High-throughput identification and characterization of novel inhibitors of Regulator of G Protein Signaling 17 as pretherapeutic leads for the treatment of lung and prostate cancers

Mackie, Duncan Ian

01 December 2014

G–Protein Coupled Receptors are one of the most important targets in drug development, making up over 60% of drug targets. Recent studies have implicated a role of Regulator of G–Protein Signaling (RGS) proteins in the development and progression of pathologies, including some cancers. RGS17, the most–recently identified family member of the RZ family of RGS proteins, has been implicated in the growth, proliferation, metastasis and migration of prostate tumors as well as small–cell and non–small cell lung cancers. In neoplastic tumor tissues RGS17 is up–regulated 13 fold over patient–matched normal tissues in prostate cancer. Studies have shown that RGS17 RNAi knockdown inhibits colony formation and decreases tumorigenesis in nude mice. Based on these findings, this thesis explores the research undertaken to develop small molecule inhibitors of the RGS17: Gαo protein: protein interaction. In this thesis, we implemented AlphaScreen® technology to develop a high–throughput screening method for interrogating small molecule libraries for inhibitors of RGS17. Chapter 3 focuses on the initial results of the AlphaScreen® in 384–well format. The screen utilizes a measurement of the Gα: RGS17 protein: protein interaction (PPI) and with an excellent Z–score exceeding 0.73, a signal to noise ratio >70 and a screening time of 1,100 compounds per hour. Chapter 3 presents the development, validation and initial high–throughput screening for inhibitors of Gα: RGS17 interaction as well as preliminary characterization of the RL series of hits. In this pilot screen the NCI Diversity Set II was interrogated, yielding 35 initial hits of which 16 were confirmed after screening against controls. The 16 compounds exhibited IC50 <10 ΜM in dose–response experiments for inhibiting the Gα: RGS17 interaction. Four exhibited IC50 values <6 ΜM while inhibiting the Gα: RGS17 interaction >50% when compared to a biotinylated GST control (TrueHits). Compounds RL–1 and RL–2 were confirmed by flow cytometry protein interaction assay (FCPIA) while RL–3 and RL–4 were unable to disrupt this PPI in FCPIA. All four compounds were tested using the differential scanning fluorimetry (DSF) method, which is based on energetic coupling between ligand binding and protein unfolding and found compounds RL–1 to RL–4 all slightly increased protein stability upon ligand binding. Chapter 4 focuses on the miniaturization and optimization of AlphaScreen® to a 1536–well format and screening of the MicroSource SPECTRUM and NDL3000 small molecule libraries. This increased throughput 11–fold and decreased our working volumes from 45 ΜL to 10 ΜL, which reduced reagent cost. After optimization, we retained in an excellent Z–factor ≥0.70 with S/N>5.77 and increased the screening rate to more than 12,000 compounds per hour. In this format, the initial screening of the SPECTRUM and NDL3000 libraries was completed and filtered the initial hits by counter screening and PAINs filtering as well as developing four powerful orthogonal assays for the characterization of potential lead molecules. Chapter 6 focuses on the future directions, which include the screening the in–house 50,000 compound library in the University of Iowa HTS Core facility as well as the development of cell based assays to determine the activity of these leads in the cellular milieu. These screens are the first step to developing novel pharmacophores for further optimization of structure with the focus on RGS17 activity in enzymatic, whole cell, xenograft and whole animal models as well as providing new avenues for the development of anticancer therapies.

biochemical pharmacology

G protein coupled receptors

High-throughput screening

Lung and prostate cancers

RGS17

Pharmacy and Pharmaceutical Sciences

Rôle du gène de fusion TMPRSS2.ERG dans la formation des métastases osseuses du cancer de la prostate / Role of TMPRSS2.ERG fusion gene in prostate cancer bone metastasis formation

