The effect of four kinds of prior-microstructure on the impact toughness of the modified JIS SKD61 hot work tool steel was investigated in this study. These four kinds of prior-microstructure are the macro-segregation which causes the alloy content deviation in the different ingot position, the micro-segregation which causes the segregation band, the carbide morphology and the non-metallic inclusion. The specimens were extracted from commercial ingots and were divided into two groups, the surface and center material. In order to evaluate more kinds of the prior-microstructure, the specimens were annealed by two kinds of processes. In order to compare the toughness, the specimens were heated slowly and quenched at two kinds of the specific rate to simulate the quenching thermal history of the center of the 100mm and 300mm thick molds, then were tempered to the same hardness. For understanding the effect of the prior-microstructure on the austenite grain growing during quenching, the observation specimens were prepared to reveal the grain boundary clearly. After observing the prior-microstructure and comparing the hardness, quenched-tempered microstructure, the effect of the prior-microstructure on the impact toughness was verified. The results are as follow: 1. The severe band segregation of the center material of the ingots induces the lower toughness than the surface one in the untreated and annealed states. 2. The specific prior-microstructure, the degenerate pearlite and acicular ferrite, induces its quenched-tempered microstructure much coarser than the one with the well-spheroidized prior-microstructure. 3. The toughness significantly affected by the band segregation and the size of the non-metallic inclusion, not the austenite grain size. 4. The toughness could be improved by breaking the carbide-networks through a proper annealing process. 5. The relatively high concentration of the micro non-metallic inclusion in the ESR steel may reduce the advantage of less sulfur on the toughness.