Root exudate-mediated nutrient exchange in the rhizosphere: multi-element networks, dynamic regulation, and implications for sustainable agriculture

Key Points

Nutrient exchange is heavily influenced by root exudate-mediated interaction networks among macronutrients and micronutrients.
Element interactions adjust to plant growth stages and environmental stresses, promoting adaptability and resilience.
The study highlights the co-evolution of nutrient strategies among plants and microbes in the rhizosphere.
Dynamic regulation of nutrient exchange can support more sustainable agricultural practices amidst soil challenges.

Abstract

Root exudates act as both chemical signals for cross-kingdom communication and metabolic resources. Via root exudate-mediated carbon allocation mechanisms, plants and microbes construct multidimensional interaction networks in the rhizosphere. These networks involve both macronutrients (nitrogen, phosphorus, potassium) and micronutrients (sulfur, iron, zinc), with synergistic regulation between elements. The co-evolved nutrient exchange strategies are highly diverse and precise. They not only regulate nutrient exchange via element interaction networks but also dynamically adjust to plant growth stages, soil conditions, and stresses (e.g., drought, salinity, pathogens). This dynamic adjustment helps plants overcome soil nutrient limitations, thereby enhancing their adaptability to complex environments.

Root exudate-mediated nutrient exchange in the rhizosphere: multi-element networks, dynamic regulation, and implications for sustainable agriculture

Key Points

Abstract

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