Dielectric response and vibrational energy relaxation in photoactive yellow protein: A molecular dynamics simulation study

Revisiting the electron transfer pathways between amicyanin and cytochrome c from a theoretical perspective

The phenomenon of electron transfer between cytochrome c and amicyanin is a prevalent chemical process found in biological systems. In this study, we used MD simulation to explore the dynamic conformational changes and studied the possibilities of different electron transport pathways. Along with DFT computations, we employed the non-equilibrium green function for identifying electron transport channels within the system. The role of water molecules is also significant in tailoring the pathways. The research results prove that it is impossible to establish specific electron transport channels between the iron atom of cytochrome and the copper of amicyanin. Multiple paths are feasible, as the electron density of states varies with residual fluctuations.

Probing the early stages of photoreception in photoactive yellow protein with ultrafast time-domain Raman spectroscopy

Unveiling the nuclear motions of photoreceptor proteins in action is a crucial goal in protein science in order to understand their elaborate mechanisms and how they achieve optimal selectivity and efficiency. Previous studies have provided detailed information on the structures of intermediates that appear during the later stages (>ns) of such photoreception cycles, yet the initial events immediately after photoabsorption remain unclear because of experimental challenges in monitoring nuclear rearrangements on ultrafast timescales, including protein-specific low-frequency motions. Using time-domain Raman probing with sub-7-fs pulses, we obtain snapshot vibrational spectra of photoactive yellow protein and a mutant with high sensitivity, providing insights into the key responses that drive photoreception. Our data show a drastic intensity drop of the excited-state marker band at 135 cm^-1 within a few hundred femtoseconds, suggesting a rapid weakening of the hydrogen bond that anchors the chromophore. We also track formation of the first ground-state intermediate over the first few picoseconds and fully characterize its vibrational structure, revealing a substantially-twisted cis conformation.

Communication maps of vibrational energy transport through Photoactive Yellow Protein

We calculate communication maps for Photoactive Yellow Protein (PYP) from the purple phototropic eubacterium Halorhodospira halophile and use them to elucidate energy transfer pathways from the chromophore through the rest of the protein in the ground and excited state. The calculations reveal that in PYP excess energy from the chromophore flows mainly to regions of the surrounding residues that hydrogen bond to the chromophore. In addition, quantum mechanics/molecular mechanics and molecular dynamics (MD) simulations of the dielectric response of the protein and solvent environment due to charge rearrangement on the chromophore following photoexcitation are also presented, with both approaches yielding similar time constants for the response. Results of MD simulations indicate that the residues hydrogen bonding to the chromophore make the largest contribution to the response.