Luciferin Explained

Luciferin is a generic term for the light-emitting compound found in organisms that generate bioluminescence. Luciferins typically undergo an enzyme-catalyzed reaction with molecular oxygen. The resulting transformation, which usually involves breaking off a molecular fragment, produces an excited state intermediate that emits light upon decaying to its ground state. The term may refer to molecules that are substrates for both luciferases and photoproteins.^[1]

Types

Luciferins are a class of small-molecule substrates that react with oxygen in the presence of a luciferase (an enzyme) to release energy in the form of light. It is not known just how many types of luciferins there are, but some of the better-studied compounds are listed below.

Because of the chemical diversity of luciferins, there is no clear unifying mechanism of action, except that all require molecular oxygen,^[2] The variety of luciferins and luciferases, their diverse reaction mechanisms and the scattered phylogenetic distribution indicate that many of them have arisen independently in the course of evolution.

Firefly

See main article: Firefly luciferin. Firefly luciferin is the luciferin found in many Lampyridae species, such as P. pyralis. It is the substrate of beetle luciferases (EC 1.13.12.7) responsible for the characteristic yellow light emission from fireflies, though can cross-react to produce light with related enzymes from non-luminous species.^[3] The chemistry is unusual, as adenosine triphosphate (ATP) is required for light emission, in addition to molecular oxygen.^[4]

Snail

Latia luciferin is, in terms of chemistry, (E)-2-methyl-4-(2,6,6-trimethyl-1-cyclohex-1-yl)-1-buten-1-ol formate and is from the freshwater snail Latia neritoides.^[5]

Bacterial

Bacterial luciferin is two-component system consisting of flavin mononucleotide and a fatty aldehyde found in bioluminescent bacteria.^[6]

Coelenterazine

See main article: Coelenterazine. Coelenterazine is found in radiolarians, ctenophores, cnidarians, squid, brittle stars, copepods, chaetognaths, fish, and shrimp. It is the prosthetic group in the protein aequorin responsible for the blue light emission.^[7]

Dinoflagellate

See main article: Dinoflagellate luciferase. Dinoflagellate luciferin is a chlorophyll derivative (i. e. a tetrapyrrole) and is found in some dinoflagellates, which are often responsible for the phenomenon of nighttime glowing waves (historically this was called phosphorescence, but is a misleading term). A very similar type of luciferin is found in some types of euphausiid shrimp.^[8]

Vargulin

See main article: Vargulin. Vargulin is found in certain ostracods and deep-sea fish, to be specific, Poricthys. Like the compound coelenterazine, it is an imidazopyrazinone and emits primarily blue light in the animals.

Fungi

Foxfire is the bioluminescence created by some species of fungi present in decaying wood. While there may be multiple different luciferins within the kingdom of fungi, 3-hydroxy hispidin was determined to be the luciferin in the fruiting bodies of several species of fungi, including Neonothopanus nambi, Omphalotus olearius, Omphalotus nidiformis, and Panellus stipticus.^[9]

Usage in science

Luciferin is widely used in science and medicine as a method of in vivo imaging, using living organisms to non-invasively detect images and in molecular imaging. The reaction between luciferin substrate paired with the receptor enzyme luciferase produces a catalytic reaction, generating bioluminescence.^[10] This reaction and the luminescence produced is useful for imaging such as detecting tumors from cancer or capable of measuring gene expression.

External links

• Web site: Major luciferin types . 2009-01-09 . The Bioluminescence Web Page . . 2009-03-06.

Notes and References

1. Hastings JW . Chemistries and colors of bioluminescent reactions: a review . Gene . 173 . 1 Spec No . 5–11 . 1996 . 8707056 . 10.1016/0378-1119(95)00676-1 .
2. Hastings JW . Biological diversity, chemical mechanisms, and the evolutionary origins of bioluminescent systems . Journal of Molecular Evolution . 19 . 5 . 309–321 . 1983 . 6358519 . 10.1007/BF02101634 . 1983JMolE..19..309H . 875590 .
3. Viviani VR, Bechara EJ . Larval Tenebrio molitor (Coleoptera: Tenebrionidae) Fat Body Extracts Catalyze Firefly D-Luciferin-and ATP-Dependent Chemiluminescence: A Luciferase-like Enzyme . Photochemistry and Photobiology . 63 . 6 . 713–718 . 1996 . 10.1111/j.1751-1097.1996.tb09620.x . 83498776 .
4. Green A, Mcelroy WD . Function of adenosine triphosphate in the activation of luciferin . Archives of Biochemistry and Biophysics . 64 . 2 . 257–271 . October 1956 . 13363432 . 10.1016/0003-9861(56)90268-5 .
5. http://www.orenza.u-psud.fr/query_by_ec.php?EC_number=EC%201.14.99.21 EC 1.14.99.21
6. Madden D, Lidesten BM . 2001 . Bacterial illumination . Bioscience Explained . 1 . 1.
7. Shimomura O, Johnson FH . Chemical nature of bioluminescence systems in coelenterates . Proceedings of the National Academy of Sciences of the United States of America . 72 . 4 . 1546–1549 . April 1975 . 236561 . 432574 . 10.1073/pnas.72.4.1546 . free . 1975PNAS...72.1546S .
8. Dunlap JC, Hastings JW, Shimomura O . Crossreactivity between the light-emitting systems of distantly related organisms: Novel type of light-emitting compound . Proceedings of the National Academy of Sciences of the United States of America . 77 . 3 . 1394–1397 . March 1980 . 16592787 . 348501 . 10.1073/pnas.77.3.1394 . free . 1980PNAS...77.1394D .
9. Purtov KV, Petushkov VN, Baranov MS, Mineev KS, Rodionova NS, Kaskova ZM, Tsarkova AS, Petunin AI, Bondar VS, Rodicheva EK, Medvedeva SE, Oba Y, Oba Y, Arseniev AS, Lukyanov S, Gitelson JI, Yampolsky IV . 6 . The Chemical Basis of Fungal Bioluminescence . Angewandte Chemie . 54 . 28 . 8124–8128 . July 2015 . 26094784 . 10.1002/anie.201501779 .
10. Badr CE, Tannous BA . Bioluminescence imaging: progress and applications . Trends in Biotechnology . 29 . 12 . 624–633 . December 2011 . 21788092 . 4314955 . 10.1016/j.tibtech.2011.06.010 .