Project description:MYB10 and MYB72 are two transcription factors expressed in Arabidopsis roots under iron deficiency. To understand the contribution of these factors, we analyzed gene expression in roots of wild-type (Col) and mutant (myb10myb72 double knockout) seedlings exposed to iron deficiency for 72 hours.

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Project description:Phosphate is an essential macronutrient required for plant growth and development. However, it is present at suboptimal levels in many terrestrial ecosystems. To ameliorate this limitation, plants have evolved developmental and physiological mechanisms known as phosphate starvation responses (PSR). One of the main PSR in Arabidopsis thaliana is a deep restructuration of the root system architecture, which includes a reduction in primary root growth resulting in a shallower root system better adapted to explore the nutrient-rich topsoil. Intense research over the last years has shown that this developmental change is dependent on the accumulation and redistribution of iron (Fe) at the root tip, which in turn, participates in Fenton reactions and generates reactive oxygen species that affect meristem function and cell elongation. We have recently identified and characterized a cytochrome-containing protein in A. thaliana, named CRR, which is involved in the primary root growth response to phosphate starvation. Our results showed that CRR is an ascorbate-dependent ferric-reductase whose expression levels modulates iron distribution pattern in the root, affecting meristem function and cell elongation. Moreover, this activity also has shown to be critical for iron toxicity tolerance since CRR determines the transport rate of iron from root to shoot.

Project description:Phosphate is an essential macronutrient required for plant growth and development. However, it is present at suboptimal levels in many terrestrial ecosystems. To ameliorate this limitation, plants have evolved developmental and physiological mechanisms known as phosphate starvation responses (PSR). One of the main PSR in Arabidopsis thaliana is a deep restructuration of the root system architecture, which includes a reduction in primary root growth resulting in a shallower root system better adapted to explore the nutrient-rich topsoil. Intense research over the last years has shown that this developmental change is dependent on the accumulation and redistribution of iron (Fe) at the root tip, which in turn, participates in Fenton reactions and generates reactive oxygen species that affect meristem function and cell elongation. We have recently identified and characterized a cytochrome-containing protein in A. thaliana, named CRR, which is involved in the primary root growth response to phosphate starvation. Our results showed that CRR is an ascorbate-dependent ferric-reductase whose expression levels modulates iron distribution pattern in the root, affecting meristem function and cell elongation. Moreover, this activity also has shown to be critical for iron toxicity tolerance since CRR determines the transport rate of iron from root to shoot.

Project description:To identify the mechanism of how the microbiota induces lateral root development independently of auxin signalling, we performed a transcriptional analysis using roots of wild type plants and lateral root mutants arf7 arf19, nph4-1, lbd16-1, and gnom184, in mono-association with a selection of 16 bacteria able to restore the lateral root formation in the mutants used.

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