Validation of Mycobacterium tuberculosis dihydroneopterin aldolase as a molecular target for anti-tuberculosis drug development.

An early step of target validation in antimicrobial drug discovery is to prove that a gene coding for a putative target is essential for pathogen's viability. However, little attention has been paid to demonstrate the causal links between gene essentiality and a particular protein function that will be the focus of a drug discovery effort. This should be considered an important step in target validation since a growing number of proteins are found to exhibit multiple and unrelated tasks. Here, we show that the Mycobacterium tuberculosis (Mtb) folB gene is essential and that this essentiality depends on the dihydroneopterin aldolase/epimerase activities of its protein product, the FolB protein from the folate biosynthesis pathway. The wild-type (WT) MtFolB and point mutants K99A and Y54F were cloned, expressed, purified and monitored for the aldolase, epimerase and oxygenase activities using HPLC. In contrast to the WT MtFolB, both mutants have neither aldolase nor epimerase activities in the conditions assayed. We then performed gene knockout experiments and showed that folB gene is essential for Mtb survival under the conditions tested. Moreover, only the WT folB sequence could be used as a rescue copy in gene complementation studies. When the sequences of mutants K99A or Y54F were used for complementation, no viable colonies were obtained, indicating that aldolase and/or epimerase activities are crucial for Mtb survival. These results provide a solid basis for further work aiming to develop new anti-TB agents acting as inhibitors of the aldolase/epimerase activities of MtFolB.

Purine nucleoside phosphorylase activity and expression are upregulated in sites affected by periodontal disease.

BACKGROUND AND OBJECTIVE: Purine nucleoside phosphorylase (PNP) is an enzyme that catalyzes the reversible phosphorolysis of purine nucleosides, playing a key role in the purine salvage pathway. Activated T cells seem to rely heavily on PNP to remain functionally active and are particularly sensitive to PNP deficiency. The role of PNP in periodontal tissues has not been characterized thus far. The aim of this study therefore was to assess the activity and expression of PNP in the gingival tissues of periodontitis patients. MATERIAL AND METHODS: Ten patients consecutively admitted for treatment had their periodontal clinical variables recorded and their gingival crevicular fluid collected. After periodontal treatment the patients were seen once a month for plaque and bleeding control, and had their periodontal variables recorded and gingival crevicular fluid collected at 90 and 180 d. Purine nucleoside phosphorylase-specific activity was assessed using a spectrophotometer through the addition of the PNP substrate analog 2-amino-6mercapto-7-methyl purine riboside to the gingival crevicular fluid. In parallel, PNP expression was assessed by immunohistochemistry and real-time PCR in gingival biopsies and cell culture. RESULTS: Purine nucleoside phosphorylase activity was higher in the gingival crevicular fluid of periodontally diseased sites, which was positively correlated with improvements of the clinical variables. Treatment of periodontal disease induced a striking decrease of PNP activity in periodontally diseased sites. Expression of PNP was more pronounced in mononuclear cells and endothelial cells of the gingiva, and the mRNA levels were 5.7-fold higher in inflamed tissues compared with control samples. CONCLUSION: Purine nucleoside phosphorylase activity and expression are upregulated in periodontally diseased sites and can be detected in the gingival crevicular fluid.

Structural bioinformatics study of PNP from Listeria monocytogenes.

This work describes for the first time a model of Purine Nucleoside Phosphorylase from Listeria monocytogenes (LmPNP). We modeled the complexes of LmPNP with ligands in order to determine the structural basis for specificity. Comparative analysis of the model of LmPNP allowed identification of structural features responsible for ligand affinities.

Ab initio 3-D structure prediction of an artificially designed three-alpha-helix bundle via all-atom molecular dynamics simulations.

