Synopses & Reviews
As more and more plant genomes are sequenced, plant researchers have been inundated with an avalanche of novel methodologies to identify the function of tens of thousands of plant genes. In Plant Functional Genomics, Erich Grotewold has assembled a team of leading plant scientists to describe in detail the most commonly used methods for investigating plant gene function in a wide variety of plants, during plant pathogen interactions, and even in algae. These readily reproducible protocols include computational, molecular, and genetic methodologies designed for both general and specific problems. Here the reader will learn how to identify genes in complex systems that have large genomes, few cells, and mixed cell systems. Readers will also learn the use of powerful computational and statistical tools to help predict gene function, either on the basis of comparative genomics, or from the analysis of complex genome sequences. Because establishing gene function relies on the identification of phenotypes, the authors expand the concept of phenotypes, including the use of multiple outputs as the ultimate phenotypic result of changes in gene activity. Numerous loss-of-function and gain-of-function techniques for discovering gene function are presented in step-by-step detail. Comprehensive and highly practical, Plant Functional Genomics offers plant biologists readily reproducible computational, molecular, and genetic protocols, powerful tools that will enable them, with little or no experience, successfully to investigate any gene function with the most recent methodologies.
Review
"...provides in a single volume most of the commonly used approaches in plant genomics...worth reading and should interest a large public." - Proteomics "This well written and illustrated guide reads easily and provides detailed protocols and an up-to-date bibliography for all reviewed strategies, making it the book that everybody in this field would need." - Cell Biochem Funct
Synopsis
Erich Grotewold has assembled a team of leading plant scientists to describe in detail the most commonly used methods for investigating plant gene function in a wide variety of plants, during plant pathogen interactions, and even in algae. These readily reproducible protocols include computational, molecular, and genetic methodologies designed for both general and specific problems. Here the reader will learn about powerful computational and statistical tools to help predict gene function either on the basis of comparative genomics, or from the analysis of complex genome sequences. Numerous loss-of-function and gain-of-function techniques for discovering gene function are presented in step-by-step detail.
Table of Contents
Part I. Finding Genes in Complex Plant Systems An Improved Method for Plant BAC Library Construction Meizhong Luo and Rod A. Wing Constructing Gene-Enriched Plant Genomic Libraries Using Methylation Filtration Technology Pablo D. Rabinowicz RescueMu Protocols for Maize Functional Genomics Manish N. Raizada Precious Cells Contain Precious Information: Strategies and Pitfalls in Expression Analysis from a Few Cells Isabelle M. Henry and Dina F. Mandoli Combined ESTs from Plant-Microbe Interactions: Using GC Counting to Determine the Species of Origin Edgar Huitema, Trudy A. Torto, Allison Styer, and Sophien Kamoun Part II. In Silico Prediction of Plant Gene Function Computer Software to Find Genes in Plant Genomic DNA Ramana V. Davuluri and Michael Q. Zhang Genomic Colinearity as a Tool for Plant Gene Isolation Wusirika Ramakrishna and Jeffrey L. Bennetzen Using Natural Allelic Diversity to Evaluate Gene Function Sherry R. Whitt and Edward S. Buckler, IV Quantitative Trait Locus Analysis as a Gene Discovery Tool Michael D. McMullen Part III. Forward and Reverse Genetic Strategies Transposon Tagging Using Activator (Ac) in Maize Thomas P. Brutnell and Liza J. Conrad T-DNA Mutagenesis in Arabidopsis Jose M. Alonso and Anna N. Stepanova Physical and Chemical Mutagenesis Andrea Kodym and Rownak Afza High-Throughput TILLING for Functional Genomics Bradley J. Till, Trenton Colbert, Rachel Tompa, Linda C. Enns, Christine A. Codomo, Jessica E. Johnson, Steven H. Reynolds, Jorja G. Henikoff, Elizabeth A. Greene, Michael N. Steine, Luca Comai, and Steven Henikoff Gene and Enhancer Traps for Gene Discovery Marcela Rojas-Pierce and Patricia S. Springer High-Throughput TAIL-PCR as a Tool to Identify DNA Flanking Insertions Tatjana Singer and Ellen Burke Custom Knock-Outs with Hairpin RNA-Mediated Gene Silencing Susan Varsha Wesley, Qing Liu, Anna Wielopolska, Geoff Ellacott, Neil Smith, Surinder Singh, and Chris Helliwell Virus-Induced Gene Silencing S. P. Dinesh-Kumar, Radhamani Anandalakshmi, Rajendra Marathe, Michael Schiff, and Yule Liu Exploring the Potential of Plant RNase P as a Functional Genomics Tool Dileep K. Pulukkunat, M. L. Stephen Raj, Debasis Pattanayak, Lien B. Lai, and Venkat Gopalan Maintaining Collections of Mutants for Plant Functional Genomics Randy Scholl, Martin M. Sachs, and Doreen Ware Part IV. Gain of Function Approaches Vector Construction for Gene Overexpression as a Tool to Elucidate Gene Function Alan Lloyd T-DNA Activation Tagging Johan Memelink Part V. Phenotypic Profiling as a Tool to Determine Gene Function Expression Profiling Using cDNA Microarrays Suling Zhao and Wesley B. Bruce Open Architecture Expression Profiling of Plant Transcriptomes and Gene Discovery Using GeneCalling® Technology Oswald R. Crasta and Otto Folkerts Proteomics as a Functional Genomics Tool Ulrike Mathesius, Nijat Imin, Siria H. A. Natera, and Barry G. Rolfe Metabolite Profiling as a Functional Genomics Tool Anusha P. Dias, Johnny Brown, Pierluigi Bonello, and Erich Grotewold Growth Stage-Based Phenotypic Profiling of Plants Susanne Kjemtrup, Douglas C. Boyes, Cory Christensen, Amy J. McCaskill, Michelle Hylton, and Keith Davis Index