Design and Synthesis of Acyclic and Macrocyclic Peptidomimetics as Inhibitors of the Hepatitis C Virus NS3 Protease

Lampa, Anna

January 2012

Hepatitis C is a blood-borne disease affecting 130-170 million people worldwide. The causative agent, hepatitis C virus (HCV), infects the liver and is the major reason for chronic liver disease worldwide. The HCV NS3 protease, a key enzyme in the virus replication cycle, has been confirmed to be an important target for drug development. With the recent release of two HCV NS3 protease inhibitors onto the market and an arsenal of inhibitors in clinical trials, there are now hopes of finally combating the disease. However, the success of treatment relies heavily on the ability to overcome the emergence of drug-resistant forms of the protease. The main focus of this thesis was on designing and synthesizing novel inhibitors of the NS3 protease with a unique resistance profile. Efforts were also made to decrease the peptide character of the compounds, with the long-term goal of making them into more drug-like compounds. Special attention was devoted to developing inhibitors based on a phenylglycine in the P2 position, instead of the highly optimized and commonly used P2 proline. Around ninety acyclic and macrocyclic inhibitors have been synthesized and biochemically evaluated. P2 pyrimidinyloxy phenylglycine was successfully combined with an aromatic P1 moiety and alkenylic P1´ elongations, yielding a distinct class of HCV NS3 protease inhibitors. Macrocyclization was performed in several directions of the inhibitors via ring-closing metathesis. Only the macrocyclization between the P3-P1´ residues was successful in terms of inhibitory potency, which suggests that the elongated P1-P1´ residue is oriented towards the P3 side chain. The metathesis reaction was found to be significantly more dependent on the substrate than on the reaction conditions. It was also found that the P3 truncated inhibitors were able to retain good inhibitory potency, which initiated the synthesis and evaluation of a series of P2-P1´ inhibitors. The potential of the P3-P1´cyclized inhibitor and the smaller, acyclic P2-P1´ as new potential drug leads remains to be determined through pharmacokinetic profiling. Gratifyingly, all the inhibitors evaluated on A156T and D168V substituted enzyme variants were able to retain inhibitory potency towards these as compared to wild-type inhibition.

hepatitis C virus

HCV

NS3 protease inhibitor

structure-activity relationship

phenylglycine

ring-closing metathesis

The Use of Soluble Polyolefins as Supports for Transition Metal Catalysts

Hobbs, Christopher Eugene

2011 August 1900

The use of polymer supports for transition metal catalysts are very important and useful in synthetic organic chemistry as they make possible the separation and isolation of catalysts and products quite easy. These polymer-bound ligands/catalysts/reagents can, often, be recovered and recycled numerous times and typically yield products in high purity, negating the need for further purification steps (i.e. column chromatography). Because of this, interest in these systems has garnered international attention in the scientific community as being “Green”. Historically, insoluble, polymer-supports (i.e. Merrifield resin) were used to develop recoverable catalysts. This has the advantage of easy separation and isolation from products after a reaction; because of their insolubility, such supported catalysts can be easily removed by gravity filtration. However, these catalysts often have relatively poor reactivity and selectivity when compared to homogeneous catalysts. Because of this disadvantage, our lab has had interest in the development of soluble polymer-supports for transition metal catalysts. We have developed several separation methods for these soluble polymer-bound catalysts. These include thermomorphic liquid/liquid and solid/liquid as well as latent biphasic liquid/liquid separation techniques. This dissertation describes the use of both, latent biphasic liquid/liquid separation systems and thermomorphic solid/liquid separation systems. In order to perform a latent biphasic iii liquid/liquid separation, a polymer-bound catalyst must have a very high selectivity for one liquid phase over the other. Our lab has pioneered the use of polyisobutylene (PIB) oligomers as supports for transition metal catalysts. Previous work has shown that these oligomers are > 99.96 % phase selectively soluble in nonpolar solvents. This has allowed us to prepare PIB-supported salen Cr(III) complexes that can be used in a latent biphasic liquid/liquid solvent system. The synthesis of these complexes is quite straightforward and such species can be characterized using solution state 1H and 13C NMR spectroscopy. Also, these complexes can be used to catalyze the ring opening of meso epoxides with azidotrimethylsilane (TMS-N3) and can be recovered and recycled up to 6 times, with no loss in catalytic activity. To perform a thermomorphic solid/liquid separation, a polymer-bound catalyst that is completely insoluble at room temperature but soluble upon heating must be used. Our lab has pioneered the use of polyethylene oligomers (PEOlig) as supports for transition metal catalysts. Such PEOlig-supported catalysts are able perform homogeneous catalytic reactions at elevated temperatures (ca. 65 ○C), but, upon cooling, precipitate out of solution as solids while the products stay in solution. This process allows for the easy separation of a solid catalyst from the product solution. Described herein, is the development of PEOlig-supported salen-Cr(III) complexes and PEOlig-supported NHC-Ru complexes. The preparation of these complexes is also straightforward and such species can be characterized using solution state variable temperature (VT) 1H and 13C NMR spectroscopy. In the case of the PEOlig-supported salen-Cr(III) complex, it was found to be a recoverable/recyclable catalyst for the ring opening of epoxides with TMS-N3 and could be reused 6 times with no loss in activity. The PE-supported NHC-Ru complex was able to be used as a recyclable ring closing metathesis (RCM) catalyst and could be used up to 10 times.

