Bladder-cancer-associated mutations in RXRA activate peroxisome proliferator-activated receptors to drive urothelial proliferation

Angela M. Halstead; Chiraag D. Kapadia; Jennifer Bolzenius; Clarence E. Chu; Andrew Schriefer; Lukas D. Wartman; Gregory R. Bowman; Vivek K. Arora

doi:10.7554/eLife.30862

Bladder-cancer-associated mutations in RXRA activate peroxisome proliferator-activated receptors to drive urothelial proliferation

Angela M. Halstead, Chiraag D. Kapadia, Jennifer Bolzenius, Clarence E. Chu, Andrew Schriefer, Lukas D. Wartman, Gregory R. Bowman, Vivek K. Arora

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38 Scopus citations

Abstract

RXRA regulates transcription as part of a heterodimer with 14 other nuclear receptors, including the peroxisome proliferator-activated receptors (PPARs). Analysis from TCGA raised the possibility that hyperactive PPAR signaling, either due to PPAR gamma gene amplification or RXRA hot-spot mutation (S427F/Y) drives 20–25% of human bladder cancers. Here, we characterize mutant RXRA, demonstrating it induces enhancer/promoter activity in the context of RXRA/PPAR heterodimers in human bladder cancer cells. Structure-function studies indicate that the RXRA substitution allosterically regulates the PPAR AF2 domain via an aromatic interaction with the terminal tyrosine found in PPARs. In mouse urothelial organoids, PPAR agonism is sufficient to drive growth-factor-independent growth in the context of concurrent tumor suppressor loss. Similarly, mutant RXRA stimulates growth-factor-independent growth of Trp53/Kdm6a null bladder organoids. Mutant RXRA-driven growth of urothelium is reversible by PPAR inhibition, supporting PPARs as targetable drivers of bladder cancer.

Original language	English
Article number	e30862
Journal	eLife
Volume	6
DOIs	https://doi.org/10.7554/eLife.30862
State	Published - Nov 16 2017

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title = "Bladder-cancer-associated mutations in RXRA activate peroxisome proliferator-activated receptors to drive urothelial proliferation",

abstract = "RXRA regulates transcription as part of a heterodimer with 14 other nuclear receptors, including the peroxisome proliferator-activated receptors (PPARs). Analysis from TCGA raised the possibility that hyperactive PPAR signaling, either due to PPAR gamma gene amplification or RXRA hot-spot mutation (S427F/Y) drives 20–25% of human bladder cancers. Here, we characterize mutant RXRA, demonstrating it induces enhancer/promoter activity in the context of RXRA/PPAR heterodimers in human bladder cancer cells. Structure-function studies indicate that the RXRA substitution allosterically regulates the PPAR AF2 domain via an aromatic interaction with the terminal tyrosine found in PPARs. In mouse urothelial organoids, PPAR agonism is sufficient to drive growth-factor-independent growth in the context of concurrent tumor suppressor loss. Similarly, mutant RXRA stimulates growth-factor-independent growth of Trp53/Kdm6a null bladder organoids. Mutant RXRA-driven growth of urothelium is reversible by PPAR inhibition, supporting PPARs as targetable drivers of bladder cancer.",

author = "Halstead, {Angela M.} and Kapadia, {Chiraag D.} and Jennifer Bolzenius and Chu, {Clarence E.} and Andrew Schriefer and Wartman, {Lukas D.} and Bowman, {Gregory R.} and Arora, {Vivek K.}",

note = "Funding Information: Damon Runyon Cancer Research Foundation Clinical Investigator Vivek K Arora Cancer Research Foundation Young Investigator Vivek K Arora National Cancer Institute T32 CA113275 Angela M Halstead National Center for Advancing Translational Sciences UL1TR000448 Vivek K Arora National Cancer Institute P30 CA91842 Andrew Schriefer National Institute of Diabetes and Digestive and Kidney Diseases U54DK104279 Chiraag D Kapadia Publisher Copyright: {\textcopyright} Halstead et al.",

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doi = "10.7554/eLife.30862",

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AU - Halstead, Angela M.

AU - Kapadia, Chiraag D.

AU - Bolzenius, Jennifer

AU - Chu, Clarence E.

AU - Schriefer, Andrew

AU - Wartman, Lukas D.

AU - Bowman, Gregory R.

AU - Arora, Vivek K.

N1 - Funding Information: Damon Runyon Cancer Research Foundation Clinical Investigator Vivek K Arora Cancer Research Foundation Young Investigator Vivek K Arora National Cancer Institute T32 CA113275 Angela M Halstead National Center for Advancing Translational Sciences UL1TR000448 Vivek K Arora National Cancer Institute P30 CA91842 Andrew Schriefer National Institute of Diabetes and Digestive and Kidney Diseases U54DK104279 Chiraag D Kapadia Publisher Copyright: © Halstead et al.

PY - 2017/11/16

Y1 - 2017/11/16

N2 - RXRA regulates transcription as part of a heterodimer with 14 other nuclear receptors, including the peroxisome proliferator-activated receptors (PPARs). Analysis from TCGA raised the possibility that hyperactive PPAR signaling, either due to PPAR gamma gene amplification or RXRA hot-spot mutation (S427F/Y) drives 20–25% of human bladder cancers. Here, we characterize mutant RXRA, demonstrating it induces enhancer/promoter activity in the context of RXRA/PPAR heterodimers in human bladder cancer cells. Structure-function studies indicate that the RXRA substitution allosterically regulates the PPAR AF2 domain via an aromatic interaction with the terminal tyrosine found in PPARs. In mouse urothelial organoids, PPAR agonism is sufficient to drive growth-factor-independent growth in the context of concurrent tumor suppressor loss. Similarly, mutant RXRA stimulates growth-factor-independent growth of Trp53/Kdm6a null bladder organoids. Mutant RXRA-driven growth of urothelium is reversible by PPAR inhibition, supporting PPARs as targetable drivers of bladder cancer.

AB - RXRA regulates transcription as part of a heterodimer with 14 other nuclear receptors, including the peroxisome proliferator-activated receptors (PPARs). Analysis from TCGA raised the possibility that hyperactive PPAR signaling, either due to PPAR gamma gene amplification or RXRA hot-spot mutation (S427F/Y) drives 20–25% of human bladder cancers. Here, we characterize mutant RXRA, demonstrating it induces enhancer/promoter activity in the context of RXRA/PPAR heterodimers in human bladder cancer cells. Structure-function studies indicate that the RXRA substitution allosterically regulates the PPAR AF2 domain via an aromatic interaction with the terminal tyrosine found in PPARs. In mouse urothelial organoids, PPAR agonism is sufficient to drive growth-factor-independent growth in the context of concurrent tumor suppressor loss. Similarly, mutant RXRA stimulates growth-factor-independent growth of Trp53/Kdm6a null bladder organoids. Mutant RXRA-driven growth of urothelium is reversible by PPAR inhibition, supporting PPARs as targetable drivers of bladder cancer.

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Bladder-cancer-associated mutations in RXRA activate peroxisome proliferator-activated receptors to drive urothelial proliferation

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