A central goal in neuroscience is to identify cellular ensembles supporting mental and behavioral states, but these ensembles cannot be defined a priori. The dentate gyrus (DG), for example, contains more than 1M granule cells, which are essentially indistinguishable from each other, but less than 5% of these seemingly identical neurons are active during any one behavioral event, suggesting that the associated mental states are each mediated by a small subset of neurons. We propose to develop a novel method for identifying and gaining genetic access to such transient, behaviorally-relevant assemblies of neurons in awake animals. The key unique features of our approach are (1) its temporal precision is unprecedented because it is the first neuronal tagging technique that matches the timescale of naturalistic behavior; and (2) its ability to label multiple cell populations in the sme animal enables the comparison of state-specific cell ensembles. Our novel molecular-genetic technique first identifies activated neurons on the basis of elevated intracellular calcium and then tags them using light. Light application is especially attractive because it is temporally precise: just as other optogenetic methods have aided neuronal circuit analysis by approximating the timescale of cell activity, so too will a light-dependent labeling technique illuminate functional cell assemblies. The technique will be entirely virus-based, so it is usable across species without relying on transgenic animals. Under this award we will establish the technique by developing and testing two critical innovations: (1) a synthetic bidirectional promoter system, and (2) caging chemistry for multi-wavelength visible light regulation of promoter function. Ultimately this technique will be used to elucidate the neuronal substrates of diverse mental states, such as fear, hunger, depression, anxiety, and addiction, thereby advancing the exploration of critical brain networks. This high-risk, high-reward project comprises multiple innovative features. Elements of the nascent reporter system described here, such as promoter strength, mechanism for regulating gene expression, choice of activating ligand, caging chemistry, and in vivo ligand and light delivery represent starting point that will benefit from extensive optimization. Once existing reporter components have been sufficiently refined, we envision replacing fluorescent reporters with recombinases, so that actuators can be expressed in identified cells for testing neuronal function. Other features, including the development of novel caged ligands, as well as additional methods for brain-wide activity reporting will also be addressed following achievement of our Aims. Despite the inherent risks, we are confident that our proposed system represents a fundamental and much-needed departure from existing techniques. We believe that our approach will evolve from its present status as a promising endeavor into a widely-used tool with the support of the BRAIN Initiative.

Public Health Relevance

This project will produce several highly original and powerful tools for functional brain mapping, enabling the experimenter to target subsets of neurons activated during transient behavioral or mental events. Cell function can then be analyzed in vivo using selective activity manipulation, while cell properties can be examined ex vivo using protein, gene or histological assays. When used in the context of disease states-addiction, depression, anxiety, and many others-this new technique will yield novel cellular targets for clinical intervention.

Agency
National Institute of Health (NIH)
Institute
National Eye Institute (NEI)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21EY026446-01
Application #
9056270
Study Section
Special Emphasis Panel (ZEY1)
Program Officer
Wujek, Jerome R
Project Start
2015-09-30
Project End
2017-08-31
Budget Start
2015-09-30
Budget End
2016-08-31
Support Year
1
Fiscal Year
2015
Total Cost
Indirect Cost
Name
University of Texas Austin
Department
Type
DUNS #
170230239
City
Austin
State
TX
Country
United States
Zip Code
78712
Huckleberry, Kylie A; Shue, Francis; Copeland, Taylor et al. (2018) Dorsal and ventral hippocampal adult-born neurons contribute to context fear memory. Neuropsychopharmacology 43:2487-2496
Bernier, Brian E; Lacagnina, Anthony F; Ayoub, Adam et al. (2017) Dentate Gyrus Contributes to Retrieval as well as Encoding: Evidence from Context Fear Conditioning, Recall, and Extinction. J Neurosci 37:6359-6371
Drew, Michael R; Huckleberry, Kylie A (2017) Modulation of Aversive Memory by Adult Hippocampal Neurogenesis. Neurotherapeutics 14:646-661
Huckleberry, Kylie A; Ferguson, Laura B; Drew, Michael R (2016) Behavioral mechanisms of context fear generalization in mice. Learn Mem 23:703-709
Seidemann, Eyal; Chen, Yuzhi; Bai, Yoon et al. (2016) Calcium imaging with genetically encoded indicators in behaving primates. Elife 5: