Biomimetic Aminoacylation

Tzvetkova, Svetlana

01 August 2008

Abstract “Biomimetic Aminoacylation” Svetlana K. Tzvetkova Doctor of Philosophy, 2008 Graduate Department of Chemistry University of Toronto The accuracy of ribosomal protein synthesis depends on the fidelity of highly specific enzymes, aminoacyl tRNA synthetases, towards amino acid – tRNA pairs. These biological catalysts are responsible for activating the amino acids as aminoacyl adenylates and for their subsequent attachment to the 2’- or 3’-OH at the 3’-terminal of the correct tRNA to give aminoacyl-tRNA. Extended diversity in protein structure and function could be achieved if non-natural side chains can be introduced in protein synthesis. This requires that the acceptor stem of a tRNA molecule be synthetically aminoacylated. The most widely used methods for charging tRNA with non-natural amino acids involve multi-step synthesis of an aminoacyl-pCpA and its consequent enzymatic ligation to truncated tRNA. No direct route to these species has been reported. We have developed a method for direct biomimetic aminoacylation of the 3’-terminal hydroxyls of tRNA. Our approach shows to be promising in reactions leading to direct 2’- or 3’-O-aminoacylation of not only nucleosides and nucleotides but also RNA in general and tRNA in particular. The system we have developed provides: 1) efficient activation of the amino acids as aminoacyl phosphates, analogues of the enzymatic intermediates, and 2) specific recognition of the 3’-terminal of tRNA by lanthanide ions present in the reaction. The aminoacylating reagents used in our studies were carefully selected to provide handles to follow the reaction: UV absorbance, fluorescence spectroscopy and 19F NMR. Lanthanide (III) ions can play a role similar to a key part of the aminoacyl tRNA synthetases – they bring the aminoacyl close to the 3’-terminal of tRNA, in this case by forming a bis-bidentate complex with the aminoacyl phosphate and the 2’,3’-diol functionality of the 3’-terminal adenosine. This process relies on the specificity towards the unique 3’-terminal diol on tRNA, provided by the metal ion and the simultaneous complexation of the aminoacyl phosphate.

Aminoacylation tRNA

non-natural amino acids

0490

Hydrogen Bond-directed Stereospecific Interactions in (A) General Synthesis of Chiral Vicinal Diamines and (B) Generation of Helical Chirality with Amino Acids

Kim, Hyunwoo

15 September 2011

Hydrogen bonding interactions have been applied to the synthesis of chiral vicinal diamines and the generation of helical chirality. A stereospecific synthesis of vicinal diamines was developed by using the diaza-Cope rearrangement reaction driven by resonance-assisted hydrogen bonds (RAHBs). This process for making a wide variety of chiral diamines requires only a single starting chiral diamine, 1,2-bis(2-hydroxyphenyl)-1,2-diaminoethane (HPEN) and aldehydes. Experimental and computational studies reveal that this process provides one of the simplest and most versatile approaches to preparing chiral vicinal diamines including not only C2 symmetric diaryl and dialkyl diamines but also unsymmetrical alkyl-aryl and aryl-aryl diamines with excellent yields and enantiopurities. Weak forces affecting kinetics and thermodynamics of the diaza-Cope rearrangement were systematically studied by combining experimental and computational approaches. These forces include hydrogen bonding effects, electronic effects, steric effects, and oxyanion effects. As an example of tuning diamine catalysts, a vicinal diamine-catalyzed synthesis of warfarin is described. Detailed mechanistic studies lead to a new mechanism involving diimine intermediates. Decreasing the NCCN dihedral angle by varying the diamine structure results in an increase of the enantioselectivity up to 92% ee. Hydrogen bonds have been used to generate helical chirality in a highly stereospecific manner with a single amino acid and 2,2′-dihydroxybenzophenone. DFT computational and experimental data including circular dichroism (CD), X-ray crystallography and 1H NMR data provide insight into the origin of the stereospecificity. A signalling dizao group can be attached to the receptor for general sensing of amino acid enantiopurity.

diamine

rearrangement

amino acid

helical chirality

0490

Mechanisms of Decarboxylation: Internal Return, Water Addition, and Their Isotope Effects

Mundle, Scott Owen Chelmsford

31 August 2010

2-(2-mandelyl)thiamin (MTh), the adduct of benzoylformate and thiamin, is an accurate model of 2-(2-mandelyl)thiamin diphosphate, the initial covalent intermediate in the decarboxylation of benzoylformate by benzoylformate decarboxylase (BFDC). The first order rate constant for spontaneous decarboxylation of MTh is about 106 times smaller than the enzymic rate (kcat) for the BFDC reaction. Based on the similarities of MTh and the corresponding enzymic intermediate, as well as the inherent nature of the intermediate, it is not obvious why the enzyme-catalyzed reaction is so much faster. However, earlier studies showed that the decarboxylation of MTh is catalyzed by protonated pyridines and this was proposed to occur through a preassociation mechanism. If this explanation is correct, then the observed 12C/13C kinetic isotope effect (CKIE) will increase in the presence of the catalyst as a more favorable forward commitment is made possible. This provides a specific model for the enzyme-catalyzed process. We developed a technique using headspace analysis and compound specific isotope analysis (CSIA) to determine the CKIE for the decarboxylation of MTh in the presence and absence of pyridinium. We found that the CKIE increases in the presence of the catalyst, as predicted for the preassociation mechanism. In a related study, we investigated the kinetics of decarboxylation of pyrrole-2-carboxylic acid, which was known to be subject to acid catalysis in highly acidic solutions. In the expected mechanism, protonation of the pyrrole ring at C2 destroys the aromaticity of the ring. C-C bond cleavage in the process of decarboxylation will re-establish the aromatic pyrrole. However, the overall reaction rate would not increase as it is counteracted by a larger concentration of the undissociated carboxyl group compared to carboxylate ion necessary for decarboxylation. Since the reaction occurs readily, there must be an alternative pathway for the acid-catalyzed reaction. This can be achieved in an associative mechanism that is initiated by addition of water to the carboxyl group of the carboxyl-protonated reactant. C-C bond cleavage results in formation of pyrrole and protonated carbonic acid, a species that has been recognized as a viable intermediate in related processes. Protonated carbonic acid is spontaneously converted to H3O+ and carbon dioxide. The associative mechanism is consistent with solvent-deuterium kinetic isotope effects and 12C/13C kinetic isotope effects.

Decarboxylation

Isotope effects

Internal return

hydrolytic

0490

Synthesis of Heterocycles and Carbocycles Through Tandem and Domino Palladium-catalyzed Reactions

Chai, David

29 August 2011

We have described two important classes of palladium-catalyzed reactions for the synthesis of heterocycles and carbocycles: tandem Pd-catalyzed reactions of gem-dibromoolefins and domino Pd-catalyzed reactions via an ortho C−H functionalization. Chapter 1 describes the tandem Pd-catalyzed reaction of gem-dibromoolefins via an intramolecular direct arylation and an intermolecular Suzuki-Miyaura cross-coupling. A number of aromatic carbocycles were synthesized by this method. Chapter 2 describes the tandem Pd-catalyzed reactions of β,β-dibromoenamides via an intramolecular C−O bond formation and an intermolecular Suzuki-Miyaura cross-coupling. Depending on the substituent on the nitrogen of β,β-dibromoenamides, either aromatic heterocycles or acyclic compounds can be synthesized. Chapter 3 and 4 describe the domino Pd-catalyzed reactions via an ortho C−H functionalization of aryl iodides. 2-Pyrrole substituted phenyl iodides were coupled with alkyl bromides in the presence of norbornene to provide aromatic tetracyclic compounds through three C−C bond formations (Chapter 3). However, the reaction between 2-methyl substituted phenyl iodides and the alkyl bromides in the presence of norbornene provided tetrasubstituted helical alkenes with the norbornene incorporated in the final product through four C−C bond formations (chapter 4). In Chapter 5, detailed mechanistic studies including kinetic and NMR studies were described for the regioselective C−H functionalization of 2-pyrrole substituted phenyl iodides. The studies provided advanced and important understanding of the mechanism, and a rationale for the high regioselectivity.

tandem and domino reactions

palladium catalyzed reactions

0490

Verdazyl Radicals as Substrates for Organic Synthesis

Bancerz, Matthew

12 December 2013

Verdazyl radicals, discovered in 1963, are a family of exceptionally stable radicals defined by their 6-membered ring containing four nitrogen atoms. Verdazyl radicals are highly modular compounds with a large assortment of substitution patterns reported. Their stability and high degree of structural variability has been exploited in the fields of materials, inorganic, polymer and physical chemistry; however their deliberate use as starting materials towards organic synthesis had only been reported in recent years by the Georges lab. In 2008, the Georges group reported a disproportionation reaction that was observed to a occur with 6-oxoverdazyl radicals resulting in azomethine imines capable of undergoing 1,3-dipolar cycloaddition reactions. With this discovery, the door to using verdazyl radicals as substrates towards organic synthesis had been opened. Their utility in synthesis was soon discovered not to be limited to just the cycloadducts their azomethine imine derivatives could generate but also the increasing number of N-heterocycles that could be generated from these cycloadducts via unique rearrangement reactions, a major theme of this thesis. In addition, triphenyl verdazyl radicals, a distinct class of verdazyl radicals, has been shown to react with alkynes by direct radical addition and rearrangement to afford isoquinolines. As part of this thesis, a new synthetic methodology of generating 6-oxoverdazyl radicals is reported that does not rely on the use of phosgene or hydrazines. This new synthesis allows for the expansion of available alkyl substituents possible on N1 and N5 positions of 6-oxoverdazyl radicals, as well as, generation of unsymmetrical examples of 6-oxoverdazyl radicals with non-identical N1 and N5 alkyl substituents. Employing the new 6-oxoverdazyl radicals synthesized via this method, a study on the effects of different alkyl substituents on the disproportionation reaction of 6-oxoverdazyls was undertaken. Lastly, given the assortment of N-heterocyclic molecular scaffolds capable of being synthesised starting from verdazyl radicals as precursors, the applicability of verdazyl radicals in making a diversity oriented synthesis (DOS) based library was explored. In a group effort with other Georges lab members, a small library composed of various classes of verdazyl radical derived compounds was synthesized and non-specifically tested for cytotoxicity against acute myeloid leukemia and multiple myeloma cell lines in collaboration with The Princess Margaret Hospital. One example was shown to effectively kill cancer cells in both these lines in 250 μM concentration pointing out the potential of using verdazyl radical based chemistry in drug discovery.

verdazyl

radical

cycloaddition

heterocycle

rearrangement

0490

Verdazyl Radicals as Substrates for Organic Synthesis

Bancerz, Matthew

12 December 2013

Verdazyl radicals, discovered in 1963, are a family of exceptionally stable radicals defined by their 6-membered ring containing four nitrogen atoms. Verdazyl radicals are highly modular compounds with a large assortment of substitution patterns reported. Their stability and high degree of structural variability has been exploited in the fields of materials, inorganic, polymer and physical chemistry; however their deliberate use as starting materials towards organic synthesis had only been reported in recent years by the Georges lab. In 2008, the Georges group reported a disproportionation reaction that was observed to a occur with 6-oxoverdazyl radicals resulting in azomethine imines capable of undergoing 1,3-dipolar cycloaddition reactions. With this discovery, the door to using verdazyl radicals as substrates towards organic synthesis had been opened. Their utility in synthesis was soon discovered not to be limited to just the cycloadducts their azomethine imine derivatives could generate but also the increasing number of N-heterocycles that could be generated from these cycloadducts via unique rearrangement reactions, a major theme of this thesis. In addition, triphenyl verdazyl radicals, a distinct class of verdazyl radicals, has been shown to react with alkynes by direct radical addition and rearrangement to afford isoquinolines. As part of this thesis, a new synthetic methodology of generating 6-oxoverdazyl radicals is reported that does not rely on the use of phosgene or hydrazines. This new synthesis allows for the expansion of available alkyl substituents possible on N1 and N5 positions of 6-oxoverdazyl radicals, as well as, generation of unsymmetrical examples of 6-oxoverdazyl radicals with non-identical N1 and N5 alkyl substituents. Employing the new 6-oxoverdazyl radicals synthesized via this method, a study on the effects of different alkyl substituents on the disproportionation reaction of 6-oxoverdazyls was undertaken. Lastly, given the assortment of N-heterocyclic molecular scaffolds capable of being synthesised starting from verdazyl radicals as precursors, the applicability of verdazyl radicals in making a diversity oriented synthesis (DOS) based library was explored. In a group effort with other Georges lab members, a small library composed of various classes of verdazyl radical derived compounds was synthesized and non-specifically tested for cytotoxicity against acute myeloid leukemia and multiple myeloma cell lines in collaboration with The Princess Margaret Hospital. One example was shown to effectively kill cancer cells in both these lines in 250 μM concentration pointing out the potential of using verdazyl radical based chemistry in drug discovery.

