Cyclic Sulfamide HIV-1 Protease Inhibitors : Design, Synthesis and Modelling

Ax, Anna

January 2005

Ten years ago, the first protease inhibitor targeting the human immunodeficiency virus (HIV) was approved for clinical use. Highly active antiretroviral therapy (HAART), which combined protease and reverse transcriptase inhibitors, quickly became the standard therapy for treating patients infected with HIV and Acquired Immune Deficiency Syndrome (AIDS). Nevertheless, last year the AIDS pandemic reached its highest level ever. Many infected patients, mainly in the developing countries, are still without treatment. Among those patients who receive treatment, an increase in drug resistance and new-infection with drug-resistant strains are seen. To come to terms with these problems, new drugs that are efficient against resistant strains and can be produced at low cost are needed. In this study, we have focused our research efforts on cyclic sulfamides active as HIV-1 protease inhibitors. Distinctive to this compound class, as compared to the inhibitors so far approved for clinical use, was the incorporation of a water mimic that displaces the structural water (W301) observed in the X-ray crystal co-complexes. The first part of the study was aimed at understanding the rationale behind the nonsymmetric binding mode that the inhibitor adopted when bound to the enzyme. Symmetric and nonsymmetric inhibitors were synthesized and the structure-activity relationships and preferable binding modes were rationalized with the help of Comparative Molecular Field Analysis (CoMFA). In the second part of the study, an attempt was made to reduce the size of these inhibitors. As a result, the traditional P1/P1' substituents were removed, while the P2/P2' substituents were elongated in an attempt to reach between the binding sites. The design hypothesis was shown to be successful and inhibitors possessing nanomolar activity were identified.

Pharmaceutical chemistry

AIDS

HIV

protease inhibitor

aspartic protease

molecular modelling

3D-QSAR

CoMFA

Farmaceutisk kemi

Pharmaceutical chemistry

Farmaceutisk kemi

Design and Synthesis of Novel HIV-1 Protease Inhibitors Comprising a Tertiary Alcohol in the Transition-State Mimic

Ekegren, Jenny

January 2006

HIV-1 protease inhibitors are important in the most frequently used regimen for the treatment of HIV/AIDS, the highly active antiretroviral therapy (HAART). For patients with access to this treatment, an HIV infection is no longer lethal, but rather a manageable, chronic infection. However, the HIV-1 protease inhibitors are generally associated with serious shortcomings such as adverse events, development of drug resistance and poor pharmacokinetic properties. Most of the approved inhibitors suffer from high protein binding, rapid metabolism and/or low membrane permeability. In this project, novel HIV-1 protease inhibitors comprising a rarely used tertiary alcohol in the transition-state mimic were designed, synthesized and evaluated. The rationale behind the design was to achieve ‘masking’ of the tertiary alcohol by for example, intramolecular hydrogen bonding, which was believed could enhance transcellular transport. A reliable synthetic protocol was developed and a series of highly potent inhibitors was obtained exhibiting excellent membrane permeation properties in a Caco-2 cell assay. However, the cellular antiviral potencies of these compounds were low. In an attempt to improve the anti-HIV activity, microwave-accelerated, palladium-catalyzed cross-coupling reactions and aminocarbonylation of aryl bromide precursors were employed to produce P1'-extended test compounds. Inhibitors demonstrating up to six times higher antiviral effect were obtained, the best derivatives having para 3- or 4-pyridyl elongations in P1'. Fast metabolic degradation was observed in liver microsome homogenate, which is believed, at least partly, to be attributable to benzylic oxidation of the indanol P2 group of the inhibitors. To enable facile variation of the P2 side chain a new synthetic route was developed using an enantiomerically pure, benzyl-substituted epoxy carboxylic acid as the key intermediate. Cyclic and amino-acid-residue-derived P2 groups were evaluated, and inhibitors equipotent to the series containing an indanol moiety were produced.

