Your search keyword '"C. Ryan Miller"' showing total 7 results

1. Trans-lesion synthesis and mismatch repair pathway crosstalk defines chemoresistance and hypermutation mechanisms in glioblastoma

Author

Xing Cheng, Jing An, Jitong Lou, Qisheng Gu, Weimin Ding, Gaith Nabil Droby, Yilin Wang, Chenghao Wang, Yanzhe Gao, Jay Ramanlal Anand, Abigail Shelton, Andrew Benson Satterlee, Breanna Mann, Yun-Chung Hsiao, Chih-Wei Liu, Kun Lu, Shawn Hingtgen, Jiguang Wang, Zhaoliang Liu, C. Ryan Miller, Di Wu, Cyrus Vaziri, and Yang Yang

Subjects

Science

Abstract

Abstract Almost all Glioblastoma (GBM) are either intrinsically resistant to the chemotherapeutical drug temozolomide (TMZ) or acquire therapy-induced mutations that cause chemoresistance and recurrence. The genome maintenance mechanisms responsible for GBM chemoresistance and hypermutation are unknown. We show that the E3 ubiquitin ligase RAD18 (a proximal regulator of TLS) is activated in a Mismatch repair (MMR)-dependent manner in TMZ-treated GBM cells, promoting post-replicative gap-filling and survival. An unbiased CRISPR screen provides an aerial map of RAD18-interacting DNA damage response (DDR) pathways deployed by GBM to tolerate TMZ genotoxicity. Analysis of mutation signatures from TMZ-treated GBM reveals a role for RAD18 in error-free bypass of O6mG (the most toxic TMZ-induced lesion), and error-prone bypass of other TMZ-induced lesions. Our analyses of recurrent GBM patient samples establishes a correlation between low RAD18 expression and hypermutation. Taken together we define molecular underpinnings for the hallmark tumorigenic phenotypes of TMZ-treated GBM.

Published

2024

2. Quinolinate promotes macrophage-induced immune tolerance in glioblastoma through the NMDAR/PPARγ signaling axis

Author

Pravin Kesarwani, Shiva Kant, Yi Zhao, Antony Prabhu, Katie L. Buelow, C. Ryan Miller, and Prakash Chinnaiyan

Subjects

Science

Abstract

The upstream metabolism of tryptophan has been described as a metabolic node in glioblastoma. Here the authors show that the downstream metabolism of tryptophan, resulting in the accumulation of quinolinate in glioblastoma, contributes to pro-tumorigenic immune suppressive activation of macrophages.

Published

2023

3. Author Correction: Atrx inactivation drives disease-defining phenotypes in glioma cells of origin through global epigenomic remodeling

Author

Carla Danussi, Promita Bose, Prasanna T. Parthasarathy, Pedro C. Silberman, John S. Van Arnam, Mark Vitucci, Oliver Y. Tang, Adriana Heguy, Yuxiang Wang, Timothy A. Chan, Gregory J. Riggins, Erik P. Sulman, Frederick F. Lang, Chad J. Creighton, Benjamin Deneen, C. Ryan Miller, David J. Picketts, Kasthuri Kannan, and Jason T. Huse

Subjects

Science

Published

2022

4. Atrx inactivation drives disease-defining phenotypes in glioma cells of origin through global epigenomic remodeling

Author

Carla Danussi, Promita Bose, Prasanna T. Parthasarathy, Pedro C. Silberman, John S. Van Arnam, Mark Vitucci, Oliver Y. Tang, Adriana Heguy, Yuxiang Wang, Timothy A. Chan, Gregory J. Riggins, Erik P. Sulman, Frederick Lang, Chad J. Creighton, Benjamin Deneen, C. Ryan Miller, David J. Picketts, Kasthuri Kannan, and Jason T. Huse

Subjects

Science

Abstract

ATRX inactivation frequently occurs in glioma. Here, the authors explore the role of ATRX inactivation in oncogenesis, highlighting ATRX deficiency driven epigenomic changes that influence the expression of genes crucial to the oncogenic phenotype.

Published

2018

5. Therapeutically engineered induced neural stem cells are tumour-homing and inhibit progression of glioblastoma

Author

Juli R. Bagó, Adolfo Alfonso-Pecchio, Onyi Okolie, Raluca Dumitru, Amanda Rinkenbaugh, Albert S. Baldwin, C. Ryan Miller, Scott T. Magness, and Shawn D. Hingtgen

Subjects

Science

Abstract

Neural stem cells have a tropism for glioblastoma. Here the authors employ fibroblasts directly reprogrammed into induced neural stem cells and loaded with cytotoxic molecules to migrate to xenotransplanted brain tumours in mice, achieving tumour shrinkage and prolonged survival.