Transition metal catalysts

polymer chemistry

polymer-bound catalysts

salen-catalysts

ring closing metathesis

Grubbs catalyst

1. Synthetic Study of Pyrrolizidine Skeleton 2. Synthetic Study Toward Tylophorine and Cryptopleurine 3. Synthetic Study of Fused Bicyclic Glutarimides

Hsu, Ru-Ting

18 January 2005

Reaction of 3-sulfonyl acetamides with various substituted methyl acrylate derivatives furnished pyroglutamate and glutarimidess via [3+2] and [3+3] cycloaddition respectively. The results were applied to the synthesis of pyrrolizidine skeleton, tylophorine, cryptopleurine and fused bicyclic glutarimides.

[3+2] annulation

pyroglutamate

pyrrolizidine

fused bicyclic

[3+3] annulation

quinolizidine

ring-closing metathesis

1. Synthesis of Nonlinear Optical Chromophores 2. New Approaches to Quinolone Skeleton

Tsai, Tsung-Hsiu

27 June 2005

Chapter 1: Reaction of benzoaldehyde with wittig agents or isophone to build up conjugate carbon chain, then combined with electron acceptor to furnished the chromophores. The charge-transfer chromophores, which have the first molecular hyperpolarizability

benzo[c]phenanthridine alkaloid

chromophore

Grignard addition

ring-closing metathesis

toddaquinoline

hyperpolarizability

quinolone

[3+3] annulation

Synthetic Studies Toward Xylopinine

Chang, Jung-Kai

18 August 2005

We use stepwise [3+3] annulation to prepare the asymmetric glutarimides, and then establish a new approach to isoquinolone skeleton starting from glutarimides via regioselective nucleophilic addition and ring-closing metathesis reaction. Finally, we applied this method to the synthetic studies toward (¡Ó)-Xylopinine.

isoquinolone

pyridine-2-one

xylopinine

ring-closing metathesis

[3+3] annulation

Synthesis Of Heteroaryl Substituted Dihydrofuran And Dihydropyran Derivatives By Green Chemistry Approach

Demirci, Sema

01 September 2009

The thesis subject is mainly involved in Green Chemistry approach. Thiophene, furan and pyridine carboxaldehydes were chosen as starting compounds and vinylation and allylation with Grignard reaction afforded the corresponding racemic heteroaryl substituted allylic and homoallylic alcohols. Subsequent resolution with enzymes (PS-Amano II, Lipozym and Novazym 435) gave enantiomerically enriched alcohols with the e.e. values varied between 65 and 99%. The absolute configurations of all substrates are known. As a result of O-allylation with the common procedure formed the feasible carbon backbone for the ring closing metathesis reaction. All ring closing metathesis reactions were performed by Grubbs&rsquo / catalyst with just 5% catalyst loading. The absolute configurations of dihydrofuran and dihydropyran derivatives are known, since the chiral center configurations of all substrates are preserved throughout all the applied processes.

