LOV domains act as versatile photochromic switches servicing multiple effector domains in a variety of blue light sensing photoreceptors abundant in a multitude of organisms from all kingdoms of life. The perception of light is realized by a flavin chromophore that upon illumination reversibly switches from the non-covalently bound dark-state to a covalently linked flavin-LOV adduct. It is usually assumed that most LOV domains preferably bind FMN, but heterologous expression frequently results in the incorporation of all natural occurring flavins, i.e. riboflavin, FMN and FAD. Over recent years, the structures, photochemical properties, activation mechanisms and physiological functions of a multitude of LOV proteins have been studied intensively, but little is known about its affinities to physiologically relevant flavins or the thermodynamics of the flavin-LOV interaction. We have investigated the interaction of the LOV domain of the well characterized bacterial photoreceptor YtvA with riboflavin, FMN and FAD by ITC experiments providing binding constants and thermodynamic profiles of these interactions. For this purpose, we have developed a protocol for the production of the apo forms of YtvA and its isolated LOV domain and we demonstrate that the latter can be used as a molecular probe for free flavins in cell lysates. Furthermore, we show here using NMR spectroscopic techniques and Analytical Ultracentrifugation that the flavin moiety stabilizes the conformation of the LOV domain and that dimerization of YtvA is caused not only by intermolecular LOV-LOV but also by STAS-STAS contacts.
Site-directed spin labeling of the unnatural amino acid p-acetylphenylalanine (p-AcPhe) using oxime based coupling chemistry is successfully applied to investigate human sulfite oxidase (hSO), a protein containing an essential cysteine residue, which impedes the use of thiol based coupling chemistry. The protein was found to be sensitive toward typical reaction conditions of oxime coupling, namely, acidic reaction conditions and elevated temperatures. Thus, coupling at neutral pH and room temperature is mandatory. Three catalysts described in the literature to accelerate the reaction rate have been tested. Best spin labeling efficiencies were observed for p-methoxyaniline, while the other catalysts described in the literature to have even better performance for oxime coupling at neutral pH were substantially less active or led to precipitation of the protein. A clear correlation of spin labeling efficiency with the local environment of the residue is found, shedding some light on the importance of the sterically demanding reaction complex between p-AcPhe, the aniline catalyst, and the spin label for the reaction rate. The analysis of the line shape has shown that its interpretation in terms of local environment is more challenging as compared to the well-established spin labels based on cysteine chemistry. To this end the results presented here indicate that the larger steric demand of the spin labeled p-AcPhe can induce structural effects instead of reporting on them.
Mononuclear molybdoenzymes catalyze a broad range of redox reactions and are highly conserved in all kingdoms of life. This study addresses the question of how the Mo cofactor (Moco) is incorporated into the apo form of human sulfite oxidase (hSO) by using site-directed spin labeling to determine intramolecular distances in the nanometer range. Comparative measurements of the holo and apo forms of hSO enabled the localization of the corresponding structural changes, which are localized to a short loop (residues 263-273) of the Moco-containing domain. A flap-like movement of the loop provides access to the Moco binding-pocket in the apo form of the protein and explains the earlier studies on the in vitro reconstitution of apo-hSO with Moco. Remarkably, the loop motif can be found in a variety of structurally similar molybdoenzymes among various organisms, thus suggesting a common mechanism of Moco incorporation.
[11] (pdb:1 SOX, 67 %i dentische Reste) [12] gelçst werden. Ausgehend von der Struktur von cSO wurden geeignete Positionen zur Detektion von Strukturänderungenin der Moco-Domäne ausgewählt. Zwischen Paaren von ortsspezifisch eingeführten Spinmarkern der jeweiligen Holound Apoproteinformen wurden Abstandsverteilungen mittels gepulster Elektron-Elektron-Doppelresonanzspektroskopie (PELDOR, auch:D EER) bestimmt und so nach Strukturunterschieden in Abwesenheit des Moco gesucht.[13] Die Ergebnisse zeigen die stark lokalisierte ¾nderung einer kurzen Schleife (Reste 263-273 in hSO) in der Moco-Domäne.D ie beobachtete Klappbewegung der Schleife ermçglicht den
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