Your search keyword '"Guanglong Jiang"' showing total 3 results

1. Comprehensive comparison of molecular portraits between cell lines and tumors in breast cancer.

Author

Guanglong Jiang, Shijun Zhang, Yazdanparast, Aida, Meng Li, Vikram Pawar, Aniruddha, Yunlong Liu, Mounika Inavolu, Sai, and Lijun Cheng

Subjects

*BREAST cancer, *TUMORS, *CANCER research, *CELL lines, *PROTEIN expression

Abstract

Background: Proper cell models for breast cancer primary tumors have long been the focal point in the cancer's research. The genomic comparison between cell lines and tumors can investigate the similarity and dissimilarity and help to select right cell model to mimic tumor tissues to properly evaluate the drug reaction in vitro. In this paper, a comprehensive comparison in copy number variation (CNV), mutation, mRNA expression and protein expression between 68 breast cancer cell lines and 1375 primary breast tumors is conducted and presented. Results: Using whole genome expression arrays, strong correlations were observed between cells and tumors. PAM50 gene expression differentiated them into four major breast cancer subtypes: Luminal A and B, HER2amp, and Basal-like in both cells and tumors partially. Genomic CNVs patterns were observed between tumors and cells across chromosomes in general. High C > T and C > G trans-version rates were observed in both cells and tumors, while the cells had slightly higher somatic mutation rates than tumors. Clustering analysis on protein expression data can reasonably recover the breast cancer subtypes in cell lines and tumors. Although the drug-targeted proteins ER/PR and interesting mTOR/GSK3/TS2/PDK1/ER_P118 cluster had shown the consistent patterns between cells and tumor, low protein-based correlations were observed between cells and tumors. The expression consistency of mRNA verse protein between cell line and tumors reaches 0.7076. These important drug targets in breast cancer, ESR1, PGR, HER2, EGFR and AR have a high similarity in mRNA and protein variation in both tumors and cell lines. GATA3 and RP56KB1 are two promising drug targets for breast cancer. A total score developed from the four correlations among four molecular profiles suggests that cell lines, BT483, T47D and MDAMB453 have the highest similarity with tumors. Conclusions: The integrated data from across these multiple platforms demonstrates the existence of the similarity and dissimilarity of molecular features between breast cancer tumors and cell lines. The cell lines only mirror some but not all of the molecular properties of primary tumors. The study results add more evidence in selecting cell line models for breast cancer research. [ABSTRACT FROM AUTHOR]

Published

2016

2. Simultaneous inferences based on empirical Bayes methods and false discovery rates ineQTL data analysis.

Author

Chakraborty, Arindom, Guanglong Jiang, Boustani, Malaz, Yunlong Liu, Todd Skaar, and Lang Li

Subjects

*EMPIRICAL Bayes methods, *FALSE discovery rate, *GENE mapping, *SINGLE nucleotide polymorphisms, *GENE expression

Abstract

Background: Genome-wide association studies (GWAS) have identified hundreds of genetic variants associated with complex human diseases, clinical conditions and traits. Genetic mapping of expression quantitative trait loci (eQTLs) is providing us with novel functional effects of thousands of single nucleotide polymorphisms (SNPs). In a classical quantitative trail loci (QTL) mapping problem multiple tests are done to assess whether one trait is associated with a number of loci. In contrast to QTL studies, thousands of traits are measured alongwith thousands of gene expressions in an eQTL study. For such a study, a huge number of tests have to be performed (~ 106). This extreme multiplicity gives rise to many computational and statistical problems. In this paper we have tried to address these issues using two closely related inferential approaches: an empirical Bayes method that bears the Bayesian flavor without having much a priori knowledge and the frequentist method of false discovery rates. A three-component t-mixture model has been used for the parametric empirical Bayes (PEB) method. Inferences have been obtained using Expectation/Conditional Maximization Either (ECME) algorithm. A simulation study has also been performed and has been compared with a nonparametric empirical Bayes (NPEB) alternative. Results: The results show that PEB has an edge over NPEB. The proposed methodology has been applied to human liver cohort (LHC) data. Our method enables to discover more significant SNPs with FDR<10% compared to the previous study done by Yang et al. (Genome Research, 2010). Conclusions: In contrast to previously available methods based on p-values, the empirical Bayes method uses local false discovery rate (lfdr) as the threshold. This method controls false positive rate. [ABSTRACT FROM AUTHOR]

Published

2013

3. A modulator based regulatory network for ERa signaling pathway.

Author

Heng-Yi Wu, Pengyue Zheng, Guanglong Jiang, Yunlong Liu, Nephew, Kenneth P., Tim HM Huang, and Lang Li

Subjects

ESTROGEN receptors, CANCER cells, GENE expression, CELL culture, STEROID hormones

Abstract

Background: Estrogens control multiple functions of hormone-responsive breast cancer cells. They regulate diverse physiological processes in various tissues through genomic and non-genomic mechanisms that result in activation or repression of gene expression. Transcription regulation upon estrogen stimulation is a critical biological process underlying the onset and progress of the majority of breast cancer. ERa requires distinct co-regulator or modulators for efficient transcriptional regulation, and they form a regulatory network. Knowing this regulatory network will enable systematic study of the effect of ERa on breast cancer. Methods: To investigate the regulatory network of ERa and discover novel modulators of ERa functions, we proposed an analytical method based on a linear regression model to identify translational modulators and their network relationships. In the network analysis, a group of specific modulator and target genes were selected according to the functionality of modulator and the ERa binding. Network formed from targets genes with ERa binding was called ERa genomic regulatory network; while network formed from targets genes without ERa binding was called ERa non-genomic regulatory network. Considering the active or repressive function of ERa, active or repressive function of a modulator, and agonist or antagonist effect of a modulator on ERa, the ERa/modulator/target relationships were categorized into 27 classes. Results: Using the gene expression data and ERa Chip-seq data from the MCF-7 cell line, the ERa genomic/nongenomic regulatory networks were built by merging ERa/ modulator/target triplets (TF, M, T), where TF refers to the ERa, M refers to the modulator, and T refers to the target. Comparing these two networks, ERa non-genomic network has lower FDR than the genomic network. In order to validate these two networks, the same network analysis was performed in the gene expression data from the ZR-75.1 cell. The network overlap analysis between two cancer cells showed 1% overlap for the ERa genomic regulatory network, but 4% overlap for the non-genomic regulatory network. Conclusions: We proposed a novel approach to infer the ERa/modulator/target relationships, and construct the genomic/non-genomic regulatory networks in two cancer cells. We found that the non-genomic regulatory network is more reliable than the genomic regulatory network. [ABSTRACT FROM AUTHOR]

Published

2012