Fatigue crack growth rate of low-alloy steels exposed to a simulated boiling water reactor (BWR) environment was found to be dependent upon the loading frequency and the amount of dissolved hydrogen. The time-dependent crack propagation rate (da/dt) increased as the loading frequency increased under the same water quality and pre-crack length. In addition, the electrochemical corrosion potential (ECP) of low-alloy steel in high temperature pure water, is closely related to the amounts of dissolved oxygen and hydrogen. It was observed that dissolving a little amount of hydrogen, i.e. to lower the ECP, could effectively suppress the crack growth rate (CGR). The CGR data from this study were comparable with those obtained from some well-known CGR prediction models for BWR environments. Combining lower loading frequencies with the addition of a small amount of dissolved hydrogen can result a significant reduction in CGR, an extended lifetime of the material and an increase in operating safety. Finally, a comparison of the fractographs of the low-alloy steel before and after the oxide removal shows that the fracture appearance of EAC (environmentally assisted cracking) reveals mainly cleavage and transgranular cracking (TGC).