Primary reactions of sensory rhodopsins

Lutz, I.

doi:10.1073/pnas.021560298

Cited by 37 publications

(68 citation statements)

References 23 publications

(29 reference statements)

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“…It has been also proposed that the first step in OCP photoactivation involves a rotation of the β-ionone ring about the C6-C7 single bond in the CTD (9). However, our observations do not support significant rotational motions in both β-ionone rings nor a photoisomerization event as observed for retinal in rhodopsins (33). Instead, the difference electron densities suggest a small displacement of the carotenoid mostly in the plane of the polyene chain (Fig.…”

contrasting

confidence: 55%

“…We propose that the initial photochemical event in OCP originates in the essential conjugated carbonyl group of the β1 ring, where a lightinduced shift in keto-enol equilibrium weakens the interactions between the chromophore and protein moiety. Similar to other photoreceptors (33,38), subsequent protein structural changes in OCP are driven by thermal relaxation of the strained chromophore in a confined protein cavity. However, a key difference is that the strain energy is preloaded in a distorted ketocarotenoid in the OCP O structure, whereas the initial conformational strain arises from photoisomerization in phytochromes and rhodopsins (33,38).…”

mentioning

confidence: 99%

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Photoactivation mechanism of a carotenoid-based photoreceptor

Bandara

Ren

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Photoprotection is essential for efficient photosynthesis. Cyanobacteria have evolved a unique photoprotective mechanism mediated by a water-soluble carotenoid-based photoreceptor known as orange carotenoid protein (OCP). OCP undergoes large conformational changes in response to intense blue light, and the photoactivated OCP facilitates dissipation of excess energy via direct interaction with allophycocyanins at the phycobilisome core. However, the structural events leading up to the OCP photoactivation remain elusive at the molecular level. Here we present direct observations of light-induced structural changes in OCP captured by dynamic crystallography. Difference electron densities between the dark and illuminated states reveal widespread and concerted atomic motions that lead to altered protein-pigment interactions, displacement of secondary structures, and domain separation. Based on these crystallographic observations together with sitedirected mutagenesis, we propose a molecular mechanism for OCP light perception, in which the photochemical property of a conjugated carbonyl group is exploited. We hypothesize that the OCP photoactivation starts with keto-enol tautomerization of the essential 4-keto group in the carotenoid, which disrupts the strong hydrogen bonds between the bent chromophore and the protein moiety. Subsequent structural changes trapped in the crystal lattice offer a high-resolution glimpse of the initial molecular events as OCP begins to transition from the orange-absorbing state to the active red-absorbing state.photoreceptor | light perception | photoprotection | carotenoid-binding protein | dynamic crystallography

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contrasting

confidence: 55%

mentioning

confidence: 99%

Photoactivation mechanism of a carotenoid-based photoreceptor

Bandara

Ren

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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“…The high similarity to the primary dynamics observed in BR and in NpSRII, [18] especially the high resemblance of the time constants (see Table 1), is taken as evidence that the driving forces of the primary events, for example, the electrostatics in www.chemphyschem.org the binding pocket, the hydrogen-bonding network, and also the steric properties, are most likely close to the conditions found in BR. The primary reaction dynamics can therefore be interpreted within the framework of the models developed for this protein.…”

Section: Ultrafast Excited-state Deactivationmentioning

confidence: 93%

“…[15][16][17] 0.1 0.5 3-5 -infinite NpSRII [18] 0.1 0.4 5 -infinite Figure 5. DAS of the global fit analysis of the Vis pump-Vis probe dataset using five decay time constants.…”

Section: Ultrafast Reaction Dynamics Determined By Visible Pump-probementioning

confidence: 98%

The Photocycle of Channelrhodopsin‐2: Ultrafast Reaction Dynamics and Subsequent Reaction Steps

et al. 2010

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The photocycle of channelrhodopsin-2 is investigated in a comprehensive study by ultrafast absorption and fluorescence spectroscopy as well as flash photolysis in the visible spectral range. The ultrafast techniques reveal an excited-state decay mechanism analogous to that of the archaeal bacteriorhodopsin and sensory rhodopsin II from Natronomonas pharaonis. After a fast vibrational relaxation of the excited-state population with 150 fs its decay with mainly 400 fs is observed. Hereby, both the initial all-trans retinal ground state and the 13-cis-retinal K photoproduct are populated. The reaction proceeds with a 2.7 ps component assigned to cooling processes. Small spectral shifts are observed on a 200 ps timescale. They are attributed to conformational rearrangements in the retinal binding pocket. The subsequent dynamics progresses with the formation of an M-like intermediate (7 and 120 μs), which decays into red-shifted states within 3 ms. Ground-state recovery including channel closing and reisomerization of the retinal chromophore occurs in a triexponential manner (6 ms, 33 ms, 3.4 s). To learn more about the energy barriers between the different photocycle intermediates, temperature-dependent flash photolysis measurements are performed between 10 and 30°C. The first five time constants decrease with increasing temperature. The calculated thermodynamic parameters indicate that the closing mechanism is controlled by large negative entropy changes. The last time constant is temperature independent, which demonstrates that the photocycle is most likely completed by a series of individual steps recovering the initial structure.

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“…An example are the transducers mediating the phototactic response. Natronomonas has a single blue-light photoreceptor (sensory rhodopsin II; SRII, NP4834A) that is photochemically very similar to the blue-light photoreceptor SRII from Halobacterium but rather different from the orange/UV light photoreceptor SRI (Lutz et al 2001). Although the transducers HtrII from these two archaea form a complex with their respective blue-light photoreceptors SRII (thus mediating the same photophobic response) and genes for receptor and transducer are cotranscribed (Seidel et al 1995;Zhang et al 1996), their domain architecture differs.…”

Section: Motility and Signal Transductionmentioning

confidence: 99%

Living with two extremes: Conclusions from the genome sequence of Natronomonas pharaonis

Pfeiffer²,

et al. 2005

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Natronomonas pharaonis is an extremely haloalkaliphilic archaeon that was isolated from salt-saturated lakes of pH 11. We sequenced its 2.6-Mb GC-rich chromosome and two plasmids (131 and 23 kb). Genome analysis suggests that it is adapted to cope with severe ammonia and heavy metal deficiencies that arise at high pH values. A high degree of nutritional self-sufficiency was predicted and confirmed by growth in a minimal medium containing leucine but no other amino acids or vitamins. Genes for a complex III analog of the respiratory chain could not be identified in the N. pharaonis genome, but respiration and oxidative phosphorylation were experimentally proven. These studies identified protons as coupling ion between respiratory chain and ATP synthase, in contrast to other alkaliphiles using sodium instead. Secretome analysis predicts many extracellular proteins with alkaline-resistant lipid anchors, which are predominantly exported through the twin-arginine pathway. In addition, a variety of glycosylated cell surface proteins probably form a protective complex cell envelope. N. pharaonis is fully equipped with archaeal signal transduction and motility genes. Several receptors/transducers signaling to the flagellar motor display novel domain architectures. Clusters of signal transduction genes are rearranged in haloarchaeal genomes, whereas those involved in information processing or energy metabolism show a highly conserved gene order.

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Primary reactions of sensory rhodopsins

Cited by 37 publications

References 23 publications

Photoactivation mechanism of a carotenoid-based photoreceptor

Photoactivation mechanism of a carotenoid-based photoreceptor

The Photocycle of Channelrhodopsin‐2: Ultrafast Reaction Dynamics and Subsequent Reaction Steps

Living with two extremes: Conclusions from the genome sequence of Natronomonas pharaonis

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