent PFKs. The active site of T. brucei PFK (which is strictly ATP-dependent but belongs to the PP(i)-dependent family by sequence similarities) is a chimera of the two types of PFK. In particular, the active site of T. brucei PFK possesses amino acid residues and structural features characteristic of both types of PFK. Conformational changes upon ATP binding are observed that include the opening of the active site to accommodate the two substrates, MgATP and fructose 6-phosphate, and a dramatic ordering of the C-terminal helices, which act like reaching arms to hold the tetramer together. These conformational transitions are fundamentally different from those of other ATP-dependent PFKs. The substantial differences in structure and mechanism of T. brucei PFK compared with bacterial and mammalian PFKs give optimism for the discovery of species-specific drugs for the treatment of diseases caused by protist parasites of the trypanosomatid family.

Crystal structure of YegS, a homologue to the mammalian diacylglycerol kinases, reveals a novel regulatory metal binding site

The human lipid kinase family controls cell proliferation, differentiation, and tumorigenesis and includes diacylglycerol kinases, sphingosine kinases, and ceramide kinases. YegS is an Escherichia coli protein with significant sequence homology to the catalytic domain of the human lipid kinases. We have solved the crystal structure of YegS and shown that it is a lipid kinase with phosphatidylglycerol kinase activity. The crystal structure reveals a two-domain protein with significant structural similarity to a family of NAD kinases. The active site is located in the interdomain cleft formed by four conserved sequence motifs. Surprisingly, the structure reveals a novel metal binding site composed of residues conserved in most lipid kinases.

Mutational analysis of the active-site residues crucial for catalytic activity of adenosine kinase from Leishmania donovani

Leishmania donovani adenosine kinase (LdAdK) plays a pivotal role in scavenging of purines from the host. Exploiting interspecies homology and structural co-ordinates of the enzyme from other sources, we generated a model of LdAdK that led us to target several amino acid residues (namely Gly-62, Arg-69, Arg-131 and Asp-299). Replacement of Gly-62 with aspartate caused a drastic reduction in catalytic activity, with decreased affinity for either substrate. Asp-299 was found to be catalytically indispensable. Mutation of either Arg-131 or Arg-69 caused a significant reduction in kcat. R69A (Arg-69-->Ala) and R131A mutants exhibited unaltered K(m) for either substrate, whereas ATP K(m) for R69K increased 6-fold. Importance of both of the arginine residues was reaffirmed by the R69K/R131A double mutant, which exhibited approx. 0.5% residual activity with a large increase in ATP K(m). Phenylglyoxal, which inhibits the wild-type enzyme, also inactivated the arginine mutants to different extents. Adenosine protected both of the Arg-69 mutants, but not the R131A variant, from inactivation. Binding experiments revealed that the AMP-binding property of R69K or R69A and D299A mutants remained largely unaltered, but R131A and R69K/R131A mutants lost their AMP binding ability significantly. The G62D mutant did not bind AMP at all. Free energy calculations indicated that Arg-69 and Arg-131 are functionally independent. Thus, apart from the mandatory requirement of flexibility around the diglycyl (Gly-61-Gly-62) motif, our results identified Asp-299 and Arg-131 as key catalytic residues, with the former functioning as the proton abstractor from the 5'-OH of adenosine, while the latter acts as a bidentate electrophile to stabilize the negative charge on the leaving group during the phosphate transfer. Moreover, the positive charge distribution of Arg-69 probably helps in maintaining the flexibility of the alpha-3 helix needed for proper domain movement. These findings provide the first comprehensive biochemical evidence implicating the mechanistic roles of the functionally important residues of this chemotherapeutically exploitable enzyme.

Site-directed mutagenesis of the active site of diacylglycerol kinase alpha: calcium and phosphatidylserine stimulate enzyme activity via distinct mechanisms

Diacylglycerol kinases (DAGKs) catalyse ATP-dependent phosphorylation of sn-1,2-diacylglycerol that arises during stimulated phosphatidylinositol turnover. DAGKa is activated in vitro by Ca2+ and by acidic phospholipids. The regulatory region of DAGKa includes an N-terminal RVH motif and EF hands that mediate Ca2+-dependent activation. DAGKa also contains tandem C1 protein kinase C homology domains. We utilized yeast, Saccharomyces cerevisiae, which lacks an endogenous DAGK, to express DAGKa and to determine the enzymic activities of different mutant forms of pig DAGKa in vitro. Six aspartate residues conserved in all DAGKs were individually examined by site-directed mutagenesis. Five of these aspartate residues reside in conserved blocks that correspond to sequences in the catalytic site of phosphofructokinases. Mutation of D434 (Asp434) or D650 abolished all DAGKa activity, whereas substitution of one among D465, D497, D529 and D697 decreased the activity to 6% or less of that for wild-type DAGKa. Roles of homologous residues in phosphofructokinases suggested that the N-terminal half of the DAGK catalytic domain binds Mg-ATP and the C-terminal half binds diacylglycerol. A DAGKa mutant with its entire regulatory region deleted showed a much decreased activity that was not activated by Ca2+, but still exhibited PS (phosphatidylserine)-dependent activation. Moreover, mutations of aspartate residues at the catalytic domain had differential effects on activation by Ca2+ and PS. These results indicate that Ca2+ and PS stimulate DAGKa via distinct mechanisms.

