Strain-promoted stapled peptides for inhibiting protein-protein interactions

Sharma, Krishna

January 2019

Protein-protein interactions (PPIs) are responsible for the regulation of a variety of important functions within living organisms. Compounds which can selectively modulate aberrant PPIs are novel therapeutic candidates for treating human diseases. Whilst PPIs have traditionally been considered as "undruggable", research in this area has led to the emergence of several effective methodologies for targeting PPIs. One such methodology is peptide stapling, which involves constraining a short peptide into its native alpha-helical form by forming a covalent link between two of its amino acid side-chains. The Sondheimer dialkyne reagent has previously been used in strain-promoted double-click cycloadditions with diazidopeptides to generate stapled peptides that are capable of inhibiting PPIs. However, the Sondheimer dialkyne suffers from poor water-solubility; it decomposes rapidly in aqueous solutions which limits its application in biological systems. This dissertation describes the design and synthesis of new substituted variants of the Sondheimer dialkyne with increased solubility and stability, that are suitable for application in strain promoted double click peptide stapling. In total, ten different derivatives were generated; of these, a meta-trimethylammonium substituted variant was found to have particularly high water-solubility and aqueous stability, as well as high azide reactivity. The substituted Sondheimer dialkynes were applied to the strain promoted double click stapling of p53-based diazido peptides in an effort to generate stapled peptide-based inhibitors of the oncogenic p53 MDM2 PPI, a validated target for anticancer therapeutics. Three stapled peptides were found to have inhibitory activity, thus demonstrating the utility of the novel dialkynes in the preparation of PPI inhibitors. The functionalised stapled peptide formed from a meta-fluoro substituted Sondheimer dialkyne was found to be the most potent inhibitor. All ortho-substituted Sondheimer dialkynes were found to be unreactive, whereas those with a meta-trimethylammonium substituent were highly reactive when compared to other meta-substituted dialkynes. These patterns in azide reactivity could be explained through X-ray crystallographic studies and density functional theory calculations.

Synthesis of Boronic Acid-Tosyl Chemical Probes and Its Applications in the Study of Glycoprotein-Protein Interactions

Yang, Yung-Lin

05 September 2012

In this research, a method for site-selective attachment of synthetic molecules into glycoproteins using Boronic acid (BA)-directed tosyl chemistry is proposed. The synthetic BA-tosyl chemical probes are composed of boronic asid as a affinity ligand, a tosyl group as a reactive group and a terminal alkyne group for reporting. In neutral and alkaline environment, boronic acid can act as a targeting head to react with the cis-diol of carbohydrates and therefore forms a covalently reversible boronic diester ring. The newly formed boronate ring can withdraw the probe moeular close to the molecular surface of glycoproteins of interest. Followed by a SN2 reaction with the nucleophilic residues of labeled glycoproteins, the report alkyne group can covalently shift to the protein surface apart from the BA-tosyl skeleton. With the competition of polyols, the BA modified carbohydrates can be recovered to the native glycan structures. The traceless labeling strategy developed in the work has been demonstrated in the specific interaction with a known glycoprotein feutin with negatives controls. We believe that the successful development of this methodology can certainly accelerate the study of glycoproteomics and glycobiology.

Western Blotting

Boronic acid

Tosyl

Glycoprotein

New Routes to Functional Siloxanes: Applications of the Thermal Azide-Alkyne Cycloaddition for the Silicone Chemist

