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41	Development of new bioorthogonal ligation reactions / Développement de nouvelles réactions de ligation bioorthogonales King, Mathias 04 June 2013 (has links) Le principal objectif de cette thèse a consisté au développement d’une méthode de screenning pour la découverte de nouvelles réactions de ligations bioorthogonales ainsi que son application sur une bibliothèque développée pour cette étude. Par conséquent, un système de screening a été conçu en trois étapes consistant au départ en une analyse HPLC, puis une évaluation basée sur la fluorescence de haute résolution et finalement un test de microscopie confocal in cellulo. Puis, nous avons standardisé toutes les analyses avec les réactions CuAAC et SpAAC. En outre, nous avons synthétisés 18 réactifs d’intérêts et effectué un screening de 58 expériences de ligation avec une évaluation par méthode HPLC. Parmi les 9 réponses positives obtenues figure 6 réactions impliquant de nouveaux réactifs et les analyses LC‐MS ont pu tous les valider comme des réactions de cycloaddition directe à l’exception d’une réaction. Finalement, nous avons pu appliquer la méthode in cellulo développée, afin d’évaluer la pertinence des réactions de chélation CuAAC pour une application sur cellules. / The main goal of this thesis was the development of a screening method for the discovery of new bioorthogonal ligation reactions as well as its application on a self‐designed library. Therefore we designed a three step screening system consisting of a preliminary HPLC assay, a high resolution fluorescence based assay and a final in cellulo confocal microscopy assay.Subsequently we standardized all assays with the highly established CuAAC and SpAAC. Furthermore, we successfully synthesized 18 reagents of interest and screened 58 ligation experiments with the help of the HPLC setup. The 9 positive hits from this screening contained 6 reactions involving novel reagents and LCMS analysis was able to validate all but one as straight forward cycloaddition reaction. Finally we were able to apply the newly developed in cellulo assay to assess the suitability of chelating CuAAC for in cell application. Ligation bioorthogonale CuAAC SpAAC Microscopy de fluorescence confocale Ligation in cellulo Screening HPLC Bioorthogonal ligation CuAAC SpAAC Confocal fluorescence microscopy In cellulo HPLC screening 547.2
42	Développements en chimie bioorthogonale pour des applications en protéomique chimique et en pharmacocinétique / Developments in bioorthogonal chemistry for applications in chemical proteomics and pharmacokinetics Recher, Marion 10 October 2014 (has links) Ce travail a consisté en la synthèse d’outils chimiques et au développement de leurs applications biologiques. Dans un premier temps, des sondes pour l’étude de la Topoisomérase IIA humaine ont été synthétisées. Ces sondes ont alors été testées sur lysat cellulaire pour la capture des protéines présentant une affinité pour ces médicaments. Dans un second temps, un nouveau lien clivable en conditions non dénaturantes pour des applications en protéomique chimique a été developpé. Ainsi, après optimisation de la structure, il a été intégré au sein d’une sonde d’affinité pour évaluer sa capacité de capture et libération de la PARP 1. Enfin, la réaction de click entre un azoture et un cyclooctyne a été appliquée à l’élimination d’une drogue circulante dans le sang.Après l’étude cinétique de la réaction, l’activité biologique et la pharmacocinétique des différents composés ont été évaluées pour optimiser la réaction de click in vivo. / The main goal of this work was to synthesize chemical tools and to developp their biological applications. In the first part, probes for the study of Topoisomerase II via chemical proteomic were synthesized. They were then used for pulldown experiments on cell lysats. In a second part, a new cleavable linker in non denaturing conditions was developped for chemical proteomic applications. After optimisation of the structure, it was incorporated in an affinity probe and tested for the pulldown of PARP 1. Finally, a click chemistry reaction, the SPAAC, was used to provok the elimination of a circulating drug. After the study of the kinetic of the reaction, the biological activity and the pharmacokinetic of the different compounds were evaluated to optimise the click reaction in vivo. Chimie bioorthogonale Protéomique chimique Lien clivable Topoisomérase II SPAAC Anticoagulant Pharmacocinétique Bioorthogonal chemistry Chemical proteomic Cleavable linker Topoisomerase II SPAAC Anticoagulant Pharmacokinetics 615.19
