SEARCH

SEARCH BY CITATION

References

  • 1
    Hastings JW. Chemistries and colors of bioluminescent reactions: a review. Gene 1996;173:511.
  • 2
    Haddock SHD, Moline MA, Case JF. Bioluminescence in the sea. Ann Rev Mar Sci 2010;2:44393.
  • 3
    Harvey EN. Bioluminescence. 1st edn. New York: Academic Press, 1952.
  • 4
    Harvey EN. Bioluminescence and fluorescence in the living world. Am J Physiol 1926;77:55561.
  • 5
    Dales RP. Bioluminescence in pelagic polychaetes. J Fish Res Board Canada 1971;28:14879.
  • 6
    Shimomura O. Bioluminescence: chemical principles and methods. Singapore: World Scientific, 2006.
  • 7
    Shimomura O, Johnson FH. Calcium binding, quantum yield, and emitting molecule in Aequorin bioluminescence. Nature 1970;227(5265):13567.
  • 8
    Suzuki N, Sato M, Nishikawa K, Goto T. Synthesis and spectral properties of 2-(6′-hydroxybenzothiazol-2′-yl)-4-hydroxythiazole, a possible emitting species in the firefly bioluminescence. Tetrahedron Lett 1969;10:46834.
  • 9
    Suzuki N, Goto T. Firefly bioluminescence II. Identification of 2-(6′-hydroxybenzothiazol-2′-yl)-4-hydroxythiazole as a product in the bioluminescence of firefly lanterns and as a product in the chemiluminescence of firefly luciferin in DMSO. Tetrahedron Lett 1971;22:20214.
  • 10
    Gibson QH, Hastings JW. The oxidation of reduced flavin mononucleotide by molecular oxygen. Biochem J 1962;83:36877.
  • 11
    Eley M, Lee J, Lhoste JM, Lee CY, Cormier MJ, Hemmerich P. Bacterial bioluminescence. Comparisons of bioluminescence emission spectra, the fluorescence of luciferase reaction mixtures, and the fluorescence of flavin cations. Biochemistry 1970;9:29028.
  • 12
    Towner RD, Neufeld HA, Shevlin PB. Some characteristics of riboflavin chemiluminescence. Arch Biochem Biophys 1970;137:1028.
  • 13
    Terio B. Su un pigmento fluorescente presente nella pinna del remo dorsale di un annelide polichete (Tomopteris septentrionalis Steenstrup). Boll Soc Ital Biol Sper 1960;36:7257.
  • 14
    Terio B. Possibili interrelazioni tra bioluminescenza e fluorescenza di materiali fotosensibili presenti nelle pinne e sui parapodi dei Tomopterid. Atti Soc Peloritana Sci Fis Mat Natur 1964;10:111.
  • 15
    Hastings JW. Biological diversity, chemical mechanisms, and the evolutionary origins of bioluminescent systems. J Mol Evol 1983;19:30921.
  • 16
    Latz MI, Frank TM, Case JF. Spectral composition of bioluminescence of epipelagic organisms from the Sargasso Sea. Mar Biol 1988;98:4416.
  • 17
    Hori K, Cormier MJ. Structure and synthesis of a luciferin active in the bioluminescent systems of sea pansy (Renilla) and certain other bioluminescent coelenterates. Chemilumin Biolumin. 1972: 3618.
  • 18
    Shimomura O, Johnson FH. Chemical nature of bioluminescence systems in coelenterates. Proc Natl Acad Sci U S A 1975;72:15469.
  • 19
    Shimomura O, Teranishi K. Light-emitters involved in the luminescence of coelenterazine. Luminescence 2000;15:518.
  • 20
    Howard DF, Phillips DW, Jones TH, Blum MS. Anthraquinones and anthrones: occurrence and defensive function in a Chrysomelid beetle. Naturwissenschaften 1982;69(2):912.
  • 21
    Thomson RH. Naturally occurring quinones. 1st edn. New York: Academic Press; 1971.
  • 22
    Thomson RH. Naturally occurring quinones III: recent advances. 1st edn. London: Chapman and Hall, 1987.