Chemistry

HIV/AIDS

HIV-1 protease inhibitor

transition-state mimic

tertiary alcohol

palladium

cross-coupling

aminocarbonylation

microwave

molybdenum hexacarbonyl

Kemi

Apoptosis Regulation in Multiple Myeloma

Dimberg, Lina

January 2006

Multiple myeloma (MM) is a virtually incurable B cell malignancy of the bone marrow. One important part of tumor progression and an obstacle for successful therapy is resistance to apoptosis. To combat this resistance, the mechanisms of apoptosis and survival in MM must be better defined. In this thesis, we identified Fas up-regulation as a mechanism underlying interferon (IFN)-mediated sensitization to Fas-induced apoptosis in the MM cell line U-266-1970. IFN treatment induced activation of signal transducer and activator of transcription (Stat)1 but, intriguingly, also attenuated activation of MM survival factor Stat3. Exploring the role of Stat1 further, we established sub-lines of U-266-1970 with a stable over-expression of Stat1 and of its active mutant Stat1C. These sub-lines displayed a decreased expression and activation of Stat3, and an altered expression of apoptosis-related genes Harakiri, Bcl-2 and Mcl-1. In a drug library screening, Stat1 over-expression was associated with an increased sensitivity to Fas-induced apoptosis and, conversely, an increased resistance to several drugs, including the cyclin dependent kinase (cdk)1 inhibitor CGP74514A. We conclude that Stat1 over-expression does not confer a general resistance or sensitivity to apoptosis in MM, but may strongly affect the response to some specific drugs. We also explored the effects of picropodophyllin (PPP), an inhibitor of the insulin-like growth factor I (IGF-I) receptor tyrosine kinase (RTK), in MM. PPP selectively inhibited the IGF-I RTK activity without inhibiting the insulin RTK activity. Furthermore, PPP potently induced cell cycle arrest and apoptosis in all MM cell lines and patient samples tested, also in the presence of survival factors IGF-I and IL-6. We conclude that PPP has great therapeutic potential in MM Finally, we examined the expression and regulation of the inhibitors of apoptosis proteins (IAPs) in a panel of MM cell lines and patient samples. The glucocorticoid dexamethasone, which is used in MM therapy, induced a transient up-regulation and a subsequent down-regulation of c-IAP2, as well as a down-regulation of XIAP, possibly influencing the sensitivity to apoptosis induced by this drug. Supporting this notion, abrogation of IGF-IR signaling by PPP, which sensitizes MM cells to dexamethasone-induced apoptosis, enhanced the down-regulation of c-IAP2 and XIAP.

Biomedicine

multiple myeloma

apoptosis

survival

IFN

Stat1

Stat3

IGF-I

RTK inhibitor

PPP

IAP

Fas/CD95

dexamethasone

Biomedicin

Palladium-Catalysed Carbon–Carbon Coupling Reactions : Focusing on Microwave Heating, Low Catalyst Concentrations, Aqueous Conditions, Regioselectivity and Medicinal Chemistry Applications

Arvela, Riina K

January 2009

It is widely accepted that palladium is one of the most useful catalysts in organic chemistry, and many palladium(0)-catalysed carbon–carbon bond-forming reactions have been developed over the years. In addition, the ever-growing need for more environmentally benign processes in the chemical industry has driven scientists to look for greener options while developing new methodologies for organic synthesis. This thesis describes a series of studies on Suzuki and Heck coupling reactions in water and the application of palladium(0) catalysis to the development of new HIV-1 integrase inhibitors. The previously described 'transition-metal-free Suzuki-type coupling' reaction was shown to take place due to sub-ppm levels of palladium contaminants present in the commercially available sodium carbonate base. Based on this finding, a new, microwave-assisted Suzuki protocol utilizing ppb/ppm levels of palladium in water was developed. This methodology was adapted to terminal Heck coupling, although the scope of the protocol was found to be rather limited. Finally, both Suzuki and Heck reaction processes were successfully scaled up to 100 mmol using an automated batch stop-flow microwave apparatus. As the methodologies utilizing ultralow palladium concentrations were not applicable to aryl chlorides, attention was shifted towards palladium on carbon. This simple catalyst, together with microwave heating employing simultaneous cooling, was found to be beneficial in the Suzuki coupling of aryl chlorides with phenylboronic acid in water. Ligand-controlled internal arylation of ethylene glycol vinyl ether with aryl halides was shown to be possible in water alone without any additives. Reactions were run under air, using conventional heating and the products formed were isolated as aryl methyl ketones in good to excellent yields. The electron-rich (dippp)2Pd complex was shown to be beneficial for the microwave-assisted internal arylation of some aryl chlorides. Furthermore, the active role of the hydroxyl group of ethylene glycol vinyl ether in the formation of a cationic intermediate leading to internal Heck coupling product was elucidated. Finally, to demonstrate the usefulness of palladium(0) catalysis in the development of new pharmaceutical entities, a series of HIV-1 integrase inhibitors was synthesised and evaluated in strand transfer assays and in vitro. Based on the results and docking studies performed, valuable information related to the structure–activity relationship was obtained.

