Your search keyword '"Adam E. Cohen"' showing total 123 results

1. Dendritic excitations govern back-propagation via a spike-rate accelerometer

Author

Pojeong Park, J. David Wong-Campos, Daniel G. Itkis, Byung Hun Lee, Yitong Qi, Hunter C. Davis, Benjamin Antin, Amol Pasarkar, Jonathan B. Grimm, Sarah E. Plutkis, Katie L. Holland, Liam Paninski, Luke D. Lavis, and Adam E. Cohen

Subjects

Science

Abstract

Abstract Dendrites on neurons support electrical excitations, but the computational significance of these events is not well understood. We developed molecular, optical, and computational tools for all-optical electrophysiology in dendrites. We mapped sub-millisecond voltage dynamics throughout the dendritic trees of CA1 pyramidal neurons under diverse optogenetic and synaptic stimulus patterns, in acute brain slices. Our data show history-dependent spike back-propagation in distal dendrites, driven by locally generated Na+ spikes (dSpikes). Dendritic depolarization created a transient window for dSpike propagation, opened by A-type KV channel inactivation, and closed by slow NaV inactivation. Collisions of dSpikes with synaptic inputs triggered calcium channel and N-methyl-D-aspartate receptor (NMDAR)-dependent dendritic plateau potentials and accompanying complex spikes at the soma. This hierarchical ion channel network acts as a spike-rate accelerometer, providing an intuitive picture connecting dendritic biophysics to associative plasticity rules.

Published

2025

2. Multiplexed Optical Sensors in Arrayed Islands of Cells for multimodal recordings of cellular physiology

Author

Christopher A. Werley, Stefano Boccardo, Alessandra Rigamonti, Emil M. Hansson, and Adam E. Cohen

Subjects

Science

Abstract

Existing fluorescent protein-based sensor measurements are limited to 4 or fewer simultaneously recorded modalities due to spectral overlap. Here the authors introduce Multiplexed Optical Sensors in Arrayed Islands of Cells (MOSAIC), which enables parallel recording of tens of physiological parameters using dense arrays of cell islands, each expressing a different fluorescent sensor.

Published

2020

3. High-fidelity estimates of spikes and subthreshold waveforms from 1-photon voltage imaging in vivo

Author

Michael E. Xie, Yoav Adam, Linlin Z. Fan, Urs L. Böhm, Ian Kinsella, Ding Zhou, Marton Rozsa, Amrita Singh, Karel Svoboda, Liam Paninski, and Adam E. Cohen

Subjects

voltage imaging, signal extraction, Biology (General), QH301-705.5

Abstract

Summary: The ability to probe the membrane potential of multiple genetically defined neurons simultaneously would have a profound impact on neuroscience research. Genetically encoded voltage indicators are a promising tool for this purpose, and recent developments have achieved a high signal-to-noise ratio in vivo with 1-photon fluorescence imaging. However, these recordings exhibit several sources of noise and signal extraction remains a challenge. We present an improved signal extraction pipeline, spike-guided penalized matrix decomposition-nonnegative matrix factorization (SGPMD-NMF), which resolves supra- and subthreshold voltages in vivo. The method incorporates biophysical and optical constraints. We validate the pipeline with simultaneous patch-clamp and optical recordings from mouse layer 1 in vivo and with simulated and composite datasets with realistic noise. We demonstrate applications to mouse hippocampus expressing paQuasAr3-s or SomArchon1, mouse cortex expressing SomArchon1 or Voltron, and zebrafish spines expressing zArchon1.

Published

2021

4. Optically Controlled Oscillators in an Engineered Bioelectric Tissue

Author

Harold M. McNamara, Hongkang Zhang, Christopher A. Werley, and Adam E. Cohen

Subjects

Physics, QC1-999

Abstract

Complex electrical dynamics in excitable tissues occur throughout biology, but the roles of individual ion channels can be difficult to determine due to the complex nonlinear interactions in native tissue. Here, we ask whether we can engineer a tissue capable of basic information storage and processing, where all functional components are known and well understood. We develop a cell line with four transgenic components: two to enable collective propagation of electrical waves and two to enable optical perturbation and optical readout of membrane potential. We pattern the cell growth to define simple cellular ring oscillators that run stably for >2 h (∼10^{4} cycles) and that can store data encoded in the direction of electrical circulation. Using patterned optogenetic stimulation, we probe the biophysical attributes of this synthetic excitable tissue in detail, including dispersion relations, curvature-dependent wave front propagation, electrotonic coupling, and boundary effects. We then apply the biophysical characterization to develop an optically reconfigurable bioelectric oscillator. These results demonstrate the feasibility of engineering bioelectric tissues capable of complex information processing with optical input and output.

Published

2016

5. Voltage dynamics of dendritic integration and back-propagation in vivo

Author

J. David Wong-Campos, Pojeong Park, Hunter C. Davis, Yitong Qi, He Tian, Daniel G. Itkis, Doyeon Kim, Jonathan B. Grimm, Sarah E. Plutkis, Luke Lavis, and Adam E. Cohen

Subjects

Article

Abstract

Neurons integrate synaptic inputs within their dendrites and produce spiking outputs, which then propagate down the axon and back into the dendrites where they contribute to plasticity. Mapping the voltage dynamics in dendritic arbors of live animals is crucial for understanding neuronal computation and plasticity rules. Here we combine patterned channelrhodopsin activation with dual-plane structured illumination voltage imaging, for simultaneous perturbation and monitoring of dendritic and somatic voltage in Layer 2/3 pyramidal neurons in anesthetized and awake mice. We examined the integration of synaptic inputs and compared the dynamics of optogenetically evoked, spontaneous, and sensory-evoked back-propagating action potentials (bAPs). Our measurements revealed a broadly shared membrane voltage throughout the dendritic arbor, and few signatures of electrical compartmentalization among synaptic inputs. However, we observed spike rate acceleration-dependent propagation of bAPs into distal dendrites. We propose that this dendritic filtering of bAPs may play a critical role in activity-dependent plasticity.

Published

2023

6. Mapping memories: pulse-chase labeling reveals AMPA receptor dynamics during memory formation

Author

Doyeon Kim, Pojeong Park, Xiuyuan Ted Li, J. David Wong-Campos, He Tian, Eric M. Moult, Jonathan B. Grimm, Luke Lavis, and Adam E. Cohen

Subjects

Article

Abstract

A tool to map changes in synaptic strength during a defined time window could provide powerful insights into the mechanisms governing learning and memory. We developed a technique, Extracellular Protein Surface Labeling in Neurons (EPSILON), to map alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor (AMPAR) insertion in vivo by pulse-chase labeling of surface AMPARs with membrane-impermeable dyes. This approach allows for single-synapse resolution maps of plasticity in genetically targeted neurons during memory formation. We investigated the relationship between synapse-level and cell-level memory encodings by mapping synaptic plasticity and cFos expression in hippocampal CA1 pyramidal cells upon contextual fear conditioning (CFC). We observed a strong correlation between synaptic plasticity and cFos expression, suggesting a synaptic mechanism for the association of cFos expression with memory engrams. The EPSILON technique is a useful tool for mapping synaptic plasticity and may be extended to investigate trafficking of other transmembrane proteins.

Published

2023

7. Diminishing neuronal acidification by channelrhodopsins with low proton conduction

Author

Rebecca Frank Hayward, F. Phil Brooks, Shang Yang, Shiqiang Gao, and Adam E Cohen

Subjects

Biophysics, Article

Abstract

Many channelrhodopsins are permeable to protons. We found that in neurons, activation of a high-current channelrhodopsin, CheRiff, led to significant acidification, with faster acidification in the dendrites than in the soma. Experiments with patterned optogenetic stimulation in monolayers of HEK cells established that the acidification was due to proton transport through the opsin, rather than through other voltage-dependent channels. We identified and characterized two opsins which showed large photocurrents, but small proton permeability, PsCatCh2.0 and ChR2-3M. PsCatCh2.0 showed excellent response kinetics and was also spectrally compatible with simultaneous voltage imaging with QuasAr6a. Stimulation-evoked acidification is a possible source of disruptions to cell health in scientific and prospective therapeutic applications of optogenetics. Channelrhodopsins with low proton permeability are a promising strategy for avoiding these problems.Statement of SignificanceAcidification is an undesirable artifact of optogenetic stimulation. Low proton-permeability opsins minimize this artifact while still allowing robust optogenetic control.

Published

2023

8. Linearly polarized excitation enhances signals from fluorescent voltage indicators

Author

Simon Kheifets, Daan Brinks, William Bloxham, Adam E. Cohen, and Molecular Genetics

Subjects

0303 health sciences, Brightness, Materials science, business.industry, Linear polarization, Biophysics, Action Potentials, Articles, Signal, Fluorescence, Noise (electronics), 03 medical and health sciences, 0302 clinical medicine, Optoelectronics, Animals, Indicators and Reagents, business, Polarization (electrochemistry), Coloring Agents, 030217 neurology & neurosurgery, Excitation, 030304 developmental biology, Voltage, Fluorescent Dyes

Abstract

Voltage imaging in cells requires high-speed recording of small fluorescent signals, often leading to low signal/noise ratios. Because voltage indicators are membrane bound, their orientations are partially constrained by the plane of the membrane. We explored whether tuning the linear polarization of excitation light could enhance voltage indicator fluorescence. We tested a panel of dye- and protein-based voltage indicators in mammalian cells. The dye BeRST1 showed a 73% increase in brightness between the least and most favorable polarizations. The protein-based reporter ASAP1 showed a 22% increase in brightness, and QuasAr3 showed a 14% increase in brightness. In very thin neurites expressing QuasAr3, improvements were anomalously large, with a 170% increase in brightness between polarization parallel versus perpendicular to the dendrite. Signal/noise ratios of optically recorded action potentials were increased by up to 50% in neurites expressing QuasAr3. These results demonstrate that polarization control can be a facile means to enhance signals from fluorescent voltage indicators, particularly in thin neurites or in high-background environments.

