Non-native plant invasion can accelerate global climate change by increasing wetland methane and terrestrial nitrous oxide emissions.

Approximately 17% of the land worldwide is considered highly vulnerable to non-native plant invasion, which can dramatically alter nutrient cycles and influence greenhouse gas (GHG) emissions in terrestrial and wetland ecosystems. However, a systematic investigation of the impact of non-native plant invasion on GHG dynamics at a global scale has not yet been conducted, making it impossible to predict the exact biological feedback of non-native plant invasion to global climate change. Here, we compiled 273 paired observational cases from 94 peer-reviewed articles to evaluate the effects of plant invasion on GHG emissions and to identify the associated key drivers. Non-native plant invasion significantly increased methane (CH 4 ) emissions from 129 kg CH 4 ha -1  year -1 in natural wetlands to 217 kg CH 4 ha -1  year -1 in invaded wetlands. Plant invasion showed a significant tendency to increase CH 4 uptakes from 2.95 to 3.64 kg CH 4 ha -1  year -1 in terrestrial ecosystems. Invasive plant species also significantly increased nitrous oxide (N 2 O) emissions in grasslands from an average of 0.76 kg N 2 O ha -1  year -1 in native sites to 1.35 kg N 2 O ha -1  year -1 but did not affect N 2 O emissions in forests or wetlands. Soil organic carbon, mean annual air temperature (MAT), and nitrogenous deposition (N_DEP) were the key factors responsible for the changes in wetland CH 4 emissions due to plant invasion. The responses of terrestrial CH 4 uptake rates to plant invasion were mainly driven by MAT, soil NH 4 + , and soil moisture. Soil NO 3 - , mean annual precipitation, and N_DEP affected terrestrial N 2 O emissions in response to plant invasion. Our meta-analysis not only sheds light on the stimulatory effects of plant invasion on GHG emissions from wetland and terrestrial ecosystems but also improves our current understanding of the mechanisms underlying the responses of GHG emissions to plant invasion.