43	Modifications chimiques contrôlées du pillar[5]arène et préparation de [2]rotaxanes / Chemical modifications of pillar[5]arene scaffold and preparation of [2]rotaxanes Meichsner, Eric 13 October 2017 (has links) Analogues aux cyclotrivératrilènes et aux calix[n]arènes, les pillar[n]arènes sont composés de n unités hydroquinoliques et reliés entre elles par un pont méthylénique en position para. Ces macrocycles ont été utilisés en tant que supports fonctionnalisables afin de préparer divers nanomatériaux. Dans ce contexte, la modification chimique du pont méthylénique a été réalisée sur le pillar[5]arène afin d’obtenir un nouveau site de fonctionnalisation, à ce jour jamais exploité. L’oxydation de cette position a permis dans un premier temps de réaliser une extension de cycle par une réaction de Colvin, afin d’obtenir un macrocycle portant une triple liaison tendue. Cette particularité a permis la réalisation de cycloaddition 1,3-dipolaire de Huisgen ou chimie click sans utilisation de cuivre(I), mais également l’obtention de produits de cycloadditions [2+2] par voie thermique normalement interdites. L’introduction d’un fullerène C60 sur ce pont méthylénique a également été réalisée sans déformation de la cavité. C’est pourquoi dans un deuxième temps des [2]rotaxanes photoactifs ont pu être élaborés à partir de ce fulléropillar[5]arène. Dans un dernier temps, une nouvelle méthode de préparation des [2]rotaxanes a été développée. Par échange de bouchons activés, divers [2]rotaxanes ont pu être synthétisés, sans être limités par la nature des bouchons souhaités. A partir de cette méthode de préparation, des cristaux liquides ont pu être obtenus en substituant ces bouchons activés par des bouchons portants des groupements post-fonctionnalisables, puis en greffant des groupements cyanobiphényles. / Analogues of cyclotriveratrylenes and calix[n]arenes, pillar[n]arenes are composed of 1,4-disubstituted hydroquinone subunits linked by methylene bridges in their para positions. This macrocyclic core has been used as a compact scaffold for the preparation of nanomaterials. In this context, the chemical modification of the methylene bridge has been achieved to further functionalize the core in a way never explored so far. Firstly, oxidation of this position followed by Colvin reaction generated a strained triple bond in the macrocyclic scaffold. This particularity allowed the introduction of functional groups under copper free Huisgen 1,3-dipolar cycloadditions as well as by thermal [2+2] cycloadditions normally prohibited. Insertion of [60]fullerene on the methylene bridge has been also carried out. In a second time, photoactive [2]rotaxanes have been obtained from this fulleropillar[5]arene. Finally, a new methodology for the preparation of [2]rotaxanes has been developed. By exchange of activated stoppers, various [2]rotaxanes were thus obtained and this method is not limited by the nature of the stopper. This methodology has been used to prepare new liquid crystalline rotaxane derivatives by introduction of clickable stoppers followed by the grafting of dendritic mesogenic subunits. Chimie bioorthogonale Chimie supramoléculaire [60]fullerène Pillar[5]arène Porphyrine [2]rotaxane Bioorthogonal chemistry Supramolecular chemistry [60]fullerene Pillar[5]arene Porphyrine [2]rotaxane 547.1
44	Selective protein functionalisation via enzymatic phosphocholination Ochtrop, Philipp January 2017 (has links) Proteins are the most abundant biomolecules within a cell and are involved in all biochemical cellular processes ultimately determining cellular function. Therefore, to develop a complete understanding of cellular processes, obtaining knowledge about protein function and interaction at a molecular level is critical. Consequently, the investigation of proteins in their native environment or in partially purified mixtures is a major endeavour in modern life sciences. Due to their high chemical similarity, the inherent problem of studying proteins in complex mixtures is to specifically differentiate one protein of interest from the bulk of other proteins. Site-specific protein functionalisation strategies have become an indispensable tool in biochemical- and cell biology studies. This thesis presents the development of a new enzymatic site-specific protein functionalisation strategy that is based on the reversible covalent phosphocholination of short amino acid sequences in