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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Mechanism Elucidation and Inhibitor Discovery against Serine and Metallo-Beta-Lactamases Involved in Bacterial Antibiotic Resistance

Pemberton, 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.
2

A spectrophotometric method to analyze antibiotics in plasma: A validation study

Lindman, Elin January 2018 (has links)
Antibiotic resistance is one of the most serious medical problems in the world. To counteract the increase in antibiotic resistance, new rapid and effective analytical methods are needed. To effectively treat infections in critically ill patients, optimal antibiotic dosages are required. DrugLog® is an instrument that uses a spectrophotometric method to analyze antibiotics in plasma in the wavelength range 200-800 nm. The aim of this study was to do a method validation of the instrument DrugLog®.     The study material that was used was whole blood from healthy donor and routine citrate plasma samples from the laboratory. The precision of the method and stability of plasma, the best way to filtrate lipids from plasma and four antibiotics (meropenem, cefotaxime, vancomycin, piperacillin/tazobactam) were investigated.     The precision of the method, measured as CV% was less than 0.62 and stability plasma showed a CV% of 135.74 after 24 h in room temperature. The stability for the different antibiotics after 24 h in room temperature showed a CV% of 8.11 for meropenem, 40.80 for vancomycin, 16.55 for cefotaxime and 2.92 for the combination antibiotic piperacillin/tazobactam. It was also determined that bacterial filter was the best way to remove lipids from plasma.     In conclusion DrugLog® is a suitable instrument to analyze concentration of antibiotics in patients during antibiotic treatment, however further validations are needed.
3

Individualized treatment and control of bacterial infections

Woksepp, Hanna January 2017 (has links)
Infectious diseases cause substantial morbidity and mortality, exacerbated by increasing antibiotic resistance. In critically ill patients, recent studies indicate a substantial variability in β-lactam antibiotic levels when standardized dosing is applied. New methods for characterizing nosocomial outbreaks of bacterial infections are needed to limit transmission. The goals of this thesis were to investigate new strategies towards individualized treatment and control of bacterial infections.  In Paper I we confirmed high variability in β-lactam antibiotic levels among intensive care unit (ICU) patients from southeastern Sweden, where 45 % failed to reach treatment targets (100 % fT>MIC). Augmented renal clearance and establishing the minimum inhibitory concentration of the bacteria were important for evaluating the risk of not attaining adequate drug levels. In Paper II a rapid ultra-performance liquid chromatography tandem mass spectrometry (UPLC-MS/MS) method for simultaneous quantification of 11 commonly used antibiotics was developed and tested in clinical samples. Performance goals (CV<15%) were reached. A microbiological method for quantification of β-lactam antibiotics in serum was developed in Paper III. The method could be important for hospitals without access to an LC-MS method. Paper IV and Paper V investigated ligation-mediated qPCR with high resolution melt analysis (LMqPCR HRMA), for transmission investigation of extended spectrum β-lactamase (ESBL)-producing E. coli and other common bacterial pathogens. Results comparable to the reference method (PFGE) could be achieved within one day in a closed system and confirmed a nosocomial outbreak in Kalmar County. In Paper VI whole genome sequencing followed by bioinformatic analysis resolved transmission links within a nosocomial outbreak due to improved discriminatory power compared to LMqPCR HRMA. The high proportion of ICU patients with insufficient β-lactam drug levels emphasizes the need for individualized treatment by therapeutic drug monitoring (TDM). TDM is enabled by a highly sensitive method, such as UPLC-MS/MS, but if unavailable, also by a microbial method. Molecular typing methods used for transmission investigation can detect nosocomial outbreaks. LMqPCR HRMA can be used for screening purposes. For enhanced resolution, whole genome sequencing should be used, but always together with a rigorous epidemiological investigation.
4

Biological and Pharmacological Factor that Influence the Selection of Antibiotic Resistance

