Abstract
Soil-free assays that induce water stress are routinely used to investigate drought responses in the plant Arabidopsis thaliana. Due to their ease of use, the research community often relies on polyethylene glycol (PEG), mannitol and salt (NaCl) treatments to reduce the water potential of agar media, and thus induce drought conditions in the laboratory. However, while these types of stress can create phenotypes that resemble those of water deficit experienced by soil-grown plants, it remains unclear how these treatments compare at the transcriptional level. Here, we demonstrate that these different methods of lowering water potential elicit both shared and distinct transcriptional responses in Arabidopsis shoot and root tissue. When we compared these transcriptional responses to those found in Arabidopsis roots subject to vermiculite drying, we discovered many genes induced by vermiculite drying were repressed by low water potential treatments on agar plates (and vice versa). Additionally, we also tested another method for lowering water potential of agar media. By increasing the nutrient content and tensile strength of agar, we show the ‘hard agar’ (HA) treatment can be leveraged as a high-throughput assay to investigate natural variation in Arabidopsis growth responses to low water potential.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
The "low water" assay has been renamed "hard agar" assay. The distinction between low water potential and drought stress has been made more clear in the text. Additional replication provided for low water potential measurements (Figure 1B). Additional transcriptomic comparisons to published literature presented (Figure 2 - figure supplement 1). Greater clarity on the effect of agar volume on gene expression presented (Figure 2-figure supplement 7).
