Spelling suggestions: "subject:"bioorthogonal reactions"" "subject:"bioorthogonale reactions""
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Biocompatible palladium catalysts for biological applicationsIndrigo, Eugenio January 2016 (has links)
Transition metals have been used to mediate bioorthogonal reactions within a biological environment. In particular, applications of biocompatible palladium catalysis currently range from biomolecules modification to the in cellulo synthesis or activation of drugs. Here, the scope of palladium-mediated chemistry in living systems has been further extended with the development of a new homogenous palladium catalyst. This water-soluble, biocompatible, and traceable catalysts is based on a palladium-carbene complex coupled to a fluorescent labelled homing peptide for targeted delivery inside cells. This “SMART” catalyst is designed to activate both caged fluorophores and drugs through the cleavage of protecting groups or cross-coupling reactions. A second strategy for targeted delivery of a biocompatible palladium catalysis involves metal nanoparticles loaded onto a heterogeneous solid support. This “modular” catalyst can be implanted in vivo at the desired site of action, e.g. a tumour, and locally activate biomolecules. These two catalytic systems will allow us to selectively activate pro-drugs in vivo, with spatial control, thus minimising the side effects of the treatment on the whole body.
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Applications of tetrazines in chemical biologyNeumann, Kevin January 2018 (has links)
The need for chemoselective bond formation within complex biological systems has driven much research in chemical biology and chemical medicine and has allowed control over the structure and biological properties of a range of chemical entities. Reactions that are highly biocompatible, selective and occur at low concentration are classified as being bioorthogonal. Although bioorthogonal reactions have been successfully applied to bioconjugation and imaging in living systems, only a few examples exist of bioorthogonal reactions being utilised for the activation of prodrugs. The tetrazine mediated inverse electron demand Diels-Alder reaction is characterized by excellent reaction rates and high biocompatibility in both in vitro and in vivo applications. To date, this chemistry has found only limited application in prodrug activation or drug release strategies. Herein, a series of tetrazine-trigger systems are reported in which an active drug is liberated from its inactive form upon triggering with tetrazine. It is shown that the release of encapsulated and conjugated drugs from polymeric nanoparticles can be triggered by tetrazines providing an on-demand release within biological systems. In a totally new approach that fully complies with the principle of bioorthogonality by avoiding the generation of any by-products, tetrazine was utilised as a prodrug scaffold leading to symbiotic and traceless dyadic prodrug activation. The simultaneous formation of two active drugs (here the anticancer drug camptothecin and a known micro RNA inhibitor) was confirmed and validated within a biological environment. The use of tetrazines as a trigger to activate or release an active drug will open new directions in the field of chemical biology/medicine.
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Alkyne-Nitrone Cycloadditions for Functionalizing Cell Surface ProteinsMcKay, Craig 19 December 2012 (has links)
Over the past decade, bioorthogonal chemistry has emerged as powerful tools used for tracking biomolecules within living systems. Despite the vast number of organic transformations in the literature, only select few reactions meet the stringent requirements of bioorthogonality. There is increasing demands to develop biocompatible reactions that display high specificity and exquisitely fast kinetics under physiological conditions. With the goal of increasing reaction rates as a means for reducing the concentrations of labelling reagents used for bioconjugation, we have developed metal-catalyzed and metal-free alkyne-nitrone cycloadditions as alternatives to azide-alkyne cycloadditions and demonstrate their applications for imaging cell surface proteins. The copper(I)-catalyzed alkyne-nitrone cycloaddition, also known as the Kinugasa reaction, is typically conducted with a Cu(I) catalyst in the absence of air. We have developed highly efficient micelle promoted multicomponent Kinugasa reactions in aqueous media to make the reaction faster and more efficient. Despite good product yields, the slow kinetics, limited substrate scope and competing side-reaction pathways precludes its practical applicability for biological labelling. We have designed and synthesized β-lactam alkyne probes obtained from these reactions for activity-based protein profiling of the activities of membrane proteins. Additionally, we report that alkyne tethered β-lactams serve as surface enhanced Raman spectroscopy (SERS) reporters bound to silver nanoparticles, and demonstrated that alkyne bound silver nanoparticles can be used for SERS imaging cell surface proteins. The strain-promoted alkyne-nitrone cycloaddition (SPANC) was also explored as a rapid alternative bioorthogonal reaction. We found that the reaction proceeded in high yield within aqueous media, and displayed rate enhancements that were 1-2 orders of magnitude faster than analogous reactions involving azides. The scope and kinetics of SPANC was evaluated in model reactions of various nitrones (acyclic and cyclic) with cyclooctynes, with the purpose of identifying stable nitrones that displayed intrinsically faster kinetics than azides in strain-promoted cycloadditions with cyclooctynes. Cyclic nitrones displayed good stability and exceptionally fast reactivity in these reactions. The SPANC reaction exhibited high selectivity in the presence of biological nucleophilic amino acid side chains and the presence of biological media did not adversely affect the reaction. We have utilized SPANC for highly specific labelling of proteins in vitro and for imaging ligand-receptor interactions on the surfaces of live cancer cells. The high selectivity, fast reaction rate, and aqueous compatibility of SPANC makes the reaction suitable for a variety of in vivo biological imaging applications.
