Global ETD Search

21	Characterization of Lipoxygenases from Cyanothece sp. Newie, Julia 01 January 2016 (has links) No description available. 572 lipoxygenase enzyme kinetics metalloenzyme protein structure membrane binding assay Cyanobacteria lipid oxidation
22	Cloning, Expression, and Sequence Analysis of Camelysin, a Zinc Metalloprotease from <em>Bacillus anthracis</em> and <em>B. cereus</em> Myers, Andrew Ross 18 July 2005 (has links) Bacillus anthracis and B. cereus are well known etiological agents, which cause disease in healthy and immunocompromised individuals. Considering the abundance and lethality of these organisms it is imperative that research is performed to identify and analyze new factors that may contribute to their pathogenicity. Camelysin is a membrane bound, zinc metalloprotease isolated from B. cereus. Assays performed on purified camelysin demonstrate that the protease exhibits fibrinolytic, collagenolytic, and actin degradation activity, any of which can contribute to the organisms ability to invade host tissues and cause damage. Considering the putative role of camelysin in pathogenicity, it would be beneficial to study the effects of camelysin in tissue cultures or animal models. The goal of this study focused on the cloning and expression of camelysin from B. cereus and its homolog in B. anthracis. Expression of a fusion tagged protein may assist in the purification of camelysin as well as overcoming the native proteins extreme insolubility. Primers were designed to amplify the camelysin gene from B. cereus for cloning into the prokaryotic pBAD TOPO® TA, pET100/D-TOPO®, and the eukaryotic pcDNA3.1/V5-His© TOPO[registered trademark] TA expression vectors. Primers were also designed to amplify the gene from B. anthracis for cloning into the pBAD TOPO® TA vector. The recombinant clones were induced and successful expression of the protein was confirmed by performing SDS-PAGE, Western blotting, and an azocasein protease assay. The recombinant proteins exhibited casein degradation activity which is observed with purified camelysin from B. cereus. This study successfully demonstrated the presence of the camelysin protein in B. anthracis. Furthermore, the recombinant clones obtained will be useful for purification and analysis of camelysin and delineation of its role in the pathogenicity of B. cereus and B. anthracis. Metalloenzyme Collagen Pathogenic factor Recombinant protein Nosocomial infections American Studies Arts and Humanities
23	Isolation and Characterisation of the 5'-Nucleotidase from Escherichia coli McMillen, Lyle, l.mcmillen@sct.gu.edu.au January 2001 (has links) Escherichia coli 5'-nucleotidase is a periplasmically localised enzyme capable of hydrolysing a broad range of substrates, including all 5'-ribo- and 5'-deoxyribonucleotides, uridine diphosphate sugars, and a number of synthetic substrates such as bis (r-nitrophenyl) phosphate. The enzyme has been shown to contain at least one zinc ion following purification, and to have two metal binding sites in the catalytic cleft. 5'-Nucleotidase activity is significantly stimulated by the addition of particular divalent metal ions, most notably cobalt which results in a 30-50 fold increase in activity. Significant sequence homology between the E. coli 5'-nucleotidase and members of the Ser/Thr protein phosphatase family in the catalytic site has lead to 5'-nucleotidase being included in this protein family. This thesis describes the development of a rapid purification methodology for milligram quantities of 5'-nucleotidase, and the investigation of a number of physical and biochemical properties of the enzyme with the aim of comparing these properties to those of certain catalytic site mutants. The molecular weight of the mature protein was estimated as 58219 daltons, with a specific activity for 5'-AMP, in the presence of 4 mM Co2+ and 13 mM Ca2+ at pH 6.0, of 730 mmol/min/mg. The presence of up to two zinc ions associated with the purified enzyme was observed using ICP-ES analysis, suggesting both metal ion binding sites are occupied by zinc in vivo, and some degree of displacement of zinc by cobalt could be observed. Mass spectrometry data, gathered at 60 and 70 mS orifice potential, suggested the presence of a small proportion of material with a mass 118 to 130 daltons greater than the main 5'-nucleotidase mass estimation. This study suggests that this mass difference, only evident at the lower orificepotential, is due to the presence of two zinc ions closely associated with 5'-nucleotidase. To account for the observed high level of activation of 5'-nucleotidase activity by particular divalent metal ions, this thesis describes a proposed model in which these divalent ions may displace the zinc ion at one of the metal ion binding sites. This displacement only occurs at one of the two metal ion binding sites, with the other metal binding site retaining the zinc ion already present. Studies with purified enzyme, each with a single amino acid substitution, lend support to this hypothesis and suggest the identity of the metal ion binding site at which displacement occurs. Seven key catalytic site residues (Asp-41, His-43, Asp-84, His-117, Glu-118, His-217 and His-252) were selected on the basis of sequence conservation within the Ser/Thr protein phosphatases and 5'-nucleotidases. X-ray crystallographic data published by others during this study implicated five of the selected residues (Asp-41, His-43, Asp-84, His-217 and His-252) directly in metal ion binding, including two residues from each metal ion binding site and one directly involved in both sites (Asp-84). The remaining two residues (His-117 and Glu-118) are highly conserved but were not thought to play direct roles in metal ion binding. The seven selected residues were modified by site-directed mutagenesis, and the effect of the amino acid substitutions upon the kinetic properties of 5'-nucleotidase activity was determined. Residues hypothesised to be involved in metal ion displacement, and subsequent activation of 5'-nucleotidase activity, were identified by reductions in metal ion affinity and increased levels of activation by cobalt compared to the wild type 5'-nucleotidase. This study suggests that the metal binding site, M2, that includes residues Asp-84, His-217 and His-252, is involved in metal ion displacement, while the other metal binding site, M1, is not. This, in turn, suggests the metal binding sites are functionally non-equivalent and kinetically distinct. No residues were identified in this study as playing significant roles in substrate binding, as there was no significant reduction observed in affinity for 5'-AMP observed in any of the catalytic site mutants. 5'-nucleotidase zinc metalloenzyme phosphoesterase cobalt activation consensus sequence sequence motif
24	HOW A SILENT MUTATION SUPPRESSES THE ACTIVITY AND IRON INCORPORATION IN SUPEROXIDE DISMUTASE Mei, Xiaonan 01 January 2012 (has links) A mutation (CTG to TTG) of FeSOD gene was found in Escherichia coli. Since they both encode leucine, it is a silent mutation. Site-‐directed mutagenesis was applied to correct the mutation, and the mutant FeSOD (before gene correction) and wild type FeSOD (after gene correction) were purified. The FeSODs from the two genes were Characterized using different assays and spectroscopic methods including EPR and CD. The requirement for the rare codon TTG may result in slowed translation and heavy demand on a scarce tRNA. Cultures expressing wild type FeSOD are better able to grow for long times after addition of IPTG and more mature to incorporate Fe atoms to the active sites than are cultures expressing the mutant gene. Moreover, the wild type FeSOD has more activity than the mutant. To our knowledge, this is the first time that a silent mutation has been demonstrated to affect metal incorporation into a metalloenzyme. Metalloenzyme Metal incorporation Silent mutation Site-‐directed mutagenesis EPR Chemistry
25	Design de nouvelles métalloenzymes artificielles / A green approach for drug synthesis : design of artificial metalloenzymes Rondot, Laurianne 15 December 2016 (has links) Dans l’industrie chimique, de nombreux composés organiques sont issus d’étapes d’oxydation, pouvant être énantiosélectives et mettant en jeux des conditions dangereuses et polluantes, comme par exemple l’emploi du tétraoxide d’osmium comme oxydant. Dans un souci de respect de l’environnement, il est alors nécessaire de repenser les procédés de synthèse vers un développement de la chimie verte et durable.Dans cet objectif, mes travaux de thèse consistent à développer des nouveaux catalyseurs d’oxydation de molécules organiques en rassemblant les mondes de la catalyse inorganique et de la biocatalyse par la conception de Métalloenzymes artificielles. Ces hybrides catalytiques développés en ancrant un complexe inorganique au sein d’une protéine hôte permettent ainsi des catalyses d’oxydation de façon douce et propre. Premièrement, nous avons développé et caractérisé une métalloenzyme artificielle à centre ruthénium (II) scorpionnate ancrée dans la protéine bactérienne NikA. Nous nous sommes ensuite intéressés à sa réactivité en oxydation asymétrique d’alcène en milieu aqueux en présence de diacétate d’iodobenzène. Ceci a permis de mettre en évidence une activité singulière de l’hybride par la formation de de produit d’oxydation de type chlorhydrine. Enfin, l’énantiosélèctivité de cette activité catalytique a été étudiée en fonction d’un panel de substrat et de l’influence de la cavité protéique.Dans un second temps mes travaux de thèses ont consisté à concevoir et caractérisé une nouvelle oxygénase artificielle FeLn (III)-NikA. La seconde étape fut ensuite de vérifier la capacité de cet hybride catalytique à activer l’oxygène moléculaire en présence de réducteur, Puis d’étudier son aptitude à le transférer à un substrat exogène en condition de catalyse d’oxydation d’alcène aromatique. En parallèle, nous