The structure of a pyrophosphate-dependent phosphofructokinase from the Lyme disease spirochete Borrelia burgdorferi

The structure of the 60 kDa pyrophosphate (PP(i))-dependent phosphofructokinase (PFK) from Borrelia burgdorferi has been solved and refined (R(free) = 0.243) at 2.55 A resolution. The domain structure of eubacterial ATP-dependent PFKs is conserved in B. burgdorferi PFK, and there are three large insertions relative to E. coli PFK, including a helical domain containing a hairpin structure that interacts with the active site. Asp177, conserved in all PP(i) PFKs, negates the binding of the alpha-phosphate group of ATP and likely contacts the essential Mg(2+) cation via a water molecule. Asn181 blocks the binding of the adenine moiety of ATP. Lys203 hydrogen bonds to a sulfate anion that likely mimics PP(i) substrate binding.

Kinetic analysis of yeast galactokinase: implications for transcriptional activation of the GAL genes

Galactokinase (EC 2.7.1.6) catalyses the first step in the catabolism of galactose. Yeast galactokinase, Gal1p, and the closely related but catalytically inactive Gal3p, also function as ligand sensors in the GAL genetic switch. In the presence of galactose and ATP (the substrates of the reaction catalysed by Gal1p) Gal1p or Gal3p can bind to Gal80p, a transcriptional repressor. This relieves the inhibition of a transcriptional activator, Gal4p, and permits expression of the GAL genes. In order to learn more about the mechanism of ligand sensing by Gal3p and Gal1p, we studied the kinetics of the reaction catalysed by Gal1p. Galactose-1-phosphate, a product of the reaction, is a mixed inhibitor both with respect to galactose and to ATP suggesting that the reaction proceeds via a compulsory, ordered, ternary complex mechanism. There is little variation in either the turnover number or the specificity constants in the pH range 6.0-9.5, implying that no catalytic base is required in the reaction. These data are discussed both in the context of galactokinase enzymology and their implications for the mechanism of transcriptional induction.

Structural basis for the feedback regulation of Escherichia coli pantothenate kinase by coenzyme A

Pantothenate kinase (PanK) is a key regulatory enzyme in the coenzyme A (CoA) biosynthetic pathway and catalyzes the phosphorylation of pantothenic acid to form phosphopantothenate. CoA is a feedback inhibitor of PanK activity by competitive binding to the ATP site. The structures of the Escherichia coli enzyme, in complex with a nonhydrolyzable analogue of ATP, 5'-adenylimido-diphosphate (AMPPNP), or with CoA, were determined at 2.6 and 2.5 A, respectively. Both structures show that two dimers occupy an asymmetric unit; each subunit has a alpha/beta mononucleotide-binding fold with an extensive antiparallel coiled coil formed by two long helices along the dimerization interface. The two ligands, AMPPNP and CoA, associate with PanK in very different ways, but their phosphate binding sites overlap, explaining the kinetic competition between CoA and ATP. Residues Asp(127), His(177), and Arg(243) are proposed to be involved in catalysis, based on modeling of the pentacoordinate transition state. The more potent inhibition by CoA, compared with the CoA thioesters, is explained by a tight interaction of the CoA thiol group with the side chains of aromatic residues, which is predicted to discriminate against the CoA thioesters. The PanK structure provides the framework for a more detailed understanding of the mechanism of catalysis and feedback regulation of PanK.

Site-directed mutagenesis of the fructose 6-phosphate binding site of the pyrophosphate-dependent phosphofructokinase of Entamoeba histolytica

Attempts to define the active site of pyrophosphate-dependent phosphofructokinase (PPi-PFK) using homology modeling based on the three-dimensional structure of the ATP-dependent PFKs from bacteria have been frustrated by low sequence identity between PPi- and ATP-PFKs in their carboxyl terminal halves. In the current study, alanine scanning mutagenesis of residues in the carboxyl terminal half of the PPi-PFK of Entamoeba histolytica coupled with comparative sequence analysis and computational modeling is used to identify residues that contribute to fructose 6-phosphate (fructose 6-P) binding. Of seven alanine mutants that were generated by site-directed mutagenesis, Arg377, Ser392, Arg405, Lys408, His415, His416, and Arg423, only the last mutant, Arg423Ala, was found to have dramatically lower affinity for fructose 6-P. Mutation of Arg 423 decreased k(cat) by 10,000-fold and decreased apparent affinity for fructose 6-P by 126-fold, while the K(m) for PPi increased only 4-fold. The second greatest effect was seen with Arg377Ala, which had a nearly 10-fold decrease in apparent affinity and an approximate 60-fold decrease in maximal activity. Another residue, Tyr420, was chosen for mutagenesis by its complete identity in all other PPi-PFK. This residue and its homologue in Escherichia coli ATP-PFK, His249, were mutated and shown to be very important for substrate binding in both enzymes.

