Table 2 BR response to various kinds of high temperature stresses
From: The physiological and molecular mechanism of brassinosteroid in response to stress: a review
Stress | Crop | Year | Remarks | References |
|---|---|---|---|---|
High temperature | Brassica | 2013 | Decreased lipid peroxidation, increase proline contents, protect cell membrane by EBR | [96] |
Heat stress | Tomato | 2005 | EBR increase basic thermotolerance of germinating pollen | [97] |
Heat stress | Rice | 2016 | BER increase pollen fertility, germination rate and reduce the effect of heat stress | [98] |
Heat stress | Brassica | 2002 | EBR increase accumulation and biosynthesis of heat shock protein (HSPs), protect plant form heat stress | [99] |
Lethal heat stress | Tomato/Brassica | 1999 | EBR induce expression of HSPs and significant increase plant survival under heat stress condition | [100] |
High temperature | Rice | 2015 | EBR significantly enhance photosynthetic activity, chlorophyll, yield and yield components under stress | [65] |
Heat drought | Wheat | 2017 | EBR increase significantly photosynthetic capacity by increasing RCA subunit and Rubisco activity under drought and heat stress | [45] |
Thermo-tolerance | Tomato | 2011 | EBR significantly increase photosynthesis, chlorophyll, pollen germination % and bursting % yield and related parameters under heat stress | [101] |
Heat stress | Tomato | 2016 | EBR enhance antioxidant enzyme activity, photosynthesis, chlorophyll fluorescence, electron transport rate and Rubisco activity under heat stress condition | [100] |
Heat stress | Banana | 2004 | EBR significantly increase shoot length, shoot induction %, fresh weight and reduce injury % under heat stress in In vitro condition | [71] |
High temperature stress | Leymus chinensis | 2016 | EBR enhance plant growth, antioxidant enzyme capacity, chlorophyll, GR, under high temperature stress | [102] |