intact proteins. A synthetic strategy has been established that allows access to functionalised CDP-choline derivatives carrying fluorescent reporter groups, affinity tags or bioorthogonal handles. These CDP-choline derivatives serve as co-substrates for the bacterial phosphocholinating enzyme AnkX from Legionella pneumophila, which transfers a phosphocholine moiety to the switch II region of its native target protein Rab1b during infection. We identified the octapeptide sequence TITSSYYR as the minimum recognition sequence required to direct the AnkX catalysed phosphocholination and demonstrated the functionalisation of proteins of interest carrying this recognition tag at the N- or C-terminus as well as in internal loop regions. Moreover, this covalent modification can be hydrolytically reversed by the action of the Legionella enzyme Lem3, which makes the labeling strategy the first example of a covalent and reversible approach that is fully orthogonal to current existing methodologies. Thus, the here presented protein functionalisation approach holds the potential to increase the scope of possible labeling strategies in complex biological systems. In addition to the labeling of tagged target proteins, a CDP-choline derivative equipped with a biotin affinity-tag was synthesised and used in pull-down experiments to investigate the substrate scope of AnkX and to elucidate the role of protein phosphocholination during Legionella pneumophila infection. / Proteiner utgör huvudbeståndsdelen av alla biomolekyler i en cell. Dessa är involverade i alla cellulära processer som bestämmer cellens egenskaper. För att förstå de cellulära processerna är det nödvändigt att förstå proteinernas funktion på molekylär nivå. Att studera proteiner i deras naturliga omgivning, det vill säga inuti en cell eller i ett cellextrakt, är en stor utmaning i dagens livsvetenskaper. Eftersom proteiner är kemiskt lika varandra så är det svårt att skilja ett från tusentals andra. Att specifikt märka proteiner för att skilja ut dem från bakgrunden har blivit ett viktigt arbetssätt i modern biokemi och cellbiologi. Avhandlingen beskriver utvecklandet av en ny metod för reversibel och kovalent enzymatisk märkning baserat på fosfokolinering/defosfokolinering av en kort aminosyrasekvens i intakta proteiner. En syntesmetod för att framställa onaturliga CDP-kolinderivat har etablerats vilket tillåter oss att framställa CDP-kolin som bär en funktionalitet, vilket kan vara ett färgämne eller en affinitetstagg. Dessa onaturliga CDP-kolinderivat accepteras som co-substrat av enzymet AnkX från Legionella pneumophila vilket transfererar den funktionaliserade delen av CDP-kolinderivatet till en kort aminosyrasekvens baserad på AnkX’s naturliga substrat vid infektion, det lilla GTPaset Rab1. Under avhandlingsarbetets gång identifierades den kortaste aminosyrasekvensen som känns igen av AnkX, endast de åtta aminosyrorna TITSSYYR är nödvändiga för igenkänning av AnkX. Dessa åtta aminosyror kan genetiskt infogas i början, slutet eller mitt i ett protein för igenkänning och funktionalisering via AnkX och våra syntetiska CDP-kolinderivat. Vid Legionellainfektion i eukaryota celler klyvs fosfokolineringen efter en viss tid, eftersom Legionella pneumophila producerar ett fosfodiesteras, Lem3, som tar bort de fosfokolineringar som AnkX har installerat när de inte längre behövs. Vi har använt Lem3 för att ta bort märkning i sekvensen TITSS(PC)YYR, vilket gör vår strategi helt reversibel. Vi har kunnat demonstrera att AnkX-Lem3 systemet accepterar ett brett spektrum av CDP-kolinderivat, vilket gör metoden till den första av sitt slag, eftersom den är fullt reversibel. Vi har vidare undersökt vilka proteiner AnkX reagerar med inuti celler, vi använde oss av ett CDP-kolinderivat funktionaliserat med biotin, vilket har tillåtit oss att fiska ut alla de proteiner som fosfokolineras av AnkX. Förutom de små GTPaserna i Rab-familjen så identifierade vi även IMPDH2, ett enzym som reglerar det hastighetsbestämmande steget i syntesen av guanosin-nukleotider. Detta är mycket intressant, eftersom det leder till frågan ifall Legionella pneumophila manipulerar sin värdcell genom att förändra mängden GTP i förhållande till ATP. chemical biology organic synthesis site-selective protein labeling PTM phosphocholination nucleotides bioorthogonal chemistry proteomics IMPDH2 Organic Chemistry Organisk kemi Biochemistry and Molecular Biology Biokemi och molekylärbiologi
