Abstract

Electrical (voltage) signal is the primary substrate of information processing in the brain. Detecting and recording voltage changes from neurons in living animals remains the ultimate goal of experimental neuroscience to the present day. Standard glass and metal electrodes are hugely invasive and their use suffers from poor spatial resolution, limited coverage, and blindness to cellular identity. The popular calcium-sensitive indicators generate signals contaminated with changes in intracellular calcium that are unrelated to neuronal electrical signals, and only indirectly report the electrical signals with distorted tiing and highly distorted waveform. A conceptually ideal principle to achieve monitoring of neuronal electrical activity is provided by optical voltage imaging using genetically-encoded voltage indicators (GEVIs). However, even the best performing GEVIs currently available are suitable only for in vivo monitoring of compound synaptic potentials (the summated voltage signal from unidentified number of neurons), but fail to resolve simultaneously signals from many individual cells in intact nervous tissue. While better performing GEVIs with higher sensitivity are expected to emerge from the on-going BRAIN Initiative-funded activities, this alone does not resolve the single-cell resolution voltage imaging problem: signals from individual cells are not spatially segregated. The solution to this issue requires other technologies including refined genetic targeting and data analysis methods. We plan to develop protocols for sparse GEVI targeting of central nervous system neurons. Sparse cellular targeting will allow imaging of neuronal activity with little spatial overlap. We also plan to develop data analysis routines for isolating single cel responses from data obtained in sparsely labelled tissue and, building on this, in densely targeted tissue. In summary, we propose to develop a novel genetically-directed voltage imaging tool that is qualitatively different than those currently available, along with data analyss methods to facilitate the use of electrical signals from large number of neurons embedded in functioning neuronal networks. The novel GEVI labelling protocols and data acquisition and analysis algorithms developed here should be immediately useful and impactful for studying brain function in health and disease.

Public Health Relevance

Massive networks of neurons communicate via electrical signals. Very mild disruptions in network activity are believed to be responsible for a number of mental disorders. Understanding the molecular and cellular events underlying brain function would allow us to pinpoint the best time periods and techniques to preempt the onset of symptoms or to halt the progression of mental illness.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Research Project--Cooperative Agreements (U01)
Project #
1U01MH109091-01
Application #
9037189
Study Section
Special Emphasis Panel (ZMH1-ERB-L (06))
Program Officer
Freund, Michelle
Project Start
2015-09-18
Project End
2018-06-30
Budget Start
2015-09-18
Budget End
2016-06-30
Support Year
1
Fiscal Year
2015
Total Cost
$549,797
Indirect Cost
$116,912

  Institution

Name
University of Connecticut
Department
Neurosciences
Type
Schools of Medicine
DUNS #
022254226
City
Farmington
State
CT
Country
United States
Zip Code
06030

  Publications

Fagerholm, Erik D; Dinov, Martin; Knöpfel, Thomas et al. (2018) The characteristic patterns of neuronal avalanches in mice under anesthesia and at rest: An investigation using constrained artificial neural networks. PLoS One 13:e0197893
Song, Chenchen; Piscopo, Denise M; Niell, Cristopher M et al. (2018) Cortical signatures of wakeful somatosensory processing. Sci Rep 8:11977
Antic, Srdjan D; Hines, Michael; Lytton, William W (2018) Embedded ensemble encoding hypothesis: The role of the ""Prepared"" cell. J Neurosci Res 96:1543-1559
Quicke, Peter; Barnes, Samuel J; Knöpfel, Thomas (2017) Imaging of Brain Slices with a Genetically Encoded Voltage Indicator. Methods Mol Biol 1563:73-84
Short, Shaina M; Oikonomou, Katerina D; Zhou, Wen-Liang et al. (2017) The stochastic nature of action potential backpropagation in apical tuft dendrites. J Neurophysiol 118:1394-1414
Song, Chenchen; Do, Quyen B; Antic, Srdjan D et al. (2017) Transgenic Strategies for Sparse but Strong Expression of Genetically Encoded Voltage and Calcium Indicators. Int J Mol Sci 18:
Song, Chenchen; Barnes, Samuel; Knöpfel, Thomas (2017) Mammalian cortical voltage imaging using genetically encoded voltage indicators: a review honoring professor Amiram Grinvald. Neurophotonics 4:031214
Antic, Srdjan D; Empson, Ruth M; Knöpfel, Thomas (2016) Voltage imaging to understand connections and functions of neuronal circuits. J Neurophysiol 116:135-52
Fagerholm, Erik D; Scott, Gregory; Shew, Woodrow L et al. (2016) Cortical Entropy, Mutual Information and Scale-Free Dynamics in Waking Mice. Cereb Cortex 26:3945-52
Cho, Yong Ku; Zheng, Guoan; Augustine, George J et al. (2016) Roadmap on neurophotonics. J Opt 18: