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Luciferase

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Bacterial Luciferase monooxygenase family
Identifiers
SymbolBac_luciferase
PfamPF00296
InterProIPR016048
PROSITEPDOC00397
SCOP21nfp / SCOPe / SUPFAM
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
PDB1brl​, 1bsl​, 1ezw​, 1fvp​, 1luc​, 1m41​, 1nfp​, 1nqk​, 1rhc​, 1xkj
Dinoflagellate Luciferase catalytic domain
crystal structure of a luciferase domain from the dinoflagellate Lingulodinium polyedrum
Identifiers
SymbolLuciferase_cat
PfamPF10285
InterProIPR018804
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
Dinoflagellate Luciferase/LBP N-terminal domain
Identifiers
SymbolLuciferase_N
PfamPF05295
InterProIPR007959
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
Dinoflagellate Luciferase helical bundle domain
Identifiers
SymbolLuciferase_3H
PfamPF10284
InterProIPR018475
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary

Luciferase is a generic term for the class of oxidative enzymes that produce bioluminescence, and is usually distinguished from a photoprotein. The name was first used by Raphaël Dubois who invented the words luciferin and luciferase, for the substrate and enzyme, respectively.[1] Both words are derived from the Latin word lucifer, meaning "lightbearer", which in turn is derived from the Latin words for "light" (lux) and "to bring or carry" (ferre).[2]

Firefly luciferase
Structure of Photinus pyralis firefly luciferase.
Identifiers
OrganismPhotinus pyralis
SymbolFirefly luciferase
PDB1LCI More structures
UniProtP08659
Other data
EC number1.13.12.7
Search for
StructuresSwiss-model
DomainsInterPro

Luciferases are widely used in biotechnology, for bioluminescence imaging[3] microscopy and as reporter genes, for many of the same applications as fluorescent proteins. However, unlike fluorescent proteins, luciferases do not require an external light source, but do require addition of luciferin, the consumable substrate.

Examples

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A variety of organisms regulate their light production using different luciferases in a variety of light-emitting reactions. The majority of studied luciferases have been found in animals, including fireflies,[4] and many marine animals such as copepods, jellyfish, and the sea pansy. However, luciferases have been studied in luminous fungi, like the Jack-O-Lantern mushroom, as well as examples in other kingdoms including bioluminescent bacteria, and dinoflagellates.

Firefly and click beetle

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The luciferases of fireflies – of which there are over 2000 species – and of the other Elateroidea (click beetles and relatives in general) are diverse enough to be useful in molecular phylogeny.[5] In fireflies, the oxygen required is supplied through a tube in the abdomen called the abdominal trachea. One well-studied luciferase is that of the Photinini firefly Photinus pyralis, which has an optimum pH of 7.8.[6]

Sea pansy

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Also well studied is the sea pansy, Renilla reniformis. In this organism, the luciferase (Renilla-luciferin 2-monooxygenase) is closely associated with a luciferin-binding protein as well as a green fluorescent protein (GFP). Calcium triggers release of the luciferin (coelenterazine) from the luciferin binding protein. The substrate is then available for oxidation by the luciferase, where it is degraded to coelenteramide with a resultant release of energy. In the absence of GFP, this energy would be released as a photon of blue light (peak emission wavelength 482 nm). However, due to the closely associated GFP, the energy released by the luciferase is instead coupled through resonance energy transfer to the fluorophore of the GFP, and is subsequently released as a photon of green light (peak emission wavelength 510 nm). The catalyzed reaction is:[7]

Copepod

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Newer luciferases have recently been identified that, unlike other luciferases, are naturally secreted molecules. One such example is the Metridia coelenterazine-dependent luciferase (MetLuc, A0A1L6CBM1) that is derived from the marine copepod Metridia longa. The Metridia longa secreted luciferase gene encodes a 24 kDa protein containing an N-terminal secretory signal peptide of 17 amino acid residues. The sensitivity and high signal intensity of this luciferase molecule proves advantageous in many reporter studies. Some of the benefits of using a secreted reporter molecule like MetLuc is its no-lysis protocol that allows one to be able to conduct live cell assays and multiple assays on the same cell.[8]