The rate at which knowledge about genomic sequences and their protein products is produced is increasing much faster than the rate of 3-dimensional protein structure determination by experimental methods, such as X-ray diffraction and nuclear magnetic resonance. One of the major challenges in structural bioinformatics is the conversion of genomic sequences into useful information, such as characterization of protein structure and function. Using molecular dynamics (MD) simulations, we predicted the 3-dimensional structure of an artificially designed three- alpha -helix bundle, called A3, from a fully extended initial conformation, based on its amino acid sequence. The MD protocol enabled us to obtain the secondary, in 1.0 ns, as well as the supersecondary and tertiary structures, in 4.0-10.0 ns, of A3, much faster than previously described for a similar protein system. The structure obtained at the end of the 10.0-ns MD simulation was topologically a three-alpha-helix bundle.

Initial formation of a non-covalent enzyme-reagent complex during the inactivation of clostridial glutamate dehydrogenase by Ellman's reagent: determination of the enzyme's dissociation constant for the binary complex with NAD+ from protection studies.

The time-course of reaction between Ellman's reagent (DTNB) and clostridial glutamate dehydrogenase has been investigated over a wide range of reagent concentrations (50-5000 microM) and showed pseudo-first-order kinetics throughout. The reaction was followed both by monitoring loss of enzyme activity and by detection of released thionitrobenzoate through its absorbance at 412 nm, and, when both methods were used for the same DTNB concentration, the pseudo-first-order rate constants were identical within experimental error, suggesting that the two methods detect the same process. The dependence of the rate constants on DTNB concentration clearly shows saturation, with a limiting value of 1.62 x 10(-3) s-1 and a dissociation constant of 1.0 mM governing the formation of the implied non-covalent enzyme-DTNB complex. This information has allowed a detailed analysis of the protection of the enzyme by NAD+, yielding a value of 334 microM for the dissociation constant for the enzyme-coenzyme binary complex. In view of the convenience of protection studies as a means of determining dissociation constants, this study emphasizes the importance of establishing whether a chemical modification reaction follows simple first-order kinetics with respect to the chemical reagent.

Kinetic studies on the binding of 1,N6-etheno-NAD+ to glutamate dehydrogenase from Clostridium symbiosum.

The mechanism of the binding of reduced coenzyme (NAD+) to clostridial glutamate dehydrogenase (GDH) was determined by transient kinetics. The fluorescent 1,N6-ethenoadenine analogue of NAD+ (epsilonNAD+) was used as a probe of nucleotide binary and ternary complex formation because the binding of NAD+ is optically silent. The kinetics of epsilonNAD+ binding were consistent with a 3-step binding process. The enzyme was found to oscillate between two conformational forms, termed E1 and E2, in the presence and absence of L-glutamate. However, L-glutamate shifted the equilibrium from 96.8% to 99% of the enzyme in the E1 form. The rapid-equilibrium binding of epsilonNAD+ to the E2 form was rate limited by a slow isomerisation of the ternary complex as the binary complex became saturated with epsilonNAD+. The L-glutamate binary complex had a greater affinity for the coenzyme (Kd = 11 microM) than the free enzyme (Km = 39 microM), indicative of a positive interaction of the substrate and coenzyme binding sites. Steady-state studies were also indicative of a positive interaction in the formation of the catalytic complex, with this complex having a Kd for epsilonNAD+ of 6.8 microM. Consequently, there is stabilization of successive complexes on the reaction pathway.

Drugs that inhibit mycolic acid biosynthesis in Mycobacterium tuberculosis.

Tuberculosis resurged in the late 1980s and now kills more than 2 million people a year. The reemergence of tuberculosis as a potential public health threat, the high susceptibility of human immunodeficiency virus-infected persons to the disease, and the proliferation of multi-drug-resistant (MDR) strains have created much scientific interest in developing new antimycobacterial agents to both treat Mycobacterium tuberculosis strains resistant to existing drugs, and shorten the duration of short-course treatment to improve patient compliance. Bacterial cell-wall biosynthesis is a proven target for new antibacterial drugs. Mycolic acids, which are key components of the mycobacterial cell wall, are alpha-alkyl, beta-hydroxy fatty acids, with a species-dependent saturated "short" arm of 20-26 carbon atoms and a "long" meromycolic acid arm of 50-60 carbon atoms. The latter arm is functionalized at regular intervals by cyclopropyl, alpha-methyl ketone, or alpha-methyl methylethers groups. The mycolic acid biosynthetic pathway has been proposed to involve five distinct stages: (i) synthesis of C20 to C26 straight-chain saturated fatty acids to provide the alpha-alkyl branch; (ii) synthesis of the meromycolic acid chain to provide the main carbon backbone, (iii) modification of this backbone to introduce other functional groups; (iv) the final Claisen-type condensation step followed by reduction; and (v) various mycolyltransferase processes to cellular lipids. The drugs shown to inhibit mycolic acid biosynthesis are isoniazid, ethionamide, isoxyl, thiolactomycin, and triclosan. In addition, pyrazinamide was shown to inhibit fatty acid synthase type I which, in turn, provides precursors for fatty acid elongation to long-chain mycolic acids by fatty acid synthase II. Here we review the biosynthesis of mycolic acids and the mechanism of action of antimicrobial agents that act upon this pathway. In addition, we describe molecular modeling studies on InhA, the bona-fide target for isoniazid, which should improve our understanding of the amino acid residues involved in the enzyme's mechanism of action and, accordingly, provide a rational approach to the design of new drugs.

Purine Salvage Pathway in Mycobacterium tuberculosis.

Millions of deaths worldwide are caused by the aetiological agent of tuberculosis, Mycobacterium tuberculosis. The increasing prevalence of this disease, the emergence of drug-resistant strains, and the devastating effect of human immunodeficiency virus coinfection have led to an urgent need for the development of new and more efficient antimycobacterial drugs. The modern approach to the development of new chemical compounds against complex diseases, especially the neglected endemic ones, such as tuberculosis, is based on the use of defined molecular targets. Among the advantages, this approach allows (i) the search and identification of lead compounds with defined molecular mechanisms against a specific target (e.g. enzymes from defined pathways), (ii) the analysis of a great number of compounds with a favorable cost/benefit ratio, and (iii) the development of compounds with selective toxicity. The present review describes the enzymes of the purine salvage pathway in M. tuberculosis as attractive targets for the development of new antimycobacterial agents. Enzyme kinetics and structural data have been included to provide a thorough knowledge on which to base the search for compounds with biological activity. We have focused on the mycobacterial homologues of this pathway as potential targets for the development of new antitubercular agents.

Shikimate kinase (EC 2.7.1.71) from Mycobacterium tuberculosis: kinetics and structural dynamics of a potential molecular target for drug development.

The enzymes of the shikimate pathway represent potential molecular targets for the development of non-toxic antimicrobial agents and anti-parasite drugs. One of the most promising of these enzymes is shikimate kinase (EC 2.7.1.71), which is responsible for the fifth step in the shikimate pathway. This enzyme phosphorylates shikimic acid to yield shikimate-3-phosphate, using ATP as a substrate. In this work, the conformational dynamics of the shikimate kinase from Mycobacterium tuberculosis was investigated in its apostate in solution. For this study, the enzyme was subjected to a gradient of temperatures from 15°C to 45°C in the presence or absence of deuterium oxide, and the amide H/D exchange was monitored using ESI-mass spectrometry. We observed: i) the phosphate binding domain in the apo-enzyme is fairly rigid and largely protected from solvent access, even at relatively high temperatures; ii) the shikimate binding domain is highly flexible, as indicated by the tendency of the apo-enzyme to exhibit large conformational changes to permit LID closure after the shikimate binding; iii) the nucleotide binding domain is initially conformationally rigid, which seems to favour the initial orientation of ADP/ATP, but becomes highly flexible at temperatures above 30°C, which may permit domain rotation; iv) part of the LID domain, including the phosphate binding site, is partially rigid, while another part is highly flexible and accessible to the solvent.

Pyrimidine salvage pathway in Mycobacterium tuberculosis.

