Your search keyword '"LaFosse PK"' showing total 9 results

1. Cellular-resolution optogenetics reveals attenuation-by-suppression in visual cortical neurons.

Author

LaFosse PK, Zhou Z, O'Rawe JF, Friedman NG, Scott VM, Deng Y, and Histed MH

Subjects

Animals, Mice, Photic Stimulation methods, Action Potentials physiology, Optogenetics methods, Visual Cortex physiology, Visual Cortex cytology, Neurons physiology

Abstract

The relationship between neurons' input and spiking output is central to brain computation. Studies in vitro and in anesthetized animals suggest that nonlinearities emerge in cells' input-output (IO; activation) functions as network activity increases, yet how neurons transform inputs in vivo has been unclear. Here, we characterize cortical principal neurons' activation functions in awake mice using two-photon optogenetics. We deliver fixed inputs at the soma while neurons' activity varies with sensory stimuli. We find that responses to fixed optogenetic input are nearly unchanged as neurons are excited, reflecting a linear response regime above neurons' resting point. In contrast, responses are dramatically attenuated by suppression. This attenuation is a powerful means to filter inputs arriving to suppressed cells, privileging other inputs arriving to excited neurons. These results have two major implications. First, somatic neural activation functions in vivo accord with the activation functions used in recent machine learning systems. Second, neurons' IO functions can filter sensory inputs-not only do sensory stimuli change neurons' spiking outputs, but these changes also affect responses to input, attenuating responses to some inputs while leaving others unchanged., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

2. Recurrent cortical networks encode natural sensory statistics via sequence filtering.

Author

Deveau CE, Zhou Z, LaFosse PK, Deng Y, Mirbagheri S, Steinmetz N, and Histed MH

Abstract

Recurrent neural networks can generate dynamics, but in sensory cortex it has been unclear if any dynamic processing is supported by the dense recurrent excitatory-excitatory network. Here we show a new role for recurrent connections in mouse visual cortex: they support powerful dynamical computations, but by filtering sequences of input instead of generating sequences. Using two-photon optogenetics, we measure neural responses to natural images and play them back, finding inputs are amplified when played back during the correct movie dynamic context- when the preceding sequence corresponds to natural vision. This sequence selectivity depends on a network mechanism: earlier input patterns produce responses in other local neurons, which interact with later input patterns. We confirm this mechanism by designing sequences of inputs that are amplified or suppressed by the network. These data suggest recurrent cortical connections perform predictive processing, encoding the statistics of the natural world in input-output transformations.

Published

2024

3. Single-cell optogenetics reveals attenuation-by-suppression in visual cortical neurons.

Author

LaFosse PK, Zhou Z, O'Rawe JF, Friedman NG, Scott VM, Deng Y, and Histed MH

Abstract

The relationship between neurons' input and spiking output is central to brain computation. Studies in vitro and in anesthetized animals suggest nonlinearities emerge in cells' input-output (activation) functions as network activity increases, yet how neurons transform inputs in vivo has been unclear. Here, we characterize cortical principal neurons' activation functions in awake mice using two-photon optogenetics. We deliver fixed inputs at the soma while neurons' activity varies with sensory stimuli. We find responses to fixed optogenetic input are nearly unchanged as neurons are excited, reflecting a linear response regime above neurons' resting point. In contrast, responses are dramatically attenuated by suppression. This attenuation is a powerful means to filter inputs arriving to suppressed cells, privileging other inputs arriving to excited neurons. These results have two major implications. First, somatic neural activation functions in vivo accord with the activation functions used in recent machine learning systems. Second, neurons' IO functions can filter sensory inputs - not only do sensory stimuli change neurons' spiking outputs, but these changes also affect responses to input, attenuating responses to some inputs while leaving others unchanged.