Rambarran, Talena

January 2016

Silicone oils (polysiloxane) and elastomers are a class of hydrophobic polymers with an extensive range of uses. While the high hydrophobicity can be beneficial in a variety of applications, it is not universally the case. Modification strategies for both fluid and elastomeric polydimethylsiloxane (PDMS) must be employed to create silicones with the appropriate properties for a given application, including enhanced hydrophilicity. Derivatization of PDMS leads to functional silicones with unique properties and added value. Strategies have been developed to modify both fluid and elastomeric PDMS, however, they all have varying degrees of drawbacks: the use of sophisticated equipment or expensive catalysts, restrictions to certain types of solvents, cumbersome multi-step synthetic procedures and surface reversion are some of the challenges faced. There is an opportunity to develop a simple and generic method for the controlled functionalization of PDMS. The Sharpless concept of ‘Click’ chemistry was an ideal approach to solving some of these challenges. Following nature’s lead, these reactions that are modular, wide in scope, high yielding, have simple reaction conditions and generate inoffensive byproducts. Herein, a synthetic method to functionalize silicones using the thermal Huisgen 1,3-dipolar cycloaddition of azides to alkynes is described. Initial exploration focused on the creation of inherently reactive elastomers that could be modified with a model hydrophilic moiety, poly(ethylene glycol). This was extended to the creation of amphiphilic multi-functional polysiloxanes and amphiphilic networks. Furthermore, the ‘Click’ approach was used to solve challenges faced in applications where silicones find use. The method described overcomes silicone modification challenges. The cycloaddition reaction is tolerant to many reaction conditions, is orthoganol to a variety of chemical reactions, does not require the use of a catalyst, the starting functional groups and bonds formed are stable and the reaction is high yielding, positioning the Huisgen ‘click’ reaction is an exceptional synthetic tool for the silicone chemist. / Dissertation / Doctor of Philosophy (PhD) / Polydimethylsiloxane (PDMS or silicone) fluids and elastomers are materials that find use in many applications owing to the many desirable properties they possess; personal care products, electrical insulators, sealants and biomedical are examples of products containing silicone. Native PDMS is highly hydrophobic (water repellent) and certain applications require silicones that are more compatible in environments containing water. Methods have been developed to modify both fluid and elastomeric silicones; incorporation of different molecules or polymers can enhance the properties of silicone for various applications or create unique materials. However, many of these methods have certain drawbacks: the use of sophisticated equipment, expensive ingredients, or a lack of permanence. For this reason, a new method to modify fluid and elastomeric silicones has been developed. The new method is based on the concept of ‘Click’ chemistry and has overcome some of challenges associated with other modification methods.

