SA533B low-alloy steel is the material mainly used for the reactor pressure vessels (RPVs) of nuclear power plants. This report is focused on the effects of dissolved oxygen content in feed water, strain amplitude and sulfur content in steel on the low-cycle fatigue (LCF) behavior of SA533B RPV steel in circulating water environments at a pressure of 10 MPa and a temperature of 300℃. The test results show the effect of strain amplitude can be studied from the perspectives of mechanical force of fatigue, fatigue-corrosioin interaction, low-cycle fatigue limit and cyclic hardening. The most significant fatigue-corrosion interaction occurred in a water environment saturated with dissolved oxygen under a strain amplitude of 0.2%. The variation of low-cycle fatigue limit is deeply affected by the change of test environments. The low-cycle fatigue life of the RPV steel is obviously varied with the dissolved oxygen content in the water environment. The best low-cycle fatigue resistance of SA533B steel was observed with the specimens tested in air at 300℃, which could be related with the dynamic strain aging (DSA). No or little dependence of fatigue life on sulfur content in steel was noted under the present test conditions. The fracture appearance and morphology were examined and discussed.