Gustafsson, Ingegerd January 2003 (has links)
<p>Antibiotic treatment causes an ecological disturbance on the human microflora. Four commensal bacteria: E. coli, enterococci, a-streptococci and coagulase-negative staphylococci, from patients with extensive, high antibiotic usage were investigated with regard to resistance pattern and mutation frequency. Among 193 investigated strains it was found that high antibiotic usage selected for resistant bacteria and enriched for bacteria with a small but significantly increased mutation frequency. </p><p>The relative biological fitness cost of resistance in <i>Staphylococcus epidermidis</i> was assessed in a human in vivo model where the indigenous flora was present. In vitro data of the bacterial growth rate correlated well to in vivo fitness assayed in the competition experiments on skin. </p><p>An in vitro kinetic model was shown to be a useful tool to establish the pharmacokinetic and pharmacodynamic (PK/PD) indices for efficacy of antibiotics. It was confirmed that the time, when the concentration exceeds the minimal inhibitory concentration (MIC), correlates with efficacy for b-lactam antibiotics. To achieve maximal killing for penicillin-resistant pneumococci, with an MIC of 2 mg/L, the peak concentration was also of importance. </p><p>Suboptimal dosing regimen facilitates selection of resistance. Penicillin-resistant pneumococci were easily selected in a mixed population with penicillin-sensitive, -intermediate and -resistant pneumococci in an in vitro kinetic model. The selection of the resistant strain was prevented when the benzylpenicillin concentration exceeded the MIC for approximately 50% of 24 h.</p>
5

Antibiotic-induced Bacterial Toxin Release – Inhibition by Protein Synthesis Inhibitors

Hjerdt-Goscinski, Gunilla January 2004 (has links)
<p>Toxic products, such as endotoxin from the gram-negative and exotoxin from the gram-positive bacteria, are the most important initiators of the inflammatory host response in sepsis. In addition to antibacterial treatment, numerous attempts have been made to interfere with the exaggerated proinflammatory cascade initiated by the toxins. As most antitoxic and anti-inflammatory agents have shown no clear efficacy, an attractive alternative has been to prevent or minimise their release. Therefore, it was of interest to further study the antibiotic-induced release of toxins after exposure to antibiotics used for the treatment of the most severe infections, especially if protein synthesis inhibitors could reduce the release induced by PBP 3-specific β-lactam antibiotics.</p><p>There were significant reductions in endotoxin release from gram-negative bacteria when the combination of the PBP 3-specific β-lactam antibiotic, cefuroxime, and the protein synthesis inhibitor, tobramycin, was compared with cefuroxime alone. Increasing doses of tobramycin reduced endotoxin release and increased the killing rate. In a kinetic <i>in vitro</i> model the endotoxin release from <i>E.coli</i> was higher after the second dose of cefuroxime. Nevertheless, it was reduced after addition of tobramycin.</p><p>No binding of tobramycin to endotoxin was observed, either <i>in vivo</i> or <i>in vitro</i>. In a porcine sepsis model, a possible anti-inflammatory effect of ceftazidime and tobramycin, expressed as late cytokine inhibition, was seen.</p><p>The protein synthesis inhibitor, clindamycin, released less streptococcal pyrogenic exotoxin A (SpeA) from a group A streptococcus strain than penicillin, and addition of clindamycin to penicillin resulted in less toxin production than penicillin alone. The SpeA production was dependent on the bacterial number at the start of treatment. Higher doses of penicillin also led to less SpeA. </p><p>The choice of antibiotic class and dose may be important in the severely ill septic patient in whom an additional toxin release could be deleterious. A combination of a β-lactam antibiotic and a protein synthesis inhibitor seems beneficial but further investigations are needed.</p>
6

Antibiotic-induced Bacterial Toxin Release – Inhibition by Protein Synthesis Inhibitors