silicones

azide-alkyne cycloaddition

click chemistry

modification

Huisgen 1,3 dipolar cycloaddition

thermal

PDMS

Ligand-Assisted Catalysis Using Metal SNS Complexes

Khanzadeh, Atousa

08 January 2024

In molecular transition metal catalyst architectures, ligand design plays a crucial role in enhancing the efficiency of catalytic reactions. Selected ligands can play a bifunctional role in ligand-assisted catalysis, providing first coordination sphere basic sites and facilitating formation of multinuclear species through monomer bridging, as well as through their electronic and steric effects. This research addresses the underutilization of SNS complexes in various catalytic cycles. Our aim is to expand their activity in different cycles, unlocking untapped reactivity. Specifically, we focus on SNS ligands with soft thiolate and hard amido donors, comparing their catalytic performance in diverse coupling reactions. This comparative study provides insights into the suitability of these ligands with different transition metals, contributing to the understanding of ligand-assisted catalysis. Chapter 1 introduces these concepts and outlines the relevant catalytic reactions studied herein. To gain a deeper understanding of the chemistry involved, a comparative analysis of the reactivity differences between transition metal complexes with similar coordination structures is conducted. This investigation is crucial as it provides valuable insights into the design of suitable ligands for transition metal catalysts. Specifically, Chapters 2 and 3 of this thesis delve into a comparison of the reactivity of coordination complexes with identical metal centers and similar ligands, or even the same molecular formula, in catalysis. In the second chapter, we introduce a new cobalt (II) complex bearing an (SNS) amido ligand for the bifunctional hydroboration of carbonyls. Following an unsuccessful attempt to mono-protonate the amido donor in the bis(amido) complex Co(SᴹᵉNSᴹᵉ)₂ (2.1) treatment with 1 equivalent of 1,3-bis(1-adamantyl)imidazolium chloride (IAd•HCl) resulted in the liberation of one protonated ligand, affording CoᴵᴵCl(SᴹᵉNSᴹᵉ)(a-IAd) (2.2) with an "abnormally" coordinated IAd ligand, i.e., specifically bound through C4 instead of C2 of the imidazole ring. Compound 2.2 exhibited excellent catalytic activity in the hydroboration of aldehydes, displaying high substrate tolerance under mild reaction conditions and short reaction times. Stoichiometric reactions of 2.2 with pinacolborane (HBpin) revealed a bifunctional catalyst activation step, generating free SNS-amine, ClBpin and the active cobalt dihydride catalyst. Generation of an analogous catalyst with a normally coordinated IAd ligand showed poor reactivity in the hydroboration of aldehydes and was unable to effect ketone hydroboration. In Chapter 3, two tetranuclear copper(I) complexes bearing thiolate [Cu(SNSᴹᵉ)]₄ (3.1) and amido [Cu(SNSᴹᵉ)]₄ (3.2) SNS ligands are synthesized and their catalytic activity in a base-free azide-alkyne cycloaddition is compared. Complex 3.1 (1 mol%) demonstrated excellent reactivity for performing this 'click' reaction in water, exhibiting a broad substrate scope and enabling the production of various triazole compounds, including bioactive compound 3.16, which holds potential as an anti-cancer drug. DFT calculations suggested a proton shuttle role for the thiolate donor in conversion of the Cu-coordinated terminal alkyne to the key Cu-alkynyl intermediate. On the other hand, complex 3.2 exhibited reactivity similar to copper chloride. This observation was attributed to the basic nature of the amido ligand, which undergoes protonation by the coordinated alkyne C-H bond, with subsequent dissociation of the SNS-amine from the copper. Without a ligand to stabilize the copper in the less stable +1 oxidation state, a disproportionation reaction occurs, leading to catalyst deactivation. Chapter 4 introduces two palladium(II) thiolate complexes: PdI(κ³-SNSᴹᵉ) (4.1) exhibits catalytic activity in promoting the Heck cross-coupling reaction, while Pd(κ²-SNSᴹᵉ)₂ (4.2) affords no coupling product. In concert with triethylamine base, catalyst 4.1 efficiently produces olefin products with excellent yields, even at low catalyst loadings, and exhibits broad substrate tolerance over a 5 h reaction period. In contrast, the limited catalytic activity of 4.2 can be rationalized by proposing the formation of a Pd(N₂S₂) complex through ligand imine coupling at elevated temperatures, a reaction reported previously for Ni and Co analogs. The tetra-coordinated ligand formed through this isomerization occupies critical coordination sites around the metal, thereby preventing oxidative addition of the organohalide substrate, a key step in the Heck reaction mechanism. This work sheds light on the divergent catalytic behaviors of these two intriguing complexes. Finally, in Chapter 5 we assess what has been learned and identify relevant implications for further work.

