Discussions of "jellyfish DNA" that can make "glowing" animals often refer to transgenic animals that express the green fluorescent protein, not aequorin, although both originally derive from the same animal.
Work on aequorin began with E. Newton Harvey in 1921.[3] Though Harvey was unable to demonstrate a classical luciferase-luciferin reaction, he showed that water could produce light from dried photocytes and that light could be produced even in the absence of oxygen. Later, Osamu Shimomura began work into the bioluminescence of Aequorea in 1961. This involved tedious harvesting of tens of thousands of jellyfish from the docks in Friday Harbor, Washington.[1] It was determined that light could be produced from extracts with seawater, and more specifically, with calcium.[2] It was also noted during the extraction the animal creates green light due to the presence of the green fluorescent protein, which changes the native blue light of aequorin to green.[4]
Aequorin is a holoprotein composed of two distinct units, the apoprotein that is called apoaequorin, which has an approximate molecular weight of 21 kDa, and the prosthetic groupcoelenterazine, the luciferin.[6] This is to say, apoaequorin is the enzyme produced in the photocytes of the animal, and coelenterazine is the substrate whose oxidation the enzyme catalyzes. When coelenterazine is bound, it is called aequorin. Notably, the protein contains three EF hand motifs that function as binding sites for Ca2+ ions.[7] The protein is a member of the superfamily of the calcium-binding proteins, of which there are some 66 subfamilies.[8]
The crystal structure revealed that aequorin binds coelenterazine and oxygen in the form of a peroxide, coelenterazine-2-hydroperoxide.[9] The binding site for the first two calcium atoms show a 20 times greater affinity for calcium than the third site.[10] However, earlier claims that only two EF-hands bind calcium[11] were questioned when later structures indicated that all three sites can indeed bind calcium.[12] Thus, titration studies show that all three calcium-binding sites are active but only two ions are needed to trigger the enzymatic reaction.[13]
Other studies have shown the presence of an internal cysteine bond that maintains the structure of aequorin.[14] This has also explained the need for a thiol reagent like beta mercaptoethanol in the regeneration of the protein since such reagents weaken the sulfhydryl bonds between cysteine residues, expediting the regeneration of the aequorin.
Chemical characterization of aequorin indicates the protein is somewhat resilient to harsh treatments. Aequorin is heat resistant.[15] Held at 95 °C for 2 minutes the protein lost only 25% activity. Denaturants such as 6-M urea or 4-M guanidine hydrochloride did not destroy the protein.
Genetics
Aequorin is presumably encoded in the genome of Aequorea. At least four copies of the gene were recovered as cDNA from the animal.[16][17] Because the genome has not been sequenced, it is unclear if the cDNA variants can account for all of the isoforms of the protein.[18]
Mechanism of action
Early studies of the bioluminescence of Aequorea by E. Newton Harvey had noted that the bioluminescence appears as a ring around the bell, and occurs even in the absence of air.[19] This was remarkable because most bioluminescence reactions require oxygen, and led to the idea that the animals somehow store oxygen.[20] It was later discovered that the apoprotein can stably bind coelenterazine-2-hydroperoxide, and oxygen is required for the regeneration to this active form of aequorin.[21] However, in the presence of calcium ions, the protein undergoes a conformational change and converts its prosthetic group, coelenterazine-2-hydroperoxide, into excited coelenteramide and CO2.[22] As the excited coelenteramide relaxes to the ground state, blue light (wavelength of 465 nm) is emitted. Before coelenteramide is exchanged out, the entire protein is still fluorescent blue.[23][24] because of the connection between bioluminescence and fluorescence, this property was ultimately important in the discovery of the luciferin coelenterazine.[25]
Applications
Since the emitted light can be easily detected with a luminometer, aequorin has become a useful tool in molecular biology for the measurement of intracellular Ca2+ levels.[26] The early successful purification of aequorin led to the first experiments involving the injection of the protein into the tissues of living animals to visualize the physiological release of calcium in the muscle fibers of a barnacle.[27] Since then, the protein has been widely used in many model biological systems, including zebrafish,[28]rats, mice, and cultured cells.[29][30][31][32]
Cultured cells expressing the aequorin gene can effectively synthesize apoaequorin; however, recombinant expression yields only the apoprotein. Therefore it is necessary to add coelenterazine into the culture medium of the cells to obtain a functional protein and thus use its blue light emission to measure Ca2+ concentration. Coelenterazine is a hydrophobic molecule, and therefore is easily taken up across plant and fungal cell walls, as well as the plasma membrane of higher eukaryotes, making aequorin suitable as a Ca2+ reporter in plants, fungi, and mammalian cells.[33][34]
