Porphyrins for Probing Electrical Potential Across Lipid Bilayer Membranes by Second Harmonic Generation

Reeve, James E.; Corbett, Alexander D.; Boczarow, Igor; Kaluza, Wojciech; Barford, William; Bayley, Hagan; Wilson, Tony; Anderson, Harry L.

doi:10.1002/ange.201304515

Cited by 11 publications

(12 citation statements)

References 52 publications

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“…The challenge of achieving optical voltage sensing is a longstanding goal within the scientific community (4,5), and recent approaches have included fluorinated styryl dyes (6), annulated hemicyanines (7,8) and cyanines (9), lipophilic anions (10,11), hybrid small-molecule/fluorescent protein probes (12,13), porphyrins (14), and nanoparticles (15,16). However, combinations of poor sensitivity, slow kinetics, ineffective membrane localization, rapid photobleaching, and/or limited two-photon crosssection, which is important for imaging in thick tissue, have hampered rapid progress toward a general solution for optical voltage imaging.…”

mentioning

confidence: 99%

Voltage-sensitive rhodol with enhanced two-photon brightness

Kulkarni

Kramer

Pourmandi

et al. 2017

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

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We have designed, synthesized, and applied a rhodol-based chromophore to a molecular wire-based platform for voltage sensing to achieve fast, sensitive, and bright voltage sensing using twophoton (2P) illumination. Rhodol VoltageFluor-5 (RVF5) is a voltage-sensitive dye with improved 2P cross-section for use in thick tissue or brain samples. RVF5 features a dichlororhodol core with pyrrolidyl substitution at the nitrogen center. In mammalian cells under one-photon (1P) illumination, RVF5 demonstrates high voltage sensitivity (28% ΔF/F per 100 mV) and improved photostability relative to first-generation voltage sensors. This photostability enables multisite optical recordings from neurons lacking tuberous sclerosis complex 1, Tsc1, in a mouse model of genetic epilepsy. Using RVF5, we show that Tsc1 KO neurons exhibit increased activity relative to wild-type neurons and additionally show that the proportion of active neurons in the network increases with the loss of Tsc1. The high photostability and voltage sensitivity of RVF5 is recapitulated under 2P illumination. Finally, the ability to chemically tune the 2P absorption profile through the use of rhodol scaffolds affords the unique opportunity to image neuronal voltage changes in acutely prepared mouse brain slices using 2P illumination. Stimulation of the mouse hippocampus evoked spiking activity that was readily discerned with bath-applied RVF5, demonstrating the utility of RVF5 and molecular wire-based voltage sensors with 2P-optimized fluorophores for imaging voltage in intact brain tissue. Neuronal membrane potential dynamics drive neurotransmitter release and are therefore responsible for the unique physiology associated with neurons at cellular, circuit, and organismal levels. Despite the central importance of proper neuronal firing to human health, an integrated understanding of neuronal activity in the context of larger brain circuits remains elusive, due in part to a lack of methods for interrogating membrane potential dynamics with sufficient spatial and temporal resolution.Traditional methods for monitoring membrane potential rely heavily on the use of invasive electrodes, through one of two methods. The first method, patch-clamp electrophysiology, uses a single electrode to make contact with or puncture a cell to record changes in membrane potential, sacrificing throughput and spatial resolution to achieve a comprehensive description of a single cellular electrophysiological profile. A second method uses multielectrode arrays (MEAs), in which patterned arrays of electrodes introduced to cells or tissues report on electrical changes. Spatial resolution of MEAs depends on the number and positioning of the electrodes within the array. Although throughput is improved relative to patch-clamp electrophysiology, the extracellularly recorded signals are typically less sensitive than whole-cell methods and can be an amalgamation of several cells, making deconvolution of recorded signals and precise correlation to specific cells difficult or impossible. Addi...