The effect of monovalent ions on polyphosphate binding to Escherichia coli exopolyphosphatase

The thermodynamic driving force for the interaction of Escherichia coli exopolyphosphatase (PPX) with polyphosphate was investigated by varying salt choice and concentration. This interaction was found to be cation concentration independent but weakly dependent on the concentration of certain anions. Both of these traits are very uncommon for nonspecific protein-polyelectrolyte interactions. Interpretation of these results based on theory indicated that binding was not entropy driven due to release of polyelectrolyte-condensed counterions, as is the case for nearly all protein-polyelectrolyte interactions. The thermodynamics of the PPX-polyphosphate interaction showed similarity only to the interaction of polynucleotides with single stranded binding proteins.

Phosphoribulokinase: current perspectives on the structure/function basis for regulation and catalysis

Phosphoribulokinase (PRK), an enzyme unique to the reductive pentose phosphate pathway of CO2 assimilation, exhibits distinctive contrasting properties when the proteins from eukaryotic and prokaryotic sources are compared. The eukaryotic PRKs are typically dimers of -39 kDa subunits while the prokaryotic PRKs are octamers of -32 kDa subunits. The enzymes from these two classes are regulated by different mechanisms. Thioredoxin of mediated thiol-disulfide exchange interconverts eukaryotic PRKs between reduced (active) and oxidized (inactive) forms. Allosteric effectors, including activator NADH and inhibitors AMP and phosphoenolpyruvate, regulate activity of prokaryotic PRK. The effector binding site has been identified in the high resolution structure recently elucidated for prokaryotic PRK and the7 apparatus for transmission of the allosteric stimulus has been identified. Additional contrasts between PRKs include marked differences in primary structure between eukaryotic and prokaryotic PRKs. Alignment of all available deduced PRK sequences indicates that less than 10% of the amino acid residues are invariant. In contrast to these differences, the mechanism for ribulose 1,5-biphosphate synthesis from ATP and ribulose 5-phosphate (Ru5P) appears to be the same for all PRKs. Consensus sequences associated with M++-ATP binding, identified in all PRK proteins, are closely juxtaposed to the residue proposed to function as general base catalyst. Sequence homology and mutagenesis approaches have suggested several residues that may potentially function in Ru5P binding. Not all of these proposed Ru5P binding residues are closely juxtaposed in the structure of unliganded PRK. Mechanistic approaches have been employed to investigate the amino acids which influence K(m Ru5P) and identify those amino acids most directly involved in Ru5P binding. PRK is one member of a family of phospho or sulfo transferase proteins which exhibit a nucleotide monophosphate kinase fold. Structure/function correlations elucidated for PRK suggest analogous assignments for other members of this family of proteins.

Chemical modification of SH groups of E. coli phosphofructokinase-2 induces subunit dissociation: monomers are inactive but preserve ligand binding properties

Modification of Escherichia coli phosphofructokinase-2 (Pfk-2) with N-(1-pyrenil)maleimide results in an enzyme form that is inactive. However, the rate of modification is drastically reduced in the presence of the allosteric effector MgATP. The stoichiometry of the label incorporation was found to be 2.03 +/- 0.035 mol of the reagent/mol of subunit, in agreement with the number of titratable SH groups by 5,5'-dithiobis(2-nitrobenzoic acid) in the labeled protein. HPLC gel filtration experiments demonstrate that native Pfk-2 is a dimer in the absence of ligands, while in the presence of MgATP a dimer-tetramer transition is promoted. In contrast, the modified enzyme eluted as a monomer and the presence of MgATP was not able to induce aggregation. Although the modified monomers are inactive, the dissociation constants for the substrates and the allosteric effector MgATP, measured by following the fluorescence of the binding probe, are the same as for the native enzyme. Quenching of pyrene fluorescence emission of labeled phosphofructokinase-2 monomers by acrylamide gave downward curved Stern-Volmer plots, with very similar quenching efficiencies for the control and for the fructose-6-P and MgATP-enzyme complexes. These results show the presence of SH groups in the interface of Pfk-2 subunits, critical for subunit interactions, and that conformational changes occurring through the dimers are essential for catalytic activity.

An essential methionine residue involved in substrate binding by phosphofructokinases

An alignment of all PPi-dependent phosphofructokinases and all allosteric ATP-dependent PFKs shows relatively few residues that are fully conserved. One residue that is conserved is a methionine residue that appears from the crystal structure of Escherichia coli PFK to be interacting with fructose 6-P. Very conservative substitutions for this methionine with leucine or isoleucine by site-directed mutagenesis of E. coli ATP-PFK and Entamoeba histolytica PPi-PFK produced profound decreases either in the apparent affinity for fructose 6-P or in maximal velocity, or both. Methionine provides a highly specific interaction with fructose 6-P for binding and for transition state stabilization.

An ExeAB complex in the type II secretion pathway of Aeromonas hydrophila: effect of ATP-binding cassette mutations on complex formation and function

The energy-dependent secretion of aerolysin by Aeromonas hydrophila requires the ExeA and ExeB proteins. An 85 kDa complex containing the two proteins was identified in wild-type cells but not in cells producing either protein alone. Radiolabelling followed by cross-linking, immunoprecipitation and then reduction of the cross-links confirmed the presence of the two proteins in the same complex. The complex could also be extracted intact from cell membranes with non-ionic detergents. A G229D substitution in the kinase-3a motif of ExeA strongly reduced the level of aerolysin secretion, as did the replacement of the invariant Lys of the kinase-1a motif (K56) with Arg. The G229D mutant contained very little of the ExeA-ExeB complex, but overexpression of the mutant complex until wild-type levels were achieved allowed normal secretion. In contrast, the K56R mutation had no effect on complex formation, but normal secretion levels occurred only when there was a far greater amount of the complex present. These results are consistent with a model in which binding of ATP by ExeA is required for ExeA-ExeB complex formation, while hydrolysis is required for its function in secretion once established.