Hjerdt-Goscinski, Gunilla January 2004 (has links)
Toxic products, such as endotoxin from the gram-negative and exotoxin from the gram-positive bacteria, are the most important initiators of the inflammatory host response in sepsis. In addition to antibacterial treatment, numerous attempts have been made to interfere with the exaggerated proinflammatory cascade initiated by the toxins. As most antitoxic and anti-inflammatory agents have shown no clear efficacy, an attractive alternative has been to prevent or minimise their release. Therefore, it was of interest to further study the antibiotic-induced release of toxins after exposure to antibiotics used for the treatment of the most severe infections, especially if protein synthesis inhibitors could reduce the release induced by PBP 3-specific β-lactam antibiotics. There were significant reductions in endotoxin release from gram-negative bacteria when the combination of the PBP 3-specific β-lactam antibiotic, cefuroxime, and the protein synthesis inhibitor, tobramycin, was compared with cefuroxime alone. Increasing doses of tobramycin reduced endotoxin release and increased the killing rate. In a kinetic in vitro model the endotoxin release from E.coli was higher after the second dose of cefuroxime. Nevertheless, it was reduced after addition of tobramycin. No binding of tobramycin to endotoxin was observed, either in vivo or in vitro. In a porcine sepsis model, a possible anti-inflammatory effect of ceftazidime and tobramycin, expressed as late cytokine inhibition, was seen. The protein synthesis inhibitor, clindamycin, released less streptococcal pyrogenic exotoxin A (SpeA) from a group A streptococcus strain than penicillin, and addition of clindamycin to penicillin resulted in less toxin production than penicillin alone. The SpeA production was dependent on the bacterial number at the start of treatment. Higher doses of penicillin also led to less SpeA. The choice of antibiotic class and dose may be important in the severely ill septic patient in whom an additional toxin release could be deleterious. A combination of a β-lactam antibiotic and a protein synthesis inhibitor seems beneficial but further investigations are needed.
7

Biological and Pharmacological Factor that Influence the Selection of Antibiotic Resistance

Gustafsson, Ingegerd January 2003 (has links)
Antibiotic treatment causes an ecological disturbance on the human microflora. Four commensal bacteria: E. coli, enterococci, a-streptococci and coagulase-negative staphylococci, from patients with extensive, high antibiotic usage were investigated with regard to resistance pattern and mutation frequency. Among 193 investigated strains it was found that high antibiotic usage selected for resistant bacteria and enriched for bacteria with a small but significantly increased mutation frequency. The relative biological fitness cost of resistance in Staphylococcus epidermidis was assessed in a human in vivo model where the indigenous flora was present. In vitro data of the bacterial growth rate correlated well to in vivo fitness assayed in the competition experiments on skin. An in vitro kinetic model was shown to be a useful tool to establish the pharmacokinetic and pharmacodynamic (PK/PD) indices for efficacy of antibiotics. It was confirmed that the time, when the concentration exceeds the minimal inhibitory concentration (MIC), correlates with efficacy for b-lactam antibiotics. To achieve maximal killing for penicillin-resistant pneumococci, with an MIC of 2 mg/L, the peak concentration was also of importance. Suboptimal dosing regimen facilitates selection of resistance. Penicillin-resistant pneumococci were easily selected in a mixed population with penicillin-sensitive, -intermediate and -resistant pneumococci in an in vitro kinetic model. The selection of the resistant strain was prevented when the benzylpenicillin concentration exceeded the MIC for approximately 50% of 24 h.
8

Synthesis and Evaluation of Antigenic Determinants for ß-lactam Allergy Diagnosis

