Literature DB >> 30101659

Bootstrapping and Empirical Bayes Methods Improve Rhythm Detection in Sparsely Sampled Data.

Alan L Hutchison1,2,3, Ravi Allada4, Aaron R Dinner3,5,6.   

Abstract

There is much interest in using genome-wide expression time series to identify circadian genes. However, the cost and effort of such measurements often limit data collection. Consequently, it is difficult to assess the experimental uncertainty in the measurements and, in turn, to detect periodic patterns with statistical confidence. We show that parametric bootstrapping and empirical Bayes methods for variance shrinkage can improve rhythm detection in genome-wide expression time series. We demonstrate these approaches by building on the empirical JTK_CYCLE method (eJTK) to formulate a method that we term BooteJTK. Our procedure rapidly and accurately detects cycling time series by combining information about measurement uncertainty with information about the rank order of the time series values. We exploit a publicly available genome-wide data set with high time resolution to show that BooteJTK provides more consistent rhythm detection than existing methods at typical sampling frequencies. Then, we apply BooteJTK to genome-wide expression time series from multiple tissues and show that it reveals biologically sensible tissue relationships that eJTK misses. BooteJTK is implemented in Python and is freely available on GitHub at https://github.com/alanlhutchison/BooteJTK .

Entities:  

Keywords:  bioinformatics; circadian; empirical Bayes; gene expression analysis; rhythm detection

Mesh:

Year:  2018        PMID: 30101659      PMCID: PMC6347739          DOI: 10.1177/0748730418789536

Source DB:  PubMed          Journal:  J Biol Rhythms        ISSN: 0748-7304            Impact factor:   3.182


  29 in total

1.  Coordinated transcription of key pathways in the mouse by the circadian clock.

Authors:  Satchidananda Panda; Marina P Antoch; Brooke H Miller; Andrew I Su; Andrew B Schook; Marty Straume; Peter G Schultz; Steve A Kay; Joseph S Takahashi; John B Hogenesch
Journal:  Cell       Date:  2002-05-03       Impact factor: 41.582

2.  Extensive and divergent circadian gene expression in liver and heart.

Authors:  Kai-Florian Storch; Ovidiu Lipan; Igor Leykin; N Viswanathan; Fred C Davis; Wing H Wong; Charles J Weitz
Journal:  Nature       Date:  2002-04-21       Impact factor: 49.962

3.  A Conserved Bicycle Model for Circadian Clock Control of Membrane Excitability.

Authors:  Matthieu Flourakis; Elzbieta Kula-Eversole; Alan L Hutchison; Tae Hee Han; Kimberly Aranda; Devon L Moose; Kevin P White; Aaron R Dinner; Bridget C Lear; Dejian Ren; Casey O Diekman; Indira M Raman; Ravi Allada
Journal:  Cell       Date:  2015-08-13       Impact factor: 41.582

4.  Systematic and integrative analysis of large gene lists using DAVID bioinformatics resources.

Authors:  Da Wei Huang; Brad T Sherman; Richard A Lempicki
Journal:  Nat Protoc       Date:  2009       Impact factor: 13.491

5.  Differential analysis of RNA-seq incorporating quantification uncertainty.

Authors:  Harold Pimentel; Nicolas L Bray; Suzette Puente; Páll Melsted; Lior Pachter
Journal:  Nat Methods       Date:  2017-06-05       Impact factor: 28.547

6.  Pancreatic β cell enhancers regulate rhythmic transcription of genes controlling insulin secretion.

Authors:  Mark Perelis; Biliana Marcheva; Kathryn Moynihan Ramsey; Matthew J Schipma; Alan L Hutchison; Akihiko Taguchi; Clara Bien Peek; Heekyung Hong; Wenyu Huang; Chiaki Omura; Amanda L Allred; Christopher A Bradfield; Aaron R Dinner; Grant D Barish; Joseph Bass
Journal:  Science       Date:  2015-11-06       Impact factor: 47.728

Review 7.  Wee1-dependent mechanisms required for coordination of cell growth and cell division.