Bacterial

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Bacterial bioluminescence is seen in Photobacterium species, Vibrio fischeri, Vibrio haweyi, and Vibrio harveyi. Light emission in some bioluminescent bacteria utilizes 'antenna' such as lumazine protein to accept the energy from the primary excited state on the luciferase, resulting in an excited lulnazine chromophore which emits light that is of a shorter wavelength (more blue), while in others use a yellow fluorescent protein (YFP) with flavin mononucleotide (FMN) as the chromophore and emits light that is red-shifted relative to that from luciferase.[9]

Dinoflagellate

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Dinoflagellate luciferase is a multi-domain eukaryote protein, consisting of an N-terminal domain, and three catalytic domains, each of which preceded by a helical bundle domain. The structure of the dinoflagellate luciferase catalytic domain has been solved.[10] The core part of the domain is a 10 stranded beta barrel that is structurally similar to lipocalins and FABP.[10] The N-terminal domain is conserved between dinoflagellate luciferase and luciferin binding proteins (LBPs). It has been suggested that this region may mediate an interaction between LBP and luciferase or their association with the vacuolar membrane.[11] The helical bundle domain has a three helix bundle structure that holds four important histidines that are thought to play a role in the pH regulation of the enzyme.[10] There is a large pocket in the β-barrel of the dinoflagellate luciferase at pH 8 to accommodate the tetrapyrrole substrate but there is no opening to allow the substrate to enter. Therefore, a significant conformational change must occur to provide access and space for a ligand in the active site and the source for this change is through the four N-terminal histidine residues.[10] At pH 8, it can be seen that the unprotonated histidine residues are involved in a network of hydrogen bonds at the interface of the helices in the bundle that block substrate access to the active site and disruption of this interaction by protonation (at pH 6.3) or by replacement of the histidine residues by alanine causes a large molecular motion of the bundle, separating the helices by 11Å and opening the catalytic site.[10] Logically, the histidine residues cannot be replaced by alanine in nature but this experimental replacement further confirms that the larger histidine residues block the active site. Additionally, three Gly-Gly sequences, one in the N-terminal helix and two in the helix-loop-helix motif, could serve as hinges about which the chains rotate in order to further open the pathway to the catalytic site and enlarge the active site.[10]

A dinoflagellate luciferase is capable of emitting light due to its interaction with its substrate (luciferin) and the luciferin-binding protein (LBP) in the scintillon organelle found in dinoflagellates.[10] The luciferase acts in accordance with luciferin and LBP in order to emit light but each component functions at a different pH. Luciferase and its domains are not active at pH 8 but they are extremely active at the optimum pH of 6.3 whereas LBP binds luciferin at pH 8 and releases it at pH 6.3.[10] Consequently, luciferin is only released to react with an active luciferase when the scintillon is acidified to pH 6.3. Therefore, in order to lower the pH, voltage-gated channels in the scintillon membrane are opened to allow the entry of protons from a vacuole possessing an action potential produced from a mechanical stimulation.[10] Hence, it can be seen that the action potential in the vacuolar membrane leads to acidification and this in turn allows the luciferin to be released to react with luciferase in the scintillon, producing a flash of blue light.

Mechanism of reaction

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All luciferases are classified as oxidoreductases (EC 1.13.12.-), meaning they act on single donors with incorporation of molecular oxygen. Because luciferases are from many diverse protein families that are unrelated, there is no unifying mechanism, as any mechanism depends on the luciferase and luciferin combination. However, all characterised luciferase-luciferin reactions to date have been shown to require molecular oxygen at some stage.

