Author
GARCIA-PLAZAOLA, JOSE IGNACIO - University Of Basque Country | |
FERNÁNDEZ-MARÍN, BEATRIZ - University Of Basque Country | |
Duke, Stephen | |
HERNÁNDEZ, ANTONIO - University Of Basque Country | |
LOPEZ-ARBELOA, FERNANDO - University Of Basque Country | |
BECERRIL, JOSE MARIA - University Of Basque Country |
Submitted to: Plant Science
Publication Type: Review Article Publication Acceptance Date: 3/14/2015 Publication Date: 3/21/2015 Publication URL: http://handle.nal.usda.gov/10113/62274 Citation: Garcia-Plazaola, J., Fernández-Marín, B., Duke, S.O., Hernández, A., Becerril, J.M. 2015. Autofluorescences: Biological functions and technical applications. Plant Science. 236:136-145. Interpretive Summary: Fluorescence is the property by which a molecule (fluorophore), excited after the absorption of a photon, is able to de-excite by re-emitting a photon of a longer wavelength. Chlorophylls are the most remarkable examples of plant fluorophores, and their properties have been intensively studied as a useful tool that allows the simple and non-invasive assessment of photosynthesis. However, this is only one example among the many plant fluorophores, such as alkaloids (betalains), phenolics (anthocyanins) and porphyrins, many of which emit fluorescence in the visible portion of the light spectrum. Whether fluorescence is just a physicochemical curiosity in the plant kingdom or whether it plays a functional role in photoprotection or as a cue in biocommunication is subject to active discussion and experimentation. Independently of their putative functions, plant fluorophores provide researchers with a tool to visualize certain metabolites in plants and cells, complementing and overcoming some of the limitations of the use of fluorescent proteins and dyes. As some of these fluorophores are involved in environmental interactions, fluorescence can be also used as a specific stress indicator. Technical Abstract: Fluorescence is the property by which a molecule (fluorophore), excited after the absorption of a photon, is able to de-excite by re-emitting a photon of a longer wavelength. Chlorophylls are the most remarkable examples of plant fluorophores, and their properties have been intensively studied as a useful tool that allows the simple and non-invasive assessment of photosynthesis. However, this is only one example among the many plant fluorophores, such as alkaloids (betalains), phenolics (anthocyanins) and porphyrins, many of which emit fluorescence in the visible portion of the light spectrum. Whether fluorescence is just a physicochemical curiosity in the plant kingdom or whether it plays a functional role in photoprotection or as a cue in biocommunication is subject to active discussion and experimentation. Independently of their putative functions, plant fluorophores provide researchers with a tool to visualize certain metabolites in plants and cells, complementing and overcoming some of the limitations of the use of fluorescent proteins and dyes. As some of these fluorophores are involved in environmental interactions, fluorescence can be also used as a specific stress indicator. |