Published

2016

6. Atrx inactivation drives disease-defining phenotypes in glioma cells of origin through global epigenomic remodeling

Author

Frederick Lang, Promita Bose, Mark Vitucci, Timothy A. Chan, Carla Danussi, Gregory J. Riggins, Chad J. Creighton, Yuxiang Wang, Erik P. Sulman, Oliver Y. Tang, Kasthuri Kannan, Adriana Heguy, David J. Picketts, Benjamin Deneen, Pedro Silberman, John S. Van Arnam, Prasanna Tamarapu Parthasarathy, C. Ryan Miller, and Jason T. Huse

Subjects

0301 basic medicine, Genome instability, X-linked Nuclear Protein, Science, Cellular differentiation, Neuroepithelial Cells, General Physics and Astronomy, GTP-Binding Protein alpha Subunits, G12-G13, Article, General Biochemistry, Genetics and Molecular Biology, Cell Line, 03 medical and health sciences, Neural Stem Cells, Cell Movement, Animals, Humans, Gene silencing, Gene Silencing, lcsh:Science, Author Correction, ATRX, Epigenomics, Mice, Knockout, Multidisciplinary, biology, Cell Differentiation, Glioma, General Chemistry, Chromatin Assembly and Disassembly, Genes, p53, Phenotype, Chromatin, Cell biology, 030104 developmental biology, Histone, biology.protein, lcsh:Q, rhoA GTP-Binding Protein

Abstract

Mutational inactivation of the SWI/SNF chromatin regulator ATRX occurs frequently in gliomas, the most common primary brain tumors. Whether and how ATRX deficiency promotes oncogenesis by epigenomic dysregulation remains unclear, despite its recent implication in both genomic instability and telomere dysfunction. Here we report that Atrx loss recapitulates characteristic disease phenotypes and molecular features in putative glioma cells of origin, inducing cellular motility although also shifting differentiation state and potential toward an astrocytic rather than neuronal histiogenic profile. Moreover, Atrx deficiency drives widespread shifts in chromatin accessibility, histone composition, and transcription in a distribution almost entirely restricted to genomic sites normally bound by the protein. Finally, direct gene targets of Atrx that mediate specific Atrx-deficient phenotypes in vitro exhibit similarly selective misexpression in ATRX-mutant human gliomas. These findings demonstrate that ATRX deficiency and its epigenomic sequelae are sufficient to induce disease-defining oncogenic phenotypes in appropriate cellular and molecular contexts., ATRX inactivation frequently occurs in glioma. Here, the authors explore the role of ATRX inactivation in oncogenesis, highlighting ATRX deficiency driven epigenomic changes that influence the expression of genes crucial to the oncogenic phenotype.

Published

2018

7. Therapeutically engineered induced neural stem cells are tumour-homing and inhibit progression of glioblastoma

Author

Scott T. Magness, C. Ryan Miller, Albert S. Baldwin, Onyi Okolie, Adolfo Alfonso-Pecchio, Juli R. Bagó, Amanda L. Rinkenbaugh, Raluca Dumitru, and Shawn Hingtgen

Subjects

0301 basic medicine, Multidisciplinary, Somatic cell, business.industry, Science, Cellular differentiation, Transdifferentiation, General Physics and Astronomy, General Chemistry, Article, General Biochemistry, Genetics and Molecular Biology, Neural stem cell, 3. Good health, Cell therapy, 03 medical and health sciences, 030104 developmental biology, Cancer research, Medicine, Induced pluripotent stem cell, business, Reprogramming, Homing (hematopoietic)

Abstract

Transdifferentiation (TD) is a recent advancement in somatic cell reprogramming. The direct conversion of TD eliminates the pluripotent intermediate state to create cells that are ideal for personalized cell therapy. Here we provide evidence that TD-derived induced neural stem cells (iNSCs) are an efficacious therapeutic strategy for brain cancer. We find that iNSCs genetically engineered with optical reporters and tumouricidal gene products retain the capacity to differentiate and induced apoptosis in co-cultured human glioblastoma cells. Time-lapse imaging shows that iNSCs are tumouritropic, homing rapidly to co-cultured glioblastoma cells and migrating extensively to distant tumour foci in the murine brain. Multimodality imaging reveals that iNSC delivery of the anticancer molecule TRAIL decreases the growth of established solid and diffuse patient-derived orthotopic glioblastoma xenografts 230- and 20-fold, respectively, while significantly prolonging the median mouse survival. These findings establish a strategy for creating autologous cell-based therapies to treat patients with aggressive forms of brain cancer., Neural stem cells have a tropism for glioblastoma. Here the authors employ fibroblasts directly reprogrammed into induced neural stem cells and loaded with cytotoxic molecules to migrate to xenotransplanted brain tumours in mice, achieving tumour shrinkage and prolonged survival.

Published

2016