Published

2024

4. Excitation creates a distributed pattern of cortical suppression due to varied recurrent input.

Author

O'Rawe JF, Zhou Z, Li AJ, LaFosse PK, Goldbach HC, and Histed MH

Subjects

Mice, Animals, Neurons physiology, Optogenetics

Abstract

Dense local, recurrent connections are a major feature of cortical circuits, yet how they affect neurons' responses has been unclear, with some studies reporting weak recurrent effects, some reporting amplification, and others indicating local suppression. Here, we show that optogenetic input to mouse V1 excitatory neurons generates salt-and-pepper patterns of both excitation and suppression. Responses in individual neurons are not strongly predicted by that neuron's direct input. A balanced-state network model reconciles a set of diverse observations: the observed dynamics, suppressed responses, decoupling of input and output, and long tail of excited responses. The model shows recurrent excitatory-excitatory connections are strong and also variable across neurons. Together, these results demonstrate that excitatory recurrent connections can have major effects on cortical computations by shaping and changing neurons' responses to input., Competing Interests: Declaration of interests The authors declare no competing interests., (Published by Elsevier Inc.)

Published

2023

5. Amplified cortical neural responses as animals learn to use novel activity patterns.

Author

Akitake B, Douglas HM, LaFosse PK, Beiran M, Deveau CE, O'Rawe J, Li AJ, Ryan LN, Duffy SP, Zhou Z, Deng Y, Rajan K, and Histed MH

Subjects

Mice, Animals, Cerebral Cortex, Visual Perception physiology, Neurons physiology, Learning

Abstract

Cerebral cortex supports representations of the world in patterns of neural activity, used by the brain to make decisions and guide behavior. Past work has found diverse, or limited, changes in the primary sensory cortex in response to learning, suggesting that the key computations might occur in downstream regions. Alternatively, sensory cortical changes may be central to learning. We studied cortical learning by using controlled inputs we insert: we trained mice to recognize entirely novel, non-sensory patterns of cortical activity in the primary visual cortex (V1) created by optogenetic stimulation. As animals learned to use these novel patterns, we found that their detection abilities improved by an order of magnitude or more. The behavioral change was accompanied by large increases in V1 neural responses to fixed optogenetic input. Neural response amplification to novel optogenetic inputs had little effect on existing visual sensory responses. A recurrent cortical model shows that this amplification can be achieved by a small mean shift in recurrent network synaptic strength. Amplification would seem to be desirable to improve decision-making in a detection task; therefore, these results suggest that adult recurrent cortical plasticity plays a significant role in improving behavioral performance during learning., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023. Published by Elsevier Inc.)

Published

2023

6. Bicistronic Expression of a High-Performance Calcium Indicator and Opsin for All-Optical Stimulation and Imaging at Cellular Resolution.

Author

LaFosse PK, Zhou Z, Friedman NG, Deng Y, Li AJ, Akitake B, and Histed MH

Subjects

Animals, Mice, Photic Stimulation methods, Neurons physiology, Rod Opsins metabolism, Optogenetics methods, Opsins genetics, Calcium metabolism

Abstract

State-of-the-art all-optical systems promise unprecedented access to neural activity in vivo , using multiphoton optogenetics to allow simultaneous imaging and control of activity in selected neurons at cellular resolution. However, to achieve wide use of all-optical stimulation and imaging, simple strategies are needed to robustly and stably express opsins and indicators in the same cells. Here, we describe a bicistronic adeno-associated virus (AAV) that expresses both the fast and bright calcium indicator jGCaMP8s, and a soma-targeted (st) and two-photon-activatable opsin, ChrimsonR. With this method, stChrimsonR stimulation with two-photon holography in the visual cortex of mice drives robust spiking in targeted cells, and neural responses to visual sensory stimuli and spontaneous activity are strong and stable. Cells expressing this bicistronic construct show responses to both photostimulation and visual stimulation that are similar to responses measured from cells expressing the same opsin and indicator via separate viruses. This approach is a simple and robust way to prepare neurons in vivo for two-photon holography and imaging., Competing Interests: The authors declare no competing financial interests., (Copyright © 2023 LaFosse et al.)