avons développé un système de réduction photocatalytique associé à cette nouvelle métalloenzyme artificielle sous apport de source lumineuse bleue et en présence de photosensibilisateur (chlorure de ruthénium (II) ) couplé à un donneur d’électron sacrificiel (triéthanolamine). / Dans l’industrie chimique, de nombreux composés organiques sont issus d’étapes d’oxydation, pouvant être énantiosélectives et mettant en jeux des conditions dangereuses et polluantes, comme par exemple l’emploi du tétraoxide d’osmium comme oxydant. Dans un souci de respect de l’environnement, il est alors nécessaire de repenser les procédés de synthèse vers un développement de la chimie verte et durable.Dans cet objectif, mes travaux de thèse consistent à développer des nouveaux catalyseurs d’oxydation de molécules organiques en rassemblant les mondes de la catalyse inorganique et de la biocatalyse par la conception de Métalloenzymes artificielles. Ces hybrides catalytiques développés en ancrant un complexe inorganique au sein d’une protéine hôte permettent ainsi des catalyses d’oxydation de façon douce et propre. Premièrement, nous avons développé et caractérisé une métalloenzyme artificielle à centre ruthénium (II) scorpionnate ancrée dans la protéine bactérienne NikA. Nous nous sommes ensuite intéressés à sa réactivité en oxydation asymétrique d’alcène en milieu aqueux en présence de diacétate d’iodobenzène. Ceci a permis de mettre en évidence une activité singulière de l’hybride par la formation de de produit d’oxydation de type chlorhydrine. Enfin, l’énantiosélèctivité de cette activité catalytique a été étudiée en fonction d’un panel de substrat et de l’influence de la cavité protéique.Dans un second temps mes travaux de thèses ont consisté à concevoir et caractérisé une nouvelle oxygénase artificielle FeLn (III)-NikA. La seconde étape fut ensuite de vérifier la capacité de cet hybride catalytique à activer l’oxygène moléculaire en présence de réducteur, Puis d’étudier son aptitude à le transférer à un substrat exogène en condition de catalyse d’oxydation d’alcène aromatique. En parallèle, nous avons développé un système de réduction photocatalytique associé à cette nouvelle métalloenzyme artificielle sous apport de source lumineuse bleue et en présence de photosensibilisateur (chlorure de ruthénium (II) ) couplé à un donneur d’électron sacrificiel (triéthanolamine). Catalyse Metaloenzymes artificielles Activation oxygene moléculaire Catalysis Artificial metalloenzyme Activation of molecular oxygen
26	From Unnatural Amino Acid Incorporation to Artificial Metalloenzymes Makki, Arwa 04 December 2016 (has links) Studies and development of artificial metalloenzymes have developed into vibrant areas of research. It is expected that artificial metalloenzymes will be able to combine the best of enzymatic and homogenous catalysis, that is, a broad catalytic scope, high selectivity and activity under mild, aqueous conditions. Artificial metalloenzyme consist of a host protein and a newly introduced artificial metal center. The host protein merely functions as ligand controlling selectivity and augmenting reactivity, while the metal center determines the reactivity. Potential applications range from catalytic production of fine chemicals and feedstock to electron transfer utilization (e.g. fuel cells, water splitting) and medical research (e.g. metabolic screening). Particularly modern asymmetric synthesis is expected to benefit from a successful combination of the power of biocatalysis (substrate conversion via multi-step or cascade reactions, potentially immortal catalyst, unparalleled selectivity and optimization by evolutionary methods) with the versatility and mechanism based optimization methods of homogeneous catalysis. However, so far systems are either limited in structural diversity (biotin-avidin technology) or fail to deliver the selectivities expected (covalent approaches). This thesis explores a novel strategy based on the site-selective incorporation of unnatural, metal binding amino acids into a host protein. The unnatural amino acids can either serve directly as metal binding centers can be used as anchoring points for artificial metallo-cofactors. The identification expression, purification and modification of a suitable protein scaffolds is fundamental to successfully develop this field. Chapter 2 and 3 detail a rational approach leading to a highly engineered host protein. Starting with fluorescent proteins, which combine high thermal and pH stability, high expression yields, and fluorescence for ease of quantification and monitoring an efficient and fast purification protocol was developed first. The purification protocol uses a combination of heat precipitation and three-phase-partitioning (TPP). It provides high yield and purity without requiring any tag. Building on the favourable properties of fluorescent proteins, the non-metal binding, highly stable host-scaffold mTFP* was generated through rational design. The