Conserved active site aspartates and domain-domain interactions in regulatory properties of the sugar kinase superfamily

The structures of the sugar kinase/heat shock 70/actin superfamily of enzymes show that the active site is located in a deep cleft between two domains whose relative movement defines a domain closure conformational change thought to be involved in the catalytic and regulatory properties of members of the superfamily. To investigate the role of the domain closure in the regulatory behavior, site-directed mutagenesis is used to alter specific domain-domain interactions in Escherichia coli glycerol kinase (EC 2.7.1.30; ATP:glycerol 3-phosphotransferase), a member of this superfamily. Two active site aspartate residues are conserved throughout the superfamily, one (Asp245 in glycerol kinase) which is proposed to act as a general base during catalysis and one (Asp10 in glycerol kinase) which interacts with the Mg(II) ion of the bound Mg(II)-nucleotide complex. Each of these residues participates in domain-domain interactions that are mediated by the bound substrates. The enzymes containing the substitutions Asp245 to Asn (D245N) or Asp10 to Asn (D10N) were purified by affinity chromatography, and the effects of the substitutions on the catalytic properties and regulation by the allosteric effectors, fructose 1,6-bisphosphate (FBP), and the glucose-specific phosphocarrier protein, IIIGlc (also known as IIAGlc), were determined. Each of the residues participates in catalysis; kcat/Katp is decreased 300-fold by the D245N substitution and 100-fold by the D10N substitution. Affinity labeling with the glycerol analog 1,3-dichloroacetone shows that the level of activity seen for the D245N mutant enzyme is not due to deamidation of the substituted asparagine. Each of the substitutions has little effect on regulation by FBP and the apparent affinity for IIIGlc, and the D245N substitution does not affect the extent of inhibition by IIIGlc. However, the D10N substitution decreases the maximum extent of inhibition by IIIGlc from 100 to 60%, thus changing the action of IIIGlc to that of a partial inhibitor. The different sensitivities of the extents of FBP and IIIGlc inhibition to perturbation of a domain-domain interaction mediated by Asp10 suggest that the relations of the actions of these allosteric effectors to the domain closure conformational change are different.

The active site of pyrophosphate-dependent phosphofructo-1-kinase based on site-directed mutagenesis and molecular modeling

Despite a low level of overall sequence identity between PPi-dependent and ATP-dependent phosphofructo-1-kinases (PFKs), similarities in active-site residues permit a convincing amino acid alignment of these two groups of kinases. Employing recent protein sequence and site-directed mutagenesis data along with the known three-dimensional coordinates of Escherichia coli ATP-dependent PFK, a model of the active site of PPi-dependent PFK was proposed. In addition to providing compatible placement of residues shown to be important by earlier mutagenesis studies, the model predicted an important role for two arginyl residues that are conserved in all known PPi-PFK sequences. Replacement by site-directed mutagenesis of these two residues with neutral amino acids in the PPi-PFK of Naegleria fowleri resulted in a substantial reduction in kcat while not altering the global structure of the enzyme. While the data indicate many similarities in the active-site structures and mechanisms of ATP-dependent and PPi-dependent PFKs, subtle differences, such as the relative roles of Arg residues in the active sites, have evolved in the development of these two subgroups of the PFK family.

Identification of catalytic residues in human mevalonate kinase

cDNA encoding human mevalonate kinase has been overexpressed and the recombinant enzyme isolated. This stable enzyme is a dimer of 42-kDa subunits and exhibits a Vm = 37 units/mg, Km(ATP) = 74 microM, and Km(DL-MVA) = 24 microM. The sensitivity of enzyme to water-soluble carbodiimide modification of carboxyl groups prompted evaluation of four invariant acidic amino acids (Glu-19, Glu-193, Asp-204, and Glu-296) by site-directed mutagenesis. Elimination of Glu-19's carboxyl group (E19A, E19Q) destabilizes the enzyme, whereas E19D is stable but exhibits only approximately 2-fold changes in Vm and Km values. E296Q is a stable enzyme, which exhibits kinetic parameters comparable to those measured for wild-type enzyme. E193A is a labile protein, whereas E193Q is stable, exhibiting >50-fold diminution in Vm and elevated Km values for ATP (approximately 20-fold) and mevalonate (approximately 40-fold). Such effects would be compatible with a role for Glu-193 in interacting with the cation of the MgATP substrate. D204A and D204N are stable enzymes lacking substantial mevalonate kinase activity. The active sites of these Asp-204 mutants are intact, based on their ability to bind a spin-labeled ATP analog with stoichiometries and equilibrium binding constants that are comparable to those determined for wild-type enzyme. Competitive displacement experiments demonstrate that the Asp-204 mutants can bind ATP with Kd values that are comparable to estimates for wild-type enzyme. The >40,000-fold diminution in kcat for the Asp-204 mutants and the demonstration that they contain an otherwise intact active site support assignment of a crucial catalytic role to Asp-204. The assignment of Asp-204 as the catalytic base that facilitates deprotonation of the C-5 hydroxyl of mevalonic acid would be compatible with the experimental observations.