Suzuki coupling

Heck reaction

palladium

microwave heating

water

vinyl ethregioselective

HIV-1 integrase inhibitor

Pharmaceutical chemistry

Farmaceutisk kemi

Structure-Based Design and Synthesis of Protease Inhibitors Using Cycloalkenes as Proline Bioisosteres and Combinatorial Syntheses of a Targeted Library

Thorstensson, Fredrik

January 2005

Structure-based drug design and combinatorial chemistry play important roles in the search for new drugs, and both these elements of medicinal chemistry were included in the present studies. This thesis outlines the synthesis of protease inhibitors against thrombin and the HCV NS3 protease, as well as the synthesis of a combinatorial library using solid phase chemistry.In the current work potent thrombin inhibitors were generated based on the D-Phe-Pro-Arg motif incorporating cyclopentene and cyclohexene scaffolds that were synthesized by ring-closing metathesis chemistry. A structure-activity relationship study was carried out using the crystallographic results for one of the inhibitors co-crystallized with thrombin. HCV NS3 protease inhibitors comprising the proline bioisostere 4-hydroxy-cyclopent-2-ene-1,2-dicarbboxylic acid were synthesized displaying low nanomolar activity. The stereochemistry and regiochemistry of the scaffolds were determined by NOESY and HMBC spectra, respectively. The final diastereomeric target compounds were isolated and annotated by applying TOCSY and ROESY NMR experiments. Furthermore, a 4-phenyl-2-carboxypiperazine targeted combinatorial chemistry library was synthesized to be used early in the lead discovery phase. This was done using a scaffold that was synthesized by palladiumcatalyzed aromatic amination chemistry and subsequently derivatized with eight electrophiles and ten nucleophiles.

organic chemistry

organic synthesis

combinatorial synthesis

metathesis

olefin metathesis

thrombin

HCV

NS3

protease

proline isosteres

inhibitor

Organic synthesis

Organisk syntes

Synthesis of β-turn and pyridine based peptidomimetics

Blomberg, David

January 2007

Despite the unfavorable pharmacokinetic properties associated with peptides, they are still of great interest in drug development due to a multitude of interesting biological functions. The development of peptidomimetics strives to maintain or improve the biological activity of a peptide concurrently with removing the unwanted properties. This thesis describes two synthetic approaches to peptidomimetics with particular emphasis on secondary structure mimetics. First the design, synthesis and evaluation of two beta-turn mimetics incorporated in the endorphin Leu-enkephalin is presented. The beta-turn mimetics were stabilized by replacement of the intramolecular hydrogen bond with an ethylene bridge, and the amide bond between Tyr and Gly was replaced with an ether linkage. Linear analogues of the two mimetics were also synthesized. The peptidomimetics and their linear analogues were evaluated in a competitive binding assay at two opiate receptors, my and delta. One of the cyclized beta-turn mimetics was found to be a delta receptor antagonist with an IC50 value of 160 nM. Second a synthetic strategy to a beta-strand mimetic using 2-fluoro-4-iodopyridine as scaffold is described. The synthesis involved a Grignard exchange reaction on the pyridine scaffold using an amino acid derivative as electrophile followed by an SNAr reaction using an amine as nucleophile. The synthesis of a tripeptidomimetic of Leu-Gly-Gly and attempts to introduce chiral building blocks at the C-terminal, as well as studies towards elongated mimetics are presented. Two additional studies deal with the synthesis of two classes of potential thrombin inhibitors based on the pyridine scaffold. The first class contain pyridine as central fragment (P2 residue) substituted with a para-amidinobenzylamine group as P1 residue and various benzoyl groups as P3 residues. Three potential thrombin inhibitors were synthesized and found to be microM inhibitors in an enzymatic assay. In the second class, the pyridine ring serves as P3 residue. This class also lacks a strongly basic group in the P1 position. A small library of eight compounds were synthesized and evaluated in the enzymatic assay. Unfortunately, these compounds lacked inhibitory activity.

Peptidomimetics

beta-turn

beta-strand

pyridine scaffold

Grignard exchange reaction

SNAr reaction

thrombin inhibitor

Leu-enkephalin.