incorporation of artificial metal binding sites, the allowed the selective formation of artificial metalloenzymes, which show catalytic activity and moderat to good chiral induction in the Diels-Alder Cyclization and Friedl-Crafts Acylation Chapter 4 of the thesis describes the use of UAA incorporation to generate artificial metal binding sites. Computational studies and homology modelling successfully highlighted several positions in mTFP, which are particularly suitable for UAA incorporation without any disruption of the protein structure. Application of a functional orthogonal aaRS/tRNA pair developed by P.G. Schultz and co-workers allowed the site-specific incorporation of UAAs in the host protein framework. Changes in fluorescence intensity revealed preferences of varieous UAAs for specific incorporations sites. The three UAAs, pIF, pAzF, and pEynF were incorporated into mTFP in good yields, while pBF does only deliver low protein yields. A successfully established on-protein MIYAURA borylation reaction allows convert well-incorporated pIF into pBF circumventing the problem of low expression yields. Chapter 5 details the use of the azide-functionality of pAzF for the bioconjugation of artificial metal-binding cofactors through CuAAC. The triazole ring formed during this reaction serves as an additional moderate σ -donor/π –acceptor ligand of the metal binding site. We demonstrated the potential of site-specific modifications within the protein host with a versatile subset of artificial cofactors. Following transition metal binding, the newly created metal sites show catalytic activities that nature does not provide. The proof of concept study highlights the potential of the present mTFP* based catalysts in asymmetric Tsuji Trost allylation reactions and Diels-Alder cycloadditions. Dual anchoring of the cofactor lead to increased enantioselectivities, which is a direct result of a better-defined orientation of the catalytic center on the protein surface. Following the utilization of the CuAAC click reaction for the generation of artificial metalloenzymes, the last chapter of this thesis reports the development of a heterogeneous catalyst system for this reaction, which overcomes limitations of homogenous protocols. The recyclable core-shell structured Cu2O/Cu-nanowire catalyst is highly active, does not lead to protein precipitation, can be filtered off after the reaction and provides copper free bioconjugation products. Artificial metalloenzyme Catalysis fluorescent protein Click Chemistry Unnational Unnatural Amino Acids
27	Rational Metalloprotein Design for Energy Conversion Applications January 2019 (has links) abstract: Continuing and increasing reliance on fossil fuels to satisfy our population’s energy demands has encouraged the search for renewable carbon-free and carbon-neutral sources, such as hydrogen gas or CO2 reduction products. Inspired by nature, one of the objectives of this dissertation was to develop protein-based strategies that can be applied in the production of green fuels. The first project of this dissertation aimed at developing a controllable strategy to incorporate domains with different functions (e. g. catalytic sites, electron transfer modules, light absorbing subunits) into a single multicomponent system. This was accomplished through the rational design of 2,2’-bipyridine modified dimeric peptides that allowed their metal-directed oligomerization by forming tris(bipyridine) complexes, thus resulting in the formation of a hexameric assembly. Additionally, two different approaches to incorporate non-natural organometallic catalysts into protein matrix are discussed. First, cobalt protoporphyrin IX was incorporated into cytochrome b562 to produce a water-soluble proton and CO2 reduction catalyst that is active upon irradiation in the presence of a photosensitizer. The effect of the porphyrin axial ligands provided by the protein environment has been investigated by introducing mutations into the native scaffold, indicating that catalytic activity of proton reduction is dependent on axial coordination to the porphyrin. It is also shown that effects of the protein environment are not directly transferred when applied to other reactions, such as CO2 reduction. Inspired by the active site of [FeFe]-hydrogenases, the second approach is based on the stereoselective preparation of a novel amino acid bearing a 1,2-benzenedithiol side chain. This moiety can serve as an anchoring point for the introduction of metal complexes into protein matrices. By doing so, this strategy enables the study of protein interactions with non-natural cofactors and the effects that it may have on catalysis. The work developed herein lays a foundation for furthering the study of the use of proteins as suitable environments for tuning the activity of organometallic catalysts in aqueous conditions, and interfacing these systems with other supporting units into supramolecular assemblies. / Dissertation/Thesis / Doctoral Dissertation Chemistry 2019 Chemistry Biochemistry energy conversion metalloenzyme photocatalysis protein assembly protein design unnatural amino acid
