Plants, being immobile and cannot escape from their habitat, are vulnerable to various environmental stresses. One of the most typical stress plants encounte is high temperature stress. Heat stress can cause serious injuries to plants, including structural damage of membrane and inhibition of enzyme activities that will eventually leading to plant death. In order to identify genetic determinants that are essential for plant heat tolerance, with the ultimate goal of improving crop heat tolerance through genetic engineering, we have used a forward genetic approach to screen for heat-intolerant mutants of Arabidopsis after ethyl-methane sulfonate (EMS) -mutagenesis. Two of the mutants, hit3 and et were isolated because of their inability to tolerate sustained high temperature stress. To identify the mutated loci of hit3 and et, we employed map-based cloning procedures. Results indicated that hit3 is located at a region between AGI map 3,104 kb and 3,143 kb of the chromosome Ⅴ. The et locus is mapped to At5g10010. The mutation of et is a single nucleotide change from C to A. ET encodes a novel protein of 434 amino acids. NCBI protein blast, PredictProtein and NetNES 1.1 Server analysis indicate that ET protein contains a strong nuclear localization signal sequence (NLS) and is predicted to subcellularly localized to nucleus. These result suggest that the physiological role of ET is involved in nuclear function by which plant can survive under heat stress condition. Meanwhile, et was found to exhibit hypersensitivity to heat shock, abscisic acid and paraquat as well, suggesting that ET also participate in protecting plants from other forms of stresses.