Organic synthesis

Organisk syntes

Design and Synthesis of Inhibitors Targeting the Hepatitis C Virus NS3 Protease : Focus on C-Terminal Acyl Sulfonamides

Rönn, Robert

January 2007

Hepatitis C is a global health problem that affects approximately 120–180 million people. This viral infection causes serious liver diseases and the therapy available suffers from low efficiency and severe side effects. Consequently, there is a huge unmet medical need for new therapeutic agents to combat the hepatitis C virus (HCV). Inhibition of the viral NS3 protease has recently emerged as a promising approach to defeat this infection, and the first HCV NS3 protease inhibitors have now entered clinical trials. In this project, several novel HCV NS3 protease inhibitors have been designed, synthesized and biochemically evaluated. Inhibitors with various P1 C-terminal functional groups intended as potential bioisosteres to the carboxylic acid found in product-based inhibitors have been revealed. Special focus has been placed on establishing structure–activity relationships of inhibitors containing the promising P1 C-terminal acyl sulfonamide group. The properties of the acyl sulfonamide functionality that are important for producing potent inhibitors have been identified. In addition, the advantages of the acyl sulfonamide group compared to the carboxylic acid have been demonstrated in both enzymatic and cell-based assays. Besides the acyl sulfonamide functionality, the acyl cyanamide and the acyl sulfinamide groups have been identified as new carboxylic acid bioisosteres in HCV NS3 protease inhibitors. The synthetic work included the development of a fast and convenient methodology for the preparation of aryl acyl sulfonamides. The use of microwave heating and Mo(CO)6 as a solid carbon monoxide source provided aryl acyl sulfonamides from aryl halides in excellent yields. This method was subsequently used in the decoration of novel HCV NS3 protease inhibitors comprising a non-natural P1 moiety. This new class of compounds can be used as lead structures in a future optimization process aimed at producing more drug-like HCV NS3 protease inhibitors.

Pharmaceutical chemistry

hepatitis C virus

HCV

NS3 protease inhibitor

acyl sulfonamide

bioisostere

palladium

carbonylation

microwave

molybdenum hexacarbonyl

Farmaceutisk kemi

Improved CoMFA Modeling by Optimization of Settings : Toward the Design of Inhibitors of the HCV NS3 Protease

Peterson, Shane

January 2007

The hepatitis C virus (HCV), with a global prevalence of roughly 2%, is among the most serious diseases today. Among the more promising HCV targets is the NS3 protease, for which several drug candidates have entered clinical trials. In this work, computational methods have been developed and applied to the design of inhibitors of the HCV NS3 protease. Comparative molecular field analysis (CoMFA) modeling and molecular docking are the two main computational tools used in this work. CoMFA is currently the most widely used 3D-QSAR method. Methodology for improving its predictive performance by evaluating 6120 combinations of non-default parameters has been developed. This methodology was tested on 9 data sets for various targets and found to consistently provide models of enhanced predictive accuracy. Validation was performed using q2, r2pred and response variable randomization. Molecular docking was used to develop SARs in two series of inhibitors of the HCV NS3 protease. In the first series, preliminary investigations indicated that replacement of P2 proline with phenylglycine would improve potency. Docking suggested that phenylglycine-based inhibitors may participate in two additional interactions but that the larger, more flexible phenylglycine group may result in worse ligand fit, explaining the loss in potency. In the second series, β-amino acids were explored as α-amino acid substitutes. Although β-amino acid substitution may reduce the negative attributes of peptide-like compounds, this study showed that β-amino acid substitution resulted in reduced potency. The P3 position was least sensitive to substitution and the study highlighted the importance of interactions in the oxyanion hole. Finally, docking was used to provide the conformations and alignment necessary for a CoMFA model. This CoMFA model, derived using default settings, had q2 = 0.31 and r2pred = 0.56. Application of the optimization methodology provided a more predictive model with q2 = 0.48 and r2pred = 0.68.

