Your search keyword '"Channelrhodopsins chemistry"' showing total 62 results

1. Unique hydrogen-bonding network in a viral channelrhodopsin.

Author

Aoyama M, Katayama K, and Kandori H

Subjects

Channelrhodopsins chemistry, Channelrhodopsins metabolism, Channelrhodopsins genetics, Spectroscopy, Fourier Transform Infrared, Schiff Bases chemistry, Bacteriorhodopsins chemistry, Bacteriorhodopsins metabolism, Bacteriorhodopsins genetics, Water chemistry, Water metabolism, Viral Proteins chemistry, Viral Proteins metabolism, Viral Proteins genetics, Models, Molecular, Hydrogen Bonding

Abstract

Channelrhodopsins (CRs) are used as key tools in optogenetics, and novel CRs, either found from nature or engineered by mutation, have greatly contributed to the development of optogenetics. Recently CRs were discovered from viruses, and crystal structure of a viral CR, OLPVR1, reported a very similar water-containing hydrogen-bonding network near the retinal Schiff base to that of a light-driven proton-pump bacteriorhodopsin (BR). In both OLPVR1 and BR, nearly planar pentagonal cluster structures are comprised of five oxygen atoms, three oxygens from water molecules and two oxygens from the Schiff base counterions. The planar pentagonal cluster stabilizes a quadrupole, two positive charges at the Schiff base and an arginine, and two negative charges at the counterions, and thus plays important roles in light-gated channel function of OLPVR1 and light-driven proton pump function of BR. Despite similar pentagonal cluster structures, present FTIR analysis revealed different hydrogen-bonding networks between OLPVR1 and BR. The hydrogen bond between the protonated Schiff base and a water is stronger in OLPVR1 than in BR, and internal water molecules donate hydrogen bonds much weaker in OLPVR1 than in BR. In OLPVR1, the bridged water molecule between the Schiff base and counterions forms hydrogen bonds to D76 and D200 equally, while the hydrogen-bonding interaction is much stronger to D85 than to D212 in BR. The present interpretation is supported by the mutation results, where D76 and D200 equally work as the Schiff base counterions in OLPVR1, but D85 is the primary counterion in BR. This work reports highly sensitive hydrogen-bonding network in the Schiff base region, which would be closely related to each function through light-induced alterations of the network., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Hideki Kandori reports was provided by Nagoya Institute of Technology. Hideki Kandori reports a relationship with Nagoya Institute of Technology that includes: employment. Hideki Kandori has patent pending to No. No If there are other authors, they declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

2. The high-light-sensitivity mechanism and optogenetic properties of the bacteriorhodopsin-like channelrhodopsin GtCCR4.

Author

Tanaka T, Hososhima S, Yamashita Y, Sugimoto T, Nakamura T, Shigemura S, Iida W, Sano FK, Oda K, Uchihashi T, Katayama K, Furutani Y, Tsunoda SP, Shihoya W, Kandori H, and Nureki O

Subjects

Animals, Humans, Action Potentials, Channelrhodopsins genetics, Channelrhodopsins metabolism, Channelrhodopsins chemistry, Cryptophyta genetics, Cryptophyta metabolism, HEK293 Cells, Ion Channel Gating radiation effects, Light, Mutation, Structure-Activity Relationship, Bacteriorhodopsins metabolism, Bacteriorhodopsins genetics, Bacteriorhodopsins chemistry, Neurons metabolism, Neurons radiation effects, Optogenetics methods

Abstract

Channelrhodopsins are microbial light-gated ion channels that can control the firing of neurons in response to light. Among several cation channelrhodopsins identified in Guillardia theta (GtCCRs), GtCCR4 has higher light sensitivity than typical channelrhodopsins. Furthermore, GtCCR4 shows superior properties as an optogenetic tool, such as minimal desensitization. Our structural analyses of GtCCR2 and GtCCR4 revealed that GtCCR4 has an outwardly bent transmembrane helix, resembling the conformation of activated G-protein-coupled receptors. Spectroscopic and electrophysiological comparisons suggested that this helix bend in GtCCR4 omits channel recovery time and contributes to high light sensitivity. An electrophysiological comparison of GtCCR4 and the well-characterized optogenetic tool ChRmine demonstrated that GtCCR4 has superior current continuity and action-potential spike generation with less invasiveness in neurons. We also identified highly active mutants of GtCCR4. These results shed light on the diverse structures and dynamics of microbial rhodopsins and demonstrate the strong optogenetic potential of GtCCR4., Competing Interests: Declaration of interests O.N. is a co-founder and scientific advisor for Curreio, Inc. This research was funded by Daiichi Sankyo Co., Ltd. S.H., S.S., S.P.T., and H.K. have a patent related to this work (U.S. Patent No. 12,030,917,　 Japan Patent No. 7492777)., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. Exploring Protonation State, Ion Binding, and Photoactivated Channel Opening of an Anion Channelrhodopsin by Molecular Simulations.

Author

Shikakura T, Cheng C, Hasegawa T, and Hayashi S

Subjects

Channelrhodopsins chemistry, Channelrhodopsins metabolism, Anions chemistry, Anions metabolism, Photochemical Processes, Molecular Dynamics Simulation, Protons, Quantum Theory

Abstract

Channelrhodopsins are light-gated ion channels with a retinal chromophore found in microbes and are widely used in optogenetics, a field of neuroscience that utilizes light to regulate neuronal activity. Gt ACR1, an anion conducting channelrhodopsin derived from Guillardia theta , has attracted attention for its application as a neuronal silencer in optogenetics because of its high conductivity and selectivity. However, atomistic mechanisms of channel photoactivation and ion conduction have not yet been elucidated. In the present study, we investigated the molecular characteristics of Gt ACR1 and its photoactivation processes by molecular simulations. The QM/MM RWFE-SCF method which combines highly accurate quantum chemistry calculations with long-time molecular dynamics (MD) simulations were used to model protein structures of the wild-type and mutants with different protonation states of key groups and to calculate absorption energies for verification of the models. The QM/MM modeling together with MD simulations of free-energy calculations favors protonation of a key counterion carboxyl group of Asp234 with a strong binding of a chloride ion in the extracellular pocket in the dark state. A channel open state was also successfully modeled by the QM/MM RWFE-SCF free-energy optimizations, providing atomistic insights into the channel activation mechanism.

Published

2024

4. Metadynamics simulations reveal mechanisms of Na+ and Ca2+ transport in two open states of the channelrhodopsin chimera, C1C2.

Author

Prignano LA, Stevens MJ, Vanegas JM, Rempe SB, and Dempski RE

Subjects

Animals, Ion Transport, Humans, HEK293 Cells, Ion Channel Gating, Sodium metabolism, Calcium metabolism, Channelrhodopsins metabolism, Channelrhodopsins genetics, Channelrhodopsins chemistry, Molecular Dynamics Simulation

Abstract

Cation conducting channelrhodopsins (ChRs) are a popular tool used in optogenetics to control the activity of excitable cells and tissues using light. ChRs with altered ion selectivity are in high demand for use in different cell types and for other specialized applications. However, a detailed mechanism of ion permeation in ChRs is not fully resolved. Here, we use complementary experimental and computational methods to uncover the mechanisms of cation transport and valence selectivity through the channelrhodopsin chimera, C1C2, in the high- and low-conducting open states. Electrophysiology measurements identified a single-residue substitution within the central gate, N297D, that increased Ca2+ permeability vs. Na+ by nearly two-fold at peak current, but less so at stationary current. We then developed molecular models of dimeric wild-type C1C2 and N297D mutant channels in both open states and calculated the PMF profiles for Na+ and Ca2+ permeation through each protein using well-tempered/multiple-walker metadynamics. Results of these studies agree well with experimental measurements and demonstrate that the pore entrance on the extracellular side differs from original predictions and is actually located in a gap between helices I and II. Cation transport occurs via a relay mechanism where cations are passed between flexible carboxylate sidechains lining the full length of the pore by sidechain swinging, like a monkey swinging on vines. In the mutant channel, residue D297 enhances Ca2+ permeability by mediating the handoff between the central and cytosolic binding sites via direct coordination and sidechain swinging. We also found that altered cation binding affinities at both the extracellular entrance and central binding sites underly the distinct transport properties of the low-conducting open state. This work significantly advances our understanding of ion selectivity and permeation in cation channelrhodopsins and provides the insights needed for successful development of new ion-selective optogenetic tools., Competing Interests: Sandia National Laboratories is a multimission laboratory managed and operated by National Technology & Engineering Solutions of Sandia, LLC, a wholly owned subsidiary of Honeywell International, Inc., for the U.S. DOE’s National Nuclear Security Administration under contract DE-NA-0003525. This does not alter our adherence to PLOS ONE policies on sharing data and materials. There are no patents, products in development or marketed products associated with this research to declare., (Copyright: © 2024 Prignano et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

5. Channelrhodopsins with distinct chromophores and binding patterns.

Author

Shan Y, Zhao L, Chen M, Li X, Zhang M, and Pei D

Subjects

HEK293 Cells, Humans, Cryoelectron Microscopy, Retinaldehyde metabolism, Retinaldehyde chemistry, Protein Binding, Binding Sites, Rhodopsin metabolism, Rhodopsin chemistry, Rhodopsin genetics, Light, Chlamydomonas reinhardtii metabolism, Chlamydomonas reinhardtii genetics, Optogenetics methods, Channelrhodopsins metabolism, Channelrhodopsins genetics, Channelrhodopsins chemistry

Abstract

Channelrhodopsins are popular optogenetic tools in neuroscience, but remain poorly understood mechanistically. Here we report the cryo-EM structures of channelrhodopsin-2 (ChR2) from Chlamydomonas reinhardtii and H. catenoides kalium channelrhodopsin (KCR1). We show that ChR2 recruits an endogenous N-retinylidene-PE-like molecule to a previously unidentified lateral retinal binding pocket, exhibiting a reduced light response in HEK293 cells. In contrast, H. catenoides kalium channelrhodopsin (KCR1) binds an endogenous retinal in its canonical retinal binding pocket under identical condition. However, exogenous ATR reduces the photocurrent magnitude of wild type KCR1 and also inhibits its leaky mutant C110T. Our results uncover diverse retinal chromophores with distinct binding patterns for channelrhodopsins in mammalian cells, which may further inspire next generation optogenetics for complex tasks such as cell fate control., (© 2024. The Author(s).)