Bifunctional ligand

Hydroboration catalysis

Heck reaction

Organic synthesis

ligand-assisted catalysis

Polyamides and polyesters made of bile acids in the main chain

Ivanysenko, Olga

09 1900

La préparation de polymères à base d’acides biliaires, molécules biologiques, a attiré l'attention des chercheurs en raison des applications potentielles dans les domaines biomédicaux et pharmaceutiques. L’objectif de ce travail est de synthétiser de nouveaux biopolymères dont la chaîne principale est constituée d’unités d’acides biliaires. La polymérisation par étapes a été adoptée dans ce projet afin de préparer les deux principales classes de polymères utilisés en fibres textiles: les polyamides et les polyesters. Des monomères hétéro-fonctionnels à base d’acides biliaires ont été synthétisés et utilisés afin de surmonter le déséquilibre stoechiométrique lors de la polymérisation par étapes. Le dérivé de l’acide lithocholique modifié par une fonction amine et un groupement carboxylique protégé a été polymérisé en masse à températures élevées. Les polyamides obtenus sont très peu solubles dans les solvants organiques. Des polyamides et des polyesters solubles en milieu organique ont pu être obtenus dans des conditions modérées en utilisant l’acide cholique modifié par des groupements azide et alcyne. La polymérisation a été réalisée par cycloaddition azoture-alcyne catalysée par l'intermédiaire du cuivre(Ι) avec deux systèmes catalytiques différents, le bromure de cuivre(I) et le sulfate de cuivre(II). Seul le bromure de cuivre(Ι) s’est avéré être un catalyseur efficace pour le système, permettant la préparation des polymères avec un degré de polymérisation égale à 50 et une distribution monomodale de masse moléculaire (PDI ˂ 1.7). Les polymères synthétisés à base d'acide cholique sont thermiquement stables (307 °C ≤ Td ≤ 372 °C) avec des températures de transition vitreuse élevées (137 °C ≤ Tg ≤ 167 °C) et modules de Young au-dessus de 280 MPa, dépendamment de la nature chimique du lien. / Bile acids have drawn attention in the synthesis of polymers for biomedical and pharmaceutical applications due to their natural origin. The objective of this work is to synthesize main-chain bile acid-based polymers. The step-growth polymerization was used to prepare two important classes of polymers used in textile fibers, polyamides and polyesters. Heterofunctional bile acid-based monomers were synthesized and used in order to overcome stoichiometric imbalances during step-growth polymerization. The lithocholic acid derivative bearing amine and protected carboxylic functional groups was polymerized in bulk at high temperatures, yielding polyamides that were poorly soluble in common organic solvents. Soluble triazole-linked polyamides and polyesters were obtained when the cholic acid derivative bearing azide and alkyne functional groups was polymerized under mild conditions via copper(Ι)-catalyzed azide-alkyne cycloaddition. Two different catalytic systems, copper(Ι) bromide and copper(ΙΙ) sulfate, were tested. Only copper(Ι) bromide proved to be an effective catalyst for the system, allowing the synthesis of the polymers with a degree of polymerization of ca. 50 and an unimodal molecular weight distribution(PDI ˂ 1.7). The main-chain cholic acid-based polymers are thermally stable (307 °C ≤ Td ≤ 372 °C) with high glass transition temperatures (137 °C ≤ Tg ≤ 167 °C) and Young’s moduli in excess of 280 MPa, depending on the chemical structure of the linker.

Bile acids

Polycondensation

Azide-alkyne cycloaddition

Polyamides

Polyesters

Acide biliaire

Cycloaddition azoture-alcyne

Polyamides and polyesters made of bile acids in the main chain

Ivanysenko, Olga

09 1900

La préparation de polymères à base d’acides biliaires, molécules biologiques, a attiré l'attention des chercheurs en raison des applications potentielles dans les domaines biomédicaux et pharmaceutiques. L’objectif de ce travail est de synthétiser de nouveaux biopolymères dont la chaîne principale est constituée d’unités d’acides biliaires. La polymérisation par étapes a été adoptée dans ce projet afin de préparer les deux principales classes de polymères utilisés en fibres textiles: les polyamides et les polyesters. Des monomères hétéro-fonctionnels à base d’acides biliaires ont été synthétisés et utilisés afin de surmonter le déséquilibre stoechiométrique lors de la polymérisation par étapes. Le dérivé de l’acide lithocholique modifié par une fonction amine et un groupement carboxylique protégé a été polymérisé en masse à températures élevées. Les polyamides obtenus sont très peu solubles dans les solvants organiques. Des polyamides et des polyesters solubles en milieu organique ont pu être obtenus dans des conditions modérées en utilisant l’acide cholique modifié par des groupements azide et alcyne. La polymérisation a été réalisée par cycloaddition azoture-alcyne catalysée par l'intermédiaire du cuivre(Ι) avec deux systèmes catalytiques différents, le bromure de cuivre(I) et le sulfate de cuivre(II). Seul le bromure de cuivre(Ι) s’est avéré être un catalyseur efficace pour le système, permettant la préparation des polymères avec un degré de polymérisation égale à 50 et une distribution monomodale de masse moléculaire (PDI ˂ 1.7). Les polymères synthétisés à base d'acide cholique sont thermiquement stables (307 °C ≤ Td ≤ 372 °C) avec des températures de transition vitreuse élevées (137 °C ≤ Tg ≤ 167 °C) et modules de Young au-dessus de 280 MPa, dépendamment de la nature chimique du lien. / Bile acids have drawn attention in the synthesis of polymers for biomedical and pharmaceutical applications due to their natural origin. The objective of this work is to synthesize main-chain bile acid-based polymers. The step-growth polymerization was used to prepare two important classes of polymers used in textile fibers, polyamides and polyesters. Heterofunctional bile acid-based monomers were synthesized and used in order to overcome stoichiometric imbalances during step-growth polymerization. The lithocholic acid derivative bearing amine and protected carboxylic functional groups was polymerized in bulk at high temperatures, yielding polyamides that were poorly soluble in common organic solvents. Soluble triazole-linked polyamides and polyesters were obtained when the cholic acid derivative bearing azide and alkyne functional groups was polymerized under mild conditions via copper(Ι)-catalyzed azide-alkyne cycloaddition. Two different catalytic systems, copper(Ι) bromide and copper(ΙΙ) sulfate, were tested. Only copper(Ι) bromide proved to be an effective catalyst for the system, allowing the synthesis of the polymers with a degree of polymerization of ca. 50 and an unimodal molecular weight distribution(PDI ˂ 1.7). The main-chain cholic acid-based polymers are thermally stable (307 °C ≤ Td ≤ 372 °C) with high glass transition temperatures (137 °C ≤ Tg ≤ 167 °C) and Young’s moduli in excess of 280 MPa, depending on the chemical structure of the linker.