Published

2021

9. Which Way Does Stimulated Emission Go?

Author

J. V. Porto, J. David Wong-Campos, and Adam E. Cohen

Subjects

Quantum Physics, Fluorophore, Scattering, FOS: Physical sciences, Optical theorem, Chromophore, chemistry.chemical_compound, Wavelength, symbols.namesake, chemistry, Excited state, symbols, Stimulated emission, Physical and Theoretical Chemistry, Atomic physics, Rayleigh scattering, Quantum Physics (quant-ph), Optics (physics.optics), Physics - Optics

Abstract

Is it possible to form an image using light produced by stimulated emission? Here we study light scatter off an assembly of excited chromophores. Due to the Optical Theorem, stimulated emission is necessarily accompanied by excited state Rayleigh scattering. Both processes can be used to form images, though they have different dependencies on scattering direction, wavelength and chromophore configuration. Our results suggest several new approaches to optical imaging using fluorophore excited states., 11 pages, 4 figures

Published

2021

10. Dendritic branch structure compartmentalizes voltage-dependent calcium influx in cortical layer 2/3 pyramidal cells

Author

Andrew T Landau, Pojeong Park, J David Wong-Campos, He Tian, Adam E Cohen, and Bernardo L Sabatini

Subjects

animal structures, General Immunology and Microbiology, General Neuroscience, Pyramidal Cells, Action Potentials, General Medicine, Dendrites, complex mixtures, General Biochemistry, Genetics and Molecular Biology, Mice, embryonic structures, polycyclic compounds, Animals, Calcium, Calcium Channels

Abstract

Back-propagating action potentials (bAPs) regulate synaptic plasticity by evoking voltage-dependent calcium influx throughout dendrites. Attenuation of bAP amplitude in distal dendritic compartments alters plasticity in a location-specific manner by reducing bAP-dependent calcium influx. However, it is not known if neurons exhibit branch-specific variability in bAP-dependent calcium signals, independent of distance-dependent attenuation. Here, we reveal that bAPs fail to evoke calcium influx through voltage-gated calcium channels (VGCCs) in a specific population of dendritic branches in cortical layer 2/3 pyramidal cells, despite evoking substantial VGCC-mediated calcium influx in sister branches. These branches contain VGCCs and successfully propagate bAPs in the absence of synaptic input; nevertheless, they fail to exhibit bAP-evoked calcium influx due to a branch-specific reduction in bAP amplitude. We demonstrate that these branches have more elaborate branch structure compared to sister branches, which causes a local reduction in electrotonic impedance and bAP amplitude. Finally, we show that bAPs still amplify synaptically-mediated calcium influx in these branches because of differences in the voltage-dependence and kinetics of VGCCs and NMDA-type glutamate receptors. Branch-specific compartmentalization of bAP-dependent calcium signals may provide a mechanism for neurons to diversify synaptic tuning across the dendritic tree.

Published

2022

11. All-optical physiology resolves a synaptic basis for behavioral timescale plasticity

Author

Linlin Z. Fan, Doo Kyung Kim, Joshua H. Jennings, He Tian, Peter Y. Wang, Charu Ramakrishnan, Sawyer Randles, Yanjun Sun, Elina Thadhani, Yoon Seok Kim, Sean Quirin, Lisa Giocomo, Adam E. Cohen, and Karl Deisseroth

Subjects

General Biochemistry, Genetics and Molecular Biology

Published

2023

12. All-optical electrophysiology with improved genetically encoded voltage indicators reveals interneuron network dynamics in vivo

Author

Christopher A. Werley, Pojeong Park, Shahinoor Begum, He Tian, Vicente Parot, Benjamin Gmeiner, Gabriel B. Borja, Hansini Upadhyay, J. David Wong-Campos, Linlin Z. Fan, Yitong Qi, Hunter C. Davis, Himali Shah, Jane Jacques, Karl Deisseroth, and Adam E. Cohen

Subjects

Coupling (electronics), Electrophysiology, medicine.anatomical_structure, Interneuron, Chemistry, medicine, Channelrhodopsin, Neuron, Hippocampal formation, Optogenetics, Inhibitory postsynaptic potential, Neuroscience

Abstract

All-optical electrophysiology can be a powerful tool for studying neural dynamics in vivo, as it offers the ability to image and perturb membrane voltage in multiple cells simultaneously. The “Optopatch” constructs combine a red-shifted archaerhodopsin (Arch)-derived genetically encoded voltage indicator (GEVI) with a blue-shifted channelrhodopsin actuator (ChR). We used a video-based pooled screen to evolve Arch-derived GEVIs with improved signal-to-noise ratio (QuasAr6a) and kinetics (QuasAr6b). By combining optogenetic stimulation of individual cells with high-precision voltage imaging in neighboring cells, we mapped inhibitory and gap junction-mediated connections, in vivo. Optogenetic activation of a single NDNF-expressing neuron in visual cortex Layer 1 significantly suppressed the spike rate in some neighboring NDNF interneurons. Hippocampal PV cells showed near-synchronous spikes across multiple cells at a frequency significantly above what one would expect from independent spiking, suggesting that collective inhibitory spikes may play an important signaling role in vivo. By stimulating individual cells and recording from neighbors, we quantified gap junction coupling strengths. Together, these results demonstrate powerful new tools for all-optical microcircuit dissection in live mice.

Published

2021

13. Time-tagged ticker tapes for intracellular recordings

Author

Xiuyuan (Ted) Li, Hao Shen, Jonathan B. Grimm, Pojeong Park, David Baker, Adam E. Cohen, Dingchang Lin, Benjamin Tang, Luke D. Lavis, and Natalie Falco

Subjects

Climate events, Neural activity, Intracellular protein, Absolute accuracy, Biology, Neuroscience, Intracellular

Abstract

A core taken in a tree today can reveal climate events from centuries past. Here we adapt this idea to record histories of neural activation. We engineered slowly growing intracellular protein fibers which can incorporate diverse fluorescent marks during growth to store linear ticker tape-like histories. An embedded HaloTag reporter incorporated user-supplied HaloTag-ligand dyes, leading to colored stripes whose boundaries mapped fiber growth to wall-clock time. A co-expressed eGFP tag driven by the cFos immediate early gene promoter recorded the history of neural activity. High-resolution multispectral imaging on fixed samples read the cellular histories. We demonstrated recordings of cFos activation in ensembles of cultured neurons with a single-cell absolute accuracy of approximately 39 min over a 12-hour interval. Protein-based ticker tapes have the potential to achieve massively parallel single-cell recordings of multiple physiological modalities.

Published

2021

14. Time-tagged ticker tapes for intracellular recordings

Author

Dingchang Lin, Xiuyuan Li, Eric Moult, Pojeong Park, Benjamin Tang, Hao Shen, Jonathan B. Grimm, Natalie Falco, Bill Z. Jia, David Baker, Luke D. Lavis, and Adam E. Cohen

Subjects

Biomedical Engineering, Molecular Medicine, Bioengineering, Applied Microbiology and Biotechnology, Biotechnology

Abstract

Recording transcriptional histories of a cell would enable deeper understanding of cellular developmental trajectories and responses to external perturbations. Here we describe an engineered protein fiber that incorporates diverse fluorescent marks during its growth to store a ticker tape-like history. An embedded HaloTag reporter incorporates user-supplied dyes, leading to colored stripes that map the growth of each individual fiber to wall clock time. A co-expressed eGFP tag driven by a promoter of interest records a history of transcriptional activation. High-resolution multi-spectral imaging on fixed samples reads the cellular histories, and interpolation of eGFP marks relative to HaloTag timestamps provides accurate absolute timing. We demonstrate recordings of doxycycline-induced transcription in HEK cells and cFos promoter activation in cultured neurons, with a single-cell absolute accuracy of 30-40 minutes over a 12-hour recording. The protein-based ticker tape design we present here could be generalized to achieve massively parallel single-cell recordings of diverse physiological modalities.

Published

2021

15. Bioelectrical domain walls in homogeneous tissues

Author

Gloria Ortiz, Rajath Salegame, Adam E. Cohen, Haitan Xu, Ziad Al Tanoury, Shahinoor Begum, Olivier Pourquié, and Harold M. McNamara

Subjects

Physics, Membrane potential, General Physics and Astronomy, Conductance, 01 natural sciences, Resting potential, Article, 010305 fluids & plasmas, Electrophysiology, Domain wall (string theory), 0103 physical sciences, Biophysics, Myocyte, Symmetry breaking, 010306 general physics, Induced pluripotent stem cell

Abstract

Electrical signaling in biology is typically associated with action potentials, transient spikes in membrane voltage that return to baseline. Hodgkin-Huxley and related conductance-based models of electrophysiology belong to a more general class of reaction-diffusion equations which could, in principle, support spontaneous emergence of patterns of membrane voltage which are stable in time but structured in space. Here we show theoretically and experimentally that homogeneous or nearly homogeneous tissues can undergo spontaneous spatial symmetry breaking through a purely electrophysiological mechanism, leading to formation of domains with different resting potentials separated by stable bioelectrical domain walls. Transitions from one resting potential to another can occur through long-range migration of these domain walls. We map bioelectrical domain wall motion using all-optical electrophysiology in an engineered cell line and in human induced pluripotent stem cell (iPSC)-derived myoblasts. Bioelectrical domain wall migration may occur during embryonic development and during physiological signaling processes in polarized tissues. These results demonstrate that nominally homogeneous tissues can undergo spontaneous bioelectrical symmetry breaking.

Published

2020

16. Wide-Area All-Optical Neurophysiology in Acute Brain Slices

Author

Shan Lou, Masahito Yamagata, Robert E. Campbell, Yoav Adam, Vicente Parot, David D. Cox, Adam E. Cohen, Ahmed S. Abdelfattah, Jeong Jun Kim, Abhinav Grama, and Samouil L. Farhi

Subjects

0301 basic medicine, Computer science, Action Potentials, Channelrhodopsin, Brain tissue, Striatum, AMPA receptor, Optogenetics, Neurotransmission, Hippocampus, Synaptic Transmission, All optical, Mice, 03 medical and health sciences, 0302 clinical medicine, Calcium imaging, Slice preparation, Hadamard transform, Animals, Humans, Research Articles, Neurons, Functional connectivity, General Neuroscience, Optical Imaging, Neurophysiology, Cortex (botany), Rats, HEK293 Cells, 030104 developmental biology, Wide area, NMDA receptor, Anticonvulsants, Nerve Net, Excitatory Amino Acid Antagonists, Neuroscience, Photic Stimulation, 030217 neurology & neurosurgery

Abstract

Optical tools for simultaneous perturbation and measurement of neural activity open the possibility of mapping neural function over wide areas of brain tissue. However, spectral overlap of actuators and reporters presents a challenge for their simultaneous use, and optical scattering and out-of-focus fluorescence in tissue degrade resolution. To minimize optical crosstalk, we combined an optimized variant (eTsChR) of the most blue-shifted channelrhodopsin reported to-date with a nuclear-localized red-shifted Ca(2+) indicator, H2B-jRGECO1a. To perform wide-area optically sectioned imaging in tissue, we designed a structured illumination technique that uses Hadamard matrices to encode spatial information. By combining these molecular and optical approaches we made wide-area functional maps in acute brain slices from mice of both sexes. The maps spanned cortex and striatum and probed the effects of antiepileptic drugs on neural excitability and the effects of AMPA and NMDA receptor blockers on functional connectivity. Together, these tools provide a powerful capability for wide-area mapping of neuronal excitability and functional connectivity in acute brain slices. SIGNIFICANCE STATEMENT A new technique for simultaneous optogenetic stimulation and calcium imaging across wide areas of brain slice enables high-throughput mapping of neuronal excitability and synaptic transmission.

