Asymmetric expression of homoeologous genes in wheat roots modulates the early phase of iron-deficiency signalling

Abstract

AbstractIron (Fe) limitation leads to dramatic changes in gene expression in plants, to induce iron uptake and mobilization, while at the same time restrict Fe-dependent metabolism and growth. Although transcriptional changes in response to Fe deficiency have recently been charted in wheat, this was performed at a stage when photosynthesis and growth were severely impacted, confounding primary and secondary responses. Here, we specifically uncover the transcriptional landscape of wheat roots during the early stages of the Fe deficiency response (4 and 8 days) and after Fe resupply. Root growth was significantly inhibited at day 4, but chlorosis only became apparent on day 8. The number of differentially expressed genes increased from 1386 on day 4 to 3538 on day 8, with an overlap of 2006 genes. Genes with dynamic changes in expression patterns include membrane transporters and transcription factors shown to be involved in Fe homeostasis in other plant species. Comparative analysis of the Fe deficiency response at 4, 8 and 20 days identified a core set of Fe-regulated genes.Analysis of the expression of homoeologs suggests an increase in induction bias at 8 days compared to 4 days particularly, A genome contributing high at 4 days and the A+D genomes at 8 days. Overall, our work will contribute towards fundamental knowledge of the Fe signalling networks in wheat and point to the interplay of the three sub-genomes in this hexaploid species to fine tune the transcriptional response.