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Understanding The Biosynthesis And Utilization Of Non-Proteinogenic Amino Acids For The Production Of Secondary Metabolites In BacteriaChristianson, Carl Victor January 2008 (has links)
Thesis advisor: Steven D. Bruner / Bacteria utilize complex enzymatic machinery to create diverse secondary metabolites. The architectural complexities of these small molecules are enhanced by nature’s ability to synthesize non-proteinogenic amino acids for incorporation into these scaffolds. Many of these natural products are utilized as therapeutic agents, and it would be advantageous to understand how the bacteria create various non-natural amino acid building blocks. With a greater understanding of these systems, engineering could be used to create libraries of potentially useful natural product analogs. The tyrosine aminomutase SgTAM from the soil bacteria Streptomyces globisporus catalyzes the formation of tyrosine to generate (S)-B-tyrosine. The precise mechanistic role of MIO in this novel family of aminomutases has not been established. We report the first X-ray crystal--> structure of an MIO based aminomutase and confirm the structural homology of SgTAM to ammonia lyases. Further work with mechanistic inhibitors provide structural evidence of the mechanism by which MIO dependent enzymes operate. We have also investigated LnmQ, an adenylation domain in the biosynthetic pathway of leinamycin. Leinamycin is an antitumor antibiotic that was isolated from soil samples in 1989. LnmQ is responsible for the specific recognition of D-alanine and subsequent activation as an aminoacyl adenylate species. We have cloned the gene into a DNA vector and expressed it in E. coli. Upon purification of the protein, crystallization conditions have been tested. Synthesis of an inhibitor that mimics the aminoacyl adenylate product catalyzed by LnmQ has been completed. Crystallization with this--> inhibitor will provide better quality crystals and a catalytically informative co-complex. / Thesis (PhD) — Boston College, 2008. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.
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Adenylate forming enzymes involved in NRPS-independent siderophore biosynthesisSchmelz, Stefan January 2010 (has links)
Activation of otherwise unreactive substrates is a common strategy in chemistry and in nature. Adenylate-forming enzymes use adenosine monophosphate to activate the hydroxyl of their carboxylic substrate, creating a better leaving group. In a second step this reactive group is replaced in a nucleophilic elimination reaction to form esters, amides or thioesters. Recent studies have revealed that NRPS- independent siderophore (NIS) synthetases are also adenylate-forming enzymes, but are not included in the current superfamily description. NIS enzymes are involved in biosynthesis of high-affinity iron chelators which are used for iron acquisition by many pathogenic microorganisms. This is an important area of study, not only for potential therapeutic intervention, but also to illuminate new enzyme chemistries. Here the structural and biochemical studies of AcsD from Pectobacterium chrysanthemi are reported. AcsD is a NIS synthetase involved in achromobactin biosynthesis. The co-complex structures of ATP and citrate provide a mechanism for the stereospecific formation of an enzyme-bound citryl-adenylate. This intermediate reacts with L-serine to form a likely achromobactin precursor. A detailed characterization of AcsD nucleophile profile showed that it can not only catalyze ester formation, but also amide and possibly thioester formation, creating new stereospecific citric acid derivatives. The structure of a N-citryl-ethylenediamine product co-complex identifies the residues that are important for both recognition of L-serine and for catalyzing ester formation. The structural studies on the processive enzyme AlcC, which is involved in the final step of alcaligin biosynthesis of Bordetella pertussis, show that it has a similar topology to AcsD. It also shows that ATP is coordinated in a manner similar to that seen in AcsD. Biochemical studies of a substrate analogue establish that AlcC is not only capable of synthesizing substrate dimers and trimers, but also able to assemble the respective dimer and trimer macrocycles. A series of docked binding models have been developed to illustrate the likely substrate coordination and the steps along dimerization and macrocyclization formation. Structural and mechanistic comparison of NIS enzymes with other adenylate-forming enzymes highlights the diversity of the fold, active site architecture, and metal coordination that has evolved. Hence, a new classification scheme for adenylate forming enzymes is proposed.
