Abstract
Nutrient resorption from senesced leaves is an important mechanism for nutrient conservation in plants. However, little is known about the effect of grazing on plant nutrient resorption from senesced leaves, especially in semiarid ecosystems. Here, we evaluated the effects of grazing on N and P resorption in the three most dominant grass species in a typical steppe in northern China. We identified the key pathways of grazing-induced effects on N and P resorption efficiency. Grazing increased N and P concentrations in the green leaves of Leymus chinensis and Stipa grandis but not in Cleistogenes squarossa. Both L. chinensis and S. grandis exhibited an increasing trend of leaf N resorption, whereas C. squarrosa recorded a decline in both leaf N and P resorption efficiency under grazing. Structural equation models showed that grazing is the primary driver of the changes in N resorption efficiency of the three dominant grass species. For L. chinensis, the P concentration in green and senesced leaves increased the P resorption efficiency, whereas the senesced leaf P concentration played an important role in the P resorption efficiency of C. squarrosa. Grazing directly drove the change in P resorption efficiency of S. grandis. Our results suggest that large variations in nutrient resorption patterns among plant species depend on leaf nutritional status and nutrient-use strategies under overgrazing, and indicate that overgrazing may have indirect effects on plant-mediated nutrient cycling via inducing shifts in the dominance of the three plant species.
Highlights
Plant growth is limited by nutrient availability and uptake in various ecosystems (Chapin III, 1980)
Compared with the grazing exclusion plot, the high green leaf nitrogen contents (Ns) concentration recorded for the dominant species (L. chinensis, S. grandis, and C. squarrosa) in the long-term grazing plot may be attributed to increased synthesis of protein by the ribosome to aid plant growth after successive grazing (Elser et al, 2000; Ma et al, 2019)
With respect to plant nutrient resorption efficiency, our results suggest that the divergent response of leaf N and P resorption efficiency pattern to overgrazing between the three species most likely resulted from the differences in biological features and resource-use strategies
Summary
Plant growth is limited by nutrient availability and uptake in various ecosystems (Chapin III, 1980). Leaf nutrient resorption is a key process that controls nutrient fluxes from plants to soil and the nutrients available for storage and reuse (Millard & Proe, 1993). When plants reuse these nutrients, it improves their nutrient retention and adaptability to the. Many studies have reported the effect of climate change factors such as temperature (Yuan & Chen, 2009), nitrogen addition (Lü et al, 2013) and precipitation (Lü et al, 2012) on nutrient resorption in plants. There is a paucity of information on how grazing impacts nutrient resorption in plants and this study sought to fill this knowledge gap
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