Anders Krøll Didriksen scite author profile

The neuroendocrine peptides CCHamide-1 and -2, encoded by the genes ccha1 and -2, are produced by endocrine cells in the midgut and by neurons in the brain of Drosophila melanogaster. Here, we used the CRISPR/Cas9 technique to disrupt the ccha1 and -2 genes and identify mutant phenotypes with a focus on ccha-2 mutants. We found that both larval and adult ccha2 mutants showed a significantly reduced food intake as measured in adult flies by the Capillary Feeding (CAFE) assay (up to 72% reduced food intake compared to wild-type). Locomotion tests in adult flies showed that ccha2 mutants had a significantly reduced locomotor activity especially around 8 a.m. and 8 p.m., where adult Drosophila normally feeds (up to 70% reduced locomotor activity compared to wild-type). Reduced larval feeding is normally coupled to a delayed larval development, a process that is mediated by insulin. Accordingly, we found that the ccha2 mutants had a remarkably delayed development, showing pupariation 70 hours after the pupariation time point of the wild-type. In contrast, the ccha-1 mutants were not developmentally delayed. We also found that the ccha2 mutants had up to 80% reduced mRNA concentrations coding for the Drosophila insulin-like-peptides-2 and -3, while these concentrations were unchanged for the ccha1 mutants. From these experiments we conclude that CCHamide-2 is an orexigenic peptide and an important factor for controlling developmental timing in Drosophila.

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Flash properties of Gaussia luciferase are the result of covalent inhibition after a limited number of cycles

Dijkema

Nordentoft

Didriksen

et al. 2021

Protein Science

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Luciferases are widely used as reporters for gene expression and for sensitive detection systems. The luciferase (GLuc) from the marine copepod Gaussia princeps, has gained popularity, primarily because it is secreted and displays a very high light intensity. While firefly luciferase is characterized by kinetic behavior which is consistent with conventional steady‐state Michaelis–Menten kinetics, GLuc displays what has been termed “flash” kinetics, which signify a burst in light emission followed by a rapid decay. As the mechanistic background for this behavior was unclear, we decided to decipher this in more detail. We show that decay in light signal is not due to depletion of substrate, but rather is caused by the irreversible inactivation of the enzyme. Inactivation takes place after between 10 and 200 reaction cycles, depending on substrate concentration and can be described by the sum of two exponentials with associated rate constants. The dominant of these increases linearly with substrate concentration while the minor is substrate‐concentration independent. In terms of rate of initial luminescence reaction, this increases with the substrate concentration to the power of 1.5 and shows no signs of saturation up to 10 μM coelenterazine. Finally, we find that the inactivated form of the enzyme has a larger apparent size in both size exclusion chromatography and SDS‐PAGE analysis and shows a fluorescence peak at 410 nm when excited at 333 nm. These findings indicate that the “flash” kinetics in Gaussia luciferase are caused by an irreversible covalent binding to a substrate derivative during catalysis.

show abstract

Flash properties of Gaussia Luciferase are the result of covalent inhibition after a limited number of cycles

Dijkema

Nordentoft

Didriksen

et al. 2020

Preprint

View full text Add to dashboard Cite

Luciferases are widely used as reporters for gene expression and for sensitive detection systems. While luciferases from firefly and Renilla have long been used for analysis of intracellular expression, the luciferase (GLuc) from the marine copepod Gaussia princeps, has gained popularity, primarily because it is secreted and displays a very high light intensity. Firefly luciferase is characterized by kinetic behavior which is consistent with conventional steady-state Michaelis-Menten kinetics (termed “glow” kinetics). GLuc, conversely, displays what has been termed “flash” kinetics which signify a burst in light emission followed by a rapid decay. As the mechanistic background for this behavior is poorly characterized, we decided to decipher the mechanism in more detail. We show that decay in light signal is not due to depletion of substrate, but rather is caused by the irreversible inactivation of the enzyme. Inactivation takes place after between 10 and 200 reaction cycles, depending on substrate concentration. We found that the rate of inactivation is described by the sum of two exponentials with associated rate constants. The dominant of these of these increases linearly with substrate concentration while the minor is substrate-concentration independent. In terms of rate of initial luminescence reaction, this increases with the substrate concentration to the power of 1.53 and shows no signs of saturation up to 10 μM coelenterazine. Finally, we found that the inactivated form of the enzyme has a larger apparent size in both size exclusion chromatography and SDS-PAGE analysis and shows a fluorescence peak at 410 nm when excited at 333 nm. These findings indicate that the “flash” kinetics in Gaussia luciferase are caused by an irreversible covalent binding to a derivative of the substrate during the reaction.

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