Catálogo de publicaciones - revistas

<jats:title>Abstract</jats:title><jats:sec> <jats:title>Background</jats:title> <jats:p>The rhizosphere is the interface between roots and the soil and the site of nutrient and water uptake for plant growth. Root anatomy and the physical, chemical, and biological components of the rhizosphere interact to influence plant growth. Several root developmental and rhizosphere signals combine in the patterning of root cortical anatomy and have implications for the plant’s hydro-mineral nutrition and carbon partitioning and therefore crop productivity, especially in edaphic stress.</jats:p> </jats:sec><jats:sec> <jats:title>Scope</jats:title> <jats:p>Here, we highlight how mutualistic mycorrhizal fungi from the rhizosphere mobilize plant molecular actors controlling root anatomical traits, including cortical cell size, to facilitate their establishment and accommodation within the cortex. We explore the effects on plant growth and stress tolerance that may result from the changes in root anatomy driven by interactions with arbuscular mycorrhizal fungi, including altering the metabolic efficiency required for nutrient exploitation. We also discuss opportunities for understanding the genetic control of root anatomy and rhizosphere interactions to enable a comprehensive understanding of the benefits and trade-offs of root-rhizosphere interactions for more productive crops.</jats:p> </jats:sec>

<jats:title>Abstract</jats:title><jats:sec> <jats:title>Background</jats:title> <jats:p>As the world grapples with increasing agricultural demands and unpredictable environmental stressors, there is a pressing need to improve plant resilience. Therefore, understanding the pioneering role of nanoparticles in alleviating plant stress is crucial for developing stress-resilient varieties to enhance food secure world. Nanoparticles have unique physical and chemical properties, and demonstrate their potential to enhance plant growth, nutrient utilization, and stress tolerance. This review delves into the mechanistic insights of nanoparticle-plant interactions, highlighting how these tiny particles can mitigate diverse stressors such as drought, salinity, and heavy metal toxicity. The action of different types of nanoparticles, including metal, carbon-based, and biogenic nanoparticles, are discussed in the context of their interaction with plant physiology and stress responses.</jats:p> </jats:sec><jats:sec> <jats:title>Aims</jats:title> <jats:p>This article also explores the potential drawbacks and environmental implications of nanoparticle use, emphasizing the need for responsible and sustainable applications. Therefore, this study aimed to offer exciting possibilities for managing both biotic and abiotic stress in plant species, from improving water-use efficiency and stress resilience via nanotechnology.</jats:p> </jats:sec><jats:sec> <jats:title>Conclusions </jats:title> <jats:p>Future research directions are suggested, focusing on nano-bioengineering and precision agriculture to create stress-resilient crops and enhance food security. Through the lens of interdisciplinary research, this paper underscores the significance of nanoparticles as innovative tools in the realm of agriculture, catalyzing a paradigm shift towards sustainable and stress-resilient farming systems.</jats:p> </jats:sec>

<jats:title>Abstract</jats:title><jats:sec> <jats:title>Background and aims</jats:title> <jats:p>Nickel (Ni) deficiency has been reported to occur in soybean (<jats:italic>Glycine max</jats:italic>) grown on leached tropical soils in Brazil. We aimed to determine whether an internal or external Ni supply can compensate for low Ni within the seed by assessing whether the amount of Ni in the seed whether the foliar-application of aqueous NiSO<jats:sub>4</jats:sub> influenced the uptake of Ni by the leaf, the nutritional status of the plant, urease activity and growth.</jats:p> </jats:sec><jats:sec> <jats:title>Methods</jats:title> <jats:p>We used Ni-depleted seeds (&lt;0.35 μg Ni per g) and Ni-sufficient seeds (11.1 μg Ni g<jats:sup>−1</jats:sup>) for hydroponic experiments. Seedlings were grown either with or without an external Ni supply (0 or 0.85 μM Ni in nutrient solution) and either with or without an internal Ni supply (with or cotyledons removed). In addition, we used synchrotron-based micro-X-ray fluorescence analysis to examine the distribution of foliar-applied Ni (50 and 100 mg L<jats:sup>-1</jats:sup>).</jats:p> </jats:sec><jats:sec> <jats:title>Key results</jats:title> <jats:p>Leaf Ni concentration and urease activity were both enhanced by increasing either the internal (cotyledon seed store) or external (solution) Ni supply. In addition, plants derived from Ni-depleted seed that received external Ni supply had 9.2% higher biomass relative to plants derived from Ni-sufficient seeds which received Ni. When foliar-applied, Ni accumulated in the pedicles of the trichomes within 15 minutes of application, and then moved to the vascular bundles before dispersing further into tissues within 3 hours.</jats:p> </jats:sec><jats:sec> <jats:title>Conclusions</jats:title> <jats:p>Trichomes are an important pathway for foliar Ni absorption in soybean, but there are still major knowledge gaps our understanding of the physiological function of trichomes in the uptake of metal ions from foliar micro-nutrient treatments.</jats:p> </jats:sec>