Distinct co-expression networks using multi-omic data reveal novel interventional targets in HPV-positive and negative head-and-neck squamous cell cancer

Costa, Raquel L.; Boroni, Mariana; Soares, Marcelo A.

doi:10.1101/236133

Cited by 3 publications

(6 citation statements)

References 70 publications

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“…This gene is downregulated in HPV induced tumors. SPRR2G shows downregulation in HPV-positive cases as compared with HPVnegative cases (Costa et al, 2018).…”

Section: Small Proline-rich Protein 2g (Sprr2g)mentioning

confidence: 86%

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Human papillomavirus elevated genetic biomarker signature by statistical algorithm

Tripathi

Keshari

Shahi

et al. 2020

Journal Cellular Physiology

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Head and neck squamous cell carcinoma (HNSCC) is the one of the most frequently found cancers in the world. The aim of the study was to find the genes responsible and enriched pathways associated with HNSCC using bioinformatics and survival analysis methods. A total of 646 patients with HNSCC based on clinical information were considered for the study. HNSCC samples were grouped according to the parameters (RFS, DFS, PFS, or OS). The probe ID of these 11 genes was retrieved by Affymetrix using the NetAffx Query algorithm. The protein–protein interaction (PPI) network and Kaplan–Meier curve were used to find associations among the genes' expression data. We found that among these 11 genes, nine genes, CCNA1, MMP3, FLRT3, GJB6, ZFR2, PITX2, SYCP2, MEI1, and UGT8 were significant (p < .05). A survival plot was drawn between the p value and gene expression. This study helped us find the nine significant genes which play vital roles in HNSCC along with their key pathways and their interaction with other genes in the PPI network. Finally, we found the biomarker index for relapse time and risk factors for HNSCC in cancer patients.

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“…This gene is downregulated in HPV induced tumors. SPRR2G shows downregulation in HPV-positive cases as compared with HPVnegative cases (Costa et al, 2018).…”

Section: Small Proline-rich Protein 2g (Sprr2g)mentioning

confidence: 86%

“…This gene shows a downregulated pathway and is connected to HPV-positive tumors. This gene is significantly downregulated and shows more methylation in HPV-negative HNSCC (Costa, Boroni, & Soares, 2018).…”

Section: Gap-junction Beta-6 Protein (Gjb6)mentioning

confidence: 98%

Human papillomavirus elevated genetic biomarker signature by statistical algorithm

Tripathi

Keshari

Shahi

et al. 2020

Journal Cellular Physiology

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“…However, a low overlap is observed between rebound CpGs and genes. Although this is not an uncommon occurrence, and indeed multiple examples can be found in the literature (Costa et al, 2018;Guo et al, 2020;Imran et al, 2021;Yang and Wang, 2015), this observation poses the question on how to integrate DNA methylation and RNA-seq data in case-control studies. The approach used in this study is to analyze DMGs and DEGs from a systemic perspective, meaning looking at the pathways associated with these sets of genes.…”

Section: Heuristics For Conditional Independence (Paper A-b-c)mentioning

confidence: 98%

“…An intuitive approach to the problem is to analyze the omics separately, and to select shared molecular events (i.e., changes associated to the same gene across omics) in a second step. Indeed, examples of this approach can be found in analyses of paired epigenetics/transcriptomics data (Costa et al, 2018;Imran et al, 2021) and transcriptomics/proteomics data Dumitriu et al (2016). However, a limitation of this strategy is that the overlap between the omics may be poor (Guo et al, 2020;Yang and Wang, 2015), as the analysis treats the multi-omics data as independent.…”

