Abstract
In response to biotic stresses, such as herbivore attack, plants reorganize their transcriptomes and reconfigure their physiologies not only in attacked tissues but throughout the plant. These whole-organismic reconfigurations are coordinated by a poorly understood network of signal transduction cascades. To explore tissue-based interdependencies in the resistance of Nicotiana attenuata to insect attack, we conducted time-series transcriptome and metabolome profiling of herbivory-elicited source leaves and unelicited sink leaves and roots. To probe the multidimensionality of these molecular responses, we designed a novel approach of combining an extended self-organizing maps-based dimensionality reduction method with bootstrap-based nonparametric analysis of variance models to identify the onset and context of signaling and metabolic pathway activations. We illustrate the value of this analysis by revisiting dynamic changes in the expression of regulatory and structural genes of the oxylipin pathway and by studying nonlinearities in gene-metabolite associations involved in the acyclic diterpene glucoside pathway after selectively extracting modules based on their dynamic response patterns. This novel dimensionality reduction approach is broadly applicable to capture the dynamic rewiring of gene and metabolite networks in experimental design with multiple factors.
Highlights
In response to biotic stresses, such as herbivore attack, plants reorganize their transcriptomes and reconfigure their physiologies in attacked tissues but throughout the plant
Spatiotemporal maps produced in this study underscore the high plasticity of oral secretions (OS) elicitation responses and provide a powerful data platform for the functional genomics of novel regulatory and structural genes involved in antiherbivory processes
Elucidating groups of genes involved in the sequential reorganization of biological networks is extremely challenging using the available bioinformatics approaches, but we successfully studied such a reorganization by systematically combining information about when to respond with information about how to respond
Summary
In response to biotic stresses, such as herbivore attack, plants reorganize their transcriptomes and reconfigure their physiologies in attacked tissues but throughout the plant. We illustrate the value of this analysis by revisiting dynamic changes in the expression of regulatory and structural genes of the oxylipin pathway and by studying nonlinearities in gene-metabolite associations involved in the acyclic diterpene glucoside pathway after selectively extracting modules based on their dynamic response patterns This novel dimensionality reduction approach is broadly applicable to capture the dynamic rewiring of gene and metabolite networks in experimental design with multiple factors. Plants adapt to environmental stresses through large-scale transcriptional reprogramming, which involves intricate signaling pathways (Hahlbrock et al, 2003; Nakashima et al, 2009; Zeller et al, 2009; Walley and Dehesh, 2010) These transcriptional adjustments can be captured by studying changes in the expression of genes in different tissues in order to elucidate the influence of particular pathways as well as the relative contribution of a given tissue to the whole-organism response. Via a set of largely unknown pathway-specific transcription factors, profound changes in the expression of regulatory and structural genes (Halitschke and Baldwin, 2003; Wang et al, 2008)
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