Published

2019

17. Voltage imaging identifies spinal circuits that modulate locomotor adaptation in zebrafish

Author

Urs L. Böhm, Yukiko Kimura, Takashi Kawashima, Misha B. Ahrens, Shin-ichi Higashijima, Florian Engert, and Adam E. Cohen

Subjects

Motor Neurons, Spinal Cord, General Neuroscience, Animals, Locomotion, Swimming, Zebrafish

Abstract

Motor systems must continuously adapt their output to maintain a desired trajectory. While the spinal circuits underlying rhythmic locomotion are well described, little is known about how the network modulates its output strength. A major challenge has been the difficulty of recording from spinal neurons during behavior. Here, we use voltage imaging to map the membrane potential of large populations of glutamatergic neurons throughout the spinal cord of the larval zebrafish during fictive swimming in a virtual environment. We characterized a previously undescribed subpopulation of tonic-spiking ventral V3 neurons whose spike rate correlated with swimming strength and bout length. Optogenetic activation of V3 neurons led to stronger swimming and longer bouts but did not affect tail beat frequency. Genetic ablation of V3 neurons led to reduced locomotor adaptation. The power of voltage imaging allowed us to identify V3 neurons as a critical driver of locomotor adaptation in zebrafish.

Published

2021

18. Voltage imaging identifies spinal circuits that modulate locomotor adaptation in zebrafish

Author

Misha B. Ahrens, Florian Engert, Urs Lucas Böhm, Takashi Kawashima, Yukiko Kimura, Adam E. Cohen, and Shin-ichi Higashijima

Subjects

Membrane potential, Glutamatergic, Rhythm, medicine.anatomical_structure, biology, Subthreshold conduction, Motor system, medicine, Optogenetics, biology.organism_classification, Spinal cord, Zebrafish, Neuroscience

Abstract

Motor systems must continuously adapt their output to maintain a desired trajectory. While the spinal circuits underlying rhythmic locomotion are well described, little is known about how the network modulates its output strength. A major challenge has been the difficulty of recording from spinal neurons during behavior. Here, we use voltage imaging to map the membrane potential of glutamatergic neurons throughout the spinal cord of the larval zebrafish during fictive swimming in a virtual environment. We mapped the spiking, subthreshold dynamics, relative timing, and sub-cellular electrical propagation across large populations of simultaneously recorded cells. We validated the approach by confirming properties of known sub-types, and we characterized a yet undescribed sub-population of tonic-spiking ventral V3 neurons whose spike rate correlated with swimming strength and bout length. Optogenetic activation of V3 neurons led to stronger swimming and longer bouts but did not affect tail-beat frequency. Genetic ablation of V3 neurons led to reduced locomotor adaptation. The power of voltage imaging allowed us to identify V3 neurons as a critical driver of locomotor adaptation in zebrafish.

Published

2021

19. Prednisolone rescues Duchenne muscular dystrophy phenotypes in human pluripotent stem cell-derived skeletal muscle in vitro

Author

Charlotte Fugier-Schmucker, Fanny Bousson, Aurore Hick-Colin, Fabio Marchiano, Daniel Sieiro, Ziad Al Tanoury, Jérome Chal, Harold M. McNamara, Erica Wagner, Rhonda Bassel-Duby, Kevin Kit Parker, Alejandra Rodríguez-delaRosa, Svetlana Gapon, Vandana Gupta, Olivier Pourquié, Jyoti Rao, Eric N. Olson, Thomas Cherrier, John F. Zimmerman, Alexander P. Nesmith, Bianca Habermann, Adam E. Cohen, Harvard Medical School [Boston] (HMS), Institut de Biologie du Développement de Marseille (IBDM), Aix Marseille Université (AMU)-Collège de France (CdF (institution))-Centre National de la Recherche Scientifique (CNRS), and ANR-18-CE45-0016,MITO-DYNAMICS,Analyse fonctionnelle intégrative de la dynamique mitochondriale dans le muscle sain jeune et âgé et sarcopénique.(2018)

Subjects

0301 basic medicine, musculoskeletal diseases, congenital, hereditary, and neonatal diseases and abnormalities, Duchenne muscular dystrophy, Prednisolone, Induced Pluripotent Stem Cells, Muscle Fibers, Skeletal, Cell Line, Dystrophin, 03 medical and health sciences, 0302 clinical medicine, Directed differentiation, Glycoprotein complex, Medicine, Humans, Induced pluripotent stem cell, Muscle, Skeletal, Glycoproteins, Multidisciplinary, biology, Myogenesis, business.industry, Skeletal muscle, [SDV.BDD.MOR]Life Sciences [q-bio]/Development Biology/Morphogenesis, Cell Differentiation, Biological Sciences, medicine.disease, Embryonic stem cell, 3. Good health, Cell biology, Biomechanical Phenomena, Muscular Dystrophy, Duchenne, Optogenetics, 030104 developmental biology, medicine.anatomical_structure, Phenotype, Mutation, biology.protein, Calcium, business, 030217 neurology & neurosurgery

Abstract

International audience; Duchenne muscular dystrophy (DMD) is a devastating genetic disease leading to degeneration of skeletal muscles and premature death. How dystrophin absence leads to muscle wasting remains unclear. Here, we describe an optimized protocol to differentiate human induced pluripotent stem cells (iPSC) to a late myogenic stage. This allows us to recapitulate classical DMD phenotypes (mislocalization of proteins of the dystrophin-associated glycoprotein complex, increased fusion, myofiber branching, force contraction defects, and calcium hyperactivation) in isogenic DMD-mutant iPSC lines in vitro. Treatment of the myogenic cultures with prednisolone (the standard of care for DMD) can dramatically rescue force contraction, fusion, and branching defects in DMD iPSC lines. This argues that prednisolone acts directly on myofibers, challenging the largely prevalent view that its beneficial effects are caused by antiinflammatory properties. Our work introduces a human in vitro model to study the onset of DMD pathology and test novel therapeutic approaches.

Published

2021

20. Neuronal activity drives pathway-specific depolarization of astrocyte distal processes

Author

Yoav Adam, Mary E. Sommer, Naskar S, Adam E. Cohen, Garcia J, Moritz Armbruster, Edward S. Boyden, Philip G. Haydon, Kim E, and Chris G. Dulla

Subjects

Glutamate uptake, Membrane potential, medicine.anatomical_structure, Chemistry, Glutamate receptor, Extracellular, medicine, Premovement neuronal activity, Depolarization, Efflux, Astrocyte, Cell biology

Abstract

Astrocytes are glial cells that interact with neuronal synapses via their distal processes, where they remove glutamate and potassium (K+) from the extracellular space following neuronal activity. Astrocyte clearance of both glutamate and K+is voltage-dependent, but astrocyte membrane potential (Vm) has been thought to be largely invariant. As a result, these voltage-dependencies have not been considered relevant to astrocyte function. Using genetically encoded voltage indicators enabling the measurement of Vmat distal astrocyte processes (DAPs), we report large, rapid, focal, and pathway-specific depolarizations in DAPs during neuronal activity. These activity-dependent astrocyte depolarizations are driven by action potential-mediated presynaptic K+efflux and electrogenic glutamate transporters. We find that DAP depolarization inhibits astrocyte glutamate clearance during neuronal activity, enhancing neuronal activation by glutamate. This represents a novel class of sub-cellular astrocyte membrane dynamics and a new form of astrocyte-neuron interaction.One Sentence SummaryGenetically encoded voltage imaging of astrocytes shows that presynaptic neuronal activity drives focal astrocyte depolarization, contributing to activity-dependent inhibition of glutamate uptake.

Published

2021

21. United States: invest infrastructure stimulus in astronomy facilities

Author

David Reitze, Matt Mountain, and Adam E. Cohen

Subjects

Stimulus (psychology), Multidisciplinary, Research management, Cognitive psychology

Published

2021

22. Photoactivated voltage imaging in tissue with an archaerhodopsin-derived reporter

Author

Daan Brinks, F. Phil Brooks, Adam E. Cohen, Miao-Ping Chien, Benjamin Gmeiner, He Tian, Yoav Adam, Simon Kheifets, Guilherme Testa-Silva, William Bloxham, and Molecular Genetics

Subjects

Membrane potential, 0303 health sciences, Multidisciplinary, Materials science, Optical sectioning, Fluorescence, 03 medical and health sciences, 0302 clinical medicine, In vivo, Optical mapping, Biophysics, Bacterial rhodopsins, Laser power scaling, 030217 neurology & neurosurgery, Excitation, 030304 developmental biology

Abstract

Photoactivated genetically encoded voltage indicators (GEVIs) have the potential to enable optically sectioned voltage imaging at the intersection of a photoactivation beam and an imaging beam. We developed a pooled high-throughput screen to identify archaerhodopsin mutants with enhanced photoactivation. After screening ~105 cells, we identified a novel GEVI, NovArch, whose one-photon near-infrared fluorescence is reversibly enhanced by weak one-photon blue or two-photon near-infrared excitation. Because the photoactivation leads to fluorescent signals catalytically rather than stoichiometrically, high fluorescence signals, optical sectioning, and high time resolution are achieved simultaneously at modest blue or two-photon laser power. We demonstrate applications of the combined molecular and optical tools to optical mapping of membrane voltage in distal dendrites in acute mouse brain slices and in spontaneously active neurons in vivo.