Published

2024

6. Parallel photocycle kinetic model of anion channelrhodopsin GtACR1 function.

Author

Szundi I and Kliger DS

Subjects

Kinetics, Rhodopsin metabolism, Rhodopsin chemistry, Rhodopsin genetics, Animals, Anions metabolism, Light, Models, Biological, Channelrhodopsins metabolism, Channelrhodopsins genetics, Channelrhodopsins chemistry, Ion Channel Gating

Abstract

The light-gated anion channelrhodopsin GtACR1 is an important optogenetic tool for neuronal silencing. Its photochemistry, including its photointermediates, is poorly understood. The current mechanistic view presumes BR-like kinetics and assigns the open channel to a blue-absorbing L intermediate. Based on time-resolved absorption and electrophysiological data, we recently proposed a red-absorbing spectral form for the open channel state. Here, we report the results of a comprehensive kinetic analysis of the spectroscopic data combined with channel current information. The time evolutions of the spectral forms derived from the spectroscopic data are inconsistent with the single chain mechanism and are analyzed within the concept of parallel photocycles. The spectral forms partitioned into conductive and nonconductive parallel cycles are assigned to intermediate states. Rejecting reversible connections between conductive and nonconductive channel states leads to kinetic schemes with two independent conductive states corresponding to the fast- and slow-decaying current components. The conductive cycle is discussed in terms of a single cycle and two parallel cycles. The reaction mechanisms and reaction rates for the wild-type protein, the A75E, and the low-conductance D234N and S97E protein variants are derived. The parallel cycles of channelrhodopsin kinetics, its relation to BR photocycle, and the role of the M intermediate in channel closure are discussed., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2024

7. Molecular Mechanisms behind Circular Dichroism Spectral Variations between Channelrhodopsin and Heliorhodopsin Dimers.

Author

Fujimoto KJ, Tsuzuki YA, Inoue K, and Yanai T

Subjects

Channelrhodopsins chemistry, Protein Multimerization, Quantum Theory, Models, Molecular, Circular Dichroism

Abstract

Channelrhodopsin (ChR) and heliorhodopsin (HeR) are microbial rhodopsins with similar structures but different circular dichroism (CD) spectra: ChR shows biphasic negative and positive bands, whereas HeR shows a single positive band. We explored the physicochemical factors underlying these differences through computational methods. Using the exciton model based on first-principles computations, we obtained the CD spectra of ChR and HeR. The obtained spectra indicate that the protein dimer structures and the quantum mechanical treatment of the retinal chromophore and its interacting amino acids are crucial for accurately reproducing the experimental spectra. Further calculations revealed that the sign of the excitonic coupling was opposite between the ChR and HeR dimers, which was attributed to the contrasting second term of the orientation factor between the two retinal chromophores. These findings demonstrate that slight variations in the intermolecular orientation of the two chromophores can result in significant differences in the CD spectral shape.

Published

2024

8. Control of polymers' amorphous-crystalline transition enables miniaturization and multifunctional integration for hydrogel bioelectronics.

Author

Huang S, Liu X, Lin S, Glynn C, Felix K, Sahasrabudhe A, Maley C, Xu J, Chen W, Hong E, Crosby AJ, Wang Q, and Rao S

Subjects

Animals, Mice, Nanotubes, Carbon chemistry, Ventral Tegmental Area physiology, Microelectrodes, Male, Channelrhodopsins metabolism, Channelrhodopsins chemistry, Channelrhodopsins genetics, Polyvinyl Alcohol chemistry, Hydrogels chemistry, Optogenetics methods, Mice, Transgenic, Polymers chemistry

Abstract

Soft bioelectronic devices exhibit motion-adaptive properties for neural interfaces to investigate complex neural circuits. Here, we develop a fabrication approach through the control of metamorphic polymers' amorphous-crystalline transition to miniaturize and integrate multiple components into hydrogel bioelectronics. We attain an about 80% diameter reduction in chemically cross-linked polyvinyl alcohol hydrogel fibers in a fully hydrated state. This strategy allows regulation of hydrogel properties, including refractive index (1.37-1.40 at 480 nm), light transmission (>96%), stretchability (139-169%), bending stiffness (4.6 ± 1.4 N/m), and elastic modulus (2.8-9.3 MPa). To exploit the applications, we apply step-index hydrogel optical probes in the mouse ventral tegmental area, coupled with fiber photometry recordings and social behavioral assays. Additionally, we fabricate carbon nanotubes-PVA hydrogel microelectrodes by incorporating conductive nanomaterials in hydrogel for spontaneous neural activities recording. We enable simultaneous optogenetic stimulation and electrophysiological recordings of light-triggered neural activities in Channelrhodopsin-2 transgenic mice., (© 2024. The Author(s).)

Published

2024

9. Channel Gating in Kalium Channelrhodopsin Slow Mutants.

Author

Sineshchekov OA, Govorunova EG, Li H, Wang Y, and Spudich JL

Subjects

Light, Mutation, Cysteine chemistry, Cysteine genetics, Protein Conformation, alpha-Helical, Humans, HEK293 Cells, Conserved Sequence, Amino Acid Substitution, Channelrhodopsins chemistry, Channelrhodopsins genetics, Rhinosporidium, Ion Channel Gating genetics, Optogenetics

Abstract

Kalium channelrhodopsin 1 from Hyphochytrium catenoides (HcKCR1) is the first discovered natural light-gated ion channel that shows higher selectivity to K + than to Na + and therefore is used to silence neurons with light (optogenetics). Replacement of the conserved cysteine residue in the transmembrane helix 3 (Cys110) with alanine or threonine results in a >1,000-fold decrease in the channel closing rate. The phenotype of the corresponding mutants in channelrhodopsin 2 is attributed to breaking of a specific interhelical hydrogen bond (the "DC gate"). Unlike CrChR2 and other ChRs with long distance "DC gates", the HcKCR1 structure does not reveal any hydrogen bonding partners to Cys110, indicating that the mutant phenotype is likely caused by disruption of direct interaction between this residue and the chromophore. In HcKCR1_C110A, fast photochemical conversions corresponding to channel gating were followed by dramatically slower absorption changes. Full recovery of the unphotolyzed state in HcKCR1_C110A was extremely slow with two time constants 5.2 and 70 min. Analysis of the light-minus-dark difference spectra during these slow processes revealed accumulation of at least four spectrally distinct blue light-absorbing photocycle intermediates, L, M 1 and M 2 , and a UV light-absorbing form, typical of bacteriorhodopsin-like channelrhodopsins from cryptophytes. Our results contribute to better understanding of the mechanistic links between the chromophore photochemistry and channel conductance, and provide the basis for using HcKCR1_C110A as an optogenetic tool., Competing Interests: Declaration of competing interest The authors declare that they have no competing financial interests or personal relationships that influence the work reported in this paper., (Copyright © 2023. Published by Elsevier Ltd.)

Published

2024

10. Structural basis for ion selectivity in potassium-selective channelrhodopsins.

Author

Tajima S, Kim YS, Fukuda M, Jo Y, Wang PY, Paggi JM, Inoue M, Byrne EFX, Kishi KE, Nakamura S, Ramakrishnan C, Takaramoto S, Nagata T, Konno M, Sugiura M, Katayama K, Matsui TE, Yamashita K, Kim S, Ikeda H, Kim J, Kandori H, Dror RO, Inoue K, Deisseroth K, and Kato HE

Subjects

Humans, Cryoelectron Microscopy, Ion Channels, Potassium metabolism, Channelrhodopsins chemistry, Channelrhodopsins genetics, Channelrhodopsins metabolism, Channelrhodopsins ultrastructure, Rhinosporidium chemistry

Abstract

KCR channelrhodopsins (K + -selective light-gated ion channels) have received attention as potential inhibitory optogenetic tools but more broadly pose a fundamental mystery regarding how their K + selectivity is achieved. Here, we present 2.5-2.7 Å cryo-electron microscopy structures of HcKCR1 and HcKCR2 and of a structure-guided mutant with enhanced K + selectivity. Structural, electrophysiological, computational, spectroscopic, and biochemical analyses reveal a distinctive mechanism for K + selectivity; rather than forming the symmetrical filter of canonical K + channels achieving both selectivity and dehydration, instead, three extracellular-vestibule residues within each monomer form a flexible asymmetric selectivity gate, while a distinct dehydration pathway extends intracellularly. Structural comparisons reveal a retinal-binding pocket that induces retinal rotation (accounting for HcKCR1/HcKCR2 spectral differences), and design of corresponding KCR variants with increased K + selectivity (KALI-1/KALI-2) provides key advantages for optogenetic inhibition in vitro and in vivo. Thus, discovery of a mechanism for ion-channel K + selectivity also provides a framework for next-generation optogenetics., Competing Interests: Declaration of interests The KCR variants are described in pending patent application material; these tools and all methods, protocols, clones, and sequences are freely available to nonprofit institutions and investigators. K.D. is a member of the Cell Advisory Board, a co-founder and Scientific Advisory Board member of Stellaromics and Maplight Therapeutics, and a Scientific Advisory Board member of BrightMinds Biosciences., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2023

11. Twisting and Protonation of Retinal Chromophore Regulate Channel Gating of Channelrhodopsin C1C2.

Author

Shibata K, Oda K, Nishizawa T, Hazama Y, Ono R, Takaramoto S, Bagherzadeh R, Yawo H, Nureki O, Inoue K, and Akiyama H

Subjects

Channelrhodopsins chemistry, Protons, Light, Ion Channels, Electrophysiological Phenomena

Abstract

Channelrhodopsins (ChRs) are light-gated ion channels and central optogenetic tools that can control neuronal activity with high temporal resolution at the single-cell level. Although their application in optogenetics has rapidly progressed, it is unsolved how their channels open and close. ChRs transport ions through a series of interlocking elementary processes that occur over a broad time scale of subpicoseconds to seconds. During these processes, the retinal chromophore functions as a channel regulatory domain and transfers the optical input as local structural changes to the channel operating domain, the helices, leading to channel gating. Thus, the core question on channel gating dynamics is how the retinal chromophore structure changes throughout the photocycle and what rate-limits the kinetics. Here, we investigated the structural changes in the retinal chromophore of canonical ChR, C1C2, in all photointermediates using time-resolved resonance Raman spectroscopy. Moreover, to reveal the rate-limiting factors of the photocycle and channel gating, we measured the kinetic isotope effect of all photoreaction processes using laser flash photolysis and laser patch clamp, respectively. Spectroscopic and electrophysiological results provided the following understanding of the channel gating: the retinal chromophore highly twists upon the retinal Schiff base (RSB) deprotonation, causing the surrounding helices to move and open the channel. The ion-conducting pathway includes the RSB, where inflowing water mediates the proton to the deprotonated RSB. The twisting of the retinal chromophore relaxes upon the RSB reprotonation, which closes the channel. The RSB reprotonation rate-limits the channel closing.

