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The Utilization of Enzymes in the Synthesis and Modification of Natural and NonNatural Compounds: A Chemo-Enzymatic Approach to Enantiomerically Pure CompoundsCarr, Jason A 07 July 2004 (has links)
The employment of enzymes and whole cells has been important in many industries for centuries. However, it is only in the last 30 years that the use of enzymes for the synthesis of high-value fine chemicals has enjoyed increasing popularity. In fact, esterases and lipases are used almost routinely these days to provide optically active building blocks for the construction of imaginative new routes to chiral target molecules. The major topic of this work describes the utilization of enzymes (namely lipases) in the synthesis and modification of natural and non-natural compounds.
Chapter 1 outlines the strengths and weaknesses of the most widely used enzyme systems and a description of a brief summary on the state of the art of biotransformations with special emphasis on the general applicability and reliability of various reaction types is described.
Chapter 2 describes the enzymatic resolution of various 3-acetoxy-4-aryl-substituted azetidin-2-ones. Following screening of enzymes, such as Novozym-435, PS-30, PPL and AYS the best conditions were a phosphate buffer with PS-30 as the enzyme. The resulting products were the (3S, 4R)-3-hydroxy-4-aryl-substituted azetidin-2-ones and the unreacted (3R, 4S)-3-acetoxy-4-aryl-substituted azetidin-2-ones. Reactions generally occurred with high conversion and high selectivity.
In Chapter 3, the regioselective transesterifications and hydrolysis of peracylated sophorolipid (SL) derivatives catalyzed by lipases was investigated. It was confirmed from the detailed spectral analysis of the products that transesterification failed to furnish any free hydroxyls on the sophorose ring. Instead, transesterification took place on the methyl ester located at the carboxylic end of the 17-hydroxyoctadecenoic acid chain attached to the C-1' position of the sophorose ring.
In Chapter 4, the chemo-enzymatic syntheses of enantiomerically pure R and S imperanene from vanillin are described. The key step entails the asymmetrization of a prochiral diol using lipase PS-30. The resulting monoacetate has enantiomeric excesses of >97%.
Biocatalysts represent a new class of chiral catalysts useful for a broad range of selective organic transformations. It is stating the obvious to say that biocatalysis is not a panacea for synthetic organic chemistry. However, advances over the past thirty years mean that it would be a serious mistake not to consider the employment of a biocatalyst, in, perhaps, the key step in a sequence of transformations that turn a cheap starting material into an expensive fine chemical.
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Studies in Rhodium Catalyzed Intramolecular C-H Insertion of Amino Acid Derived α-Diazo-α-(substituted)acetamides and its Application to the Total Synthesis of <em>clasto</em>-Lactacystin β-LactoneFlanigan, David L, Jr. 24 May 2004 (has links)
Lactacystin is a microbial metabolite isolated by Omura that exhibits neurotrophic activity in neuroblastoma cell lines. Lactacystin and especially its β-lactone analog are the first examples of non-polypeptide small molecules capable of specifically inhibiting the 20S proteasome. Various asymmetric total syntheses of lactacystin and its analogs have been reported. The total synthesis of clasto -lactacystin β-lactone is achieved using L-serine methyl ester as the starting material and the sole source of stereochemical induction. The success of this synthesis hinges on two featured transformations. The first key step involves formation of the γ -lactam core via rhodium (II) catalyzed intramolecular C-H insertion of the α-diazo-α-(phenylsulfonyl)acetamide intermediate. The methodology for this transformation has been developed and applied to the synthesis of highly functionalized stereogenic γ-lactams from natural α-amino acids. Three control elements that govern γ-lactam formation are described. This step is highlighted by the xvi simultaneous creation of two stereogenic centers of the γ-lactam core. The second key step involves the late stage aldol coupling for quaternary carbon formation and installation of the hydroxyisobutyl group. In all previously reported syntheses, this is the very first aspect which is addressed. The stereochemical outcome of this step is directed by the chiral environment of the enolate itself. Various attempts to achieve selectivity are explored and reported. Completion of the synthesis of clasto-lactacystin β-lactone requires 17 steps with an overall yield of 10%. Some general attempts for optimizing the synthetic scheme are discussed as well as the future direction of this research.