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mentioning

confidence: 99%

Voltage-sensitive rhodol with enhanced two-photon brightness

Kulkarni

Kramer

Pourmandi

et al. 2017

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

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“…+ 𝜒 𝑒𝑓𝑓,𝑆 (2) )𝐸 𝜔 𝐸 𝜔 (6) The effective susceptibilities describe the contribution of SONLO and TONLO induced polarization within the lipid bilayer (𝜒 𝑒𝑓𝑓,𝐵𝐿…”

Section: Discussionmentioning

confidence: 99%

“…The electric field dependence of SHG is governed by a third-order nonlinear optical (TONLO) response, with a sensitivity greatly exceeding that of fluorescence. 4,5 SHG voltage imaging has been primarily based on engineered molecules with large hyperpolarizabilities and amphiphilic properties, [6][7][8][9] with new, unlabelled approaches now beginning to emerge. [10][11][12] All techniques using membrane dyes can interfere with the delicate cell membrane as they often have significant dipole moments leading to local field disruption and alteration in membrane capacitance, thereby affecting both action potential conductance and membrane transport.…”

Section: Introductionmentioning

confidence: 99%

Label-free imaging of membrane potentials by intramembrane field modulation, assessed by Second Harmonic Generation Microscopy

Jooken

Deschaume

et al. 2021

Preprint

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Optical interrogation of cellular electrical activity has proven itself essential for understanding cellular function and communication in complex networks. Voltage-sensitive dyes are important tools for assessing excitability but these highly lipophilic sensors may affect cellular function. Label-free techniques offer a major advantage as they eliminate the need for these external probes. In this work, we show that endogenous second harmonic generation (SHG) from live cells is highly sensitive to changes in membrane potential. Simultaneous electrophysiological control of a living (HEK293T) cell, through whole-cell voltage clamp reveals a linear relation between the SHG intensity and membrane voltage. Our results suggest that due to the high ionic strengths and fast optical response of biofluids, membrane hydration is not the main contributor to the observed field sensitivity. We further provide a conceptual framework that indicates that the SHG voltage sensitivity reflects the electric field within the biological asymmetric lipid bilayer owing to a nonzero χeff(2) tensor. Changing the membrane potential without surface modifications such as electrolyte screening offers high optical sensitivity to membrane voltage (≈40% per 100 mV), indicating the power of SHG for label-free read-out. These results hold promise for the design of a non-invasive label-free read-out tool for electrogenic cells.

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“…gives similar or lower SHG signals than the styryl dye, FM4-64 ( β zzz ≈ 1,100 × 10 −30 esu at 800 nm in CHCl 3 ) ( Khadria et al., 2017 ), and exhibits lower voltage sensitivity (<5% per 100 mV) ( Nuriya et al., 2016 ). We have previously demonstrated that highly electronically conjugated porphyrin-based donor-acceptor chromophores possess high first-order hyperpolarizability ( β zzz ≈ 2500 × 10 −30 esu at 800 nm in CHCl 3 ), and they are 5–10 times more voltage sensitive than FM4-64 ( Reeve et al., 2013 , Reeve et al., 2009 ). One of the major criteria for SHG-based dyes is that they must localize effectively at the plasma membrane of cells and their major transition dipole moment (TDM) should be collinearly oriented with the polarization of laser light to generate high signal ( Khadria et al., 2017 , Reeve et al., 2012 ).…”

Section: Introductionmentioning

confidence: 99%

Porphyrin Dyes for Nonlinear Optical Imaging of Live Cells

et al. 2018

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SummarySecond harmonic generation (SHG)-based probes are useful for nonlinear optical imaging of biological structures, such as the plasma membrane. Several amphiphilic porphyrin-based dyes with high SHG coefficients have been synthesized with different hydrophilic head groups, and their cellular targeting has been studied. The probes with cationic head groups localize better at the plasma membrane than the neutral probes with zwitterionic or non-charged ethylene glycol-based head groups. Porphyrin dyes with only dications as hydrophilic head groups localize inside HEK293T cells to give SHG, whereas tricationic dyes localize robustly at the plasma membrane of cells, including neurons, in vitro and ex vivo. The copper(II) complex of the tricationic dye with negligible fluorescence quantum yield works as an SHG-only dye. The free-base tricationic dye has been demonstrated for two-photon fluorescence and SHG-based multimodal imaging. This study demonstrates the importance of a balance between the hydrophobicity and hydrophilicity of amphiphilic dyes for effective plasma membrane localization.

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Porphyrins for Probing Electrical Potential Across Lipid Bilayer Membranes by Second Harmonic Generation

Cited by 11 publications

References 52 publications

Voltage-sensitive rhodol with enhanced two-photon brightness

Voltage-sensitive rhodol with enhanced two-photon brightness

Label-free imaging of membrane potentials by intramembrane field modulation, assessed by Second Harmonic Generation Microscopy

Porphyrin Dyes for Nonlinear Optical Imaging of Live Cells

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