Pharmaceutical chemistry

CoMFA

3D-QSAR

model validation

Docking

SAR

hepatitis C virus

HCV

NS3 protease inhibitor

Farmaceutisk kemi

On the Design and Synthesis of Hepatitis C Virus NS3 Protease Inhibitors : From Tripeptides to Achiral Compounds

Örtqvist, Pernilla

January 2010

Infection by the hepatitis C virus (HCV) leads to inflammation of the liver, i.e. hepatitis. The acute infection often progresses to a chronic phase during which the liver function is gradually impaired. Approximately 20% of these chronic cases develop liver cirrhosis, with an ensuing increased risk of liver cancer. Global estimates of the total number of chronic cases range from 123–170 million. Yet, neither specific anti-HCV drugs nor vaccines are available. When drugs become available for daily clinical use, rapid development of drug-resistant strains is expected, making resistance an important issue. One of the most studied targets for specific anti-HCV drugs is the NS3 protease. The main objectives of the work presented in this thesis were to design and synthesise peptidomimetic inhibitors of this enzyme, and to establish the structure–activity relationships (SARs) regarding the inhibition of the wild type as well as of the known resistant variants A156T and D168V. Substituted prolines are common P2 residues in HCV NS3 protease inhibitors. To decrease the peptide character of the inhibitors, the non-coded phenylglycine was evaluated as a proline replacement in combination with known and novel P3 and P1 residues and P2 substituents. The results confirmed that phenylglycine is a promising P2 scaffold, with a possible π-stacking interaction with histidine 57 of the active site. However, to benefit from its full potential, additional optimisation is required. A 2(1H)-pyrazinone-based scaffold was introduced as P3 residue. Utilising the scope of the method developed for the pyrazinone scaffold synthesis, the phenylglycine side-chain was transferred to the scaffold. In combination with an aromatic P1 building-block, this design yielded achiral, peptidomimetic inhibitors, three times more potent than the tripeptide lead. The SARs for the inhibition of the resistant variants A156T and D168V were investigated for compounds based on either P2 proline or phenyl­glycine. It was concluded that the vulnerability of the inhibitors to alterations in the enzyme depends on the P2 and the P1 residue, not only on the P2 as previously suggested. These results provide important information for the design of a new generation of inhibitors with improved properties.

hepatitis C virus

NS3 protease inhibitor

structure-activity relationship

resistance

2(1H)-pyrazinone

phenylglycine

Pharmaceutical chemistry

Farmaceutisk kemi

Peptidomimetic Enzyme Inhibitors : Targeting M. tuberculosis Ribonucleotide Reductase and Hepatitis C Virus NS3 Protease

Nurbo, Johanna

January 2010

This thesis focuses on the design and synthesis of inhibitors targeting Mycobacterium tuberculosis ribonucleotide reductase (RNR) and hepatitis C virus (HCV) NS3 protease; enzymes that have been identified as potential drug targets for the treatment of tuberculosis and hepatitis C, respectively. Small peptides have been recognized as inhibitors of these enzymes. However, the use of peptides as drugs is limited due to their unfavorable properties. These can be circumvented by the development of less peptidic molecules, often referred to as peptidomimetics. When this work was initiated, only a few inhibitors targeting M. tuberculosis RNR had been identified, whereas the HCV NS3 protease was an established drug target. Therefore, early peptidomimetic design strategies were applied to inhibitors of RNR while the NS3 protease inhibitors were subjected to modifications in a later stage of development. It has previously been shown that peptides derived from the C-terminus of the small subunit of M. tuberculosis RNR can compete for binding to the large subunit, and thus inhibit enzyme activity. To investigate the structural requirements of these inhibitors, different series of peptides were evaluated. First, peptides from an N-terminal truncation, an alanine scan and a designed library were synthesized and evaluated to examine the importance of the individual amino acid residues. Then, a set of N-terminally Fmoc-protected peptides was evaluated, and it was found that the N-terminal group improved the affinity of the peptides even when the length of the compounds was reduced. Furthermore, potential inhibitors of less peptidic character were generated by the introduction of a benzodiazepine-based scaffold. To further reduce the peptidic character and investigate the binding properties of HCV NS3 protease inhibitors, a series of tripeptides incorporating a β-amino acid was synthesized. Inhibition was evaluated and docking studies were performed to understand how the structural changes affected inhibitory potency. The results illustrated the importance of preserving the hydrogen bonding network and retaining electrostatic interactions in the oxyanion hole between inhibitor and protein.

enzyme inhibitor

peptidomimetics

structure-activity relationship

tuberculosis

ribonucleotide reductase

hepatitis C virus

NS3 protease

Pharmaceutical chemistry

Farmaceutisk kemi