Abstract
Tree decline is a global concern and the primary cause is often unknown. Complex interactions between fluctuations in nitrogen (N) and acidifying compounds have been proposed as factors causing nutrient imbalances and decreasing stress tolerance of oak trees. Microorganisms are crucial in regulating soil N available to plants, yet little is known about the relationships between soil N-cycling and tree health. Here, we combined high-throughput sequencing and qPCR analysis of key nitrification and denitrification genes with soil chemical analyses to characterise ammonia-oxidising bacteria (AOB), archaea (AOA) and denitrifying communities in soils associated with symptomatic (declining) and asymptomatic (apparently healthy) oak trees (Quercus robur and Q. petraea) in the United Kingdom. Asymptomatic trees were associated with a higher abundance of AOB that is driven positively by soil pH. No relationship was found between AOA abundance and tree health. However, AOA abundance was driven by lower concentrations of NH4+, further supporting the idea of AOA favouring lower soil NH4+ concentrations. Denitrifier abundance was influenced primarily by soil C:N ratio, and correlations with AOB regardless of tree health. These findings indicate that amelioration of soil acidification by balancing C:N may affect AOB abundance driving N transformations, reducing stress on declining oak trees.
Highlights
Tree health is a global concern as they provide essential ecosystem services, yet significant areas of forests are being lost due to pest and disease outbreaks or environmental change
Our study provides new empirical evidence that asymptomatic oak trees are associated with increased ammonia-oxidising bacteria (AOB) ammonia monooxygenase (amoA) gene abundance, and that this is in turn modulated by soil conditions, notably pH
Soil pH was found to be the key driver of AOB abundance, suggesting that soil pH has an indirect effect on tree health, by supporting AOB abundance and AOBdriven ammonia oxidation
Summary
Tree health is a global concern as they provide essential ecosystem services, yet significant areas of forests are being lost due to pest and disease outbreaks or environmental change. Soils deficient in N may inhibit plant growth, resulting in weaker and slower growing plants, that may be more susceptible to insect attack (e.g. Agrilus) and pathogens [16, 20, 21]. Disentangling the direct and indirect effects of soil N availability on tree health is difficult, largely due to the confounding influences of plant pathogens and insect pests, plant physiology, root microclimate and the soil microbiome [20, 22]
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