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Mechanism Elucidation and Inhibitor Discovery against Serine and Metallo-Beta-Lactamases Involved in Bacterial Antibiotic ResistancePemberton, Orville A. 03 November 2017 (has links)
The emergence and proliferation of Gram-negative bacteria expressing β-lactamases is a significant threat to human health. β-Lactamases are enzymes that degrade the β-lactam antibiotics (e.g., penicillins, cephalosporins, monobactams, and carbapenems) that we use to treat a diverse range of bacterial infections. Specifically, β-lactamases catalyze a hydrolysis reaction where the β-lactam ring common to all β-lactam antibiotics and responsible for their antibacterial activity, is opened, leaving an inactive drug. There are two groups of β-lactamases: serine enzymes that use an active site serine residue for β-lactam hydrolysis and metalloenzymes that use either one or two zinc ions for catalysis. Serine enzymes are divided into three classes (A, C, and D), while there is only one class of metalloenzymes, class B. Clavulanic acid, sulbactam, and tazobactam are β-lactam-based BLIs that demonstrate activity against class A and C β-lactamases; however, they have no activity against the class A KPC and MBLs, NDM and VIM. Avibactam and vaborbactam are novel BLIs approved in the last two years that have activity against serine carbapenemases (e.g., KPC), but do not inhibit MBLs. The overall goals of this project were to use X-ray crystallography to study the catalytic mechanism of serine β-lactamases with β-lactam antibiotics and to understand the mechanisms behind the broad-spectrum inhibition of class A β-lactamases by avibactam and vaborbactam. This project also set out to find novel inhibitors using molecular docking and FBDD that would simultaneously inactivate serine β-lactamases and MBLs commonly expressed in Gram-negative pathogenic bacteria.
The first project involved examining the structural basis for the class A KPC-2 β-lactamase broad-spectrum of activity that includes cephalosporins and carbapenems. Three crystal structures were solved of KPC-2: (1) an apo-structure at 1.15 Å; (2) a complex structure with the hydrolyzed cephalosporin, cefotaxime at 1.45 Å; and (3) a complex structure with the hydrolyzed penem, faropenem at 1.40 Å. These complex structures show how alternative conformations of Ser70 and Lys73 play a role in the product release step. The large and shallow active site of KPC-2 can accommodate a wide variety of β-lactams, including the bulky oxyimino side chain of cefotaxime and also permits the rotation of faropenem’s 6-alpha-1R-hydroxyethyl group to promote carbapenem hydrolysis. Lastly, the complex structures highlight that the catalytic versatility of KPC-2 may expose a potential opportunity for drug discovery.
The second project focused on understanding the stability of the BLI, avibactam, against hydrolysis by serine β-lactamases. A 0.83 Å crystal structure of CTX-M-14 bound by avibactam revealed that binding of the inhibitor impedes a critical proton transfer between Glu166 and Lys73. This results in a neutral Glu166 and neutral Lys73. A neutral Glu166 is unable to serve as a general base to activate the catalytic water for the hydrolysis reaction. Overall, this structure suggests that avibactam can influence the protonation state of catalytic residues.
The third project centered on vaborbactam, a cyclic boronic acid inhibitor of class A and C β-lactamases, including the serine class A carbapenemase KPC-2. To characterize vaborbactam inhibition, binding kinetic experiments, MIC assays, and mutagenesis studies were performed. A crystal structure of the inhibitor bound to KPC-2 was solved to 1.25 Å. These data revealed that vaborbactam achieves nanomolar potency against KPC-2 due to its covalent and extensive non-covalent interactions with conserved active site residues. Also, a slow off-rate and long drug-target residence time of vaborbactam with KPC-2 strongly correlates with in vitro and in vivo activity.
