AISI 301 stainless steel（SS）, a metastable austenite SS, is commonly used in applications requiring severe forming operations such as screw, aircraft and rail car structural components. Since it has a high Md30 temperature（~ 67℃）, the austenite (γ) phase can be transformed partly to α'- and ε-martensites during deformation at room temperature. In this study, the effects of cold work on the microstructure, notched tensile strength and fatigue crack growth behavior were carried out using variously cold-rolled specimens. Notched tensile and fatigue tests were conducted in atmosphere as well as in gaseous hydrogen to study the influence of hydrogen embrittlement on the mechanical properties of 301 SS specimens. Additionally, the SEM fractography and phase identification using electron backscatter diffraction（EBSD）of fractured specimens were examined, and the measurement of α' content was performed on cold-rolled specimens during the tensile tests. The results of notched tensile tests indicated that the susceptibility to hydrogen embrittlement decreased in the order through the CR0 （base metal）, CR30（cold-rolled at room temperature to 30% reduction in thickness）, and HR30（cold-rolled at 150℃ to 30% reduction in thickness） specimens. The notched tensile strengths （NTSs）of the CR0 and HR30 specimens were independent of hydrogen pressure, while the NTS of the CR30 specimen reduced significantly as hydrogen pressure increased. The fracture surfaces of the CR0, HR30 and CR30 specimens in hydrogen exhibited intergranular, transgranular（cleavage）and mixed modes fractures, respectively. During the notched tensile test, the transformation of γ to α'-martensite was relatively slow in the CR0 specimens but rather fast in the HR30 specimens after yielding. EBSD phase identification in the region close to the fracture location revealed that α'-martensite was formed along the grain boundaries in the CR0 specimen and along slip bands in the HR30 specimen during the notched tensile test. The fatigue crack growth rates (FCGRs）in air were found to be the CR0, HR30, and CR30 specimens in order of increasing FCGRs. Although the FCGR of the CR0 specimen was slowest, it increased rapidly with ∆K（stress intensity factor range）due to strongly cyclic hardening. For the specimens tested in gaseous hydrogen, the CR0 specimen had the lowest FCGR, while the HR30 specimen had the highest FCGR. The transformation of γ to α'-martensite was concentrated in the plastic zone ahead of the crack tip, resulting in an accelerated FCGR of the HR30 specimen in hydrogen. The influence of hydrogen embrittlement on the fracture appearance was particularly clear for the CR0 and CR30 specimens with the presence of intergranular fracture.