Bacterial luciferase

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The reaction catalyzed by bacterial luciferase is also an oxidative process:

  • FMNH2 + O2 + RCHO → FMN + RCOOH + H2O + light

In the reaction, molecular oxygen oxidizes flavin mononucleotide and a long-chain aliphatic aldehyde to an aliphatic carboxylic acid. The reaction forms an excited hydroxyflavin intermediate, which is dehydrated to the product FMN to emit blue-green light.[12]

Nearly all of the energy input into the reaction is transformed into light. The reaction is 80%[13] to 90%[14] efficient. In comparison, the incandescent light bulb only converts about 10% of its energy into light[15] and a 150 lumen per Watt (lm/W) LED converts 20% of input energy to visible light.[14]

Applications

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Luciferases can be produced in the lab through genetic engineering for a number of purposes. Luciferase genes can be synthesized and inserted into organisms or transfected into cells. As of 2002, mice, silkworms, and potatoes are just a few of the organisms that have already been engineered to produce the protein.[16]

In the luciferase reaction, light is emitted when luciferase acts on the appropriate luciferin substrate. Photon emission can be detected by light sensitive apparatus such as a luminometer or an optical microscope with a CCD camera. This allows observation of biological processes.[17] Since light excitation is not needed for luciferase bioluminescence, there is minimal autofluorescence and therefore the bioluminescent signal is virtually background-free.[18] Therefore, as little as 0.02 pg can still be accurately measured using a standard scintillation counter.[19]

In biological research, luciferase is commonly used as a reporter to assess the transcriptional activity in cells that are transfected with a genetic construct containing the luciferase gene under the control of a promoter of interest.[20] Additionally, proluminescent molecules that are converted to luciferin upon activity of a particular enzyme can be used to detect enzyme activity in coupled or two-step luciferase assays. Such substrates have been used to detect caspase activity and cytochrome P450 activity, among others.[17][20]

Luciferase can also be used to detect the level of cellular ATP in cell viability assays or for kinase activity assays.[20][21] Luciferase can act as an ATP sensor protein through biotinylation. Biotinylation will immobilize luciferase on the cell-surface by binding to a streptavidin-biotin complex. This allows luciferase to detect the efflux of ATP from the cell and will effectively display the real-time release of ATP through bioluminescence.[22] Luciferase can additionally be made more sensitive for ATP detection by increasing the luminescence intensity by changing certain amino acid residues in the sequence of the protein.[23]

Graph with four rhythmic lines that peak in pairs, at alternating times over six, 24-hour cycles.
Graph showing timeseries data from in vivo imaging of firefly luciferase bioluminescence. Transgenic seedlings of Arabidopsis thaliana were imaged by a cooled CCD camera under three cycles of 12h light: 12h dark followed by 3 days of constant light. Their genomes carry firefly luciferase reporter genes, so the signals of seedlings 61 (red) and 62 (blue) reflect transcription of the gene CCA1, while 64 (pale grey) and 65 (teal) reflect TOC1. The timeseries show 24-hour, circadian rhythms of gene expression in the living plants.

Whole organism imaging (referred to as in vivo when intact or, otherwise called ex vivo imaging for example of living but explanted tissue) is a powerful technique for studying cell populations in live plants or animals, such as mice.[24] Different types of cells (e.g. bone marrow stem cells, T-cells) can be engineered to express a luciferase allowing their non-invasive visualization inside a live animal using a sensitive charge-couple device camera (CCD camera).This technique has been used to follow tumorigenesis and response of tumors to treatment in animal models.[25][26] However, environmental factors and therapeutic interferences may cause some discrepancies between tumor burden and bioluminescence intensity in relation to changes in proliferative activity. The intensity of the signal measured by in vivo imaging may depend on various factors, such as D-luciferin absorption through the peritoneum, blood flow, cell membrane permeability, availability of co-factors, intracellular pH and transparency of overlying tissue, in addition to the amount of luciferase.[27]

Luciferase is a heat-sensitive protein that is used in studies on protein denaturation, testing the protective capacities of heat shock proteins. The opportunities for using luciferase continue to expand.[28]