Published

2021

23. Reconstructing tumor trajectories during therapy through integration of multiple measurement modalities

Author

Jason I. Griffiths, Aditya Bardia, Meghna S. Trivedi, Yuan Yuan, Jinfeng Chen, Kari B. Wisinski, Laura Spring, Onalisa Winblad, Kevin Kalinsky, Mohammad Jahanzeb, Adam E. Cohen, Anne O'Dea, Priyanka Sharma, Issam Makhoul, Ruth O'Regan, Qamar Khan, Andrea Bild, and Frederick R. Adler

Subjects

Oncology, medicine.medical_specialty, Modality (human–computer interaction), Modalities, business.industry, Ultrasound, medicine.disease, Clinical trial, Breast cancer, Tumor progression, Internal medicine, Cancer evolution, medicine, business, Pathological

Abstract

BackgroundAccurately determining changes in tumor size during therapy is essential to evaluating response or progression. However, individual imaging methodologies often poorly reflect pathologic response and long-term treatment efficacy in patients with estrogen receptor positive (ER+) early-stage breast cancer. Mathematical models that measure tumor progression over time by integrating diverse imaging and tumor measurement modalities are not currently used but could increase accuracy in measuring response and provide biological insights into cancer evolution.MethodsFor ER+ breast cancer patients enrolled on a neoadjuvant clinical trial, we reconstructed their tumor size trajectories during therapy by combining all available information on tumor size, including different imaging modalities, physical examinations and pathological assessment data. Tumor trajectories during six months of treatment were generated, using a Gaussian process and the most probable trajectories were evaluated, based on clinical data, using measurement models that account for biases and differences in precision between tumor measurement methods, such as MRI, ultrasound and mammograms.ResultsReconstruction of tumor trajectories during treatment identified five distinct patterns of tumor size changes, including rebound growth not evident from any single modality. These results increase specificity to distinguish innate or acquired resistance compared to using any single measurement alone. The speed of therapeutic response and extent of subsequent rebound tumor growth quantify sensitivity or resistance in this patient population.ConclusionsTumor trajectory reconstruction integrating multiple modalities of tumor measurement accurately describes tumor progression on therapy and reveals various patterns of patient responses. Mathematical models can integrate diverse response assessments and account for biases in tumor measurement, thereby providing insights into the timing and rate at which resistance emerges.

Published

2021

24. High-fidelity estimates of spikes and subthreshold waveforms from 1-photon voltage imaging in vivo

Author

Karel Svoboda, Liam Paninski, Linlin Z. Fan, Márton Rózsa, Adam E. Cohen, Ian Kinsella, Yoav Adam, Ding Zhou, Michael E. Xie, Urs Lucas Böhm, and Amrita Singh

Subjects

0301 basic medicine, Fluorescence-lifetime imaging microscopy, Pipeline (computing), Action Potentials, Mice, Transgenic, Hippocampus, General Biochemistry, Genetics and Molecular Biology, Article, Matrix decomposition, 03 medical and health sciences, 0302 clinical medicine, High fidelity, Imaging, Three-Dimensional, Waveform, Animals, Computer Simulation, lcsh:QH301-705.5, Zebrafish, Physics, Photons, Subthreshold conduction, Noise (signal processing), Pyramidal Cells, Reproducibility of Results, signal extraction, 030104 developmental biology, lcsh:Biology (General), Biological system, 030217 neurology & neurosurgery, Algorithms, Voltage, voltage imaging, Signal Transduction

Abstract

Summary The ability to probe the membrane potential of multiple genetically defined neurons simultaneously would have a profound impact on neuroscience research. Genetically encoded voltage indicators are a promising tool for this purpose, and recent developments have achieved a high signal-to-noise ratio in vivo with 1-photon fluorescence imaging. However, these recordings exhibit several sources of noise and signal extraction remains a challenge. We present an improved signal extraction pipeline, spike-guided penalized matrix decomposition-nonnegative matrix factorization (SGPMD-NMF), which resolves supra- and subthreshold voltages in vivo. The method incorporates biophysical and optical constraints. We validate the pipeline with simultaneous patch-clamp and optical recordings from mouse layer 1 in vivo and with simulated and composite datasets with realistic noise. We demonstrate applications to mouse hippocampus expressing paQuasAr3-s or SomArchon1, mouse cortex expressing SomArchon1 or Voltron, and zebrafish spines expressing zArchon1.

Published

2020

25. Optogenetic Approaches to Drug Discovery in Neuroscience and Beyond

Author

Adam E. Cohen and Hongkang Zhang

Subjects

0301 basic medicine, Mechanism (biology), Drug discovery, Genomic data, Phenotypic screening, Neurosciences, Bioengineering, Biology, Optogenetics, Article, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Drug Discovery, Animals, Humans, Identification (biology), Neuroscience, 030217 neurology & neurosurgery, Biotechnology

Abstract

Recent advances in optogenetics have opened new routes to drug discovery, particularly in neuroscience. Physiological cellular assays probe functional phenotypes that connect genomic data to patient health. Optogenetic tools, and in particular tools for all-optical electrophysiology, now provide means to probe cellular disease models with unprecedented throughput and information content. These techniques promise to identify functional phenotypes associated with disease states and to identify compounds that improve cellular function regardless of whether the compound acts directly on a target or through a bypass mechanism. This review discusses opportunities and unresolved challenges in applying optogenetic techniques throughout the discovery pipeline, from target identification and validation, to target-based and phenotypic screens, to clinical trials.

Published

2017

26. All-Optical Electrophysiology Reveals the Role of Lateral Inhibition in Sensory Processing in Cortical Layer 1

Author

Michael E. Xie, Kiryl D. Piatkevich, Edward S. Boyden, Yooree Ha, Hao Wu, Linlin Z. Fan, Kathryn E. Evans, Vicente Parot, Adam E. Cohen, Simon Kheifets, Anne E. Takesian, Urs Lucas Böhm, Program in Media Arts and Sciences (Massachusetts Institute of Technology), and McGovern Institute for Brain Research at MIT

Subjects

Male, Patch-Clamp Techniques, Sensory processing, medicine.medical_treatment, Action Potentials, Mice, Transgenic, Sensory system, Optogenetics, Biology, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, 0302 clinical medicine, Interneurons, Lateral inhibition, Evoked Potentials, Somatosensory, Cortex (anatomy), medicine, Animals, Humans, 030304 developmental biology, 0303 health sciences, Optical Imaging, Neural Inhibition, Somatosensory Cortex, Synaptic Potentials, Barrel cortex, Cholinergic Neurons, Electrophysiology, Mice, Inbred C57BL, HEK293 Cells, medicine.anatomical_structure, Vibrissae, Excitatory postsynaptic potential, Female, Neuroscience, 030217 neurology & neurosurgery

Abstract

Cortical layer 1 (L1) interneurons have been proposed as a hub for attentional modulation of underlying cortex, but the transformations that this circuit implements are not known. We combined genetically targeted voltage imaging with optogenetic activation and silencing to study the mechanisms underlying sensory processing in mouse barrel cortex L1. Whisker stimuli evoked precisely timed single spikes in L1 interneurons, followed by strong lateral inhibition. A mild aversive stimulus activated cholinergic inputs and evoked a bimodal distribution of spiking responses in L1. A simple conductance-based model that only contained lateral inhibition within L1 recapitulated the sensory responses and the winner-takes-all cholinergic responses, and the model correctly predicted that the network would function as a spatial and temporal high-pass filter for excitatory inputs. Our results demonstrate that all-optical electrophysiology can reveal basic principles of neural circuit function in vivo and suggest an intuitive picture for how L1 transforms sensory and modulatory inputs. Video Abstract: [Figure presented] By simultaneously combining genetically targeted voltage imaging with optogenetic modulation of neuronal activity, Fan et al. demonstrate that all-optical electrophysiology in awake animals can be a powerful tool for revealing hidden principles of neural circuit function.

Published

2020

27. High fidelity estimates of spikes and subthreshold waveforms from 1-photon voltage imaging in vivo

Author

Yoav Adam, Ian Kinsella, Adam E. Cohen, Ding Zhou, Liam Paninski, Linlin Z. Fan, Michael E. Xie, and Urs Lucas Böhm

Subjects

Physics, 0303 health sciences, Fluorescence-lifetime imaging microscopy, Noise (signal processing), Subthreshold conduction, Signal, Light scattering, Matrix decomposition, 03 medical and health sciences, 0302 clinical medicine, High fidelity, Waveform, Biological system, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The ability to probe the membrane potential of multiple genetically defined neurons simultaneously would have a profound impact on neuroscience research. Genetically encoded voltage indicators are a promising tool for this purpose, and recent developments have achieved high signal to noise ratio in vivo with 1-photon fluorescence imaging. However, these recordings exhibit several sources of noise that present analysis challenges, namely light scattering, out-of-focus sources, motion, and blood flow. We present a novel signal extraction methodology, Spike-Guided Penalized Matrix Decomposition-Nonnegative Matrix Factorization (SGPMD-NMF), which resolves supra- and sub-threshold voltages with high fidelity, even in the presence of correlated noise. The method incorporates biophysical constraints (shared soma profiles for spiking and subthreshold dynamics) and optical constraints (smoother spatial profiles from defocused vs. in-focus sources) to cleave signal from background. We validated the pipeline using simulated and composite datasets with realistic noise properties. We demonstrate applications to mouse hippocampus expressing paQuasAr3-s or SomArchon, mouse cortex expressing SomArchon or Voltron, and zebrafish spine expressing zArchon1.

Published

2020

28. Billion-dollar telescopes could end up beyond the reach of US astronomers

Author

Matt Mountain and Adam E. Cohen

Subjects

Multidisciplinary, 010504 meteorology & atmospheric sciences, 0103 physical sciences, Economic history, Liberian dollar, 010303 astronomy & astrophysics, 01 natural sciences, 0105 earth and related environmental sciences

Abstract

Change the funding system and approaches to international partnerships for US-led big science projects, urge Matt Mountain and Adam Cohen. Change the funding system and approaches to international partnerships for US-led big science projects, urge Matt Mountain and Adam Cohen.

Published

2018

29. Sculpting light to reveal brain function

Author

Samouil L. Farhi and Adam E. Cohen

Subjects

0301 basic medicine, Physics, Opsin, genetic structures, General Neuroscience, Brain, Stimulation, Optogenetics, Article, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Calcium imaging, Neuropil, medicine, sense organs, Neuroscience, 030217 neurology & neurosurgery, Brain function

Abstract

Understanding brain function requires technologies that can control the activity of large populations of neurons with high fidelity in space and time. We developed a new multiphoton holographic approach to activate or suppress the activity of ensembles of cortical neurons with cellular resolution and sub-millisecond precision. Since existing opsins were inadequate, we engineered new soma-targeted (ST) optogenetic tools, ST-ChroME and IRES-ST-eGtACR1, optimized for multiphoton activation and suppression. Employing a three-dimensional all-optical read/write interface, we demonstrate the ability to photo-stimulate up to 50 neurons simultaneously distributed in three dimensions in a 550 × 550 × 100 μm volume of brain tissue. This new approach allows the synthesis and editing of complex neural activity patterns needed to gain insight into the principles of neural codes.

