A developing Setaria viridis internode: an experimental system for the study of biomass generation in a C4 model species.

Antony P Martin,Christopher Brown,Robert T Furbank,John E Lunn,Christopher P L Grof,Christin Abel,William M Palmer

doi:10.1186/s13068-016-0457-6

Abstract

BackgroundRecently, there has been interest in establishing a monocot C4 model species with a small genome, short lifecycle, and capacity for genetic transformation. Setaria viridis has been adopted to fill this role, since reports of Agrobacterium-mediated transformation in 2010, and sequencing of its genome in 2012. To date, S. viridis has primarily been used to further our understanding of C4 photosynthesis, but is also an ideal system for the study of biomass crops, which are almost exclusively C4 panicoid grasses. Biogenesis of stem tissue, its cell wall composition, and soluble sugar content are important determinants of bioenergy crop yields. Here we show that a developing S. viridis internode is a valuable experimental system for gene discovery in relation to these important bioenergy feedstock traits.ResultsThe rate of maximal stem biomass accumulation in S. viridis A10 under long day growth was at the half-head emergence developmental stage. At this stage of development, internode 5 (of 7) was found to be rapidly expanding with an active meristem, a zone of cell expansion (primary cell walls), a transitional zone where cell expansion ceased and secondary cell wall deposition was initiated, and a mature zone that was actively accumulating soluble sugars. A simple method for identifying these zones was established allowing rapid dissection and snap-freezing for RNAseq analysis. A transcriptome profile was generated for each zone showing a transition from cell division and nucleic acid synthesis/processing in the meristem, to metabolism, energy synthesis, and primary cell wall synthesis in the cell expansion zone, to secondary cell wall synthesis in the transitional zone, to sugar transport, and photosynthesis in the mature zone.ConclusionThe identification of these zones has provided a valuable experimental system for investigating key bioenergy traits, including meristematic activity, cell wall biosynthesis, and soluble sugar accumulation, in a C4 panicoid grass that has genetic resources, a short life cycle, and small stature allowing controlled experimental conditions in growth cabinets. Here we have presented a comprehensive map of gene expression and metabolites in this experimental system to facilitate gene discovery and controlled hypothesis testing for bioenergy research in S. viridis.Electronic supplementary materialThe online version of this article (doi:10.1186/s13068-016-0457-6) contains supplementary material, which is available to authorized users.

Highlights

There has been interest in establishing a monocot C4 model species with a small genome, short lifecycle, and capacity for genetic transformation
Reported uses of Setaria viridis to date have focused on the collection of natural diversity panels [8, 9], the development of mapping populations [10], transformation [11,12,13,14] and crossing [15] techniques, and generation of molecular resources such as transformation vectors [12] and Martin et al Biotechnol Biofuels (2016) 9:45 notably a genome sequence [16]. Most research using these resources has been directed towards the study of C4 photosynthesis and associated leaf development and cellular differentiation [17]; S. viridis is a valuable model species for the study of biomass crops, which are almost exclusively C4 panicoid grasses (e.g. giant miscanthus (Miscanthus x giganteus), switchgrass (Panicum virgatum), sugarcane (Saccharum officinarum), maize (Zea mays), and sorghum (Sorghum bicolor)) sharing a highly similar lineage to Setaria
Whilst photosynthesis is an important determinant of crop biomass yield, knowledge of the factors controlling biogenesis of stem sink tissue, its cell wall composition, and soluble sugar content are crucial for the improvement of forage and bioenergy crop quality and yields

Summary

Introduction

There has been interest in establishing a monocot C4 model species with a small genome, short lifecycle, and capacity for genetic transformation. Biogenesis of stem tissue, its cell wall composition, and soluble sugar content are important determinants of bioenergy crop yields. Martin et al Biotechnol Biofuels (2016) 9:45 notably a genome sequence [16] Most research using these resources has been directed towards the study of C4 photosynthesis and associated leaf development and cellular differentiation [17]; S. viridis is a valuable model species for the study of biomass crops, which are almost exclusively C4 panicoid grasses (e.g. giant miscanthus (Miscanthus x giganteus), switchgrass (Panicum virgatum), sugarcane (Saccharum officinarum), maize (Zea mays), and sorghum (Sorghum bicolor)) sharing a highly similar lineage to Setaria. Whilst photosynthesis is an important determinant of crop biomass yield, knowledge of the factors controlling biogenesis of stem sink tissue, its cell wall composition, and soluble sugar content are crucial for the improvement of forage and bioenergy crop quality and yields. Setaria viridis culms possess attributes that suggest they would be a valuable C4 model system for the study of cell wall synthesis and stem development and sugar accumulation in C4 panicoid grass culms

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