Published

2023

12. Structural basis for channel conduction in the pump-like channelrhodopsin ChRmine.

Author

Kishi KE, Kim YS, Fukuda M, Inoue M, Kusakizako T, Wang PY, Ramakrishnan C, Byrne EFX, Thadhani E, Paggi JM, Matsui TE, Yamashita K, Nagata T, Konno M, Quirin S, Lo M, Benster T, Uemura T, Liu K, Shibata M, Nomura N, Iwata S, Nureki O, Dror RO, Inoue K, Deisseroth K, and Kato HE

Subjects

Animals, Channelrhodopsins ultrastructure, Cryoelectron Microscopy, Female, HEK293 Cells, Humans, Male, Mice, Inbred C57BL, Models, Molecular, Optogenetics, Phylogeny, Rats, Sprague-Dawley, Schiff Bases chemistry, Sf9 Cells, Structure-Activity Relationship, Mice, Rats, Channelrhodopsins chemistry, Channelrhodopsins metabolism, Ion Channel Gating

Abstract

ChRmine, a recently discovered pump-like cation-conducting channelrhodopsin, exhibits puzzling properties (large photocurrents, red-shifted spectrum, and extreme light sensitivity) that have created new opportunities in optogenetics. ChRmine and its homologs function as ion channels but, by primary sequence, more closely resemble ion pump rhodopsins; mechanisms for passive channel conduction in this family have remained mysterious. Here, we present the 2.0 Å resolution cryo-EM structure of ChRmine, revealing architectural features atypical for channelrhodopsins: trimeric assembly, a short transmembrane-helix 3, a twisting extracellular-loop 1, large vestibules within the monomer, and an opening at the trimer interface. We applied this structure to design three proteins (rsChRmine and hsChRmine, conferring further red-shifted and high-speed properties, respectively, and frChRmine, combining faster and more red-shifted performance) suitable for fundamental neuroscience opportunities. These results illuminate the conduction and gating of pump-like channelrhodopsins and point the way toward further structure-guided creation of channelrhodopsins for applications across biology., Competing Interests: Declaration of interests The ChRmine antibody (Fab02) and ChRmine variants are described in the pending patent application material; these tools and all methods, protocols, clones, and sequences are freely available to nonprofit institutions and investigators. K.D. is a member of the Cell advisory board., (Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2022

13. Structural Factors Determining the Absorption Spectrum of Channelrhodopsins: A Case Study of the Chimera C1C2.

Author

Adam S, Wiebeler C, and Schapiro I

Subjects

Hydrogen Bonding, Channelrhodopsins chemistry, Schiff Bases

Abstract

Channelrhodopsins are photosensitive proteins that trigger flagella motion in single-cell algae and have been successfully utilized in optogenetic applications. In optogenetics, light is used to activate neural cells in living organisms, which can be achieved by exploiting the ion channel signaling of channelrhodopsins. Tailoring channelrhodopsins for such applications includes the tuning of the absorption maximum. In order to establish rational design and to obtain a desired spectral shift, a basic understanding of the absorption spectrum is required. We have studied the chimera C1C2 as a representative of this protein family and the first member with an available crystal structure. For this purpose, we sampled the conformations of C1C2 using quantum mechanical/molecular mechanical molecular dynamics and subjected the resulting snapshots of the trajectory to excitation energy calculations using ADC(2) and simplified time-dependent density functional theory. In contrast to previous reports, we found that different hydrogen-bonding networks-involving the retinal protonated Schiff base, the putative counterions E162 and D292, and water molecules-had only a small impact on the absorption spectrum. However, in the case of deprotonated E162, increasing the distance to the Schiff base hydrogen-bonding partner led to a systematic blue shift. The β-ionone ring rotation was identified as another important contributor. Yet the most important factors were found to be the bond length alternation and bond order alternation that were linearly correlated to the absorption maximum by up to 62 and 82%, respectively. We ascribe this novel insight into the structural basis of the absorption spectrum to our enhanced protein setup that includes membrane embedding as well as long and extensive sampling.

Published

2021

14. The Desensitized Channelrhodopsin-2 Photointermediate Contains 13 -cis, 15 -syn Retinal Schiff Base.

Author

Becker-Baldus J, Leeder A, Brown LJ, Brown RCD, Bamann C, and Glaubitz C

Subjects

Cations chemistry, Light, Magnetic Resonance Spectroscopy, Photochemical Processes, Photons, Protein Conformation, Channelrhodopsins chemistry, Chlamydomonas reinhardtii chemistry, Diterpenes chemistry, Retinaldehyde chemistry, Schiff Bases chemistry

Abstract

Channelrhodopsin-2 (ChR2) is a light-gated cation channel and was used to lay the foundations of optogenetics. Its dark state X-ray structure has been determined in 2017 for the wild-type, which is the prototype for all other ChR variants. However, the mechanistic understanding of the channel function is still incomplete in terms of structural changes after photon absorption by the retinal chromophore and in the framework of functional models. Hence, detailed information needs to be collected on the dark state as well as on the different photointermediates. For ChR2 detailed knowledge on the chromophore configuration in the different states is still missing and a consensus has not been achieved. Using DNP-enhanced solid-state MAS NMR spectroscopy on proteoliposome samples, we unambiguously determined the chromophore configuration in the desensitized state, and we show that this state occurs towards the end of the photocycle., (© 2021 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2021

15. The crystal structure of bromide-bound Gt ACR1 reveals a pre-activated state in the transmembrane anion tunnel.

Author

Li H, Huang CY, Govorunova EG, Sineshchekov OA, Yi A, Rothschild KJ, Wang M, Zheng L, and Spudich JL

Subjects

Animals, Anions chemistry, Bromides chemistry, Cell Membrane, Channelrhodopsins genetics, Cryptophyta chemistry, Crystallography, X-Ray, HEK293 Cells, Humans, Ion Transport, Optogenetics, Sf9 Cells, Channelrhodopsins chemistry, Ion Channel Gating physiology

Abstract

The crystal structure of the light-gated anion channel Gt ACR1 reported in our previous Research Article (Li et al., 2019) revealed a continuous tunnel traversing the protein from extracellular to intracellular pores. We proposed the tunnel as the conductance channel closed by three constrictions: C1 in the extracellular half, mid-membrane C2 containing the photoactive site, and C3 on the cytoplasmic side. Reported here, the crystal structure of bromide-bound Gt ACR1 reveals structural changes that relax the C1 and C3 constrictions, including a novel salt-bridge switch mechanism involving C1 and the photoactive site. These findings indicate that substrate binding induces a transition from an inactivated state to a pre-activated state in the dark that facilitates channel opening by reducing free energy in the tunnel constrictions. The results provide direct evidence that the tunnel is the closed form of the channel of Gt ACR1 and shed light on the light-gated channel activation mechanism., Competing Interests: HL, CH, AY, KR, MW, LZ No competing interests declared, EG, OS, JS as an inventor and The University of Texas Health Science Center at Houston has been granted a patent titled: Compositions and Methods for Use of Anion Channel Rhodopsins Patent # 10,519,205 granted Dec 31, 2019 by the US Patent and Trademark Office., (© 2021, Li et al.)

Published

2021

16. Electrostatic Control of Photoisomerization in Channelrhodopsin 2.

Author

Liang R, Yu JK, Meisner J, Liu F, and Martinez TJ

Subjects

Isomerism, Molecular Dynamics Simulation, Schiff Bases chemistry, Mutation, Optogenetics methods, Static Electricity, Photochemical Processes, Channelrhodopsins chemistry, Channelrhodopsins genetics, Channelrhodopsins metabolism

Abstract

Channelrhodopsin 2 (ChR2) is the most commonly used tool in optogenetics. Because of its faster photocycle compared to wild-type (WT) ChR2, the E123T mutant of ChR2 is a useful optogenetic tool when fast neuronal stimulation is needed. Interestingly, in spite of its faster photocycle, the initial step of the photocycle in E123T (photoisomerization of retinal protonated Schiff base or RPSB) was found experimentally to be much slower than that of WT ChR2. The E123T mutant replaces the negatively charged E123 residue with a neutral T123 residue, perturbing the electric field around the RPSB. Understanding the RPSB photoisomerization mechanism in ChR2 mutants will provide molecular-level insights into how ChR2 photochemical reactivity can be controlled, which will lay the foundation for improving the design of optogenetic tools. In this work, we combine ab initio nonadiabatic dynamics simulation, excited state free energy calculation, and reaction path search to comprehensively characterize the RPSB photoisomerization mechanism in the E123T mutant of ChR2. Our simulation agrees with previous experiments in predicting a red-shifted absorption spectrum and significant slowdown of photoisomerization in the E123T mutant. Interestingly, our simulations predict similar photoisomerization quantum yields for the mutant and WT despite the differences in excited-state lifetime and absorption maximum. Upon mutation, the neutralization of the negative charge on the E123 residue increases the isomerization barrier, alters the reaction pathway, and changes the relative stability of two fluorescent states. Our findings provide new insight into the intricate role of the electrostatic environment on the RPSB photoisomerization mechanism in microbial rhodopsins.