Published

2018

30. All-optical electrophysiology reveals excitation, inhibition, and neuromodulation in cortical layer 1

Author

Simon Kheifets, Anne E. Takesian, Edward S. Boyden, Michael E. Xie, Urs Lucas Böhm, Linlin Z. Fan, Vicente Parot, Hao Wu, Kiryl D. Piatkevich, and Adam E. Cohen

Subjects

Physics, Electrophysiology, medicine.anatomical_structure, Lateral inhibition, Cortex (anatomy), medicine, Excitatory postsynaptic potential, Gating, Barrel cortex, Optogenetics, Inhibitory postsynaptic potential, Neuroscience

Abstract

The stability of neural dynamics arises through a tight coupling of excitatory (E) and inhibitory (I) signals. Genetically encoded voltage indicators (GEVIs) can report both spikes and subthreshold dynamics in vivo, but voltage only reveals the combined effects of E and I synaptic inputs, not their separate contributions individually. Here we combine optical recording of membrane voltage with simultaneous optogenetic manipulation to probe E and I individually in barrel cortex Layer 1 (L1) neurons in awake mice. Our studies reveal how the L1 microcircuit integrates thalamocortical excitation, lateral inhibition and top-down neuromodulatory inputs. We develop a simple computational model of the L1 microcircuit which captures the main features of our data. Together, these results suggest a model for computation in L1 interneurons consistent with their hypothesized role in attentional gating of the underlying cortex. Our results demonstrate that all-optical electrophysiology can reveal basic principles of neural circuit function in vivo.One Sentence SummaryAll-optical electrophysiology revealed the function in awake mice of an inhibitory microcircuit in barrel cortex Layer 1.

Published

2019

31. Abstract 341: Predicting clinical endocrine response in advanced breast cancers using a reproducible low-dimensional biomarker

Author

Andrea Bild, Jeffrey T. Chang, Aritro Nath, and Adam E. Cohen

Subjects

Oncology, Cancer Research, medicine.medical_specialty, business.industry, medicine.drug_class, Cancer, medicine.disease, Transcriptome, Clinical trial, Risk Estimate, Estrogen, Internal medicine, medicine, Endocrine system, Biomarker (medicine), business, Adverse effect

Abstract

In the absence of reliable and effective prognostic biomarkers, endocrine therapy remains the standard of care for all advanced and metastatic estrogen receptor-positive (ER+) breast cancers. Attempts to develop biomarkers using the baseline tumor transcriptome or genome of advanced ER+ breast cancers have so far been unsuccessful due to predictive models with poor reproducibility in independent studies. Here we present an approach to develop a low-dimensional biomarker that estimates the risk of adverse events on endocrine therapy using the baseline tumor transcriptome of patients. Using a framework for supervised dimensionality reduction of the gene expression feature space, we constructed an endocrine response signature (ENDORSE) modeled on the survival outcomes of ER+ breast cancers from METABRIC. ENDORSE outperformed transcriptome-wide and knowledge-based signature models while significantly improving upon routine histopathological and genomic classifiers in cross-validation analyses. The ENDORSE risk estimate accurately predicted the outcomes for endocrine therapy in three independent clinical trials for ER+ breast cancers. Further, analysis of the phenotypes enriched in high-risk categories show endocrine resistance was not associated with rates of proliferation, but instead with a potential loss of DNA damage repair and cell-matrix interaction pathways. Citation Format: Aritro Nath, Adam Cohen, Jeffrey Chang, Andrea Bild. Predicting clinical endocrine response in advanced breast cancers using a reproducible low-dimensional biomarker [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 341.

Published

2021

32. Genetically Targeted All-Optical Electrophysiology with a Transgenic Cre-Dependent Optopatch Mouse

Author

Nikita Kavokine, Linda Madisen, Erika K. Williams, Adam E. Cohen, Stephen D. Liberles, Vicente Parot, Hongkui Zeng, Yoav Adam, Shan Lou, Katherine J. Williams, and Eli N. Weinstein

Subjects

Male, 0301 basic medicine, Genetically modified mouse, Transgene, Action Potentials, Channelrhodopsin, Mice, Transgenic, Biology, Optogenetics, Mice, 03 medical and health sciences, Calcium imaging, In vivo, Optical mapping, Animals, Cells, Cultured, Research Articles, Neurons, Integrases, General Neuroscience, Recombinant Proteins, Voltage-Sensitive Dye Imaging, Luminescent Proteins, Electrophysiology, 030104 developmental biology, Gene Targeting, Neuroscience

Abstract

Recent advances in optogenetics have enabled simultaneous optical perturbation and optical readout of membrane potential in diverse cell types. Here, we develop and characterize aCre-dependent transgenic Optopatch2 mouse line that we call Floxopatch. The animals expressed a blue-shifted channelrhodopsin, CheRiff, and a near infrared Archaerhodopsin-derived voltage indicator, QuasAr2, via targeted knock-in at the rosa26 locus. In Optopatch-expressing animals, we tested for overall health, genetically targeted expression, and function of the optogenetic components. In offspring of Floxopatch mice crossed with a variety ofCredriver lines, we observed spontaneous and optically evoked activityin vitroin acute brain slices andin vivoin somatosensory ganglia. Cell-type-specific expression allowed classification and characterization of neuronal subtypes based on their firing patterns. The Floxopatch mouse line is a useful tool for fast and sensitive characterization of neural activity in genetically specified cell types in intact tissue.SIGNIFICANCE STATEMENTOptical recordings of neural activity offer the promise of rapid and spatially resolved mapping of neural function. Calcium imaging has been widely applied in this mode, but is insensitive to the details of action potential waveforms and subthreshold events. Simultaneous optical perturbation and optical readout of single-cell electrical activity (“Optopatch”) has been demonstrated in cultured neurons and in organotypic brain slices, but not in acute brain slices orin vivo. Here, we describe a transgenic mouse in which expression of Optopatch constructs is controlled by the Cre-recombinase enzyme. This animal enables fast and robust optical measurements of single-cell electrical excitability in acute brain slices and in somatosensory gangliain vivo, opening the door to rapid optical mapping of neuronal excitability.

Published

2016

33. Bioelectrical signaling via domain wall migration

Author

Olivier Pourquié, Gloria Ortiz, Rajath Salegame, Haitan Xu, Shahinoor Begum, Ziad Al Tanoury, Adam E. Cohen, and Harold M. McNamara

Subjects

Membrane potential, Electrophysiology, Domain wall (string theory), Homogeneous, Domain (ring theory), Biophysics, Myocyte, Pattern formation, Resting potential

Abstract

Electrical signaling in biology is typically associated with action potentials, transient spikes in membrane voltage that return to baseline. The Hodgkin-Huxley equations of electrophysiology belong to a more general class of reaction-diffusion equations which could, in principle, support patterns of membrane voltage which are stable in time but structured in space. Here we show theoretically and experimentally that homogeneous or nearly homogeneous tissues can undergo spontaneous spatial symmetry breaking into domains with different resting potentials, separated by stable bioelectrical domain walls. Transitions from one resting potential to another can occur through long-range migration of these domain walls. We map bioelectrical domain wall motion using all-optical electrophysiology in an engineered stable cell line and in human iPSC-derived myoblasts. Bioelectrical domain wall migration may occur during embryonic development and during physiological signaling processes in polarized tissues. These results demonstrate a novel form of bioelectrical pattern formation and long-range signaling.

Published

2019

34. Geometry dependent arrhythmias in electrically excitable tissues

Author

Adam E. Cohen, Stephanie Dodson, Harold M. McNamara, Björn Sandstede, Evan W. Miller, and Yi-Lin Huang

Subjects

0301 basic medicine, Histology, Excitable cell, Materials science, Induced Pluripotent Stem Cells, Gap junction, Gap Junctions, Geometry, Arrhythmias, Cardiac, Cell Biology, Article, Pathology and Forensic Medicine, Membrane Potentials, 03 medical and health sciences, Electrophysiology, 030104 developmental biology, HEK293 Cells, Line (geometry), Humans, Myocytes, Cardiac, Induced pluripotent stem cell, Cells, Cultured

Abstract

Summary Little is known about how individual cells sense the macroscopic geometry of their tissue environment. Here, we explore whether long-range electrical signaling can convey information on tissue geometry to individual cells. First, we studied an engineered electrically excitable cell line. Cells grown in patterned islands of different shapes showed remarkably diverse firing patterns under otherwise identical conditions, including regular spiking, period-doubling alternans, and arrhythmic firing. A Hodgkin-Huxley numerical model quantitatively reproduced these effects, showing how the macroscopic geometry affected the single-cell electrophysiology via the influence of gap junction-mediated electrical coupling. Qualitatively similar geometry-dependent dynamics were observed in human induced pluripotent stem cell (iPSC)-derived cardiomyocytes. The cardiac results urge caution in translating observations of arrhythmia in vitro to predictions in vivo, where the tissue geometry is very different. We study how to extrapolate electrophysiological measurements between tissues with different geometries and different gap junction couplings.

