In this work, total-ionizing-dose (TID) radiation-induced drain leakage current ( ${I} _{\text {off}}$ ) degradation in p-GaN gate high electron mobility transistors (HEMTs) is studied. Irradiation-induced ${I} _{\text {off}}$ degradation is dominated by source current and substrate current, and irradiation damage mechanism is revealed. Irradiation-induced holes are trapped at GaN channel under the gate and near the buffer/transition layer interface, which would lower energy barrier for electron injection and increase ${I} _{\text {off}}$ . Electron traps are generated in the buffer layer under both irradiation and high electric field, which would raise energy barrier in the buffer for electron and suppress the increase of ${I} _{\text {off}}$ . The combined effect of the hole trapping and the electron trap generation results in nonmonotonic degradation of ${I} _{\text {off}}$ with TID. Deep-level transient spectroscopy and capacitance test results show that irradiation-induced electron trap is not recoverable, while the hole trapping under the gate could anneal with time.