QD Organic Chemistry 241-441

Chemoenzymatic Synthesis Of Enantiomerically Enriched Gamma And Delta Lactones

Sardan, Melis

01 September 2010

The major subject of this thesis is the synthesis of enantiomerically enriched gamma and delta lactones via Ring Closing Metathesis (RCM). Furan and thiophene substituted aldehydes were transformed to the corresponding heteroaryl substituted allylic and homoallylic alcohols by using vinyl and allylmagnesium bromide, respectively and then resultant racemic alcohols were resolved by hydrolase type enzymes (PSC-II, Lipozyme, CAL-B) with high enantiomeric excess values. Since the absolute configuration of alcohols were known, it was possible to determine the configuration of the synthesized compounds. After the enantiomeric enrichment of the alcohols, subsequent acylation with acryloyl and methacryloyl chloride afforded feasible diene system that was subjected to ring closing metathesis reaction 1st and 2nd generation Grubbs&rsquo / catalysts were used. These lactones were used to test their biological activities.

QD Organic Chemistry 241-441

Functionalization of Resorcinarenes and Study of Antimicrobial Activity

Muppalla, Kirankirti

21 May 2001

Cavitands are very important class of compounds in supramolecular chemistry. These molecules contain rigid enforced cavity,and have attracted considerable attention in supramolecular chemistry as building blocks for the construction of carcerands, hemicarcerands, and other host guests complexes. Nearly 40 years ago, Niederl and Vogel laid foundation for the study of such type of condensation reactions. In our laboratory we are involved in synthesis of resorcinarenes with readily available substrates such as resorcinol and aldehydes to form a cyclic tetramer. Herein, I present detailed studies about the functionalization of the synthesized tetramers and their antimicrobial activity. Octahydroxy resorcinarenes were synthesized and perallylated which served as acyclic diene precursors for ring closing metathesis reaction. Studies were carried out to see effect of C-2 substituent of resorcinol and effect of aryl substituents, and aliphatic substituents on ring closing metathesis. This thesis describes the synthesis of bridged resorcinarenes and study of antimicrobial activity of resorcinarenes.

cavitand

ring closing metathesis

crystal structure

NMR

antimicrobial activity

American Studies

Arts and Humanities

Chemistry

Application of the Moore rearrangement to the synthesis of 1,4-dioxygenated xanthones and efforts toward the total synthesis of lundurine B

Nichols, Alexander Lindsey

31 January 2013

A novel application of the Moore rearrangement was successfully developed and applied to the synthesis of 1,4-dioxygenated xanthones that would have been difficult to obtain otherwise. The 1,4-dioxygenated xanthone moiety is found in several naturally occurring, biologically active compounds. Several methods by which to obtain the 1,4-dioxygenated xanthone core have been reported; however, high step counts, low yields, and harsh reaction conditions preclude the use of these methods to complex xanthone natural products. Using the Moore rearrangement as a key step in the synthetic sequence has allowed us to prepare several xanthone natural products quickly and more efficiently than what is possible with the prior art. Using the Martin group’s prior experience with the application of ring closing metathesis (RCM) to the field of alkaloid natural product synthesis, the preparation of lundurine B was undertaken. Key features of the proposed synthesis to lundurine B include the formation of a cyclopropane ring by the formation pyrazoline intermediate via [3+2] dipolar cycloaddition followed by dinitrogen extrusion. A second key step in the proposed sequence to lundurine B is a double RCM to form a five- and eight-membered ring in a single operation. While double RCM strategies have been applied to several elegant natural product syntheses, the formation of a five- and eight-membered ring in a single sequence has not been reported. Should the double RCM strategy prove successful for lundurine B, the conditions could in principle be applied to other structurally related natural products. / text

Xanthone

Moore rearrangement

Total synthesis

Alkaloid

Natural product

Ring closing metathesis

A novel approach to manipulate cavity size In resorcinarenes

Parulekar, Sumedh

01 June 2006

Intramolecular ring closing metathesis in the presence of Grubbs' catalyst has been used as an efficient approach to synthesize bridged resorcinarenes. Octaallyl cavitands may undergo conformational changes; however bridge formation by RCM of the allyl groups gives a rigid, enforced, concave cavity capable of holding neutral molecules. This is the first report describing tandem formation of the four bridges on the upper rim of resorcinarenes. Structures of bridged resorcinarenes are confirmed by spectral analysis data.This report also describes the synthesis of polyhydroxy resorcinarenes, which have been used as metal complexing agents, sensors, receptors, molecular reaction vessels and catalytic chambers. They are able to encapsulate small neutral molecules, drug molecules inside the cavity. Such cavitands offer unique molecular platforms for host--guest chemistries, as well as new polymers and self-assembled systems.

Cavitand

Ring closing metathesis

Bromination

Crystal structure

NMR

American Studies

Arts and Humanities