Published

2018

35. Molecular mimicry in deoxy-nucleotide catalysis: the structure of Escherichia coli dGTPase reveals the molecular basis of dGTP selectivity: New structural methods offer insight on dGTPases

Author

Guillermo Calero, J. Song, E.L. Baxter, Nagarajan, Avram J. Holmes, Nicholas K. Sauter, Aaron S. Brewster, M. Soltis, Guowu Lin, Yang Wu, Adam E. Cohen, Christopher O. Barnes, and Jinwoo Ahn

Subjects

0303 health sciences, biology, Chemistry, Allosteric regulation, dGTPase, DGTP binding, DNA replication, Active site, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Biochemistry, 030220 oncology & carcinogenesis, biology.protein, heterocyclic compounds, Sterile alpha motif, DNA, 030304 developmental biology, SAMHD1

Abstract

Deoxynucleotide triphosphate triphosphyohydrolyases (dNTPases) play a critical role in cellular survival and DNA replication through the proper maintenance of cellular dNTP pools by hydrolyzing dNTPs into deoxynucleosides and inorganic triphosphate (PPPi). While the vast majority of these enzymes display broad activity towards canonical dNTPs, exemplified by Sterile Alpha Motif (SAM) and Histidine-aspartate (HD) domain-containing protein 1 (SAMHD1), which blocks reverse transcription of retroviruses in macrophages by maintaining dNTP pools at low levels,Escherichia coli (Ec)-dGTPase is the only known enzyme that specifically hydrolyzes dGTP. However, the mechanism behind dGTP selectivity is unclear. Here we present the free-, ligand (dGTP)- and inhibitor (GTP)-bound structures of hexameric E. coli dGTPase. To obtain these structures, we applied UV-fluorescence microscopy, video analysis and highly automated goniometer-based instrumentation to map and rapidly position individual crystals randomly-located on fixed target holders, resulting in the highest indexing-rates observed for a serial femtosecond crystallography (SFX) experiment. The structure features a highly dynamic active site where conformational changes are coupled to substrate (dGTP), but not inhibitor binding, since GTP locks dGTPase in its apo form. Moreover, despite no sequence homology, dGTPase and SAMHD1 share similar active site and HD motif architectures; however, dGTPase residues at the end of the substrate-binding pocket mimic Watson Crick interactions providing Guanine base specificity, while a 7 Å cleft separates SAMHD1 residues from dNTP bases, abolishing nucleotide-type discrimination. Furthermore, the structures sheds light into the mechanism by which long distance binding (25 Å) of single stranded DNA in an allosteric site primes the active site by conformationally “opening” a tyrosine gate allowing enhanced substrate binding.Significance StatementdNTPases play a critical role in cellular survival through maintenance of cellular dNTP. While dNTPases display activity towards dNTPs, such as SAMHD1 –which blocks reverse transcription of HIV-1 in macrophages– Escherichia coli (Ec)-dGTPase is the only known enzyme that specifically hydrolyzes dGTP. Here we use novel free electron laser data collection to shed light into the mechanisms of (Ec)-dGTPase selectivity. The structure features a dynamic active site where conformational changes are coupled to dGTP binding. Moreover, despite no sequence homology between (Ec)-dGTPase and SAMHD1, both enzymes share similar active site architectures; however, dGTPase residues at the end of the substrate-binding pocket provide dGTP specificity, while a 7 Å cleft separates SAMHD1 residues from dNTP.

Published

2018

36. All-optical electrophysiology for high-throughput functional characterization of a human iPSC-Derived motor neuron model of ALS

Author

Konstantinos Tsioras, Ole Wiskow, Hongkang Zhang, Evangelos Kiskinis, J. Alberto Ortega, Kevin Eggan, Eli N. Weinstein, Peng Zou, Adam E. Cohen, and Joel M. Kralj

Subjects

0301 basic medicine, Resource, SOD1, Induced Pluripotent Stem Cells, Action Potentials, Gene Expression, Stem cells, Optogenetics, Stimulus (physiology), Biology, Biochemistry, 03 medical and health sciences, Superoxide Dismutase-1, Genetics, medicine, Humans, Amyotrophic lateral sclerosis, Induced pluripotent stem cell, Electrofisiologia, Motor neurons, Gene Editing, Motor Neurons, iPSC, Amyotrophic Lateral Sclerosis, Depolarization, Cell Biology, all-optical electrophysiology, Motor neuron, medicine.disease, Electrophysiological Phenomena, Molecular Imaging, Electrophysiology, 030104 developmental biology, medicine.anatomical_structure, Neurones motores, Mutation, ALS, Cèl·lules mare, Neuroscience, Biomarkers, Esclerosi lateral amiotròfica, Developmental Biology

Abstract

Summary Human induced pluripotent stem cell (iPSC)-derived neurons are an attractive substrate for modeling disease, yet the heterogeneity of these cultures presents a challenge for functional characterization by manual patch-clamp electrophysiology. Here, we describe an optimized all-optical electrophysiology, “Optopatch,” pipeline for high-throughput functional characterization of human iPSC-derived neuronal cultures. We demonstrate the method in a human iPSC-derived motor neuron (iPSC-MN) model of amyotrophic lateral sclerosis (ALS). In a comparison of iPSC-MNs with an ALS-causing mutation (SOD1 A4V) with their genome-corrected controls, the mutants showed elevated spike rates under weak or no stimulus and greater likelihood of entering depolarization block under strong optogenetic stimulus. We compared these results with numerical simulations of simple conductance-based neuronal models and with literature results in this and other iPSC-based models of ALS. Our data and simulations suggest that deficits in slowly activating potassium channels may underlie the changes in electrophysiology in the SOD1 A4V mutation., Graphical Abstract, Highlights • All-optical electrophysiology enables high-throughput assays in hiPSC-derived neurons • Neurons derived from ALS patients fire differently from genome-corrected controls • A deficit in the Kv7 potassium current can explain the difference in firing, In this article, Kiskinis and coworkers use all-optical electrophysiology to characterize an iPSC-based model of ALS. By performing high-throughput optical measurements of excitability in motor neurons derived from patients with a SOD1 (A4V) mutations and genome-corrected controls, the authors identify differences in firing consistent with a deficit in KV7 current in the mutants.

Published

2018

37. Geometry-dependent instabilities in electrically excitable tissues

Author

Harold M. McNamara, Yi-Lin Huang, Stephanie Dodson, Björn Sandstede, Adam E. Cohen, and Evan W. Miller

Subjects

Physics, 0303 health sciences, Excitable cell, Spatially resolved, Dynamics (mechanics), Geometry, 030204 cardiovascular system & hematology, 03 medical and health sciences, Electrophysiology, 0302 clinical medicine, Line (geometry), Electrical dynamics, Induced pluripotent stem cell, 030304 developmental biology

Abstract

Little is known about how individual cells sense the macroscopic geometry of their tissue environment. Here we explore whether long-range electrical signaling can convey information on tissue geometry to influence electrical dynamics of individual cells. First, we studied an engineered electrically excitable cell line where all voltage-gated channels were well characterized. Cells grown in patterned islands of different shapes showed remarkably diverse firing patterns under otherwise identical conditions, including regular spiking, period-doubling alternans, and arrhythmic firing. A Hodgkin-Huxley numerical model quantitatively reproduced these effects, showing how the macroscopic geometry affected the single-cell electrophysiology via the influence of gap junction-mediated electrical coupling. Qualitatively similar geometry dependent dynamics were experimentally observed in human induced pluripotent stem cell (iPSC)-derived cardiomyocytes. The cardiac results urge caution in translating observations of arrhythmia in vitro to predictions in vivo where the tissue geometry is very different. We present simulation results and scaling arguments which explore how to extrapolate electrophysiological measurements between tissues with different geometries and different gap junction couplings.

Published

2018

38. Optogenetics: Turning the Microscope on Its Head

Author

Adam E. Cohen

Subjects

Biophysics Week, 0301 basic medicine, Microscopy, Rhodopsin, Dead sea, Computer science, Cells, Ecology (disciplines), Biophysics, Optogenetics, Bioinformatics, Luminescent Proteins, 03 medical and health sciences, 030104 developmental biology, Structural biology, Genes, Reporter, Animals, Humans, Neuroscience

Abstract

Optogenetics as a field cuts cleanly across traditional disciplinary boundaries. Ecology and genetics provide a source of proteins; advanced spectroscopy and structural biology elucidate molecular mechanisms; molecular biology and biochemistry are used to engineer proteins; sophisticated instrumentation delivers light. An understanding of cell biology or neuroscience is needed to develop reasonable biological questions, and rigorous computation is essential to process the torrents of data that often result. The development of optically instrumented life forms promises to continue for the decades ahead.Optogenetics also illustrates the difficulty in predicting where basic science will lead. The Optopatch constructs combine genes from an archaeon from the Dead Sea, an alga from England, an FP from a coral, an FP from a jellyfish, and a peptide from a pig virus. The discoverers of these individual genes likely never suspected that they would be combined one day and used in human neurons to study a cell-based model of neurodegeneration in amyotrophic lateral sclerosis.

Published

2016

39. A Bright and Fast Red Fluorescent Protein Voltage Indicator That Reports Neuronal Activity in Organotypic Brain Slices

Author

Jelena Platisa, Daan Brinks, Robert E. Campbell, Vincent A. Pieribone, Araya Ruangkittisakul, Yongxin Zhao, Ahmed S. Abdelfattah, Samouil L. Farhi, Klaus Ballanyi, Adam E. Cohen, and Peng Zou

Subjects

Male, 0301 basic medicine, Fluorescence-lifetime imaging microscopy, Channelrhodopsin, Optogenetics, Biology, Real-Time Polymerase Chain Reaction, Hippocampus, Green fluorescent protein, Rats, Sprague-Dawley, 03 medical and health sciences, Organ Culture Techniques, Fluorescence microscope, Animals, Humans, Cells, Cultured, Fluorescent Dyes, Neurons, General Neuroscience, Articles, Fluorescence, Rats, Luminescent Proteins, Electrophysiology, HEK293 Cells, 030104 developmental biology, Animals, Newborn, Microscopy, Fluorescence, Temporal resolution, Biophysics, Female, HeLa Cells

Abstract

Optical imaging of voltage indicators based on green fluorescent proteins (FPs) or archaerhodopsin has emerged as a powerful approach for detecting the activity of many individual neurons with high spatial and temporal resolution. Relative to green FP-based voltage indicators, a bright red-shifted FP-based voltage indicator has the intrinsic advantages of lower phototoxicity, lower autofluorescent background, and compatibility with blue-light-excitable channelrhodopsins. Here, we report a bright red fluorescent voltage indicator (fluorescent indicator for voltage imaging red; FlicR1) with properties that are comparable to the best available green indicators. To develop FlicR1, we used directed protein evolution and rational engineering to screen libraries of thousands of variants. FlicR1 faithfully reports single action potentials (∼3% ΔF/F) and tracks electrically driven voltage oscillations at 100 Hz in dissociated Sprague Dawley rat hippocampal neurons in single trial recordings. Furthermore, FlicR1 can be easily imaged with wide-field fluorescence microscopy. We demonstrate that FlicR1 can be used in conjunction with a blue-shifted channelrhodopsin for all-optical electrophysiology, although blue light photoactivation of the FlicR1 chromophore presents a challenge for applications that require spatially overlapping yellow and blue excitation.SIGNIFICANCE STATEMENTFluorescent-protein-based voltage indicators enable imaging of the electrical activity of many genetically targeted neurons with high spatial and temporal resolution. Here, we describe the engineering of a bright red fluorescent protein-based voltage indicator designated as FlicR1 (fluorescent indicator for voltage imaging red). FlicR1 has sufficient speed and sensitivity to report single action potentials and voltage fluctuations at frequencies up to 100 Hz in single-trial recordings with wide-field microscopy. Because it is excitable with yellow light, FlicR1 can be used in conjunction with blue-light-activated optogenetic actuators. However, spatially distinct patterns of optogenetic activation and voltage imaging are required to avoid fluorescence artifacts due to photoactivation of the FlicR1 chromophore.