Published

2023

7. Software for lattice light-sheet imaging of FRET biosensors, illustrated with a new Rap1 biosensor.

Author

O'Shaughnessy EC, Stone OJ, LaFosse PK, Azoitei ML, Tsygankov D, Heddleston JM, Legant WR, Wittchen ES, Burridge K, Elston TC, Betzig E, Chew TL, Adalsteinsson D, and Hahn KM

Subjects

Human Umbilical Vein Endothelial Cells cytology, Humans, Microscopy, Fluorescence, Shelterin Complex, Telomere-Binding Proteins genetics, Biosensing Techniques, Fluorescence Resonance Energy Transfer, Human Umbilical Vein Endothelial Cells metabolism, Image Processing, Computer-Assisted, Signal Transduction, Software, Telomere-Binding Proteins metabolism

Abstract

Lattice light-sheet microscopy (LLSM) is valuable for its combination of reduced photobleaching and outstanding spatiotemporal resolution in 3D. Using LLSM to image biosensors in living cells could provide unprecedented visualization of rapid, localized changes in protein conformation or posttranslational modification. However, computational manipulations required for biosensor imaging with LLSM are challenging for many software packages. The calculations require processing large amounts of data even for simple changes such as reorientation of cell renderings or testing the effects of user-selectable settings, and lattice imaging poses unique challenges in thresholding and ratio imaging. We describe here a new software package, named ImageTank, that is specifically designed for practical imaging of biosensors using LLSM. To demonstrate its capabilities, we use a new biosensor to study the rapid 3D dynamics of the small GTPase Rap1 in vesicles and cell protrusions., (© 2019 O'Shaughnessy et al.)

Published

2019

8. Emergent spatiotemporal dynamics of the actomyosin network in the presence of chemical gradients.

Author

Miller CJ, LaFosse PK, Asokan SB, Haugh JM, Bear JE, and Elston TC

Subjects

Animals, Cell Movement, Humans, Models, Biological, Myosin Type II metabolism, Pattern Recognition, Automated, Platelet-Derived Growth Factor metabolism, Signal Transduction, Actin Cytoskeleton metabolism, Actomyosin physiology, Chemotaxis, Computer Simulation, Fibroblasts cytology

Abstract

We used particle-based computer simulations to study the emergent properties of the actomyosin cytoskeleton. Our model accounted for biophysical interactions between filamentous actin and non-muscle myosin II and was motivated by recent experiments demonstrating that spatial regulation of myosin activity is required for fibroblasts responding to spatial gradients of platelet derived growth factor (PDGF) to undergo chemotaxis. Our simulations revealed the spontaneous formation of actin asters, consistent with the punctate actin structures observed in chemotacting fibroblasts. We performed a systematic analysis of model parameters to identify biochemical steps in myosin activity that significantly affect aster formation and performed simulations in which model parameter values vary spatially to investigate how the model responds to chemical gradients. Interestingly, spatial variations in motor stiffness generated time-dependent behavior of the actomyosin network, in which actin asters continued to spontaneously form and dissociate in different regions of the gradient. Our results should serve as a guide for future experimental investigations., (© The Author(s) 2019. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2019

9. Long-Term Depression Learning in Spinal Cord Networks.

Author

Baker Z, Therrien K, LaFosse PK, Noor A, and Peixoto N

Subjects

Action Potentials, Animals, Mice, Long-Term Synaptic Depression, Microelectrodes, Nerve Net, Neurons physiology, Spinal Cord physiology

Abstract

Investigating learning in networks of spinal cord neurons can provide insight into the dynamics of connectivity in human spinal cords. It may also hold implications for developing neural prosthetics and neurocomputers. Culturing neural networks on microelectrode arrays (MEAs) allows for the repeated observation and stimulation of electrophysiological activity in vitro. Here we used MEAs to demonstrate learning in networks of spinal cord neurons. This was done by exposing E17 mouse spinal cord cultures to high frequency artificial spike trains, or tetanization. Unexpectedly, when comparing the networks' responses to low-frequency probing stimulations before and after tetanization, the cultures were found to demonstrate long-term depression (LTD). LTD was most significantly observed between 500-1000 ms after low-frequency probing. These results indicate that periodic high-frequency excitation of spinal cord networks can result in decreased synaptic efficacy.

Published

2018