Bile acids

Polycondensation

Azide-alkyne cycloaddition

Polyamides

Polyesters

Acide biliaire

Cycloaddition azoture-alcyne

Cyclic graft copolymer unimolecular micelles : effects of cyclization on particle morphology and thermoresponsive behavior

Williams, R.J., Pitto-Barry, Anaïs, Kirby, N., Dove, A.P., O'Reilly, R.K.

2016 March 1917

Yes / The synthesis of cyclic amphiphilic graft copolymers with a hydrophobic polycarbonate backbone and hydrophilic poly(N-acryloylmorpholine) (PNAM) side arms via a combination of ring-opening polymerization (ROP), cyclization via copper-catalyzed azide–alkyne cycloaddition (CuAAC), and reversible addition–fragmentation chain transfer (RAFT) polymerization is reported. The ability of these cyclic graft copolymers to form unimolecular micelles in water is explored using a combination of light scattering, small-angle X-ray scattering (SAXS), and cryogenic transmission electron microscopy (cryoTEM) analyses, where particle size was found to increase with increasing PNAM arm length. Further analysis revealed differences in the solution conformations, loading capabilities, and morphologies of the cyclic graft copolymers in comparison to equivalent linear graft copolymer unimolecular micelle analogues. Furthermore, the cyclic and linear graft copolymers were found to exhibit significantly different cloud point temperatures. This study highlights how subtle changes in polymer architecture (linear graft copolymer versus cyclic graft copolymer) can dramatically influence a polymer’s nanostructure and its properties. / Royal Society (Great Britain), Engineering and Physical Sciences Research Council (EPSRC), European Research Council (ERC)

Cyclic polymers

RAFT polymerisation

Unimolecular micelles

Self-assembly

Linear polymers

Graft copolymers

NHC portant des azotures : intermédiaires dans la synthèse catalysée d‘hétérocycles polyazotés et auto-fonctionnalisation de complexes métal-NHC / Azide tagged NHC : intermediates in the catalysed synthesis of nitrogen rich heterocycles and auto-functionalization of metal-NHC complexes

