Hayley A. Bounds scite author profile

The biophysical properties of existing optogenetic tools constrain the scale, speed, and fidelity of precise optogenetic control. Here, we use structure-guided mutagenesis to engineer opsins that exhibit very high potency while retaining fast kinetics. These new opsins enable large-scale, temporally and spatially precise control of population neural activity. We extensively benchmark these new opsins against existing optogenetic tools and provide a detailed biophysical characterization of a diverse family of opsins under two-photon illumination. This establishes a resource for matching the optimal opsin to the goals and constraints of patterned optogenetics experiments. Finally, by combining these new opsins with optimized procedures for holographic photostimulation, we demonstrate the simultaneous coactivation of several hundred spatially defined neurons with a single hologram and nearly double that number by temporally interleaving holograms at fast rates. These newly engineered opsins substantially extend the capabilities of patterned illumination optogenetic paradigms for addressing neural circuits and behavior.

show abstract

High performance microbial opsins for spatially and temporally precise perturbations of large neuronal networks

Sridharan

Gajowa

et al. 2021

Preprint

View full text Add to dashboard Cite

Patterned optogenetic activation of defined neuronal populations in the intact brain can reveal fundamental aspects of the neural codes of perception and behavior. The biophysical properties of existing optogenetic tools, however, constrain the scale, speed, and fidelity of precise optical control. Here we use structure-guided mutagenesis to engineer opsins that exhibit very high potency while retaining fast kinetics. These new opsins enable large-scale, temporally and spatially precise control of population neural activity in vivo and in vitro. We benchmark these new opsins against existing optogenetics tools with whole-cell electrophysiology and all-optical physiology and provide a detailed biophysical characterization of a diverse family of microbial opsins under two-photon illumination. This establishes a toolkit and a resource for matching the optimal opsin to the goals and constraints of patterned optogenetics experiments. Finally, by combining these new opsins with optimized procedures for cell-specific holographic photo-stimulation, we demonstrate the simultaneous co-activation of several hundred spatially defined neurons with a single hologram, and nearly double that number by temporally interleaving holograms at fast rates. These newly engineered opsins substantially extend the capabilities of patterned illumination optogenetic paradigms for addressing neural circuits and behavior.

show abstract

The logic of recurrent circuits in the primary visual cortex

Oldenburg

Hendricks

Handy

et al. 2022

Preprint

View full text Add to dashboard Cite

Recurrent cortical activity sculpts visual perception by refining, amplifying, or suppressing incoming visual signals. Despite the importance of recurrent circuits for cortical processing, the basic rules that govern how nearby cortical neurons influence each other remains enigmatic. We used two-photon holographic optogenetics to activate ensembles of neurons in Layer 2/3 of the primary visual cortex (V1) in the absence of external stimuli to isolate the impact of local recurrence from external inputs. We find that the spatial arrangement and the stimulus feature preference of both the stimulated and the target ensemble jointly determine the net effect of recurrent activity, defining the cortical activity patterns that drive competition versus facilitation in L2/3 circuits. Computational modeling suggests that a combination of highly local recurrent excitatory connectivity and selective convergence onto inhibitory neurons give rise to these principles of recurrent activity. Our data and modeling reveal that recurrent activity can have varied impact, but a logic emerges through an understanding of the precise spatial distribution and feature preference of the multicellular pattern of activity.

show abstract

Ultra-precise all-optical manipulation of neural circuits with multifunctional Cre-dependent transgenic mice

Bounds

Sadahiro²,

Hendricks³

et al. 2021

Preprint

View full text Add to dashboard Cite

Causally relating the detailed structure and function of neural circuits to behavior requires the ability to precisely and simultaneously write-in and read-out neural activity. All optical systems that combine two photon (2p) calcium imaging and targeted photostimulation provide such an approach, but require co-expression of an activity indicator, such as GCaMP, and an optogenetic actuator, ideally a potent soma-targeted opsin. In the mammalian brain, such co-expression has so far been achieved by viral transduction, which is invasive and can produce variable, focal, and sometimes toxic overexpression. To overcome this challenge, we developed and validated a Cre-reporter mouse ("Ai203") that conditionally expresses a soma-targeted opsin, ChroME, fused to GCaMP7s. 1p or 2p illumination of expressing neurons in vitro and in vivo produces powerful, precise activation comparable to viral expression of ChroME. The soma-targeted GCaMP7s provides sensitive activity measurements for tracking physiological activity, and the soma-targeted ChroME provides powerful control over neural ensemble activity with holographic optogenetics. We further demonstrate the use of the Ai203 reporter line in 1p optogenetic manipulation of performance on a cortex-dependent visual task and in 2p synaptic connectivity mapping. This new transgenic line could thus greatly facilitate the study of neural circuits by providing a flexible, convenient, and stable tool for all-optical access to large, cell-type specific neural populations throughout the nervous system.

show abstract

Automated real-time quantification of group locomotor activity in Drosophila melanogaster

Scaplen

Mei

Bounds

et al. 2019

Sci Rep

View full text Add to dashboard Cite

Recent advances in neurogenetics have highlighted Drosophila melanogaster as an exciting model to study neural circuit dynamics and complex behavior. Automated tracking methods have facilitated the study of complex behaviors via high throughput behavioral screening. Here we describe a newly developed low-cost assay capable of real-time monitoring and quantifying Drosophila group activity. This platform offers reliable real-time quantification with open source software and a user-friendly interface for data acquisition and analysis. We demonstrate the utility of this platform by characterizing ethanol-induced locomotor activity in a dose-dependent manner as well as the effects of thermo and optogenetic manipulation of ellipsoid body neurons important for ethanol-induced locomotor activity. As expected, low doses of ethanol induced an initial startle and slow ramping of group activity, whereas high doses of ethanol induced sustained group activity followed by sedation. Advanced offline processing revealed discrete behavioral features characteristic of intoxication. Thermogenetic inactivation of ellipsoid body ring neurons reduced group activity whereas optogenetic activation increased activity. Together, these data establish the fly Group Activity Monitor (flyGrAM) platform as a robust means of obtaining an online read out of group activity in response to manipulations to the environment or neural activity, with an opportunity for more advanced post-processing offline.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Hayley A. Bounds

High-performance microbial opsins for spatially and temporally precise perturbations of large neuronal networks

High performance microbial opsins for spatially and temporally precise perturbations of large neuronal networks

The logic of recurrent circuits in the primary visual cortex

Ultra-precise all-optical manipulation of neural circuits with multifunctional Cre-dependent transgenic mice

Automated real-time quantification of group locomotor activity in Drosophila melanogaster

Contact Info

Product

Resources

About