28	Structure-Function Studies of Xanthine Oxidoreductase Pauff, James Michael January 2008 (has links) No description available. Biochemistry Biomedical Research Neurology Pathology Xanthine Oxidase Enzme Catalysis Molybdenum Metalloenzyme
29	Biochemical Characterization of Self-Sacrificing P-Aminobenzoate Synthases from Chlamydia Trachomatis and Nitrosomonas Europaea Stone, Spenser 05 June 2023 (has links) Tetrahydrofolate (THF) is an essential cofactor for one-carbon transfer reactions in various biochemical pathways including DNA and amino acid biosynthesis. This cofactor is made up of three distinct moieties: a pteridine ring, p-aminobenzoate (pABA), and glutamate residues. Most bacteria and plants can synthesize folate de novo, unlike animals that obtain folate from their diet. An established pathway for THF biosynthesis exists in most bacteria, but there is evidence of some organisms such as Chlamydia trachomatis and Nitrosomonas europaea which do not contain the canonical THF biosynthesis genes, despite still being able to synthesize THF de novo. Previous studies have shown that these organisms do not contain the pabABC genes, normally required to synthesize the pABA portion of THF, and can circumvent their presence with just a single gene: ct610 and ne1434 from C. trachomatis and N. europaea, respectively. Interestingly, these novel enzymes for pABA synthesis do not use the canonical substrates, chorismate or other shikimate pathway intermediates. The gene product of ct610 was named Chlamydia Protein Associating with Death Domains (CADD) due to its established role in host mediated apoptosis, while the crystal structure showed an architecture similar to know diiron oxygenases. However, we provide evidence of a moonlighting function in pABA synthesis. Isotopic labeling experiments to understand what substrate might be used by CADD found that isotopically labeled tyrosine was incorporated into the final pABA product. Compellingly, CADD was able to produce pABA in the presence of molecular oxygen and a reducing agent alone without the addition of any exogenous substrate, implicating this unusual enzyme as a self-sacrificing pABA synthase from C. trachomatis. Here, we provide strong evidence for Tyr27 being a sacrificial residue that is cleaved from the protein backbone to serve as the pABA scaffold. Furthermore, we also provide evidence that K152 is an internal amino donor for this pABA synthase reaction performed by CADD. In the case of NE1434, we have conducted initial experiments such as site-directed mutagenesis and our findings suggest that these self-sacrificing residues are conserved between two distantly related organisms. Finally, the pABA synthase activity is reliant on an oxygenated dimetal cofactor and despite the crystal structure of CADD depicting a diiron active site, we have demonstrated that CADD's pABA synthase activity is dependent on a heterodinuclear Mn/Fe cofactor. Conversely, NE1434 demonstrates no preference for manganese and likely employs a more traditional Fe/Fe cofactor for catalysis. Our results implicate the CADD and NE1434 as self-sacrificing pABA synthases that have diverging metal requirements for catalysis. / Master of Science in Life Sciences / Folate is a molecule used by all organisms that is necessary for survival. Many kinds of bacteria are able to make this molecule with proteins called enzymes, which help by quickening the rate of a reaction. Enzymes are catalysts that usually work by binding a molecule, called a substrate, and will act on this substrate to generate a product; the enzyme remains unchanged in this process, which allows it to facilitate many more of these reactions. Chlamydia trachomatis, which is a leading cause of sexually transmitted infections (STIs) in the United States, and Nitrosomonas europaea, an environmental bacterium, are able to use enzymes to make their own folate, but not in the way that many other bacteria do. These organisms contain enzymes that use a part of their own structure as a substrate, making them "sacrificial lambs". Our study provides evidence of how these organisms carry out an abnormal chemical reaction to make folate which can help scientists target this pathway for the development of antibiotics. Chlamydia trachomatis Nitrosomonas europaea self-sacrificing enzyme folate biosynthesis p-aminobenzoate oxygenase metalloenzyme