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Studium klíčových bodů biosyntézy linkomycinu a celesticetinu / Study of the key points of lincomycin and celesticetin biosynthesisVobruba, Šimon January 2021 (has links)
Lincosamides form a small but important group of specialized microbial metabolites with antibiotic activity. The most important members of this group are celesticetin and clinically used lincomycin. Structurally, lincosamides are composed of an amino sugar and an amino acid connected by an amide bond. The amino acid precursors of both lincosamides remarkably differ. Proteinogenic L-proline is the precursor of celesticetin, while an unusual amino acid (2S,4R)-4-propyl- L-proline (PPL) is incorporated in the more efficient compound lincomycin. Surprisingly, both these precursors are recognized and activated for further biosynthetic steps by homologous adenylation domains CcbC and LmbC, respectively. The detailed description of this amino acid recognition and activation step, which is critical for the biological activity of the resulting compound, was the aim of the first part of this thesis. The site-directed mutagenesis of the LmbC substrate binding pocket and biochemical characterization of resulting mutants were employed to identify the residues crucial for the activation of PPL. Subsequently, we experimentally simulated the molecular evolution leading from L-proline-specific substrate binding pocket (like in CcbC) to the PPL-specific enzyme (LmbC). The substitution of only three amino acid...
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Substrátová specifita adenylačních domén synthetas v sekundárním metabolismu. / The substrate specificity of adenylation domains of synthetases in secondary methabolism.Vobruba, Šimon January 2015 (has links)
The crucial part of the biosynthesis of lincosamide antibiotics lincomycin and celesticetin is the condensation of amino sugar and amino acid moieties. This reaction is catalysed by the oligomeric enzyme lincosamide synthetase (LS). One of the most important components of LS is adenylation domain recognizing and activating amino acid precursor. The substrate specificity of adenylation domain is determined by "nonribosomal code", 10 amino acids residues which side chains are in close contact with the activated substrate. The homologous adenylation domains LmbC from biosynthesis of lincomycin and CcbC from biosynthesis of celesticetin exhibit strong substrate specificity for their natural substrates (2S,4R)-4-propyl-L-proline (PPL) and L-proline, respectively. At first the effect of selected amino acid residues of LmbC nonribosomal code on the substrate specificity of the whole domain was tested. The amino acids residues, most important for preference of PPL substrate over L proline, were determined: G308, A207 and L246. Then the effect of double mutations in nonribosomal codes of both LmbC and CcbC on their substrate specificity was evaluated. The double mutants LmbC G308V + A207F and CcbC V306G + F205A were prepared and tested biochemically. The results brought new evidence of validity of homologous models...
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Unveiling the architectures of five bacterial biomolecular machinesFage, Christopher Dane 10 September 2015 (has links)
Natural products represent an incredibly diverse set of chemical structures and activities. Given this fathomless, ever-evolving diversity, a reasonable approach to designing new molecules entails taking a closer look at the biochemistry that Nature has crafted over billions of years on Earth. In particular, much can be learned by unveiling the architectures of proteins, life’s molecular machines, through methods like X-ray crystallography. Acquiring the blueprints of an enzyme brings us closer to understanding the mechanism by which the enzyme transforms a simple substrate it into a complex product with biological function, and inspires us to engineer such systems to our own ends. With a focus on macromolecular structural characterization, this document elaborates on five Gram-negative bacterial biosynthetic enzymes from two categories: Cell-surface modifiers and polyketide synthases. Among the first category are the glycyl carrier protein AlmF and its ligase AlmE of Vibrio cholerae and the phosphoethanolamine transferase EptC of Campylobacter jejuni. These proteins are responsible for decorating cell-surface molecules (e.g., lipid A) of pathogenic bacteria with small functional groups to promote antibiotic resistance, motility, and host colonization. AlmE and EptC represent potential drug targets and their structures lay the groundwork for the design of therapeutics against food-borne illnesses. Included in the second category are the [4+2]-cyclase SpnF and two ketoreductase-linked dimerization elements, each from the spinosyn biosynthetic pathway in Saccharopolyspora spinosa. The former catalyzes a putative Diels-Alder reaction to form a tricyclic precursor of the insecticide spinosad, while the latter two organize ketoreductase domains within modules of a polyketide synthase. The second category also includes Ralstonia eutropha β-ketoacyl thiolase B, a substrate-permissive enzyme that can make or break carbon-carbon bonds with assistance from Coenzyme A or an analogous thiol. Each of these proteins exhibit intriguing structural features or catalyze reactions that show promise for biochemical engineering. / text
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