The Community Earth System Model (CESM) coupled to a mixed layer slab ocean is used to understand the seasonal sensitivity of atmospheric tropical circulation to two idealized regional thermal forcings over the Southern Ocean and the equatorial region. In response to heating over the Southern Ocean, an anomalous cross-equatorial overturning circulation with less than 25% variation takes place year-round, transporting air with high geopotential energy toward the Northern Hemisphere through its upper branch and pushing moisture transport toward the Southern Hemisphere through its lower branch. Due to the seasonality of climatological Hadley cell (HC), the anomalous cross-equatorial cell has a stronger effect on the cross-equatorial winter HC and almost no influence on the summer cell. As a result, there are more significant changes in the advection of angular momentum flux and the strength of subtropical jets (STJs) in winter months in both hemispheres. In response to equatorial heating, a dipole of enhanced anomalous HCs develops in the inner tropics, similar to those during El Niño, strengthening both STJs. The anomalous enhanced HC is stronger in summer months, because the anomalous ascending motion caused by the equatorial warming takes place in the summer hemisphere, where the climatological ascending motion occurs. The stronger STJ response during winter months is not as significant as that in the Southern Ocean heating experiment, since the stronger anomalous HC in the summer hemisphere compensates some of the seasonal sensitivity of STJs. Moreover, in both experiments, the seasonality of anomalous HC is tightly linked with sea surface temperature (SST), which is closely related to the seasonality of surface shortwave and latent heat fluxes. The seasonal changes of shortwave and latent heat can be traced back to the seasonal changes of cloud and wind, both of which could be understood and predicted by the properties of their climatological annual cycle. The seasonality of a realistic aerosols forcing experiment in CESM fully-coupled model with the dynamical ocean is compared to that of the two idealized experiments, demonstrating that the mechanisms identified from this simplified modeling study could be useful for understanding the HC and STJ responses to anthropogenic climate change.