The active sites of fructose 6-phosphate,2-kinase: fructose-2, 6-bisphosphatase from rat testis. Roles of Asp-128, Thr-52, Thr-130, Asn-73, and Tyr-197

To investigate the role in catalysis and/or substrate binding of the Walker motif residues of rat testis fructose 6-phosphate, 2-kinase:fructose-2,6-bisphosphatase (Fru 6-P,2-kinase:Fru-2,6-Pase), we have constructed and characterized mutant enzymes of Asp-128, Thr-52, Asn-73, Thr-130, and Tyr-197. Replacement of Asp-128 by Ala, Asn, and Ser resulted in a small decrease in Vmax and a significant increase in Km values for both substrates. These mutants exhibited similar pH activity profiles as that of the wild type enzyme. Mutation of Thr-52 to Ala resulted in an enzyme with an infinitely high Km for both substrates and an 800-fold decreased Vmax. Substitution of Asn-73 with Ala or Asp caused a 100- and 600-fold increase, respectively in KFru 6-P with only a small increase in KATP and small changes in Vmax. Mutation of Thr-130 caused small changes in the kinetic properties. Replacement of Tyr-197 with Ser resulted in an enzyme with severely decreased binding of Fru 6-P with 3-fold decreased Vmax. A fluorescent analog of ATP, 2'(3')-O-(N-methylanthraniloyl)ATP (mant-ATP) served as a substrate with Km = 0.64 microM, and Vmax = 25 milliunits/mg and was a competitive inhibitor with respect to ATP. When mant-ATP bound to the enzyme, fluorescence intensity at 440 nm increased. mant-ATP binding of the wild type and the mutant enzymes were compared using the fluorometric method. The Kd values of the T52A and D128N enzymes were infinitely high and could not be measured, while those of the other mutant enzymes increased slightly. These results provide evidence that those amino acids are involved in substrate binding, and they are consistent with the crystallographic data. The results also suggest that Asp-128 does not serve as a nucleophile in catalysis, and since there are no other potential nucleophiles in the active site, we hypothesize that the Fru 6-P,2-kinase reaction is mediated via a transition state stabilization mechanism.

Modelling the 2-kinase domain of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase on adenylate kinase

Simultaneous multiple alignment of available sequences of the bifunctional enzyme 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase revealed several segments of conserved residues in the 2-kinase domain. The sequence of the kinase domain was also compared with proteins of known three-dimensional structure. No similarity was found between the kinase domain of 6-phosphofructo-2-kinase and 6-phosphofructo-1-kinase. This questions the modelling of the 2-kinase domain on bacterial 6-phosphofructo-1-kinase that has previously been proposed [Bazan, Fletterick and Pilkis (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 9642-9646]. However, sequence similarities were found between the 2-kinase domain and several nucleotide-binding proteins, the most similar being adenylate kinase. A structural model of the 2-kinase domain based on adenylate kinase is proposed. It accommodates all the results of site-directed mutagenesis studies carried out to date on residues in the 2-kinase domain. It also allows residues potentially involved in catalysis and/or substrate binding to be predicted.

Cloning, sequencing and developmental expression of phosphofructokinase from Dictyostelium discoideum

Phosphofructokinase (PFK) from Dictyostelium discoideum is a non-allosteric enzyme that lacks any of the characteristic regulatory mechanisms of PFK from other cells. We have determined the DNA sequence and analyzed the amino acid sequence of D. discoideum PFK, as an initial step toward understanding the peculiar properties of this enzyme. Three overlapping fragments, two of cDNA and one of genomic DNA, were isolated, which together could encode the complete sequence of D. discoideum PFK. The constructed full-length cDNA coded for a protein of 834 amino acids, with a calculated molecular mass of 92.4 kDa, which was similar to other eukaryotic and prokaryotic PFK. Alignments of the amino acid sequence with other isozymes revealed that many of the amino acid residues assigned to binding sites of substrates and allosteric effectors are conserved in this enzyme, but changes were also found that may contribute to the absence of allosteric mechanisms. A phylogenetic tree for the eukaryotic PFK family was constructed and showed that the N-terminal domain clustered with those of yeast subunits, whereas the C-terminal domain was more related to PFK from metazoa. Southern blotting indicated that D. discoideum PFK is encoded by a single gene. The enzyme is present throughout the life cycle of D. discoideum, with a gradual decrease of its expression during development.

