Cadmium accumulation suppresses rice nitrogen use efficiency by inhibiting rhizosphere nitrification and promoting nitrate reduction

Cadmium (Cd) pollution significantly disrupts paddy soil nitrogen (N) availability and impairs rice nitrogen use efficiency (NUE). However, most existing studies rely on microcosm or pot experiments, with limited field-based manipulative studies involving Cd addition. The regulatory mechanisms by which N transformation processes influence rice N utilization under Cd stress remain poorly understood. In this study, a field experiment incorporating multiple levels of Cd addition was conducted to address this gap. Plant traits, nutrient content, and microbial community characteristics in rhizosphere and bulk soils were examined through soil chemical analysis, metagenomic sequencing, and bioinformatics approaches. The results demonstrated that microbial communities, soil N transformation potential, and rice NUE responded to Cd addition in a dose-dependent manner, with rhizosphere soils exhibiting greater sensitivity than bulk soils. Cd addition reduced dissolved organic carbon (DOC), NH₄⁺-N, and NO₃⁻-N in rhizosphere soil, while increasing total and available phosphorus (P) contents in both rhizosphere and bulk soils. Although Cd addition enhanced aboveground biomass and total N uptake, it led to a decline in plant N concentration and NUE. Moreover, Cd accumulation markedly suppressed the abundance of nitrification genes while promoting genes involved in dissimilatory nitrate reduction to ammonium (DNRA) and denitrification. Overall, Cd stress altered microbial community structure and soil N and P availability, thereby impairing rice N uptake and NUE. These findings suggest that acute Cd exposure rapidly disrupts microbial ecology, decouples the soil N cycle, and reduces N supply potential of paddy soils and rice NUE, ultimately threatening agroecosystem stability in southern China. These impacts warrant greater consideration in future farmland management strategies.