Dual and spatially resolved drought responses in the Arabidopsis leaf mesophyll revealed by single-cell transcriptomics

ABSTRACT Drought stress imposes severe challenges on agriculture by impacting crop performance. Understanding drought responses in plants at a cellular level is a crucial first step towards engineering improved drought resilience. However, the molecular responses to drought are complex as they depend on multiple factors including the severity of drought, the profiled organ, its developmental stage or even the cell types therein. Thus, deciphering the transcriptional responses to drought is specially challenging. Here, we investigated tissue-specific responses to mild drought in young Arabidopsis thaliana (Arabidopsis) leaves using single-cell RNA sequencing (scRNA-seq). To preserve transcriptional integrity during cell isolation, we inhibited RNA synthesis using the transcription inhibitor actinomycin D, demonstrating the benefits of transcriptome fixation for studying mild stress responses at single-cell level. We present a curated and validated single-cell atlas comprising 50,797 high-quality cells from almost all known cell types present in the leaf. We show that the mesophyll contains two spatially separated cell populations with distinct responses to drought: one enriched in canonical abscisic acid-related drought-responsive genes, and another one depicting iron starvation responses. Our study thus reveals a dual adaptive mechanism of the leaf mesophyll in response to mild drought and provides a valuable resource for future research on stress responses.