Evidence supporting catalytic roles for aspartate residues in phosphoribulokinase

The DNA encoding Rhodobacter sphaeroides phosphoribulokinase (PRK) has been modified to allow ligation into pET-3d. Using the resulting expression plasmid, PRK was overexpressed in Escherichia coli and isolated in milligram quantities. Homogeneous preparations of the enzyme exhibit properties comparable to those of PRK expressed using a previously described pUC19-derived construct [Sandbaken et al., Biochemistry 31, 3715-3719]. Mutagenesis experiments have been designed to produce conservative substitutions that eliminate the carboxyl groups of each of four conserved acidic residues (D42, E131, D169, and E178). Using the newly developed expression system, the resulting PRK variants have been expressed, isolated, and characterized. Expression levels and recoveries upon affinity chromatography purification are similar to the results obtained with wild-type PRK. Apparent substrate affinities of these mutant proteins do not differ greatly from values observed for wild-type PRK. In contrast, these PRK variants display a wide range of Vmax values, ranging from wild-type activity (approximately 200 units/mg; E178A) to levels that are diminished by 4 (D169A) to 5 (D42A, D42N) orders of magnitude. That the large diminutions in catalytic activity are significant and do not merely reflect gross perturbations in protein structure is suggested not only by the modest effects on substrate affinity but also by the allosteric properties of D169A, D42A, and D42N. The activities of these proteins, like that of wild-type PRK, are markedly stimulated by the positive effector NADH. The magnitude of the Vmax perturbations suggests that D42 and D169 are candidates for the role of active site base or activator cation ligand.(ABSTRACT TRUNCATED AT 250 WORDS)

Site-directed mutagenesis of rat muscle 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase: role of Asp-130 in the 2-kinase domain

Asp-130 of the recombinant skeletal-muscle 6-phosphofructo-2-kinase (PFK-2)/fructose-2,6-bisphosphatase was mutated into Ala in order to study its role in catalysis and/or substrate binding. The D130A mutant displayed a 30- to 140-fold decreased 2-kinase Vmax, depending on the pH, and a 30- and 60-fold increase in Km for MgATP and Fru-6-P respectively at pH 8.5 compared with the wild-type. Mutagenesis of Asp-130 to Ala had no effect on the 2-phosphatase activity, and fluorescence measurements indicated that the changes in kinetic properties of PFK-2 in the D130A mutant were not due to instability. The role of Asp-130 in the 2-kinase reaction is discussed and compared with that of Asp-103 of 6-phosphofructo-1-kinase from Escherichia coli, which binds Mg2+.

The functions and consensus motifs of nine types of peptide segments that form different types of nucleotide-binding sites

From an analysis of current data on 16 protein structures with defined nucleotide-binding sites consensus motifs were determined for the peptide segments that form such nucleotide-binding sites. This was done by using the actual residues shown to contact ligands in the different protein structures, plus an additional 50 sequences for various kinases. Three peptide segments are commonly required to form the binding site for ATP or GTP. Binding motif Kinase-1a is found in almost all sequences examined, and functions in binding the phosphates of the ligand. Variant versions, comparable to Kinase-1a, are found in a subset of proteins and appear to be related to unique functions of those enzymes. Motif Kinase-2 contains the conserved aspartate that coordinates the metal ion on Mg-ATP. Motif Kinase-3 occurs in at least four versions, and functions in binding the purine base or the pentose. Two protein structures show ATP-binding at a separate regulatory site, formed by the motifs Regulatory-1 and Regulatory-2. Structures for adenylate kinase and guanylate kinase show three different sequence motifs that form the binding site for a nucleoside monophosphate (NMP). NMP-1 and NMP-2 bind to the pentose and phosphate of the bound ligand. NMP-1 is found in almost all the kinases that phosphorylate AMP, CMP, GMP, dTMP, or UMP. NMP-3a is found in kinases for AMP, GMP, and UMP, while NMP-3b binds only GMP. For the binding of NTPs, three distinct types of nucleotide-binding fold structures have been described. Each structure is associated with a particular function (e.g. transfer of the gamma-phosphate, or of the adenylate to an acceptor) and also with a particular spatial arrangement of the three Kinase segments evident in the linear sequence for the protein.

Lanthanide pyrophosphates as substrates for the pyrophosphate-dependent phosphofructokinases from Propionibacterium freudenreichii and Phaseolus aureus: evidence for a second metal ion required for reaction

In the absence of Mg2+, both the dimeric bacterial and tetrameric plant fructose 2,6-bisphosphate-activated pyrophosphate-dependent phosphofructokinases (PPi-PFKs) are inactive at pH 8 and 25 degrees C. In the presence of a low concentration of Mg2+ (5 microM), both enzymes will utilize a variety of metal-pyrophosphate complexes as reactant in the direction of fructose 6-phosphate (F6P) phosphorylation. The Vmax values are about 100-fold lower and the Km values about 10-fold greater than those measured with MgPPi when lanthanide-PPi complexes are used as a substrate. In the presence of added Mg2+, the Km values of the above remain essentially unchanged, while Vmax values increase 10-fold for lanthanide-PPi complexes. These data, along with the 12-16 order of magnitude increased affinity of the lanthanides for PPi compared to Mg2+, indicate that the PPi-PFKs require two metal ions for catalysis, one to form a chelate with PPi and a second as an essential activator. With CePPi, an activation constant of about 25 microM is measured for Mg2+. In addition, a number of other divalent (but no tripositive) metal ions serve as activators including Mn2+, Co2+, Mo2+, Cr2+, Fe2+, and Ni2+; activation constants are in the range 20-150 microM. The exchange-inert CrIII(PPi)(H2O)4 complex is not a substrate, but is an inhibitor competitive against MgPPi with a Ki of 27 microM. Results are discussed in terms of the possible role of the divalent metal ion activators.