The final project focused on discovering dual action inhibitors targeting serine carbapenemases and MBLs. Performing molecular docking against KPC-2 led to the identification of a compound with a phosphonate-based scaffold. Testing this compound using a nitrocefin assay confirmed that it had micromolar potency against KPC-2. SAR studies were performed on this scaffold, which led to a nanomolar inhibitor against KPC-2. Crystal structures of the inhibitors complexed with KPC-2 revealed interactions with active site residues such as Trp105, Ser130, Thr235, and Thr237, which are all important in ligand binding and catalysis. Interestingly, the phosphonate inhibitors that displayed activity against KPC-2, also displayed activity against the MBLs NDM-1 and VIM-2. Crystal structures of the inhibitors complexed with NDM-1 and VIM-2 showed that the phosphonate group displaces a catalytic hydroxide ion located between the two zinc ions in the active site. Additionally, the compounds form extensive hydrophobic interactions that contribute to their activity against NDM-1 and VIM-2. MIC assays were performed on select inhibitors against clinical isolates of Gram-negative bacteria expressing KPC-2, NDM-1, and VIM-2. One phosphonate inhibitor was able to reduce the MIC of the carbapenem, imipenem 64-fold against a K. pneumoniae strain producing KPC-2. The same phosphonate inhibitor also reduced the MIC of imipenem 4-fold against an E. coli strain producing NDM-1. Unfortunately, no cell-based activity was observed for any of the phosphonate inhibitors when tested against a P. aeruginosa strain producing VIM-2. Ultimately, this project demonstrated the feasibility of developing cross-class BLIs using molecular docking, FBDD, and SAR studies.
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Tertiary Alcohol- or β-Hydroxy γ-Lactam-Based HIV-1 Protease Inhibitors : Microwave Applications in Batch and Continuous Flow Organic SynthesisÖhrngren, Per January 2011 (has links)
Since the outbreak of the HIV/AIDS pandemic in the 1980s, the disease has cost the lives of over 30 million people, and a further 33 million are currently living with the HIV infection. With the appropriate treatment, HIV/AIDS can today be regarded as a chronic but manageable disease. However, treatment is not available globally and UNAIDS still estimates that there are currently 5000 AIDS-related deaths worldwide per day. HIV protease inhibitors (PIs) constitute one of the fundaments of HIV treatment, and are commonly used in so-called highly active antiretroviral therapy (HAART), together with reverse transcriptase inhibitors. Although there are ten PIs on the market, there is still a need for novel structures. The rapid development of resistant strains, due to the high frequency of mutations, together with the commonly observed adverse effects of the drugs available, illustrate the need to develop new potent structures. Two novel scaffolds were investigated in this work. A tertiary alcohol-containing scaffold comprising a three-carbon tether, and a β-hydroxy γ-lactam-based scaffold were designed, synthesized and evaluated using enzyme- and cell-based assays. X-ray analyses of inhibitors from each class provided information on inhibitor–protease interactions. The inhibitors containing the tertiary alcohol provided at best an enzymatic inhibition (Ki) of 2.3 nM, and an inhibition in the cell-based assay (EC50) of 0.17 µM. The γ-lactam-based inhibitors exhibited better inhibition than the first series; the best values being Ki = 0.7 nM and EC50 = 0.04 µM. The second part of these studies involved the evaluation of a novel non-resonance continuous-flow microwave instrument. The instrument was validated regarding heating capacity, temperature stability and temperature homogeneity. A number of model reactions were performed with low- and high-microwave-absorbing solvents. It was found that the microwave heating source allowed rapid temperature adjustment, together with easily regulated, flow-dependent reaction times, providing an efficient tool for reaction optimisation.
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Improving the enzymatic synthesis of semi-synthetic beta-lactam antibiotics via reaction engineering and data-driven protein engineeringDeaguero, Andria Lynn 16 August 2011 (has links)
Semi-synthetic β-lactam antibiotics are the most prescribed class of antibiotics in the world. Chemical coupling of a β-lactam moiety with an acyl side chain has dominated the industrial production of semi-synthetic β-lactam antibiotics since their discovery in the early 1960s. Enzymatic coupling of a β-lactam moiety with an acyl side chain can be accomplished in a process that is much more environmentally benign but also results in a much lower yield. The goal of the research presented in this dissertation is to improve the enzymatic synthesis of β-lactam antibiotics via reaction engineering, medium engineering and data-drive protein engineering.