Delliaux, Carine

14 June 2017

Les tumeurs locales de la prostate sont associées à une évolution lente et une bonne survie, alors que les stades plus avancés révèlent dans 80% des cas des métastases osseuses incurables. La découverte de gènes de fusion issus de remaniements chromosomiques, tel que TMPRSS2:ERG dans plus de 50% des cas, a ouvert une nouvelle voie dans la compréhension du processus de cancérisation de la prostate. La présence de ce gène de fusion peut être associée à un mauvais pronostic dans de nombreuses études cliniques. Cependant, son rôle précis au cours de la cancérisation et de la progression du cancer de la prostate reste à déterminer. Le gène Erg (Ets related gene) code un facteur de transcription dont l’expression est notamment associée à la mise en place du cartilage, et plus largement du squelette. Ceci suggère un rôle potentiel du gène de fusion impliquant ce facteur, et de ses gènes cibles, dans la formation des métastases osseuses du cancer de la prostate.Pour notre étude, nous avons utilisé des lignées de cellules tumorales prostatiques PC3 et PC3c, exprimant stablement le gène de fusion TMPRSS2:ERG et précédemment établies au laboratoire. Dans un premier temps, en utilisant un modèle d’injections intratibiales chez les souris SCID, nous avons démontré que l’expression ectopique de la fusion améliore la capacité d’induction de lésions ostéocondensantes en inhibant l’ostéolyse dans le modèle PC3 ostéolytique, et en stimulant l’ostéoformation dans le modèle PC3c mixte (ostéolytique et ostéocondensant). Cette expression ectopique de la fusion augmente également l’ostéomimétisme dans les deux modèles cellulaires, c’est-à-dire l’acquisition d’un phénotype semblable aux cellules osseuses leur conférant des avantages de survie et de propagation dans la moelle osseuse. En outre, trois nouveaux gènes cibles de TMPRSS2:ERG ont été mis en évidence : ET-1 (Endothelin-1), stimulant la différenciation ostéoblastique et inhibant la résorption osseuse ostéoclastique, ALPL (Alkaline Phosphatase Liver/Bone/Kidney), marqueur de différenciation des ostéoblastes, et COL1A1 (Collagen Type 1 Alpha 1), composant de la matrice osseuse, témoignant d’un rôle du gène de fusion dans la formation de métastases ostéocondensantes du cancer de la prostate.Par ailleurs, deux autres gènes ont été étudiés, codant soit une protéine impliquée dans la stabilisation de structures particulières appelées invadopodes, soit une protéine impliquée dans le métabolisme des lipides. L’ensemble de ces résultats contribue à mieux comprendre les mécanismes de cancérisation et d’évolution métastatique du cancer de la prostate, en particulier l’influence de l’expression du gène de fusion TMPRSS2:ERG dans les métastases osseuses du cancer de la prostate. / Local prostate cancers are associated with slow progression and good survival, while advanced stages reveal incurable bone metastases in 80% of cases. The discovery of fusion genes resulting from chromosomal rearrangements, such as TMPRSS2:ERG in more than 50% of cases, opened a new way in understanding the process of prostate cancer. The presence of this fusion gene may be associated with poor prognosis in many clinical studies. However, its precise role during cancerization and progression of prostate cancer remains to be determined. The Erg gene (Ets related gene) encodes a transcription factor whose expression is associated in particular with embryonic skeleton development. This suggests a potential role of the fusion gene involving this factor, and its target genes, in the formation of prostate cancer bone metastases.In this study, we used prostate cancer cell lines PC3 and PC3c, stably expressing the TMPRSS2:ERG fusion gene and previously established in the laboratory. First, using a model of intratibial injections in SCID mice, we demonstrated that ectopic expression of the fusion enhances the ability to induce osteoblastic lesions by inhibiting osteolysis in the osteolytic PC3 model, and by stimulating osteoformation in the mixed PC3c model (osteolytic and osteoblastic). This ectopic expression of the fusion also increases osteomimicry in both cell models, meaning the acquisition of a bone-cell-like phenotype which gives them advantages of survival and spread in the bone marrow. In addition, three new TMPRSS2:ERG target genes have been described: ET-1 (Endothelin-1), stimulating osteoblastic differentiation and inhibiting osteoclastic bone resorption, ALPL (Alkaline Phosphatase Liver/Bone/Kidney), a marker of the osteoblasts differentiation, and COL1A1 (Collagen Type 1 Alpha 1), a component of the bone matrix, providing novel insights into the role of the fusion gene in the formation of osteoblastic metastases of prostate cancer.In addition, two other genes have been studied, encoding either a protein involved in the stabilization of particular structures called invadopodia, or a protein involved in lipid metabolism.All these results contribute to decipher the mechanisms of cancerization and metastatic progression of prostate cancer, in particular the influence of the expression of TMPRSS2:ERG fusion gene in prostate cancer bone metastases.

Fusion des gènes

Métastases osseuses

Cancer de la prostate

TMPRSSE:ERG

Prostate cancers

Bone metastases

Fusion gene

TMPRSS2:ERG