Chinese Bulletin of Botany ›› 2023, Vol. 58 ›› Issue (4): 622-637.DOI: 10.11983/CBB22087
• SPECIAL TOPICS • Previous Articles Next Articles
Yanan Xu1, Jiarong Yan1, Xin Sun2, Xiaomei Wang3, Yufeng Liu1, Zhouping Sun1, Mingfang Qi1, Tianlai Li1,4,5,6, Feng Wang1,4,5,6()
Received:
2022-04-24
Accepted:
2022-08-24
Online:
2023-07-01
Published:
2022-08-30
Contact:
*E-mail: fengwang@syau.edu.cn
Yanan Xu, Jiarong Yan, Xin Sun, Xiaomei Wang, Yufeng Liu, Zhouping Sun, Mingfang Qi, Tianlai Li, Feng Wang. Red and Far-red Light Regulation of Plant Growth, Development, and Abiotic Stress Responses[J]. Chinese Bulletin of Botany, 2023, 58(4): 622-637.
Figure 1 Regulation of seed germination by phytochromes PHYA: PHYTOCHROME A; PHYB: PHYTOCHROME B; ABA: Abscisic acid; GA: Gibberellic acid. Arrows indicate positive regulation, bars indicate negative regulation, and dotted lines indicate the ambiguous pathways.
Figure 2 The signaling network of phytochrome-regulation of bud outgrowth L-R/FR: Low red to far-red light ratios; phyB: Phytochrome B; phyA: Phytochrome A; PIFs: Phytochrome-interacting factors; CKs: Cytokinins; CKX: CYTOKININ OXIDASE; SLs: Strigolactones; ABA: Abscisic acid. Arrows indicate positive regulation, bars indicate negative regulation.
Figure 3 Regulation of flowering time by phytochromes phyB: Phytochrome B; L-R/FR: Low red to far-red light ratios; R: Red light. Arrows indicate positive regulation, bars indicate negative regulation, and dotted lines indicate the ambiguous pathways.
非生物胁迫 | 光信号因子 | 调控机制 | 参考文献 |
---|---|---|---|
盐害 | phyB | 红光通过phyB诱导脯氨酸合成基因P5CS1和代谢途径基因PDH1的表达, 促进脯氨酸的积累, 提高植物的耐盐性 | Hayashi et al., |
phyB | phyB突变体气孔关闭速度减慢, 水分损失增加, 抗旱性降低 | González et al., | |
干旱 | OsPIL1 | 水稻OsPIL1通过DREB1A正调控植物的耐旱性 | Todaka et al., |
ZmPIF3 | ZmPIF3促进脱落酸介导的气孔关闭, 减少水分损失, 增强抗旱性 | Gao et al., | |
高温 | phyB | 高温使phyB失活, 促进PIF4-BES1复合物通过生长素信号诱导叶片伸长; phyB正调控高温抗性 | Mart?nez et al., |
HY5 | 热形态建成中HY5与PIF4竞争与靶蛋白的结合 | Delker et al., | |
COP1 | 高温使COP1进入细胞核, 通过26S蛋白酶体途径降解HY5 | Park et al., | |
PIF4 | 高温诱导PIF4过度磷酸化, 增强蛋白的稳定性; 高温诱导PIF4蛋白的积累依赖于DET1和COP1 | Foreman et al., | |
TCP5/17 | 高温下, TCP5/17通过调控PIF4活性诱导下胚轴伸长 | Han et al., | |
BBX18/23 | 高温下, BBX18/23通过招募XBAT31/35泛素降解ELF3, 进而促进PIF4活性, 诱导下胚轴伸长 | Ding et al., | |
PIF4/5 | 高温下, PIF4/5通过直接转录激活NAC019和SAG113, 介导热胁迫诱导的叶片衰老过程 | Li et al., | |
SlBBX17 | 高温下, 通过促进SlHSF和SlHSP等基因的表达以及抗氧化物酶活性增高, 增强番茄的耐热性 | Xu et al., | |
低温 | PIF4/7 | PIF4和PIF7负调控CBF的表达和耐低温性 | Lee and Thomashow, |
PIF3 | PIF3负调控植物低温抗性; 低温下, CBF蛋白与PIF3互作, 抑制phyB、EBF1和EBF2对PIF3蛋白的降解 | Jiang et al., | |
SlphyA | SlphyA通过脱落酸与茉莉酸等激素途径正调控番茄的耐低温性 | Wang et al., | |
SlphyB | SlphyB通过负调控CBFs等基因的表达以及光保护抑制番茄的耐低温性 | Wang et al., | |
SlHY5 | SlHY5通过CBF、激素及光保护途径正调控耐低温性 | Wang et al., | |
SlFHY3 | SlFHY3通过肌醇途径正调控番茄的耐低温性 | Wang et al., |
Table 1 Regulatory mechanisms of light signaling factors in response to abiotic stress
非生物胁迫 | 光信号因子 | 调控机制 | 参考文献 |
---|---|---|---|
盐害 | phyB | 红光通过phyB诱导脯氨酸合成基因P5CS1和代谢途径基因PDH1的表达, 促进脯氨酸的积累, 提高植物的耐盐性 | Hayashi et al., |
phyB | phyB突变体气孔关闭速度减慢, 水分损失增加, 抗旱性降低 | González et al., | |
干旱 | OsPIL1 | 水稻OsPIL1通过DREB1A正调控植物的耐旱性 | Todaka et al., |
ZmPIF3 | ZmPIF3促进脱落酸介导的气孔关闭, 减少水分损失, 增强抗旱性 | Gao et al., | |
高温 | phyB | 高温使phyB失活, 促进PIF4-BES1复合物通过生长素信号诱导叶片伸长; phyB正调控高温抗性 | Mart?nez et al., |
HY5 | 热形态建成中HY5与PIF4竞争与靶蛋白的结合 | Delker et al., | |
COP1 | 高温使COP1进入细胞核, 通过26S蛋白酶体途径降解HY5 | Park et al., | |
PIF4 | 高温诱导PIF4过度磷酸化, 增强蛋白的稳定性; 高温诱导PIF4蛋白的积累依赖于DET1和COP1 | Foreman et al., | |
TCP5/17 | 高温下, TCP5/17通过调控PIF4活性诱导下胚轴伸长 | Han et al., | |
BBX18/23 | 高温下, BBX18/23通过招募XBAT31/35泛素降解ELF3, 进而促进PIF4活性, 诱导下胚轴伸长 | Ding et al., | |
PIF4/5 | 高温下, PIF4/5通过直接转录激活NAC019和SAG113, 介导热胁迫诱导的叶片衰老过程 | Li et al., | |
SlBBX17 | 高温下, 通过促进SlHSF和SlHSP等基因的表达以及抗氧化物酶活性增高, 增强番茄的耐热性 | Xu et al., | |
低温 | PIF4/7 | PIF4和PIF7负调控CBF的表达和耐低温性 | Lee and Thomashow, |
PIF3 | PIF3负调控植物低温抗性; 低温下, CBF蛋白与PIF3互作, 抑制phyB、EBF1和EBF2对PIF3蛋白的降解 | Jiang et al., | |
SlphyA | SlphyA通过脱落酸与茉莉酸等激素途径正调控番茄的耐低温性 | Wang et al., | |
SlphyB | SlphyB通过负调控CBFs等基因的表达以及光保护抑制番茄的耐低温性 | Wang et al., | |
SlHY5 | SlHY5通过CBF、激素及光保护途径正调控耐低温性 | Wang et al., | |
SlFHY3 | SlFHY3通过肌醇途径正调控番茄的耐低温性 | Wang et al., |
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