Your search keyword '"Scott, Kenneth L"' showing total 5 results

1. Cancer driver mutation prediction through Bayesian integration of multi-omic data.

Author

Wang, Zixing, Ng, Kwok-Shing, Chen, Tenghui, Kim, Tae-Beom, Wang, Fang, Shaw, Kenna, Scott, Kenneth L., Meric-Bernstam, Funda, Mills, Gordon B., and Chen, Ken

Subjects

GENETIC mutation, CANCER diagnosis, CANCER genetics, GENE expression, BAYESIAN analysis

Abstract

Identification of cancer driver mutations is critical for advancing cancer research and personalized medicine. Due to inter-tumor genetic heterogeneity, many driver mutations occur at low frequencies, which make it challenging to distinguish them from passenger mutations. Here, we show that a novel Bayesian hierarchical modeling approach, named rDriver can achieve enhanced prediction accuracy by identifying mutations that not only have high functional impact scores but also are associated with systemic variation in gene expression levels. In examining 3,080 tumor samples from 8 cancer types in The Cancer Genome Atlas, rDriver predicted 1,389 driver mutations. Compared with existing tools, rDriver identified more low frequency mutations associated with lineage specific functional properties, timing of occurrence and patient survival. Evaluation of rDriver predictions using engineered cell-line models resulted in a positive predictive value of 0.94 in PIK3CA genes. Our study highlights the importance of integrating multi-omic data in predicting cancer driver mutations and provides a statistically rigorous solution for cancer target discovery and development. [ABSTRACT FROM AUTHOR]

Published

2018

2. Integrative Genome Comparison of Primary and Metastatic Melanomas

Author

Kabbarah, Omar, Nogueira, Cristina, Feng, Bin, Bosenberg, Marcus, Scott, Kenneth L., Xiao, Yonghong, Cordon-Cardo, Carlos, Wagner, Stephan N., Brennan, Cameron, Nazarian, Rosalynn, Wu, Min, Kwong, Lawrence Noc-Woon, Granter, Scott R., Ramaswamy, Sridhar, Golub, Todd R., Duncan, Lyn M., and Chin, Lynda

Subjects

cancer genetics, comparative genomics, genomics, genetics

Abstract

A cardinal feature of malignant melanoma is its metastatic propensity. An incomplete view of the genetic events driving metastatic progression has been a major barrier to rational development of effective therapeutics and prognostic diagnostics for melanoma patients. In this study, we conducted global genomic characterization of primary and metastatic melanomas to examine the genomic landscape associated with metastatic progression. In addition to uncovering three genomic subclasses of metastastic melanomas, we delineated 39 focal and recurrent regions of amplification and deletions, many of which encompassed resident genes that have not been implicated in cancer or metastasis. To identify progression-associated metastasis gene candidates, we applied a statistical approach, Integrative Genome Comparison (IGC), to define 32 genomic regions of interest that were significantly altered in metastatic relative to primary melanomas, encompassing 30 resident genes with statistically significant expression deregulation. Functional assays on a subset of these candidates, including MET, ASPM, AKAP9, IMP3, PRKCA, RPA3, and SCAP2, validated their pro-invasion activities in human melanoma cells. Validity of the IGC approach was further reinforced by tissue microarray analysis of Survivin showing significant increased protein expression in thick versus thin primary cutaneous melanomas, and a progression correlation with lymph node metastases. Together, these functional validation results and correlative analysis of human tissues support the thesis that integrated genomic and pathological analyses of staged melanomas provide a productive entry point for discovery of melanoma metastases genes.

Published

2010

3. Engineering and Functional Characterization of Fusion Genes Identifies Novel Oncogenic Drivers of Cancer.

Author

Hengyu Lu, Villafane, Nicole, Dogruluk, Turgut, Grzeskowiak, Caitlin L., Kong, Kathleen, Yiu Huen Tsang, Zagorodna, Oksana, Pantazi, Angeliki, Lixing Yang, Neill, Nicholas J., Young Won Kim, Creighton, Chad J., Verhaak, Roel G., Mills, Gordon B., Park, Peter J., Kucherlapati, Raju, and Scott, Kenneth L.

