Funding information: National Institute of Health, Grant/Award Numbers: NIH MIRA 5R35GM133684-02, NIH DK104770; National Science Foundation, Grant/Award Number: NSF CAREER 2048265

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Abstract

The development of bioluminescence-based tools has seen steady growth in the field of chemical biology over the past few decades ranging in uses from reporter genes to assay development and targeted imaging. More recently, coelenterazine-utilizing luciferases such as Gaussia, Renilla, and the engineered nano-luciferases have been utilized due to their intense luminescence relative to firefly luciferin/luciferase. The emerging importance of these systems warrants investigations into the components that affect their light production. Previous work has reported that one marine luciferase, Gaussia, is potently inhibited by copper salt. The mechanism for inhibition was not elucidated but was hypothesized to occur via binding to the enzyme. In this study, we provide the first report of a group of nonhomologous marine luciferases also exhibiting marked decreases in light emission in the presence of copper (II). We investigate the mechanism of action behind this inhibition and demonstrate that the observed copper inhibition does not stem from a luciferase interaction but rather the chemical oxidation of imidazopyrazinone luciferins generating inert, dehydrated luciferins.

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bio4415-sup-0001-Supplementary.docxWord 2007 document , 1.3 MB

Figure S1. Calculated area under the curve over 20 min of kinetic luminescence measurements of DTZ (10 μM) in the absence or presence of Cu(II) ions (100 μM) with recombinant Nluc (0.4 μg/ml)

Figure S2. Calculated area under the curve over 20 min of kinetic luminescence measurements of DTZ (1 μM) in the absence or presence of varying stoichiometric equivalents of Cu(II) ions (0 to 4 equivalents) with recombinant Nluc (0.4 μg/ml)

Figure S3. Calculated area under the curve (AUC) over 20 min of kinetic luminescence measurements of DTZ (10 μM) in the presence of Gaussia luciferase (0.4 μg/ml) with or without preincubation with Cu(II) for 10 min

Figure S4. Electronic absorption spectra of 50 μM CTZ with and without addition of 50 μM CuSO₄ in ethanol. Spectral changes upon the addition of Cu(II) suggest oxidation of CTZ. Addition of 500 μM EDTA does not restore the CTZ spectrum pointing to an irreversible reaction, and addition of 500 μM BCS confirms the presence of Cu(I) in solution resulting from the redox reaction

Figure S5. Electronic absorption spectra of 50 μM (a) CTZ and (b) DTZ alone (black) and upon the addition of 50 μM biologically relevant metal ions. Significant spectral changes occur in both CTZ and DTZ spectra upon the addition of Cu(II) and Fe (III) ions indicating interactions between the luciferins and these metal ions

Figure S6. Calculated area under the curve over 20 min of kinetic luminescence measurements of 10 μM (a) CTZ or (b) DTZ in the absence or presence of Fe(III) ions (100 μM) with recombinant Nluc (0.4 μg/ml)

Figure S7. Chromatograms of (a) DTZ and (b) dhDTZ reveal a 10 min longer retention time

Figure S8. Mass spectra of (a) DTZ and (b) dhDTZ show an m/z of 378.2 and 376.1 for DTZ and dhDTZ respectively

Figure S9. Chromatograms of (a) CTZ and (b) dhCTZ reveal a 3 min longer retention for dhCTZ

Figure S10. Mass spectra of (a) CTZ and (b) dhCTZ show an m/z of 424.1 and 422.1 for CTZ and dhCTZ respectively

Figure S11. Calculated area under the curve over 15 min of kinetic luminescence measurements of 10 μM dhDTZ with or without preincubation with NaBH₄ (100 μM) in the presence of recombinant Nluc (0.4 μg/ml)

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Volume38, Issue2

February 2023

Pages 216-220

Copper-mediated oxidation of imidazopyrazinones inhibits marine luciferase activity

Abstract

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Copper-mediated oxidation of imidazopyrazinones inhibits marine luciferase activity

Abstract

Supporting Information

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