FeS has been considered to be one of the constituents of the planetary cores. Many polymorphs are known for FeS, which have superlattice structures related to NiAs-type structures. Under high pressure and high temperature conditions in planetary interiors, the FeS V phase with a simple NiAs-type structure has a wide stability region. At room temperature, FeS undergoes a transition from the high-spin FeS II to the low-spin FeS III around 6 GPa, while FeS V, which is stable at high temperatures, is also considered to be in a high-spin states below 5 GPa and a low-spin states above 10 GPa. In this study, we have investigated the stability region and the equation of state of the high-spin FeS V up to 5 GPa from the high-temperature and high-pressure experiments using synchrotron X-rays. The isothermal bulk modulus of high-spine FeS is about 20% smaller than the bulk modulus of low-spine FeS V determined by Urakawa et al. (2004). The present experiments show that the phase boundary between FeS IV and FeS V is consistent with the Néel temperature at 1 atm. These are important fundamental data for discussing the internal structure of relatively small bodies.