Published

2021

17. Time-resolved serial femtosecond crystallography reveals early structural changes in channelrhodopsin.

Author

Oda K, Nomura T, Nakane T, Yamashita K, Inoue K, Ito S, Vierock J, Hirata K, Maturana AD, Katayama K, Ikuta T, Ishigami I, Izume T, Umeda R, Eguma R, Oishi S, Kasuya G, Kato T, Kusakizako T, Shihoya W, Shimada H, Takatsuji T, Takemoto M, Taniguchi R, Tomita A, Nakamura R, Fukuda M, Miyauchi H, Lee Y, Nango E, Tanaka R, Tanaka T, Sugahara M, Kimura T, Shimamura T, Fujiwara T, Yamanaka Y, Owada S, Joti Y, Tono K, Ishitani R, Hayashi S, Kandori H, Hegemann P, Iwata S, Kubo M, Nishizawa T, and Nureki O

Subjects

Algal Proteins chemistry, Algal Proteins metabolism, Amino Acid Sequence, Channelrhodopsins chemistry, Channelrhodopsins metabolism, Chlamydomonas reinhardtii metabolism, Crystallography, Isomerism, Protein Conformation, Protein Structure, Secondary, Sequence Alignment, Algal Proteins genetics, Channelrhodopsins genetics, Chlamydomonas reinhardtii genetics

Abstract

Channelrhodopsins (ChRs) are microbial light-gated ion channels utilized in optogenetics to control neural activity with light . Light absorption causes retinal chromophore isomerization and subsequent protein conformational changes visualized as optically distinguished intermediates, coupled with channel opening and closing. However, the detailed molecular events underlying channel gating remain unknown. We performed time-resolved serial femtosecond crystallographic analyses of ChR by using an X-ray free electron laser, which revealed conformational changes following photoactivation. The isomerized retinal adopts a twisted conformation and shifts toward the putative internal proton donor residues, consequently inducing an outward shift of TM3, as well as a local deformation in TM7. These early conformational changes in the pore-forming helices should be the triggers that lead to opening of the ion conducting pore., Competing Interests: KO, TN, TN, KY, KI, SI, JV, KH, AM, KK, TI, II, TI, RU, RE, SO, GK, TK, TK, WS, HS, TT, MT, RT, AT, RN, MF, HM, YL, EN, RT, TT, MS, TK, TS, TF, YY, SO, YJ, KT, RI, SH, HK, PH, SI, MK, TN, ON No competing interests declared, (© 2021, Oda et al.)

Published

2021

18. Specific residues in the cytoplasmic domain modulate photocurrent kinetics of channelrhodopsin from Klebsormidium nitens.

Author

Tashiro R, Sushmita K, Hososhima S, Sharma S, Kateriya S, Kandori H, and Tsunoda SP

Subjects

Amino Acid Sequence, Animals, Cell Line, Channelrhodopsins chemistry, Channelrhodopsins genetics, Channelrhodopsins radiation effects, Chlorophyta genetics, Chlorophyta radiation effects, Kinetics, Light, Membrane Potentials, Mice, Optogenetics, Protein Domains, Rats, Structure-Activity Relationship, Channelrhodopsins metabolism, Chlorophyta metabolism, Ion Channel Gating radiation effects

Abstract

Channelrhodopsins (ChRs) are light-gated ion channels extensively applied as optogenetics tools for manipulating neuronal activity. All currently known ChRs comprise a large cytoplasmic domain, whose function is elusive. Here, we report the cation channel properties of KnChR, one of the photoreceptors from a filamentous terrestrial alga Klebsormidium nitens, and demonstrate that the cytoplasmic domain of KnChR modulates the ion channel properties. KnChR is constituted of a 7-transmembrane domain forming a channel pore, followed by a C-terminus moiety encoding a peptidoglycan binding domain (FimV). Notably, the channel closure rate was affected by the C-terminus moiety. Truncation of the moiety to various lengths prolonged the channel open lifetime by more than 10-fold. Two Arginine residues (R287 and R291) are crucial for altering the photocurrent kinetics. We propose that electrostatic interaction between the rhodopsin domain and the C-terminus domain accelerates the channel kinetics. Additionally, maximal sensitivity was exhibited at 430 and 460 nm, the former making KnChR one of the most blue-shifted ChRs characterized thus far, serving as a novel prototype for studying the molecular mechanism of color tuning of the ChRs. Furthermore, KnChR would expand the optogenetics tool kit, especially for dual light applications when short-wavelength excitation is required.

Published

2021

19. Characterizing Channelrhodopsin Channel Properties Via Two-Electrode Voltage Clamp and Kinetic Modeling.

Author

Prignano L, Herchenroder L, and Dempski RE

Subjects

Animals, Cell Membrane genetics, Channelrhodopsins genetics, Ion Channel Gating, Kinetics, Membrane Potentials genetics, Microelectrodes, Oocytes chemistry, Oocytes growth & development, Xenopus laevis genetics, Channelrhodopsins chemistry, Molecular Biology methods, Oocytes metabolism, Patch-Clamp Techniques methods

Abstract

Two-electrode voltage clamp (TEVC) is a preferred electrophysiological technique used to study gating kinetics and ion selectivity of light-activated channelrhodopsins (ChRs). The method uses two intracellular microelectrodes to hold, or clamp, the membrane potential at a specific value and measure the flow of ions across the plasma membrane. Here, we describe the use of TEVC and a simple solution exchange protocol to measure cation selectivity and analyze gating kinetics of the C1C2 chimera expressed in Xenopus laevis oocytes. Detailed instructions on how to process the collected data and interpret the results are also provided.

Published

2021

20. Two-Photon Optogenetic Stimulation of Drosophila Neurons.

Author

Fişek M and Jeanne JM

Subjects

Animals, Channelrhodopsins radiation effects, Drosophila melanogaster chemistry, Light, Photons, Channelrhodopsins chemistry, Drosophila melanogaster radiation effects, Neurons radiation effects, Optogenetics methods

Abstract

Optogenetics enables experimental control over neural activity using light. Channelrhodopsin and its variants are typically activated using visible light excitation but can also be activated using infrared two-photon excitation. Two-photon excitation can improve the spatial precision of stimulation in scattering tissue but has several practical limitations that need to be considered before use. Here we describe the methodology and best practices for using two-photon optogenetic stimulation of neurons within the brain of the fruit fly, Drosophila melanogaster, with an emphasis on projection neurons of the antennal lobe.

Published

2021

21. Molecular Dynamics Simulations of Channelrhodopsin Chimera, C1C2.

Author

VanGordon MR

Subjects

Ions chemistry, Lipid Bilayers chemistry, Solvents chemistry, Water chemistry, Channelrhodopsins chemistry, Channelrhodopsins genetics, Molecular Dynamics Simulation, Sodium chemistry

Abstract

Molecular dynamics (MD) simulations have been successfully used for modeling dynamic behavior of biologically relevant systems, such as ion channels in representative environments to decode protein structure-function relationships. Protocol presented here describes steps for generating input files and modeling a monomer of transmembrane cation channel, channelrhodopsin chimera (C1C2), in representative environment of 1,2-dioleoyl-sn-glycero-3-phosphatidylcholine (DOPC) planar lipid bilayer, TIP3P water and ions (Na + and Cl - ) using molecular dynamics package NAMD, molecular graphics/analysis tool VMD, and other relevant tools. MD simulations of C1C2 were performed at 303.15 K and in constant particle number, isothermal-isobaric (NpT) ensemble. The results of modeling have helped understand how key interactions in the center of the C1C2 channel contribute to channel gating and subsequent solvent transport across the membrane.

Published

2021

22. Probing Channelrhodopsin Electrical Activity in Algal Cell Populations.

Author

Sineshchekov OA, Govorunova EG, and Spudich JL

Subjects

Light, Rhodopsin, Algal Proteins chemistry, Channelrhodopsins chemistry, Chlamydomonas reinhardtii chemistry, Molecular Biology methods

Abstract

Photoelectric recording from populations of phototactic flagellate algae provides a means to study channelrhodopsin functions in vivo. Technical simplicity, versatility, high sensitivity, and reproducibility are the advantages of this assay over recording from individual algal cells by the suction pipette technique. Here we describe the principles and procedures of this assay.

Published

2021

23. Structure-Function Relationship of Channelrhodopsins.

Author

Kato HE

Subjects

Channelrhodopsins genetics, Channelrhodopsins radiation effects, Light, Membrane Potentials, Rhodopsin genetics, Rhodopsin radiation effects, Structure-Activity Relationship, Channelrhodopsins chemistry, Channelrhodopsins metabolism, Optogenetics methods, Rhodopsin chemistry, Rhodopsin metabolism

Abstract

Ion-translocating rhodopsins, especially channelrhodopsins (ChRs), have attracted broad attention as a powerful tool to modulate the membrane potential of cells with light (optogenetics). Because of recent biophysical, spectroscopic, and computational studies, including the structural determination of cation and anion ChRs, our understanding of the molecular mechanism underlying light-gated ion conduction has been greatly advanced. In this chapter, I first describe the background of rhodopsin family proteins including ChR, and how the optogenetics technology has been established from the discovery of first ChR in 2002. I later introduce the recent findings of the structure-function relationship of ChR by comparing the crystal structures of cation and anion ChRs. I further discuss the future goal in the fields of ChR research and optogenetic tool development.

Published

2021

24. Charge Transport by Light-Activated Rhodopsins Determined by Electrophysiological Recordings.

Author

Hussein T and Bamann C

Subjects

Channelrhodopsins radiation effects, Ion Channel Gating radiation effects, Ion Transport radiation effects, Kinetics, Light, Membrane Potentials radiation effects, Rhodopsins, Microbial radiation effects, Channelrhodopsins chemistry, Electrophysiological Phenomena radiation effects, Molecular Biology methods, Rhodopsins, Microbial chemistry

Abstract

Electrophysiological experiments are required to determine the ion transport properties of light-activated currents from microbial rhodopsin expressing cells. The recordings set the quantitative basis for correlation with spectroscopic data and for understanding of channel gating, ion transport vectoriality, or ion selectivity. This chapter focuses on voltage-clamp recordings of channelrhodopsin-2-expressing cells, and it will describe different illumination protocols that reveal the kinetic properties of gating. While the opening and closing reaction is determined from a single turnover upon a short laser flash, desensitization of the light-gated currents is studied under continuous illumination. Recovery from the desensitized state is probed after prolonged illumination with a subsequent light activation upon different dark intervals. Compiling the experimental data will define a minimum number of states in kinetic schemes used to describe the light-gated currents in channelrhodopsins, and emphasis will be given on how to correlate the results with the different time-resolved spectroscopic experiments.

Published

2021

25. Computing Potential of the Mean Force Profiles for Ion Permeation Through Channelrhodopsin Chimera, C1C2.

Author

Priest C, VanGordon MR, Rempe C, Chaudhari MI, Stevens MJ, Rick S, and Rempe SB

Subjects

Ions chemistry, Mechanical Phenomena, Sodium chemistry, Thermodynamics, Water chemistry, Channelrhodopsins chemistry, Molecular Dynamics Simulation

Abstract

Umbrella sampling, coupled with a weighted histogram analysis method (US-WHAM), can be used to construct potentials of mean force (PMFs) for studying the complex ion permeation pathways of membrane transport proteins. Despite the widespread use of US-WHAM, obtaining a physically meaningful PMF can be challenging. Here, we provide a protocol to resolve that issue. Then, we apply that protocol to compute a meaningful PMF for sodium ion permeation through channelrhodopsin chimera, C1C2, for illustration.