See also

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References

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  1. ^ Lee J (28 February 2014). "A History of Bioluminescence". photobiology.info. Archived from the original on 29 March 2015.
  2. ^ Lee J (September 2008). "Bioluminescence: the First 3000 Years (Review)". Journal of Siberian Federal University. Biology. 1 (3): 194–205. doi:10.17516/1997-1389-0264.
  3. ^ Brennan CK, Ornelas MY, Yao ZW, Prescher JA (August 2021). "Multicomponent Bioluminescence Imaging with Naphthylamino Luciferins". ChemBioChem. 22 (16): 2650–2654. doi:10.1002/cbic.202100202. PMC 8496354. PMID 34139065.
  4. ^ "X-Shining Thermostable Luciferase".
  5. ^ Gould SJ, Subramani S (November 1988). "Firefly luciferase as a tool in molecular and cell biology". Analytical Biochemistry. 175 (1): 5–13. doi:10.1016/0003-2697(88)90353-3. PMID 3072883.
  6. ^ Steghens JP, Min KL, Bernengo JC (November 1998). "Firefly luciferase has two nucleotide binding sites: effect of nucleoside monophosphate and CoA on the light-emission spectra". The Biochemical Journal. 336 (Pt 1): 109–13. doi:10.1042/bj3360109. PMC 1219848. PMID 9806891.
  7. ^ Shimomura O (1985). "Bioluminescence in the sea: photoprotein systems". Symposia of the Society for Experimental Biology. 39: 351–72. PMID 2871634.
  8. ^ Huh S, Lee J, Jung E, Kim SC, Kang JI, Lee J, Kim YW, Sung YK, Kang HK, Park D (Jun 2009). "A cell-based system for screening hair growth-promoting agents". Archives of Dermatological Research. 301 (5): 381–85. doi:10.1007/s00403-009-0931-0. PMID 19277688. S2CID 23916875.
  9. ^ Baldwin TO, Christopher JA, Raushel FM, Sinclair JF, Ziegler MM, Fisher AJ, Rayment I (Dec 1995). "Structure of bacterial luciferase". Current Opinion in Structural Biology. 5 (6): 798–809. doi:10.1016/0959-440x(95)80014-x. PMID 8749369.
  10. ^ a b c d e f g h i Schultz LW, Liu L, Cegielski M, Hastings JW (Feb 2005). "Crystal structure of a pH-regulated luciferase catalyzing the bioluminescent oxidation of an open tetrapyrrole". Proceedings of the National Academy of Sciences of the United States of America. 102 (5): 1378–83. Bibcode:2005PNAS..102.1378S. doi:10.1073/pnas.0409335102. PMC 547824. PMID 15665092.
  11. ^ Okamoto OK, Liu L, Robertson DL, Hastings JW (Dec 2001). "Members of a dinoflagellate luciferase gene family differ in synonymous substitution rates". Biochemistry. 40 (51): 15862–68. CiteSeerX 10.1.1.494.3563. doi:10.1021/bi011651q. PMID 11747464.
  12. ^ Fisher AJ, Thompson TB, Thoden JB, Baldwin TO, Rayment I (Sep 1996). "The 1.5-A resolution crystal structure of bacterial luciferase in low salt conditions". The Journal of Biological Chemistry. 271 (36): 21956–68. doi:10.1074/jbc.271.36.21956. PMID 8703001.
  13. ^ Wilson E (Jan 18, 1999). "What's That Stuff?". Chemical and Engineering News. 77 (3): 65. doi:10.1021/cen-v077n003.p065.
  14. ^ a b Knivett V (2009). "Lighting the way". EE Times. Archived from the original on 2012-10-05. Retrieved 2011-09-18.
  15. ^ General Electric TP-110, p. 23, table.
  16. ^ Contag CH, Bachmann MH (2002). "Advances in in vivo bioluminescence imaging of gene expression". Annual Review of Biomedical Engineering. 4: 235–60. doi:10.1146/annurev.bioeng.4.111901.093336. PMID 12117758.
