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The floods caused by the extreme precipitation in the Yangtze River basin (YRB) and Murray-Darling River basin (MDRB), the largest basins in China and Australia, have significant impacts on the society and regional economies. Based on the spatial-temporal analysis of the daily precipitation extremes (DPEs) during 1982-2016, we found that for both basins, the whole-basin-type DPEs have the highest proportion and a synchronous DPE interannual vari-ation characteristic exists in the two basins, with the 3-yr running correlation coefficient of the annual DPE days (DPEDs) reaching almost 0.7 (significant at the 0.01 level). The El Ni?o-Southern Oscillation (ENSO), which is one of the most significant climate disturbance factors in the world, plays an important role in modulating the variability of the DPEs in the two basins. Singular value decomposition (SVD) analysis revealed that both the YRB and the MDRB's whole-basin-type DPEs are closely coupled with the procedure that the preceding winter eastern Pacific (EP)-type El Ni?o faded to a central Pacific (CP)-type La Ni?a. This means that the DPEs in the YRB and MDRB may synchronously occur more frequently when the above process occurs. Owing to the atmosphere-ocean interac-tion from the east-west dipole sea surface temperature (SST) anomaly pattern, the atmospheric circulation disturb-ance exhibits a pattern in which the equatorial eastern Pacific region is a mass source anomaly with a higher pressure, drier air, and weaker convection, while the equatorial western Pacific region is a mass sink anomaly with a lower pressure, wetter air, and stronger convection. Moreover, two wave trains that originated from the tropical western Pa-cific were found to extend to the YRB and MDRB. The interaction between the wave train's interphase dynamics and water vapor transport disturbance results in the ascent conditions and enhanced water vapor transport, which leads to the synchronous occurrence of DPEs in the YRB and MDRB on an interannual scale.