The Concept of Fact in German Physics around 1900: A Comparison between Mach and Einstein

Physics in Perspective - The concept of “fact” has a history. Over the past centuries, physicists have appropriated it in various ways. In this article, we compare Ernst Mach and Albert...     

Protonation of the chromophore in the photoactive yellow protein

The photoactive yellow protein (PYP) acts as a light sensor to its bacterial host: it responds to light by changing shape. After excitation by blue light, PYP undergoes several transformations, to partially unfold into its signaling state. One of the crucial steps in this photocycle is the protonation of p-coumaric acid after excitation and isomerization of this chromophore. Experimentalists still debate on the nature of the proton donor and on whether it donates the hydrogen directly or indirectly. To obtain better knowledge of the mechanism, we studied this proton transfer using Car-Parrinello molecular dynamics, classical molecular dynamics, and computer simulations combining these two methods (quantum mechanics/molecular mechanics, QMMM). The simulations reproduce the chromophore structure and hydrogen-bond network of the protein measured by X-ray crystallography and NMR. When the chromophore is protonated, it leaves the assumed proton donor, glutamic acid 46, with a negative charge in a hydrophobic environment. We show that the stabilization of this charge is a very important factor in the mechanism of protonation. Protonation frequently occurs in simplified ab initio simulations of the chromophore binding pocket in vacuum, where amino acids can easily hydrogen bond to Glu46. When the complete protein environment is incorporated in a QMMM simulation on the complete protein, no proton transfer is observed within 14 ps. The hydrogen-bond rearrangements in this time span are not sufficient to stabilize the new protonation state. Force field molecular dynamics simulations on a much longer time scale have shown which internal rearrangements of the protein are needed. Combining these simulations with more QMMM calculations enabled us to check the stability of protonation states and clarify the initial requirements for the proton transfer in PYP.     

Solvation of p-coumaric acid in water

The photoactive yellow protein (PYP) is an important model protein for many (photoactive) signaling proteins. Key steps in the PYP photocycle are the isomerization and protonation of its chromophore, p-coumaric acid (pCA). In the ground state of the protein, this chromophore is in the trans configuration with its phenolic oxygen deprotonated. For this paper, we studied four different configurations of pCA solvated in water with ab initio molecular dynamics simulations as implemented in CP2K/Quickstep. We researched the influence of the protonation and isomerization state of pCA on its hydrogen-bonding properties and on the Mulliken charges of the atoms in the simulation. The chromophore isomerization state influenced the hydrogen-bonding less than its protonation state. In general, more charge yielded a higher hydrogen-bond coordination number. Where deprotonation increases both the coordination number and the residence time of the water molecules around the chromophore, protonation showed a somewhat lower coordination number on two of the three pCA oxygens but much higher residence times on all of them. This could be explained by the increased polarization of the OH groups of the molecule. The presence of the chromophore also influenced the charge and polarization of the water molecules around it. This effect was different in the four systems studied and mainly localized in the first solvation shell. We also performed a proton-transfer reaction from hydronium through various other water molecules to the chromophore. In this small charge-separated system, the protonation occurred within 6.5 ps. We identified the transition state for the final step in this protonation series.