45	From Probes to Cell Surface Labelling: Towards the Development of New Chemical Biology Compounds and Methods Legault, Marc January 2011 (has links) Chemical biology encompasses the study and manipulation of biological system using chemistry, often by virtue of small molecules or unnatural amino acids. Much insight has been gained into the mechanisms of biological processes with regards to protein structure and function, metabolic processes and changes between healthy and diseased states. As an ever expanding field, developing new tools to interact with and impact biological systems is an extremely valuable goal. Herein, work is described towards the synthesis of a small library of heterocyclic-containing small molecules and the mechanistic details regarding the interesting and unexpected chemical compounds that arose; an alternative set of non-toxic copper catalyzed azide-alkyne click conditions for in vivo metabolic labelling; and the synthesis of an unnatural amino acid for further chemical modification via [3+2] cycloadditions with nitrones upon incorporation into a peptide of interest. Altogether, these projects strive to supplement pre-existing methodology for the synthesis of small molecule libraries and tools for metabolic labelling, and thus provide further small molecules for understanding biological systems. CuAAC click chemistry N-heterocyclic carbene intramolecular cyclization diversity oriented synthesis unnatural amino acid metabolic labelling rearrangement small molecule library chemical biology bioorthogonal
46	Synthesis of Amine Derivatives from a “One-Pot” Synthesis of Biphenyl-4-methylazide Delost, Michael D. 16 September 2015 (has links) No description available. Chemistry Organic Chemistry Pharmaceuticals Staudinger reduction with DPPE
47	Développement de nouvelles réactions de click in situ appliquées à la synthése d'inhibiteurs de la β-sécrétase. / Synthesis of bio-organic tools for the development of new in situ click reaction applied to the synthesis of β-secretase inhibitors Lizzul-Jurse, Antoine 13 January 2017 (has links) La synthèse contrôlée par la cible sous contrôle cinétique (Kinetic Target-Guided Synthesis, KTGS) est une approche relativement peu explorée, alternative à la chimie combinatoire traditionnelle,dans laquelle la protéine cible participe à la synthèse du ou de ses propres ligands. Ainsi, les travaux présentés dans la première partie de cette thèse ont pour principal objectif d'élargir l'éventail des réactions actuellement disponibles en KTGS grâce à la réaction d'aldolisation voire d'amidation, et ce en utilisant la β-sécrétase (BACE-1) comme cible biologique, qui est une enzyme étroitement impliquée dans la maladie d'Alzheimer. La seconde partie de cette thèse a été consacrée à la synthèse de marqueurs de masse fluorescents bioconjugables basés sur l'association d'un noyau coumarinique et d'une fonction phosphonium. Les deux générations présentées dans ce manuscrit ont entre autre permis de synthétiser une sonde FRET permettant de détecter l'activité enzymatique de la BACE-1, qui pourrait par ailleurs être un outil intéressant pour l'analyse des bruts réactionnels des réactions de click in situ,et diminuer les quantités d'enzyme engagées dans ces expériences. Enfin dans la dernière partie de cette thèse nous décrivons la mise au point de nouvelles réactions de conjugaison bio-orthogonale pour le marquage de molécules comportant une fonction aldéhyde. Nous avons ainsi développé d'une part une réaction trois composants via une séquence de condensation/Mannich/lactamisation et d'autre part une réaction d'oléfination de Wittig. / The kinetic target-guided synthesis (KTGS), is an underexplored alternative approach to combinatorial chemistry, in which the biological target is able to assemble its own inhibitors from a pool of fragments. Thus, the first part of this thesis aimed at extending the scope of the reactions available for the KTGS, by investigating the aldolisation and amidation reaction, using the β-secretase (BACE-1) as biological target, which is an enzyme narrowly involved in the Alzheimer's disease. The second part of this thesis was dedicated to the synthesis of bioconjagatable fluorophores containing a phosphonium group as mass tag associated to a coumarin core. Both generations presented in this manuscript allowed us, among other things, to synthesize a FRET probe that proved suitable for the determination of BACE-1 enzymatic activity. The utility of such a fluorogenic tool could be leveraged to facilitate the analysis of crude mixtures obtained during KTGS experiments, and lessen the amount of enzyme required in these experiments. Finally, in the last part of this thesis, we describe the development of two new bioorthogonal reactions allowing the selective labeling of molecules containing an aldehyde moiety : 1) a three component reaction involving a condensation/Mannich/lactamisation procedure, between an amine, an aldehyde and an enol partner; 2) a Wittig ligation between an aldehyde and a phosphonium bearing an active methylene. Dir. chimie BACE-1 Marqueur de masse Coumarine Phosphonium Conjugaison bio-orthogonale Kinetic target-guided synthesis BACE-1 Mass tag Coumarin Phosphonium Bioorthogonal conjugation 541.39