Peña Mendizabal, Edurne 09 May 2022 (has links)
Tesis por compendio / [EN] About 10 % of all adverse drug reactions are due to allergies, with ß-lactam antibiotics causing the majority of the episodes. Although the actual incidence remains unknown, individuals suspected of being allergic to a drug end up being prescribed with other medications that are less effective, more expensive or harmful. Consequently, a correct diagnosis is key to reduce the derived economic costs and proceed to an adequate 'delabeling' of the population. At present, clinical approaches to diagnose allergies to ß-lactam antibiotics are based on in vivo and in vitro tests. These tests present limited clinical performances since they are invasive, dangerous, and provide false positives and/or negatives. Moreover, the diagnostic sensitivity is far from what is expected, possibly because the epitopes that cause the allergic episodes are still not well detected. In this respect, the preparation of antigens has commonly been determined by the direct attachment of antibiotics to carrier molecules through the formation of an amide bond between amino lysine groups of the carrier molecule and the carboxylate group of the antibiotic. Even so, specific IgE are barely detected with such antigens. This dissertation addresses the synthesis of haptens and the generation of antigens to ß-lactam antibiotics, which develop a more reliable in vitro diagnosis of allergies to these drugs. The evaluation of the antigens has been carried out by means of multiplex in vitro tests based on compact disc technology. This research begins by focusing on the synthesis and preparation of penicillin antigens. To this end, first, the effect of the incorporation of aliphatic spacer arms in the chemical structure of penicillin has been approached, considering the possibility that a better molecular recognition is obtained by moving the hapten away from the carrier protein. Thirteen haptens derived from benzylpenicillin and amoxicillin were synthesized in order to prepare antigens with human serum albumin. The evaluation of the antigens revealed that even though they were immunogenic and were detected by the raised IgG antibodies, they were not detected by specific IgE from allergic patients. Additionally, the next approach considered the cationization of the carrier proteins, human serum albumin and histone. The modification of carboxylate groups of the protein to amino groups allow for an increase of the molar hapten/protein ratio. This strategy led to the generation of five antigens, four of which (only those histone-based antigens), did increase the sensitivity of the assay. Concretely, specific IgE has been determined in sera from allergic patients at low concentrations (LOD = 0.07 IU/mL) with a diagnostic specificity of 100 % and a sensitivity of 60 and 31 % for benzylpenicillin and amoxicillin, respectively. That means a 60 % improvement in the diagnostic sensitivity when compared to the in vitro reference test. Subsequently, the idea of preparing minor antigens based on penicillin metabolites was approached. Penicilloic, penilloic, penicillic, and 6-aminopenicillanic acids, together with penicillamine, were therefore conjugated to the carrier proteins human serum albumin and histone. Except penilloic acid, the rest of antigens were selectively detected when testing a set of serum samples from allergic patients. The diagnostic specificity obtained was 100 %, 94 % in the case of penicillic acid, and the sensitivity was between 67 and 100 %. Another approach was focused on the production of antigens for other families of ß-lactam antibiotics. The generation of antigens for cephalosporins, carbapenems, monobactams or ß-lactam inhibitors is essential, since in vitro tests for the detection of allergies to these antibiotics are not commercially available. Therefore, the results obtained after the preparation of major and minor antigens for the antibiotics cefuroxime, cefotaxime, ceftriaxone, meropenem, and aztreonam were evaluated. / [ES] Alrededor del 10 % de las reacciones adversas a medicamentos son debidas a alergias, siendo los antibióticos ß-lactámicos los que más episodios alérgicos ocasionan. Aunque la incidencia real sigue siendo desconocida, los individuos sospechosos de presentar alergia a algún medicamento acaban siendo prescritos con otros medicamentos, menos efectivos, más caros o perjudiciales. Así pues, un correcto diagnóstico resulta clave para disminuir los costes económicos derivados y proceder a un adecuado 'desetiquetado' de la población. En la actualidad, las pruebas de diagnóstico de alergias a antibióticos ß-lactámicos se basan en ensayos in vivo e in vitro. Estos ensayos muestran bajas prestaciones, ya que son invasivos y peligrosos y proporcionan falsos positivos y/o negativos. Además, la