Aerosols can affect the cloud radiative forcing by acting as the cloud condensation nuclei and subsequently changing the micro- and macro-physical properties of clouds. The classical theory states that the increase in CCN concentration results in the decrease of cloud droplet effective radius (Re), thereby inhibiting the coalescence process, which in turn may extend the cloud lifetime, enhance cloud water contents and increase the clod fraction, producing negative radiative forcing. More recent studies focusing on the aerosol-cloud interactions of shallow clouds have suggested that the cloud liquid water path does not necessarily increase with increasing aerosol loading, and the response depends on the precipitation state of the cloud and the thermodynamic conditions of the environment. It is found that the environmental condition in East Asian winter and spring is largely controlled by the monsoonal circulation and the warm sea surface temperature associated with the Kuroshio current. The environmental factors not only affect the types of low clouds but also the aerosol-cloud responses. The current study applies the co-located aerosol and cloud retrievals from the A- train satellites during 2006-2010 to investigate the aerosol-cloud interactions of marine warm clouds in East Asia in winter and spring, the seasons in which the low-level marine clouds and high aerosol pollution coexist most frequently. First, the single-layer warm clouds over the open ocean are identified based on the number of cloud layers detected by Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observations (CALIPSO) and the cloud-top temperature and pressure retrieved from Moderate Resolution Imaging Spectroradiometer (MODIS). The precipitation flag retrieved from the Cloud Profiling Radar on CloudSat are also applied to separate the state of precipitation of the clouds. The clouds are then further classified based on the near-surface stability (NSS) and estimated inversion strength (EIS) to explore variation of the susceptibility of cloud properties under different environmental conditions. As cold continental air moves onto the warm ocean, it destabilizes the marine boundary layer, resulting in the formation of more shallow convective clouds. As the large-scale subsidence associated with the southeastward movement of Siberian high strengthens, the type of clouds transfer from broken clouds into continuous clouds. The cloud susceptibility is stronger for precipitating clouds and under unstable conditions. For non-precipitating clouds, LWP decreases slightly under the stable condition and increases in unstable condition with increasing aerosols. For precipitating clouds, LWP increases with increasing aerosols and increases more under unstable condition. Note that the susceptibility of precipitating clouds is stronger than non- precipitating ones, it results in larger cloud optical depth and cloud albedo. In the future, the susceptibility of precipitation of marine warm clouds will be analyzed by high resolution model in purpose of understanding the unique aerosol-cloud interaction among different cloud types. In addition, the aerosol-cloud radiative forcing during winter and spring in East Asia will also be estimated.