Under climate change scenarios, optimizing water and fertilizer management measures to mitigate the negative impacts of climate change on rice production in Southwest China can provide a theoretical basis for the sustainability of rice production in this region. The APSIM?ORYZA model was used to simulate and analyze the impacts of different irrigation modes (conventional flooding irrigation (CK) and controlled irrigation (I1, I2, I3, with lower limits of 50%, 70%, and 90% of the soil available moisture content and upper limits of the field capacity)) and combined application of organic and inorganic fertilizers (20% (F1), 40% (F2), 60% (F3) organic fertilizer substitution) on rice yield, soil organic carbon, and total nitrogen in Southwest China under the future SSP2?4.5 and SSP5?8.5 climate scenarios. The results showed that different future climate change scenarios had negative impacts on rice yield in Southwest China, but the yield reduction rate was decreased with the increase in irrigation water volume. Compared with the historical baseline period, in the 2050s under the SSP2?4.5 scenario, the rice yields of the I1, I2, I3, and CK treatments were decreased by 6.9%, 5.8%, 5.7%, and 5.3%, respectively;by the 2080s, the yield reduction rate of the CK treatment was increased to 8.7%, and those of the I1~I3 treatments were increased to 10.1%, 9.1%, and 8.9%, respectively. In addition, the rice yields of the controlled irrigation treatments were generally decreased in the order of I3, I2, I1, all of which were lower than that of the CK, and different irrigation modes had little impact on soil organic carbon. However, in the 2080s under the SSP5?8.5 scenario, the rice yield of the I3 treatment in Yunnan Province was equal to that of the flooding irrigation. With the increase in the organic fertilizer substitution ratio, the rice yield was firstly increased and then decreased. Compared with the conventional fertilization rate, under the SSP2?4.5 scenario, the rice yields of the F1 and F2 treatments were increased by 91 kg/hm2 and 27 kg/hm2, respectively, while that of the F3 treatment was decreased by 232 kg/hm2;under the SSP5?8.5 scenario, the rice yields of the F1 and F2 treatments were increased by 97 kg/hm2 and 43 kg/hm2, respectively, while that of the F3 treatment was decreased by 155 kg/hm2. Moreover, under different future climate change scenarios, organic fertilizer substitution could significantly increase the soil organic carbon and total nitrogen contents of rice in Southwest China. Under the future SSP2?4.5 (SSP5?8.5) climate scenario, the soil organic carbon contents of the F1, F2, and F3 treatments in the 2050s were 209 (213) kg/hm2, 347 (336) kg/hm2, 346 (355) kg/hm2 respectively, which were increased by 71 (80) kg/hm2, 209 (203) kg/hm2, 208 (222) kg/hm2, respectively compared with that of CK;the soil organic carbon contents of the F1, F2, and F3 treatments in the 2080s were 318 (323) kg/hm2, 554 (533) kg/hm2, 523 (541) kg/hm2, respectively, which were increased by 159 (167) kg/hm2, 395 (376) kg/hm2, 364 (385) kg/hm2, respectively compared with that of CK. Under the water?fertilizer coupling treatment, the F1I3 treatment had the best yield?increasing effect. Compared with the conventional water and fertilizer management, this combination increased the yield by 45~186 kg/hm2 under the SSP2?4.5 scenario and by 38~185 kg/hm2 under the SSP5?8.5 scenario. The research result showed that moderate coordinated water and fertilizer management can effectively increase rice yield and improve soil fertility in Southwest China under the background of future climate warming, promoting the sustainable development of agricultural production.