48	Konstrukce modifikovaných DNA s vybranými reaktivními či chránícími skupinami / Construction of modified DNAs with selected reactive or protective groups Vaníková, Zuzana January 2020 (has links) This PhD thesis is focused on the synthesis of DNA modified with photocleavable 2- nitrobenzyl protecting groups in major groove and its applications in the regulation of gene expression in the level of transcription. In the first part of my thesis, the synthesis of photocaged 2'-deoxyribonucleosides triphosphates and their photolysis to unprotected 5-hydroxymethylated nucleotides is described. All prepared nucleoside triphosphates were good substrates for their enzymatic incorporation into DNA. Synthesized 5-(2-nitrobenzyloxy)methyl-2'-deoxyuridine-5'- monophosphate (dUNBMP) and DNA with one 5-(2-nitrobenzyloxy)methyl- modification in the sequence were used for the detailed kinetic studies of photocleavage reactions. In the second part of the thesis, the series of modified DNAs with specific sequences were prepared by primer extension (PEX) and/or polymerase chain reaction (PCR). A cleavage of prepared modified DNAs was studied by selected restriction endonucleases (REs). In all cases, the nitrobenzylated DNA fully resist the cleavage by REs. The deprotection/ photocleavage conditions for nitrobenzylated DNA were studied in the case of DNAs with positive restriction endonuclease digestion of hydroxymethylated DNA. The resulting photocleaved DNA was fully digested by REs, therefore 2-nitrobenzyl...
49	Application of chemoselective tools for the protein semi-synthesis of tau and the development of a novel photo-cleavable tag Siebertz, Kristina D. 29 March 2019 (has links) Posttranslationale Modifikationen sind chemische Veränderungen, die ein Protein nach der Translation durchläuft. Sie sind wichtig für die Regulierung der Funktion, Struktur und Interaktion von Proteinen. Die Einführung von Modifikationen in Biomoleküle ist zudem ein Hilfsmittel in der Chemischen Biologie, um neue Informationen über ihr Verhalten zu erlangen und ihre Aktivität zu verändern. Die Fehlregulierung von posttranslationalen Modifikationen steht häufig in direkter Verbindung zum Ausbruch von Krankheiten. Ein Beispiel ist das Tau Protein welches eine Schlüsselrolle in der Alzheimer Erkrankung hat. Im Laufe der Krankheit wird Tau hyperphosphoryliert, was zu einem Funktionsverlust des Proteins und zur Bildung von nicht-löslichen Aggregaten führt. Die Mechanismen hinter dieser Fehlregulierung zu eluieren gehört zu einer der großen Herausforderungen der Alzheimerforschung. Diese Doktorarbeit hat sich mit der Entwicklung einer neuen semi-synthetischen Ligationsstrategie beschäftigt, die es ermöglichen soll die Rolle einzelner Phosphorylierungen in der Prolin-reichen Region des Tau Proteins zu untersuchen. Hierfür wurden geeignete Ligationsstellen identifiziert, Ligationsmöglichkeiten geprüft und die Synthese der einzelnen Fragmente optimiert. Desweiteren wurde in dieser Dissertation eine neuartige Anwendung der Staudinger-Phosphonit Ligation entwickelt, die es ermöglicht mit Boran-geschützten P(III) Verbindungen azidhaltige Moleküle zu lichtspaltbaren Phosphonamidaten zu modifizieren. Die P(III) Bausteine beinhalteten dabei nicht nur zwei lichtspaltbare 2-Nitrobenzyl-Substituenten, sondern erlauben zudem über eine Alkingruppe eine vielfältige Funktionalisierung. Die Bestrahlung durch UV Licht induziert die Spaltung der P-N Bindung der Phosphonamidate und setzte das Ursprungsmolekül mit einer zusätzlichen Aminfunktion frei. Dahingehend wurden erste Schritte unternommen, damit die Lichtspaltung keine Modifikation mehr am Ursprungsmolekül hinterlässt. / Post-translational modifications are essential in the regulation of the function, folding and interaction of proteins. Similarly, the modification of biomolecules is a main tool in chemical biology to