Aequorin has a number of advantages over other Ca2+ indicators. Because the protein is large, it has a low leakage rate from cells compared to lipophilic dyes such as DiI. It lacks phenomena of intracellular compartmentalization or sequestration as is often seen for Voltage-sensitive dyes, and does not disrupt cell functions or embryo development. Moreover, the light emitted by the oxidation of coelenterazine does not depend on any optical excitation, so problems with auto-fluorescence are eliminated.[35] The primary limitation of aequorin is that the prosthetic group coelenterazine is irreversibly consumed to produce light, and requires continuous addition of coelenterazine into the media. Such issues led to developments of other genetically encoded calcium sensors including the calmodulin-based sensor cameleon,[36] developed by Roger Tsien and the troponin-based sensor, TN-XXL, developed by Oliver Griesbeck.[37]
Marketing and legal challenges
Apoaequorin is an ingredient in "Prevagen", which is marketed by Quincy Bioscience as a memory supplement. In 2017, the US Federal Trade Commission (FTC) charged the maker with falsely advertising that the product improves memory, provides cognitive benefits, and is "clinically shown" to work.[38] According to the FTC, "the marketers of Prevagen preyed on the fears of older consumers experiencing age-related memory loss". Quincy said that it would fight the charges.[39][40][41]
Prior to the suit, a clinical trial run by researchers employed by Quincy Bioscience "found no overall benefit compared to a placebo for its primary endpoints involving memory and cognition", while the company's advertising misleadingly cited a few contested subgroup analyses that showed slight improvements.[42][43]
The suit (Spath, et al. v. Quincy Bioscience Holding Company, Inc., et al., Case No. 18-cv-12416, D. NJ.) was dismissed in the District court, but an appeal seeking to overturn the dismissal was filed. The suit was consolidated with another against Quincy Pharmaceuticals, Vanderwerff v. Quincy Bioscience (Case No. 17-cv-784, D. NJ), which was the lead case.[44]
On February 21, 2019, the United States Court of Appeals for the Second Circuit ruled that the FTC and the state of New York could proceed with their lawsuit against Quincy Bioscience for its claims that Prevagen can improve memory. The order came less than two weeks after the parties argued the case before a three-judge panel of the circuit, where company lawyers admitted they did not "dispute that if you look across the entire 211 people who completed the study there was no statistically significant difference". The court vigorously dismissed allegations by the company lawyers that the FTC pursued its action for political reasons.[45][46]
As of September 21, 2020[update], Quincy Bioscience agreed to settle the claims that it misrepresented its Prevagen products as supporting brain health and helping with memory loss. Under the terms of the settlement, eligible purchasers applying by October 26, 2020, for purchases made from 2007 through July 31, 2020, could recover refunds of up to $70.
[49]
Dr. Harriet Hall, writing for Science-Based Medicine, noted that the Quincy-sponsored study (known as "Madison Memory Study") was negative, but that the company utilized p-hacking to find favorable results. She wrote that their cited safety studies were all rat studies and their claim that apoaequorin crosses the blood–brain barrier was based solely on a dog study.[50] The American Pharmacists Association warns that Apoaequorin "is unlikely to be absorbed to a significant degree; instead it degrades into amino acids".[51]
^ abShimomura O, Johnson FH, Saiga Y (1962). "Extraction, purification and properties of aequorin, a bioluminescent protein from the luminous hydromedusan, Aequorea". J Cell Comp Physiol. 59 (3): 223–39. doi:10.1002/jcp.1030590302. PMID13911999.
^Charbonneau H, Walsh KA, McCann RO, Prendergast FG, Cormier MJ, Vanaman TC (1985). "Amino acid sequence of the calcium-dependent photoprotein aequorin". Biochemistry. 24 (24): 6762–6771. doi:10.1021/bi00345a006. PMID2866797.
^Zhou Y, Yang W, Kirberger M, Lee HW, Ayalasomayajula G, Yang JJ (2006). "Prediction of EF-hand calcium-binding proteins and analysis of bacterial EF-hand proteins". Proteins. 65 (3): 643–655. doi:10.1002/prot.21139. PMID16981205. S2CID8904181.
^Shimomura O (1995). "Luminescence of aequorin is triggered by the binding of two calcium ions". Biochem. Biophys. Res. Commun. 211 (2): 359–363. doi:10.1006/bbrc.1995.1821. PMID7794244.
^Shimomura O (1995). "Luminescence of aequorin is triggered by the binding of two calcium ions". Biochemical and Biophysical Research Communications. 211 (2): 359–363. doi:10.1006/bbrc.1995.1821. PMID7794244.
^Masuda H, Takenaka Y, Shikamoto Y, Kagawa M, Mizuno H, Tsuji FI (2003). "Chromatography of isoforms of recombinant apoaequorin and method for the preparation of aequorin". Protein Expr. Purif. 31 (2): 181–187. doi:10.1016/s1046-5928(03)00186-4. PMID14550635.
^Shimomura O, Johnson FH, Morise H (1974). "Mechanism of the luminescent intramolecular reaction of aequorin". Biochemistry. 13 (16): 3278–3286. doi:10.1021/bi00713a016. PMID4152180.
^Rembold CM, Kendall JM, Campbell AK (January 1997). "Measurement of changes in sarcoplasmic reticulum [Ca2+] in rat tail artery with targeted apoaequorin delivered by an adenoviral vector". Cell Calcium. 21 (1): 69–79. doi:10.1016/s0143-4160(97)90098-1. PMID9056079.
^Yamano K, Mori K, Nakano R, Kusunoki M, Inoue M, Satoh M (2007). "Identification of the functional expression of adenosine A3 receptor in pancreas using transgenic mice expressing jellyfish apoaequorin". Transgenic Res. 16 (4): 429–435. doi:10.1007/s11248-007-9084-0. PMID17387626. S2CID19339429.
^FTC vs. Quincy Bioscience Holding Company, United States Court of Appeals for the Second Circuit, Case 17-3745, Document 257, February 21, 2019. Retrieved March 26, 2019.