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Alkyne-Nitrone Cycloadditions for Functionalizing Cell Surface ProteinsMcKay, Craig 19 December 2012 (has links)
Over the past decade, bioorthogonal chemistry has emerged as powerful tools used for tracking biomolecules within living systems. Despite the vast number of organic transformations in the literature, only select few reactions meet the stringent requirements of bioorthogonality. There is increasing demands to develop biocompatible reactions that display high specificity and exquisitely fast kinetics under physiological conditions. With the goal of increasing reaction rates as a means for reducing the concentrations of labelling reagents used for bioconjugation, we have developed metal-catalyzed and metal-free alkyne-nitrone cycloadditions as alternatives to azide-alkyne cycloadditions and demonstrate their applications for imaging cell surface proteins. The copper(I)-catalyzed alkyne-nitrone cycloaddition, also known as the Kinugasa reaction, is typically conducted with a Cu(I) catalyst in the absence of air. We have developed highly efficient micelle promoted multicomponent Kinugasa reactions in aqueous media to make the reaction faster and more efficient. Despite good product yields, the slow kinetics, limited substrate scope and competing side-reaction pathways precludes its practical applicability for biological labelling. We have designed and synthesized β-lactam alkyne probes obtained from these reactions for activity-based protein profiling of the activities of membrane proteins. Additionally, we report that alkyne tethered β-lactams serve as surface enhanced Raman spectroscopy (SERS) reporters bound to silver nanoparticles, and demonstrated that alkyne bound silver nanoparticles can be used for SERS imaging cell surface proteins. The strain-promoted alkyne-nitrone cycloaddition (SPANC) was also explored as a rapid alternative bioorthogonal reaction. We found that the reaction proceeded in high yield within aqueous media, and displayed rate enhancements that were 1-2 orders of magnitude faster than analogous reactions involving azides. The scope and kinetics of SPANC was evaluated in model reactions of various nitrones (acyclic and cyclic) with cyclooctynes, with the purpose of identifying stable nitrones that displayed intrinsically faster kinetics than azides in strain-promoted cycloadditions with cyclooctynes. Cyclic nitrones displayed good stability and exceptionally fast reactivity in these reactions. The SPANC reaction exhibited high selectivity in the presence of biological nucleophilic amino acid side chains and the presence of biological media did not adversely affect the reaction. We have utilized SPANC for highly specific labelling of proteins in vitro and for imaging ligand-receptor interactions on the surfaces of live cancer cells. The high selectivity, fast reaction rate, and aqueous compatibility of SPANC makes the reaction suitable for a variety of in vivo biological imaging applications.
