AI Article Synopsis
- Understanding the interaction between water uptake and nutrient acquisition, particularly nitrogen (N), is crucial for predicting how plants react to environmental changes, but existing models show conflicting results.
- A new isotopic labelling method was used to study how trees in different soil N availability areas acquire water and N simultaneously, revealing that trees in high-N areas absorbed twice as much N compared to those in low-N areas, with water uptake being critical for N absorption.
- In low-N environments, water uptake did not enhance N acquisition, indicating that trees adapt their nutrient acquisition strategies significantly based on the nitrogen availability in the soil.
Article Abstract
Understanding how plant water uptake interacts with acquisition of soil nitrogen (N) and other nutrients is fundamental for predicting plant responses to a changing environment, but it is an area where models disagree. We present a novel isotopic labelling approach which reveals spatial patterns of water and N uptake, and their interaction, by trees. The stable isotopes N and H were applied to a small area of the forest floor in stands with high and low soil N availability. Uptake by surrounding trees was measured. The sensitivity of N acquisition to water uptake was quantified by statistical modelling. Trees in the high-N stand acquired twice as much N as in the low-N stand and around half of their N uptake was dependent on water uptake ( H enrichment). By contrast, in the low-N stand there was no positive effect of water uptake on N uptake. We conclude that tree N acquisition was only marginally dependent on water flux toward the root surface under low-N conditions whereas under high-N conditions, the water-associated N uptake was substantial. The results suggest a fundamental shift in N acquisition strategy under high-N conditions.
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| http://dx.doi.org/10.1111/nph.17578 | DOI Listing |
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