The causative agent of tuberculosis (TB), Mycobacterium tuberculosis, infects one-third of the world population. TB remains the leading cause of mortality due to a single bacterial pathogen. The worldwide increase in incidence of M. tuberculosis has been attributed to the high proliferation rates of multi and extensively drug-resistant strains, and to co-infection with the human immunodeficiency virus. There is thus a continuous requirement for studies on mycobacterial metabolism to identify promising targets for the development of new agents to combat TB. Singular characteristics of this pathogen, such as functional and structural features of enzymes involved in fundamental metabolic pathways, can be evaluated to identify possible targets for drug development. Enzymes involved in the pyrimidine salvage pathway might be attractive targets for rational drug design against TB, since this pathway is vital for all bacterial cells, and is composed of enzymes considerably different from those present in humans. Moreover, the enzymes of the pyrimidine salvage pathway might have an important role in the mycobacterial latent state, since M. tuberculosis has to recycle bases and/or nucleosides to survive in the hostile environment imposed by the host. The present review describes the enzymes of M. tuberculosis pyrimidine salvage pathway as attractive targets for the development of new antimycobacterial agents. Enzyme functional and structural data have been included to provide a broader knowledge on which to base the search for compounds with selective biological activity.

Mycobacterial shikimate pathway enzymes as targets for drug design.

The aetiological agent of tuberculosis (TB), Mycobacterium tuberculosis, is responsible for millions of deaths annually. The increasing prevalence of the disease, the emergence of multidrug-resistant strains, and the devastating effect of human immunodeficiency virus co-infection have led to an urgent need for the development of new and more efficient antimycobacterial drugs. Since the shikimate pathway is present and essential in algae, higher plants, bacteria, and fungi, but absent from mammals, the gene products of the common pathway might represent attractive targets for the development of new antimycobacterial agents. In this review we describe studies on shikimate pathway enzymes, including enzyme kinetics and structural data. We have focused on mycobacterial shikimate pathway enzymes as potential targets for the development of new anti-TB agents.

Enoyl reductases as targets for the development of anti-tubercular and anti-malarial agents.

Tuberculosis (TB) and Malaria are neglected diseases, which continue to be major causes of morbidity and mortality worldwide, killing together around 5 million people each year. Mycolic acids, the hallmark of mycobacteria, are high-molecular-weight alpha-alkyl, beta-hydroxy fatty acids. Biochemical and genetic experimental data have shown that the product of the M. tuberculosis inhA structural gene (InhA) is the primary target of isoniazid mode of action, the most prescribed anti-tubercular agent. InhA was identified as an NADH-dependent enoyl-ACP(CoA) reductase specific for long-chain enoyl thioesters and is a member of the Type II fatty acid biosynthesis system, which elongates acyl fatty acid precursors of mycolic acids. M. tuberculosis and P. falciparum enoyl reductases are targets for the development of anti-tubercular and antimalarial agents. Here we present a brief description of the mechanism of action of, and resistance to, isoniazid. In addition, data on inhibition of mycobacterial and plasmodial enoyl reductases by triclosan are presented. We also describe recent efforts to develop inhibitors of M. tuberculosis and P. falciparum enoyl reductase enzyme activity.

Purine nucleoside phosphorylase: a potential target for the development of drugs to treat T-cell- and apicomplexan parasite-mediated diseases.

Purine nucleoside phosphorylase (PNP) catalyzes the reversible phosphorolysis of nucleosides and deoxynucleosides, generating ribose 1-phosphate and the purine base, which is an important step of purine catabolism pathway. The lack of such an activity in humans, owing to a genetic disorder, causes T-cell impairment, and thus drugs that inhibit human PNP activity have the potential of being utilized as modulators of the immunological system to treat leukemia, autoimmune diseases, and rejection in organ transplantation. Besides, the purine salvage pathway is the only possible way for apicomplexan parasites to obtain the building blocks for RNA and DNA synthesis, which makes PNP from these parasites an attractive target for drug development against diseases such as malaria. Hence, a number of research groups have made efforts to elucidate the mechanism of action of PNP based on structural and kinetic studies. It is conceivable that the mechanism may be different for PNPs from diverse sources, and influenced by the oligomeric state of the enzyme in solution. Furthermore, distinct transition state structures can make possible the rational design of specific inhibitors for human and apicomplexan enzymes. Here, we review the current status of these research efforts to elucidate the mechanism of PNP-catalyzed chemical reaction, focusing on the mammalian and Plamodium falciparum enzymes, targets for drug development against, respectively, T-Cell- and Apicomplexan parasites-mediated diseases.