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Alkyne-Nitrone Cycloadditions for Functionalizing Cell Surface ProteinsMcKay, Craig January 2012 (has links)
Over the past decade, bioorthogonal chemistry has emerged as powerful tools used for tracking biomolecules within living systems. Despite the vast number of organic transformations in the literature, only select few reactions meet the stringent requirements of bioorthogonality. There is increasing demands to develop biocompatible reactions that display high specificity and exquisitely fast kinetics under physiological conditions. With the goal of increasing reaction rates as a means for reducing the concentrations of labelling reagents used for bioconjugation, we have developed metal-catalyzed and metal-free alkyne-nitrone cycloadditions as alternatives to azide-alkyne cycloadditions and demonstrate their applications for imaging cell surface proteins. The copper(I)-catalyzed alkyne-nitrone cycloaddition, also known as the Kinugasa reaction, is typically conducted with a Cu(I) catalyst in the absence of air. We have developed highly efficient micelle promoted multicomponent Kinugasa reactions in aqueous media to make the reaction faster and more efficient. Despite good product yields, the slow kinetics, limited substrate scope and competing side-reaction pathways precludes its practical applicability for biological labelling. We have designed and synthesized β-lactam alkyne probes obtained from these reactions for activity-based protein profiling of the activities of membrane proteins. Additionally, we report that alkyne tethered β-lactams serve as surface enhanced Raman spectroscopy (SERS) reporters bound to silver nanoparticles, and demonstrated that alkyne bound silver nanoparticles can be used for SERS imaging cell surface proteins. The strain-promoted alkyne-nitrone cycloaddition (SPANC) was also explored as a rapid alternative bioorthogonal reaction. We found that the reaction proceeded in high yield within aqueous media, and displayed rate enhancements that were 1-2 orders of magnitude faster than analogous reactions involving azides. The scope and kinetics of SPANC was evaluated in model reactions of various nitrones (acyclic and cyclic) with cyclooctynes, with the purpose of identifying stable nitrones that displayed intrinsically faster kinetics than azides in strain-promoted cycloadditions with cyclooctynes. Cyclic nitrones displayed good stability and exceptionally fast reactivity in these reactions. The SPANC reaction exhibited high selectivity in the presence of biological nucleophilic amino acid side chains and the presence of biological media did not adversely affect the reaction. We have utilized SPANC for highly specific labelling of proteins in vitro and for imaging ligand-receptor interactions on the surfaces of live cancer cells. The high selectivity, fast reaction rate, and aqueous compatibility of SPANC makes the reaction suitable for a variety of in vivo biological imaging applications.
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Transition metal catalysis : a new paradigm in bioorthogonal drug activationClavadetscher, Jessica Veronica January 2017 (has links)
Powerful tools have emerged in the past few years to allow the sensing, imaging and modulation of biological processes in living systems. Bioorthogonal organometallic reactions are transformations catalysed by transition metals, which are compatible within a biological environment. Palladium-mediated cross-coupling and decaging reactions, for example, have been successfully applied to catalyse non-natural chemical transformations within a biological milieu. Up until now, copper-catalysed cycloaddition reactions have been used extensively for the conjugation, immobilisation, and purification of biomolecules, but their further application in vivo has been limited by the inherent toxicity of copper. Herein, different transition metal catalysts were designed and applied in cellular and in vivo manipulations. Polymeric solid supports were functionalised with palladium nanoparticles and used as biocompatible, heterogeneous catalysts in selective decaging and cross-coupling reactions to activate fluorescent probes and synthesise cytotoxic anticancer drugs in situ. In order to gain tumour selectively, targeting functionalities were incorporated into the particles to allow the spatial control of the selective activation of labelling probes. The simultaneous synthesis of two different anticancer agents intracellularly, by two totally different mechanisms (in situ synthesis and decaging), is reported. The cellular toxicity of copper was addressed by entrapping copper nanoparticles on a polymeric solid support, allowing the activation of labelling probes, as well as the synthesis of an anticancer agent from two benign components through the well-known copper catalysed azide-alkyne cycloaddition. The biocompatibility of the copper catalysts in vivo was shown by implantation in zebrafish embryos.
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Konstrukce modifikovaných DNA s vybranými reaktivními či chránícími skupinami / Construction of modified DNAs with selected reactive or protective groupsVaníková, 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...
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