Authors:  Douglas R Kellogg
Journal:  J Cell Sci       Date:  2003-12-15       Impact factor: 5.285

8.  Transcriptional architecture and chromatin landscape of the core circadian clock in mammals.

Authors:  Nobuya Koike; Seung-Hee Yoo; Hung-Chung Huang; Vivek Kumar; Choogon Lee; Tae-Kyung Kim; Joseph S Takahashi
Journal:  Science       Date:  2012-08-30       Impact factor: 47.728

9.  Improved statistical methods enable greater sensitivity in rhythm detection for genome-wide data.

Authors:  Alan L Hutchison; Mark Maienschein-Cline; Andrew H Chiang; S M Ali Tabei; Herman Gudjonson; Neil Bahroos; Ravi Allada; Aaron R Dinner
Journal:  PLoS Comput Biol       Date:  2015-03-20       Impact factor: 4.475

10.  Bioinformatics enrichment tools: paths toward the comprehensive functional analysis of large gene lists.

Authors:  Da Wei Huang; Brad T Sherman; Richard A Lempicki
Journal:  Nucleic Acids Res       Date:  2008-11-25       Impact factor: 16.971
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  9 in total

1.  Circadian Proteomic Analysis Uncovers Mechanisms of Post-Transcriptional Regulation in Metabolic Pathways.

Authors:  Jennifer M Hurley; Meaghan S Jankowski; Hannah De Los Santos; Alexander M Crowell; Samuel B Fordyce; Jeremy D Zucker; Neeraj Kumar; Samuel O Purvine; Errol W Robinson; Anil Shukla; Erika Zink; William R Cannon; Scott E Baker; Jennifer J Loros; Jay C Dunlap
Journal:  Cell Syst       Date:  2018-12-12       Impact factor: 10.304

2.  Applications of cosinor rhythmometry in pharmacology.

Authors:  Germaine Cornelissen
Journal:  J Pharmacokinet Pharmacodyn       Date:  2021-03-23       Impact factor: 2.745

3.  Aging disrupts circadian gene regulation and function in macrophages.

Authors:  Eran Blacher; Connie Tsai; Lev Litichevskiy; Zohar Shipony; Chinyere Agbaegbu Iweka; Kai Markus Schneider; Bayarsaikhan Chuluun; H Craig Heller; Vilas Menon; Christoph A Thaiss; Katrin I Andreasson
Journal:  Nat Immunol       Date:  2021-12-23       Impact factor: 25.606

4.  Comment on "Circadian rhythms in the absence of the clock gene Bmal1".

Authors:  Elan Ness-Cohn; Ravi Allada; Rosemary Braun
Journal:  Science       Date:  2021-04-16       Impact factor: 63.714

5.  TimeTrial: An Interactive Application for Optimizing the Design and Analysis of Transcriptomic Time-Series Data in Circadian Biology Research.

Authors:  Elan Ness-Cohn; Marta Iwanaszko; William L Kath; Ravi Allada; Rosemary Braun
Journal:  J Biol Rhythms       Date:  2020-07-02       Impact factor: 3.182

6.  Time-course RNASeq of Camponotus floridanus forager and nurse ant brains indicate links between plasticity in the biological clock and behavioral division of labor.

Authors:  Biplabendu Das; Charissa de Bekker
Journal:  BMC Genomics       Date:  2022-01-15       Impact factor: 3.969

7.  Methods detecting rhythmic gene expression are biologically relevant only for strong signal.

Authors:  David Laloum; Marc Robinson-Rechavi
Journal:  PLoS Comput Biol       Date:  2020-03-17       Impact factor: 4.475

8.  TimeCycle: Topology Inspired MEthod for the Detection of Cycling Transcripts in Circadian Time-Series Data.

Authors:  Elan Ness-Cohn; Rosemary Braun
Journal:  Bioinformatics       Date:  2021-06-27       Impact factor: 6.937

9.  Interpreting machine learning models to investigate circadian regulation and facilitate exploration of clock function.

Authors:  Laura-Jayne Gardiner; Rachel Rusholme-Pilcher; Josh Colmer; Hannah Rees; Juan Manuel Crescente; Anna Paola Carrieri; Susan Duncan; Edward O Pyzer-Knapp; Ritesh Krishna; Anthony Hall
Journal:  Proc Natl Acad Sci U S A       Date:  2021-08-10       Impact factor: 11.205
  9 in total

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