As a great threat to the normal growth of rice, drought not only restricts the growth of rice, but also affects its yield. Glutathione S-transferases (GSTs) have antioxidant and detoxification functions. In rice, GSTs can not only effectively cope with biological stress, but also play a defense role against abiotic stress. In this study, we selected
OsGSTU17, a member gene that was induced by drought, to explore the role of GSTs and analyze their physiological mechanisms that are involved in rice drought tolerance. With the CRISPR/Cas9 knockout system techniques, we obtained two independent mutant lines of
osgstu17. After 14 days of drought stress treatment, and then re-supply of the water for 10 days, the survival rate of the
osgstu17 mutant lines was significantly reduced compared to the wild-type (WT). Similarly, with the 10% (
w/
v) PEG6000 hydroponics experiment at the seedling stage, we also found that compared with the WT, the shoot and root biomass of
osgstu17 mutant lines decreased significantly. In addition, both the content of the MDA and H
2O
2, which are toxic to plants, increased in the
osgtu17 mutant lines. On the other hand, chlorophyll and proline decreased by about 20%. The activity of catalase and superoxide dismutase, which react with peroxides, also decreased by about 20%. Under drought conditions, compared with the WT, the expressions of the drought stress-related genes
OsNAC10,
OsDREB2A,
OsAP37,
OsP5CS1,
OsRAB16C,
OsPOX1,
OsCATA, and
OsCATB in the
osgtu17 mutant lines were significantly decreased. Finally, we concluded that knocking out
OsGSTU17 significantly reduced the drought tolerance of rice;
OsGSTU17 could be used as a candidate gene for rice drought-tolerant cultivation. However, the molecular mechanism of
OsGSTU17 involved in rice drought resistance needs to be further studied.
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