Published

2016

40. All-Optical Interrogation of Neural Circuits

Author

Michael Häusser, Valentina Emiliani, Karl Deisseroth, and Adam E. Cohen

Subjects

Neurons, business.industry, General Neuroscience, Symposium and Mini-Symposium, Brain, Intact brain, Biology, Optogenetics, All optical, nervous system, Biological neural network, Animals, Humans, Neuroscience research, Nerve Net, Interrogation, Neural coding, business, Neuroscience, Computer hardware

Abstract

There have been two recent revolutionary advances in neuroscience: First, genetically encoded activity sensors have brought the goal of optical detection of single action potentialsin vivowithin reach. Second, optogenetic actuators now allow the activity of neurons to be controlled with millisecond precision. These revolutions have now been combined, together with advanced microscopies, to allow “all-optical” readout and manipulation of activity in neural circuits with single-spike and single-neuron precision. This is a transformational advance that will open new frontiers in neuroscience research. Harnessing the power of light in the all-optical approach requires coexpression of genetically encoded activity sensors and optogenetic probes in the same neurons, as well as the ability to simultaneously target and record the light from the selected neurons. It has recently become possible to combine sensors and optical strategies that are sufficiently sensitive and cross talk free to enable single-action-potential sensitivity and precision for both readout and manipulation in the intact brain. The combination of simultaneous readout and manipulation from the same genetically defined cells will enable a wide range of new experiments as well as inspire new technologies for interacting with the brain. The advances described in this review herald a future where the traditional tools used for generations by physiologists to study and interact with the brain—stimulation and recording electrodes—can largely be replaced by light. We outline potential future developments in this field and discuss how the all-optical strategy can be applied to solve fundamental problems in neuroscience.SIGNIFICANCE STATEMENTThis review describes the nexus of dramatic recent developments in optogenetic probes, genetically encoded activity sensors, and novel microscopies, which together allow the activity of neural circuits to be recorded and manipulated entirely using light. The optical and protein engineering strategies that form the basis of this “all-optical” approach are now sufficiently advanced to enable single-neuron and single-action potential precision for simultaneous readout and manipulation from the same functionally defined neurons in the intact brain. These advances promise to illuminate many fundamental challenges in neuroscience, including transforming our search for the neural code and the links between neural circuit activity and behavior.

Published

2015

41. Two-Photon Lifetime Imaging of Voltage Indicating Proteins as a Probe of Absolute Membrane Voltage

Author

Aaron J. Klein, Daan Brinks, and Adam E. Cohen

Subjects

Photons, Brightness, Fluorescence-lifetime imaging microscopy, Photon, Chemistry, business.industry, Optical Imaging, Biophysics, Action Potentials, Membrane Proteins, 7. Clean energy, Fluorescence, Membrane Potentials, HEK293 Cells, Nuclear magnetic resonance, Förster resonance energy transfer, Two-photon excitation microscopy, Cell Biophysics, Humans, Optoelectronics, business, Sensitivity (electronics), Voltage

Abstract

Genetically encoded voltage indicators (GEVIs) can report cellular electrophysiology with high resolution in space and time. Two-photon (2P) fluorescence has been explored as a means to image voltage in tissue. Here, we used the 2P electronic excited-state lifetime to probe absolute membrane voltage in a manner that is insensitive to the protein expression level, illumination intensity, or photon detection efficiency. First, we tested several GEVIs for 2P brightness, response speed, and voltage sensitivity. ASAP1 and a previously described citrine-Arch electrochromic Förster resonance energy transfer sensor (dubbed CAESR) showed the best characteristics. We then characterized the voltage-dependent lifetime of ASAP1, CAESR, and ArcLight under voltage-clamp conditions. ASAP1 and CAESR showed voltage-dependent lifetimes, whereas ArcLight did not. These results establish 2P fluorescence lifetime imaging as a viable means of measuring absolute membrane voltage. We discuss the prospects and improvements necessary for applications in tissue.

Published

2015

42. Can Species Distribution Models Aid Bioassessment when Reference Sites are Lacking? Tests Based on Freshwater Fishes

Author

Adam E. Cohen, Ben J. Labay, Gordon W. Linam, Kirk O. Winemiller, Leroy J. Kleinsasser, Ryan S. King, Dean A. Hendrickson, and Timothy H. Bonner

Subjects

Global and Planetary Change, Ecology, Population Dynamics, Species distribution, Fishes, Biodiversity, Fresh Water, Models, Theoretical, Biology, biology.organism_classification, Texas, Pollution, Index of biological integrity, Biological integrity, Freshwater fish, Animals, Spatial variability, Species richness, Environmental Monitoring, Global biodiversity

Abstract

Recent literature reviews of bioassessment methods raise questions about use of least-impacted reference sites to characterize natural conditions that no longer exist within contemporary landscapes. We explore an alternate approach for bioassessment that uses species site occupancy data from museum archives as input for species distribution models (SDMs) stacked to predict species assemblages of freshwater fishes in Texas. When data for estimating reference conditions are lacking, deviation between richness of contemporary versus modeled species assemblages could provide a means to infer relative biological integrity at appropriate spatial scales. We constructed SDMs for 100 freshwater fish species to compare predicted species assemblages to data on contemporary assemblages acquired by four independent surveys that sampled 269 sites. We then compared site-specific observed/predicted ratios of the number of species at sites to scores from a multimetric index of biotic integrity (IBI). Predicted numbers of species were moderately to strongly correlated with the numbers observed by the four surveys. We found significant, though weak, relationships between observed/predicted ratios and IBI scores. SDM-based assessments identified patterns of local assemblage change that were congruent with IBI inferences; however, modeling artifacts that likely contributed to over-prediction of species presence may restrict the stand-alone use of SDM-derived patterns for bioassessment and therefore warrant examination. Our results suggest that when extensive standardized survey data that include reference sites are lacking, as is commonly the case, SDMs derived from generally much more readily available species site occupancy data could be used to provide a complementary tool for bioassessment.

Published

2015

43. Cell membranes resist flow

Author

Zheng Shi, Zachary T. Graber, Tobias Baumgart, Adam E. Cohen, and Howard A. Stone

Subjects

0303 health sciences, Vesicle fusion, Chemistry, Tension (physics), Cell, Motility, Transmembrane protein, 03 medical and health sciences, 0302 clinical medicine, medicine.anatomical_structure, Membrane, medicine, Biophysics, Mechanosensitive channels, 030217 neurology & neurosurgery, Ion channel, 030304 developmental biology

Abstract

SUMMARYThe fluid-mosaic model posits a liquid-like plasma membrane, which can flow in response to tension gradients. It is widely assumed that membrane flow transmits local changes in membrane tension across the cell in milliseconds. This conjectured signaling mechanism has been invoked to explain how cells coordinate changes in shape, motility, and vesicle fusion, but the underlying propagation has never been observed. Here we show that propagation of membrane tension occurs quickly in cell-attached blebs, but is largely suppressed in intact cells. The failure of tension to propagate in cells is explained by a fluid dynamical model that incorporates the flow resistance from cytoskeleton-bound transmembrane proteins. In primary endothelial cells, local increases in membrane tension lead only to local activation of mechanosensitive ion channels and to local vesicle fusion. Thus membrane tension is not a mediator of long-range intra-cellular signaling, but local variations in tension mediate distinct processes in sub-cellular domains.

Published

2018

44. All-optical electrophysiology for high-throughput functional characterization of human iPSC-derived motor neuron model of ALS

Author

Ole Wiskow, Peng Zou, Joel M. Kralj, Kevin Eggan, Hongkang Zhang, Eli N. Weinstein, Evangelos Kiskinis, J. Alberto Ortega, Konstantinos Tsioras, and Adam E. Cohen

Subjects

0303 health sciences, Mutant, Depolarization, Optogenetics, Stimulus (physiology), Motor neuron, Biology, Potassium channel, 03 medical and health sciences, Electrophysiology, 0302 clinical medicine, medicine.anatomical_structure, medicine, Induced pluripotent stem cell, Neuroscience, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

Human induced pluripotent stem cell (iPSC)-derived neurons are an attractive substrate for modeling disease, yet the heterogeneity of these cultures presents a challenge for functional characterization by manual patch clamp electrophysiology. Here we describe an optimized all-optical electrophysiology, “Optopatch”, pipeline for high-throughput functional characterization of human iPSC-derived neuronal cultures. We demonstrate the method in a human iPSC-derived motor neuron model of ALS. In a comparison of neurons with an ALS-causing mutation (SOD1 A4V) with their genome-corrected controls, the mutants showed elevated spike rates under weak or no stimulus, and greater likelihood of entering depolarization block under strong optogenetic stimulus. We compared these results to numerical simulations of simple conductance-based neuronal models and to literature results in this and other iPSC-based models of ALS. Our data and simulations suggest that deficits in slowly activating potassium channels may underlie the changes in electrophysiology in the SOD1 A4V mutation.

