Heat stress is a serious abiotic stress that affects plant survival and crop production. Plants have evolved diverse mechanisms to adapt to stressful conditions. Understanding the heat stress defense mechanisms of plants and enhancing their thermotolerance are critical issues for improving crop production and yield. To identify genetic determinants that are essential for plant heat tolerance, we used a forward genetic approach to isolate and characterize the heat-intolerant mutants. hit2 was isolated by growth inhibition under sustained high temperature conditions. The basal thermotolerance of hit2 to heat shock was also impaired. Furthermore, the growth and development of hit2 seedlings were more sensitive to inhibition with methyl viologen than those of wild-type seedlings, and the survival rate of hit2 seedlings in response to heat stress was affected by light exporsure, suggesting that hit2 is also hypersensitive to oxidative stress. The mutated locus was mapped to EXPORTIN 1A, which encodes a nuclear export receptor. These results demonstrated that a nuclear transport receptor that regulates nucleo-cytoplasmic trafficking is not necessary for normal growth and development, but this receptor is vital for plant heat tolerance, in part, by mediating the protection of plants against heat-induced oxidative stress. hit1-1 is another heat-intolerant mutant of Arabidopsis. HIT1 encodes a homolog of the yeast VPS53p protein that mediates the recognition between vesicles in retrograde trafficking and the late Golgi. HIT1 can interact with AtVPS52 and AtVPS54 to form the Golgi-associated retrograde protein complex. Mutations of HIT1 led to reduced pollen tube length and plasma membrane thermostability. Furthermore, hit1-1 was hypersensitive to long-term heat stress but not to sudden heat shock. This phenomenon correlates with the known effect of impaired membrane remodeling. These results imply that HIT1 participates in the vesicle trafficking required for pollen tube elongation and the thermal adaptation of the plasma membrane in response to long-term heat stress.