Reaction engineering was employed to demonstrate that the hydrolysis of penicillin G to produce the β-lactam nucleus 6-aminopenicillanic acid (6-APA), and the synthesis of ampicillin from 6-APA and (R)-phenylglycine methyl ester ((R)-PGME), can be combined in a cascade conversion. In this work, penicillin G acylase (PGA) was utilized to catalyze the hydrolysis step, and PGA and α-amino ester hydrolase (AEH) were both studied to catalyze the synthesis step. Two different reaction configurations and various relative enzyme loadings were studied. Both configurations present a promising alternative to the current two-pot set-up which requires intermittent isolation of the intermediate, 6-APA.
Medium engineering is primarily of interest in β-lactam antibiotic synthesis as a means to suppress the undesired primary and secondary hydrolysis reactions. The synthesis of ampicillin from 6-APA and (R)-PGME in the presence of ethylene glycol was chosen for study after a review of the literature. It was discovered that the transesterification product of (R)-PGME and ethylene glycol, (R)-phenylglycine hydroxyethyl ester, is transiently formed during the synthesis reactions. This never reported side reaction has the ability to positively affect yield by re-directing a portion of the consumption of (R)-PGME to an intermediate that could be used to synthesize ampicillin, rather than to an unusable hydrolysis product.
Protein engineering was utilized to alter the selectivity of wild-type PGA with respect to the substituent on the alpha carbon of its substrates. Four residues were identified that had altered selectivity toward the desired product, (R)-ampicillin. Furthermore, the (R)-selective variants improved the yield from pure (R)-PGME up to 2-fold and significantly decreased the amount of secondary hydrolysis present in the reactions.
Overall, we have expanded the applicability of PGA and AEH for the synthesis of semi-synthetic β-lactam antibiotics. We have shown the two enzymes can be combined in a novel one-pot cascade, which has the potential to eliminate an isolation step in the current manufacturing process. Furthermore, we have shown that the previously reported ex-situ mixed donor synthesis of ampicillin for PGA can also occur in-situ in the presence of a suitable side chain acyl donor and co-solvent. Finally, we have made significant progress towards obtaining a selective PGA that is capable of synthesizing diastereomerically pure semi-synthetic β-lactam antibiotics from racemic substrates.
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A new approach to kainoids: Total syntheses of (-)-kainic acid and (+)-allokainic acidJung, Young Chun 01 June 2006 (has links)
(-)-Kainic acid and its C-4 epimer, (+)-allokainic acid are parent members of a class of substituted pyrrolidines known as kainoids. They have been found to exhibit powerful biological properties, principally neuroexcitatory. Kainic acid has become especially important in the study of Alzheimer's disease, epilepsy, and other neurological disorders. The total syntheses of (-)-kainic acid and (+)-allokainic acid were achieved using (L)-glutamic acid as the starting material and the sole source of stereochemical induction. The key steps for these successful syntheses involve formation of the gamma-lactam core via rhodium (II) catalyzed intramolecular C-H insertion of the alpha-diazo-alpha-(phenylsulfonyl)acetamide intermediate and the stereoselective dephenylsufonylation. Pd(II)-catalyzed and oxygen promoted carbon-carbon bond formation methodologies using organoboronic reagents were developed. The first one is a mild and efficient Pd(II) catalysis, leading to the formation of carbon-carbon bonds between a broad spectrum of organoboron compounds and alkenes. Molecular oxygen was employed to reoxidize the resultant Pd(0) species back to Pd(II) during catalytic cycles.This oxygen protocol promoted the desired Pd(II) catalysis, whereas it retarded competing Pd(0) catalytic pathways such as Heck or Suzuki couplings. The second one is the formation of symmetric biaryls and dienes via oxidative dimerization of aryl and alkenyl boronic acids. These conditions utilized Pd(II) catalysts under an oxygen atmosphere with water as the solvent. The use of phase transfer catalysts promoted efficient and mild syntheses of a wide range of materials.