Subjects

*CANCER genetics, *ONCOGENES, *GENETIC engineering, *GENETIC mutation, *INDIVIDUALIZED medicine

Abstract

Oncogenic gene fusions drive many human cancers, but tools to more quickly unravel their functional contributions are needed. Here we describe methodology permitting fusion gene construction for functional evaluation. Using this strategy, we engineered the known fusion oncogenes, BCR-ABL1, EML4-ALK, and ETV6-NTRK3, as well as 20 previously uncharacterized fusion genes identified in The Cancer Genome Atlas datasets. In addition to confirming oncogenic activity of the known fusion oncogenes engineered by our construction strategy, we validated five novel fusion genes involving MET, NTRK2, and BRAF kinases that exhibited potent transforming activity and conferred sensitivity to FDA-approved kinase inhibitors. Our fusion construction strategy also enabled domain-function studies of BRAF fusion genes. Our results confirmed other reports that the transforming activity of BRAF fusions results from truncation-mediated loss of inhibitory domains within the N-terminus of the BRAF protein. BRAF mutations residing within this inhibitory region may provide a means for BRAF activation in cancer, therefore we leveraged the modular design of our fusion gene construction methodology to screen N-terminal domain mutations discovered in tumors that are wild-type at the BRAF mutation hotspot, V600. We identified an oncogenic mutation, F247L, whose expression robustly activated the MAPK pathway and sensitized cells to BRAF and MEK inhibitors. When applied broadly, these tools will facilitate rapid fusion gene construction for subsequent functional characterization and translation into personalized treatment strategies. [ABSTRACT FROM AUTHOR]

Published

2017

4. Identification of Variant-Specific Functions of PIK3CA by Rapid Phenotyping of Rare Mutations.

Author

Dogruluk, Turgut, Yiu Huen Tsang, Espitia, Maribel, Fengju Chen, Tenghui Chen, Zechen Chong, Appadurai, Vivek, Dogruluk, Armel, Eterovic, Agna Karina, Bonnen, Penelope E., Creighton, Chad J., Ken Chen, Mills, Gordon B., and Scott, Kenneth L.

Subjects

*CANCER genetics, *HUMAN phenotype, *CANCER invasiveness, *GENE expression, *PHOSPHATIDYLINOSITOLS

Abstract

Large-scale sequencing efforts are uncovering the complexity of cancer genomes, which are composed of causal "driver" mutations that promote tumor progression along with many more pathologically neutral "passenger" events. The majority of mutations, both in known cancer drivers and uncharacterized genes, are generally of low occurrence, highlighting the need to functionally annotate the long tail of infrequent mutations present in heterogeneous cancers. Here we describe a mutation assessment pipeline enabled by high-throughput engineering of molecularly barcoded gene variant expression clones identified by tumor sequencing. We first used this platform to functionally assess tail mutations observed in PIK3CA, which encodes the catalytic subunit alpha of the phosphatidylinositol-4,5-bisphosphate 3-kinase (PI3K) frequently mutated in cancer. Orthogonal screening for PIK3CA variant activity using in vitro and in vivo cell growth and transformation assays differentiated driver from passenger mutations, revealing that PIK3CA variant activity correlates imperfectly with its mutation frequency across breast cancer populations. Although PIK3CA mutations with frequencies above 5% were significantly more oncogenic than wild-type in all assays, mutations occurring at 0.07% to 5.0% included those with and without oncogenic activities that ranged from weak to strong in at least one assay. Proteomic profiling coupled with therapeutic sensitivity assays on PIK3CA variant-expressing cell models revealed variantspecific activation of PI3K signaling as well as other pathways that include the MEK1/2 module of mitogen-activated protein kinase pathway. Our data indicate that cancer treatments will need to increasingly consider the functional relevance of specific mutations in driver genes rather than considering all mutations in drivers as equivalent. [ABSTRACT FROM AUTHOR]

Published

2015

5. A-to-I RNA Editing Contributes to Proteomic Diversity in Cancer.

Author

Peng, Xinxin, Xu, Xiaoyan, Wang, Yumeng, Hawke, David H., Yu, Shuangxing, Han, Leng, Zhou, Zhicheng, Mojumdar, Kamalika, Jeong, Kang Jin, Labrie, Marilyne, Tsang, Yiu Huen, Zhang, Minying, Lu, Yiling, Hwu, Patrick, Scott, Kenneth L., Liang, Han, and Mills, Gordon B.

Subjects

*RNA editing, *CANCER genetics, *ADENOSINES, *INOSINE, *AMINO acid sequence, *CANCER cell migration

Abstract

Summary Adenosine (A) to inosine (I) RNA editing introduces many nucleotide changes in cancer transcriptomes. However, due to the complexity of post-transcriptional regulation, the contribution of RNA editing to proteomic diversity in human cancers remains unclear. Here, we performed an integrated analysis of TCGA genomic data and CPTAC proteomic data. Despite limited site diversity, we demonstrate that A-to-I RNA editing contributes to proteomic diversity in breast cancer through changes in amino acid sequences. We validate the presence of editing events at both RNA and protein levels. The edited COPA protein increases proliferation, migration, and invasion of cancer cells in vitro . Our study suggests an important contribution of A-to-I RNA editing to protein diversity in cancer and highlights its translational potential. [ABSTRACT FROM AUTHOR]

Published

2018