Published

2021

26. Nanodisc Reconstitution of Channelrhodopsins Heterologously Expressed in Pichia pastoris for Biophysical Investigations.

Author

Walter M and Schlesinger R

Subjects

Biophysical Phenomena, Channelrhodopsins chemistry, Chlamydomonas chemistry, Gene Expression Regulation genetics, Light, Plant Proteins chemistry, Spectroscopy, Fourier Transform Infrared, Channelrhodopsins genetics, Molecular Biology methods, Nanocomposites chemistry, Saccharomycetales genetics

Abstract

For a successful characterization of channelrhodopsins with biophysical methods like FTIR, Raman, EPR and NMR spectroscopy and X-ray crystallography, large amounts of purified protein are requested. For proteins of eukaryotic origin, which are poorly expressing in bacterial systems or not at all, the yeast Pichia pastoris represents a promising alternative for overexpression. Here we describe the methods for cloning, overexpression and mutagenesis as well as the purification procedures for channelrhodopsin-2 from Chlamydomonas reinhardtii (CrChR2), channelrhodopsin-1 from Chlamydomonas augustae (CaChR1) and the scaffold protein MSP1D1 for reconstitution of the membrane proteins into nanodiscs. Finally, protocols are provided to study CaChR1 by FTIR difference spectroscopy and by time-resolved UV/Vis spectroscopy.

Published

2021

27. An efficient cell type specific conjugating method for incorporating various nanostructures to genetically encoded AviTag expressed optogenetic opsins.

Author

Bang Y, Kim YY, and Song YK

Subjects

Animals, Biotinylation, Cells, Cultured, Channelrhodopsins chemistry, Neurons cytology, Opsins chemistry, Peptides chemistry, Peptides genetics, Rats, Sprague-Dawley, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Transduction, Genetic, Channelrhodopsins genetics, Neurons metabolism, Opsins genetics, Optogenetics methods, Quantum Dots chemistry

Abstract

Here, we report genetically encoded AviTag conjugating system for Channelrhodopsin-2(ChR2) in order to attach various nanostructures to the membrane protein in a cell type specific manner. First, AviTag peptide sequence is cloned to N-terminal site of ChR2 construct and expressed at the membrane of primary-cultured hippocampal neurons via lentiviral transduction. Second, with the help of BirA enzyme and ATP, biotin coated quantum dots (Qdots) and streptavidin (SAv) coated Qdots are successfully bound to AviTag sites at the membrane where ChR2 is located and confirmed by fluorescence imaging. Moreover, we synthesize biotinylated Traptavidin-DNA conjugate probes containing a desthio-biotin that has weaker affinity than a regular biotin, and successfully exchange them with pre-conjugated Biotin-AviTag-ChR2 site at the membrane of neuronal cells which can potentially solve the crosslinking issue of Avidin linked probes. Therefore, we expect the AviTag-ChR2 fusion platform to become a great tool for incorporating various nanostructures at the specific sites of a cellular membrane in order to overcome the limits of optogenetic opsins., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

28. RubyACRs, nonalgal anion channelrhodopsins with highly red-shifted absorption.

Author

Govorunova EG, Sineshchekov OA, Li H, Wang Y, Brown LS, and Spudich JL

Subjects

Anions metabolism, Cryptophyta genetics, HEK293 Cells, Humans, Ion Channels chemistry, Ion Channels metabolism, Light, Membrane Potentials physiology, Neurons metabolism, Optogenetics methods, Rhodopsin metabolism, Channelrhodopsins chemistry, Ion Channel Gating physiology

Abstract

Channelrhodopsins are light-gated ion channels widely used to control neuronal firing with light (optogenetics). We report two previously unknown families of anion channelrhodopsins (ACRs), one from the heterotrophic protists labyrinthulea and the other from haptophyte algae. Four closely related labyrinthulea ACRs, named RubyACRs here, exhibit a unique retinal-binding pocket that creates spectral sensitivities with maxima at 590 to 610 nm, the most red-shifted channelrhodopsins known, long-sought for optogenetics, and more broadly the most red-shifted microbial rhodopsins thus far reported. We identified three spectral tuning residues critical for the red-shifted absorption. Photocurrents recorded from the RubyACR from Aurantiochytrium limacinum (designated Al ACR1) under single-turnover excitation exhibited biphasic decay, the rate of which was only weakly voltage dependent, in contrast to that in previously characterized cryptophyte ACRs, indicating differences in channel gating mechanisms between the two ACR families. Moreover, in A. limacinum we identified three ACRs with absorption maxima at 485, 545, and 590 nm, indicating color-sensitive photosensing with blue, green, and red spectral variation of ACRs within individual species of the labyrinthulea family. We also report functional energy transfer from a cytoplasmic fluorescent protein domain to the retinal chromophore bound within RubyACRs., Competing Interests: The authors declare no competing interest.

Published

2020

29. Seeing (and Using) the Light: Recent Developments in Bioluminescence Technology.

Author

Love AC and Prescher JA

Subjects

Animals, Channelrhodopsins chemistry, Channelrhodopsins metabolism, Firefly Luciferin metabolism, Imidazoles chemistry, Light, Luciferases genetics, Luciferases metabolism, Microscopy, Fluorescence, Neoplasms diagnostic imaging, Optical Imaging, Pyrazines chemistry, Luminescent Measurements methods

Abstract

Bioluminescence has long been used to image biological processes in vivo. This technology features luciferase enzymes and luciferin small molecules that produce visible light. Bioluminescent photons can be detected in tissues and live organisms, enabling sensitive and noninvasive readouts on physiological function. Traditional applications have focused on tracking cells and gene expression patterns, but new probes are pushing the frontiers of what can be visualized. The past few years have also seen the merger of bioluminescence with optogenetic platforms. Luciferase-luciferin reactions can drive light-activatable proteins, ultimately triggering signal transduction and other downstream events. This review highlights these and other recent advances in bioluminescence technology, with an emphasis on tool development. We showcase how new luciferins and engineered luciferases are expanding the scope of optical imaging. We also highlight how bioluminescent systems are being leveraged not just for sensing-but also controlling-biological processes., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

30. Green-Sensitive, Long-Lived, Step-Functional Anion Channelrhodopsin-2 Variant as a High-Potential Neural Silencing Tool.

Author

Kojima K, Miyoshi N, Shibukawa A, Chowdhury S, Tsujimura M, Noji T, Ishikita H, Yamanaka A, and Sudo Y

Subjects

Anions chemistry, Channelrhodopsins genetics, Cryptophyta genetics, Escherichia coli genetics, Gene Expression Regulation, Green Chemistry Technology, HEK293 Cells, Humans, Ion Transport, Mutation, Optogenetics, Photochemical Processes, Channelrhodopsins chemistry, Cryptophyta chemistry, Fluorescent Dyes chemistry

Abstract

Anion channelrhodopsin-2 (GtACR2) was identified from the alga Guillardia theta as a light-gated anion channel, providing a powerful neural silencing tool for optogenetics. To expand its molecular properties, we produced here GtACR2 variants by strategic mutations on the four residues around the retinal chromophore (i.e., R129, G152, P204, and C233). After the screening with the Escherichia coli expression system, we estimated spectral sensitivities and the anion channeling function by using the HEK293 expression system. Among the mutants, triple (R129M/G152S/C233A) and quadruple (R129M/G152S/P204T/C233A) mutants showed the significantly red-shifted absorption maxima (λ max = 498 and 514 nm, respectively) and the long-lived channel-conducting states (the half-life times were 3.4 and 5.4 s, respectively). In addition, both mutants can be activated and inactivated by different wavelengths, representing their step-functional ability. We nicknamed the quadruple mutant "GLaS-ACR2" from its green-sensitive, long-lived, step-functional properties. The unique characteristics of GLaS-ACR2 suggest its high potential as a neural silencing tool.

Published

2020

31. Output from VIP cells of the mammalian central clock regulates daily physiological rhythms.

Author

Paul S, Hanna L, Harding C, Hayter EA, Walmsley L, Bechtold DA, and Brown TM

Subjects

Action Potentials drug effects, Action Potentials physiology, Animals, Bicuculline pharmacology, Channelrhodopsins chemistry, Channelrhodopsins genetics, Channelrhodopsins metabolism, Circadian Clocks drug effects, Corticosterone blood, Corticosterone metabolism, Electrodes, Implanted, Female, GABA-A Receptor Antagonists pharmacology, GABAergic Neurons drug effects, Heart Rate physiology, Male, Mice, Mice, Transgenic, Models, Animal, Suprachiasmatic Nucleus cytology, Vasoactive Intestinal Peptide antagonists & inhibitors, Vasoactive Intestinal Peptide genetics, Circadian Clocks physiology, Circadian Rhythm physiology, GABAergic Neurons metabolism, Suprachiasmatic Nucleus physiology, Vasoactive Intestinal Peptide metabolism

Abstract

The suprachiasmatic nucleus (SCN) circadian clock is critical for optimising daily cycles in mammalian physiology and behaviour. The roles of the various SCN cell types in communicating timing information to downstream physiological systems remain incompletely understood, however. In particular, while vasoactive intestinal polypeptide (VIP) signalling is essential for SCN function and whole animal circadian rhythmicity, the specific contributions of VIP cell output to physiological control remains uncertain. Here we reveal a key role for SCN VIP cells in central clock output. Using multielectrode recording and optogenetic manipulations, we show that VIP neurons provide coordinated daily waves of GABAergic input to target cells across the paraventricular hypothalamus and ventral thalamus, supressing their activity during the mid to late day. Using chemogenetic manipulation, we further demonstrate specific roles for this circuitry in the daily control of heart rate and corticosterone secretion, collectively establishing SCN VIP cells as influential regulators of physiological timing.

Published

2020

32. Ultrafast Backbone Protonation in Channelrhodopsin-1 Captured by Polarization Resolved Fs Vis-pump-IR-Probe Spectroscopy and Computational Methods.