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Structural characterization of superbug proteins involved in regulating beta-lactam resistanceWilke, Mark Steven 05 1900 (has links)
The widespread use of β-lactams has undermined their effectiveness as chemotherapeutic agents by fueling the evolution and dissemination of multiple resistance mechanisms, including: (1) production of hydrolytic β-lactamase enzymes that inactivate β-lactams, (2) expression of PBPs with low-affinity for β-lactams and (3) overexpression of multidrug efflux pumps which actively expunge β-lactams and other toxic substances. The overall goal of this thesis is the structural characterization of bacterial proteins involved in regulating β-lactam resistance.
The notorious resistance of Staphylococcus aureus primarily stems from the production of β-lactamases and PBP2a, a low-affinity PBP which confers broad-spectrum β-lactam resistance in methicillin-resistant S. aureus (MRSA) strains. Expression of these resistance determinants is controlled by a β-lactam-inducible transmembrane receptor (BlaR1/MecR1) and repressor (BlaI/MecI). This dissertation presents the crystal structure of the BlaR1 sensor domain (BlaRs) from S. aureus, determined in its apo form and acylated with penicillin G. These structures reveal that acylation by β-lactams is not accompanied by a BlaRs conformational change. It is also shown that mutation of the BlaR1 L2 loop prevents induction of β-lactamase expression in vivo, supporting that the L2 loop plays an important role in signal transduction.
The intrinsic resistance of Pseudomonas aeruginosa to a variety of antibiotics (including β-lactams) is exacerbated in mutant strains that overexpress multidrug efflux pumps such as MexAB-OprM. Production of MexAB-OprM is controlled by the MarR family repressor, MexR, and several hyper-resistant strains of P. aeruginosa appear to involve mutations in either MexR or additional regulatory factors upstream of MexR. The allosteric effectors of MarR proteins are typically small lipophenolic compounds. This dissertation confirms that MexR is uniquely modulated by the 53 residue protein, ArmR. Electromobility gel shift assays and isothermal titration calorimetry demonstrate that a direct MexR-ArmR interaction is responsible for neutralizing the affinity of MexR for its DNA operator. The allosteric conformational change induced by ArmR-binding was assessed by determining the crystal structure of MexR double mutant Q106L/A110L (MexRLL) in complex with ArmR residues 29-53 (ArmRC). This structure shows that ArmR induces a dramatic conformational change which repositions the MexR DNA-binding lobes into an orientation that is incompatible with binding DNA.
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Investigation of exudative epidermitis and ear necrosis in pigsPark, Jeonghwa 23 December 2011 (has links)
This thesis is an investigation of two common skin conditions of pigs: exudative epidermitis (EE) and ear necrosis (EN). The cause of exudative epidermitis and risk factors are well understood, however the study was prompted because of reports of treatment failure. A survey of veterinary practitioners (n=15) and pork producers (n=58) was conducted to determine which treatments are commonly used. Amongst farmer respondents topical treatments were often used and in serious cases injectable penicillin G was administered. Thirty farms with a history of EE were visited and skin samples taken from affected pigs. The antimicrobial resistance pattern for isolates of Staphylococcus hyicus and Staphylococcus aureus revealed that almost all isolates were resistant to penicillin G and ampicillin. In addition, certain isolates of S. hyicus as well as S. aureus were shown to possess the mecA gene which is associated with resistance to methicillin. The presence of widespread resistance to penicillin G among staphylococci isolates suggests a reason for poor treatment response. The presence of the mecA gene in staphylococci other than S. aureus recovered from pigs has not been reported before and is of interest from a public health standpoint.