sensibilidad diagnóstica está lejos de ser la esperada, posiblemente porque aún no se ha conseguido reconocer todos los epítopos causantes de los episodios alérgicos. En este sentido, la preparación de antígenos se ha basado hasta el momento, en mayor medida, en la unión directa de los antibióticos a las moléculas portadoras mediante la formación de un enlace amida entre los grupos amino de las lisinas de la molécula portadora y el grupo carboxilato del antibiótico. Aun así, las IgE específicas son vagamente detectadas con estos antígenos. En esta tesis se ha abordado la síntesis de haptenos y la generación de determinantes antigénicos a antibióticos ß-lactámicos con los que poder realizar un diagnóstico in vitro más fiable de alergias a estos fármacos. La evaluación de los mismos se ha llevado a cabo mediante ensayos in vitro multiplex basados en tecnología de disco compacto. Esta investigación comienza centrándose en la síntesis y preparación de antígenos de penicilina. Para ello, en una primera fase se ha estudiado el efecto de la incorporación de brazos espaciadores alifáticos en la generación de antígenos, considerando la posibilidad de que se obtenga un mejor reconocimiento molecular al alejar el hapteno de la proteína portadora. Se sintetizaron trece haptenos derivados de bencilpenicilina y amoxicilina con los que se prepararon antígenos con la proteína albumina de suero humano. La evaluación de los antígenos reveló que a pesar de ser suficientemente inmunogénicos y ser reconocidos por anticuerpos IgG de conejo, éstos no fueron reconocidos por IgE específicas de muestras de pacientes alérgicos. Así bien, por otro lado, la estrategia de cationización de las proteínas albumina de suero humano e histona fue abordada teniendo en cuenta que la modificación de grupos carboxilatos de la proteína a grupos amino aumenta la relación molar hapteno/proteína. Esta estrategia permitió la generación de 5 antígenos, 4 de los cuales (los antígenos de histona), esta vez sí, incrementaron la especificidad de la respuesta inmunológica obtenida, reconociendo IgE específicas. Concretamente, se han determinado IgE específicas en suero de pacientes alérgicos a bajas concentraciones (LOD = 0.07 IU/mL) con una especificidad diagnóstica del 100 % y una sensibilidad del 60 y 31 % para bencilpenicilina y amoxicilina, respectivamente, mejorando la sensibilidad un 60 % en comparación con el ensayo in vitro de referencia. A pesar de las mejoras obtenidas con las estrategias llevadas a cabo, se estudiaron otras vías no clásicas para la síntesis de nuevos haptenos con mayor diversidad química. Este enfoque se basa en la generación de antígenos en librerías químicas de compuestos con diversidad estructural para encontrar nuevos haptenos biológicamente activos. Dichas estrategias, hasta el momento, no han sido empleadas para la generación de antígenos y el análisis de muestras de suero de pacientes alérgicos. Con el fin de incorporar diversidad estructural, se sintetizaron, mediante la técnica combinatoria diversity-oriented synthesis, 22 compuestos de los precursores de las penicilinas y cefalosporinas, ácido 6-aminopenicilánico y ácido 7-amino-desacetoxicefalosporánico, respectivamente, y de los antibióticos amoxicilina y ampicilina. Su evaluación con el inmunoensayo in vitro basado en disco compacto ha demostrado que la incorporación de diversidad permite el reconocimiento de epítopos causantes de episodios alérgicos. Concretamente, se observó que estos antígenos eran capaces de detectar anticuerpos tipo IgG e IgE específicos procedentes de suero de conejos inmunizados y de suero humano de pacientes alérgicos, siendo especialmente selectivos los determinantes de amoxicilina y ampicilina. Concretamente, se obtuvo una sensibilidad diagnóstica del 79 % y una especificidad diagnóstica del 100 % / [CA] Al voltant del 10% de les reaccions adverses a medicaments són degudes a al·lèrgies, sent els antibiòtics ß-lactàmics aquells que més episodis al·lèrgics ocasionen. Encara que la incidència real continua sent desconeguda, els individus sospitosos de presentar al·lèrgia a algun medicament acaben sent prescrits amb altres medicaments, menys efectius, més cars o perjudicials. Així doncs, un correcte diagnòstic resulta clau per a disminuir els costos econòmics derivats i procedir a un adequat 'desetiquetatge' de la població. En l'actualitat, les proves de diagnòstic d'al·lèrgies a antibiòtics ß-lactàmics es basen en assaigs in vivo i in vitro. Aquests assaigs mostren baixes prestacions, ja que són invasius i perillosos i proporcionen falsos positius i/o negatius. A més a més, la sensibilitat diagnòstica està lluny de ser l'esperada, possiblement perquè encara no s'ha aconseguit reconéixer tots els epítopes causants dels episodis al·lèrgics. En aquest sentit, la preparació