Abstract
BackgroundOne of the great advantages of next generation sequencing is the ability to generate large genomic datasets for virtually all species, including non-model organisms. It should be possible, in turn, to apply advanced computational approaches to these datasets to develop models of biological processes. In a practical sense, working with non-model organisms presents unique challenges. In this paper we discuss some of these challenges for ChIP-seq and RNA-seq experiments using the undomesticated tree species of the genus Populus.ResultsWe describe specific challenges associated with experimental design in Populus, including selection of optimal genotypes for different technical approaches and development of antibodies against Populus transcription factors. Execution of the experimental design included the generation and analysis of Chromatin immunoprecipitation-sequencing (ChIP-seq) data for RNA polymerase II and transcription factors involved in wood formation. We discuss criteria for analyzing the resulting datasets, determination of appropriate control sequencing libraries, evaluation of sequencing coverage needs, and optimization of parameters. We also describe the evaluation of ChIP-seq data from Populus, and discuss the comparison between ChIP-seq and RNA-seq data and biological interpretations of these comparisons.ConclusionsThese and other "lessons learned" highlight the challenges but also the potential insights to be gained from extending next generation sequencing-supported network analyses to undomesticated non-model species.
Highlights
One of the great advantages of generation sequencing is the ability to generate large genomic datasets for virtually all species, including non-model organisms
The process of secondary growth is tightly regulated transcriptionally but, the genes expressed during secondary growth have been previously catalogued using microarrays [6], we currently lack an understanding of how genes are regulated or interact to condition the complex phenotypes seen in the woody stems of trees
We presented analyses showing the effects of various parameters affecting the outcome of ChIP-seq and RNA-seq analyses, including the differences of mapping to Antibody for ChIP-seq A monoclonal antibody against RNA Polymerase II (MMS-126R) was used for RNA pol II ChIP-seq
Summary
One of the great advantages of generation sequencing is the ability to generate large genomic datasets for virtually all species, including non-model organisms. It should be possible, in turn, to apply advanced computational approaches to these datasets to develop models of biological processes. Comparative and evolutionary genomic studies are increasingly recognized as being fundamental [1,2,3] Such studies are tractable through the extension of generation sequencingbased tools and analytical approaches to non-model. Forest trees present the opportunity to test the extension of generation sequencing-based tools and associated analytical approaches to non-model plants. The process of secondary growth is tightly regulated transcriptionally but, the genes expressed during secondary growth have been previously catalogued using microarrays [6], we currently lack an understanding of how genes are regulated or interact to condition the complex phenotypes seen in the woody stems of trees
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