Author

Stensitzki T, Adam S, Schlesinger R, Schapiro I, and Heyne K

Subjects

Channelrhodopsins ultrastructure, Chlamydomonas chemistry, Isomerism, Light, Molecular Dynamics Simulation, Protons, Quantum Theory, Rhodopsin ultrastructure, Spectrum Analysis, Channelrhodopsins chemistry, Models, Molecular, Protein Conformation, Rhodopsin chemistry

Abstract

Channelrhodopsins (ChR) are light-gated ion-channels heavily used in optogenetics. Upon light excitation an ultrafast all- trans to 13- cis isomerization of the retinal chromophore takes place. It is still uncertain by what means this reaction leads to further protein changes and channel conductivity. Channelrhodopsin-1 in Chlamydomonas augustae exhibits a 100 fs photoisomerization and a protonated counterion complex. By polarization resolved ultrafast spectroscopy in the mid-IR we show that the initial reaction of the retinal is accompanied by changes in the protein backbone and ultrafast protonation changes at the counterion complex comprising Asp299 and Glu169. In combination with homology modelling and quantum mechanics/molecular mechanics (QM/MM) geometry optimization we assign the protonation dynamics to ultrafast deprotonation of Glu169, and transient protonation of the Glu169 backbone, followed by a proton transfer from the backbone to the carboxylate group of Asp299 on a timescale of tens of picoseconds. The second proton transfer is not related to retinal dynamics and reflects pure protein changes in the first photoproduct. We assume these protein dynamics to be the first steps in a cascade of protein-wide changes resulting in channel conductivity.

Published

2020

33. Synthesis of One Double Bond-Inserted Retinal Analogs and Their Binding Experiments with Opsins: Preparation of Novel Red-Shifted Channelrhodopsin Variants.

Author

Okitsu T, Yamano Y, Shen YC, Sasaki T, Kobayashi Y, Morisawa S, Yamashita T, Imamoto Y, Shichida Y, and Wada A

Subjects

Binding Sites, Channelrhodopsins metabolism, HEK293 Cells, Humans, Molecular Structure, Retinaldehyde chemistry, Structure-Activity Relationship, Channelrhodopsins chemistry, Channelrhodopsins genetics, Retinaldehyde analogs & derivatives, Retinaldehyde chemical synthesis

Abstract

In optogenetics, red-shifted channelrhodopsins (ChRs) are eagerly sought. We prepared six kinds of new chromophores with one double bond inserted into the polyene side chain of retinal (A1) or 3,4-didehydroretinal (A2), and examined their binding efficiency with opsins (ReaChR and ChrimsonR). All analogs bound with opsins to afford new ChRs. Among them, A2-10ex (an extra double bond is inserted at the C10-C11 position of A2) showed the greatest red-shift in the absorption spectrum of ChrimsonR, with a maximum absorbance at 654 nm (67 nm red-shifted from that of A1-ChrimsonR). Moreover, a long-wavelength spectral boundary of A2-10ex-ChrimsonR was extended to 756 nm, which reached into the far-red region (710-850 nm).

Published

2020

34. Molecular Dynamics Simulation of Transmembrane Transport of Chloride Ions in Mutants of Channelrhodopsin.

Author

Zhang W, Yang T, Zhou S, Cheng J, Yuan S, Lo GV, and Dou Y

Subjects

Channelrhodopsins genetics, Ion Channels chemistry, Mutation, Optogenetics methods, Biological Transport, Channelrhodopsins chemistry, Chlorides metabolism, Molecular Dynamics Simulation

Abstract

Channelrhodopsins (ChRs) are light-gated transmembrane cation channels which are widely used for optogenetic technology. Replacing glutamate located at the central gate of the ion channel with positively charged amino acid residues will reverse ion selectivity and allow anion conduction. The structures and properties of the ion channel, the transport of chloride, and potential of mean force (PMF) of the chimera protein (C1C2) and its mutants, EK-TC, ER-TC and iChloC, were investigated by molecular dynamics simulation. The results show that the five-fold mutation in E122Q-E129R-E140S-D195N-T198C (iChloC) increases the flexibility of the transmembrane channel protein better than the double mutations in EK-TC and ER-TC, and results in an expanded ion channel pore size and decreased steric resistance. The iChloC mutant was also found to have a higher affinity for chloride ions and, based on surface electrostatic potential analysis, provides a favorable electrostatic environment for anion conduction. The PMF free energy curves revealed that high affinity Cl - binding sites are generated near the central gate of the three mutant proteins. The energy barriers for the EK-TC and ER-TC were found to be much higher than that of iChloC. The results suggest that the transmembrane ion channel of iChloC protein is better at facilitating the capture and transport of chloride ions.

Published

2019

35. Formation Mechanism of Ion Channel in Channelrhodopsin-2: Molecular Dynamics Simulation and Steering Molecular Dynamics Simulations.

Author

Yang T, Zhang W, Cheng J, Nie Y, Xin Q, Yuan S, and Dou Y

Subjects

Channelrhodopsins chemistry, Chlamydomonas reinhardtii chemistry, Diterpenes chemistry, Diterpenes metabolism, Ion Transport, Isomerism, Molecular Dynamics Simulation, Plant Proteins chemistry, Protein Conformation, Protein Multimerization, Retinaldehyde chemistry, Retinaldehyde metabolism, Channelrhodopsins metabolism, Chlamydomonas reinhardtii metabolism, Plant Proteins metabolism

Abstract

Channelrhodopsin-2 (ChR2) is a light-activated and non-selective cationic channel protein that can be easily expressed in specific neurons to control neuronal activity by light. Although ChR2 has been extensively used as an optogenetic tool in neuroscience research, the molecular mechanism of cation channel formation following retinal photoisomerization in ChR2 is not well understood. In this paper, studies of the closed and opened state ChR2 structures are presented. The formation of the cationic channel is elucidated in atomic detail using molecular dynamics simulations on the all-trans-retinal (ChR2-trans) configuration of ChR2 and its isomerization products, 13-cis-retinal (ChR2-cis) configuration, respectively. Photoisomerization of the retinal-chromophore causes the destruction of interactions among the crucial residues (e.g., E90, E82, N258, and R268) around the channel and the extended H-bond network mediated by numerous water molecules, which opens the pore. Steering molecular dynamics (SMD) simulations show that the electrostatic interactions at the binding sites in intracellular gate (ICG) and central gate (CG) can influence the transmembrane transport of Na + in ChR2-cis obviously. Potential of mean force (PMF) constructed by SMD and umbrella sampling also found the existing energy wells at these two binding sites during the transportation of Na + . These wells partly hinder the penetration of Na + into cytoplasm through the ion channel. This investigation provides a theoretical insight on the formation mechanism of ion channels and the mechanism of ion permeation.

Published

2019

36. Structural basis for ion selectivity and engineering in channelrhodopsins.

Author

Rappleye M and Berndt A

Subjects

Animals, Cell Membrane metabolism, Channelrhodopsins genetics, Humans, Neurons cytology, Potassium metabolism, Channelrhodopsins chemistry, Channelrhodopsins metabolism, Protein Engineering methods

Abstract

Channelrhodopsins have become an integral part of modern neuroscience approaches due to their ability to control neuronal activity in targeted cell populations. The recent determination of several channelrhodopsin X-ray structures now enables us to study their function with unprecedented molecular precision. We will discuss how these insights can guide the engineering of the ion conducting pathway to increase its selectivity for Cl - , Ca 2+ , and K + ions and improve the overall conductance. Engineering such channelrhodopsins would further increase their utility in neuroscience research and beyond by controlling a wider range of physiological events. To thoroughly address this issue, we compare channelrhodopsin structures with structural features of voltage and ligand-gated K + , Cl - and Ca 2+ channels and discuss how these could be implemented in channelrhodopsins., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

37. MerMAIDs: a family of metagenomically discovered marine anion-conducting and intensely desensitizing channelrhodopsins.

Author

Oppermann J, Fischer P, Silapetere A, Liepe B, Rodriguez-Rozada S, Flores-Uribe J, Schiewer E, Keidel A, Vierock J, Kaufmann J, Broser M, Luck M, Bartl F, Hildebrandt P, Wiegert JS, Béjà O, Hegemann P, and Wietek J

Subjects

Animals, Bacteria classification, Bacteria isolation & purification, Bacteria metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Channelrhodopsins chemistry, Channelrhodopsins metabolism, Humans, Kinetics, Light, Metagenome, Neurons metabolism, Optogenetics, Phylogeny, Seawater microbiology, Seawater virology, Viral Proteins genetics, Viral Proteins metabolism, Viruses classification, Viruses isolation & purification, Viruses metabolism, Anions metabolism, Bacteria genetics, Channelrhodopsins genetics, Multigene Family, Viruses genetics

Abstract

Channelrhodopsins (ChRs) are algal light-gated ion channels widely used as optogenetic tools for manipulating neuronal activity. ChRs desensitize under continuous bright-light illumination, resulting in a significant decline of photocurrents. Here we describe a metagenomically identified family of phylogenetically distinct anion-conducting ChRs (designated MerMAIDs). MerMAIDs almost completely desensitize during continuous illumination due to accumulation of a late non-conducting photointermediate that disrupts the ion permeation pathway. MerMAID desensitization can be fully explained by a single photocycle in which a long-lived desensitized state follows the short-lived conducting state. A conserved cysteine is the critical factor in desensitization, as its mutation results in recovery of large stationary photocurrents. The rapid desensitization of MerMAIDs enables their use as optogenetic silencers for transient suppression of individual action potentials without affecting subsequent spiking during continuous illumination. Our results could facilitate the development of optogenetic tools from metagenomic databases and enhance general understanding of ChR function.

Published

2019

38. Nonadiabatic Photodynamics of Retinal Protonated Schiff Base in Channelrhodopsin 2.

Author

Liang R, Liu F, and Martínez TJ

Subjects

Isomerism, Molecular Dynamics Simulation, Photochemical Processes, Protein Conformation, Quantum Theory, Channelrhodopsins chemistry, Retina chemistry, Schiff Bases chemistry

Abstract

Channelrhodopsin 2 (ChR2) is a light-gated ion channel and an important tool in optogenetics. Photoisomerization of retinal protonated Schiff base (RPSB) in ChR2 triggers channel activation. Despite the importance of ChR2 in optogenetics, the detailed mechanism for photoisomerization and channel activation is still not fully understood. Here, we report on computer simulations to investigate the photoisomerization mechanism and its effect on the activation of ChR2. Nonadiabatic dynamics simulation of ChR2 was carried out using the ab initio multiple spawning (AIMS) method and quantum mechanics/molecular mechanics (QM/MM) with a restricted ensemble Kohn-Sham (REKS) treatment of the QM region. Our results agree well with spectroscopic measurements and reveal that the RPSB isomerization is highly specific around the C 13 =C 14 bond and follows the "aborted bicycle-pedal" mechanism. In addition, RPSB photoisomerization facilitates its deprotonation and partially increases the hydration level in the channel, which could trigger subsequent channel opening and ion conduction.