A second study investigated EN. The causative agent(s) and the associated risk factors are not well understood. Eleven case farms were visited and skin biopsies and oral swabs taken from pigs in early, mid and late stages of the disease. Bacteriological culturing was performed for staphylococci and spirochetes as well as histological examination of the biopsy samples. Farm-level risk factors were assessed on 14 case farms and 9 control farms. Staphylococci were generally recovered in abundance from the majority of samples but spirochetes were not cultured and only identified microscopically in a small number of tissue samples. Histology revealed that the disease appeared to occur first as a lesion on the epidermal surface that caused tissue damage and led to subsequent invasion of the dermis. This pathogenesis was consistent with the hypothesis that staphylococci colonize the skin surface and produce exfoliating toxins. Ear biting was noted to be commonly present and may be an important contributing factor. / Ontario Pork
Animal Health Strategic Initiative Fund
Ontario Ministry of Agriculture, Food and Rural Affairs(OMAFRA)
Ontario Veterinary College, University of Guelph
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Cyclobutanone Analogues of ??-Lactam Antibiotics as Inhibitors of Serine- and Metallo-??-LactamasesJohnson, Jarrod William 06 November 2014 (has links)
Bacterial resistance to antibiotics is an emerging epidemic throughout the world and there is a desperate need for new antibiotics and new strategies to maintain the effectiveness of current agents. ??-Lactams, such as the penicillins and cephalosporins, have been the most important class of antibiotic for several decades and represent half of the global antibacterial market, but the continued use of ??-lactams is threatened by ??-lactamases, enzymes that efficiently inactivate ??-lactams through hydrolysis. Class A, C, and D ??-lactamases use an active-site serine residue for hydrolysis and achieve turnover through an acylenzyme intermediate while the class B metallo-??-lactamases (MBLs) use a zinc-bound hydroxide as the active-site nucleophile.
Two successful approaches to combat ??-lactamase-mediated resistance have involved the development of ??-lactam antibiotics which bind poorly to ??-lactamases and the combination of ??-lactams with ??-lactamase inhibitors. These strategies have been effective for overcoming resistance due to class A ??-lactamases, but the ever-increasing prevalence of extended-spectrum ??-lactamases (ESBLs), metallo-??-lactamases, and carbapenemases compromises the effectiveness of current penicillins, cephalosporins, carbapenems, and mechanism-based ??-lactamase inhibitors.
Cyclobutanone analogues of ??-lactam antibiotics were explored in the early 1980s as potential inhibitors of ??-lactamases and D-Ala-D-Ala transpeptidases, but simple analogues showed only weak inhibitory activity and this approach was subsequently abandoned. The increasing threat of multidrug-resistant ??-lactamase-producing organisms in recent years, however, has inspired a re-evaluation of these inhibitors since cyclobutanones have the potential to exhibit broad-spectrum inhibition of both serine- and metallo-??-lactamases through the formation of enzyme-bound hemiketals or hydrates.
7,7-Dichloro-2-thia-bicyclo[3.2.0]heptan-6-one-4-carboxylic acid (65), a dichlorocyclobutanone that had shown modest inhibition of the class B and D ??-lactamases IMP-1 and OXA-10 in earlier work in this laboratory, was prepared in an efficient seven-step sequence from triethyl phosphonoacetate (103) with an overall yield of 28%. Initial efforts to improve upon the potency of the cyclobutanones involved functionalization at C3 and a highly stereoselective chlorination with sulfuryl chloride provided the 3??-chloro derivative 117?? in nearly quantitative yield. Elimination of HCl from 117?? was achieved under a variety of conditions and 3-alkoxy derivatives were prepared from 117?? through diastereoselective substitution reactions with alcohols. Cyclobutanones with 3??-OR substituents were found to favour an endo envelope conformation while the 3??-OR derivatives adopt the exo envelope conformation. Evidence from X-ray crystal structures and ab initio molecular orbital calculations suggests that an anomeric effect contributes to the large conformational preference of the tetrahydrothiophene ring that favours the 3-alkoxy substituent in an axial orientation. In addition, the conformation of the bicyclic system was found to have a dramatic effect on the tendency of the cyclobutanone to undergo hemiketal formation.
