Spatially resolved fluorescence lifetime mapping of enzyme kinetics in living cells

Spatially resolved fluorescence lifetime mapping of enzyme kinetics in living cells

Traditional cuvette-based enzyme studies lack spatial information and do not allow real-time monitoring of the effects of modulating enzyme functions in vivo. In order to probe the realistic timescales of steric modifications in enzyme-substrate complexes and functional binding-unbinding kinetics in...

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Veröffentlicht in:Journal of microscopy (Oxford) 2008-06, Vol.230 (3), p.329-338
Hauptverfasser: RAMANUJAN, V.K, JO, J.A, CANTU, G, HERMAN, B.A
Format: Artikel
Sprache:eng
Schlagworte:
Algorithms
Animals
Electron Transport Complex I - chemistry
Electron Transport Complex I - metabolism
Enzyme kinetics
Hepatocytes - enzymology
Kinetics
lifetime imaging
metabolism
Mice
Microscopy, Fluorescence - methods
Mitochondria - chemistry
Mitochondria - enzymology
multiphoton
NADH
Photons
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container_issue 3
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container_title Journal of microscopy (Oxford)
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creator RAMANUJAN, V.K
JO, J.A
CANTU, G
HERMAN, B.A
description Traditional cuvette-based enzyme studies lack spatial information and do not allow real-time monitoring of the effects of modulating enzyme functions in vivo. In order to probe the realistic timescales of steric modifications in enzyme-substrate complexes and functional binding-unbinding kinetics in living cells without losing spatial information, it is imperative to develop sensitive imaging strategies that can report enzyme kinetics in real time over a wide dynamic range of timescales. Here we present a multi-photon excitation-based, ultra-fast photon detection using a streak camera and Laguerre expansion-based fast deconvolution approach for achieving high spatio-temporal resolution in monitoring real-time enzyme kinetics in single cells. In particular, we report spatially resolved, nanosecond-scale fluorescence dynamics associated with binding-unbinding kinetics of endogenous metabolic co-factor nicotinamide adenine dinucleotide with enzymes in intact living cells. By monitoring real-time kinetics of NAD(P)H-enzyme kinetics in primary hepatocytes isolated from young and aged mouse models, we observed that the mechanism of inhibition of mitochondrial respiration at complex I site is mediated by redistribution of free and protein-bound nicotinamide adenine dinucleotide pools and that this equilibrium redistribution is affected by age-related modifications in mitochondrial function. We describe unique advantages of Laguerre deconvolution algorithm in comparison with conventional lifetime analysis approaches. Non-invasive monitoring of metabolic dysfunctions in intact animal models is an attractive strategy for gaining insight into the dynamics of tissue metabolism in health and in various metabolic syndromes such as cancer, diabetes and aging-induced metabolic dysfunctions. Besides the example demonstrated above, we envisage that the proposed method can find applications in a variety of other situations where intensity-based approaches fall short owing to spectroscopic artefacts.
doi_str_mv 10.1111/j.1365-2818.2008.01991.x
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source Wiley Free Content; MEDLINE; Wiley Online Library Journals Frontfile Complete
subjects Algorithms
Animals
Electron Transport Complex I - chemistry
Electron Transport Complex I - metabolism
Enzyme kinetics
Hepatocytes - enzymology
Kinetics
lifetime imaging
metabolism
Mice
Microscopy, Fluorescence - methods
Mitochondria - chemistry
Mitochondria - enzymology
multiphoton
NADH
Photons
title Spatially resolved fluorescence lifetime mapping of enzyme kinetics in living cells
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