ISOPRENOID ANALOGS AS CHEMICAL GENETIC TOOLS TO PROVIDE INSIGHTS INTO FARNESYL TRANSFERASE TARGET SELECTION AND CELLULAR ACTIVITY

Troutman, Jerry

01 January 2006

Protein farnesylation is an essential post-translational modification required for the function of numerous cellular proteins including the oncoprotein Ras. The farnesyl transferase (FTase) catalyzed reaction is unique because farnesyl diphosphate (FPP), the farnesyl group donor for the reaction, forms a significant portion of a target protein binding site. The major goal of this research was to exploit this unique property of the FTase reaction and determine if changing the structure of the farnesyl donor group would affect FTase protein targeting. A small library of structural analogues of FPP was synthesized. Michelis-Menten steady-state kinetic analyses and competition reactions were used to determine the effect of these structural modifications on FTase targeting. We found that the analogues did affect FTase protein selectivity and that this could be exploited to induce unnatural target selectivity into the enzyme. The second goal of this research was to determine the effect of FPP analogues on the function of FTase target proteins. To test the effect of these analogues we determined whether the unnatural lipid could ablate oncogenic H-Ras biological function in a Xenopus laevis model system. Several analogues were able to disrupt oncogenic H-Ras function while others mimicked the activity of FPP. These results indicated that some of the FPP analogues may act a prenyl group function inhibitors that could lead to an important new class of anti-cancer therapeutics. Another major goal of this research was to use the FPP analogues as unnatural probes for the endogenous cellular activity of FTase target proteins. We developed antibodies to two of the unnatural FPP analogues to study their activity in cell cultureUtilizing these antibodies we found that alcohol prodrugs of the FPP analogues could be incorporated into cellular proteins in an FTase dependent manner. The ability of cell permeant analogues to be incorporated into live cells enhances the chances that such a molecule could be used to modify oncogenic cellular proteins with a prenyl group function inhibitor.

Protein Farnesyl Transferase

Enzyme Kinetics

Prenyl Transferases

Solid-Phase Organic Synthesis

Hapten Synthesis

Medical Biochemistry

Synergy and Resistance Mechanisms in R115777 and PS-341 Models of Myeloma and Leukemia

Buzzeo, Robert William

25 June 2009

The farnesyl transferase inhibitor R115777 (Zarnestra, Tipifarnib) has been found to have clinical activity in diverse hematopoietic tumors. Clinical efficacy, however, does not correlate with Ras mutation status or inhibition of farnesyl transferase. To further elucidate the mechanisms by which R115777 induces apoptosis and to investigate drug resistance, we have identified and characterized a R115777-resistant human myeloma cell line. 8226/R5 cells were found to be at least 50 times more resistant to R115777 compared with the parent cell line 8226/S. 8226/R5 cells were insensitive to a diverse group of antitumor agents including PS-341 (Bortezomib, Velcade). Comparison of gene expression profiles between resistant and sensitive cells revealed expression changes in several genes involved in myeloma survival and drug resistance. Identification and characterization of the 8226/R5 cell line helped us evaluate and confirm that the Akt tumor survival pathway plays an important role in Tipifarnib induced apoptosis and resistance in myeloma cells. Additionally, 8226/R5 cells helped to evaluate other molecules exhibiting synergistic cell death. In this study, we investigated the activity of R115777 combined with Bortezomib in microenvironment models of multiple myeloma and AML. The combination proved to be synergistic in multiple myeloma and AML cell lines treated in suspension culture. Even in tumor cells relatively resistant to Tipifarnib, combined activity was maintained. Of importance, activation of the endoplasmic reticulum stress response was enhanced and correlated with apoptosis and reversal of CAM-DR. Our study provides the preclinical rationale for trials testing the Tipifarnib and Bortezomib combination in patients with multiple myeloma and AML.

