TY - JOUR
T1 - Imaging voltage in genetically defined neuronal subpopulations with a cre recombinase-targeted hybrid voltage sensor
AU - Bayguinov, Peter O.
AU - Ma, Yihe
AU - Gao, Yu
AU - Zhao, Xinyu
AU - Jackson, Meyer B.
N1 - Publisher Copyright:
© 2017 the authors.
PY - 2017/9/20
Y1 - 2017/9/20
N2 - Genetically encoded voltage indicators create an opportunity to monitor electrical activity in defined sets of neurons as they participate in the complex patterns of coordinated electrical activity that underlie nervous system function. Taking full advantage of genetically encoded voltage indicators requires a generalized strategy for targeting the probe to genetically defined populations of cells. To this end, we have generated a mouse line with an optimized hybrid voltage sensor (hVOS) probe within a locus designed for efficient Cre recombinase-dependent expression. Crossing this mouse with Cre drivers generated double transgenics expressing hVOS probe in GABAergic, parvalbumin, and calretinin interneurons, as well as hilar mossy cells, new adult-born neurons, and recently active neurons. In each case, imaging in brain slices from male or female animals revealed electrically evoked optical signals from multiple individual neurons in single trials. These imaging experiments revealed action potentials, dynamic aspects of dendritic integration, and trial-to-trial fluctuations in response latency. The rapid time response of hVOS imaging revealed action potentials with high temporal fidelity, and enabled accurate measurements of spike half-widths characteristic of each cell type. Simultaneous recording of rapid voltage changes in multiple neurons with a common genetic signature offers a powerful approach to the study of neural circuit function and the investigation of how neural networks encode, process, and store information.
AB - Genetically encoded voltage indicators create an opportunity to monitor electrical activity in defined sets of neurons as they participate in the complex patterns of coordinated electrical activity that underlie nervous system function. Taking full advantage of genetically encoded voltage indicators requires a generalized strategy for targeting the probe to genetically defined populations of cells. To this end, we have generated a mouse line with an optimized hybrid voltage sensor (hVOS) probe within a locus designed for efficient Cre recombinase-dependent expression. Crossing this mouse with Cre drivers generated double transgenics expressing hVOS probe in GABAergic, parvalbumin, and calretinin interneurons, as well as hilar mossy cells, new adult-born neurons, and recently active neurons. In each case, imaging in brain slices from male or female animals revealed electrically evoked optical signals from multiple individual neurons in single trials. These imaging experiments revealed action potentials, dynamic aspects of dendritic integration, and trial-to-trial fluctuations in response latency. The rapid time response of hVOS imaging revealed action potentials with high temporal fidelity, and enabled accurate measurements of spike half-widths characteristic of each cell type. Simultaneous recording of rapid voltage changes in multiple neurons with a common genetic signature offers a powerful approach to the study of neural circuit function and the investigation of how neural networks encode, process, and store information.
KW - Cre-lox
KW - Genetically encoded voltage indicators
KW - Interneuron
KW - Mossy cells
KW - Neural circuits
KW - Voltage imaging
UR - http://www.scopus.com/inward/record.url?scp=85029765392&partnerID=8YFLogxK
U2 - 10.1523/JNEUROSCI.1363-17.2017
DO - 10.1523/JNEUROSCI.1363-17.2017
M3 - Article
C2 - 28842412
AN - SCOPUS:85029765392
SN - 0270-6474
VL - 37
SP - 9305
EP - 9319
JO - Journal of Neuroscience
JF - Journal of Neuroscience
IS - 38
ER -