verdazyl

radical

cycloaddition

heterocycle

rearrangement

0490

Development of Small Molecule Activators of Caseinolytic Protease P

Nhieu, Alan

18 June 2014

Caseinolytic protease (ClpP) is a cylindrical protease that degrades proteins in the presence of ATPase chaperones. On its own, bacterial ClpP can only degrade small peptides; however, the addition of a novel class of antibiotics, ADEPs, can cause unregulated proteolysis leading to bacterial cell death. Bacterial ClpP is an attractive target for antibiotic development. A high-throughput screen of small molecules identified a group of compounds which are termed Activators of Self-Compartmentalizing Proteases (ACP). A collection of ACP3 and ACP4/5 analogs was synthesized and investigated for biological activity. The project resulted in compounds with greater activity than the lead structures against isolated E. coli ClpP. Also, several analogs possessed bacteriostatic activity against N. meningitidis and S. aureus cell lines.

Caseinolytic Protease P

ClpP, antibiotics

0490

Development of Small Molecule Activators of Caseinolytic Protease P

Nhieu, Alan

18 June 2014

Caseinolytic protease (ClpP) is a cylindrical protease that degrades proteins in the presence of ATPase chaperones. On its own, bacterial ClpP can only degrade small peptides; however, the addition of a novel class of antibiotics, ADEPs, can cause unregulated proteolysis leading to bacterial cell death. Bacterial ClpP is an attractive target for antibiotic development. A high-throughput screen of small molecules identified a group of compounds which are termed Activators of Self-Compartmentalizing Proteases (ACP). A collection of ACP3 and ACP4/5 analogs was synthesized and investigated for biological activity. The project resulted in compounds with greater activity than the lead structures against isolated E. coli ClpP. Also, several analogs possessed bacteriostatic activity against N. meningitidis and S. aureus cell lines.

Caseinolytic Protease P

ClpP, antibiotics

0490

Heteroatom-directed Olefin Hydroacylation

Coulter, Matthew

05 January 2012

Rhodium-catalyzed hydroacylation is a powerful and atom-economical method for synthesizing ketones from aldehydes and olefins. Despite this, a narrow scope of reactive substrates has limited the utility and broad application of this transformation. Efforts towards the development of new classes of reactive substrates have focused on the use of oxygen- and sulfur-containing olefins, which have enabled various modes of reactivity and thus allowed access to novel types of hydroacylation products. In addition to reactivity, a key to the success of these transformations is the control of regio-, stereo-, and chemoselectivity. In combination with substrate structure, strategies in enantioselective catalysis and metal-organic cooperative catalysis have been applied to achieve requisite reactivity and selectivity when required. A variety of products, such as medium-sized heterocycles, branched sulfur-containing and β-hydroxy ketones, and ketones bearing quaternary carbon centres have been synthesized via hydroacylation using these strategies. A method for preparing polyelectrolyte-stabilized palladium nanoparticles and their use in Suzuki coupling reactions have also been developed.

Hydroacylation

Catalysis

Rhodium

Asymmetric Catalysis

0490

Rhodium-catalyzed Intermolecular Hydroacylation of Unactivated Alkenes and Application to the Total Synthesis of Octaketide Natural Products

Le, Christine

20 November 2012

Transition metal-catalyzed olefin hydroacylation represents an atom-economical approach for the synthesis of valuable ketone products. To date, the intermolecular variant of this reaction suffers from several drawbacks, which include limited substrate scope, poor reactivity and/or regioselectivity for non-activated, non-chelating alkene substrates, and competitive reductive decarbonylation pathways that lead to catalyst decomposition. Herein, we report the linear-selective intermolecular hydroacylation of a wide range of electronically diverse olefins with salicylaldehydes employing catalyst loadings as low as 2 mol%. A unique reactivity profile is observed for the chiral C2-symmetric phosphoramidite ligand employed in our catalyst system, and thus, we outline progress made towards the synthesis of new phosphoramidite ligands. We have applied our methodology in the total synthesis of nine octaketide natural products belonging to the dothiorelone, cytosporone, and phomopsin families. Due to recent reports demonstrating the anticancer activity of cytosporone B (Csn-B), we will also discuss progress towards the synthesis of Csn-B analogues.

Hydroacylation

Octaketide natural product

Rhodium-catalysis

0490