Cloning, sequencing, and expression in Escherichia coli of the gene coding for phosphofructokinase in Lactobacillus bulgaricus

A fragment of 1,185 bp containing the gene coding for phosphofructokinase (ATP:D-fructose-6-phosphate-1-phosphotransferase; EC 2.7.1.11) in Lactobacillus bulgaricus has been cloned, sequenced, and expressed in Escherichia coli. The amino acid sequence of this enzyme was homologous to those of the ATP-dependent phosphofructokinases from E. coli, Thermus thermophilus, Spiroplasma citri, and Bacillus stearothermophilus, suggesting that these enzymes have closely related structures despite their different regulatory properties. The recombinant protein had the same structural and functional properties as did the original enzyme. The 3' end of the 1,185-bp fragment showed the presence of an open reading frame corresponding to the N-terminal amino acid sequence of the pyruvate kinase from L. bulgaricus. This gene organization, the same as that in S. citri (C. Chevalier, C. Saillard, and J. M. Bové, J. Bacteriol. 172:2693-2703, 1990) and B. stearothermophilus (D. Walker, W. N. Chia, and H. Muirhead, J. Mol. Biol. 228:265-276, 1992; H. Sakai and T. Ohta, Eur. J. Biochem. 311:851-859, 1993) but different from that in E. coli (H. W. Hellinga and P. R. Evans, Eur. J. Biochem. 149:363-373, 1985), indicated that the same transcription unit apparently contained the genes for phosphofructokinase and pyruvate kinase, the two key enzymes of glycolysis. The possibility that these genes could be transcribed at the same time suggested that in L. bulgaricus, the coordinated regulation of phosphofructokinase and pyruvate kinase occurs at the levels of both biosynthesis and enzymatic activity.

Interaction between the carboxyl groups of Asp127 and Asp129 in the active site of Escherichia coli phosphofructokinase

The pH dependence of the enzymic properties of the phosphofructokinase from Escherichia coli was compared to those of two mutants in which one carboxyl group of the active site has been removed from either Asp127 or Asp129. All measurements of activity were made in the presence of allosteric activator ADP or GDP to eliminate any cooperative process. Asp129 is a crucial residue for the activity of phosphofructokinase since its conversion to Ser decreases the catalytic activity by 2-3 orders of magnitude in both the forward and reverse reactions, but the ionization of Asp129 is not directly related the pH dependence of phosphofructokinase activity. This pH dependence is however modified by the Asp129----Ser mutation, which decreases the pK of another residue, Asp127, by as much as pH of 1.5. The side chain of Asp127 has the catalytic role proposed earlier: its deprotonated form acts as a base in the forward reaction, and its protonated form acts as an acid in the reverse reaction. The protonated form of Asp127 is also required for the binding of fructose 1,6-bisphosphate. The electrostatic interaction between the carboxyl groups of Asp127 and Asp129 seems different in free phosphofructokinase to that in enzyme/substrate complexes, suggesting that a conformational change occurs upon substrate binding. The pH dependence of phosphofructokinase activity involves one other ionizable group with a pK of approximately 6 which does not belong to the side chains of Asp127 or Asp129.

Mutational analysis of carbamyl phosphate synthetase. Substitution of Glu841 leads to loss of functional coupling between the two catalytic domains of the synthetase subunit

The synthetase subunit of Escherichia coli carbamyl phosphate synthetase has two catalytic nucleotide-binding domains, one involved in the activation of HCO3- and the second in phosphorylation of carbamate. Here we show that a Glu841----Lys841 substitution in a putative ATP-binding domain located in the carboxyl half of the synthetase abolishes overall synthesis of carbamyl phosphate with either glutamine or NH3 as the nitrogen source. Measurements of partial activities indicate that while HCO3(-)-dependent ATP hydrolysis at saturating concentrations of substrate proceeds at higher than normal rates, ATP synthesis from ADP and carbamyl phosphate is nearly completely suppressed by the mutation. These results indicate Glu841 to be an essential residue for the phosphorylation of carbamate in the terminal step of the catalytic mechanism. The Lys841 substitution also affects the kinetic properties of the HCO3- activation site. Both kcat and Km for ATP increase 10-fold, while Km for HCO3- is increased 100-fold. Significantly, NH3 decreases rather than stimulates Pi release from ATP in the HCO3(-)-dependent ATPase reaction. The increase in kcat of the HCO3(-)-dependent ATPase reaction, and an impaired ability of the Lys841 enzyme to catalyze the reaction of NH3 with carboxy phosphate, strongly argues for interactions between the two catalytic ATP sites that couple the formation of enzyme-bound carbamate with its phosphorylation.

