Fluorescence is the emission of
light by a
molecule or an
atom that has absorbed light or other
electromagnetic radiation. In most cases, the emitted light has a longer
wavelength, and therefore a lower
photonenergy, than the absorbed radiation. A perceptible example of fluorescence occurs when the absorbed radiation is in the
ultraviolet region of the
electromagnetic spectrum (invisible to the human eye), while the emitted light is in the
visible region; this gives the fluorescent substance a distinct
color that can only be seen when the substance has been exposed to
UV light.
Biofluorescence is fluorescence emitted by a living organism. Biofluorescence requires an external light source and a biomolecular substance that converts absorbed light into a new one. The fluorescent substance absorbs light at one wavelength, often blue or UV, and emits at another, longer wavelength, green, red, or anything in between. In a living organism, the fluorescent agent often is a
protein (or several), but it could be other
biomolecules as well.
Since biofluorescence was discovered in Aequorea victoria and the
green fluorescent protein structure was resolved, many other organisms have been shown to exhibit biofluorescence and many new fluorescent proteins have been discovered.[1][2][3]
Taxonomic range
Plants
Biofluorescence is frequent in plants, and can occur in many of their parts.[4] The biofluorescence in chlorophyll but has been studied since the 1800s.[5] Generally,
chlorophyllfluoresces red,[6] and can be used as a measure of
photosynthetic capabilities,[7][6] or general health.[5] After absorbing light, chlorophyll may fluoresce as part of the physiological processes involved in photosynthesis.[6]
Reproductive organs such as pollen,[8][9] anthers [9] or petals[10] may also fluoresce. These characters may produce a variety of colors depending on the pigment responsible for fluorescence.[10][8][5][9] While it is unclear what the primary function of different kinds of fluorescence are in plants,[4] reproductive characters may biofluoresce as a signal to attract pollinators,[11][9] However, biofluorescence may also attract prey in predatory plants,[12] or serve no function.[5]
Animals
While biofluorescence was first discovered and extensively characterized in invertebrates, recent work has observed biofluorescence in many vertebrates, with discoveries of biofluorescence have been made in salamanders and frogs,[13][14][15] fish,[16][17][18] birds,[19][20][21] and mammals.[22][23][21]
Functions
The function of biofluorescence in each case is not completely known. The fluorescent signal may play a role in inter- and intraspecific communication, such as
camouflage (e.g. corals[24]), attracting mates (e.g. birds[25] and copepods[26]) and symbionts (e.g. corals[3]), or deterring predators.[26]
Other explanations are physiological, with bright color being a side-product of a defense from UV (e.g. the protein sandercyanin,[17] and UV protection of genes in pollen[9]). Bright red fluorescence in the larvae of Acropora millepora coral correlates with the activation of a
diapause-like state that may aid in conserving energy and tolerating heat and other stressors during a long dispersal to novel habitats.[27]
Evolution
Most likely biofluorescence arose multiple times by
convergent evolution.[3][28] Reconstruction experiments suggest the original fluorescent protein was green, and had a simple beta-barrel shape with a
chromophore hidden inside. Different colors of
green fluorescent proteins (GFP), yellow, red, cyan, and amber, are determined by variations in chromophore structure. Red fluorescent proteins chromophore are the most complex and require extra maturation steps. New fluorescent proteins evolved through gene duplication and accumulation of multiple mutations which gradually changed autocatalytic functions and final chromophore structure.[28]
GFP analogs are common, but this is not the only possible structural solution for biofluorescence. In freshwater Japanese eels Anguilla japonica the unique protein UnaG fluoresces by binding
bilirubin, a mechanism very distinct from that of green fluorescent protein.[16] UnaG absorbs blue light and emits green only when the complex with bilirubin is formed. This feature makes UnaG attractive for biomedical assays in exploration of bilirubin-dependent
cellular processes.[29]
Another non-GFP- like fluorescent protein is a blue protein, sandercyanin, from freshwater fish walleye, Sander vitreus, in the North hemisphere. Sandercyanin is seasonally produced, with production peaking in the late summer, and is thought to be a defense against high UV. Sandercyanin binds
biliverdin IXa, and together they form a tetra-homomer which absorbs UV light at 375nm and emits red light at 675nm.[17]
Two species of
catsharks, Cephaloscyllium ventriosum, endemic to the eastern Pacific, and Scyliorhinus retifer, from the western Atlantic, fluoresce by a different mechanism.[18] The fluorescence is produced by brominated tryptophan-kynurenine metabolites, small
aromatic compounds present in the lighter-colored regions of skin on the fish. Dermal features of the shark skin optically enhance the fluorescent signal.[18]