Abstract
Abstract Disclosure: D. Zhang: None. M. Bergsneider: None. W. Kim: None. M.B. Wang: None. H. Vinters: None. A.P. Heaney: None. Clinically non-functioning pituitary tumors (CNFTs) account for one-third of all pituitary adenomas. They do not cause clinical and/or biochemical evidence of tumor-related hormone hypersecretion, grow insidiously and typically present with mass effect symptoms such as headache and visual field deficits. Surgical resection is the current standard of care for CNFTs but complete resection is infrequently achieved due to their size and invariable invasion of locally adjacent structures. CNFT remnant tumor regrowth rates approach 50% and these patients may need repeat surgery and/or radiotherapy (RT). The latter is quite effective in achieving tumor control, but carries a risk of hypopituitarism of ∼ 40% at 10 years. Although dopamine agonists and somatostatin receptor ligands have been explored as medical therapy, there are currently no consistently effective medical treatments for CNFTs. There is a clear unmet need for novel safe and effective medical therapies for these comparatively common tumors. In a highly innovative approach we have used patient-derived ex vivo 3D tumoroid human CNFTs in an automated high throughput compound screen (HTS) to identify novel tumoricidal and growth inhibitory compounds for CNFTs. To date, we have screened ∼4,000 compounds and have identified 13 potential hits that inhibited tumor cell proliferation (a reduction of 76±15%) and induced apoptosis (induction rate of 8.2 ± 6.6) in the CNFT tumoroids respectively. The hit compounds to date fall into 3 categories based on their targets, namely Na+/K+-ATPase inhibitors (n=6), reactive oxygen species (ROS) regulators (n=4), and cell cycle inhibitors (n=3). Representative “hit” compounds from each group identified in our primary screen were rescreened in triplicate in 20 concentrations from 25µM to 50pM at 2-fold dilutions. Dose-response curves characterized compound doses that inhibited cell viability by 50% (IC50) and ranged from 13nM to 103nM. Two of these 3 compounds also induced 2-3-fold apoptosis at 0.1uM with the final compound displaying a potent 5-10-fold pro-apoptotic effect at 0.15uM concentration. In parallel, we used single cell RNA sequencing to validate targets that emerged from our HTS and to characterize the mechanism of action (MOA) of these hit compounds. As proof of concept, several of the known drug targets were noted to be amongst the highest differentially expressed genes in the CNFT tumor cell population. This approach validating a candidate target in conjunction with demonstrable activity of a drug for that same target in CNFTs may simultaneously provide us with a back-bone molecule to further develop with structural activity relationship analysis and/or allow us to individualize drug choice in patients based on immunocytochemical tumor target expression. Presentation: 6/1/2024
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