The mechanism of substrate and coenzyme binding to clostridial glutamate dehydrogenase during oxidative deamination.

The binding of NAD+ and L-Glutamate to glutamate dehydrogenase (GDH) from Clostridium symbiosum has been investigated by stopped-flow fluorescence spectroscopy. The formation of the binary complexes produces little change in the protein fluorescence but formation of the ternary complex results in quenching of its fluorescence with a maximum value of 40%. This finding, coupled with the finding that a step prior to hydride transfer but subsequent to ternary complex formation is rate limiting, has enabled us to monitor the kinetics of ternary complex formation in detail. The ternary complex can be formed via the GDH-NAD+ or the GDH-L-Glu binary complexes, but the route via the GDH-NAD+ binary complex is the preferred pathway. The equilibrium and rate constants for the formation of the two binary complexes and the ternary complex formed via the two possible pathways have been determined. These studies have revealed an interaction between the coenzyme-binding site and the substrate-binding site, which lead to a decrease in the binding constant for the second substrate binding to the enzyme. The free energy coupling between the binary and ternary complexes is about 2.4-2.8 kJ.mol-1. We propose that there is a further isomerisation of the ternary complex, which is rate limiting for the steady-state turnover of the enzyme. Formation of this complex is characterised by an increased negative interaction, with a free energy coupling between these complexes of 6.3-11.6 kJ.mol-1.

The mechanism of substrate and coenzyme binding to clostridial glutamate dehydrogenase during reductive amination.

The binding of NADH and 2-oxoglutarate to glutamate dehydrogenase (GDH) from Clostridium symbiosum has been studied by fluorescence spectroscopy. The Kd values for the binding of these ligands have been measured by titration of either the nucleotide or protein fluorescence. During ternary complex formation, the substrate and coenzyme binding sites interact in a positive cooperative manner, but steady-state studies reveal a decrease in affinity of the catalytic complex indicative of negative cooperativity. It was possible to determine the kinetics of formation of the glutamate-dehydrogenase-NADH complex by stopped-flow fluorescence spectroscopy but formation of the glutamate-dehydrogenase-2-oxoglutarate complex was optically silent. Ternary complex formation was characterized by a large quench in protein fluorescence. The binding of NADH to the glutamate-dehydrogenase-2-oxoglutarate binary complex is characterised by a linear increase in the association rate constant, consistent with a one-step binding process. However, the binding of 2-oxoglutarate to the glutamate-dehydrogenase-NADH binary complex is characterised by a decrease in the rate for the observed transient. This suggests that 2-oxoglutarate binds to a different conformation of the enzyme to that stabilized by NADH, and that the transition between these different conformational forms is rate limiting for ternary complex formation. NADH and 2-oxoglutarate can therefore stabilize different conformational states of the enzyme. Collectively, these studies are suggestive of a kinetic model for ternary complex formation that involves the oscillation of the free, binary, and ternary glutamate dehydrogenase complexes between two different conformational states, termed E1 and E2. The equilibrium constants for ternary complex formation via the predominant pathway have been determined. The cooperativity between the substrate and coenzyme binding sites can be accounted for by the displacement of the equilibria between the E1 and E2 states because of their difference in affinities for NADH and 2-oxoglutarate.

Cloning and overexpression in soluble form of functional shikimate kinase and 5-enolpyruvylshikimate 3-phosphate synthase enzymes from Mycobacterium tuberculosis.

Tuberculosis (TB) resurged in the late 1980s and an estimated 1.87 million people died of TB in 1997. The reemergence of tuberculosis as a public health threat, the high susceptibility of HIV-infected persons, and the proliferation of multidrug-resistant strains have created a need to develop new antimycobacterial agents. The existence of a shikimate pathway has been predicted by the determination of the genome sequence of Mycobacterium tuberculosis. The M. tuberculosis aroK-encoded shikimate kinase and aroA-encoded 5-enolpyruvylshikimate 3-phosphate (EPSP) synthase were cloned and the enzymes overexpressed in soluble form. Overexpression was achieved without isopropyl beta-d-thiogalactoside induction, and cells grown to stationary phase yielded approximately 30% of target proteins to total soluble cell proteins. Enzyme activity measurements using coupled assays demonstrated that there was a 328-fold increase in specific activity for shikimate kinase and 101-fold increase for EPSP synthase.