30	O estudo da enzima deidroquinato sintase de Mycobacterium tuberculosis H37Rv como alvo para o desenvolvimento de fármacos antituberculose Mendonça, Jordana Dutra de January 2010 (has links) Apesar da incidência per capita da tuberculose (TB) ter se mantido estável em 2005, o número de novos casos que surgem a cada ano continua a aumentar no mundo todo. De acordo com a Organização Mundial de Saúde, foram estimados 9,4 milhões de novos casos de TB em 2008, dos quais 1,4 milhões eram HIV - positivos, e com 1,8 milhões de mortes - o equivalente a 4.500 mortes por dia. Fatores como migração, privação sócio-econômica, co-infecção TB-HIV e o aparecimento de cepas resistentes contribuíram para o aumento do número de casos de TB no mundo, principalmente nos países onde a TB já foi considerada erradicada, e criaram a necessidade do desenvolvimento de novas terapêuticas. Alvos moleculares específicos, que são essenciais para o patógeno, e ausentes no hospedeiro, como as enzimas da via do ácido chiquímico são alvos atraentes para o desenvolvimento de novas drogas antituberculose. Essa via leva à síntese de compostos aromáticos, como aminoácidos aromáticos, e é encontrada em plantas, fungos, bactérias e parasitas do phylum Apicomplexa, mas está ausente em humanos. No ano de 2000, foi comprovada a essencialidade dessa via para a viabilidade do bacilo, tornando todas essas enzimas alvos validados para estudo. A segunda enzima da via, deidroquinato sintase (DHQS), catalisa a conversão de 3-deoxi-D-arabino heptulosonato-7-fosfato em 3-deidroquinato, o primeiro composto cíclico. Neste trabalho, são descritos o requerimento de metais divalentes na reação e a determinação do mecanismo cinético da DHQS. Os parâmetros cinéticos verdadeiros foram determinados e, juntamente com os experimentos de ligação, o mecanismo rápido-equilíbrio aleatório foi proposto. O tratamento com EDTA aboliu completamente a atividade de DHQS, sendo que a adição de Co+2 e Zn+2 levam a recuperação total e parcial da atividade enzimática, respectivamente. O excesso de Zn+2 inibe a atividade DHQS, e os dados de ITC indicaram a presença de dois sítios seqüenciais de ligação, o que é consistente com a existência de um sítio secundário inibitório. O protocolo de cristalização foi estabelecido e experimentos em andamento proporcionarão a elucidação da estrutura tridimensional da DHQS, que irá beneficiar tanto o desenho de novos inibidores como uma análise detalhada dos rearranjos do domínio da proteína. Em conjunto, estes resultados representam um passo essencial para o desenho racional de inibidores específicos que podem fornecer uma alternativa promissora para um novo, eficaz, e mais curto de tratamento para TB. / Although the estimated per capita tuberculosis (TB) incidence was stable in 2005, the number of new cases arising each year is still increasing globally. According with World Health Organization, there were estimated 9.4 million new TB cases in 2008, from which 1.4 million were HIV-positive, with 1.8 million deaths total – equal to 4500 deaths a day. Migration, socio-economic deprivation, HIV co-infection and the emergence of extensively-resistance strains, have all contributed to the increasing number of TB cases worldwide, mainly in countries where it was once considered eradicated, and have created an urgent need for the development of new therapeutics against TB. Specific molecular targets, that are essential to the pathogen, and absent in the host, like the enzymes of the shikimate pathway, are attractive targets to development of new antitubercular drugs. This pathway leads to the biosynthesis of aromatic compounds, including aromatic amino acids and it is found in plant, fungi, bacteria and Apicomplexa parasites, but is absent in humans. In 2000, this pathway was proved to be essential to the viability of the pathogen, which validates all its enzymes as potential targets. The second enzyme of this pathway, dehydroquinate synthase (DHQS), catalyzes the conversion of 3-deoxy-D-arabinoheptulosonate 7-phosphate in 3-dehydroquinate, the first cyclic compound. In this work, we described the metal requirement and kinetic mechanism determination of the dehydroquinate synthase. The determination of the true kinetic parameters was performed, and, in addition to ligand binding experiments, the rapid-equilibrium random mechanism was determined. The treatment with EDTA abolished completely the activity of DHQS, and the addition of Co+2 and Zn+2 leads to full and partial recovery of enzyme activity, respectively. Excess of Zn+2 inhibits the DHQS activity, and the ITC data revealed two sequential binding sites, which is consistent with the existence of a secondary inhibitory site. The crystallization protocol was established and ongoing experiments will provide the three-dimensional structure of mtDHQS, which will benefit both the design of novel inhibitors as well as detailed analysis of domain rearrangements of protein. Taken together, these results represent an essential step for the rational design of specific inhibitors that can provide a promising alternative to a new, effective, and shorter treatment for TB. Tuberculose Mycobacterium tuberculosis Cinética Enzimas Ácido chiquímico Dehydroquinate synthase Isothermal titration calorimetry Kinetic characterization Metalloenzyme Mycobacterium tuberculosis Shikimate pathway Tuberculosis

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