High temperature in the root zone repressed flowering in Lilium × formolongi by disturbing the photoperiodic pathway and reconfiguring hormones and primary metabolism

•High temperature in the root zone caused the inhibition of LD-mediated flowering induction in Lilium×formolongi seedlings.•Through the analysis of gene expression, the key genes in circadian clock and photoperiod pathways were disturbed by root zone heating.•The metabolome analysis revealed the flu...

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Bibliographic Details
Published in:Environmental and experimental botany 2021-12, Vol.192, p.104644, Article 104644
Main Authors: Zhao, Yuqian, Zhang, Qian, Li, Jiewen, Yan, Xiao, He, Hengbin, Gao, Xue, Jia, Guixia
Format: Article
Language:English
Subjects:
Circadian clock
Flowering inhibition
High temperature
Lilium×formolongi
Metabolomics
Photoperiod
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Summary:•High temperature in the root zone caused the inhibition of LD-mediated flowering induction in Lilium×formolongi seedlings.•Through the analysis of gene expression, the key genes in circadian clock and photoperiod pathways were disturbed by root zone heating.•The metabolome analysis revealed the fluctuation of hormones and primary metabolites caused by temperature were flowering regulators.•The work can provide deep understanding on flowering induction in complicated natural environment for lily seedlings. Lilium × formolongi, a facultative long-day (LD) plant, has precocious flowering characteristics, as it can flower within one year from seeds without the need for vernalization. Under normal LD conditions, the seedlings entered the flowering induction phase and bolted with 9−10 rosette leaves at 6 months after sowing. High temperature, especially at the root zone, inhibited bolting of the seedlings in LDs, accompanied by changes in plant shape and rapid expansion of underground bulbs. Low temperature in the natural environment could rapidly reverse the inhibition caused by high temperature, and promote bolting even under non-induced short days. The circadian clock and photoperiod pathways were disturbed at the transcriptional level by high temperature in both leaves and bulbs, such as LfCCA1, LfCRY, LfCOP1, LfFKF1, LfCOLs and LfPIFs. Thus, the flowering integrators LfFT1 and LfSOC1 were suppressed by high temperature. To determine the flowering inhibitors induced by high temperature in the root zone, the metabolome was analyzed under different conditions. ABA and ACC accumulation in the leaves and bulbs respectively during high temperature, was crucial to flowering inhibition possibly via interaction with the circadian clock and photoperiod-dependent pathways. Additionally, under high temperature conditions, D-allose, pentose and glucuronate interconversions and glutathione metabolism in the leaves were significantly activated. After cold exposure, TCA cycle was suppressed and SA, JA and some sugar (D-mannose, D-fructose, D-arabinose and maltotriose) levels were upregulated in the leaves, simultaneously with the vigorous fatty acid metabolism in the bulbs. These metabolic regulations were crucial to the phase transition under different conditions.
ISSN:0098-8472
1873-7307
DOI:10.1016/j.envexpbot.2021.104644