FRET-based glucose imaging identifies glucose signalling in response to biotic and abiotic stresses in rice roots

Glucose is the primary energy provider and the most important sugar-signalling molecule, regulating metabolites and modulating gene expression from unicellular yeast to multicellular plants and animals. Therefore, monitoring intracellular glucose levels temporally and spatially in living cells is an...

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Bibliographic Details
Published in:Journal of plant physiology 2017-08, Vol.215, p.65-72
Main Authors: Zhu, Qingdong, Wang, Li, Dong, Qianli, Chang, Shu, Wen, Kexin, Jia, Shenghua, Chu, Zhilin, Wang, Hanmeng, Gao, Ping, Zhao, Heping, Han, Shengcheng, Wang, Yingdian
Format: Article
Language:English
Subjects:
Abiotic stress
Biotic stress
Chitin
Decoding
Deoxyglucose
Energy measurement
Energy transfer
Fluorescence resonance energy transfer
Fluorescence Resonance Energy Transfer - methods
FRET nanosensor
Gene expression
Gene Expression Regulation, Plant
Genetic code
Glucose
Glucose - metabolism
Glucose dynamics
Intracellular
Metabolites
Oryza - genetics
Oryza - metabolism
Osmotic stress
Physiological responses
Physiology
Plant Proteins - metabolism
Plant Roots - genetics
Plant Roots - metabolism
Plants (botany)
Plants, Genetically Modified - genetics
Plants, Genetically Modified - metabolism
Rice
Selectivity
Signaling
Stimuli
Stresses
Sugar
Yeast
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Summary:Glucose is the primary energy provider and the most important sugar-signalling molecule, regulating metabolites and modulating gene expression from unicellular yeast to multicellular plants and animals. Therefore, monitoring intracellular glucose levels temporally and spatially in living cells is an essential step for decoding the glucose signalling in response to biotic and abiotic stresses. In this study, the genetically encoded FRET (Förster resonance energy transfer) nanosensors, FLIPglu–2μ∆13 and FLIPglu–600μΔ13, were used to measure cytosolic glucose dynamics in rice plants. First, we found that the FRET signal decreased in response to external glucose in a concentration-dependent manner. The glucose concentration at which the cytosolic level corresponded to the K0.5 value for FLIPglu–2μΔ13 was approximately 10.05μM, and that for FLIPglu–600μΔ13 was 0.9mM, respectively. The substrate selectivity of nanosensors for glucose and its analogues is D-Glucose>2-deoxyglucose>3-O-methylglucose>L-Glucose. We further showed that the biotic elicitors (flg22 and chitin) and the abiotic elicitors (osmotic stress, salinity and extreme temperature) induce the intracellular glucose increases in the detached root segments of transgenic rice containing FLIPglu–2μΔ13 in a stimulus-specific manner, but not in FLIPglu–600μΔ13 transgenic lines. These results demonstrated that FRET nanosensors can be used to detect increases in intracellular glucose within the physiological range of 0.2–20μM in response to various stimuli in transgenic rice root cells, which indicated that intracellular glucose may act as a potential secondary messenger to connect extracellular stimuli with cellular physiological responses in plants.
ISSN:0176-1617
1618-1328
DOI:10.1016/j.jplph.2017.05.007