Fauché, Kévin

13 December 2018

Les carbènes N-hétérocycliques (NHC) sont très utilisés pour complexer les métaux de transition. Ils quittent rarement ce rôle de ligand ancillaire et trouvent, depuis une vingtaine d’années, des applications en catalyse ou, plus récemment, en chimie médicinale. Dans ce travail, nous discuterons d’une méthode de synthèse douce conduisant à la formation de complexes AgI – NHC via une source d’argent soluble. Cette méthode nous a permis d’obtenir des complexes bien connus mais également d’accéder à une nouvelle série de complexes NHC-Ag-phosphine. Nous présenterons également une nouvelle réaction où des NHC portant une fonction azoture à proximité du carbone du carbène quittent leur rôle de ligand ancillaire et conduisent à la formation d’hétérocycles azotés par cyclisation carbène-nitrène. Cette réaction sera présentée en détail, ainsi que la caractérisation spectroscopique concernant une sous-série de composés fluorescents obtenus par cette méthode. Enfin, nous présenterons une stratégie de post-fonctionnalisation de complexes développée dans notre équipe. Des complexes argent(I)-NHC portant un azoture proches du centre carbénique catalysent leur propre fonctionnalisation. De plus, des complexes de cuivre(I) portant des azotures en position éloignée du centre métallique seront greffés sur des nanoparticules magnétiques pour servir de catalyseur recyclables. / N-heterocyclic carbenes (NHC) are widely used to complex transition metals. They rarely leave their role as ancillary ligand and find, since 20 years, applications in catalysis or, more recently, in medicinal chemistry. In this work, we will discuss a mild synthetic method leading to the formation of AgI – NHC complexes via a soluble silver species. This method allowed us to obtain well known complexes but also to access a new series of NHC-Ag-phosphine complexes. We will also present a new reaction where NHC ligands bearing an azide function close to the carbenic center leave their role as ancillary ligand and lead to the formation of nitrogen rich heterocycles by a carbene-nitrene cyclization. This reaction will be presented in detail, along with the spectroscopic characterization regarding a sub-series of fluorescent compounds obtained by this method. Finally, we will present a post-functionalization strategy of complexes developed in our team. Silver(I)-NHC complexes tagged by an azide close to the carbenic center catalysed their own functionalization. Moreover, copper(I) complexes tagged by an azide function in a distant position from the metallic centre will be grafted on magnetic nanoparticles to act as recyclable catalysts.

Carbène N-hétérocyclique (NHC)

Carbène mésoionique (MIC)

Nitrène

Métaux du groupe 11

Catalyse

Fonctionnalisation

Cycloaddition azoture-alcyne

N-heterocyclic carbene (NHC)

Mesoionic carbene (MIC)

Nitrene

Group 11 metals

Catalysis

Functionalization

Azide-alkyne cycloaddition

Functionalized Nanofiber Substrates for Nerve Regeneration

Silantyeva, Elena A.

26 June 2019

No description available.

Polymer Chemistry

Polymers

Biomedical Engineering

RGD

Nuclear translation

Baboo, Sabyasachi

January 2012

In bacteria, protein synthesis can occur tightly coupled to transcription. In eukaryotes, it is believed that translation occurs solely in the cytoplasm; I test whether some occurs in nuclei and find: (1) L-azidohomoalanine (Aha) – a methionine analogue (detected by microscopy after attaching a fluorescent tag using ‘click’ chemistry) – is incorporated within 5 s into nuclei in a process sensitive to the translation inhibitor, anisomycin. (2) Puromycin – another inhibitor that end-labels nascent peptides (detected by immuno-fluorescence) – is similarly incorporated in a manner sensitive to a transcriptional inhibitor. (3) CD2 – a non-nuclear protein – is found in nuclei close to the nascent RNA that encodes it (detected by combining indirect immuno-labelling with RNA fluorescence in situ hybridization using intronic probes); faulty (nascent) RNA is destroyed by a quality-control mechanism sensitive to translational inhibitors. I conclude that substantial translation occurs in the nucleus, with some being closely coupled to transcription and the associated proof-reading. Moreover, most peptides made in both the nucleus and cytoplasm are degraded soon after they are made with half-lives of about one minute. I also collaborated on two additional projects: the purification of mega-complexes (transcription ‘factories’) containing RNA polymerases I, II, or III (I used immuno-fluorescence to confirm that each contained the expected constituents), and the demonstration that some ‘factories’ specialize in transcribing genes responding to tumour necrosis factor α – a cytokine that signals through NFκB (I used RNA fluorescence in situ hybridization coupled with immuno-labelling to show active NFκB is found in factories transcribing responsive genes).

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