Catalytic enantioselective synthesis of O- and N-substituted quaternary carbon stereogenic centers : 1. AL-catalyzed alkylations of α-ketoesters with dialkylzinc reagents. 2. AG-catalyzed vinylogous Mannich-type reactions of α-ketoimine esters with siloxyfurans

Wieland, Laura Caroline

January 2008

Thesis advisor: Amir H. Hoveyda / Chapter 1: We disclose an Al-catalyzed enantioselective method for additions of Me2Zn and Et2Zn to α-ketoesters bearing aromatic alkenyl, and alkyl substituents. These transformations are promoted in the presence of a readily available amino acid-based ligand, and afforded the desired products in excellent yields and in up to 95% ee. In addition, we discovered a remarkable enhancement of efficiency and selectivity in the presence of an achiral phosphoramidate additive. Chapter 2: An efficient diastereo- and enantioselective Ag-catalyzed method for additions of a commercially available siloxyfuran to α-ketoimine esters is disclosed. Catalytic transformations require an inexpensive metal salt (AgOAc) and an air stable chiral ligand that is readily prepared in three steps from commercially available materials in 42% overall yield. Aryl- as well as heterocyclic substituted ketoimines can be used effectively in the Ag-catalyzed process. Additionally, two examples regarding reactions of alkyl-substituted ketoimines are presented. An electronically modified N-aryl group is introduced that is responsible for high reaction efficiency (>98% conversion, 72–95% yields after purification), diastereo- (up to >98:2 dr) and enantioselectivity (up to 97:3 er or 94% ee). The new N-aryl unit is also crucial for conversion of the asymmetric vinylogous Mannich products to the unprotected amines in high yields. Spectroscopic and X-ray data are among the physical evidence provided that shed light on the identity of the Ag-based chiral catalysts and some of the mechanistic subtleties of this class of enantioselective C–C bond forming processes. / Thesis (PhD) — Boston College, 2008. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

catalytic

enantioselective

Mannich

tertiary alcohol

ketoimine

Development of HIV-1 Protease Inhibitors and Palladium-Catalyzed Synthesis of Aryl Ketones and N-Allylbenzamides

Axelsson, Linda

January 2014

The use of palladium-catalyzed reactions to introduce new carbon-carbon bonds is a fundamental synthetic strategy that has been widely embraced due to its high chemo- and regioselectivity and functional group tolerance. In this context, Pd(0)-catalyzed aminocarbonylations using Mo(CO)6 instead of toxic and gaseous CO and with allylamine as the nucleophile were investigated. The aminocarbonylated product dominated over the Mizoroki-Heck product, and (hetero)aryl iodides, bromides and chlorides gave N-allylbenzamides in good yields. In this thesis improvements to an existing protocol for the Pd(II)-catalyzed synthesis of aryl ketones from five benzoic acids and a variety of nitriles are also presented. Addition of TFA improved the yields and employing THF as solvent enabled the use of solid nitriles, and the aryl ketones were isolated in good yields. The pandemic of HIV infection is one of the greatest public health issues of our time and approximately 35.3 million people worldwide are living with HIV. There are currently many drugs on the market targeting various parts of the viral reproduction cycle, but the problems of resistance warrant the search for new drugs. HIV-1 protease makes the virus mature into infectious particles. In this thesis a new type of HIV-1 protease inhibitor (PI) is presented, based on two of the PIs on the market, atazanavir and indinavir, but it has a tertiary alcohol, as well as a two-carbon tether between the quaternary carbon and the hydrazide β-nitrogen. A total of 25 new inhibitors were designed, synthesized and biologically evaluated, the best compound had an EC50 value of 3 nM. Based on this series a project aimed at synthesizing macrocycles spanning the P1-P3 area was initiated. Macrocycles often tend to have an improved affinity and metabolic profile compared to their linear analogs. Introduction of a handle in the para position of the P1 benzyl group proved difficult, despite efforts to synthesize intermediates containing either a bromo-, hydroxy-, methoxy-, silyl-group protected hydroxy- or an alkyne-group. The lactone intermediate was abandoned in favor of an alternative synthetic route and initial studies were found to be promising. This new approach requires further investigation before the target macrocycles can be synthesized.

palladium

aminocarbonylation

aryl ketones

decarboxylation

HIV

protease inhibitor

tertiary alcohol

macrocycles

Tertiary Alcohol- or β-Hydroxy γ-Lactam-Based HIV-1 Protease Inhibitors : Microwave Applications in Batch and Continuous Flow Organic Synthesis

Öhrngren, Per

January 2011

Since the outbreak of the HIV/AIDS pandemic in the 1980s, the disease has cost the lives of over 30 million people, and a further 33 million are currently living with the HIV infection. With the appropriate treatment, HIV/AIDS can today be regarded as a chronic but manageable disease. However, treatment is not available globally and UNAIDS still estimates that there are currently 5000 AIDS-related deaths worldwide per day. HIV protease inhibitors (PIs) constitute one of the fundaments of HIV treatment, and are commonly used in so-called highly active antiretroviral therapy (HAART), together with reverse transcriptase inhibitors. Although there are ten PIs on the market, there is still a need for novel structures. The rapid development of resistant strains, due to the high frequency of mutations, together with the commonly observed adverse effects of the drugs available, illustrate the need to develop new potent structures. Two novel scaffolds were investigated in this work. A tertiary alcohol-containing scaffold comprising a three-carbon tether, and a β-hydroxy γ-lactam-based scaffold were designed, synthesized and evaluated using enzyme- and cell-based assays. X-ray analyses of inhibitors from each class provided information on inhibitor–protease interactions. The inhibitors containing the tertiary alcohol provided at best an enzymatic inhibition (Ki) of 2.3 nM, and an inhibition in the cell-based assay (EC50) of 0.17 µM. The γ-lactam-based inhibitors exhibited better inhibition than the first series; the best values being Ki = 0.7 nM and EC50 = 0.04 µM. The second part of these studies involved the evaluation of a novel non-resonance continuous-flow microwave instrument. The instrument was validated regarding heating capacity, temperature stability and temperature homogeneity. A number of model reactions were performed with low- and high-microwave-absorbing solvents. It was found that the microwave heating source allowed rapid temperature adjustment, together with easily regulated, flow-dependent reaction times, providing an efficient tool for reaction optimisation.

HIV

AIDS

protease inhibitor

aspartic protease

lactam

tertiary alcohol

continuous-flow

microwave

non-resonant

MAOS

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

Ekegren, Jenny

January 2006

<p>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. </p><p>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. </p><p>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'.</p><p>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.</p>

Chemistry

HIV/AIDS

HIV-1 protease inhibitor

transition-state mimic

tertiary alcohol

palladium

cross-coupling

aminocarbonylation

microwave

molybdenum hexacarbonyl

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