Cell-specific regulation of TCA cycle and cell division related genes at roots following aluminium exposure

Aluminium (Al) toxicity is a critical factor that limits plant growth in acidic soils (pH < 5.5) worldwide. Intracellular Al can bind to various biomolecules and significantly affect gene expression, protein biosynthesis, and cell membrane integrity, ultimately inhibiting nutrients and water uptake. This leads to the arrest of root cell divisions and growth. Organic acids (OAs) produced in mitochondrial-related reactions are strongly linked to Al tolerance, as they bind to Al and neutralize its toxic effects. Recently, the manipulation of root cell divisions through DNA checkpoints has been proposed as an alternative to increase Al tolerance. In this context, molecular interactions between these two mechanisms could potentially enhance plant tolerance to Al toxicity. Here, we investigate this topic using a translatome approach, which enables specific analyses of root cell types (namely, whole root, the quiescent centre region, and the cortical region). This approach offers a promising tool for unravelling how mitochondrial metabolism, particularly the TCA cycle, and the DNA damage response (DDR) pathway are interconnected in Al-mitigation process. Our results revealed that the TCA cycle is induced in differentiated cells, with no significant alteration in meristematic cells, while genes associated with cell cycle progression and DNA checkpoints show differential expression across the distinct cell types. Collectively, our data contribute to understand cell-specific internal detoxification mechanism related to Al tolerance in plants. This knowledge could assist crop breeding by providing a better understanding of the cellular physiological responses to Al toxicity.