Sensorimotor processing during spatial navigation requires the communication between a large number of brain areas. The posterior parietal cortex (PPC) is a crucial interface for arranging this communication. Leading models, based on extensive work in primates and more recently in rodents, hypothesize that the PPC links sensory and cognitive signals, such as those that guide navigation, with the decisions and plans that drive upcoming locomotor actions. The PPC is therefore predicted to receive sensory signals as inputs and to transmit signals regarding navigation decisions and plans. Although all models of PPC function rely on the interaction between the PPC and multiple other regions, it is currently poorly understood what input signals the PPC receives and how the PPC routes output information to target regions, in large part due to technical limitations. Here we will develop and implement new approaches to measure directly the signals contained in the PPC's input and output channels. Our approach will be to use optical imaging and anatomical tracing technologies in the mouse in combination with behavioral tasks in virtual reality environments. In a first aim, we will examine how the PPC routes information related to sensory and motor events during navigation decision tasks. We will test if the PPC selectively routes different types of information to different target regions or if the PPC transmits information generally to establish widely distributed network. In a second aim, we will measure the input signals the PPC receives from the auditory cortex. We will test if these signals selectively encode specific features of the sensory world, such as spatial information, and how the input signals to the PPC are modulated depending on behavioral relevance and behavioral state. Together this work will advance our understanding of information transfer in a multi-region network for sensorimotor processing, which is essential for nearly all complex behavioral tasks.

Public Health Relevance

Disrupted communication between brain regions contributes to many neurological disorders, including Alzheimer's, autism, and schizophrenia. The proposed experiments will reveal fundamental aspects of how the parietal cortex, which is one of the first and main areas disrupted in Alzheimer's, communicates with other brain regions. By using new approaches to study information flow between brain regions, our results are expected to reveal insights into sensorimotor processing both in health and disease.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
1R01NS089521-01A1
Application #
8960382
Study Section
Sensorimotor Integration Study Section (SMI)
Program Officer
Gnadt, James W
Project Start
2015-07-01
Project End
2020-04-30
Budget Start
2015-07-01
Budget End
2016-04-30
Support Year
1
Fiscal Year
2015
Total Cost
Indirect Cost
Name
Harvard Medical School
Department
Biology
Type
Schools of Medicine
DUNS #
047006379
City
Boston
State
MA
Country
United States
Zip Code
Jackman, Skyler L; Chen, Christopher H; Chettih, Selmaan N et al. (2018) Silk Fibroin Films Facilitate Single-Step Targeted Expression of Optogenetic Proteins. Cell Rep 22:3351-3361
Runyan, Caroline A; Piasini, Eugenio; Panzeri, Stefano et al. (2017) Distinct timescales of population coding across cortex. Nature 548:92-96
Driscoll, Laura N; Pettit, Noah L; Minderer, Matthias et al. (2017) Dynamic Reorganization of Neuronal Activity Patterns in Parietal Cortex. Cell 170:986-999.e16
Panzeri, Stefano; Harvey, Christopher D; Piasini, Eugenio et al. (2017) Cracking the Neural Code for Sensory Perception by Combining Statistics, Intervention, and Behavior. Neuron 93:491-507
Rajan, Kanaka; Harvey, Christopher D; Tank, David W (2016) Recurrent Network Models of Sequence Generation and Memory. Neuron 90:128-42
Morcos, Ari S; Harvey, Christopher D (2016) History-dependent variability in population dynamics during evidence accumulation in cortex. Nat Neurosci 19:1672-1681