d'antígens s'ha basat fins al moment, en major mesura, en la unió directa dels antibiòtics a les molècules portadores mitjançant la formació d'un enllaç amida entre els grups amino de les lisines de la molècula portadora i el grup carboxilat de l'antibiòtic. Així i tot, les IgE específiques són vagament detectades amb aquests antígens. En aquesta tesi s'ha abordat la síntesi d'haptens i la generació de determinants antigènics a antibiòtics ß-lactàmics amb els quals poder realitzar un diagnòstic in vitro més fiable d'al·lèrgies a aquests fàrmacs. La seua avaluació s'ha dut a terme mitjançant assaigs in vitro multiplex basats en tecnologia de disc compacte. Aquesta investigació comença centrant-se en la síntesi i preparació d'antígens de penicil·lina. Per a això, en una primera fase s'ha estudiat l'efecte de la incorporació de braços espaiadors alifàtics en la generació d'antígens, considerant la possibilitat que s'obtinga un millor reconeixement molecular en allunyar l'haptè de la proteïna portadora. Es van sintetitzar tretze haptens derivats de bencilpenicil·lina i amoxicil·lina amb els quals es van preparar antígens amb la proteïna albúmina de sèrum humà. L'avaluació dels antígens va revelar que malgrat ser prou immunogènics i ser reconeguts per anticossos IgG de conill, aquests no van ser reconeguts per IgE específiques de mostres de pacients al·lèrgics. Així bé, d'altra banda, l'estratègia de cationització de les proteïnes albúmina de sèrum humà i histona va ser abordada tenint en compte que la modificació dels grups carboxilats de la proteïna a grups amino augmenta la relació molar hapten/proteïna. Aquesta estratègia va permetre la generació de 5 antígens, 4 dels quals (els antígens d'histona), aquesta vegada sí, van incrementar l'especificitat de la resposta immunològica obtinguda, reconeixent IgE específiques. Concretament, s'han determinat IgE específiques en sèrum de pacients al·lèrgics a baixes concentracions (LOD = 0.07 IU/mL) amb una especificitat diagnòstica del 100 % i una sensibilitat del 60 i 31 % per a bencilpenicil·lina i amoxicil·lina, respectivament, millorant la sensibilitat un 60 % en comparació amb l'assaig in vitro de referència. Malgrat les millores obtingudes amb les estratègies dutes a terme, es van estudiar altres vies no clàssiques per a la síntesi de nous haptens amb major diversitat química. Aquest enfocament es basa en la generació d'antígens en llibreries químiques de compostos amb diversitat estructural per a trobar nous haptens biològicament actius. Aquestes estratègies, fins al moment, no han sigut emprades per a la generació d'antígens i l'anàlisi de mostres de sèrum de pacients al·lèrgics. Amb la finalitat d'incorporar diversitat estructural, es van sintetitzar, mitjançant la tècnica combinatòria diversity- oriented synthesis, 22 compostos dels precursors de les penicil·lines i cefalosporines, àcid 6-aminopenicilànic i àcid 7-amino-desacetoxicefalosporànic, respectivament, i dels antibiòtics amoxicil·ina i ampicil·lina. La seua avaluació amb l'immunoassaig in vitro basat en disc compacte ha demostrat que la incorporació de diversitat permet el reconeixement d’epítops causants d'episodis al·lèrgics. Concretament, es va observar que aquests antígens eren capaços de detectar anticossos tipus IgG i IgE específics procedents de sèrum de conills immunitzats i de sèrum humà de pacients al·lèrgics, sent especialment selectius els determinants d’amoxicil·lina i ampicil·lina. Concretament, es va obtindre una sensibilitat diagnòstica del 79 % i una especificitat diagnòstica del 100 %. / This work was supported by the H2020 program (project COBIOPHAD, grant agreement No. 688448 awarded to A.M.), being an initiative of the Photonics Public Private Partnership; Agencia Estatal de Investigación Agencia Estatal de Investigación (CTQ2016-75749-R, FEDER) (PID2019-110713RB-I00, FEDER) awarded to S.M.; Generalitat Valenciana (PROMETEO/2020/094 awarded to A.M. & S.M.); program UPV-La FE 2019 (P105 VALBIOAL awarded to S.M & E. I-E.); and the National Institute of General Medical Sciences (GM-1R35GM127045 awarded to S.L.S.). E.P.M. was supported by a FPU fellowship from the Ministerio de Educación, Cultura y Deporte (FPU15/01738 and EST18/00360). B.K.H. was supported by a fellowship from the National Science Foundation (DGE1144152 and DGE1745303). The authors acknowledge the Instituto de Investigación Sanitaria La Fe, Valencia, Spain, which provided the samples from both allergic patients and controls. / Peña Mendizabal, E. (2022). Synthesis and Evaluation of Antigenic Determinants for ß-lactam Allergy Diagnosis [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/182979 / Compendio
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Evolutionary analysis of the β-lactamase families / Analyse évolutive des familles de β-lactamase

