RSEQREP: RNA-Seq Reports, an open-source cloud-enabled framework for reproducible RNA-Seq data processing, analysis, and result reporting

Jensen, Travis L.; Frasketi, Michael; Conway, Kevin P.; Villarroel, Leigh; Hill, Heather; Krampis, Konstantinos; Goll, Johannes

doi:10.12688/f1000research.13049.1

Cited by 7 publications

(14 citation statements)

References 45 publications

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“…To address intervention cause, we need to perform a sequence of established steps to pre-process the RNA-seq data, by performing quality control, alignment, read count calculation, filtering, normalization and correction. Several pipeline methods codify these steps to enable users to subsequently perform DE analysis and summarize uncovered regulatory mechanisms (Afgan et al, 2018;Torre et al, 2018;Ge et al, 2018;Cornwell et al, 2018;de Jong et al, 2015;Jensen et al, 2017;Kartashov and Barski, 2015;Spurney et al, 2020). However, there are many possible methods to choose from at each step in this process (STAR Methods), not all experimental designs are the same, and downstream results heavily depend on how the RNA-seq data are processed.…”

Section: Current Pipeline Methods Are Unable To Effectively Uncover Amentioning

confidence: 99%

“…However, there are many possible methods to choose from at each step in this process (STAR Methods), not all experimental designs are the same, and downstream results heavily depend on how the RNA-seq data are processed. Most current pipeline methods do not allow users to compare the many possible methods, providing only one tool for each step (BioJupies (Torre et al, 2018); RSEQREP (Jensen et al, 2017)) even though it is recommended to consider methods for analyses such as DE (Spies et al, 2019). Furthermore, most only perform part of the analysis to infer altered regulatory mechanisms (VIPER (Cornwell et al, 2018); BioWardrobe (Kartashov and Barski, 2015)).…”

Section: Current Pipeline Methods Are Unable To Effectively Uncover Amentioning

confidence: 99%

“…Importantly, time series DE methods algorithms are still in their infancy and are underutilized (Spies et al, 2019). The few DE methods that do consider temporal dynamics are not yet part of pipeline methods to infer GRNs and are therefore incomplete (Fischer et al, 2018;Jensen et al, 2017;Michna et al, 2016;Nueda et al, 2014;Spurney et al, 2020;Wani and Raza, 2019). For time series DE methods that do exist, some can only analyze specific experimental designs or require normalized and corrected data on input (Sahraeian et al, 2017;Spies and Ciaudo, 2015;Spies et al, 2019).…”

Section: Current Pipeline Methods Are Unable To Effectively Uncover Amentioning

confidence: 99%

“…We compared these methods in terms of 14 features ( Figure S1). Some of these methods analyze RNA-seq data from raw .fastq files and perform gene ontology, claim to be able to analyze time series RNA-seq data, and/or report gene regulatory networks (Afgan et al, 2018;Torre et al, 2018;Ge et al, 2018;Cornwell et al, 2018;de Jong et al, 2015;Jensen et al, 2017;Kartashov and Barski, 2015;Spurney et al, 2020). TIMEOR fills a gap by providing at least twice as many features to uncover gene regulatory mechanisms from time series data compared to existing methods.…”

Section: Comparison Of Timeor To Existing Methodsmentioning

confidence: 99%

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TIMEOR: a web-based tool to uncover temporal regulatory mechanisms from multi-omics data

Conard

Goodman

et al. 2020

Preprint

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SummaryUncovering how transcription factors (TFs) regulate their targets at the DNA, RNA and protein levels over time is critical to define gene regulatory networks (GRNs) in normal and diseased states. RNA-seq has become a standard method to measure gene regulation using an established set of analysis steps. However, none of the currently available pipeline methods for interpreting ordered genomic data (in time or space) use time series models to assign cause and effect relationships within GRNs, are adaptive to diverse experimental designs, or enable user interpretation through a web-based platform. Furthermore, methods which integrate ordered RNA-seq data with transcription factor binding data are urgently needed. Here, we present TIMEOR (Trajectory Inference and Mechanism Exploration with Omics data in R), the first web-based and adaptive time series multi-omics pipeline method which infers the relationship between gene regulatory events across time. TIMEOR addresses the critical need for methods to predict causal regulatory mechanism networks between TFs from time series multi-omics data. We used TIMEOR to identify a new link between insulin stimulation and the circadian rhythm cycle. TIMEOR is available at https://github.com/ashleymaeconard/TIMEOR.git.

