Mechanistic insight into marine bioluminescence: Photochemistry of the chemiexcited cypridina (sea firefly) lumophore

Bo Wen Ding, Pance Naumov, Ya Jun Liu

Research output: Contribution to journalArticle

Abstract

Cypridina hilgendorfii (sea firefly) is a bioluminescent crustacean whose bioluminescence (BL) reaction is archetypal for a number of marine organisms, notably other bioluminescent crustaceans and coelenterates. Unraveling the mechanism of its BL is paramount for future applications of its strongly emissive lumophore. Cypridina produces light in a three-step reaction: First, the cypridinid luciferin is activated by an enzyme to produce a peroxide intermediate, cypridinid dioxetanone (CDO), which then decomposes to generate excited oxyluciferin (OxyCLnH∗). Finally, OxyCLnH∗ deexcites to its ground state along with emission of bright blue light. Unfortunately, the detailed mechanism of the critical step, the thermolysis of CDO, remains unknown, and it is unclear whether the light emitter is generated from a neutral form (CDOH) or anionic form (CDO-) of the CDO precursor. In this work, we investigated the key step in the process by modeling the thermal decompositions of both CDOH and CDO-. The calculated results indicate that the decomposition of CDO- occurs via the gradually reversible charge transfer (CT)-initiated luminescence (GRCTIL) mechanism, whereas CDOH decomposes through an entropic trapping mechanism without an obvious CT process. The thermolysis of CDO- is sensitive to solvent effects and is energetically favorable in polar environments compared with the thermolysis of CDOH. The thermolysis of CDO- produces the excited oxyluciferin anion (OxyCLn-∗), which combines with a proton from the environment to form OxyCLnH∗, the actual light emitter for the natural system.

Original languageEnglish (US)
Pages (from-to)591-599
Number of pages9
JournalJournal of Chemical Theory and Computation
Volume11
Issue number2
DOIs
StatePublished - Feb 10 2015

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fireflies
Bioluminescence
bioluminescence
Thermolysis
Photochemical reactions
photochemical reactions
Charge transfer
emitters
charge transfer
peroxides
Peroxides
organisms
Ground state
thermal decomposition
Luminescence
enzymes
Protons
Pyrolysis
Negative ions
Enzymes

ASJC Scopus subject areas

  • Computer Science Applications
  • Physical and Theoretical Chemistry

Cite this

Mechanistic insight into marine bioluminescence : Photochemistry of the chemiexcited cypridina (sea firefly) lumophore. / Ding, Bo Wen; Naumov, Pance; Liu, Ya Jun.

In: Journal of Chemical Theory and Computation, Vol. 11, No. 2, 10.02.2015, p. 591-599.

Research output: Contribution to journalArticle

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