Section: Multi-omics Datamentioning

confidence: 99%

Integration of epigenetic, transcriptomic and proteomic data

Zenere

2023

Linköping Studies in Science and Technology. Dissertations

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One of the scopes of Systems Biology is to propose mathematical models that best capture the dynamic behavior of intra-cellular processes. In this regard, the last two decades have brought up a shift in the field, with technological advances now allowing researchers to access a wide range of high-throughput technologies at an affordable cost. These techniques allow to simultaneously interrogate thousands of variables, such as genome-wide transcriptomics and proteomics. However, parallel to these technological advances, there is a growing need for mathematical models that are suited to integrate measurements obtained from different cellular processes.In this thesis we aim to model combinations of three commonly used highthroughput data: epigenetic (namely ATAC-seq and DNA methylation), transcriptomic (RNA-seq) and proteomic data (MASS-spectrometry). In the first work we analyze paired ATAC-seq and RNA-seq data to integrate measurements of (i) chromatin openness, (ii) transcription factors (TFs) availability and (iii) gene expression. To model these data, we use elementary causal motifs, a class of mathematical models which is suited to represent causal interactions between three nodes. Indeed, our analysis shows that the elementary causal motifs in the data are enriched for biologically relevant TF-gene interactions. Moreover, a significant overlap is observed between the causal motifs identified in datasets representing similar cell stimuli, suggesting that causal motifs represent a robust biological signal.This work is then extended to include another class of high-throughput data: MASS-spectrometry. More precisely, we propose a framework to model the flow of events that goes from chromatin remodeling to splice variants expression, and from splice variants to protein synthesis. As the underlying graph becomes more complex than the previous case, a more general mathematical framework is considered: Bayesian networks. Interestingly, this work shows that most putative associations between chromatin regions, splice variants and proteins that have been gathered by scientific community so far, are supported by the data. Moreover, similarly to the previous work, the causal interactions identified in the data highlight relevant biological features; more precisely, causal chains between chromatin regions, splice variants and proteins are enriched for splice variants that have a major role in protein synthesis.From a technical point of view, causal motifs are characterized by a property known as conditional independence, which can be used to identify causal interactions in the data. However, particularly when the data available is limited, it is challenging to assess conditional independencies in the data. It is therefore of interest to investigate the existence of properties that allow us to predict conditional independence. In particular, in our work we propose two properties: structural balance and inverse balance, which are closely connected to what is known in the literature as positive association and multivariate t...

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“…To date, GRN analysis has been used successfully by ourselves and others to pinpoint factors and pathways underpinning normal development (Viiri et al 2019;M.-A. Mendoza-Parra et al 2016), cancer progression Costa, Boroni, and Soares 2018;Verfaillie et al 2015) and transdifferentiation (M.-A. Mendoza-Parra et al 2016;Ieda et al 2010).…”

Section: Introductionmentioning

confidence: 99%

Gene regulatory network reconstruction incorporating 3D chromosomal architecture reveals key transcription factors and DNA elements driving neural lineage commitment

Malysheva¹,

Mendoza-Parra

Blum

et al. 2018

Preprint

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Lineage commitment is a fundamental process that enables the morphogenesis of multicellular organisms from a single pluripotent cell. While many genes involved in the commitment to specific lineages are known, the logic of their joint action is incompletely understood, and predicting the effects of genetic perturbations on lineage commitment is still challenging. Here, we devised a gene regulatory network analysis approach, GRN-loop, to identify key cisregulatory DNA elements and transcription factors that drive lineage commitment. GRN-loop is based on signal propagation and combines transcription factor binding data with the temporal profiles of gene expression, chromatin state and 3D chromosomal architecture. Applying GRN-loop to a model of morphogen-induced early neural lineage commitment, we discovered a set of driver transcription factors and enhancers, some of them validated in recent data and others hitherto unknown. Our work provides the basis for an integrated understanding of neural lineage commitment, and demonstrates the potential of gene regulatory network analyses informed by 3D chromatin architecture to uncover the key genes and regulatory elements driving developmental processes.

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Distinct co-expression networks using multi-omic data reveal novel interventional targets in HPV-positive and negative head-and-neck squamous cell cancer

Cited by 3 publications

References 70 publications

Human papillomavirus elevated genetic biomarker signature by statistical algorithm

Human papillomavirus elevated genetic biomarker signature by statistical algorithm

Integration of epigenetic, transcriptomic and proteomic data

Gene regulatory network reconstruction incorporating 3D chromosomal architecture reveals key transcription factors and DNA elements driving neural lineage commitment

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