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Section: Current Pipeline Methods Are Unable To Effectively Uncover Amentioning

confidence: 99%

Section: Current Pipeline Methods Are Unable To Effectively Uncover Amentioning

confidence: 99%

Section: Current Pipeline Methods Are Unable To Effectively Uncover Amentioning

confidence: 99%

Section: Comparison Of Timeor To Existing Methodsmentioning

confidence: 99%

See 2 more Smart Citations

TIMEOR: a web-based tool to uncover temporal regulatory mechanisms from multi-omics data

Conard

Goodman

et al. 2020

Preprint

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“…But 433 big data tools from outside biomedicine tend to focus on narrow aspects of the analytic 434 problem, leaving researchers on their own when it comes to managing the end-to-end 435 discovery process [49]. 436 Many approaches to reproducibility focus on using mechanisms such as 437 makefiles [50,51], open source software [30,31], specialized programming 438 environments [52], and virtual machines [53] to organize the code and/or data required 439 for a computation. These approaches work well for small data but face challenges when 440 computations must scale to terabytes and span sites.…”

mentioning

confidence: 99%

Reproducible big data science: A case study in continuous FAIRness

Madduri

Chard

D’Arcy

et al. 2018

Preprint

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Big biomedical data create exciting opportunities for discovery, but make it difficult to capture analyses and outputs in forms that are findable, accessible, interoperable, and reusable (FAIR). In response, we describe tools that make it easy to capture, and assign identifiers to, data and code throughout the data lifecycle. We illustrate the use of these tools via a case study involving a multi-step analysis that creates an atlas of putative transcription factor binding sites from terabytes of ENCODE DNase I hypersensitive sites sequencing data. We show how the tools automate routine but complex tasks, capture analysis algorithms in understandable and reusable forms, and harness fast networks and powerful cloud computers to process data rapidly, all without sacrificing usability or reproducibility-thus ensuring that big data are not hard-to-(re)use data. We compare and contrast our approach with other approaches to big data analysis and reproducibility.

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TIMEOR: a web-based tool to uncover temporal regulatory mechanisms from multi-omics data

Conard

Goodman

et al. 2021

Nucleic Acids Research

View full text Add to dashboard Cite

Uncovering how transcription factors regulate their targets at DNA, RNA and protein levels over time is critical to define gene regulatory networks (GRNs) and assign mechanisms in normal and diseased states. RNA-seq is a standard method measuring gene regulation using an established set of analysis stages. However, none of the currently available pipeline methods for interpreting ordered genomic data (in time or space) use time-series models to assign cause and effect relationships within GRNs, are adaptive to diverse experimental designs, or enable user interpretation through a web-based platform. Furthermore, methods integrating ordered RNA-seq data with protein–DNA binding data to distinguish direct from indirect interactions are urgently needed. We present TIMEOR (Trajectory Inference and Mechanism Exploration with Omics data in R), the first web-based and adaptive time-series multi-omics pipeline method which infers the relationship between gene regulatory events across time. TIMEOR addresses the critical need for methods to determine causal regulatory mechanism networks by leveraging time-series RNA-seq, motif analysis, protein–DNA binding data, and protein-protein interaction networks. TIMEOR’s user-catered approach helps non-coders generate new hypotheses and validate known mechanisms. We used TIMEOR to identify a novel link between insulin stimulation and the circadian rhythm cycle. TIMEOR is available at https://github.com/ashleymaeconard/TIMEOR.git and http://timeor.brown.edu.

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RSEQREP: RNA-Seq Reports, an open-source cloud-enabled framework for reproducible RNA-Seq data processing, analysis, and result reporting

Cited by 7 publications

References 45 publications

TIMEOR: a web-based tool to uncover temporal regulatory mechanisms from multi-omics data

TIMEOR: a web-based tool to uncover temporal regulatory mechanisms from multi-omics data

Reproducible big data science: A case study in continuous FAIRness

TIMEOR: a web-based tool to uncover temporal regulatory mechanisms from multi-omics data

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