Published

2019

39. Unifying photocycle model for light adaptation and temporal evolution of cation conductance in channelrhodopsin-2.

Author

Kuhne J, Vierock J, Tennigkeit SA, Dreier MA, Wietek J, Petersen D, Gavriljuk K, El-Mashtoly SF, Hegemann P, and Gerwert K

Subjects

Cations chemistry, Channelrhodopsins genetics, Chlamydomonas reinhardtii genetics, Chlamydomonas reinhardtii metabolism, HEK293 Cells, Humans, Isomerism, Light, Protein Conformation, Protons, Retinaldehyde chemistry, Cations metabolism, Channelrhodopsins chemistry, Channelrhodopsins metabolism

Abstract

Although channelrhodopsin (ChR) is a widely applied light-activated ion channel, important properties such as light adaptation, photocurrent inactivation, and alteration of the ion selectivity during continuous illumination are not well understood from a molecular perspective. Herein, we address these open questions using single-turnover electrophysiology, time-resolved step-scan FTIR, and Raman spectroscopy of fully dark-adapted ChR2. This yields a unifying parallel photocycle model integrating now all so far controversial discussed data. In dark-adapted ChR2, the protonated retinal Schiff base chromophore (RSBH + ) adopts an all- trans ,C=N- anti conformation only. Upon light activation, a branching reaction into either a 13- cis ,C=N- anti or a 13- cis ,C=N- syn retinal conformation occurs. The anti -cycle features sequential H + and Na + conductance in a late M-like state and an N-like open-channel state. In contrast, the 13- cis ,C=N- syn isomer represents a second closed-channel state identical to the long-lived P 480 state, which has been previously assigned to a late intermediate in a single-photocycle model. Light excitation of P 480 induces a parallel syn -photocycle with an open-channel state of small conductance and high proton selectivity. E90 becomes deprotonated in P 480 and stays deprotonated in the C=N- syn cycle. Deprotonation of E90 and successive pore hydration are crucial for late proton conductance following light adaptation. Parallel anti - and syn -photocycles now explain inactivation and ion selectivity changes of ChR2 during continuous illumination, fostering the future rational design of optogenetic tools., Competing Interests: The authors declare no conflict of interest., (Copyright © 2019 the Author(s). Published by PNAS.)

Published

2019

40. Tracking Pore Hydration in Channelrhodopsin by Site-Directed Infrared-Active Azido Probes.

Author

Krause BS, Kaufmann JCD, Kuhne J, Vierock J, Huber T, Sakmar TP, Gerwert K, Bartl FJ, and Hegemann P

Subjects

Azides chemistry, Channelrhodopsins genetics, Codon, Terminator, HEK293 Cells, Humans, Molecular Probes chemistry, Mutagenesis, Site-Directed, Phenylalanine analogs & derivatives, Phenylalanine chemistry, Spectroscopy, Fourier Transform Infrared, Channelrhodopsins chemistry, Channelrhodopsins metabolism

Abstract

In recent years, gating and transient ion-pathway formation in the light-gated channelrhodopsins (ChRs) have been intensively studied. Despite these efforts, a profound understanding of the mechanistic details is still lacking. To track structural changes concomitant with the formation and subsequent collapse of the ion-conducting pore, we site-specifically introduced the artificial polarity-sensing probe p-azido-l-phenylalanine (azF) into several ChRs by amber stop codon suppression. The frequently used optogenetic actuator ReaChR (red-activatable ChR) exhibited the best expression properties of the wild type and the azF mutants. By exploiting the unique infrared spectral absorption of azF [ν as (N 3 ) ∼ 2100 cm -1 ] and its sensitivity to polarity changes, we monitored hydration changes at various sites of the pore region and the inner gate by stationary and time-resolved infrared spectroscopy. Our data imply that channel closure coincides with a dehydration event occurring between the interface of the central and the inner gate. In contrast, the extracellular ion pathway seems to be hydrated in the open and closed states to similar extents. Mutagenesis of sites in the inner gate suggests that it acts as an intracellular entry funnel, whose architecture and composition modulate water influx and efflux within the channel pore. Our results highlight the potential of genetic code expansion technology combined with biophysical methods to investigate channel gating, particularly hydration dynamics at specific sites, with a so far unprecedented spatial resolution.

Published

2019

41. Photostimulation for In Vitro Optogenetics with High-Power Blue Organic Light-Emitting Diodes.

Author

Morton A, Murawski C, Deng Y, Keum C, Miles GB, Tello JA, and Gather MC

Subjects

Animals, Cells, Cultured, Channelrhodopsins chemistry, Channelrhodopsins metabolism, Electrodes, Implanted, Hippocampus cytology, Mice, Recombinant Proteins, Neurons chemistry, Neurons cytology, Neurons metabolism, Optogenetics methods, Photic Stimulation methods

Abstract

Optogenetics, photostimulation of neural tissues rendered sensitive to light, is widely used in neuroscience to modulate the electrical excitability of neurons. For effective optical excitation of neurons, light wavelength and power density must fit with the expression levels and biophysical properties of the genetically encoded light-sensitive ion channels used to confer light sensitivity on cells-most commonly, channelrhodopsins (ChRs). As light sources, organic light-emitting diodes (OLEDs) offer attractive properties for miniaturized implantable devices for in vivo optical stimulation, but they do not yet operate routinely at the optical powers required for optogenetics. Here, OLEDs with doped charge transport layers are demonstrated that deliver blue light with good stability over millions of pulses, at powers sufficient to activate the ChR, CheRiff when expressed in cultured primary neurons, allowing live cell imaging of neural activity with the red genetically encoded calcium indicator, jRCaMP1a. Intracellular calcium responses scale with the radiant flux of OLED emission, when varied through changes in the current density, number of pulses, frequency, and pulse width delivered to the devices. The reported optimization and characterization of high-power OLEDs are foundational for the development of miniaturized OLEDs with thin-layer encapsulation on bioimplantable devices to allow single-cell activation in vivo., (© 2019 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

42. An optimized and automated approach to quantifying channelrhodopsin photocurrent kinetics.

Author

Prignano L, Faal SG, Hera A, and Dempski RE

Subjects

Animals, Channelrhodopsins chemistry, Cloning, Molecular methods, Kinetics, Oocytes cytology, Oocytes metabolism, Software, Xenopus laevis genetics, Channelrhodopsins analysis, Ion Channel Gating

Abstract

Channelrhodopsins are light-activated ion channels that enable targetable activation or inhibition of excitable cells with light. Ion conductance can generally be described by a four step photocycle, which includes two open and two closed states. While a complete understanding of channelrhodopsin function cannot be understood in the absence of kinetic modeling, model fitting requires manual fitting, which is laborious and technically complicated for non-experts. To enhance analysis of photocurrent data, this manuscript describes a fitting program where electrophysiology data can be automatically and quantitatively analyzed. Significant improvement in this program when compared to our previous version includes 1) the ability to automatically find the experiment start time using the derivative of the current signal, 2) utilizing the Object Oriented Programing (OPP) paradigm which is significantly more reliable if the code is used by people with little to no programming experience and 3) the distribution of the code is simplified to sharing a single MATLAB file, including rigorous comments throughout. To demonstrate the utility of this program, we show automated fitting of photocurrents from two member proteins: channelrhodopsin-2 and a chimera between channelrhodopsin-1 and channelrhodopsin-2 (C1C2)., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2019

43. Crystal structure of a natural light-gated anion channelrhodopsin.

Author

Li H, Huang CY, Govorunova EG, Schafer CT, Sineshchekov OA, Wang M, Zheng L, and Spudich JL

Subjects

Anions chemistry, Channelrhodopsins chemistry, Crystallography, X-Ray, Ion Channel Gating physiology, Ion Transport, Optogenetics methods, Retinoids chemistry, Schiff Bases chemistry, Schiff Bases metabolism, Channelrhodopsins metabolism, Cryptophyta metabolism, Retinoids metabolism

Abstract

The anion channelrhodopsin Gt ACR1 from the alga Guillardia theta is a potent neuron-inhibiting optogenetics tool. Presented here, its X-ray structure at 2.9 Å reveals a tunnel traversing the protein from its extracellular surface to a large cytoplasmic cavity. The tunnel is lined primarily by small polar and aliphatic residues essential for anion conductance. A disulfide-immobilized extracellular cap facilitates channel closing and the ion path is blocked mid-membrane by its photoactive retinylidene chromophore and further by a cytoplasmic side constriction. The structure also reveals a novel photoactive site configuration that maintains the retinylidene Schiff base protonated when the channel is open. These findings suggest a new channelrhodopsin mechanism, in which the Schiff base not only controls gating, but also serves as a direct mediator for anion flux., Competing Interests: HL, CH, CS, MW, LZ No competing interests declared, EG EGG and The University of Texas Health Science Center at Houston have filed patent applications that relate to ACRs (PCT application PCT/US2016/023095, entitled Compositions And Methods For Use Of Anion Channel Rhodopsins), OS OAS and The University of Texas Health Science Center at Houston have filed patent applications that relate to ACRs (PCT application PCT/US2016/023095, entitled Compositions And Methods For Use Of Anion Channel Rhodopsins), JS JLS and The University of Texas Health Science Center at Houston have filed patent applications that relate to ACRs (PCT application PCT/US2016/023095, entitled Compositions And Methods For Use Of Anion Channel Rhodopsins), (© 2019, Li et al.)

Published

2019

44. Different hydrogen bonding environments of the retinal protonated Schiff base control the photoisomerization in channelrhodopsin-2.

Author

Guo Y, Wolff FE, Schapiro I, Elstner M, and Marazzi M

Subjects

Animals, Hydrogen Bonding, Isomerism, Photochemistry, Retina chemistry, Channelrhodopsins chemistry, Models, Molecular, Schiff Bases chemistry

Abstract

The first event of the channelrhodopsin-2 (ChR2) photocycle, i.e. trans-to-cis photoisomerization, is studied by means of quantum mechanics/molecular mechanics, taking into account the flexible retinal environment in the ground state. By treating the chromophore at the ab initio multiconfigurational level of theory, we can rationalize the experimental findings based on pump-probe spectroscopy, explaining the different and more complex scenario found for ChR2 in comparison to other rhodopsins. In particular, we find that depending on the hydrogen bonding pattern, different excited states are involved, hence making it possible to suggest one pattern as the most productive. Moreover, after photoisomerization the structure of the first photocycle intermediate, P5001, is characterized by simulating the infrared spectrum and compared to available experimental data. This was obtained by extensive molecular dynamics, where the chromophore is described by a semi-empirical method based on density functional theory. The results clearly identify which counterion is responsible for accepting the proton from the retinal Schiff base: the side chain of the glutamic acid E123.