Published

2018

45. All-optical electrophysiology reveals brain-state dependent changes in hippocampal subthreshold dynamics and excitability

Author

Christopher D. Harvey, Yongxin Zhao, Linda Madisen, Hao Wu, Robert E. Campbell, Daan Brinks, Mohammed A. Mostajo-Radji, Hongkui Zeng, Paola Arlotta, Parot, Yoav Adam, Katherine J. Williams, Samouil L. Farhi, Jeong J. Kim, Adam E. Cohen, Selmaan N. Chettih, Shan Lou, and Simon Kheifets

Subjects

Physics, Electrophysiology, Subthreshold conduction, Excitatory postsynaptic potential, Context (language use), Optogenetics, Hippocampal formation, Network dynamics, Inhibitory postsynaptic potential, Neuroscience

Abstract

A technology to record membrane potential from multiple neurons, simultaneously, in behaving animals will have a transformative impact on neuroscience research1. Parallel recordings could reveal the subthreshold potentials and intercellular correlations that underlie network behavior2. Paired stimulation and recording can further reveal the input-output properties of individual cells or networks in the context of different brain states3. Genetically encoded voltage indicators are a promising tool for these purposes, but were so far limited to single-cell recordings with marginal signal to noise ratio (SNR) in vivo4-6. We developed improved near infrared voltage indicators, high speed microscopes and targeted gene expression schemes which enabled recordings of supra- and subthreshold voltage dynamics from multiple neurons simultaneously in mouse hippocampus, in vivo. The reporters revealed sub-cellular details of back-propagating action potentials, correlations in sub-threshold voltage between multiple cells, and changes in dynamics associated with transitions from resting to locomotion. In combination with optogenetic stimulation, the reporters revealed brain state-dependent changes in neuronal excitability, reflecting the interplay of excitatory and inhibitory synaptic inputs. These tools open the possibility for detailed explorations of network dynamics in the context of behavior.

Published

2018

46. Voltage imaging and optogenetics reveal behaviour-dependent changes in hippocampal dynamics

Author

Robert E. Campbell, Simon Kheifets, Daan Brinks, Christopher D. Harvey, Liam Paninski, Ding Zhou, Katherine J. Williams, Yongxin Zhao, E. Kelly Buchanan, Benjamin Gmeiner, Ian Kinsella, Yoav Adam, Hao Wu, Michael E. Xie, Hongkui Zeng, Adam E. Cohen, Vicente Parot, Mohammed A. Mostajo-Radji, Paola Arlotta, Linda Madisen, Samouil L. Farhi, Jeong J. Kim, Selmaan N. Chettih, and Shan Lou

Subjects

0301 basic medicine, Male, Archaeal Proteins, Hippocampus, Action Potentials, Context (language use), Walking, Hippocampal formation, Optogenetics, Inhibitory postsynaptic potential, Article, 03 medical and health sciences, Mice, 0302 clinical medicine, Animals, Humans, Cells, Cultured, Membrane potential, Neurons, Multidisciplinary, Subthreshold conduction, Chemistry, Mice, Inbred C57BL, 030104 developmental biology, HEK293 Cells, nervous system, Bacteriorhodopsins, Excitatory postsynaptic potential, Female, Neuroscience, 030217 neurology & neurosurgery, Algorithms

Abstract

A technology that simultaneously records membrane potential from multiple neurons in behaving animals will have a transformative effect on neuroscience research1,2. Genetically encoded voltage indicators are a promising tool for these purposes; however, these have so far been limited to single-cell recordings with a marginal signal-to-noise ratio in vivo3–5. Here we developed improved near-infrared voltage indicators, high-speed microscopes and targeted gene expression schemes that enabled simultaneous in vivo recordings of supra- and subthreshold voltage dynamics in multiple neurons in the hippocampus of behaving mice. The reporters revealed subcellular details of back-propagating action potentials and correlations in subthreshold voltage between multiple cells. In combination with stimulation using optogenetics, the reporters revealed changes in neuronal excitability that were dependent on the behavioural state, reflecting the interplay of excitatory and inhibitory synaptic inputs. These tools open the possibility for detailed explorations of network dynamics in the context of behaviour. A combination of improved near-infrared voltage indicators, high-speed microscopes and targeted gene expression schemes enabled simultaneous in vivo optogenetic control and recording of voltage dynamics in multiple neurons in the hippocampus of behaving mice.

Published

2018

47. Cell Membranes Resist Flow

Author

Zachary T. Graber, Adam E. Cohen, Zheng Shi, Tobias Baumgart, and Howard A. Stone

Subjects

0301 basic medicine, Vesicle fusion, Cell, Biology, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Ion Channels, Madin Darby Canine Kidney Cells, 03 medical and health sciences, Mice, 0302 clinical medicine, Dogs, medicine, Animals, Humans, Ion channel, Cytoskeleton, Tension (physics), Cell Membrane, Transmembrane protein, Rats, 030104 developmental biology, Membrane, medicine.anatomical_structure, Biophysics, NIH 3T3 Cells, Mechanosensitive channels, 030217 neurology & neurosurgery, Intracellular, HeLa Cells, Signal Transduction

Abstract

The fluid-mosaic model posits a liquid-like plasma membrane, which can flow in response to tension gradients. It is widely assumed that membrane flow transmits local changes in membrane tension across the cell in milliseconds, mediating long-range signaling. Here, we show that propagation of membrane tension occurs quickly in cell-attached blebs but is largely suppressed in intact cells. The failure of tension to propagate in cells is explained by a fluid dynamical model that incorporates the flow resistance from cytoskeleton-bound transmembrane proteins. Perturbations to tension propagate diffusively, with a diffusion coefficient Dσ ∼0.024 μm2/s in HeLa cells. In primary endothelial cells, local increases in membrane tension lead only to local activation of mechanosensitive ion channels and to local vesicle fusion. Thus, membrane tension is not a mediator of long-range intracellular signaling, but local variations in tension mediate distinct processes in sub-cellular domains.

Published

2017

48. All-optical synaptic electrophysiology probes mechanism of ketamine-induced disinhibition

Author

Hao Wu, Eun Sun Jung, Don B. Arnold, Ralda Nehme, Linlin Z. Fan, Adam E. Cohen, Kevin Eggan, and Yoav Adam

Subjects

0301 basic medicine, Channelrhodopsin, Action Potentials, Inhibitory postsynaptic potential, Biochemistry, Synaptic Transmission, Neuronal Transmission, Article, 03 medical and health sciences, Mice, Slice preparation, Postsynaptic potential, medicine, Animals, Humans, Molecular Biology, Cells, Cultured, Neurons, Chemistry, Cell Biology, Electrophysiological Phenomena, Mice, Inbred C57BL, Electrophysiology, 030104 developmental biology, Disinhibition, Synapses, Excitatory postsynaptic potential, Ketamine, medicine.symptom, Neuroscience, Biotechnology

Abstract

Optical assays of synaptic strength would greatly facilitate studies of neuronal transmission and its dysregulation in disease. Here we introduce a genetic toolbox for all-optical interrogation of synaptic electrophysiology (‘synOptopatch’) via mutually exclusive expression of a channelrhodopsin actuator and an archaerhodopsin-derived voltage indicator. Optically induced activity in the channelrhodopsin-expressing neurons generated excitatory and inhibitory post-synaptic potentials which were optically resolved in the reporter-expressing neurons. We further developed a yellow spine-targeted Ca2+ indicator to localize optogenetically triggered synaptic inputs. We demonstrated synOptopatch recordings in cultured rodent neurons and in acute rodent brain slice. In synOptopatch measurements of primary rodent cultures, acute ketamine administration suppressed disynaptic inhibitory feedbacks, mimicking the effect of this drug on network function in both rodents and humans. We localized this action of ketamine to excitatory synapses onto interneurons. These results establish an in vitro all-optical model of disynaptic disinhibition, a synaptic defect hypothesized in schizophrenia-associated psychosis.

Published

2017

49. Two-photon photoactivated voltage imaging in tissue with an Archaerhodopsin-derived reporter

Author

Daan Brinks, Yoav Adam, Simon Kheifets, William Bloxham, Miao-Ping Chien, and Adam E. Cohen

Subjects

0303 health sciences, Materials science, Optical sectioning, Optical engineering, FOS: Physical sciences, High voltage, Fluorescence, Signal, Quantitative Biology - Quantitative Methods, 03 medical and health sciences, 0302 clinical medicine, Two-photon excitation microscopy, Biological Physics (physics.bio-ph), Optical mapping, FOS: Biological sciences, Microscopy, Biophysics, Physics - Biological Physics, 030217 neurology & neurosurgery, Quantitative Methods (q-bio.QM), 030304 developmental biology

Abstract

Robust voltage imaging in tissue remains a technical challenge. Existing combinations of genetically encoded voltage indicators (GEVIs) and microscopy techniques cannot simultaneously achieve sufficiently high voltage sensitivity, background rejection, and time resolution for highresolution mapping of sub-cellular voltage dynamics in intact brain tissue. We developed a pooled high-throughput screening approach to identify Archaerhodopsin mutants with unusual photophysical properties. After screening ~105 cells, we identified a novel GEVI, NovArch, whose 1-photon near infrared fluorescence is reversibly enhanced by weak 2-photon excitation. Because the 2-photon excitation acts catalytically rather than stoichiometrically, high fluorescence signals, optical sectioning, and high time resolution are achieved simultaneously, at modest 2-photon laser power. We developed a microscopy system optimized for NovArch imaging in tissue. The combination of protein and optical engineering enhanced signal contrast sufficiently to enable optical mapping of back-propagating action potentials in dendrites in acute mouse brain slice.

Published

2017

50. Ultrawidefield microscope for high-speed fluorescence imaging and targeted optogenetic stimulation

Author

Adam E. Cohen, Christopher A. Werley, and Miao-Ping Chien

Subjects

0301 basic medicine, Fluorescence-lifetime imaging microscopy, Materials science, Microscope, Magnification, Optogenetics, Atomic and Molecular Physics, and Optics, Article, Photostimulation, law.invention, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, law, Temporal resolution, Light sheet fluorescence microscopy, Fluorescence microscope, 030217 neurology & neurosurgery, Biotechnology, Biomedical engineering

Abstract

The rapid increase in the number and quality of fluorescent reporters and optogenetic actuators has yielded a powerful set of tools for recording and controlling cellular state and function. To achieve the full benefit of these tools requires improved optical systems with high light collection efficiency, high spatial and temporal resolution, and patterned optical stimulation, in a wide field of view (FOV). Here we describe our ‘Firefly’ microscope, which achieves these goals in a O6 mm FOV. The Firefly optical system is optimized for simultaneous photostimulation and fluorescence imaging in cultured cells. All but one of the optical elements are commercially available, yet the microscope achieves 10-fold higher light collection efficiency at its design magnification than the comparable commercially available microscope using the same objective. The Firefly microscope enables all-optical electrophysiology (‘Optopatch’) in cultured neurons with a throughput and information content unmatched by other neuronal phenotyping systems. This capability opens possibilities in disease modeling and phenotypic drug screening. We also demonstrate applications of the system to voltage and calcium recordings in human induced pluripotent stem cell derived cardiomyocytes.

Published

2017