Opposite effects of N on warming-induced changes in bacterial and fungal diversity.

The diversity of bacteria and fungi is linked to distinct ecosystem functions, and divergent responses to global changes in these two kingdoms affect the relative contributions of the kingdoms to the soil carbon and nutrient cycles. Climate warming and nitrogen (N) enrichment, which are projected to increase concurrently through modelling efforts, are considered the main drivers of biodiversity loss. However, it is unclear how bacterial and fungal diversity respond differently to the simultaneous occurrence of climate warming and nitrogen enrichment, and the underlying mechanisms involved remain unknown. Using a 9-yr warming and N enrichment experiment in an alpine permafrost area of the Tibetan Plateau, we demonstrated the contrasting response of bacterial and fungal diversity to combined warming and N enrichment, showing a reduction in bacterial richness (8.8%) and an increase in fungal diversity (33.6%). Furthermore, the negative effects of warming on fungal richness were reversed by N enrichment, and the negative effects of nitrogen enrichment on bacteria were amplified by warming. Our results also demonstrated that both biotic interactions, such as bacterial-fungal antagonism, and abiotic factors, primarily the soil C/N ratio and pH, play crucial roles in shaping microbial biodiversity. Our findings suggest that fungal diversity is expected to greatly increase in a warmer and more nitrogen-enriched world, potentially leading to the enhancement of ecosystem functions driven by fungi.