Mechanisms of nitrogen transfer in a model clover-ryegrass pasture: a 15 N-tracer approach.

Purpose: Nitrogen (N) transfer from white clover ( Trifolium repens cv.) to ryegrass ( Lolium perenne cv.) has the potential to meet ryegrass N requirements. This study aimed to quantify N transfer in a mixed pasture and investigate the influence of the microbial community and land management on N transfer.
Methods: Split root ¹⁵ N-labelling of clover quantified N transfer to ryegrass via exudation, microbial assimilation, decomposition, defoliation and soil biota. Incorporation into the microbial protein pool was determined using compound-specific ¹⁵ N-stable isotope probing approaches.
Results: N transfer to ryegrass and soil microbial protein in the model system was relatively small, with one-third arising from root exudation. N transfer to ryegrass increased with no microbial competition but soil microbes also increased N transfer via shoot decomposition. Addition of mycorrhizal fungi did not alter N transfer, due to the source-sink nature of this pathway, whilst weevil grazing on roots decreased microbial N transfer. N transfer was bidirectional, and comparable on a short-term scale.
Conclusions: N transfer was low in a model young pasture established from soil from a permanent grassland with long-term N fertilisation. Root exudation and decomposition were major N transfer pathways. N transfer was influenced by soil biota (weevils, mycorrhizae) and land management (e.g. grazing). Previous land management and the role of the microbial community in N transfer must be considered when determining the potential for N transfer to ryegrass.
Supplementary Information: The online version contains supplementary material available at 10.1007/s11104-022-05585-0.
Competing Interests: Conflicts of interestWe have no conflicts of interest nor competing interests.
(© The Author(s) 2022.)