Abstract
Simple SummaryGlioblastoma (GBM) resistance to standard treatment is driven by stem-like cell behavior and epithelial-like-mesenchymal transition. The main purpose of this paper was to functionally validate a novel discovered pharmacological strategy to treat GBM, the dual mTOR pathway inhibitor Rapalink-1 (RL1) using relevant stem cell models of the disease to unravel mechanistic insights. Our approach also interrogates combination studies with clinical treatment options of tumor treating fields (TTFields) and the best standard of care chemotherapy, temozolomide (TMZ). We provided clinical relevance of our experimental work through in silico evaluation on molecular data of diverse patient samples. RL1 effectively impaired motility and clonogenicity of GBM stem cells and reduced the expression of stem cell molecules. We elucidated a synergistic therapeutic potential of the inhibitor with TTFields to minimize therapy resistance toward TMZ, which supports its consideration for further translational oriented studies.Glioblastoma (GBM) is a lethal disease with limited clinical treatment options available. Recently, a new inhibitor targeting the prominent cancer signaling pathway mTOR was discovered (Rapalink-1), but its therapeutic potential on stem cell populations of GBM is unknown. We applied a collection of physiological relevant organoid-like stem cell models of GBM and studied the effect of RL1 exposure on various cellular features as well as on the expression of mTOR signaling targets and stem cell molecules. We also undertook combination treatments with this agent and clinical GBM treatments tumor treating fields (TTFields) and the standard-of-care drug temozolomide, TMZ. Low nanomolar (nM) RL1 treatment significantly reduced cell growth, proliferation, migration, and clonogenic potential of our stem cell models. It acted synergistically to reduce cell growth when applied in combination with TMZ and TTFields. We performed an in silico analysis from the molecular data of diverse patient samples to probe for a relationship between the expression of mTOR genes, and mesenchymal markers in different GBM cohorts. We supported the in silico results with correlative protein data retrieved from tumor specimens. Our study further validates mTOR signaling as a druggable target in GBM and supports RL1, representing a promising therapeutic target in brain oncology.
Highlights
Glioblastoma (GBM) is a fatal disease that can occur at any age, with a worse prognosis in older patients
Our results clearly demonstrated the potency of this drug candidate to be able block stem cell markers and properties including migration and clonogenicity in GBM
We identified a tendency of direct correlation between the expression of the Mammalian Target of Rapamycin (mTOR)
Summary
Glioblastoma (GBM) is a fatal disease that can occur at any age, with a worse prognosis in older patients. Sub classification of GBM into transcriptomic or epigenetic subtypes, associated with different gene activation signatures and clinical features have been described [10]; namely, proneural (PN), neural (NE), mesenchymal (MES), and classical (CL). Despite this progress in clinical diagnostics, adequate advances on the therapeutic side, targeting molecular features of the disease, are lagging behind. The available knowledge as to its therapeutic potential in combination with other treatment regimens, or its potential to attack GSC/EMT is not fully known. TTFields system in our experimental design, we believe our results are of interest for translational oriented research community of neuro oncology and beyond
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