Atomistic Insight into the Role of Threonine 127 in the Functional Mechanism of Channelrhodopsin-2

Ehrenberg, D.; Krause, Nils; Saita, Mattia; Bamann, Christian; Kar, Rup Kumar; Hoffmann, Katharina; Heinrich, Dorothea; Schapiro, Igor; Heberle, Joachim; Schlesinger, Ramona

doi:10.3390/app9224905

Cited by 4 publications

(2 citation statements)

References 40 publications

(41 reference statements)

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“…The D140 homolog position occupied by Thr in many microbial rhodopsins has been widely disregarded by experimentalists but was suggested by theoreticians to contribute to the proton transfer from RSBH + to the acceptor Asp or Glu in rhodopsin pumps and channels [33][34][35] . Moreover, replacement of this Thr in the proton pump Arch to Cys, T99C, in combination with the D95E mutation of the primary proton acceptor shifted the absorption from 556 nm to 626 nm thus creating the largest bathochromic color shift and the most red-shifted microbial rhodopsin which, however, remained unexplained 21 .…”

Section: Rgc1mentioning

confidence: 99%

NeoR, a near-infrared absorbing rhodopsin

et al. 2020

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The Rhizoclosmatium globosum genome encodes three rhodopsin-guanylyl cyclases (RGCs), which are predicted to facilitate visual orientation of the fungal zoospores. Here, we show that RGC1 and RGC2 function as light-activated cyclases only upon heterodimerization with RGC3 (NeoR). RGC1/2 utilize conventional green or blue-light-sensitive rhodopsins (λmax = 550 and 480 nm, respectively), with short-lived signaling states, responsible for light-activation of the enzyme. The bistable NeoR is photoswitchable between a near-infrared-sensitive (NIR, λmax = 690 nm) highly fluorescent state (QF = 0.2) and a UV-sensitive non-fluorescent state, thereby modulating the activity by NIR pre-illumination. No other rhodopsin has been reported so far to be functional as a heterooligomer, or as having such a long wavelength absorption or high fluorescence yield. Site-specific mutagenesis and hybrid quantum mechanics/molecular mechanics simulations support the idea that the unusual photochemical properties result from the rigidity of the retinal chromophore and a unique counterion triad composed of two glutamic and one aspartic acids. These findings substantially expand our understanding of the natural potential and limitations of spectral tuning in rhodopsin photoreceptors.

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Section: Rgc1mentioning

confidence: 99%

NeoR, a near-infrared absorbing rhodopsin

et al. 2020

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“…165 QM/MM methods are now widely applied to the study of excited electronic states, in tandem with electronic structure software packages capable of time-dependent density functional theory or wavefunction-based excited state calculations. Light-sensitive proteins that have been simulated with Chem-Shell in recent studies include a wide range of rhodopsins, [166][167][168][169][170][171][172][173] photosystem II, [174][175][176] calcium-regulated photoproteins, 177 green fluorescent protein, 178 the phototoxic protein KillerRed, 179 bacterial phytochromes, 180,181 and cyanobacteriochromes. [182][183][184] Excited state calculations are typically used to simulate experimental UV-vis spectra, 185 and so are useful for characterising any molecular system containing a chromophore, including catalytic intermediates.…”

Section: Qm/mm Simulations Of Biomoleculesmentioning

confidence: 99%