gain new insights into their molecular mechanisms and to alter and fine-tune their activity. The dysregulation of post-translational modifications is often associated with disease. An example are the abnormally hyperphosphorylated tau proteins that are the main component of neurofibrillary tangles, one of the pathological hallmarks of the neurodegenerative disease Alzheimer‘s disease. The origin of these hyperphosphorylations, which render a soluble and mostly unstructured protein into insoluble aggregates, is a key question in Alzheimer research. First steps towards a tau semi-synthesis that allow for the site-specific introduction of phosphorylations in the proline-rich domain were taken by identifying suitable ligation sites, finding the ideal sequential ligation strategy, providing reliable protein expression protocols and optimizing the synthesis of the synthetic peptides equipped with phosphorylated residues. Furthermore, this thesis explored the use of the Staudinger-phosphonite reaction in the synthesis of photo-cleavable phosphonamidates to modify biomolecules in a reversible manner. This conjugation method allowed for the chemoselective modification of an azido-containing target molecule with a borane-protected P(III) reagent that was equipped with photo-cleavable 2-nitrobenzyl substituents and one alkyne for functionalization. UV irradiation induced the phosphonamidate P-N bond cleavage and resulted in the release of the target molecule with an additional amine functionality. In this regard, first steps were undertaken to develop a traceless variant of this cleavage. The application of the photo-cleavable phosphonamidates was demonstrated in streptavidin-mediated immobilization assays, which is just one example for the use of this valuable methodology. Chemoselektive Reaktion Tau Protein Semi-Synthese Staudinger Ligation Bioorthogonale Chemie chemoselective reaction tau protein semi-synthesis Staudinger ligation bioorthogonal chemistry 547 Organische Chemie VK 8567 WD 5100 YG 4000 ddc:547
50	TOWARD AN ENZYME-COUPLED, BIOORTHOGONAL PLATFORM FOR METHYLTRANSFERASES: PROBING THE SPECIFICITY OF METHIONINE ADENOSYLTRANSFERASES Huber, Tyler D. 01 January 2019 (has links) Methyl group transfer from S-adenosyl-l-methionine (AdoMet) to various substrates including DNA, proteins, and natural products (NPs), is accomplished by methyltransferases (MTs). Analogs of AdoMet, bearing an alternative S-alkyl group can be exploited, in the context of an array of wild-type MT-catalyzed reactions, to differentially alkylate DNA, proteins, and NPs. This technology provides a means to elucidate MT targets by the MT-mediated installation of chemoselective handles from AdoMet analogs to biologically relevant molecules and affords researchers a fresh route to diversify NP scaffolds by permitting the differential alkylation of chemical sites vulnerable to NP MTs that are unreactive to traditional, synthetic organic chemistry alkylation protocols. The full potential of this technology is stifled by several impediments largely deriving from the AdoMet-based reagents, including the instability, membrane impermeability, poor synthetic yield and resulting diastereomeric mixtures. To circumvent these main liabilities, novel chemoenzymatic strategies that employ methionine adenosyltransferases (MATs) and methionine (Met) analogs to synthesize AdoMet analogs in vitro were advanced. Unstable AdoMet analogs are simultaneously utilized in a one-pot reaction by MTs for the alkylrandomization of NP scaffolds. As cell membranes are permeable to Met analogs, this also sets the stage for cell-based and, potentially, in vivo applications. In order to further address the instability of AdoMet and analogs thereof, MAT-catalyzed reactions utilizing Met and ATP isosteres generated highly stable AdoMet isosteres that were capable of downstream utilization by MTs. Finally, the development, use, and results of a high-throughput screen identified mutant-MAT/Met-analog pairs suitable for postliminary bioorthogonal applications. Methionine Adenosyltransferase Methyltransferase S-Adenosyl-L-methionine Natural Product Diversification Bioorthogonal Labelling Platforms Amino Acids, Peptides, and Proteins Biochemistry Biotechnology Chemical and Pharmacologic Phenomena Enzymes and Coenzymes Medicinal and Pharmaceutical Chemistry Medicinal Chemistry and Pharmaceutics Medicinal-Pharmaceutical Chemistry Molecular Biology Organic Chemistry Structural Biology

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