Your search keyword '"Kasey R. Skinner"' showing total 2 results

1. ARID1A-deficient bladder cancer is dependent on PI3K signaling and sensitive to EZH2 and PI3K inhibitors

Author

Hasibur Rehman, Darshan S. Chandrashekar, Chakravarthi Balabhadrapatruni, Saroj Nepal, Sai Akshaya Hodigere Balasubramanya, Abigail K. Shelton, Kasey R. Skinner, Ai-Hong Ma, Ting Rao, Sumit Agarwal, Marie-Lisa Eich, Alyncia D. Robinson, Gurudatta Naik, Upender Manne, George J. Netto, C. Ryan Miller, Chong-xian Pan, Guru Sonpavde, Sooryanarayana Varambally, and James E. Ferguson III

Subjects

Oncology, Medicine

Abstract

Metastatic urothelial carcinoma is generally incurable with current systemic therapies. Chromatin modifiers are frequently mutated in bladder cancer, with ARID1A-inactivating mutations present in about 20% of tumors. EZH2, a histone methyltransferase, acts as an oncogene that functionally opposes ARID1A. In addition, PI3K signaling is activated in more than 20% of bladder cancers. Using a combination of in vitro and in vivo data, including patient-derived xenografts, we show that ARID1A-mutant tumors were more sensitive to EZH2 inhibition than ARID1A WT tumors. Mechanistic studies revealed that (a) ARID1A deficiency results in a dependency on PI3K/AKT/mTOR signaling via upregulation of a noncanonical PI3K regulatory subunit, PIK3R3, and downregulation of MAPK signaling and (b) EZH2 inhibitor sensitivity is due to upregulation of PIK3IP1, a protein inhibitor of PI3K signaling. We show that PIK3IP1 inhibited PI3K signaling by inducing proteasomal degradation of PIK3R3. Furthermore, ARID1A-deficient bladder cancer was sensitive to combination therapies with EZH2 and PI3K inhibitors in a synergistic manner. Thus, our studies suggest that bladder cancers with ARID1A mutations can be treated with inhibitors of EZH2 and/or PI3K and revealed mechanistic insights into the role of noncanonical PI3K constituents in bladder cancer biology.

Published

2022

2. PIK3CA missense mutations promote glioblastoma pathogenesis, but do not enhance targeted PI3K inhibition.

Author

Robert S McNeill, Emily E Stroobant, Erin Smithberger, Demitra A Canoutas, Madison K Butler, Abigail K Shelton, Shrey D Patel, Juanita C Limas, Kasey R Skinner, Ryan E Bash, Ralf S Schmid, and C Ryan Miller

Subjects

Medicine, Science

Abstract

BackgroundGlioblastoma (GBM) is the most common adult primary brain tumor. Multimodal treatment is empiric and prognosis remains poor. Recurrent PIK3CA missense mutations (PIK3CAmut) in GBM are restricted to three functional domains: adaptor binding (ABD), helical, and kinase. Defining how these mutations influence gliomagenesis and response to kinase inhibitors may aid in the clinical development of novel targeted therapies in biomarker-stratified patients.MethodsWe used normal human astrocytes immortalized via expression of hTERT, E6, and E7 (NHA). We selected two PIK3CAmut from each of 3 mutated domains and induced their expression in NHA with (NHARAS) and without mutant RAS using lentiviral vectors. We then examined the role of PIK3CAmut in gliomagenesis in vitro and in mice, as well as response to targeted PI3K (PI3Ki) and MEK (MEKi) inhibitors in vitro.ResultsPIK3CAmut, particularly helical and kinase domain mutations, potentiated proximal PI3K signaling and migration of NHA and NHARAS in vitro. Only kinase domain mutations promoted NHA colony formation, but both helical and kinase domain mutations promoted NHARAS tumorigenesis in vivo. PIK3CAmut status had minimal effects on PI3Ki and MEKi efficacy. However, PI3Ki/MEKi synergism was pronounced in NHA and NHARAS harboring ABD or helical mutations.ConclusionPIK3CAmut promoted differential gliomagenesis based on the mutated domain. While PIK3CAmut did not influence sensitivity to single agent PI3Ki, they did alter PI3Ki/MEKi synergism. Taken together, our results demonstrate that a subset of PIK3CAmut promote tumorigenesis and suggest that patients with helical domain mutations may be most sensitive to dual PI3Ki/MEKi treatment.

Published

2018