Cyclobutanone analogues of penicillins, including 3-alkoxy derivatives, and cyclobutanone analogues of penems were evaluated against class A, B, C, and D ??-lactamases and found to be moderate inhibitors of KPC-2, IMP-1, GC1, and OXA-10. The cyclobutanones found to be most potent were those which are hydrated to a larger extent in aqueous solution. Dichlorocyclobutanones were found to be better inhibitors than dechlorinated cyclobutanones and a 3??-methoxy derivative 152??, which favours the exo envelope conformation in which the C4 carboxylate is equatorial, was found to be a better inhibitor than cyclobutanones that favour the endo envelope conformation. A 3,4-unsaturated penem analogue, 153, showed comparable potency to that of 152?? and molecular models of enzyme-inhibitor complexes indicate that an equatorial carboxylate is required for binding to ??-lactamases. An X-ray crystal structure of 152?? bound to the class D ??-lactamase OXA-10 confirms that a serine hemiketal is formed in the active site and that the inhibitor adopts the exo envelope.
The biochemical data described above demonstrate that cyclobutanones can indeed act as inhibitors of serine- and metallo-??-lactamases and these cyclobutanones represent the first class of reversible inhibitors to show moderate inhibition of all four classes of ??-lactamase. Although the inhibitory potency of these compounds is modest (low micromolar IC50 values), penem analogue 153 was able to enhance the potency of meropenem against carbapenem-resistant MBL-producing clinical isolates of Chryseobacterium meningosepticum and Stenotrophomonas maltophilia and the synergy demonstrated in these antimicrobial assays is encouraging.
Synthetic studies toward other C3-alkyl and C3-thioalkyl-substituted inhibitors are described and the design and synthesis of C7-monochloro- and 7??-hydroxymethyl-7??-chloro cyclobutanone derivatives is presented.
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Structural characterization of superbug proteins involved in regulating beta-lactam resistanceWilke, Mark Steven 05 1900 (has links)
The widespread use of β-lactams has undermined their effectiveness as chemotherapeutic agents by fueling the evolution and dissemination of multiple resistance mechanisms, including: (1) production of hydrolytic β-lactamase enzymes that inactivate β-lactams, (2) expression of PBPs with low-affinity for β-lactams and (3) overexpression of multidrug efflux pumps which actively expunge β-lactams and other toxic substances. The overall goal of this thesis is the structural characterization of bacterial proteins involved in regulating β-lactam resistance.
The notorious resistance of Staphylococcus aureus primarily stems from the production of β-lactamases and PBP2a, a low-affinity PBP which confers broad-spectrum β-lactam resistance in methicillin-resistant S. aureus (MRSA) strains. Expression of these resistance determinants is controlled by a β-lactam-inducible transmembrane receptor (BlaR1/MecR1) and repressor (BlaI/MecI). This dissertation presents the crystal structure of the BlaR1 sensor domain (BlaRs) from S. aureus, determined in its apo form and acylated with penicillin G. These structures reveal that acylation by β-lactams is not accompanied by a BlaRs conformational change. It is also shown that mutation of the BlaR1 L2 loop prevents induction of β-lactamase expression in vivo, supporting that the L2 loop plays an important role in signal transduction.
The intrinsic resistance of Pseudomonas aeruginosa to a variety of antibiotics (including β-lactams) is exacerbated in mutant strains that overexpress multidrug efflux pumps such as MexAB-OprM. Production of MexAB-OprM is controlled by the MarR family repressor, MexR, and several hyper-resistant strains of P. aeruginosa appear to involve mutations in either MexR or additional regulatory factors upstream of MexR. The allosteric effectors of MarR proteins are typically small lipophenolic compounds. This dissertation confirms that MexR is uniquely modulated by the 53 residue protein, ArmR. Electromobility gel shift assays and isothermal titration calorimetry demonstrate that a direct MexR-ArmR interaction is responsible for neutralizing the affinity of MexR for its DNA operator. The allosteric conformational change induced by ArmR-binding was assessed by determining the crystal structure of MexR double mutant Q106L/A110L (MexRLL) in complex with ArmR residues 29-53 (ArmRC). This structure shows that ArmR induces a dramatic conformational change which repositions the MexR DNA-binding lobes into an orientation that is incompatible with binding DNA.
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