All organisms possess an intrinsic ability to detect and respond to threats in their environments, but the underlying molecular mechanisms are poorly understood. A complete understanding of this process requires knowledge of the underlying neural circuits along with an ability to measure and, most importantly, perturb their activity. This is difficult to obtain in complex vertebrate circuits. However, invertebrate circuit with their well-defined neuroanatomy and quantitative behaviors are ideally placed to decipher the underlying machinery guiding complex outputs. This proposal aims to understand the neural mechanisms that code threat responses (both behavioral and physiological) in an invertebrate brain model. The nematode, Caenorhabditis elegans, provides a unique opportunity to analyze, using a multi- scale approach, genes, cells and circuits that regulate complex behaviors. The Chalasani lab has developed a novel model of threat behaviors using the interactions between C. elegans and a second nematode, Pristionchus pacificus. A starving Pristionchus will attack and devour C. elegans in 30 minutes. C. elegans in turn, will avoid both Pristionchus and its secretions. Apart from this behavioral response, C. elegans also activates mitochondrial stress upon exposure to Pristionchus. The goals of the proposed research program are to define the cellular and molecular mechanisms regulating avoidance behavior in this model system. It has already been determined that a novel neural circuit including three new sensory neurons (ASJ, ASK and ASI) drive avoidance behavior and physiological stress responses.
Specific aim 1 will identify this neuronal circuit and the associated neurotransmitters and receptors that regulate predator avoidance and mitochondrial stress responses.
Aim 2 will optimize an automated behavioral platform to rapidly analyze behaviors from large numbers of worms and perform a large screen for genes affecting avoidance behavior. A pilot screen has identified 4 interesting genes as required for regulating avoidance behavior. These include a TRPV channel (might be part of the Pristionchus sensing machinery), glutamate transporters and serotonin biosynthesis enzyme and serotonin re-uptake transporter.
Aim 3 is focused on validating these and other candidates from the genetic screen. These studies will clarify how neural circuits process information about environmental threats at the level of synapses, neural circuits and whole organisms. Moreover, we will identify basic principles and conserved mechanisms of how neural circuits integrate glutamate and serotonin signaling to generate complex behaviors.

Public Health Relevance

Animals integrate information about environmental threats into their behavior and physiology with disruptions leading to a number of anxiety related disorders. This proposal uses a simple, well-defined genetic model to understand how external threats are detected and processed. We also aim to use our model to develop new diagnostic tools and identify new targets for therapeutic intervention in human anxiety related diseases.

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Research Project (R01)
Project #
1R01MH098001-01A1
Application #
8506622
Study Section
Neurobiology of Motivated Behavior Study Section (NMB)
Program Officer
Beckel-Mitchener, Andrea C
Project Start
2013-07-01
Project End
2015-06-30
Budget Start
2013-07-01
Budget End
2014-06-30
Support Year
1
Fiscal Year
2013
Total Cost
$485,000
Indirect Cost
$235,000
Name
Salk Institute for Biological Studies
Department
Type
DUNS #
078731668
City
La Jolla
State
CA
Country
United States
Zip Code
92037
Liu, Zheng; Kariya, Maro J; Chute, Christopher D et al. (2018) Predator-secreted sulfolipids induce defensive responses in C. elegans. Nat Commun 9:1128
Lau, Hiu E; Chalasani, Sreekanth H (2014) Divergent and convergent roles for insulin-like peptides in the worm, fly and mammalian nervous systems. Invert Neurosci 14:71-8
Joens, Matthew S; Huynh, Chuong; Kasuboski, James M et al. (2013) Helium Ion Microscopy (HIM) for the imaging of biological samples at sub-nanometer resolution. Sci Rep 3:3514