Keshri, Vivek 05 July 2018 (has links)
Les antibiotiques β-lactamines sont parmi les médicaments antimicrobiens les plus anciens et les plus utilisés. L'enzyme bactérienne β-lactamase hydrolyse l'antibiotique β-lactame en cassant la structure de base "anneau β-lactame". Pour identifier les nouvelles β-lactamases, une étude complète a été réalisée dans diverses bases de données biologiques telles que Human Microbiome Project, env_nr et NCBI nr. L'analyse a révélé que les séquences ancestrales putatives et les recherches de profil HMM jouaient un rôle important dans l'identification de la base de données homologue et métagénomique à distance dans l'enzyme β-lactamase existante comme matière noire. Les larges analyses phylogénétiques des β-lactamases existantes et nouvellement identifiées représentent les nouveaux clades dans les arbres. En outre, l'activité d'hydrolyse des antibiotiques β-lactamines de séquences nouvellement identifiées (provenant d'archées et d'humains) a été étudiée en laboratoire, ce qui montre l'activité de la β-lactamase. La deuxième phase de l'étude a été entreprise pour examiner l'évolution fonctionnelle des β-lactamases. Premièrement, des séquences de protéines ß-lactamase 1155 ont été extraites de la base de données ARG-ANNOT et des valeurs CMI la littérature correspondante. Les résultats ont révélé que l'activité fonctionnelle de la β-lactamase évoluait de manière convergente au sein de la classe moléculaire. La troisième phase de cette thèse représente le développement d'une base de données intégrative de β-lactamases. La base de données publique actuelle de β-lactamases a des informations limitées, par conséquence, une base de données intégrative a été développée. / The β-lactam antibiotics are one of the oldest and widely used antimicrobial drugs. The bacterial enzyme β-lactamase hydrolyzes the β-lactam antibiotic by breaking the core structure “β-lactam ring”. To identify the novel β-lactamases a comprehensive investigation was performed in different biological databases such as Human Microbiome Project, env_nr, and NCBI nr. The analysis revealed that putative ancestral sequences and HMM profile searches played a significant role in the identification of remote homologous and uncovered the existing β-lactamase enzyme in the metagenomic database as dark-matter. The comprehensive phylogenetic analyses of extant and newly identified β-lactamase represent the novel clades in the trees. Further, the β-lactam antibiotic hydrolysis activity of newly identified sequences (from archaea and human) was investigated in laboratory, which shows β-lactamase activity.The second phase of the investigation was undertaken to examine the functional evolution of β-lactamases. First, 1155 β-lactamase protein sequences were retrieved from ARG-ANNOT database and MIC values from the corresponding literature. The results revealed that the functional activity of β-lactamase evolved convergently within the molecular class.The third phase of this thesis presents development of an integrative β-lactamase database. The existing public database of β-lactamase has limited information, therefore, an integrative database was developed.

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