  • 23
    Wamer WG, Vath P, Falvey DE. In vitro studies on the photobiological properties of aloe emodin and aloin A. Free Radical Biol Med 2003;34:23342.
  • 24
    Lee DY, Bowen BP, Northen TR. Mass spectrometry-based metabolomics, analysis of metabolite–protein interactions, and imaging. Biotechniques 2010;49:55765.
  • 25
    Clarke A, Holmes LJ, Gore DJ. Proximate and elemental composition of gelatinous zooplankton from the Southern Ocean. J Exp Mar Biol Ecol 1992;155:5568.
  • 26
    Weatherston BJ. The chemistry of arthropod defensive substances. Quart Rev 1967;21:287313.
  • 27
    Eisner T, Meinwald J. Defensive secretions of arthropods. Science 1966;153(3742):134150.
  • 28
    Malterud KE, Farbrot TL, Huse AE, Sund RB. Antioxidant and radical scavenging effects of anthraquinones and anthrones. Pharmacology 1993;47(Suppl 1):7785.
  • 29
    Yen Gc. Antioxidant activity of anthraquinones and anthrone. Food Chem 2000;70:43741.
  • 30
    Tian B, Hua Y. Concentration-dependence of prooxidant and antioxidant effects of aloin and aloe-emodin on DNA. Food Chem 2005;91:41318.
  • 31
    Kanakubo A, Isobe M. Isolation of brominated quinones showing chemiluminescence activity from luminous acorn worm, Ptychodera flava. Bioorg Med Chem 2005;13:27417
  • 32
    Kanakubo A, Koga K, Isobe M, Yoza K. Tetrabromohydroquinone and riboflavin are possibly responsible for green luminescence in the luminous acorn worm, Ptychodera flava. Luminescence 2005;20:397400.
  • 33
    Stauff J, Bartolmes P. Chemiluminescence on oxidative formation of triplet states of anthrasemiquinone- and anthraquinone-2-sulfonate. Ang Chem Int Ed 1970;9:3078.
  • 34
    Foster H, Gardner JH. The preparation and hydrolysis of some polyhydroxyanthraquinone glucosides. J Am Chem Soc 1936;318:19346.
  • 35
    Hay JE, Haynes LJ. 605. The aloins. Part I. The structure of barbaloin. J Chem Soc 1956;31417.
  • 36
    Shimomura O, Johnson FH. Chaetopterus photoprotein: crystallization and cofactor requirements for bioluminescence. Science 1968;159(3820):123940.
  • 37
    Nicolas MT, Bassot JM, Shimomura O. Polynoidin: a membrane photoprotein isolated from the bioluminescent system of scale-worms. Photochem Photobiol 1982;35:2017.
  • 38
    Lucas M, Solano F. Coelenterazine is a superoxide anion-sensitive chemiluminescent probe: its usefulness in the assay of respiratory burst in neutrophils. Anal Biochem 1992;206:2737.
  • 39
    Bringmann G, Irmer A. Acetogenic anthraquinones: biosynthetic convergence and chemical evidence of enzymatic cooperation in nature. Phytochem Rev 2008;7:499511.
  • 40
    Bringmann G, Noll TF, Gulder TaM, Grüne M, Dreyer M, Wilde C, et al. Different polyketide folding modes converge to an identical molecular architecture. Nat Chem Biology 2006;2:42933.
  • 41
    Wolkenstein K, Schoefberger W, Müller N, Oji T. Proisocrinins A–F, brominated anthraquinone pigments from the stalked crinoid Proisocrinus ruberrimus. J Nat Prod 2009;72:20369.
  • 42
    Hawas UW, El-Beih AA, El-Halawany AM. Bioactive anthraquinones from endophytic fungus Aspergillus versicolor isolated from red sea algae. Arch Pharm Res 2012;35:174956.
  • 43
    Piel J. A polyketide synthase-peptide synthetase gene cluster from an uncultured bacterial symbiont of Paederus beetles. Proc Natl Acad Sci U S A 2002;99:140027.