A conformational transition involved in antagonistic substrate binding to the allosteric phosphofructokinase from Escherichia coli

The binding of fructose 6-phosphate, ATP or its nonhydrolyzable analogue adenylyl 5'-(beta,gamma-methylenediphosphonate), ADP, and phosphoenolpyruvate to Escherichia coli phosphofructokinase has been studied by changes in the protein fluorescence and/or equilibrium dialysis. The results lead to the following conclusions: (1) tetrameric phosphofructokinase can bind four ATP but only two fructose-6-phosphate, and this binding occurs without cooperativity; (2) only two conformational states, T and R, with respectively a high and a low fluorescence, seem accessible to phosphofructokinase, which exists as a mixture of one-third R and two-third T states in the absence of ligand; (3) the substrate fructose 6-phosphate and the allosteric activator ADP bind preferentially to the low-fluorescence R state, while the other substrate, ATP [or its nonhydrolyzable analogue adenylyl 5'-(beta,gamma-methylenediphosphonate)], and the allosteric inhibitor phosphoenolpyruvate bind to the high-fluorescence T state; (4) the binding of a given ligand is cooperative, with a Hill coefficient of 2, only when this binding is accompanied by a complete shift from one state to the other; for instance, the binding of the ATP analogue adenylyl 5'-(beta,gamma-methylenediphosphonate) to the T state is cooperative only in the presence of fructose 6-phosphate which favors the R state. This behavior is qualitatively consistent with a concerted transition, but quite different from that described earlier for phosphofructokinase from steady-state activity measurements (Blangy et al., 1968). This discrepancy suggests that the allosteric properties of phosphofructokinase are due in part to ligand binding and in part to the kinetics of the enzymatic reaction.

pH dependence of the reverse reaction catalyzed by phosphofructokinase I from Escherichia coli: implications for the role of Asp 127

The kinetics of the reverse reaction catalyzed by Escherichia coli phosphofructokinase, i.e., the synthesis of ATP and fructose-6-phosphate from ADP and fructose-1,6-bisphosphate, have been studied at different pH values, from pH 6 to pH 9.2. Hyperbolic saturations of the enzyme are observed for both substrates. The affinity for fructose-1,6-bisphosphate decreases with pH following the ionization of a group with a pK of 6.6, whereas the catalytic rate constant and perhaps the affinity for ADP are controlled by the ionization of a group with a pK of 6. Several arguments show that the pK of 6.6 is probably that of the carboxyl group of Asp 127, whereas the pK of 6 is tentatively attributed to the carboxyl group of Asp 103. The pK of 6.6 is assigned to the carboxyl group of Asp 127 in the free enzyme, and a simple model suggests that the same group would have an abnormally high pK, above 9.6, in the complex between phosphofructokinase and fructose-1,6-bisphosphate. It is proposed that the large pK shift of more than 3 pH units upon binding of fructose-1,6-bisphosphate is due to an electrostatic repulsion that could exist between the 1-phosphate group and the carboxyl group of Asp 127, which are close to each other in the crystal structure of phosphofructokinase (Shirakihara, Y. & Evans, P.R., 1988, J. Mol. Biol. 204, 973-994). The same interpretation would also explain the much higher affinity of the enzyme for fructose-1,6-bisphosphate when Asp 127 is protonated.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression and site-directed mutagenesis of hepatic glucokinase

Soluble rat liver glucokinase was expressed at high levels at 22 degrees C in the BL21(DE3)pLysS strain of Escherichia coli. Aspartate-211 of yeast hexokinase has been implicated as a catalytic residue from crystallographic data. The corresponding residue in rat liver glucokinase, aspartate-205, was mutated to alanine and the expressed mutant had 1/500th of the activity of the wild type, with no change in the Km values for glucose or ATP. The results support a role for this residue as a base catalyst in the glucokinase reaction and, most probably, a similar role in the reactions of all members of the hexokinase family.

Nucleotide sequence of the Rhodobacter capsulatus fruK gene, which encodes fructose-1-phosphate kinase: evidence for a kinase superfamily including both phosphofructokinases of Escherichia coli

The fruK gene encoding fructose-1-phosphate kinase (FruK), located within the fructose (fru)-catabolic operon of Rhodobacter capsulatus, was sequenced. FruK of R. capsulatus (316 amino acids; molecular weight = 31,232) is the same size as and is homologous to FruK of Escherichia coli, phosphofructokinase B (PfkB) of E. coli, phosphotagatokinase of Staphylococcus aureus, and ribokinase of E. coli. These proteins therefore make up a family of homologous proteins, termed the PfkB family. A phylogenetic tree for this new family was constructed. Sequence comparisons plus chemical inactivation studies suggested the lack of involvement of specific residues in catalysis. Although the Rhodobacter FruK differed markedly from the other enzymes within the PfkB family with respect to amino acid composition, these enzymes exhibited similar predicted secondary structural features. A large internal segment of the Rhodobacter FruK was found to be similar in sequence to the domain bearing the sugar bisphosphate-binding region of the large subunit of ribulose 1,5-bisphosphate carboxylase/oxygenase of plants and bacteria. Proteins of the PfkB family did not exhibit statistically significant sequence identity with PfkA of E. coli. PfkA, however, is homologous to other prokaryotic and eukaryotic ATP- and PPi-dependent Pfks (the PfkA family). These eukaryotic, ATP-dependent enzymes each consist of a homotetramer (mammalian) or a heterooctamer (yeasts), with each subunit containing an internal duplication of the size of the entire PfkA protein of E. coli. In some of these enzymes, additional domains are present. A phylogenetic tree was constructed for the PfkA family and revealed that the bacterial enzymes closely resemble the N-terminal domains of the eukaryotic enzyme subunits whereas the C-terminal domains have diverged more extensively. The PPi-dependent Pfk of potato is only distantly related to the ATP-dependent enzymes. On the basis of their similar functions, sizes, predicted secondary structures, and sequences, we suggest that the PfkA and PfkB families share a common evolutionary origin.