AI Article Synopsis
- - The study investigates how Arabidopsis plants respond to phosphate (Pi) deficiency, specifically focusing on how it inhibits primary root (PR) growth and the roles of various key components in this process.
- - Researchers discovered that three main components—STOP1, ALMT1, and LPR1—work together downstream of ALS3/STAR1 to regulate PR growth under Pi deficiency, with ALS3/STAR1 inhibiting the STOP1-ALMT1 pathway in the nucleus.
- - The findings suggest that while STOP1-ALMT1 and LPR1 are interdependent in controlling Fe accumulation in roots due to malate and that this malate-dependent Fe accumulation is influenced by external Pi levels, the inhibition of
Article Abstract
The inhibition of primary root (PR) growth is a major developmental response of Arabidopsis () to phosphate (Pi) deficiency. Previous studies have independently uncovered key roles of the LOW PHOSPHATE RESPONSE1 (LPR1) ferroxidase, the tonoplast-localized ALUMINUM SENSITIVE3 (ALS3)/SENSITIVE TO ALUMINUM RHIZOTOXICITY1 (STAR1) transporter complex, and the SENSITIVE TO PROTON RHIZOTOXICITY1 (STOP1; a transcription factor)-ALUMINUM-ACTIVATED MALATE TRANSPORTER1 (ALMT1; a malate transporter) regulatory module in mediating this response by controlling iron (Fe) homeostasis in roots, but how these three components interact to regulate PR growth under Pi deficiency remains unknown. Here, we dissected genetic relationships among these three key components and found that (1) STOP1, ALMT1, and LPR1 act downstream of ALS3/STAR1 in controlling PR growth under Pi deficiency; (2) ALS3/STAR1 inhibits the STOP1-ALMT1 pathway by repressing STOP1 protein accumulation in the nucleus; and (3) STOP1-ALMT1 and LPR1 control PR growth under Pi deficiency in an interdependent manner involving the promotion of malate-dependent Fe accumulation in roots. Furthermore, this malate-mediated Fe accumulation depends on external Pi availability. We also performed a detailed analysis of the dynamic changes in the tissue-specific Fe accumulation patterns in the root tips of plants exposed to Pi deficiency. The results indicate that the degree of inhibition of PR growth induced by Pi deficiency is not linked to the level of Fe accumulated in the root apical meristem or the elongation zone. Our work provides insights into the molecular mechanism that regulates the root developmental response to Pi deficiency.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6324241 | PMC |
| http://dx.doi.org/10.1104/pp.18.00907 | DOI Listing |
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