Mechanisms of isoniazid resistance in Mycobacterium tuberculosis: enzymatic characterization of enoyl reductase mutants identified in isoniazid-resistant clinical isolates.

Mutants in the structural gene of the inhA-encoded NADH-dependent 2-trans enoyl-acyl carrier protein reductase were identified from isoniazid-resistant clinical isolates of Mycobacterium tuberculosis. Recombinant InhA proteins with defined single amino acid replacements were expressed in Escherichia coli and purified to homogeneity. Steady-state kinetic parameters for wild type (WT) and I16T, I21V, I47T, and I95P mutants of the enoyl reductase were measured spectrophotometrically. NADH binding to WT and I16T, I21V, I47T, S94A, and I95P mutant reductases were determined by fluorescence spectroscopy and demonstrated that all mutant enzymes had reduced NADH affinity and that NADH binding to all mutants was cooperative as compared with the hyperbolic binding of NADH to the WT enzyme. Since KatG-produced electrophilic derivatives of isoniazid have been suggested to inactivate the enoyl reductase-NADH complex, the kinetics of inactivation for the WT and I21V and I95P mutants was determined. Both mutations resulted in significantly increased values for the apparent first-order rate constant of inactivation.

Purine nucleoside phosphorylase from Mycobacterium tuberculosis. Analysis of inhibition by a transition-state analogue and dissection by parts.

Purine salvage pathways are predicted to be present from the genome sequence of Mycobacterium tuberculosis. The M. tuberculosis deoD gene encodes a presumptive purine nucleoside phosphorylase (PNP). The gene was cloned, expressed, purified, and found to exhibit PNP activity. Purified M. tuberculosis PNP is trimeric, similar to mammalian PNP's but unlike the hexameric Escherichia coli enzyme. Immucillin-H is a rationally designed analogue of the transition state that has been shown to be a potent inhibitor of mammalian PNP's. This inhibitor also exhibits slow-onset inhibition of M. tuberculosis PNP with a rapid, reversible inhibitor binding (K(i) of 2.2 nM) followed by an overall dissociation constant (K(i)) of 28 pM, yielding a K(m)/K(i) value of 10(6). Time-dependent tight binding of the inhibitor occurs with a rate of 0.1 s(-)(1), while relaxation of the complex is slower at 1.4 x 10(-)(3) s(-)(1). The pH dependence of the K(i) value of immucillin-H to the M. tuberculosis PNP suggests that the inhibitor binds as the neutral, unprotonated form that is subsequently protonated to generate the tight-binding species. The M. tuberculosis enzyme demonstrates independent and equivalent binding of immucilin-H at each of the three catalytic sites, unlike mammalian PNP. Analysis of the components of immucillin-H confirms that the inhibition gains most of its binding energy from the 9-deazahypoxanthine group (K(is) of 0.39 microM) while the 1,4-dideoxy-1,4-iminoribitol binds weakly (K(is) of 2.9 mM). Double-inhibition studies demonstrate antagonistic binding of 9-deazahypoxanthine and iminoribitol (beta = 13). However, the covalent attachment of these two components in immucillin-H increases equilibrium binding affinity by a factor of >14 000 (28 pM vs 0.39 microM) compared to 9-deazahypoxanthine alone, and by a factor of >10(8) compared to iminoribitol alone (28 pM vs 2.9 mM), from initial velocity measurements. The structural basis for M. tuberculosis PNP inhibition by immucillin-H and by its component parts is reported in the following paper [Shi, W., Basso, L. A., Santos, D. S., Tyler, P. C., Furneaux, R. H., Blanchard, J. S., Almo, S. C., and Schramm, V. L. (2001) Biochemistry 40, 8204-8215].