Abstract

BackgroundSoybean is a major crop that provides an important source of protein and oil to humans and animals, but its production can be dramatically decreased by the occurrence of drought stress. Soybeans can survive drought stress if there is a robust and deep root system at the early vegetative growth stage. However, little is known about the genome-wide molecular mechanisms contributing to soybean root system architecture. This study was performed to gain knowledge on transcriptome changes and related molecular mechanisms contributing to soybean root development under water limited conditions.ResultsThe soybean Williams 82 genotype was subjected to very mild stress (VMS), mild stress (MS) and severe stress (SS) conditions, as well as recovery from the severe stress after re-watering (SR). In total, 6,609 genes in the roots showed differential expression patterns in response to different water-deficit stress levels. Genes involved in hormone (Auxin/Ethylene), carbohydrate, and cell wall-related metabolism (XTH/lipid/flavonoids/lignin) pathways were differentially regulated in the soybean root system. Several transcription factors (TFs) regulating root growth and responses under varying water-deficit conditions were identified and the expression patterns of six TFs were found to be common across the stress levels. Further analysis on the whole plant level led to the finding of tissue-specific or water-deficit levels specific regulation of transcription factors. Analysis of the over-represented motif of different gene groups revealed several new cis-elements associated with different levels of water deficit. The expression patterns of 18 genes were confirmed byquantitative reverse transcription polymerase chain reaction method and demonstrated the accuracy and effectiveness of RNA-Seq.ConclusionsThe primary root specific transcriptome in soybean can enable a better understanding of the root response to water deficit conditions. The genes detected in root tissues that were associated with key hormones, carbohydrates, and cell wall-related metabolism could play a vital role in achieving drought tolerance and could be promising candidates for future functional characterization. TFs involved in the soybean root and at the whole plant level could be used for future network analysis between TFs and cis-elements. All of these findings will be helpful in elucidating the molecular mechanisms associated with water stress responses in soybean roots.Electronic supplementary materialThe online version of this article (doi:10.1186/s12864-016-2378-y) contains supplementary material, which is available to authorized users.

Highlights

  • Soybean is a major crop that provides an important source of protein and oil to humans and animals, but its production can be dramatically decreased by the occurrence of drought stress

  • These results indicated that the lack of soil moisture at critical stages of growth will profoundly impact the productivity and that developing a large root system at the early vegetative (V) growth stage will place the soybeans in an excellent position to maintain turgor under drought conditions

  • The leaf water potential reached in this experiment reflected the severe drought stress treatment in the field with a LWP of −2.5 MPa

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Summary

Introduction

Soybean is a major crop that provides an important source of protein and oil to humans and animals, but its production can be dramatically decreased by the occurrence of drought stress. It has been reported that low water potential at soybean vegetative stages will decrease or stop its shoot growth, while the root continues to grow [4] This shoot-root response in soybean under water-deficit conditions allows the plant to search for additional soil water while maintaining higher water use efficiency [5]. The taproot elongation rate is the major factor influencing the depth of the soybean rooting system under water-deficit conditions [8] These results indicated that the lack of soil moisture at critical stages of growth will profoundly impact the productivity and that developing a large root system at the early vegetative (V) growth stage will place the soybeans in an excellent position to maintain turgor under drought conditions

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