TOR, a widely conserved eukaryotic protein kinase, forms TORC1 and TORC2 to regulate diverse cell signaling. TORC1 controls protein synthesis, cell cycle, and autophagy, whereas TORC2 manages cell polarity, cytoskeleton, and membrane structure. Our previous research found that MoVast2, along with MoVast1, regulates TOR in rice blast fungus Magnaporthe oryzae, maintaining lipid and autophagy balance. Lst8, a key TOR complex component in yeast and mammalian cells. However, the precise role of MoLst8 in M. oryzae is still unclear. In this study, we obtained the DeltaMolst8 mutant through high-through gene knockout strategies. The results showed that loss of MoLST8 leading to a series of defects, such as growth and sporulation reduction, abnormal conidia, and loss of virulence. In addition, this mutant is highly sensitive to rapamycin, leading to growth arrest and autophagy impairment, indicated that MoLst8 positively regulates TORC1 for cellular growth, metabolism, and autophagy. Lipidomics analysis in the mutant revealed lipid metabolism dysregulation, sphingolipid reduction, disrupting membrane tension and homeostasis, suggested that TORC2 mediated lipid regulation is disordered in DeltaMolst8 mutant. Additionally, the study explored TOR-MAPK crosstalk, finding that the mutant shows heightened cell wall stress sensitivity but fails to restore integrity despite MAPK activation. These findings offer insights into MoLst8's role in fungal pathogenesis, contributing to an understanding of fungal biology and disease control strategies.