Table of Contents
Novel Techniques for Analyzing and Combining Data from Modern Biological Studies
Broadens the Traditional Definition of Meta-Analysis
With the diversity of data and meta-data now available, there is increased interest in analyzing multiple studies beyond statistical approaches of formal meta-analysis. Covering an extensive range of quantitative information combination methods, Meta-analysis and Combining Information in Genetics and Genomics looks at how to analyze multiple studies from a broad perspective.
After presenting the basic ideas and tools of meta-analysis, the book addresses the combination of similar data types: genotype data from genome-wide linkage scans and data derived from microarray gene expression experiments. The expert contributors show how some data combination problems can arise even within the same basic framework and offer solutions to these problems. They also discuss the combined analysis of different data types, giving readers an opportunity to see data combination approaches in action across a wide variety of genome-scale investigations.
As heterogeneous data sets become more common, biological understanding will be significantly aided by jointly analyzing such data using fundamentally sound statistical methodology. This book provides many novel techniques for analyzing data from modern biological studies that involve multiple data sets, either of the same type or multiple data sources.
Introductory Material
A brief introduction to meta-analysis, genetics, and genomics Darlene R. Goldstein and Rudy Guerra
Similar Data Types I: Genotype Data
Combining information across genome-wide linkage scans Carol J. Etzel and Tracy J. Costello
Genome search meta-analysis (GSMA): a nonparametric method for meta-analysis of genome-wide linkage studies Cathryn M. Lewis
Heterogeneity in meta-analysis of quantitative trait linkage studies Hans C. van Houwelingen and Jérémie J.P. Lebrec
An empirical Bayesian framework for QTL genome-wide scans Kui Zhang, Howard Wiener, T. Mark Beasley, Christopher I. Amos, and David B. Allison
Similar Data Types II: Gene Expression Data
Composite hypothesis testing: an approach built on intersection-union tests and Bayesian posterior probabilities Stephen Erickson, Kyoungmi Kim, and David B. Allison
Frequentist and Bayesian error pooling methods for enhancing statistical power in small sample microarray data analysis Jae K. Lee, Hyung Jun Cho, and Michael O’Connell
Significance testing for small microarray experiments Charles Kooperberg, Aaron Aragaki, Charles C. Carey, and Suzannah Rutherford
Comparison of meta-analysis to combined analysis of a replicated microarray study Darlene R. Goldstein, Mauro Delorenzi, Ruth Luthi-Carter, and Thierry Sengstag
Alternative probe set definitions for combining microarray data across studies using different versions of Affymetrix oligonucleotide arrays Jeffrey S. Morris, Chunlei Wu, Kevin R. Coombes, Keith A. Baggerly, Jing Wang, and Li Zhang
Gene ontology-based meta-analysis of genome-scale experiments Chad A. Shaw
Combining Different Data Types
Combining genomic data in human studies Debashis Ghosh, Daniel Rhodes, and Arul Chinnaiyan
An overview of statistical approaches for expression trait loci mapping Christina Kendziorski and Meng Chen
Incorporating GO annotation information in expression trait loci mapping J. Blair Christian and Rudy Guerra
A misclassification model for inferring transcriptional regulatory networks Ning Sun and Hongyu Zhao
Data integration for the study of protein interactions Fengzhu Sun, Ting Chen, Minghua Deng, Hyunju Lee, and Zhidong Tu
Gene trees, species trees, and species networks Luay Nakhleh, Derek Ruths, and Hideki Innan
References
Index