The C-terminal domain (CTD) of tumour suppressor p53 is an intrinsically disordered protein which has been shown to be able to bind multiple partner proteins and exercise diverse physiological functions in the cell. In this study, we performed molecular dynamics simulations on the isolated p53 CTD, as well as three regulatory binding complexes to investigate the conformational ensemble of isolated p53 CTD and its dynamic structures when different binding partner present. The results demonstrate that the isolated p53 CTD resembles a molten globule rather than extended structure. It mainly adopts random coil conformations with some tendency to form helical structures, which is consistent with experimental observations. For isolated p53 CTD, the dynamics is exclusively dominated by the intrinsic free energy and the p53 CTD could not folded spontaneously to each binding competent state which is located in high free energy region. However, when the binding partners present, the dynamics of p53 CTD are dominated by two mechanisms, the p53 CTD tending to adopt the structure with minimum free energy as isolate existed and the binding energy from partner protein tending to minimum. Each of them has an extreme tendency and corresponds to a possible characteristic state, the random coil state and each binding competent state. The compromise in competition between these two mechanisms results in alternate realisation of different characteristic states, while the relative strength of each mechanism determines the sampling frequency of each characteristic state.