Engineering and exploiting synthetic allostery of NanoLuc luciferase.

Allostery enables proteins to interconvert different biochemical signals and form complex metabolic and signaling networks. We hypothesize that circular permutation of proteins increases the probability of functional coupling of new N- and C- termini with the protein's active center through increased local structural disorder. To test this we construct a synthetically allosteric version of circular permutated NanoLuc luciferase that can be activated through ligand-induced intramolecular non-covalent cyclisation. This switch module is tolerant of the structure of binding domains and their ligands, and can be used to create biosensors of proteins and small molecules. The developed biosensors covers a range of emission wavelengths and displays sensitivity as low as 50pM and dynamic range as high as 16-fold and could quantify their cognate ligand in human fluids. We apply hydrogen exchange kinetic mass spectroscopy to analyze time resolved structural changes in the developed biosensors and observe ligand-mediated folding of newly created termini.

The proportion of Met80-sulfoxide dictates peroxidase activity of human cytochrome c.

The peroxidase activity of cytochrome c is proposed to contribute to apoptosis by peroxidation of cardiolipin in the mitochondrial inner membrane. However, cytochrome c heme is hexa-coordinate with a methionine (Met80) on the distal side, stopping it from acting as an efficient peroxidase. The first naturally occurring variant of cytochrome c discovered, G41S, has higher peroxidase activity than wild-type. To understand the basis for this increase and gain insight into the peroxidase activity of wild-type, we have studied wild-type, G41S and the unnatural variant G41T. Through a combined kinetic and mass spectrometric analysis, we have shown that hydrogen peroxide specifically oxidizes Met80 to the sulfoxide. In the absence of substrate this can be further oxidized to the sulfone, leading to a decrease in peroxidase activity. Peroxidase activity can be correlated with the proportion of sulfoxide present and if fully in that form, all variants have the same activity without a lag phase caused by activation of the protein.