Published

2018

45. Expanding the Optogenetics Toolkit by Topological Inversion of Rhodopsins.

Author

Brown J, Behnam R, Coddington L, Tervo DGR, Martin K, Proskurin M, Kuleshova E, Park J, Phillips J, Bergs ACF, Gottschalk A, Dudman JT, and Karpova AY

Subjects

Animals, Caenorhabditis elegans, Cell Membrane chemistry, Cell Membrane metabolism, Cells, Cultured, Channelrhodopsins genetics, Channelrhodopsins metabolism, Male, Mice, Protein Engineering methods, Rats, Rats, Long-Evans, Channelrhodopsins chemistry, Optogenetics methods

Abstract

Targeted manipulation of activity in specific populations of neurons is important for investigating the neural circuit basis of behavior. Optogenetic approaches using light-sensitive microbial rhodopsins have permitted manipulations to reach a level of temporal precision that is enabling functional circuit dissection. As demand for more precise perturbations to serve specific experimental goals increases, a palette of opsins with diverse selectivity, kinetics, and spectral properties will be needed. Here, we introduce a novel approach of "topological engineering"-inversion of opsins in the plasma membrane-and demonstrate that it can produce variants with unique functional properties of interest for circuit neuroscience. In one striking example, inversion of a Channelrhodopsin variant converted it from a potent activator into a fast-acting inhibitor that operates as a cation pump. Our findings argue that membrane topology provides a useful orthogonal dimension of protein engineering that immediately permits as much as a doubling of the available toolkit., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

46. An Atomistic Model of a Precursor State of Light-Induced Channel Opening of Channelrhodopsin.

Author

Cheng C, Kamiya M, Takemoto M, Ishitani R, Nureki O, Yoshida N, and Hayashi S

Subjects

Models, Molecular, Protein Conformation radiation effects, Thermodynamics, Channelrhodopsins chemistry, Channelrhodopsins metabolism, Ion Channel Gating radiation effects, Light

Abstract

Channelrhodopsins (ChRs) are microbial light-gated ion channels with a retinal chromophore and are widely utilized in optogenetics to precisely control neuronal activity with light. Despite increasing understanding of their structures and photoactivation kinetics, the atomistic mechanism of light gating and ion conduction remains elusive. Here, we present an atomic structural model of a chimeric ChR in a precursor state of the channel opening determined by an accurate hybrid molecular simulation technique and a statistical theory of internal water distribution. The photoactivated structure features extensive tilt of the chromophore accompanied by redistribution of water molecules in its binding pocket, which is absent in previously known photoactivated structures of analogous photoreceptors, and widely agrees with structural and spectroscopic experimental evidence of ChRs. The atomistic model manifests a photoactivated ion-conduction pathway that is markedly different from a previously proposed one and successfully explains experimentally observed mutagenic effects on key channel properties., (Copyright © 2018 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2018

47. Crystal structure of the red light-activated channelrhodopsin Chrimson.

Author

Oda K, Vierock J, Oishi S, Rodriguez-Rozada S, Taniguchi R, Yamashita K, Wiegert JS, Nishizawa T, Hegemann P, and Nureki O

Subjects

Channelrhodopsins genetics, Channelrhodopsins metabolism, Chlamydomonas, Genetic Engineering, Molecular Structure, Protons, Schiff Bases metabolism, Channelrhodopsins chemistry

Abstract

Channelrhodopsins are light-activated ion channels that mediate cation permeation across cell membranes upon light absorption. Red-light-activated channelrhodopsins are of particular interest, because red light penetrates deeper into biological tissues and also enables dual-color experiments in combination with blue-light-activated optogenetic tools. Here we report the crystal structure of the most red-shifted channelrhodopsin from the algae Chlamydomonas noctigama, Chrimson, at 2.6 Å resolution. Chrimson resembles prokaryotic proton pumps in the retinal binding pocket, while sharing similarity with other channelrhodopsins in the ion-conducting pore. Concomitant mutation analysis identified the structural features that are responsible for Chrimson's red light sensitivity; namely, the protonation of the counterion for the retinal Schiff base, and the polar residue distribution and rigidity of the retinal binding pocket. Based on these mechanistic insights, we engineered ChrimsonSA, a mutant with a maximum activation wavelength red-shifted beyond 605 nm and accelerated closing kinetics.

Published

2018

48. Red-Tuning of the Channelrhodopsin Spectrum Using Long Conjugated Retinal Analogues.

Author

Shen YC, Sasaki T, Matsuyama T, Yamashita T, Shichida Y, Okitsu T, Yamano Y, Wada A, Ishizuka T, Yawo H, and Imamoto Y

Subjects

Animals, Channelrhodopsins genetics, Kinetics, Models, Molecular, Mutagenesis, Site-Directed, Mutation, Protein Conformation, Channelrhodopsins chemistry, Channelrhodopsins metabolism, Chlamydomonas reinhardtii metabolism, Retinaldehyde analogs & derivatives, Retinaldehyde metabolism

Abstract

As optogenetic studies become more popular, the demand for red-shifted channelrhodopsin is increasing, because blue-green light is highly scattered or absorbed by animal tissues. In this study, we developed a red-shifted channelrhodopsin by elongating the conjugated double-bond system of the native chromophore, all -trans-retinal (ATR1). Analogues of ATR1 and ATR2 (3,4-didehydro-retinal) in which an extra C═C bond is inserted at different positions (C6-C7, C10-C11, and C14-C15) were synthesized and introduced into a widely used channelrhodopsin variant, C1C2 (a chimeric protein of channelrhodopsin-1 and channelrhodopsin-2 from Chlamydomonas reinhardtii). C1C2 bearing these retinal analogues as chromophores showed broadened absorption spectra toward the long-wavelength side and photocycle intermediates similar to the conducting state of channelrhodopsin. However, the position of methyl groups on the retinal polyene chain influenced the yield of the pigment, absorption maximum, and photocycle pattern to a variable degree. The lack of a methyl group at position C9 of the analogues considerably decreased the yield of the pigment, whereas a methyl group at position C15 exhibited a large red-shift in the absorption spectra of the C1C2 analogue. Expansion of the chromophore binding pocket by mutation of aromatic residue Phe265 to Ala improved the yield of the pigment bearing elongated ATR1 analogues without a great alteration of the photocycle kinetics of C1C2. Our results show that elongation of the conjugated double-bond system of retinal is a promising strategy for improving the ability of channelrhodopsin to absorb long-wavelength light passing through the biological optical window.

Published

2018

49. Enhanced overexpression, purification of a channelrhodopsin and a fluorescent flux assay for its functional characterization.

Author

Hoi H, Qi Z, Zhou H, and Montemagno CD

Subjects

Aminoacridines, Bacterial Proteins, Biological Assay, Chlamydomonas reinhardtii, Fluorescence, Fluorescent Dyes, Luminescent Proteins, Vitamin A pharmacology, Channelrhodopsins chemistry, Channelrhodopsins genetics, Channelrhodopsins metabolism, Pichia drug effects, Pichia genetics, Pichia metabolism, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism

Abstract

Channelrhodopsins (ChRs) are a group of membrane proteins that allow cation flux across the cellular membrane when stimulated by light. They have been emerged as important tools in optogenetics where light is used to trigger a change in the membrane potential of live cells which induces downstream physiological cascades. There is also increased interest in their applications for generating light-responsive biomaterials. Here we have used a two-step screening protocol to develop a Pichia pastoris strain that produces superior yields of an enhance variant of CaChR2 (from Chlamydomonas reinhardtii), called ChIEF. We have also studied the effect of the co-factor, namely all-trans retinal (ATR), on the recombinant overexpression, folding, and function of the protein. We found that both ChIEF-mCitrine and CaChR2 can be overexpressed and properly trafficked to the plasma membrane in yeast regardless of the presence of the ATR. The purified protein was reconstituted into large unilamellar lipid vesicle using the detergent-assisted method. Using 9-amino-6-chloro-2-methoxyacridine (ACMA) as the fluorescent proton indicator, we have developed a flux assay to verify the light-activated proton flux in the ChIEF-mCitrine vesicles. Hence such vesicles are effectively light-responsive nano-compartments. The results presented in this work lays foundations for creating bio-mimetic materials with a light-responsive function using channelrhodopsins., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

50. Implications for the impairment of the rapid channel closing of Proteomonas sulcata anion channelrhodopsin 1 at high Cl - concentrations.

Author

Tsukamoto T, Kikuchi C, Suzuki H, Aizawa T, Kikukawa T, and Demura M

Subjects

Channelrhodopsins metabolism, Channelrhodopsins radiation effects, Chloride Channels metabolism, Chloride Channels radiation effects, Chlorides metabolism, Ion Channel Gating, Light, Optogenetics methods, Channelrhodopsins chemistry, Chloride Channels chemistry, Cryptophyta metabolism

Abstract

Natural anion channelrhodopsins (ACRs) have recently received increased attention because of their effectiveness in optogenetic manipulation for neuronal silencing. In this study, we focused on Proteomonas sulcata ACR1 (PsuACR1), which has rapid channel closing kinetics and a rapid recovery to the initial state of its anion channel function that is useful for rapid optogenetic control. To reveal the anion concentration dependency of the channel function, we investigated the photochemical properties of PsuACR1 using spectroscopic techniques. Recombinant PsuACR1 exhibited a Cl - dependent spectral red-shift from 531 nm at 0.1 mM to 535 nm at 1000 mM, suggesting that it binds Cl - in the initial state with a K d of 5.5 mM. Flash-photolysis experiments revealed that the photocycle was significantly changed at high Cl - concentrations, which led not only to suppression of the accumulation of the M-intermediate involved in the Cl - non-conducting state but also to a drastic change in the equilibrium state of the other photo-intermediates. Because of this, the Cl - conducting state is protracted by one order of magnitude, which implies an impairment of the rapid channel closing of PsuACR1 in the presence of high concentrations of Cl - .

Published

2018