Quantitative in vivo imaging of neuronal glucose concentrations with a genetically encoded fluorescence lifetime sensor

Glucose is an essential source of energy for the brain. Recently, the development of genetically encoded fluorescent biosensors has allowed real time visualization of glucose dynamics from individual neurons and astrocytes. A major difficulty for this approach, even for ratiometric sensors, is the l...

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Bibliographic Details
Published in:Journal of neuroscience research 2019-08, Vol.97 (8), p.946-960
Main Authors: Díaz‐García, Carlos Manlio, Lahmann, Carolina, Martínez‐François, Juan Ramón, Li, Binsen, Koveal, Dorothy, Nathwani, Nidhi, Rahman, Mahia, Keller, Jacob P., Marvin, Jonathan S., Looger, Loren L., Yellen, Gary
Format: Article
Language:English
Subjects:
Astrocytes
Biosensors
Brain
Brain slice preparation
Coding
energy metabolism
Fluorescence
Fluorescence lifetime sensing devices
fluorescent biosensor
Genetic code
Glucose
glucose metabolism
Hippocampus
Neuroimaging
Neurons
Proteins
Sapphire
Sensors
Temperature
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Summary:Glucose is an essential source of energy for the brain. Recently, the development of genetically encoded fluorescent biosensors has allowed real time visualization of glucose dynamics from individual neurons and astrocytes. A major difficulty for this approach, even for ratiometric sensors, is the lack of a practical method to convert such measurements into actual concentrations in ex vivo brain tissue or in vivo. Fluorescence lifetime imaging provides a strategy to overcome this. In a previous study, we reported the lifetime glucose sensor iGlucoSnFR‐TS (then called SweetieTS) for monitoring changes in neuronal glucose levels in response to stimulation. This genetically encoded sensor was generated by combining the Thermus thermophilus glucose‐binding protein with a circularly permuted variant of the monomeric fluorescent protein T‐Sapphire. Here, we provide more details on iGlucoSnFR‐TS design and characterization, as well as pH and temperature sensitivities. For accurate estimation of glucose concentrations, the sensor must be calibrated at the same temperature as the experiments. We find that when the extracellular glucose concentration is in the range 2–10 mM, the intracellular glucose concentration in hippocampal neurons from acute brain slices is ~20% of the nominal external glucose concentration (~0.4–2 mM). We also measured the cytosolic neuronal glucose concentration in vivo, finding a range of ~0.7–2.5 mM in cortical neurons from awake mice.
ISSN:0360-4012
1097-4547
DOI:10.1002/jnr.24433