Tipifarnib

8226/R5

Velcade

Farnesyl Transferase

Proteasome

American Studies

Arts and Humanities

The Asymmetric Phase-Transfer Catalyzed Alkylation of Imidazolyl Ketones and Aryl Acetates and Their Applications to Total Synthesis

Christiansen, Michael Andrew

10 March 2010

Phase-transfer catalysts derived from the cinchona alkaloids cinchonine and cinchonidine are widely used in the asymmetric alkylation of substrates bearing moieties that resonance stabilize their enolates. The investigation of α-oxygenated esters revealed decreased α-proton acidity, indicating the oxygen's overall destabilizing effect on enolates by electron-pair repulsion. Alkylation of α-oxygenated aryl ketones with various alkyl halides proved successful with a cinchonidine catalyst, giving products with high yield and enantioselectivity. The resulting compounds were converted to esters through modified Baeyer-Villiger oxidation. Alkylation with indolyl electrophiles gave products that underwent decomposition under Baeyer-Villiger conditions. Alternative N-methylimidazolyl ketones were explored. Alkylated imidazolyl ketones, obtained in high yield and enantioselectivity, could be converted to esters through treatment with methyl triflate and basic methanol. This technique has the advantage of not requiring stoichiometric addition of chiral reagents, which is requisite when employing traditional chiral auxiliaries. This method's utility is demonstrated in the total asymmetric syntheses of (+)-kurasoin B and analogs, and 12-(S)-HETE. Kurasoin B is a fungal-derived natural compound possessing moderate farnesyl transfer (FTase) inhibitive activity (IC50 = 58.7 μM). FTase catalyzes post-translation modifications of membrane-bound Ras proteins, which function in signal cell transduction that stimulates cell growth and division. The oncogenic nature of mutated Ras proteins is demonstrated by their commonality in human tumors. Thus, FTase inhibitors like (+)-kurasoin B possess potential as cancer chemotherapy leads. Derivatization may enable structure-activity-relationship studies and greater FTase inhibition activity to be found. 12-(S)-HETE, a metabolite from a 12-lipoxygenase pathway from arachidonic acid, has been found to participate in a large number of physiological processes. Its transient presence in natural tissues makes total synthesis an attractive avenue for obtaining sufficient quantities for further study. Five asymmetric syntheses of 12-(S)-HETE have been reported. Three require chiral resolutions of racemates, with the undesired enantiomers being discarded or used for other applications. Asymmetric PTC alkylation is also described for aryl acetates, whose products were enantioenriched through recrystallization. This technique is applied to a total synthesis of the anti-inflammatory drug (S)-Naproxen.

phase-transfer catalysis

asymmetric alkylation

kurasoin

12-(S)-HETE

farnesyl transferase

acyl imidazole

aryl acetate

(S)-Naproxen

Biochemistry

Chemistry

Synthetic strategies for potential trypanocides

Capes, Amy

January 2011

Human African trypanosomiasis (sleeping sickness) is a devastating disease which is endemic in parts of sub-Saharan Africa. It is caused by the protozoan parasite T. brucei, which are transmitted by the bite of infected tsetse flies. Although the disease is fatal if left untreated, there is a lack of safe, effective and affordable drugs available; therefore new drugs are urgently needed. The aim of the work presented in this thesis is to develop novel trypanocidal compounds. It is divided into two parts to reflect the two distinct strategies employed to achieve this aim. The first part focuses on the inhibition of glycophosphoinositol (GPI) anchor synthesis by inhibiting the Zn2+-dependent enzyme, GlcNAc-PI de-N-acetylase. Trypanosomes have a variable surface glycoprotein (VSG) coat, which allows them to evade the human immune system. The GPI anchor attaches the VSG to the cell membrane; therefore inhibiting GPI synthesis should expose the parasite to the immune system. Initially, large substrate analogues were synthesized. These showed weak inhibition of the enzyme. Zinc-binding fragments were screened, and small molecule inhibitors based on salicylhydroxamic acid were then synthesized. These compounds showed modest inhibition, but the excellent ligand efficiency of salicylhydroxamic acid indicates this may be a promising starting point for further inhibitors. The second part details the P2 strategy. The P2 transporter is a nucleoside transporter unique to T. brucei, which concentrates adenosine. The transporter also binds and selectively concentrates compounds that contain benzamidine and diaminotriazine P2 motifs, which can enhance the potency and selectivity of these compounds. The sleeping sickness drugs melarsoprol and pentamidine contain P2 motifs. Compounds comprising a P2 targeting motif, a linker and a trypanocidal moiety were synthesized. Initially, a diaminotriazine P2 motif was attached to a trypanocidal tetrahydroquinoline (THQ) protein farnesyl transferase (PFT) inhibitor, with limited success. The P2 strategy was also applied to a non-selective, trypanocidal, quinol moiety. The quinol moiety was attached to diaminotriazine and benzamidine P2 motifs, and an increase in selectivity for T. brucei over MRC5 cells was observed.

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