  17. ^ a b "Introduction to Bioluminescence Assays". Promega Corporation. Archived from the original on 2010-08-14. Retrieved 2009-03-07.
  18. ^ Williams TM, Burlein JE, Ogden S, Kricka LJ, Kant JA (Jan 1989). "Advantages of firefly luciferase as a reporter gene: application to the interleukin-2 gene promoter". Analytical Biochemistry. 176 (1): 28–32. doi:10.1016/0003-2697(89)90267-4. PMID 2785354.
  19. ^ Nguyen VT, Morange M, Bensaude O (Jun 1988). "Firefly luciferase luminescence assays using scintillation counters for quantitation in transfected mammalian cells". Analytical Biochemistry. 171 (2): 404–08. doi:10.1016/0003-2697(88)90505-2. PMID 3407940.
  20. ^ a b c Fan F, Wood KV (Feb 2007). "Bioluminescent assays for high-throughput screening". ASSAY and Drug Development Technologies. 5 (1): 127–36. doi:10.1089/adt.2006.053. PMID 17355205.
  21. ^ Meisenheimer PL, O'Brien MA, Cali JJ (September 2008). "Luminogenic enzyme substrates: The basis for a new paradigm in assay design" (PDF). Promega Notes. 100: 22–26. Archived from the original (PDF) on 2009-03-06. Retrieved 2008-10-01.
  22. ^ Nakamura M, Mie M, Funabashi H, Yamamoto K, Ando J, Kobatake E (May 2006). "Cell-surface-localized ATP detection with immobilized firefly luciferase". Analytical Biochemistry. 352 (1): 61–67. doi:10.1016/j.ab.2006.02.019. PMID 16564487.
  23. ^ Fujii H, Noda K, Asami Y, Kuroda A, Sakata M, Tokida A (Jul 2007). "Increase in bioluminescence intensity of firefly luciferase using genetic modification". Analytical Biochemistry. 366 (2): 131–36. doi:10.1016/j.ab.2007.04.018. PMID 17540326.
  24. ^ Greer LF, Szalay AA (2002). "Imaging of light emission from the expression of luciferases in living cells and organisms: a review". Luminescence. 17 (1): 43–74. doi:10.1002/bio.676. PMID 11816060.
  25. ^ Lyons SK, Meuwissen R, Krimpenfort P, Berns A (Nov 2003). "The generation of a conditional reporter that enables bioluminescence imaging of Cre/loxP-dependent tumorigenesis in mice". Cancer Research. 63 (21): 7042–46. PMID 14612492.
  26. ^ Becher OJ, Holland EC (Apr 2006). "Genetically engineered models have advantages over xenografts for preclinical studies". Cancer Research. 66 (7): 3355–58, discussion 3358–59. doi:10.1158/0008-5472.CAN-05-3827. PMID 16585152.
  27. ^ Inoue Y, Tojo A, Sekine R, Soda Y, Kobayashi S, Nomura A, Izawa K, Kitamura T, Okubo T, Ohtomo K (May 2006). "In vitro validation of bioluminescent monitoring of disease progression and therapeutic response in leukaemia model animals". European Journal of Nuclear Medicine and Molecular Imaging. 33 (5): 557–65. doi:10.1007/s00259-005-0048-4. PMID 16501974. S2CID 40630078.
  28. ^ Massoud TF, Paulmurugan R, De A, Ray P, Gambhir SS (Feb 2007). "Reporter gene imaging of protein-protein interactions in living subjects". Current Opinion in Biotechnology. 18 (1): 31–37. doi:10.1016/j.copbio.2007.01.007. PMC 4141564. PMID 17254764.
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This article incorporates text from the public domain Pfam and InterPro: IPR018804
This article incorporates text from the public domain Pfam and InterPro: IPR007959
This article incorporates text from the public domain Pfam and InterPro: IPR018475